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Permit EL10-0157 - INTERNAP NETWORK SERVICES
INTERNAP NETWORK SERVICES 3355 S 120 PL EL1O-0157 Cityglif Tukwila Department of Community Development 6300 Southcenter Boulevard, Suite #100 Tukwila, Washington 98188 Phone: 206 - 431 -3670 Inspection Request Line: 206 - 431 -2451 Web site: http: / /www.ci.tukwila.wa.us Parcel No.: 1023049082 Address: 3355 S 120 PL TUKW Suite No: ELECTRICAL PERMIT Permit Number: EL10 -0157 Issue Date: 03/23/2010 Permit Expires On: 09/19/2010 Tenant: Name: INTERNAP NETWORK SERVICES Address: 3355 S 120 PL , TUKWILA WA Owner: Name: SABEY CORPORATION Phone: Address: 12201 TUKWILA INTL BLVD 4THFL , SEATTLE WA Contact Person: Name: KATHY MCINVALE Phone: 404 - 302 -9753 Address: 250 WILLIAMS ST SUITE M -100 , ATLANTA GA Contractor: Name: PRECISION ELECTRIC GROUP INC Phone: Address: 13609 NE 126 PL STE 100 , IHRKLAND WA Contractor License No: PRECIEG969PH Expiration Date: 10/08/2010 DESCRIPTION OF WORK: INSTALLATION OF UPS /SWITCH GEAR, GENERATOR CONNECTIONS, CONNECTION OF MECHANICAL EQUIPMENT Value of Electrical: NRES: 2,775,193.00 RES: $0.00 Type of Fire Protection: UNKNOWN Electrical Service provided by: SEATTLE CITY LIGHT Permit Center Authorized Signature: Fees Collected: $12,708.94 National Electrical Code Edition: 2008 LJAJni, Date: I hereby certify that I have read and examined this permit and know the same to be true and correct. All provisions of law and ordinances governing this work will be complied with, whether specified herein or not. The granting of this permit does not presume to give authority to violate or cancel the provisions of any other state or local laws regulating construction or the performance of work. I am authorized to sign and obtain this electrical permit. Signature: Print Name: 44, Date: 3-2-3 '-`V This permit shall become ull and void if the work is not commenced within 180 days from the date of issuance, or if the work is suspended or abandoned for a period of 180 days from the last inspection. doc: EL -4/07 EL10 -0157 Printed: 03 -23 -2010 • • City of Tukwila Department of Community Development 6300 Southcenter Boulevard, Suite #100 Tukwila, Washington 98188 Phone: 206 - 431 -3670 Fax: 206 - 431 -3665 Web site: http: / /www.ci.tukwila.wa.us PERMIT CONDITIONS Parcel No.: 1023049082 Address: Suite No: Tenant: 3355 S 120 PL TUKW INTERNAP NETWORK SERVICES Permit Number: Status: Applied Date: Issue Date: EL10 -0157 ISSUED 03/02/2010 03/23/2010 1: ** *ELECTRICAL * ** • 2: A copy of the electrical work permit shall be posted or otherwise made readily accessible to the Electrical Inspector at each work site. 3: Approved plans shall be maintained at the construction site and shall be readily available to the Electrical Inspector. 4: All electrical work shall be in accordance with NFPA 70 - NEC, and requirements for electrical installations, Chapter 296 -46B WAC. 5: When any portion of the electrical installation is to be hidden from view by permanent placement of parts of the building, such equipment shall not be concealed until it has been inspected and approved by the Electrical Inspector. 6: The issuance of an electrical work permit shall not be construed to be a permit for, or an approval of, any violation of the provisions of the electrical code or other ordinances of the jurisdiction. Permits or related documentation that presumes to grant this authority are therefore not valid. 7: Any change in the scope of work described by the electrical work permit shall require additional work permits. Where approved plans have been issued, revisions to the plans and additional review may be required. I hereby certify that I have read these conditions and will comply with them as outlined. All provisions of law and ordinances governing this work will be complied with, whether specified herein or not. The granting of this permit does not presume to give authority to violate or cancel the provision of any other work or local laws regulating construction or the performance of work. Signature: Print Name: R4o: y ICz r-- Date: 3 3 " doc: Cond -Elec EL10 -0157 Printed: 03 -23 -2010 CITY OF TUKWILA Community Development Department Permit Center 6300 Southcenter Blvd., Suite 100 Tukwila, WA 98188 http://www.ci.tukwila.wa.us Electrical Permit No. E L10- 015 7 Project No. (For office use only) ELECTRICAL PERMIT APPLICATION Applications and plans must be complete in order to be accepted for plan review. Applications will not be accepted through the mail or by fax. * *Please Print ** SITE LOCATION King Co Assessor's Tax No.: 8810200800 Site Address: 3355 S 120th Place Tukwila WA 98168 Suite Number: Floor: Tenant Name: Internap Network Services New Tenant: ❑ Yes VI ..No Property Owners Name: Sabey Corporation Mailing Address: 12201 Tukwila International Blvd 4th Flo Seattle City WA State 98168 Zip CONTACT PERSON - Who do we contact when your permit is ready to be issued Name: Kathy Mclnvale Mailing Address: 250 Williams St Suite M -100 E -Mail Address: kmcinvale @ internap.com Day Telephone: Atlanta City Fax Number: (404) 302 -9753 GA State 30303 Zip ELECTRICAL CONTRACTOR INFORMATION Company Name: Precision Electric Group, Inc. Mailing Address: 13609 NE 126th P1. , Suite 100 Kirkland WA 98034 City state Zip Day Telephone: 425-823-8600 Ext 1 Fax Number: 425 - 823 -8655 Contractor Registration Number: PRECI EG969PH Expiration Date: 10/08/2010 Contact Person: Mark Davi s E -Mail Address: markd@peqiinc.com Valuation of Project (contractor's bid price): $ 2 '77 S t 1 9 31 Scope of Work (please provide detailed information): 'SnS *, -4.1 -c " rF C.PS / S AA earl Q .Pntr.t4v,- (drin2c�,u^S, Lon/1fc -(!' ✓- G ` -. i, ecwolt'c J Will service be altered? ❑ Yes 0 No Adding more than 50 amps? ❑ Yes ❑ No Type of Use: Type of work: ❑ New ❑ Addition ❑ Service Change ❑ Remodel ig Tenant Improvement ❑ Low Voltage ❑ Generator ❑ Fire Alarm ❑ Telecommunication ❑ Temporary Service .Property Served by: ❑ Puget Sound Energy ' Seattle City Light H:\Applicat ions \Forms - Applications On Line\2010 Applications \I -2010 - Electrical Permit Application.doc bh Page l of 2 RESIDENTIAL NEW RESIDENTIAL SERVICE ❑ New single family dwellings $152.85 (including an attached garage) ❑ Garages, pools, spas and outbuildings $81.90 ea ❑ Low voltage systems (alarm, furnace thermostat) $59.85 ea RESIDENTIAL REMODEL AND SERVICE CHANGES ❑ Service change or alteration $81.90 (no added/altered circuits) ❑ Service change with added/altered circuits $81.90 number of added circuits $11.55 ea ❑ Circuits added/altered without service change $54.60 (up to 5 circuits) ❑ Circuits added/altered without service change $54.60 (6 or more circuits) $7.65 ea ❑ Meter /mast repair $68.25 ❑ Low voltage systems $59.85 (alarm, furnace thermostat) MULTI - FAMILY AND COMMERCIAL Fees are based on the valuation of the electrical contract. MISCELLANEOUS FEES ❑ Temporary service (residential) $63.00 ❑ Temporary service (generator) $78.75 ❑ Manufactured/mobile home service $84.00 (excluding garage or outbuilding) ❑ . Carnivals $78.75 Number of concessions $10.50 ea PERMIT APPLICATION NOTES - Value of Construction — In all cases, a value of construction amount should be entered by the applicant. This figure will be reviewed and is subject to possible revision by the Permit Center to comply with current fee schedules. Expiration of Plan Review — Applications for which no permit is issued within 180 days following the date of application shall expire by limitation. The Building Official may grant one extension of time for an additional period not to exceed 90 days. The extension shall be requested in writing and justifiable cause demonstrated. I HEREBY CERTIFY THAT I HAVE READ AND EXAMINED THIS APPLICATION AND KNOW THE SAME TO BE TRUE UNDER PENALTY OF PERJURY BY THE LAWS OF THE STATE OF WASHINGTON, AND I AM AUTHORIZED TO APPLY FOR THIS PERMIT. BUILDING OWNER OR ELECTRICAL CONTRACTOR: Signature: ^ Date: O3 ffL /ld Print Name: Mailing Address: 2(00 ( 4`4C S(.4.e SSZ Day Telephone: Zd% II? 400Q Stw'gt City t✓4 ?e1Z! Date Application Accepted: 3 _ �� 1 0 Date Application Expires: ct ..44-1/0 State Zip Staff Initials: A"1'`. H:\Applicat ions \Forms - Applications On t.ine\2010 Applications \1 -2010 - Electrical Pennit Application.doc bh Page 2 of 2 City of Tukwila Department of Community Development 6300 Southcenter Boulevard, Suite #100 Tukwila, Washington 98188 Phone: 206-431-3670 Fax: 206 - 431 -3665 Web site: http: / /www.ci.tukwila.wa.us Parcel No.: 1023049082 Address: 3355 S 120 PL TUKW Suite No: Applicant: INTERNAP NETWORK SERVICES RECEIPT Permit Number: Status: Applied Date: Issue Date: EL10 -0157 ISSUED 03/02/2010 03/23/2010 Receipt No.: Initials: User ID: Payee: R10 -00968 JEM 1165 Payment Amount: Payment Date: Balance: $63.00 06/01/2010 04:16 PM $0.00 CHAD R GRENNER TRANSACTION LIST: Type Method Descriptio Amount Payment Credit Crd VISA Authorization No. 019667 ACCOUNT ITEM LIST: Description 63.00 Account Code Current Pmts ELECTRICAL PERMIT - NONR 000.322.101.00.00 Total: $63.00 63.00 PAYMENT RECEIVED doc: Receiot -06 Printed: 06 -01 -2010 • City of Tukwila • Department of Community Development 6300 Southcenter Boulevard, Suite #100 Tukwila, Washington 98188 Phone: 206 - 431 -3670 Fax: 206 - 431 -3665 Web site: http: / /www.ci.tukwila.wa.us RECEIPT Parcel No.: 1023049069 Permit Number: EL10 -0157 Address: 3355 S 120 PL TUKW Status: APPROVED Suite No: Applied Date: 03/02/2010 Applicant: INTERNAP NETWORK SERVICES Issue Date: Receipt No.: R10 -00483 Payment Amount: $19,043.12 Initials: JEM Payment Date: 03/18/2010 12:26 PM User ID: 1165 Balance: $0.00 Payee: BNBUILDERS, INC. TRANSACTION LIST: Type Method Descriptio Amount Payment Check 49387 19,043.12 Authorization No. ACCOUNT ITEM LIST: Description Account Code Current Pmts ELECTRICAL PERMIT - NONR 000.322.101.00.00 19,043.12 Total: $19,043.12 PAYMENT RE(EIVED. doc: Receiot -06 Printed: 03 -18 -2010 • City of Tukwila Department of Community Development 6300 Southcenter Boulevard, Suite #100 Tukwila, Washington 98188 Phone: 206-431-3670 Fax: 206 - 431 -3665 Web site: http: / /www.ci.tukwila.wa.us RECEIPT Parcel No.: 1023049069 Permit Number: EL10 -0157 Address: 3355 S 120 PL TUKW Status: PENDING Suite No: Applied Date: 03/02/2010 Applicant: INTERNAP NETWORK SERVICES Issue Date: Receipt No.: R10 -00371 Initials: WER User ID: 1655 Payment Amount: $4,760.78 Payment Date: 03/02/2010 04:09 PM Balance: $19,043.12 Payee: BNBUILDERS TRANSACTION LIST: Type Method Descriptio Amount Payment Check 49066 4,760.78 Authorization No. ACCOUNT ITEM LIST: Description Account Code Current Pmts ELECTRICAL PLAN - NONRES 000.345.832.00.00 4,760.78 Total: $4,760.78 doc: Receipt -06 Printed: 03 -02 -2010 NSPECTION RECORD Retain a copy with permit INSPECTION NO. PERMIT NO. CITY OF TUKWILA BUILDING DIVISION. 6300 Southcenter Blvd., #100, Tukwila. WA 98188 (206) 431 -3670 Permit Inspection Request Line (206) 431 -2451 I 0E57 Project: khr Ake Type of Inspection: 100 Address: 535:5I .�- �� L • Date Called: r- Special Instructions: Date Wanted: /® Requester: Phone No: Approved per applicable codes. a Corrections required prior to approval. COMMENTS: h/ Inspector: Date: I n REINSPECTION+EE REQUIRED. Prior to next inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. ZZ- INSPECTION NO. INSPECTION RECORD Retain a copy with permit PERMIT NO. CITY OF TUKWILA BUILDING DIVISION 1�- 6300 Southcenter Blvd., #100, Tukwila, WA 98188 (206)431 -3670 Project: idroci.414) Type of Inspection: 70070-- Address: 3355- Date Called: Special Instructions: Date Wanted: 7/10 m. Requester: Phone No: 0 Approved per applicable codes. Corrections required prior to approval. COMMENTS: &Attu- (0/4 .I Jo eo'l/lc,erE Inspector: /3ri4e\ ❑ $60.00 REINSPECTION FEE REQUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Date: //0 Receipt No.: Date: INSPECTION NO. INSPECTION RECORD Retain a copy with permit 640.0157 PERMIT NO. CITY OF TUKWILA BUILDING DIVISION' 6300 Southcenter Blvd., #100, Tukwila, WA 98188 (206)431 -3670 Project: ',WA? Type of Inspection: Address: 355-5. ! uf .1.-Al / L.• Date Called: Special Instructions: . Date Wanted: .on 6L Requester: Phone No: Approved per applicable codes. Corrections required prior to approval. COMMENTS: Jcpod wit4-55 ,efo ftD t1Jc1 regr or (oi6oJhy /Z63o2f5 44D topcnoJ' Inspector: Date: Oft to El $60.00 REINSPECTION FEE REQUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Receipt No.: Date: ....»... 1Vac.. INSPECTION NO. CITY OF TUKWILA BUILDING DIVISION 6300 Southcenter Blvd., #100, Tukwila, WA 98188 (206)431 -3670 INSPECTION RECORD Retain a copy with permit (uo.-0157 PERMIT NO. Project: /Alto& Type of Inspection: /00 P6Rriartp v'4D6 R4-is FL-00c Address: P. . 3555 3355 5. /ZO _ Date Called: Special Instructions: Date Wanted: / 6%0 p.m• Requester: Phone No: ❑ Approved per applicable codes. Corrections required prior to approval. /t COMMENTS: -- T/C. .s4646-1147 s fr 1 vn i - ,J0 P6Rriartp v'4D6 R4-is FL-00c 04(--4) (-PR Nvt2olrj6Jr4j, A-I z Inspector: Date: 07 //2- f v `I'L'\ LI $60.00 REINSPECTION FEE REQUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Receipt No.: Date: ,•'-.k 4y...;_..,,-: w .�.,....��.•.,.._,�lv..�..,a --� = .. �, cca° �'^..<. t,. e, .,es�- �.�- �•..._fY�.- �r..,,,t�= INSPECfiION NO. INSPECTION RECORD Retain a copy with permit o PERMIT NO. CITY OF TUKWILA BUILDING DIVISION 6300 Southcenter Blvd., #100, Tukwila, WA 98188 (206)431 -3670 Project: AT t /l,i(h r n Type of Inspection: �° Address: 33 51-12-Ortn, Date Called: Special Instructions: 1 Date Wanted: 7 o a. p.m. Requester: Phone No: Approved per applicable codes. Corrections required prior to approval. COMMENTS: t Ip 3--/ 'reqf7744) bJw Inspector: Date: 07/a, f to ri $60.00 REINSPECTION FEE REQUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Receipt No.: Date: z ¢ a ?niN'_"!r2a's or�?."ist- INSPECTION RECORD Retain a copy with permit INSPECTION NO. PERMIT NO. CITY OF TUKWILA BUILDING DIVISION 1= 6300 Southcenter Blvd., #100, Tukwila, WA 98188 (206)431 -3670 alo-0(57 Project: / Type of Inspection: 749°3 Address: 3 iZv �. Date Called: ,• Special Instructions: Date Wanted: 6n . ° Requester: Phone No: giApproved per applicable codes. Corrections required prior to approval. COMMENTS: (9,4. - Coa-R1 3.d gu:04;\ go‘Atik '4 &114,61 Date: v7/00 / 17,,-.1 ri $60.00 REINSPECTION FEE REQUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Inspector: Receipt No.: Date: INSPECTION RECORD Retain a copy with permit INSPECTION NO. PERMIT NO. CITY OF TUKWILA BUILDING DIVISION (4— 6300 Southcenter Blvd., #100, Tukwila, WA 98188 (206)431 -3670 Project: n /AI ,/j'�ij' Type of Inspection: 003 Address: 3355 5 Pt- - (Zo Date Called: Special Instructions: Date Wanted: /O17 (.....rm. Requester: ,"11. Phone No: ElApproved per applicable codes. ❑ Corrections required prior to approval. COMMENTS: i 5C J LF rd r\ Yo a •�'1. Inspector: l% i7 Date: 07/0//0 $60.00 REINSPECTION FEE REQUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Receipt No.: Date: INSPECTION RECORD Retain a copy with permit INSPECT ON NO. PERMIT NO. CITY OF TUKWILA BUILDING DIVISION 1°- 6300 Southcenter Blvd., #100, Tukwila, WA 98188 (206)431 -3670 6i1O-6157 /6 Project: hire4A/440 Type of Inspection: w Address 335-5- 5 /ZDli • Date Called: Special Instructions: Date Wanted: m. Requester: Phone No: Approved per applicable codes. ❑ Corrections required prior to approval. 2 COMMENTS: I�CT I,JdqrNKoJq 1,1 Inspector. �r� &))//161\ Date: Wade D 0 $60.00 REINSPECTION FEE REQUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Receipt No.: Date: ry,..., �asmtnr�l .�,man.�4,...i�*+.e�;.wa- rya..' �- 1': T:! �.,:"'.: �;+ .; �"'? s;; Ji"`° vs�. �. �.' �"_: Y.^.'° z `+.er^Y"� +,..r °•t.^,.�iT�r,�a6. .�.. � ..�..0 �lD INSPECTION NO. INSPECTION RECORD Retain a copy with permit 610-0(57 PERMIT NO. (206)431 -3670 CITY OF TUKWILA BUILDING DIVISION 6300 Southcenter Blvd., #100, Tukwila, WA 98188 Project: ' � Type of Inspection: /903 Address: 33S�s. /1 Date Called: �- Special Instructions: Date Wanted: 7 0! a.m. I Requester: Phone No: 0 Approved per applicable codes. Corrections required prior to approval. COMMENTS: 66a/fAiii cov6K 17;441-Si zfr Inspector: Date: 61 /b ri $60.00 REINSF1ECTION FEE REQUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Receipt No.: Date: IS INSPECTION.,RECORD Retain a copy with permit (7' INSPECTION NO. PERMIT NO. 1 CITY OF TUKWILA BUILDING DIVISION 6300 Southcenter Blvd., #100, Tukwila, WA 98188 (206)431 -3670 Project: IA��� /``1'�� � Q..�� �t� m, t d5 FL4 Type of Inspection: 0 °Z - Raul (DMP676 -r rig 4 iot 5 Address: 33 5, / nt • ej� Date Called: - - 053A k 36 Akv -r 'i,dn45 42 °J4D149/ 1.or^'61 Special Instructions: Date Wanted: t0 Om /� 3 a.m Requester: Phone No: Approved per applicable codes. Corrections required prior to approval. COMMENTS: yeA w p�, ne, 4, fA ,pr, � Q..�� �t� m, t d5 FL4 - ("3 - 5fntmJS 31' (p - OP5 515761 CP4 712.01. - Raul (DMP676 -r rig 4 iot 5 _, �-0 62_00 IivQoJD/Ak - - 053A k 36 Akv -r 'i,dn45 42 °J4D149/ 1.or^'61 - ?Ix)34/iJ( N,,I 04 A-0 6110446llitlikAmici Inspector: �i Date: 063oio El $60.00 REINSPECTION FEE REQUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Receipt No.: Date: toltad INSPECTION RECORD Retain a copy with permit INSPECTION NO. CITY OF TUKWILA BUILDING DIVISION 6300 Southcenter #1 00, Tukwila, WA 98188 £i) t5 PERMIT NO. f VR (206)431 -3670 Project: 14 Jr ' Type of Inspection: 7� Address: 3355 ...5.120 J + . Date Called: -- Special Instructions: Date Wanted: a.m. Requester: Phone No: Approved per applicable codes. Corrections required prior to approval. COMMENTS: Ct(Lt1JC1 C44� Fks Mr 2046 r�Z SDdII¢ DF 4,1CIk Il'ikl/ A AID Faroe= 2.0A1!-3 Inspector: j 6(14140\ Date: D(a Z`t ID ri $60.00 REINSP CTION FEE REQUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Receipt No.: Date: INSPECTION NO. INSPECTION ,RECORD Retain a copy with permit 6/10-015-7 PERMIT NO. (206)431 -3670 CITY OF TUKWILA BUILDING DIVISION 6300 Southcenter Blvd., #100, Tukwila, WA 98188 Project: 1��r N/ Type of Inspection: 3; Address: 3;55 5. /2D Pi- Date Called: Special Instructions: Date Wanted: 6/2. 7 ren.. a: Requester: 1 Phone No: ElApproved per applicable codes. Corrections required prior to approval. Pi COMMENTS: 46043A - 516545 — M-5 (AWOL- To BE PAdE7 f WO\ Date: 96/pi lie f D $60.00 REINSPECTION FEE REQUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Inspector: Receipt No.: Date: r.?...,r•.*.....y...... =, •r- ..r�rs...,- •..r.• i_.,,._. ^•�i.«:wt...?',tr- ...f:r:".?' .•- -Se.,, ?. h" �crr;�1�- ^-- n._.s- a.+•�.•. -Si -t s- Mat -__.._ INSPECTION RECORD Retain a copy with permit INSPECTION NO. PERMIT NO. SID -D►S7 CITY OF TUKWILA BUILDING DIVISION R- 6300 Southcenter Blvd., #100, Tukwila, WA 98188 (206)431 -3670 Project: /A di' Type of Inspection: ®fin Address: Date Called: Special Instructions: Date Wanted: /24 f/ a P Requester: Phone No: &Nip 5014Di 1 Approved per applicable codes. ElCorrections required prior to approval.- COMMENTS: /16464kKok 16. 14-1'10/8 - ONAiDid 44DD - 56 - Ii 3 oAle, (4- 2 rkintipir &Nip 5014Di 1 Inspector: (4", Date: 06/2_1110 D $60.00 REINSPitCTION FEE REQUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Receipt No.: Date: INSPECTION NO. CITY OF TUKWILA BUILDING DIVISION 6300 Southcenter Blvd., #100, Tukwila, WA 98188 INSPECTION (RECORD Retain a copy with permit 6-10-01.57 PERMIT NO. 2 (206)431 -3670 Project/4/1,6w Type of Inspection: 70010- -- r3 4 I onf/9D 64oJ#JOR fly ' 7 Address: ll Date Called: Q t_sC 1 l MD 0.11T, - K1 ?-1 enkJ .7-S-- beNZL t GuJ Special. Instructions: RN 5 -lo -`$ c'IU LzixJ Date Wanted: / :m m. Requester: Phone No: Approved per applicable codes. Corrections required prior to approval. o MMENTS:,,iL,., t `lisp. S13.. t4E�' 13 H,\ (.7047 l(1(UU��''' aJ Df dJGt - 4 rwr[ / — iN5 n. 1 F ` r gJ /PII5 d p i t J, —1 Mi o -- r3 4 I onf/9D 64oJ#JOR fly ' 7 r \ -‘ L., 11(r4 - C 3- ! Tow 3-q BzL emu) Q t_sC 1 l MD 0.11T, - K1 ?-1 enkJ .7-S-- beNZL t GuJ b tSc- !/.1,6c, RN 5 -lo -`$ c'IU LzixJ otScoALi 1,-33 P- d-&Afoi 60.00 REINS ,ECTION FEE REQUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Inspector: Date:O6 t 7// 0 Receipt No.: Date: .._.cs&- i.A_ INSPECTION NO. INSPECTION RECORD Retain a copy with permit 610 -0157 PERMIT NO. �6 CITY OF TUKWILA BUILDING DIVISION 6300.Southcenter Blvd., #100, Tukwila, 'WA 98188 (206)431 -3670 Project: I Type of Inspection: Address: 3 35SS•�2vpc. Date Called: /— Special Instructions: Date Wanted: 040 (a.rry m. Requester: Phone No: ❑ Approved per applicable codes. Corrections required prior to approval. COMMENTS: Date: fx9 l t iV IT $60.00 REINSPECTION FEE REQUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Receipt No.: Date: INSPECTION NO. INSPECTION RECORD Retain a copy with permit (uo -0(57 CITY OF TUKWILA BUILDING DIVISION 6300 Southcenter Blvd., #100, Tukwila, WA 98188 PERMIT NO. (206)431 -3670 Project: r 1 d Type of Inspection: °0 3 Address: 56. /20Pi,• Date Called: -- Special Instructions: Date Wanted: / W m: Requester: Phone No: 0 Approved per applicable codes. ❑ Corrections required prior to approval. • COMMENTS: t k1 o'11 t wain 3io 400i&. SNmYFTS `/lti) Inspector: Date: OQ bo ri $60.00 REINSPECTION FEE REbUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Receipt No.: Date:. INSPECTION NO. INSPECTION RECORD Retain a copy with permit OA- 8157 PERMIT NO. CITY OF TUKWILA BUILDING DIVISION 6300 Southcenter Blvd., #100, Tukwila, WA 98188 (206)431 -3670 Project: Type of Inspection: 7. 3 ov Address:- S iza f t. Date Called: Special Instructions: Date Wanted: Q � a.m .,„ p.m. Requester: Phone No: LIApproved per applicable codes. Corrections required prior to approval. COMMENTS: Owc-K E t AJ'c wmv tAJ i 5 tie 2 504'N 5T' 3rol it0 Inspector: Date: 06 /04 0 El $60.00 REINSPECTION FEE REQUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Receipt No.: Date: ��.••.,- - .a- sar�ia,8r,.� �r.. n•• S'?. �Y- �, �Sh�t;,. �.: �+ TR.' Stsn2 "~.usstyae�i»�.%r�'�'a''�.tk3^' .•� tuo -057 PERMIT NO. INSPE ' ION NO. INSPECTION RECORD Retain a copy with permit it6 CITY OF TUKWILA BUILDING DIVISION - 6300 Southcenter Blvd., #100, Tukwila, WA 98188 (206)431 -3670 Project: 1 d,rg e p v �r - Type of Inspection: 70 Address: ` L 3355-5 Zo P. Date Called: Special Instructions: Date Wanted: 6/67/ a.m. p.m. Requester: Phone No: ElApproved per applicable codes. COMMENTS: Corrections required prior to approval. L-33 P Rc'Ocv c y2 ,,ic,4 ,,P Date: O� ®! ,� D $60.00 REIN5PECTION FEE R QUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Receipt No.: Date: 17sarn."Tark7 -,. .: 2";1- '- ''"C,.i` .eW.;c.! -r n..v.�.:'d,lY,',` �?�T r,'�•�•?�.:.s`' .?ti. INSPE ION NO. INSPECTION RECORD IfuO. 067 Retain a copy with permit PERMIT NO. (11 CITY OF TUKWILA BUILDING DIVISION 6300 Southcenter Blvd., #100, Tukwila, WA 98188 (206)431 -3670 Project:/Al hi �P Type of Inspection: -7O 03 Address: 33s5— S .120 pt. Date Called: Special Instructions: Date Wanted: / 1D m. p'i' Requester: Phone No: 9ty ca0 f 0 Approved per applicable codes. Corrections required prior to approval. COMMENTS: ezu6K1/4 tAkai4,5 ,ten 040.),19 `JUVIT/,Nrlon) Inspector: /I �� Date: 06 0. 10 ❑ $60.00 REINSPECTION FEE REQUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Receipt No.: Date: INSPECTION NO. INSPECTION RECORD Retain a copy with permit (�67 PERMIT NO. 1 CITY OF TUKWILA BUILDING DIVISION °`-- 6300 Southcenter Blvd., #100, Tukwila, WA 98188 (206)431 -3670 Project: /4 env' ( kr) Type of Inspection: DO Address: 3355" 5 .at) pi,- Date Called: ` Special Instructions: Date Wanted: 07 a r p.m. Requester: f Phone No: Approved per applicable codes. El Corrections required prior to approval. COMMENTS: D 41- e0 6c amouA uPs a4D Aid . vzNrlitic 2oo/ Date: V L? 60 ri $60.00 REINSPECTION FEE REQUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Receipt No.: Date: _.:> ..... .cdu :. iA. .sla°i�_cmo��?"- .3..'°'T:i : giryi �.`"'r_,cakr,s„•rr �a�nG�:3�'tzvy -arCt s...,,s,1 •as .1c INSPECTION RECORD OAD-Oi57 Retain a. copy with permit INSPE ION N0. PERMIT NO. CITY OF TUKWILA BUILDING DIVISION 6300 Southcenter Blvd., #100, Tukwila, WA 98188 (206)431 -3670 Project: jj�. jj �pp tlU rV Type of Inspection: l ooy Address: \\ 33SSs•/2011-. Date Called: ..--- Special Instructions: ,:. Date Wanted: S 2- a.r p.m. Requester: Phone No: Approved per applicab odes. COMMENTS: Corrections required prior to approval. bt4hPT5 64 E 04E IJ Dirlt vi 0a4,/b A . Odi Inspector: Date: ©5121 /0 r7 $60.00 REINS'ECTION FEE REQUIRED. Prior to inspection, fed must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Receipt No.: Date: _ 6 _w ]&. —'._.... N"..? tii'..✓" t+-^ 1F\ �v. art.._ i_.J•':!"'.^t.7`"!'w- ..:Y�.v... ...f -.. sa?` � _ru._�.....— ....._�.!5.:,i�_... INSPECTION. RECORD Retain a copy with permit Guo'Dis7 PERMIT NO. A (2'06)431 -3670 CITY OF TUKWILA BUILDING DIVISION 6300 Southcenter Blvd., #100, Tukwila, WA 98188 Project: r n Type of Inspection: 70 3 Address: 3355 S. Pi- Date Called: .., Special Instructions: - Date Wanted: /� j (/ / a.m m. Requester: Phone No: Approved per applicable codes. Corrections required prior to approval. COMMENTS: Co6S 64A-Fr Rizei< cadOtir - IA1. Ana o/ C rr 6x/r id ,d rn c4Mgt/ ) Inspector: Date: 05,..-/24 L1 $60.00 REINSPECTION FEE REQUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Receipt No.: Date: -WetNL.: w t#"a�u ,� INSPECTION NO. INSPECTION RECORD Retain a copy with permit PERMIT NO. CITY OF TUKWILA BUILDING DIVISION 6300 Southcenter Blvd., #100, Tukwila, WA 98188 (206)431 -3670 (6 Project:'d � Type of Inspection: 7003 Address: .ass s. . ,Z�P� Date Called: Special Instructions: Date Wanted: a.m; Requester: Phone No: Approved per applicable codes. Corrections required prior to approval. tit COMMENTS: klA-t�/ CAJ ' i c. 'f ti kOCI k►3> CZI.0 t1tsi Inspector: Date: 0011/0 El $60.00 REINSPECTION FEE REQUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Receipt No.: Date: . INSPECTION RECORD' -'V 1t Retain a copy with permit INSP CTION NO. PERMIT NO. CITY OF TUKWILA BUILDING DIVISION , 6300 Southcenter Blvd., #100, Tukwila, WA 98188 (206)431 -3670 (6 Project: No44) Type of Inspection: Dt%- Address' ul J 55 5 f / ak. Date Called: Special Instructions: Date Wanted: % a.my Pim Requester: Phone No: ❑ Approved per applicable codes. El Corrections required prior to approval. COMMENTS: :1/64-41), 1-14k ouv Inspector: Date: A 5 0? El $60.00 REINSPECTION FEE REQUIRED. Prior to inspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. Receipt No.: Date: 0 LEE TECHNOLOGIES` • • ghlt INTERNAP6 Internap TEC100049 Data Center Expansion Phase 3 & 4 Tukwila Washington Commissioning Report 07/30/3010 HERBERT E. BURNETT, TECHNICAL SPECIALIST LEE TECHNOLOGIES SERVICES, INC. 12150 MONUMENT DR. SUITE 150, FAIRFAX, VA 22033 ©2010 ELIO-- 0 i51 RECEIVED JAN 06 2011 PERMIT CENTEF • • INTERNAP• Internap Data Center Expansion Phase 3 & 4 Tukwila Washington Commissioning Report 7 -30 -2010 LEE TECHNOLOGIES' July 21, 2010 City of Tukwila Department of Community Development 6300 Southcenter Blvd. Suite 100 Tukwila, WA 98188 -2544 Attn: Mr. James Dunaway Senior Building Inspector Re: Internap -Phase 3 Permit #D10 -058 Permit #M10 -030 • Dear Mr. Dunaway: LEE TECHNOLOGIES' Lee Technologies- Mission Critical Infrastructure Solutions has been retained by Internap to perform the commissioning of the Internap phase 3 facility located at the Sabey Property in Tukwila, WA. We have been involved with project since March 2010 and we have been onsite over the past month. We have observed and performed substantial testing on the MEP systems and we observe the systems are operating as intended and designed. We have attached field copies of many of these tests. If you have any questions, please don't hesitate to call. Again, it is Lee Technologies' observation that systems are operating as designed. Sincerely, Herbert E. Burnett, Jr. Lee Technologies • . L � LEE TECHNOLOGIES" EXECUTIVE SUMMARY 1) COMMISSIONING ACTION LIST 2) EQUIPMENT LIST 3) ELECTRICAL ATO/ SWITCHBOARD TABLE OF CONTENTS • 4) GENERATOR COMMISSIONING REPORT/ SYSTEM INTEGRATION 5) PDU COMMISSIONING REPORT 6) UPS DRANETZ REPORTS & COMMISSIONING REPORTS 7) EPO/ FIRE/ 1ST SUMMARIES 8) MECHANICAL: (CRACS, DRYCOOLERS, FANS, FUEL OIL, GLYCOL PUMPS, HUMIDIFIERS, LIFT PUMPS, ROOF TOP UNITS) • LEE TECHNOLOGIES' Commissioning Report INTERNAP TUKWILA, WASHINGTON 010 IIVTERNAF" INTERNAP TUKWILA, WASHINGTON COMMISSIONING REPORT Page 1 of 10 Lee Technologies Group © Copyright 2010 Proprietary use Pursuant to Company Policy LEE TECHNOLOGIES' 4,/, 4;16/ Table of Contents INTERNAP 'TUKWILA, WASHINGTON COMMISSIONING REPORT Executive Summary 3 Equipment Inspection and Commissioning 3 Commissioning Procedures and Integrated Systems Test 3 Equipment Testing 4 Electrical Equipment 4 Stand -by Generator 2250 KW 4 Switchgear 5 ATO Switchgear 5 UPS System w /Full Duty 2000 amp Static Switch 5 Power Distribution Unit 5 Emergency Power Off 5 Mechanical Equipnient Computer Room Air Handlers w/Dry cooler, Pump package 6 Roof Top Unit 6 Humidifier 6 Fire Alarm System 6 Fuel System 7 Integrated System Testing (1ST) 7 Purpose 7 Overview 7 Integrated System Testing Results 8 Overview 8 Fuel System Operation 8 Results of Roof Top Unit Operation 8 Results of CRAC Unit Operation 9 UPS Testing 9 Loss of Utility Power 9 Return to Utility 9 Conclusion 10 Lee Technologies Group © Copyright 2010 Proprietary use Pursuant to Company Policy Page 2 of 10 LEE TECHNOLOGIES' 4;46/41 • INTERNAP TUKWILA, WASHINGTON COMMISSIONING REPORT EXECUTIVE SUMMARY Lee Technologies is pleased to provide this report on the testing and commissioning of the Internap data center in Tukwila, WA. As of July 22, 2010, the Internap data center has been commissioned and is ready to provide reliable power from the UPS system to the critical load equipment via utility and the power generation systems. Environmental support has been fully installed and tested to a point that Lee Technologies feels will provide adequate air conditioning. Equipment commissioned included the following: • (3) 2.25 MW Standby Generators • (1) 8000 amp Switchgear • (1) ATO Switchboard UPS 4000 amps • (4) UPS module and Battery Cabinets w/Full duty 2000 amp static switch • (2) Switchboard 3000 amps • (14) Power Distribution Unit • (1) Emergency Power Off (EPO) System. • (5) 130 Ton Roof Top Units • (5) Humidifier • (4) 20 Ton CRAC units. • (2) 55 Ton Drycooler units. • (1) Pump package • (1) Fire Alarm Panel • (1) Fuel System Equipment Inspection, Installation, Pre Startup, Startup, and Commissioning: Each piece of equipment that was integral to the operation of the critical environment was started up by the equipment vendor in accordance with vendor supplied startup checklists. During the startup process, Lee Technologies provided guidance and ensured compliance with specifications and design parameters at all times. In addition to the factory supplied startup sheets, Lee Technologies developed detailed commissioning procedures. This ensured that they were properly completed to verify operation and installation of the critical equipment. These procedures were tailored specifically for Internap and provide detailed step -by -step guidelines to be followed. The checklists have been supplied to the customer and can be found in the applicable binders. Commissioning Procedures were used to document Operations Acceptance Testing. Each procedure was developed using contract documents, operations and maintenance manuals, and engineering specifications and drawings to verify proper operation and installation of the individual pieces of equipment and systems in which they operate. These procedures were detailed step -by -step testing procedures designed to monitor and verify the equipment is installed properly, not damaged, operates as designed, and is properly integrated into other systems. Lee Technologies Group © Copyright 2010 Proprietary use Pursuant to Company Policy Page 3 of 10 et LEE TECHNOLOGIES" INTERNAP TUKWILA, WASHINGTON COMMISSIONING REPORT Integrated Systems Testing was performed on all critical power systems to display how all systems work together, rather than just each system individually. Systems may operate without issue as a stand -alone module; problems may arise when they are used in conjunction with other systems which may not have been otherwise identified until an emergency situation arose. Power quality analysis test equipment, temperature analysis probes, and other testing devices were used during testing to provide objective quality evidence of the parameters being monitored at all times. Testing that was performed during the Integrated Systems portion of testing was, but not limited to: • Generator compatibility with UPS systems: It was quite possible that the output signals from the standby generators did not fall within the acceptable input tolerance of the UPSs. This would result in the UPS "rejecting" the supplied input, discharging the batteries, and eventually leading to loss of the critical load. Generators were run to supply power to the UPS systems to ensure that the generators and UPSs would supply power to the load without adverse results. • Simulated heat load in datacenters: A portable heat generating load bank was connected to the Power Panels in the server room to ensure that design heat load was evenly distributed. This ensured that the RTU system would maintain proper temperature and humidity conditions within the datacenter and also throughout the entirety of the RTU system. The room was loaded with as close to design load as possible and was given time to stabilize to uncover any potential problems. • Test transfers of the switchgear: The distribution switchgear was tested by simulating failure conditions to ensure that with a loss of utility power, the switchgear would identify the loss of utility, it would work in conjunction with the generators to bring standby generators on line, and re- supply power to the load. • Transfers of system to bypass operation: The systems were placed into maintenance bypass and regular bypass operational lineups. Interlocks of various systems were verified to operate as designed. Potential problems such as improperly terminated wires, incorrect key location, and incorrect key labeling were verified non - existent so that all procedures could be properly performed if and when they were actually needed. Maintenance bypass lineup procedures were performed while under load while using dedicated monitoring equipment to ensure that power was maintained at all times. EQUIPMENT TESTING Lee Technologies Services did participate in the installation inspection and performed commissioning and testing on each piece of equipment. The following is a summary of some of the findings of these inspections and testing. The complete list of outstanding and resolved discrepancies can be found in the Commissioning Action List (CxAL) section. Electrical Equipment: Standby Generators: • Generator 4 threw a rod during the load bank test. • Generator 4, 5, and 6 were load tested for four hours at 2.2 MW with a resistive load bank. Page 4 of 10 Lee Technologies Group © Copyright 2010 Proprietary use Pursuant to Company Policy LEE TECHNOLOGIES" 41;i6,/4111 INTERNAP T IJKWILA, WASHINGTON COMMISSIONING REPORT Switchgear: • Switchgear was started up by GE and was tested to verify it is capable of providing reliable power to the critical load. • Tested the switchgear in both auto and manual mode and verified the interface with the generators. ATO Switchgear: • Switchgear was started up by GE and was tested to verify it is capable of providing reliable power to the critical load. • Tested the switchgear in both auto and manual mode and verified the interface with the generators. • Switchgear did not display any current of KW during the IST. GE had to change software for sensing current and KW in the equipment. UPS System: • The new UPS system was installed, started up and commissioned to verify proper operation. • Conducted step loading of the UPS system at 25 %, 50 %, 75% and 99% of rated load. • The UPS system was tested at 99% load for 4 hours. • Infrared scanned UPS and battery cabinet associate with the UPS system. No hot spots were found in any of the items. • Lee Tech conducted a battery rundown test on UPS System. o UPS module 1 had a battery runtime of 8 minutes 13 seconds. o UPS module 2 had a battery runtime of 8 minutes 20 seconds. o UPS module 3 had a battery runtime of 8 minutes 17 seconds. o UPS module 4 had a battery runtime of 8 minutes 12 seconds. • Transferred UPS system to generators during the IST. Power Distribution Units: • PDU 3A4 amp readings were wrong. • PDU 3A5 had a low voltage alarm between phase A -B • PDU 3B3 Phases A and B amp readings were higher than the actual reading. Emergency Power Off: • No issues were found with the EPO. Lee Technologies Group © Copyright 2010 Proprietary use Pursuant to Company Policy Page 5 of 10 LLEE TECHNOLOGIES" Mechanical Equipment: INTERNAP TUKWILA, WASHINGTON COMMISSIONING REPORT Computer Room Air Compressor Units (CRACs): • CRAC 3 -1 Compressor circuits 1 and 2 have bubbles in the site glass during operation. • CRAC 3 -4 Compressor circuit 1 has bubbles in the site glass during operation. • BMS is not receiving a loss of power or communication when power is off at the CRAC. It shows the last known status of the unit. • Dry Cooler fans are not coming on with the outlet water temperature at 100 °F. • DC -2 fans 3 and 4 contactor is not pulling in when the unit stages up. • DC -1 fan #4 has heavy vibration during operation. Roof Top Unit: • RTU's do not have access to the area forward of the supply fan. This does not allow McQuay the access to remove the shipping hold downs on the forward fan isolators. • RTU's require access to the area forward of the supply fan for maintenance of the forward bearing. • RTU's are dual fed, there needs to be signage that warns of two power sources going to the unit. • RTU's have trash and debris inside the units. • RTU 3 -3 Supply fan J -box is loose and missing screws. • RTU 3 -5 has water under the drip tray, appears to be from an overflow of the drip tray. • RTU isolation dampers are not shutting when the unit is shut down. The RTU's disconnect must be open or shut by Fire alarm for the dampers to close. Humidifier: • Humidifier automatic fill and drain valves are not electrically termin • Humidifier manual drain isolation valves are shut. This is due to the operating. • Humidifier second stage solenoid valve is not electrically connected • Humidifier submittal schematic does not match the schematic of the • Humidifiers basins have trash and debris in them. • HUM 3 -2 door hits the drain solenoid valve handle. • HUM 3 -2 piping leaking at the brazed union above pump. • HUM 3 -1 basin float requires adjustment; the level is running to higl • HUM 3 -1 union leaking downstream of the solenoid valve. • HUM 3 -5 door is hitting the automatic drain solenoid valve handle. ated. automatic drain valves not in the control panel. one supplied with the unit. 1. Page 6 of 10 Lee Technologies Group © Copyright 2010 Proprietary use Pursuant to Company Policy LEE TECHNOLOGIES" %,"/ • HUM 3 -4 union at the piping tee is leaking. • HUM 3 -2 automatic fill and drain valves do not shut. INTERNAP TUKWILA, WASHINGTON COMMISSIONING REPORT Fire System: • Phase 3 strobes are rated at 30 candelas, but the Fire Marshal stated that the construction prints should have been changed to 75 candelas. • Phase 4 strobes are rated at 30 candelas, but the Fire Marshal stated that the construction prints should have been changed to 75 candelas. • Entry door to the Fire Alarm Panel room does not have a sign stating that there is a FACP in the room. • Panel P -33 which feeds the Fire Panel is missing a breaker lock. Fuel System: • Fuel Oil Emergency Shut Down valves do not operate as Normal Open valves. • Return pump comes on at the High Level alarm, but shuts off as soon as the High Level float seat. • Phase 1 Fuel oil control panel PLC needs to be replaced to allow the connection of the Phase 3 control panel for operation of the supply pumps. • Fuel flow in to Day Tanks has been noted at 1 tank 17gpm, 2 tanks lOgpm, and 3 tanks 7gpm. This could be a problem when all six Day Tanks are calling for fuel. • Fuel Oil system is unable to meet the demand of six Day Tanks calling for fuel. • Leak Detect alarm comes in when the power is restored after power has been cycled. INTEGRATED SYSTEM TESTING (IST) Purpose: After each piece of equipment and sub - systems have been started up and tested, it is necessary to verify that all systems operate together to maintain reliable power and cooling to the critical environment. The Integrated System Testing (IST) is used to determine if electrical and mechanical equipment is ready for use and if design reliability and redundancy can be expected. Overview: Participants included Internap, BNBuilders, Rubicon, and Lee Technologies, Inc. Subsystem performance has already been tested to specifications. During the IST, the integrated systems were tested to design intent. The testing was managed by Lee Technologies and validated the following items prior to acceptance: • Installation integrity including wiring and terminations. Weak components, loose internal connections, "hot spots ", and manufacturing defects may not fail until they are heated and operated at full design load for a prolonged period of time. The purpose of the heat loading and operating a full design load during the IST. Thermo graphic imaging of all accessible power components will reveal "hot spots" requiring immediate attention. Page 7 of 10 Lee Technologies Group © Copyright 2010 Proprietary use Pursuant to Company Policy LEE TECHNOLOGIES' INTERNAP TUKWILA, WASHINGTON COMMISSIONING REPORT • Power failure test for proper output voltage during transition from normal to battery operation on the UPS, and for UPS acceptance of generator power. This will include momentary and extended outages and various failures during these outages. • UPS input and output voltage and current measurement and waveform observation, from very light load to full load, to verify specification compliance and UPS /Generator compatibility, especially for items such as harmonic distortion, input power factor, and UPS acceptance of generator power. • UPS inverter failure test via simulation, to test for proper output voltage during transition from normal to static bypass operation. • RTU performance and redundancy tests, startup, cycling and system operation. Verify systems will operate as designed during momentary power outages as well as extended power outages with no operator action. Also, will test the operation of the system to recover from equipment malfunctions or failures to maintain continuous cooling to the critical environment • CRAC performance and redundancy tests, startup, cycling and system operation. Verify systems will operate as designed during momentary power outages as well as extended power outages with no operator action. Also, will test the operation of the system to recover from equipment malfunctions or failures to maintain continuous cooling to the critical environment. • These tests will provide benchmarking performance data and operation for future preventive and corrective maintenance, testing or troubleshooting. Any areas that are weak but within specification will be documented for close observation during future testing. Integrated System Testing Results Overview: Integrated system testing by artificially loading the electrical distribution system with resistive load banks connected to the maintenance bypass cabinet of both UPS modules. Results of Fuel System Operation: During the mechanical systems verification, it was found that all Day Tanks performed as designed. Fuel Oil system was found to have various issues that are further outlined in the Commissioning Action List. Recommend the Fuel Oil system as a whole have an Engineering review. Recommend that the Day Tank Low Level alarms be moved up to 25% to match Day Tanks 1, 2, And 3. Results of RTU Operation: During the mechanical systems verification, it was found that all RTU's performed as designed removing all simulated load heat that was generated. RTU's were found to have various issues that are further outlined in the Commissioning Action List. This does verify redundancy capability in a sense but could leave open the possibility for unknown factors affecting airflow and cooling. Lee Technologies Group © Copyright 2010 Proprietary use Pursuant to Company Policy Page 8 of 10 LEE TECHNOLOGIES" INTERNAP TUKWILA, WASHINGTON COMMISSIONING REPORT Results of CRAC Operation: During the mechanical systems verification, it was found that all CRACs performed as designed removing all simulated load heat that was generated. CRACs were found to have various issues that are further outlined in the Commissioning Action List. This does verify redundancy capability in a sense but could leave open the possibility for unknown factors affecting airflow and cooling. UPS Testing: The UPS system was step loaded to test the unit's ability to handle load steps. Then the unit was burned in for four hours at 1822 KW. This was conducted on the entire system. There were no problems found during the burn in. An Infrared scan was conducted on each UPS module and battery cabinet during level 4 testing. Everything checked out ok from the infrared scan. Each UPS module passed its battery run down test above the required design of 8 minutes. The UPS system accepted generator power without any issues. As while as the UPS system transferring to static switch with 1822 KW on the system without any problems The UPS system was transferred to static bypass without any issues. UPS system was taken to maintenance bypass to verify proper sequencing as for system maintenance procedures on emergency power. UPS system has meet design intent at N +1. Loss of Utility Power: Under simulated load in the data center, normal power was removed at the service entrance main. Generators started without any issues and the ATO switchgear for both the mechanical and electrical equipment transferred to generator power without any issues. The rise rate was 3.3 degrees per minutes when transferring from normal to emergency power in the data center. Once the Roof Top Units staged back online from the outage, they rejected the heat in the data center. The CRAC units restarted after the loss of power and rejected the heat in the UPS room. During the entire transfer from utility to generator power, the critical loads in the data center remain online via the UPS system. Return to Utility: Under simulated load conditions utility power was restored. The ATO switchgear sensed adequate and stable power and began a time delay count down. Once the time delay expired the ATO switchgear conducted open transition to the available utility power and the standby generators went into cool down. The UPS maintained the critical load during this retransfer. The integrated system- testing portion was completed. The design intent was meet under this test. Page 9 of 10 Lee Technologies Group © Copyright 2010 Proprietary use Pursuant to Company Policy LEE TECHNOLOGIES" 4;0 INTERNAP TUKWILA, WASHINGTON COMIVIISSIONING REPORT Conclusion: Lee Technologies has verified through commissioning and testing that the critical equipment within the Internap facility is capable of maintaining continuous electrical power under normal and casualty conditions. There are some minor discrepancies that need to be resolved and /or corrected to ensure continued reliable operation of the facility that are further outlined in the Commissioning Action List. Lee Technologies Group © Copyright 2010 Proprietary use Pursuant to Company Policy Page 10 of 10 • 08/24/2010 Internap Phase 111 & IV Cxing Action List Project Manager: Publish Date: Revision Date: Marc Maities June 14, 2010 August 24, 2010 %I. LEE TECHNOLOGIES Pro ect co.e @gip uescn•tion: ( f•'-th closed uata venter uxmg Summary JltrflTrtl action By Precision Electrical Protect -nor Action (a Remarks Description CQ Discrepancy DI. r • nit INAP #1 06/23/2010 Closed 06/24/2010 USS -3 unloaded output voltage as measured by DVM and metering is 470 volts. Substation Voltage sags when loaded High INAP #2 06232010 Closed 06/24/2010 USS-4 unloaded output voltage as measured by DVM and metering is 470 volts. Substation Precision Electrical Voltage sags when loaded High INAP #3 06/28/2010 Closed 07/03/2010 BTU's do not have access to the area forward of the supply fan. This dots not allow Mc Quay the access to remove the shipping hold downs on the forward fan isolators. Roof McQuay/ Auburn Operation of the fan with the hold down in place could cause damage to the fan if not removed Low 1214 received to remove forward plenum and reinstall with angle pieces. For access to the blocks INAP #4 06/28/2010 Closed 07/06/2010 RTU's require access to the area forward of the supply fan for maintenance of the forward bearing Roof McQuay/ Auburn Low t nere is a grease line in place to allow for the greasing of the forward bearing INAP #5 06/30/2010 Closed 07/06/2010 Fuel oil Emergency Shutdown valves do not operate as Normal Open valves. The valves have been removed and a jumper installed to allow filling of the Day Tanks. New valves are on order Generator Room Northwest / Auburn Emergency shutdown is required for safety of the Day tanks High Valves have been replaced with the correct solenoid INAP #6 06/30/2010 Closed 07/15/2010 Return pump comes on at the High Level alarm but shuts off as soon as the High level float seats. The pump should continue to operate down to 85%. Generator Room Northwest / Auburn Retum Pump logic needs work correctly for safety of the system High Correction have been made in the programming, verified during Level 4 INAP #6 06/30/2010 Closed 07/02/2010 Phase 'Fuel 00 control panel PLC needs to be replaced to allow the connection of the Phase 3 Control Panel for operation of the Supply Pumps Generator Room Auburn Day Tanks can not be tilled in auto. High Monte Programmer installed new PLC and verified /corrected PLC for INAP 67 07/02/2010 Closed 07/02/2010 PDU 3A4 Amp readings were wrong. The Control panel requires calibration Data Center PDI Low 07/02/2010 PDI verified CT turn ratio and Reprogrammed the control panel Lee Technologies (c) 2009 All Rights Reserved Revised Page 1 08/24/2010 Cxing Action List Project Manager: Publish Date: Revision Date: Project Scope Description: Marc Maities June 14, 2010 August 24, 2010 Data Center Cxin LEE TECHNOLOGIES" @aMp El L DQ2 Summary Description C4 Discrepancy Mr. Orzi i Action By Project Action Remarks DiscrepancyGZ3i 0.0 1 8 INAP #8 07/02/2010 Fuel flow in to Day Tanks have been noted at I tank 17 gym, 2 tanks 10 gpm 3 tanks 7 gpm. This could be a problem Open when all 6 Day Tanks are calling for fuel Generator Room Rubicon If fill rate falls below consumption rate this could starve the generators of fuel High This will be verified at Level 4 INAP #9 07/03/2010 PDU 3A5 had a low. voltage alarm between Phasc A -B Closed 07/20/2010 during load hank testing, the alarm was cleared. Data Center PDI Low PDI corrected the issues with the unit INAP #l0 07/032010 PDU 3B3 Control Panel requires calibration, Phases A and Closed 0720/2010 B Amps are reading higher than actual Amperage Data Center PDI Low PDI corrected the issues with the unit INAP # 1 I 07/03/2010 Closed 07/09/2010 Lift Station transformer needs to he replaced Breezeway Auburn Pumps are none operational Low Transformer received and replaced INAP #12 07/082010 Closed 07/212010 . CRAC 3 -1 Compressor systems 1 and 2 have bubble in the sight glass during operation. Recommend that the vendor verifies the refrigerant charge correct UPS room Stutz Low Stutz has investigated, the hot gas and pressures were with in tolerance. They did not add any refrigerant to the systems. Stulz indicates refrigerant level is ok INAP #13 07/082010 Closed 07/21/2010 CRAC 3-4 Compressor system 1 has bubbles in the sight glass during operation. Recommend that the vendor verities the refrigerant charge correct UPS room Stutz Low Stulz has investigated, the hot gas and pressures were with in tolerance. They did not add any refrigerant to the systems. Stutz indicates refrigerant level is ok INAP #I4 07/082010 Closed Dry Cooler fans were not coming on with the outlet water at 100 degrees (at the inlet of the CRAC's) ATS disconnected the thermostat to cause all the fans to start. This allow the load banking of the UPS to continue Roof Stutz The Dry Coolers must he fully operational to support the operation of the CRAC's High Stutz investigated the controls, the Dry Cooler adjustment has been made. There still needs to be a set point temperature agreed on. • Lee Technologies (c) 2009 All Rights Reserved Revised • • Page 2 ae/24i2Cixing Action List Project Manager: Publish Date: Revision Date: Proiect Scope Description: Marc Maitles June 14, 2010 August 24, 2010 Data Center Cxin • 41 LEE TECHNOLOGIES" t p • � Acr�tlon closed Summary LIrX ($i� Action By Project Action Remarks Description �Q Di n (; Qly Discrepancy " IJJL JC Breezeway Auburn Low INAP #15 07/09/2010 Closed 07/19/2010 The till rate of two RTU drains over comes the flow rate of the Lift Pumps There is a possibility that when the Drain Valves open once a week or for freeze protection the collection tank may over flow The pumps were running backwards, pumps have been corrected. The pumps kept up with three RTU's INAP #16 07/10/2010 Closed 07/14/2010 RTU's are dual source feed, there need to be signage that warns of two power sources going to the unit Roof Bellevue This is a safely issue High Signage has been attached INAP #17 07/10/_010 Closed 07/14/2010 RTU's have trash and debris in side the units. Roof Bellevue Low RTU's have been cleaned out INAP #18 07/10/2010 Closed 07/17/2010 RTU 3 -3 Supply fan J box is loss and missing the screws Roof PEG Low INAP #19 07/10/2010 Closed 07/14/2010 RTU 3 -5 has water under the coil drip tray, appears to be from an over flow of the drip tray Roof Bellevue Could cause a flooding in the unit High Water has cleaned out of unit INAP #20 07/10/2010 Closed 07/19/2010 Humidifier automatic fill and drain valves are not electrically terminated Roof ATS The weekly drain and filI of the basin and the freeze protection not operational High wiring has been corrected INAP #21 07/10/2010 Closed 07/17/2010 Humidifier manual drain isolation valves are shut, this is due to the automatic drain valves not operating Roof Bellevue Low INAP #22 07/10/2010 Closed 07/14/2010 Humidifiers second stage solenoid valve is not electrically connected in the control panel. The units are a single stage unit at this time. The submittal shows the units as two stage humidifiers Roof Bellevue Humidifiers can not go into full humidification or partial humidification at this point High Units are a single stage humidifier INAP #23 07 /10/2010 Closed 07/20/2010 Humidifier submittal schematic does not match the schematic of the supplied with the unit. Roof Bellevue Low Corrected schematic has been place in the units Lee Technologies (c) 2009 All Rights Reserved Revised Page 3 08/24/2010 Cxing Action List Project Manager: Publish Date: Revision Date: Project Scope Description: Marc Maitles June 14, 2010 August 24, 2010 Data Center Cxin LLEE TECHNOLOGIES' @E p G Ell am C l _ Summary (14-r-4,111:1-") Action By Bellevue Project e Action ". - Remarks Description CQ DI Qty FL�3 This could hang up the pump or the drain valves. Di - C = l2auF>;i,J INAP #24 07 /10/2010 Closed 07/17/2010 Humidifier basins have trash and debris in them Roof High INAP #25 07/10/2010 Closed 07/19/2010 HUM 3 -2 door hit the drain solenoid valve handle - Roof Bellevue This can cause damage to the valve and hindcr access to the unit High This can not be changed due to the routing of the pipes INAP #26 07/10/2010 Closed 07/20/2010 HUM 3 -2 piping leaking at the brazed union above pump Roof Bellevue The Icak could get worse, making the humidifier ineffective High Leak has been corrected INAP #27 07/102010 Closed 117 /19/2010 HUM 3 -1 Basin float requires adjustment, the level is running to high Roof Bellevue The water level is at the edge of the overflow High Float has been adjusted INAP #28 07/102010 Closed 07/19/201(1 HUM 3 -1 union leaking down stream of the solenoid valve Roof Bellevue Low Leak has been corrected INAP #29 07/10/2 2010 Closed 07/19/2010 HUM 3 -5 Door is hitting the automatic drain solenoid valve handle Roof Bellevue This can cause damage to the valve and hinder access to the unit High This can not be changed due to the routing of the pipes INAP #30 07/10/ 2010 Closed 07/192010 HUM 3-4 Union at the piping tee is leaking Roof Bellevue Low Leak has been corrected INAP #31 07/102010 Closed 00/14i/20(0 UPS Static Switch has a bad blower micro switch UPS room MGE- APC Prevent full operation of UPS High INAP #32 07/102010 Closed 07/142010 Gen #4 throw rod during load testing Generator Room CAT Generator is Inoperable Critical CAT repaired and replaced parts. Lee Technologies (c) 2009 All Rights Reserved Revised • • Page 4 • 08/24/2010 Cxing Action List Project Manager: Publish Date: Revision Date: Marc Maitles June 14, 2010 August 24, 2010 Data Center Cxin • el LEE TECHNOLOGIES° 12e214) Action DIN — Summary i Action By Project e Action COD Remarks (kVA High Description ( Qut:1 [ Final Fire is not complete Changed the switch to 75 vice 30 candela. INAP #33 07/13/2010 Closed 07/15/2010 Phase 3 strobes are rated at 30 candelas but Fire Marshal stated the construction prints should have been changed to 75 candela. Phase 3 Data Center Fire Chief INAP #34 07/13/ 2010 Closed 07/15/2010 Phase 4 strobes are rated at 30 candelas but Fire Marshal stated the construction prints should have been changed to 75 candela. Phase 4 Data Center Fire Chief Final Fire is not complete High Changed the switch to 75 vice 30 candela. INAP #35 07/13/2010 Closed Phase 4 smoke detectors (159, 160, 163 & 164) have duplicate numbers of the final construction drawings. Phase 3 Data Center Fire Chief Final Fire is not complete High INAP #36 07/13/2010 Closed 07/13/2010 Riser 3 -17 activated upon activation of smoke detector 4- 178 instead of riser 3 -19. Riser Room Phase 4 Data Center Fire Chief Final Fire is not complete High Reprogrammed fire panel. INAP #37 07/14/2010 Closed 07/17/2010 BMS is not receiving a loss of power or communication when the power is off at the CRAC. It show the last known status of the unit. UPS room ATS BMS does not recognize that the CRAC is down, so it does not roll to the stand -by unit. Low INAP #38 07/15/2010 Closed DB- UPS -3A/3B energize transfer sequence step is incorrect. States opening DB- MACH -3Aor 313 should state S13-UPS -B starts Generators Electrical Distribution Room PEG Could cause operation of the wrong breaker High INAP #39 07/15/ 2010 Open Fuel Oil system is unable to meet the demand of 6 Day Tanks calling for Fuel Generator Room Rubicon Could cause the Generators to starve of Fuel • High This issue follows line item #8 INAP #40 07/15/2010 Closed Entry Door to the Fire Alarm Panel room does not have a sign stating that there is a FACP in the room INAP Lohhy Fire Chief Low INAP #41 07/15/ 2010 Closed Panel P -33 which feeds the Fire Panel is missing a breaker lock INAP Lohhy INAP Low Lock has been installed on the breaker Lee Technologies (c) 2009 All Rights Reserved Revised Page 5 °8124i2 ing Action List Project Manager: Publish Date: Revision Date: Marc Maities June 14, 2010 August 24, 2010 *l LEE TECHNOLOGIES" vro ect co ,CESID se uescn.non: � aGDP• Y,1 uara t.enrer t„xtng Summary Mr'fit i Action B ATS Project G2aZiO -"ior ActionRemarks N:151 Low 1:= Discrepancy Giiiiri1 Description CQ Di ( Quj This can cause a loss of appropriate air flow into the data center Roof INAP #42 07/152010 RTU isolation dampers are not shutting when the unit is shut down. The RTU's disconnect must be open or shut by Fire Closed 07 /17/2010 alarm for the damper to close Dampers shut when the RTU's are shutdown INAP #43 07/16/2010 Closed 07212010 lB MECH3A section 3 is missing a cover plate under the TVSS and over the CRAC 3 -1 and CRAC 3 -2 breaker sections Switchgear room PEG Low INAP #44 07/16/2010 Closed 08/02/2010 DC -2 fans 3 and 4 contactor is not pulling in whcn the unit stages up. Roof Stulz Unit is not as efficient Low INAP #45 07/162010 Closed 07/212010 DC -I fan 414 has heavy vibration during operation Roof Stutz Could cause early wear on the unit Low Found loss wires at the unit. Corrected the problem INAP #46 (17/162010 Closed 08 /042014 UPS Module 3 is missing EPO cover UPS room MGE Could cause an inadvertent shut down Low INAP #47 07/16/ 2010 Closed 07/20/2010 UPS Module battery leak barrier is missing sealant UPS room PEG Low Barrier was removed. INAP #48 07/16/2010 Closed 07/192010 DB- MECH3A/Generator Breaker failed to open during Level 4 testing. Ban Trip unit in Generator Breaker Switchgear room GE Breaker will not trip High Trip mechanism was not fully seated INAP 649 07/16/2010 Closed 07202010 Generator room needs a thorough cleaning. There is debris under the generators Generator Room BNB Radiator could he damaged by debris Low Room has been cleaned INAP #50 (17 /16/2 2010 Closed 08/11220111 D13- MECH3B 3136 is missing clear Trip setting cover Switchgcar room PEG Low - INAP #51 07/16/2010 Closed 0720/2010 Leak Detect alarm comes in when the power is restored after power is cycled Generator Room NW pump The panel requires a manual reset after power has been failed Low INAP #52 07/19/2010 Closed 07/20/2010 HUM 3 -2 auto fill and drain valves do not shut. Roof ATS RTU has no water in it to operate the pump. High Loose wire has been correct. Fill valve is operational (NAP #53 07201 2010 Open Arc Flash labels are not posted at the breakers Equipment Sigma 6 Low • Lee Technologies (c) 2009 All Rights Reserved Revised • • Page 6 08/24 /2ing Action List Project Manager: Publish Date: Revision Date: Project Scope Description: Marc Maitles June 14, 2010 August 24, 2010 Data Center Cxin 41 LEE TECHNOLOGIES` (RIM _ Ac, IIIIII I?tbQ l Summary (...:1Rn Switchgear room Action By Bellevue Protect Action G 64 ; Remarks Description CQ Discrepancy Low Discrepancy LS u i i INAP #54 07/202010 Open TF S -1 and S -2 are operating above Full Load Amps at 100% read at VFD This could cause early failure of the motors INAP #55 07/20/2010 Open TF 3T -1 and 3T -2 are operating above Full Load Amps at 100% read at VFD Transfonner Room Bellevue This could cause early failure of the motors Low INAP #56 07/20/2010 Open UPS room economizer and CRAC's were operating at the same time UPS room ATS outside, making the CRAC's work harder Low INAP #57 07222010 Open Maintenance Bypass Procedures are needed at SB- UPSBP -3 Switchgear room Rubicon High INAP #58 07/22/2010 Open DB- UPS -3A &3B don't have retransfer procedures out of maintenance bypass Distribution Room Rubicon High INAP #59 07222010 Open DB- MECH3A label NORMAL/TEST is missing Switchgear room GEIRubic on Low • Lee Technologies (c) 2009 All Rights Reserved Revised • • Page 7 • SIGMA SIX SOLUTIONS • Relay Settings Page 1/1 Bus Position Manuf. I Type 351 I.CT Ratio 1200:5 -Protection' 50P/51P Settings Range Recomm. Pick -up 1 (0.5 -16x) 1 I Curve Multi Ex. Inv.(U4) Time Dial I (.5 -15) 6 Inst. I (0.25 -100) 10 Comments' MSG2 52 Main SEL 1200:5 50N/51N Range Existing (0.5 -16x) 0.55 Multi Ex. Inv.(U4) (.5 -15) , 4.5 (0.25 -100) 6.25 Tie SEL 551 1200:5 50P/51P Range Recomm. (0.5-16x) Ex. nvl (U4) (.5-15) (0.25-100) 1200:5 50N /51N I Range Recomm. (0.5 -16x) 0.5 I Multi Ex. Inv.(U4) 1 (.5 -15) ' 3 I (0.25 -100)1 5.5 I (0.25-100) (0.25 -100)) I 10 to Internap SEL 551 600:5 50P/51P I Recomm. (0.5-16x) 1.4 Ex. vl (U4) (.5-15) ) I 5.5 (.5 -15) 1 3 600:5 50N/51N Range I Recomm. , (0.5 -16x) 0.8 Multi I Ex. Inv.(U4) • SD -1 ; Feeder To MSG -2 SEL 501 600:5 50P /51P Range I Recomm. (0.5-16x) ) 1 Ex. nvl (U4) . ('5 -815) (0.5-80) 600:5 50N/51N Range Existing (0.5 -16x) 1.1 Multi Ex. Inv. (U4) (.5 -15) 6 (0.5 -80) 14 Panel SWBD -1 SIGMA SIX SOLUTIONS Circuit Breaker Settings Page 1/6 Main 1&2 Tie ATS -1 ATS -2 ATS -3 GEN BOARD Gen1,2 &3 Main ATS -E1 ATS -E2 ATS -E3 LB GE SS GE SS GE SS GE SS GE ' SS I MG MPactl. MG . MPact 1 MG MPact I MG MPact I MG MPact MVT+ (LSIG) MVT+ (LSIG) MVT+ (LSIG) MVT+ (LSIG) MVT+ (LSIG) NW (LSI) NW (LSIG) NW (LSIG) NW (LSIG) NW (LSIG) 4000 A 4000 Al (0.5 -1x) (1-4) (1.5-`9xL I) trnn- rlax,ic�� ll I ix I 3 I 9 I Min,Out 4000 A 4000 Al. (0.5 -1x)1 (1-4) 1 (1.5- 9xLT)1(Min- Max,i2t) (1.5 -9xP) lx 2 6 Min,Out 9 3000 A 3000 Al lx 1 4 Min,Out 13 • (0.5 -1x)1, (1 -4) I (1.5- 9xLT)1(Min- Max,i2t) (1.5 -13xP) 3000 Al 3000 Al (0.5 -1x)1' (1 -4) 1 (1.5 -9xLT) I (Min- Max,i2t) (1.5 -13xP) ix 3 9 Min,Out ' 9 3000 A 3000 Al (0.5 -1x)1' (1 -4) I (1.5- 9xLT)1(Min- Max,i2t) ,(1.5 -13xP) ix 2 2.5 . Min,Out 10 3000 A 3000 AI, (0.4- 1x)1(.5- 24)1(1.5- 10xLT)1; (0- 0.4,i2t) (1.5 -9xP) ix 2 6 0.1 15 3000 A 3000 Al (0.4- 1x)1:(.5- 24)1,(1.5- 10xLT)I (0- 0.4,i2t) (2 -15xP) ix 2 4 0.1 12 3000 Al 3000 Al (0.4 -1x)1 (.5-24)1 (1.5-10xLT) ; (0- 0.4,i2t) (2 -15xP) ix ' 12 10 0.1,Out ' 12 3000 A13000 Al (0.4 -1x)1 (.5 -24)I (1.5- 10xLT)1 (0- 0.4,i2t) (2 -15xP) lx 4 2.5 0.1 10 3000 A 3000 A (0.4 -1x) (.5 -24) (1.5- 10xLT) (0- 0.4,i2t) (2 -15xP) 1. ix 1 12 1 10 0.1 15 .J- .L- V. ,u 9 0.3 Max,i2t (0.2- 0.3xS) 0.24 (0.2- 0.37xS) 0.26 (0.2- 0.37xS) 0.26 (0.2- 0.37xS) 0.26 (A -J) F(960) (Min- Max,i2t) Int,i2t (Min- Max,i2t) Int,i2t (Min- Max,i2t) Int,i2t (Min- Max,i2t) Int,i2t (0- 0.4,i2t) 0.4,i2t (A -J) F(960) (0- 0.4,i2t) 0.4,i2t • • Position ' Manuf. Type Tri • Unit Frame Sensor Long Time Pickup Long Time Delay • Short Time Pickup Short Time Delay Instate nous Pickup ,. r n_.n\ Ground Fault Picku . 1 /n 7 fl 4..C\ Ground Fault Delay 1 /Min -Mw P.N.\ Main 1&2 Tie ATS -1 ATS -2 ATS -3 GEN BOARD Gen1,2 &3 Main ATS -E1 ATS -E2 ATS -E3 LB GE SS GE SS GE SS GE SS GE ' SS I MG MPactl. MG . MPact 1 MG MPact I MG MPact I MG MPact MVT+ (LSIG) MVT+ (LSIG) MVT+ (LSIG) MVT+ (LSIG) MVT+ (LSIG) NW (LSI) NW (LSIG) NW (LSIG) NW (LSIG) NW (LSIG) 4000 A 4000 Al (0.5 -1x) (1-4) (1.5-`9xL I) trnn- rlax,ic�� ll I ix I 3 I 9 I Min,Out 4000 A 4000 Al. (0.5 -1x)1 (1-4) 1 (1.5- 9xLT)1(Min- Max,i2t) (1.5 -9xP) lx 2 6 Min,Out 9 3000 A 3000 Al lx 1 4 Min,Out 13 • (0.5 -1x)1, (1 -4) I (1.5- 9xLT)1(Min- Max,i2t) (1.5 -13xP) 3000 Al 3000 Al (0.5 -1x)1' (1 -4) 1 (1.5 -9xLT) I (Min- Max,i2t) (1.5 -13xP) ix 3 9 Min,Out ' 9 3000 A 3000 Al (0.5 -1x)1' (1 -4) I (1.5- 9xLT)1(Min- Max,i2t) ,(1.5 -13xP) ix 2 2.5 . Min,Out 10 3000 A 3000 AI, (0.4- 1x)1(.5- 24)1(1.5- 10xLT)1; (0- 0.4,i2t) (1.5 -9xP) ix 2 6 0.1 15 3000 A 3000 Al (0.4- 1x)1:(.5- 24)1,(1.5- 10xLT)I (0- 0.4,i2t) (2 -15xP) ix 2 4 0.1 12 3000 Al 3000 Al (0.4 -1x)1 (.5-24)1 (1.5-10xLT) ; (0- 0.4,i2t) (2 -15xP) ix ' 12 10 0.1,Out ' 12 3000 A13000 Al (0.4 -1x)1 (.5 -24)I (1.5- 10xLT)1 (0- 0.4,i2t) (2 -15xP) lx 4 2.5 0.1 10 3000 A 3000 A (0.4 -1x) (.5 -24) (1.5- 10xLT) (0- 0.4,i2t) (2 -15xP) 1. ix 1 12 1 10 0.1 15 .J- .L- V. ,u 9 0.3 Max,i2t (0.2- 0.3xS) 0.24 (0.2- 0.37xS) 0.26 (0.2- 0.37xS) 0.26 (0.2- 0.37xS) 0.26 (A -J) F(960) (Min- Max,i2t) Int,i2t (Min- Max,i2t) Int,i2t (Min- Max,i2t) Int,i2t (Min- Max,i2t) Int,i2t (0- 0.4,i2t) 0.4,i2t (A -J) F(960) (0- 0.4,i2t) 0.4,i2t • • • rSIGMA SIX SOLUTIONS • • Circuit Breaker Settings Page 2/6 Panel UPS OUT BOARD Position Manuf. Mainl&2 (Static MG Switch) Bypass 1 &2 MG Typ T 300kVA UPS IN BOARD Main GE Siemens MPact Trip Unit Frame STR58U (LSI) MPact STR58U (LSI) 3000 A 3000 A SGLA 1 Spectra Static Trip UPS OUT Siemens Static I: Tri p Typ UPS Siemens SBS I: Mech. Dis. Board Main 1 GE SS RL (LSIG) RL (LSIG) SB -EC (LSI) MVT+ (LSIG) Typ 1 GE SGHA Spectra DP -CPP Main Typ Feeder GE SKI-IA Spectra GE SFHA Spectra Sensor 3000 A 3000 A 600A I.600A 4000 AI 4000 A Long Time Picku (0.5 -1x) (0.8 -1x) 1 /1x Long Time Delay (15 -480) 30 Short Time Picku (1.5 -10xL) 4 Short Time Delay Instate Ground nous Fault Ground Fault Picku • Picku . Delay (In.- .4,i2t) (2 -12xP) 0.1 10 (0.5 -1x) (0.8 -1x) 1 /1x (15 -480) 30 (1.5 -10xL) 4 (In.- .4,i2t) 0.1 (2 -12xP) 10 (20 -60 %) (0.1- 0.4,i2t) (Min -Max) Max (0.5 -1x) (3.5 -30) (2- 12xLT) • (.08- 0.4,i2t) (2 -15xP) (20 -60 %) (0.1- 0.4,i2t) ix 3.5 , 6 0.15 12 30% 0.25,i2t 4000 A 3000 AI (0.5 -1x) ix 1600 AI 1600 A 3000 AI 3000 A ix (0.5 -ix) 600A 600A 800A 800A 250A 225A (3.5-30) (2- 12xLT) 3.5 6 (.08- 0.4,12t) I (2 -15xP) . (20 -60 %) (0.1- 0.4,i2t) 0.08 12 30% 0.25,i2t I(50- 100 %) (2.5 -30) 9xLT) I (1.5 -8 (.07- 0.3,i2t) � (1.5 -12xP) I 100% 10 0.07 10 (1 -4) 1 (1.5 -9xLT) 2 (Min- Max,i2t) (1.5 -13xP) (0.2- 0.3xS) (Min- Max,i2t) Min 10 0.24 Int,i2t (Min -Max) Max (Min -Max) Max (Min- Max) I Max SIGMA $1X SOLUTIONS Circuit Breaker Settings Page 3/6 Panel Position Manuf. Type Trip Unit Frame Sensor Long Time Pickup Long Time Delay Short Time ` Pickup Short Time Delay Instate nous Pickup ' Ground Fault Pickup Ground Fault Delay SB UPSBP1 Mainl&2 I Siemens Static Tri. SS I ETU745 (LSIG) EGTU (LSIG) 3200 A 3000 AI 3000 AI 3000 AI 4000 A 2000 A : 3000 A 3000 A I (0.4 -1x) ix (0.5 -1x) ix (0.5 -1x) ix I (0.5 -1x) lx (0.5 -1x) I lx (0.5 -1x) ix (2 -30) ' 2 (C1-19)1 C -5 (C1 -19) C -8 (. (C1 -19) C -8 . (C1 -19) I C -8 (C1 -19) I1 C -5 (1.25 -12) 3 I (ST01 -11) I 3 (ST01 -11) 8 , (ST01 -11) I 9 • (ST01 -11) 8 (ST01 -11) 3 (1.5 -9xLT) I 4 . (ST01 -11) 3 I;(1.5 -9xLT) 4 (.1- 0.4,i2t) 0.1,Out (ST01 -11) I 06- Min,Out (STO1-11) .09- Min,Outl (ST01 -11) 05- Min,Out (ST01 -11) 09-Min,Out ' (ST01 -11) I04- Min,Outl (1- 4,i2t) I 2,Out (ST01 -11) I04- Min,Outl (1- 4,i2t) 2,Out (1.5 -12xP) 10 (2 -9xP) 13 (2 -9xP) 9 I (2 -9xP) 10 (2 -9xP) 10 (2 -9xP) 8 - F(1.510xP) 10 (2 -9xP) 8 (1.5 -10xP) 10 (100 -1200) C(600) (0.2- 0.3xS) 0.2 (0.2- 0.3xS) 0.3 (0.2- 0.3xS)I 0.4 (0.2- 0.3xS) 0.3 (0.2- 0.3xS) 0.2 (0.2 -1xS) 0.5 (0.2- 0.3xS) 0.2 (0.2 -1xS) 0.5 (0.1- 0.5,i2t) 2,i2t (01- 13,i2t) 06,I2t SB- UPSBP3 Output I 1 &2 GE SB -UPS3 Main1&2 GE SS EGTU (LSIG) EGTU (LSIG) (LSIG) EGTU EGTU (LSIG) 4000 A I 2000 2000 A 3000 A 3000 A (01- 13,i2t) 08,I2t UPS input GE I� GE SS (01- 13,i2t) 06,I2t (01- 13,i2t) I 06,I2t Bypass SS DB -UPS3A Mains &2 GE I, SS (01- 13,i2t) 06,I2t I (1- 4,i2t) 1,I2t (01- 13,i2t) 06,I2t Typ PDU 1 GE SGHB M\11-+ (LSIG) EGTU (LSIG) MVT+ (LSIG) 800 A 3000 A 800 A 1 600 A 3000 A I 600 A (0.5 -1x) 0.8x (0.5 -1x) ix (0.5 -1x) 0.8x (1 -3) 1 (C1 -19) I C -5 I' (1 -3) 1 DB-UPS3B Mainl&2 GE SS Typ PDU I GE SGHB I (1 -4,120 1,I2t • • • • 215 SIGMA $1X SOLUTIONS • • Circuit Breaker Settings Page 4/6 Panel Position Manuf. Type TYP PDU I Main I SqD I LC 480V T #3 Sec CBI GE SS T #4 Sec CBI GE SS SB -SG3 SB -MECH3 Trip Unit Frame Gen# 4 5 &6 ' Siemens Static M CH3A Siemens ° Static DB- Si Static MECH3B emens Trip SB -UPS3 I; Siemens! Static Trip SB- Siemens Static UPSBP3 Trip DB- MECH3A GE SS DB- GE SS MECH3B TM EGTU (LSIG) EGTU (LSIG) ETU745 (LSIG) ETU745 (LSIG) ETU745 (LSIG) ETU745 (LSIG) ETU745 (LSIG) EGTU (LSIG) EGTU (LSIG)) 600A 4000 A 3000 A Long Long Time ° Time Sensor Picku Delay 500A 4000 A Short Time ° Short Time Picku . Delay Instate nous Ground Faul• Ground Picku . Picku • Fault Delay (Min -Max) Max l (0.5 -1x) ix (C1 -19) C -12 (ST01 -11) 9 (ST01 -11) 06- Min,Out (2 -9xP) 9 (0.2- 0.3xS) 0.3 (01- 13,i2t) 08,I2t 3000 AI (0.5 -1x) ix 4000 AI 4000 A (C1 -19) (STO1 -11) , (STO1 -11) C -7 3 09- Min,Out (2 -13xP) (0.2- 0.4xS) (01- 13,i2t) 13 0.4 08 12t (0.5 -1x) 1x (2 -30) 5.5 (1.25 -12) 6 (.1- 0.4,i2t) 0.2,Out (1.5 -12xP) I 12 (400 -1200) E(1200) (1- 5,i2t) 5,I2t 3200 A 3200 A ix 2 2 0.1 (0.5 -1x) (2 -30) 1 (1.25 -12) (.1- 0.4,i2t) 3200 AI 3200 Al (0.5 -ix) I (2 -30) 1 (1.25 -12) I (.1- 0.4,i2t) 1x 2 2 0.1 4000 A 4000 A (0.5 -1x) I (2 -30) (1.25 -12) (.1- 0.4,i2t) ix 10 10 0.1,Out 4000 AI 4000 A. (0.1x 5 -1x) 3000 Al 3000 Al (0.5 -1x) 11 ix 3000 AI 3000 A (1.5 -12xP) (100 -1200) 12 D(900) (1.512 xP) (100-1200) D(900) (1.5- 12xP) (400 -1200) 12 C( 00) (1- 5,i2t) 4,I2t (1- 5,i2t) 4,I2t (1- 5,i2t) 4 I2 (2 -30) (1.25 -12) (.1- 0.4,i2t) (1.5 -12xP) (400 -1200) (1- 5,i2t) 3.5 3 1 0.2,Out 12 C(800) 4,I2t .(C1 -19) (ST01 -11) (ST01 -11) (2 -13xP) ° (0.2- 0.3xS) (01- 13,i2t) C -4 2 06- Min,Out 13 0.3 06 12t (0.5 -1x) 1x (C1 -19) C -4 (ST01 -11) 2 (STO1 -11) I 06- Min,Out (2 -13xP) 13 (0.2- 0.3xS) ( 0.3 (01- 13,i2t) 06,I2t 26 SIGMA SIX SOLUTIONS Circuit Breaker Settings Page 5/6 Panel Position Manuf. Type SS I Trip Unit EGTU (LSIG)) Frame 3000 A1 600 A I 400 A 150A �� 80A Sensor 3000 A 450 A I" 350 A I 125A 180A Long Time Pickup (0.5 -1x) ix (0.5 -1x) ix (0.5 -1x) I ix Long Time Delay , (C1 -19) C -2 (1 -3) 2 (1 -3) 2 Short Time Pickup (ST01 -11) 2 I04- (1.5-9xLT)1 8 (1.5 -9xLT) I 9 Short Time Delay (STO1 -11) Min,Out) (1- 4,i2t) 1,Out (1- 4,i2t) 1,Out I I' Instate nous Pickup (2 -13xP) 12 (1.5 -10xP) 9 (1.5 -10xP) I 10 I_ (Min -Max) Max I (Min -Max) Max (Min -Max) Max Ground Fault Pickup (0.2- 0.3xS) 0.3 (0.2 -1xS) 1 (0.2 -1xS) 1 I I Ground Fault Delay (01- 13,i2t) 06,I2t DB- MECH3A &B Main1 &2 GE (1- 4,i2t) 1,I2t (1- 4,i2t) 1,I2t RTU3;1 -5 GE SGHB MVT+ (LSIG) MVT+ I (LSIG) SPECTRA I RTU5- 6,8 &10 GE SGHB XFR -P3 GE SFPA XFR -L3 GE SEPA ('SPECTRA HP -31 ; GE SEPA SPECTRA 100A ' 100A CAC 3- 1,2,3 GE SEPA SPECTRA 60A 1_60A (Min -Max) Max • • • 2-V SIGMA SIX SOLUTIONS Circuit Breaker Settings Page 6/6 Panel CONT CAB UPS3 Position Manuf. CB21&22 . SqD DB-UPS Q2S SqD Type CB11- CB14 SqD Q1 SqD Q5N SqD NW NW NW I. PHF MHL Trip Unit MPact (LSI) MPact (LSI) MPact Frame 'Sensor 3000 Al 3000 Al 3000 A 3000 Al + 1200 AI 1200 A (LSI) II TM 1600A1 1600A I TM 1600A 1200A1 Long Time Picku (0.5 -1x) lx (0.5 -1x) 1.x Long Time Delay (1 -24) 4 (1 -24) 8 Short Time Short Time Picku . Delay (1.5- 10xLT) (0- .4,i2t) 3 0.1,Out Instate nous Ground Faul Ground Fault Pickup Picku . Delay (1.5- 10xLT) (0- .4,i2t) 5 0.2,Out (2- 15xP) I 8 (2- 15xP)I 15 I(0.5 -1x) lx (1 -24) 12 (1.5- 10xLT)I (0- .4,i2t) 8 0.1,Out (2 -15xP) 15 (Min -Max)) Max (Min -Max)) Max • • • • • 1111Wdiprner111111. Location Manufacturer Model Serial Number Comments RDT130DL4 FBOU100400294 00 RTU 3 -1 Roof McQuay RTU 3 -2 Roof McQuay RDT130DL4 FBOU100400293 00 RTU 3 -3 Roof McQuay RDT130DL4 FBOU100400344 00 RTU 3 -4 Roof McQuay RDT130DL4 FBOU100400709 00 RTU 3 -5 Roof McQuay RDT130DL4 FBOU100400571 00 CRAC 3 -1 UPS Room Stulz VFS- 240 -DG -D 10190035 CRAC 3 -2 UPS Room Stulz VFS- 240 -DG -D 10190037 CRAC 3 -3 UPS Room Stulz VFS- 240 -DG -D 10190038 CRAC 3 -4 UPS Room Stulz VFS- 240 -DG -D 10190036 DC 3 -1 Roof Gunter S -MFH 08EA/2X4 -N (L)- F6 /4P 300/256035 -0001 DC 3 -2 Roof Gunter S -MFH 08EA/2X4 -N (L)- F6 /4P , 300/256035 -0002 TF 3U -1 UPS Room Green Neck BDF- 200 - 100 -BHX 12053698 1004 TF 3U -2 UPS Room Green Neck BDF- 200 - 100 -BHX 12053699 1004 TF 5 -1 Switchgear Room Green Neck BCF- 206 -7 -THX 12053701 1004 TF S -2 Switchgear Room Green Neck BCF- 206 -7 -THX 12053702 1004 TF 3T -1 Transformer Room Green Neck BDF- 180- 20 -BH -X 12053695 1004 TF 3T -2 Transformer Room Green Neck BDF- 180- 20 -BH -X 12053696 1004 HUM 3 -1 Roof SPEC -AIR N/A 4282 HUM 3 -2 Roof SPEC -AIR N/A 4283 HUM 3 -3 Roof SPEC -AIR N/A 4284 HUM 3 -4 Roof SPEC -AIR N/A 4285 HUM 3 -5 Roof SPEC -AIR N/A 4286 Generator #4 Generator Room Caterpillar 3516B G5J00399 Generator #5 Generator Room Caterpillar 3516B G5J00401 Generator #6 Generator Room Caterpillar 3516b G5J00400 Day Tank #4 Generator Room Old Castel Precast WRN 250 3SF R419905 Day Tank #5 Generator Room Old Castel Precast WRN 250 3SF R419906 Day Tank #6 Generator Room Old Castel Precast WRN 250 3SF R419904 USS -4 SUBStation Transformer Room MGM Transformer AC379 -Y0105 10- 06- 10- 12633B USS -3 SUB Station Transformer Room MGM Transformer AC379 -20120 10- 06- 10- 12633A USS -4 Secondary Transformer Room GE Spectra(SB) 43229094 -S2 Secondary USS -4 1 &2 USS -4 Secondary Transformer Room GE Spectra(SB) 43229094 -S2 Secondary USS -4 2 &2 • 1 ap Equipment Location Manufacturer Model 43229094 -S2 Serial Number Secondary USS -3 1 of 2 Comments USS -3 Secondary Transformer Room GE Spectra Series USS -3 Secondary Transformer Room GE Spectra Series 43229094 -S2 Secondary USS -3 2 of 2 SB -MECH3 Switchboard Transformer Room GE Spectra Series 43229094 -S3 Section 1 of 3 Input MGE UPS Static Switch UPS Room APC 72- 132005 -30 Section 2 of 3 DB -MECH 3B MGE UPS Static Switch UPS Room APC 72- 132005 -30 Section 3 of 3 DB -MECH 3A MGE UPS Static Switch UPS Room APC 72- 132005 -30 H10 -10034 MGE UPS Continuous Dut■ UPS Room APC 72- 134600 -40 H10 -10034 MGE UPS Switchgear UPS Room GE Spectra Series 43229094 -S1 SB -UPS B 1 of 6 SB -UPS3 (Main Gear) MGE UPS Switchgear UPS Room GE Spectra Series 43229094 -S1 SB -UPS B 2 of 6 MAIN MGE UPS Switchgear UPS Room GE Spectra Series 43229094 -S1 SB -UPS B 3 of 6 Module3 /HMI MGE UPS Switchgear UPS Room GE Spectra Series 43229094 -S1 SB -UPS B 4 of 6 Spare /MOD 1 MGE UPS Switchgear UPS Room GE Spectra Series 43229094 -S1 SB -UPS B 5 of 6 MOD2/MOD 4 MGE UPS Switchgear UPS Room GE Spectra Series 43229094 -S1 SB -UPS B 6 of 6 UPS Bypass MGE /APC UPS #1 UPS Room MGE/APC E8TUPS750EPS- 8750144 ND0942000974 MGE /APC UPS #2 UPS Room MGE/APC E8TUPS750EPS- 8750144 ND0946001704 MGE /APC UPS #3 UPS Room MGE/APC E8TUPS750EPS- 8750144 ND0949001703 MGE /APC UPS #4 UPS Room MGE/APC E8TUPS750EPS- 8750144 ND0942000973 Battery Cabinet #1 UPS Room INTRA PACK EPSSD- 40H505- 480 -1 -1 DE EPS5D-160H505- 480 -4- 4D500 11000298 -1A Battery Cabinet #1 UPS Room INTRA PACK EPSSD- 40H505- 480 -1 -1 DE E PS5 D -160 H 505- 480 -4- 4D500 11000298 -1 B Battery Cabinet #1 UPS Room INTRA PACK EPSSD- 40H505- 480 -1 -1 DE EPS5 D-160H505- 480 -4- 4D500 I1000298-1C Battery Cabinet #1 UPS Room INTRA PACK EPSSD- 40H505- 480 -1 -1 DE E P S 5 D -160 H 505- 480 -4- 40500 11000298 -1 D Battery Cabinet #2 UPS Room INTRA PACK EPSSD- 40H505- 480 -1 -1 DE EPS5 D-160H505- 480 -4- 4D500 11 000298-2A Battery Cabinet #2 UPS Room INTRA PACK EPSSD- 40H505- 480 -1 -1 DE EPS5D-160H505- 480 -4- 4D500 11000298 -2B Battery Cabinet #2 UPS Room INTRA PACK EPSSD-40H505- 480 -1 -1 DE EPS5D-160H505- 480 -4- 40500 11000298 -2C Battery Cabinet #2 UPS Room INTRA PACK EPSSD- 40H505- 480 -1 -1 DE EPS5 D-160H505- 480 -4- 40500 11000298 -2D Battery Cabinet #3 UPS Room INTRA PACK EPSSD- 40H505- 480 -1 -1 DE EPS5 D-160H505- 480 -4- 4D500 11000298 -3A 2 • Inap • 3 Equipment Location Manufacturer Model EPSSD- 40H505- 480 -1 -1 DE Serial Number EPS5D-160H505- 480 -4- 4D500 Comments Battery Cabinet #3 UPS Room INTRA PACK 11000298 -3B Battery Cabinet #3 UPS Room INTRA PACK EPSSD- 40H505- 480 -1 -1 DE EPS5D-160H505- 480 -4- 40500 11000298 -3C Battery Cabinet #3 UPS Room INTRA PACK EPSSD- 40H505- 480 -1 -1 DE E PS5D-160H505- 480 -4- 40500 11000298 -3D Battery Cabinet #4 UPS Room INTRA PACK EPSSD- 40H505- 480 -1 -1 DE EPS5D-160H505- 480 -4- 40500 11000298 -4A Battery Cabinet #4 UPS Room INTRA PACK EPSSD- 40H505- 480 -1 -1 DE E P S5 D -160 H 505- 480 -4- 40500 11000298 -4B Battery Cabinet #4 UPS Room INTRA PACK EPSSD- 40H505- 480 -1 -1 DE E PS 5 D -160 H 505- 480 -4- 40500 11000298 -4C Battery Cabinet #4 UPS Room INTRA PACK EPSSD- 40H505- 480 -1 -1 DE E PS5D-160H505- 480 -4- 40500 11000298 -4D PDI PDU 3B6 Phase 1 Data Center PDI PP13 -WS- 300 -G -641 110- 2679 -5 PDI PDU 3B7 Phase 2 Data Center PDI PP13 -WS- 300 -G -641 110 - 2679 -1 PDI PDU 3A6 Phase 2 Data Center PDI PP13 -WS- 300 -G -641 110 - 2679 -7 PDI PDU 3A7 Phase 2 Data Center PD1 PP13 -WS- 300 -G -641 110 - 2679 -4 PDI PDU 3B1 Phase 3 Data Center PD1 PP13 -WS- 300 -G -641 110 - 2679 -3 PDI PDU 3B2 Phase 3 Data Center PD1 PP13 -WS- 300 -G -641 110 - 2679 -8 PDI PDU 3B4 Phase 3 Data Center PDI PP13 -WS- 300 -G -641 110 - 2679 -9 PDI PDU 3B5 Phase 3 Data Center PDI PP13 -WS- 300 -G -641 110 - 2679 -10 PDI PDU 3B3 Phase 3 Data Center PD1 PP13 -WS- 300 -G -641 110 - 2679 -14 PDI PDU 3A5 Phase 3 Data Center PDI PP13 -WS- 300 -G -641 110 - 2679 -2 PDI PDU 3A4 Phase 3 Data Center PDI PP13 -WS- 300 -G -641 110 - 2679 -12 PDI PDU 3A3 Phase 3 Data Center PD1 PP13 -WS- 300 -G -641 110 - 2679 -13 PD1 PDU 3A2 Phase 3 Data Center PDI PP13 -WS- 300 -G -641 110 - 2679 -11 PDI PDU 3A1 Phase 3 Data Center PDI PP13 -WS- 300 -G -641 110 - 2679 -6 Smart Monitoring Sys Generator Room OMNTEC OEL800011 EL101592 Tank Monitoring system Fuel Tank Control Panel Generator Room OMNTEC P -03 -1A Roof Stulz GPS-150-D 1012231 P-03-1B Roof Stulz GPS-150-D 1012231 LIFT PUMP Breeze Way Weil Duplex W- 1601 -17 N/A 3 • Inap • 4 Ectuigment Location Manufacturer Model 43229094 -53 agifd Number Comments 1 of 3 TVSS Input SWBD SB- UPSBP -3 Switchgear Rm. 155 GE 2 of 3 DB -UPS3A 3 of 3 DB -UPS3B Sw.gear DB -MECH 3B Switchgear Rm. 155 GE 43229094 -51 1 of 3 PLC/ GEN Source 2 . 2 of 3 UtilitySource 1 3 of 3 Feeder BKRs Sw.gear DB -MECH 3A Swithcgear Rm. 155 GE 43229094 -S1 1 of 3 PLC/ GEN Source 2 2 of 3 UtilitySource 1 3 of 3 Feeder BKRs MTS CRAC # 3 -1 Switchgear Rm. 155 Square D 40275- 951 -02 600 VAC/ 100 AMPs MTS CRAC # 3 -2 Switchgear Rm. 155 Square D 40275 - 951 -02 600 VAC/ 100 AMPs MTS CRAC # 3 -3 Switchgear Rm. 155 Square D 40275 - 951 -02 600 VAC/ 100 AMPs MTS CRAC #3 -4 Switchgear Rm. 155 Square D 40275- 951 -02 600 VAC/ 100 AMPs MTS RTU #3 -1 Switchgear Rm. 155 Square D 40281 - 441 -01 600 VAC/ 600 AMPs MTS RTU #3 -2 Switchgear Rm. 155 Square D 40281 - 441 -01 600 VAC/ 600 AMPs MTS RTU #3 -3 Switchgear Rm. 155 Square D 40281 - 441 -01 600 VAC/ 600 AMPs MTS RTU #3 -4 Switchgear Rm. 155 Square D 40281 - 441 -01 600 VAC/ 600 AMPs MTS RTU #3 -5 Switchgear Rm. 155 Square D 40281 - 441 -01 600 VAC/ 600 AMPs MTS RTU 5 -10 Switchgear Rm. 155 Square D 40281 - 337 -01 600 VAC /400 AMPs MTS RTU 5 -6 Switchgear Rm. 155 Square D 40281 - 337 -01 600 VAC /400 AMPs MTS RTU 5 -8 Switchgear Rm. 155 Square D 40281 - 337 -01 600 VAC /400 AMPs Battery Charger Sw. gear Switchgear Rm. 155 ALCAD Stdby Battery AT10- 024 - 030 - 120 - 010102 128698 Battery Charger Gen #4 LA Marche Generator Room A46- 20- 24V- AI -12L -00864 205264 -1 Battery Charger Gen #5 LA Marche Generator Room A46 -20- 24V- AI -12L -00864 205264 -2 Battery Charger Gen #6 LA Marche Generator Room A46 -20- 24V- AI -12L -00864 205264 -3 4 • %it LEE TECHNOLOGIES' LEVEL 4 PROCEDURE Section 01 '1' "C'°"' - 1- ,'' I Procedure Mix ATO Switchgear Engineers Specification Number(s): Procedure Work Date: 077/2010 11 Procedure Work Time Frame: 08 :00- 18:00EST Customer Name: Intemap ReWsbn Number REV-0 Address: Street Ad ams: _.... . -- :..._.. 3355 South 120"' Place �zv: Site coda, City: : - Tukwila WA 98169 NIA Customer POC: Customer POC Name: Kathy Mclnvale Phone Numbers: Woe 404.302 -9753 Mobile: 404- 547 -8915 Installing Contractor. CempenYNams: BNB Builders Contractor POC: Supervisor Name: Jim Gylling DIHOe: Motile 509 -499 -8194 Lee Technologies Supervisor Paul Jahnke Herbert E. Burnett Phone Numbers: Number: (703) 968 0300 ) Mobile: (70 (703) 906 3422 (713) 423 4335 Pager NIA s, ction 02 Verify proper operation of the DB- MECH3A #1 under automatic and ..manual conditions._ - Glil . ilOn:.1 .tlei t'I, 0,El.1e:. Affected Area: Facility systems Affected: Electrical Systems Equipment Information: Manufacturer GE `2c Equipment Type: ATO Switchgear Model al: Serielfi 1785055E -9 Procedure overview: Procedure will demonstrate the operation of the low voltage switchgear system during all modes . of manual, automatic and emergency modes. Systems failures are not part of this procedure Anticipated Results: System will perform as designed. System will maintain power to load during failures pre. Requirements: Low Voltage Switchgear start up and verification completed by vendor. Generators startup completed vendor Any discrepancies noted during startup resolved. Section 0 -tint. lor, .t,-c;1,,1 Detailed Procedure DetailedPioceckoe: "' Complete 1. Verify Line Up with Source 1 Preferred in Auto 1.1. Breaker Configuration 1.1.1. Main M1is CLOSED 1.1.2. Main Gen is OPEN 1.2. System Lights 1.2.1. Main M1 CLOSED RED 1.2.2. Main GEN OPEN GREEN Lee Technologies Services, Inc. ©: Copynght 2010 Proprietary use pursuant to company policy. Page ,1 of 5. LEE TECHNOLOGIES' . LEVEL 4 PROCEDURE Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy. Page 2 of 5 1.2.3. Source. M1 Available WHITE 1.2.4. Source 1 Preferred GREEN �. 1.2.5. Load Energized BLUE 1.2.6. PLC Control Power GREEN 1.3. System Selector Switches 1.3.1. UPS Enable/Bypass to ENABLE _ l 1.3.2. Source 1 / Source 2 to SOURCE 1 1.3.3. Normal / Test to NORMAL 1.3.4. Auto / Manual to AUTOMATIC 11 1.3.5. Exercise Timer to NO -XFER .' 1.4. Verify all Generators in AUTO 2. Automatic Operation of the ATO Switchgear with Source 1 Preferred (Utility) 2.1. Source 1 out of tolerance 2.1.1. Delay timer will count down (adjustable from .5 to 15 seconds) 2.1.2. Generator start relay will close requesting the generator to come online 2.1.3. Upon the start relay closing the generator failure timer will begin 2.1.4. Generator is within tolerance the generator failure timer will stop 2.1.5. Main M1 will OPEN. 2.1.6. Once M1 is OPEN an open transition delay timer (adjustable from 0 — 30 seconds) will start. ' J 2.1.7. Upon completion of the timer the GEN breaker will CLOSE. 2.1.8. NOTE: Should Source 1 "recover before the expiration of the delay timer the system shall remain in the normal operating mode and the transfer delay timer will be reset. 2.2. Return of Source 1 back into tolerance 2.2.1. Retransfer timer (adjustable from .5 to 32 minutes) will begin 2.2.2. Upon completion of the timer the GEN breaker will OPEN 2.2.3. Upon opening of the GEN breaker the open transition timer (adjustable from 0 to 30 seconds) will begin 2.2.4. Upon completion of the open transition timer breaker M1 will CLOSE Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy. Page 2 of 5 • TECHNOLOGIES LEVEL 4 PROCEDURE 2.2.5. Once the transfer is complete a generator cool -down timer will start (adjustable from .5 to 32 minutes) 2.2.6. Upon completion of the cool -down timer the generator start signal will be removed 2.2.7. NOTE: Should Source 1 fall out of tolerance during the retransfer timer, the timer will reset to 0 and resume its countdown when the Source 1 returns to tolerance. Verify Line Up with Source 2 Preferred in Auto 3.1. Breaker Configuration 3.1.1. Main Mils OPEN 3.1.2. Main Gen is CLOSE 3.2. . System Lights 3.2.1. Main M1 OPEN GREEN 3.2.2. Main GEN CLOSE RED 3.2.3. Source M2 Available WHITE 3.2.4. Source 2 Preferred GREEN 3.2.5. Load Energized BLUE 3.2.6. PLC Control Power GREEN _ _ 1 V 3.3. System Selector Switches 3.3.1. UPS Enable/Bypass to ENABLE 3.3.2. Source 1 / Source 2 to SOURCE 2 3.3.3. Normal / Test to NORMAL 3.3.4. Auto / Manual to AUTOMATIC 3.3.5. Exercise Timer to NO -XFER 3.4. Verify all Generators in AUTO 3.5. Automatic Operation of the ATO Switchgearwith Source 2 Preferred (Gen) 3.6. Source 2 out of tolerance (failure) 3.6.1. The generator failure indication will display on the HMI. 3.6.2. If Source #1(Utility) is within tolerance GEN breaker will open. 3.6.3. Once "GEN' is open an open transition delay timer (adjustable from 0 to 30 seconds) will begin. Lee Technologies Services, Inc. © Copyright 2010' Proprietary use pursuant to company policy • L� LEE TECHNOLOGIES` LEVEL 4 PROCEDURE Lee Technologies Services, Inc. ©Copyright 2010 Proprietary use pursuant to company policy 3.6.4. Upon completion of this timer the Main 1 "M1" breaker will close 3.6.5. The open transition from the preferred source to the alternate source. 3.7. Return of Source 2 back into tolerance ' J 3.7.1. Retransfer timer (adjustable from .5 to 32 minutes) will begin 3.7.2. Upon completion of the timer the Main (utility) breaker will OPEN 3.7.3. Upon opening of the Main breaker the open transition timer (adjustable from 0 to 30 seconds) will begin _ 1 3.7.4. Upon completion of the open transition timer breaker GEN will CLOSE 3.7.4.1. NOTE: Should Source 2 fall out of tolerance during the retransfer timer, the timer will reset to 0 and resume its countdown when the Source 1 returns to tolerance. _ I 4. Verify Line Up with Source 1 Preferred in Manual 4.1. Breaker Configuration 4.1.1. Main M1 is CLOSED 4.1.2. Main Gen is OPEN 4.2. System Lights Main M1 CLOSED RED 4.2.2. Main GEN OPEN GREEN 4.2.3. Source M1 Available WHITE 4.2.4. Source 1 Preferred GREEN 4 4.2.5. Load Energized BLUE 4.2.6. PLC Control Power GREEN 11 4.3. System Selector Switches 4.3.1. . UPS Enable/Bypass to ENABLE 4.3.2. Source 1 / Source 2 to SOURCE 2 4.3.3. Normal / Test to NORMAL 4.3.4. Auto / Manual to MANUAL 4.3.5. Exercise Timer to NO -XFER 4.4. Verify all Generators in AUTO 5. Manual Operation of the ATO Switchgear with Source 1 Preferred Lee Technologies Services, Inc. ©Copyright 2010 Proprietary use pursuant to company policy • ./4111 LEE TECHNOLOGIES* LEVEL 4 PROCEDURE 5.1. NOTE: Either of the breakers may be opened and/or closed when the system is in manual . with the following exceptions: (1) both breakers may not be dosed at the same time. If one breaker is closed the opposite breaker is interlocked from closing (2) if either breaker is tripped open, the system will interlock the opposite breaker from closing into the fault condition. Once the bell alarm is reset at the breaker either breaker may be closed. 5.2. Place switchgear into MANUAL position y 5.3. Test the interlock by trying to CLOSE Main Gen breaker with Main MI CLOSED 5.4. Verify that the Main Gen breaker remains OPEN 5.5. OPEN the Main M1 breaker 5.6. CLOSE the selected generator breaker to the emergency buss 5.7. CLOSE the Main Gen breaker 5.8. Test the interlock by trying to CLOSE Main M1 breaker with Main Gen CLOSED 5.9. Verify that the Main M1 breaker remains OPEN 5.10. OPEN the Main Gen breaker at the ATO switchgear 5.11. CLOSE the Main M1 breaker for the utility source 5.12. At SG3 OPEN generator breaker that was supplying power to the ATO 5.12.1. Verify the generator goes into cool down 5.13. Place the MANUAL switch at the ATO back in AUTO 4 5.14. Place the select switch at SG3 back to AUTO 5.15. Restore system to normal line -up Svction 04 Comments Insert any comments applicable to the procedure: • Generator breaker would not trip while conducting level 4 testing. Sigma 6 and the GE technician found the trip unit not fully seated into the breaker. • Two dead front covers were missing in section 3 of the switchgear unit. • The HMI for the switchgear was not reading current, demand KW, and KW at the display panel (lion 05 The following has witnessed or participated in this procedure and attests to the accuracy and completeness of this report. :>■ _ , euu a . ; ,- _ �5 ,. Lee Technologies Printed Nerve -- Date: A eir- ,, P- 1/7/90/0 Lee Technolog $s Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy • LLEE TECHNOLOGIES' LEVEL 4 PROCEDURE Section 01 FoncUCna1 t,heck'st Iniorr,at■n Pn>:eqae ATO Switchgear Engineers Specl lcation Number(s): Procedure Work Date: 07/16/2010 Procedure Work Time Frame: 08:00- 18:OOEST Customer Name: Internap Reaslen Number REV-0 Address: Street Address: 3355 South 120th Place City. State: Zip: Site Cad a: Tukwila WA 98169 NIA Customer POC: Customer POC Name: Kathy Mclnvale Phone Numbers: Off e: 404302 -9753 Mobile: 404547 -8915 installing contractor. Company Name. BNB Builders Contractor POC: Supervisor Name: Jim Gylling OtAoe Mobile 509- 499 -8194 Lee Technologies Supervisor Paul Jahnke Herbert E. Burnett Phone Numbers: Phone Number (703) 968 0300 Mobilm (703) 906 3422 (713) 423 4335 Pager N/A Section 02 =:.n∎ tonal Che.kli -;t Verify proper operation of the DB- MECH3B #1 under automatic and manual conditions. Facility Systems Affected: Electrical Systems Affected Area: Equipment Information: Manufacturer GE Equipment Type: ATO Switchgear Modell: 43229094 -S1 Soria l: 1785055E -8 Procedure overview: Procedure will demonstrate the operation of the low voltage switchgear system during all modes of manual, automatic and emergency modes. Systems failures are not part of this procedure Anticipated Results: System will perform as designed. System will maintain power to Toad during failures Pre.pi ocedure Requirements: Low Voltage Switchgear start up and verification completed by vendor. Generators startup completed vendor. Any discrepancies noted during startup resolved. Section 03 Detailed Procedure rwcoona Ch,ct list Details Detailed Prtxediae: Complete 1. Verify Line Up with Source 1 Preferred in Auto 1.1. Breaker Configuration 4 1.1.1. Main Mils CLOSED 1.1.2. Main Gen is OPEN 4 1.2. System Lights 1.2.1. Main M1 CLOSED RED 1.2.2. Main GEN OPEN GREEN Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 5 • L� LEE TECHNOLOGIES" LEVEL 4 PROCEDURE Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 5 1.2.3. Source M1 Available WHITE 1.2.4. Source 1 Preferred GREEN 1.2.5. Load Energized BLUE 4 1.2.6. PLC Control Power GREEN ' J 1.3. System Selector Switches 1.3.1. UPS Enable/Bypass to ENABLE 1.3.2. Source 1 / Source 2 to SOURCE 1 1.3.3. Normal / Test to NORMAL 1.3.4. Auto / Manual to AUTOMATIC 1.3.5. Exercise Timer to NO -XFER . J 1.4. Verify all Generators in AUTO 'J 2. Automatic Operation of the ATO Switchgear with Source 1 Preferred (Utility) 2.1. Source 1 out of tolerance . J 2.1.1. Delay timer will count down (adjustable from .5 to 15 seconds) . 2.1.2. start relay will close requesting the generator to come online V 2.1.3. Upon the start relay dosing the generator failure timer will begin 4 2.1.4. Generator is within tolerance the generator failure timer will stop ' J 2.1.5. Main M1 will OPEN. 'J 2.1.6. Once M1 is OPEN an open transition delay timer (adjustable from 0 — 30 seconds) will start. 4 2.1.7. Upon completion of the timer the GEN breaker will CLOSE. ' J . 2.1.8. NOTE: Should Source 1 recover before the expiration of the delay, timer the system shall remain in the normal operating mode and the transfer delay timer will be reset. _ t 2.2. Return of Source 1 back into tolerance _V( 2.2.1. Retransfer timer (adjustable from .5 to 32 minutes) will begin . J 2.2.2. Upon completion of the timer the GEN breaker will OPEN . J 2.2.3. Upon opening of the GEN breaker the open transition timer (adjustable from 0 to 30 seconds) will begin _ r 2.2.4. Upon completion of the open transition timer breaker M1 will CLOSE Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 5 • L� LEE TECHNOLOGIES' LEVEL 4 PROCEDURE Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 5 2.2.5. Once the transfer is complete a generator cool -down timer will start (adjustable from .5 to 32 minutes) 2.2.6. Upon completion of the cool -down timer the generator start signal will be removed 2.2.7. NOTE: Should Source 1 fall out of tolerance during the retransfer timer, the timer will reset to 0 and resume its countdown When the Source 1 returns to tolerance. 3. Verify Line Up with Source 2 Preferred in Auto 3.1. Breaker Configuration 4 3.1.1. Main M1 is OPEN 3.1.2. Main Gen is CLOSE 4 3.2. System Lights 3.2.1. Main M1 OPEN GREEN 3.2.2. Main GEN CLOSE RED 4 3.2.3. Source M2 Available WHITE 4 3.2.4. Source 2 Preferred GREEN 4 3.2.5. Load Energized BLUE 4 3.2.6. PLC Control Power GREEN 3.3. System Selector Switches 3.3.1. UPS Enable/Bypass to ENABLE 3.3.2. Source 1 / Source 2 to SOURCE 2 3.3.3. Normal / Test to NORMAL 4 3.3.4. Auto / Manual to AUTOMATIC 4 3.3.5. Exercise Timer to NO -XFER 3.4. Verify all Generators in AUTO . 3.5. Automatic Operation of the ATO Switchgear with Source 2 Preferred (Gen) 3.6. Source 2 out of tolerance (failure) 3.6.1. The generator failure indication will display on the HMI. . 3.6.2. If Source #1(Utility) is within tolerance GEN breaker will open. 3.6.3. Once "GEN' is open an open transition delay timer (adjustable from 0 to 30 seconds). will begin. Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 5 • ‘41, LEE TECHNOLOGIES` LEVEL 4 PROCEDURE Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 4 of 5 3.6.4. Upon completion of this timer the Main 1 °M1° breaker will close 3.6.5. The open transition from the preferred source to the altemate source. 3.7. Return of Source 2 back into tolerance 3.7.1. Retransfer timer (adjustable from .5 to 32 minutes) will begin 3.7.2. Upon completion of the timer the Main (utility) breaker will OPEN 4 3.7.3. Upon opening of the Main breaker the open transition timer (adjustable from 0 to 30 seconds) will begin 3.7.4. Upon completion of the open transition timer breaker GEN will CLOSE 4 3.7.4.1. NOTE Should Source 2 fall out of tolerance during the retransfer timer, the timer will reset to 0 and resume its countdown when the Source 1 returns to tolerance.. 4. Verify Line Up with Source 1 Preferred in Manual 4.1. Breaker Configuration 4.1.1. Main M1 is CLOSED 4.1.2. Main Gen is OPEN 4.2. System Lights 4.2.1. Main M1 CLOSED RED 44 4.2.2. Main GEN OPEN GREEN 4.2.3. Source M1 Available WHITE 4.2.4._ Source 1 Preferred GREEN 4.2.5. Load Energized BLUE 4.2.6. PLC Control Power GREEN 4.3. System Selector Switches 4.3.1. UPS Enable/Bypass to ENABLE 4.3.2. Source 1 / Source 2 to SOURCE 2 4.3.3. Normal / Test to NORMAL 4 4.3.4. Auto /Manual to MANUAL 4.3.5. Exercise Timer to NO -XFER V 4.4. Verify all Generators in AUTO 5. Manual Operation of the ATO Switchgear with Source 1 Preferred' Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 4 of 5 • • L� ' LEE TECHNOLOGIES LEVEL 4 PROCEDURE 5.1. NOTE: Either of the breakers may be opened and/or closed when the system is in manual with the following exceptions: (1) both breakers may not be closed at the same time If one breaker is closed the opposite breaker is interlocked from closing (2) if either breaker is tripped open, the system will interlock the opposite breaker from closing into the fault condition. Once the bell alarm is reset at the breaker either breaker may be closed. 5.2. Place switchgear into MANUAL position 4 5.3. Test the interlock by trying to CLOSE Main Gen breaker with Main M1 CLOSED 4 5.4. Verify that the Main Gen breaker remains OPEN 5.5. OPEN the Main M1 breaker 5.6. CLOSE the selected generator breaker to the emergency buss 5.7. CLOSE the Main Gen breaker 5.8. Test the interlock by trying to CLOSE Main M1 breaker with Main Gen CLOSED 5.9. Verify that the Main M1 breaker remains OPEN 5.10. OPEN the Main Gen breaker at the ATO switchgear 5.11. CLOSE the Main M1 breaker for the utility source I/ 5.12. At SG3 OPEN generator breaker that was supplying power to the ATO. .4 5.121. Verify the generator goes into cool down 5.13. Place the MANUAL switch at the ATO back in AUTO . 5.14. Place the select switch at SG3 back to AUTO 4 5.15. Restore system to normal Tine -up 4 Beckon oa - Comments Co,ni n�ant�, Insert any comments applicable to the procedure: • The HMI for the switchgear was not reading current, demand KW, and KW at the display panel Section 05 The following has witnessed or participated in this procedure and attests to the accuracy and completeness of this report. n,, ocedur tVnnes _ E Veniic3trcn Lee Technologies S�ip�:. I / Date: Pit „- • Nar%�f,0f 1/2' ����'C��.f`�r p-; p. , —f t"--• /l �`��J .,�.1 `�� 4��,' ,/ /1 ©� Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 5of5: • .a.,1) LEE TECHNOLOGIES` LEVEL 4 PROCEDURE Section 01 Preceding ATO Switchgear run, Ronal Chec;ost Irk:, n2hon Engineers Specification Number(s): Procedure Work Date: 07/17/2010 Procedure Work Time Frame: 08:00- 18:00EST Customer Name: Intemap Revision Number REV-0 'dam: SbeetAddresx 3355 South 120th Place City: Siam: Zip: Site Code: Tukwila WA 98169 N/A Customer POC: CustomerPOC Nemo: KathyMclnvale Phone Numbers: Office: 404 -302 -9753 Mobile: 404 - 547 -8915 installing Contractor: Company Name: BNB Builders Contractor POC: Supervisor Name: Jim Gylling 0llioe: Motile 509- 499 -8194 Lee Technologies Supervisor Paul Jahnke Herbert E. Burnett Phone Numbers: Phone Number (703) 968 0300 Mobil (703) 906 3422 (713) 423 4335 Paler N/A Section 02 Verify proper operation of the SB -UPS3 under automatic and manual conditions. F mcprna (; hccKlist Affected Area: Facility Systems Affected. ' Electrical Systems Equipment information: Manufacturer GE Equipment Type: ATO Switchgear Model is 43229094 -S1 Serial is 1785055E -7 Procedure overview: Procedure will demonstrate the operation of the low voltage switchgear system during all modes of manual, automatic and emergency modes. Systems failures are not part of this procedure Anticipated Results: System will perform as designed. System will maintain power to Toad during failures Pre - Procedure Requirements: Low Voltage Switchgear start up and verification completed by vendor. Generators startup completed vendor. Any discrepancies noted during startup resolved. Section 00 Funct,sral Ch- c4.ugt Detailed Procedure p.mads Detailed Procedure: Complete 1. Verify Line Up with Source 1 Preferred in Auto 1.1. Breaker Configuration . J 1.1.1. Main M1 is CLOSED 1.1.2. Main Gen is OPEN •J 1.2. System Lights 1.2.1. Main M1 CLOSED RED 1.2.2. Main GEN OPEN GREEN Lee Technologies Services, Inc: © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 5 • LEE TECHNOLOGIES` %.1 LEVEL 4 PROCEDURE Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 5 1.2.3. Source M1 Available WHITE 1.2.4. Source 1 Preferred GREEN 4 1.2.5. Load Energized BLUE 1.2.6. PLC Control Power GREEN 4 1.3. System Selector Switches 4 1.3.1. UPS Enable/Bypass to ENABLE 4 1.3.2. Source 1 / Source 2 to SOURCE 1 4 1.3.3. Normal / Test to NORMAL 4 1.3.4. Auto / Manual to AUTOMATIC 1.3.5. Exercise Timer to NO -XFER 4 1.4. Verify all Generators in AUTO 4 2. Automatic Operation of the ATO Switchgear with Source 1 Preferred (Utility) 4 2.1. Source 1 out of tolerance 4 2.1.1. Delay timer will count down (adjustable from .5 to 15 seconds) 4 2.1.2. Generator start relay will close requesting the generator to come online 4 2.1.3. Upon the start relay closing the generator failure timer will begin 2.1.4. Generator is within tolerance the generator failure timer will stop 4 2.1.5. Main M1 will OPEN. 4 2.1.6. Once M1 is OPEN an open transition delay timer (adjustable from 0 — 30 seconds) will start. _ t �1 2.1.7. Upon completion of the timer the GEN breaker will CLOSE. 4 2.1.8. NOTE: Should Source 1 recover before the expiration of the delay timer the system shall remain in the normal operating mode and the transfer delay timer will be reset. 2.2. Return of Source 1 back into tolerance 4 2.2.1. Retransfer timer (adjustable from .5 to 32 minutes) will begin NI 2.2.2. Upon completion of the timer the GEN breaker will OPEN 4 2.2.3. Upon opening of the GEN breaker the open transition timer (adjustable from 0 to 30 seconds) will begin 2.2.4. Upon completion of the open transition timer breaker M1 will CLOSE Al Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 5 • %1 LEE TECHNOLOGIES' LEVEL 4 PROCEDURE Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 5 Oc the minutes) rane p generator cool -down timer will start (adjustable from .5 2.2.5. Once the transfer is complete a enerat _ _V 2.2.6. Upon completion of the cool -down timer the generator start signal will be removed 4 2.2.7. NOTE: Should Source 1 fall out of tolerance during the retransfer timer, the timer will reset to 0 and resume its countdown when the Source 1 returns to tolerance. _ r 11 3. Verify Line Up with Source 2 Preferred in Auto 3.1. Breaker Configuration 4 3.1.1. Main M1 is OPEN 3.1.2. Main Gen is CLOSE 4 3.2. System Lights 3.2.1. Main M1 OPEN GREEN 3.2.2. Main GEN CLOSE RED 3.2.3.: Source M2 Available WHITE 3.2.4. Source 2 Preferred GREEN 4 3.2.5. Load Energized BLUE 4 32.6. PLC Control Power GREEN 3.3. System Selector Switches 3.3.1. UPS Enable/Bypass to ENABLE 3.3.2. Source 1 / Source 2 to SOURCE 2. 3.3.3. Normal / Test to NORMAL 4 3.3.4. Auto / Manual to AUTOMATIC 11 3.3.5. Exercise Timer to NO -XFER 3.4. Verify all Generators in AUTO 3.5: Automatic Operation of the ATO Switchgear with Source 2 Preferred (Gen) 3.6. Source 2 out of tolerance (failure) J 3.6.1. The generator failure indication will display . on the HMI. 4 3.6.2. If Source #1(Utility) is within tolerance GEN breaker will open. 4 16.3. Once "GEN" is open an open transition delay timer (adjustable from 0 to 30 seconds) will begin. Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 5 • �� LEE TECHNOLOGIES' LEVEL 4 PROCEDURE Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 4 of 5 3.6.4. Upon completion of this timer the Main 1 °M1" breaker will close 3.6.5. The open transition from the preferred source to the altemate source. 3.7. Return of Source 2 back into tolerance 3.7.1. Retransfer timer (adjustable from .5 to 32 minutes) will begin - 3.7.2. Upon completion of the timer the Main (utility) breaker will OPEN 3.7.3. Upon opening of the Main breaker the open transition timer (adjustable from 0 to 30 seconds) will begin 3.7.4. Upon completion of the open transition timer breaker GEN will CLOSE 3.7.4.1. NOTE: Should Source 2 fall out of tolerance during the retransfer timer, the timer will reset to 0 and resume its countdown when the Source 1 returns to tolerance. 4 4. Verify Line Up with Source 1 Preferred in Manual 4 4.1. Breaker Configuration J 4,1.1. Main M1 is CLOSED 4.1.2. Main Gen is OPEN 4.2. System Lights 'J 4.2.1. Main M1 CLOSED RED 4 4.2.2. Main GEN OPEN GREEN 4.2.3. Source M1 Available WHITE 4.2.4. Source 1 Preferred GREEN 4.2.5. Load Energized BLUE 4.2.6. PLC Control Power GREEN 4.3. System Selector Switches. 4.3.1. UPS Enable /Bypass to ENABLE 4.3.2. Source 1 / Source 2 to SOURCE 2 4 4.3.3. Normal / Test to NORMAL 4 4.3.4. Auto / Manual to MANUAL 4.3.5. Exercise Timer to NO -XFER 4.4. Verify all Generators in AUTO 5. Manual Operation of the ATO Switchgear with Source 1 Preferred Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 4 of 5 • LEE TECHNOLOGIES' %IP/ LEVEL 4 PROCEDURE 5.1. NOTE: Either of the breakers may be opened and/or dosed when the system is in manual with the following exceptions: (1) both breakers may not be closed at the same time. If one breaker is closed the opposite breaker is interlocked from closing (2) if either breaker is tripped open, the system will interlock the opposite breaker from closing into the fault condition. Once the bell alarm is reset at the breaker either breaker may be closed.. 5.2. Place switchgear into MANUAL position 5.3. Test the interlock by trying to CLOSE Main Gen breaker with Main M1CLOSED 5.4. Verify that the Main Gen breaker remains OPEN 5.5. OPEN the Main M1 breaker 4 4 5.6. CLOSE the selected generator breaker to the emergency buss 4 4 5.7. CLOSE the. Main Gen breaker 5.8. Test the interlock by trying to CLOSE Main M1 breaker with Main Gen CLOSED 5.9. Verify that the Main M1 breaker remains OPEN 5.10. OPEN the Main Gen breaker at the ATO switchgear 4 4 5.11. CLOSE the Main M1 breaker for the utility source 4 4 5.12. At SG3 OPEN generator breaker that was supplying power to the ATO 4 4 5.12.1. Verify the generator goes into cool down Y Y 5.13. Place the MANUAL switch at the ATO back in AUTO 5.14. Place the select switch at SG3 back to AUTO 4 4 5.15. Restore system to normal line -up 4 4 Section 04 Comments ronime11s .. Insert any comments applicable to the procedure: • The HMI for the switchgear was not reading current, demand KW, and KW at the display panel Seclion 05 The following has witnessed or participated in this procedure = • attests to the accuracy and completeness of this report. Vei f cat ri Lee Technologies I Printed Name: • • .. - i t tleAg: I i �. / � � ' Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 5 of 5 10 LEE TECHNOLOGIES" LEVEL 4 CHECKLIST Section 01 Procedure Tide: - COMMISSIONING- GENERATORS Syste,n■ CunIIniSScning Submittal Date: Procedure Work Date: 7/8/201 O Procedure Work Time Frame: Customer Name: Internap Customer's Solomon Pct Cab: Address: Street Address 3355 South 120th Place City: State: Zip: Site Code: Tukwila WA 98169 Customer POC: Customer POC Name: Kathy McInvale Phone Numbers: Office: Mobile: General Contractor Company Name: Gylling Consulting Contractor POC: Engineer Name: Jim Gylling Office: Mobile: 504.499.8194 Lee Technologies Integrated System Testing Su.ervisor. Herbert Burnett Paul Jahnke Phone Numbers: Plane Number 703.968.0300 Mobile: 713.423.4335 713.906.3422 Pager. Section 02 Generator System Testing Procedure C on tn n S :i Ortln_ O °er:IC ^✓ Affected Area: Generators and Outside Yard area Systems Affected: Electrical and Mechanical Systems Procedure Overview: Procedure will demonstrate the proper operation of the Generators. Anticipated Results: Generators will operate as designed. Pre - Procedure Requirements: Generators available for testing. Sufficient fuel is available for operation of the generators. Load banks are installed on electrical distribution system for false electrical loading. Section 03 Commissioning System Testing Details Sy:; "11 „:-,nmusva,uul Geldd; Detailed Procedure: Complete 1. Visual Check Generator 4. 4 1.1. Check for loose objects on and around generator. Ni 1.2. Check belt tension on radiator fan 4 1.3. Ensure all covers are in place over generator air intake and exhaust 4 1.4. Ensure generator radiator exhaust clear. Y 1.5. Check fuel system piping for any signs of leaks in generator 1.6. Check coolant level at radiator. 1.7. Breaker cabinet dosed and all panels in place Template Rev. 110606 Lee Technologies Services, Inc. © Copyright 2010;;' Proprietary use pursuant to company policy L� S" LEE TECHNOLOGIE LEVEL 4 CHECKLIST Template Rev. 110606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 13. 1.8. Enclosure Emergency Lamps working 4 1.9. Block heater(s) on 'J 1.10. Battery voltage (28 volts) 4 1.11. Fire Extinguishers mounted and charged q 1.12. All pop rivets and screws secure 'J 1.13. All electrical conduit secured properly 'J 1.14. Inside of enclosure is cleaned by the installing contractor and free of construction materials or debris _ f V 1.15. Exhaust and Intake Louvers closed 1.16. Fuel Piping secured and no leaks or frayed hoses. 4 2. Alarm Checks Gen 4 Switchboard: 2.1. Activate High Coolant Temperature Alarm 2.2. Activate Low Coolant Temperature Alarm I/ 2.3. Activate Low Oil Pressure Alarm 4 2.4. Activate Not in Auto Alarm 4 2.5. Activate Low Battery Alarm 4 2.6. Activate Battery Charger Failure Alarm 4 2.7. Activate Over Speed Alarm 2.8. Activate Over Crank 3. Visual Check Generator 5. 4 3.1. Check for loose objects on and around generator. 3.2. Check belt tension on radiator fan V Template Rev. 110606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 13. el LEE TECHNOLOGIES" LEVEL 4 CHECKLIST Template Rev. 110606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 13 3.3. Ensure all covers are in place over generator air intake and exhaust 4 3.4. Ensure generator radiator exhaust clear. 4 3.5. Check fuel system piping for any signs of leaks in generator 4 3.6. Check coolant level at radiator. Y 3.7. Breaker cabinet closed and all panels in place 4 3.8. Enclosure Emergency Lamps working 4 3.9. Block heater(s) on 4 3.10. Battery voltage (28 volts) 4 3.11. Fire Extinguishers mounted and charged 4 3.12. All pop rivets and screws secure 3.13. All electrical conduit secured properly 4 3.14. Inside of enclosure is cleaned by the installing contractor and free of construction materials or debris 4 3.15. Exhaust and Intake Louvers closed 4 3.16. Fuel Piping secured and no leaks or frayed hoses. 4 4. Alarm Checks Gen 5 Switchboard: 4 4.1. Activate High Coolant Temperature Alarm 4.2. Activate Low Coolant Temperature Alarm 4 4.3. Activate Low Oil Pressure Alarm 4 4.4. Activate Not in Auto Alarm 4.5. Activate Low Battery Alarm _r 4.6. Activate Battery Charger Failure Alarm Template Rev. 110606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 13 LEE TECHNOLOGIES" LEVEL 4 CHECKLIST Template Rev. 110606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 4of13 4.7. Activate Over Speed Alarm ' f 4.8. Activate Over Crank 'J 5. Visual Check Generator 6 'J 5.1. Check for loose objects on and around generator. 'J 5.2. Check belt tension on radiator fan 4 5.3. Ensure all covers are in place over generator air intake and exhaust 4 5.4. Ensure generator radiator exhaust clear. 'J 5.5. Check fuel system piping for any signs of leaks in generator 5.6. Check coolant level at radiator. 4 5.7. Breaker cabinet closed and all panels in place 'J 5.8. Enclosure Emergency Lamps working 5.9. Block heater(s) on 'J 5.10. Battery voltage (28 volts) 'J 5.11. Fire Extinguishers mounted and charged 'J 5.12. All pop rivets and screws secure 'J 5.13. All electrical conduit secured properly 5.14. Inside of enclosure is cleaned by the installing contractor and free of construction materials or debris 5.15. Exhaust and Intake Louvers closed 5.16. Fuel Piping secured and no leaks or frayed hoses. 4 6. Alarm Checks Gen 6 Switchboard: . 6.1. Activate High Coolant Temperature Alarm Template Rev. 110606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 4of13 LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Template Rev. 110606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy 6.2. Activate Low Coolant Temperature Alarm 4 6.3. Activate Low Oil Pressure Alarm 'J 6.4. Activate Not in Auto Alarm 'J 6.5. Activate Low Battery Alarm 'J 6.6. Activate Battery Charger Failure Alarm 'J 6.7. Activate Over Speed Alarm J 6.8. Activate Over Crank 4 7. Manual Start Generator 4. 7.1. Record Generator Hours 1 'J 7.2. Check Generator Oil Level 'J 7.3. Check Generator Coolant Level 'J 7.4. Check Generator Coolant Temperature 108°f 4 7.5. At the generator 4 local control panel selector switch select Manual (Parallel Switch in Auto). 4 7.6. Record the following from the generator local control panel: 4 7.6.1. Voltage Phase A to B 480 VAC 4 7.6.2. Voltage Phase B to C 480 VAC 4 7.6.3. Voltage Phase A to C 480 VAC 4 7.6.4. Oil Pressure 57 PSI 4 7.7. Frequency 60HZ 'J 7.8. Temperature 130 °f 4 7.9. Retum Generator selector switch to auto, generator will shutdown after a timed cool down period. 5 minute cool down 8. Testing local shutdown and Emergency Off Template Rev. 110606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy LEE TECHNOLOGIES" Li LEVEL 4 CHECKLIST Template Rev. 110606 Lee Technologies Services, Inc.: © Copyright 2010 Proprietary use pursuant to company policy„ 8.1. Start generator again by selecting Manual on the local control panel. 4 8.2. Allow generator to reach operating speed. 'J 8.3. At the generator local control panel press the Emergency Stop Button 4 8.4. Note generator comes to complete stop and indicates. 8.4.1. Emergency Stop 'J 8.4.2. Fault Shutdown 'J 8.5. Check for the following alarms at the paralleling switchboard 8.5.1. Generator Circuit Breaker Open 'J 8.5.2. Engine Failure Alarm 4 8.5.3. EMPD Diagnostics Fault 'J 8.5.4. Engine Failure 'J 8.5.5. Generator 4 Locked out © Tie Breaker Panel 8.6. Reset Emergency stop by turning selector switch to stop reset position and again to auto. 9. Manual Start Generator 5. 'J 9.1. Record Generator Hours 2.1 9.2. Check Generator Oil Level 'J 9.3. Check Generator Coolant Level 4 9.4. Check Generator Coolant Temperature 102 °f 4 9.5. At the generator 5 local control panel selector switch select Manual (Parallel Switch in Auto). 9.6. Record the following from the generator local control panel: 11 9.6.1. Voltage Phase A to B 480 VAC Template Rev. 110606 Lee Technologies Services, Inc.: © Copyright 2010 Proprietary use pursuant to company policy„ to/ � LEE TECHNOLOGIES" • 4)) LEVEL 4 CHECKLIST Template Rev. 110606 Lee Technologies Services, Inc: Copyright 2010. Proprietary use pursuant to company policy. Page ,7of13 9.6.2. Voltage Phase B to C 480 VAC '` f 9.6.3. Voltage Phase A to C 480 VAC 'J 9.6.4. Oil Pressure 57 PSI 'J 9.7. Frequency 60 HZ 4 9.8. Temperature 159°f 4 9.9. Return Generator selector switch to auto, generator will shutdown after a timed cool down period. 5 minute cool down _ 11 10. Testing local shutdown and Emergency Off 10.1. Start generator again by selecting Manual on the local control panel. 10.2. Allow generator to reach operating speed. 'J 10.3. At the generator local control panel press the Emergency Stop Button 4 10.4. Note generator comes to complete stop and indicates. 10.4.1. Emergency Stop 10.4.2. Fault Shutdown 'J 10.5. Check for the following alarms at the paralleling switchboard 10.5.1. Generator Circuit Breaker Open q 10.5.2. Engine Failure Alarm 10.5.3. EMPD Diagnostics Fault 'J 10.5.4. Engine Failure 4 10.5.5. Generator 5 Locked Out © Tie Breaker Panel 4 10.6. Reset Emergency stop by turning selector switch to stop reset position and again to auto. �. 11. Manual Start Generator 6. 11.1. Record Generator Hours .2 Template Rev. 110606 Lee Technologies Services, Inc: Copyright 2010. Proprietary use pursuant to company policy. Page ,7of13 • LLEE TECHNOLOGIES' LEVEL 4 CHECKLIST Template Rev. 110606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy. Page 8 of 13. 11.2. Check Generator Oil Level 'J 11.3. Check Generator Coolant Level 'J 11.4. Check Generator Coolant Temperature 156 °f 4 11.5. At the generator 6 local control panel selector switch select Manual (Parallel Switch in Auto). iJ 11.6. Record the following from the generator local control panel: g 11.6.1. Voltage Phase A to B 480 4 11.6.2. Voltage Phase B to C 480 4 11.6.3. Voltage Phase A to C 480 4 11.6.4. Oil Pressure 80 'J 11.7. Frequency 60.1 'J 11.8. Temperature 158°f 11 11.9. Return Generator selector switch to auto, generator will shutdown after a timed cool down period. 5 minute cool down _ J 12. Testing local shutdown and Emergency Off 12.1. Start generator again by selecting Manual on the local control panel. 12.2. Allow generator to reach operating speed. 1 12.3. At the generator local control panel press the Emergency Stop Button 12.4. Note generator comes to complete stop and indicates. 4 12.4.1. Emergency Stop 'J 12.4.2. Fault Shutdown 'J 12.5. Check for the following alarms at the paralleling switchboard 12.5.1. Generator Circuit Breaker Open 12.5.2. Engine Failure Alarm ' + Template Rev. 110606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy. Page 8 of 13. LEE TECHNOLOGIES` 410 � L LEVEL 4 CHECKLIST Template Rev. 110806 • . Lee Technologies Services, Inc.. Copyright 2010 Proprietary use pursuant to company policy Page9.of13 12.5.3. EMPD Diagnostics Fault 4 12.5.4. Engine Failure 4 12.5.5. Generator 6 Locked out @ Tie Breaker Panel 4 12.6. Reset Emergency stop by turning selector switch to stop reset position and again to auto. 4 13. Perform Generator Load test from Generator Control Panel, perform the following: 4 13.1. Select Manual on the AUTO/MANUAL Selector Switch 4 13.2. Select Gen 4 on the Generator Parallel Selector Switch 4 13.3. Select Test On Line On Generator 1 Selector Switch 13.3.1. Generator will Start and Generator Output Breaker 52G1 will close 4 13.3.2. Check Generator Systems prior to closing load bank 4 13.4. Close Load Bank Circuit Breaker 'J 13.4.1. Load Step Generator 4 and record 7/9/2010 4 9.4.2 19% TIME: 1000 KW 422 9.4.3 28% TIME: 1010 KW 834 4 9.4.4 55% TIME: 1020 MW 1.23 4 9.4.5 73% TIME: 1030 MW 1.63 9.4.6 90% TIME: 1040 MW 2.02 4 9.4.7 100% TIME: 1050 MW 2.24 4 13.5. 4 hour Bum-in Note: Periodic reading will be taken of the generator. _ 1 11 13.6. Disconnect load at load bank Master Load selector and panel, leave fan running until heater coils cool 9.5 Cycle Crank Test. Template Rev. 110806 • . Lee Technologies Services, Inc.. Copyright 2010 Proprietary use pursuant to company policy Page9.of13 LEE TECHNOLOGIES" 10 to/ LEVEL 4 CHECKLIST Lee Technologies Services, Inc. © Copyright 2010.. Proprietary use pursuant to company policy 9.5.2 Any method recommended by the manufacturer for the cycle crank test shall be utilized to prevent the prime mover from running. 9.5.3 Place the control switch to RUN. 4 9.5.4 Verify that the complete crank/rest cycle specified in NFPA 110 5.6.4.2 and Table 5.6.4.2 shall be observed. 1 11 13.7. At the generator 4 remote control panel selector switch select Auto, allow generator to cool down. 1 11 13.8. Repeat Step for Generator 5 'J 13.9. Select Gen 2 on the Generator Parallel Selector Switch 4 13.10. Select Test On Line On Generator 5 Selector Switch 13.10.1. Generator will Start and Generator Output Breaker 52G2 will close y 13.10.2. Check Generator Systems prior to closing load bank Al 13.11. Close Load Bank Circuit Breaker 'J 13.11.1. Load Step Generator 5 and record 'J 9.5.5 19% TIME: 0935 KW 422 4 9.5.6 28% TIME: 0945 KW 834 9.5.7 55% TIME: 0955 MW 1.23 4 9.5.8 73% TIME: 1005 MW 1.63 9.5.9 90% TIME: 1010 MW 2.02 4 9.5.10 100% TIME: 1020 MW 2.24 4 13.12. 4 hour Bum-in Note: Periodic reading will be taken of the generator. 13.13. Disconnect load at load bank panel, leave fan running until heater coils cool g 13.14. Cycle Crank Test. _ 1 13.14.1. Any method recommended by the manufacturer for the cycle crank test shall be utilized to prevent the prime mover from running. Lee Technologies Services, Inc. © Copyright 2010.. Proprietary use pursuant to company policy LEE TECHNOLOGIES" ,Zgl 410 LEVEL 4 CHECKLIST Template Rev. 1 10606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy.;. Page 11..of -13. • 13.14.2. Place the control switch to RUN. 'J 13.14.3. Verify that the complete crank/rest cycle specified in NFPA 110 5.6.4.2 and Table 5.6.4.2 shall be observed. 13.15. At the generator 5 remote control panel selector switch select Auto, allow generator to cool down and shut off. 4 13.16. Repeat Step for Generator 6 'J 13.17. Select Gen 6 on the Generator Parallel Selector Switch 4 13.18. Select Test On Line On Generator 6 Selector Switch 13.18.1.. Generator will Start and Generator Output Breaker 52G3 will close 4 13.18.2. Check Generator Systems prior to closing Toad bank 13.19. Load Bank Generators: 13.19.1. Load Step Generator 6 and record 4 13.20. Close Load Bank Circuit Breaker 13.20.1. Load Step Generator 6 and record 7/10/2010 4 9.5.11 19% TIME:1730 KW 422 4 9.5.12 37% TIME:1750 KW 834 9.5.13 55% TIME:1804 MW 1.24 4 9.5.14 73% TIME:1811 MW 1.64 4 9.5.15 90% TIME:1825 MW 2.03 li 9.5.16 100% TIME:1835 MW 2.24 4 13.21. 4 hour Bum -in Note: Periodic reading will be taken of the generator. _ r �V 13.22. Disconnect load at Toad bank panel, leave fan running until heater coils cool 13.23. Cycle Crank Test. Template Rev. 1 10606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy.;. Page 11..of -13. • LLEE TECHNOLOGIES' LEVEL 4 CHECKLIST Template Rev. 110606 Lee Technologies Services, Inc. Copyright 2010 Proprietary use pursuant to company policy Page.12 of:13 13.23.1. Any method recommended by the manufacturer for the cycle crank test shall be utilized to prevent the prime mover from running. 13.23.2. Place the control switch to RUN. 'J 13.23.3. Verify that the complete crank/rest cycle speed in NFPA 110 5.6.4.2 and Table 5.6.4.2 shall be observed. 4 13.24. At the generator 6 remote control panel selector switch select Auto, allow generator to cool down and shut off. 1 11 13.25. Record Generator 'J 13.25.1. Generator 4 Hours 5.8 'J 13.25.2.. Generator 5 Hours 6.5 13.25.3. Generator 6 Hours 5.5 'J 13.25.4. Generator 4 Fuel Level Prior to Testing 'J 13.25.5. Generator 5 Fuel Level Prior to Testing 4 13.25.6. Generator 6 Fuel Level Prior to Testing ' 1 13.25.7. Generator 4 Fuel Level After Test 7/8 Inches 218 Gallons 13.25.8. Generator 5 Fuel Level After Test 7/8 Inches 218 Gallons 4 13.25.9. Generator 6 Fuel Level After Test 7/8 Inches 218 Gallons 13.25.10. Generator 4 Fuel Used 576 gallons 4 13.25.11. Generator 5 Fuel Used 576 gallons 4 13.25.12. Generator 6 Fuel Used 576 gallons 4 Template Rev. 110606 Lee Technologies Services, Inc. Copyright 2010 Proprietary use pursuant to company policy Page.12 of:13 ‘P/ LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Section 04 Come nFniC Comments Insert any comments applicable to the procedure: • Generators used 144 gallons/ per hour during the bum -in. • Generator #4 throw a rod an hour into the 4 hour load bank test. Generator had 2.24 MW of resistive load connected to it through a Toad bank. • Generator #6 Display was reading 420AB 410BC 399CA. Switchgear technician found a bad crimp in the switchgear associated with the PTs that was loading down the voltage reading at the generator. Technician repaired the problem. Display read the correct voltages. • Generator #6 temperature was high due to a short cycle of the exhaust air reentering the louvers and air intake via the gated partition. ection • Inteuraled cv5iem T estn q �Pitlnes5 1 Lee Technologies Services, Inc. has witnessed or participated in this procedure and attests to the accuracy and completeness of this report. Printed Name: Template Rev. 110606 Signature: y./ .01/I.L 41ge JAANfitt Dan: 1 go /6 Lee Technologies Services, Inca © Copyright 2010 :.. Proprietary :use pursuant to company policy Page 1.3,of.13 Generator,#4Burn Sheet Ste p Time/Min; Record '-Time Total Voltage u- A-B •• B-C .: ;, ' `Amperage_ •. . .. 011. Pies, . KVII C-A A B.' C' . .00 9:13 2240 481 478 479 2684 2714 2681 60 57 2240 • 0• :15 °.;• 9:28 2240 481 479 479 2685 2714 2685 60 57 2240 0:30 9:43 2240 480 479 478 2687 2712 2680 60 57 2240 9:58 2240 481 478 479 2688 2713 2681 60 57 2240 10:13 2240 481 479 479 2684 2712 2680 60 57 2240 ,.1:15:;;;'.; 10:28 2240 481 478 479 2683 2711 2680 60 57 2240 1 30 10:43 2240 481 478 479 2682 2710 2684 60 57 2240 14.. 10:58 2240 481 478 479 2683 2711 2676 60 57 2240 . 11:13 2240 481 479 479 2684 2712 2682 60 57 2240 215'x' 11:28 2240 480 479 478 2679 2707 2678 60 57 2240 T x230 11:43 2240 481 478 479 2682 2712 2677 60 57 2240 2 :45 11:58 2240 481 479 479 2683 2711 2681 60 57 2240 12:13 2240 481 478 479 2680 2710 2682 60 57 2240 3.15 12:28 2230 481 479 479 2670 2704 2671 60 58 2230 3 ! -,- 12:43 2230 482 478 479 2669 2703 2669 60 58 2230 r i 3:45 >� :. 12:58 2230 482 479 479 2668 2704 2671 60 56 2230 4:00 13:13 2230 481 478 479 2670 2702 2670 60 56 2230 ;'4t30{ 5:00 ;5:30• :30'r.: eneratoar. #5: Burn Sheet?. Slap Time/Min Record Time fi� M1�i! Total VQlfrige Ampe!iye Hz Prey TEMP.' 00 1035 2.24 481 479 481 2715 2694 2667 60.1 57 189 0:15 ' 1050 2.24 481 479 481 2715 2694 2667 60.1 57 189 0:30 `, 1105 2.24 481 478 481 2714 2692 2666 60.1 57 189 . 45 1120 2.24 481 478 481 2712 2691 2668 60.1 57 189 :00 '' 1135 2.24 481 478 481 2713 2692 2664 60.1 57 189 115 • .� 1150 2.24 481 479 481 2711 2692 2666 60.1 57 189 :3 " ' ' 1205 2.24 481 479 481 2712 2690 2665 60.1 57 189 1220 2.24 481 478 481 2711 2692 2664 60.1 57 189 1235 2.24 481 478 481 2711 2692 2664 60.1 57 189 2:15 4 ` 1250 2.24 481 479 481 2711 2689 2663 60.1 57 189 1305 2.24 481 479 481 2712 2693 2665 60.1 57 189 2: 1320 2.24 481 478 481 2711 2690 2664 60.1 57 189 3:00 `;`, 1335 2.24 481 478 481 2712 2690 2664 60.1 57 189 :15 1350 2.24 481 478 481 2712 2689 2663 60.1 57 189 1405 2.24 481 479 481 2712 2690 2665 60.1 57 189 3.45 1420 2.24 481 478 481 2712 2690 2665 60.1 57 189 1435 2.24 482 478 480 2714 2691 2666 60.1 57 189 4 :15 ' 4:30 4:45 5:00 ,. 5:15 5c30 . $ :45 '6:00 6 :15: :30' 8 :45 nerator #6 Burn Sheet T ielMin:' res. 0: 10' 1835 2.24 481 479 481 2705 2711 2660 60 58 194 0:15 1850 2.24 481 479 480 2704 2711 2659 60 57 198 1905 2.24 481 479 481 2701 2709 2657 60 57 198 1920 2.24 481 479 480 2703 2709 2657 60 57 198 1: 1935 2.24 481 479 480 2703 2711 2657 60 57 198 1 :15_ 1950 2.24 481 479 480 2703 2710 2657 60 57 198 2005 2.24 481 479 481 2701 2700 2658 60 57 196 2020 2.24 481 479 480 2702 2709 2658 60 57 198 2035 2.24 481 479 480 2702 2709 2658 60 57 198 2050 2.24 481 479 480 2702 2709 2659 60 57 198 2105 2.24 481 479 480 2701 2708 2657 60 57 196 2120 2.24 481 479 480 2703 2708 2657 60 57 196 2135 2.24 481 479 480 2701 2700 2658 60 58 194 2150 2.24 481 479 480 2703 2701 2658 60 58 192 2205 2.24 481 479 480 2701 2709 2657 60 58 192 2220 2.24 481 479 480 2703 2708 2658 60 58 192 2235 2.24 481 479 480 2702 2708 2657 60 58 192 5:1 6:00 6:15 64 LEE • L� 1fS° TEGHNOLOG • • SWITCHGEAR SYSTEM INTEGRATION 'SeCtlun�1 Cheddist Title: ' comnvssioomc� ; _' INTERNAP- TUK -WA- GENERATOR - SYSTEM INTEGRATION • 'Checklist Information,: i Submittal Date: ChecMist Work Date: 7/16/2010 Checklist Work Time Frame: Customer Name: Intemap Address: Street Address: 3355 South 120th Place city Tukwila State: WA Zip: 98169 Customer POC: Customer POC Wain: Kathy Mcinvale Phone Numbers: office: 404.302.9753 Mobile: 404.547.8915 General Contractor. COMParlY Ntee: BNBuiiders Contractor POC: SueNvieer Name: Jim Gylling Office: Mobile: 509.499.8194 Lee Technologies Integration pSystem supervisor Herbert E. Burnett Paul Jahnke Phone Numbers: . Phone Numb 703- 968 -0300 Mobile: 713.423.4335 703.908.3422 Revision: Rev. 0 ,saction 02 ;.'l hetklist Qvuvi C.y. , Equipment System Integration Checks for Generators , Equipment Information: Manurectrcer. Caterpillar /GE Equipment Type: Stand by Generator/ Zenith Switchgear Model It: EC100K Sedate: 1588828 checklist Overview: Integrating new generators and the switchgear Anticipated - Results: All generator will function as one system controlled the by switchgear Pre - Checklist Requirements: Generators has completed its individual commissioning Precautions Wear hearing and eye protection around the generator area when generators are online Do not stand in front of the Switchgear breakers during the opening and closing of the switchgear breakers Caution: Proper PPE's to be wom when performing any breaker closures and openings, or if personnel is in an area requiring proper PPE ' Secfion•03 St trlufi.. . lin bot:iile.��' a.5 Detailed System Integration Checklist/ .kfiat • - .- -. checakt Complete ': Generator Prestart_ Inspection ' . TIME Generator #4 Generator #5 Generator #6 Place the generator control switch to the Lockout/Reset position and lock - out/tag -out. OK ► OK 0 OK 0 J Press in the generator EMERGENCY STOP button and lock - out/tag -out. OK 0 OK 0 OK ■ Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 1 of 17 • • • LEE TECHNOLOGIES' SWITCHGEAR SYSTEM INTEGRATION Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 2 of 17 Perform a visual inspection of the generator and check for any obvious damage or discrepancies. OK e OK ►5 OK o 4 Record fuel level: 250 gals 218.75 gals 218.75 gals Did the air cleaner elements require leaning: 0 YES • NO 0 YES • NO 0 YES • NO 4 Are all the hoses in satisfactory condition? 0 YES • NO r YES • NO 0 YES ■ NO Did any hose clamps require tightening? e YES • NO C. YES • NO ►5 YES • NO Did any belts require adjustment ■ YES 0 NO • YES e NO • YES 0 NO Is all the piping in satisfactory condition? 0 YES • NO 0 YES • NO o YES • NO Inspect batteries and ensure they are in satisfactory condition and inspect cables and Tugs for tightness (tighten if required) OK 0 OK 0 OK 0 Are battery system components in satisfactory condition 0 YES • NO ►5 YES • NO 0 YES • NO Did any connections require tightening? • YES ►.o NO • YES ►5 NO • YES 0 NO J Is the battery charger operating properly? 0 YES • NO o YES • NO 0 YES • NO Record battery charger output voltage: 27.3 VDC 27.2 VDC 27.4 VDC Inspect engine control panel and verify there are no loose connections (tighten if required). OK OK ►( OK Z� Is the jacket water heater operating properly 0 YES • NO ■- YES • NO ►_ YES • NO 4 Record coolant temperature 108 F 108 F 108 F Are the radiator and fins in satisfactory condition? F.2 YES • NO ► YES • NO 0 YES • NO J . Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 2 of 17 .1. S" LEE TECHN010GIE • • SWITCHGEAR SYSTEM INTEGRATION Does crankcase have evidence of excessive blow - by? • YES CI NO • YES 0 NO • YES ►5 NO Did the engine need to have coolant added? • YES ►5 NO • YES 0 NO • YES NO Are exhaust components in satisfactory condition? ►5 YES • NO ►5 YES • NO 0 YES ■ NO 4 Place all generators in AUTO at the generator and at the switchgear OK ►5 OK 0 OK ►5 1.1. Verify all tools and excess materials are clear of the generator and enclosure. 4 1.2. Verify all alarms have cleared, and all Generators and GE Zenith switchgear is in normal configuration with all switches in AUTO *******Monitor the refueling system for the generators verifying the generator maintain adequate fuel in there day tank.** *** **** - System No Load Test Switch: 2. At generator #6 cubide place the Engine Control Switch in the OFF position 1� 3. - Select SB -SG6A 4. At generator #6 cubicle place the Engine Control Switch in the Auto position -4 5. With the SB-SG3 in AUTO at the Master cubicle and at each generator ECS 1r g ; • Desc "'ptro z Engine Control Switch voiliol Positi o n AUTO Switch cation Generator door ECS AUMS Auto -Man Switch AUTO Master door TWLS Test With Load Switch OFF ACS LBTS Load Bank Test Switch OFF ACS 6. WARNING: System Test No Load Operation can only be performed when the switchgear is not operating in the following modes: Emergency /Standby (active) or System Test With Load 7. Go to MAIN MENU 8. Select the TEST button and TEST MENU above will be presented Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 3 of 17 • • • LEE TECHNOLOGIES' SWITCHGEAR SYSTEM INTEGRATION 9. Select each of the generators to run in the test no load operation and press the TEST NO LOAD button. J 10. The TEST NO LOAD IN PROGRESS label will illuminate. Concurrently, the system is performing the following steps: J 10.1. System under test light located on the master annunciator panel will illuminate 4 10.2. Start signal will be issued to the selected engine - generator sets. d 10.3. First generator reaching proper operating parameters will close to the de- energized emergency bus. 4 10.4. Subsequent units will synchronize and connect to the energized emergency bus. 11. Record the generator voltage, KW, and current readings: Generator #4 0 KW 477 VAC 0 AMPS Generator #5 0 KW 477 VAC 0 AMPS Generator #6 0 KW 478 VAC 0 AMPS TIME 0930. 4 12. Press the TEST NO LOAD SWITCH button again. The label will change from TEST NO LOAD IN PROGRESS to OFF. Concurrently, the system is performing the following operations: J 12.1. Signal is sent to open, each generator circuit breaker 12.2. The engine - generators will run through a cool down cycle before shutting down. 12.3. Record the cool down time delay. TD 1 minute Load Bank Test 13. Prior to the operation of the Load Bank Test, the following switches must be placed to the following position Note 1 n h c .r r s.` a tr Posisn " :rcation Y .., ° .' ECS Engine Control Switch AUTO Generator door AUMS Auto -Man Switch AUTO Master door TNL Test no Load OFF ACS TWL Test With Load OFF ACS Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 4 of 17 • • • LEE TECHNOLOGIES SWI TCHGEAR SYSTEM INTEGRATION Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 5 of 17 LBTS Load bank Test OFF I ACS 14. WARNING: System Test with Load Operation can only be performed when the switchgear is not operating in the following modes: Emergency /Standby (active), Test No Load operation or Test With Load J 15. Load demand is disabled during this test. 4 16. Zenith will enable the load demand during load bank test 1� 17. Go To MAIN MENU 4 18. Select the TEST button and TEST MENU above will be presented 19. Select the LOAD BANK button 4 20. Select the START TEST button, the LOAD BANK TEST IN PROGRESS label will illuminate. Concurrently, the system is performing the following steps: 20.1. System Test With Load Bank light located on the master annunciation panel will illuminate. 4 - 20.2. Start signal will be issued to all engine - generator sets. 4 20.3. First generator reaching proper operation parameters will close to the de- energized 4 21. CAUTION: To close load bank breaker, at least one of the generator circuit breaker must connect to the emergency bus. 4 22. Pressing the LOAD BANK BREAKER button; the LOAD BANK BREAKER CLOSED label will illuminate. NOTE: The load bank breaker is electrically interlocked to the other switchgear load bank breaker. It requires the other load bank breaker to be in open position in order that you can close the selected load bank breaker. 1 11 23. Subsequent units will synchronize and connect to the energized emergency bus. .4 24. Place the load bank online at 500 KW 25. Allow the load bank to run for 15 minutes 4 26. Verify all generators are sharing 4 Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 5 of 17 0 LEE TECHNOLOGIES° i • • SWITCHGEAR SYSTEM INTEGRATION 27. Record the actual readings. Generator #4 100 KW 480 Generator #5 200 KW 479 Generator#6 200 KW 479 VAC VAC VAC 200 AMPS 200 AMPS 200 AMPS TIME 0950 28. Place the Toad bank online at 1000 KW 29. Allow the load bank to run for 15 minutes 30. Verify all generators are sharing 31. Record the actual readings. Generator #4 100 KW 480 Generator #5 200 KW 479 Generator #6 200 KW 479 VAC VAC VAC 200 AMPS 200 AMPS 200 AMPS TIME 0950 32. Place the load bank online at 1500 KW J 33. Allow the load bank to run for 15 minutes 34. Verify all generators are sharing 4 35. Record the actual readings. Generator #4 100 KW 480 Generator #5 200 KW 479 Generator #6 200 KW 479 VAC VAC VAC 200 AMPS 200 AMPS 200 AMPS TIME 0950 36. Place the load bank online at 2000 KW '4 37. Allow the load bank to run for 15 minutes 4 38. Verify all generators are sharing ,i 39. Record the actual readings. Generator #4 100 KW 480 VAC 200 AMPS TIME , J • Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 6 of 17 • • /4t LEE TECHNOLOGIES" t, SWITCHGEAR SYSTEM INTEGRATION Generator #5 200 KW 479 VAC 200 AMPS Generator #8 200 KW 479 VAC 200 AMPS 0950 40. Tum the Master control power off 1i 41. Allow the Toad bank to cool down 42. Press the Load Bank Test In Progress to the OFF position. Concurrently, the system is performing the following operations 42.1. Signal to sent to open each generator circuit breaker 4 42.2. Load Bank Breaker (52- TB -LB3) will trip open and remain in the OPEN position 1I 42.3. The engine - generators will run through a cool down cycle before shutting down 1� ya }..:.. � r � t r Yr t . . } r j m4 -c } tk... . ,.r .., `j'- .7 .>.'WA r lll .M T r. , %` 3 /� ry 's'Y h5 •.7 ' 7 j11, anual. O�rao,.. . 141.Y '''614.7..t �. +9+R. i�+ .',,, , '4 . 1?57raf41 {a.J�4,47.4 l , :k: . ,4 o• ,,, { v �`ZT u Note 1 CAUTION: 43: Place each engine - generator's ECS in the OFF position prior to start the manual operation. 44. Ensure that each engine - generator's breaker is in the OPEN position. 1[ 45. Place the AUMS switch, located on master control section door, in the MANUAL position. 11 46. Manually start generator #4 48.1. At Master cubicle place the Master Selector switch from AUTO to MANUAL 46.1.1. The red "System Not In Auto" light on the Master Cubicle flashes to indicate that the system is not under automatic control. 48.2. Open the swing panel on the master control cubicle position, it so that its instruments can be observed from in front of the generator control cubicles. 48.3. At Generator #4 cubicle "Engine Control Switch" switch located on the generator control cubicle in the "MAN" position 46.3.1. Initially, the emergency bus is DE- ENERGIZED; tum Synchronizing Switch (SS) knob to the ON position. 46.3.2. Verify that Generator #4 starts and begin ramping up in frequency and voltage 11 Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 7 of 17 ill LEE TECHNOLOGIES' • • • SWITCHGEAR SYSTEM INTEGRATION 46.3.3. At generator #4 cubicle tum the "Speed Control" (85S) switch located on the generator control cubicle for the engine running. 46.3.3.1. If the frequency is not correct + or— 0.5HZ, turn the °Speed Adjust" potentiometer on the cubicle to correct the frequency (clockwise to raise, counter clockwise to lower). 4 46.3.4. The "Voltage Control" switch, located on the generator control cubicle for the running engine, verify that voltage is present on all three phases of the generator output, and then leave the switch In the 3 -1 position. Phase to Phase voltage should read approximately 480 VAC. 4 46.3.4.1. If the voltages are not correct + or —10V, tum the "Voltage Control" potentiometer (90S) on the cubicle to correct the voltage (under normal conditions voltage should not need adjustment). (Clockwise to raise, Counter clockwise to lower). 46.3.5. Place the "Generator Circuit Breaker" switch, located on the generator control cubicle for the running engine, in the "Close position and release it. 46.3.6. Place the Synchronizing Switch (SS) in the OFF position and remove the handle from the slot for operation with the next engine - generator to parallel. 46.4. Walk to Standby Generator #4 Control panel and view the display. The display voltage will be around 480 VAC. The display frequency will be 60 HZ 4 46.5. At the switchgear verify generator #4 breaker closes 47: Go To MAIN MENU 4 48. Select the TEST button and TEST MENU above will be presented 1i 49. Select the LOAD BANK button 4 50. Select the START TEST button, the LOAD BANK TEST IN PROGRESS label will illuminate. Concurrently, the system is performing the following steps: 50.1. System Test With Load Bank light located on the master annunciation panel will illuminate. 50.2. Start signal will be issued to all engine - generator sets. 50.3. First generator reaching proper operation parameters will close to the de- energized 51. CAUTION: To close load bank breaker, at least one of the generator circuit breaker must connect to the emergency bus. 51.1.1. Tum the master select switch to On v 51.1.2. Load bank should be placed online at 25% initially, and then after 15 min 100% for the rest of the test. TIME Template Rev. 021105 Lee Technologies Group ©2010 Proprietary use pursuant to company policy Page 8 of 17 LEE TECHNOLOGIES' •L • • SWITCHGEAR SYSTEM INTEGRATION Template Rev. 021108 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 9 of 17 1115 512. Lee will take reading at the generators regarding voltage and current. Readings will be taken every 15 min intervals. 51.3. Record the actual readings: Generator #4 1988 KW 476 VAC 2414 AMPS TIME 1115 Synchronizing and Paralleling : Note 1 52. At Generator# 5 cubicle "Engine Control Switch" switch located on the generator control cubicle in the "MAN" position 52.1. Verify that generator #5 starts and begin ramping up in frequency and voltage 4 52.2. At generator #5 cubide tum the "Speed Control" (65S) switch located on the generator control cubicle for the engine running. J 52.2.1. If the frequency is not correct + or— 0.5HZ, tum the °Speed Adjust" potentiometer on the cubicle to correct the frequency (clockwise to raise, counter clockwise to lower). 52.3. Rotate the 'Voltmeter" switch, located on the generator control cubicle for the running engine, verify that voltage is present on all three phases of the generator output, and then leave the switch in the 3-1 position. Phase voltages should read approximately 480V. 52.3.1. If the voltages are not correct + or —10V, tum the 'Voltage Adjust" potentiometer on the cubide to correct the voltage (under normal conditions voltage should not need adjustment). (Clockwise to raise, Counter clockwise to lower). _ -r �1 52.4. Walk to Standby Generator #5 Control panel and view the display. The display Voltage will be around 480V. The display frequency will be 60HZ 52.5. Insert It In the `Synchronizing switch (SS) located on fourth generator control cubicle, and Place the switch in the °On" position. 52.5.1. If the synchronscope needle rotates rapidly in a clockwise direction, adjusting 65S can slow it down. The synchronscope needle should be rotating slowly in the clockwise or 'fast" direction before closing the engine-generator circuit breaker manually NOTE: Observe the synchronizing lights of the subsequent generators. They should be dimmed when the incoming generator is in phase with the emergency bus. The synchronizing lights are at their brightest when the incoming generators and the emergency bus re completely out of phase. 4 52.6. Place generator #5 circuit breaker switch (52S) in the CLOSED position. The emergency main bus is now energized by generators 4 and 5 4 52.7. At the swltchgear verify generator #5 breaker closes 4 52.8. Retum the Synchronizing switch to the off position. 4 Template Rev. 021108 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 9 of 17 • • • LEE TECHNOLOGIES' SWITCHGEAR SYSTEM INTEGRATION 52.9. Check to see that the KW and amps are shared equally between the two generators 4 and 5 52.10. Record the actual readings: Generator #4 1000 KW 476 VAC 1200 AMPS Generator #5 1000 KW 476 VAC 1200 AMPS TIME 1120 52.11. Monitor the operations of the generators for 15 minutes 52.12. At generator #6 section place the Engine Control Switch in the OFF position 52.12.1. Select SB -SG3A 52.12.2. Place the Engine Control Switch to the "MAN" position '4 52.13. Verify that generator# 6 starts and begin ramping up in frequency and voltage '4 52.14. At generator #6 cubicle tum the "Speed Control" (65S) switch located on the generator control cubicle for the engine running. 52.14.1. If the frequency is not correct + or — 0.5HZ, tum the "Speed Adjust" potentiometer on the cubicle to correct the frequency (clockwise to raise, counter clockwise to lower). - 52.15. Rotate the "Voltmeter" switch, located on the generator control cubicle for the running engine, verify that voltage is present on all three phases of the generator output, and then leave the switch in the 3-1 position. Phase voltages should read approximately 480V. 52.15.1. If the voltages are not correct + or — 10V, turn the "Voltage Adjust" potentiometer on the cubicle to correct the voltage (under normal conditions voltage should not need adjustment). (Clockwise to raise, Counter clockwise to lower). 4 52.16. Walk to Standby Generator #3 Control panel and view the display. The display Voltage will be around 480V. The display frequency will be 60HZ 52.17. Place the keyed - handle from the "Synchronizing" switch, located on the second generator control cubicle C2 in the "Off° position and remove it. Insert it in the "Synchroscope° switch located on the second generator control cubicle C3. Place the switch in the On position. 52.18. Insert it in the "Synchronizing switch (SS) located on fourth generator control cubicle, and Place the switch in the "On" position. 52.18.1. If the synchronscope needle rotates rapidly in a clockwise direction, adjusting 65S can slow it down. The synchronscope needle should be rotating slowly in the clockwise or °fast" direction before closing the engine - generator circuit breaker manually NOTE: Observe the synchronizing lights of the subsequent generators. They should be dimmed when the incoming generator is in phase with the emergency bus. The synchronizing lights are at their brightest when the incoming generators and the emergency bus re completely out of phase. Template Rev. 021105 Lee Technologies Group @ 2010 Proprietary use pursuant to company policy Page 10 of 17 • • • LEE TECHNOLOGIES' SWITCHGEAR SYSTEM INTEGRATION 52.19. Place generator #6 circuit breaker switch (52S) in the CLOSED position.. The emergency main bus is now energized by generators 4, 5, and 6 4 52.20. At the switchgear generator #6 breaker will dose 52.21. Retum the Synchronizing switch to the off position. 1� 52.22. Check to see that the KW and amps are shared equally between the three generators 4 52.22.1. Record the actual readings: Generator #4 700 KW 476 VAC 800 AMPS Generator #5 700 KW 476 VAC 800 AMPS Generator #6 700 KW 476 VAC 800 AMPS TIME 1124 J 52.23. Place the 'Engine Control Switch" located on generator #5 cubide in the "Off position. 4 52.24. Verify at the switchgear generator #6 breaker will open 4 52.25. Generator engines will automatically go into cool down. After cool down, engines automatically shutdown. Wait for generators to shutdown before proceeding to next step. 52.26. Check to see the KW and amps are shared equally between the two generators 4 and 6 If 52.26.1. Record the actual readings: Generator #4 1000 KW 476 VAC 1200 AMPS Generator #6 1000 KW 476 VAC 1200 AMPS TIME 1125 4 52.27. Monitor the operations of the generators for 15 minutes 52.28. Tum off the load bank master switch and allow Toad banks to cool down 4 52.29. Turn off control power to the Toad bank 4 52.30. Allow the generators to go through cool down Time Delay 6 minutes 4 52.31. Place the "Engine Control Switch' located on each generator cubicle 4 in the °Off' position. 52.32. Place the "Engine Control Switch" located on each generator cubicle 6 in the Off position. J 52.33. At Generator #4 (C3) place the °Circuit Breaker Control° switch in the 'TRIP" position. : = 4 Template Rev. 021105 Lee Technologies Group © 2010 Proprletary use pursuant to company policy Page 11 of 17 • • • LEE TECHNOLOGIES" SWITCHGEAR SYSTEM INTEGRATION 52.34. At Generator #6 (C4) place the "Circuit Breaker Control" switch in the "TRIP" position. 4 52.35. At the switchgear generator #4 breaker will open 1' 52.36. At the switchgear generator #6 breaker will open 52.37. Verify all generators are okay mechanically 4 52.38. Record the amount of fuel in the day tanks by the Omntec monitoring system Day Tank# 1 7/8 Day Tank #2 7/8 Day Tank #3 7/8 52.39. At each generator cubicle "Engine Control Switch" into AUTO '4 52.40. At the Master cubicle (CC) place the switch into AUTO 52.41. Verify all generator go through a cool down and tum off 1� Alarms, Swttchgear Generator, Generators" 3 . • Pass • Fail ' _.: r. Overvoltage alarm Monitored through the generator bus and controlled by MFR -13 Relay • Pass • Fail • Pass • Fail Under voltage alarm Monitored through the generator bus and controlled by MFR -13 Relay • Pass ■ Fail • Pass • Fail • Pass • Fail Over frequency alarm Monitored through the generator bus and controlled by MFR -13 Relay I■ Pass • Fail • Pass • Fail • Pass • Fail Under frequency alarm Monitored through the generator bus and controlled by MFR-13 Relay • Pass ■ Fail • Pass • Fa it • Pass • Fail Reverse Power Mo Monitored through the • Pass ■ Fail • Pass 1 Fail . • Pass • Fail Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 12 of 17 • • • LEE TECHNOLOGIES SWITCHGEAR SYSTEM INTEGRATION Template Rev. 021105 Lee Technologies Group @ 2010 Proprietary use pursuant to company policy Page 13 of 17 generator bus and controlled by MFR - 13 Relay nitored through the generator bus and controlled by MFR - 13 Relay Load Imbalance Monitored through the generator bus and controlled by MFR -13 Relay ❑ Pass ❑ Fail ❑ Pass • Fail • Pass • Fail Loss of Excitation Monitored through the generator bus and controlled by MFR -13 Relay • Pass • Fail • Pass • Fail • Pass • Fail Time Overcurrent Monitored through the generator bus and controlled by MFR -13 Relay • Pass ❑ Fail • Pass • Fail • Pass • Fail Voltage Asymmetry Monitored through the generator bus and controlled by MFR -13 Relay • Pass • Fail • Pass • Fail • Pass • Fail High Water Temperature (Shutdown) 0 Pass • Fail 0 Pass • Fail ►Z4 Pass • Fail Low 011 Pressure (Shutdown) 0 Pass . 0 Fail ►Z4 Pass I■ Fail 0 Pass • Fail Engine Summary Alarm ►1 Pass • Fail 0 Pass • Fail 0 Pass ❑ Fail Engine Overcrank (Shutdown) �1 Pass • Fail ►5 Pass • Fail 0 Pass • Fail wit • , gea A arms ; Sh d ns , enerator l ; s- Gene for f • Fail ,,r 0 Generator Generator Summary Shutdown 0 Pass • Fail 0 Pass Pass • Fail Generator Protective Relay Summary Alarm • 0 Pass • Fan ►Z. Pass • Fail ►.0 Pass • Fail Template Rev. 021105 Lee Technologies Group @ 2010 Proprietary use pursuant to company policy Page 13 of 17 • • • LEE TECHNOLOGIES SWITCHGEAR SYSTEM INTEGRATION Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 14 of 17 Generator Protective Relay Summary Alarm (Shutdown) Pass Fail Pass Fail Pass ' • Fail ►_ • ■ • 0 Generator Failed to Synchronize 0 Pass • Fail r Pass • Fail 0 Pass • Fail High Water Temperature Warning CI Pass • Fail 0 Pass • Fail 0 Pass • Fail Low Oil Pressure Warning 0 Pass ■ Fail 0 Pass • Fail 0 Pass • Fail Battery Charger Failure 0 Pass • Fail 0 Pass ❑ Fail 0 Pass • Fail Low Water Level Note 2 • Pass • Fail • Pass • Fail • Pass • Fail Emergency Stop Activated (Shutdown) ►� Pass • Fail 0 Pass • Fail ►5 Pass • Fail Engine Summary Alarm ►5 Pass • Fail 0 Pass • Fail 0 Pass • Fail Engine Running 0 Pass • Fail 0 Pass • Fail 0 Pass • Fail Engine Not In AUTO R =NOT In AUTO(FLASHING) 0 Pass • Fail 0 Pass • Fail ►5 Pass • Fail Control Voltage Failure 0 Pass • Fail 0 Pass • Fail ►5 Pass • Fail Low Water Temperature Alarm Pass Fail Pass Fail Pass • Fail ►5 • 0 • ►:4 Day Tank Critical Low Fuel Level (Shutdown) Generator & BMS Only ►5 Pass • Fail ►Z4 Pass • Fail 0 Pass • Fail Day Tank High Fuel Level BMS Only 0 Pass • Fail ►Z1 Pass • Fail L Pass • Fail Su(' - gearGL,us3 Generate Generate C . Day Tank Low Fuel Level 0 Pass • Fail r Pass • Fail 0 Pass • Fail Generator Protective Relay Failsafe 0 Pass • Fail 0 Pass • Fail ►P Pass • Fail Remote Gen. Breaker 0 Pass • Fail ►Z. Pass • Fail ►5 Pass • Fail Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 14 of 17 • • LEE TECHNOLOGIES' 16, SWITCHGEAR SYSTEM INTEGRATION Template Rev. 021105 Lee Technologies Group @ 2010 Proprietary use pursuant to company policy Page 15of17 Open (Shutdown) Engine in Cool down Mode (Status) 0 Pass • Fail C1 Pass • Fail ►0 Pass • Fail Generator Breaker Failed to Close ►..4 Pass • Fail 0 Pass • Fail 0 Pass • Fail Generator Breaker Failed to Open ►5 Pass • Fail 0 Pass • Fail i2 Pass • Fail Template Rev. 021105 Lee Technologies Group @ 2010 Proprietary use pursuant to company policy Page 15of17 • • • LEE TECHNOLOGIES SWITCHGEAR SYSTEM INTEGRATION Generator Post Inspection TIME 1135 Gene..., 7/8 gals ,y ere ..... :y e , or Record fuel level: 7/8 gals 7/8 gals Did the air cleaner elements require leaning: 0 YES • NO 0 YES • NO 0 YES II NO Are all the hoses in satisfactory condition? 0 YES • NO ►5 YES • NO 0 YES • NO Did any hose damps require tightening? • YES 0 NO • YES 0 NO • YES 0 NO Did any belts require adjustment • YES 0 NO • YES ►5 NO • YES 0 NO Is all the piping in satisfactory condition? 0 YES • NO e YES • NO ►5 YES • NO Inspect batteries and ensure they are in satisfactory condition and inspect cables and lugs for tightness (tighten if required) OK 0 OK 0 OK 0 Are battery system components in satisfactory condition 0 YES • NO 0 YES • NO 0 YES • NO -Did any connections require tightening? • YES NO • YES ►5 NO • YES ►0� NO Is the battery charger operating properly? 0 YES • NO ►5 YES • NO 0 YES • NO Record battery charger output voltage: 27.3 VDC 27.3 VDC 27.3 VDC Inspect engine control panel and verify there are no loose connections (tighten if required). OK 0 OK 0 OK 0 Is the jacket water heater operating properly .0 YES • NO e YES ® NO 0 YES • NO Record coolant temperature 174 F 174 F 174 F Are the radiator and fins in satisfactory condition? 0 YES • NO 0 YES • NO 0 YES • NO Does crankcase have evidence of excessive blow -by? • YES 0 NO • YES e NO • YES NO Did the engine need to have coolant added? • YES ►5 NO • YES ►5 NO • YES ►5 NO Template Rev. 021105 Lee Technologies Group @ 2010 Proprietary use pursuant to company policy Page 16 of 17 • • • LEE TECHNOLOGIES' SWITCHGEAR SYSTEM INTEGRATION Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 17 of 17 Are exhaust components in satisfactory condition? 0 YES • NO 0 YES • NO 0 YES • NO Place all generators in AUTO at the generator and at the switchgear OK 0 OK e OK e 52.42. Verify all tools and excess materials are clear of the generator and enclosure. 1� 52.43. Verify all alarms have cleared and check the configuration for both the generators and switchgear is in normal configuration Section 0-1 Comments Insert any comments applicable to the Checklist: Note 1: These tests were simulated by the GE technician by placing jumpers into the switchgear to get the unit to conduct the test. Note 2: Discrete VO module is full with no dry contact available to produce this alarm at the switchgear. Section 05 Lee Technologies representative has witnessed or participated in this checklist, has verified equipment is ready per cl,eckt;st witness u checklist, and attests to the accuracy and completeness of .Is report, Va14ication Lee Tech's Representative A7nted Narre* is Ft= ��M Sig bare. Mi y /�f 0.7 LIti ji°t "11�►v,��`M Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 17 of 17 • VOLTAGE TIMEPLOTS Site: !NAP PDU 3A1 Measured from 07/03/2010 07:34:22.0 to 07/03/2010 11:30:37.0 230 220 .0 210 O 200 190 230 220 .ts 210 6 200 190 230 220 ZI 210 0 200 190 1 9 T 1 .—A B Vrms .w/m■Ia•M. — B-C Vr ms — C-A Vr ms 08:00 07/03/2010 Saturday I 08:30 09:00 1 1 1 1 1 1 I 11:30 09:30 Cessix1.1110EnVlom 10:00 10:30 11:00 • WORST CASE SUMMARY Site: INAP PDU 3A1 Measured from 07/03/2010 07:34:22.0 to 07/03/2010 11:30:37.0 Of 0 total VOLTAGE SAGS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE SWELLS DATEITIME CRITERIA PHASE CATEGORY DATA Of 0 total VOLTAGE INTERRUPTIONS DATE/TIME CRITERIA PHASE CATEGORY DATA Of 0 total VOLTAGE TRANSIENTS DATA DATEITIME CRITERIA PHASE WORST CASE SUMMARY WAVEFORMS Site: INAP PDU 3A1 Measured from 07/03/2010 07:34:22.0 to 07/03/2010 11:30:37.0 Lowest Magnitude Voltage Sag:No event Highest Magnitude Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Sag:No event Longest Duration Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Most Energy Missing Voltage Sag:No event Most Energy Added Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Interruption:No event Largest Magnitude Voltage Transients:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE 0 • PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3A1 Measured from 07/03/2010 07:34:22.0 to 07/03/2010 11:30:37.0 VOLTAGE Volts 3.175 3.150 3.125 3.100 3.075 3.050 0730 07/03/2010 Saturday Volts 3.0 2.5 2.0 1.5 1.0 0.5 0.0 r � 08 00 r i 08 30 09:00 09 30 -A BVTHDRss(mg) C mod Cl.1 10:00 I 10:30 r � 11 00 11 30 _ /mina r r H2O 1 I i THD I I I I I r r�r H10 Total RMS: DC Level: Fundarrental(H1) RMS: Total Hamlonic Distortion THD: Nil_ lm___rm_Q_ r 1 1 1 1 1 1 1 1 1 1 1 1 ri H30 H40 ® A- BVHarm 117.72 V 0.00V 0.00V 3.19V(Eva1:0.12V, Odd 3.19V) H50 4Il • PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3A1 Measured from 07/03/2010 07:34:22.0 to 07/03/2010 11:30:37.0 CURRENT Amps 9.7 9.6 9.5 9.4 9.3 bamssmaz • • 92 — 07 30 07/03/2010 Saturday Amps 10.0 7.5 —A 5.0 — 2.5 0.0 08:00 08:30 09:00 09:30 — A ITHDRss (arg) c..r wit ncmvi.. 811.1 1 1 1 10:00 10:30 11.00 11:30 1 1 1 1 THD H10 i i 1 1 H2O ® A!Harm 1 ' H30 Total RMS: 60 &84 A DC Level: 323A Furxarrental(H1) RMS: 60 &90 A Total HamnnicDistortionTHD: 9.75A(Eve'1:045A, Odct 9.74 A) H40 H50 PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3A1 Measured from 07/03/2010 07:34:22.0 to 07/03/2010 11:30:37.0 VOLTAGE Volts 3.425 3.400 3.375 3.350 3.325 3.300 3275 I ' 07:30 07/03/2010 Saturday Volt 3.5 3.0 - 2.5 2.0 1.5 — 1 1 1 1 1 1 1 1 1 06:00 06:30 09:00 09:30 1 1 I 1 1 10:00 10:30 11:00 11:30 — B C VTHDRss (atg) 1.0 j 0.5 0.0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 care THD H10 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 H1 H2O H30 H40 ® B-CVHarm Total RMS: 11803 V DC Level: 0.00V Furtdarrental(H1) RMS: 0.00V Total HarrrtonicDistortionTHD: 3.43V(Evat:0.11 V, Odd 3.43V) PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3A1 Measured from 07/03/2010 07:34:22.0 to 07/03/2010 11:30:37.0 CURRENT Amps 9.75 9.70 9.65 9.60 9.55 9.50 9.45 9.40 9.35 07:30 07/0312010 Saturday Amps 10.0 7.5 — 5.0 r • � I ' 08:00 e • 1 1 1 1 1 1 1 1 1 1 1 r 1. 1 ' 1 08:30 09:00 09:30 10:00 10:30 11:00 11:30 2.5 — 0.0 — B ITHDRss (aag) cw.a...uavir WI • i 1 1 1 r r i THD 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 l i 1 1 1 1 1 1 1 1 l i i r 1 1 1 1 1 1H5o H40 H2O ® BIHarm H30 Total RMS: 59896 A DC Level: 3.09 A Fund-arrental(H1) RMS: 59882 A Total HarmonicDistortionTHD: 9.75 A (Even: 0.50 A Odct 9.74A) PHASE C HARMONIC TIMEPLOT Site: INAP PDU 3A1 Measured from 07/03/2010 07:34:22.0 to 07/03/2010 11:30:37.0 VOLTAGE Volts 3.40 3.35 3.30 E 325 320 i 07.30 07/03312010 Saturday Volts 3.5 3.0 2.5 2.0 1.5 1.0 0.5 0.0 r 1 i 08:00 � I � 08:30 1 1 1 I 1 1 1 1 1 1 1 1 1 1 09:00 09:30 10:00 10:30 11:00 11:30 C AVTHDRss(amg) CamodwilitOmVIlwr 1 1 1 1 1 1 1 1 1 1 1 1 1 H10 T H D 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 H50 ® C- AVHarm H30 Total RMS: 117.83 V DC Level: 0.00V Fundarrental(H1) RMS: 0.00V Total Harmonic Distortion THD: 3.40V (Eve:: 0.11 V, Odct 3.40V) c =WI .nn 1noVI.. nea H40 0 PHASE C HARMONIC TIMEPLOT Site: 'NAP PDU 3A1 Measured from 07/03/2010 07:34:22.0 to 07/03/2010 11:30:37.0 CURRENT Amps 10.3 102 10.1 10.0 9.9 07 30 07/03/2010 Saturday Amps 10.0 7.5 5.0 2.5 1 i 1 1 1 08:00 08:30 09:00 09:30 0.0 — i 1 i 10:00 10:30 11:00 11:30 .-- C ITHDRss (avg) cm.. anomvi «m., 1 1 1 1 1 THD 11 1 1 1 H10 I H2O Total RMS: DC Leval: Fundarrental(H1) RMS: Total Harmonic Distortion THD: ® C IHarm 11 I 1 1 1 1 1 1 1 1 1 I I I I I I I I I I H40 H50 H30 60608 A 3.41 A 605.84 A 10.33A(Een: 0.34A,Odd: 10.33 A) • • • LLEE TECHNOLOGIES' LEVEL 4 CHECKLIST SECt101 , i Procedure Title: '"C 0(111" 1NT- TUK -WA- COMMISSIONING -PDI -PDU tntorm.ztlon Submittal Date: 18 Ma 10 y Procedure Work Date: 03 Jul 10 Procedure Walt , Time Frame: 0800 -1700 Customer Name: Intemap Customer's Solomon Pht'ecf Code: Address: Street Address: 3355 South 120th Place Sta City M' Zip: Tukwila WA 98168 Customer POC: Customer POC Name: Kathy Mclnvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissloning su . : /visor: Herbert Bumett Phone Numbers: lie Number 703- 968 -0300 Mobile: 713.423.4335 Paper ,Q = P'11;oc1' r° " dul , O d, rl du•,', Equipment PDI PDU CX Procedure 3A1 Affected Area: Data Center I Systems Affected: Load Distribution Equipment Information: Manufacturer PDI , EquipmerdType: PDU Model 0: PP13 -WS- 300 -6-641 Serial e: 110 - 2679 -6 Procedure Overview: This testing will verify the operation of the PDU. Arrt Results: Resu The PDU will operate as per design. Pre - Procedure Requirements: Manufacturer's startup completed on the module. Air conditioning system is functional and capable of supporting the heat toad generated by the PDU module. Ensure that all test equipment that is required is onsite and operational. Load banks will be hooked up and ready for testing. Conduct a point to point test to verify correct wiring. Boundaries are placed around the PDU. The Power Quality Meter is set up and ready to record. scat °� 0' DIGS -UJiF D■,t,ils Detailed Procedure Detailed Procedure: COIllpbte 1. Record start date: 03 Jul 10 Record start time:7:25 2. Document that vendor start up has been performed. 3. Perform a visual of the PDU to ensure that there is no external damage to the PDU. 4. Check that the PDU is level and stable with all stabilizers flush to the floor. 5. Close the feeder breaker to the PDU. 6. Ensure that all PDU load breakers are in the OPEN position. d 7. Close the input main circuit breaker inside the PDU. 8. Press the monitor on button. Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 3 • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST • Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 input V Output V Output ,i Amps;:. 617 A ff�n .,F { 4,;.-r. <:x t s" ;#* ' ' DVM 116 LCD 118 B w �t a tt � s der ', .- ': yx, *. _� DVM 117 LCD 118 625 Y * } k; " ` q" tk DVM 117 LCD 118 626 AB DVM LCD 479 DVM 202 LCD 202 i",,; BC = DVM LCD 481 DVM 203 LCD 203 KW 221 ,. , DVM LCD 477 DVM 202 LCD 202 KVA 221 8.1. Apply control power to the Toad bank. 8.2. Apply 100% Toad to the PDU. KW:225 X 8.3. Start a 4 hour bum test of the PDU: 8.4. Monitor temperature in the surrounding area. ✓ 8.5. PDU BURN SHEET. Time Output Volts (L-N) Output;Amps,. 00 00 A 118 B 118 C 118 A 617 B 625 C 626 221 x- - X00 15 � A 118 B 118 C 118 A 613 B 622 C 625 220 00 30 ' A 118 B 118 C 119 A 613 B 622 C 625 220 t ys A 119 B 118 C 118 A 617 B 626 C 628 222 11 Hr a A 118 BC 119 118 A 618 B 627 C 630 223 , N hy�2Hr A 119 B 119 C 119 A 619 B 6297 C 630 229 ,.' .3Hr A 119 B 118 C 119 A 617 B 626 C 628 227 �- A 119 B 118 C 119 A 618 B 627 C 628 227 8.6. Shut down all Toad on the Toad bank. 8.7. Allow the Toad bank to run with no Toad for 5 minutes for cool down purposes. 8.8. At the PDU, flip up the protective cover over the EPO button and press it in. NOTE: THE INPUT BREAKER SHOULD TRIP AND SHUT OFF ALL POWER FROM THE PDU. 8.9. Verify that all power was removed from the Toad bank. / • Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 • • • &/.1 LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 8.10. Reset the tripped input breaker at the PDU. 8.11. OPEN the feeder breaker to the PDU. 8.12. Check that the PDU cabinet is not - energized and safe to work in. 8.13. Secure from the Toad banking. S--non 04 Comments 8.2 225 KW was applied due to the current limitations of the Toad bank at 208 volts. Conducted an IR scan after two hours and at the end of the four hour Toad bank test. No hot spots were found. Section US Pr,i,ad,Pc v∎miW'S 8 Urltfl'nL,m Lee Technologies Group has witnessed or pa ipated in this procedure and attests to the accuracy and completeness of this rBpOft Printed Name: t Date: Herb Burnett / !i %!4 1i 03July 10 I Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 3 of 3 • VOLTAGE TIMEPLOTS Site: INAP PDU 3A2 Measured from 07/03/2010 08:56:30.0 to 07/03/2010 11:23:30.0 • • 230 220 PI 210 0 200 190 230 220 210 O 200 190 230 220 ra 210 0 200 - A B Vrms 190 - B C Vrms \_ 1 1 1 1 1 09:00 09:15 09:30 07/03/2010 Saturday - C A Vrms 1 1 1 1 1 1 1 1'' 1 1 1 1 1 1 1 1 09:45 10:00 10:15 10:30 10:45 11:00 11:15 C nt Y0 wit hD on V w 68.1 • WORST CASE SUMMARY Site: INAP PDU 3A2 Measured from 07/03/2010 08:56:30.0 to 07/03/2010 11:23:30.0 Of 0 total VOLTAGE SAGS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE SWELLS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE INTERRUPTIONS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE TRANSIENTS CRITERIA PHASE DATA DATE/TIME • • 0 WORST CASE SUMMARY WAVEFORMS Site: INAP PDU 3A2 Measured from 07/03/2010 08:56:30.0 to 07/03/2010 11:23:30.0 • • Lowest Magnitude Voltage Sag:No event Highest Magnitude Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Sag:No event Longest Duration Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Most Energy Missing Voltage Sag:No event Most Energy Added Voltage Swell:No event • • • NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Interruption:No event Largest Magnitude Voltage Transients:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE • PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3A2 Measured from 07/03/2010 08:56:30.0 to 07/03/2010 11:23:30.0 VOLTAGE Volts 3.175 3.150 3.125 3.100 3.075 3.050 3.025 • Volts 3.0 2.5 2.0 1.5 1.0 0.5 • • • i I � 09:00 07/03/2010 Saturday 0915 09 30 09 45 10 00 1015 - A B VTHDRss (avg) Cm.] wneonn■.w ee.1 1 1 1030 1045 11 00 11 15 i t 1 1 1 1 1 1 THD H10 1 1 I I I I I I I I I I I I 1 1 1 I I I I I I H20 MN A- BVHarm H30 Total RMS: 117.78 V DC Level: 0.00V Furxbmental(H1) RMS: O.00V Total Harmonic Distortion THD: 3.19 V ( Ever 0.19V, Odd 3.19 V) I I 1 1 1 1 H40 1 r H 50 • PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3A2 Measured from 07/03/2010 08:56:30.0 to 07/03/2010 11:23:30.0 CURRENT Amps 19 18 17 16 15 14 • • • • • • Amps 20.0 17.5 15.0 12.5 10.0 7.5 5.0 2.5 - 0.0 - • 09 00 07/03,2010 Saturday 09 15 09 30 09 45 10 00 1015 - A ITHDRss (avg) a..w..noar.. 611.1 10 30 1045 11 00 1115 1 1 1 1 1 1 1 THD i 1 1 1 1 1 1 1 1 1 I I I I I I I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 H10 H2O H30 H40 H50 ® A[Harm Total RMS: 605.82 A DC Level: 3.59 A Functanental(H1) RMS: 604.53 A Total Harmonic D istortion THD: 19.18 A (Ben: 11.69 A Odd: 15.20 A) C.rru..nOnnVlr. 00.1 • • PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3A2 Measured from 07/03/2010 08:56:30.0 to 07/03/2010 11:23:30.0 VOLTAGE Volts 3.425 3.400 3.375 3.350 3.325 3.300 Volts 3.5 3.0 2.5 2.0 1.5 1.0 0.5 0.0 • • i I i 09:00 07/03/2010 Saturday 0915 09 30 09 45 10 00 1015 - B C VTHDRss (avg) C mind.mo mww aea 10 30 10 45 11 00 11 15 THD H10 H 20 B -C VHarm H 30 Total RMS: 11803 V DC Level: 0.00V Fundamental(H1) RMS: O.00V Total Harmonic Distortion THD: 3.43 V (Ever. 0.12V, Odd 3.42V) H40 H 50 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I 1 1 1 1 1 1 1 1 THD H10 H 20 B -C VHarm H 30 Total RMS: 11803 V DC Level: 0.00V Fundamental(H1) RMS: O.00V Total Harmonic Distortion THD: 3.43 V (Ever. 0.12V, Odd 3.42V) H40 H 50 PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3A2 Measured from 07/03/2010 08:56:30.0 to 07/03/2010 11:23:30.0 CURRENT Amps 10.2 10.1 10.0 9.9 9.8 • • • • Amps 10.0 7.5 5.0 2.5 0.0 • 09 00 07/03/2010 Saturday 09 15 09 30 09 45 10 00 1015 - B ITHDRss (arg) cw..0 wnowi.. aea 10 30 10 45 11 00 11 15 THD H10 H20 BIHarm H30 Total RMS: 61613 A DC Level: 5.95A Funcfarrental(H1) RMS: 616,54A Total Harmonic Distortion THD: 1022 A (Even: 1.49A, Odd: 1Q11 A) H40 H50 1 1 1 1 1 1 1 1 1 1 1 I I I I I I I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I I 1 1 1 1 1 1 1 1 THD H10 H20 BIHarm H30 Total RMS: 61613 A DC Level: 5.95A Funcfarrental(H1) RMS: 616,54A Total Harmonic Distortion THD: 1022 A (Even: 1.49A, Odd: 1Q11 A) H40 H50 • PHASE C HARMONIC TIMEPLOT Site: INAP PDU 3A2 Measured from 07/03/2010 08:56:30.0 to 07/03/2010 11:23:30.0 VOLTAGE Volts 3.35 3.30 3.25 3.20 • • Volts i • 1 1 09:00 07/03!2010 Saturday 0915 09 30 09 45 10 00 1015 - C A VTHDRss (mg) Cram.] .110ralViow ee.1 10 30 10 45 11 00 11 15 3.5 3.0 2.5 2.0 -. 1.5 1.0 0.5 0.0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I I I I I 1 1 1 1 I 1 1 1 1 1 1 I I THD • H10 H20 C -A VHarm H30 Total RMS: 117.74 V DC Level: 0.00 V Fundamental(H1) RMS: 0.00 V Total Harrmnic D istort ion THD: 3.39 V ( Ever: 0.12 V, Odd 3.38 V) H40 H50 • PHASE C HARMONIC TIMEPLOT Site: INAP PDU 3A2 Measured from 07/03/2010 08:56:30.0 to 07/03/2010 11:23:30.0 CURRENT Amps 22 21 20 19 18 17 • Amps 20 15 10 5 0 1 1 THD 1 1 1 1 0900 0915 07/03/2010 Saturday 1 1 1 1 1 1 1 1 1 09 30 09 45 10 00 1015 10 30 10 45 11 00 - C ITHDRss (aug) CosswO. 11Don Viw U1.1 11 15 • i I I I I I I I 1 1 1 1 1 1 1 1 I I I I 1 1 1 1 1 H10 H2O H30 H40 H50 C IHarm Total RMS: 605.81 A DC Level: 3.82 A Fundamental(H1) RMS: 60325A Total Harmonic Distortion THD: 21.73 A (Ren: 13.55 A Odd: 16.98 A) • • • L� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST S cr cl, Oi P'c edu Inton1aillon Procedure Tdle: INT- TUK -WA -COMMISSIONING -PDI -PDU Submittal Date: 18 May 10 y Procedure Work Date: 03 Jul 10 procedure Work Time Frame: 0800 -1700 Customer Name: Intemap Customer's Solomon Pmjeot Code: Address: Street Address: 3355 South 120th Place City: State: ZIP: Tukwila WA 98188 Customer POC: CusbnerFOC Mame: Kathy Mclnvale Phone Numbers: office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning Su . ervisor. Herbert Burnett Phone Numbers: Phone Number 703- 968 -0300 Mobile: 713.423.4335 Pager.' s<c'o" °= Proaerhue Overview Equipment PDI PDU CX Procedure 3A2 Affected Area: Data Center Systems Affected: Load Distribution Equipment information: Manufacturer PDI Equipment .: 1p PDU Model #: PP13 -WS- 300 -G-641 Serial #: 110 - 2679 -11 Procedure Overview: This testing will verify the operation of the PDU. Anticipated Results: The PDU will operate as per design. Pre- procedum Requirements: Manufacturer's startup completed on the module. Air conditioning system is functional and capable of supporting the heat load generated by the PDU module. Ensure that all test equipment that is required is onsite and operational. Load banks will be hooked up and ready for testing. Conduct a point to point test to verify correct wiring. Boundaries are placed around the PDU. The Power Quality Meter is set up and ready to record. ectign 03 Pi,r,,:duic Delon:, Detailed Procedure Detailed Roeedure: Complete 1. Record start date: 03 Ju 10 Record start time:7:20 2. Document that vendor start up has been performed. ✓ 3. Perform a visual of the PDU to ensure that there is no external damage to the PDU. 4. Check that the PDU is level and stable with all stabilizers flush to the floor. 5. Close the feeder breaker to the PDU. 6. Ensure that all PDU load breakers are in the OPEN position. 7. Close the input main circuit breaker inside the PDU. 8. Press the monitor on button. Template Rev. 07022010 Lee Technologies Group Copyright 2010 Proprietary use pursuant to company policy Page -1 of 3 • • LEE TECHNOLOGIES" LEVEL 4 CHECKLIST Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 Input V ` ;* Output V Output "Amps`-- ,. DVM 116 LCD 117 614 ;, . B ii`i r6 r b'tt;. zz DVM 117 LCD 117 621 r C, cr i� j DVM 117 LCD 118 629 �yk? #` ' � � `,•.eta. AB DVM LCD 477 DVM 202 LCD 202 -* , trct' BC DVM LCD 478 DVM 203 LCD 203 KW 219 A : DVM LCD 474 DVM 202 LCD 202 KVA 219 8.1. Apply control power to the Toad bank. V' 8.2. Apply 100% Toad to the PDU. KW:225 X 8.3. Start a 4 hour bum test of the PDU. v' 8.4. Monitor temperature in the surrounding area. 8.5. PDU BURN SHEET. V 1 ° Tilme ;.,Output Volts (L N) , :Outpt`Amps _ . t� ' ` :00 :00 :,1,441 A 117 B 117 C 118 A 614 B 621 C 629 219 ,., firma 15a A 117 B 117 C 118 A 610 B 617 C 625 216 1,00.30. A 118 B 118 C 118 A 610 8 617 C 625 217 00 45t`m. 117 1117 118 613 621 628 219 ' 1Hi. A 117 1117 118 615 624 630 221 ,.2Hr,z A 117 1118 118 615 624 630 221 � -, .,., 3Hr A 117 B 117 C 118. A 614 B 621 C 628 219 117 1117 118 614 621 C 629 219 8.6. Shut down all Toad on the Toad bank. ✓ 8.7. Allow the load bank to run with no load for 5 minutes for cool down purposes. ✓ 8.8. At the PDU, flip up the protective cover over the EPO button and press it in. NOTE: THE INPUT BREAKER SHOULD TRIP AND SHUT OFF ALL POWER FROM THE PDU. 8.9. Verify that all power was removed from the load bank. ✓ Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 • • 411 LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 8.10. Reset the tripped input breaker at the PDU. 8.11. OPEN the feeder breaker to the PDU. 8.12. Check that the PDU cabinet is not - energized and safe to work in. 8.13. Secure from the Toad banking. `r s ct,o, 3-1 Comments 8.2 225 KW was applied due to the current limitations of the load bank at 208 volts. Conducted an IR scan after two hours and at the end of the four hour load bank test. No hot spots were found. _r/ ,`ction ' Lee Technologies Group has witnessed or partl 'sated in this procedure and attests to the accuracy and completeness of this report. Panted Name: 3 1 Date: Herb Burnett ���_L�L/.�'L�.��ea �J� • 03 July 10 PfoGLallre Witnirtis E Vr:nhcntinn Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 3 of 3 VOLTAGE TIMEPLOTS Site: INAP PDU 3A3 Measured from 07/02/2010 11:50:39.0 to 07/02/2010 18:23:13.0 200 150 0 100 50 0 200 150 • 50 0 200 150 j 100 50 0 • - A B Vrms - BCVrms 1 - C AVrms 12:00 07/02/2010 Friday 13:00 14:00 15:00 Ci.ed *,tno.V 16.1 16:00 17:00 18:00 • ACTIVITY PLOTS Site: INAP PDU 3A3 Measured from 07/02/2010 11:50:39.0 to 07/02/2010 18:23:13.0 VOLTAGE SAGS NO EVENTS WERE FOUND IN THIS CATEGORY VOLTAGE SWELLS NO EVENTS WERE FOUND IN THIS CATEGORY VOLTAGE INTERRUPTIONS NO EVENTS WERE FOUND IN THIS CATEGORY VOLTAGE TRANSIENTS 15 10 5 0 00:013.00 03:0a 00 06:00.00 09:0a 00 GtiwEwrthDmVi.611.1 12:0a 00 15:M00 i I i 18:00:00 21:00:00 illWORST CASE SUMMARY Site: INAP PDU 3A3 Measured from 07/02/2010 11:50:39.0 to 07/02/2010 18:23:13.0 Of 0 total VOLTAGE SAGS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE SWELLS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE INTERRUPTIONS CRITERIA PHASE CATEGORY DATA DATEITIME Of 28 total VOLTAGE TRANSIENTS CRITERIA PHASE DATA DATE/TIME Largest Magnitude C -A 32.1V, 0.000 Sec. 07/02/2010 17:47:46.60 C -A 30.1V, 0.000 Sec. 07/02/2010 17:05:19.67 C -A 29.2V, 0.000 Sec. 07/02/2010 17:19:40.65 C -A 28.8V, 0.000 Sec. 07/02/2010 17:05:19.85 • • • • WORST CASE SUMMARY WAVEFORMS Site: INAP PDU 3A3 Measured from 07/02/2010 11:50:39.0 to 07/02/2010 18:23:13.0 • • Lowest Magnitude Voltage Sag:No event Highest Magnitude Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Sag:No event Longest Duration Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Most Energy Missing Voltage Sag:No event Most Energy Added Voltage Swell:No event • • • NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Interruption:No event Largest Magnitude Voltage Transients: Phase C -A NO WAVEFORM AVAILABLE Volts 300 100 -100 -300 17:47 46.56 IlffS1•f11'∎ 1___ 1i 1E� AMUR 1- U 11M11 1 1 17:47:46.60 - CAV -CI Cmetrd.hOranView ae.1 Amps 0.00100 = 0.00075 0.00060 0.00025 0.00000 32.1V,0.000 Sec., on 07/02/2010 17:47:46.60 • PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3A3 Measured from 07/02/2010 11:50:39.0 to 07/02/2010 18:23:13.0 VOLTAGE Volts 3.20 — 3.15 3.10 3.05 3.00 2.95 2.90 2.85 • e- .r J Volts 3.0 2.5 2.0 1.5 1.0 0.5 0.0 • 12 00 07/02/2010 Friday 13 00 14 00 15 00 — A B VTHDRss (avg) C nob] wrnomrw 061 16 00 17 00 18 00 THD H10 H 20 A -B VHarm H30 Total RMS: 117.85 V DC Level: 0.00 V Fundamental( H1) RMS: 0.00V Total Harmonic Distortion THD: 3.18 V ( Even: 0.17V, Odd 3.18 V) H40 H50 I l l 1 1 1 1 1 1 1 1 I I I I I I 1 1 1 1 1 1 1 1 1 1 1 1 I I I I I I I 1 1 I 1 1 1 1 1 1 1 1 THD H10 H 20 A -B VHarm H30 Total RMS: 117.85 V DC Level: 0.00 V Fundamental( H1) RMS: 0.00V Total Harmonic Distortion THD: 3.18 V ( Even: 0.17V, Odd 3.18 V) H40 H50 • PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3A3 Measured from 07/02/2010 11:50:39.0 to 07/02/2010 18:23:13.0 CURRENT Amps 9.75 9.50 9.25 9.00 8.75 • Amps 10.0 7.5 5.0 2.5 0.0 • 12 00 07/02/2010 Friday 13 00 14 00 15 00 - A ITHDRss (avg) <mr+.enowi«0e.1 16 00 17 00 18 00 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 I I I I I 1 1 1 1 1 1 1 1 1 H2O H30 H40 H50 NMI A!Harm Total RMS: 60550 A DC Level: 627A Fundamental(H1) RMS: 60581 A Total Harmonic Distortion THD: 9.77 A (Eve:: 1.39A Odd 9.67 A) c...a.nnomvi« OSA • PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3A3 Measured from 07/02/2010 11:50:39.0 to 07/02/2010 18:23:13.0 VOLTAGE Volts 3.45 3.40 3.35 3.30 3.25 3.20 3.15 12 00 07/02/2010 Friday • Volts 13 00 14 00 15 00 - B C VTHDRss (a1g) 16 00 17 00 18 00 -. 3.5 3.0 2.5 - 2.0 1.5 - 1.0 0.5 0.0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD • H10 H2O B -C VHarm H30 Total RMS: 118.19 DC Level: 0.00V Fundarrental(H1) RMS: 0.00V Total Harmonic Distortion TH D: 3.48 V (Eves: 0.12V, Odd 3.48V) H40 H50 • PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3A3 Measured from 07/02/2010 11:50:39.0 to 07/02/2010 18:23:13.0 CURRENT Amps 22 21 20 19 18 17 16 15 14 13 Amps 20 15 10 5 0 • 12 00 07/02/2010 Friday 13 00 14 00 15 00 - B ITHDRss (avg) Cw1.1 who mviw 0.0.1 16 00 17 00 18 00 1 1 1 1 1 1 1 1 1 1 1 THD H10 1 1 1 1 1 1 1 1 1 1 H 20 Total RMS: DC Level: Funcarrental(H1) RMS: Total Hamonic Distortion THD: B (Harm I I I I I I I I 1 1 1 1 1 H30 H40 62239 A 3.91 A 61997 A 21.59 A (Ben: 13.55 A Odd: 16.81 A) • • PHASE C HARMONIC TIMEPLOT Site: INAP PDU 3A3 Measured from 07/02/2010 11:50:39.0 to 07/02/2010 18:23:13.0 VOLTAGE Volts 3.35 3.30 3.25 3.20 3.15 3.10 3.05 3.00 2.95 a- • a- Volts 12 00 07/02/2010 Frida7 13 00 14 00 15 00 — C A VTHDRss (a■g) C.•a.ne o a, w es., 16 00 17 00 18 00 3.5 — : 3.0 - 2.5 -. 2.0 1.5 1.0 0.5 0.0 1 t I 1 I I 1 I I 1 I I I I I I t l l l 1 1 1 1 1 1 1 1 1 i i i 1 1 1 I I I I I I t l l l THD H10 H20 C -A VHarm H 30 Total RMS: 117.53 V DC Level: 0.00V Fundarrental(H1) RMS: 0.00V Total Harmonic D istortion THD: 3.34 V (Eve1: 0.13V, Odd 3.33 V) H40 H50 • PHASE C HARMONIC TIMEPLOT Site: INAP PDU 3A3 Measured from 07/02/2010 11:50:39.0 to 07/02/2010 18:23:13.0 • • CURRENT Amps 19 18 17 16 15 14 13 s_r • Amps 20 15 10 5 0 • 12 00 07/02/2010 Friday 13 00 14 00 15 00 - C ITHDRss (a■g) C.I.d.hrlemn,ere 68.1 16 00 17 00 18 00 1 1 1 THD 1 i 1 1 I I I I 1 1 1 I I I I I I I I I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 H10 H2O H30 H40 H50 C (Harm Total RMS: 63539 A DC Le'el: 322 A Fundamental(H1) RMS: 6337) A Total Hamxmic Distortion THD: 19.40A (E■en: 11.66 A Odd: 15.56 A) • • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST .rcii0i?��i P °,:; "'°° Procedure Tilt: INT- TUK -WA- COMMISSIONING - PDI -PDU Submittal Date: 18 May 10 Y Procedure Work Date: Jul 10 Procedure Work Procedure Time Frame: 0800 -1700 Customer Name: Intemap Customer's Solomon Project Code: Address: SbeetAddress: 3355 South 120"' Place City. slate: Z: Tukwila WA 98168 Customer POC: POC Name: Kathy Mcl ale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning Su • ervlsor: Herbert Burnett Phone Numbers: Phone Humber 703 -968 -0300 Mobile: 713.423.4335 Pager `'5 Equipment PDI PDU CX Procedure 3A3 Affected Area: Data Center Systems Affected: I Load Distribution Equipment Information: Manufacturer: PDI Equipment rypee PDU Modals PP13 -WS- 300 -G-641 Sonata: 110- 2679 -13 Procedure OveMew: This testing will verify the operation of the PDU. Anticipated Results: The PDU will operate as per design. Pre- Procedure Requirements: Manufacturer's startup completed on the module. Air conditioning system is functional and capable of supporting the heat load generated by the PDU module. Ensure that all test equipment that is required is onsite and operational. Load banks will be hooked up and ready for testing. Conduct a point to point test to verify correct wiring. Boundaries are placed around the PDU. The Power Quality Meter is set up and ready to record. Seno,03 Detailed Procedure Detailed Procedure: Complete 1. Record start date: 02 Jul 10 Record start time:13:05 2. Document that vendor start up has been performed. 3. Perform a visual of the PDU to ensure that there is no external damage to the PDU. 4. Check that the PDU is level and stable with all stabilizers flush to the floor. 5. Close the feeder breaker to the PDU. 8. Ensure that all PDU load breakers are in the OPEN position. 7. Close the input main circuit breaker inside the PDU. 8. Press the monitor on button. Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 3 • • • :11 LEE TECHNOLOGIES" 16, LEVEL 4 CHECKLIST Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 In r' • titit v o ;.....".'2. ,• '--. - ' iliPL# v3',''. •:::;,, : '..Outtniti.. '):, -' • ''','S.." ;., ,i. ir?.. •,- -;', - ,;;, . s - ..,..-- ' '41:14: -.I', " ., ' ,,, 4,Kw:Kt. DVM 117 LCD 117 620 • -v - ' B : .i."', )?p DVM 117 LCD 117 626 -"•-, - 0:.7:‘ -, ..4',,..... e,.... V'51', •e i- -..,:. ''' DVM 117 LCD 118 620 P'C ''jY -,t ? ...:: • All' :', DVM LCD 471 DVM 202 LCD 202 4 '.'.1f,::.1::;,*, ri,?/•...;.-z,•-?..il:'•tx..: Dvm LCD 473 DVM 203 LCD 203 KW 228 p, ,.:, DVM LCD 471 DVM 202 LCD 202 KVA 219 8.1. Apply control power to the load bank. 8.2. Apply 100% load to the PDU. KVV:225 X 8.3. Start a 4 hour bum test of the PDU. 8.4. Monitor temperature in the surrounding area. 8.5. PDU BURN SHEET. Tilif&-; .!-..... , = ...:-...„ .]...,::. Output (1-71,1).? ......,:t .-.,,,..,...,... .-._. T..,==,:--.1;?!..;tPut.41110s-,.. ,..,...?- ':-;‘,1s. . ■T, i';', ,31-,:' '.=; f';`..i 90;00.7-7.* A 116 B 117 C 117 A 640 B 647 C 644 226 A 116 B 117 C 117 A 640 B 647 C 644 226 Ff00:,36,..!. A 117 B 117 C 117 A 637 B 644 C 644 225 :00:45; :00:45; A 116 B 117 C 117 A 639 B 645 C 643 225 • ',, Z-',"--:---,:,-.I` A 117 B 117 C 118 A 640 B 647 C 644 226 • f cl-#:, A 118 B 117 C 117 A 647 B 650 C 653 231 ,',•;.., xl:-. .: ,'!" ;AtrZ', A 117 B 117 C 118 A 639 B 645 C 643 226 CA'=;,:•:-44,::,=, 4Filk.4-"--1 :.::;-•„/-,;',._:,.".;,i::.: A 117 B 117 C 117 A 641 B 647 C 643 227 8.8. Shut down all load on the load bank. 8.7. Allow the load bank to run with no load for 5 minutes for cool down purposes. 8.8. At the PDU, flip up the protective cover over the EPO button and press it in. NOTE: THE INPUT BREAKER SHOULD TRIP AND SHUT OFF ALL POWER FROM THE PDU. 8.9. Verify that all power was removed from the load bank. Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 • • 0 LEE TECHNOLOGIES' LEVEL 4 CHECKLIST , • 8.10. Reset the tripped input breaker at the PDU. I 8.11. OPEN the feeder breaker to the PDU. f 8.12. Check that the PDU cabinet Is not - energized and safe to work in. ✓ 8.13. Secure from the Toad banking. (11 w i 04 Comments 8.2 225 KW was applied due to the current limitations of the Toad bank at 208 volts. Conducted an IR scan after two hours and at the end of the four hour Toad bank test. No hot spots were found. S ,zction os, v , i :: e,. , Lee Technologies Group has witnessed or • artici ated in this procedure and attests to the accuracy and completeness of this report. Printed None: , .. tore: / Clete: Herb Burnett / r .- �•,.,- •,.al 02 July 10 Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 3 • VOLTAGE TIMEPLOTS Site: INAP PDU 3A4 Measured from 07/02/2010 10:54:07.0 to 07/02/2010 15:00:52.0 • • 230 220 210 0 200 190 230 220 YI 210 0 200 190 230 220 17 210 0 200 -A BVrms 190 L r - BCVrms 11:00 07/02/2010 Friday I 1 1 ' 1 11:30 12:00 - C A Vrms I 1 I 1 1 1 1 1 1 12:30 13:00 13:30 14:00 14:30 C.`] with o.hvi., 68.1 15:00 0 WORST CASE SUMMARY Site: INAP PDU 3A4 Measured from 07/02/2010 10:54:07.0 to 07/02/2010 15:00:52.0 Of 0 total VOLTAGE SAGS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE SWELLS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE INTERRUPTIONS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE TRANSIENTS CRITERIA PHASE DATA DATE/TIME • • • WORST CASE SUMMARY WAVEFORMS Site: INAP PDU 3A4 Measured from 07/02/2010 10:54:07.0 to 07/02/2010 15:00:52.0 • • Lowest Magnitude Voltage Sag:No event Highest Magnitude Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Sag:No event Longest Duration Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Most Energy Missing Voltage Sag:No event Most Energy Added Voltage Swell:No event • • • NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Interruption:No event Largest Magnitude Voltage Transients:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE • • • PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3A4 Measured from 07/02/2010 10:54:07.0 to 07/02/2010 15:00:52.0 VOLTAGE Volts 3.00 2.95 2.90 2.85 Volts 3.0 2.5 2.0 1.5 1.0 0.5 0.0 i i i 1 1 i 11 00 11 30 12 00 07/02/2010 Friday I 1 1 1 12:30 13 00 13 30 14 00 14 30 -A BVTHDRss(aeg) cn.w. 110mr «60.1 15 00 THD H10 H2O Mi A -B VHarm H 30 Total RMS: 117.17 V DC Level: 0.00 V Fundamental(H1) RMS: O.00V Total Harmonic Distortion THD: 3.01 V(Eve1: 0.14V, Odd 3.01V) H40 H50 I l 1 1 1 1 1 1 1 1 1 I I I I I t t l l 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I 1 1 1 1 1 1 1 1 THD H10 H2O Mi A -B VHarm H 30 Total RMS: 117.17 V DC Level: 0.00 V Fundamental(H1) RMS: O.00V Total Harmonic Distortion THD: 3.01 V(Eve1: 0.14V, Odd 3.01V) H40 H50 • PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3A4 Measured from 07/02/2010 10:54:07.0 to 07/02/2010 15:00:52.0 CURRENT Amps 10.4 10.3 10.2 10.1 10.0 9.9 9.8 9.7 9.6 9.5 • Amps 10.0 7.5 5.0 2.5 0.0 — • 11 00 07/02/2010 Fr ida7 11 30 1 1 1 1 1 12 00 12 30 13 00 13 30 — A ITHDRss (avg) C .anomvi.. nea 14 00 1430 1500 1 1 1 1 1 1 1 1 1 1 1 I 1 1 1 1 1 1 1 1 1 THD H10 H20 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 H30 H40 H50 ® AIHarm Total RMS: 64275 A DC Level: 2.94A Furxfamental(1-11) RMS: 64278 A Total Hanratic Distortion THD: 10.40A (Ben: 301 A, Odd: 9.96A) • PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3A4 Measured from 07/02/2010 10:54:07.0 to 07/02/2010 15:00:52.0 VOLTAGE Volts 3.300 - 3.275 3250 3225 3.200 3.175 3.150 3.125 • Volts 3.0 2.5 2.0 1.5 Li 1.0 0.5 0.0 • 11 00 07/02/2010 Friday 11 30 12 00 12 30 13 00 1 1 ' 13:30 - B C VTHDRss (aug) 14 00 14 30 15 00 .1_ i __ ona ■ r I _ rr 11• _ a • 1 1 1 1 THD r 1 1 H10 1 1 1 1 1 1 1 1 H20 B -C VHarm Total RMS: DC Le'el: Fundamental(H1) RMS: Total Hamonic Distortion THD: 1 1 I H30 117.03 V 0.00 V 0.00V 3.30 V (Even: 0.13V, Odd 329V) H40 H50 • PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3A4 Measured from 07/02/2010 10:54:07.0 to 07/02/2010 15:00:52.0 CURRENT Amps 10.6 10.5 10.4 • • 1 9.9 • J • 1 • Amps 10.0 7.5 5.0 2.5 0.0 • 11 00 07/02/2010 Friday 11 30 12 00 i 1 i 12:30 1300 1330 - B ITHDRss (avg) 14 00 r. 14 30 15 00 1 1 1 1 1 1 1 1 1 THD I t l l I I I I I t l l l 1 1 1 1 1 1 1 1 1 1 1 1 1 H10 H2O H30 H40 BlHarm Total RMS: 631.32 A DC Level: 3.49A Fundamental( H1) RMS: 631.14 A Total Hanronic DistortionTHD: 10.63A(Ren: 266A Odd: 10.30 A) • PHASE C HARMONIC TIMEPLOT Site: INAP PDU 3A4 Measured from 07/02/2010 10:54:07.0 to 07/02/2010 15:00:52.0 VOLTAGE Volts 3.15 3.10 3.05 3.00 2.95 • Volts 11 00 11 30 07/02/2010 Friday 1 1 1 1 1 12 00 12 30 13 00 13 30 14 00 14 30 -C AVTHDRss(mg) C...e.eeomrw aea 15 00 - 3.0 - 2.5 2.0 1.5 1.0 0.5 M■M& MN 1.1 1.1 MI ■ I= MN M MI III ■ — m i _Ns _ ■ 0.0 1 l I 1 1 1 1 1 1 1 1 I I I I I 1 1 1 1 1 1 1 1 1 1 1 1 1 I I I 1 1 1 1 1 1 I 1 1 1 1 1 1 1 1 THD • H10 H2O ® C -A VHarm H30 Total RMS: 116E0 V DC Level: 0.00V Fur>darrental(H1) RMS: 0.00V Total Harmonic D istortion THD: 3.16 V (Ever: 0.09 V, Odd 3.16V) H40 H 50 • • • PHASE C HARMONIC TIMEPLOT Site: INAP PDU 3A4 Measured from 07/02/2010 10:54:07.0 to 07/02/2010 15:00:52.0 CURRENT Amps 10.9 10.8 10.7 10.6 10.5 10.4 10.3 J Amps 10.0 7.5 5.0 2.5 0.0 • 11 00 07/02'2010 Friday 11 30 12 00 12 30 13 00 - C ITHDRss Ci..u. 11DmVlw esa � r 13 30 14 00 14 30 15 00 THD H10 H2O - C IHarm H30 Total RMS: 64349 A DC Level: 3.44A Furxarrental(H1) RMS: 64318 A Total HamDnic Distortion THD: 10.93A( Ben: 239AOdt: 1Q66A) H40 H50 • 1 1 i i i 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I I I I I I I 1 1 1 1 1 1 1 1 1 1 1 l l l 1 1 1 1 1 1 1 THD H10 H2O - C IHarm H30 Total RMS: 64349 A DC Level: 3.44A Furxarrental(H1) RMS: 64318 A Total HamDnic Distortion THD: 10.93A( Ben: 239AOdt: 1Q66A) H40 H50 _all LEE TECHNOLOGIES' (0 • LEVEL 4 CHECKLIST Procedure rifle: .;ecron Di. •P1O°"dLj INT-TUK-WA-COMMISSIONING - PDI -PDU :,acrmation Submittal Date: 18 May 10 Procedure Wor Dete: k 02 Jul 10 Procedure Work Time Frame: T . 0800 -1700 Customer Name: I nt e m a p Customer's Solomon Protect Code: - - Address: Street Address: 3355 South 120th Place City: Stara,: Zip.. Tukwila WA 98168 Customer POC: Customer POC Name: Kathy Mclnvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning Su • ervisor. Herbert Bumett Phone Numbers: - Phone Number 703- 968 -0300 Mobile: 713.423.4335 Pager seccion o_� Pnn:edw r. Oor;r,i�;v, Equipment PDI PDU CX Procedure 3A4 Affected Area: Data Center Systems Affected: Load Distribution Equipment Information: Menufecturec PDI Equipment Type: PDU • Model #: PP13 -WS- 300 -G-641 Serial #: 110 - 2679 -12 Procedure Overview: This testing will verify the operation of the PDU. Anticipated Results: The PDU will operate as per design. Pre - Procedure Requirements: Manufacturer's startup completed on the module. Air conditioning system is functional and capable of supporting-the heat load generated by the PDU module. Ensure that all test equipment that is required is onsite and operational. Load banks will be hooked up and ready for testing. Conduct a point to point test to verify correct wiring. Boundaries are placed around the PDU. The Power Quality Meter is setup and ready to record. section o' P, „anrinmr: tD I :: Detailed Procedure Detailed Pieced e• Comple`° 1. Record start date: 02 Jul 10 Record start time:10:55 2. Document that vendor start up has been performed. 3. Perform a visual of the PDU to ensure that there is no external damage to the PDU. 4. Check that the PDU is level and stable with all stabilizers flush to the floor. 5. Close the feeder breaker to the PDU. 6. Ensure that all PDU load breakers are in the OPEN position. 7. Close the input main drcuit breaker inside the PDU. 8. Press the monitor on button. Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 1 of 3 �� LEE TECHNOLOGIES' Ali • • LEVEL 4 CHECKLIST Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 ✓ Input V s. Output V ::output.;,: ;;Amps ,, ri. ; �, �; #-...1 arts DVM 116 LCD 116 642 4" T , K: r� "wi+x��y .'`'4 DVM 117 LCD 117 648 *, " r DVM 117 LCD 117 648 AB - DVM LCD 476 DVM 202 LCD 202 rvi i -. <_ ,'. BC; DVM LCD • 477 DVM 203 LCD 203 KW 228 Y:-CA ,t DVM LCD 477 DVM 202 LCD 202 KVA 228 8.1. Apply control power to the load bank. 8.2. Apply 76% Toad to the PDU. INV:225 X 8.3. Start a 4 hour bum test of the PDU. 8.4. Monitor temperature in the surrounding area. 8.5. PDU BURN SHEET. iTme Output Volts (LEI) OutputAps L K1N .4 -,,-`R 4. 0D" 00'J A 117 B 117 C 117 A 642 B 631 C 642 227 t' ,=! } =�� . ?;`:00:; (5- A 116 B 116 C 117 A 643 B 632 C 644 227 . 00 $0 117 117 1 7 642 630 642 226 rl.9C f: ;:-.4ij ..,15 . a 10Q:4$: A 118 B 117 C 117 A 643 B 631 C 643 226 } --.3„ 41'Hrr 117 117 C 117 A 644 B 632 C 644 226 ;: >-sSe' A 117 B 117 C 117 A 643 B 631 C 643 225 j }3r A. 116 B 117 C 117 A 639 B 628 C 639 223 =4< v°.r ? r 4Hr+ A 117 B 117 C 117 A 641 B 628 C 641 224 8.6. Shut down all load on the load bank. ' 8.7. Allow the load bank to run with no load for 5 minutes for cool down purposes. 8.8. At the PDU, flip up the protective cover over the EPO button and press it in. NOTE: THE INPUT BREAKER SHOULD TRIP AND SHUT OFF ALL POWER FROM THE PDU. 8.9. Verify that all power was removed from the load bank. Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 (10 ‘4111 LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 8:10E. Reset the tripped input breaker at the PDU. 8.11. OPEN the feeder breaker to the PDU. 'f 8.12. Check that the PDU cabinet is not - energized and safe to work in. ,r 8.13. Secure from the load banking. Seciion oa Comments 8.2 225 KW was applied due to the current limitations of the load bank at 208 volts. 8.5 The first hour of the bum in reading was taken from Power Quality Meter due to PDU metering being out of. calibration. PDI technicianfcalibrated CTs. Conducted an IR scan after two hours and at the end of the four hour load bank test. No hot spots were found. • :;:coon.__ PcouNhiro 1/V'ilnu-:; °. Lee Technologies Group has witnessed or parr ' ated in this procedure and attests to the accuracy and completeness of this report. Printed Name: • It, .. - Date: Herb Burnett / -- h•;ii/.! ,• . 02 July 10 Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 3 • • VOLTAGE TIMEPLOTS Site: INAP PDU 3A5 Measured from 07/02/2010 10:48:52.0 to 07/02/2010 15:01:00.0 200 150 0 100 50 0 200 150 ■ Y1 100 50 0 — A B Vrms 200 — 150 > 100 50 0 — B C Vrms • — C A Vr ms I 11:00 07/02/2010 Friday ' I 1 1 I ' 11:30 12:00 I 12:30 13:00 C *At eo.wi w ee i 13:30 14:00 14:30 15:00 • • • ACTIVITY PLOTS Site: INAP PDU 3A5 Measured from 07/02/2010 10:48:52.0 to 07/02/2010 15:01:00.0 VOLTAGE SAGS NO EVENTS WERE FOUND IN THIS CATEGORY VOLTAGE SWELLS NO EVENTS WERE FOUND IN THIS CATEGORY VOLTAGE INTERRUPTIONS NO EVENTS WERE FOUND IN THIS CATEGORY VOLTAGE TRANSIENTS .1 00:0000 03:0000 06:0000 09:0000 ona.e.numvi.. ae , I 12:0000 15:00.00 18:0000 21:00.00 • i� WORST CASE SUMMARY Site: INAP PDU 3A5 Measured from 07/02/2010 10:48:52.0 to 07/02/2010.15:01:00.0 Of 0 total VOLTAGE SAGS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE SWELLS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE INTERRUPTIONS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 1 total VOLTAGE TRANSIENTS CRITERIA PHASE DATA DATE/TIME Largest Magnitude C -A 27.9V, 0.000 Sec. 07/02/2010 12:15:34.22 1• i� • WORST CASE SUMMARY WAVEFORMS Site: INAP PDU 3A5 Measured from 07/02/2010 10:48:52.0 to 07/02/2010 15:01:00.0 Lowest Magnitude Voltage Sag:No event Highest Magnitude Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Sag:No event Longest Duration Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Most Energy Missing Voltage Sag:No event Most Energy Added Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Interruption:No event Largest Magnitude Voltage Transients: Phase C -A NO WAVEFORM AVAILABLE Volts 300 1 100 -300 11 1111 1111 iii 1111 111 12:15:34.210 12:15:34.220 12:15:34.230 Amps J - C -AV -CI c=•awnuw. 0.1 0.00100 0.00075 0.00050 0.00025 0.00000 27.9V,0.000 Sec., on 07/02/2010 12:15:34.22 • • PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3A5 Measured from 07/02/2010 10:48:52.0 to 07/02/2010 15:01:00.0 VOLTAGE Volts 3.00 2.95 2.90 2.85 Volts 3.0 2.5 2.0 1.5 1.0 0.5 0.0 1 1 1 1 1 1 1 i 1 1 1 1 1 1 1 1 1 1 11 00 11 30 12 00 12:30 13 00 13 30 14 00 14 30 07/02/2010 Friday - A B VTHDRss (au3) 15 00 THD H10 H2O D A -B VHarm H30 Total RMS: 117.23 V DC Leal: 0.00 V Funcarrental(H1) RMS: O.00V Total Harmonic Distortion THD: 3.01 V(Evai: 0.08 V, Odd 3.01 V) H40 1-150 ozI a_ no —Ili li♦ ._ -i .� -.. — _^° —E— — —i • • .a — — =o= 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 H2O D A -B VHarm H30 Total RMS: 117.23 V DC Leal: 0.00 V Funcarrental(H1) RMS: O.00V Total Harmonic Distortion THD: 3.01 V(Evai: 0.08 V, Odd 3.01 V) H40 1-150 • • PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3A5 Measured from 07/02/2010 10:48:52.0 to 07/02/2010 15:01:00.0 CURRENT Amps 9.5 9.4 9.3 9.2 9.1 9.0 8.9 Amps 10 — 9 8 7 6 5 4 3 2 1 0 1 r THD i i 1 1 1 i i i 11 00 11 30 12.00 12.30 07/02/2010 Friday 1 1 13 00 13 30 14 00 14 30 — A ITHDRss (avg) c.n.awnomr «me 15 00 1 1 I I I I I I I I I H10 H2O Total RMS: DC Level: Fundarrental(H1) RMS: Total Hammnic Distortion THD: 1 1 1 1 1 1 1 1 1 1 1 1 1 H 30 MI AlHarm 62593 A 4.01 A 62564 A 9.52 A (Eves: 0.46A, Odct 9.51 A) 1 I I I I I 1 1 1 H40 H50 ( • PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3A5 Measured from 07/02/2010 10:48:52.0 to 07/02/2010 15:01:00.0 VOLTAGE Volts 3.300 3275 3250 3225 3200 3.175 3.150 3.125 Volts 3.0 2.5 2.0 1.5 1.0 0.5 0.0 - i 1 i i i i 1 1 11 00 11.30 12 00 12 30 07/02/2010 Friday THD H10 13 00 13:30 14 00 14 30 15 00 - B -C VTHDRss (mg) H2O ona.a.mnomvi.., a.., B -C VHarm }-130 Total RMS: 117.10V DC Level: 0.00V Fundarrental(H1) RMS: 0.00V Total Harmonic Distortion THD: 3.30V (BRIT 0.14V, Odd 3.30V) Cm`l ve.DmVir H40 f, • • PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3A5 Measured from 07/02/2010 10:48:52.0 to 07/02/2010 15:01:00.0 CURRENT Amps 10.1 10.0 9.9 9.8 9.7 9.6 Amps 10.0 7.5 5.0 2.5 0.0 11 00 07/02/2010 Friday 11 30 1 1 1 1 1 1 1 1 12 00 12 30 13 00 13:30 14 00 14 30 - B ITHDRss (avg) < .wnomvi« “.1 15 00 THD 1 1 1 1 1 1 1 H10 H2O I I I I I I ® B IHarm H 30 Total RMS: 63203 A DC Level: 3.90 A Funthn>rntal(H1) RMS: 631.97 A Total Harmonic Distortion THD: 10.11 A (Eeen: 0.62 A Odd: 1009 A) CI*wilhomvI.o as H40 . H50 • PHASE C HARMONIC TIMEPLOT Site: INAP PDU 3A5 Measured from 07/02/2010 10:48:52.0 to 07/02/2010 15:01:00.0 VOLTAGE Volts 3.15 3.10 3.05 3.00 Volts 3.0 2.5 2.0 1.5 1.0 0.5 0.0 I I I I I 11 00 11 30 12:00 07/02/2010 Friday 1 I 1 1230 1300 - C A VTHDRss (mg) 13 30 1 1 1 1 I 14 00 14 30 15 00 THD H10 H2O C -A VHarm H30 Total RMS: 116.51 V DC Level: 0.00V Fundarrental(H1) RMS: 0.00V Total Harrronic Distortion THD: 3.17V(Evtn: 0.09V, Odct 3.17V) C,..1.1.1hOmVI.. m.+ H40 H50 - we 111 .rl .. NI IN — IN 111 — ■ ■ — . 1. ... IN _ al r ■ i ._ — — 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I 1 1 I 1 1 I 1 1 1 1 1 1 I 1 1 1 1 1 1 1 1 1 1 1 THD H10 H2O C -A VHarm H30 Total RMS: 116.51 V DC Level: 0.00V Fundarrental(H1) RMS: 0.00V Total Harrronic Distortion THD: 3.17V(Evtn: 0.09V, Odct 3.17V) C,..1.1.1hOmVI.. m.+ H40 H50 • PHASE C HARMONIC TIMEPLOT Site: INAP PDU 3A5 Measured from 07/02/2010 10:48:52.0 to 07/02/2010 15:01:00.0 CURRENT Amps 10.5 — 10.4 10.3 10.2 10.1 10.0 9.9 —' Amps 10.0 7.5 5.0 2.5 0.0 1 1 1 i 1 1 1 1 1 1 11 00 11 30 12 00 12 30 13 00 07/02/2010 Friday — C ITHDRss (avg) 13 30 14 00 14 30 15 00 THD H10 H2O — C IHarm H 30 Total RMS: 63333 A DC Level: 4.63A Fundanental(H1) RMS: 63310A Total Harmonic Distortion THD: 10.47A (Even: 0.40A,OW: 1Q46A) <,..d.aaomVi.,ael H40 H50 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I I 1 1 1 THD H10 H2O — C IHarm H 30 Total RMS: 63333 A DC Level: 4.63A Fundanental(H1) RMS: 63310A Total Harmonic Distortion THD: 10.47A (Even: 0.40A,OW: 1Q46A) <,..d.aaomVi.,ael H40 H50 /41, LEE TECHNOLOGIES' L 111/ • • LEVEL 4 CHECKLIST Se llOt, �1 Procedure Tide: :o"'ci.'' 1NT TUK -WA -COMMISSIONING - PDI -PDU Into?Ifl i t,t, Submittal Date: 18 May 10 y Procedure Work Date: 02 Jul 10 Procedure Work Time Frame: 0800 -1700 Customer Name: Intemap Customer's Sokrnon Rolect Code: Address: Street Addle= 3355 South 120 th Place C140: ... State: Zip: Tukwila WA 98168 CustomerPOC: Customer POC Name: Kathy Mclnvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning su • ervisor. Herbert Burnett Phone Numbers: Phone Number: 703 -968 -0300 Mobile: 713.423.4335 Pepe. `" -,'"" ° '- Ptocedure OaetVIC%I Equipment PDI PDU CX Procedure 3A5 Affected Area: Data Center I Systems Affected: Load Distribution Equipment Information: Manufacturer: PDI Equipment Type: PDU Model it: PP13 -WS- 300 -G-641 serial M: 110- 2679 -2 Procedure Overview: This testing will verify the operation of the PDU. Anticipated Results: The PDU will operate as per design. Pre - Procedure Requirements: Manufacturer's startup completed on the module. Air conditioning system is functional and capable of supporting the heat load generated by the PDU module. Ensure that all test equipment that is required is onsite and operational. Load banks will be hooked up and ready for testing. Conduct a point to point test to verify correct wiring. Boundaries are placed around the PDU. The Power Quality Meter is set up and ready to record. `-e.:i• n 03 PI,,, itlle Details Detailed Procedure Detailed Rooedu% Complete 1. Record start date: 02 Jul 10 Record start time:10:54 2. Document that vendor start up has been performed. ✓ 3. Perform a visual of the PDU to ensure that there is no extemal damage to the PDU. ✓ 4. Check that the PDU Is level and stable with all stabilizers flush to the floor. .7 5. Close the feeder breaker to the PDU. 6. Ensure that all PDU Toad breakers are in the OPEN position. 7. Close the input main circuit breaker inside the PDU. ✓ 8. Press the monitor on button. V Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 3 410 • • .&./4111 LEE TECHNOLOGIES' 16, LEVEL 4 CHECKLIST Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 ... 1113 .. ., --:',:o ".;. '' ... .-;. ., ,., ,,,P#P-ii..,. • -` ps %is .,;, ' ' , Y!,; - l' DVM 116 LCD 116 642 1.-'•;;;z ! .11 ',f, , ... '..,. )Lt'e , Y-V, -I; .;,:ii,k DVM 117 LCD 117 648 --C. I....: ,5,i%,,, ..‘'.44..,,,,. f - - • .J U. _, '441^e-, ,, ' — DVM 117 LCD 117 648 "i- - ‘: .i'1,43.:;:- DVM LCD 476 DVM 202 LCD 202 ie,li, DVM LCD 477 DVM 203 LCD 203 KW 228 CA 4.--, ,_,,,- DVM LCD 477 DVM 202 LCD 202 KVA 228 8.1. Apply control power to the load bank. 8.2. Apply 100% load to the PDU. KW:225 X 83. Start a 4 hour bum test of the PDU. / 8.4. Monitor temperature In the surrounding area. / 8.5. PDU BURN SHEET. -,,,T-i?2, i-iirie., ,-,..,..., ,, ,--; “,.,;,;-,,. -.:.;:, ,:4,‘:,:-.;,. ,.- 06tRut.Vofts (L-N) -- .: , .: ,,;:,,, :-..,:°:;:--,,- 4 -.. :ra','")*. Output Amps 4 "-• :)•:Y.,•.•,'.: ..,-,:-..,,,,- KW rs,:-....4-.., f 00110,';! A 117 B 117 C 117 A 644 B 648 C 647 228 ,;o:: 0015M A 116 B 117 C 117 A 642 B 647 C 648 228 k..10.9:40 `e.% A 117 B 117 C 117 A 642 B 646 C 848 226 ..— V OXI:4P , A 116 B 117 C 117 A 644 B 649 C 650 228 ' •-•••-•,. ,-. IHi. A 118 B 117 C 117 A 642 B 648 C 648 227 N A 116 13 117 C 117 A 644 El 649 C 650 228 ...' ' 7;3Hri,4; A 116 B 117 C 117 A 642 13 647 C 649 225 ...,..:,..r„ ,4111-441. A 118 B 117 C 117 A 641 B 645 C 647 226 8.6. Shut down all load on the load bank. v 8.7. Allow the load bank to run with no load for 5 minutes for cool down purposes. V. 8.8. At the PDU, flip up the protective cover over the EPO button and press it in. NOTE: THE INPUT BREAKER SHOULD TRIP AND SHUT OFF ALL POWER FROM THE PDU. i 8.9. Verify that all power was removed from the load bank. • i Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 • • • ,elk LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 8.10. Reset the tripped input breaker at the PDU. ✓ 8.11. OPEN the feeder breaker to the PDU. 8.12. Check that the PDU cabinet is not - energized and safe to work in. r'" 8.13. Secure from the Toad banking. Se ucn0 -1 Comments 8.2 225 KW was applied due to the current limitations of the Toad bank at 208 volts. Conducted an IR scan after two hours and at the end of the four hour Toad bank test. No hot spots were found. 3ecncn05 P{./;E`()I.•r`•: ,ttiil£ P. Lee Technologies Group has witnessed participated in this procedure and attests to the accuracy and completeness of this report / Printed NW*: 1. - bilk.- Data Herb Bumett irt�� r 'l 02 July 10 template Rev, 07022010 , Lee Technologies Group 0 Copyright 2010 Proprietary use pursuant to company policy Page 3 of 3 • VOLTAGE TIMEPLOTS Site: INAP PDU 3A6 Measured from 07/06/2010 14:19:15.0 to 07/06/2010 18:20:45.0 230 220 43 210 0 200 190 230 220 43 210 0 200 190 230 1 1 220 43 210 200 190 T T —A B V1MS — B C Vrms 1 — C A Vrms 111111111 14:30 15:00 15:30 07/06/2010 Tuesday 16:00 C NNW .110.1,••■ 11111111111 16:30 17:00 17:30 18:00 • WORST CASE SUMMARY Site: INAP PDU 3A6 Measured from 07/06/2010 14:19:15.0 to 07/06/2010 18:20:45.0 Of 0 total VOLTAGE SAGS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE SWELLS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE INTERRUPTIONS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE TRANSIENTS CRITERIA PHASE DATA DATE/TIME • • • WORST CASE SUMMARY WAVEFORMS Site: INAP PDU 3A6 Measured from 07/06/2010 14:19:15.0 to 07/06/2010 18:20:45.0 • • Lowest Magnitude Voltage Sag:No event Highest Magnitude Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Sag:No event Longest Duration Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Most Energy Missing Voltage Sag:No event Most Energy Added Voltage Swell:No event • • • NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Interruption:No event Largest Magnitude Voltage Transients:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE • PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3A6 Measured from 07/06/2010 14:19:15.0 to 07/06/2010 18:20:45.0 VOLTAGE Volts 3.75 3.50 325 3.00 2.75 • Volts 4.0 3.5 3.0 2.5 2.0 1.5 1.0 0.5 0.0 • 1 1 1430 1500 07/002010 Tuesday 15 30 1 1 1 1 1 1600 1630 1700 1730 1800 - A BVTHDRss (avg) LmW r+YnDmVlwv 00.1 THD H10 H2O I♦ A- BVHarm H30 Total RMS: 11828 DC Level: 0.00V Fur rrental(H1) RMS: 0.00V Total Harmonic D istortion TH D: 3.85 V ( Ever 020V, Odd 3.85V) Lm.OwanDmVlwr 00.1 H40 H 50 I 1 1 1 1 1 1 1 1 1 1 11 1 1 1 1 r 1 1 r r 1 r t 1 1 r r I i r 1 1 1 1 1 1 r l l l l l r l l THD H10 H2O I♦ A- BVHarm H30 Total RMS: 11828 DC Level: 0.00V Fur rrental(H1) RMS: 0.00V Total Harmonic D istortion TH D: 3.85 V ( Ever 020V, Odd 3.85V) Lm.OwanDmVlwr 00.1 H40 H 50 PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3A6 Measured from 07/06/2010 14:19:15.0 to 07/06/2010 18:20:45.0 CURRENT Amps 11.5 11.0 10.5 10.0 9.5 9.0 8.5 8.0 • Amps 10.0 7.5 5.0 2.5 0.0 • 1430 1500 07/06/2010 Tuesday 15 30 1 1 1 1 1 1 1 16 00 16 30 17 00 17 30 18 00 - A ITHDRss (avg) Cm.e.anomviwv..1 THD H10 H20 Total RMS: DC Level: Furxtanmental(H1) RMS: Total Hamnnic Distortion THD: H 30 AIHarm 58Q 9g A 3.31 A 580.95 A 11.42A(Even: 1.36A Odd: 11.33A) H40 H50 1 I I I I 1 1 1 1 1 1 I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I I I 1 1 1 1 1 1 THD H10 H20 Total RMS: DC Level: Furxtanmental(H1) RMS: Total Hamnnic Distortion THD: H 30 AIHarm 58Q 9g A 3.31 A 580.95 A 11.42A(Even: 1.36A Odd: 11.33A) H40 H50 PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3A6 Measured from 07/06/2010 14:19:15.0 to 07/06/2010 18:20:45.0 VOLTAGE Volts 3.75 3.50 3.25 3.00 • Volts 1430 1500 1530 1600 1630 1700 1730 07/06/2010 Tuesday — B C VTHDRss (av3) CmeMhomVia,6e.1 18 00 4.0 3.5 3.0 2.5 2.0 1.5 1.0 0.5 0.0 - ∎ — — mom we — - I — ill ® — NI - — ■ No — ■ i t I I I I I I I I I I I I I I I I 1 1 1 1 1 1 1 1 1 1 1 I I I I I I I I I THD • H10 H20 B -C VHarm H30 Total RMS: 11866 V DC Level: 0.00 V Fundamental( H1) RMS: 0.00V Total Harmonic Distortion THD: 3.80 V ( Ever: 0.12V, Odd 3.80V) H40 H 50 PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3A6 Measured from 07/06/2010 14:19:15.0 to 07/06/2010 18:20:45.0 CURRENT Amps 11.0 10.5 10.0 9.5 9.0 8.5 • Amps 10.0 7.5 5.0 2.5 0.0 • 1 1 1 1430 1500 0 7/0 612 01 0 Tuesday 1 I I 1 1 1 1 1 15 30 16 00 16 30 17 00 17 30 - B ITHDRss (arg) Cm199.11OrnVl« 09.1 18 00 THD H10 H 20 BIHarm H30 Total RMS: 611.87 A DC level: 3.43 A Furxl3rrental(H1) RMS: 611.63 A Total Harmonic Distortion THD: 1126A(Een: 1.40A Odd: 11.19 A) Cm`] wth Dom Viw 09.1 H40 H 50 1 1 I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 H 20 BIHarm H30 Total RMS: 611.87 A DC level: 3.43 A Furxl3rrental(H1) RMS: 611.63 A Total Harmonic Distortion THD: 1126A(Een: 1.40A Odd: 11.19 A) Cm`] wth Dom Viw 09.1 H40 H 50 PHASE C HARMONIC TIMEPLOT Site: INAP PDU 3A6 Measured from 07/06/2010 14:19:15.0 to 07/06/2010 18:20:45.0 VOLTAGE Volts 4.00 3.75 3.50 3.25 3.00 2.75 Volts 1 1 1 1430 1500 07/0612010 Tuesday 15 30 1 1 1 1 16 00 16 30 17 00 17 30 18 00 -C AVTHDRss(av0) cs=.a.aeowi.. a..+ THD • H10 H2O C -A VHarm H30 Total RMS: 117.85 V DC Level: 0.00V Furxfamental(H1) RMS: O.00V Total HamcnicDistortionTHD: 4.02V(Ever: 0.11 V, Odd 4.02V) c�.e wnomvi... aea H40 H50 4.0 3.5 3.0 2.5 2.0 1.5 : 1.0 0.5 0.0 r r 1 1 1 1 1 1 1 1 1 11 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD • H10 H2O C -A VHarm H30 Total RMS: 117.85 V DC Level: 0.00V Furxfamental(H1) RMS: O.00V Total HamcnicDistortionTHD: 4.02V(Ever: 0.11 V, Odd 4.02V) c�.e wnomvi... aea H40 H50 • PHASE C HARMONIC TIMEPLOT Site: INAP PDU 3A6 Measured from 07/06/2010 14:19:15.0 to 07/06/2010 18:20:45.0 CURRENT Amps 11.5 11.0 10.5 10.0 9.5 9.0 • Amps 10.0 7.5 5.0 2.5 0.0 • 1430 1500 07/06/2010 Tuesday i 1 15 30 16 00 16 30 - C ITHDRss (alg) 17 00 1730 1800 • • • 1 I 1 1 1 1 1 1 1 1 1 I I I 1 1 1 1 l 1 1 1 1 1 1 1 1 1 1 I I I I I I 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 H 20 Total RMS: DC Level: Fundamental(H1) RMS: Total Harmonic DistortionTHD: H30 �C!Harm 609.31 A 3.10A 609.06 A 11.72 A (Even: 1.42 A, Odd: 11.63A) H40 H 50 L� LEE TECHNOLOGIES' AK • LEVEL 4 CHECKLIST Secuo Q Procedun7Title: Pi0,:oc' "o INT TUK WA- COMMISSIONING - PDI -PDU I1to,r.,,,io„ Submittal Date: 18 May 10 y Procedure Work Date: 06 Jul 10 Procedure work Time Frame: 0800 -1700 . . customer Name: Internap Customer's Soloman Project coda. Address: Sheet Address: 3355 South 120th Place City: Tukwila WA 98188 Customer' Customer POC llama: Kathy Mcinvale Phone Numbers: Office: 404,302.9753 Mobile: 404.547.8915 Lee Technologies Corrrmksloning su • : rvisor. Herbert Burnett Phone Numbers: PhoneManber: 703 - 968 -0300 Mobile` 713.423.4335 Pager. p=`1io .- o Piocudwr ht'dlYii' ;� Equipment PDI PDU CX Procedure 3A6 Affected area: Data Center Systems Affected: Load Distribution Equipment Information: Manufacturer PDI Equipment TYPe: PDU Model #: PP13 -WS- 300 -6-641 serial #: 110- 2879 -7 Procedure Overview: This testing will verify the operation of the PDU. Anticipated Results: The PDU will operate as per design. Pre Procedure Requirements: Manufacturer's startup completed on the module. Air conditioning system is functional and capable of supporting the heat load generated by the PDU module. Ensure that all test equipment that is required is onsite and operational. Load banks will be hooked up and ready for testing. Conduct a point to point test to verify coned wiring. Boundaries are placed around the PDU. The Power Quality Meter is set up and ready to record. sec: ::.1 `J3 Detailed Procedure Detailed Pocedrae: Complete 1. Record start date: 06 Jul 10 Record start time:14:17, 2. Document that vendor start up has been performed. 3. Perform a visual of the PDU to ensure that there is no external damage to the PDU. ✓ 4. Check that the PDU is level and stable with all stabilizers flush to the floor. 5. Close the feeder breaker to the PDU. 8. Ensure that all PDU load breakers are in the OPEN position. if 7. Close the input main circuit breaker inside the PDU. 8. Press the monitor on button. Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 3 41 • 4.,11 LEE TECHNOLOGIES' 116, LEVEL 4 CHECKLIST Template Rev. 07022010 Lee Technologies Group CO Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 • : - ,-- _..', 1- - ,. . , :.iripirt Vs.-: • ,: -:;t:." -,,'. -77,•','...-:.. 7Outtii#V77...: ;.::.-: ::!. auttitit, :•--,:- :-. ,..;-„ DVM 116 LCD 117 604 .$0 B : .r - zs 4 vt, ' x , gs DVM 117 LCD 117 608 C : si,s;,,,,,. — ,,g-- '... ' DVM 117 LCD 117 611 : AB 4: r DVM LCD 472 DVM 202 LCD 203 't ' ■ , ,. '•,, BC,' DVM LCD 473 DVM 201 LCD 203 WV 213 .-ck,--,'' DVM LCD 471 DVM 202 LCD 201 KVA 213 8.1. Apply control power to the load bank. V' 8.2. Apply 100% load to the PDU. KW:220 X 8.3. Start a 4 hour burn test of the PDU. 8.4. Monitor temperature in the surrounding area. 8.5. PDU BURN SHEET. '.i Time gn7. ,..','..-:-7,..-.,!• • :-"' : .7 ''';" ,• output=yolts.g.-Ny- .,..;.:.!j,-,:. :::/' . . -.' ''''''... , ' ■ :'?.'''', ''. =-= ' OutputAmps,:z., '..',..-c:. ,: ., ,.:,,, ".--, KW :00: 00 i A-BC 117 117 117 A 604 BC 608 611 213 _4, tr•-40-1104 , ''.4 A 116 B 116 C 116 A 604 B 610 C 612 214 7,-•"' ":---"'---..i ii*,4y7, A 117 B 117 C 117 A 604 B 608 C 611 213 .-'-.2---..--i.it-t .,.. 101*, ' e---:?: A 117 B 117 C 117 A 605 B 610 C 612 214 :04:-f--- A 117 B 117 C 117 A 607 B 612 C 614 215 Hrt.. A 117 B 117 C 117 A 607 B 611 c 615 215 ,:iiej 7-T.Z-314f:',A A 117 B 117 C 117 A 608 B 613 c 615 216 gle4fr,45,1,U R:11n.T A 116 B 117 C 117 A 609 B 613 C 615 216 8.6. Shut down all load on the load bank. 8.7. Allow the load bank to run with no load for 5 minutes for cool down purposes. v. 8.8. At the PDU, flip up the protective cover over the EPO button and press it in. NOTE: THE INPUT BREAKER SHOULD TRIP AND SHUT OFF ALL POWER FROM THE PDU. 8.9. Verify that all power was removed from the load bank. Template Rev. 07022010 Lee Technologies Group CO Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 • • LEE TECHNOLOGIES° L LEVEL 4 CHECKLIST 8.10. Reset the tripped input breaker at the PDU. / 8.11. OPEN the feeder breaker to the PDU. ✓ 8.12. Check that the PDU cabinet is not - energized and safe to work in. ✓ 8.13. Secure from the Toad banking. 5,ctton o COO" x'11 @IIt,. Comments 8.2 220 KW was applied due to the current limitations of the load bank at 208 volts. Conducted an IR scan after two hours and at the end of the four hour load bank test. No hot spots were found. Section 05 F,cceau, W■ulc•ss A V∎.I,f... 311']II Lee Technologies Group has witnessed or , . rticipated in this procedure a :,attests to the accuracy and completeness report. \S. Date Name: )) '• ' of this Herb Burnett % I - 4f. %00-. - _ 06July 10 Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 3 • VOLTAGE TIMEPLOTS Site: INAP PDU 3A7 Measured from 07/07/2010 08:14:07.0 to 07/07/2010 12:20:52.0 • • 230 220 Sa 210 0 200 190 230 220 t9 210 0 200 190 230 220 se 210 O 200 190 T T - r - A B Vrms 1 J T - B C Vrms 1 - C A Vrms I ' ' I ' 1 I 1 1 I 1 1 1 1 1 08:30 09:00 09:30 10:00 10:30 11:00 07/07/2010 Wednesday o..e.ano.,«nea I 11:30 ' I ' 12:00 0 WORST CASE SUMMARY Site: INAP PDU 3A7 Measured from 07/07/2010 08:14:07.0 to 07/07/2010 12:20:52.0 Of 0 total VOLTAGE SAGS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE SWELLS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE INTERRUPTIONS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE TRANSIENTS CRITERIA PHASE DATA DATE/TIME • • • WORST CASE SUMMARY WAVEFORMS Site: INAP PDU 3A7 Measured from 07/07/2010 08:14:07.0 to 07/07/2010 12:20:52.0 • • Lowest Magnitude Voltage Sag:No event Highest Magnitude Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Sag:No event Longest Duration Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Most Energy Missing Voltage Sag:No event Most Energy Added Voltage Swell:No event • • • NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Interruption:No event Largest Magnitude Voltage Transients:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE • PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3A7 Measured from 07/07/2010 08:14:07.0 to 07/07/2010 12:20:52.0 VOLTAGE Volts 3.4 3.3 3.2 3.1 — 3.0 2.9 2.8 2.7 2.6 Volts 3.5 3.0 2.5 2.0 1.5 1.0 0.5 0.0 • 08 30 09 00 09 30 07/07/2010 Wednesday 1 1 1 1 1 1 10 00 10 30 11 00 11 30 12:00 —A BVTHDRss(a∎g) THD H10 H20 A -B VHarm H30 Total RMS: 117.39 V DC Level: 0.00 V Furxtnlental(H1) RMS: O.00V Total Harrronic D istortion THD: 3.40V(Eve1:0.13V, Odd 3.40V) H40 H50 I r 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 H20 A -B VHarm H30 Total RMS: 117.39 V DC Level: 0.00 V Furxtnlental(H1) RMS: O.00V Total Harrronic D istortion THD: 3.40V(Eve1:0.13V, Odd 3.40V) H40 H50 PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3A7 Measured from 07/07/2010 08:14:07.0 to 07/07/2010 12:20:52.0 CURRENT Amps 10.0 9.5 - 9.0 8.5 8.0 — • Amps 10.0 7.5 5.0 2.5 0.0 • 1 1 1 1 1 1 1 1 1 1 1 1 08.30 09 00 09 30 10 00 10 30 11 00 07/07 2010 Wednesday — A ITHDRss (avg) m..wa vie Is mV ae.1 11 30 I l i 12:00 THD H10 H20 MIE AlHarm H30 Total RMS: 596.03 A DC Level: 3.34A Fundarrental(H1) RMS: 596.14 A Total Hanronic Distortion THD: 1026 A (Even: Q88 A, Odd: 1022A) H40 H50 1 1 1 1 1 1 1 1 1 1 1 I I I 1 1 1 1 1 1 I I I I I I I I 1 t t l 1 1 1 1 I I I I I I I I I I I THD H10 H20 MIE AlHarm H30 Total RMS: 596.03 A DC Level: 3.34A Fundarrental(H1) RMS: 596.14 A Total Hanronic Distortion THD: 1026 A (Even: Q88 A, Odd: 1022A) H40 H50 • PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3A7 Measured from 07/07/2010 08:14:07.0 to 07/07/2010 12:20:52.0 VOLTAGE Volts 3.6 3.5 3.4 3.3 3.2 3.1 3.0 2.9 2.8 • Volts 3.5 3.0 2.5 2.0 1.5 1.0 0.5 0.0 • 08 30 09 00 09 30 10 00 10 30 11 00 11 30 07/07/2010 Wednesday - B C VTHDRss (a■g) I 12:00 THD H10 H20 B -C VHarm H30 Total RMS: 117.56 V DC Level: 0.00 V Fur danental(H 1) RMS: 0.00 V Total Harmonic D istortion TH D: 3.57 V (Even: 0.09 V, Odd 3.57 V) H40 H50 _tom - __ . NMI mom ill ME ■ - .__ El in - -__ . - _ - 1 I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 i I i � 1 1 1 1 1 1 1 1 1 1 THD H10 H20 B -C VHarm H30 Total RMS: 117.56 V DC Level: 0.00 V Fur danental(H 1) RMS: 0.00 V Total Harmonic D istortion TH D: 3.57 V (Even: 0.09 V, Odd 3.57 V) H40 H50 • PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3A7 Measured from 07/07/2010 08:14:07.0 to 07/07/2010 12:20:52.0 CURRENT Amps 10.5 10.0 9.5 9.0 8.5 • Amps 10.0 7.5 5.0 2.5 0.0 • 08 30 09 00 07/07 2010 Wednesday 09 30 1 1 1 1 1 1 I 10 00 10 30 11 00 11 30 12:00 - B ITHDRss (avg) THD H10 H2O Total RMS: DC Level: Furldanrental(H1) RMS: Total HamlonicDistortionTHD: H30 MIN B (Harm 61a 18 A 3.10A 61293A 10.44A(Een: 0.95A, Odd: 1Q39A) H40 H50 1 1 1 1 1 1 1 1 1 1 1 I I I I I I I I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I I I I I 1 1 1 1 THD H10 H2O Total RMS: DC Level: Furldanrental(H1) RMS: Total HamlonicDistortionTHD: H30 MIN B (Harm 61a 18 A 3.10A 61293A 10.44A(Een: 0.95A, Odd: 1Q39A) H40 H50 PHASE C HARMONIC TIMEPLOT Site: INAP PDU 3A7 Measured from 07/07/2010 08:14:07.0 to 07/07/2010 12:20:52.0 VOLTAGE Volts 3.50 3.25 3.00 2.75 • Volts 3.5 3.0 2.5 2.0 1.5 1.0 0.5 0.0 • 08 30 09 00 07/07 2010 Wednesday i 1 1 1 1 1 1 1 1 1 l 09 30 10 00 10 30 11 00 11 30 12:00 - C A VTHDRss (avg) Cole.u.hDmviw eea THD H10 H2O C -A VHarm H30 Total RMS: 117.19 V DC Level: 0.00V FUndarrental(H1) RMS: O.00V Total Harmonic D istortion TH D: 3.61 V (Evan: 0.10V, Odd 3.61V) H40 H50 f 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 H2O C -A VHarm H30 Total RMS: 117.19 V DC Level: 0.00V FUndarrental(H1) RMS: O.00V Total Harmonic D istortion TH D: 3.61 V (Evan: 0.10V, Odd 3.61V) H40 H50 • PHASE C HARMONIC TIMEPLOT Site: INAP PDU 3A7 Measured from 07/07/2010 08:14:07.0 to 07/07/2010 12:20:52.0 CURRENT Amps 10.5 10.0 9.5 9.0 8.5 • Amps 10.0 7.5 5.0 2.5 0.0 • 08 30 07/07 2010 Wednesday 09 00 1 1 1 1 1 1 09 30 10 00 10 30 11 00 11 30 - C ITHDRss (aug) c..wa+ 110mr.. ee.i 12:00 THD H10 H20 Total RMS: DC Level: Furxbnlental(H1) RMS: Total Harmonic Distortion THD: H30 C !Harm 601.07 A 3.41 A 600E6 A 10.80A(Even: Q85 A, Odd: 1Q77A) H40 H50 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 H20 Total RMS: DC Level: Furxbnlental(H1) RMS: Total Harmonic Distortion THD: H30 C !Harm 601.07 A 3.41 A 600E6 A 10.80A(Even: Q85 A, Odd: 1Q77A) H40 H50 • • • L� � ��NoLOGfEs- LEVEL 4 CHECKLIST R Senior 01 ocedureTdle: P'° :0mile INT-TUK-WA-COMMISSIONING - PDI -PDU infoirmition Submittal Date: 18 May 10 y Procedure Work Date: 07 Jul 10 Procedure Work rime Frame: 0800 -1700 Customer Name: Intemap Customer's Solomon AoJeol Coda: Address: Street Address: 3355 South 120th Place City State: ZIP: Tukwila WA 98168 Customer POC: Customer POC Name: Kathy Mclnvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissloning Su • ervlsor. Herbert Burnett Phone Numbers: Phone Number 703 - 968 -0300 Mobile: 713.423.4335 Pager SeGitor °= Pincefhua Ovo!vtev.r Affected area: Equipment PDI PDU CX Procedure 3A7 Data Center Systems Affected: I Load Distribution Equipment information: Manufacture. PDI Equipment Type: PDU Model e: PP13 -WS- 300 -G-641 serial a: 110 - 2679 -4 Pmcedu a Overview: This testing will verify the operation of the PDU. Anticipated Results: The PDU will operate as per design. Pre- Procedure Requirements: Manufacturer's startup completed on the module. Air conditioning system is functional and capable of supporting the heat load generated by the PDU module. Ensure that all test equipment that is required is onsite and operational. Load banks will be hooked up and ready for testing. Conduct a point to point test to verify correct wiring. Boundaries are placed around the PDU. The Power Quality Meter is set up and ready to record. :,e ,ion o3 ,,,„,.„.1.,, De9.u1a Detailed Procedure - - Detailed Aocedum: Complete 1. Record start date: 07 Jul 10 Record start time:8:10 2. Document that vendor start up has been performed. 3. Perform a visual of the PDU to ensure that there is no external damage to the PDU. ✓ 4. Check that the PDU is level and stable with all stabilizers flush to the floor. 5. Close the feeder breaker to the PDU. '/` 6. Ensure that all PDU load breakers are in the OPEN position. 7. Close the input main circuit breaker inside the PDU. 8. Press the monitor on button. Temp ate Rev. 07022010 Lee Technologies Group 0 Copyright 2010 Proprietary use pursuant to company policy Page 1 of 3 • • • L� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 Input V ; `. r Output V c- "Putput .< f :Amps:.: n. 'I ;; DVM 116 LCD 116 617 J B r ' I �Iw S 4. >� r.! . °�►S DVM 117 LCD 117 622 r� cti a�,``� '; �;: DVM 117 LCD 117 616 .: AB DVM LCD 475 DVM 202 LCD 203 '' \1 �;, tBC ` DVM LCD 475 DVM 203 LCD 204 KW 217 CA, ;.; -. DVM LCD 475 _ DVM 202 LCD 201 KVA 217 8.1. Apply control power to the Toad bank. 8.2. Apply 100% Toad to the PDU. KW:220 X 8.3. Start a 4 hour bum test of the PDU. 8.4. Monitor temperature in the surrounding area. V 8.5. PDU BURN SHEET. ✓ Time Output Volts (L' -N) Outp lit 'Amps' " KW 9 00 :00 A 116 B 117 C 117 A 617 B 622 C 616 217 5 00 18` A 116 BC 116 117 A 614 BC 619 615 215 00 30 {'. 117 B 118 C 118 A 615 B 620 C 815 216 4100 :45 � 116 116 116 612 617 7 611 213 :e 1Hr A 115 BC 116 116 A 610 BC 615 610 213 �2H 116 1117 117 C A 614 6119 612 214 y� x, ,73Hrr _ A 116 B 118 C 117 A 615 B 620 C 615 216 e • 4Hr 3 A 116 B 116 C 116 A 612 B 618 C 611 214 6.6. Shut down all Toad on the Toad bank. 8.7. Allow the Toad bank to run with no load for 5 minutes for cool down purposes. 8.8. At the PDU, flip up the protective cover over the EPO button and press it in. NOTE: THE INPUT BREAKER SHOULD TRIP AND SHUT OFF ALL POWER FROM THE PDU. 8.9. Verify that all power was removed from the load bank. Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 8.10. Reset the tripped input breaker at the PDU. 8.11. OPEN the feeder breaker to the PDU. i 8.12. Check that the PDU cabinet is not-energized and safe to work in. 8.13. Secure from the Toad banking. v se ;,ot,0=-, Comments 8.2 220 KW was applied due to the current limitations of the load bank at 208 volts. Conducted an IR scan after two hours and at the end of the four hour load bank test. No hot spots were found. Sec,wn 05 �rocedu:�: UVitriess S \Mniic oh(,,, Lee Technologies Group has witnessed or parts ated in this procedure and attests to the accuracy and completeness of this report. ' Printed Name: I ►, Date: Herb Burnett 4, i II 1 07July 10 Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 3 of 3 • VOLTAGE TIMEPLOTS Site: INAP PDU 3B1 Measured from 07/03/2010 07:34:22.0 to 07/03/2010 11:30:37.0 • • 230 220 la 210 0 200 190 230 220 ill 210 0 200 190 1 1 230 220 10 210 0 200 T T - A B Vrms 190 1 - BCVrms ' I ' ' 08:00 08:30 07/03/2010 Saturday - C AVrms 1 1 1 1 i i 1 1 1 1 i 1 09:00 09:30 10:00 10:30 11:00 cn..e.nno.rviw CIA 11:30 • WORST CASE SUMMARY Site: INAP PDU 3B1 Measured from 07/03/2010 07:34:22.0 to 07/03/2010 11:30:37.0 Of 0 total VOLTAGE SAGS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE SWELLS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE INTERRUPTIONS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE TRANSIENTS CRITERIA PHASE DATA DATE/TIME • • • WORST CASE SUMMARY WAVEFORMS Site: INAP PDU 3B1 Measured from 07/03/2010 07:34:22.0 to 07/03/2010 11:30:37.0 • • Lowest Magnitude Voltage Sag:No event Highest Magnitude Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Sag:No event Longest Duration Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Most Energy Missing Voltage Sag:No event Most Energy Added Voltage Swell:No event • • • NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Interruption:No event Largest Magnitude Voltage Transients:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE • PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3B1 Measured from 07/03/2010 07:34:22.0 to 07/03/2010 11:30:37.0 • VOLTAGE Volts 3.175 • • 3.150 3.125 • 3.100 3.075 3.050 • n • • a • • 07 30 07/0312010 Saturday Volts 3.0 2.5 2.0 1.5 1.0 0.5 0.0 08 00 08 30 09:00 09 30 - A B VTHDRss (avg) CM. wnomvI «aea 10 00 10 30 11 00 11 30 1 THD 1- MI 1_ ■ ■ • i ■ _ • _ 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I 1 1 1 1 1 1 1 1 H10 H2O A- BVHarm H30 H40 H50 Total RMS: 117.72 V DC Level: 0.00V Fundanental(H1) RMS: O.00V Total Hanrnnic Distortion TH D: 3.19 V (Een: 0.12V, Odd 3.19V) • • PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3B1 Measured from 07/03/2010 07:34:22.0 to 07/03/2010 11:30:37.0 CURRENT Amps 9.7 9.6 9.5 9.4 9.3 • • • • • 92 — 1 07 30 07/03/2010 Saturday Amps 10.0 7.5 5.0 2.5 0.0 08 00 08 30 ' I ' 09:00 09 30 — A ITHDRss (arg) Cnoled.hDrnVia■ 0.0.1 10 00 10 30 11 00 11 30 THD H10 H2O MN AIHarm H30 Total RMS: 60884 A DC Level: 323A Functarrental(H1) RMS: 60890 A Total HarrrpnicDistortionTHD: 9.75A( BRIT 0.45A Odd 9.74 A) CleaftdvathOsnVlaw 5.0.1 H40 H50 1 1 1 1 1 1 1 1 1 1 1 I I t l l l l l l I I I I I t l l t 1 1 1 1 1 1 1 1 1 I I I I I I I t l THD H10 H2O MN AIHarm H30 Total RMS: 60884 A DC Level: 323A Functarrental(H1) RMS: 60890 A Total HarrrpnicDistortionTHD: 9.75A( BRIT 0.45A Odd 9.74 A) CleaftdvathOsnVlaw 5.0.1 H40 H50 • PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3B1 Measured from 07/03/2010 07:34:22.0 to 07/03/2010 11:30:37.0 • • VOLTAGE Volts 3.425 3.400 3.375 3.350 3.325 3.300 3.275 • • • • i • • 1 1 07 30 07/03/2010 Saturday Volts 3.5 3.0 2.5 2.0 1.5 1.0 0.5 0.0 08 00 08 30 09:00 09 30 - B C VTHDRss (avg) Comuu nilnDmVi. ae.+ 10 00 10 30 11 00 11 30 THD H10 H 20 B -C VHarm H30 Total RMS: iiacev DC Level: 0.00V Fundamental(H1) RMS: 0.00V Total HarrronicDistortionTHD: 3.43V(Eve1:0.11 V, Odd 3.43V) H40 H50 i 1 1 .. 1 1 1 1 1 1 . I 1 1 1 1 1 1 1 . . 1 1 1 1 1 . 1 1 1 1 1 1 1 1 1 1 . 1 1 1 1 1 1 1 1 THD H10 H 20 B -C VHarm H30 Total RMS: iiacev DC Level: 0.00V Fundamental(H1) RMS: 0.00V Total HarrronicDistortionTHD: 3.43V(Eve1:0.11 V, Odd 3.43V) H40 H50 PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3B1 Measured from 07/03/2010 07:34:22.0 to 07/03/2010 11:30:37.0 CURRENT Amps 9.75 9.70 9.65 9.60 9.55 9.50 9.45 9.40 9.35 • • l• • • • • 07 30 07/03/2010 Saturday Amps 10.0 7.5 5.0 2.5 0.0 • 08 00 08 30 09 00 09 30 - B ITHDRss (avg) c �.e.vnow��, eee 10 00 10 30 11 00 11 30 THD H10 H20 B'Harm H30 Total RMS: 598 A DC Level: 3.09 A Furxianental(H1) RMS: 598.82 A Total Harmonic DistortionTHD: 9.75A(Eval: 0.50 A, Odd 9.74A) H40 H50 1 1 1 1 1 1 1 1 1 1 1 I I I I t l l l 1 I I I 1 1 1 1 1 1 I I I l t l t 1 1 1 1 1 1 1 1 1 1 1 THD H10 H20 B'Harm H30 Total RMS: 598 A DC Level: 3.09 A Furxianental(H1) RMS: 598.82 A Total Harmonic DistortionTHD: 9.75A(Eval: 0.50 A, Odd 9.74A) H40 H50 • PHASE C HARMONIC TIMEPLOT Site: INAP PDU 3B1 Measured from 07/03/2010 07:34:22.0 to 07/03/2010 11:30:37.0 VOLTAGE Volts 3.40 3.35 3.30 3.25 3.20 • 1 1 i 1 1 1 I 1 1 1 1 1 1 1 1 1 1 07 30 08 00 08 30 09:00 09 30 10 00 10 30 11 00 07/03/2010 Saturday Volts - C AVTHDRss (mg) C .`e.vnownw« 48.1 11 30 THD • H10 H2O C- AVHarm H30 Total RMS: 117.83 V DC Level: 0.00 V Furxtarrental(H1) RMS: O.00V Total Harmonic Distortion THD: 3.40 V (Even: 0.11 V, Odd 3.40V) H40 H50 3.5 : 3.0 2.5 2.0 : 1.5 1.0 0.5 0.0 1 1 1 1 i i r 1 1 1 t l l r l l l r l 1 1 1 1 1 1 1 1 1 1 1 i i i 1 1 1 t l l l l l l l l THD • H10 H2O C- AVHarm H30 Total RMS: 117.83 V DC Level: 0.00 V Furxtarrental(H1) RMS: O.00V Total Harmonic Distortion THD: 3.40 V (Even: 0.11 V, Odd 3.40V) H40 H50 • PHASE C HARMONIC TIMEPLOT Site: INAP PDU 3B1 Measured from 07/03/2010 07:34:22.0 to 07/03/2010 11:30:37.0 CURRENT Amps 10.3 10.2 10.1 10.0 9.9 • • • J • • • 07 30 07/03'2010 Saturday Amps 10.0 7.5 5.0 2.5 0.0 • 08 00 08 30 ' I ' 09:00 09 30 - C ITHDRss (mg) wno «vi «013 10 00 10 30 11 00 11 30 THD H10 H 20 Total RMS: DC Level: Fundamental(1-11) RMS: Total HamnnicDistortionTHD: H30 C (Harm 60603 A 3.41 A 605.84 A 10.33 A (Een: 0.34 A, 0W: 10.33 A) H40 H50 1 1 1 1 1 1 1 1 1 1 1 I 1 1 1 1 1 1 1 1 I I I I I I 1 1 1 1 1 1 1 1 1 1 1 1 I I I I I 1 1 1 1 THD H10 H 20 Total RMS: DC Level: Fundamental(1-11) RMS: Total HamnnicDistortionTHD: H30 C (Harm 60603 A 3.41 A 605.84 A 10.33 A (Een: 0.34 A, 0W: 10.33 A) H40 H50 • • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST S ^nnn ; Procedure tree: Pr c�;11,.: INT- TUK -WA- COMMISSIONING - PDI -PDU Submittal Date: 18 May 10 Y Pmcedure Work Date: 03 Jul 10 Procedure Work Time Frame: 0800-1700 Customer Name: I ntema p Customer's Soloman Project Coda: Address: Street Address: 3355 South 120th Place Statm Zip: Tukwila WA 98168 CustomerPOC: CusAtinerPDC Name: Kathy Mcinvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning Su • eMsor: Herbert Burnett Phone Numbers: Phone Number 703- 988 -0300 Mobile: 713.423.4335 Pager Section C2 Equipment PDI PDU CX Procedure 3B1 Affected Area: Data Center 1 Systems Affected: I Load Distribution Equipment Information: Manufacturer PDI Equipment Type: PDU Model 0: PP13 -WS- 300 -6-641 Serial #: 110 - 2679 -3 Procedure Overview: This testing will verify the operation of the PDU. Anticipated Results: The PDU will operate as per design. Pre- Procedure Requirements: Manufacturer's startup completed on the module. Air conditioning system is functional and capable of supporting the heat load generated by the PDU module. Ensure that all test equipment that is required is onsite and operational. Load banks will be hooked up and ready for testing. Conduct a point to point test to verify correct wiring. Boundaries are placed around the PDU. The Power Quality Meter is set up and ready to record Section os Detailed Procedure pt,,u•diu,. [l. 1.,11 , Detailed Ftocedure: Complete 1. Record start date: 03 Jul 10 Record start time:12:13 2. Document that vendor start up has been performed. 3. Perform a visual of the PDU to ensure that there is no external damage to the PDU. v 4. Check that the PDU is level and stable with all stabilizers flush to the floor. 5. Close the feeder breaker to the PDU. "` 8. Ensure that all PDU load breakers are in the OPEN position. i- 7. Close the input main circuit breaker inside the PDU. B. Press the monitor on button. ✓ Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 3 • • • LEE TECHNOLOGIES° LEVEL 4 CHECKLIST Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page2of3 Input V " - . ,. Output V: : �,, Amps'. A P�'r ";� a-Rrxs DVM 116 LCD 116 609 8 � 'tia °w ,4 DVM 117 LCD 117 615 C dlri{ + �w`: 4 F DVM 117 LCD 117 614 AB ; DVM LCD 476 DVM 202 LCD 203 , °. "' DVM LCD 477 DVM 203 LCD 203 KW 215 CA DVM LCD 477 DVM 202 LCD 202 K15 215 8.1. Apply control power to the Toad bank. ✓ 8.2. Apply 100% load to the PDU. KW:220 X 8.3. Start a 4 hour bum test of the PDU. 8.4. Monitor temperature in the surrounding area. ✓ 8.5. PDU BURN SHEET. ✓ ,Time` { Outpiit:Volts p_-N){ OutputYAmps2 ' X00 00 ' A 117 B 117 C 117 A 609 B 615 C 614 215 • r ? 00 15 'i A 117 B 117 C 117 A 810 B 617 C 615 215 04 :30..'; A 117 B 117 C 117 A 609 B 615 C 614 215 OD4J >4: A 117 B 117 C 117 A 611 8 616 C 613 215 A 117 B 117 C 117 A 609 B 615 C 614 215 =r7Hry ., ry A 118 B 117 C 117 A 612 B 617 C 615 216 Ir + _3Hr+— A 116 B 117 C 117 A 610 B 617 C 615 216 �ry?'; 4Hr A 116 B 117 C 117 A 613 B 618 C 617 217 8.6. Shut down all load on the Toad bank. 8.7. Allow the load bank to run with no load for 5 minutes for cool down purposes. ve 8.8. At the PDU, flip up the protective cover over the EPO button and press it in. NOTE: THE INPUT BREAKER SHOULD TRIP AND SHUT OFF ALL POWER FROM THE PDU. 8.9. Verify that all power was removed from the load bank. ✓ Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page2of3 • • L� c LEE TcHrooiocIes° LEVEL 4 CHECKLIST 8.10. Reset the tripped input breaker at the PDU. '` 8.11. OPEN the feeder breaker to the PDU. 8.12. Check that the PDU cabinet is not - energized and safe to work In. 8.13. Secure from the load banking. 'r Sec, en - Comments Corwlei.ts, 8.2 220 KW was applied due to the current limitations of the load bank at 208 volts. Conducted an IR scan after two hours and at the end of the four hour Toad bank test. No hot spots were found. Section 05 Proa:,luur',vttrt, :,::. r,, `Jr nhc:iLnn Lee Technologies Group has witnessed or particlp -, - • in this procedure and attests to the accuracy and completeness of this report. • Date: Printed Notes: A� ,r . '' Herb Burnett .� /-��4 03 July ul 10 Template Rev. 07022010 Lee Technologies Group 0 Copyright 2010 Proprietary use pursuant to company policy Page 3 of 3 • • VOLTAGE TIMEPLOTS Site: INAP PDU 3B2 Measured from 07/03/2010 12:14:00.0 to 07/03/2010 16:26:00.0 230 220 j 210 0 200 190 230 220 Y1 210 0 200 190 230 220 s 210 0 200 - A B Vrms 190 - BCVrms - C A Vrms 12:30 13:00 13:30 14:00 07/0312010 Saturday I ' 1 I i 1 1430 15:00 15:30 16:00 c...a wnno wv�w 11/1.1 S WORST CASE SUMMARY Site: INAP PDU 3B2 Measured from 07/03/2010 12:14:00.0 to 07/03/2010 16:26:00.0 Of 0 total VOLTAGE SAGS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE SWELLS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE INTERRUPTIONS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE TRANSIENTS CRITERIA PHASE DATA DATE/TIME • • SWORST CASE SUMMARY WAVEFORMS Site: INAP PDU 3B2 Measured from 07/03/2010 12:14:00.0 to 07/03/2010 16:26:00.0 • • Lowest Magnitude Voltage Sag:No event Highest Magnitude Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Sag:No event Longest Duration Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Most Energy Missing Voltage Sag:No event Most Energy Added Voltage Swell:No event • • • NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Interruption:No event Largest Magnitude Voltage Transients:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3B2 Measured from 07/03/2010 12:14:00.0 to 07/03/2010 16:26:00.0 VOLTAGE Volts 3.50 3.45 3.40 3.35 3.30 • Volts 1 1 1 1 1 1 1 1 1 1 1 1 12 30 13 00 13 30 14 00 14 30 15 00 07/03'2010 Saturday - A B VTHDRss (avg) Covello] ...DmVlwv Gl.1 15 30 16 00 16 30 THD • H10 H2O ENO A- BVHarm H30 Total RMS: 117.73 V DC Level: 0.00V Furxtamental(H1) RMS: 0.00V Total Harmonic D istortion THD: 3.50 V (Bet 0.11 V, Odd 3.50V) CnoYl..nUmVl« GOA H40 H 50 3.5 3.0 : 2.5 2.0 1.5 : - 1.0 0.5 0.0 - 11 1 I 1 1 I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD • H10 H2O ENO A- BVHarm H30 Total RMS: 117.73 V DC Level: 0.00V Furxtamental(H1) RMS: 0.00V Total Harmonic D istortion THD: 3.50 V (Bet 0.11 V, Odd 3.50V) CnoYl..nUmVl« GOA H40 H 50 • PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3B2 Measured from 07/03/2010 12:14:00.0 to 07/03/2010 16:26:00.0 • • CURRENT Amps 20 19 18 17 16 • 1 • 1 • Amps 20 15 10 5 0 12 30 07/03'2010 Saturday I ' 13:00 13 30 14 00 14 30 - A ITHDRss (avg) Cleel.1.4110mVim (111.1 15 00 15 30 16 00 16 30 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 H2O A!Harm H30 1 1 1 1 1 1 I I I I I I Total RMS: 59879A DC Level: 420A Fundarrental(H1) RMS: 59668 A Total Hanrnnic Distortion THD: 20.11 A(Een: 12.13 A Odd: 16.04 A) H40 • PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3B2 Measured from 07/03/2010 12:14:00.0 to 07/03/2010 16:26:00.0 • • VOLTAGE Volts 3.725 3.700 3.675 3.650 3.625 3.600 3.575 3.550 Volts 12 30 13 00 13 30 14 00 14 30 15 00 15 30 16 00 07/03'2010 Saturday - B C VTHDRss (mg) n..e.nnomvi.. 011.1 16 30 THD H10 H2O B -C VHarm H30 Total RMS: 11813 V DC Level: 0.00V Fundarrental(H1) RMS: 0.00V Total Har conic Distortion THD: 3.74 V (Eve1: 0.09V, Odd 3.74V) .m*1.enomv... ea., H40 H 50 3.5 3.0 2.5 2.0 : 1.5 1.0 : 0.5 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 H2O B -C VHarm H30 Total RMS: 11813 V DC Level: 0.00V Fundarrental(H1) RMS: 0.00V Total Har conic Distortion THD: 3.74 V (Eve1: 0.09V, Odd 3.74V) .m*1.enomv... ea., H40 H 50 • PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3B2 Measured from 07/03/2010 12:14:00.0 to 07/03/2010 16:26:00.0 • • CURRENT Amps 18.0 17.5 17.0 16.5 16.0 15.5 15.0 14.5 Amps 17.5 15.0 12.5 10.0 7.5 5.0 2.5 0.0 12 30 07/03/2010 Saturday 13 00 13 30 14 00 14 30 - B ITHDRss (avg) 1500 15 30 16 00 16 30 THD H10 H2O B IHarm H30 Total RMS: 60539 A DC Level: 3.33A Funrbnental(H1) RMS: 603.31 A Total Hamnnic D istortion TH D: 18.12 A (Eken: 10.42 A Odd: 14.82 A) cn...wnomvim ee., H40 H50 1 1 1 1 1 1 1 1 1 1 1 I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I I I 1 1 1 1 1 1 THD H10 H2O B IHarm H30 Total RMS: 60539 A DC Level: 3.33A Funrbnental(H1) RMS: 603.31 A Total Hamnnic D istortion TH D: 18.12 A (Eken: 10.42 A Odd: 14.82 A) cn...wnomvim ee., H40 H50 • • PHASE C HARMONIC TIMEPLOT Site: INAP PDU 3B2 Measured from 07/03/2010 12:14:00.0 to 07/03/2010 16:26:00.0 VOLTAGE Volts 3.65 3.60 1 3.55 - 3.50 3.45 Volt J 1 • .1 12 30 07/03'2010 Saturday 13 00 13 30 14 00 14 30 - C AVTHDRss(avg) cre..e.nnomvi«,as, 15 00 15 30 16 00 16 30 3.5 it 3.0 j 2.5 2.0 1.5 1.0 0.5 0.0 1 1 i 1 1 1 1 1 1 1 1 I I I I I I I I I 1 1 1 1 1 1 1 1 1 i i i 1 1 1 1 1 1 I I I l l l l t l THD H10 H20 C -A VHarm H30 Total RMS: 117.E V DC Level: 0.00V Fundamental(H1) RMS: 0.00V Total Harmonic Distortion THD: 3.67V(Evse 0.11 V, Odd 3.67V) H40 H50 • PHASE C HARMONIC TIMEPLOT Site: INAP PDU 3B2 Measured from 07/03/2010 12:14:00.0 to 07/03/2010 16:26:00.0 • • CURRENT Amps 11.4 11.3 11.2 11.0 10.9 • • 1 �Z- J 1 • Amps 10.0 7.5 5.0 2.5 0.0 • 1230 1300 07/033/2010 Saturday 13 30 14 00 14 30 — C ITHDRss (avg) Dnr1■1.taDmViwi &CI 15 00 15 30 16 00 16 30 • • 1 1 1 I I I I 1 1 1 1 I I I I I I I I I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 H2O fib C IHarm H30 Total RMS: 611.42 A DC Level: 5.76A Fundamental(H1) RMS: 611.03 A Total Harmonic Distortion THD: 11.39 A ( Even: 0.91 A Odd: 11.35 A) H40 H50 • • • LEE TECHNOLOGIES" LEVEL 4 CHECKLIST sect onOi RocedraeMb: P1 O0r.d'' r e INT- TUK -WA- COMMISSIONING - PDI -PDU Information Submittal Date: 18 May 10 Procedure work Date: 03 Jul 10 Procedure Work Time Frame: 0800 -1700 Customer Name: Intemap Customers Solomon Rgiect Code: Address. Street Address: 3355 South 120th Place CI Slate: Zip: Tukwila WA 98168 CustomerPOC: Custc ner POC Name: Kathy Mclnvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissloning su . = rvisoc Herbert Bumett Phone Numbers: mom Number 703- 968 -0300 Mobile: 713.423.4335 Pager SE�tiop 02 Equipment PDI PDU CX Procedure 3B2 Data Center Systems Affected: Load Distribution Affected Area: Equipment Information: Manulachoer: PDI Equipment Type: PDU Model p: PP13 -WS- 300 -G-641 Serial*: 110- 2679 -8 Procedure Overview: This testing will verify the operation of the PDU. Anticipated Results: The PDU will operate as per design. pn3-P dure Requirements: Manufacturer's startup completed on the module. Air conditioning system is functional and capable of supporting the heat load generated by the PDU module. Ensure that all test equipment that is required is onsite and operational. Load banks will be hooked up and ready for testing. Conduct a point to point test to verify correct wiring.. Boundaries are placed around the PDU. The Power Quality Meter is set up and ready to record se ton os Procedure Details Detailed Procedure Detailed Procedure: Complete 1. Record start date: 03 Jul 10 Record start time:12:13 2. Document that vendor start up has been performed. f 3. Perform a visual of the PDU to ensure that there is no extemal damage to the PDU. 4. Check that the PDU is level and stable with all stabilizers flush to the floor. ✓ 5.. Close the feeder breaker to the PDU. 6. Ensure that all PDU load breakers are in the OPEN position. *` 7. Close the input main circuit breaker inside the PDU. 1. 8. Press the monitor on button. J Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 1 of 3 • • • LEE TECHNOLOGIES" LEVEL 4 CHECKLIST Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 . ',.,-, - , -• '..;-",-:, OLtpUtV 2N,...4.z.,:; , -, •;.*. ' ' , ' , ':Output,' li'; A ••••• ' '',. P.1111PS-.. DVM 118 LCD 118 613 B :-:'-;- •1;..67 . . i ' -,•. ,•-,. . • - .-i• • a-i!' • , DVM 117 LCD 117 625 t ' ' 4 - • d'' ' . DVM 117 LCD 117 627 Aiii...,- LCD 476 DVM 202 LCD 202 ,;;,* ■ . , ,t''.. ''13c2,.. DVM LCD 477 DVM 203 LCD 203 KW 220 CA i DVM LCD 479 DVM 202 LCD 202 KVA 220 8.1. Apply control power to the load bank. i 8.2. Apply 100% load to the PDU. KW:220 X 8.3. Start a 4 hour bum test of the PDU. ./ 8.4. Monitor temperature in the surrounding area. 8.5. PDU BURN SHEET. .:::,,,,,A;t4,4..,:.z,: Time - r, :,,,,,,,--1,;`, :: , .:-.,:,,,..f,';''' ', ? '. :;;•,+ • ?outOutvoite(yit) .;,, ,,zi......,.,,- ..:,..::3' 7 :1--:.." l''',. : • ,,',A4,.'-',..,:;:,,;•:"`.: t, ' q Output Amps .:':.'' :1 ''-.,,..7 ;f:'•-:,.,...,, , ;I;5.1., ,:- :'•:-.':''A.,-' -.',5,,,,.- 40LO0- , idil.hrs2NE:g, A 117 B 118 C 118 A 613 B 625 C 627 220 00:i5: 117 B 118 C 118 A 613 8 625 C 627 220 X.ifil,5212 V4/:ittlt: A 117 B 118 C 118 A 614 B 626 C 626 220 ;puu:45s7 A 117 B 118 C 118 A 613 B 625 C 627 220 ;•';':71HEr-, A 117 B 118 C 118 A 613 B 825 C 627 220 ',.".4••"");,, 2nr4:,-1, A 117 B 118 C 117 A 612 8 623 C 625 219 .0. _,:,,0=L , d.:.,441",:',': tc.i4ifiasi- A 117 B 118 C 118 A 612 B 625 C 628 220 .„., ,33,4 ':':: A 117 B 118 C 118 A 613 B 626 C 627 220 8.8. Shut down all load on the load bank. v 8.7. Allow the load bank to run with no load for 5 minutes for cool down purposes. 1 8.8. At the PDU, flip up the protective cover over the EPO button and press it in. NOTE: THE INPUT BREAKER SHOULD TRIP AND SHUT OFF ALL POWER FROM THE PDU. i 8.9. Verify that all power was removed from the load bank. v Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 • • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 8.10. • Reset the tripped input breaker at the PDU. 8.11, OPEN the feeder breaker to the PDU. ✓ 8.12. Check that the PDU cabinet is not - energized and safe to work in. 8.13. Secure from the load banking. ✓ Section 04 C,onunonIs Comments 8.2 220 KW was applied due to the current limitations of the Toad bank at 208 volts. Conducted an IR scan after two hours and at the end of the four hour load bank test. No hot spots were found. section 05 P,,,, ed.-, Bon,. P. Lee Technologies Group has witnessed or pa ' ipated in this procedure and attests to the accuracy and completeness dills report. Printed Name: iOn .. I Date: Herb Bumett ! / ;' 7 "' 1 03 July 10 Template Rev. 07022010 i (v Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 3 of 3 • VOLTAGE TIMEPLOTS Site: INAP 3B3 Measured from 07/03/2010 12:13:52.0 to 07/03/2010 16:31:07.0 • • 230 220 s 210 0 200 190 230 220 17 210 0 200 190 230 220 m 210 0 200 190 - A B Vrms - BCVrms eiremeser— 1E15,1. - C A Vrms 1 1 1 1 ' ' 1 1 1 I 1 1 1 12:30 13:00 13:30 14:00 14:30 07/03/2010 Saturday C1111.010.0161VION 6.8.1 1 ' ' 1 1 ' 1 1 1 15:00 15:30 16:00 16:30 • WORST CASE SUMMARY Site: INAP 3B3 Measured from 07/03/2010 12:13:52.0 to 07/03/2010 16:31:07.0 Of 0 total VOLTAGE SAGS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE SWELLS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE INTERRUPTIONS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE TRANSIENTS CRITERIA PHASE DATA DATE/TIME • • . WORST CASE SUMMARY WAVEFORMS Site: INAP 3B3 Measured from 07/03/2010 12:13:52.0 to 07/03/2010 16:31:07.0 • • Lowest Magnitude Voltage Sag:No event Highest Magnitude Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Sag:No event Longest Duration Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Most Energy Missing Voltage Sag:No event Most Energy Added Voltage Swell:No event • • • NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Interruption:No event Largest Magnitude Voltage Transients:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE • PHASE A HARMONIC TIMEPLOT Site: INAP 3B3 Measured from 07/03/2010 12:13:52.0 to 07/03/2010 16:31:07.0 VOLTAGE Volts 3.50 3.45 3.40 3.35 3.30 • Volts 3.5 3.0 2.5 2.0 1.5 1.0 0.5 0.0 • 12 30 07/03/2010 Saturday 13 00 1 1 13 30 14 00 I 1 14 30 - A B VTHDRss (ag) 1 1 I 1 15 00 15 30 16 00 16 30 THD H10 H2O MI A- BVHarm H30 Total RMS: 117.72 V DC Level: 0.00 V Fundamental(H1) RMS: 0.00V Total Harmonic Distortion THD: 3.50V(E n: 0.11 V, Odd 3.50V) H40 H50 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 H2O MI A- BVHarm H30 Total RMS: 117.72 V DC Level: 0.00 V Fundamental(H1) RMS: 0.00V Total Harmonic Distortion THD: 3.50V(E n: 0.11 V, Odd 3.50V) H40 H50 • PHASE A HARMONIC TIMEPLOT Site: INAP 3B3 Measured from 07/03/2010 12:13:52.0 to 07/03/2010 16:31:07.0 CURRENT Amps 10.4 10.3 10.2 10.1 10.0 9.9 • • Amps 10.0 7.5 5.0 2.5 0.0 • • 12 30 07103'2010 Saturday 13 00 r r 13 30 14 00 i r 14 30 - A ITHDRss (ag) C i..w wllnOnnV1« 11.0.1 15 00 15 30 16 00 16 30 THD H10 H20 MMI A!Harm H30 Total RMS: 59557 A DC Level: 447A Furxtanlental(H1) RMS: 59558A Total Hanronic Distortion THD: 10.46A (Even: Q72 A, Odd: 1Q44 A) H40 H50 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 H20 MMI A!Harm H30 Total RMS: 59557 A DC Level: 447A Furxtanlental(H1) RMS: 59558A Total Hanronic Distortion THD: 10.46A (Even: Q72 A, Odd: 1Q44 A) H40 H50 PHASE B HARMONIC TIMEPLOT Site: INAP 3B3 Measured from 07/03/2010 12:13:52.0 to 07/03/2010 16:31:07.0 VOLTAGE Voris 3.725 3.700 3.675 3.650 3.625 3.600 3.575 3.550 • Volts 3.5 3.0 - 2.5 - 2.0 1.5 1.0 0.5 0.0 • 12 30 0 7/0 312 01 0 Saturday 13 00 1 1 1330 1400 14 30 - B C VTHDRss (atg) cm.a.nnomvi.. eea 1500 1530 16 00 16 30 - - -- 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 1 1 1 1 1 1 1 1 1 1 1 H2O H30 H40 Total RMS: DC Level: Fundamental(H1) RMS: Total Harmonic Distortion THD: B -C VHarm 11801 v 0.00V 0.00V 3.72 V (Ever. 0.09V, Odd 3.72V) 1 1 1 1 H 50 • PHASE B HARMONIC TIMEPLOT Site: INAP 3B3 Measured from 07/03/2010 12:13:52.0 to 07/03/2010 16:31:07.0 • • CURRENT Amps 10.8 10.7 10.6 10.5 10.4 10.3 • • • 7 • J Amps 10.0 7.5 5.0 2.5 0.0 r r 1 i 1230 1300 07/03/2010 Saturday 13 30 14 00 14 30 - B ITHDRss (avg) C..w..nDaw.. 00.1 15 00 15 30 16 00 16 30 THD H10 H2O Total RMS: DC Level: Furxtarrental(H1) RMS: Total Harmonic Distortion THD: H30 BIHarm 60333 A 3.91 A 60334 A 10.80A (Ben: 0.94 A, Odd: 1076 A) C..`C wnDmViwv 6A.1 H40 H50 • 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I I I I I I I I I I r I i i r i I I I I l t 1 1 1 1 THD H10 H2O Total RMS: DC Level: Furxtarrental(H1) RMS: Total Harmonic Distortion THD: H30 BIHarm 60333 A 3.91 A 60334 A 10.80A (Ben: 0.94 A, Odd: 1076 A) C..`C wnDmViwv 6A.1 H40 H50 • PHASE C HARMONIC TIMEPLOT Site: INAP 3B3 Measured from 07/03/2010 12:13:52.0 to 07/03/2010 16:31:07.0 • • VOLTAGE Volts 3.65 3.60 3.55 3.50 3.45 I 1 1 1230 1300 07/03/2010 Saturday Volts 1 1 1 1 1 1 1 13 30 14 00 14 30 15 00 15 30 - C A VTHDRss (avg) 1 1 1600 1630 THD H10 H2O C -A VHarm H30 Total RMS: 117.E V DC Level: 0.00V Fundarrental(H1) RMS: 0.00V Total Harmonic Distortion THD: 3.66 V (Evai: 0.11 V, Odd 3.66V) H40 H 50 3.5 3.0 - 2.5 2.0 - 1.5 1.0 0.5 0.0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 H2O C -A VHarm H30 Total RMS: 117.E V DC Level: 0.00V Fundarrental(H1) RMS: 0.00V Total Harmonic Distortion THD: 3.66 V (Evai: 0.11 V, Odd 3.66V) H40 H 50 110 PHASE C HARMONIC TIMEPLOT Site: INAP 3B3 Measured from 07/03/2010 12:13:52.0 to 07/03/2010 16:31:07.0 CURRENT Amps 11.6 11.5 11.4 11.3 11.2 • Amps 10.0 7.5 5.0 2.5 0.0 • 12 30 13 00 13 30 14 00 14 30 07/03/2010 Saturday - C ITHDRss 15 00 15 30 16 00 16 30 THD H10 H 20 Total RMS: DC Level: Furldarrental(H1) RMS: Total Harmonic Distortion THD: H30 C (Harm 62851 A 4.16A 62872 A 11.61 A(Even: Q92 A, OW: 11.57A) H40 H50 . 1 t l l 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 H 20 Total RMS: DC Level: Furldarrental(H1) RMS: Total Harmonic Distortion THD: H30 C (Harm 62851 A 4.16A 62872 A 11.61 A(Even: Q92 A, OW: 11.57A) H40 H50 • • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Section 01 Prc�eduii: Infor rein fon Recedure T (e: INT_TUK WA- COMMISSIONING - PDI -PDU Submittal Date: 18 May 10 Procedure Work Date: 03 Jul 10 Procedure Work Time Frame: 0800 -1700 Customer Name: I me m a p Customer's Solomon Froiect Code: Address: Sbeet Address: 3355 South 120u' Place City State: Zn Tukwila WA 98168 Customer POC: CustonnrP+OCName: KathyMcinvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning su • : rvisor. Herbert Burnett Phone Numbers: PtweronMnbar 703- 968 -0300 mobHe 713.423.4335 y= F`?"ar: Equipment PDI PDU CX Procedure 3B3 Affected Area: Data Center Systems Affected: I Load Distribution Equipment Information: Stanutbchser. PDI Equipment Type: PDU Model a: PP13-WS-300-G-641 Serra/ s: 110- 2679 -14 Procedure Overview: This testing will verify the operation of the PDU. Anticipated Results: The PDU will operate as per design. pre,, dufe Requirements: Manufacturer's startup completed on the module. Air conditioning system is functional and capable of supporting the heat Toad generated by the PDU module. Ensure that all test equipment that is required is onsite and operational. Load banks will be hooked up and ready for testing. Conduct a point to point test to verify correct wiring. Boundaries are placed around the PDU. The Power Quality Meter is set up and ready to record. S.r..tIon 03 Detailed Procedure Detailed Procedure: 1. Record start date: 03 Jul 10 Record start time:12:14 2. Document that vendor start up has been performed. V 3. Perform a visual of the PDU to ensure that there is no external damage to the PDU. ✓ 4. Check that the PDU is level and stable with all stabilizers flush to the floor. ✓ 5. Close the feeder breaker to the PDU. 6. Ensure that all PDU load breakers are in the OPEN position. 7. Close the Input main circuit breaker inside the PDU. 8. Press the monitor on button. Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 3 • • • 4,,41 LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 Input V :. Output V , Output ` .Amps_ i '; '.: "+s, '0.. DVM 116 LCD 116 596 A r g ' ` l } Y .. .. ? . �z DVM 117 LCD 117 601 ��s'x ,, " �yk� ;; DVM 117 LCD 117 626 AB " v DVM LCD 476 DVM 202 LCD 202 + 1.1 '�` '� 3 L•v, BC DVM LCD 448 DVM 203 LCD 203 KW 228 CA .. DVM LCD 477 DVM 202 LCD 202 KVA 228 8.1. Apply control power to the Toad bank. 8.2. Apply 100% load to the PDU. KW:220 X 8.3. Start a 4 hour bum test of the PDU. { 8.4. Monitortemperature in the surrounding area. 8.5. PDU BURN SHEET. Time Output Vohs {L.N) Output'AmpswJ 00 t?Oa ° 117 1117 117 596 801 626 211 , - ,,.00 :16; °; A 116 B 117 C 117 A 598 B 603 C 628 212 X00 :30m 116 117 117 598 603 628 213 0045 A 117 B 117 C 117 A 601 B 604 C 626 213 � 1 L f ; A 116 117 117 599 soy 629 214 ZHri A 116 B 117 C 118 A 598 8 607 C 628 214 +, X - �• =31r:_ A . 117 B 117 C 117 A 594 B 604 C 629 214 1.4 t A 117 t C 598 603 628 214 8.8. Shut down all load on the load bank. '/` 8.7. Allow the load bank to run with no load for 5 minutes for cool down purposes. ✓ 8.8. At the PDU, flip up the protective cover over the EPO button and press it in. NOTE: THE INPUT BREAKER SHOULD TRIP AND SHUT OFF ALL POWER FROM THE PDU. 8.9. Verify that all power was removed from the load bank. Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 • • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 8.10. Reset the tripped input breaker at the PDU. 8.11. OPEN the feeder breaker to the PDU. 8.12. Check that the PDU cabinet is not - energized and safe to work in. 8.13. Secure from the Toad banking. SeCtIOn 04 Cpl„ 1,onin Comments applied due to the current limitations of the load bank at 208 volts. was indicating 448 volts. reading was taken from Power Quality Meter due to PDU metering being out of calibration. readings were (A) 816, (B).814 phase and (C) 614. These values are incorrect and the CTs. IR scan after two hours and at the end of the four hour Toad bank test. No hot spots were 8.2 220 KW was 8 The B -C voltage 8.5 The bum in LCD Display current PDI will calibrate Conducted an found. fiecron DS FrOfr:MP :. .W11 It, P. VPIIII ..1i1C111 Lee Technologies Group has witnessed or partici. •ted In this procedure and attests to the accuracy and completeness of this report Rioted /Vane: Signet/ Date: Herb Burnett 7�i� - 03 July 10 Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 3of3 VOLTAGE TIMEPLOTS Site: INAP PDU 3B4 Measured from 07/02/2010 15:45:14.0 to 07/02/2010 19:50:50.0 200 — 150 YI 100 50 0 200 150 100 50 0 200 150 17 100 50 0 — A B Vrms — B C Vrms — C AVrms I I 1 1 1 i 1 1 i 1 1 1 i 1 1 1 1 1 1 1 I 1 i 16:00 16:30 17:00 17:30 18:00 18:30 19:00 19:30 07/02/2010 Friday • WORST CASE SUMMARY Site: INAP PDU 3B4 Measured from 07/02/2010 15:45:14.0 to 07/02/2010 19:50:50.0 Of 0 total VOLTAGE SAGS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE SWELLS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE INTERRUPTIONS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE TRANSIENTS CRITERIA PHASE DATA DATE/TIME • • WORST CASE SUMMARY WAVEFORMS Site: INAP PDU 3B4 Measured from 07/02/2010 15:45:14.0 to 07/02/2010 19:50:50.0 Lowest Magnitude Voltage Sag:No event Highest Magnitude Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Sag:No event Longest Duration Voltage Swell:No event , NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Most Energy Missing Voltage Sag:No event Most Energy Added Voltage Swell:No event • NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Interruption:No event Largest Magnitude Voltage Transients:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE • PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3B4 Measured from 07/02/2010 15:45:14.0 to 07/02/2010 19:50:50.0 VOLTAGE Volts 3.5 3.4 3.3 32 3.1 • Volts 3.5 3.0 2.5 2.0 1.5 1.0 0.5 0.0 40 16 00 16 30 17 00 17 30 18 00 18 30 07/02/2010 Friday -A B VTH DR ss (avg) cm.a wnowi.. nse 19 00 19:30 THD H10 H20 A -B VHarm H30 Total RMS: iiacov DC Level: 0.00 V Fundamental( H1) RMS: O.00V Total Harmonic Distortion THD: 3.53 V ( Ever 0.10V, Odd 3.52 V) H40 H50 1 1 1 1 1 1 1 1 1 1 1 I I I I I I 1 1 1 I I I I 1 1 1 1 1 I I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 H20 A -B VHarm H30 Total RMS: iiacov DC Level: 0.00 V Fundamental( H1) RMS: O.00V Total Harmonic Distortion THD: 3.53 V ( Ever 0.10V, Odd 3.52 V) H40 H50 PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3B4 Measured from 07/02/2010 15:45:14.0 to 07/02/2010 19:50:50.0 CURRENT Amps 1125 11.00 10.75 10.50 10.25 10.00 • Amps 10.0 7.5 5.0 2.5 0.0 1 l 1 THD 16 00 16 30 17 00 17 30 18 00 07/0212010 Friday - AITHDRss(avg) C mos`a.an° wiw 0.e.1 18 30 19 00 19 30 • I 1 1 1 1 1 1 I I I I I I I I I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I I I I I I I I I H10 H20 H30 H40 H50 NM A!Harm Total RMS: 646.36 A DC Level: 3.00A Fur rrental(H1) RMS: 64633A Total Harmonic Distortion THD: 1121 A (Een: 1.05A, Odd: 11.16A) • PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3B4 Measured from 07/02/2010 15:45:14.0 to 07/02/2010 19:50:50.0 VOLTAGE Volts 3.75 3.70 3.65 3.60 3.55 3.50 3.45 3.40 • Volts i 1 1 1 1 1 1 1 16 00 16 30 17 00 17 30 07/02/2010 Friday 18 00 — B C VTHDRss (avg) 1 1 1 1830 1900 19 30 - 3.5 3.0 2.5 2.0 1.5 1.0 0.5 0.0 =... ,_ _ —■ I _ El - M - - in . ■ El I• ■ M 1 I 1 I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD • H10 H2O ® B -C VHarm H30 Total RMS: 11821 V DC Level: 0.00V Fundarrental(H1) RMS: 0.00V Total Harmonic Distortion THD: 3.75V(Eve1:0.10V, Odd 375V) H40 H50 PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3B4 Measured from 07/02/2010 15:45:14.0 to 07/02/2010 19:50:50.0 CURRENT Amps 11.2 11.1 11.0 10.9 10.8 10.7 10.6 10.5 10.4 • • • i Amps J 10.0 7.5 5.0 2.5 0.0 • 16 00 07/02/2010 Fridaj 16 30 17 00 17 30 18 00 - B ITHDRss (arg) c,..e.aeomr.. nea 18 30 19 00 19 30 1 1 1 THD 1 1 1 1 1 1 I I I 1 1 1 H10 I I I I I I 1 1 1 1 1 H20 H30 Total RMS: DC Level: Furxfamental(H1) RMS: Total Hamionic Distortion THD: B'Harm 1 1 1 1 637.33 A 3.51 A 637.10 A 1123 A (Even: 994 A, OW: 11.19A) H40 H50 • PHASE C HARMONIC TIMEPLOT Site: INAP PDU 3B4 Measured from 07/02/2010 15:45:14.0 to 07/02/2010 19:50:50.0 VOLTAGE Volts 3.7 3.6 3.5 3.4 3.3 • Volts 1 1 1 1 1 1 1 1 � 16 00 16 30 17 00 17 30 18 00 18 30 07/02/2010 Friday -C A VTH D Rss (avg) C OA wilhOmVieet 04.1 1 1 l i 19 00 19:30 THD • H10 H20 C -A VHarm H 30 Total RMS: 117.72 V DC Le'el: 0.00 V Fundarrental( H 1) RMS: 0.00 V Total Harmonic D istortion THD: 3.68 V (Bet: 0.10 V, Odd 3.68 V) H40 H50 3.5 3.0 -. 2.5 2.0 1.5 1.0 0.5 0.0 I r 1 1 1 1 1 1 1 1 1 I I I I I I 1 1 1 I I I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I 1 1 1 1 1 1 1 1 THD • H10 H20 C -A VHarm H 30 Total RMS: 117.72 V DC Le'el: 0.00 V Fundarrental( H 1) RMS: 0.00 V Total Harmonic D istortion THD: 3.68 V (Bet: 0.10 V, Odd 3.68 V) H40 H50 • PHASE C HARMONIC TIMEPLOT Site: INAP PDU 3B4 Measured from 07/02/2010 15:45:14.0 to 07/02/2010 19:50:50.0 CURRENT Amps 11.5 11.4 11.3 112 11.0 10.9 10.8 10.7 Amps 10.0 7.5 5.0 2.5 0.0 • 16 00 16 30 17 00 17 30 18 00 07/02/2010 Friday - C ITHDRss (aug) C newC. 110 =Vim 111.1 1830 1900 19.30 THD H10 H20 C [Harm H 30 Total RMS: 62670 A DC Level: 3.40A Funcrrental(H1) RMS: 62648 A Total Harmonic Distortion THD: 11.53 A (Even: Q73 A, Odd: 11.51A) H40 H50 1 1 1 1 1 lllll 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 i 1 r i I l I l 1 1 1 1 1 1 1 1 1 THD H10 H20 C [Harm H 30 Total RMS: 62670 A DC Level: 3.40A Funcrrental(H1) RMS: 62648 A Total Harmonic Distortion THD: 11.53 A (Even: Q73 A, Odd: 11.51A) H40 H50 • • • �11 r LEE TECHNOLOGIES' LEVEL 4 CHECKLIST or..4, '' cecluie Infor m.it on Roomful's ram INT- TUK-WA -COMMISSIONING - PDI -PDU Submittal Date: 18 May 10 Procedure Work Date: 02 Jul 10 Procedure Work Time Frame: 0800 -1700 Customer Name: Intemap Customer's Solomon Project Code: Address: Street Address: 3355 South 120th Place City: State: Zip. Tukwila WA 98168 Customer PDC: Customer POC Name: Kathy Mclnvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning Su• ='visor. Herbert Burnett Phone Numbers: Phone Number. 703- 968 -0300 Mobile: 713.423.4335 Peper. :e"r,71 °` Equipment PDI PDU CX Procedure 3B4 Affected Area: Data Center Systems Affected: Load Distribution Equipment Information: Manufacturer. PDI Equipment Type: PDU Models: PP13 -WS -300 -G -641 Serial it: 110 - 2679 -9 Procedure Overview: This testing will verify the operation of the PDU. Anticipated Results: The PDU will operate as per design. Pre - Procedure Requirements: Manufacturers startup completed on the module. Air conditioning system is functional and capable of supporting the heat Toad generated by the PDU module. Ensure that all test equipment that is required is onsite and operational. Load banks will be hooked up and ready for testing. Conduct a point to point test to verify correct wiring. Boundaries are placed around the PDU. The Power Quality Meter is set up and ready to record. `e :t,°�, cs Detailed Procedure Deviled Procedure: Complete 1. Record start date: 02 Jul 10 Record start time:15:45 ✓ 2. Document that vendor start up has been performed. 3. Perform a visual of the PDU to ensure that there is no external damage to the PDU. •% 4. Check that the PDU is level and stable with all stabilizers flush to the floor. 5. Close the feeder breaker to the PDU. 6. Ensure that all PDU Toad breakers are in the OPEN position. ✓ 7. Close the input main circuit breaker inside the PDU. �r 8. Press the monitor on button. y Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 3 • • • 41, LEE TECHNOLOGIES"' LEVEL 4 CHECKLIST Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 • . ,,'•::.-. Inp .,--..:,--. • , .^:,, ut V : - r,- .:; : 1.".:-‘.:"-: , . , • f = ,,:-. r- ,CO. W:,-;;- i ;•te;-;:t '-'2'. - t'k v.-.;:'.',Nt4 ,1, '• • DVM 116 LCD 117 640 , -*:,1,,, ■,',Z. '''''t! DVM 117 LCD 117 651 , .4 DVM 117 LCD 117 653 r,,-- AB DVM LCD 476 DVM 202 LCD 202 • .:BC-:," LCD 477 DVM 203 LCD 203 KW 228 =--':''''' DVM LCD 477 DVM 202 LCD 202 KVA 228 8.1. Apply control power to the load bank. V 8.2. Apply 100% load to the PDU. KVV:220 X 8.3. Start a 4 hour bum test of the PDU. i 8.4. Monitor temperature in the surrounding area. 8.5. PDU BURN SHEET. ,:, ,,,:, ?7:.'',',, liae,y)1. 7 ." 'ti.:":‘,..., ...,t'..1‘.■;1:; - ',1, ' -:9*P.4.,gf31tl-. . (Y.N) 4' 1..: • ChTA': A'7 -•PR:;—s-- KW it, 1/9:00r0 A 117 B 117 C 117 A 640 B 651 C 653 228 ,:-•--;;A;-',=-",fit, t:Y*3 51 ,3, ----,, A 116 13 117 C 117 A 639 B 652 c 654 227 100:;SUre AWS', A 117 B 117 C 117 A 642 B 654 C 656 229 famov, . .-1'.."0....015-'f' A 116 B 118 C 117 A 640 B 653 C 653 227 z Iii faki.4. A 117 B 118 C 117 A 640 B 653 C 656 226 .,-,:z -ZITIFftit 721P, A 116 B 116 C 117 A 640 B 652 C 655 227 t,ee A 116 B 116 C 117 A 642 B 654 C 657 229 ,1„,__PW 'Ar,3:::-1 re: r4 A 118 B 117 C 118 A 623 B 634 C 636 222 8.6. Shut down all load on the load bank. v 8.7. Allow the load bank to run with no load for 5 minutes for cool down purposes. 8.8. At the PDU, flip up the protective cover over the EPO button and press it in. NOTE: THE INPUT BREAKER SHOULD TRIP AND SHUT OFF ALL POWER FROM THE PDU. 8.9. Verify that all power was removed from the load bank. Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 • • • LEE TECHNOLOGIES" LEVEL_ 4 CHECKLIST 8.10. Reset the tripped input breaker at the PDU. 8.11. OPEN the feeder breaker to the PDU. s' 812. Check that the PDU cabinet is not - energized and safe to work in. 8.13. Secure from the Toad banking. sectio_ oa cc:nronents Comments 8.2 220 KW was applied due to the current limitations of the Toad bank at 208 volts. Conducted an IR scan after two hours and at the end of the four hour load bank test. No hot spots were found. Section 05 Lee Technologies Group has witnessed or participated in this procedure and attests to the accuracy and completeness of this report. Hinted Name: Sig u . 1 Date: Herb Bumett _ , 4 i, /, 02 July 10 Procedure Witness E. Ven(icetion Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 3 • VOLTAGE T1MEPLOTS Site: INAP PDU 3B5 Measured from 07/02/2010 14:29:56.0 to 07/02/2010 18:33:54.0 200 150 0 100 50 0 200 150 100 • 50 0 • • • • • _ w 200 • 150 0 100 50 0 • - A B Vrms - B C Vrms • • - C AVrms 16:00 16:20 16:40 17:00 07/02/2010 Friday Cm.] withOonViorx 17:20 17:40 18:00 18:20 • ACTIVITY PLOTS Site: INAP PDU 3B5 Measured from 07/02/2010 14:29:56.0 to 07/02/2010 18:33:54.00 VOLTAGE SAGS NO EVENTS WERE FOUND IN THIS CATEGORY VOLTAGE SWELLS NO EVENTS WERE FOUND IN THIS CATEGORY • VOLTAGE INTERRUPTIONS NO EVENTS WERE FOUND IN THIS CATEGORY VOLTAGE TRANSIENTS 0 • i 00:00 00 03:0000 06:0000 09:0000 wnomvi«.&SA 12:0000 15:0000 18:0000 21:0000 • WORST CASE SUMMARY Site: INAP PDU 3B5 Measured from 07/02/2010 14:29:56.0 to 07/02/2010 18:33:54.0 Of 0 total VOLTAGE SAGS CRITERIA Of 0 total VOLTAGE CRITERIA Of 0 total VOLTAGE CRITERIA Of 1 total VOLTAGE CRITERIA Largest Magnitude 16:23:50.65 1 • PHASE CATEGORY DATA DATE/TIME SWELLS PHASE CATEGORY DATA DATE/TIME INTERRUPTIONS PHASE CATEGORY DATA DATE/TIME TRANSIENTS PHASE DATA DATEITIME A -B 4.0V, 0.002 Sec. 07/02/2010 • WORST CASE SUMMARY WAVEFORMS Site: INAP PDU 3B5 Measured from 07/02/2010 14:29:56.0 to 07/02/2010 18:33:54.0 • Lowest Magnitude Voltage Sag:No event Highest Magnitude Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Sag:No event Longest Duration Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Most Energy Missing Voltage Sag:No event Most Energy Added Voltage Swell:No event • • • NO WAVEFORM AVAILABLE NO WAVEFORM AVNLABLE Longest Duration Voltage Interruption:No event Largest Magnitude Voltage Transients: Phase A -B NO WAVEFORM AVNLN3LE Volts 300 100 -100 -300 Amps 1 INIMIIIEJIfIMMI7 IiIIMMII iUIfif attall111it,i1 IfIrMIMIMMINNISSF=11 RIaILMill1Li]I• 16:2250.64 16:2250.68 - ABV -Al CmimixthDranView 68.1 - 498.48275 - 498.48300 FL - 498.48325 - ▪ 498.48350 4.0V,0.002 Sec., on 07/02/2010 16:23:50.65 • PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3B5 Measured from 07/02/2010 14:29:56.0 to 07/02/2010 18:33:54.0 VOLTAGE Volts 3.35 3.30 3.25 3.20 3.15 3.10 16 00 07/02/2010 Friday • Volts � I 16 20 16 40 17 00 17 20 17 40 18:00 18 20 - A BVTHDRss (avg) C no`e.nnumvi« ee i 3.5 3.0 2.5 2.0 - 1.5 1.0 0.5 I 0.0 I l l 1 1 1 1 1 1 1 1 I I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 l u l i I i i i 1 I 1 1 1 1 1 1 1 1 THD • H10 H2O NM A- BVHarm H30 Total RMS: 117:11 V DC level: 0.00 V Fundarrental(H1) RMS: O.00V Total Hanronic D istort ion TH D: 3.36 V ( Ever. 0.07 V, Odd 3.36 V) H40 H 50 • PHASE A HARMONIC TIMEPLOT Site: INAP PDU 3B5 Measured from 07/02/2010 14:29:56.0 to 07/02/2010 18:33:54.0 CURRENT Amps 10.75 10.50 10.25 10.00 • Amps 10.0 7.5 — 5.0 2.5 — 0.0 • 16 00 07/02/2010 Friday 16.20 16 40 17 00 17 20 17 40 18:00 18 20 — A ITHDRss (ag) c...a wnoavo.. 611.1 1 1 THD 1 1 1 1 1 1 1 1 1 1 H10 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I I I I I 1 1 1 1 H2O H30 H40 H50 A!Harm Total RMS: 63680 A DC Level: 4.48A Funchrmntal(H1) RMS: 636.81 A Total Harn cnic Distort ion THD: 10.78 A (Een: Q61 A, OW: 1Q 76 A) PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3B5 Measured from 07/02/2010 14:29:56.0 to 07/02/2010 18:33:54.0 VOLTAGE Volts 3.65 3.60 3.55 3.50 3.45 3.40 16 00 07/02/2010 Friday • Volts � I 16 20 16 40 17 00 17 20 17 40 18:00 18 20 - B C VTHDRss (mg) c...a an o=V..* ee.1 THD • H10 H20 B -C VHarm H 30 Total RMS: 117.44 V DC Level: 0.00 V Funcfarrental(H1) RMS: 0.00V Total HanronicDistortionTHD: 3.64V(Ever:0.06V, Odd 3.64 V) H40 H50 3.5 : 3.0 2.5 : 2.0 1.5 1.0 - 0.5 : 0.0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I I 1 1 I 1 1 1 1 1 1 1 1 THD • H10 H20 B -C VHarm H 30 Total RMS: 117.44 V DC Level: 0.00 V Funcfarrental(H1) RMS: 0.00V Total HanronicDistortionTHD: 3.64V(Ever:0.06V, Odd 3.64 V) H40 H50 PHASE B HARMONIC TIMEPLOT Site: INAP PDU 3B5 Measured from 07/02/2010 14:29:56.0 to 07/02/2010 18:33:54.0 CURRENT Amps 10.8 10.7 10.6 10.5 10.4 10.3 10.2 10.1 • Amps 10.0 7.5 5.0 2.5 0.0 • 16 00 07/02/2010 Friday 16 20 16 40 17 00 17 20 17 40 18:00 18 20 - B ITHDRss (avg) CnolgeloilhOmVieve (MA • • • 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I I I I I I I I I THD H10 H20 ® B!Harm H30 Total RMS: 62016 A DC Level: 3.93A Furrttn ntal(H1) RMS: 62Q80 A Total Harmonic Distortion THD: 10.82A (Een: Q45 A OW: 10.81 A) H40 H50 • PHASE C HARMONIC TIMEPLOT Site: INAP PDU 3B5 Measured from 07/02/2010 14:29:56.0 to 07/02/2010 18:33:54.0 VOLTAGE Volts 3.50 3.45 3.40 3.35 3.30 3.25 16 00 07/02/2010 Friday • Volts ' I 16 20 16 40 17 00 17 20 17 40 18:00 18 20 -C AVTHDRss(aeg) cno.a..no„nvi«s-0.1 THD • H10 H2O C- AVHarm H 30 Total RMS: 11 6.98 V DC Level: 0.00 V Furtdarrental(H1) RMS: 0.00V Total Harmonic D istort ion THD: 3.53 V (Even: 0.08 V, Odd 3.53 V) H40 H50 3.5 3.0 2.5 2.0 1.5 1.0 0.5 0.0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD • H10 H2O C- AVHarm H 30 Total RMS: 11 6.98 V DC Level: 0.00 V Furtdarrental(H1) RMS: 0.00V Total Harmonic D istort ion THD: 3.53 V (Even: 0.08 V, Odd 3.53 V) H40 H50 • PHASE C HARMONIC TIMEPLOT Site: INAP PDU 3B5 Measured from 07/02/2010 14:29:56.0 to 07/02/2010 18:33:54.0 CURRENT Amps 11.1 11.0 10.9 10.8 10.7 10.6 10.5 10.4 10.3 • Amps 10.0 7.5 5.0 2.5 0.0 • 16 00 07/02/2010 Friday 16 20 16 40 17 00 17 20 - C ITHDRss (mg) 17 40 18:00 18 20 THD H10 H2O Total RMS: DC Level: Furxbmental(H1) RMS: Total HamonicDistortionTHD: H30 C (Harm 619.86 A 4.19A 61963 A 11.06A (Ben: Q46 A, Odd: 11.05A) H40 H50 1 1 1 1 1 l l l l t 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 H2O Total RMS: DC Level: Furxbmental(H1) RMS: Total HamonicDistortionTHD: H30 C (Harm 619.86 A 4.19A 61963 A 11.06A (Ben: Q46 A, Odd: 11.05A) H40 H50 • • • L� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Se on Rocedn a Title: Procedure INT TUK -WA- COMMISSIONING -PDI -PDU Submittal Date: 18 May 10 y Procedure Work Date: 03 Jul 10 Procedure Work Time Frame: 0800 -1700 Customer Name: Intemap Customer's Solomon Poled Code: Address: Street Address: 3355 South 120th Place City: State: zip: Tukwila WA 98188 Customer POC: Customer POC Name: Kathy Mclnvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning Su • ervlsor. Herbert Burnett Phone Numbers: Phone Ntanber. 703- 968 -0300 Mobile. 713.423.4335 Pager c,ctF °" °^ Equipment PDI PDU CX Procedure 3B5 Affected Area: Data Center Systems Affected: I Load Distribution Equipment Intimation: Menufactrrrr. PDI Epuipment 7Ype: PDU Model t*: PP13 -WS- 300 -G-641 Serial #: 110- 2679 -10 Procedure Overview: This testing will verify the operation of the PDU. Anticipated Results: The PDU will operate as per design. Pre - Procedure Requirements: Manufacturer's startup completed on the module. Air conditioning system is functional and capable of supporting the heat Toad generated by the PDU module. Ensure that all test equipment that is required is onsite and operational. Load banks will be hooked up and ready for testing. Conduct a point to point test to verify correct wiring. Boundaries are placed around the PDU. The Power Quality Meter is set up and ready to record ` ;c..ction -D.3 Detailed Procedure Detailed Procedure: Complete 1. Record start date: 03 Jul 10 Record start time:7 :35 2. Document that vendor start up has been performed. 3. Perform a visual of the PDU to ensure that there is no external damage to the PDU. 4. Check that the PDU is level and stable with all stabilizers flush to the floor. ,/ 5. Close the feeder breaker to the PDU. v 6. Ensure that all PDU load breakers are In the OPEN position. 7. Close the input main circuit breaker inside the PDU. 8. Press the monitor on button. ✓ Template Rev. 07022010 Lee Technologies Group Copyright 2010 Proprietary use pursuant to company policy Page 1 of 3 • • • LEE TECHNOLOGIES' L LEVEL 4 CHECKLIST Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 • Input V _° Output ` Output;' :Amps bad �'Kn� + , to DVM 116 LCD 117 638 B ,�3 DVM 117 LCD 117 844 C s `Yr k ' " DVM 117 LCD 117 645 . � a}' • . ... ,. '• om AB DVM 476 203 LCD �;"� t 4 !( , BC'; DVM LCD 477 DVM 203 LCD 203 KW 226 CA < , ,,; _ _ DVM LCD 477 DVM 202 LCD 203 KVA 226 8.1. Apply control power to the Toad bank. 1 8.2. Apply 100% load to the PDU. KW:220 X 8.3. Start a 4 hour bum test of the PDU. 8.4. Monitor temperature in the surrounding area. ✓ 8.5. PDU BURN SHEET. ✓ Time,' Output Voits (L N) , Output..Amps ,`�••"'r, 00 00 A 117 B 117 C 117 A 638 B 644 C 645 226 .: 00 :15;•: A 116 B 117 C 117 A 639 8 648 C 646 228 iO0 :30 „. 117 B 117 1 C 643 650 6448 226 `�?'. x' •00 45 yts_ .. • A 116 B 117 C 117 A 640 B 649 C 647 227 tea. 1 .,1Hr >< A 116 B 117 C 117 A 641 B 650 C 647 228 .; A 117 B 117 C 117 A 640 B 648 C 647 227 ` t4r , 3HC„t A 117 B 117 C 117 A 642 B 652 C 650 229 4Hr. A 118 B 118 C 118 A 623 B 630 C 638 222 8.6. Shut down all Toad on the Toad bank. / 8.7. Allow the load bank to run with no load for 5 minutes for cool down purposes. ✓ 8.8. At the PDU, flip up the protective cover over the EPO button and press it in. NOTE: THE INPUT BREAKER SHOULD TRIP AND SHUT OFF ALL POWER FROM THE PDU. V 8.9. Verify that all power was removed from the load bank. Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 • • • %lit LEE TECHNOLOGIES" LEVEL 4 CHECKLIST 8.10. Reset the tripped input breaker at the PDU. 8.11. OPEN the feeder breaker to the PDU. 8.12. Check that the PDU cabinet is not - energized and safe to work in. J 8.13. Secure from the Toad banking. Sect on '34 Comments 8.2 220 KW was applied due to the current limitations of the load bank at 208 volts. Conducted an IR scan after two hours and at the end of the four hour load bank test. No hot spots were found. Sc-cricm nJ Prop, .hi,:Rif,,r•sF w. V,•nhrsAinn Lee Technologies Group has witnessed or partic ed in this procedure and attests to the accuracy and completeness report. Printed Name: Ski. , : , Date: of this , AA Herb Burnett /� . '//��%�/ '',_ 03 July 10 Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 3 of 3 • VOLTAGE TIMEPLOTS Site: INAP 3B6 Measured from 07/06/2010 14:19:07.0 to 07/06/2010 18:25:52.0 • • 230 220 • 210 0 200 190 230 220 ▪ 210 O 200 190 230 220 ra 210 O 200 — A B Vrms 1 — 6CVrms 190 —� 14:30 07/06/2010 Tuesday — C A Vrms 1 1 1 I i 1 1 r 1 1 I 1 i I I i 1 15:00 15:30 16:00 16:30 17:00 17:30 18:00 m..e.nino.nr« ae., • WORST CASE SUMMARY Site: INAP 3B6 Measured from 07/06/2010 14:19:07.0 to 07/06/2010 18:25:52.0 Of 0 total VOLTAGE SAGS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE SWELLS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE INTERRUPTIONS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE TRANSIENTS CRITERIA PHASE DATA DATE/TIME • • • • WORST CASE SUMMARY WAVEFORMS Site: INAP 3B6 Measured from 07/06/2010 14:19:07.0 to 07/06/2010 18:25:52.0 Lowest Magnitude Voltage Sag:No event Highest Magnitude Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Sag:No event Longest Duration Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Most Energy Missing Voltage Sag:No event Most Energy Added Voltage Swell:No event • • • NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Interruption:No event Largest Magnitude Voltage Transients:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE • PHASE A HARMONIC TIMEPLOT Site: INAP 3B6 Measured from 07/06/2010 14:19:07.0 to 07/06/2010 18:25:52.0 VOLTAGE Volts 3.75 3.50 3.25 3.00 2.75 • Volts 4.0 � 3.5 3.0 2.5 2.0 15 1.0 — 0.5 0.0 • 1430 1500 07/06/2010 Tuesday 1 1 1 1 i 15 30 16 00 16 30 17 00 — A B VTHDRss (mg) Cr.u..nOmvi «aea 17 30 18 00 18 30 1 1 1 1 1 1 1 THD 1 I I I 1 1 1 1 1 1 1 H10 H2O iM A- BVHarm 1 1 1 1 1 1 H30 Total RMS: 118.07v DC Level: 0.00V Fundar ental(H1) RMS: 0.00V Total Harmonic Distortion TH D: 3.85 V (Ere1: 0.19V, Odd 3.85V) 1 1 1 H40 • PHASE A HARMONIC TIMEPLOT Site: INAP 3B6 Measured from 07/06/2010 14:19:07.0 to 07/06/2010 18:25:52.0 CURRENT Amps 11.0 10.5 10.0 9.5 9.0 8.5 8.0 • 1-- ■ • • Amps 10.0 7.5 5.0 2.5 0.0 • • 14 30 07/06!2010 Tuesday 15 00 15 30 16 00 16 30 - A ITHDRss (am) Cm`! wahDmvlr 68.1 1700 17 30 18 00 18 30 THD H10 H20 Total RMS: DC Level: Furxtarrental(H1) RMS: Total Hanronic Distortion THD: H30 MI AIHarm 59576 A 441A 59575 A 1127A(Even: 1.27 A, Odd: 11.20 A) H40 H50 i 1 i 1 1 1 1 1 1 1 1 I I I I I I I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 t H 1 1 I I I I I 1 1 1 1 THD H10 H20 Total RMS: DC Level: Furxtarrental(H1) RMS: Total Hanronic Distortion THD: H30 MI AIHarm 59576 A 441A 59575 A 1127A(Even: 1.27 A, Odd: 11.20 A) H40 H50 • PHASE B HARMONIC TIMEPLOT Site: INAP 3B6 Measured from 07/06/2010 14:19:07.0 to 07/06/2010 18:25:52.0 VOLTAGE Volts 3.75 3.50 3.25 3.00 • Volts 3.5 3.0 2.5 2.0 1.5 1.0 — 0.5 0.0 • 1 1 1 1430 1500 07/06/2010 Tuesday 15 30 16 00 1 1 1 1 1 16 30 17 00 17 30 18 00 — B C VTHDRss (a■g) Crested MnDmViwv 10.1 18 30 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 H2O 1 1 1 1 1 1 1 1 B -C VHarm 1 I I I I H30 Total RMS: 11821 V DC Level: 0.00V Fundamental(H1) RMS: 0.00V Total Harmonic Distortion THD: 3.78 V (Even: 0.11 V, Odd 3.78V) i 1 11 1 1 H40 • PHASE B HARMONIC TIMEPLOT Site: INAP 3B6 Measured from 07/06/2010 14:19:07.0 to 07/06/2010 18:25:52.0 CURRENT Amps 11.0 10.5 10.0 9.5 9.0 8.5 • Amps 10.0 7.5 5.0 2.5 0.0 • 1430 1500 1530 1600 1630 1700 1730 1800 07/06!2010 Tuesday - B ITHDRss (avg) Cru wnUrvir 60.1 18 30 1) 1 1 1 1 1 THD i I t l l l t l l l 1 1 1 H10 H2O B (Harm 1 1 1 1 1 1 1 1 1 I I I 1 1 1 1 1 1 H30 H40 H50 Total RMS: 597.2 A DC Level: 3.90A Furxtarrental(H1) RMS: 597.2 A Total HarrrnnicDistortionTHD: 11.04A(E■en: 1.77A,Odj: 1(190A) • PHASE C HARMONIC TIMEPLOT Site: INAP 3B6 Measured from 07/06/2010 14:19:07.0 to 07/06/2010 18:25:52.0 VOLTAGE Volts 4.00 3.75 3.50 325 3.00 2.75 • Volts 4.0 3.5 3.0 2.5 2.0 1.5 1.0 0.5 0.0 • 1 1 1430 1500 07/062010 Tuesday 1 1 1 1 1 1 1530 1600 1630 1700 -C A VTHDRss (avg) Cm.] with 0. mvir 0.11.1 1 1 1 1 1730 1800 18 30 THD H10 H20 C -A VHarm H30 Total RMS: 117.62 V DC Level: 0.00V Fundamental(H1) RMS: 0.00V Total Harmonic Distortion THD: 3.98 V (Ever. 0.11 V, Odd 3.98V) H40 H50 . 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 H20 C -A VHarm H30 Total RMS: 117.62 V DC Level: 0.00V Fundamental(H1) RMS: 0.00V Total Harmonic Distortion THD: 3.98 V (Ever. 0.11 V, Odd 3.98V) H40 H50 PHASE C HARMONIC TIMEPLOT Site: INAP 3B6 Measured from 07/06/2010 14:19:07.0 to 07/06/2010 18:25:52.0 CURRENT Amps 11.5 — 11.0 10.5 10.0 9.5 9.0 8.5 • Amps 10.0 7.5 — 5.0 2.5 0.0 • 1 1 1430 1500 07/06/2010 Tuesday 15 30 16 00 16 30 — C ITHDRss (avg) 17 00 1730 1800 18 30 1 1 1 1 1 1 1 1 1 TH D H10 H2O Total RMS: DC Level: Furldanental(H1) RMS: Total HarmonicDistortionTHD: 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 H30 H40 H50 — ClHarm 60&91 A 4.14A 60&6? A 11.43A(Even: 1.75A Odd: 11.29A) • • • 4,1 LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Sect ; { rr P"', cdure Infolmation Procedure me: INT- TUK -WA- COMMISSIONING - PDI -PDU Submittal Date: 18 May 10 Y Procedure Work Date: 06 Jul 10 Procedure work Time Frame: 0800 -1700 Customer Name: Intemap Customer* sots, ttCmo. Address: Address: 3355 South 120th Place City State: Zip: Tukwila WA 98168 CustomerPOC: Customer AOC Name: Kathy Mdnvale Phone Numbers: Cie: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commfssioning Su • ervlsor. Herbert Burnett Phone Numbers: Phone Number 703 -968- 0300 Mobile: 713.423.4335 leper: Section 02 Ploroch :a Overvie.v Equipment PDI PDU CX Procedure 3B6 Affected Area: Data Center I Systems Affected: I Load Distribution Equipment Information: Mamdacturer. PDI Equipment Type: PDU Model tl: - PP13 -WS- 300 -G-641 Serial d: 110-2679-5 Procedure Overview: This testing will verify the operation of the PDU. Anticipated Results: The PDU will operate as per design. Pre-Procedure Requirements: Manufacturer's startup completed on the module. Air conditioning system is functional and capable of supporting the heat Toad generated by the PDU module. Ensure that all test equipment that is required is onsite and operational. Load banks will be hooked up and ready for testing. Conduct a point to point test to verify correct wiring. Boundaries are placed around the PDU. The Power Quality Meter is set up and ready to record s. =too, 7,' p.,,,..Uwe: D. :1 „,1,. Detailed Procedure DetalledRaoedure: Complete 1. Record start date: 06 Jul 10 Record start time:14:16 2. Document that vendor start up has been performed. 3. Perform a visual of the PDU to ensure that there is no external damage to the PDU. 4. Check that the PDU is level and stable with all stabilizers flush to the floor. / 5. Close the feeder breaker to the PDU. v 6. Ensure that all PDU load breakers are in the OPEN position. 7. Close the input main drcuit breaker inside the PDU. 8. Press the monitor on button. Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 3 .a,"411 LEE TECHNOLOGIEr IP Ask 16/ • LEVEL 4 CHECKLIST Template Rev. 07022010 Lee Technologies Group Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 , •.' -i- Input y.;.:; . .. ..-,-,.. =, .,.. . -.-, putput .k., '''' Ailipi ' 608 . • . , . . - ..;:fir DVM 116 LCD 116 • '',':; t•-• ,,... B hi "i",:i --$..1.11 ' —^ DVM 117 LCD 117 605 C -, , .,,,,, k , „01_.4k■ •-. DVM 117 LCD 117 615 .:- A B. DVM LCD 474 DVM 202 LCD 203 ,s15_,. x NI, • :5'...,:; BC '', DVM LCD 474 DVM 203 LCD 202 KW 214 'i • '. CA . DVM LCD 472 DVM 202 LCD 203 KVA 214 8.1. Apply control power to the load bank. 8.2. Apply 100% load to the PDU. KW:225 X 8.3. Start a 4 hour bum test of the PDU. .7 8.4. Monitor temperature in the surrounding area. '\ 8.5. PDU BURN SHEET. -.,:°:•:,,,•'-'e -...,toni.,,,i, '.:7-:•:-., ' . , ‘'' i',", ''''s • • -,outpt0.Y914-.(1i. - .,7,4„ ... ,*,!PiOPu Aint) - ; _..„:?.,'-‘,4 --- • '' • ' ‘'..:.-",:': KW ....---„,.....--t ,( N umuti igsfg':'.5vi, A 116 6 117 C 117 A 608 B 605 C 615 214 ..,•.7iLA-,ckl-,.-:,-; T0t15 ,5" A 116 B 117 C 117 A 608 El 605 C 615 214 ,,.,..,,..z..,,',.' ?-..vv...10k A 116 B 117 C 117 A 608 B 604 C 613 214 ', A 116 B 117 C 117 A 606 B 605 c 613 214 A 116 B 117 C 117 A 608 B 605 C 615 214 4 :: • ■ , i cl. ,..^. * 21;i1rA A 116 B 117 C 117 A 609 B 605 C 616 215 ..,,''''; ,"-S''...-,N ;911:'?•41 ,..-- , A 116 BC 116 117 A 611 B 609 C 620 217 1'04 --1, A 117 B 116 C 117 A 612 B 610 C 619 217 8.8. Shut down all load on the oad bank. / 8.7. Allow the load bank to run with no load for 5 minutes for cool down purposes. 8.8. At the PDU, flip up the protective cover over the EPO button and press it in. NOTE: THE INPUT BREAKER SHOULD TRIP AND SHUT OFF ALL POWER FROM THE PDU. 8.9. Verify that alt power was removed from the load bank. v' Template Rev. 07022010 Lee Technologies Group Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 • • • LEE TECHNOLOGIES° LEVEL 4 CHECKLIST 8.10.. Reset the tripped input breaker at the PDU. 8.11. OPEN the feeder breaker to the PDU. 8.12. Check that the PDU cabinet is not - energized and safe to work in. 8.13. Secure from the Toad banking. `'' Section -0- Comments applied due to the current limitations of the Toad bank at 208 volts. scan after two hours and at the end of the four hour Toad bank test. No hot spots were 8.2 220 KW was Conducted an IR found. section 05 �,c :,wt... wro1, %L V,NIIC. d!I017 Lee Technologies Group has witnessed or participated in this procedure and attests to the accuracy and completeness of this report. Printed Wren.: sic ji » / Darer Herb Burnett ( - , % /, /•.• ! 06Juiy 10 Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 3 of 3 • VOLTAGE TIMEPLOTS Site: INAP 3B7 Measured from 07/07/2010 08:01:16.0 to 07/07/2010 12:21:11.0 • 0 • 200 — 150 100 50 0 200 150 100 50 0 100 75 50 25 0 — A BVrms • — B C Vrms 1 1 1 1 1 1 1 1 08:30 09:00 09:30 07/07/2010 Wednesday — C A Vrms 1 1 1 1 1 1 1 1 1 1 1 1 1 I 10:00 10:30 11:00 11:30 12:00 C'W W1 wino.rvI.. eee • ACTIVITY PLOTS Site: INAP 3B7 Measured from 07/07/2010 08:01:16.0 to 07/07/2010 12:21:11.0 VOLTAGE SAGS NO EVENTS WERE FOUND IN THIS CATEGORY VOLTAGE SWELLS NO EVENTS WERE FOUND IN THIS CATEGORY VOLTAGE INTERRUPTIONS NO EVENTS WERE FOUND IN THIS CATEGORY VOLTAGE TRANSIENTS 10 8 6 4 2 0 • • 00:00 00 03:0000 06:0000 1 1 09:0000 Om W wi1.mViwr GOA 12:0000 15:0000 18:00.00 21:0000 • WORST CASE SUMMARY Site: INAP 3B7 Measured from 07/07/2010 08:01:16.0 to 07/07/2010 12:21:11.0 Of 0 total VOLTAGE SAGS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE SWELLS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE INTERRUPTIONS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 17 total VOLTAGE TRANSIENTS CRITERIA PHASE DATA DATE/TIME Largest Magnitude B -C 21.3V, 0.000 Sec. 07/07/2010 10:09:10.55 A -B 13.8V, 0.000 Sec. 07/07/2010 09:23:55.71 A -B 12.8V, 0.000 Sec. 07/07/2010 09:24:51.55 B -C 8.0V, 0.000 Sec. 07/07/2010 09:45:02.63 • • • WORST CASE SUMMARY WAVEFORMS Site: INAP 3B7 Measured from 07/07/2010 08:01:16.0 to 07/07/2010 12:21:11.0 • • Lowest Magnitude Voltage Sag:No event Highest Magnitude Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Sag:No event Longest Duration Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Most Energy Missing Voltage Sag:No event Most Energy Added Voltage Swell:No event LummtJRor■ Olt LWIWIM UMW= ■PJL*IIaiiLVL I tL':ilU ■ *J� *iu *JIHH�JITif� S }J L }i�itl lf�!J■ n ■ TU t • • NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Interruption:No event Largest Magnitude Voltage Transients: Phase B -C NO WAVEFORM AVAILABLE Volts 300 1 100 -300 11 1111 11111111 10:0910.45 10:0910.55 - BCV -BI CIo Yf W1113MVMW E8.1 Amps 0.00100 ▪ 0.00075 • 0.00050 0.00025 o.00000 21.3V,0.000 Sec., on 07/07/2010 10:09:10.55 • PHASE A HARMONIC TIMEPLOT Site: INAP 3B7 Measured from 07/07/2010 08:01:16.0 to 07/07/2010 12:21:11.0 VOLTAGE Volts 3.4 3.3 32 3.1 3.0 2.9 2.8 2.7 2.6 • 08 00 07/07 2010 Wednesday Volts 3.5 3.0 2.5 2.0 — 1.5 - 1.0 0.5 0.0 • 08 30 r i 09 00 09 30 10 00 10 30 —A 8 VTHDRss (avg) 11 00 11 30 i 12:00 r l i 1 1 1 1 THD i I I I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 H10 H2O H30 H40 Total RMS: DC Level: Furrrental(H1) RMS: Total Har nicDistortionTHD: MN A -B VHarm 117.18 V 0.00V 0.00V 3.38 V (Evan: 0.12V, Odd 3.37V) • PHASE A HARMONIC TIMEPLOT Site: INAP 3B7 Measured from 07/07/2010 08:01:16.0 to 07/07/2010 12:21:11.0 CURRENT Amps 10.0 9.5 9.0 8.5 8.0 • 06 00 08 30 09 00 09 30 10 00 07/07 2010 Wednesday Amps 10.0 7.5 5.0 2.5 0.0 • i 1 1 1 1 10 30 11 00 11 30 12 00 - A ITHDRss (aig) ComeltlwIDmVi•v &ISA THD H10 H2O A I H arm H30 Total RMS: 58685 A DC Level: 4.48 A Fundan>ental(H1) RMS: 58675A Total Hamionic Distortion THD: 9.95A(Eve1: 1.36A Odd 9.86A) Cnoln1.1.110/Inv 6.1 H40 H50 1 1 1 1 1 1 1 1 1 1 1 I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I I I I I I I I I THD H10 H2O A I H arm H30 Total RMS: 58685 A DC Level: 4.48 A Fundan>ental(H1) RMS: 58675A Total Hamionic Distortion THD: 9.95A(Eve1: 1.36A Odd 9.86A) Cnoln1.1.110/Inv 6.1 H40 H50 PHASE B HARMONIC TIMEPLOT Site: INAP 3B7 Measured from 07/07/2010 08:01:16.0 to 07/07/2010 12:21:11.0 VOLTAGE Volts 3.5 3.4 3.3 3.2 3.1 3.0 2.9 2.8 • 1 1 1 1 1 1 1 1 1 08 00 08 30 09 00 09 30 10 00 07/07 2010 Wednesday Volts 1 1 1 1 1 I 1 10 30 11 00 11 30 12:00 - B C VTHDRss (avg) THD • H10 H2O B -C VHarm H30 Total RMS: 10374 V DC Level: 0.00V Fundarrental(H1) RMS: O.00V Total Harmonic Distortion THD: 3.53 V ( Ever. 0.10V, Odd 3.52V) H40 H50 3.5 3.0 2.5 2.0 1.5 1.0 0.5 0.0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD • H10 H2O B -C VHarm H30 Total RMS: 10374 V DC Level: 0.00V Fundarrental(H1) RMS: O.00V Total Harmonic Distortion THD: 3.53 V ( Ever. 0.10V, Odd 3.52V) H40 H50 PHASE B HARMONIC TIMEPLOT Site: INAP 3B7 Measured from 07/07/2010 08:01:16.0 to 07/07/2010 12:21:11.0 CURRENT Amps 9.50 9.25 9.00 8.75 8.50 8.25 8.00 7.75 • 08 00 08 30 09 00 07/07 2010 Wednesday Amps 10.0 7.5 5.0 2.5 0.0 • • 1 1 1 1 1 1 1 09 30 10 00 10 30 11 00 11 30 12:00 - B ITHDRss (avg) 1 1 1 I I THD I I I I I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 H10 H2O B IHarm H30 Total RMS: 571.47 A DC Level: 3.96A Furrrental(H1) RMS: 571.46A Total Harmonic D'stortion TH D: 9.60 A (Eve1: 1.17 A Odd 9.53 A) 11 1 1 1 1 1 1 1 1 1 1 1 H40 H50 • PHASE C HARMONIC TIMEPLOT Site: INAP 3B7 Measured from 07/07/2010 08:01:16.0 to 07/07/2010 12:21:11.0 VOLTAGE Volts 2.1 — 2.0 1.9 1.8 1.7 1.6 • • t ' • • 08 00 07/07/2010 Wednesday Volts 2.0 1.5 1.0 0.5 0.0 • 08 30 1 1 09 00 09 30 10 00 10 30 — C A VTHDRss (mg) c..w.nnoan., ee.1 11 00 11 30 12 00 THD ' 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 H10 1 i 1 H2O Total RMS: DC Level: Furxtar ntal(H1) RMS: Total Harmonic Distortion THD: 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 H30 C-AVHarm 103.03 V 0.00V 0.00V 2.08 V (Ever: 0.07V, Odd 2.08V) H40 PHASE C HARMONIC TIMEPLOT Site: !NAP 3B7 Measured from 07/07/2010 08:01:16.0 to 07/07/2010 12:21:11.0 CURRENT Amps 10.5 10.0 9.5 9.0 8.5 • 1 1 1 1 1 1 1 1 1 08 00 08 30 09 00 09 30 10 00 10 30 07/07/2010 Wednesday Amps 10.0 7.5 5.0 2.5 0.0 • - C ITHDRss (mg) C.., vat no mvi«+ aea I 1 I 1 1 1 11 00 11 30 12:00 THD H10 H2O Total RMS: DC Level: Furlctarrental(H1) RMS: Total Harmonic Distortion THD: H30 �C!Harm 60331 A 4.11 A 59999 A 10.53 A (Even: 1.13A, Ocb: 1Q47 A) H40 H50 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 H2O Total RMS: DC Level: Furlctarrental(H1) RMS: Total Harmonic Distortion THD: H30 �C!Harm 60331 A 4.11 A 59999 A 10.53 A (Even: 1.13A, Ocb: 1Q47 A) H40 H50 • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Sect n 0� P'°t•`' °'r IntC,r;;,:,in■ Procedure ril : INT-TUK-WA-COMMISSIONING - PDI -PDU Submittal Date: 18 May 10 Y Procedure Work Date: 07 Jul 10 . Procedure Work Time Frame: 0800 -1700 Customer Name: - Intemap Cuatmelea Sdrnwn Project Code. Address: Street Address: 3355 South 120th Place C Stele. Zip Tukwila WA 98168 CustomerPOC: Customer POC Name: Kathy Mcinvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning su • revisor: Herbert Burnett Phone Numbers: PhmeNunber. 703- 968-0300 Mobile: 713.423.4335 Pete: Je -- , — °' Equipment PDI PDU CX Procedure 3B7 Affected tree: Data Center I systems Affected: I Load Distribution Equipment Information: Menuracbaer. PDI Equipment Type: PDU Modena; PP13 -WS- 300 -6-641 Serial a: 110- 2679 -1 Procedure Overview: This testing will verify the operation of the PDU. Andclpated Results: The PDU will operate as per design. Pre- Procedure Requirements: Manufacturer's startup completed on the module. Air conditioning system is functional and capable of supporting the heat Toad generated by the PDU module. Ensure that all test equipment that is required is onsite and operational. Load banks will be hooked up and ready for testing. Conduct a point to point test to verify correct wiring. Boundaries are placed around the PDU. The Power Quality Meter is set up and ready to record. :section 03 ..vca:fure Details Detailed Procedure - - Detailed Procedure complete 1. Record start date: 07 Jul 10 Record start time:8:07 2. Document that vendor start up has been performed. 3. Perform a visual of the PDU to ensure that there is no external damage to the PDU. 1 4. Check that the PDU is level and stable with all stabilizers flush to the floor. ,r 5. Close the feeder breaker to the PDU. 1 6. . Ensure that all PDU load breakers are in the OPEN position. ✓ 7. Close the input main circuit breaker inside the PDU. 8. Press the monitor on button. Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 1 of 3 • • • 4:1) LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 ;. Input V 4 Output ,:; Output' . ::Amps - _ : DVM 117 LCD 117 608 ( gli'4. DVM 117 LCD 118 810 -fir C+ a�'tt.n'r , + r Sw;r 3: r : a , DVM 117 LCD 118 823 Y. DVM LCD 476 DVM 203 LCD 204 "RIA x"FPC , �, DVM LCD 477 DVM 203 LCD 204 KW 218 CA ' DVM LCD 475 DVM 203 - LCD 204 KV 218 8.1. Apply control power to the Toad bank. ✓ 8.2. Apply 100% Toad to the PDU. KW:220 X 8.3. Start a 4 hour bum test of the PDU. 8.4. Monitor temperature in the surrounding area. r " 8.5. PDU BURN SHEET. . Time Output Voits (L-N) Output AmpsAY �;KW.: 00'00 117 1118 118 608 6110 C 623 218 W rte` 00 1 _ A' 117 B 117 C 117 A 604 B 606 C 619 215 00 30 117 B 118 118 605 608 620 216 ,: `k 00.45 A 118 B 117 C 117 A 601 B 604 C 615 213 A 116 B 116 C 116 A 600 B 603 C 615 212 { ZHr�, A 117 B 117 C 117 A 604 B 606 C 618 214 41,,�3Hr, `'' A 117 1117 117 604 608 619 215 a h V A 118 B 117 C 117 A 601 B 604 C 615 213 8.6. Shut down all load on the load bank. 8.7. Allow the Toad bank to run with no load for 5 minutes for cool down purposes. 8.8. At the PDU, flip up the protective cover over the EPO button and press it in. NOTE: THE INPUT BREAKER SHOULD TRIP AND SHUT OFF ALL POWER FROM THE PDU. 8.9. Verify that all power was removed from the load bank. Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 • • • L� LEE TK S' HNOLOGfE LEVEL 4 CHECKLIST 8.10. Reset the tripped input breaker at the PDU. 8.11. OPEN the feeder breaker to the PDU. ✓ 8.12. Check that the PDU cabinet is not - energized and safe to work in. 8.13. Secure from the load banking. Section al Comments Comments 8.2 220 KW was applied due to the current limitations of the Toad bank at 208 volts. Conducted an IR scan after two hours and at the end of the four hour load bank test. No hot spots were found. Section O °roc.cduie 4n /dncss £. Ven4,.atinn Lee Technologies Group has witnessed or participated in this procedure and attests to the accuracy and completeness report. of this Ranted Name: ne , -.7 Date: Herb Burnett %' �j %.4� t 07July 10 Template Rev, 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 3 of 3 • VOLTAGE TIMEPLOTS Site: INAP UPS PHASE 3 Measured from 07/08/2010 16:48:30.0 to 07/08/2010 17:51:30.0 • 525 500 — N > • 475 — 450 525 ■ 500 — — en 0 > 475 — 450 1 1 • 1- — A B Vrms L 1 • — B C Vrms — C A Vrms I 16:50 07/08/2010 Thursday 1 17:00 17:10 I 17:20 1 17:30 I 17:40 I 17:50 0 WORST CASE SUMMARY Site: INAP UPS PHASE 3 Measured from 07/08/2010 16:48:30.0 to 07/08/2010 17:51:30.0 Of 0 total VOLTAGE SAGS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE SWELLS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE INTERRUPTIONS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 0 total VOLTAGE TRANSIENTS CRITERIA PHASE DATA DATE/TIME • • . WORST CASE SUMMARY WAVEFORMS Site: INAP UPS PHASE 3 Measured from 07/08/2010 16:48:30.0 to 07/08/2010 17:51:30.0 • • Lowest Magnitude Voltage Sag:No event Highest Magnitude Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Sag:No event Longest Duration Voltage Swell:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Most Energy Missing Voltage Sag:No event Most Energy Added Voltage Swell:No event • • • NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE Longest Duration Voltage Interruption:No event Largest Magnitude Voltage Transients:No event NO WAVEFORM AVAILABLE NO WAVEFORM AVAILABLE • PHASE A HARMONIC TIMEPLOT Site: INAP UPS PHASE 3 Measured from 07/08/2010 16:48:30.0 to 07/08/2010 17:51:30.0 VOLTAGE Volts 12.0 11.5 • • 9.5 9.0 8.5 • • • • • Volts 10.0 7.5 5.0 2.5 0.0 -. • I 16 50 17 00 17 10 17 20 17:30 17 40 17 50 07/08/2010 Thursday - A B VTHDRss (avg) 1 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 1 1 1 1 1 1 1 1 1 1 H2O Total RMS: DC Level: Fundamental(H1) RMS: Total Harmonic Distortion THD: A -B VHarm H30 278.90 V 0.00 V 0.00 11.87 V (Even: 1.04 V, Odd: 11.82 V) 1 1 1 1 H40 H50 • PHASE A HARMONIC TIMEPLOT Site: INAP UPS PHASE 3 Measured from 07/08/2010 16:48:30.0 to 07/08/2010 17:51:30.0 • • CURRENT Amps 57.5 55.0 52.5 50.0 47.5 45.0 • • • • • 16 50 17 00 17 10 17 20 17 30 17 40 17 50 07/08/2010 Thursday Amps 60 50 40 30 20 10- 0„ 1 ( THD — A ITHDRss (avg) Imillinlili1111111 11111®111111111111111111 „r„1 „ H10 H2O H30 H40 Total RMS: DC Level: Fundamental(H1) RMS: Total Harmonic Distortion THD: A IHarm 1951.74 A 4.09 A 1967.70 A 56.88 A (Even: 30.71 A, Odd: 47.87 A) H50 • PHASE B HARMONIC TIMEPLOT Site: INAP UPS PHASE 3 Measured from 07/08/2010 16:48:30.0 to 07/08/2010 17:51:30.0 • • VOLTAGE Volts 12.5 12.0 11.5 0 10.0 9.5 9.0 • • Volts 12.5 10.0 7.5 5.0 2.5 0.0 • 16 50 17 00 17 10 17 20 17 30 17 40 17 50 07/08/2010 Thursday - B C VTHDRss (avg) 1 1 1 1 1 1 1 1 1 1 1 THD H10 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 H30 H2O Total RMS: DC Level: Fundamental(H1) RMS: Total Harmonic Distortion THD: B -C VHarm 1 1 1 1 1 1 1 1 1 1 1 H40 278.54 V 0.00 V 0.00 V 12.39 V (Even: 1.09 V, Odd: 12.34 V) H50 • PHASE B HARMONIC TIMEPLOT Site: INAP UPS PHASE 3 Measured from 07/08/2010 16:48:30.0 to 07/08/2010 17:51:30.0 • • CURRENT Amps 50.0 47.5 45.0 42.5 40.0 • • • • • Amps 50 40 30 20 10 0 • 16 50 17 00 17 10 17 20 17 30 17 40 17 50 07/08/2010 Thursday - B ITHDRss (avg) 111 minium 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 THD H10 H2O H30 H40 H50 Total RMS: DC Level: Fundamental(H1) RMS: Total Harmonic Distortion THD: B IHarm 1807.84 A 4.45 A 1824.14 A 51.21 A (Even: 26.83 A, Odd: 43.61 A) • PHASE C HARMONIC TIMEPLOT Site: INAP UPS PHASE 3 Measured from 07/08/2010 16:48:30.0 to 07/08/2010 17:51:30.0 VOLTAGE Volts 12 11 10 9 • • • • • Volts 12.5 10.0 7.5 5.0 2.5 • 16 50 17 00 17 10 17 20 17 30 17 40 17 50 07/08/2010 Thursday - C A VTHDRss (avg) 0.01. • .1I i IBM 1 I I I I I t t 1 1 1 1 1 1 1 1 1 1 1 1 I I I I I I I I I 1 THD H10 H2O H30 = C -A VHarm Total RMS: DC Level: Fundamental(H1) RMS: Total Harmonic Distortion THD: 1 I 1 277.01 V 0.00 V 0.00 V 12.76 V (Even: 1.04 V, Odd: 12.72 V) H40 H50 • PHASE C HARMONIC TIMEPLOT Site: INAP UPS PHASE 3 Measured from 07/08/2010 16:48:30.0 to 07/08/2010 17:51:30.0 CURRENT Amps J 50.0 47.5 45.0 42.5 40.0 37.5 35.0 • • • • • • • Amps 50 40 30 20 10 1650 1700 1710 1720 1730 1740 1750 07/08/2010 Thursday - C ITHDRss (avg) • 1 1 1 1 1 1 I I I I I I I I I 1 1 1 1 1 1 1 H2O H10 Total RMS: DC Level: Fundamental(H1) RMS: Total Harmonic Distortion THD: - C IHarm 1 1 1 1 1 H30 1 i i 1954.22 A 4.26 A 1972.45 A 50.76 A (Even: 24.22 A, Odd: 44.61 A) 1 1 1 I I I I I H40 1 H50 0 VOLTAGE TIMEPLOTS Site: INAP UPS PHASE 3 DAY 2 Measured from 07/09/2010 07:24:45.0 to 07/09/2010 07:35:15.0 • • 500 400 3 co) 300 8 :21 > 200 100 0 500 400 to 300 TD > 200 100 0 500 400 0 300 - A B Vrms .■1 8 ■■1 - B C Vrms 8 5 > 200 100 0 - C A Vrms I 07:26 07/09/2010 Friday i 07:28 i 07:30 i 07:32 i 07:34 • ACTIVITY PLOTS Site: INAP UPS PHASE 3 DAY 2 Measured from 07/09/2010 07:24:45.0 to 07/09/2010 07:35:15.0 VOLTAGE SAGS 1 0 1 00:00:00 03:00:00 VOLTAGE SWELLS 06:00:00 NO EVENTS WERE FOUND IN THIS CATEGORY • VOLTAGE INTERRUPTIONS 1 0 00:00:00 09:00:00 12:00:00 15:00:00 18:00:00 21:00:00 1 03:00:00 VOLTAGE TRANSIENTS 25 20 15 10 5 0 • 06:00:00 09:00:00 12:00:00 15:00:00 18:00:00 21:00:00 00:00:00 03:00:00 06:00:00 09:00:00 12:00:00 15:00:00 18:00:00 21:00:00 • WORST CASE SUMMARY Site: INAP UPS PHASE 3 DAY 2 Measured from 07/09/2010 07:24:45.0 to 07/09/2010 07:35:15.0 • • Of 1 total VOLTAGE SAGS CRITERIA PHASE CATEGORY DATA DATE/TIME Lowest Magnitude A -B INSTANTANEOUS 6.0V, 0.175 Sec. 07/09/2010 07:31:24.24 Longest Duration A -B INSTANTANEOUS 6.0V, 0.175 Sec. 07/09/2010 07:31:24.24 Most Energy Missing B -C INSTANTANEOUS 6.0V, 0.175 Sec. 07/09/2010 07:31:24.24 Of 0 total VOLTAGE SWELLS CRITERIA PHASE CATEGORY DATA DATE/TIME Of 1 total VOLTAGE INTERRUPTIONS CRITERIA PHASE CATEGORY DATA DATE/TIME Longest Duration A -B SUSTAINED 0.0V, 168.842 Sec. 07/09/2010 07:31:24.42 Of 24 total VOLTAGE TRANSIENTS CRITERIA PHASE DATA DATE/TIME Largest Magnitude C -A 1358.3V, 0.000 Sec. 07/09/2010 07:34:13.25 C -A 1355.5V, 0.002 Sec. 07/09/2010 07:34:13.24 B -C 1294.7V, 0.000 Sec. 07/09/2010 07:31:24.28 A -B 1167.6V, 0.000 Sec. 07/09/2010 07:31:24.27 • WORST CASE SUMMARY WAVEFORMS Site: INAP UPS PHASE 3 DAY 2 Measured from 07/09/2010 07:24:45.0 to 07/09/2010 07:35:15.0 • • Lowest Magnitude Voltage Sag: Phase A -B Highest Magnitude Voltage Swell:No event Instantaneous 6.0V,0.175 Sec., on 07/09/2010 07:31:24.24 Volts 750 250 -250 -750 IENNWI IMMENSE _111.1 11W1f#111iNLWI ___ �fifif11w111 1 111 111111111111 MINIM 1 1. dials �>riaiirarru 1 r U11 ILIlilili1iI'J■I•411i1 u `1�11��1�■1 Amps 500 =0 -500 111111 1111 1111 1111 11 07:31:24.20 07:31 24.30 07:31 24.40 - ABV -Al NO WAVEFORM AVAILABLE Longest Duration Voltage Sag: Phase A -B Longest Duration Voltage Swell:No event Instantaneous 6.0V,0.175 Sec., on 07/09/2010 07:31:24.24 Volts 750 250 -250 -750 Amps W17LA1 ■MIN__ 1111 11 l>•S_Ail 1 ,, i =SI NI I ..1. ,�iruii�tnalilirarn 1 a 41111111/ Dili1J l'EM u `uL'i111M1M11■11∎M 111111 1111 1111 1111 11 07:31:24.20 07:31 24.30 07:31 24.40 - ABV -AI NO WAVEFORM AVAILABLE 500 0 -500 Most Energy Missing Voltage Sag: Phase B -C Most Energy Added Voltage Swell:No event Instantaneous 6.0V,0.175 Sec., on 07/09/2010 07:31:24.24 • • • Volts 750 250 -250 -750 ■ytillumii,imil■1 mom rimmilmo 1JIItiiiuiw'JJMIM*PIPPli i Li ui illi1i1il1iIMIlYMw! 1 I l l ill 1i ri it ■�s! L� �1 ■I LJWiNIMMIN■11•I Amps = 400 = 200 0 -200 -400 11111 1111 1111 1111 11 07:31:24.20 07:31 24.30 07:31 24.40 -BCV -BI NO WAVEFORM AVAILABLE Longest Duration Voltage Interruption: Phase A -B Largest Magnitude Voltage Transients: Phase C -A Sustained 0.0V,168.842 Sec., on 07/09/2010 07:31:24.42 Volts 750 250 -250 -750 Amps 07:31:30 Volts 750 250 -250 -750 07:32:30 07:33:30 - ABV -Al 500 0 -500 1000 Amps li11∎111 .11r•MIKUlli=li■ E M IN ∎iriiiii'■ri>!ii iu i,I=IlltilrMEVEIVilliail 1M�1 pail intilLL'Alla, 1 1 1 1 1 1 = = 1 11 1 1 1 1 11 1 1 1 07:31:30 Volts 750 250 -250 -750 07:32:30 07:33:30 - ABV -Al 500 0 -500 1000 Amps 07:34 13.22 07:34:13.26 07:34 13.30 -CAV -CI 2000 1000 500 0 -500 1358.3V,0.000 Sec., on 07/09/2010 07:34:13.25 li11∎111 .11r•MIKUlli=li■ E M IN ∎iriiiii'■ri>!ii iu i,I=IlltilrMEVEIVilliail 1M�1 pail intilLL'Alla, 1 1 1 1 1 1 07:34 13.22 07:34:13.26 07:34 13.30 -CAV -CI 2000 1000 500 0 -500 1358.3V,0.000 Sec., on 07/09/2010 07:34:13.25 • PHASE A HARMONIC TIMEPLOT Site: INAP UPS PHASE 3 DAY 2 Measured from 07/09/2010 07:24:45.0 to 07/09/2010 07:35:15.0 VOLTAGE Volts 9.77300 9.77275 9.77250 9.77225 9.77200 • Volts 10.0 7.5 5.0 2.5 0.0 • • 07 26 07 28 07 30 07 32 07 34 07/09/2010 Friday - A B VTHDRss (avg) IRA t l i i i i 1 1 1 1 1 THD H10 I I I i I I 1 1 1 1 1 1 1 1 1 I 1 1 1 1 1 H2O Total RMS: DC Level: Fundamental(H1) RMS: Total Harmonic Distortion THD: H30 A -B VHarm 276.62 V 0.00 V 0.00 V 9.81 V (Even: 1.02 V, Odd: 9.76 V) I I H40 H50 • PHASE A HARMONIC TIMEPLOT Site: INAP UPS PHASE 3 DAY 2 Measured from 07/09/2010 07:24:45.0 to 07/09/2010 07:35:15.0 CURRENT Amps 60.14900 60.14875 60.14850 60.14825 • Amps • I ' 07 26 07 28 07:30 07 32 07 34 07/09/2010 Friday — A ITHDRss (avg) 60 50 40 30 20 10 0 1 1 1 THD • 111 1 !!11111!!I!II!!J!!!!!I!!!!!!!!!l!!!!!!!!!l 11111111111 1 1 1 I I I 1 1 1 1 1 1 1 1 1 1 H10 H2O H30 H40 A IHarm Total RMS: DC Level: Fundamental(H1) RMS: Total Harmonic Distortion THD: 2041.23 A 4.19 A 2141.26 A 60.09 A (Even: 33.02 A, Odd: 50.20 A) H50 • PHASE B HARMONIC TIMEPLOT Site: INAP UPS PHASE 3 DAY 2 Measured from 07/09/2010 07:24:45.0 to 07/09/2010 07:35:15.0 VOLTAGE Volts 9.90425 9.90400 9.90375 9.90350 9.90325 • Volts 10.0 7.5 5.0 2.5 0.0 • • 07 26 07/09/2010 Friday 07 28 07 30 - B C VTHDRss (avg) 07 32 07 34 M W .LL..0 ._.u_ . -- IIN 1 I I I I I THD I I I II H10 1 1 1 1 1 1 1 1 1 1 H2O Total RMS: DC Level: Fundamental(H1) RMS: Total Harmonic Distortion THD: B -C VHarm H30 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 H40 H50 277.27 V 0.00 V 0.00 V 9.94 V (Even: 0.98 V, Odd: 9.89 V) • PHASE B HARMONIC TIMEPLOT Site: INAP UPS PHASE 3 DAY 2 Measured from 07/09/2010 07:24:45.0 to 07/09/2010 07:35:15.0 • • CURRENT Amps 53.23525 53.23500 53.23475 53.23450 Amps 50 40 30 20 10 • 07 26 07 28 07:30 07 32 07 34 07/09/2010 Friday — B ITHDRss (avg) 0-. — ) I 1 THD 111 ilmhlmhliMMM111111111111M1111111 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 H10 H2O H30 H40 H50 Total RMS: DC Level: Fundamental(H1) RMS: Total Harmonic Distortion THD: B (Harm 1891.76 A 4.78 A 1985.69 A 53.34 A (Even: 28.65 A, Odd: 44.99 A) • PHASE C HARMONIC TIMEPLOT Site: INAP UPS PHASE 3 DAY 2 Measured from 07/09/2010 07:24:45.0 to 07/09/2010 07:35:15.0 • • VOLTAGE Volts 9.97450 9.97425 9.97400 9.97375 Volts 10.0 7.5 5.0 2.5 0.0 • 07 26 07/09/2010 Friday 07 28 07 30 - C A VTHDRss (avg) 07 32 07 34 THD H10 H2O Total RMS: DC Level: Fundamental(H1) RMS: Total Harmonic Distortion THD: H30 C -A VHarm 276.24 V 0.00 V 0.00 V 10.02 V (Even: 1.04 V, Odd: 9.96 V) H40 H50 i t 1 I l I l l t l 1 1 1 1 1 1 1 1 1 I I I I 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I I I I I I I I I THD H10 H2O Total RMS: DC Level: Fundamental(H1) RMS: Total Harmonic Distortion THD: H30 C -A VHarm 276.24 V 0.00 V 0.00 V 10.02 V (Even: 1.04 V, Odd: 9.96 V) H40 H50 PHASE C HARMONIC TIMEPLOT Site: INAP UPS PHASE 3 DAY 2 Measured from 07/09/2010 07:24:45.0 to 07/09/2010 07:35:15.0 CURRENT Amps 55.73450 55.73425 55.73400 55.73375 • Amps 50 40 30 20 10 • 9 07 26 07 28 07 30 07 32 07 34 07/09/2010 Friday - C ITHDRss (avg) 111 1�111�1111111I11111111111111I1I111111�1111I1�1 1 i I I I I 1 1 1 1 I I I I I I I I I I I I I I I I I I I I I I I I I I I 1 1 1 1 1 1 1 1 1 THD H10 H2O H30 H40 H50 Total RMS: DC Level: Fundamental(H1) RMS: Total Harmonic Distortion THD: C IHarm 2046.53 A 4.57 A 2149.49 A 55.23 A (Even: 27.81 A, Odd: 47.71 A) • 410 *,4) LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Section 01 Checkid rifle: INT-TUK-WA-CX-A-UPS-SYSTEM-COMMISSIONING c°n""''''''''''.9 Ch,cklist Info: matoon Submittal Date: Checklist Work Date: 07/08/2010 Checklist Work Time Frame: Customer Name: Intemap Address: Street Address: 3355 South 120th Place City: Slate: Zip: Tukwila WA 98168 Customer POC: Cusforner POC Name: Kathy Mclnvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 General Contractor c4mPanY Nan'°: BNBuilders Contractor POC: Supervisor Name: Jim Gylling Office: Mobile: 509.499.8194 Lee Technologies Commissioning Su•ervisor Herbert Bumett Phone Numbers: Phone Number 703-968-0300 03-968-0300 Mobile: enter: N/A Section 02 , Equipment Commissioning Checks for UPS l' Commissioning Checklist 0% ervi:-. , • Equipment information: MGE UPS SYSTEMS &POMO TYPe: UPS System. Model it: SSC-, UPSs- Serial #: H10-10034 Checklist Overview' Equipment commissioning checklist. Results: Units and systems will conform to all specified requirements and will operate as designed. Pre-Checldist Requirements: Unit has been started up / initialized and all required pre-commissioning testing has been performed by vendor or other authorized agent. Section 03 Detailed Commissioning Checklist. Commissicning Checklist Dot;i11,-, Complete 1. Record start date: 07/08/2010 Record start time 1620 2. Verify that the entire system is in a non-energized state and that all associated breakers are in the OPEN position. •Nt 3. Verify that all of the associated test equipment is onsite, operational and has a valid certificate of calibration, 4. Verify that all equipment and system labeling is attached and correct. 141 5. Attach the power recorder to an appropriate spot on the output load buss of a system A PDU. NOTE: Do not start the recorder until the unit is energized and ready to test so that the voltage averages are not skewed on the final report 6. Verify that the loadbanks are connected at the PDUs. 7. Verify that the appropriate personnel are present from each sub-contractor or vender. 7.1. Verify that all parties are ready to proceed. Template Rev. 021105 Lee Technologies Group © 2010- Proprietary use pursuant to company policy Page 1 of 13 LEE TECHNOLOGIES" �• t./ l• LEVEL 4 CHECKLIST 8.1. Close the A Static Switch Bypass breaker in the switchgear. 8.2. Open the door on the Static Switch Cabinet and close Switch 1 and Switch 2. 8.3. Verify that the Static Switch Cabinet initializes and that the language is set to English US. 4 8.4. Verify the Static Switch energizes and the Q2S closes. 9.1. Close the 1 UPS breaker in the switchgear. 9.2. Close the 2 UPS breaker in the switchgear. 9.3. Close the 3 UPS breaker in the switchgear. 9.4. Close the 4 UPS breaker in the switchgear 9.5. At UPS module 1 close the Q1 input breaker. 9.6. At UPS module 2 close the Q1 input breaker. 9.7. At UPS module 3 close the Q1 input breaker. _V 9.8. At UPS module 4 close the Q1 input breaker 9.9. Verify on all modules that the logic initializes and that the language is set for English US. 4 9.10. Close the Q5N output breaker for UPS module 1. 4 9.11. Close the Q5N output breaker for UPS module 2. 9.12. Close the Q5N output breaker for UPS module 3. �. 9.13. Close the Q5N output breaker for UPS module 4. 4 9.14. Close the UPS Output Switchgear. 4 9.15. Verify that the only alarms displayed on both UPS modules are Phase out of tolerance, Battery breaker OPEN and Fan Failure. 4 Temp late Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 2 of 13 r� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 9.16. Verify the green "B" LED is lit on UPS module 1. 4 9.17. Close all battery breakers for UPS module 1. 9.18. Verify the green "B" LED is lit on UPS module 2. 9.19. Close all battery breakers for UPS module 2. 4 9.20. Verify the green "B" LED is lit on UPS module 3. 9.21. Close all battery breakers for UPS module 3. 4 9.22. Verify the green "B" LED is lit on UPS module 4. 9.23. Close all battery breakers for UPS module 4. 9.24. Start UPS 1 inverter locally ' 9.25. Verify the system does not transfer out of Static Bypass. 9.26. Start UPS 2 inverter locally. 9.27. Verify the system does not transfer out of Static Bypass. 9.28. Start UPS 3 Inverter locally. 9.29. Verify the system transfer off of Static Bypass 9.30. Start UPS 4 Inverter locally �. • 10.1., During step loading, record any alarms noted with the UPM or PDU's in the comments section of this procedure. Add and remove load to achieve the following'step loads.; 10.1.1. 0% - 25% TIME: 1620 KW: 455 ' J 10.1.2. 25% - 50% TIME: 1625 KW: 911 ' J 10.1.3. 50% - 0% TIME 1630 KW: 0 4 10.1.4. 0% - 75% TIME: 1635. KW: 1366. Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 3 of 13 LEE TECHNOLOGIES" (0 t LEVEL 4 CHECKLIST 10.1.5. 75% -100% TIME: 1640 KW: 1822 4 10.1.6. 100% - 0% TIME 1645 KW: 0 10.1.7.0 % - 100% TIME: 1650 KW: 1822 4 11. Shut off UPS 1 and 3 inverters and verify the system transfers to Static Bypass. 11.1. Start UPS 3 Inverter locally. 11.2. Verify the system transfer off of Static Bypass to inverter 11.3. Start UPS 1 Inverter locally. 11.4. Shut off UPS 2 and 4 inverters and verify the system transfers to static bypass. 11.5. Start UPS 2 Inverter locally. 11.6. Verify the system transfer off of Static Bypass to inverter �. 11.7. Start UPS 4 locally. 11.8. Shut off UPS 1 and 4 inverters and verify the system transfers to static bypass. 11.9. Start UPS 4 Inverter locally. 'J 11.10. Verify the system transfer off of Static Bypass to inverter 4 11.11. Start UPS 1 Inverter locally 11.12. At the SSC control panel, push and hold the transfer to inverter pushbutton. 11.13. Verify all system inverters start. 4 11.14. Verify the system transfers from Static Bypass to inverter. 11.15. Verify the Static Switch indicates the following: 4 11.15.1. Static Switch Available. 4 11.15.2. Static Switch OFF. 4 Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 4 of 13 LEE TECHNOLOGIES" LEVEL 4 CHECKLIST 11.15.3. Inverters ON. 12. Place the Data recorder device in. the MONITORING position at this time • 13.1. Apply 25% load to the system. (455 KW System 113.87 KW per Module). TIME: 1730 13.2. Verify the following voltages on the display and then by a Digital Volt Meter (DVM). 13.2.1. UPS 1 Output Volts: A -B 485 B -C 483 C -A482. 13.2.2. UPS 1 Output Amps: A 140 B 146 C143. 4 13.2.3. UPS 2 Output Volts: A -B 484 B -C 483 C -A481. 13.2.4. UPS 2 Output Amps: A 143 B 144 C139. 13.2.5. UPS 3 Output Volts: A -B 483 B -C 481 C -A481. 13.2.6. UPS 3 Output Amps A 144 B 144 C146. 13.2.7. UPS 4 Output Volts: A -B 482 B -C 481 C -A481. 13.2.8. UPS 4 Output Amps A 142 B 144 C142. . 13.2.9. SSC Output Volts: A -B 476 B -C 479 C -A483. 13.2.10. SSC Amps: A 537 B 538 C536. KW: 443 KVA: 447 13.3. Apply 50% load to the system. (911 KW System 227.75 KW per Module). TIME: 1734 4 13.3.1. UPS 1 Output Volts: A -B 485 B -C 482 C -A482. 4 13.3.2. UPS 1 Output Amps: A 277 B 276 C279. 4 13.3.3. UPS 2 Output Volts: A -B 483 B -C 481 C -A481. 4 13.3.4. UPS 2 Output Amps A 280 B 280 C282. 13.3.5. UPS 3 Output Volts: A -B 483 B -C 481 C -A480. 4 Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 5 of 13 • LEE TECHNOLOGIES LEVEL 4' CHECKLIST 13.3.6. UPS 3 Output Amps: A 277 B 274 C279. 4 13.3.7. UPS 4 Output Volts: A -B 481 B -C 481 C -A480. 13.3.8. UPS 4 Output Amps: A 269 B 268 C269. 13.3.9. SSC Output Volts: A -B 478 B -C 477 C -A480. 13.3.10. SSC Amps: A 1074 B 1076 C1088. KW: 891 KVA: 893 13.4. Apply 75% Toad to the system. (1366.5 KW System 341.6 KW per Module)TIME: 1740 13.4.1. UPS 1 Output Volts: A -B 484 B -C 482 C -A482. 13.4.2. UPS 1 Output Amps: A 415 B 420 C413. 13.4.3. UPS 2 Output Volts: A -B 483 B -C 483 C -A483 13.4.4. UPS 2 Output Amps: A 423 B 421 C417. 13.4.5. UPS 3 Output Volts: A -B 483 B -C 481 C-A480. 13.4.6. UPS 3 Output Amps: A 423 B 427 C429. • 13.4.7. UPS 4 Output Volts: A -B 481 B -C 480 C -A480. 13.4.8. UPS 4 Output Amps: A 423 B 421 C422. 4 13.4.9. SSC Output Volts: A -B 476 B-C 474 C -A478. 13.4.10. SSC Amps: A 1647 B 1679 C1691. KW: 1386 KVA; 1391 13.5. Apply 100% Toad to the system. (1822 KW System 455.5 KW per Module). TIME: 1749 4 13.5.1. UPS 1 Output Volts: A -B 482 B -C 482 C-A481. 13.5.2. UPS 1 Output Amps: A 566 B 575 C569. 4 13.5.3. UPS 2 Output Volts: A -B 483 B -C 482 C -A480. 13.5.4. UPS 2 Output Amps: A 569 B 561 C563. Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 6 of 13 ci LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 7 of 13 13.5.5. UPS 3 Output Volts: A -B 482 B -C 480 C -A480. 13.5.6. UPS 3 Output Amps: A 565 B 575 C575. -4 13.5.7. UPS 4 Output Volts: A -B 480 B -C 480 C -A480. .J 13.5.8. UPS 4 Output Amps: A 563 B 569 C571. 13.5.9. SSC Output Volts: A -B 476 B -C 479 C -A476. 4 13.5.10. SSC Amps: A 2220 B 2247 C2286. KW: 1856 KVA; 1864 13.6. Calculate the UPS system Toad percentage: : (1.73 x Volts x Amps x P.FJ 1000 )/9.99 1 14 1 � ; } 4 u ) `- Y i, .. . i i ! K : } 5'J I t •.h' .. L I � . M17 CL ;j � fV {S i �. t I � = 1 Transfer to Static Bypass (Transient/lnterlock Testing) ,e , r. \. ..,.mot . ..'; rt.,: .. . �' ., . .. ..,a , „!C + {`it ,.. .. .. Y, .. ff +. L + rl h + 1 J � . _.,.. 14.1. Turn all Inverters Off 4 14.2. Verify that the system transfers to static bypass. TIME: 1830 14.3. Verify that the load remained uninterrupted. 'J Y� ib 7', M 1..LL L :.;:...;!7.;,:,,q,,!..-...:1.'t n�4!) A *a ) '4 f ) JJ'{l 11 .. .� i er. X15 ! r « Transfer UPS Static Switch to MainteMnance Bypass , y t- f,i " -•if CV r yfl .Y .•.TYJ./, f f'i Y.: ..f' 1.. a. .V. :)..:��e ( r. • 1'.lr ; +t s .._ _ -lH L .. ...Sf•C,a: 15.1. Place generator 4 and 5 online thru switchgear NOTE 1 15.2. Transfer the system to Static Switch NOTE 1 15.3. Verify SCC is on Static Switch NOTE 1 15.4. At maintenance bypass SB- UPSBP3 NOTE 1 15.4.1. Close breaker feeding Maintenance Bypass switchboard for DB -UPS3A and DB -UPS3B NOTE 1 15.5. Verify ATO switchboard indicates UPS on Bypass and Generators online before operating breakers in both UPS distribution UPS3A and UPS3B NOTE 1 15.5.1. Close Breakers at DB -UPS3A and DB -UPS3B NOTE 1 15.6. Verify PDUs stay online during the entire transfer NOTE 1 4 16 { Sf y/ °, J V. 5 ` • Jr w }.. S i i S -y 4 rn s a t Transfer from Maintenance Bypass to UPS Static Switch r( a y. f- .S iL iVf .w--;. 1'„ 1 . 1 . 4. t )n.., f S:,” C ,. M,)' i. ..'{ 1 ) . � � Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 7 of 13 • LEE TECHNOLOGIES LEVEL 4 CHECKLIST Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 8 of 13 16.1. Verify UPS is on static switch supported by generators NOTE 1 16.2. Verify ATO switchboard indicates UPS on Bypass and Generators online before operating breakers in both UPS distribution UPS3A and UPS38 NOTE 1 16.3. Close the Main normal breakers for DB-UPS3A and DB-UPS3B NOTE 1 16.4. Open the emergency breakers at DB-UPS3A and DB-UPS3B NOTE 1 16.5. Open breaker at SB-UPSBP3 for DB-UPS3A and DB-UPS3B NOTE 1 16.6. Verify PDU stay online during the entire transfer NOTE 1 16.7, At UPS switchgear SB-UPS3 transfer to normal power NOTE 1 16.8. Place generators into cool down NOTE 1 16.9. Shutdown generators NOTE 1 't,:.'... i17; •:.'i: .;.:!;4.4. 1::.'i,,, ';,",:.'",;:14 .g..;;•-.1.. ,,.;::`'. ,',C.L ie::',,t.s..."':V,,•"ii,,N. 'jV.:.:?:,,:.„;,:.;o;.1,":i",-,;,Aff.W,/:.:;:r;;I::t:!iti'.. . ,:05;,-,:;:ii: 1...Fit'tlieh' the $iiet`eia' o din e':. etrinateninnieriiiC ii:Tesiiiig .'")- . 1:$;:1-.,.:4A, f,,:-...:::::::',.,',.Y;J:,i'JJ:..:-:6;.,1-.,F,,,,.tx:11,.E:,:.'.;.:,',4:4.*;!,.:*.i.?,..,,!.-vr' ..''' .1:".4 '..-LF.:;.i. .,.._ 17.1. Push the green Inverter ON all UPS Modules. NOTE 1 17.2. The system will transfer online. TIME: NOTE 1 ,r:F;:-1.-,,•,-.... • ,,,.;,! . r; , ''.i':•.::'',:■-•'.•:,,"*. fi, _ ,.; •■ w f, I,:,. OZ:t1°1;...e:'4A.,i r 1 ) #1 ;IsAy., ,, 4. ,:-. , ',.b."..!.. ..''.*.I.A.'11'!IL, 1.Y.. " ' ;,:.4‘..A.1.1,•17.q.ti;.. ...”7 ...' ''''1..i '",,',7:- •i. ,.$6 .•...V.,s:;,F '..',...,--e,;;;:-2,%;•1:4,•:•..ii:::1-.,...,-,•:4ii;.‘%.:. ,,,., - - — - A Beil-FI:i;;•.' {: ',...7.•!..,y. : ,....,/,•)-, ; -.v.': 61.' ;6,7.... ,;vr,. ; .., 7: iii :' , , ,:.i. ...ilr .., •-• + ',--‘ ,:,.. ,:'`''' ystemBum, wriest 4 111%:_g,;.,,,. -4 ;. . ,,, v. Px.r.:.,.,4,,-,...-7:;...;:,7,745.:-:"4:1;:is:'-''''.:;;,.:';:i.:::,!':ir 4A ., L, --:, . . 18.1. Verify all load banks are turned on supplying maximum load to the UPS System. 4 18.2. RECORD ALL INFORMATION IN THE ATTACHED SPREADSHEET. . 11 18.3. Start the bum in. 4 )., 4 ',.; ' 0. " ' ",:,: .:0", •';',.-,, '., .-0. 7 ?V.t' ''' - ' ' 'I 'W. ''Cr•J +.7t;.'''' ..f 4..:':-.. ''.!:. :•:,;'. ■-! 191 f Module Failtire,TeMing:;;;:i. 4 ', v . , •!'..1 .4., ::4 , , %......C.;.::,;;I:.:':..4.3.-0=.'ze .u...k.lir'.; ,',. ., :4f.r.,;..-::,.. ,., ..... ''.• ■-.7 Il 1., 19.1: Removed the load from the UPS system to test online failure of a module. The only load was the blower on the load bank. 19.2. At UPS 1 induce an inverter fault by tripping an output fuse blown indicator. TIME: 1140 11 • 19.2.1. Verify that the load was assumed by UPS 2, 3, and 4. 1 Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 8 of 13 • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 19.2.2. Clear the fault and verify that the UPS 1 couples to the bus and shares the load. 19.3. At UPS 2 induce an inverter fault by tripping an output fuse blown indicator. TIME: 1145 19.4. Verify that the load was assumed by UPS 1, 3, and 4. 19.5. Clear the fault and verify that the UPS 2 couples to the bus and shares the Toad. .4 19.6. At UPS 3 induce an inverter fault by tripping an output fuse blown indicator. TIME: 1150 19.7. Verify that the load was assumed by UPS 1, 2, and 4. . 19,8. Clear the fault and verify that the UPS 3 couples to the bus and shares the Toad. 19.9. At UPS 4 induce an inverter fault by tripping an output fuse blown indicator. TIME: 1151 y 19.10. Verify that the Toad was assumed by UPS 1, 2, and 3. 4 19.11. Clear the fault and verify that the UPS 4 couples to the bus and shares the load. 19.12: At SWB. OPEN the Bypass Feeder breaker. TIME: 1152 19.12.1. Verify that the system goes into a Transfer Lockout condition. 19.12.2. Verify that the Toad remains uninterrupted. 4 19.12.3. At SWB. CLOSE the Bypass Feeder breaker. TIME: 1153 19.12.4. Verify that the Transfer Lockout alarm clears out. 19.13. Verify that the system is online with no visible faults. 4 L y '" Z � 17-i .. � f ,..t Y ��+ f �' ;Battery Rundown Testing ,, �, r20 ; lip S v. Fy� � e'x 1 7 '�� � ' � r _ � 7� � 4 `NOTE 'All IEEE testing must,have already, been preformred44w,th no;outstanding deflclencies„ 54/ Y I' Hef�nre tills test can be preformed ` ..r. IR scans 4 tieprefonned during ~this test 4t''' F : t �'r n iL f . y! , t,: Lv rr, . ry, �i 20.1. Place 675 KW of load on the system. 4 20.2. Take Modules 2, 3, and 4 offline by turning off the inverters on these modules. 4 20.3. At UPS 1 verify that the display shows 675 KW of load. 20.4: At the SSC verify that the display shows 675 KW of load. Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 9 of 13 LEE TECHNOLOGIES" LEVEL 4 CHECKLIST 20.5. Verify on the recording device that it shows 675 KW of load. 20.6. Initial KW: 696 Initial KVA: 696 20,7. Initial % Load: 103 Power Factor: .9 4 20.8. RECORD ALL VOLTAGE AND AMPERAGE VALUES ON ATTACHED SPREADSHEET. 20.9. Open the Q1 input breaker on UPS 1. TIME: 1212 20.10. Record the total time on battery. Minutes 8 Seconds 13 TIME 1220 4 20.11. The battery bank should transfer at approximately 401 Vdc. Record DC Voltage: 401 4 20.12. Once Static Switch Cabinet transfers to static bypass, close the Q1 input breaker at UPS 1. 4 20.13. Verify that power has been restored to the UPS and that the batteries are charging. y 20.14. Place UPS Modules 1 and 2 online by pressing the green inverter on button on UPS 1 and 2. 20.15. Verify the system transfers to inverter and all the system alarms clear. 20.16. Turn off the UPS 1 inverter. 4 20.17. At UPS 2 verify that the display shows 675 KW of load. 4 20.18. At the SSC verify that the display shows 675 KW of load. 20.19. Verify on the recording device that it shows 675 KW of load. q 20.20. Initial KW: 694 Initial KVA: 694 4 20.21. Initial % Load: 102 Power Factor: .9 lii 20.22. RECORD ALL VOLTAGE AND AMPERAGE VALUES ON ATTACHED SPREADSHEET. 20.23. Open the Q1 input breaker on UPS 2. TIME: 1124 4 20.24. Record the total time on battery. Minutes 8 Seconds 20 TIME: 1232 • 4 20.25. The battery bank should transfer at 401 Vdc. Record DC Voltage: 401 Template Rev. 021105 Lee Technologies Group 2010 Proprietary use pursuant to company policy Page 10 of 13 • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 20.26. Once the Static Switch Cabinet transfers to static bypass, close the Q1 input breaker at UPS 2. 20.27. Verify that power has been restored to the UPS and that the batteries are charging. 20.28: Place UPS Modules 3 and 2 online by pressing the green inverter on button on UPS 3 and 2. 4 20.29. Verify the system transfers to inverter and all the system alarms clear. 4 20.30. Tum off the UPS 2 inverter. 20.31. At UPS 3 verify that the display shows 675 KW of load. 20.32. At the SSC verify that the display shows 675 KW of load. 20.33. Verify on the recording device that it shows 675 KW of load.. 20.34. Initial KW: 680 Initial KVA: 680 20.35. Initial % Load: 101 Power Factor: .9 20.36. RECORD ALL VOLTAGE AND AMPERAGE VALUES ON ATTACHED SPREADSHEET. 20.37. Open the Q1 input breaker on UPS 3. TIME: 1236 20.38. Record the total time on battery. Minutes 8 Seconds 17 TIME: 1244 20.39. The battery bank should transfer at 401 Vdc. Record DC Voltage: 401 20.40. Once the Static Switch Cabinet transfers to static bypass, close the Q1 input breaker at UPS 3. 1J 20.41. Verify that power has been restored to the UPS, and that the batteries are charging. 20.42. At UPS 4 verify that the display shows 675 KW of load. 4 20.43. At the SSC verify that the display shows 675 KW of load. 4 20.44. Verify on the recording device that it shows 675 KW of load. \ 20.45. Initial KW: 680 Initial KVA: 680 20.46. Initial % Load: 101 Power Factor: .9 Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 11 of 13 LEE TECHNOLOGIES" LEVEL 4 CHECKLIST 20.47. RECORD ALL VOLTAGE AND AMPERAGE VALUES ON ATTACHED SPREADSHEET. 4 20.48. Open the 01 input breaker on UPS 4. TIME: 1247 q 20.49. Record the total time on battery. Minutes 8 Seconds 12 TIME: 1255 4 20.50. The battery bank should transfer at 401 Vdc. Record DC Voltage: 401 4 20.51. Once the Static Switch Cabinet transfers to static bypass, close the 01 input breaker at UPS 3. 4 20.52. Verify that power has been restored to the UPS and that the batteries are charging. 4 2053. AT THE POWER RECORDER STOP RECORDING AND SAVE THE DATA. 4 20.54. Reduce the load on:the load bank to 0 kW and allow the load bank to cool for approximately 10 minutes before proceeding to prevent damage to the load bank. ' Secure ,L':;!`.7.i::::' _1: „:: si''...' .;,,:'',::: i3/4 W ZL ' • • , • , SystemA for , load banktearcawn ::: ':-.'z:IV,;,-.: '.- : .1;:::':-:4,--,"::,:,:.',:‘;L• I l'al,V5c.i.'KY1,,If:I.' •:::Ai '.'Z :Z:".,i; 16;-1-r-: .5:4::',1:.,"-:;,. Y - ,,, ,. :.,!._•4 .'''; .6. 21.1. Place the system in static bypass by pressing and hold the grey "Inverter Off” pushbuttons for 3 seconds on all UPS modules: 4 21.2. Verify the Static Switch Cabinet transfer to static bypass. 21.3. OPEN the Q5N breakers for UPS modules 11 21.4. OPEN the QF1 battery breakers for UPS modules 4 21.5. OPEN the 01 input breakers at UPS modules 4 21.6. At the Static Switch Cabinet, open the front door and place the Si and S2 switch in the OFF • position. 11 21.7. At the UPS switchboard OPEN UPS Bypass breaker. 4 21.8. OPEN the input feeder breaker to UPS 1 at SWB 4 21.9. OPEN the input feeder breaker to UPS 2 at SWB q 21.10. OPEN the input feeder breaker to UPS 3 at SWB 4 21.11. OPEN the input feeder breaker to UPS 4 at SWB 4 21.12. With a known good Digital Volt Meter verify that the output and surrounding buss is non- energized and remove all load bank connections. 4 Template Rev. 021105 Lee Technologies Group C12010 Proprietary use pursuant to company policy Page 12 of 13 LEE TECHNOLOGIES" LEVEL 4 CHECKLIST 22. Secure from test. Section 04 Comments Commons Insert any comments applicable to the Checklist: • NOTE 1: The maintenance bypass portion of the test, was not ready at this point in the construction, because it involves SG3. The startup of that gear was not complete at the time level 4 was conducted on the UPS system. The maintenance bypass portion will be tested the first day of the IST. Section 05 Lee Technologies representative has witnessed or • ated In this checklist, has verified equipment is ready per partic Checklist Witness 8 checklist, and attests to the accuracy and completene of this rep V Verification DeM: �•rHed Name: .. > tP✓ef ie '• /7/17ef/- '% V0 Template Rev. 021105 Lee Technologies Group © 2010 Proprietary use pursuant to company policy Page 13 of 13 1 UPS Module #1 Burn In Input Values • Time Vab 1 Vbc Vac la lb lc KwA 1 KwB KwC Total Iva 460 464 . 457 713 727 707 etz09, taiWgz 4 WU lat54.: 2,49: KW 454 460 454 713 724 703 Ett7/74$11; rii10210 .P.,17151105, Ni35f27 rican 455 460 455 713 727 707 i,'.'15717AON -00f42 if WAN re_5_3_7,(en nife. 455 460 455 713 727 700 rea471000342, Ellafpl. Itige),5, two, 455 462 456 713 727 710 N207, At NOW f40705$ tv:539 3_ Sna 456 461 456 713 727 710 git1018,3:, avast% N1eg56 61539,70 MA 458 460 456 717 727 710 gragrat raangjaIgjai. MHO gar44 456 462 456 713 720 710 UMW int$21,0 SRI P7A51 ' _ 53.35 Rglotig 455 459 457 717 724 710 gilMOM Man tkiR7A74 MOO tw-go 456 460 456 713 727 710 slow: Vill3t2'. Wit-gfpf, E53Si33 01416 456 460 456 717 727 713 rila9130 ; 4132 team i.3i :: Oa Ez363 457 462 456 717 724 710 MT,9gr2: at8146. itt1ggi58: MW4_00.. um 455 ' 462 456 713 724 714 '6347re94 :io ii46 Etiololloissaw ifsl', 455 462 456 713 724 714 ikraVA494; neliar40 iffit7i058 w00% ig•Vja 460 465 460 721 720 718 61009111 att$311Sajrifaiffo ittaam 1105S 457 461 458 728 727 718 R10234$ Ci103:182 Ri.:', ltsg §iiMoisz MR 457 462 457 717 724 718 MOW MOW Ii-f1,709,7 grfAilarg Input pf= 0.95 UPS 1 Burn In Output Values ,Time Vab - Vbc . Vac la lb lc Kwa 1 Kwb Kwc. Total actIggh 481 483 - 482 560 580 574 MUM pli:59,02 Mog,4, MIK47022 EOM 481 . 482 482 564 ' 575 578 12110S05: f215.815, /1MM ',l'o,1031.00 Etlf592 14, /615,917,19 KOZO BIATEMY PIO 483 482 482 573 577 580 Iff.:0 483 482 480 564 582 578 EAr5517,9 S16jn'4! NOT% DE474162 WOW, 483 482 481 560 569 578 4.7:.,, 54140 faiWZO F4115131fe SE47.0127h Mr3,2 483 482 483 566 569 567 g#415626, §06717:6; MOM in:69_ grtg-a 483 482 481 564 571 576 Kt5.50: ififitOjia EN5)31$$: legaz $15.01 483 482 482 564 577 578 /42MiZA N51010. lier59.12:4- FO7431.91! 2)O . 484 482 482 568 573 572 gal',57:.,13 OR5.V66:015745.0 E4721$11 PIO 482 483 482 566 577 563 MO/a, 3 M02.0;23,15..53101 147001: Ege, 484 482 481 568 573 574 *;15V210 Viii.5706M746) 01471204 pm 483 , 482 481 562 567 563 Ignan. rA156f21 MI 614M3, fOre#5, ipta 482 • 483 482 562 571 572 051,80 atom at tali% s10:0; Effai 483 483 482 562 580 576 grif$.0, 4la0n2 .1ATA . 50.9, 47,08 ri.41101 483 482 482 566 567 574 q% :50 lft'a *low frayip_I$0, am 483 482 483 564 575 569 moo gm $83fi MVO IM476120 i: weaggo .141-01 483 483 482 564 577 580 MVO 0159i29 . 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E .e ss•e 00. 43s- •0 0. 0 UPS Module #1 Battery Discharge Battery Discharge lime:) VBArr :: J . !Barr.: n- o oo p? 447 -1618 AD OJ 448 -1613 Et oo 448 -1613 UMW 448 -1613 WOO 446 -1620 Et 01,10 446 -1630 24 ' : 444 -1632 Witral 439 -1645 egg 434 -1666 tigt : 429 -1684 pig ow 424 -1702 AIR': Ira 416 • -1739 ittoyfiff 405 -1786 WM MOO VIDA U';9'fil I 04300 , rim ENO Mgr DIME Low battery shutdown warning: 5:30:00 Time transferred to bypass: Total time on battery Auggimoo, UPS load 103% Battery Discharge Test ... ,,,,e, 2,-4: ..?St .;,-.;*/s....:F• .7°;f'i?-4I- 1,?•6 4:'' 2 ,.loie '..:•••:-....- .I.V.i.,1 a-....'• P- ,-..; . ,I, ..,,,,z, rti . fik4 ? ,_ • V ' ....„ , P ( • ;-•11,-i. '5 4 • , ,... , '"7' • 4 • -• ., •,t '5?' . 7 • . tA "AV; „. '% ,,.. ... ■,. —4 1. ; ..,..t 5,...• : ... ' ' -'.,..1 • ,,,4.t _,,,I, " 0.P. .".? , '''' ••:"/Vkil '-‘0. ,4 ' 43,i .,...,- .-- ,,. 1.; . ,-,- - ,„. . • . .1- t , "•,' ' a . ' ' '" . 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Eipy%4: 153$0; T 303 454 461 458 701 735 702 j 4Y;5,6,W88'85: 7,67$5 53F10' WT51 456 462 456 701 732 702 :475133 8549 1 5f58. 15309. Egte 456 460 457 701 732 702 11511}71a 3 1 1 559_fi: If0X5W91 trig 454 459 457 702 732 702 Ma4 81j 'r '8, ;08, =OM 96 97535105 grao, 455 460 457 705 732 702 Nina r, Ism Emma X5359; 2",45 455 460 458 705 732 698 I' 1594` in A09; ` * 70,04: ` 1; 5.35 97 riggi 453 459 456 701 732 698 itfi(g 55104.12BINZ08. ¶ 5$3T03: 3. U 457 463 457 705 728 706 420174, lialfga Stai76f98 Eg.5381:5.5. 13.d 459 463 457 705 728 702 110009 151 $ 7n. RitIM 5.38. 32 alati 457 461 457 705 728 702 ga 6.71 s etsioa, 01706 536 Z5; MN 456 461 458 705 732 706 G +, ,1:76i3 ' 1,885(39 moss 5'3816 Input pf= 0.95 UPS MODULE #2 BURN IN Output Values Time , Vab Vbc. • Vac la lb lc 1 Kwa Kwb Kwc Total KOTM 481 483 ' 481 569 552 570 P030143. ntozo. PEMST .a465353 tXXE 482 482 481 571 563 563 a57,1034 liergflit Istaim gam ifflitt 482 482 480 569 - 565 570 IMOS, an135:7% '7."-t" 1.0 36108T% EOM . 481 482 - 481 573 557 565 NM% NE15:31.5, avow 0,714-600-2 Atiga 481 482 481 569 559 570 61156640 *I1540O, 310565.14 i467.ri1J52 igstol 483 482 480 566 570 559 g511026 .:,,11571,0 %:410joye riaeoso NE:ai 482 481 481 560 579 575 laWei: WOW% 190158ma J47a155 45 483 482 - 481 577 565 561 !VIL6g1J29 "14%66: 10002-3 wato MAI 483 482 4 . 481 ' 577 565 561 teg115929 Sr4;13566 1$7023 . 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C u1•� s gh7 Na ` ". 1 .,, ,jC SL 7 k� J� l i ? t }••''t ,+5”' `A f y, 14 =:et. �'t mss r L,, O' , ,dyTru Jix �`to }., 4iif i t x: F�taf y .ti"3 e ^i �1 iy 4', lit°'{r. j �{ t•+-k:t t t �IAI i d°t''� FymJb',� r'�•w r7 Y,4i'4 >.' `HX -2'c t • T1C } F• t th�i ' .' �'t�7{{ .l�{. fib' r( + / `{4 0t j(� lr� {( �'S +r i Sr 1 4r T.ce rPs il'F: a5 xL� '4 4 { yJ� fir 6, d f J q T 4' -1 ., s" , �t r sP�i.`'r p3 4.- 5� < ` " i dD' s ip�lA' 'oily T+v$ i" +' � A�y t i .� .1y � 4, t - `, .fie t "i-''t f e$, un ✓ .4, 't 4 Y ti , y ''..°3'l :td4�A {,•» ay !r °C {xi Yi �.�' p �1 0. i-Q < w d ;sal e6Jey3sla Mee 110 • • UPS Module #3 Burn In Input Values Time • Vab Vbc Vac la lb lc KwA KwB 1 KwC 1 Total lo:pqy 460 459 458 712 725 693 spl:910: gmez52 oxix40.9 30.3012:5 01J5 458 462 456 712 725 697 )... in, fff1)38•011§itz433 , ;,,i., Ergs 456 460 457 716 729 693 lega91.68 Kt803 Rom gm.vit FrAm 458 458 457 716 725 693 gotzgtoo a fano is Rug agooeo siltio 458 459 457 716 725 693 ierEtZ980: MO% gegoz tg5009:. glite . 455 459 455 712 725 689 mug 82 1795 Vid02115 Mil 454 461 457 712 725 693 WIlasstl. Wital:32 FitIVOS lit5302 Spagt 455 459 457 716 725 693 011/8:00 M1021:52 ligZ,Vit M15.3479:11 Ma 452 459 457 716 725 693 'Moot aim% I MOM IMAM' 457 459 457 712 725 689 NUMMI 8452: mg-zzo gc 5369 , go 457 459 457 712 725 693 Oft1700 CO AZ% itat7730 tit 5009 pm 457 459 457 712 725 693 StgaT4E i;‘,111052 WAWA tram19: in-ga 456 ' 458 455 712 725 693 ma108 •4t. Apso yettole Ersvm Dm . 460 462 458 716 725 697 Nit1�805&1ial1 W0000 t05005. warsol 459 462 458 720 729 697 fal81.,T26 N1503 MOW ef.5X108 VA-51 458 460 457 716 725 697 avOlo M829-2 M77074 al5071,49, OM . 458 461 458 716 725 697 MOM ','n , . OW ElfZ61419, tg5,38F27s; Input pf= 0.95 UPS MODULE #3 Burn In Output pf= 0.99 • Output Values Time1 Vab Vbc Vac la lb lc Kwa 1 Kwb 1 Kwc 1 Total 483 481 480 560 575 573 f tigg60, rm5_870.8 Noma M469T89 10,Df : 482 482 480 563 566 578 :4,- MOM Wag IR 15213Y,515 #00.93.62 DT-3-6 482 481 480 561 583 573 ff,',101102 NOM MOTO sti,570 Ilifeat .•:4-: gam Bf4Z20 Foe 482 481 480 . 561 583 573 §Eli,64M: 4001 . - 482 482 480 574 579 573 ,W589I4 6101715, lialOnti MA916111 111,0$130, OfP318.5.:, FiltrAV-2T ittrif506 M858 le4.70-6., ef451j72 1,457141...0 Kira 482 480 480 569 570 578 PM ' 482 480 480 571 579 578 Kra - 483 481 479 567 570 575 itlt*6154 58ft-a LW.501413. :,,v, Ffsiiii . ' 482 481 481 567 570 575 kW-$.00 gfa§.6.17,016.116408 WNW, AT:51 , 482 481 481 567 575 584 6156124 iims_048, ago grow olle 483 480 479 563 570 578 tgolta rat6ys8(mi58!gi5 . gd4co6 two 482 481 481 574 575 573 aitaeg Magfai: 01053. ';;; - gagi.5 faca 482 • 481 481 563 568 566 15t1 i5616 ,01 Am mem DOI 482 482 480 563 568 571 egrOYN, kg5115.6:70: Unfie6 Eitg8TI5 an . 481 481 480 556 570 580 ge.$.20 ggiogt 059:140; Nem ga51 481 482 480 558 570 582 4211,534i Mao. lis1591.08 Emma We 483 481 480 565 575 578 We',1051:913' ral$810,8: R150150 4W021$21,. ' Output pf= 0.99 • Total kW vs Time ''• {,�,�; ^• % k Ifi tt 4� ,7! %" { T Wry M1 '` �,s, ` ( •!xl AI R1 m" +. S "� ra CI F - .p•R; o f r s 5 Pi Y' .. V pfd r 44 1 f K% i ,*� I ± + � Ftti� Ili ` ,r lk•+eq'.:.r yff �y'y•tiW �' I.' A, 'r X f; :x.1t. t .T • ": "'_i C .s l'' a .i ,,, •� 3 S 4 '< ^' P .+ =3' "s.",S''n "k n y _..�'re ,7n Y•'4¢• r �7i 41 i y,4 i �)� t 'V Vy#.1'tr 5'f t[�x5 �,qta t { A. :, �` Pte• � n Mu∎» tk`" h `!p IW' .. �r •( t4. , 'K+. r t`t I � d :F ty.. �+� .. 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Ai 115038 51615085 , s'4i 0)1110 ktfie : 481 481 479 567 578 573 tt'i 10,15.9" gfit52YA EfA015:4 itt4,501 Ea* . 481 481 479 565 578 571 Migo' 0 pr, 5240 liI6�3i Mirt5 _0, 481 480 480 574 578 571 VA1Silf,434102471 gaol ammo Rpm , 480 480 480 567 577 571 maw SPAL6091 11)075.01313. ;zi':'461F0,11 SP13/6 -. 480 481 480 563 569 566 - MO itigic6f1t1N egA910;11 ,: 0505. EA* . 481 480 480 565 580 573 mo6 ! vmono mom gwoniii era*. 480 480 481 563 576 566 KO .81421 itiWICA 974-3.9132 Vr49'E10. WO - 480 481 480 561 562 566 moo, .e'-'15182z ial4.010 Kam 6-2:15J 481 481 480 561 562 566 btracto aritazt rair9TIV303.50 Sgla 481 480 480 567 573 579 ,`,€-..124.91.59 , 4:41:50i85' N152,44. 04440 r,4:51 480 480 480 574 576 577 .4''.116,0101CUMS iffiffigli fiE45.111 lar4wga We 480 • 481 480 574 576 577 tf14102. 1$1616 , gmvoill 01-E 480 481 479 564 578 575 a1r4By49; go.5249 wit5jyg towa ggs2 480 481 479 567 576 577 41M8 1i9.01 .i.f.71Y,51f.59 .. 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E - ; .!4 p i�e M . - y "y' • 1)C •a k-•t .K ro, 'S j s t 1' 7'f .�!,"(' f q. el �'YY �S4 G ` fJig \ ` ,ft ,> fi,� r R�3:S "^ 'm'3 r fr !, .yt ' i a ,�� e' ' -•. i�l., 0 O O vO 0 0 0 O 0 0 S 0 lue.uno / e6e ;BOA r r cV • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST' Section Ot c°n-,,Iris■ 01 ',..1 Procedure Title: INAP- TUK- WA -EPO- COMMISSIONING Submittal Date: Procedure Work Date: Procedure Work Time Frame: Test Number (If Applicable): : Engineers Specification Number(s): Customer Name: Intemap Customers Solomon ProOct Code: Address: Shed Address': ; 3355 South 120th Place Cibr Stet: Zip: She Cods: Tukwila WA 98167 CustomerPOC: Customer POC Name: .. KathyMclnvale Phone Numbers: 404.302.9753 404.547.8915 General Contractor: r CompsnyNarrro BNBuilders Engineer POC: Engineer Name: Jim G Ilin Gylling O/Roe: Moai6 509.499.8194 Lee Technologies Commissioning supervisor. Herbert Burnett Paul Jahnke Phone Numbers. Rem Plumber 703- 968 4300 Mobile: :.. - 713.423.4335 703.906.3422 Peper' Section 02 t.3,,,,,ts,,ct,,,1., EPO Operation Affected Area: Data Center Systems Affected. Critical Infrastructure Procedure Overview: Procedure will demonstrate the operation of EPO in all modes and during fault conditions. AntiRescipated ults: EPO will operate as designed. Pre - Procedure Requirements: Environmental system is fully operational. Section 0 Commissioning Details 0.0,,u, i5 ,,,,,,, , -) D: -tai s OemlkdProcsdtae Complete EPO ARMED MODE 1. Place the test mode selector switch , in the ARMED position 1.1. Verify a white incandescent light on the ECP lights indicating the selector switch is in the ARMED position 1.2. Press EPO button #1 in the datacenter on the west wall 1.2.1. Red incandescent will light on the ECP shall illuminate indicating an E.P.O button has been activated 1.2.2. Verify BMS indicates an E.P.O activation and the zone 1.2.3. Verify at DB- MECH3A the feeder breaker for the RTUs and CRACS for phase 3 trip Lee Technologies Services, Inc.. © Copyright 2010 Proprietary use Pursuant to Company Policy, ICE TECHNOLOGIES" • L LEVEL 4 CHECKLIST 1.2.3.1. RTU #3-1 breaker trip 1.2.4. RTU #3-2 breaker trip 1.2.5. RTU #3-3 breaker trip 1.2.6. RTU #3-4 breaker trip 1.2.7. RTU #3-5 breaker trip 1.2.8. CRAC #3-1 breaker trip 1.2.10. CRAC #3-3 breaker trip 1.2.11. CRAC #3-4 breaker trip 1.3. Verify at DB- MECH3B the feeder breaker for the RTUs and CRACS for phase 3 trip 1.3.1. RTU #3-1 breaker trip 1.3.2. RTU #3-2 breaker trip 1.3.3. RTU #3-3 breaker trip.: 1.3.4. RTU #3-4 breaker trip 1.3.5. RTU #3-5 breaker trip 1.3.6. CRAC #3 -1 breaker trip 1.3.7::.. CRAC #3 -2 breaker trip 1.3.8. CRAC #3-3 breaker trip 1.3.9. CRAC #3-4 breaker trip 1.4. At DB -UPS3A verify breaker for PDU 3A1 -3A7 trip Lee Technologies Services, Inc. © Copyright 2010 Proprietary use Pursuant to Company Policy LEE TECHNOLOGIES" • tit" LEVEL 4 CHECKLIST 1.4.2. PDU breaker trip 3A2 1.4.3. PDU breaker trip 3A3 1.4.4. PDU breaker trip 3A4 1.4.5. PDU breaker trip 3A5 1.4.6. PDU breaker trip 3A6 1.4.7. PDU breaker trip 3A7 1.5. At DB -UPS3B verify breaker for PDU 3B1 -3B7 trip 1.5.1. PDU breaker trip 3B1 1.5.2. PDU breaker trip 3B2 1.5.3. PDU breaker trip 3B3 1.5.4. PDU breaker trip 3B4 1.5.5. PDU breaker trip 3B5 1.5.6. PDU breaker trip 3B6 1.5.7. PDU breaker trip 3B7 1.5.7.1. Verify PDUs are down due to a, loss of power 1.5.7.2. Verify RTUs and UPS room CRACs are down due to a loss of power 1.5.8: Verify BMS indicates an E.P.O activation and the zone 1.6. Tum key to release EPO button #1 in the datacenter on the west wall 1.6.1. Press the reset button for the E.P. O activation 1.6.2. Verify the red incandescent light clears 1.6.3. ' Verify BMS indicates EPO has been released, Lee Technologies Services, Inc:. © Copyright 2010 Proprietary use Pursuant to Company Policy. Page 3 of 25 • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 1.6.4. Close feeder breaker for RTUs and CRACs units at DB- MECH3A and DB- MECH3B 1.6.4.1. Close RTU #3-1 breaker 1.6.4.2. Close RTU #3-2 breaker 1.6.4.3. Close RTU #3-3 breaker 1.6.4.4. Close RTU #3-4 breaker 1.6.4.6. Close CRAC #3 -1 breaker 1.6.4.7. Close CRAC #3 -2 breaker 1.6.4.8. Close CRAG #3-3 breaker 1.6.4.9. Close CRAC #3-4 breaker 1.6.4.10. RTUs will restart after individual time delays have expired 1.6.4.11. CRACs will restart after individual time delays have expired 1.7:. Place UPS on static switch Close feeder breakers for PDUs at DB -UPS3A 1.7.1.1. Close PDU breaker for 3A1 1.7.1.2. Close PDU breaker for 3A2 1.7.1.3. Close PDU breaker for 3A3, 1.7.1.4. Close PDU breaker for 3A4 1.7.1.5. Close PDU breaker for 3A5 1.7.1.6. Close PDU breaker for 3A6 1.7.1.7. Close PDU breaker for 3A7. Lee Technologies Services, Inc.: © Copyright 2010 Proprietary use Pursuant to Company Policy • L- LEE TECHNOLOGIES` LEVEL 4 CHECKLIST 1.7.2. Close feeder breakers for PDUs at DB -UPS3B 1.7.2.1. Close PDU breaker for 3B1 1.7.2.2. Close PDU breaker for 3B2 1.7.2.3. Close PDU breaker for 3B3 1.7.2.4. Close PDU breaker for 3B4 1.7.2.5. Close PDU breaker for 3B5 1.7.2.6. Close PDU breaker for 3B6. 1.7.2.7. Close PDU breaker for 3B7 1.7.3. Verify PDUs are online 1.8. Place UPS on inverter 1.9. Press EPO button #2 on the west wall by DB -UPS3A 1.9.1. Red incandescent , will light on the ECP shall illuminate indicating an E.P.0 button has been activated 1.9.2. Verify BMS indicates an E.P.0 activation and the zone 1.9.3. Verify at DB- MECH3A the feeder breaker for the RTUs and CRACS for phase 3 trip 1.9.3.1. RTU #3-1 breaker trip 1.9.4. RTU #3-2 breaker trip 1.9.5. RTU #3-3 breaker trip. 1.9.6. RTU #3-4 breaker trip 1.9.7. RTU #3-5 breaker trip. 1.9.8. CRAC #3-1 breaker trip 1.9.9. CRAC #3 -2 breaker trip Lee Technologies Services, Inc: Copyright 2010 Proprietary use Pursuant to Company Policy Page 5 of 25 • LEE TECHNOLOGIES"` LEVEL 4 CHECKLIST 1.9.10. CRAG #3-3 breaker trip 1.9.11. CRAG #3-4 breaker trip 1.10. Verify at DB- MECH3B the feeder breaker for the RTUs and CRACS for phase 3 trip 1.10.1. RTU #3-1 breaker trip 1.10.2. RTU #3 -2 breaker trip 1.10.3. RTU #3-3 breaker trip 1.10.4. RTU #3-4 breaker trip 1.10.5. RTU #3-5 breaker trip 1.10.6. CRAC #3-1 breaker trip 1.10.7. CRAC #3-2 breaker trip 1.10.8. CRAC #3-3 breaker trip 1.10.9. CRAC #3-4 breaker trip 1.11. At DB -UPS3A verify breaker for PDU 3A1 -3A7 trip 1.11.1. PDU breaker trip 3A1 1.11.2. PDU breaker trip 3A2 1. 11.3. PDU breaker trip 3A3 1.11.4. PDU breaker trip 3A4 PDU breaker trip 3A5 1.11.6. PDU breaker trip 3A6 1.11.7. PDU breaker trip 3A7 1.12: At DB -UPS3B verify breaker for PDU 3B1 -3B7 trip Lee Technologies Services, Inc.. © Copyright 2010 Proprietary use Pursuant to Company Policy Page 6 of 25. • %Ilk LEE TECHNOLOGIES" LEVEL 4 CHECKLIST 1.12.1. PDU breaker trip 3B1 1.12.2. PDU breaker trip 3B2 1.12.3. PDU breaker trip 3B3 1.12.4. PDU breaker trip 3B4 1.12.5. PDU breaker trip 3B5 1.12.6. PDU breaker trip 3B6 1.12.7. PDU breaker trip 3B7 1.12.7.1. Verify PDUs are down due to a Toss of power 1:12.7.2. Verify RTUs and UPS room CRACs are down due to a loss of power 1.12.8. Verify BMS indicates an E.P.O activation and the zone 1.13. Tum key to release EPO button #2 in the datacenter on the west wall by DB -UPS3A 1.13.1. Press the reset button for the E.P. 0 activation 1.13.2. Verify the red incandescent light clears 1.13.3. Verify BMS indicates EPO has been released 1.13.4. Close feeder breaker for RTUs and CRACs units at DB- MECH3A and DB- MECH3B 1.13.4.1. Close RTU #3-1 breaker 1.13.4.2. Close RTU #3-2 breaker 1.13.4.3. Close RTU #3-3 breaker 1.13.4.4. Close RTU #3-4 breaker 1.13.4.5. Close RTU #3-5 breaker 1.13.4.6. Close CRAC #3 -1 breaker`. Lee Technologies Services, Inc. © Copyright 2010 Proprietary use Pursuant to Company Policy. Page 7 of 25 e/41)LEE TECHNOLOGIES" • 46' LEVEL 4 CHECKLIST 1.13.4.7. Close CRAC #3 -2 breaker 1.13.4.8. Close CRAC #3-3 breaker 1.13.4.9. Close CRAC #3-4 breaker. 1.13.4.10. RTUs will restart after individual time delays have expired 1.13.4.11.. CRACs will restart after individual time delays have expired 1.14. Place UPS on static switch 1.14.1. Close feeder breakers for PDUs at DB -UPS3A 1.14.1.1. Close PDU breaker for 3A1 1.14.1.2. Close PDU breaker for 3A2 1.14.1.3. Close PDU breaker for 3A3 1.14.1.4. Close PDU breaker for 3A4 . . 1.14.1.5. Close PDU breaker for 3A5 1.14.1.6. Close PDU breaker for 3A6 1.14.1.7. Close PDU breaker for 3A7 1.14.2. Close feeder breakers for PDUs at DB -UPS3B 1.14.2.1. Close PDU breaker for 3B1 1.14.2.2. Close. PDU breaker for 3B2 1.14.2.3. Close PDU breaker for 3B3 1.14.2.4. Close PDU breaker for 3B4 1.14.2.5. Close PDU breaker for 3B5 1.14.2.6. Close PDU breaker for 3B6' Lee Technologies Services, Inc. © Copyright 2010 Proprietary use Pursuant to Company Policy. ,. Page 8 of 25. L LEE TECHNOLOGIES' • LEVEL 4 CHECKLIST 1.14.2.7. Close PDU breaker for 3B7 1.14.3. Verify PDUs are online 1.15. Place UPS on inverter 1.16. Press EPO button #3 on the east wall;, by DB- UPS3B' 1.16.1. Red incandescent will light on the ECP shall illuminate indicating an E.P.O button has been activated 1.16.2. Verify BMS indicates an E.P.O activation and the zone 1.16.3. Verify at DB- MECH3A the feeder breaker for the RTUs and CRACS for phase 3 trip 1.16.3.1. RTU #3 -1 breaker trip 1.16.3.2. RTU #3-2 breaker trip 1.16.3.3. RTU #3-3 breaker trip 1.16.3.5. RTU #3-5 breaker trip 1.16.3.6. CRAC #3-1 breaker trip 1.16.3.7. CRAC #3 -2 breaker trip 1.16.3.8. CRAG #3-3 breaker trip 1.16.3.9. CRAC #3-1 breaker trip 1.17. Verify at DB- MECH3B the feeder breaker for the RTUs and CRACS for phase 3 trip 1.17.1. RTU #3-1 breaker trip 1.17.2. RTU #3-2 breaker trip 1.17.3. RTU #3-3 breaker trip 1.17.4. RTU #3-4 breaker trip Lee Technologies Services, Inc. ©,,Copyright 2010 Proprietary use Pursuant to Company Policy Page 9 of 25 lk LEE TECHNOLOGIES" LEVEL 4 CHECKLIST 1.17.5. RTU #3-5 breaker trip 1.17.6. CRAG #3-1 breaker trip 1.17.7. CRAC #3-2 breaker trip 1.17.8. CRAG #3-3 breaker trip 1.17.9. CRAC #3-4 breaker trip 1.18. At DB -UPS3A verify breaker for PDU 3A1 -3A7 trip 1.18.1. PDU breaker trip 3A1 1.18.2. PDU breaker trip 3A2 1.18.3. PDU breaker trip 3A3 1.18.4. PDU breaker trip 3A4 1.18.5.; -PDU breaker trip 3A5 1.18.6. PDU breaker trip 3A6 1.18.7. PDU breaker trip 3A7 1.19. At DB -UPS3B verify breaker for PDU 3B1 -3B7 trip 1.19.1. PDU breaker trip 3B1 1.19.2. PDU breaker trip 3B2 1.19.3. PDU breaker trip 3B3 1.19.4. PDU breaker trip 3B4 1.19.5: PDU breaker trip 3B5 1.19.6. PDU breaker trip 3B6 1.19.7. PDU breaker trip 3B7. Lee Technologies Services, Inc. © Copyright 2010 Proprietary use Pursuant to Company Policy LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 1.19.7.1. Verify PDUs are down due to a loss of power 1.19.7.2_ Verify RTUs and UPS room CRACs are down due to a loss of power 1.19.8. Verify BMS indicates an E.P.O activation and the zone 1.20. Tum key to release EPO button #3 on the east wall by DB -UPS3B 1.20.1. Press the reset button for the E.P. 0 activation 1.20.2. Verify the red incandescent light clears 1.20.3. Verify BMS indicates EPO has been released 1.20.4. Close feeder breaker for RTUs and CRACs units at DB- MECH3A and DB- MECH3B 1.20.4.1. Close RTU #3 -1 breaker 1.20.4.2. Close RTU #3-2 breaker 1.20.4.3. Close RTU #3-3 breaker 1.20.4.4. Close RTU #3-4 breaker 1.20.4.5. Close RTU #3-5 breaker 1.20.4.6. Close CRAC #3 -1 breaker' 1.20.4.7. Close CRAC #3 -2 breaker 1.20.4.9. Close CRAC #3-4 breaker 1.20.4.10. RTUs will restart after individual time delays have expired 1.20.4.11. CRACs will restart after individual time delays have expired 1.21. Place UPS on static switch 1.21.1. Close feeder breakers for PDUs at DB -UPS3A Lee Technologies Services; Inc. © Copyright 2010 Proprietary use Pursuant to Company Policy • 4,,,) LEE TECHNOLOGIES' %•/ LEVEL 4 CHECKLIST 1.21.1.1. Close PDU breaker for 3A1 1.21.1.2. Close PDU breaker for 3A2 1.21.1.3. Close PDU breaker for 3A3 1.21.1.4.. Close PDU breaker for 3A4, 1.21.1.5: Close PDU breaker for 3A5 1.21.1.6. Close PDU breaker for 3A6:: 1.21.1.7. Close PDU breaker for 3A7 1.21.2. Close feeder breakers for. PDUs at DB -UPS3B 1.21.2.1. Close PDU breaker for 3B1 1.21.2.2. Close PDU breaker for 3B2 1.21.2.3. Close PDU breaker for 3B3 1.21.2.4. Close PDU breaker for 3B4 1.21.2.5. Close PDU breaker for 3B5 1.21.2.6.. Close PDU breaker for 3B6 1.21.2.7. Close PDU breaker for 3B7 1.21.3. Verify PDUs are online 1.22. Place UPS on inverter 1.23. Press EPO button #4 on the datacenter east wall 1.23.1. Red incandescent will light on the ECP shall illuminate indicating an E.P.O button has been activated 1.23.2. Verify BMS indicates an E.P.O activation and the zone. 1.23.3. Verify at DB- MECH3A the feeder breaker for the RTUs and. CRACS for phase 3 trip Lee Technologies Services, Inc.. © Copyright 2010 Proprietary use Pursuant to Company Policy Page 12 of 25 LEE TECHNOLOGIES* LEVEL 4 CHECKLIST 1.23.3.1. RTU #3-1 breaker trip 1.23.3.2. RTU #3 -2 breaker trip 1.23.3.3. RTU #3-3 breaker trip 1.23.3.4. RTU #3-4 breaker trip . 1.23.3.5. RTU #3-5 breaker trip 1.23.3.6. CRAC #3-1 breaker trip CRAC #3 -2 breaker trip 1.23.3.8. CRAG #3-3 breaker trip 1.23.3.9. CRAC #3-4 breaker trip 1.24. Verify at DB- MECH3B the feeder breaker for the RTUs and CRACS for phase 3 trip 1.24.1. RTU #3-1 breaker trip 1.24.2. RTU #3-2 breaker trip 1.24.3. RTU #3-3 breaker trip 1.24.4. RTU #3-4 breaker trip. 1.24.5. RTU #3 -5 breaker trip 1.24.6. CRAC #3-1 breaker trip 1.24.7. CRAC #3-2 breaker trip, 1.24.8. CRAG #3-3 breaker trip 1.24.9. CRAC #3-4 breaker trip 1.25. At DB -UPS3A verify breaker for PDU 3A1 -3A7 trip 1.25.1. PDU breaker trip 3A1 Lee Technologies Services, Inc. Page 13 of 25. © Copyright 2010 Proprietary use Pursuant to Company Policy L LEE TECHNOLOGIES" */). LEVEL 4 CHECKLIST 1.25.2. PDU breaker trip 3A2 1.25.3.. PDU breaker trip 3A3 1.25.4. PDU breaker trip 3A4 1.25.5. PDU breaker trip 3A5 1.25.6. PDU breaker trip 3A6 1.25.7. PDU breaker trip 3A7 1.26. At DB -UPS3B verify breaker for PDU 3B1-3B7 trip 1.26.1. PDU breaker trip 3B1. 1.26.2. PDU breaker trip 3B2 1.26.3. PDU breaker trip 3B3 1.26.4. PDU breaker trip 3B4 1.26.5. PDU breaker trip 3B5 1.26.6. PDU breaker trip 3B6 1.26.7. PDU breaker trip 3B7 1.26.7.1. Verify PDUs are down due to a loss of power 1.26.7.2. Verify RTUs and, UPS room CRACs are down due to a loss of power 1.26.8. Verify BMS indicates an E.P.O activation and the zone. 1.27.: Tum key to release EPO button #4 on the datacenter east wall 1.27.1. Press the reset button for the E.P. 0 activation 1.27.2. Verify the red incandescent Tight clears 1.27.3. Verify BMS indicates EPO has been released Lee Technologies Services, Inc. © Copyright 2010 Proprietary use Pursuant to Company Policy • LLEE TECHNOLOGIES' LEVEL 4 CHECKLIST 1.27.4. Close feeder breaker for RTUs and CRACs units at DB- MECH3A and DB- MECH3B 1.27.4.1. Close RTU #3-1 breaker 1.27.4.2. Close RTU #3-2 breaker 1.27.4.3. Close RTU #3-3 breaker 1.27.4.4. Close RTU #3-4 breaker 1.27.4.5. Close RTU #3-5 breaker 1.27.4.6. Close CRAC #3 -1 breaker 1.27.4.7. Close CRAC #3-2 breaker 1.27.4.8. Close CRAC #3-3 breaker 1.27.4.9. Close CRAC #3-4 breaker 1.27.4.10. RTUs will restart after individual time delays have expired 1.27.4.11. CRACs will restart after individual time delays have expired 1.28. Place UPS on static switch 1.28.1. Close feeder breakers for PDUs at DB -UPS3A 1.28.1.1. Close PDU breaker for 3A1 1.28.1.2. 1.28.1.3. Close PDU breaker for 3A3 . . 1.28.1.4. Close PDU breaker for 3A4 1.28.1.5. Close PDU breaker for 3A5 1.28.1.6. Close PDU breaker for 3A6 1.28.1.7.: Close PDU breaker for 3A7 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use Pursuant to Company Policy LEE TECHNOLOGIES` is/ LEVEL 4 CHECKLIST 1.28.2. Close feeder breakers for PDUs at DB -UPS3B 1.28.2.1. Close PDU breaker for 3B1 1.28.2.2: Close PDU breaker for 3B2 1.28.2.3. Close PDU breaker for 3B3 1.28.2.4. Close PDU breaker for 3B4 1.28.2.5. Close PDU breaker for 3B5 1.28.2.7. Close PDU breaker for 3B7 1.28.3. Verify PDUs are online 1.29. Place UPS on inverter Place the ECP selector switch in the MAINTENANCE MODE 2.1. A green incandescent light on the ECP shall illuminate when the ECP is placed in MAINTENANCE MODE 22 Press EPO button #1 in the datacenter on the west wall 2.2.1. Verify red incandescent Light remains off 2.2.2. Verify BMS does not have an EPO alarm 2.2.3. Verify the TEST MODE light remains off 2.2.4. Verify the feeder breakers for the RTUs, CRACs and PDUs remain online 2.2.5. At DB- MECH3A 2.2.5.1. RTU #3 -1 close Lee Technologies Services, Inc. © Copyright 2010 Proprietary use Pursuant to Company Policy LEE TECHNOLOGIES° �L LEVEL 4 CHECKLIST 2.2.5.5. RTU #3 -5 close 2.2.5.6. CRAC #3-1 close 2.2.5.7. CRAC #3-2 close 2.2.5.9. CRAC #3-4 close 2.2.6.1. RTU #3 -1 close 2.2.6.2. RTU #3 -2 close 2.2.6.3. RTU #3-3 close 2.2.6.5. RTU #3-5 close 2.2.6.6. CRAC #3-1 close 2.2.6.7. CRAC #3-2 close 2.2.6.8. CRAC #3-3 close 2.2.6.9. CRAC #3-4 close 2.17. At DB -UPS3A 2.2.7.1. PDU 3A1 close 2.2.7.2. PDU 3A2 close 2.2.7.3. PDU 3A3 close Lee Technologies Services, Inc. © Copyright 2010 Proprietary use Pursuant to Company Policy Page 17of25 LEE TECHNOLOGIES' ID 161 LEVEL 4 CHECKLIST 2.2.7.5. PDU 3A5 close 2.2.7.6. PDU 3A6 close 2.2.7.7: PDU 3A7 close 2.2.8. At DB-UPS3B 2.2.8.1. PDU 3B1 close 2.2.8.2. PDU 3B2 close 2.2.8.3: PDU 3B3 close 2.2.8.4. PDU 3B4 close 2.2.8.5. PDU 3B5 close 2.2.8.6: PDU 3B6 close 2.2.8.7: PDU 3B7 close 2.3. Turn key to release EPO button #1 in the datacenter on the west wall 2.4. Press EPO button #2 on the west wall by DB- MECH3A 2.4.1. Verify red incandescent light remains off 2.4.2.. Verify BMS does not have an EPO alarm 2.4.3. Verify the TEST MODE Tight remains off 2.4.4. Verify the feeder breakers for the RTUs, CRACs and. PDUs remain online 2.4.5. At DB- MECH3A 2.4.5.2. RTU #3-2 close 2.4.5.3. RTU #3 -3 close Page 18 of 25 Lee Technologies Services; Inc. © Copyright 2010 Proprietary use Pursuant to Company Policy LEE TECHNOLOGIES" • 11.1 LEVEL 4 CHECKLIST 2.4.5.4. RTU #3-4 close 2.4.5.6. CRAG #3-1 close 2.4.5.7. CRAC #3-2 close 2.4.5.8. CRAC #3-3 close 2.4.5.9. CRAG #3-4 close 2.4.6.1. RTU #3 -1 close 2.4.6.3. RTU #3-3 close 2.4.6.4. RTU #3-4 close. 2.4.6.5. RTU #3-5 close 2.4.6.6. CRAG #3 -1 close 2.4.6.8. CRAC #3-3 close 2.4.6.9. CRAC #3-4 close 2.4.7. At DB -UPS3A 2.4.7.3. PDU 3A3 close 2.4.7.4. PDU 3A4 close Lee Technologies Services, Inc: © Copyright 2010 Proprietary use Pursuant to Company Policy Page 19 of 25 L LEE TECHNOLOGIES` • LEVEL 4 CHECKLIST 2.4.7.5. PDU 3A5 close 2.4.7.6. PDU 3A6 close 2.4.7.7. PDU 3A7 close 2.4.8. At DB -UPS3B 2.4.8.1. PDU 3B1 close. 2.4.8.2. PDU 3B2 close 2.4.8.3. PDU 3B3 close 2.4.8.4. PDU 3B4 close 2.4.8.5. PDU 3B5 close 2.4.8.6. PDU 3B6 close 2.4.8.7. PDU 3B7 close 2.5: Turn key to release EPO button #2 on the west wall by DB- MECH3A 2.6. Press EPO button #3 on the east wall by DB- MECH3A 2.6.1.. Verify red incandescent light remains off Verify BMS does not have an EPO alarm 2.6.3. Verify the TEST MODE Tight remains off 2.6.4. Verify the feeder breakers for the RTUs, CRACs and PDUs remain online 2.6.5.1. RTU #3-1 close 2.6.5.3. RTU #3 -3 close Lee Technologies Services, Inc. Copyright 2010,: Proprietary use Pursuant to Company Policy LEE TECHNOLOGIES' • tl LEVEL 4 CHECKLIST 2.6.5.5. RTU #3-5 close 2.6.5.6. CRAC #3-1 close 2.6.5.7. CRAC #3 -2 close 2.6.5.8. CRAC #3 -3 close 2.6.5.9. CRAC #3-4 close 2.6.6. At DB- MECH3B 2.6.6.2. RTU #3 -2 dose 2.6.6.3. RTU #3-3 dose 2.6.6.5. RTU #3-5 close 2.6.6.6. CRAC #3 -1 close 2.6.6.7. CRAC #3-2 dose 2.6.6.8. CRAC #3=3 close 2.6.6.9. CRAC #3-4 close 2.6.7:. At DB -UPS3A 2.6.7.1. PDU 3A1 close 2.6.7.2. PDU 3A2 close 2.6.7.4. PDU 3A4 close Lee Technologies Services, Inc. © Copyright 2010 Proprietary use Pursuant to Company Policy Page 21 of 25 LEE TECHNOLOGIES' • ti LEVEL 4 CHECKLIST 2.6.7.5. PDU 3A5 close 2.6.7.6. PDU 3A6 close 2.6.7.7. PDU 3A7 close 2.6.8. At DB -UPS3B 2.6.8.1. PDU 3B1 close 2.6.8.2. PDU 3B2 close 2.6.8.3: PDU 3B3 close.. 2.6.8.4. PDU 3B4 close 2.6.8.5. PDU 3B5 close: 2.6.8.6. PDU 3B6 close 2.6.8.7. PDU 3B7 close 27. Turn key to release EPO button #3 on the east wall by DB- MECH3B 2.8. Press EPO button #4 in the datacenter on the east wall 2.8.1. Verify red incandescent light remains off 2.8.2. Verify.BMS does not have an EPO alarm. 2.8.1 Verify the TEST MODE light remains off 2.8.4. Verify the feeder breakers for the RTUs, CRACs and PDUs remain online 2.8.5. At DB- MECH3A; 2.8.5.3. RTU #3 -3 close Lee Technologies Services, Inc. © Copyright 2010 Proprietary use Pursuant to Company Policy Page 22 of 25 • .11, LEE TECHNOLOGIES" %./ LEVEL 4 CHECKLIST 2.8.5.4. RTU #3-4 close 2.8.5.6. CRAC #3-1 close 2.8.5.7. CRAG #3-2 close 2.8.5.8. CRAC #3-3 close 2.8.5.9. CRAC #3-4 close 2.8.6.1. RTU #3-1 close 2.8.6.3. RTU #3-3 dose 2.8.6.4. RTU #3-4 dose 2.8.6.5. RTU #3-5 close 2.8.6.6. CRAC #3-1 close 2.8.6.7. CRAC #3 -2 close 2.8.6.8. CRAC #3-3 close 2.8.6.9. CRAG #3-4 close 2.8.7. At DB -UPS3A 2.8.7.1. PDU 3A1 close 2.8.7.2. PDU 3A2 close 2.8.7.3. PDU 3A3 close Lee Technologies Services, Inc. © Copyright 2010 Proprietary use Pursuant to Company Policy L LEE TECHNOLOGIES` • LEVEL 4 CHECKLIST 2.8.7.6. PDU 3A6 close 2.8.7.7. PDU 3A7 close 2.8.8. At DB -UPS3B 2.8.9. At DB -UPS3B 2.8.9.1. PDU 3B1 close' 2.8.9.2. PDU 3B2 close 2.8.9.3. PDU 3B3 close 2.8.9.4. PDU 3B4 close 2.8.9.5. PDU 3B5 close 2.8.9.6. PDU 3B6 close 2.8.9.7. PDU 3B7 close 2.9. Tum key to release EPO button #4 in the datacenter on the east wall 3. Place selector switch into the ARMED MODE !. 3.1. Verify a white incandescent light on the ECP lights indicating the selector switch is in the ARMED position Section 04 Comments Insert any comments applicable to the checklist: Note: Drawing on E500 has been changed by RFI 260000 -02. There needs to be an As -Built regarding the EPO System. SecI on 05 Ch.--; it,: 0. V2r '•C 3pra, Lee Technologies Services, Inc. Representative has witnessed or participated in this procedure and attests to the accuracy and completeness of this report Pefd Nang: 1 Lueilerfle 4 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use Pursuant to Company Policy` 7/07/ae�d Page 24 of 25 LEE TECHNOLOGIES' .1;. • • LEVEL 4 CHECKLIST Section Dt Checklist Title: Commissioning INAP- TUK-WA -FIRE SYSTEMS -CX Checklist Inforrna; ion Submittal Date: Checklist Work Date: 7/12/2010 Checklist Work Time Frame: 0700 -1800 Customer Name: Intemap Address Street At/dives: 3355 South 120th Place City: State: Zip: Tukwila WA 98169 CustornerPOC: Customer POC Name: Kathy Mcinvale Phone Numbers: Office :: 404.302.9753 Mobile: 404.547.8915 General Contractor. Company Name: BNBuilders COntractorPOC. Supervisor Name: Jim Gylling Office: Mobile: 509.499.8194 Lee Technologies Commissloning Supervisor: Herbert Burnett Phone Numbers: Phase Number. 703.968.0300 Mobile: 713.423.4335 Page! Section 02 Comnussioning Checklist Overvie!vi Equipment Commissioning Checks for Fire Systems Equipment Information: Manufacturer: Various Equipment Type: Fire Systems Model II: Various Serial q: Various Checklist OveMew: This testing will verify the operation of the fire alarm / protection system Anticipated Results: Equipment will operate within design Pre - Checklist Requirements: Unit has been started up / initialized and all required pre- commissioning testing has been performed by vendor or other authorized agent. Section 03 Detailed Commissioning Checklist Cnmmissinnmg Checklist Details Detaded.Checldist ( Complete t: » Resul»> Alarm on CP15 Activate. Solenoid Sound Horns Close FSD's • • Send Alarm • • Send Trouble Send pes >: Su rn orll S5e • gn PR2-1-16 FCPS 12a -' Control Relay • 153a . Alerton Alerton - ;': . Alerton <. Building panel ' • CP =2 for, alarm SCM 15-1- 104 ' CP -2 SOM 2-1 -28 R2M 15 -1-80. R2M 15 -1-81 ... R2M 15 -1-82 , R2M 1-83 CP -15 Supervisory OK Template Rev. 072606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page1 of 17 LEE TECHNOLOGIES' • ts/1 • CP-15 Trouble LEVEL 4 CHECKLIST OK ►z. Heats - FRCM 15 -1- 72 OK El OK OK OK ❑ Heats - FRCM 15-1- 73 OK El OK OK El OK ❑. Pull Sta - 15 -1 -77 OK OK OK OK El Heats - FRCM 15-1- 74 OK OK El OK El OK ED OK Z Heats - FRCM 15 -1- 84 OK El OK OK Ej OK OK El Pull Sta - 15 -1 -75 OK ❑ OK El OK ig OK OK El Pull Sta - 15 -1 -76 OK ❑ OK El OK OK El OK IZ Result » »> Alarm on CP15 Activate Solenoid Activate Bldg' horns/strob ess • Send Alarm Send Trouble Send Supetvis ory CP -15 Supervisory Sends signal. to Building panel. CP -2 for alarm • , PRZ -1 -17 SCM 15-1 - 100 FCPS 12a CP -2 5OM CR 154a , R2M 15 -1-80 Alerton." R2M 15 -1-81, Alerton R2M 15 -1-82 Alerton R2M1rr: 1-83 OK Template Rev. 072606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 17 LEE TECHNOLOGIES` •L • LEVEL 4 CHECKLIST CP -15 Trouble OK 4 evice: address• & type UPS2A roam:154;b�:; Smoke Det - 15-1- 38 OK ►■ � OK ►5 OK 4 OK ►Z4 OK ►5 Smoke Det - 15-1 39 OK 0 OK , OK 0 OK 0 OK 0 Smoke Det - 15 1- 41 OK t OK 0 OK ►5 OK 0 OK /� Smoke Det - 15-1- 42 OK ►5 OK ►5 OK OK 0 OK .4 Smoke Det -15-1- 43 OK ►5 OK 0 OK 0 OK ►Z.. OK Smoke Det - 15 -1- 44 OK ►'/ OK ►.0 OK ►Z1 OK 0 OK ►5 Smoke Det - 15-1- 45 OK 0 OK r OK ►5 OK 0 OK r Smoke Det -15 -1- 46 OK 0 OK ►5 OK r OK ►:t OK 0 Smoke Det - 15-1- 47 OK 0 OK 0 OK 01 OK 0 OK ►5 Smoke Det -15 -1- 48 OK ►5 OK 0 OK 4 OK 0 OK 0 Smoke Det -15 -1- 49 OK ►5 OK 0 OK OK 0 OK J. Smoke Det -15-1- 50 OK ►5 OK 0 OK te. OK ►:� OK 0 Template Rev. 072606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 17 LEE TECHNOLOGIES' • th, • Smoke Det -15-1 - 52 OK ® OK ® OK El OK OK El LEVEL 4 CHECKLIST Smoke Det -15-1 - 53 OK OK El OK OK OK El Pull Station 15 -1- 40 OK OK ❑ OK OK Eg OK El Pull Station 15 -1- 51 OK El OK ❑ OK OK ID OK El CRAC 3 -1 FRCM 15- 1-71 OK El CRAC 3-2 FRCM 15- 1-68 OK El CRAC 3-3 FRCM 15- 1-70 OK CRAC 3-4 FRCM 15- 1-69 OK El Alarm on CP15 Sends.. signal to Building:' CP -2 for alarm , Activate Solenoid PRZ -1 -17 SCM 15-1 - 100 Activate Bldg horns /strob es FCPS 12a CP -2 SOM 2-1-2.8 Close FSD's Control Relay 154a R2M 15 -1-81 Send Alarm . Alerton R2M 15 -1-81. Send Trouble Alerton:. R2M 15 -1-82 Send Supervis ory .Merton R2M 15-: 1-83 CP -15 Supervisory OK Ej CP -15 Trouble OK Template Rev. 072606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 4 of 17 • • • LEE TECHNOLOGIEr LEVEL 4 CHECKLIST Smoke detector 15 -1 -54 OK OK OK 0 OK ►.. e ►i OK ►� Pull Station 15 -1- 55 OK OK OK►� OK OK Smoke detector 15 -1 -56 OK OK OK e OK 0 OK ►Z� Smoke detector 15 -1 -57 OK OK OK 0 OK N ►Z1 0 OK e Smoke detector 15 -1 -58 OK OK OK 0 OK @ 0 0 OK 0 Smoke detector 15 -1 -59 OK OK OK OK ►5 0 ►:/ OK 0 Smoke detector 15 -1 -60 OK OK OK ► OK 12 1 ►- OK ►5 Smoke detector 15 -1 -61 OK OK OK ►I OK ►'' ►.0 0 OK 0 Smoke detector 15 -1 -62 OK OK OK ►5 OK 0 ►1 0 OK e Smoke detector 15 -1 -63 OK OK OK 0 OK ►4 ►5 0 OK 0 Smoke detector 15 -1 -64 OK OK OK 0 OK 0 ►5 0 OK ► 0 Smoke detector 15 -1 -65 OK OK OK 0 OK N ►5 0 OK 0 Pull Station 15 -1- 66 OK OK OK OK 0 0 OK ►5 Smoke Detector 15 -1 -67 OK OK OK ►5 OK 0 0 OK ►5 Template Rev. 072606 Lee Technologies Services, Inc. Copyright 2010 Proprietary use pursuant to company policy Page 5 of 17 LEE TECHNOLOGIES' • to/fil • • LEVEL 4 CHECKLIST Activate Solenoid PRZ -3-20 Activate Bldg Horns /Strobes FCPS #25 acts #1 & 2 Send Alarm Alert- lerton Send Trouble Alerton Send Supervis ory -- Merton Building Panel CP-2 for alarm • SCM 14-1 -112 SOM 2 -4-123 R2M 14-3-217 R2M 14-3 - 218 R2M 14 3-219 CP -14 Supervisory OK CP -14 Trouble OK Dig Smoke Detector 14- 3 -78 OK El OK OK OK Eg Smoke Detector 14 3 -79 OK OK El OK El OK Smoke Detector 14- 3 -80 OK El ,OK OK El OK El Smoke Detector 14 3 -81 OK OK El OK OK Template Rev. 072606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 6 of 17 • • • LEE TECHNOLOGIEr LEVEL 4 CHECKLIST Smoke Detector 14- 3-82 OK OK OK OK 0 :1 Smoke Detector 14- 3 -83 OK OK OK OK 0 0 ►1 ►1 Smoke Detector 14- 3 -84 OK OK OK OK 0 0 ►: ►./ Smoke Detector 14- 3 -85 OK OK OK OK ►5 0 ►5 0 Smoke Detector 14- 3 -86 OK OK OK OK ►Z/ ►./ 0 r Smoke Detector 14- 3 -87 OK OK OK OK ► I N ►5 Smoke Detector 14- 3-88 OK OK OK OK 0 ►1 0 /1 Smoke Detector 14 3 -89 OK OK OK OK 0 0 ►4 Smoke Detector 14 3 -90 OK OK OK OK / ►:/ 11 0 Smoke Detector 14 3-91 OK OK OK OK ► 4 ►4 Smoke Detector 14- 3 -92 OK OK OK OK ►1 ►5 4 ►Z� Smoke Detector 14- 3-93 OK OK OK OK / 1 0 ►4 ►Z� Smoke Detector 14- 3-94 OK OK OK OK ►4 ►.1 ►5 0 Smoke Detector 14 3-95 OK OK OK OK 0 N 0 0 Smoke Detector 14- 3-96 ' OK OK OK OK ►5 0 y Template Rev. 072606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 7 of 17 • • • LEE TECHNOLOGIES° LEVEL 4 CHECKLIST Smoke Detector 14- 3 -97 OK OK OK OK 0 Smoke Detector 14- 3-98 OK 0 OK 0 OK 0 OK 0 Smoke Detector 14- 3 -99 OK 0 OK 0 OK 0 OK 0 Smoke Detector 14- 3 -100 OK r OK ►5 OK OK 0 Smoke Detector 14- 3-101 OK 1 OK 0 OK > OK Smoke Detector 14- 3 -102 OK 11 OK 15 OK 0 OK 0 Smoke Detector 14 3 -103 OK 0 OK ►1 OK 0 OK ►� Smoke Detector 14- 3 -104 OK 0 OK e OK N OK ►.1 Smoke Detector 14- 3-105 OK e OK 0 OK N OK /1 Smoke Detector 14-. 3-106 OK OK 0 OK ►5 OK ►Z/ Smoke Detector 14- 3 -107 3-107 OK / OK a OK 0 OK "4 Smoke Detector 14- 3 -108 OK ® OK 4 OK 0 OK ►./ Smoke Detector 14- 3 -109 OK ►5 OK 0 OK 0 OK ►5 Smoke Detector 14- 3 -110 OK 0 OK 0 OK 0 OK ►5 Smoke Detector 14 3 -111 OK 0 OK 0 OK ►Z OK 0 Template Rev. 072606 Lee Technologies Services, Inc. 0 Copyright 2010 Proprietary use pursuant to company policy Page 8 of 17 LEE TECHNOLOGIES' II IL • • LEVEL 4 CHECKLIST Smoke Detector 14- 3 -112 OK OK OK OK ►5 L N J Smoke Detector 1.4- 3-113 OK OK OK OK ►5 N 11 ►5 Smoke Detector 14- 3-114 OK OK OK OK / 1 ►ZI 0 ►5 Smoke Detector 14- 3-115 OK OK OK OK /. ►. ►. 0 Smoke Detector 14- 3 -116 OK OK OK OK ►. 0 ►; ► � Smoke Detector 14- 3 -117 OK OK OK OK ►5 ►5 ►1 Z Smoke Detector 14- 3-118 OK OK OK OK /; 0 0 Smoke Detector 14- 3 -119 OK OK OK OK ►Z1 0 J ►Z� Smoke Detector 14- 3 -120. OK OK OK OK ►ZI e Smoke Detector 14- 3-121. OK OK OK OK ►5 ■ CI Smoke Detector 14- 3 -122 OK OK OK OK 0 ►. ► ..1 0 Smoke Detector 14 3 -123 OK OK OK OK 0 0 .1 ►5 Smoke Detector 14- 3 -124 OK OK OK OK / ■ 0 Smoke Detector 14- 3-125 OK OK OK OK 0 ►1 e ►ZI Template Rev. 072606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 9 of 17 • • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Smoke Detector 14- 3-126 OK OK OK OK 0 0 0 Smoke Detector 14- 3 -127 OK ® OK OK OK ►5 e 11 Smoke Detector 14- 3-128 OK OK OK OK J ■ ./ Smoke Detector 14- 3 -129 OK OK OK OK ►5 / �1 Smoke Detector 14- 3430 OK OK OK OK ►1 1 0 0 Smoke Detector 14- 3 -131 OK OK OK OK ►1 ►5 0 e Smoke Detector 14- 3 -132 OK OK OK OK ►. ..1 0 ►Z� Smoke Detector 14- 3 -133 OK OK OK OK ►1 r ►5 .1 Smoke Detector 14 3 -134 OK OK OK OK 0 P 7i 4.4 Smoke Detector 14- 3 -135 OK OK OK OK 0 ►5 ► ► Smoke Detector 14- 3-136 OK OK OK OK 0 0 0 ►� Smoke Detector 14- 3 -137 OK OK OK OK ► ►5 0 0 Smoke Detector 14- 3-138 OK OK OK OK y 0 0 Smoke Detector 14 3-139 OK OK OK OK ►"4 e 0 Smoke Detector 14- 3-140 OK OK OK OK 0 J ►5 0 Template Rev. 072606 Lee Technologies Services, Inc. O Copyright 2010 Proprietary use pursuant to company policy Page 10 of 17 .tp,/ LEf TECHNOLOGIES" • Smoke Detector 14- 3 -215 OK EE OK El OK LEVEL 4 CHECKLIST OK El Smoke Detector 14- 3-216 OK OK OK OK RTU 3-1 FROM 14-3- 211 OK ❑ RTU 3-2 FRCM 14-3- 213 OK ❑ RTU 3-3 FRCM 14-3- 214 OK RTU 3-4 FRCM 14-3- 210 OK ❑ RTU 3 -5 FRCM 14-3- 212 OK ❑ PRZ 3-20 Tamper 14- 1 -109 OK ❑ PRZ 3-20 Flow 14-1- 110 OK El OK Eg OK OK El PRZ 3-20 Low Air 14- 1 -111 OK ❑ sends signal to. Activate Solenoid ' SCM 141 -103 Activate Bldg Horns /Strobes FOPS #25 acts #1 &2. SOM 2 -4-123 . Send Trouble Supervis ory Aiertan R2M 14-3-'. 218 Merton • 112M 14- 3-219 Template Rev. 072606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 11 of 17 • • • LEE TECHNOLOGIES LEVEL 4 CHECKLIST Device address & Phase 4SServer,Room' Smoke Detector 14- 3 -141 OK 0 O / OK ►� OK Smoke Detector 14- 3 -142 OK ►5 OK ■ OK 0 OK 0 Smoke Detector 14- 3 -143 OK 0 OK 0 OK /5 OK 0 Smoke Detector 14- 3 -144 OK 0 OK 0 OK ►'l OK ►5 Smoke Detector 14- 3 -145 OK 0 OK 0 OK ►Z/ OK ■ Smoke Detector 14 3-146 OK ► OK ■ OK ► OK 0 Smoke Detector 14- 3 -147 OK 0 OK r OK OK 1 Smoke Detector 14- 3 -148 OK 0 OK 0 OK 0 OK ►1 Smoke Detector 14- 3-149 OK ►1 OK 0 OK 0 OK 0 Smoke Detector 14- 3 -150 OK 0 OK 0 OK ►�� OK 0 Template Rev. 072606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 12 of 17 • • • el LEE TECHNOLOGIES" LEVEL 4 CHECKLIST Smoke Detector 14- 3 -151 OK / OK ►ZI OK e OK /1 Smoke Detector 14- 3 -152 OK 0 OK 1 OK 1 OK ►5 Smoke Detector 14- 3 -153 OK 0 OK 0 OK A OK ►1 Smoke Detector 14- 3-154 OK 0 OK 0 OK 0 OK / 1 Smoke Detector 14- 3 -156 OK J OK 0 OK ►Zi OK Smoke Detector 14- 3 -157 OK ►5 OK 0 OK 0 OK 0 Smoke Detector 14- 3-158 OK 0 OK ►5 OK 0 OK ►5 Smoke Detector 14- 3-159 OK 0 OK 0 OK 4 OK Co Smoke Detector 14- 3-160 OK 0 OK 0 OK ►1 OK ►■ Smoke Detector 14- 3 -161 OK ® OK 0 OK r OK ►5 Smoke Detector 14- 3 -162 OK r4 OK ►1 OK e OK CI Smoke Detector 14- 3 -163 OK ►5 OK ►A OK N OK ►4 Smoke Detector 14- 3 -164 OK 0 OK 0 OK 0. OK 0 Smoke Detector 14- 3-165 OK ►5 OK 0 OK 0 OK ►2 Template Rev. 072606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 13 of 17 • • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Smoke Detector 14- 3-166 OK OK 0 OK ►.1 OK Smoke Detector 14- 3-167 OK OK ►1 OK 0 OK e Smoke Detector 14- 3 -168 OK OK ►1 OK OK 11 Smoke Detector 14- 3-169 OK 0 OK 0 OK OK / Smoke Detector 14- 3 -170 OK ►.1 OK ►5 OK 11 OK ►1 Smoke Detector 14- 3-171 OK 0 OK 0 OK 0 OK ►1 Smoke Detector 14- 3 -172 OK 0 OK 0 OK / 1 OK ►5 Smoke Detector 14- - 3-173 OK ►Z/ OK 0 OK 0 OK ►.� Smoke Detector 14- 3-174 OK /.1 OK 4 OK 0 OK /.1 Smoke Detector 14- 3 -175 OK ►5 OK / 1 OK 0 OK 0 Smoke Detector 14- 3 -176 OK 0 OK 0 OK 0 OK ►5 Smoke Detector 14- 3-177 OK El OK ►1 OK ►5 OK ► Smoke Detector 14- 3 -178 OK /I OK r OK y OK J Smoke Detector 14 3-179 OK A OK I— OK OK Smoke Detector 14- 3 -180 OK 0 OK OK 0 OK 1.i Template Rev. 072606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 14 of 17 � 1 LEE TECHNOLOGIES' • • • LEVEL 4 CHECKLIST Smoke Detector 14 3 -181 OK OK OK OK 1 ►1 ►.1 ►� Smoke Detector 14- 3-182 OK OK OK OK e r 0 ■ Smoke Detector 14- 3-183 OK OK OK OK 0 0 0 Z� Smoke Detector 14- 3-184 OK OK OK OK e ►/ ►1 :� Smoke Detector 14- 3 -185 OK OK OK OK 0 ►:/ ►'/ Smoke Detector 14- 3 -186 OK OK OK OK 0 0 ►1 Smoke Detector 14- 3-187 OK OK OK OK ►1 ' ►� Smoke Detector 14- - 3-188 OK OK OK OK 0 e 5 Smoke Detector 14- 3 -189 OK OK OK OK ►./ ►5 0 ►� Smoke Detector 14- 3 -190 OK OK OK OK ►5 ►5 0 Smoke Detector 14- 3 -191 OK OK OK OK 1 / 0 0 0 Smoke Detector 14- 3 -192 OK OK OK OK ►,/ ►./ .1 r Smoke Detector 14- 3-193 OK OK OK OK 0 1 0 ZI Smoke Detector 14- 3-194 OK OK OK OK ./ 0 0 t:/ Template Rev. 072606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 15 of 17 • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Smoke Detector 14 3 -195 OK OK./ OK OK El 11 0 Smoke Detector 14- 3 -196 OK OK OK OK ►1 0 0 `vi Smoke Detector 14- 3 -197 OK OK OK OK ►1 ►5 0 .1 Smoke Detector 14- 3-198 OK OK OK OK 0 0 0 ►/ Smoke Detector 14- 3 -199 OK OK OK OK ./ 0 0 0 Smoke Detector 14- 3 -200 OK OK OK OK .1 0 0 0 Smoke Detector 14 3 -201 OK OK OK OK 0 I ► ►Z� Smoke Detector 14- 3 -202 OK OK OK OK ►ZA .e ►5 ►5 Smoke Detector 14 3 -203 OK OK OK OK .1 0 .1 . Smoke Detector 14- 3-204 OK OK OK OK 0 0 0 .1 Smoke Detector 14- 3 -205 OK OK OK OK .1 ..4 ►5 ■ Smoke Detector 14 3-206 OK OK OK OK ► 1 Smoke Detector 14- 3-207 OK OK OK OK 0 ►5 ►/ ./ Template Rev. 072606 Lee Technologies Services, Inc. © Copyright 2010 Proprietary use pursuant to company policy Page 16 of 17 • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Smoke Detector 14 3-208 OK ►5 OK ■ OK 1 OK 0 Pull Station 14-3-155 OK 0 OK r OK 0 OK */ PRZ 3-19 Tamper 14 1 -100 OK ❑ PRZ 3-19 Flow 141- 101 OK • PRZ 3-19 Low Air 14 1 -102 OK ►N 1. Ensure that any off -site monitoring company is notified that maintenance is complete and to resume monitoring the facility. List the actual company name and phone number. Section 04 Comments C,,,-, ,erils Insert any comments applicable to the Checldist Section 05 Lee Technologies Services, Inc. representative has witnessed or participated in this checiist, has verified equipment checklist ei fic u v�;iinass r; is ready per checklist, and attests to the accuracy and corn. eness of th' • re... Veriticatfon Y P Y Lee Tech 's Representative Printed Name: Sign 5 IN v Date- Herbert Burnett _327ff`fff �I���I,1111 7n2f2010 Template Rev. 072606 Lee Technologies Services, Inc. ® Copyright 2010 Proprietary use pursuant CO company policy Page 17 of 17 • • Outside Atr Tempest's,: ' no Outside All HmddI y ' no Tuesday. 7202010 4:42:27PM SEA1j .€ (SFF00 )) SITE' SPU Space Space Discharge Cooing Lead 1 Lead 2 Lead 3 Badly Unfit Fan Unit O Set Pons Temp Temp Signal Status Status Status Status Command Status Manual an SPU -40.11 no ' nor ergry • no entry ' no entry ' no entry • no entry ' no entry • no entry • no entry Force Fan On r no army • entry • Force Fan Off r ^ SP1F102 ;• • n0 • wiry ' no arty ' no ditty ' n0 ends ' no entry 'nor entry ' no entry ' no entry • Force Fan On r • entry • Force Fan Off r no entry +?LSPlL.10J ' no no angry 'nor entry ' no entry ' no entry ' no entry • nor entry nor entry ' no entry Force Fan On r no entry • entry • Force Fan Off r Force Fan On r eS01104}) ' no entry ' no arty • no army ' no entry • no entry • no entry • no entry ' no tidy ' no entry • •.no entry Force Fan OR r • Manual Lead Rotation SPU Space Space Discharge Cooling Lead 1 Lead 2 Lead 3 Badd>p Unit Airflow Una 1) Set Pond Temp Temp Signal Status Status Status Status Command Proof Manual ,,CRA6.3.1 1 70.0 °F 73.3 °F NA NA tractive Active inactive tractive Stop ;CRAG =312 70.0 °F 73.0 °F NA NA Active tractive Active Inactive Slop CRA0=313 j 70.0 °F 71.3 °F NA NA Inactive Active Inactive Adis® Stop CRAC1'3 4) 70.01 70.4 °F NA NA Inactive Inactive Active Inactive Stop r Manual Lead Rotation Force Urdu On r Unit Failure • Force Unit Off r On as Back UP • Force Unit On r Unfit Failure Force Unnl Of r • Force Uni On r Unit Failure Force Unit Off r • - Force IAni On r thdt Failure Force Uni OR r Note: Manual Reset of Faihse , „ ed 4. EP: (pimipe } en ecril y's "s%cuailr soiUTIONS • • • Outside Ak Temperature: ' no Outside de litmddl3A • no Tuesday, 71202010 4:50t09PM -.GAMMON! Nqf MOMMMOOMONN LEATITAgi #10,034 41ire 411 • .."7. ',....::::...",•.Generatin.- 6 :"., . ' ',.. .1 Generator Rtimilnm Acute • Generator Running Generator % Loaded Total Kw: ' no entlY . • no °idly ' no entry ' • , Total Kw: 142800000000 : I Generator Runnbut ' no enNY ' • Total Kw -0 KW Generator % Loaded • 110 elltlY ' Generator Runnkut Active • Total Kw: ' n0 0110y Generator % Loaded 27S Generator Romthrm • no entry • • Generator % Loaded • no entry Total Kw: ' no entry • 411 • atm MENU .."7. ',....::::...",•.Generatin.- 6 :"., . ' ',.. .1 Generator Rtimilnm Acute • Generator % Loadect 26 % Total Kw: 142800000000 : Generator Rurstbo &true • Generator % Loaded 26 % Total Kw -0 KW \ ,:., , • - Generator- 6 ''':' ". ''. ' I Generator Runnkut Active • Generator % Loaded 27S Total Kw: -14317374 atm MENU • • Outside Alt Temperance: ' no Outside Alt Hunidpy no CPDU 3A1 3A /Text;,.,;I. Total KW: 0 KW PDU 3A6 3A6 Text , Total KW: 0 KW Tuesday, 7/2012010 4:43:32PM 4017-TLC (SE QQ.0.4 SINE' -PDU 3A2 3A2 Text Total KW: 0 KW PDU 3A7 ............. 3Ai Test I. Total KW: 0 KW -PDU 384 384Text' ;10 Total KW. 0 KW Electrical Switch Gear PDU 3A3 3A3 Text :i, ,I. Total KW: 0 KW PDU 381 381 Text... I. Total KW: 0 KW -PDU 385 385 Text, ' _ „I. Total KW: 0 KW PDU 3A4 -!3A4 Text:. ... ,I. Total KIM: 0 KW [PDU 382 382 Text Total KW: 0 KW -PDU 386 386 Tog I. Total KW: 0 KW -PDU 3A5 `-..3A5Text -.f. Total KW: 0 KW - PDU 383 - — _ ...383 Text I. Total KW: 0 KW ens c�. & SECURITY SOLUTIO■S • • • Tuesday, 7120/2010 4:4•51361 Outside Mr Temperature: 72.7'F Phase 3 SEATTLE' (SEEM SIrTg: Sensor 1 Sensor Sensor 3 Lowest Highest Zone Temperance 70.3 °F 70.0 °F 70.8 °F 70.0 °F 70.8 °F Zone Hnnidfy 81.6 % 79.6 % 79.8 % 81.6 % Sensor 1 Sensor 2 Senses 3 Lowest Highest Under Roor Static 0.207 'w.c. 0.224 "w.c. 0.219 'w.c. 0.207 w.c. 0.224 'w.c. Zone Static .0.084 0.048 .0.004 .0.048 Soppy Return Duct Static High Duct Reran Humidity Econ Suppb Fan AC UNt ID SAT SP Temp Temp Pressure Static Alarm I8mddy Status Lockout VFD Cmd Status Manual Force Fan On r RTU 31.:i1 48.01 71.1 °F 71.81 0.21 'w c Inactive 5711 Inactive Active 57 Hz • Force Fan Ott r RTU 7.2t';'1 40.01 73.01 71.5 °F Inactive 57 °A Inactive Active 57113 • Force Fan On r Force Fan Orr r RTU 3 3 °,'!� !0.0 °F 718 °F 70.1 °F inactive 63 % Inactive Active S7 Hz • Force Fan On r Fan 0rt r RTU 3 / ° ":I 48.0 °F 69.91 71.3 °F Inactive wctlInactive 59 % inactive Active 57 Hz 1111 Force Fan On r Face Fan OR r RT163.5r 1 48.0 °F 74.3 °F 70.91 Inactive 59 % Inactive Active 57 Hz • Face Fan On r Face Fan Olt r MENU:. PREVIOUS.' PHUISE Is;; tom. 8 SECURITY SOIUIIONS • • • • Outside Air Temperature: • no Outside Air Humidly: • no Tuesday. 712012010 4:4038PM . a a avanysaareenia 4.0117:03 lafrOnt fifirre Operation Mode: • no entry ' Status Mode: • no entry ' Active Power P: • no entry ' Operation Mode: ' no wary ' Status Mode: ' no entry ' Active Power P: ' no entry ' -UPS Static SwacM 1 x 3 • "ft UPS. 101 I x 3 • Operation Mode: ' no entry ' • Status Mode: • no entry • Active POW& P: ' no enny ' x • Operation Mode: • no entry Status Mode: ' no entry ' Active Power P: " no tinny' UPS- 102 • • x 3 • UPS 103: , Operation Mode: • no entry • UPS: 101... Status Mode: no entry ' • Acttve Power P: ' no entry x 3 • Operation Mode: Probetrn Status Mode: Unsafe Active Power P: 19.0 kW Operation Mode: Probelm Status Mode: Unsafe Acute Power P: 0.0 kW Operation Mode: Probelm Status Mode Unsafe Active Power P: 0.0 kW Operation Mode: Pt obelm Status Mode: Unsafe Active Power P: 0.0 kW Operation Mode: Probeim Status Mode: Unsafe Active Power P: 0.0 kW x 3 - • 1.r0 I • x 3 - • ijModnte 2 x 3 • • UPS Module 3 .° • x 3 • x 3 - MAN MENU' TfOOtitt: • Outside Air Temperature: • no Outside Air Nmhddky: • no Tuesday. 72012010 0.•OO:tOPNI S_EA, T LEi (40:003) SJTE SPU Space Space UM D Set Pohd Temp SPU- 101:.11 ' no entry ' no entry SPU=102F1 ' no entry ' no entry SP1).103 flI • no entry ' no entry SPU- 104` ;1 • no entry ' no wily r Manual Lead Rotation Discharge Cooling Lead 1 Lead 2 Lead 3 Backup lhdt Temp Signal Status Status Status Status Cormnand ' no entry • no entry • no entry ' no entry ' no entry ' no entry ' no entry ' no entry ' no entry " no entry ' no entry ' no eery ' no entry ' no entry • no entry ' no entry • no entry • no entry • no entry ' no wiry ' no wiry • no entry • no entry ' no entry • no entry ' no entry ' no entry ' no entry Fan Status • • • • Manual Force Fan On Face Fan OR Force Fan On Force Fan Off Force Fan On Force Fan Ott Force Fan On Force Fan Off r r r. r r. r r ' no entry no entry ' ' no entry ' no entry ' SPU Space Uudt D Set Point Temp Space CRAG =3-1 ";I CRAG =3 21 CRAC -3.31 CRAC?3 3 I 70.01 78.59' NA NA inactive Inactive Active tractive Manual Lead Rotation 70.09' 70.2°' 70.01 76.3 °F Discharge Cooling Lead 1 Lead 2 Lead 3 Bad Up Ul* Airflow Temp Signal Status Status Status Status Command Proof NA NA Inactive Acttve inactive hwctive Stop NA NA Active klactive Active Inactive Stop 70.0 °F 77.2 °F NA NA Inactive Active Inactive Active Stop Stop • • O • Manual Force Unit On Force Unit Off ✓ Unit Failure ✓ On as Back UP Force Unh On r lhdl Failure Force Unll Off r - Force Un l Oli r Unit Failure Force Unh Off r Force Unit On r Unit Failure Force Unit OR r - Note: Manual Reset of Fannie Required • II PRENOUS: ;I .e.nlTTc i 8 SECURITY SOLUTIONS • • Outside Ak Temperance: ' no Outside Ak Muddily: ' no Tuesday. 720/2010 5:48:20PM EATTLE{ (SEF003), SIiTE __Generator. t Generator Rmmd nd ' no entry' • Generator % Loadet ' no entry' Total Kw: ' no entry • Generator - 2 Generator Rmnkrs ' no entry' • Generator % loaded: ' no entry Total Kw: ' no entry' Generator - 3 Generator Rutting ' no entry • • Generator K Loaded: ' no entry ' Total Kw: ' no entry ' 4 Genes d t 4,5,8 Swkch Gear - -1 • .Geiieraaor 4,0 Fuel Oil System _ _ , • Generator 4 Generator Rumtn¢ Active Generator % Loaded: 17 % Total Kw: -0 KW Generator - 5 • Generator Rrcnhua Active • Generator % Loaded: 18 % Total Kw: 501381780701 Generator -8 Generator Mamba; Active Generator % Loaded 18 % Total Kw: -0 KW • MAN MENU PREVIOUS • • • Outside Mr Temperature: `no Outside Atr H mdddy. • no �PDU 3A1 , `.. 3A1 Taxi, ;: 1 Total KW 114 KW POU 3A6 3A6 Text . ,; I • Total KW: O KW Tuesday, 7,2012010 6:01:20PM MAIN MENU PREVIOUS 8QA-M1 4.011tTAC REIYQQ BYTE -POD 3A2 3A2Text,' 1 • Total KW: 3 KW PDU 3A7 3A7 Text. ,.I • Total KW: 0 KW -POU 384 384 Text " 1 • Toth KW: 112 KW Electrical Switch Gear 1-POU 3A3 3AMText :'I • Total KW: 112 KW -NV 381 381 Text ...,_1 • Total KW: 0 KW -POU 385 385 Text :, l • Total KW: 3 KW PDU 3A4 3A4 Text l • Total KW: 3 KW -PDU 382 --- -- 382 Text I • Total KW: 114 KW -PIM 386 386 Text • •, ?1 • Total KIM 0 KW -PDU 3A5 9A5 I• Total KW. 111 KW - POU 383 383 Text ,I • Total KW: 3 KW -P011387 387 Text 1 • Total KIM 0 KW • &O.enhich PI :0 8 SECURITY SOWTIONS • • Tuesday, 71202010 5:57:31PM Outside Air Temperature: 73.0 °F Phase 3 S 0-TrTM MEEQO IT 4 Sensor 1 Sensor 2 Sensor 3 Lowest Highest Zone Temperature 70.7 °F 76.6 °F 74.7 °F 70.7 °F 76.7 °F Zone Humidity 59.2 % 64.2 % 59.2 % 64.2 % Sensor 1 Sensor 2 Sensor 3 Lowest Highest Under Floor Static 0.168 'w.c. 0.191 '1v.c. 0.178 "w.c. 0.168 "v.c. 0.191 'w.c. Zone Static 0.273 "w.c. 0.290 w.c. 0.273 ' w.c. 0.290 "w.c. Supply Rehm Dud Static High Dud Return HHunddiy Econ Suppy Fan AC Unit ID SAT SP Temp Temp Pressure Static Alarm Humidity idity Status Lockout VFD Cmd Status Manual Force Fan On r Rill -3.1 1 45.0 °F 70.1 °F 78.5 °F 0.17'w.c. Inactive 43 % Masan Inactive 51 112 • Face Fan Off r Face Fan On T RTU -3.2 I 45.0 °F 70.41 76.1 °F Inactive 46 % 6wcWe Inactive 5114z • Force Fan Off f- Force Fan On r RTU 3 3 1 45.0 °F 68.3 °F 74.5 °F Inactive 50 % irwcnve Inadere 51 I12 • Force Fan off r Force Fan On r RTU-3-4 1 45.0 °F 68.6 °F 75.1 °F Inactive 49 % Inactive Inactive 51 It II Force Fan Off r RTU-3.5 1 45.0 °F 69.5 °F 76.6 °F Inactive 46 % inactive Inactive 51 R: • Force Fan On r Face fan Off r MAN MENU PHASE! �en Tec h 8 SECURITY SOLUTIONS • • Tuesday. 7120/2010 5:5923PM Outside Alt Temperature: • no Outside Alt Itunddity: • no 4-01Trirle CVECIAM) Operation Mode: • 00 entry ' Status Mode: ' no entry Active Power P: ' no entry ' UPS Static Sidtch:- I x 3 Operation Mode: ' no entry ' • LIPS% 101 I Status Mode • no entry ' Active Power P: ' no allay x 3 Opera:Ion Mode ' no entry ' • UPS - 102 I Status Mode: ' no ashy ' • Active Power P: ' no stilly x 3 Operation Mode • no erdry Status Mode: no entry ' Active Power P. ' no tinny' Operation Mode: ' no entry ' Status Mode no entry • Active Power P: ' no early UPS -103:: x 3 • UPS 104 x 3 Operation Mode Normal • tips Statk Switch I Status Mode: Safe Active Power P: 578.0 kW x 3 Operation Mode Normal Status Mode: Safe Active Power P. 142.0 kW Operation Mode: Normal Status Mode: Safe Active Power P 144.0 kW Operation Mode Notmal Status Mode: Safe Active Power P 149.0 kW Operation Mode: Normal Status Mode: Safe Active Power P 145.0 kW • ' • x 3 - -LIPS MOM° - ups module 2 ' I • UPS 1.1odule 3 I • x 41,1. UPS Modtde 4- I x 3 I MAIN MENU PREVIOUS • • • Outside Ab Temperature: ' ro Outside Alt IAmddiyr. ' no Tuesday. 7!202010 9:38:20AM $; 111:1 (SEF0031) SVI SPU Space Space Discharge Cooling Lead 1 Lead 2 Lead 3 Backup Unit Fan Untt 9 Set Point Temp Temp Signal Status Status Status Status Command Status Manual SPU 101 no Force Fan On r entry • no entry ' no entry ' no entry ' no entry • no entry • no entry ' no entry ' no entry • Force Fan Off r SPU -102 I ' no entry ' no entry • no entry ' no entry ' no entry ' no entry ' no entry ' no entry ' no entry • SPU -103 I ' no entry • no entry • no entry ' no entry ' no entry ' no entry • no entry ' no entry ' no entry • SPU -104 I • no entry ' no entry ' no entry ' no entry ' no entry ' no entry ' no entry ' no entry ' no entry • r Manual Lead Rotation Force Fan On r Force Fan Off r Force Fan On r Force Fan Off r Force Fan On r Force Fan Off r ' no entry ' ' no entry ' ' no entry • ' noentry' SPU Space Unit ID Set Point Temp Space Discharge Cooling Lead 1 Lead 2 Lead 3 Backup Unit Airflow Temp Signal Status Status Status Status Conrnand Proof CRAC.3.1 1 70.0 °F 71.4 °F NA NA Inactive Active Inactive Inactive Rim CFtAC.3 -2 1 70.0 °F 71.9 °F NA NA Active Inactive Active twctie Run CRAC-3-3 1 70.01 69.7 °F NA NA Inactive Active Inactive Active Stop CRAC -3-4 I 70.001 69.4 °F NA NA Inactive Inactive Active Inactive Run r Manual Lead Rotation Manual • Force thdtOn r Force UM Off r • Force tkdtOn r Force tpdt Off r • Force Un8 On r Force Urdf Off r • Force IAdt On r Force Unit off r Note: Manual Reset of Failure Required MAN M@Al PREVIOUS • • • Outside Ali Temperature: ' no Outside Air Humidity: ' no -PDU 3A1 3A1 Text I • Total KW 27 KW POW 9A6 .3A8,Text I• Total KW O KW Tuesday, 7,202010 9:24:15AM 4011711Ef (4 EF0031 SJ.iTE -PDU 3A2 3A2 Text I • Total KW: 27 KW -PDU 3A7 - -- 3A7 Text. I • Total KW: OKW -P011 3B4 364:Text'.. Total KW: 28 KW Electrical Switch Gear POO 3A3 3A3 Text , I • Total KW: 27 KW PDU 361...._ 381 Text I • Total KW: 27 KW PDU 3M 3A4 Text•: I • Total KW: 27 KW PD 13B2 -- -. 3132 Teed I • Total KW: 27 KW -PDU 368 ..: 3B6.•Text I • Total KW: 0 KW -PDU 3A5 9A5Te�A ..::I• Total KIM: 27 KW - P0U 363 363 Text ) • Total KW: 32 KW -PDU 367 967 Text I • Total KW: OKW • MENU ............. 'PREVIOUS BctlN2 a .. BCM-M4' .1�en1 ech SECURITY SOLUTIONS • • Tuesday. 7/20$2010 9:21A8AM Outside At Temperance: 54.8 °F Phase 3 Wr ' (4.EF003) SI1TlEf Sensor 1 Sensor 2 Sensor 3 Lowest Highest Zone Temperature 68.9 `F 69.2 °F 71.0 °F 68.9 °F 71.0 °F Zone l#nnId ty 63.5 % 64.9 % 63.5 % 64.9 % Sensor 1 Sensor 2 Sensor 3 Lowest Hlippest Under Root Static 0.146 'w.c. 0.164 'w.c. 0.158 'w.c. 0.146 'w.c. 0.164 W.C. ' Zone Stalls 0.057 'w.c. 0.063 'w.c 0.057 w.c. 0.063 "w.c. Supply Return Duct Stark High Duct Return it mddOy Econ Supply Far AC Unit ID SAT SP Temp Temp Pressure Stank Alarm FMmddity Status Lodwut VFD Cmd Status Manual Force Fan On r -`' Ril! S 1 :) 65.01 67.41 71.81 0.15'w.c Inactive 5115 IwcUre inactive 47 HZ • Face Fan Off r Force Fan On I- RTlL3.2,` 'I 65.0 °F 66.81 70.51 Ywcthre 54 % Inactive elective 47 H= • Force Fan Off r Force Fan On r 3 65.0 °F 661 °F 67.91 Inactive 59 °6 hledlpra Inac ive 47 Hi • Face Fan Off r Force Fan On r RTU.0 ' 1 65.01 66.1 °F 70.2 °F Inactive 56 % bwctive Inactive 47 H: • Force Fan Off r FtTU 3 5 "1 65.01 67.31 71.2 °F bwdI o 53% elective elective Force Fan On r t a 47 Hz • ice Fan OR r maitiltii PHASEI PHASE Ot' en iec & sfeuair4 sotiffiONs • • • Tuesday, 7f20i2010 9t1935AM WWILE MEMO,* Vfile Operation Mode: ' no entry " • UPS Static Seritch I Status Mode: ' no enny • • Active Power P: ' no erdry • x 3 -. Operation Mode: ' no entry ' • LIPS Status Mode: • no Wry ' • Active Powes P: ' no why ' x 3 ■ Operation Mode ' no entry ' • UPS- 102 Status Mode • no ugly ' • Active Power P: ' no entry ' x 3 Operation Mode: ' no entry • , UPS 103 Status Mode: ' no witty ' • Active Power P: ' no entry • x 3 Operation Mode: ' no entry ' Status Mode: • no entry ' Active Power P: ' no entry • • UPS - 104 I • x Operation Mode: Normal Status Mode: Safe Active Powet P. 290.0 kW Operation Mode: Normal Status Mode: Safe Active Power P 73.0 kW LiliS Stthkswech • I x 3 • Modnie 1' I • x Operation Mode: Normal Status Mode: Safe Active Power P: 73.0 kW x 3 ■ Demotion Mode: Normal Status Mode: Sate • Active Power P 75.0 kW x 3 Operation Mode: Normal Status Mode: Sate Active Power P. 75.0 kW UPS Modtde 2, I •UPS Module 3 I IF UPS-Ittodnie4 I x 3 iiPs'Ait: I mot maiul PREVIOUS e nTe r 11,1 esEcuziri souniotsis • • • • L� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Section of PToccdure Intorrndlion Rncedraerrtle: INTERNAP- TUK- WA- CX -CRAC - .. Submittal Date: 18 May 10 y Procedure Work Date: - 7/14/2010 Procedure Work Time Frame: 0800 -1700 customer Name: - Intemap Customer's Salomon P cyecr Code. Address: Street Address: 3355 South 120 Place City: VP: Tukwila WA 98168 CustomerPOC: Customer POC Name: Kathy Mclnvale Phone Numbers: Me: 404.302.9753 Mobile: 404.547.8915 Lee Technologies commissioning Su.ervisor: Herbert Burnett Phone Numbers: Phone Number. 703 - 968-0300 Mobile: 713.423.4335 Pager Section 02 Equipment System Checklist for CRAC # 3 -1 p Y . Prnc,:rLire 0W2IVI„N Affected Area: Systems Affected: Equipment Information: Manufacturer. Stutz Equipment Type: CRAC Model N: VFS- 240 -DG -D Serial #: 10190035 Procedure Overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Requirements: Pre-Procedure Manufacturers start up complete and all discrepancies corrected or noted for future correction. Section 03 Pmcochao Detak; Detailed Procedure Detailed Procedure: Con e 1. Verify calibration of ALL sensors 1 2. Verify Refrigeration piping has been hydrostatically tested. 3. Verify Glycol piping has been hydrostatically tested 4. Verify all piping connections are tight and complete 5. Verifyrefrigerant has been properly charged. X 6. Verify fan operation and proper rotation. ' 7. Verify coil surfaces are free of obstructions, dirt or blocked fins. / 8. Verify fan motors are securely mounted. / 9. Verify fan motor bearings are in good condition. 10. Visually inspect all piping. NOTE ANY DISCREPENCIES in comment section. ✓ Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 5 L/I. LEE TECHNOLOGIES" t • • LEVEL 4 CHECKLIST 11. Verify all piping is secure. V 12. Verify condensate piping connected ✓ 13. Verify that Head Pressure Regulating Valve is installed. V' 14. Check all electrical connections (tighten as necessary), contacts and fuses. Note: Three units are operating in Lead configuration with the fourth operating In stand -by. When a CRAC shuts down the stand -by unit will start up. 15. At BMS enable the CRAC 16. At BMs simulate breeze -way temperature greater than 55° ✓ 16.1. Verify the CRAC is operational 16.2. Compressors operating v 16.3. Verify head pressure valve opens 17. Record the retum air temperature and humidity: Display Temp 71.2 Humidity 60.3 J Measured Temp 69.8 Humidity 48.7 17.1. Lower the temperature set point to the minimum value. ✓ 17.2. Measure and record return air temperature. V 17.3. Measure and record exhaust air temperature. 1 18. Raise the temperature set point to 10 degrees above ambient. 1 18.1. Measure and record retum air temperature. V 18.2. Measure and record exhaust air temperature. 19. Retum the temperature set point to normal. V 20. Check operation of the High temperature alarm by performing the following: 20.1. Lower the High Temperature set point below room temperature d 20.2. Verify the High Temperature alarm ✓ Template Rev. 07022010 Lee Technologies Group • © Copyright 2010 • Proprietary use pursuant to company policy. Page 2 of 5 • • • 4./1 LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 20.3. Verify alarm at BMS X 21. Check operation of the Low temperature alarm by performing the following:: 21.1. Raising the Low Temperature set point below room temperature ✓ 21.2. Verify the Low Temperature alarm 21.3. Verify alarm at BMS X 22. Check operation of the dirty filter switch by performing the following: 22.1. Place a sheet of cardboard over the filter intake so' /. is covered. V 22.2. Verify a CHANGE FILTER alarm. 1 22.3. Verify alarm at BMS X 23. Check operation of the fan safety switch by performing the following: 23.1. Pull the tube off the diaphragm switch. 23.2. Verify unit stops conditioning air. Fan continues to run 'f 23.3. Verify alarm 1 23.4. Verify alarm at BMS X 23.5. Reinstall tube onto fan failure switch. ./ 24. Close the top front cover. 1 25. Press RESET to clear all alarms: ✓ 26. Using UL tested smoke, spray test smoke into the smoke detector sample tube. 28.1. Verify FIRE alarm annunciates at local panel. ✓ 28.2. Unit shuts down ✓ 28.3. Verify alarm at BMS 28.4. Clear FIRE alarm. ✓ Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 5 • • • ‘ilk LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 27. Open the feeder breaker on the distribution panel. 27.1. Verify the unit shuts down. 27.2. Verify alarm at BMS 28. Close the feeder breaker. 28.1. Verify the unit starts up. ✓ 28.2. Verify the unit auto restarts. 29. Trip the unit's water detection sensor. NOTE 1 29.1. Remove front panels X 29.2.Tumunitoff. X 29.3. Place a wet rag in on the leak detector in unit. X 29.4. Start unit. Verify leak detection alarm. X 29.5. Verify unit displays a WATER alarm. X 29.6. Verify alarm at BMS 29.7. Verify unit shuts down X 30. Verify ALL set points have been returned to normal. 31. At BMS disable CRAC f 31.1. At BMS simulate breeze -way temperature lower than 55° f 31.2. Verify unit shuts down / 31.3. Compressors shut down d 32. Verify point at BMS 33. End of testing sectun oa Comments Comments Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 4of5 • • • 4./1 LEE TECHNOLOGIES` LEVEL 4 CHECKLIST Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/14/2010, the following was noted: Step 5. System 1 and 2 have bubble in the sight glass during operation of the compressor. Steps 20.3, 21.3, 22.3, and 23.4. BMS is receiving a General alarm, there are points on the graphics. BMS is not getting the signals from the MOD bus. Note 1 Leak Detect head is outside of the unit, the alarm is not received at the unit, only at BMS, the unit does not shutdown on a leak detect alarm. Section 0 Functional Tr .I Nlitness & Ve�ificalion Lee Technologies representative has witnessed or participated in this checklist, has verified equipment Is ready per checldist, and attests to the accuracy and completeness of this report. Printed Name: Trent Printz Signature: Date: 7/14/2010 Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 5 of 5 • • • L� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Section 01 Procedure Tide: Prom „,1110 INTERNAP TUK- WA- CX -CRAC into, ;,ion Submittal Date: 18 May 10 y Procedure Work Date: 7/14/2010 Procedure Work Time Frame: 0800 -1700 Customer Name: Intemap cuama,e/a Samman lamieci Coda Address: Street Address: 3355 South 120th Place City Sate. Zip: Tukwila WA 98188 Customer POC: Customer POC Name: Kathy Mclnvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning Su • ervisor. Herbert Burnett Phone Numbers: Phone Nwnb 703- 968 -0300 Mobile: 713.423.4335 Page sect'on 02 Equipment S stem Checklist for CRAC # 3 -2 System Procedni�; nvanfi;aLV Area: Systems Affected: Equipment information: Manufacturer Stutz Equipment Type: CRAC Model a: VFS- 240 -DG -D Serial #F: 10190037 Procedure Overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Resufts: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre Procedure Requirements: Manufacturers start up complete and all discrepancies corrected or noted for future correction. Section 03 Detailed Procedure Detailed P ocedun: camprete 1. Verify calibration of ALL sensors 2. Verify Refrigeration piping has been hydrostatically tested. 3. Verify Glycol piping has been hydrostatically tested ✓ 4. Verify all piping connections are tight and complete 5. Verify refrigerant has been properly charged. / 8. Verify fan operation and proper rotation. 7. Verify coil surfaces are free of obstructions, dirt or blocked fins. vf 8. Verify fan motors are securely mounted. ✓ 9. Verify fan motor bearings are in good condition. ^� 10. Visually inspect all piping. NOTE ANY DISCREPENCIES in comment section. Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 5 • • • LEE TECHNOLOGIES' L LEVEL 4 CHECKLIST 11. Verify all piping is secure. 12. Verify condensate piping connected 13. Verify that Head Pressure Regulating Valve is installed. `r 14. Check all electrical connections (tighten as necessary), contacts and fuses. 1 Note: Three units are operating in Lead configuration with the fourth operating in stand -by. When a CRAC shuts down the stand -by unit will start up. 15. At BMS enable the CRAC 16. At BMs simulate breeze -way temperature greater than 55° 'f 18.1. Verify the CRAC is operational ✓ 16.2. Compressors operating 16.3. Verify head pressure valve opens 17. Record the return air temperature and humidity: Display Temp 70.4 Humidity 52.4 V Measured Temp 69.8 Humidity 48.7 17.1. Lower the temperature set point to the minimum value. 'r 17.2. Measure and record retum air temperature. 17.3. Measure and record exhaust air temperature. ✓ 18. Raise the temperature set point to 10 degrees above ambient. / 18.1. Measure and record retum air temperature. 1 18.2. Measure and record exhaust air temperature. ✓ 19. Retum the temperature set point to normal. - 'f 20. Check operation of the High temperature alarm by performing the following: 3 , 20.1. Lower the High Temperature set point below room temperature ✓ 20.2. Verify the High Temperature alarm ✓` Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 5 • • 4,1 S° LEE TECHNOLOGIE LEVEL 4 CHECKLIST 20.3. Verify alarm at BMS X 21. Check operation of the Low temperature alarm by performing the following: 21.1. Raising the Low Temperature set point below room temperature ✓ 21.2. Verify the Low Temperature alarm 1 21.3. Verify alarm at BMS X 22. Check operation of the dirty filter switch by performing the following: 22.1. Place a sheet of cardboard over the filter intake so' is covered. v` 22.2. Verify a CHANGE FILTER alarm. 22.3. Verify alarm at BMS X 23. Check operation of the fan safety switch by performing the following: 23.1. Pull the tube off the diaphragm switch. 23.2. Verify unit stops conditioning air. Fan continues to run 23.3. Verify alarm ✓ 23.4. Verify alarm at BMS X 23.5. Reinstall tube onto fan failure switch. ✓ 24. Close the top front cover. ✓ 25. Press RESET to clear all alarms. 28. Using UL tested smoke, spray test smoke into the smoke detector sample tube. 28.1. Verify FIRE alarm annunciates at local panel. 1 28.2. Unit shuts down 1 28.3. Verify alarm at BMS f 28.4. Clear FIRE alarm. Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 3 of 5 • • • LEE TECHNOLOGIES' L LEVEL 4 CHECKLIST 27. Open the feeder breaker on the distribution panel. ✓ 27.1. Verify the unit shuts down. ✓ 27.2. Verify alarm at BMS ✓ 28. Close the feeder breaker. ✓ 28.1. Verify the unit starts up. ✓ 28.2. Verify the unit auto restarts. ✓ 29. Trip the unit's water detection sensor. kA 29.1. Remove front panels X 29.2. Tum unit off. X 29.3. Place a wet rag in on the leak detector in. unit. X 29.4. Start unit. Verify leak detection alarm. X 29.5. Verify unit displays a WATER alarm. X 29.6. Verify alarm at BMS 29.7. Verify unit shuts down X 30. Verify ALL set points have been retumed to normal. ✓ 31. At BMS disable CRAC ... ✓ 31.1. At BMS simulate breeze -way temperature lower than 55° ✓ 31.2. Verify unit shuts down ✓ 31.3. Compressors shut down 'r 32. Verify point at BMS ✓ 33. End of testing sF tton 04 Comments Corvr,m, Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 4 of 5 • • L� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/14/2010, the following was noted: Steps 20.3, 21.3, 22.3, and 23.4. BMS is receiving a General alarm, there are points on the graphics. BMS is not getting the signals from the MOD bus. Note 1 Leak Detect head is outside of the unit, the alarm is not received at the unit, only at BMS, the unit does not shutdown on a leak detect alarm. Section 05 Functional Tort Wit nos Verification Lee Technologies representative has witnessed or participated in this checklist, has verified equipment is ready per checklist, and attests to the accuracy and completeness of this report. Printed Name: Trent Printz Signetme: Date: 7/14/2010 Template Rev. D7022010 Lee Technologies Group 4 Copyright 2010 Proprietary use pursuant to company policy Page 5 of 5 • • L� LEE TECHNOLOGIES` LEVEL 4 CHECKLIST Section 01 Procedure Title: INTERNAP- TUK- WA- CX -CRAC Piocedure Infor m,,,-:ion Submittal Date: 18 May 10 _ Procedure Work Date: 7/14/2010 Procedure Work Time Frame: 0800 -1700 Customer Name: Intemap Customers Soloman Project Code Address: Street Address: 3355 South 120' Place City:' Zip: Tukwila WA 98168 CustomerPOC: Customer POC Name: Kathy Mclnvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning su . ervisoc Herbert Bumett Phone Numbers: Phone Number. 703- 968 -0300 Mobile: 713.423.4335 Pager. Section o= Equipment System Checklist for CRAC # 3 -3 q P Y Procedwe oven -feud Affected Area: Systems Affected: Equipment information: Manufacturer: Stutz Equipment Type: CRAG Model #: VFS- 240 -DG -D Serial #: 10190038 Procedure Overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre - Procedure Requirements: Manufacturers start up complete and all discrepancies corrected or noted for future correction. Section 03 Detailed Procedure P!oceduie Details Detailed Procedure: _ Complete 1. Verify calibration of ALL sensors v 2. Verify Refrigeration piping has been hydrostatically tested. w' 3. Verify Glycol piping has been hydrostatically tested 4. Verify all piping connections are tight and complete 5. Verify refrigerant has been properly charged. X 6. Verify fan operation and proper rotation. 7. Verify coil surfaces are free of obstructions, dirt or blocked fins. y` 8. Verify fan motors are securely mounted. 9. Verify fan motor bearings are in good condition. 10. Visually inspect all piping. NOTE ANY DISCREPENCIES in comment section. / Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 5 • • • /41 LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 11. Verify all piping is secure. ti 12. Verify condensate piping connected 13. Verify that Head Pressure Regulating Valve is installed. 14. Check all electrical connections (tighten as necessary), contacts and fuses. ,f Note: Three units are operating in Lead configuration with the fourth operating in stand -by. When a CRAG shuts down the stand -by unit will start up. 15. At BMS enable the CRAC / 16. At BMs simulate breeze -way temperature greater than 55 °` 16.1. Verify the CRAC is operational V 16.2. Compressors operating ,/ 16.3. Verify head pressure valve opens 17. Record the retum air temperature and humidity: Display Temp 70.4 Humidity 52.4 ✓ Measured Temp 69.8 Humidity 48.7 17.1. Lower the temperature set point to the minimum value. f, 17.2. Measure and record retum air temperature. 17.3. Measure and record exhaust air temperature. 7 18. Raise the temperature set point to 10 degrees above ambient. 18.1. Measure and record retum air temperature. 18.2. Measure and record exhaust air temperature. v- 19. Retum the temperature set point to normal. - 20. Check operation of the High temperature alarm by performing the following: 20.1. Lower the High Temperature set point below room temperature V 20.2. Verify the High Temperature alarm Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 5 • • L� LEE TECHNOLOGIES` LEVEL 4 CHECKLIST 20.3. Verify alarm at BMS X 21. Check operation of the Low temperature alarm by performing the following: 21.1. Raising the Low Temperature set point below room temperature 21.2. Verify the Low Temperature alarm 21.3. Verify alarm at BMS X 22. Check operation of the dirty filter switch by performing the following: 22.1. Place a sheet of cardboard over the filter intake so 9/. is covered. / 22.2. Verify a CHANGE FILTER alarm. 22.3. Verify alarm at BMS X 23. Check operation of the fan safety switch by performing the following: t" 23.1. Pull the tube off the diaphragm switch. t' 23.2. Verify unit stops conditioning air. Fan continues to run ✓ 23.3. Verify alarm 23.4. Verify alarm at BMS X 23.5. Reinstall tube onto fan failure switch. . 24. Close the top front cover. .f 25. Press RESET to dear all alarms. 26. Using UL tested smoke, spray test smoke into the smoke detector sample tube. 7 26.1. Verify FIRE alarm annunciates at local panel. t` 26.2. Unit shuts down 26.3. Verify alarm at BMS 26.4. Clear FIRE alarm. Template Rev. 07022010 Lee Technologies Group © Copyright2010 Proprietary use pursuant to company policy Page 3of5 • • • L� LEE TECHNOLOGIES" LEVEL 4 CHECKLIST 27. Open the feeder breaker on the distribution panel. 27.1. Verify the unit shuts down. / 27.2. Verify alarm at BMS ti 28. Close the feeder breaker. 28.1. Verify the unit starts up. ' 28.2. Verify the unit auto restarts. '1 29. Trip the unit's water detection sensor. 29.1. Remove front panels X 29.2. Turn unit off. X 29.3. Place a wet rag in on the leak detector in unit. X 29.4. Start unit. Verify leak detection alarm. X 29.5. Verify unit displays a WATER alarm. X 29.6. Verify alarm at BMS / 29.7. Verify unit shuts down X 30. Verify ALL set points have been retumed to normal. / 31. At BMS disable CRAC / 31.1. At BMS simulate breeze -way temperature lower than 55° 31.2. Verify unit shuts down / 31.3. Compressors shut down 32. Verify point at BMS ,r 33. End of testing Section 04 Comments coimmnts Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 4 of 5 • • • 4,11 LEE TECHNOLOGIES` LEVEL 4 CHECKLIST Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/14/2010, the following was noted: Step 5. System 1 has bubbles in the sight glass during operation of the compressor. Steps 20.3, 21.3, 22.3, and 23.4. BMS is receiving a General alarm, there are points on the graphics. BMS is not getting the signals from the MOD bus. Note 1 Leak Detect head is outside of the unit, the alarm is not received at the unit, only at BMS, the unit does not shutdown on a leak detect alarm. Section 05 Funclionnl Test Witness £. Verification Lee Technologies representative has witnessed or participated in this checklist, has verified equipment is ready per checklist, and attests to the accuracy and completeness of this report. Printed Name: Trent Printz Signature: Date: J 7/14/2010 Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 5of5 • • • L"1. LEE TECHNOLOGIES" LEVEL 4 CHECKLIST Section 01 Procedure Info,,rtaticc Procedure Tine: INTERNAP- TUK- WA- CX -CRAC 18 Ma y 10 Procedure Work Date: 7/14/2010 Procedure Work Time Frame: 0800 -1700 ubrnittal Date: Sub. Customer Name: I nternap Customers Solomon Project Code. Address: Street Address: 3355 South 120th Place City: State: . Zip: Tukwila WA 98168 CustomerPOC: customer POC Name: Kathy Mclnvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies commissioning Su • ervisor Herbert Burnett Phone Numbers: Phone Number: 703 -968 -0300 Mobile: 713.423.4335 Pager. ectaou r0Overvievd P Equipment System Checklist for CRAC # 3-4 Affected Area: Systems Affected: Equipment Information: Manufacturer: Stutz Equipment Type: CRAC Model # : VFS- 240 -DG -D Serial #: 10190036 Procedure Overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre-Procedure Requirements: Manufacturers start up complete and all discrepancies corrected or noted for future correction. Section 03 Detailed Procedure Procedure DEAF:1k Detailed Procedure: Complete 1. Verify calibration of ALL sensors v' 2. Verify Refrigeration piping has been hydrostatically tested. 3. Verify Glycol piping has been hydrostatically tested ✓ 4. Verify all piping connections are tight and complete 5. Verify refrigerant has been properly charged. X 6. Verify fan operation and proper rotation. 7. Verify coil surfaces are free of obstructions, dirt or blocked fins. 8. Verify fan motors are securely mounted. 9. Verify fan motor bearings are in good condition. V 10. Visually inspect all piping. NOTE ANY DISCREPENCIES in comment section. Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 5 • • • LEE TECHNOLOGIES'" LEVEL 4 CHECKLIST 11. Verify all piping is secure. ,r 12. Verify condensate piping connected 13. Verify that Head Pressure Regulating Valve is installed.' 14. Check all electrical connections (tighten as necessary), contacts and fuses. Note: Three units are operating in Lead configuration with the fourth operating in stand -by. When a CRAC shuts down the stand -by unit will start up. = 7h' 15. At BMS enable the CRAC 16. At BMs simulate breeze -way temperature greater than 55° 16.1. Verify the CRAC is operational 16.2. Compressors operating 16.3. Verify head pressure valve opens 17. Record the retum air temperature and humidity: Display Temp 70.4 Humidity 52.4 Measured Temp 69.8 Humidity 48.7 17.1. Lower the temperature set point to the minimum value. 17.2. Measure and record return air temperature. 17.3. Measure and record exhaust air temperature. 18. Raise the temperature set point to 10 degrees above ambient. / 18.1. Measure and record retum air temperature. xr 18.2. Measure and record exhaust air temperature. 19. Retum the temperature set point to normal. 20. Check operation of the High temperature alarm by performing the following: ,. 20.1. Lower the High Temperature set point below room temperature 20.2. Verify the High Temperature alarm Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2of5, • • • L� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 20.3. Verily alarm at BMS 21. Check operation of the Low temperature alarm by performing the following: 21.1. Raising the Low Temperature set point below room temperature y' 21.2. Verify the Low Temperature alarm 21.3. Verify alarm at BMS ' 22. Check operation of the dirty filter switch by performing the following: 22.1. Place a sheet of cardboard over the filter intake so 3A is covered. �r 22.2. Verify a CHANGE FILTER alarm. Y` 22.3. Verify alarm at BMS 23. Check operation of the fan safety switch by performing the following: 23.1. Pull the tube off the diaphragm switch. 23.2. Verify unit stops conditioning air. Fan continues to run J 23.3. Verify alarm "{ 23.4. Verify alarm at BMS / 23.5. Reinstall tube onto fan failure switch. w' 24. Close the top front cover. 25. Press RESET to clear all alarms. 26. Using UL tested smoke, spray test smoke into the smoke detector sample tube. 26.1. Verify FIRE alarm annunciates at local panel. ✓` 26.2. Unit shuts down v 26.3. Verify alarm at BMS u 26.4. Clear FIRE alarm. Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 5 • • • L� S° LEE TECHNOLOGIES LEVEL 4 CHECKLIST 27. Open the feeder breaker on the distribution panel. 27.1. Verify the unit shuts down. 27.2. Verify alarm at BMS 28. Close the feeder breaker. 28.1. Verify the unit starts up. sz 28.2. Verify the unit auto restarts. tir 29. Trip the unit's water detection sensor. NOTE 1 l l.: 29.1. Remove front panels X 29.2. Turn unit off. - X 29.3. Place a wet rag in on the leak detector in unit. X 29.4. Start unit. Verify leak detection alarm. X. 29.5. Verify unit displays a WATER alarm. X 29.6. Verify alarm at BMS ,/ 29.7. Verify unit shuts down X 30. Verify ALL set points have been returned to normal. .f 31. At BMS disable CRAC Y' 31.1. At BMS simulate breeze -way temperature lower than 55° sr 31.2. Verify unit shuts down - 31.3. Compressors shut down ^`r 32. Verify point at BMS 33. End of testing section 04 Comments COItunonts Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 4 of 5 • • • L!". LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/14/2010, the following was noted: Step 5. System 1 has bubbles in the sight glass during operation of the compressor. BMS is receiving a General alarm, there are points on the graphics. BMS is not getting the signals from the MOD bus. Note 1 Leak Detect head is outside of the unit, the alarm is not received at the unit, only at BMS, the unit does not shutdown on a leak detect alarm. Section O Functional Tess Witness & Veti(ication Lee Technologies representative has witnessed or participated in this checklist, has verified equipment is ready per checklist, and attests to the accuracy and completeness of this report. Printed Name: Signature Date: Trent Printz 7/14/2010 Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 5 of 5 • • • All LEE TECHNOLOGIES' LEVEL 4 CHECKLIST _.. 'Section DI Rocedure Tine: F'=- ;;' °" INTERNAP TUK WA- CX-DRY COOLER 1I0 :). , ,,ll,,,, .. _ Submittal Date: 18 May 10 Procedure Work Date: 7/14/2010 Procedure Work rme Freme: 0800-1700 Customer Name: Intemap cusb Salomon Project coda. Address: Street Address: 3355 South 120th Place City Ste: Zip: Tukwila WA 98168 CustomerPoC: Customer poc Marne: Kathy Mclnvale Phone Numbers: owe: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning Herbert Burnett Phone Numbers: MOM Number: 703 -968 -0300 Mobile: 713.423.4335 taper. `-'''= Equipment System Checklist for DC 3 -1 Affected Area I Systems Affected: Equipment Information :. Manufacturer - Gunter E9rdpment TYPE,: Dry Cooler Model It SGP08- 0350MLNAUBNNN -N- 002 Serials: 256035.0001 Procedure Overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre- Procedure Requirements: Manufacturers start up complete and all discrepancies corroded or noted for future correction. S .ion - Detailed Procedure Detailed Procedure: Ccmpleb3 1. Verify calibration of all sensors 2. Verify clearances for service access has been maintained around Dry Coolers set 3. Verify power wiring completed to disconnect switch including ground. '' 4. Verify power line circuit breakers or fuses have proper rating to equipment installed. . 5. Verify Glycol piping has been flushed. 5.1. Obtain copy of test and attach with commissioning document ✓ 6. Verify Glycol piping hydrostatically tested. 6.1. Obtain copy of test and attach with commissioning document 7. Verify the following: `' 7.1. Fan operation ,. 7.2. Fan rotation "y 8. Verify that coil surfaces are free of obstructions, dirt or blocked fins 9. Verify Glycol added to prevent freezing. Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 4 • • • L� LEE TECHNOLOGIEr LEVEL 4 CHECKLIST 10. Verify fan motors are securely mounted - / 11. Verify fan motor bearings are in good condition aF 12. Visually inspect all piping 13. The following will verify the operation and staging of the dry cooler 14. Record outside air temperature: 68.3 °F ' 15. Verify fans are operating Note: Verify the temperature set point of the thermostat has been marked 16. Record setting of the thermostat 50% ✓ 17. Adjust thermostat up to allow fans to stage down 18. Verify the following: ' " 18.1. First set of fans stage off at 44 % 18.1.1. 7 and 8 shut off 18.12. Glycol temperature at BMS 71 °F °' 18.2. Second set of fans stage off at 46 % ' 18.2.1. 5 and 6 fans shut off - 18.2.2. Glycol temperature at BMS 71 °F / 18.3. Third set of fans stage off at 48 % / 18.3.1. 3 and 4 fans shut off 18.3.2. Glycol temperature at BMS 71 °F 18.4. All fans stage off at 50 % ✓ 18.4.1. 1 to 2 fans shut off 18.4.2. Glycol temperature at BMS 71 °F 19. Slowly retum thermostat to set point verify at each temperature the fans stage up. 20: Verify the following: 20.1. No leaks 20.2. Unusual noises v 21. Verify fan monitoring active v 22. Open the breaker for fan 1 y' 23. Verify the following: , , 23.1. Fan 1 stops Template Rev. 07022010 Lee Technologies Group Copyright 2010 Proprietary use pursuant to company policy Page 2 of 4 L� LEE TECHNOLOGIES` 1111 • • LEVEL 4 CHECKLIST 23.2. Verify BMS holds fan status 24. Open the breaker for fan, 2 25. Verify the following` ` 25.1. Fan 2 stops / 25.2. Verify BMS holds fan status 26. Open the breaker for fan 3 27. Verify the following: yY 11T 27.1. Fan 3 stops �,. 27.2. Verify BMS holds fan status ✓ 28. Open the breaker for fan 4 v 29. Verify the following: yki.�4 �x•:fN:�. 29.1. Fan 4 stops '` 29.2. Verify BMS holds fan status y' 30. Open the breaker for fan 5 31. Verify the following :7 31.1. Fan 5 stops 31.2. Verify BMS holds fan status 32. Open the breaker for fan 6 f 33. Verify the following 33.1. Fan 6 stops 33.2. Verify BMS holds fan status 34. Open the breaker for fan 7 35. Verify the following: _ w 35.1. Fan 7 stops ✓ 35.2. Verify BMS holds fan status 36. Open the breaker for fan 8 ✓ 37. Verify the following: :_.. 37.1. Fan 8 stops 37.2. Verify BMS holds fan status 38. Place all breakers for the fans in the on position -i Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 3 of 4 • • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 39. Verify points at BMS 40. Place system in normal operating mode 41. End of test s�ctior. o c,., ,, cote Comments Insert any comments applicable to the checldist: Conducted Level 4 testing on 7/14/2010, the following was noted: Fan 4 has heavy vibration during operation. The Dry Coolers do not have a flow switch, this will allow the fans to operate when there is water flowing. BMS does not start or stop the units. ,, :.,,,,I , s mt_•s:, s v:- nnNOOn Lee Technologies representative has witnessed or participated in this checldist, has verified equipment Is ready per and attests to the accuracy and completeness of this report. Rioted Name: signature: fie: checldist, Trent Pnntz !!r, "f %i °'p 7/14/2010 if; Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 4 of 4 • • L� LEE TECHNOLOGfES° LEVEL 4 CHECKLIST Procedure Title: '° "F''1,11 ` iNTERNAP TUK- WA -CX -DRY COOLER Submittal Date: 18 May 10 Procedure WoNc per: 7/14/2010 Procedure Work Time Frame: 0800 -1700 Customer Name: Intemap Customer's Solomon Project Code. Address: skeet Address: 3355 South 120th Place City: state: Zia: Tukwila WA 98168 CustomerPOC: Customer POC Name: Kathy Mdnvale Phone Numbers: tee; 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning Su • rvisor. Herbert Burnett Phone Numbers: Phone Number. 703 - 968 -0300 Mobile: 713.423.4335 Paper °;' Equipment. System Checklist for DC 3 -2 ,�� ;" _, „ Affected Area: Systems Affected: Equipment information: Manufacturer Gunter Equipment Type Dry Cooler Madera: SGP08- 0350MLNAUBNNN -N- 002 Serial tt: 256035.0002 procedure overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results:, Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre- Procedure Requirements: Manufacturers start up complete and all discrepancies corrected or noted for future correction. c .Dr, 03 �.oc.zduio D< -.,cis Detailed Procedure Detailed Procedure: °orna�B 1. Verify calibration of all sensors 2. Verify dearances for service access has been maintained around Dry Coolers 3: Verify power wiring completed to disconnect switch including ground. 4. Verify power line circuit breakers or fuses have proper rating to equipment installed. 5. Verify Glycol piping has been flushed. 5.1. Obtain copy of test and attach with commissioning document 6. Verify Glycol piping hydrostatically tested. 6.1. Obtain copy of test and attach with commissioning document "` 7. Verify the following: 7.1. Fan operation 7.2. Fan rotation 8. Verify that coil surfaces are free of obstructions, dirt or blocked fins ,r 9. Verify Glycol added to prevent freezing. Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 4 • • • L� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 10. Verify fan motors are securely mounted 11. Verify fan motor bearings are in good condition / 12. Visually inspect all piping _ •1 13. The following will verify the operation and staging of the dry cooler r 14. Record outside air temperature: 68.3 °F r 15. Verify fans are operating 'r Note: Verify the temperature set point of the thermostat has been marked z `= 16. Record setting of the thermostat 50% -' 17. Adjust thermostat up to allow fans to stage down ' 18. Verify the following: ; 4 r £ 18.1. First set of fans stage off at 44 % 18.1.1. 7 and 8 shut off 18.1.2. Glycol temperature at BMS 71 °F y 18.2. Second set of fans stage off at 46 % 18.2.1. 5 and 6 fans shut off ` 18.2.2. Glycol temperature at BMS 71 °F 17 18.3. Third set of fans stage off at 48 % Y` 18.3.1. 3 and 4 fans shut off X 18.3.2. Glycol temperature at BMS 71 °F ✓ 18.4. All fans stage off at 50 % 18.4.1. 1 to 2 fans shut off L 18.4.2. Glycol temperature at BMS 71 °F 19. Slowly retum thermostat to set point verify at each temperature the fans stage up. °f 20. Verify the following: 20.1. No leaks r 20.2. Unusual noises 1r 21. Verify fan monitoring active ✓ 22. Open the breaker for fan 1 7 23. Verify the following: 23.1. Fan 1 stops Template Rev. 07022010 Lee Technologies Group Copyright 2010 Proprietary use pursuant to company policy Page 2 of 4 • • • L� S° LEE TECHNOLOGIEr LEVEL 4 CHECKLIST 23.2. Verify BMS holds fan status 24. Open the breaker for fan 2 / 25. Verify the following: 'Ivh 25.1. Fan 2 stops ✓ 25.2. Verify BMS holds fan status 'J • 26. Open the breaker for fan 3 27.. Verify the following: ; 27.1. Fan 3 stops X 27.2. Verify BMS holds fan status X 28. Open the breaker for fan 4 29. Verify the following: _ s f 29.1. Fan 4 stops X 29.2. Verify BMS holds fan status X 30. Open the breaker for fan 5 / 31. Verify the following: 31.1. Fan 5 stops 31.2. Verify BMS holds fan status 32. Open the breaker for fan 6 33. Verify the following: 33.1. Fan 6 stops / 33.2. Verify BMS holds fan status v" 34. Open the breaker for fan 7 35. Verify the following: __..; 1�;z��:� ; �.; 35.1. Fan 7 stops 35.2. Verify BMS holds fan status "x 36. Open the breaker for fan 8 ' y 37. Verify the following: 37.1. Fan 8 stops 37.2. Verify BMS holds fan status 38. Place all breakers for the fans in the on position Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 3 of 4 • • • LEE TECHNOLOGIES" L LEVEL 4 CHECKLIST 39. Verify points at BMS 40. Place system in normal operating mode V 41. End of test s_c..c_0 __ Comments Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/1412010, the following was noted: Steps 18.3, 27 and 28. Fans 3 and 4 are not operating, breakers are on. The contactors are not pulling in. The Dry Coolers do not have a flow switch, this will allow the fans to operate when there is water flowing. BMS does not start or stop the units. sec icn, o=. _,:,,, ,E.,,,,, 1 Test :.: \I; ,I, ,4Ktl, Lee Technologies representative has witnessed or participated in this checidist, has verified equipment is ready per checldist, and attests to the accuracy and completeness of this report. Printed Name: Signature: fie: �IIAV� �— 7/14/2010 Trent Printz � Ao ∎/rRV' , r ; Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 4 of 4 • • • �� LEE TEGNNOlOGIES° LEVEL 4 CHECKLIST Procedure Thle: Section 0 Proce :lic INTERNAP-TUK-WA-CX-TRANSFER FAN Submittal Date: 18 May 10 y Procedure Work Date: 7/17/2010 Procedure Work Time Frame: 0800 -1700 Customer Name: - _ - - Intemap Customers Salomon Project code. Address. Street Address: 3355 South 120th Place Cdyy state: Zip: Tukwila WA 98168 CustomerP°C: Customer POC Name: Kathy Mcinvale Phone Numbers: 0/fiae:. 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning Su • = .visor. Herbert Burnett Phone Numbers: Phone Number 703- 968 -0300 Mobile: 713.423.4335 Pager s`,t °'=' Equipment System Checklist for TRANSFER FAN # TF -3T -1 Affected Area: Systems Affected: 1 Equipment Information: Manufacturer Greenheck Equipment Type: Transfer Fan Model0: BDF- 180- 20 -BH-X Serial a: 12053695 1004 Procedure Overview: This testing will verity equipment is started up correctly in accordance with manufacturer -specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre- Procedure Requirements: Manufacturers start up complete and all discrepancies corrected or noted for future correction. ``= i n `33 Detailed Procedure Detailed Procedure: 1. Manufacturer's start up complete / 2. Manufacturer Rep present. v. 3. Breaker Panel location attached 4. Fan Name Plate Volts 460 5. Fan Name Plate Amps 2.7 y' 6. Motor HP 2HP 7. Motor Phase 3 "r 8. Fan RPM 629 9. Lubrication and belt adjustment complete 10. Fan Belt Size: AX63 Quantity: 1 v 11. Unit Clean and free of debris 12. Check that fan rotates freely 13. Verify controls are complete and operational / Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 4 • • • &/411 LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 14. Start Unit at the local BMS controls 1' 15. Verify space damper opens 16. Verify correct fan rotation ' 17. Perform a visual check of the equipment 17.1. Unusual noise V 17.2. Signs of deterioration f 18. Verify BMS Graphics 19. Verify VFD has been tested by Manufacturer Y' 20. At local VFD control panel operate the VFD through the following test points NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step Y; k 20.1. MIN 20Hz 0.8A ' 20.2. 50% 30.0Hz 1.3A ''' 20.3. 75% 45.0Hz 2.2A 20.4. 100% 60.0Hz 3.4A X 21. Once 100% is reached and the unit has been inspected and stabilized, operate the VFD through the following test points. - NOTE: Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step j° =- Y , 21.1. 75% 45.0Hz 2.1A 21.2. 50% 30.0Hz 1.3A w 21.3. MIN 20.0Hz 0.8A 22. Retum the VFD to BMS control 23. Verify BMS Graphics 24. At BMS operate the VFD through the following test points .Y 24.1. MIN 20.0Hz 0.8A 33.3% V" 24.2. 50% 29.9Hz 1.3A 49.8% 24.3. 75% 45.0Hz 2.2A 74.8% 24.4. 100% 60.0Hz 3.4A 100.0% X 25. Once 100% is reached and the unit has been inspected and stabilized, operate the VFD through the following test points. NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step x ; ; 25.1. 75% 44.9Hz 2.1A 74.8% 25.2. 50% 29.9Hz 1.3A 49.8% Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 2 of 4 • %It LEE TECHNOLOGIES' ‘11./ LEVEL 4 CHECKLIST. 25.3. MIN 20.0Hz 0.8 33.3% 26. Verify BMS Graphics Note: Transfer fans operate as Lead and Lag configuration Following will test the operation of the Lead/Lag configuration 27. Verify at BMS Transfer Fan line up 28. At BMS start the Lead Fan -."- 29. Verify the following: 29.1. Space Damper opens 29.2. Lead Transfer Fan activates Transfer Fan power failure 30. Open Transfer Fan Disconnect or Breaker 30.1. Verify the following ,..-:;_•*.:-.' '' 30.1.1. Lead Transfer Fan shut off 30.1.2. Space Damper shuts 30.1.3. Alarm received at BMS . vi 30.1.4. Space Damper opens 30.1.5. Lag Transfer Fan activates / 31. Close Lead Transfer Fan Disconnect or Breaker i 31.1. Verify the following 31.1.1. Lag Transfer Fan stops v!" 31.1.2. Lead transfer Fan starts ,.. 31.1.3. Alarm dears at BMS 31.1.4. Lead Transfer Fan ramps up to match Lag Fan 31.1.5. Lag Fan ramps down 31.1.6. Lag Fan shuts down - Transfer Fan staging . ._. 32. At BMS lower space air temperature set point below space temperature v , 33. Verify the following: 33.1. Lead Transfer Fan VFD ramps up to or above 75% ./ 33.2. Lag Transfer Fan activates ,/ Template Rev. 07022010 Lee Technologies Group Copyright 2010 Proprietary use pursuant to company policy Page 3 of 4 • • • LEE TECHNOLOGIES" LEVEL 4 CHECKLIST 33.3. Lead and Lag fan VFD's match % and increase as needed 33.4. Verify BMS graphics 33.5. Verify the following: 33.5.1. Unusual noise 33.5.2. Signs of deterioration 34. Verify the Dirty Space Filter status alarm 34.1. Simulate a dirty filter by covering % the fitter with cardboard. #' 34.2. Verify alarm received at BMS 34.3. Clear space Dirty Filter alarm 34.4. Verify alarm Geared at BMS 35. At BMS reset space air temperature set point below 35.1. Lag Transfer Fans stop 35.2. Lag Transfer Fan dampers shut 36. Restore Transfer Fan and sensors to normal operations 37. Verify BMS Graphics 38. End of test Sects °n , Comments Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/17/2010, the following was noted. Permanent unit identification labeling has not been attached to the fan. Step 20.4 and 24.4. The fan motors are running above FLA as read at the VFD. Sect;cn ]E F,,,,c',,,,,,; '-'-'3' w;,;,.., :,, Vmificra,en Lee Technologies representative has witnessed or participated in this cheddst, has verified equipment is ready per checklist, and attests to the accuracy and completeness of this report. Printed Name: Signature: Age. Trent Prirttz /'4s' 'sL1.�.1_ 7/17/2010 r Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy. Page 4 of 4 L� LEE TECHNOLOGIES' • • LEVEL 4 CHECKLIST Seciicr, 01 .Ptoc�edureTitle: 1,.,,,,,i; "" INTERNAP- TUK- WA-CX- TRANSFER FAN IrEcIri,,i1 ,1 Submittal Date: 18 May. 10 Procedure Work Date: 7/17/2010 Procedure Work rme Frame: 0800 -1.700 Customer Name: Intemap Customers Solari Project C. Address: SbeetAddress:. 3355 South 120th Place City: . Site Zip: Tukwila WA 98168 CustomerPOC: Customer POC Alain: Kathy Mclnvale Phone Numbers: Orrice: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissloning Su : rvisor. Herbert Burnett Phone Numbers: Phone Number: 703 - 968 - 0300 Mobile: 713.423.4335 Page Section Cc_ Prncrdw, Qrr:•;F r. Equipment System Checklist for TRANSFER FAN # TF -3T -2 Affected area: I Systems affected: Equipment Information: Manufacturer: Greenheck Equipment Type: Transfer Fan Models: BDF- 180- 20 -BH -X Serialtt: 12053696 1004 Procedure overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Antclpated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre- Procedure Requirements: Manufacturers start up complete and all discrepancies corrected or noted for future correction. 5e = =�,, c= P1 is C—,:: '4.," D,LIIK; Detailed Procedure Defected Rocedme: Complete 1. Manufacturers start up complete 2. Manufacturer Rep present 3. Breaker Panel location attached 1 4. Fan Name Plate Volts 460 5. Fan Name Plate Amps 2.7 6. Motor HP 2HP V 7. Motor Phase 3 `` 8. Fan RPM 629 9. Lubrication and belt adjustment complete f 10. Fan Belt Size: AX63 Quantity: 1 11. Unit Clean and free of debris .. 12. Check that fan rotates freely 13. Verify controls are complete and operational r. Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 4 LEE TECHNOlOG1ES•t./ • LEVEL 4 CHECKLIST 14. Start Unit at the Iocal BMS controls 15. Verify space damper opens 16. Verify correct fan rotation ',` 17. Perform a visual check of the equipment 17.1. Unusual noise V 17.2. Signs of deterioration` 18. Verify BMS Graphics 19. Verify VFD has been tested by Manufacturer 20. At Iocal VFD control panel operate the VFD through the following test points NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step a:. 20.1. MIN 20Hz 0.8A 20.2. 50% 30.0Hz 1.3A ✓ 20.3. 75% 45.0Hz 2.1A 20.4. 100% 60.0Hz 3.4A X 21. Once 100% is reached and the unit has been inspected and stabilized, operate the VFD through the following test points. NOTE: Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step. 21.1. 75% 45.0Hz 2.1A 21.2. 50% 30.0Hz 1.3A 21.3. MIN 20.0Hz 0.8A 22. Retum the VFD to BMS control 23. Verify BMS Graphics 24. At BMS operate the VFD through the following test points 24.1. MIN 20.0Hz 0.8A 33.3% / 24.2. 50% 29.8Hz 1.3A 49.7% ✓ 24.3. 75% 45.0Hz 2.2A 74.8% 24.4. 100% 60.0Hz 3.4A 100.0% X 25. Once 100% is reached and the unit has been inspected and stabilized, operate the VFD through the following test points. NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step 4: 25.1. 75% 45.0Hz 2.2A 75.0% y 25.2. 50% 29.8Hz 1.3A 49.7% .7 Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 2 of 4 • • • LE TECHNOLOGIES' L LEVEL 4 CHECKLIST 25.3. MIN 20.0Hz 0.8 33.3% 26. Verify BMS Graphics: Note: Transfer fans operate as Lead and Lag configuration r F Following will test the operation of the Lead/Lag configuration 27. Verify at BMS Transfer Fan line up 28. At BMS start the Lead Fan 29. Verify the following: , 29.1. Space Damper opens 29.2. Lead Transfer Fan activates Transfer Fan power failure v.� 30. Open Transfer Fan Disconnect or Breaker 30.1. Verify the following 30.1.1. Lead Transfer Fan shut off / 30.1.2. Space Damper shuts 30.1.3. Alarm received at BMS 30.1.4. Space Damper opens F 30.1.5. Lag Transfer Fan activates Y! 31. Close Lead Transfer Fan Disconnect or Breaker b` 31.1. Verify the following 31.1.1. Lag Transfer Fan stops 31.1.2. Lead transfer Fan starts *' 31.1.3. Alarm clears at BMS 31.1.4. Lead Transfer Fan ramps up to match Lag Fan Y' 31.1.5. Lag Fan ramps down v 31.1.6. Lag Fan shuts down ./ Transfer Fan staging 32. At BMS lower space air temperature set point below space temperature Y' 31 Verify the following: 33.1. Lead Transfer Fan VFD ramps up to or above 75% 33.2. Lag Transfer Fan activates ✓ Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 4 • • • LEE TECHNOLOGIES' 16,/ LEVEL 4 CHECKLIST 33.3. Lead and Lag fan VFD's match % and increase as needed 33.4. Verify BMS graphics 33.5. Verify the following: , >.m `i. 33.5.1. Unusual noise 33.5.2. Signs of deterioration 34. Verify the Dirty Space Filter status alarm 34.1. Simulate a dirty fitter by covering 3A the filter with cardboard 34.2. Verify alarm received at BMS , 34.3. Clear space Dirty Filter alarm 34.4. Verify alarm deared at BMS / 35. At BMS reset space air temperature set point below - y' 35.1. Lag Transfer Fans stop `+ 35.2. Lag Transfer Fan dampers shut 36. Restore Transfer Fan and sensors to normal operations ,< 37. Verify BMS Graphics _ -/ 38. End of test 5= ctlon' =u Comments COMM, Ill, Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/17/2010, the following was noted. Permanent unit identification labeling has not been attached to the fan. Step 20.4 and 24.4. The fan motors are running above FLA as read at the VFD. Section 05 checidist, _,,,':; ,,!::,! e`1 Lee Technologies representative has witnessed or participated in this checklist, has verified equipment is ready per vv ,,,,.;s;. and attests to the accuracy artd completeness of this report. Vert(,ci-An;u Panted Mane: Signature: Date: Trent Printz ► �%�/f /_I - 7/17/2010 goy • • . V % Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 4 of 4 • • • L� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Section J1 Procedure Title: `luce.J.he INTERNAP- TUK- WA-CX- TRANSFER FAN II1Jf ",<ii.,,, Submittal Date: 18 May 10 Procedure Wcrlr per. 7/10/2010 Procedure Work Time Frame: 0800-1700 Customer Name: Intemap Customer's Solomon Project code. Address: Street Address:. 3355 South 120th Place City sate. NV Tukwila WA 98168 CustomerPOC: Custamer POC Name: Kathy Mclnvale Phone Numbers: office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning su • 4visor. Herbert Bumett Phone Numbers: Phone Number: 703- 968 - 0300 Mobile: 713.423.4335 Pager sc,`'°,„'='� PI ncnri::rr Grri Equipment System Checklist for TRANSFER FAN # TF 3U -1 Affected Area: I Systems Affected: Equipment information: Manufacturer: Greenneck Equipment Type: Transfer Fan Mode s: BDF- 200 - 100 -BHX Serial is 12053699 1004 Procedure oven/iew: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre equProcedure R irements: Manufacturers start up complete and all discrepancies corrected or noted for future correction. s - = -_ ? =' Detailed. Procedure Detailed Procedure: I complete 1. Manufacturers start up complete / 2. Manufacturer Rep present 3. Breaker panel location attached / 4. Fan Name Plate Volts 460 5. Fan Name Plate Amps 12.5 6. Motor HP 10 HP ._. ✓ 7. Motor Phase 3 8. Fan RPM 746. 9. Lubrication and belt adjustment complete 10. Fan Belt Size: AP87 Quantity: 1 *' 11. Unit Clean and free of debris 12. Check that fan rotates freely 13. Verify controls are complete and operational Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 4• • • • L� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 14. Start Unit at the local BMS controls 15. Verify space damper opens 16. Verify correct fan rotation 17.. Perform a visual check of the equipment x ' 17.1. Unusual noise r 17.2. Signs of deterioration 18. Verify BMS Graphics 19. Verify VFD has been tested by Manufacturer s/ 20. At local VFD control panel operate the VFD through the following test points NOTE: Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step 20.1. 25% 15.0Hz 2.6A v` 20.2. 50% 30.0Hz 5.2A 20.3. 75% 45.0Hz 8.0A _� 20.4. 100% 60.0Hz 12.1A 21. Once 100% is reached and the unit has been inspected and stabilized, operate the VFD through the.ri P 9 following test points. . NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step . t sq 21.1. 75% 45.0Hz 8.0A 21.2. 50% 30.0Hz 5.2A 21.3. 25% 15.0Hz 2.7A 22. Retum the VFD to BMS control 23. Verify BMS Graphics 24. At BMS operate the VFD through the following test points z" ` , 24.1. 25% 20Hz 3.4A 33.3% "{ 24.2. 50% 29.811z 5.2A 49.7% 24.3. 75% 45.0Hz 8.0A 75.0% 24.4. 100% 59.9Hz 11.8A 99.8% 25. Once 100% is reached and the unit has been inspected and stabilized, operate the VFD through the following test points. NOTE: Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step "} 4 ' r A r 25.1. 75% 45.0Hz 7.9A 75.0% 25.2. 50% 29.8Hz 5.0A 49.7% Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 4 • • • L/� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 25.3. 25% 20.0Hz 3.4A 33.3% 26. Verify BMS Graphics Note: Transfer fans operate as Lead and Lag configuration Following will test the operation of the Lead/Lag configuration 27. Verify at BMS Transfer Fan line up ve 28. At BMS start the Lead Fan 29. Verify the following: 29.1. Space Damper opens V 29.2. Lead Transfer Fan activates Transfer Fan power failure 30. Open Transfer Fan Disconnect or Breaker 30.1. Verify the following ` ,� 30.1.1. Lead Transfer Fan shut off y 30.1.2. Space Damper shuts v 30.1.3. Alarm received at BMS 30.1.4. Space Damper opens 30.1.5. Lag Transfer Fan activates v 31. Close Lead Transfer Fan Disconnect or Breaker 31.1. Verify the following 31.1.1. Lag Transfer Fan stops 31.1.2. Lead transfer Fan starts r 31.1.3. Alarm dears at BMS 31.1.4. Lead Transfer Fan ramps up to match Lag Fan 31.1.5. Lag Fan ramps down '/ 31.1.6. Lag Fan shuts down Transfer Fan staging `' 32. At BMS lower space air temperature set point below space temperature v' 33. Verify the following: 33.1. Lead Transfer Fan VFD ramps up to or above 75% 33.2. Lag Transfer Fan activates Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 4 • • • LEE TECHNOLOGIES' L LEVEL 4 CHECKLIST 33.3. Lead and Lag fan VFD's match % and increase as needed 33.4. Verify BMS graphics 33.5. Verify the following: 33.5.1. Unusual noise 33.5.2. Signs of deterioration 34. Verify the Dirty Space Filter status alarm < 34.1. Simulate a dirty fitter by covering $ the filter with cardboard X 34.2. Verify alarm received at BMS X 34.3. Clear space Dirty Filter alarm X 34.4. Verify alarm cleared at BMS X 35. At BMS reset space air temperature set point below -/ 35.1. Lag Transfer Fans stop - 35.2. Lag Transfer Fan dampers shut 36. Restore Transfer Fan and sensors to normal operations 37. Verify BMS Graphics 38. At end of testing, verify proper operation with Vendor/Building Engineer and retum system to normal. Section 04 Comments Ccmments Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/10/2010, the following was noted: Permanent unit identification labeling has not been attached. The minimum setting at BMS is 20Hz at 33.3% 33. Dirty space filter could not be tested due to doorways being blocked open. The dirty filter alarm will be tested during economizer testing of the UPS Room. Section 0` Lee Technologies representative has witnessed or participated in this checklist, has verified equipment is ready per checklist, and attests to the accuracy and completeness of this report. Printed Name: signature: Date: 4r1� �0 _ i_1 Trent Printz `ice ��► / p ' 7/10/2010 =unct :ona4 Test v;.'nness s 'vex incaron Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 4 of 4 • • • .Z41 LEE TECHNOLOGIES" LEVEL 4 CHECKLIST Section O1 Ptocedure Title: 1NTERNAP- TUK- WA-CX- TRANSFER FAN P' °''"''' Submittal Date: 18 May 10 y Procedure work Date: 7/10/2010 Procedure work Time Frame: 0800 -1700 Customer Name: Intemap Customers Salomon Project Code:. Address: Street Add 3355 South 120 Place City: State: LP: Tukwila WA 98168 CustomerPOC: CustomermOC Name: Kathy Mclnvale Phone Numbers: Office: 404302 9753 Mobile: 404.547.8915 Lee Technologies Commissioning Su Msor Herbert Bumett Phone Numbers: Phone Number. 703-968-0300 Mobile: 713.423.4335 Pager seGiion 02 Equipment System Checklist for TRANSFER FAN # TF 3U -2 Affected Area: Systems Affected: Equipment Information: Manufacturer Greenneck Equipment type: Transfer Fan Model a : • BDF- 200 - 100 -BHX Serial is 12053698 1004 Procedure. overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre- Procedure Requirements Manufacturers start up complete and all discrepancies corrected or noted for future correction. eclion 03 Detailed Procedure Procedure Details Detailed Procedure: _ _ l Complete 1. Manufacturer's start up complete 2. Manufacturer Rep present 3. Breaker panel location attached 4. Fan Name Plate Volts 460 5. Fan Name Plate Amps 12.5 ,r' 6. Motor HP 10 HP 7. Motor Phase 3 8. Fan RPM 746 9. Lubrication and belt adjustment complete 10. Fan Belt Size: AP87 Quantity: 1 11. Unit Clean and free of debris 12. Check that fan rotates freely .f 13. Verify controls are complete and operational Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 4 • • • 0 LEE TECHNOLOGIES" LEVEL 4 CHECKLIST 14. Start Unit at the local BMS controls 15. Verify space damper opens 16. Verify coned fan rotation 17. Perform a visual check of the equipment "' 17.1. Unusual noise v 17.2. Signs of deterioration v 18. Verify BMS Graphics .7 19. Verify VFD has been tested by Manufacturer 20: At local VFD control panel operate the VFD through the following test points NOTE: Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step } 20.1. 25% 15.0Hz 2.5A �r 20.2. 50% 30.0Hz 5.1A 7 20.3. 75% 45.0Hz 7.9A v. 20.4. 100% 60.0Hz 12.1A 21. Once 100% is reached and the unit has been inspected and stabilized, operate the VFD through the following test points. - NOTE: AIIow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step fw J r ; ' 21.1. 75% 45.0Hz 7.9A x 21.2. 50% 30.0Hz 5.1A 21.3. 25% 15.0Hz 2.5A .7 22. Retum the VFD to BMS control r7 23. Verify BMS Graphics 24. At BMS operate the VFD through the following test points , r,. ;r 24.1. 25% 20Hz 3.4A 33.3% ,./ 24.2. 50% 29.8Hz 5.1A 49.9% ✓' 24.3. 75 %. 45.0Hz 7.9A 74.7% 7 24.4. 100% 59.9Hz 12.0A 99.7% .' 25. Once 100% is reached and the unit has been inspected and stabilized, operate the VFD through the following test points. NOTE: AIIow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step 25.1. 75% 45.0Hz 7.9A 74.7% : 25.2. 50% 29.8Hz 5.0A 49.8% Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 4 • • • :11k LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 25.3. 25% 20.0Hz 3.3A 33.3% „,- 26. Verify BMS Graphics ./ Note: Transfer fans operate as Lead and Lag configuration Following will test the operation of the Lead/Lag configuration 27. Verify at BMS Transfer Fan line up i 28. At BMS start the Lead Fan / 29. Verify the following: 29.1. Space Damper opens 29.2. Lead Transfer Fan activates Transfer Fan power failure 30. Open Transfer Fan Disconnect or Breaker 30.1. Verify the following 30.1.1. Lead Transfer Fan shut off v 30.1.2. Space Damper shuts 30.1.3. Alarm received at BMS . v 30.1.4. Space Damper opens 30.1.5. Lag Transfer Fan activates 31. Close Lead Transfer Fan Disconnect or Breaker 31.1. Verify the following 31.1.1. Lag Transfer Fan stops 31.1.2. Lead transfer Fan starts 31.1.3. Alarm clears at BMS 31.1.4. Lead Transfer Fan ramps up to match Lag Fan ., 31.1.5. Lag Fan ramps down 31.1.6. Lag Fan shuts down ,..- Transfer Fan staging 32. At BMS lower space air temperature set point below space temperature 33. Verify the following: 33.1. Lead Transfer Fan VFD ramps up to or above 75% 33.2. Lag Transfer Fan activates v Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proptietary use pursuant to company policy Page 3 of 4 • • • L� LEE TECHNOLOGIES" LEVEL 4 CHECKLIST 33.3. Lead and Lag fan VFD's match % and increase as needed 33.4. Verify BMS graphics 33.5. Verify the following: 33.5.1. Unusual noise 33.5.2. Signs of deterioration 34. Verify. the Dirty Space Filter status alarm Simulate a dirty filter by covering' the filter with cardboard X 34.2. Verify alarm received at BMS X 34.3. Clear space Dirty Filter alarm X 34.4. Verify alarm cleared at BMS X 35. At BMS reset space air temperature set point below 35.1. Lag Transfer Fans stop 35.2. Lag Transfer Fan dampers shut 38. Restore Transfer Fan and sensors to normal operations 37. Verify BMS Graphics 38. At end of testing, verify proper operation with Vendor/Building Engineer and retum system to normal. p' Section 01 Comments Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/10/2010, the following was noted: Permanent unit identification labeling has not been attached. The minimum setting at BMS is 20Hz at 33.3% 33. Dirty space filter could not be tested due to doorways being blocked open. The dirty filter alarm will be tested during economizer testing of the UPS Room. Section 05 Lee Technologies representative has witnessed or participated in this checklist, has verified equipment is ready per checklist, . and attests to the accuracy and completeness of this report. Printed Name: Signature: Date: Trent Printz ligiliji7'; -=� , =_,� ' 7/10/2010 Functional Tcst w t:,e us & Venticr lion Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 4 of 4 • • • L� LEE TECHNOLOGIES" LEVEL 4 CHECKLIST Section 'J1 PrccedrreRte. °r °` „h °E INTERNAP- TUK -WA -CX- TRANSFER FAN Ir(o „ndhoa, Submittal Date: 18 May 10 y Procedure Work Date: , 7/17/2010 Procedure Work Tune Frame: 0800 -1700 Customer Name: Intemap Customs” Solomon Project Coda Address: Street Address: 3355 South 120th Place C. Ste: Zip: Tukwila WA 98168 Customer POC: Customer POC Name: Kathy Mdnvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning Su • : isor Herbert Burnett Phone Numbers. Phone Number. 703- 968 -0300 Mobile: 713.423.4335 Page. ScI !j_ P,,G,,;Un �,,,,, ?,,,,,,;,_, Equipment System Checklist for TRANSFER FAN # TF-S -1 Systems Affected: Affected Area: Equipment information: Manuractuer. Greenheck c-quipmentTYpe: Transfer Fan Modem: BCF- 206-7 Serial e: 12053701 1004 Procedure Overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre - Procedure rements: Requi `° =len -,° Manufacturers start up complete and all discrepancies corrected or noted for future correction. Detailed Procedure Detailed Pmcedunte Complete 1. Manufacturer's start up complete 2. Manufacturer Rep present 3. Breaker Panel location attached 4. Fan Name Plate Volts 460 5. Fan Name Plate Amps 1.5 6. Motor HP .75 HP 7. Motor Phase 3 8. Fan RPM 2304 9. Lubrication and belt adjustment complete 10. Fan Belt Size: AP26 Quantity: 1 y` 11. Unit Clean and free of debris 'f 12. Check that fan rotates freely 13. Verify controls are complete and operational Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 4 %411 LEE TECHNOLOGIES` Iiir • LEVEL 4 CHECKLIST 14. Start Unit at the local BMS controls 15. Verify space damper opens ,. 16. Verify corned fan rotation ' 17. Perform a visual check of the equipment 17.1. Unusual noise Y` 17.2. Signs of deterioration 18. Verify BMS Graphics 19. Verify VFD has been tested by Manufacturer 20. At local VFD control panel operate the VFD through the following test points NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step • f f'LL 20.1. MIN 20Hz 0.7A ,fr 20.2. 50% 30.0Hz 0.9A 20.3. 75% 45.0Hz 1.3A 20.4. 100% 60.0Hz 1.9A X 21. Once 100% is reached and the unit has been inspected and stabilized, operate the VFD through the following test points. NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step r : �4f. s, 21.1. 75% 45.0Hz 1.3A 21.2. 50% 30.0Hz 0.9A 21.3. MIN 20.0Hz 0.7A v 22. Return the VFD to BMS control v' 23. Verify BMS Graphics 24. At BMS operate the VFD through the following test points 24.1. MIN 20.0Hz 0.7A 33.3% 24.2. 50% 29.9Hz 0.9A 49.8% 24.3. 75% 44.9Hz 1.3A 74.8% ✓ 24.4. 100% 59.9Hz 1.8A 100.0% X 25. Once 100% is reached and the unit has been inspected and stabilized, operate the VFD through the following test points. NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step Ms; 25.1. 75% 44.9Hz 1.3A 74.8% v 25.2. 50% 29.9Hz 0.9A 49.8% ✓ Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 4 • • • &/411 LEE TECHNOLOGIES" LEVEL 4 CHECKLIST 25.3. MIN 20.OHz 0.7 33.3% 26. Verify BMS Graphics Note: Transfer fans operate as Lead and Lag configuration Vim: F^ 7 Following will test the operation of the Lead/Lag configuration 27. Verify at BMS Transfer Fan line up y` 28. At BMS start the Lead Fan 29. Verify the following: 29.1. Space Damper opens / 29.2. Lead Transfer Fan activates Transfer Fan power failure ..:- 30. Open Transfer Fan Disconnect or Breaker 30.1. Verify the following 30.1.1. Lead Transfer Fan shut off ✓ 30.1.2. Space Damper shuts 30.1.3. Alarm received at BMS `` 30.1.4. Space Damper opens 30.1.5. Lag Transfer Fan activates 31. Close Lead Transfer Fan Disconnect or Breaker 31.1. Verify the following v" 31.1.1. Lag Transfer Fan stops 7 31.1.2. Lead transfer Fan starts 31.1.3. Alarm clears at BMS V 31.1.4. Lead Transfer Fan ramps up to match Lag Fan 31.1.5. Lag Fan ramps down 31.1.6. Lag Fan shuts down Transfer Fan staging 32. At BMS lower space air temperature set point below space temperature ,( 33. Verify the following: *f'} s. . 33.1. Lead Transfer Fan VFD ramps up to or above 75% 33.2. Lag Transfer Fan activates Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 4 • • • L� S° LEE TECHNOLOGIE LEVEL 4 CHECKLIST 33.3. Lead and Lag fan VFD's match % and increase as needed 33.4. Verify BMS graphics f 33.5. Verify the following: , { 33.5.1. Unusual noise 33.5.2. Signs of deterioration 34. Verify the Dirty Space Filter status alarm �F 34.1. Simulate a dirty filter by covering %the filter with cardboard V 34.2. Verify alarm received at BMS 34.3. Clear space Dirty Filter alarm 34.4. Verify alarm cleared at BMS 35. At BMS reset space air temperature set point below 35.1. Lag Transfer Fans stop 35.2. Lag Transfer Fan dampers shut ' 36. Restore Transfer Fan and sensors to normal operations 37. Verify BMS Graphics 38. End of test Sec:,-).-_,.1 Comments Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/17/2010, the following was noted. Permanent unit identification labeling has not been attached to the fan. Step 20.4 and 24.4. The fan motors are running above FLA as read at the VFD. Secuo =55 Fi , :uii,. a - -- , \Nu , ::;-, ., Verac:,,p ,:, Lee Technologies representative has witnessed or participated in this checklist, has verified equipment is ready per and attests to the accuracy and completeness of this report. Printed Name: Signature: Date: checklist, �� i i'!�/ 7/17/2010 Trent Printz •..' , / i Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 4 of 4 • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Section v? Pioced'"'c !Cf i rnr'11DR RocedureTit4e: INTERNAP-TUK-WA-CX-TRANSFER FAN Submittal Date: 18 May 10 Procedure Work Date: Procedure Procedure WOE Time Frame :. 0800 -1700 Customer Name: I me m a p Customers Solomon Project Coda Address: Street Address: 3355 South 120th Place City Sale: Zip: Tukwila WA 98168 CustomerPOC: Customer POC Name: Kathy Mclnvale Phone Numbeis Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning Su • ervisor. Herbert Burnett Phone Numbers: Phone Number. 703 -968 -0300 Mobile: 713.423.4335 Pager 'cc`' °� '= rcn:�riun� C�.rrd�ev, Equipment System Checklist for TRANSFER FAN # TF-S -2 Systems Affected: Affected Area: Equipment Information: Manufacturer: Greenheck Equipment Type: Transfer Fan Models: BCF- 206-7 Serial #: 12053702 1004 Procedure Overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre- Procedure Requirements: Manufacturers start up complete and all discrepancies corrected or noted for future correction. F(=_oo 03 0G,C11■4 D,i‘,u`, Detailed Procedure Detailed Procedure: Cumulate 1. Manufacturer's start up complete 2. Manufacturer Rep present y. 3. Breaker Panel location attached 4. Fan Name Plate Volts 460 5. Fan Name Plate Amps 1.5 6. Motor HP .75 HP 7. Motor Phase 3 8. Fan RPM 2304 9. Lubrication and belt adjustment complete 10. Fan Belt Size: AP26 Quantity: 1 11. Unit Clean and free of debris 12. Check that fan rotates freely Y 13. Verify controls are complete and operational Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 4 • • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 14. Start Unit at the local BMS controls 15. Verify space damper opens 16. Verify correct fan rotation '? 17. Perform a visual check of the equipment 17.1. Unusual noise 17.2. Signs of deterioration y' 18. Verify BMS Graphics 19. Verify VFD has been tested by Manufacturer 20. At local VFD control panel operate the VFD through the following test points NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step 20.1. MIN 20Hz 0.6A 20.2. 50% 30.0Hz 0.8A 20.3. 75% 45.0Hz 1.1A V' 20.4. 100% 60.0Hz 1.7A X 21. Once 100% is reached and the unit has been inspected and stabilized, operate the VFD through the following test points. NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step . 21.1. 75% 45.0Hz 1.1A 212. 50% 30.0Hz 0.8A 21.3. MIN 20.0Hz 0.6A *' 22. Retum the VFD to BMS control 23. Verify BMS Graphics 24. At BMS operate the VFD through the following test points ,ti 24.1. MIN 20.0Hz 0.6A 33.3% / 242. 50% 29.9Hz 0.8A 49.7% t' 24.3. 75% 44.9Hz 1.1A 75.0% 24.4. 100% 59.9Hz 1.6A 100.0% X 25. Once 100% is reached and the unit has been inspected and stabilized, operate the VFD through the following test points. NOTE: Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step`s L r` s< 25.1. 75% 44.9Hz 1.1A 74.8% 25.2. 50% 29.9Hz 0.8A 49.7% Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 4 • • &11 LEE TECHNOLOGIES° IL/ LEVEL 4 CHECKLIST 25.3. MIN 20.0Hz 0.6 33.3% v' 26. Verify BMS Graphics Note: Transfer fans operate as Lead and Lag configuration Following will test the operation of the Lead/Lag configuration 27. Verify at BMS Transfer Fan line up /- 28. At BMS start the Lead Fan 29. Verify the following: 29.1. Space Damper opens 29.2. Lead Transfer Fan activates Transfer Fan power failure . .. s. : . '! ': -.- • 30. Open Transfer Fan Disconnect or Breaker 30.1. Verify the following 30.1.1. Lead Transfer Fan shut off V 30.1.2. Space Damper shuts v 30.1.3. Alarm received at BMS 30.1.4. Space Damper opens v 30.1.5. Lag Transfer Fan activates 31. Close Lead Transfer Fan Disconnect or Breaker 31.1. Verify the following 31.1.1. Lag Transfer Fan stops 31.12. Lead transfer Fan starts 31.1.3. Alarm clears at BMS ../ 31.1.4. Lead Transfer Fan ramps up to match Lag Fan 31.1.5. Lag Fan ramps down 31.1.6. Lag Fan shuts down v Transfer Fan staging 32. At BMS lower space air temperature set point below space temperature 33. Verify the following 33.1. Lead Transfer Fan VFD ramps up to or above 75% 33.2. Lag Transfer Fan activates Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 4 • • • �� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 33.3. Lead and Lag fan VFD's match % and increase as needed 33.4. Verify BMS graphics v 33.5. Verify the following: ' 33.5.1. Unusual noise 33.5.2. Signs of deterioration 34. Verify the Dirty Space Filter status alarm .? x 34.1. Simulate a dirty filter by covering' the filter with cardboard 34.2. Verify alarm received at BMS 34.3. Clear space Dirty Filter alarm 34.4. Verify alarm cleared at BMS 35. At BMS reset space air temperature set point below 35.1. Lag Transfer Fans stop 35.2. Lag Transfer Fan dampers shut '1 36. Restore Transfer Fan and sensors to normal operations 37. Verify BMS Graphics 38. End of test sEK-Io _0 y Comments Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/17/2010, the following was noted. Permanent unit identification labeling has not been attached to the fan. Step 20.4 and 24.4. The fan motors are running above FLA as read at the VFD. sEctign u5 r u,,,t „.i,. I T,,st 1:'t1ii,tsss ,. Veiitical. ;n Lee Technologies representative has witnessed or participated in this checklist, has verified equipment is ready per and attests to the accuracy and completeness of this report. Printed Name: Signature: Date: checltist, Trent Printz '.► 7/17/2010 Template Rev. 07022010 Lee Technologies. Group © Copyright 2010 Proprietary use pursuant to company policy Page 4 of 4 • /II LEE TECHNOLOGIES" LEVEL 4 CHECKLIST Section 01 Procedure Title: INTERNAP- TUK -WA -CX -FUEL OIL SYSTEM Piocodure Information Submittal Date: 18 May 10 Procedure Work Date: 7/15/2010 Procedure Work Time Frame: 0800 -1700 Customer Name: . - Internap Customers Solomon Project Coda. Address: SbeetAddress: 3355 South 120th Place City: State: - Zip: Tukwila WA 98168 CustomerPOC: Customer POC Name: Kathy Mclnvale Phone Numbers: ice: 404.302.9753 Mobile: 404.547.8915 Lee Technologies . Commissioning Su • ervisor.: Herbert Burnett Phone Numbers: Phone Number 703 - 968 -0300 Mobile: 713.423.4335 Pager S stem Checklist for Fuel Oil s stem Equipment System system PinrSection rdruc Ovrrvirbv Affected Area: Systems Affected: Equipment Information: Manufacturer. Gunter Equipment Type: Dry Cooler Model #: SGP08-0350MLNAUBNNN-N- 002 Serial #: 256035.0001 Procedure Overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre- Procedure Requirements: Manufacturers start up complete and all discrepancies corrected or noted for future correction. Section 03 Detailed Procedure Procedure Details Detailed Procedure: Complete 1. O &M Data submitted ✓ 2. Warranties submitted 3. Manufacturer Rep Present °* 4. Tank cleaned & filled 5. Safety signs & emergency precaution documents posted 6. Supply & Retum piping connection complete 7. Vent pipe installed with approved vent cap 8. Fill pipe with spill containment installed ,` 9. Piping tested and documented . 10. Tank tested and documented r 11. Fire Marshal inspection scheduled /completed` 12. Manufacturer's Start-up Complete r C• Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 21 • • • tault LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Section 01 Procedure Title: Procedure INTERNAP— TUK —WA—CX —FUEL OIL SYSTEM In_fo_rmation _ Submittal Date: 18 May 10 y Procedure Work Date: 7/15/2010 Procedure Work Time Frame: 0800 -1700 Customer Name: I nternap Customer: Solomon Project Code: Address: Sheet Address: _ 3355 South 120th Place City: Stet9:. Zip: Tukwila WA 98168 CustomerPOC: Customer POC Name: Kathy Mclnvale Phone Numbers: office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies . Commissioning Su , eN%soC - Herbert Burnett Phone Numbers: Phone Number. 703 - 968 -0300 Mobile: 713.423.4335 Poger. , section oz E ui ment System Checklist for Fuel 00 system 4 p Y Y Procedure Ovevie.a, Affected Area: Systems Affected: Equipment Information: Manufacturer Gunter Equipment Type: Dry Cooler Model It SGP08-0350MLNAUBNNN-N- 002 serial #: 256035.0001 Procedure Overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre- Procedure Requirements: Manufacturers start up complete and all discrepancies corrected or noted for future correction. Section 03 Detailed Procedure Procedure Details Detailed Procedure: _ Complete 1. O &M Data submitted '' 2. Warranties submitted .7 3. Manufacturer Rep Present 4. Tank leaned & filled 5. Safety signs & emergency precaution documents posted p` 6. Supply & Retum piping connection complete 7. Vent pipe installed with approved vent cap .7 8. Fill pipe with spill containment installed. ,f 9. Piping tested and documented 10. Tank tested and documented ✓ 11. Fire Marshal inspection scheduled /completed 12. Manufacturer's Start-up Complete Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 21 • • • L� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 13. Mechanical Interface: Verify BMS system remote monitory functions per approved BAS submittal — point to point check 14. Supply pumps lined up and operational. Note: the follow will require the transferring of fuel to and from the Main tank and Day tanks. Note: the following will require an additional Day Tank calling for fuel to keep from over pressurizing the supply system. DAY TANK #1 c- 15. Verify that the Solenoid Valve HOA is in Auto 16. Place the Retum Pump HOA in Hand - v 17. Place the Retum Pump HOA for Day Tank 5 in hand 18. Verify that the Retum Pump Run Lamp is lit . 19. Verify that BMS hold a Retum Pump Run status NOTE 1 X 20. When the Day Tank level reaches 65% (approx) verify the following: spy 20.1. Lead Supply Pump Run Lamp is lit 20.2. Normal Fill solenoid opens 21. Place the Return Pump HOA's in Auto _ 22. Verify the following 22.1. The Retum Pump Stops 22.2. The Retum Pump Run Lamp goes out 22.3. BMS no longer has a Retum Pump Run status NOTE 1 X 22.4. Tank level increases 23. Shut the DT 1 Solenoid Valve supply isolation valve •'' 24. Verify the following: 24.1. Lag Supply Pump starts 24.2. Loss of flow Fail lamp lit, 24.3. Lead Pump Fail alarm 25. Open the DT 1 Solenoid Valve isolation valve 26. Press the silence button 27. Alarm clears 28. Lead Pump starts 29. Lag Pump stops Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 21 • • • /� LEE TECHNOLOGIES' L LEVEL 4 CHECKLIST 30. Press and hold the reset button for DT 1 at Day Tank Control Panel to reset the day tank 31. When the tank level reaches 75% 0 V 32. Verify the following: 32.1. Normal Fill solenoid valve shuts 32.2. Supply Pump stops ../ 32.3. Supply Pump Run Lamp is off v The following will test the High Level alarm Level Note: ensure that there is personnel stationed at the fill solenoid bypass valve during the testing of the High Level alarm float -,T 33. Place a supply pump in hand 34. Open the fill solenoid valve bypass valve 35. When the tank reaches 95% shut the bypass valve 36. Place the Supply Pump HOA in Auto 37. Verify the following:. 37.1. Retum Pump starts °r 37.2. Return Pump Run Lamp is lit 37.3. Emergency Shutdown Solenoid is shut 37.4. High Level alarm at the Fuel System Control and Monitoring Panel V' 37.5. High Level alarm at BMS NOTE 1 X 38. When tank level reaches 75% verify the following: " fiYr 38.1. Emergency Shutdown Solenoid valve open f 38.2. Normal fill Solenoid valve is shut 0 "r 38.3. High Level alarm clear at the Fuel System Control and Monitoring Panel 38.4. High Level alarm clear at BMS NOTE 1 X 38.5. Retum Pump is off The following will test the leak detect alarm 39. Remove the Leak Detect probe from the tank NOTE 2 X 40. Retum Fuel to the 75% level to allow the tank to call for fuel X 41. Place the probe in a cup of water X 42. Verify the following X Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 21 • • LEE TECHNOLOGIES° LEVEL 4 CHECKLIST 42.1. Leak Tamp lit at the Fuel System Control and Monitoring Panel X 42.2. Leak Detect alarm at BMS X 42.3. Supply Pump shuts down X 43. Remove probe from water X 44. Replace the probe in the tank X 45. Press and hold the reset button for 5 seconds X 46. Verify the following:` 46.1.1. Leak Tamp goes out at the Fuel System Control and Monitoring Panel X 46.1.2. Leak Detect alarm clears at BMS X 47. Reinstall the Leak Detect probe X The following will test the Low Level alarm 48. Place the Retum Pump HOA in Hand 49. Place the HOA switches for the Lead and Lag Supply Pumps in Off 50. Continue retuming fuel to the 25% level 51. Verify the following: _ 51.1. Low Level Lamp is lit 51.2. Low Level at BMS NOTE 1 X 51.3. Emergency Shut Down Valve is Shut ,t 52. Restore Lead and Lag Supply Pump HOA's to Auto 53. Open the bypass valve 54. Verify the following: r; 54.1. Tank level increases ti 54.2. At 35% the Emergency Shutdown valve opens 54.3. Shut the bypass valve 54.4. Low Level lamp goes out at the Fuel System Control and Monitoring Panel 1 54.5. Low Level alarm dears at BMS NOTE 1 X. DAY TANK #2 55. Verify that the Solenoid Valve HOA is in Auto 56. Place the Retum Pump HOA in Hand 57. Place the Retum Pump HOA for Day Tank 5 in hand Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 4 of 21 • • • L LEE TECHNOLOGIES` LEVEL 4 CHECKLIST 58. Verify that the Retum Pump Run Lamp is lit 59. Verify that BMS hold a Retum Pump Run status NOTE 1 X 60. When the Day Tank level reaches 65% (approx) verify the following: 60.1. Lead Supply Pump Run Lamp is lit V 60.2. Normal Fill solenoid opens 1' 61. Place the Return Pump HOA's in Auto 62. Verify the following 62.1. The Retum Pump Stops 62.2. The Return Pump Run Lamp goes out 62.3. BMS no longer has a Retum Pump Run status NOTE 1 X 62.4. Tank level increases V 63. Shut the DT 2 Solenoid Valve supply isolation valve 64. Verify the following: • -, :.... 64.1. Lag Supply Pump starts 64.2. Loss of flow Fail lamp lit 64.3. Lead Pump Fail alarm .1 65. Open the DT 2 Solenoid Valve isolation valve 66. Press the silence button 67. Alarm clears ,7 68. Lead Pump starts 69. Lag Pump stops 70. Press and hold the reset button for DT 2 at Day Tank Control Panel to reset the day tank 71. When the tank level reaches 75% ' 72. Verify the following: 72.1. Normal Fill solenoid valve shuts " 72.2. Supply Pump stops 72.3. Supply Pump Run Lamp is off / The following will test the High Level alarm 3+ • . y.: z. Note: ensure that there is personnel stationed at the fill solenoid bypass valve during the testing of the High Level alarm float t .. ,- Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 5 of 21 • • • .4,,11) LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 73. Place a supply pump in hand 74. Open the fill solenoid valve bypass valve 1 75. When the tank reaches 95% shut the bypass valve 76. Place the Supply Pump HOA in Auto ,,1 77. Verify the following: rq 77.1. Retum Pump starts v 77.2. Retum Pump Run Lamp is lit 77.3. Emergency Shutdown Solenoid is shut 77.4. High Level alarm at the Fuel System Control and Monitoring Panel 77.5. High Level alarm at BMS NOTE 1 X 78. When tank level reaches 75% verify the following: r 78.1. Emergency Shutdown Solenoid valve open 78.2. Normal fill Solenoid valve is shut *" 78.3. High Level alarm dear at the Fuel System Control and Monitoring Panel ,f 78.4. High Level alarm clear at BMS _NOTE 1 X 78.5. Retum Pump is off - The following will test the leak detect alarm v 79. Remove the Leak Detect probe from the tank NOTE 2 X 80. Retum Fuel to the 75% level to allow the tank to call for fuel X 81. Place the probe in a cup of water X 82. Verify the following ` r._.; 82.1. Leak Tamp lit at the Fuel System Control and Monitoring Panel X 82.2. Leak Detect alarm at BMS X 82.3. Supply Pump shuts down X 83. Remove probe from water X 84. Replace the probe in the tank X 85. Press and hold the reset button for 5 seconds X 86. Verify the following: 86.1.1. Leak Tamp goes out at the Fuel System Control and Monitoring Panel X 86.1.2. Leak Detect alarm clears at BMS X Template Rev. 07022010 Lee Technologies Group Copyright 2010 Proprietary use pursuant to company policy Page 6 of 21 • • • L� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 87. Reinstall the Leak Detect probe X The following will test the Low Level alarm 88. Place the Retum Pump HOA in Hand 89. Place the HOA switches for the Lead and Lag Supply Pumps in Off 90. Continue retuming fuel to the 25% level { 91. Verify the following: >, 91.1. Low Level Lamp is lit 91.2. Low Level at BMS NOTE 1 X 91.3. Emergency Shut Down Valve is Shut ✓J 92. Restore Lead and Lag Supply Pump HOA's to Auto ` 93. Open the bypass valve 94. Verify the following: 94.1. Tank level increases 94.2. At 35% the Emergency Shutdown valve opens ' 94.3. Shut the bypass valve '1 94.4. Low Level lamp goes out at the Fuel System Control and Monitoring. Panel 94.5. Low Level alarm dears at BMS NOTE 1 X DAY TANK #3 „" 95. Verify that the Solenoid Valve HOA is in Auto 96. Place the Retum Pump HOA in Hand .f 97. Place the Retum Pump HOA for Day Tank 5 in hand 98. Verify that the Retum Pump Run Lamp is lit 99. Verify that BMS hold a Retum Pump Run status NOTE 1 X 100. When the Day Tank level reaches 65% (approx) verify the following: 100.1. Lead Supply Pump Run Lamp is lit 100.2. Normal Fill solenoid opens v` 101. Place the Retum Pump HOA's in Auto y 102. Verify the following 102.1. The Retum Pump Stops f 102.2. The Retum Pump Run Lamp goes out Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 7 of 21 • • • L/1 LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 102.3. BMS no longer has a Retum Pump Run status NOTE 1 X 102.4. Tank level increases 103. Shut the DT 3 Solenoid Valve supply isolation valve` 104. Verify the following: 104.1. Lag Supply Pump starts d 104.2. Loss of flow Fail lamp lit y' 104.3. Lead Pump Fail alarm 105. Open the DT 3 Solenoid Valve isolation valve ✓ 106. Press the silence button 107. Alarm Gears ,r 108. Lead Pump starts 109. Lag Pump stops 110. Press and hold the reset button for DT 3 at Day Tank Control Panel to reset the day tank 111. When the tank level reaches 75% 112. Verify the following: ! 112.1. Normal Fill solenoid valve shuts 112.2. Supply Pump stops V 112.3. Supply Pump Run Lamp is off The following will test the High Level alarm Note: ensure that there is personnel stationed at the fill solenoid bypass valve during the testing of the High Level alarm float 113. Place a supply pump in hand v' 114. Open the fill solenoid valve bypass valve 115. When the tank reaches 95% shut the bypass valve v 116. Place the Supply Pump HOA in Auto / 117. Verify the following: 117.1. Return Pump starts r 117.2. Retum Pump Run Lamp is lit s` 117.3. Emergency Shutdown Solenoid is shut 117.4. High Level alarm at the Fuel System Control and Monitoring Panel t;. Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 8of21 • • • LEE TECHNOLOGIES° LEVEL 4 CHECKLIST 117.5. High Level alarm at BMS NOTE 1 X 118. When tank level reaches 75% verify the following: 118.1. Emergency Shutdown Solenoid valve open 118.2. Normal fill Solenoid valve is shut *` 118.3. High Level alarm dear at the Fuel System Control and Monitoring Panel 118.4. High Level alarm clear at BMS NOTE 1 X 118.5. Retum Pump is off / The following will test the leak detect alarm ;qty << 119. Remove the Leak Detect probe from the tank NOTE 2 X 120. Retum Fuel to the 75% level to allow the tank to call for fuel X 121. Place the probe in a cup of water X 122. Verify the following ;v 122.1. Leak Tamp lit at the Fuel System Control and Monitoring Panel X 122.2. Leak Detect alarm at BMS X 122.3. Supply Pump shuts down _ X 123. Remove probe from water X 124. Replace the probe in the tank X 125. Press and hold the reset button for 5 seconds X 126. Verify the following: " r 126.1.1. Leak lamp goes out at the Fuel System Control and Monitoring Panel X 126.1.2. Leak Detect alarm clears at BMS X 127. Reinstall the Leak Detect probe X The following will test the Low Level alarm 128. Place the Retum Pump HOA in Hand 129. Place the HOA switches for the Lead and Lag Supply Pumps in Off v 130. Continue retuming fuel to the 25% level 131. Verify the following: 131.1. Low Level Lamp is lit 131.2. Low Level at BMS NOTE 1 X 131.3. Emergency Shut Down Valve is Shut Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 9 of 21 • • LEE TECHNOLOGIES° LEVEL 4 CHECKLIST 132. Restore Lead and Lag Supply Pump HOA's to Auto 133. Open the bypass valve "f 134. Verify the following: 134.1. Tank level increases 134.2. At 35% the Emergency Shutdown valve opens 134.3. Shut the bypass valve 134.4. Low Level lamp goes out at the Fuel System Control and Monitoring Panel 134.5.. Low Level alarm dears at BMS NOTE 1 X DAY TANK #4 �S4Yf 135. Verify that the Solenoid Valve HOA is in Auto 136. Place the Retum Pump HOA in Hand d 137. Place the Retum Pump HOA for Day Tank 4 in hand r` 138. Verify that the Return Pump Run Lamp is lit 139. Verify that BMS hold a Retum Pump Run status Y' 140. When the Day Tank level reaches 75% verify the following: ; , 140.1. Lead Supply Pump Run Lamp is lit / 140.2. Normal FiII solenoid opens 4' 141. Place the Return Pump HOA's in Auto 142. Verify the following 142.1. The Retum Pump Stops v 142.2. The Retum Pump Run Lamp goes out ✓ 142.3. BMS no longer has a Retum Pump Run status 142.4. Tank level increases J 143. Shut the DT 4 Solenoid Valve supply isolation valve ../ 144. Verify the following: 144.1. Lag Supply Pump starts ✓ 144.2. Lead Pump Fail lamp lit v 144.3. Loss of Low lamp lit 'f 145. Open the DT 4 Solenoid Valve isolation valve 146. Press and hold the reset button at Day Tank Control Panel for 5 seconds to reset the day tank Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 10 of 21 • • • L� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 147. Lead Pumps starts 148. Lag Pump stops 149. When the tank level reaches 90% 150. Verify the following: ; 150.1. Normal Fill solenoid valve shuts 150.2. Supply Pump stops 150.3. Supply Pump Run Lamp is off y' The following will test the High Level alarm Note: ensure that there is personnel stationed at the fill solenoid bypass valve during the testing of the High Level alarm float = ` 151. Place a Supply Pump in hand 152. Open the fill solenoid valve bypass valve 153. When the tank reaches 95% shut the bypass valve 154. Place the Supply HOA in Auto 155. Verify the following: 155.1. Retum Pump starts 155.2. Retum Pump Run Lamp is lit 155.3. Emergency Shutdown Solenoid is shut 155.4. High Level alarm at the Fuel System Control and Monitoring Panel 155.5. High Level alarm at BMS 156. When tank level reaches 85% verify the following: 156.1. Emergency Shutdown Solenoid valve open u` 156.2. Normal fill Solenoid valve is shut ✓ 156.3. High Level alarm clear at the Fuel System Control and Monitoring Panel 156.4. High Level alarm Gear at BMS 156.5. Retum Pump is off The following will test the leak detect alarm i L 157. Remove the Leak Detect probe from the tank 158. Return Fuel to the 75% level to allow the tank to call for fuel 159. Place the probe in a cup of water Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 11 of 21 • • • L� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 160. Verify the following 160.1. Leak Tamp lit at the Fuel System Control and Monitoring Panel 160.2. Leak Detect alarm at BMS / 160.3. Supply Pump shuts down °r 161. Remove probe from water y� 162. Replace the probe in the tank / 163. Press and hold the reset button for 5 seconds 164. Verify the following: 164.1.1. Leak lamp goes out at the Fuel System Control and Monitoring Panel .� 164.1.2. Leak Detect alarm clears at BMS 165. Reinstall the Leak Detect probe The following will test the Low Level alarm 166. Place the Return Pump HOA in Hand 167. Place the HOA switches for the Lead and Lag Supply Pumps in Off v 168. Continue returning fuel to the 15% level 169. Verify the following:; : Y 169.1. Low Level Lamp is lit v 169.2. Low Level at BMS 170. Restore Lead and Lag Supply Pump HOA's to Auto '' 171. Verify the following: 171.1. Tank level increases V 171.2. Low Level lamp goes out at the Fuel System Control and Monitoring Panel +` 171.3. Low Level alarm clears at BMS °` DAY TANK #5 172. Verify that the Solenoid VaNe HOA is in Auto 173. Place the Return Pump HOA in Hand V' 174. Place the Return Pump HOA for Day Tank 5 in hand � 175. Verify that the Retum Pump Run Lamp is lit p` 176. Verify that BMS hold a Retum Pump Run status 177. When the Day Tank level reaches 75% verify the following; Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 12 of 21 • • • L� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 177.1. Lead Supply Pump Run Lamp is lit 177.2. Normal Fill solenoid opens 178. Place the Retum Pump HOA's in Auto 1.79. Verify the following 179.1. The Retum Pump Stops 179.2. The Retum Pump Run Lamp goes out 179.3. BMS no longer has a Retum Pump Run status v' 179.4. Tank level increases 180. Shut the DT 5 Solenoid Valve supply isolation valve =° 181. Verify the following: 181.1. Lag Supply Pump starts 181.2. Lead Pump Fail lamp lit 181.3. Loss of Low Tamp lit 182. Open the DT 5 Solenoid Valve isolation valve ,,/ 183. Press and hold the reset button at Day Tank Control Panel for 5 secgnds to reset the day tank 184. Lead Pumps starts 185. Lag Pump stops 186. When the tank level reaches 90% v 187. Verify the following: , 187.1. Normal Fill solenoid valve shuts 187.2. Supply Pump stops 187.3. Supply Pump Run Lamp is off The following will test the High Level alarm f: Note: ensure that there is personnel stationed at the fill solenoid bypass valve during the testing of the High Level alarm float 188. Place a Supply Pump in hand 189. Open the fill solenoid valve bypass valve 190. When the tank reaches 95% shut the bypass valve' 191. Place the Supply HOA in Auto 192. Verify the following:; Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 13 of 21 • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 192.1. Return Pump starts 192.2. Retum Pump Run Lamp is lit , 192.3. Emergency Shutdown Solenoid is shut 192.4. High Level alarm at the Fuel System Control and Monitoring Panel r� 192.5. High Level alarm at BMS 193. When tank level reaches 85% verify the following: 193.1. Emergency Shutdown Solenoid valve open 193.2. Normal fill Solenoid valve is shut 193.3. High Level alarm clear at the Fuel System Control and Monitoring Panel 193.4. High Level alarm clear at BMS 193.5. Retum Pump is off The following will test the leak detect alarm .'¢' 194. Remove the Leak Detect probe from the tank 195. Retum Fuel to the 75% level to allow the tank to call for fuel 196. Place the probe in a cup of water 197. Verify the following 197.1. Leak lamp lit at the Fuel System Control and Monitoring Panel Y` 197.2. Leak Detect alarm at BMS ;r 197.3. Supply Pump shuts down . 198. Remove probe from water 199. Replace the probe in the tank 200. Press and hold the reset button for 5 seconds 201. Verify the following: 201.1.1. Leak lamp goes out at the Fuel System Control and Monitoring Panel •{ 201.1.2. Leak Detect alarm clears at BMS .7 202. Reinstall the Leak Detect probe The following will test the Low Level alarm rr ±„ 203. Place the Return Pump HOA in Hand .7 204. Place the HOA switches for the Lead and Lag Supply Pumps in Off 205. Continue returning fuel to the 15% level of Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 14 of 21 • • • L�TECHNOLOGIES"' TECHNOLOGIES LEVEL 4 CHECKLIST 206. Verify the following: 206.1. Low Level Lamp is lit 206.2. Low Level at BMS 207. Restore Lead and Lag Supply Pump HOA's to Auto d` 208. Verify the following: ; _,. 208.1. Tank level increases ' 208.2. Low Level lamp goes out at the Fuel System Control and Monitoring Panel Y {. 208.3. Low Level alarm dears at BMS DAY TANK #6 209. Verify that the Solenoid Valve HOA is in Auto v 210. Place the Retum Pump HOA in Hand 211. Place the Return Pump HOA for Day Tank 6 in hand f 212. Verify that the Retum Pump Run Lamp is lit 213. Verify that BMS hold a Retum Pump Run status 214. When the Day Tank level reaches 75% verify the following: 214.1. Lead Supply Pump Run Lamp is lit 214.2. Normal Fill solenoid opens 215. Place the Retum Pump HOA's in Auto y 216. Verify the following Y. 216.1. The Retum Pump Stops 216.2. The Return Pump Run Lamp goes out 216.3. BMS no longer has a Retum Pump Run status ' 216.4. Tank level increases ,7 217. Shut the DT 6 Solenoid Valve supply isolation valve ' 218. Verify the following: FAX 6'2 -ii: 218.1. Lag Supply Pump starts °r 218.2. Lead Pump Fail lamp lit 218.3. Loss of Low lamp lit 219. Open the DT 4 Solenoid Valve isolation valve 220. Press and hold the reset button at Day Tank Control Panel for 5 seconds to reset the day tank '7 Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 15 of 21 • • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 221. Lead Pumps starts 222. Lag Pump stops 223. When the tank level reaches 90% L' 224. Verify the following: 224.1. Normal Fill solenoid valve shuts 1 224.2. Supply Pump stops v 224.3. Supply Pump Run Lamp is off '1' The following will test the High Level alarm Note: ensure that there is personnel stationed at the fill solenoid bypass valve during the testing of the High Level alarm float 225. Place a Supply Pump in hand *` 226. Open the fill solenoid valve bypass valve 227. When the tank reaches 95% shut the bypass valve 228. Place the Supply HOA in Auto t 229. Verify the following: 229.1. Retum Pump starts f` 229.2. Retum Pump Run Lamp is lit 229.3. Emergency Shutdown Solenoid is shut v 229.4. High Level alarm at the Fuel System Control and Monitoring Panel 229.5. High Level alamm at BMS .7 230. When tank level reaches 85% verify the following: 230.1. Emergency Shutdown Solenoid valve open 230.2. Normal fill Solenoid valve is shut 230.3. High Level alarm clear at the Fuel System Control and Monitoring Panel 230.4. High Level alarm dear at BMS 7 230.5. Retum Pump is off The following will test the leak detect alarm 231. Remove the Leak Detect probe from the tank r 232. Retum Fuel to the 75% level to allow the tank to call for fuel .rf 233. Place the probe in a cup of water 7 Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 16 of 21 • • • L� LEE TECHNOLOGIES" LEVEL 4 CHECKLIST 234. Verify the following 234.1. Leak Tamp lit at the Fuel System Control and Monitoring Panel 234.2. Leak Detect alarm at BMS V 234.3. Supply Pump shuts down 235. Remove probe from water 236. Replace the probe in the tank 237. Press and hold the reset button for 5 seconds 238. Verify the following: 238.1.1. Leak lamp goes out at the Fuel System Control and Monitoring Panel V 238.1.2. Leak Detect alarm clears at BMS 239. Reinstall the Leak Detect probe The following will test the Low Level alarm k= 240. Place the Retum Pump HOA in Hand V 241. Place the HOA switches for the Lead and Lag Supply Pumps in Off 242. Continue retuming fuel to the 15% level / 243. Verify the following: 243.1. Low Level Lamp is lit X' 243.2. Low Level at BMS 244. Restore Lead and Lag Supply Pump HOA's to Auto V` 245. Verify the following: 245.1. Tank level increases '7 245.2. Low Level Tamp goes out at the Fuel System Control and Monitoring Panel 245.3. Low Level alarm Gears at BMS x" The following is to verify the Supply Pump capacity This test will require the use of an Ultrasonic Flow Meter operated by the Test and Balance contractor Day Tank 1 flow capacity 246. Place the Supply Pumps 1 and 2 HOA in Off y' 247. Return Day Tanks 1, 2, 3, 4, 5, and 6 to 75% 1 248. Verify the following: 248.1. Fill Solenoid Valves for Day Tanks 1, 2, 3, 4, 5, and 6 are open y Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 17 of 21 • • L� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 248.2. Ultra Sonic Flow Meter installed on Day Tank 1 fill piping 249. Place the Supply Pump 1 and 2 HOA's in the Auto position 1 250. Verify the following: ''• 250.1. Lead Supply Pump starts 250.2. Flow is read on the Ultra Sonic Flow Meter 250.3. Record the flow rate from Supply Pump 1 5.3 GPM 250.4. Record the flow rate from Supply Pump 2 4.7 GPM Day Tank 2 flow capacity 251. Place the Supply Pumps 1 and 2 HOA in Off *` 252. Return Day Tanks 1, 2, 3, 4, 5, and 6 to 75% J 253. Verify the following: 253.1. Fill Solenoid Valves for Day Tanks 1, 2, 3, 4, 5, and 6 are open / 253.2. Ultra Sonic Flow Meter installed on Day Tank 1 fill piping tlf. 254. Place the Supply Pump 1 and 2 HOA's in the Auto position 255. Verify the following: _ 255.1. Lead Supply Pump starts f 255.2. Flow is read on the Uttra Sonic Flow Meter 255.3. Record the flow rate from Supply Pump 1 5.0 GPM 255.4. Record the flow rate from Supply Pump 2 6.0 GPM Day Tank 3 flow capacity 256. Place the Supply Pumps 1 and 2 HOA in Off 1 257. Retum Day Tanks 1, 2, 3, 4, 5, and 6 to 75% 258. Verify the following: ddr 258.1. Fill Solenoid Valves for Day Tanks 1, 2, 3, 4, 5, and 6 are open v 258.2. Ultra Sonic Flow Meter installed on Day Tank 1 fill piping 259. Place the Supply Pump 1 and 2 HOA's in the Auto position d 260. Verify the following: _ 260.1. Lead Supply Pump starts v 260.2. Flow is read on the Uttra Sonic Flow Meter f, 260.3. Record the flow rate from Supply Pump 1 5.75 GPM Y Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 18of21 • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 260.4. Record the flow rate from Supply Pump 2 6.25 GPM Day Tank 4 flow capacity 261. Place the Supply Pumps 1 and 2 HOA in Off 262. Retum Day Tanks 1, 2, 3, 4, 5, and 6 to 75% V 263. Verify the following: =l 283.1. Fill Solenoid Valves for Day Tanks 1, 2, 3, 4, 5, and 6 are open 263.2. Ultra Sonic Flow Meter installed on Day Tank 1 fill piping Place the Supply Pump 1 and 2 HOA's in the Auto position 265. Verify the following: 265.1. Lead Supply Pump starts . 265.2. Flow is read on the Ultra Sonic Flow Meter b` 265.3. Record the flow rate from Supply Pump 1 GPM NOTE 3 / NOTE 4 X 265.4. Record the flow rate from Supply Pump 2 GPM NOTE 3 / NOTE 4 X Day Tank 5 flow capacity to 266. Place the Supply Pumps 1 and 2 HOA in Off . 267. Retum Day Tanks 1, 2, 3, 4, 5, and 6 to 75% 268. Verify the following: 268.1. Fill Solenoid Valves for Day Tanks 1, 2, 3, 4, 5, and 6 are open ,/ 268.2. Ultra Sonic Flow Meter installed on Day Tank 1 fill piping V 269. Place the Supply Pump 1 and 2 HOA's in the Auto position ✓ 270. Verify the following: 270.1. Lead Supply Pump starts 270.2. Flow is read on the Ultra Sonic Flow Meter 270.3. Record the flow rate from Supply Pump 1 GPM NOTE 3 / NOTE 4 X 270.4. Record the flow rate from Supply Pump 2 GPM NOTE 3 / NOTE 4 X Day Tank 6 flow capacity ° 271. Place the Supply Pumps 1 and 2 HOA in Off 272. Retum Day Tanks 1, 2, 3, 4, 5, and 6 to 75% 273. Verify the following: ;_` 273.1. Fill Solenoid Valves for Day Tanks 1, 2, 3, 4, 5, and 6 are open Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 19 of 21 • • • LEE TECHNOLOGIES LEVEL 4 CHECKLIST 273.2. Ultra Sonic Flow Meter installed on Day Tank 1 fill piping 274. Place the Supply Pump 1 and 2 HOA's in the Auto position .r' 275. Verify the following: 275.1. Lead Supply Pump starts Y 275.2. Flow is read on the Ultra Sonic Flow Meter 275.3. Record the flow rate from Supply Pump 1 GPM NOTE 3 J NOTE 4 X 275.4. Record the flow rate from Supply Pump 2 GPM NOTE 3 / NOTE 4 X 276. Place Supply Pump 1 and 2 in the hand position 276.1. Record the flow rate at Day Tank 4 6.0 GPM .r 277. Verify that the Fuel System is retumed to normal line up 278. End of Test Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 20 -of 21 • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Section 0 Comments Comments Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/15/2010, the following was noted: Note 1. Phase 1 & 2 BMS does not show the Fuel Oil system alarms, there is an alarm log that show that the alarms were sent to BMS. The operating system that monitors the alarms does not show the alarm. Note 2. The Leak Detect floats were not pulled from the Phase 1 & 2 Day Tanks to keep from possibly causing damage to the wiring. Note 3. Flow could not be seen with the Ultra Sonic Flow Meter. Note 4. The received a Loss of Flow alarm during the testing of the flow. Due to the low flow rates when all Day Tanks are calling, recommend increasing the Supply Pump size or putting a piping tee in were the lines meet. Recommend moving the Low Level float up to 25% to ensure that the engine cuts out before the level of the tank get to the level of the generator suction uptake. Due to low fuel flow when all 6 tanks are calling for fuel, recommend that in the event that this happens the Supply Pumps are placed in hand until they are no longer required. Section 05 Functional Toot Witness F: Verification Lee Technologies representative has witnessed or participated in this checklist, has verified equipment is ready per checklist, and attests to the accuracy and completeness of this report. Printed Name: Trent Mintz Signature: Date: 7/15/2010 Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 21 of 21 • • LEE TECHNOLOGIES" LEVEL 4 CHECKLIST P Se�� , Procedure Me: '',,:,cod re INTERNAP-TUK-WA-CX-GLYCOL PUMPS intc:,•:,;aor, Submittal Date: 18 May 10 y - Procedure Work Date: 7/14/2010 P1 °gym Work du Time Frame: 0800-1700 Customer Name: - - I me m a p Customer's Solomon project Code. Address: Street Address: 3355 South 120th Place State: Zr ip Tukwila WA 98168 Cus omerPOC: Customer POC Name: Kathy Mclnvale Phone Numbers: shoe: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning Su • = roisor. Herbert Burnett Phone Numbers: Phone Number 703 -968 -0300 Mobile: 713.423.4335 Page- S=t'° ``2 Pine; -riw> O er.i -,. Equipment Functional Checks for Glycol Pump P -03 -1A Affected Area: I Systems Affected: Equipment Information: Manufacturer Stulz Equipment Type: Glycol Pump Modell: GPS -150 -D Serial d: 1012231 Procedure overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. educe Pre-Procedure Require Manufacturers start up complete and all discrepancies corrected or noted for future correction. ` =- - ='= Detailed Procedure �Aed / ooedure Camay 1. Review Manufactures start-up documentation. 2. Review pump curves. u 3. Review performance data. 4. Review Test and Balance report 5. Review calibration documents X 6. Manufactures Rep present. 7. Unit clean and free of leaks 8. Verify the foHowing: '''= 8.1. Motor Data 8.1.1. HP: 15 RPM: 3520 8.1.2. Volts:. 460 Phase: 3 8.1.3. Motor Nameplate Volts: 460 Volts 8.1.4. Motor Nameplate Amps: 17.7 Amps Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 4 • • • ,/141 LEE TECHNOLOGIES" LEVEL 4 CHECKLIST 82 Pump Data: 8.2.1. Flow GPM: 288 GPM ,../ 9. Verify Differential Pressure Note: The following readings will be taken at gauges located at the pump 9.1. Supply Pressure: psig X 9.2. Retum Pressure: psig X 9.3. Delta: psig X 10. Verify Controls are complete and operational .7 11. Equipment tag & nametag affixed 12. Verify alignment has been conducted. X 13. Verify the following have been installed and calibrated: = V 13.1. Sensors installed per spec 4/ 14. Verify valves installed in correct flow direction V 15. Verify pump has been properly lubricated . 16. Verify the pipe fittings are complete and pipes are supported 17. Verify the power disconnects are in place and labeled 18. Verify the foHowing: -,'7.,'..-:-' t._!1•-.7-Af., 18.1. All electrical connections tight i 18.2. Motor safeties in place and operational 18.3. Control system interlocks connected and functional 18.4. All control devices and wiring complete 19. Verify the proper pump rotation under normal operation / 20. Verify no leaking apparent around fitting Note: Pumps operate in LeacUBack-up configuration 21. At BMS start the Lead pump / 22. Verify the following 22.1. Flow switch indicates flow established 22.2. No alarms at BMS -7 23. Open disconnect on Lead Pump ..,, 24. Verify the following: Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 4 • • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 24.1. Lead Pump stops •" 24.2. Back-up Pump starts Y" 24.3. Alarm received at BMS v 25. Close Lead pump disconnect 26. Verify the following: 26.1. Back -up Pump stops 26.2. Lead Pump restarts 26.3. Alarm Geared at BMS ✓ 27. Restore system to normal operation Line -up 28. At BMS simulate need for mechanical cooling f 29. Verify the following: y r r 29.1. Lead pump comes on line 29.2. Flow is verified at BMS 30. At BMS simulate need for Economizer mode 31. Verify the following: , .. 31.1. Lead pump continues to operate for 3 minutes 32. Restore system line -up a` 33. Verify BMS graphics 34. End of test Template Rev. 07022010 Lee Technologies Group. © Copyright2010 Proprietary use pursuant to company policy Page 3 of 4 • • • LEE TECHNOLOGIES"' LEVEL 4 CHECKLIST Section 04 COP 111E. iliS Comments Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/14/2010, the following was noted: Step 5. Did not have calibration documentation at the time of testing. Steps 9.1 thru 9.3. System does not have local gauges, flow verification was done with the test and Balance report. Step 12. Pump alignment report was not received at the time of testing. Pump design flow is 288 GPM, the system is flowing at 410 GPM with one pump. The triple duty valve is set at 30% and the Motor AMPS at 17.7, FLA Secucn 05 F,:•u;tio na 7 Lee Technologies representative has witnessed or participated in this checklist; has verified equipment is ready per checklist, and attests to the accuracy and completeness of this report. Ftfnesd Name: Trent Printz Signatwe: oats:. 7/14/2010 Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 4 of 4 • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Si-cticn DI_ a"' r`itr—a Ini,rn;t•o^ Rocedure Title: INTERNAP TUK- WA-CX- GLYCOL PUMPS Submittal Date: 18 May 10 Procedure Work per: 7/14/2010 Procedure Work Time Frame: 0800 -1700 Customer Name: Intemap Customary Solomon Aged Cods: Address. SbeetAddess: 3355 South 120th Place stare: Znx Tukwila WA 98168 CustomerPOC. Customer POCName: Kathy Mclnvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning s , : rvisor Herbert Burnett Phone Numbers: Phone Number. 703- 968 -0300. Mobile: 713.423.4335 Pager. ,"''r." Equipment Functional Checks for Glycol Pump P -03 -1B P�nredcra :..�a :��.,. Affected Area: Systems Affected: Equipment information: Manufacturer: Stutz Equipment Type: Glycol Pump Model #: GPS -150 -D Serial o: 1012231 Procedure overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre-Procedure Requirements: Manufacturers start up complete and all discrepancies corrected or noted for future correction. _ , =° Detailed Procedure Detailed PIoaedfae: 1. Review Manufactures start-up documentation. 2. Review pump curves. f' 3. Review performance data. 4. Review Test and Balance report 5. Review calibration documents X 6. Manufactures Rep present. 7. Unit clean and free of leaks 8. Verify the following :. `ti 5 T 8.1. Motor Data 8.1.1. HP: 15 RPM: 3520 8.1.2: Volts: 460 Phase: .3 8.1.3. Motor Nameplate Volts: 460 Volts 8.1.4. Motor Nameplate Amps: 17.7 Amps Template Rev. 07022010 Lee Technologies Group Copyright 2010 Proprietary use pursuant to company policy Page 1 of 4 • • 11 LEE TECHwaocra° LEVEL 4 CHECKLIST 8.2. Pump Data: F..._ 8.2.1. Flow GPM: 288 GPM 9. Verify Differential Pressure Note: The following readings will be taken at gauges located at the pump 9.1. Supply Pressure: psig X 9.2. Retum Pressure: psig X 9.3. Delta: psig X 10. Verify Controls are complete and operational 11. Equipment tag & nametag affixed 12. Verify alignment has been conducted. X 13. Verify the following have been installed and calibrated: 13.1. Sensors installed per spec 14. Verify valves installed in correct flow direction 15. Verify pump has been properly lubricated 1 16. Verify the pipe fittings are complete and pipes are supported _ 1/ 17. Verify the power disconnects are in place and labeled` 18. Verify the following: ty :, "r 18.1. All electrical connections tight - 18.2. Motor safeties in place and operational 18.3. Control system interlocks connected and functional 18.4. All control devices and wiring complete 19. Verify the proper pump rotation under normal operation 20. Verify no leaking apparent around fitting Note: Pumps operate in Lead/Back -up configuration 21. At BMS start the Lead pump 22. Verify the following 22.1. Flow switch indicates flow established 22.2. No alarms at BMS 23. Open disconnect on Lead Pump 24. Verify the following: Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 4 • • L� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 24.1. Lead Pump stops 24.2. Back -up Pump starts 24.3. Alarm received at BMS 25. Close Lead pump disconnect 26. Verify the following: `' w 26.1. Back -up Pump stops 26.2. Lead Pump restarts 28.3. Alarm cleared at BMS -7 27. Restore system to normal operation Line -up 28. At BMS simulate need for mechanical cooling 29. Verify the following: 29.1. Lead pump comes on line 29.2. Flow is verified at BMS 30. At BMS simulate need for Economizer mode 31. Verify the following: Y i 4 31.1. Lead pump continues to operate for 3 minutes T` 32. Restore system line -up 33. Verify BMS graphics 34. End of test p: =' Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 4 • • L/t LEE TECHNOLOGIES' Section G' LEVEL 4 CHECKLIST Comments Insert any comments applicable to the checklist: Conducted Level 4 testing on 7114/2010, the following was noted: Step 5. Did not have calibration documentation at the time of testing. Steps 9.1 thru 9.3. System does not have local gauges, flow verification was done with the test and Balance report. Step 12. Pump alignment report was not received at the time of testing. Pump design flow is 288 GPM, the system is flowing at 410 GPM with one pump. The triple duty valve is set at 30% and the Motor AMPS at 17.7, FLA Section OE ct c.,n! _ s, Lee Technologies representative has witnessed or participated In this checklist, has verified equipment is ready per checklist, and attests to the accuracy and completeness of this report. Printed Name: Trent Printz Template Rev. 07022010 Signature: Date: Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy 7/14/2010 Page 4 of 4 • • • LEE TECHNOLOGIES°" LEVEL 4 CHECKLIST Section 01 l�oeedureTlge: INTERNAP- TUK- WA-CX- HUMIDIFIERS P1OCedLfe Information Submittal Date: 18 May 10 y Procedure Work Date: 7/10/2010 Procedure Work Time Frame: 0800 -1700 Customer Name: Intemap Customer's Solomon Project Code Address: Street Address: 3355 South 120th Place City Stets: Zip: Tukwila WA 98168 Customer POC: Customer POC Name: Kathy Mclnvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissloning Su • eN/SOr Herbert Burnett Phone Numbers: Phone Number. 703 -968 -0300 Mobile: 713.423.4335 Pages d20 a Equipment Functional Checks for Humidifier # 3 -1 r`cion P rviRw Affected Area: Systems Affected: Equipment Information: Manufacturer SPEC -AIR Equipment Type: Humidifier Model #: N/A Serial #: 4282 Procedure Overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre - Procedure Requirements: Section 03 Manufacturers start up complete and all discrepancies corrected or noted for future correction. Detailed Procedure Procedure Details Detailed Procedure: Complete 1. Record unit designation, model, and serial number in appropriate blocks above. • 2. Verify supply power connected to a GFI circuit 3. Verify piping connected and tight 4. Verify fill valve opens and closes !' 5. Verify drain valve opens and closes 6. Verify Sump Pump operational ✓ 7. Verify solenoid valve installed V NOTE: humidifier operates when the RTU economizer is inactive. 4�t 8. At BMS enable the Humidifier 9. Verify operation of freeze protection at (15° dead band) 9.1. Supply valve shuts _ 9.2. Drain valve opens 10. Space Humidity. 69.2 % v Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 3 • • • L� LEE TECHNOLOGIES" LEVEL 4 CHECKLIST 11. At BMS simulate space humidity below 35% 12. Verify the following: 12.1. Humidifier activates .` 12.2. Solenoid valve is activated and sump pump operational 13. At BMS simulate duct humidity above 80% F' 14. Verify the humidifier shuts down V 14.1. Solenoid valve shuts ,( 15. At BMS simulate duct humidity below 70% 16. Verify the humidifier activates 1 16.1. Solenoid valves opens r 17. At BMS simulate space humidity above 55% / 18. Verify the humidifier deactivates ,/ 18.1. Sump pump shuts down ,/ 18.2. Solenoid valve shuts ,r 19. At BMS deactivate the humidifier 20. At BMS restore the humidifier controls 21. Verify point in BMS v' 22. End of test. section 04 Comments commanls Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/10/2010, the following was noted: Permanent unit identification labeling has not been attached. Circuit and breaker location labeling is not attached. Sump Level float requires adjustment. Trash and debris in basin. 3. Union leaking downstream from solenoid valve Note 1 Automatic Fill and Drain Valves are not terminated in the Control Panel Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 • • %41) LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Verification of repairs to the Humidifiers was completed on 7/20/2010 Leaking union was corrected Auto Fill and Drain Valve operated correctly Section 05 Functional Test Witness R. Vet fication Lee Technologies representative has witnessed or participated in this checklist, has verified equipment is ready per checkist, and attests to the accuracy and completeness of this report. Ainted Name: Trent Printz Signature: Date: 7/20/2010 Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 3 • • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Section 01 PnxxduraTdfe. INTERNAP-TUK-WA-CX-HUMIDIFIERS P1Ocodiuee Information Submittal Date: 18 May 10 Procedure Work Date: 7/10/2010 Procedure Work Time Frame: 0800 -1700 Customer Name: Intemap Customers Solomon Project Coda. Address: SbeetAddress: 3355 South 120th Place CV ryt,. Zip: Tukwila WA 98168 CustomerPOC: Customer POCName: Kathy Mclnvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning Su . ervisor Herbert Burnett Phone Numbers: Phone Number. 703- 968 -0300 Mobile: 713.423.4335 Pager. Psectign mradure o= Over VOW Equipment Functional Checks for Humidifier # 3 -2 Affected Area Systems Affected Equipment Information: Manufacturer - - SPEC -AIR Equipment Type: Humidifier Model IF: N/A Serial A: 4283 Procedure Overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre - Procedure Requirements: section 0' Procedure Details Manufacturers start up complete and all discrepancies connected or noted for future correction. Detailed Procedure Detailed Procedure: Complete 1. Record unit designation, model, and serial number in appropriate blocks above. 2. Verify supply power connected to a GFI circuit ✓ 3. Verify piping connected and tight ✓ 4. Verify fill valve opens and closes 5. Verify drain valve opens and closes 6. Verify Sump Pump operational 7. Verify solenoid valve installed NOTE: humidifier operates when the RTU economizer is inactive. 1 r; 8. At BMS enable the Humidifier ,r 9. Verify operation of freeze protection at (15° dead band) 9.1. Supply valve shuts 9.2. Drain valve opens p . 10. Space Humidity. 69.2 % / Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 3 • • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 11. At BMS simulate space humidity below 35% 12. Verify the following: }Y7: 12.1. Humidifier activates 12.2. Solenoid valve is activated and sump pump operational 13. At BMS simulate duct humidity above 80% / 14. Verify the humidifier shuts down 14.1. Solenoid valve shuts 15. At BMS simulate duct humidity below 70% J' 16. Verify the humidifier activates ✓ 16.1. Solenoid valves opens !` 17. At BMS simulate space humidity above 55% v 18. Verify the humidifier deactivates 18.1. Sump pump shuts down ✓ 18.2. Solenoid valve shuts 19. At BMS deactivate the humidifier y` 20. At BMS restore the humidifier controls 21. Verify point in BMS 22. End of test. Y Becton oa Comments Comments Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/10/2010, the following was noted: Permanent unit identification labeling has not been attached. Circuit and breaker location labeling is not attached. Trash and debris in basin. Bolts in the overflow pan. Door hit the Drain Solenoid Valve handle. 3. Brazed union above pump is leaking Note 1 Automatic Fill and Drain Valves are not terminated in the Control Panel Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page2of3 • • %III LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Verification of repairs to the Humidifiers was completed on 7/20/2010 Auto Fill and Drain Valve operated correctly Section 05 Functional Test Witness & Verification Lee Technologies representative has witnessed or participated in this checklist, has verified equipment Is ready per checklist, and attests to the accuracy and completeness of this report. Printed Name: Trent Printz Template Rev. 07022010 Signature: Date_ Lee Technologies Group ® Copyright 2010 Proprietary use pursuant to company policy 7/20/2010 Page 3 of 3 • • /1t LEE TECHNOLOGIES" LEVEL 4 CHECKLIST Section of Procedure Information Procedure Title: INTERNAP TUK- WA-CX- HUMIDIFIERS Submittal Date: 18 May 10 y Procedure Work Date: 7/10/2010 Procedure work Time Frame: Q800 -1700 Customer Name: I ntem ap Customers Soloman Project Code: Address: Street Address: 3355 South 120th Place City Stets: Zip. Tukwila WA 98168 Customer POC: Customer POC Name: Kathy Mclnvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning Su • ndsor Herbert Burnett Phone Numbers: Phone Number. 703 - 968 -0300 Mobile: 713.423.4335 Pager. Section 02 Equipment Functional Checks for Humidifier # 3 -3 q ProcedureOvervle.0 Affected Area: Systems Affected: Equipment information: Manufacturer SPEC -AIR Equipment Type: Humidifier Model #: WA Serial #: 4284 Procedure overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre- Procedure Requirements: Manufacturers start up complete and all discrepancies corrected or noted for future correction. Section 03 Detailed Procedure - Procedure Dorarts Detailed.Proeedure: ... Complete 1. Record unit designation, model, and serial number in appropriate blocks above. V 2. Verify supply power connected to a GFI circuit ,✓ 3. Verify piping connected and tight >! 4. Verify fill valve opens and closes Vr 5. Verify drain valve opens and closes v 6. Verify Sump Pump operational 7 7. Verify solenoid valve installed NOTE: humidifier operates when the RTU economizer is inactive.' 8. At BMS enable the Humidifier 9. Verify operation of freeze protection at (15° dead band) 9.1. Supply valve shuts ./. 9.2. Drain valve opens 5` 10. Space Humidity. 69.2 % . Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 3 • • • L� LEE TECHNOLOGIES` LEVEL 4 CHECKLIST 11. At BMS simulate space humidity below 35% 12. Verify the following: 12.1. Humidifier activates 12.2. Solenoid valve is activated and sump pump operational 13. At BMS simulate duct humidity above 80% v- 14. Verify the humidifier shuts down ✓ 14.1. Solenoid valve shuts 15. At BMS simulate duct humidity below 70% V 16. Verify the humidifier activates v 16.1. Solenoid valves opens 17. At BMS simulate space humidity above 55% v 18. Verify the humidifier deactivates 18.1. Sump pump shuts down 18.2. Solenoid valve shuts 19. At BMS deactivate the humidifier 20. At BMS restore the humidifier controls 21. Verify point in BMS V 22. End of test. Section o-, Comments Comments Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/10/2010, the following was noted: Permanent unit identification labeling has not been attached. Circuit and breaker location labeling is not attached. Sump Level float requires adjustment. _ Trash and debris in basin. Note 1 Automatic Fill and Drain Valves are not terminated in the Control Panel Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 • • • L!'lt LEE TECHNOLOGIES" LEVEL 4 CHECKLIST Verification of repairs to the Humidifiers was completed on 7/20/2010 Auto Fill and Drain Valve operated correctly Section 05 Functions! Test whim E \lerIficntion Lee Technologies representative has witnessed or participated in this checklist, has verified equipment is ready per checklist, and attests to the accuracy and completeness of this report. Printed Name: Trent Printz Template Rev. 07022010 Signature: Date: Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy 7/20/2010 Page3of3 • • • .alk LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Section n1 Procedure Tide: INTERNAP- TUK- WA-CX- HUMIDIFIERS P1 oc,!ti1i 2 Inl., r t.,,, 18 May 10 y Procedure Work Date: 7/10/2010 Procedure Work Time Frame: 0800 -1700 Submittal Date: Customer Name: Intemap Customer's Solomon Project Cod.: Address: Street Address: 3355 South 120 Place City: State: Zip: Tukwila WA 98168 Customer POC: Customer POC Name: Kathy Mclnvale Phone Numbers: office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning Su • ervlsor. Herbert Burnett Phone Numbers: Phone Number. 703- 968 -0300 Montle: 713.423.4335 Paper o2Overvi,w+ Equipment Functional Checks for Humidifier # 3-4 Psection rr�red ura Affected Area: Systems Affected: Equipment Information: Manufacturer. SPEC -AIR Equipment Type: Humidifier Model &: N/A Serial #: 4285 Procedure Overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre - Procedure Requirements: Manufacturers start up complete and all discrepancies corrected or noted for future correction. Section 03 Detailed Procedure Procedure Details Detailed Rtocedure: Complete 1. Record unit designation, model, and serial number in appropriate blocks above. 2. Verify supply power connected to a GFI circuit 3. Verify piping connected and tight 4. Verify fill valve opens and closes `- 5. Verify drain valve opens and closes 6. Verify Sump Pump operational 7. Verify solenoid valve installed NOTE: humidifier operates when the RTU economizer is inactive. .Vl 8. At BMS enable the Humidifier 9. Verify operation of freeze protection at (15° dead band) 9.1. Supply valve shuts TM 9.2. Drain valve opens 10. Space Humidity. 69.2 % df Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 3 • • • a!" LEE TECHNOLOGIES` LEVEL 4 CHECKLIST 11. At BMS simulate space humidity below 35% 12. Verify the following: nx }' 12.1. Humidifier activates 12.2. Solenoid Valve is activated and sump pump operational '7 13. At BMS simulate duct humidity above 80% '* 14. Verify the humidifier shuts down 14.1. Solenoid valve shuts 15. At BMS simulate duct humidity below 70% 16. Verify the humidifier activates ri 16.1. Solenoid valves opens '7 17. At BMS simulate space humidity above 55% y` 18. Verify the humidifier deactivates 18.1. Sump pump shuts down 7 18.2. Solenoid valve shuts 19. At BMS deactivate the humidifier' 20. At BMS restore the humidifier controls 21. Verify point in BMS 22. End of test. Section 0 Comments comments Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/10/2010, the following was noted:. Permanent unit identification labeling has not been attached. Circuit and breaker location labeling is not attached. Trash and debris in basin. 3. Union next to piping tee leaking Note 1 Automatic Fill and Drain Valves are not terminated in the Control Panel Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 • • • ?gt LEE TECHNOLOGIES` LEVEL 4 CHECKLIST Verification of repairs to the Humidifiers was completed on 7/20/2010 Leaking union was corrected Auto Fill and Drain Valve operated correctly Section 05 Functional Test Witness :. Verification Lee Technologies representative has witnessed or participated in this checklist, has verified equipment is ready per checklist, and attests to the accuracy and completeness of this report. Rimed Marne: Trent Printz Template Rev. 07022010 Signature: Deter Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy 7/20/2010 Page 3 of 3 • • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Section 0 Procedure Inforniminu Submittal Date: Procedure Title: INTERNAP-TUK-WA-CX-HUMIDIFIERS 18 May 10 y Procedure Work Date: 7/10/2010 Procedure Work Time Frame: 0800 -1700 Customer Name: I me rn ap Customer's Solomon Pmf ct Code: Address: Street Address: 3355 South 120th Place City: St . Zip: Tukwila WA 98168 CustomerPOC: CustomsrPOC Name: Kathy Mclnvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning Su • ervlsor: Herbert Burnett Phone Numbers: Phone Number 703 - 968 -0300 Mobile: 713.423.4335 Pager. onircedwe o2Overview Functional Checks for Humidifier # 3 -5 Equipment Pszci Affected Area: Systems Affected: Equipment Information: Manufacturer. SPEC -AIR Equipment Type: Humidifier Model #: N/A Serial #: 4286 Procedure Overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre - Procedure Requirements: Manufacturers start up complete and all discrepancies corrected or noted for future correction. Section ore. Detailed Procedure Procedure Details Detailed Procedure: _ Complete 1. Record unit designation, model, and serial number in appropriate blocks above. r 2. Verify supply power connected to a GFI circuit 3. Verify piping connected and tight 4. Verify fill valve opens and closes v 5. Verify drain valve opens and closes 6. Verify Sump Pump operational 7. Verify solenoid valve installed / NOTE: humidifier operates when the RTU economizer is inactive. 8. At BMS enable the Humidifier 9. Verify operation of freeze protection at (15° dead band) 9.1. Supply valve shuts 9.2. Drain valve opens 10. Space Humidity. 69.2 % Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 1 of 3 • • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 11. At BMS simulate space humidity below 35% 12. Verify the following: 12.1. Humidifier activates V 12.2. Solenoid valve is activated and sump pump operational Y' 13. At BMS simulate duct humidity above 80% 14. Verify the humidifier shuts down ✓ 14.1. Solenoid valve shuts 15. At BMS simulate duct humidity below 70% .r 16. Verify the humidifier activates 16.1. Solenoid valves opens 17. At BMS simulate space humidity above 55% 18. Verify the humidifier deactivates 18.1. Sump pump shuts down 18.2. Solenoid valve shuts 19. At BMS deactivate the humidifier 20. At BMS restore the humidifier controls 21. Verify point in BMS 22. End of test. vf Section 04 Comments Comments Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/10/2010, the following was noted: Permanent unit identification labeling has not been attached: Circuit and breaker location labeling is not attached. Door hits the Drain Solenoid Valve handle. Note 1 Automatic Fill and Drain Valves are not terminated in the Control Panel Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 • • • L� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Verification of repairs to the Humidifiers was completed on 7/20/2010 Auto Fill and Drain Valve operated correctly Section 05 Functional Tc:.t V■Iitness Vet ificotion Lee Technologies representative has witnessed or participated in this checklist, has verified equipment is ready per checklist, and attests to the accuracy and completeness of this report. Printed Name: Signature: Date: Trent Printz 7/20/2010 Template Rev. 07022010 Lee Technologies Group Copyright 2010 Proprietary use pursuant to company policy Page 3 of 3 • • • L� LEE TECHNOLOGIES” LEVEL 4 CHECKLIST c- c'icr. 01 Procedure Tit b: P'°°';:'■°e INTERNAP- TUK -WA -CX -LIFT PUMP Submittal Date: 18 May 10 y Procedure Work Date: 7/8/2010 Procedure Work Time Fume: 0800 -1700 Customer Name: Intemap Customer's Solomon Roject Code. Address: Street Address: 3355 South 120th Place City State: Zip: Tukwila WA 98168 Customer POC: Customer POCName: Kathy Mclnvate Phone Numbers: Office: 404.302.9753 Mo : 404.547.8915 Lee Technologies Commissioning Su. = !visor. Herbert Burnett Phone Numbers:" Phone Number 703- 968 -0300 Mobile: 713.423.4335 Paper `,cri:- - Affected Area: Equipment Lift Pump CX Procedure I Systems Affected: Equipment information: Manufacturer WEIL Equipment Type: Lift Pump Model it W- 9709- 4T05631 Serial e: WA Procedure Overview: This testing will verify the operation of the Lift Pump. Testing will not impact operation of the operating facilities. Anticipated Results: Equipment will operate within design capabilities and factory instructions. All discrepancies will be corrected or noted for future correction. Pre-Procedure Requirements: Manufactures start-up completed. - s-='o^ ' ' p O edi,fi? Dt1; „1s Detailed Procedure Detailed Ps:cerium: CoMplate 1. Review Manufactures start-up documentation. 2. Review performance data. ✓ 3. Unit clean and free of leaks V 4. Verify the following: Motor Data:: " -:. 4.1. HP: .5 RPM: 1750 4.2. Volts: 460 Phase: 3 `f `d 4.3. Panel Number. HP 31, 37, 39, 41 5. Perform visual check of the equipment 5.1. Leaks 5.2. Signs of deterioration 6. Verify the Model 8151 Control Panel HOA is connected with power on v Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 3 L/� LEE TECHNOLOGIES` IP • LEVEL 4 CHECKLIST 7. At the Model 8151 Control Panel HOA , 7.1. Place HOA Pump 1 in off 7.2. Place HOA Pump 2 in off 8. Add water to the basin 8.1. Verify the high water alarm activates at control panel r 8.2.. Verify alarm received at BMS 9. Place the Model 8151 Control Panel HOA Pump 1 in Auto e` 10. Place the Model 8151 Control Panel HOA Pump 2 in Auto ve 10.1. Verify the following:_{ 10.1.1. Primary pump is pumping water out of the basin 10.1.2. Place primary pump HOA in Off Y' 10.1.3. Verify Back -up pump starts 10.1.4. Alarm received at BMS 10.1.5. Pump shuts off with water still covering the top of the pump J 11. Restore Model 8151 Control Panel to normal operation 12. Verify the alarm dears at BMS 13. Ensure all alarm lights/homs extinguish and panel retums to normal y, 14. Place the Model 312 Control Panel HOA in Auto 15. Perform visual check of the equipment: 15.1. Leaks / 15.2. Unusual noises 15.3. Signs of deterioration 16. Lift the second pump on float / 17. Verify that both pumps are on 18. Release float / 19. Verify that the pumps continue to operate ✓ 20. At the pump shut off float verify that both pumps shut off v' 21. Continue to fill the basin r Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 3 • • • L/411 LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 22. When the water level is above the pump shut off float 7 23. Lift the High Level float Y` 24. Verify the following: ti 24.1. Pumps 1 & 2 start 24.2. High Level alarm at the Model 312 Control Panel 1 24.3. High Level alarm received at BMS 25. Release the High Level float 26. Verify the following: 26.1. High Level alarm cleared at the Model 312 Control Panel Y 26.2. High Level alarm clear at BMS 26.3. Pumps continue to operate to the pump shut off float v 27. End of test Section `' Comments Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/8/2010 the following was noted: Drained two Humidifiers into the catch basin, with two pumps operating the level continued to rise. Section ■ - .:::;,o .d, T,SI \r,;,;:, @g� ; Lee Technologies representative has witnessed or participated in this checklist, has verified equipment Is ready per checklist, and attests to the accuracy and completeness of this report. Printed Name: S7gnatre: Data Trent Printz r / If V, 7/8/2010 Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 3 IP • • L� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Section i'i'i F "' ,doro 10(U1111.thUll Prooedure Tt : INTERNAP-TUK-WA-CX-RTU Submittal Date: 18 May 10 y Procedure Worts Date: 7/10/2010 Procedure work Time Frame: 0800 -1700 Customer Name: Intemap Custr ner s Salomon Raise Cade. Address: Sheet Address: 3355 South 120 Place City: State: Zip: Tukwila WA 98168 Customer POC: Customer POC Nine: Kathy Mdnvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning Su. =ivisor. Herbert Bumett Phone Numbers: Phone Number 703 - 968 -0300 Mobile: 713.423.4335 Paper: `6—` -°-,- I == Prnrarlwr �,,..;vi.z:,� Equipment Functional Checks for RTU # 3 -1 Affected Area: Systems Affected: Equipment Information: Manufacturer McQuay Equipment Type: RTU Model #; RTD130DLY Serial #: FB0U10040029400 Procedure Overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: ' Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pie - Procedure Requirements: ' Manufacturers start up complete and all discrepancies corrected or noted for future correction. FIB., tJd ' 03 io;ds Detailed Procedure Deta#ad Pmcedare: Complete 1. Review Manufactures start-up documentation. / 2. TAB completed and approved for hydronic systems and terminal units connected. F` 3. Manufactures Rep present. 4. Unit dean and free of leaks X 5. Verify Controls are complete and operational ✓ 6. Verify the VFD has been tested by manufacture 7. Equipment tag & nametag affixed Filters 8. Verify the following: y 8.1. 1 set of 30% Filters m 8.2. 1 set of 65% final filters Smoke Detector : t,_ 9. Simulate activation of fire alarm system by spraying test smoke into Discharge air flow Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 6 • • .‘1) LEE TECHNOLOGIES" LEVEL 4 CHECKLIST 10. Verify the following: 10.1. Supply fan(s) will stop 10.2. Retum fan(s) will stop -7 10.3. Isolation dampers will dose 11. Reset fire alarm system v, 12. Verify the following: -.. 12.1. Isolation dampers will open 12.2. Supply fan(s) will start -,,' 12.3. Retum fan(s) will start Filter Dip 1,,:::: :- 13. Record Filter D/P set point. X 14. Adjust the D/P switch to 0.0 X 15. Verify the following: ',,:,-.--,•:.‘...4...; 15.1. Alarm received at BMS X 15.2. Alarm at RTU Control Panel . X 16. Restore D/P switch to set point X Note: All operating units operate in unison. 7,,,,,2, ., '4. :'-‘41:`,.:',Y■ Static Pressure Control 17. At BMS simulate Supply Fan Static Pressure Reset 18. Lower under floor static pressure set point below 1.5" ,,i- 19. Observe the following: 19.1. The supply fan ramps down V 19.2. Under floor static pressure reduces to set point ‘i 20. At BMS simulate raising under floor static pressure above 1.5° 21. Observe the following: 21.1. The supply fan ramps up to 100% 21.2. The under floor static pressure reaches and maintains set point v' 22. At BMS restore under floor static pressure set point 23. Verify the following: , ...,... 23.1. Unit restores to the designed static pressure set point Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 2 of 6 • • .4!lt LEE TECHNOLOGIES° ‘16./ LEVEL 4 CHECKLIST 24. At the Supply fan VFD .... ," -,.......: 24.1. Shut off power feeding VFD 24.2. Verify the following: v/ 24.2.1. Alarm for Fan Failure alarm received at BMS 24.3. Restore power - 25. At BMS simulate Relief Fan Static Pressure 26. Lower the space static pressure set point below 0.05" 27. Observe the following: 27.1. The Relief fan ramps up to 100% 1 27.2. Outside air damper maintains schedule 27.3. Return air remains maintains schedule ,.. 27.4. Data Center static pressure reduces to set point 28. At BMS restore space static pressure set point 29. Verify the following: ,,... ' --,''..• . ! 29.1. Unit restores to the designed space temp set point .. 29.2. Damper retum to scheduled positions -,.. 30. At the Exhaust fan VFD 30.1. Shut off power feeding VFD ,,,,, 302. Verify the following: 30.2.1. Alarm for Fan Failure alarm received at BMS vi 30.3. Restore power 31. At local control panel simulate inactive status for the economizer ,./ 32. Verify the following: 32.1. The Exhaust fan on v 32.2. Retum Air damper is modulating to maintain the schedule / 32.3. Outside Air mixing dampers dosed 33. Record Data Center Temperature. 70 ° ,.,..." 34. At BMS lower Data Center temperature set point below 55°. ..?" 35. Verify the following: 35.1. Compressors activate for cooling. Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 3 of 6 • • • .‘11 LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 35.2. Discharge air temperature decreases 36. At BMS raise the Supply Air temperature above 55°. 37. Verify the following: 37.1. Compressors shutdown 38. Restore Data Center temperature. 39. At BMS simulate high supply air temperature 40. Verify the following 40.1. High Supply Air Temperature alarm at BMS ,..' 41. At BMS simulate low supply air temperature ../ 42 Verify the following: 42.1. Low Supply Air Temperature ale= at BMS 43. At BMS restore supply air temperature set point 44. At BMS simulate high return air temperature ../ 45. Verify the following: 45.1. Retum Air High Temperature alarm at BMS 46. At BMS restore return air temperature. 47. Space Humidity. 69.6 % 48. At Local Control Panel simulate active status for the economizer 49. Verify the following: 49.1. The economizer Outside Air damper modulates to maintain the set-point 49.2. The RA damper will modulate to maintain the set-point 50. At the RTU open the disconnect switch v( 51. Verify the following: 51.1. Unit shuts down 51.2. Alarm received at BMS 51.3. Isolation damper closed 52. Close the disconnect at the RTU v 53. Verify the following: 53.1. RTU restarts 53.2. Alarm deared at BMS Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 4 of 6 • • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 53.3. Isolation damper opens prior to supply fan starting 54. At BMS disable the unit. 55. Verify the following 55.1. Humidifier isolation damper dosed 56. At BMS enable the unit Y' 57. Verify the following: 57.1. Humidifier Damper opens prior to supply fan starting VFD 58. Auto reset . 58.1. Shut off power feeding AFD /- 58.2. Restore power .7 59. Verify that VFD resets automatically ,.. 59.1. Supply fan operational: Y / N Exhaust fan operational: Y / N ,,, , 60. Manual - .± 61. Change VFD to manual mode - v 62. Verify that the VFD can manually ramp fan speed v 62.1. Supply fan operational: Y / N Retum fan operational: Y / N ..," 63. At local Exhaust VFD control panel operate the VFD through the following test points , i -;-,,,-,s -• NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step 63.1. 25% 15Hz ,e 63.2. 50% 30Hz 63.3. 75% 45Hz -i 63.4. 100% 60Hz 64. Once 100% is reached and the unit has been inspected and stabilized, operate the VFD through the following test points ,. NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step '• ' . 64.1. 75% 45Hz 64.2. 50% 30Hz v , 64.3. 25% 15Hz v 65. At local Supply VFD control panel operate the VFD through the following test points , Template Rev. 07022010 Lee Technologies Group Copyright 2010 Proprietary use pursuant to company policy Page 5 of 6 • • L� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST NOTE: Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step 65.1. 25% 15Hz 65.2. 50% 30Hz 65.3. 75% 45Hz 65.4. 100% 60Hz 66. Once 100% is reached and the unit has been inspected and stabilized, operate the VFD through the following test points ' NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step ' x' 66.1. 75% 45Hz 66.2. 50% 30Hz 66.3. 25% 15Hz 67. Retum the VFD to normal control ../ 68. Verify BMS graphics 69. Place system in normal operating mode 70. Attain copy of alarms and verify 71. End of test :section = Comments Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/10/2010, the following was noted: Step 4. Debris needs to be cleaned out of the unit. Steps 13 thru 16. Was unable to access and trigger the filter D/P switch. Becton 5 f-u,, ,,,,,,, ,; es, Wanes, ,, '✓e•ilic.,U4n Lee Technologies representative has witnessed or participated in this checdist, has verified equipment is ready per checklist, and attests to the accuracy and completeness of this report. Printed Marne: Signature: late: Trent Prtntz 7/10/2010 Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 6 of 6 • • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST Section ,01 Procedure Title: P'°° ?`'" INTERNAP-TUK-WA-CX-RTU Submittal Date: 18 May 10 Procedure Work Date: 7/10/2010 Procedure Work Time Frame: 0800 -1700 Customer Name: Intemap cilia.,., 19 Scion= roger Codes Address: Sheet Addresa: 3355 South 120th Place Y: State: Zip: Tukwila WA 98168 customerPOC: Customer POC Name: Kathy Mclnvale Phone Numbers: Off?o . 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning Su. =rvisor. Herbert Burnett Phone Numbers: Phone Number 703- 968 -0300 Mobile: 713.423.4335 Aver `ecoon 02 Equipment Functional Checks for RTU # 3 -2 Affected Area: Systems Affected: Equipment Informaion: Manufactuer McQuay Equipment Type: RTU Model #: RTD130DLY Serial #: FBOU10040029300 Procedure overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre- Procedure Requirements: Manufacturers start up complete and all discrepancies corrected or noted for future correction. Section °: Pt ocedwe Det ,ids Detailed Procedure Detailed P ocedure: Complete 1. Review Manufactures start-up documentation. 2. TAB completed and approved for hydronic systems and terminal units connected. y' 3. Manufactures Rep present. w� 4. Unit dean and free of leaks 5. Verify Controls are complete and operational 6. Verify the VFD has been tested by manufacture 7. Equipment tag & nametag affixed Filters 8. Verify the following: 8.1. 1 set of 30% Filters 8.2. 1 set of 65% final fitters 1 Smoke Detector 9. Simulate activation of fire alarm system by spraying test smoke into Discharge air flow v` Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 1 of 6 • • • .Allk LEE TECHNOLOGIES 16, LEVEL 4 CHECKLIST 10. Verify the following: 10.1. Supply fan(s) will stop v" 10.2. Retum fan(s) will stop / 10.3. Isolation dampers will close 11. Reset fire alarm system v/ 12. Verify the following: 12.1. Isolation dampers will open V 12.2. Supply fan(s) will start v" 12.3. Retum fan(s) will start v Filter D/P .....-,3-1....;y4; 13. Record Filter D/P set point. X 14. Adjust the D/P switch to 0.0 X 15. Verify the following: 15.1. Alarm received at BMS X 15.2. Alarm at RTU Control Panel X 16. Restore D/P switch to set point. X Note: All operating units operate in unison. Static Pressure Control 17. At BMS simulate Supply Fan Static Pressure Reset V 18. Lower under floor static pressure set point below 1.5" 19. Observe the following: t,..,:,,..,.., :7..,:. 19.1. The supply fan ramps down v 19.2. Under floor static pressure reduces to set point v" 20. At BMS simulate raising under floor static pressure above 1.5" v 21. Observe the following: -r.,..,,;,=1:1-,:i• 21.1. The supply fan ramps up to 100% v• 21.2. The under floor static pressure reaches and maintains set point s' 22. At BMS restore under floor static pressure set point 23. Verify the following: 23.1. Unit restores to the designed static pressure set point Vi Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 6 • • • L/1 LEE TECHNOLOGIES" LEVEL 4 CHECKLIST 24. At the Supply fan VFD 24.1. Shut off power feeding VFD 24.2. Verify the following: 24.2.1. Alarm for Fan Failure alarm received at BMS -/ 24.3. Restore power 25. At BMS simulate Relief Fan Static Pressure ,l 26. Lower the space static pressure set point below 0.05" 27. Observe the following: , c . 27.1. The Relief fan ramps up to 100% 27.2. Outside air damper maintains schedule 27.3. Retum air remains maintains schedule 27.4. Data Center static pressure reduces to set point 28. At BMS restore space static pressure set point 29. Verify the following: 29.1. Unit restores to the designed space temp set point _ ,,' 29.2. Damper retum to scheduled positions 30. At the Exhaust fan VFD 30.1. Shut off power feeding VFD 302. Verify the following: 30.2.1. Alarm for Fan Failure alarm received at BMS 30.3. Restore power 31. At local control panel simulate inactive status for the economizer 32. Verify the following: 32.1. The Exhaust fan on 32.2. Retum Air damper is modulating to maintain the schedule 32.3. Outside Air mixing dampers dosed 33. Record Data Center Temperature. 70 ° v 34. At BMS lower Data Center temperature set point below 55 °. 35. Verify the following: Y . 35.1. Compressors activate for cooling. Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 6 • • • LEE TECHNOLOGIEr LEVEL 4 CHECKLIST 35.2. Discharge air temperature decreases / 36. At BMS raise the Supply Air temperature above 55°. v 37. Verify the following: 37.1. Compressors shutdown 38. Restore Data Center temperature. 39. At BMS simulate high supply air temperature / 40. Verify the following .',•,_,*,''..`•,,, 40.1. High Supply Air Temperature alarm at BMS ,.. 41. At BMS simulate low supply air temperature v 42. Verify the following: _ 42.1. Low Supply Air Temperature alarm at BMS V 43. At BMS restore supply air temperature set point a 44. At BMS simulate high retum air temperature 45. Verify the following: .... , , 45.1. Retum Air High Temperature alarm at BMS . J 46. At BMS restore retum air temperature. 47. Space Humidity. 69.6 a' 48. At Local Control Panel simulate active status for the economizer ,7 49. Verify the following: 49.1. The economizer Outside Air damper modulates to maintain the set-point v. 49.2. The RA damper will modulate to maintain the set-point .., 50. At the RTU open the disconnect switch 51. Verify the following: ::...."="-',....,:•• - •-:,•.„--..,, ,,, 51.1. Unit shuts down 51.2. Alarm received at BMS 51.3. Isolation damper closed J 52. Close the disconnect at the RTU 53. Verify the following: 53.1. RTU restarts 53.2. Alarm cleared at BMS Template Rev. 07022010 Lee Technologies Group Copyright 2010 Proprietary use pursuant to company policy Page 4 of 6 • • • L� LEE TECHNOLOGIES` LEVEL 4 CHECKLIST 53.3. Isolation damper opens prior to supply fan starting 54. At BMS disable the unit. 55. Verify the following 55.1. Humidifier isolation damper closed 56. At BMS enable the unit 57. Verify the following: R 57.1. Humidifier Damper opens prior to supply fan starting VFD 58. Auto reset 58.1. Shut off power feeding AFD 58.2. Restore power 59. Verify that VFD resets automatically 59.1. Supply fan operational: Y / N Exhaust fan operational: Y / N ' 60. Manual '° 61. Change VFD to manual mode • 62. Verify that the VFD can manually ramp fan speed 62.1. Supply fan operational: Y / N Retum fan operational: Y / N 63. At local Exhaust VFD control panel operate the VFD through the following test points NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step ::; , a f 63.1. 25% 15Hz ✓ 63.2. 50% 30Hz ,r 63.3. 75% 45Hz 63.4. 100% 60Hz / 64. Once 100% is reached and the unit has been inspected and stabilized, operate the VFD through the following test points NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step 1}4 z' 64.1. 75% 45Hz Y� 64.2. 50% 30Hz 64.3. 25% 15Hz / 65. At local Supply VFD control panel operate the VFD through the following test points Template Rev. 07022010 Lee Technologies Group Copyright 2010 Proprietary use pursuant to company policy Page 5 of 6 • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST NOTE: Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step 65.1. 25% 15Hz 65.2. 50% 30Hz 65.3. 75% 45Hz '' 65.4. 100% 60Hz 66. Once 100% is reached and the unit has been inspected and stabilized, operate the VFD through the following test points NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step 66.1. 75% 45Hz 66.2. 50% 30Hz 66.3. 25% 15Hz '`f 67. Retum the VFD to normal control 68. Verify BMS graphics 69. Place system in normal operating mode 70. Attain copy of alarms and verify 71. End of test ^ " sec ;Or 0- Comments Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/10/2010, the following was noted: Steps 13 thru 16. Was unable to access and trigger the filter D/P switch. Secuc n_O Fi,,,; hc;;d; -, -,; vv■inr:s s Lee Technologies representative has witnessed or participated in this checklist, has verified equipment is ready per and attests to the accuracy and completeness of this report. Printed Name: Signature: Date: 7/10/2010 ehecidist, Trent Printz Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 6 of 6 • • • /lk LEE TECHNOLOGIES' L LEVEL 4 CHECKLIST Procedure Tit!e: cec.uon 01 P1O °edhc INTERNAP- TUK -WA- CX-RTU in(oimaf,ur Submittal Date: 18 May 10 Procedure Mrork Date: 7/10/2010 Procedure Work Time Frame: 0800 -1700 Customer Name: Intemap Customers &damn Propct Code. Address: Street Address: 3355 South 120th Place City State: Zip: Tukwila WA 98168 CustomerPOC: Customer MC Name: Kathy Mcinvale Phone Numbers' Office :. Mobile: 404.547.8915 Lee Technologies Commissioning Su : :visor. Herbert Bumett Phone Numbers: Plume Number. 703 -968 -0300 Mobile: 713.423.4335 Pager '�� °' Equipment Functional Checks for RTU # 3 -3 Prnr,hea C ?:c;rn =, Affected Area: Systems Affected: Equipment Information: Manufacturer McQuay Equipment Type: RTU Model n: RTD130DLY Serial It: FBOU10040034400 Procedure Overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre-Procedure Requirements: Manufacturers start up complete and all discrepancies corrected or noted for future correction. = ° ° P:occ ■lute ^ tt.ds Detailed Procedure - Detailed PFoeedroe :. Complete 1. Review Manufactures start-up documentation. 2. TAB completed and approved for hydronic systems and terminal units connected. fr 3. Manufactures Rep present. 4. Unit clean and free of leaks 5. Verify Controls are complete and operational 6. Verify the VFD has been tested by manufacture 7. Equipment tag & nametag affixed Filters 8. Verify the following: 8.1. 1 set of 30% Fitters 8.2. 1 set of 65% final filters °F Smoke Detector ; ;F.i 9. Simulate activation of fire alarm system by spraying test smoke into Discharge air flow Template Rev. 07022010 Lee Technologies Group Copyright 2010 Proprietary use pursuant to company policy Page 1 of 6 • • • .elk LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 10. Verify the following: r' 10.1. Supply fan(s) will stop 10.2. Return fan(s) will stop 10.3. Isolation dampers will dose 11. Reset fire alarm system 12. Verify the following: , r 12.1. Isolation dampers will open '7 12.2. Supply fan(s) will start r 12.3. Return fan(s) will start Fitter D/P 13. Record Filter D/P set point X 14. Adjust the D/P switch to 0.0 X 15. Verify the following: 15.1. Alarm received at BMS X 15.2. Alarm at RTU Control Panel X 16. Restore D/P switch to set point X Note: All operating units operate in unison. Static Pressure Control 17. At BMS simulate Supply Fan Static Pressure Reset ' 18. Lower under floor static pressure set point below 1.5" v 19. Observe the following: a;;<;,;:` 19.1. The supply fan ramps down vi 19.2. Under floor static pressure reduces to set point 20. At BMS simulate raising under floor static pressure above 1.5" aF 21. Observe the following: ` 21.1. The supply fan ramps up to 100% 21.2. The under floor static pressure reaches and maintains set point Y` 22. At BMS restore under floor static pressure set point '7 23. Verify the following: 23.1. Unit restores to the designed static pressure set point v Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 2 of 6 • • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 24. At the Supply fan VFD 4, 24.1. Shut off power feeding VFD Y' 24.2. Verify the following: 242.1. Alarm for Fan Failure alarm received at BMS 24.3. Restore power 25. At BMS simulate Relief Fan Static Pressure v 28. Lower the space static pressure set point below 0.05" 27. Observe the following:w`_ } ._ 27.1. The Relief fan ramps up to 100% 27.2. Outside air damper maintains schedule 27.3. Retum air remains maintains schedule 27.4. Data Center static pressure reduces to set point 28. At BMS restore space static pressure set point 29. Verify the following:;'...` 29.1. Unit restores to the designed space temp set point 292. Damper retum to scheduled positions 30. At the Exhaust fan VFD 30.1. Shut off power feeding VFD '1 302. Verify the following: 30.2.1. Alarm for Fan Failure alarm received at BMS 30.3. Restore power 31. At Local control panel simulate inactive status for the economizer 32. Verify the following: 32.1. The Exhaust fan on 32.2. Retum Air damper is modulating to maintain the schedule 32.3. Outside Air mixing dampers closed 33. Record Data Center Temperature. 70 ° 34. At BMS lower Data Center temperature set point below 55 °. v 35. Verify the following:z 35.1. Compressors activate for cooling. i Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 6 • • • Llk LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 35.2. Discharge air temperature decreases 36. At BMS raise the Supply Air temperature above 55 °. ,/ 37. Verify the following: t y 37.1. Compressors shutdown 38. Restore Data Center temperature. 39. At BMS simulate high supply air temperature v 40. Verify the following 40.1. High Supply Air Temperature alarm at BMS �r 41. At BMS simulate low supply air temperature 42. Verify the following: 42.1. Low Supply Air Temperature alarm at BMS 43. At BMS restore supply air temperature set point 44. At BMS simulate high retum air temperature ✓ 45. Verify the following: ;�.., 45.1. Retum Air High Temperature alarm at BMS 46. At BMS restore retum air temperature. 47. Space Humidity. 69.6 % 48. At Local Control Panel simulate active status for the economizer 49. Verify the following: -zr 49.1. The economizer Outside Air damper modulates to maintain the set -point 4' 49.2. The RA damper will modulate to maintain the set -point 50. At the RTU open the disconnect switch 51. Verify the following: 51.1. Unit shuts down 51.2. Alarm received at BMS 51.3. Isolation damper dosed 52. Close the disconnect at the RTU 53. Verify the following: 53.1. RTU restarts 53.2. Alarm cleared at BMS Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 4 of 6 • • • .:11 LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 53.3. Isolation damper opens prior to supply fan starting 54. At BMS disable the unit. ✓ 55. Verify the following • Y} '.-. 55.1. Humidifier isolation damper closed 56. At BMS enable the unit 57. Verify the following: rz ; 57.1. Humidifier Damper opens prior to supply fan starting VFD 58. Auto reset #' 58.1. Shut off power feeding AFD 58.2. Restore power 59. Verify that VFD resets automatically 59.1. Supply fan operational: Y / N Exhaust fan operational: Y / N ./ 60. Manual 61. Change VFD to manual mode 62. Verify that the VFD can manually ramp fan speed 62.1. Supply fan operational: Y / N Return fan operational: Y / N 63. At local Exhaust VFD control panel operate the VFD through the following test points JF LY NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step ",� 63.1. 25% 15Hz 63.2. 50% 30Hz 63.3. 75% 45Hz 63.4. 100% 60Hz 64. Once 100% is reached and the unit has been inspected and stabilized, operate the VFD through the following test points NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step . zr: 64.1. 75% 45Hz ' 64.2. 50% 30Hz 64.3. 25% 15Hz 65. At local Supply VFD control panel operate the VFD through the following test points ^' ' Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 5 of 6 • • LEE TECHNOLOGIES' L LEVEL 4 CHECKLIST NOTE: Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step 65.1. 25% 15Hz 65.2. 50% 30Hz 65.3. 75% 45Hz 85.4. 100% 60Hz 66. Once 100% is reached and the unit has been inspected and stabilized, operate the VFD through the following test points NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step ; 3. 66.1. 75% 45Hz ,/ 66.2: 50% 30Hz 66.3. 25% 15Hz v 67. Retum the VFD to normal control v 68. Verify BMS graphics 69. Place system in normal operating mode f' 70. Attain copy of alarms and verify 71_ End of test Senor 02 Comments Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/10/2010, the following was noted: Steps 13 thru 16. Was unable to access and trigger the filter D/P switch. Sec: on O_ Fun,11-,nai rest vvan.:ss v,e r;r:,at um Lee Technologies representative has witnessed or participated in this checklist, has verified equipment is ready per and attests to the accuracy and completeness of this report. Printed Name: Signature_' Date: checldist, Trent Printz 1,-'77,54747 ` %, i. 6 7/1012010 Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 6 of 6 • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST S2r_ ±ion 01 Picc 1 '� Procedure Me: INTERNAP-TUK-WA- CX-RTU Submittal Date: 18 Ma 10 y Procedure Work Date: 7/10/2010 Procedure Work ` Time Frame: 0800 -1700 Customer Name: I me m a p Customer's Solomon Aoject Code: Address: Waal Address: 3355 South 120th Place City Slate. Zip: Tukwila WA 98168 customerPOC: Customer FOC Name: Kathy Mclnvale Phone Numbers: Office: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning su.motor. Herbert Burnett Phone Numbers: Phone Number 703 -968 -0300 Mobile: 713.423.4335 Pam --pc' =' Proo��dwa pw�rv;a�� Equipment Functional Checks for RTU # 3.4 Affected Area: Systems Affected: I Equipment Information: Manufacturer McQuay Equipment Type: RTU Model #: RTD130DLY Serial #: FBDU10040070900 Procedure overview: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre- Procedure Requirements: Manufacturers start up complete and all discrepancies corrected or noted for future correction. Sect,on °j Detailed Procedure Flo e„t :.r.: G:1,ft Detailed Procedure: COOP 1. Review Manufactures start -up documentation. V 2. TAB completed and approved for hydronic systems and terminal units connected. ° 3. Manufactures Rep present. 4. Unit clean and free of leaks 5. Verify Controls are complete and operational 6. Verify the VFD has been tested by manufacture 7. Equipment tag & nametag affixed - Y' Filters { _ •:.;. �µ,. x,. 8. Verify the following: 8.1. 1 set of 30% Filters 8.2. 1 set of 65% final filters Smoke Detector 9. Simulate activation of fire alarm system by spraying test smoke into Discharge air flow Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 1 of 6 • • • L� LEE TECHNOLOGIES` LEVEL 4 CHECKLIST 10. Verify the following: 10.1. Supply fan(s) will stop 10.2. Retum fan(s) will stop ,f 10.3. Isolation dampers will dose Y` 11. Reset fire alarm system ',' 12 Verify the following: 12.1. Isolation dampers will open ✓ 12.2. Supply fan(s) will start ✓ 12.3. Return fan(s) will start Fitter D/P 13. Record Fitter D/P set point. X 14. Adjust the D/P switch to 0.0 X 15. Verify the following: 15.1. Alarm received at BMS X 15.2. Alarm at RTU Control Panel X 16. Restore D/P switch to set point. X Note: All operating units operate in unison. Static Pressure Control 17. At BMS simulate Supply Fan Static Pressure Reset 18. Lower under floor static pressure set point below 1.5° 19. Observe the following: 19.1. The supply fan ramps down 19.2. Under floor static pressure reduces to set point 20. At BMS simulate raising under floor static pressure above 1.5° 21. Observe the following: ,1- 21.1. The supply fan ramps up to 100% 21.2. The under floor static pressure reaches and maintains set point f 22. At BMS restore under floor static pressure set point 23. Verify the following: 23.1. Unit restores to the designed static pressure set point Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 6 • • • L� LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 24. At the Supply fan VFD 24.1. Shut off power feeding VFD v 24.2. Verify the following: 24.2.1. Alarm for Fan Failure alarm received at BMS 24.3. Restore power 25. At BMS simulate Relief Fan Static Pressure 26. Lower the space static pressure set point below 0.05° 27. Observe the following: 27.1. The Relief fan ramps up to 100% 27.2. Outside air damper maintains schedule 27.3. Retum air remains maintains schedule 27.4. Data Center static pressure reduces to set point 28. At BMS restore space static pressure set point 29. Verify the following: 29.1. Unit restores to the designed space temp set point 29.2. Damper return to scheduled positions 30. At the Exhaust fan VFD 30.1. Shut off power feeding VFD 302. Verify the following: 30.2.1. Alarm for Fan Failure alarm received at BMS 30.3. Restore power `f 31. At local control panel simulate inactive status for the economizer . 32. Verify the following: rs 32.1. The Exhaust fan on 32.2. Return Air damper is modulating to maintain the schedule 4t 32.3. Outside Air mixing dampers dosed 33. Record Data Center Temperature. 70 ° 34. At BMS lower Data Center temperature set point below 55 °. 35. Verify the following: 35.1. Compressors activate for cooling. ✓ Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 3 of 6 • • filk LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 35.2. Discharge air temperature decreases v 36. At BMS raise the Supply Air temperature above 55 °. 37. Verify the following: 37.1. Compressors shutdown 38. Restore Data Center temperature. 39. At BMS simulate high supply air temperature 40. Verify the following 40.1. High Supply Air Temperature alarm at BMS 41. At BMS simulate low supply air temperature 42. Verify the following: 42.1. Low Supply Air Temperature alarm at BMS y 43. At BMS restore supply air temperature set point 44. At BMS simulate high return air temperature / 45. Verify the following: 45.1. Retum Air High Temperature alarm at BMS .. 46. At BMS restore retum air temperature. 47. Space Humidity. 69.6 % 48. At Local Control Panel simulate active status for the economizer / 49. Verify the following: 49.1. The economizer Outside Air damper modulates to maintain the set -point ' 49.2. The RA damper will modulate to maintain the set -point 50. At the RTU open the disconnect switch 51. Verify the following:',, 51.1. Unit shuts down 51.2. Alarm received at BMS 51.3. Isolation damper closed 52. Close the disconnect at the RTU 53. Verify the following: 53.1. RTU restarts "f 53.2. Alarm cleared at BMS "! Template Rev. 07022010 Lee Technologies Group Copyright 2010 Proprietary use pursuant to company policy Page4of6 • • • L!dilt LEE TECHNOLOGIES° LEVEL 4 CHECKLIST 53.3. Isolation damper opens prior to supply fan starting *� 54. At BMS disable the unit. 55. Verify the following 55.1. Humidifier isolation damper dosed 56. At BMS enable the unit 'f 57. Verify the following: 57.1. Humidifier Damper opens prior to supply fan starting VFD 58. Auto reset 58.1. Shut off power feeding AFD 58.2. Restore power 'f 59. Verify that VFD resets automatically 59.1. Supply fan operational: Y / N Exhaust fan operational: Y / N 60. Manual - ; ., 61. Change VFD to manual mode 62. Verify that the VFD can manually ramp fan speed 62.1. Supply fan operational: Y / N Retum fan operational: Y / N 63. At local Exhaust VFD control panel operate the VFD through the following test points fx NOTE: Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step 63.1. 25% 15Hz 63.2. 50% 30Hz v` 63.3. 75% 45Hz 100% 60Hz 64. Once 100% is reached and the unit has been inspected and stabilized, operate the VFD through the following test points NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step 64.1. 75% 45Hz tr 64.2. 50% 30Hz / 64.3. 25% 15Hz 65. At local Supply VFD control panel operate the VFD through the following test points f Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 5 of 6 • • • LEE TECHNOLOGIES" L LEVEL 4 CHECKLIST NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step `<<N �s f 65.1. 25% 15Hz 65.2. 50% 30Hz 65.3. 75% 45Hz si 65.4. 100% 60Hz 66. Once 100% is reached and the unit has been inspected and stabilized, operate the VFD through the following test points NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step 66.1. 75% 45Hz "' 66.2. 50% 30Hz 66.3. 25% 15Hz 67. Return the VFD to normal control 68. Verify BMS graphics 69. Place system in normal operating mode 70. Attain copy of alarms and verify v 71. End of test " F; ` ct, °n c Comments Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/1012010, the following was noted: Steps 13 thru 16. Was unable to access and trigger the filter D/P switch. Section 35 Lee Technologies representative has witnessed or participated in this checldist, has verified equipment is ready per and attests to the accuracy and completeness of this report. Printed Name: Signatwe. Date: � QA'° 7/10/2010 Trent Printz ^ / �, , W: �._ �� -.sir checldist, FlIi7C∎10tV∎I Tali V, aliess & Template Rev. 07022010 Lee Technologies Group © Copyright 2010 . Proprietary use pursuant to company policy Page 6 of 6 • • • L/� LEE TECHNOLOGIES" LEVEL 4 CHECKLIST ac _2, 3 Procedure Tide: `''"t"" INTERNAP-TUK-WA-CX-RTU Submittal Date: 18 May 10 Procedure Work Date: - 7/10/2010 Procedure work Time Frame: 0800 -1700 Customer Name: Intemap Customer's Saornon Anjert Code. Address: S� 3355 South 120"' Place City: stem: vp: Tukwila WA 98168 Customer POC: Customer POCName: Kathy Mcinvale Phone Numbers: cake: 404.302.9753 Mobile: 404.547.8915 Lee Technologies Commissioning Su,.:'visor Herbert Burnett Phone Numbers: Phone Number. 703 -968 -0300 Mobile: 713.423.4335 Pager: see:' °" Equipment Functional Checks for RTU # 3-5 Affected Area: Systems Affected: Equipment Information: Manufacturer McQuay Equipment Type: RTU Modena: RTD130DLY Serial t*: FBOU10040057100 Procedure Ovenriew: This testing will verify equipment is started up correctly in accordance with manufacturer specifications. Anticipated Results: Equipment will be started up in accordance with specifications and factory instructions and all discrepancies corrected or noted for future correction. Pre- Procedure Requirements: Manufacturers start up complete and all discrepancies corrected or noted for future correction. `ec:lion ,,,_ Detailed Procedure Detained Procedure: - Complete 1. Review Manufactures start-up documentation. - 2. TAB completed and approved for hydronic systems and terminal units connected. 3. Manufactures Rep present. 4. Unit clean and free of leaks -/ 5. Verify Controls are complete and operational 6. Verify the VFD has been tested by manufacture Yj 7. Equipment tag & nametag affixed v Filters 8. Verify the following: 8.1. 1 set of 30% Filters ,/ 8.2. 1 set of 65% final filters v Smoke Detector 9. Simulate activation of fire alarm system by spraying test smoke into Discharge air flow Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 1 of 6 11 LEE TECHNOLOGIES' 116/ • • • LEVEL 4 CHECKLIST 10. Verify the following: 10.1. Supply fan(s) will stop .7 10.2. Retum fan(s) will stop / 10.3. isolation dampers will close ../- 11. Reset fire alarm system .7 12. Verify the following: 12.1. Isolation dampers will open v 12.2. Supply fan(s) will start 7 12.3. Retum fan(s) will start Filter D/P : . 13. Record Filter D/P set point. X 14. Adjust the D/P switch to 0.0 X 15. Verify the following: • ' 15.1. Alarm received at BMS X 15.2. Alarm at RTU Control Panel . X 16. Restore D/P switch to set point. X Note: All operating units operate in unison. Static Pressure Control 17. At BMS simulate Supply Fan Static Pressure Reset ..( 18. Lower under floor static pressure set point below 1.5" ,<. 19. Observe the following: 19.1. The supply fan ramps down 19.2. Under floor static pressure reduces to set point 20. At BMS simulate raising under floor static pressure above 1.5" 21. Observe the following: 21.1. The supply fan ramps up to 100% 21.2. The under floor static pressure reaches and maintains set point i 22. At BMS restore under floor static pressure set point 23. Verify the following: 23.1. Unit restores to the designed static pressure set point / Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 2 of 6 • • LEE TECHNOLOGIES° L LEVEL 4 CHECKLIST 24. At the Supply fan VFD 't 24.1. Shut off power feeding VFD 24.2. Verify the following: 24.2.1. Alarm for Fan Failure alarm received at BMS 24.3. Restore power 25. At BMS simulate Relief Fan Static Pressure 26. Lower the space static pressure set point below 0.05° 27. Observe the following: 27.1. The Relief fan ramps up to 100% 27.2. Outside air damper maintains schedule `f 27.3. Retum air remains maintains schedule J • 27.4. Data Center static pressure reduces to set point 28. At BMS restore space static pressure set point 29. Verify the following: 29.1. Unit restores to the designed space temp set point _ 29.2. Damper return to scheduled positions '' 30. At the Exhaust fan VFD 30.1. Shut off power feeding VFD v 30.2. Verify the following: 30.2.1. Alarm for Fan Failure alarm received at BMS 30.3. Restore power 31. At local control panel simulate inactive status for the economizer of 32. Verify the following: _.... �. 32.1. The Exhaust fan on 32.2. Retum Air damper is modulating to maintain the schedule V 32.3. Outside Air mixing dampers dosed 33. Record Data Center Temperature. 70 ° 34. At BMS lower Data Center temperature set point below 55 °. ✓ 35. Verify the following: 35.1. Compressors activate for cooling. Template Rev. 07022010 Lee Technologies Group D Copyright 2010 Proprietary use pursuant to company policy Page 3 of 6 • • LEE TECHNOLOGIES' LEVEL 4 CHECKLIST 35.2. Discharge air temperature decreases ,f 36. At BMS raise the Supply Air temperature above 55°. 37. Verify the following: 37.1. Compressors shutdown v 38. Restore Data Center temperature. v 39. At BMS simulate high supply air temperature ./ 40. Verify the following 40.1. High Supply Air Temperature alarm at BMS 1 41. At BMS simulate low supply air temperature ./ 42. Verify the following: 42.1. Low Supply Air Temperature alarm at BMS v 43. At BMS restore supply air temperature set point 44. At BMS simulate high retum air temperature 45. Verify the following: 45.1. Retum Air High Temperature alarm at BMS .. .../ 46. At BMS restore retum air temperature. 47. Space Humidity. 69.6 % vi 48. At Local Control Panel simulate active status for the economizer / 49. Verify the following: ..:- ......I. , 49.1. The economizer Outside Air damper modulates to maintain the set-point 49.2. The RA damper will modulate to maintain the set-point 50. At the RTU open the disconnect switch v 51. Verify the following: 51.1. Unit shuts down 1/ 51.2. Alarrn received at BMS ,/ 51.3. Isolation damper closed 52. Close the disconnect at the RTU V 53. Verify the following: ,....- .;-.,..... , A. ,■11.1, -.. . 53.1. RTU restarts 53.2. Alarm deared at BMS Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 4 of 6 • • • LEE TECHNOLOGIES° ‘11./ LEVEL 4 CHECKLIST 53.3. Isolation damper opens prior to supply fan starting 54. At BMS disable the unit. 55. Verify the following ,-.4 :. 0 f •_:.',. ! 55.1. Humidifier isolation damper dosed 56. At BMS enable the unit 57. Verify the following: 57.1. Humidifier Damper opens prior to supply fan starting V VFD 58. Auto reset 58.1. Shut off power feeding AFD 58.2. Restore power 59. Verify that VFD resets automatically 3:;%::' "..: 't • ---. 59.1. Supply fan operational: Y / N Exhaust fart operational: Y / N 60. Manual 61. Change VFD to manual mode v' 62. Verify that the VFD can manually ramp fan speed V 62.1. Supply fan operational: Y / N Retum fan operational: Y / N / 63. At local Exhaust VFD control panel operate the VFD through the following test points NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step 63.1. 25% 15Hz v 63.2. 50% 30Hz ..,-- 63.3. 75% 45Hz 63.4. 100% 60Hz ../ 64. Once 100% is reached and the unit has been inspected and stabilized. operate the VFD through the following test points , NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step '''‘!.•4*,, '...'"?. C.., 64.1. 75% 45Hz v 64.2. 50% 30Hz 64.3. 25% 15Hz 65. At local Supply VFD control panel operate the VFD through the following test points Template Rev. 07022010 Lee Technologies Group © Copyright 2010 Proprietary use pursuant to company policy Page 5 of 6 • • :11 LEE TECHNOLOGIES" LEVEL 4 CHECKLIST NOTE: Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step 65.1. 25% 15Hz 65.2. 50% 30Hz V 65.3. 75% 45Hz 65.4. 100% 60Hz u1 66. Once 100% is reached and the unit has been inspected and stabilized, operate the VFD through the following test points { NOTE Allow unit to stabilize and conduct a visual check of the unit prior to proceeding to next step =" 66.1. 75% 45Hz 66.2. 50% 3011z 66.3. 25% 15Hz 67. Retum the VFD to normal control 68. Verify BMS graphics 69. Place system in normal operating mode 70. Attain copy of alarms and verify 71. End of test sp. cu. , c, Comments Insert any comments applicable to the checklist: Conducted Level 4 testing on 7/10/2010, the following was noted: Steps 13 thru 16. Was unable to access and trigger the filter D/P switch. S c i o_ 5 Fi,n�;,�,, al Te,,i V arigss ., Lee Technologies representative has witnessed or participated in this checklist, has verified equipment is ready per checldiist, and attests to the accuracy and completeness of this report. Panted Haan: Signature: Date: Trent Printz �/ , ,, , ;rJ r7- 7/10/2010 Template Rev. 07022010 Lee Technologies Group @ Copyright 2010 Proprietary use pursuant to company policy Page 6 of 6 2006 Washington State Nonresidential Energy Code Compliance Form 2006 Washington State Nonresidential Energy Code Compliance Forms Revised July 2007 Project Info Project Address 3355 S. 120TH PLACE Date 3/1/2010 TUKWILA, WA 98168 For Building Department Use Applicant Name: INTERNAP NETWORK SERVICES Applicant Address: 250 WILLIAMS ST. ATLANTA, GA 30303 Applicant Phone: 4134 302 9700 FILE COPY REVIEWED FOR COMPLIANCE WITH NFPA 70 - NEC MAR 15 2010 City of Tukwila BUILDING DIVISION Ei.-iO 01S7 RECEIVED MAR 0 2 2010 PERMIT CENTER 2006 Washington State Nonresidential Energy Code Compliance Form 2006 Washington State Nonresidential Energy Code Compliance Forms Revised July 2007 Project Info Project Address 3355 S. 120TH PLACE Date 3/112010 TUKWILA, WA 98168 For Building Department Use 333 Applicant Name: INTERNAP NETWORK SERVICES Applicant Address: 250 WILLIAMS ST. ATLANTA, GA 30303 Applicant Phone: 404 302 9700 Project Description 336 ❑ FEa iaEded requirements. ❑ New Building ❑ Addition -, Alteration Refer to WSEC Section 1513 for controls and commissioning Compliance Option 0 Prescriptive Q Lighting Power Allowance 0 Systems Analysis (See Qualification Checklist (over). Indicate Prescriptive & LPA spaces clearly on plans.) Alteration Exceptions (check appropriate box - sec. 1132.3) ❑ No changes are being made to the lighting ❑ Less than 60% of the fixtures new, installed wattage not increased, & space use not changed. Maximum Allowed Lighting Wattage Location (floor /room no.) Occupancy Description Allowed Watts per ft2 ** Area in ft2 Allowed x Area 333 NETWORK EQUIPMENT ROOM (ASSUME 0.8W/8F) 0.80 6880.0 5504.0 336 NETWORK EQUIPMENT ROOM (ASSUME 0.BW /SF) 0.80 9475.0 7580.0 1ST FLR /334, 335 ELECTRICAL /MECHANICAL ROOMS (EXC 1512.1.5) 78 87.0 6786.0 •• From Table 15 -1 (over) - document all exceptions on form LTG -LPA Total Allowed Watts 13084.0 Proposed Lighting Wattage Location (floor /room no.) Fixture Description Number of Fixtures Watts/ Fixture Watts Proposed 333 2'x4' 3 LAMP F32T8 W/ ELECTRONIC BALLAST 61 87.0 5307.0 333 2'X2' 2 LAMP F32T8 W/ ELECTRONIC BALLAST 7 58.0 406.0 336 2'X4' 3 LAMP F32T8 W/ ELECTRONIC BALLAST 78 87.0 6786.0 3362'7E2' 2 LAMP F32T8 W/ ELECTRONIC BALLAST 8 58.0 464.0 1ST FLR /334, 335 4' STRIP FIX 2 LAMP F32T8 W/ ELECTRONIC BALLAST 95 Total Proposed Watts may not exceed Total Allowed Watts for Interior Total Proposed Watts 12963.0 Notes: 1. For proposed Fixture Description, indicate fixture type, lamp type (e.g. T -8), number of lamps in the fixture, and ballast type (if included). For track lighting, list the length of the track (in feet) in addition to the fixture, lamp, and ballast information. 2. For proposed Watts /Fixture, use manufacturer's listed maximum input wattage of the fixture (not simply the lamp wattage) and other criteria as specified in Section 1530. For hard -wired ballasts only, the default table in the NREC Technical Reference Manual may also be used. For track lighting, list the greater of actual luminaire wattage or length of track multiplied by 50, or as applicable, the wattage of current limiting devices or of the transformer. 3. List all fixtures. For exempt lighting, note section and exception number, and leave Watts /Fixture blank. 2006 Washington State Nonresidential Energy Code Compliance Form 2006 Oashington State Nonresidential Energy Code Compliance Forms Revised July 2007 Prescriptive Spaces Occupancy: 0 Warehouses, storage areas or aircraft storage hangers QOther Q ualification Checklist answer If occupancy is cuec ed type is number of and Pies in answer is checked, the number of fixtures in the space is not limited by Code. Clearly indicate these spaces on plans. If not qualified, do LPA Calculations. Lighting Fixtures: (Section 1521) o ❑ Check if 95 /o or more of fixtures comply with 1,2 or 3 and rest are ballasted. 1. Fluorescent fixtures which are non - lensed with a 1 or 2 two lamps, b reflector a) b) or louvers, c) 5-60 watt T -1, T -2, T-4, T -5, T -8 lamps, and d) hard -wired elec- tronic dimming ballasts. Screw -in compact fluorescent fixtures do not qualify. 2. Metal Halide with a) reflector b) ceramic MH lamps <= 150w c) electronic ballasts 3. LED lights. TABLE 15 -1 Unit Listhtinst Power Allowance (LPA Use' LPAI (W /sf) Use' LPA` (W /sf) Automotive facility 0.9 Office buildings, office /administrative areas in facilities of other use types (including but not limited to schools, hospitals, institutions, museums, banks, churches) 1.0 Convention center • 1.2 Penitentiary and other Group 1 -3 Occupancies 1.0 Courthouse 1.2 Police and fire stations 1.0 Cafeterias, fast food establishments', restaurants /bars5 1.3 Post office 1.1 Dormitory 1.0 RetaiiTO, retail banking, mall concourses, wholesale stores (pallet rack shelving) 1.5 Exercise center 1.0 School buildings (Group E Occupancy only), school classrooms, day care centers 1.2 Gymnasia", assembly spaces" 1.0 Theater, motion picture 1.2 Health care clinic 1.0 Theater, performing arts 1.6 Hospital, nursing homes, and other Group 1 -1 and 1 -2 Occupancies 1.2 Transportation 1.0 Hotel /motel 1.0 Warehouses ', storage areas 0.5 Hotel banquet/conference /exhibition hall°` 2.0 Workshops 1.4 Laboratory spaces (all spaces not classified "laboratory' shall meet office and other appropriate categories) 1.8 Parking garages 0.2 Laundries 1.2 Libraries' 1.3 Plans Submitted for Common Areas Only' Manufacturing facility 1.3 Main floor building •lobbies' (except mall concourses) 1.2 Museum 1.1 Common areas, corridors, toilet facilities and washrooms, elevator lobbies 0.8 Footnotes for Table 15 -1 1) In cases in which a general use and a specific use are listed, the specific use shall apply. In cases in which a use is not mentioned specifically, the Unit Power Allowance shall be determined by the building official. This determination shall be based upon the most comparable use specified in the table. See Section 1512 for exempt areas. 2) The watts per square foot may be increased, by two percent per foot of ceiling height above twenty feet, unless specifically directed otherwise by subsequent footnotes. 3) Watts per square foot of room may be increased by two percent per foot of ceiling height above twelve feet. 4) For all other spaces, such as seating and common areas, use the Unit Light Power Allowance for assembly. 5) Watts per square foot of room may be increased by two percent per foot of ceiling height above nine feet. 6) Reserved. 7) For conference rooms and offices Tess than 150ft2 with full height partitions, a Unit Lighting Power Allowance of 1.10 w /ft2 may be used. 8) Reserved. 9) For indoor sport tournament courts with adjacent spectator seating over 5,000, the Unit Lighting Power Allowance for the court area is 2.60 W /ft2. 10) Display window illumination installed within 2 feet of the window, provided that the display window is separated from the retail space by walls or at least three - quarter- height partitions (transparent or opaque). and lighting for free - standing display where the lighting moves with the display are exempt. An additional 1.5 w /ft2 of merchandise display luminaires are exempt provided that they comply with all three of the following: a) located on ceiling- mounted track or directly on or recessed into the ceiling itself (not on the wall). b) adjustable in both the horizontal and vertical axes (vertical axis only is acceptable for fluorescent and other fixtures with two points of track attachment). c) fitted with LED, tungsten halogen, fluorescent, or high intensity discharge lamps. This additional lighting power is allowed only if the lighting is actually installed. 11) Provided that a floor plan, indicating rack location and height, is submitted, the square footage for a warehouse may be defined, for computing the interior Unit Lighting Power Allowance, as the floor area not covered by racks plus the vertical face area (access side only) of the racks. The height allowance defined in footnote 2 applies only to the floor area not covered by racks. 2006 Washington State Nonresidential Energy Code Compliance Form 2006 Washington State Nonresidential Energy Code Compliance Forms Revised July 2007 Project Info Proj Addres:3355 S. 120TH PLACE Date 3/1/2010 TUKWILA, WA 98168 For Building Department Use Name: INTERNAP NETWORK SERVICES Appl. Name 250 WILLIAMS ST. ATLANTA, GA 30303 Appl. Phone 404 302 9700 Project Description ❑ PEAted requirements. ❑ New ❑ Addition J Alteration Refer to WSEC Section 1513 for controls and commissioning Compliance Option Q Lighting Power Allowance 0 Systems Analysis Building Grounds (luminaires > 100 Watts) ❑ Efficacy > 60 lumens/W ❑ Controlled by motion Sensor ❑ Exemption (list) Alteration Exceptions (check appropriate box - sec. 1132.3) ❑ No changes are being made to the lighting ❑ Less than 60% of the fixtures new, installed wattage not increased, & space use not changed. Tradable Maximum Allowed Li tin Wattaee Tradable Locations Description Allowed Watts per ft2 or per If Area (ft2), perimeter (10 or # of items Allowed Watts x ft2 (or x If) Tradable Proposed Lighting Wattage Total Allowed Watts Use mfgr listed maximum input wattage. For fixtures with hard -wired ballasts only, the default table in the NREC Technical Reference Manual may also be used. Location Fixture Description Number of Fixtures Watts/ Fixture Watts Proposed Total Proposed Watts may not exceed Total Allowed Watts for Exterior Non - Tradable Maximum Allowed Lighting Wattage Total Proposed Watts Non - Tradable Locations Description Allowed Watts per ft2 or per If Area (ft2), perimeter (If) or # of items Allowed Watts x ft2 (or x10 Non - Tradable Proposed Lighting Wattage Location Fixture Description Number of Fixtures Watts/ Fixture Watts Proposed Proposed Watts may not exceed Allowed Watts for Category 2006 Washington State Nonresidential Energy Code Compliance Form 2006 Washington State Nonresidential Energy Code Compliance Forms TABLE 15 -2 LIGHTING POWER DENSITIES FOR BUILDING EXTERIORS Revised July 2007 Tradable Surfaces (Lighting power densities for uncovered parking areas, building grounds, building entrances and exits, canopies and overhangs and outdoor sales areas may be traded.) 1 Uncovered Parking Areas Parking Tots and drives 0.15 W/ft2 Building Grounds Walkways less than 10 feet wide 1.0 W /linear foot Walkways 10 feet wide or greater Plaza areas Special feature areas 0.2W/ft2 Stairways 1.0 W/ft2 Building Entrances and Exits Main entries 30 W /linear foot of door width Other doors 20 W /linear foot of door width Canopies and Overhangs Canopies (free standing and attached and overhangs) 1.25 W/ft2 Outdoor Sales - Open areas (including vehicle sales lots) 0.5 W/112 Street frontage for vehicle sales lots in addition to "open area" allowance 20 W /linear foot Non - Tradable Surfaces (Lighting power density calculations for the following applications can be used only for the specific application and cannot be traded between surfaces or with other exterior lighting. The following allowances are in addition to any allowance otherwise permitted in the "Tradable Surfaces" section of this table.) Building Facades 0.2 W/ft2 for each illuminated wall or surface or 5.0W /linear foot for each illuminated wall or surface length Automated teller machines and night depositories 270 W per location plus 90 W per additional ATM per location Entrances and gatehouse inspection stations at guarded facilities 1.25 W/ft2 of uncovered area (covered areas are included in the "Canopies and Overhangs" section of "Tradable Surfaces ") Loading areas for law enforcement, fire, ambulance and other emergency service vehicles 0.5 W/ft2 of uncovered area (covered areas are included in the "Canopies and Overhangs" section of "Tradable Surfaces ") Material handling and associated storage 0.5 W /ft2 Drive -up windows at fast food restaurants 400W per drive - through Parking near 24 -hour retail entrances 800 W per main entry 2006 Washington State Nonresidential Energy Code Compliance Form 2006 Washington State Nonresidential Energy Code Compliance Forms Revised July 2007 Project Address 13355 S. 120TH PLACE !Date 3/1/2010 Use this form if you are claiming any ceiling height adjustments for your Lighting Power Allowances for interior lighting. The Occupancy Description should agree with the "Use" listed on Code Table 15 -1. Identify the appropriate Ceiling Height Limit (9 feet, 12 feet or 20 feet) on which the adjustment is based. The Adjusted LPA is calculated from this number and from the Allowed Watts per ft2. Carry the Adjusted LPA to the corresponding "Allowed Watts per ft2" location on LTG -SUM. Adjusted Lighting Power Allowances (Interior) Location (floor /room no.) Occupancy Description Allowed Watts per ft2 ** Ceiling Height for this room Ceiling Height limit for this exception** Adjusted LPA Watts per ft2 From Table 15 -1 based on exceptions listed in footnotes 2006 Washington State Nonresidential Energ Code Com • liance Form 2006 Washington State Nonresidential Energy Code Compliance Forms Revises July 2007 Project Address 3355 8. 120T8 PLACE 'Date 3/1/2010 The following information is necessary to check a permit application for compliance with the lighting, motor, and transformer requirements in the 2006 Washington State Nonresidential Ene gy Code. Applicability (yes, no, n.a.) Code Section Component Information Required Location on Plans Building Department Notes LIGHTING CONTROLS (Section 1513) yea 1.0 1513.1 Local control/access Schedule with type, indicate locations E122 yes 1.0 1513.2 Area controls Maximum limit per switch E122 n.a. 3 1513.3 Daylight zone control Schedule with type and features, indicate locations n.a. 3.0 vertical glazing Indicate vertical glazing on plans n.a. 3.0 overhead glazing Indicate overhead glazing on plans n.a. 3.0 1513.4 Display /exhib /special Indicate separate controls 1513.5 Exterior shut -off Schedule with type and features, indicate location yes 1.0 (a) timer w /backup Indicate location E113 yea 1.0 (b) photocell. Indicate location E113 1513.6 Inter. auto shut -off Indicate location yes 1.0 1513.6.1 (a) occup. sensors Schedule with type and locations E122 n.a. 3.0 1513.6.2 (b) auto. switches Schedule with type and features (back -up, override capability); Indicate size of zone on plans yea 1 1513.7 Commissioning Indicate requirements for lighting controls commissioning 8122 EXIT SIGNS (Section 1514) yes 1 I 1514 'Max. watts 'Indicate watts for each exit sign 1E122 1 LIGHTING POWER ALLOWANCE (Section 1530 -1532) yea 1 1531 Interior Lighting Summary Form Completed and attached. Schedule with fixture types, lamps, ballasts, watts per fixture 4 1532 Exterior Lighting Summary Form Completed and attached. Schedule with fixture types, lamps, ballasts, watts per fixture MOTORS (Section 1511) n. a. 3.01 1511 'Elec motor efficiency IMECH -MOT or Equipment Schedule with hp, rpm, efficiency I I TRANSFORMERS (Section 1540) yes 1.01 1540 'Transformers 'Indicate size and efficiency 18700 I If "no" is circled for any question, provide explanation: 2006 Washington State Nonresidential Energy Code Compliance Form 200E gtiashington State Nonresidential Energy Code Compliance Forms Revised July 2007 Lighting - General Requirements 1513 Lighting Controls: Lighting, including exempt lighting in Section 1512, shall comply with this section. Where occupancy sensors are cited, they shall have the features listed in Section 1513.6.1. Where automatic time switches are cited, they shall have the features listed in Section 1513.6.2. 1513.1 Local Control and Accessibility: Each space, enclosed by walls or ceiling- height partitions, shall be provided with lighting controls located within that space. The lighting controls, whether one or more, shall be capable of turning off all lights within the space. The controls shall be readily accessible, at the point of entry/exit, to personnel occupying or using the space. EXCEPTIONS: The following lighting controls may be centralized in remote locations: 1. Lighting controls for spaces which must be used as a whole. 2. Automatic controls. 3. Controls requiring trained operators. 4. Controls for safety hazards and security. 1513.2 Area Controls: The maximum lighting power that may be controlled from a single switch or automatic control shall not exceed that which is provided by a 20 ampere circuit loaded to not more than 80 %. A master control may be installed provided the individual switches retain their capability to function independently. Circuit breakers may not be used as the sole means of switching. EXCEPTIONS: 1. Industrial or manufacturing process areas, as may be required for production. 2. Areas less than 5% of the building footprint for footprints over 100,000 ft2. 1513.3 Daylight Zone Control: All daylighted zones, as defined in Chapter 2, both under overhead glazing and adjacent to vertical glazing, shall be provided with individual controls, or daylight- or occupant- sensing automatic controls, which control the lights independent of general area lighting. Contiguous daylight zones adjacent to vertical glazing are allowed to be controlled by a single controlling device provided that they do not include zones facing more than two adjacent cardinal orientations (i.e. north, east, south, west). Daylight zones under overhead glazing more than 15 feet from the perimeter shall be controlled separately from daylight zones adjacent to vertical glazing. EXCEPTION: Daylight spaces enclosed by walls or ceiling height partitions and containing 2 or fewer light fixtures are not required to have a separate switch for general area lighting. 1513.4 Display, Exhibition and Specialty Lighting Controls: All display, exhibition or specialty lighting shall be controlled independently of general area lighting. 1513.5 Automatic Shut -off Controls, Exterior: Lighting for all exterior applications shall have automatic controls capable of turning off exterior lighting when sufficient daylight is available or when the lighting is not required during nighttime hours. Lighting not designated for dusk -to -dawn operation shall be controlled by either: a. A combination of a photosensor and a time switch; or b. An astronomical time switch. Lighting designated for dusk -to -dawn operation shall be controlled by an astronomical time switch or photosensor. All time switches shall be capable of retaining programming and the time setting during loss of power for a period of at least 10 hours. EXCEPTION: Lighting for covered vehicle entrances or exits from buildings or parking structures where required for safety, security, or eye adaptation. 1513.6 Automatic Shut -Off Controls, Interior: Buildings greater than 5,000 ft2 and all school classrooms shall be equipped with separate automatic controls to shut off the lighting during unoccupied hours. Within these buildings, all office areas less than 300 ft2 enclosed by walls or ceiling - height partitions, and all meeting and conference rooms, and all school classrooms, shall be equipped with occupancy sensors that comply with Section 1513.6.1. For other spaces, automatic controls may be an occupancy sensor, time switch or other device capable of automatically shutting off lighting. EXCEPTIONS: 1. Areas that must be continuously illuminated (e.g., 24 -hour convenience stores), or illuminated in a manner requiring manual operation of the lighting. • 2. Emergency lighting systems. 3. Switching for industrial or manufacturing process facilities as may be required for production. 4. Hospitals and laboratory spaces. 5. Areas in which medical or dental tasks are performed are exempt from the occupancy sensor requirement. 1513.6.1 Occupancy Sensors: Occupancy sensors shall be capable of automatically turning off all the lights in an area, no more than 30 minutes after the area has been vacated. Light fixtures controlled by occupancy sensors shall have a wall- mounted, manual switch capable of turning off lights when the space is occupied. EXCEPTION: Occupancy sensors in stairwells are allowed to have two step lighting (high -light and low - light) provided the control fails in the high -light position. 1513.6.2 Automatic Time Switches: Automatic time switches shall have a minimum 7 day clock and be capable of being set for 7 different day types per week and incorporate an automatic holiday "shut -off' feature, which turns off all loads for at least 24 hours and then resumes normally scheduled operations. Automatic time switches shall also have program back -up capabilities, which prevent the loss of program and time settings for at least 10 hours, if power is interrupted. Automatic time switches shall incorporate an over -ride switching device which: a. is readily accessible; b. is located so that a person using the device can see the lights or the areas controlled by the switch, or so that the area being illuminated is annunciated; c. is manually operated; d. allows the lighting to remain on for no more than 2 hours when an over -ride is initiated; and e. controls an area not exceeding 5,000 ft2 or 5% of the building footprint for footprints over 100,000 ft2, whichever is greater. 1513.7 Commissioning Requirements: For lighting controls which include daylight or occupant sensing automatic controls, automatic shut -off controls, occupancy sensors, or automatic time switches, the lighting controls shall be tested to ensure that control devices, components, equipment and systems are calibrated, adjusted and operate in accordance with approved plans and specifications. Sequences of operation shall be functionally tested to ensure they operate in accordance with approved plans and specifications. A complete report of test procedures and results shall be prepared and filed with the owner. Drawing notes shall require commissioning in accordance with this paragraph. 1514 Exit Signs: Exit signs shall have an input power demand of 5 Watts or less per sign. Motors - General Requirements 1511 Electric Motors: All permanently wired polyphase motors of 1 hp or more, which are not part of an HVAC system, shall comply with Section 1437. EXCEPTIONS: 1. Motors that are an integral part of specialized process equipment. 2. Where the motor is integral to a listed piece of equipment for which no complying motor has been approved. Transformers - General Requirements SECTION 1540 — TRANSFORMERS The minimum efficiency of a low voltage dry-type distribution transformer shall be the Class 1 Efficiency Levels for distribution transformers specified in Table 4 -2 of the "Guide for Determining Energy Efficiency for Distribution Transformers" published by the National Electrical Manufacturers Association (NEMA TP- 1- 2002). 12 -01 -2010 City of Tukwila Jim Haggerton, Mayor Department of Com' munity Development KATHY MCINVALE 250 WILLIAMS ST SUITE M -100 ATLANTA GA 30303 RE: Permit No. EL10 -0157 3355 S 120 PL TUKW Dear Permit Holder: Jack Pace, Director In reviewing our current records, the above noted permit has not received a final inspection by the City of Tukwila Building Division. Per the International Building Code, International Mechanical Code, Uniform Plumbing Code and /or the National Electric Code, every permit issued by the Building Division under the provisions of these codes shall expire by limitation and become null and void if the building or work authorized by such permit has not begun within 180 days from the issuance date of such permit, or if the building or work authorized by such permit is suspended or abandoned at any time after the work has begun for a period of 180 days. Your permit will expire on 01/12/2011. Based on the above, you are hereby advised to: 1) Call the City of Tukwila Inspection Request Line at 206 - 431 -2451 to schedule for the next or final inspection. Each inspection creates a new 180 day period, , provided the inspection shows progress. -or- 2) Submit a written request for permit extension to the Permit Center at least seven (7) days before it is due to expire. Address your extension request to the Building Official and state your reason(s) for the need to extend your permit. The Building Code does allow the Building Official to approve one extension of up to 180 days. If it is determined that your extension request is granted, you will be notified by mail. In the event you do not call for an inspection and /or receive an extension prior to 01/12/2011, your permit will become null and void and any further work on the project will require a new permit and associated fees. Thank you for your cooperation in this matter. Sincerely, Bill Rambo Permit Technician File: Permit File No. EL10 -0157 6300 Southcenter Boulevard, Suite #100 • Tukwila, Washington 98188 • Phone: 206 - 431 -3670 • Fax: 206 - 431 -3665 .PERlWIT COORD COPY � PLAN REVIEW /ROUTING SLIP ACTIVITY NUMBER: EL10 -0157 DATE: 05/10/10 PROJECT NAME: I NTERNAP NETWORK SERVICES' SITE ADDRESS: 3355 S 120 PL Original Plan Submittal Response to Correction Letter # Response to Incomplete Letter # X Revision # 1 after Permit Issued DEPARTMENTS. P4 Building Division Public Works Fire Prevention Structural Planning Division ❑ Permit Coordinator ❑ DETERMINATION OF COMPLETENESS: (Tues., Thurs.) Complete Ki Comments: Incomplete ❑ DUE DATE: 05/13/10 Not Applicable ❑ Perrrmit,`CenteFlUseOnly, C.v INCOMPLETE LETTER MAILED: LETTER OF COMPLETENESS MAILED: Departments determined incomplete: Bldg ❑ Fire ❑ Ping ❑ PW ❑ Staff Initials: TUES /THURS ROUTING: Building XI,Please Route REVIEWER'S INITIALS: Structural Review Required ❑ No further Review Required ❑ DATE: APPROVALS OR CORRECTIONS: DUE DATE: 06/10/10 Approved , Approved with Conditions ❑ Not Approved (attach comments) ❑ Notation: REVIEWER'S INITIALS: DATE: Permit Center., Use Only CORRECTION LETTER MAILED: Departments issued corrections: Bldg ❑ Fire ❑ Ping ❑ PW ❑ Staff Initials: Documents/routing slip.doc 2 -28 -02 • PTGUUDCOPY • PLAN REVIEW /ROUTING SLIP ACTIVITY NUMBER: EL10 -0157 DATE: 03 -02 -10 PROJECT NAME: INTERNAP NETWORK SERVICES SITE ADDRESS: 3355 S 120 PL X Original Plan Submittal Response to Incomplete Letter # Response to Correction Letter # _ Revision # After Permit Issued DEPART ENTS: L -AS--( uilding Division lip Public Works ❑ Fire Prevention Structural Planning Division Permit Coordinator u DETERMINATION OF COMPLETENESS: (Tues., Thurs.) Complete Incomplete n DUE DATE: 03-04 -10 Not Applicable n Comments: Permit Center Use Only INCOMPLETE LETTER MAILED: LETTER OF COMPLETENESS MAILED: Departments determined incomplete: Bldg ❑ Fire ❑ Ping ❑ PW ❑ Staff Initials: TUES/THURS ROUTING: Please Route 1K Structural Review Required ❑ No further Review Required ❑ REVIEWER'S INITIALS: DATE: APPROVALS OR CORRECTIONS: Approved Approved with Conditions Notation: REVIEWER'S INITIALS: DUE DATE: 04 -01 -10 Not Approved (attach comments) n DATE: Permit Center Use Only CORRECTION LETTER MAILED: Departments issued corrections: Bldg ❑ Fire ❑ Ping ❑ PW ❑ Staff Initials: Documents /routing slip.doc 2 -28 -02 PROJECT NAME: PI,i�TWO d-V- �Ic,S PERMIT NO: SITE ADDRESS: 5 11/12 � ORIGINAL ISSUE DATE: r 23t `` 110 REVISION LOG REVISION NO. DATE RECEIVED STAFF INITIALS ISSUED DATE STAFF INITIALS REVISION _ NO. DATE RECEIVED STAFF INITIALS ISSUED DATE Summary of Revision: STAFF INITIALS O bo h 1 ., 1 ul L0 _ Summary of Revision: b- U •1 rnnt 1 Li LI-L p& - L 1h af 0Lii r Acwo s Received by: e _ � ✓��! REVISION NO. DATE RECEIVED STAFF INITIALS ISSUED DATE STAFF INITIALS Summary of Revision: Received by: ease print) REVISION NO. DATE RECEIVED STAFF INITIALS ISSUED DATE STAFF INITIALS Summary of Revision: Received by: (please print) REVISION NO. DATE RECEIVED STAFF INITIALS ISSUED DATE STAFF INITIALS Summary of Revision: Received by: ease print) REVISION NO. DATE RECEIVED STAFF INITIALS ISSUED DATE STAFF INITIALS Summary of Revision: Received by: (please print) REVISION NO. DATE RECEIVED STAFF INITIALS ISSUED DATE STAFF INITIALS Summary of Revision: Received by: City of Tukwila Department of Community Development 6300 Southcenter Boulevard, Suite #100 ' Tukwila, Washington 98188 Phone: 206 - 431 -3670 Web site: http: / /www.ci.tukwila.wa.us Revision submittals must be submitted in person at the Permit Center. Revisions will not be accepted through the mail, fax, etc. Date: 5/1/2010 Plan Check/Permit Number: /0- of s7 O Response to Incomplete Letter # O Response to Correction Letter # Revision # l after Permit is Issued O Revision requested by a City Building Inspector or Plans Examiner Project Name: Project Address: Contact Person: 355 S. 12o PL • / `1 �i�c�, 1 4 `' Phone Number: 2:t. -2,2-8 • Gaff tl l Summary of Revision: 6CPU 1.--g 1 ii o loll Q.4 & Nam 46,"S LA 61 Vk T1 Cie)A1 111-4) ig4 001 CO-Ti 0"A Op Ednl III , C 1I7— 16/13 / C 114 , C /L/ Sheet Number(s): C I'-II / E/ J Z, E sot' / Edova / "Cloud" or highlight all areas of revision including date of revision / C /-zZ, 8"/ 3 ) C . 7001 E 7o l , E 7oz ,� -703 , E7ll, E71z- Received at the City of Tukwila Permit Center by: Entered in Permits Plus on 0 H: Applicatuons\Folms- Applications On L ne\2009 -08 Revision Submittal.doc Created: 8-13-2004 Revised: 8 -2009 Contractors or Tradespeople Peter Friendly Page • Electrical Contractor A business licensed by LEI to contract electrical work within the scope of its specialty. Electrical Contractors must maintain a surety bond or assignment of savings account. They also must have a designated Electrical Administrator or Master Electrician who is a member of the firm or a full -time supervisory employee. Business and Licensing Information Name Phone Address Suite /Apt. City State Zip County Business Type Parent Company Precision Electric Group Inc 2069489800 13609 Ne 126Th Pt Ste 100 Kirkland Wa 98034 King Corporation UBI No. Status License No. License Type Effective Date Expiration Date Suspend Date Specialty 1 Specialty 2 602434703 Active PRECIEG969PH Electrical Contractor 10/8/2004 10/8/2010 General Unused MASTER ELECTRICIAN INFORMATION License DAVISMD962DH Name Davis, Mark D Status Active Business Owner Information Name Role Effective Date Expiration Date Franke, Patrick J Agent 10/08/2004 Bond Amount Davis, Mark D President 10/08/2004 6572196 Bond Information Page 1 of 1 Bond Bond Company Name Bond Account Number Effective Date Expiration Date Cancel Date Impaired Date Bond Amount Received Date 3 First National Ins Co of Ameci 6572196 10/20/2008 Until Cancelled $4,000.00 10/08/2008 2 NATIONWIDE MUTUAL INS CO 7900637867 10/20/2005 Until Cancelled 01/05/2010 $4,000.00 12/08/2006 1 DEVELOPERS INSURANCE COMPANY 574104C 10/07/2004 Until Cancelled 11/29/2007 $4,000.00 10/08/2004 Assignment of Savings Information No records found for the previous 6 year period Insurance Information No records found for the previous 6 year period Summons /Complaint Information Summons and Complaints are not filed with the department for this contractor type https: // fortress .wa.gov /lni/bbip /Print.aspx 03/23/2010 10 GENERAL NOTES FIRE ALARM SYMBOL LIST WIRING / EQUIP CONNECT SYMB LIST SINGLE LINE SYSTEM SYMBOL LIST LIGHTING SYMBOL LIST ABBREVIATIONS 1. ALL WORK SHOWN IS NEW UNLESS NOTED EXISTING. 2. REMOVE ALL CONDUCTORS, DEVICES, AND CONDUIT RENDERED UNUSED BY THIS PROJECT. 3. VERIFY CIRCUITRY OF EXISTING DEVICES TO BE REMOVED PRIOR TO `DEMOLITION AND PERFORM SPLICES AS REQUIRED TO MAINTAIN CONTINUITY OF CIRCUITS TO EXISTING DEVICES TO REMAIN. 4. 5. 6. 7. SEAL ALL CONDUIT PENETRATIONS OF FLOORS AND FIRE RATED ASSEMBLIES WITH U.L. APPROVED MATERIALS AND METHODS TO MAINTAIN FIRE RATING. PROVIDE NEW TYPEWRITTEN DIRECTORIES REFLECTING WORK PERFORMED FOR ALL EXISTING PANELBOARDS MODIFIED BY THIS PROJECT. PROTECT ALL OPENINGS FOR STEEL ELECTRICAL BOXES IN FIRE RATED WALLS WITH U.L. APPROVED MATERIALS AND METHODS TO MAINTAIN THE FIRE INTEGRITY. ALL WORK ON EXISTING ELECTRICAL SYSTEM MUST BE PERFORMED USING INTERNAP CRITICAL ENVIRONMENT WORK AUTHORIZATION. CONTRACTOR SHALL BE RESPONSIBLE FOR PREPARATION OF DOCUMENT DESCRIBING WORK PROCEDURES, PROTECTION OF EXISTING SYSTEMS AND DISASTER RECOVERY PROCEDURE.. SYMBOL DESCRIPTION RECESSED WALL FIRE ALARM AUDIO DEVICE, MOUNTED 9" BELOW CEILING, UNLESS NOTED OTHERWSE. SYMBOL DESCRIPTION SYMBOL DESCRIPTION SYMBOL DESCRIPTION SUFFIX DESCRIPTION CEILING MOUNTED JUNCTION BOX. INTEGRAL KILOWATTHOUR METER. RECESSED FLUORESCENT LIGHTING FIXTURE. 4S ADA 4" SQUARE BY 2 1/8" DEEP BOX. AMERICAN WITH DISABILITIES ACT. 1--E4 SURFACE WALL FIRE ALARM AUDIO DEVICE, MOUNTED 9" BELOW CEILING, UNLESS NOTED OTHERWSE. JUNCTION BOX, FLUSH MOUNTED AT +18" UNLESS NOTED OTHERWSE. KWH KILOWATTHOUR METER WITH CT'S. RECESSED FLUORESCENT NIGHT LIGHTING FIXTURE, PANEL SWITCHED ONLY. AFF ABOVE FINISH FLOOR. AFG ABOVE FINISH GRADE. RECESSED WALL FIRE ALARM MANUAL REPORTING STATION, MOUNTED AT +48" AFF. JUNCTION BOX, SURFACE MOUNTED AT +18" UNLESS NOTED OTHERWISE. CURRENT TRANSFORMER. 01 SURFACE MOUNTED FLUORESCENT STRIP LIGHTING FIXTURE. AWG AMERICAN WIRE GAUGE. AMP, A AMPERE. SURFACE WALL FIRE ALARM MANUAL REPORTING STATION, MOUNTED AT +48" AFF. JUNCTION BOX WITH FLEXIBLE CONDUIT CONNECTION. POTENTIAL TRANSFORMER. SURFACE MOUNTED FLUORESCENT STRIP NIGHT LIGHTING FIXTURE, PANEL SWITCHED ONLY. A.I.C. AMPERES INTERRUPTING CAPACITY (SYMMETRICAL). AF /AT AMP FRAME, AMP TRIP. RECESSED WALL, FIRE ALARM AUDIO /VISUAL DEVICE, MTD. 9" BELOW CEILING, UNLESS NOTED OTHERWSE. BRANCH CIRCUIT CONDUIT, CONCEALED IN WALL OR CEILING. FUSE. tei EXIT LIGHTING FIXTURE WITH DIRECTIONAL ARROWS INDICATED. DARKENED AREA(S) INDICATES FACE(S) LIT. AS /AF AMP SWITCH, AMP FUSE. ATS AUTOMATIC TRANSFER SWITCH. i —� SURFACE WALL FIRE ALARM AUDIO /VISUAL DEVICE, MTD. 9" BELOW CEILING, UNLESS NOTED OTHERWSE. BRANCH CIRCUIT CONDUIT, CONCEALED IN FLOOR OR UNDERGROUND. FUSED CUTOUT POLE MOUNTED AREA LIGHTING FIXTURE. AUX AUXILIARY CONTACTS. BRANCH. 1>134 CEILING MTD. FIRE ALARM AUDIO /VISUAL DEVICE. RECESSED WALL FIRE ALARM VISUAL DEVICE, MTD. 9" BELOW CEILING, UNLESS NOTED OTHERWISE. BRANCH CIRCUIT CONDUIT, RUN EXPOSED. FUSIBLE ELEMENT. 2# 12, 1/2"C. 111 11 5# 12, 1/2"C. n CIRCUIT BREAKER. CONTROLS SYMBOL LIST BLDG BUILDING. CIRC., CKT. CIRCUIT. SYMBOL DESCRIPTION CB CIRCUIT BREAKER. SFD COMBINATION SMOKE FIRE DAMPER. SURFACE WALL FIRE ALARM VISUAL DEVICE, MTD. 9" BELOW CEILING, UNLESS NOTED OTHERWISE. 111 3# 12, 1/2"C. III III 6# 12, 1/TC. SWITCH SWITCH MOUNTED IN SURFACE BOX, +48" UNLESS NOTED OTHERWISE. C CONDUIT. C.O. CONDUIT ONLY, COMPLETE WITH PULLSTRING. —ID RECESSED WALL FIRE ALARM BELL. 1111 4# 12, 1/2 "C. 1111 111 7# 12, 3/4 "C. TRANSFER SWITCH. SWITCH - RECESSED, +48" UNLESS NOTED OTHERWISE. CONN CONNECTED. CT CURRENT TRANSFORMER. HID SURFACE WALL FIRE ALARM BELL. DISCONNECT SWITCH, "F" INDICATES FUSED TYPE, MOUNTED AT +54" UNLESS NOTED OTHERWISE. GENERATOR. a,b,c SPST WALL SWTCH. LETTERS INDICATE THE NUMBER OF SWITCHES AND OUTLETS THEY CONTROL. MOUNTED FLUSH IN BOX AT +48" U.O.N. CPT CONTROL POWER TRANSFORMER. DIA DIAMETER. WALL MOUNTED FIRE ALARM REMOTE TROUBLE ANNUNCIATOR +48" UNLESS NOTED OTHERWISE. MAGNETIC MOTOR STARTER, MOUNTED AT +54" UNLESS NOTED OTHERWISE. TERMINATOR. D WALL BOX DIMMER, +48" UNLESS NOTED OTHERWISE. DISC DISCONNECT. DIST DISTRIBUTION. FIRE ALARM OVERHEAD DOOR RELEASE DEVICE. FIRE ALARM MAGNETIC DOOR HOLDER. E COMBINATION MOTOR STARTER, MOUNTED AT +54" UNLESS NOTED OTHERWISE. EMERGENCY SYSTEM CONDUIT. • L T APPARATUS BUSHING. CONTACT. REVIEWED FOR - CONIPLIrANCE WITH NFPA 70 - NEC DR K REMOTE DIMMER SWITCH, +48" UNLESS NOTED OTHERWISE. KEYED WALL SWTCH, +48" UNLESS NOTED OTHERWISE. E.C. ELECTRICAL CONTRACTOR. EMS EMT ENERGY MANAGEMENT CONTROL SYSTEM. ELECTRICAL METALLIC TUBING. EWC ELECTRIC WATER COOLER. FIRE ALARM FLOW SWITCH OUTLET. A ALARM SYSTEM CONDUIT, 3/4" C.O. UNLESS NOTED OTHERWISE. 1 GROUND. JUN 01 2010 MANUAL MOTOR STARTER, +48" UNLESS NOTED OTHERWISE. E.P.O. EMERGENCY POWER OFF. EF EXHAUST FAN. FIRE ALARM POST INDICATOR VALVE OUTLET. FA FIRE ALARM SYSTEM CONDUIT. KIRK KEY INTERLOCK. FIRE ALARM TAMPER SWITCH OUTLET. T TELEPHONE SYSTEM CONDUIT, 3/4" C.O. UNLESS NOTED OTHERWISE. SHEET NOTE REFERENCE. City of BUILDING D wild VISION WALL SWITCH WITH PILOT LIGHT, +48" UNLESS NOTED OTHERWISE. SPDT WALL SWITCH, MOMENTARY CONTACT, CENTER MAINTAINED, +48" UNLESS NOTED OTHERWISE. FT or FEET. FA FLA FIRE ALARM. FULL LOAD AMPS. GRND GROUND. CEILING MOUNTED FIRE ALARM IONIZATION SMOKE DETECTOR. PA PUBLIC ADDRESS SYSTEM CONDUIT. MOTOR. 2 DPST WALL SWITCH, +48" UNLESS NOTED OTHERWSE. GFCI GROUND FAULT CIRCUIT INTERRUPTER. HOA HAND -OFF -AUTO. OA CEILING MOUNTED FIRE ALARM ADDRESSABLE IONIZATION SMOKE DETECTOR. INTERCOM SYSTEM CONDUIT. FEEDER SIZE REFERENCE. THREE -WAY WALL SWITCH, +48" UNLESS NOTED OTHERWISE. HACR HEATING AIR CONDITIONING REFRIGERATION. HVAC HEATING, VENTILATING AND AIR CONDITIONING. © A CEILING MOUNTED FIRE ALARM PHOTOELECTRIC SMOKE DETECTOR. TV TELEVISION SYSTEM CONDUIT. CEILING MOUNTED FIRE ALARM ADDRESSABLE PHOTOELECTRIC SMOKE DETECTOR. D DATA SYSTEM CONDUIT. DRAW -OUT DEVICE. FOUR -WAY WALL SWITCH, +48" UNLESS NOTED OTHERWISE. HEIGHT, WIDTH, DEPTH, LENGTH. JUNCTION BOX, FLUSH MOUNTED AT +18" UNLESS NOTED OTHERWISE. HID HP HIGH INTENSITY DISCHARGE. HORSEPOWER. HPS HIGH PRESSURE SODIUM. FIRE SMOKE DAMPER. G BARE COPPER GROUND CONDUCTOR. CEILING MOUNTED FIRE ALARM HEAT DETECTOR. LV LOW VOLTAGE CIRCUIT. DRAW -OUT MEDIUM VOLTAGE CIRCUIT BREAKER. JUNCTION BOX, SURFACE MOUNTED AT +18" UNLESS NOTED OTHERWISE. IN. or " INCHES. IG ISOLATED GROUND. CEILING MOUNTED JUNCTION BOX. JBOX JUNCTION BOX. K DEGREE KELVIN. OA CEILING MOUNTED FIRE ALARM ADDRESSABLE HEAT DETECTOR. 0 CONDUIT RUN TURNED UP. of DUCT MOUNTED SMOKE DETECTOR. CONDUIT RUN TURNED DOWN. PA/ TRANSFORMER. JUNCTION BOX PLEX. KAIC KILOVOLT AMPERES AVAILABLE INRUSH CURRENT. KVA KILOVOLT AMPERES. JUNCTION BOX WITH FLEXIBLE CONDUIT CONNECTION. KW KWH KILOWATT HOUR. DH ELECTRO- MAGNETIC DOOR HOLDER. CONDUIT RUN STUBBED OUT. FIREFIGHTERS TELEPHONE OUTLET +52" AFF. UON. BRANCH CIRCUIT HOMERUN MTH PANEL AND CIRCUIT DESIGNATED. FUSED SWITCH. THERMOSTAT OUTLET, MOUNTED AT +60" UNLESS NOTED OTHERWISE. L.F. LINEAR FEET. LTG, LTS CEILING MOUNTED FIRE ALARM SMOKE DETECTOR / STROBE DEVICE. XN INDICATES NEW CONDUCTORS IN EXISTING CONDUIT. ANN REMOTE ANNUNICATOR PANEL. FLEXIBLE CONDUIT W/ POINT OF CONNECTION. DRAW -OUT FUSED SWITCH. IT PUSHBUTTON STATION. LPS LOW PRESSURE SODIUM. WALL CLOCK /INTERVAL TIMER, MOUNTED AS INDICATED ON PLANS. MAX. MOCP MAXIMUM. MAXIMUM OVERCURRENT PROTECTION. MCB MAIN CIRCUIT BREAKER. CONTACTOR. MLO MAIN LUGS ONLY. M METER. FACP FIRE ALARM CONTROL PANEL. • POINT OF CONNECTION. SNAC SECONDARY NAC EXTENDER PANEL. CABLE TRAY. TRANSFER SWITCH WITH BYPASS ISOLATION. PHOTOCELL MOUNTED AS NOTED ON PLANS. M/M METER MAIN. MV MERCURY VAPOR. SOLENOID VALVE. MH METAL HALIDE. MIN. MINIMUM. FILE COPY Permit No tQd Plan review approval Is subject to errors and omissions. Approval of construction documents does no arms the violation of an dopt nce, Receipt of approved POWER SYMBOL LIST SYMBOL DESCRIPTION DUPLEX CONVENIENCE OUTLET MOUNTED IN FLUSH BOX AT +18" UNLESS NOTED OTHERWISE. City Of Tukwila BUILDING DIVISION SEPARATE PERMIT REQUIRED FOR: )(Mechanical Electrical lumbing Gas Piping City of Tukwila BUILDING DIVISION REVISIONS No changes shall b e made to the scope of work without prior approval of Tukwila Building Division. NOTE: Revisions will require a new plan submittMt and may include additional plan revi -A” f ;cs _ DUPLEX CONVENIENCE OUTLET MOUNTED IN SURFACE BOX AT +18" UNLESS NOTED OTHERWISE. PANELBOARD. PANELBOARD WITH DOUBLE LUG. OCCUPANCY SENSOR POWER PACK AND RELAY MCA MINIMUM CIRCUIT AMPS. MCM THOUSAND CIRCULAR MILS. INFRARED OCCUPANCY SENSOR. RECESSED WALL SWITCH OCCUPANCY SENSOR. MFR. MANUFACTURER. MTD MCP MOUNTED. MOTOR CIRCUIT PROTECTOR. SURFACE WALL SWITCH OCCUPANCY SENSOR. MW NEC MICROWAVE. NEMA NATIONAL ELECTRICAL CODE. NATIONAL ELECTRICAL MANUFACTURER'S ASSOCIATIONT DOUBLE DUPLEX CONVENIENCE OUTLET, +18" UNLESS NOTED OTHERWISE. GFI .oS CONVENIENCE OUTLET W /INTEGRAL GROUND FAULT INTERRUPTER, +18" UNLESS NOTED OTHERWISE. SECURITY SYMBOL LIST SYMBOL DESCRIPTION U DT ULTRASONIC OCCUPANCY SENSOR. DUAL TECHNOLOGY OCCUPANCY SENSOR. NC NO NF NIC NORMALLY CLOSED. NORMALLY OPENED. NON- FUSED. NOT IN CONTRACT. CONVENIENCE OUTLET WITH INTEGRAL SURGE SUPPRESSOR, +18" UNLESS NOTED OTHERWISE. MAGNETIC DOOR ALARM SWITCH. RELAY. NL NIGHT LIGHT. N.T.S. NOT TO SCALE. SINGLE CONVENIENCE OUTLET, +18" UNLESS NOTED OTHERWSE. SECURITY KEY PAD. DUPLEX CONVENIENCE OUTLET, TOP HALF SWITCHED, +18" UNLESS NOTED OTHERWISE. ELECTRIC DOOR STRIKE. TELECOMMUNICA11ONS SYMBOL LIST NL NIGHT LIGHT. SYMBOL DESCRIPTION NO. or OFCI NUMBER. OWNER FURNISHED, CONTRACTOR INSTALLED. PERCENT IMPEDANCE. DUPLEX CONVENIENCE OUTLET WITH ISOLATED GROUND, +18" UNLESS NOTED OTHERWISE. ELECTRIC DOOR LOCK. TELEPHONE OUTLET, +18" UNLESS NOTED OTHERWISE. PH. or PHASE. PC PHOTOCELL FLOOR MOUNTED DUPLEX CONVENIENCE OUTLET. SECURITY SYSTEM CARD ACCESS READER. WALL TELEPHONE OUTLET, +48" UNLESS NOTED OTHERWISE. P POLE. PVC POLY VINYL CHLORIDE. CONDUIT MOUNTED DUPLEX CONVENIENCE OUTLET. SECURITY SYSTEM PROXIMITY READER. COMBINATION TELEPHONE AND DATA OUTLET, +18" UNLESS NOTED OTHERWISE. PDU POWER DISTRIBUTION UNIT. PRIMARY OVER 600 VOLTS. FLUSH FLOOR BOX W/ DUPLEX RECEPTACLE. SECURITY SYSTEM PANIC BUTTON. DATA SYSTEM OUTLET, +18" UNLESS NOTED OTHERWISE. PROVIDE FURNISH, INSTALL AND CONNECT. PT POTENTIAL TRANSFORMER. MULTI SERVICE FLUSH FLOOR BOX. WALL MTD PANIC BUTTON. DICTATION SYSTEM OUTLET, +18" UNLESS NOTED OTHERWSE. PA PUBLIC ADDRESS. REC, RECEPT RECEPTACLE. FLUSH FLOOR POWER SYSTEM FURNITURE FEED. SECURITY CEILING MOUNTED MOTION DETECTOR. WALL MOUNTED TELECOMMUNICATION SYSTEM FURNITURE FEED. REF REFRIGERATOR. RGS RIGID GALVANIZED STEEL CLOCK HANGER OUTLET, MOUNTED AS INDICATED ON PLANS. SECURITY CEILING MOUNTED MOTION DETECTOR - 2 WAY. FLOOR MOUNTED TELEPHONE OUTLET. RL RUNNING LIGHT. SINGLE LINE DIAGRAM. SPECIAL PURPOSE RECEPTACLE, +18" UNLESS NOTED OTHERWISE, NEMA CONFIGURATION AS NOTED ON THE PLANS. SECURITY WALL MOUNTED MOTION DETECTOR +96" UNLESS NOTED OTHERWISE. FLOOR MOUNTED COMBINATION TELEPHONE AND DATA OUTLET. SCC SHORT CIRCUIT CURRENT. SFD SMOKE FIRE DAMPER. WALL MOUNTED POWER SYSTEM FURNITURE FEED. —OQ CLOSED CIRCUIT TELEVISION CAMERA. FLOOR MOUNTED DATA SYSTEM OUTLET. SQ. STB SQUARE. SHUNT TRIP BREAKER. MA TYPE "A" SURFACE MTD. MULTI OUTLET ASSEMBLY, MOUNTING HEIGHT AS NOTED ON PLANS. O4 SURFACE MTD CLOSE CIRCUIT TELEVISION CAMERA. POKE THRU DATA SYSTEM OUTLET. SU SITE UTILITIES. MAY 1 0 2010 TC SA i TYPE "A" SURFACE MTD. METAL RACEWAY, MOUNTING HEIGHT AS NOTED ON PLANS. �—d CCTV CLOSED CIRCUIT TELEVISION OUTLET. FLUSH FLOOR TELECOMMUNICATION SYSTEM FURNITURE FEED. TEL /DATA TELEPHONE AND DATA. PERMIT CEN ER TV FLUSH MOUNTED BRANCH CIRCUIT PANELBOARD. TELEVISION SYSTEM OUTLET, +18" UNLESS NOTED OTHERWISE. TELEPHONE BACKBOARD, SIZE AS NOTED ON PLANS. T.V.S.S. TRANSIENT VOLTAGE SURGE SUPPRESSION. TYP TYPICAL SURFACE MOUNTED BRANCH CIRCUIT PANELBOARD. D DOOR CONTACT SWITCH. DISTRIBUTION BOARD. REX REQUEST TO EXIT DEVICE. DISTRIBUTION PANELBOARD. �QS SECURITY MONITOR. TERMINAL CABINET. SCP SECURITY CONTROL PANEL. GROUND ROD. GROUNDING BUS BAR W /MINIMUM #6 COPPER WIRE TO EQUIPMENT GROUND BUS. GLASS BREAK SENSOR. 13 RELAY REVISION N01i. X1.10 - n 1‘.1 U.G.P.S. UNDERGROUND PULL SECTION. U.O.N. UNLESS OTHERWISE NOTED. U.P.S. UNINTERRUPTABLE POWER SYSTEM. VAV VARIABLE AIR VOLUME. V VOLTS. VA VOLT AMPERES. VD VOLTAGE DROP. WP W WIRE. XFMR X INDICATES EXISTING TO REMAIN. XR INDICATES EXISTING TO BE REMOVED. XL INDICATES EXISTING TO BE RELOCATED. XN INDICATES NEW LOCATION OF RELOCATED EQUIPMENT. 250 WILLIAMS ST., GA 30303 -J 1 1 • 877.THE.PNAP www.internap.com wooco- • 0 en ro41 (13 14 9 ft NTERGATE EAST CAMPUS co cc E CO too co 0 ISSUED / REVISED DATE CD SET 03/08/10 REV 1i 03/30/10 $$$DESIGN$SPECI FICATION$$$$$$$$$$$$$ SYMBOL LIST GENERAL NOTES E00°1 10 CD o CD 0 O O O REVIEWED AOR COMPLIANCE WITH NFPA70 - NEC JUN 01 2010 City of Tukwila BUILDING DIVISION EXISTING 12 "X12 "X60 "H HIGH VOLTAGE PULL BOX EXTEND NEW EXPOSED CONDUIT FROM EXISTING BOX EXISTING 6" HV CONDUIT UNDER EXISTING SLAB SPARE BREAKER MAIN SWITCHGEAR "MSG2" EXISTING MV SERVICE ELECTRIC ROOM ❑ EXISTING UN FUEL TANKS (40,000 GAL EACH) OFFICE 1 121K 1 111111111111111111111111111im 11 33 1ST FLOOR PARTIAL PLAN - POWER FE 33 mr- FE 3j 33 33 SCALE: 1/16"=1'-0" REVISION N ELloo (S7 $$$DESIGN$SPECI FICATION$$$$$$$$$$$$$ c�rroE�LA MAY `f 0 2010 PERMIT CENTER $$$DATE$$$$ $TIME COPYRIGHTU 2008 CALLISON 4 ftg www.internap.com CALLISON PHASE II lam INTERGATE EAST CAMPUS 0 0 ISSUED / REVISED DATE CD SET 03/08/10 REV 1 03/30/10 ESI 2 A 04/30/10 1ST FLOOR POWER PLAN E111 10 II I I ■■■E ■■■�■ ■■��P■ ■■�■�■� ■ ■M■■1■1 1111 ��':r7■ 1111■ iiibiliniMMONOMMIF _1■■■ __ ■■ 1 ■10 ■ ■ ■1■ 1111■ 1 ■1 1111 � -�i■■I MMr 11111 i I1ii1■i1111 111■i ■ ■■ ■— ■ ■.1■■■ ■ ■ MN= ND .I. 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ROUTE ALL PDU FEEDER UNDER THE RAISED FLOOR. MAKE CONNECTION TO PDU WITH LIQUID TIGHT FLEX. 2. GENERAL BUILDING POWER SHALL NOT BE RUN UNDER FLOOR, ROUTE CONCEALED IN WALLS AND CEILING. NOTES REVISION N0,1 EL14 -0 I S7 0 BMS PANEL, PROVIDE DEDICATED NEUTRAL FOR CIRCUIT. 02 CONNECT TO BREAKER TRANSFER CONTROLLER. 3RD FLOOR POWER PLAN SCALE: 1 /8 " =1' -0" clAoFcH°nut MAY 1 o zoo PERMIT CENTER 1 wan 0 0 ti N 0 M 0 I- u_ 877.THE.PNAP www.internap.com wAsii is z 0 J 0 0 0 * o J ▪ =o J v 0 INTERGATE EAST CAMPUS 0 0 co rn 0 N 1- U w 0 ISSUED / REVISED CD SET REV 10i ESI 2 DATE 03/08/10 03/30/10 04/30/10 $',$DESIGN' SPECIFICATION ','.$ $$'.DATE$$ $ $TIME COPYRIGHT O 2008 CALLISON 3RD FLOOR POWER PLAN E112 1 2 5 6 7 8 10 v4" C.O. TO 3RD FLOOR LECTRICAL ROOM FOR UTUZE HUMIDIFIER CIRCUITS �^ i i 1E1i LIGHT FIXTURE n W/PHOTOCELL U CONDUIT MOUNTED 24" ABOVE TOP OF RTU P33-21 P33-2L_ 1 a! 2 w I- D c CM ;0 �jM o O M O < N < O Z (y w 7.1 a0I J I— M I— ;Q44-N- 0 N. �1 Tr co — N < I- LL www.internap.com P33 -4 (FUTURE) MIMI' I RE) P3 P3 i111111k rairalal••••11111 PROVIDE NE REFLECT NE' 1' PLY IIall 2 pill! 31,33,35 T FLOOR ND, 3'4"C r rr 44-_r P33 -21 P33-21 TIME SWITCH AND RECEPTACLE MOUNTED IN WP BOX AT +54" ABOVE ROOF LEVEL TYP RTU LTG FIX MOUNTING DET SCALE: 1 /4 " =1' -0" RTU 4 -5 ( FUTLRE) P33 -4 (FL TURE)® 4 H P33 0 REVIEWED FOR COMPLIANCE WITH NFPA 70 - NEC FOP33 -4 P3 JUN 0 2010 L_J "mss: Aft Aft Aft l_L'w• �1' City of Tukwila BUILDING DIVISION • O 000 3" C.0 FOR RTU UNIT FEE TO ROOM 155 ON 1ST (TYP rdF 7) 1 1 1 1 1 (441 P33 -6 P33 -6 L- P33 -6© RE) RE T (FUTURE) 33" C.o TO 3RD FLOOR EL RICAL ROOM FOR H JMIDIFIER CIR UIT roc ismimmeimmialimina =MAW EXTERIOR LTC SHUT OFF SCHED. DEVICE '-0 IT LIGHT FIXTURE WITH PHOTOCELL SWITCH TIME SWITCH SET TO 30 MIN ON, AUTO OFF BATTERY BACK UP NOT REQUIRED, SWITCH PROGRAMMING NOT AFFECTED BY POWER LOSS LITHONIA ACCESSORY # RK1 PEB1 WATTSTOPPER TS -400 INTERNAP DATA CENTER PHASE III INTERGATE EAST CAMPUS 3355 S. 120th Place Tukwila, WA 98168 _J PROVIDE NEW LABEL TO REFLECT NEW FEEDER SUPPLY 1. REVISIONNO. __ L tiL1O 0157 GENERAL NOTES ROUTE ALL CONDUITS FOR RTU'S IN 3RD FLOOR CEILING SPACE. CONDUITS SHALL BE STUBBED UP IN SIDE ROOF CURB. FOR FUTURE UNITS, CAP CONDUITS. 0; u1 W c) Q q 0 0. Q W ISSUED / REVISED CD SET DATE 03/08/10 03/30/10 0 0 ti co 0 0 N 1— 0 U w 0_ 04/30/10 cRrd�nSLn MAY 10 2010 PERMITCENTER 7411Iik / ,. r, 411111k __HIIII . .i_ w*Irr11111/PNI 1IIII"AINliiiiImo" _"�_1 tir~rrial 1' -01/2' 1:11 I. ..`......111111111111111114 .IIIRI Elil■ i�rr�-+�1� Wes_ IuIIII !1�7" ril�llll� %Z %�II 6' -0' 13' -6' ' -0' Y- 101/2' 1/16' , 6'- • 1Q' -1 1/2" ROOF POWER PLAN SCALE: 1 /8 "=1' -0" ROOF POWER PLAN 6' -21/2' 15' -3 1/2' E113 DESIGN SPECIFICATION$ $$$$' $$'-$$$ $$$DATE$$$$ $TIME COPYRIGHT 2008 CALLISON 10 • CPIP.,,.,,..,,,�. , . r1' �YI•liti i� . I ■IUTAt� UIUI�Ir` a.l1=ll 114 I ll•! • rlrlRfM " NIilI I MI•Ml•,- i�= '�_11 i IiiMi��twll � I� ~tirl SAII• ■Iri•ll . _ DT -3 (FRONT) DT -2 DT -1 P31 -11 1!� DBY 1 » •» HP31 -17,19 0 HP31 -13,15 STOJDBY 1 A)_• '!! HP31 -5,7 S 5" 0 31 -3 1 ■ 0 DBY "S 6" 31 -1 ■ 0 UMMIN ■■ NMI ■■ UP s. GEN. PARALLELING SWGR. TERMINATION BUS (FRONT) X (FRONT) (FRONT) ATS #1 ATS #3 W/ BYPASS USS-1 2500KVA XFMR. #1 600A 26.4KV HV SWITCH GEN ROOM 150 (FRONT) (FRONT) USS-2 2500KVA XFMR. #1 600A 26,4KV HV SWITCH 11 • • • L INSTALL (6) 3" C.O. FOR PHASE 4 SPARE CONDUIT RISERS v _ i " ❑ s- r r 1 rr r L_ UPS /AC -1 U L DISCONNECT EXISTING FEEDER "ATSLUPSO "� FROM BREAKER Q3BP IN UPS OUTPUT BOARD. BUTT SPLICE NEW CONDUCTORS WITH COMPRESSION CONNECTOR AND INSULATE WITH HEAT SHRINK AND EXTEND TO (FRONT) (FRONT) UPS MOD -1 (FRONT) TTERY -1 mod DISCONNECT FEEDER "FUP50U01" FROM UPS OUTPUT BUTT SPLCE NEW CONDUCTORS WITH COMPRETPONNECTOR AND INSULATE WITH HEAT ®oo "DB- UPSBP1 UPS MOD -2 °c°o®I (FRONT) (FRONT) UPS " ❑ SERVICE 1 "DB -UI SBP1 ". L._ j bypass ups 1/2 SWI-CHBO upUP4S IN 3/4 'UT SWBD. ats ats input cab (FRONT) (FRONT) UPS MOD -1 (FRONT) TTERY -1 mod DISCONNECT FEEDER "FUP50U01" FROM UPS OUTPUT BUTT SPLCE NEW CONDUCTORS WITH COMPRETPONNECTOR AND INSULATE WITH HEAT ®oo "DB- UPSBP1 UPS MOD -2 °c°o®I (FRONT) (FRONT) P31 -11 P31 -7 P31 -1 P31 -11 GEN ROOM 152 cl co P31-1113=1 II _ HP31 -2,4,6 HP31 UNIT SUBSTATION "U -EH pi P31 -9s 0 P31 -11 0=1 SWITCH GEAR 153 UNI SUBSTATION "USS P31 -11 SW CH BOARD -MECF 3" n ,10,12 UPS MOD -3 B TTERY -2 —7 (FRONT) (FRONT) UPS MOD-4 BATTERY -3 (FRONT) BATTERY -4 (FRONT) UPS ROOM 151 11 E DIST BD "DB- UPSBP1" ROUTE CONDUCTORS FROM EXISTING UPS OUTPUT BUS TO DB- UPSBP1 24 "W X48 "D X48 "H PULL BOX WITH WEST SIDE OPEN, MOUNTED ADJACENT TO EXISTING PULL BOX. EXISTING PULL BOX. REMOVE EAST COVER FOR CONNECTION TO NEW PULL BOX. (10) 3" C.O. FOR FUTURE PHASE 4 DB -UPS4B BYPASS FEEDER (10) 3" C.O. FOR FUTURE PHASE 4 DB -UPS4B FEEDER (9) 3" C.O. FOR FUTURE PHASE 4 RTU FEEDERS AP PANEL HP 4R AT ROOF ANI PANEL P43 AT THIRD FLO( (10) 3" C.O. FOR FUTURE PHASE 4 DB -UPS4A BYPA FEEDER (10) 3" C.O. FOR FUTURE PHASE 4 DB -UPS4A FEEDER S 1ST FLOOR ENLARGED POWER PLAN LLW JLL HP31- 20,22,24 31 -19 U UPS " 1 SERVICE SWBD #1 PS SI Min in SWI-CHBO D rain -1 ats ats tie ats & S TEM main -2 P31 -11 P31 -7 P31 -1 P31 -11 GEN ROOM 152 cl co P31-1113=1 II _ HP31 -2,4,6 HP31 UNIT SUBSTATION "U -EH pi P31 -9s 0 P31 -11 0=1 SWITCH GEAR 153 UNI SUBSTATION "USS P31 -11 SW CH BOARD -MECF 3" n ,10,12 UPS MOD -3 B TTERY -2 —7 (FRONT) (FRONT) UPS MOD-4 BATTERY -3 (FRONT) BATTERY -4 (FRONT) UPS ROOM 151 11 E DIST BD "DB- UPSBP1" ROUTE CONDUCTORS FROM EXISTING UPS OUTPUT BUS TO DB- UPSBP1 24 "W X48 "D X48 "H PULL BOX WITH WEST SIDE OPEN, MOUNTED ADJACENT TO EXISTING PULL BOX. EXISTING PULL BOX. REMOVE EAST COVER FOR CONNECTION TO NEW PULL BOX. (10) 3" C.O. FOR FUTURE PHASE 4 DB -UPS4B BYPASS FEEDER (10) 3" C.O. FOR FUTURE PHASE 4 DB -UPS4B FEEDER (9) 3" C.O. FOR FUTURE PHASE 4 RTU FEEDERS AP PANEL HP 4R AT ROOF ANI PANEL P43 AT THIRD FLO( (10) 3" C.O. FOR FUTURE PHASE 4 DB -UPS4A BYPA FEEDER (10) 3" C.O. FOR FUTURE PHASE 4 DB -UPS4A FEEDER S 1ST FLOOR ENLARGED POWER PLAN LLW JLL HP31- 20,22,24 31 -19 U UPS " 1 AND ST RD "DR— M'CH3R" PS SI Min in SWI-CHBO D UPS3' Viral _. C INET & S TEM 'ZfC , 1 r' - BATTERY 1 UPS MODULE 1 AND ST RD "DR— M'CH3R" BATTERY 3 UPS MODULE 2 BATTERY 2 J AND ST RD BATTERY 3 UPS MODULE 3 ff C, AND ST RD "DR— M'CH3R" UPS MODULE 4 PANEL "L31 XFMR "XFR -L3" DISC SW "DS -L3" SG3 E CHARG P31 -19 PANEL BATTERY 1 \ OO ff C, AND ST RD "DR— M'CH3R" :R CABINETS -MFCI4 AIIKW sr .i Viral _. SWITCH GEAR 155 0 (FRONT) �■ P31 -1 P31 -12 HP31- 32,34,3 P31 -19 P31 -6 P31 -4 ©■ HP -26,28 3r� "RTU3- "RTU3- 3 " "RTU3 -2" "RTU3 -1 ❑ ❑ ❑ ❑ ❑ ❑ "RTU3- "RTU5- 6 " "RTU5- 8 " "RTU5 -1 P31 -2 P31 -19 PANEL "HP31" DISC SW "DS -HP3" ' DISC SW "DS -P3" ❑XFMR "XFR-P3" PANEL "P31" mom P31 -19 0 —1 0 (FRONT) (FRONT) „ " "CAC3 -1 "DIST BD "DB- UPSBP3" ❑ CAC3-2 m "CAC3c§- rRONI� SCALE: 1/8"=1'-0" NORTH REVIEWED F R COMPLIANCE ITH NFPA70 -NE JUN 01 2010 City of Tukwila BUILDING DIVISION P31 -8 P31 -8 NOTES 0 BMS CONTROL PANEL CONNECT TO CIRCUIT SHOWN. PROVIDE DEDICATED NEUTRAL. ® RELOCATE (2) BMS FAN CONTROL PANELS AND (2) 120 MANUAL MOTOR STARTERS TO ADJACENT WALL TO ALLOW NEW DOOR INSTALLATION. INSTALL BOXES AND EXTEND WIRING AS REQUIRED TO ACCOMMODATE NEW INSTALLATION 03 CONNECT TO ENGINE JACKET WATER HEATER. ® GENERATOR BATTERY CHARGER, CONNECT CIRCUIT SHOWN. Q5 FUEL OIL PUMP CONTROL PANEL. EXTEND 120V CIRCUITS TO DAY TANK PUMPS AS REQUIRED. © PROVIDE 18 CIRCUIT 120V PANEL BOARD WITH (18) 20A, 1P BREAKERS. ® CONNECT TO BREAKER TRANSFER CONTROLLER. REVISION NO � EL1O- ciTVO�u► MAY `10 2010 PERMIT CENTER M 0 M 0 M Q 1— J 1-- Q 877.THE.PNAP www.internap.conn Q J Y o0 Z O) O o_ Mop 0 I U V) 0 r�N(1, LL 0 �0000O a W 0 o W (!) N > (o m � � a) � Et D W M D i— 2 410 E 0 9 Oc H u) 0 me. J = J co Q V t! 3 v / Q N U a ao W<0 C/) W CV Q = w . c� < MI— 1-- Z Mom ti co 0) 0 N 1- 0 w 0 0 ISSUED / REVISED DATE CD SET 03/08/10 REV 10 03/30/10 ESI 2 n 04/30/10 $$$DESIGN$SPECIFICATION$$$$$$ $'.$DATE$$'.' $TIME COPYRIGHT O 2008 CALLISON 1ST FLOOR ENGLARGED POWER PLAN E114 OO O ST RD "DR— M'CH3R" DIST 11ID "DR -MFCI4 —1 0 (FRONT) (FRONT) „ " "CAC3 -1 "DIST BD "DB- UPSBP3" ❑ CAC3-2 m "CAC3c§- rRONI� SCALE: 1/8"=1'-0" NORTH REVIEWED F R COMPLIANCE ITH NFPA70 -NE JUN 01 2010 City of Tukwila BUILDING DIVISION P31 -8 P31 -8 NOTES 0 BMS CONTROL PANEL CONNECT TO CIRCUIT SHOWN. PROVIDE DEDICATED NEUTRAL. ® RELOCATE (2) BMS FAN CONTROL PANELS AND (2) 120 MANUAL MOTOR STARTERS TO ADJACENT WALL TO ALLOW NEW DOOR INSTALLATION. INSTALL BOXES AND EXTEND WIRING AS REQUIRED TO ACCOMMODATE NEW INSTALLATION 03 CONNECT TO ENGINE JACKET WATER HEATER. ® GENERATOR BATTERY CHARGER, CONNECT CIRCUIT SHOWN. Q5 FUEL OIL PUMP CONTROL PANEL. EXTEND 120V CIRCUITS TO DAY TANK PUMPS AS REQUIRED. © PROVIDE 18 CIRCUIT 120V PANEL BOARD WITH (18) 20A, 1P BREAKERS. ® CONNECT TO BREAKER TRANSFER CONTROLLER. REVISION NO � EL1O- ciTVO�u► MAY `10 2010 PERMIT CENTER M 0 M 0 M Q 1— J 1-- Q 877.THE.PNAP www.internap.conn Q J Y o0 Z O) O o_ Mop 0 I U V) 0 r�N(1, LL 0 �0000O a W 0 o W (!) N > (o m � � a) � Et D W M D i— 2 410 E 0 9 Oc H u) 0 me. J = J co Q V t! 3 v / Q N U a ao W<0 C/) W CV Q = w . c� < MI— 1-- Z Mom ti co 0) 0 N 1- 0 w 0 0 ISSUED / REVISED DATE CD SET 03/08/10 REV 10 03/30/10 ESI 2 n 04/30/10 $$$DESIGN$SPECIFICATION$$$$$$ $'.$DATE$$'.' $TIME COPYRIGHT O 2008 CALLISON 1ST FLOOR ENGLARGED POWER PLAN E114 10 _ �, w- ....y.Ili 0 it ii 11111 111111111111• 1111111111111011 (FRONT) USS -1 2500KVA XFMR. #1 600A 26.4KV HV SWITCH (FRONT) GEN ROOM bypass ups ups IN 'UT SWBD. input cab 112 3/4 ats (FRONT) El El El GEN ROOM bypass ups ups IN 'UT SWBD. input cab 112 3/4 ats (FRONT) 1!'■ [S2'� mod ctrl � (FRONT) (FRONT) (FRONT) ��1 _ I puma ui.i.i. (FRONT) USS -2 2500KVA XFMR. #1 600A 26.4KV HV SWITCH UPS /AC -1 UPS MOD -1 UPS MOD -2 BATTERY -1 ATTERY -2 S /AC-4 RMINATION BUS (FRONT) L_j FRONT) (FRONT) (FRONT) (FRONT) UPS MOD-3 UPS MOD-4 W I P •-- 1—. MINII■I■ Nli1 11 1--- 1111111111111111111111•111111111 (FRONT) FRONT (FRONT) BATTERY -4 (FRONT) (FRONT) ATS #1 ATS #3 W/ BYPASS SERVIcI:E SWBDY/1 ats I tie 1 ats main -1 main -2 UPS ROOM 1 01 o -� 6d 4 6d 6d 4 T L31 -4,6 ��\ ,---- HH- - -- 4 6b ,.- 4 6b 1 b T�--- HI+ - -- GENERAL NOTES 1. SEE SHEET E122 FOR FIXTURE SCHEDULE. 2. MOUNT ALL FIXTURES AT +10' AFF. MOUNT FIXTURE TO CHANNEL SUPPORTED FROM STRUCTURE. PROVIDE SWAY CABLE TO PREVENT MOVEMENT. 3. FIXTURES SHOWN AS NIGHT LIGHT SHALL BE UNSWITCHED. PROVIDE DEDICATED NEUTRAL FOR CIRCUIT. 4. SWITCHED FIXTURES SHALL BE CIRCUITED AS SHOWN ON DETAIL 2/E122 5. SET OCCUPANCY SENSORS FOR 30 MINUTE TIME OFF. COMMISSION LIGHTING CONTROL PER WASHINGTON STATE NON RESIDENTIAL ENERGY CODE 1513.7. 1ST FLOOR LIGHTING PLAN SCALE: 1 /8 " =1' -0" NORTH REVIEUUD FOR WITH NFPA 70 -NEC E JUN 01 2010 City of Tukwila BUILDING DIVISION REVISION MO*t_ CfTYOCF'RIKVNLA MAY "T 0 2010 PERMIT CENTER 877.THE.PNAP www.internap.com • E Z O U 0 p 0 y o J J = a J M Q V U W lea Z a III 2 V� cu v U eLao 'Q = F- -c Fu. .'- a �WN� o< w 0 a (n ICC < ce w W M ~ z 0 0 ISSUED / REVISED DATE CD SET 03/08/10 REV 1A 03/30/10 ESI 2 /2\ 04/30/10 $$$DESIGN$SPECI FICATION$T$$$$$$$$$$$ $DATE$$$$ $TIME COPYRIGHT © 2008 CALLISON 1ST FLOOR LIGHTING PLAN E121 III 1!'■ [S2'� mod ctrl � (FRONT) (FRONT) (FRONT) ��1 _ I puma ui.i.i. (FRONT) USS -2 2500KVA XFMR. #1 600A 26.4KV HV SWITCH UPS /AC -1 UPS MOD -1 UPS MOD -2 BATTERY -1 ATTERY -2 S /AC-4 RMINATION BUS (FRONT) L_j FRONT) (FRONT) (FRONT) (FRONT) UPS MOD-3 UPS MOD-4 W I P •-- 1—. MINII■I■ Nli1 11 1--- 1111111111111111111111•111111111 (FRONT) FRONT (FRONT) BATTERY -4 (FRONT) (FRONT) ATS #1 ATS #3 W/ BYPASS SERVIcI:E SWBDY/1 ats I tie 1 ats main -1 main -2 UPS ROOM 1 01 o -� 6d 4 6d 6d 4 T L31 -4,6 ��\ ,---- HH- - -- 4 6b ,.- 4 6b 1 b T�--- HI+ - -- GENERAL NOTES 1. SEE SHEET E122 FOR FIXTURE SCHEDULE. 2. MOUNT ALL FIXTURES AT +10' AFF. MOUNT FIXTURE TO CHANNEL SUPPORTED FROM STRUCTURE. PROVIDE SWAY CABLE TO PREVENT MOVEMENT. 3. FIXTURES SHOWN AS NIGHT LIGHT SHALL BE UNSWITCHED. PROVIDE DEDICATED NEUTRAL FOR CIRCUIT. 4. SWITCHED FIXTURES SHALL BE CIRCUITED AS SHOWN ON DETAIL 2/E122 5. SET OCCUPANCY SENSORS FOR 30 MINUTE TIME OFF. COMMISSION LIGHTING CONTROL PER WASHINGTON STATE NON RESIDENTIAL ENERGY CODE 1513.7. 1ST FLOOR LIGHTING PLAN SCALE: 1 /8 " =1' -0" NORTH REVIEUUD FOR WITH NFPA 70 -NEC E JUN 01 2010 City of Tukwila BUILDING DIVISION REVISION MO*t_ CfTYOCF'RIKVNLA MAY "T 0 2010 PERMIT CENTER 877.THE.PNAP www.internap.com • E Z O U 0 p 0 y o J J = a J M Q V U W lea Z a III 2 V� cu v U eLao 'Q = F- -c Fu. .'- a �WN� o< w 0 a (n ICC < ce w W M ~ z 0 0 ISSUED / REVISED DATE CD SET 03/08/10 REV 1A 03/30/10 ESI 2 /2\ 04/30/10 $$$DESIGN$SPECI FICATION$T$$$$$$$$$$$ $DATE$$$$ $TIME COPYRIGHT © 2008 CALLISON 1ST FLOOR LIGHTING PLAN E121 D 4c 10 D D D III 2a 2a VIII VII 1 • I • im. . �T� Nu . •iu I_ ° 0 ■--�] D ° u lill 2a 2a �1 6a 0 N� 1 1 MI 111111111111111111111111111111111 rfm.,..11...ormas. ■- °- °-� ° D ■ 2b 2b �� 2b 2b 111111111111EM " '�,�1� KIIIPIIIIIIIM 111M111111111 IIIIIIMMAkIIIIIIIMIIIIIIM 1 D 2b O 2b D 2b i'MI 2b 1 2b MI 111111111111111111111111i ammrt's 11111111111110111 IEEE D IIIIIIIIIIIIMMII -MIEN MN IIIIIIIIIIIIIIIIIIIIIMIIIIIIIIIII o MIN 0 — MN 1- 4c all 411111111111 NM= Elf NMI MEN MI 1111111111111111111111111111111111111111 11•1111M NMI IIIIIIIIIIIIIIIIIIIIIIIIIINBIMIIII _III ■ • • • 7 D 2b -- D 2b 0 ■ ••� • n 0 mrilwi.111111111111111111 111ImI- -- 1IU- -- • I uI 111■11 1111'".. iririi1ii " 'iii 0 1:16b Ma ■ 3 116b itluiiiIi4 Iii INIERKI Irv: Am iii••.iI IDI i scau-,..•• El .....a, 6b D 4c 1 FFFF�'1c ���FF•FF» viii■ ■■ iiii■ ■ 0 En •�•'•_ I FFF•- F•F�'!*FFF•FF• -F 6c 6c 6c ■ �U r __ MIL 1111111Mmumnigaitunfili isammommuiLiaii mum ME II ■ ,r 3 ❑ iimrisignewritatisiisign 6c 6c ,,,,,,✓ __ -m ■■ wim ■ El • 1 : i� • • -i • ■ 1 4c — 111111111111111111 1 aillillallil II III III 11111111116 mow.. O D 4c I 4c 111— II 1111111111111 _•] •ii ■m7 °r ❑°i il1■'■.Ii11111 -MI "11111111 1 ii•1r1111M111� �� � IiJ • � ° m� ./ E■ 1111111111111111 1 ®� —11111111 ���IN ir' •iii.----N_w�- mom • D D l 1 4d 4d II 1111111111111111111111 11111111111111 0111111111111 D ❑ 4e 4e IMIll mu mu. ••••••=w,„ , Jill IIII III 011E IN cim • Imompsicarami•mmin IN. Elm IR Will11111111,A1111111111111 HMS 1® i�MM'r'r'�!A w.._ 0 D D D ■ 4e - 4e - 4e 1 I :. ......... -. 1 D 4c 3 Ell MEM i• Whit • D 8d D 8d • III MI IIIIIIIIIIIINNnmIl MIME impuommusinumninmo II D Mil • 11.11 • IIMPIN 1111101111111MICEI MAN __ti�..0 ■■ iu•ii e r - DN. STAR #4 4e 0 4e III o ID o. o ae s rr D I© D D 8d Sd 8d MEE IMO= 811.1 D MIR Mill 11111111111_11115111161111F--- 1111111MMI 1 0 0 � • D 8e 8e ❑ 3 8e ymelann.,m..mgm Ohl �i'uiri i `�rdaii �. . 0 7% +rrrr .� M� 3EPAil Be — FF•FF•FFF•�•- -EPEE• FFFF■ F> — �Ii11�11riOr111 ■ �■ ■IA 8e D O 8d 8d • L 10.1 11411p1 • 1 MIN 1 D 8e • �� D tiA�■ Irair mom 1 11111 ° 1 Se 8e 0 Be O LI 1 1 Fl ■1� REVIEWED FOR COMPLIANCE WITH NFPA 70 - NEC JUN 01 2010 City of Tukwila BUILDING DIVISION LIGHTING FIXTURE SCHEDULE SYMBOL LABEL DESCRIPTION MANUFACTURER # BALLAST ACCESSORIES LAMPS QTY /W /TYPE /COLOR MANUFACTURER FIXTURE VOLTAGE INPUT WATTS 2'x4' 3 LAMP FLUORESCENT FIXTURE WITH ACRYLIC PRISMATIC LENS 2 j g U ELECTRONIC -- 3 F32T8 3500K 277 V 87 D 0 FRIES 0 2'x4' 3 LAMP FLUORESCENT FIXTURE WITH ACRYLIC PRISMATIC LENS AND EMERGENCY BALLAST COLUMBIA JT8 SERIES W11-1 EL141 BALLAST ELECTRONIC EMERGENCY BATTERY PACK 3 F32T8 3500K 277 V 87 ■ © Al 2'x2' 2 LAMP FLUORESCENT FIXTURE WITH ACRYLIC PRISMATIC LENS JT8 SERIES ELECTRONIC -- 2 FB32T8 U6 3500K 277 V 58 D Al 2'x2' 2 LAMP FLUORESCENT FlXTURE ACRYLIC PRISMATIC8 LENS AND EMERGENCY BALLAST COLUMBIA SERIES WITH EL 141 BALLAST ELECTRONIC EMERGENCY BATTERY PACK 2 FB32T8 U6 3500K 277 V 58 • © •-❑ D HI TABLE � CONDUIT MOUNTING WITH PHOTOCELL CONTROL UBBELL RG SERIES REACTOR HIGH POWER FACTOR PHOTO CELL KIT 70W HPS 120 85 w D 4' 2 LAMP FLUORESCENT STRIP LIGHT FIXTURE WITH TUBE GUARD COLUMBIA CS SERIES ELECTRONIC -- 3 F32T8 3500K 277 V 58 I—ei D 4' 2 LAMP FLUORESCENT STRIP LIGHT FIXTURE WITH TUBE GUARD AND EMERGENCY BALLAST COLUMBIA GS- SERIES TH EL141 BALLAST ELECTRONIC EMERGENCY BATTERY PACK 3 F32T8 3500K 277 V 58 I-01 Q ® EXIT LIGHT WITH LED LAMPS HUBBELL RIES LX SE __ NI CAD BATTERY BACKUP LED 277 V 0.66 0 GENERAL NOTES 1. ALL LIGH11NG CIRCUITING SHALL BE ROUTED ABOVE CEILING IN CONDUIT. 2. ALL LIGHTING FIXTURES SHALL BE CIRCUITED TO PANEL L33. 3. FIXTURES SHOWN AS NIGHT LIGHT SHALL BE UNSWITCHED. PROVIDE DEDICATED NEUTRAL FOR EACH CIRCUIT.' 4. SWITCHED FIXTURES SHALL BE CIRCUITED AS SHOWN IN DIAGRAM 2/E122 5. OCCUPANCY SENSORS SHALL BE SET FOR 30 MINUTE TIME DELAY OFF. COMMISSION LIGHTING CONTROL SYSTEM PER WASHINGTON STATE NON RESIDENTIAL ENGERGY CODE 1513.7 3RD FLOOR LIGHTING PLAN SCALE: 1 /8" =1' -0" NORTHi MANUAL OFF LIGHT SWITCH OCCUPANCY SENSOR POWER PACK AND SWITCH RELAY TO ADDIIIO ^OCC SENSORS TO ADDITIONAL FIXTURES ON SAME SWITCH CIRCUIT AND SWITCH ID X= CIRCUIT NUMBER PANEL L33 y= SWITCH CONTROL TO ADDITIONAL SIMTCHES ON SAME CIRCUIT LTG CONTROL WIRING DIAGRAM NO SCALE REVISION N0.1 LlO-O 157 ciTI,SPITHILA MAY "i o 2010 PERMIT CENTER 250 WILLIAMS ST., SUITE M -11 M 0 o n. M ° Q Q °z N- (.9 O) a - NW < 0 I— co F- Q•ti or. H 't c0 <C F- LL www.internap.com ; 00 O) O o_ 000 In Io W 0 InN(n • I O Q p nen > rn co OD woCON_ (/) z —Q D Oo wHZct wMDi: F g WRCGS, WAS4I. P ar �, 46586 • T" 0 H 1 1 u INTERGATE EAST CAMPUS 0 ISSUED / REVISED DATE CD SET 03/08/10 REV 10 03/30/10 ESI 2 04/30/10 $$DESIGN$SPECIFICATION$$$$$$$$ $$$DATE$$$$ $TIME COPYRIGHT O 2008 CALLISON 3RD FLOOR LIGHTING PLAN LTG FIXTURE SCHED E122 1.0 11 IMINIP11".1-"..' l'il - imwi 111011.- :: 7414111r INI III 1u�- MI •:• ■1111 IIIA MIN ■I■ MINIM (FRONT) EXISTING GROUND IMAM ■Itil�iN ■MINI■ IIMIM 8. 1111W Apepii. .i111.14%,_ I ill 1.11111111111 ML�i�I ■Itil ■Ir 1111111•1111111111111111 (FRONT) ATS #1 II3US "GB-GEN GEN. PARALLELING SWGR. TERMINATION BUS (FRONT) (FRONT) ATS #3 W/ BYPASS TO GB-GEN1 USS -1 2500KVA XFMR. #1 600A 26.4KV HV SWITCH GEN ROOM USS -2 2500KVA XFMR. #1 (FRONT) (FRONT) 600A 26.4KV HV SWITCH Ny UPS /AC -1 ■ ■'❑ bypass ups up IN 'UT SWBD. input cab 1 /2 3/4 ats (FRONT) (FRONT) UPS MOD -1 BATTERY -1 FRONT) (FRONT) (FRONT) UIIINGS� SWBD #1 ats an•1 a ❑�GC� 1 rr UPS MOD-3 (FRONT) I�2 1 mod ctrl S.S. • ��, utput (FRONT) UPS MOD -2 ,ATTERY -2 (FRONT) (FRONT) UPS MOD-4 BATTERY-3 (FRONT) S /AC-4 BATTERY -4 (FRONT) UPS ROOM REVIEWED FOR COMPLIANCE WITH NFPA70 -NEC 877.THE.PNAP www.internap.com TO GB -GEN3 )- 6ROUN0- BUUSr "GB -GEN 3" GROUND BUS "GB -USS3" r JUN 01 2010 City of Tukwila BUILDING DIVISION h :L0 GB -GEN3 TO GB -GEN3 TO BLDG STEEL TO GB -GEN3 TO BLDG STEEL GEN ROOM TO GB -GEN3 TO BLDG STEEL TO BLDG STEEL A TO GB -USS3 UNIT SUBSTATION "US; -3" � PHASE -��. TO GB -USS3 'I Chi v TO GB -USS3 TO GB -USS3 SWITCH GEAR < I (� I TO GB -USS3 v -MEC ROUND BUS "GB -UPS3" RN UPS /AC -1 ■ ■'❑ bypass ups up IN 'UT SWBD. input cab 1 /2 3/4 ats (FRONT) (FRONT) UPS MOD -1 BATTERY -1 FRONT) (FRONT) (FRONT) UIIINGS� SWBD #1 ats an•1 a ❑�GC� 1 rr UPS MOD-3 (FRONT) I�2 1 mod ctrl S.S. • ��, utput (FRONT) UPS MOD -2 ,ATTERY -2 (FRONT) (FRONT) UPS MOD-4 BATTERY-3 (FRONT) S /AC-4 BATTERY -4 (FRONT) UPS ROOM REVIEWED FOR COMPLIANCE WITH NFPA70 -NEC 877.THE.PNAP www.internap.com TO GB -GEN3 )- 6ROUN0- BUUSr "GB -GEN 3" GROUND BUS "GB -USS3" r JUN 01 2010 City of Tukwila BUILDING DIVISION h :L0 GB -GEN3 TO GB -GEN3 TO BLDG STEEL TO GB -GEN3 TO BLDG STEEL GEN ROOM TO GB -GEN3 TO BLDG STEEL TO BLDG STEEL A TO GB -USS3 UNIT SUBSTATION "US; -3" � PHASE -��. TO GB -USS3 'I Chi v TO GB -USS3 TO GB -USS3 SWITCH GEAR < I (� I TO GB -USS3 v -MEC ROUND BUS "GB -UPS3" BATTERY 14 BD S:� UPS 0 TP�7_J�,.�u! 0 GB -UPS3 IA PS 10' TO GB -GEN3 / TO BUILDING STEEL BATTERY UPS MOD 3 I/Q UPS MOD 2 ATTERY 2 % `_ \ TO GB-UPS3 TO GB -U�S3 UPS MOD 4 BATTERY 4 TO GB -SG3 TO BLDG STEEL PANEL L31 L3 DIS SW 1.3 PANEL HP3 DIS SW HP3 GROUND BUS "GB -SG3" TO GBUPS SWITCH GEAR BLDG STEEL DIS SW P3 XFM P3 PANEL P31 GENERATOF SWITCHGEA TO GB-UPS3 TO GB-UPS v TO GB -SG3 113-4 RTU3 -3 RTU3 -2 RTU3 -1 RTU3 -5 RTU5 -6 RTU5 -8 61TU5 -10 DE -MECH DB- MECH3A� 0 GB -SG3 -UPSB TO GB -SG3 GROUND CONDUCTOR SCHEDULE SYMBOL CONDUCTOR SIZE TYPE ® BC #2/0 AWG SRG BC 500 KCMIL, 1 -l�" C SBC © BC #2 AWG, j" C SBC G4 BC #4/0 AWG, 1" C GEC G5 BC #6 AWG, )¢" C GEC G6 BC #2 AWG, X" C GEC © BC #2 AWG," C SGE G8 G9 ABBREVIAII NS BC BARE COPPER GEC GROUNDING ELECTRODE CONDUCTOR IGC INSULATED GROUND CONDUCTOR SBC SUPPLEMENTARY BONDING CONDUCTOR SGE SUPPLEMENTARY GROUNDING ELECTRODE CONDUCTOR SRG SIGNAL REFERENCE GRID STBC SOLID TINNED BARE COPPER GENERAL NOTES 1. ALL CONNECTIONS AT GROUND BUS SHALL BE MADE USING TWO HOLE, LONG BARREL COMPRESSION LUG WITH INSPECTION HOLE. 2. ALL CONNECTIONS TO BUILDING STEEL SHALL BE MADE WITH EXOTHERMIC WELD. 3. WHERE AVAILABLE, USE TWO HOLE, LONG BARREL COMPRESSION LUG WITH INSPECTION HOLE TO MAKE MECHANICAL CONNECTION. • E 0 O c A 0 . 1 ▪ = ✓ co a" O (1) 0- 2 0 1- W < Cr) Li w °-a LLI 1-- z 0 0 ti co rn 0 N 4t 1-- U w 0 0 ISSUED / REVISE D CD SET DATE 03/08/10 03/30/10 04/30/10 1ST FLOOR GROUNDING PLAN SCALE: 1 /8 " =1' -0" NORTH $$$DESIGN$SPECI FICATION$$$$$$$$$$$$$ CITY OF TUKW!LA MAY 102010 PERMIT CENTER $$$DATE$$$$ $TIME COPYRIGHT © 2008 CALLISON 1ST FLOOR GROUNDING PLAN E131 RN BATTERY 14 BD S:� UPS 0 TP�7_J�,.�u! 0 GB -UPS3 IA PS 10' TO GB -GEN3 / TO BUILDING STEEL BATTERY UPS MOD 3 I/Q UPS MOD 2 ATTERY 2 % `_ \ TO GB-UPS3 TO GB -U�S3 UPS MOD 4 BATTERY 4 TO GB -SG3 TO BLDG STEEL PANEL L31 L3 DIS SW 1.3 PANEL HP3 DIS SW HP3 GROUND BUS "GB -SG3" TO GBUPS SWITCH GEAR BLDG STEEL DIS SW P3 XFM P3 PANEL P31 GENERATOF SWITCHGEA TO GB-UPS3 TO GB-UPS v TO GB -SG3 113-4 RTU3 -3 RTU3 -2 RTU3 -1 RTU3 -5 RTU5 -6 RTU5 -8 61TU5 -10 DE -MECH DB- MECH3A� 0 GB -SG3 -UPSB TO GB -SG3 GROUND CONDUCTOR SCHEDULE SYMBOL CONDUCTOR SIZE TYPE ® BC #2/0 AWG SRG BC 500 KCMIL, 1 -l�" C SBC © BC #2 AWG, j" C SBC G4 BC #4/0 AWG, 1" C GEC G5 BC #6 AWG, )¢" C GEC G6 BC #2 AWG, X" C GEC © BC #2 AWG," C SGE G8 G9 ABBREVIAII NS BC BARE COPPER GEC GROUNDING ELECTRODE CONDUCTOR IGC INSULATED GROUND CONDUCTOR SBC SUPPLEMENTARY BONDING CONDUCTOR SGE SUPPLEMENTARY GROUNDING ELECTRODE CONDUCTOR SRG SIGNAL REFERENCE GRID STBC SOLID TINNED BARE COPPER GENERAL NOTES 1. ALL CONNECTIONS AT GROUND BUS SHALL BE MADE USING TWO HOLE, LONG BARREL COMPRESSION LUG WITH INSPECTION HOLE. 2. ALL CONNECTIONS TO BUILDING STEEL SHALL BE MADE WITH EXOTHERMIC WELD. 3. WHERE AVAILABLE, USE TWO HOLE, LONG BARREL COMPRESSION LUG WITH INSPECTION HOLE TO MAKE MECHANICAL CONNECTION. • E 0 O c A 0 . 1 ▪ = ✓ co a" O (1) 0- 2 0 1- W < Cr) Li w °-a LLI 1-- z 0 0 ti co rn 0 N 4t 1-- U w 0 0 ISSUED / REVISE D CD SET DATE 03/08/10 03/30/10 04/30/10 1ST FLOOR GROUNDING PLAN SCALE: 1 /8 " =1' -0" NORTH $$$DESIGN$SPECI FICATION$$$$$$$$$$$$$ CITY OF TUKW!LA MAY 102010 PERMIT CENTER $$$DATE$$$$ $TIME COPYRIGHT © 2008 CALLISON 1ST FLOOR GROUNDING PLAN E131 C4_ 111 INII■MINII■INII■ wIIII NIII■IN,I ■inI ■I�iuIwu mri �■ o■ �■�iP�■uum ■pi mm i r _ lid► ia/►`Miir►�Eiiil/ ►�■�ilkini■1 NZ'�/►1i1�ii hli �■ : IIrol■iloIUINZiihlEia all btl 11131111111111111111111111111111111111111111111111111113111111111111111111111111111W 11113 ■■- .,__.-___.__■,I.___.- __.-__.._. ■IMI ►/ ■11► ■ ■►JI■I►■ ■11VA IIIMEa" Nri ■ ►1 I11, ■IIIMII i INIU aMI /P MEIVAIMI � r� rte■ r� r� r �■ r� r� ■'�r � .�� r� r �+■ ■>.- /�• -r�� r ■ ■1iiniiiiiin /iiiEN ►l�Ui�/11 r ►� ►hONME■ ►lV I/1 1 ■11 Mali► ■�i /►►�I EI II►l�i i�■Ih�iii11111�i i� RII IIIIICIIMIIIIIIMIIHIMIILIIMIKIIIIIKIIIIIRIIIIKIIIIIIIINIIKII IIMINISMIMMIMMIlliimilmikai.611 ■i1 ■r ►/■�WIIIM ■Ill MIW ■ ►/ ■� ►� ■II V I r V 1IINIr !II■IFII■IIPi_III► / ■�► /■ WI I►/ ■ ■ ►1Mil iii ■11iEi ■►\�iil■111Iai l / ►iinir iliZ ■►li �/1 11111 iEi1■ ►l EFINSH ANSI WAWA ANN ■ ■01■■0■ ■01 ■ ■11 ■ ■11 ■ ■11 ■11 ■ ■11 ■■ 1■■ I 1 X1111■ l 1 � ■11 1■■ 1 11334 13 ■�►/ u,/ ■.V/ ■.►1 ■. ►/■ ►A ■.,/ ■•�, ■•i/1 •II 1 ■irII �-_3sIV III ._ Mari �►/ IIS ■► 1ST /►1�UFNI�i ■ ►hlil ii■► O ►l�i�i/ ►\I iI idi /. 1 ■ ►\niim :. : G� i l�-M1 ►11i Bo i : I I r/1\ ■111 ■ ■11 ■■11 ■ ■C�1 ■ ■11 ■ ■1 ■ 11 ■ ■11 ■ ■11 ■ 1■01111■t��l■■11111 1 MIt�1 ■1 ■L�1 ■O■MI ■�U 11,11_■■► / ■ ■►■ ■ ■ ►/■ ■VAIN 1111► / ■ ■WINIM / ■ r irillit*WAWMfrairdirtrigrariff WIWI 1i�� !�rwA�l� /w���l�/ \11G�/ \� �ir! r`w�� � / \ �i���1. 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REVISION N0,1 �Uo-o l S"17 3RD FLOOR GROUNDING PLAN cmwFiEttEl&u► MAY o 2010 PERMIT CENTER SCALE: 1/8'1=11-0" NORTH ST., SUITE M -11 250 WILLIAMS O 0 of N 0 M 0 I– lL 8 www.internap.com c � ov viA4/14, :' A� 0�p 4 5 11101 )1 1 0 N J 0 0 Z" O c J cti 44 9 � 3 W 2 0 NTERGATE EAST CAMPUS co 0 N 1- U w ISSUED / REVISED CD SET REV 1 DATE 03/08/10 03/30/10 04/30/10 $$$DESIGN$SPECI FICATION$$$$$$$$ $$$DATE$'.',$ $TIME COPYRIGHT 0 2008 CALLISON 3RD FLOOR GROUNDING PLAN E132 10 DT -3 C MI i � ri ■I ■I■ 1I ■IAIr 1 I I, ■I^`I I (FRONT) USS -1 2500KVA XFMR. #1 600A 26.4KV HV SWITCH UP TO DB -UPS3A FOR SKRU CONTROL DT -2 0 0 (FRONT) GEN ROOM 150 0 (FRONT) UP TO DB -UPS3B FOR SKRU CONTROL 111 ■[11111 rlrl ■I1' ., I I f 1 I I DT -1 USS -2 2500KVA XFMR. #1 600A 26.4KV HV SWITCH (6) V" C.O. TO 3RD FLOOR ELECTRICAL ROOM FOR FUTURE PHASE 4 SKRU CONTROL, GEN START /STOP AND EPO -4 WIRING UPS /AC-1 EXISTING DOOR SECURITY PANEL EXISTING FIRE ALARM PANEL ■' * E c- PIR" , -U S��' w>,,Tommintii \ ups 1/2 0 upU 3/4 S IN \ VI 'i L1- input cab 1 \ 111 ■[11111 rlrl ■I1' ., I I f 1 I I DT -1 USS -2 2500KVA XFMR. #1 600A 26.4KV HV SWITCH (6) V" C.O. TO 3RD FLOOR ELECTRICAL ROOM FOR FUTURE PHASE 4 SKRU CONTROL, GEN START /STOP AND EPO -4 WIRING UPS /AC-1 EXISTING DOOR SECURITY PANEL EXISTING FIRE ALARM PANEL (FRONT) (FRONT) (FRONT) mod ■' * E PIR" , -U S��' w>,,Tommintii bypass ups 1/2 upU 3/4 S IN DUT SWBD. ats input cab (FRONT) (FRONT) (FRONT) mod ctrl s.s. I tilTil j11utput win (FRONT) 3i" C.O. TO DOOR SECURITY PANEL )¢" C.O. REX LOCATED ON INTERIOR SIDE OF DOOR )1" C.O. TO DOOR POSITION CONTACT REX )1" C.O. TO DOOR JAMB FOR DOOR LOCK OR STRIKE UPS MOD -1 UPS MOD -2 BATTERY -2 U . 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AT EACH CARD READER LOCATION PROVIDE BOXES AND CONDUIT SHOWN ON DETAIL 2/E141 ® " C TO TEL /DATA PULLBOX THIS FLOOR, (2) CAT5e CABLES IN CONDUIT TO PNAP EQUIPMENT ON 3RD FLOOR 0 )4" C TO TEL /DATA PULLBOX THIS FLOOR, (1) CAT5e CABLE IN CONDUIT TO PNAP EQUIPMENT ON 3RD FLOOR. ® 1 -r C TO PNAP EQUIPMENT ON 3RD FLOOR, ROUTE (8) CAT5e CABLES FROM OUTLETS IN CONDUIT. ® 2# 16, )¢ "C TO UPS OUTPUT/SS BOARD, RUN #23 -1, 23 -2, 23 -3, OR 23 -4. ® 4# 16, & (1) 2 PR SHIELDED CABLE BY UPS MFG ROUTED IN BATTERY CAB RUN # 16 -1, 17 -1 OR 16 -2, 17 -2 OR 16 -3, 17 -3 OR 16 -4, 17 -4. ®4# 16, VC, RUN # 21. ® 26 WIRE SHIELDED RIBBON CABLE, BY MFG, 1 "C, TO UPS OUTPUT /SS BOARD, RUN #18 -1, 18 -2, 18 -3, 10 (2) 4 WIRE TSP 4 C : MFG, RUN # 20 -1, 20-2, 20 -3, OR 20 -4. n cmr�n°nIn MAY `7 0 2010 PERMRCENTER Llt www.internap.com a Q 00 Z (3) c.:2 X000 V) 0 I)N(1) • LL 0 wo °N- u) > rn co cc) -u -< D OU ZZ� w cn ¢ 12 E 0 9 Oc A 0 J N J 0 v PHASE II INTERGATE EAST CAMPUS apco cts CD aCO s0) Q CV LO M ISSUED / REVISED DATE CD SET 03/08/10 REV 10 03/30/10 ESI 2 ^ 04/30/10 $$$ DESIGN ',SPECIFICATION$$$$$$'.$', '.$ $$' DATE '.$'.$ $TIME COPYRIGHT O 2008 CALLISON 1ST FLOOR SIGNAL PLAN E141 10 34n C.O. 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STAIR #4 ® 01 T ° DATA ROOM 301 MINIM 0 EPO EXISTING EPO CONTROL PANEL U LJ 0 0 w a_ > 0 0I 0 F- W 0�z Mal V -1 RP -3 EXISTING ELECTRICAL ROOM 1 0 0 0I- >< 0 0 N > < 0I n 0 CO 01 0 I- T 3 0 T KV 2B 302 300KVA T -1B 3DU "3E ❑ U U 0 ❑ 1 U V PNAP TEL /DATA EQUIPMENT LOCATION CONFIRM EXACT TERMINA11ON LOCATIONS WITH USER. 0 L 0 ❑ REWED COMPL NCE FOR H NFPA 70 NEC - JUN 0 1 1010 City of Tukwila BUILDING DIVISION REVStON N0:1 EXISTING SECURITY PANELS U u) 1 SCP 1 1 SCP 1 FACP XISIING FACP • UP ELIO-- b 1 S°*7 6%t STAIR #3 DN. ano n�nLn MAY 10 2010 PERMIT CENTER 3RD FLOOR SIGNAL/SECURITi PLAN $$$DESIGN$SPECI FICATION$$$$$$$$$$$$$ $$DATE$$$$ $TIME COPYRIGHT O NORTH U w O NM 3 , O M W �oo< Z cr) o z Q�- a LJJ Zc`oI- W Q.4- t- o � o-1�-o (V Q I- LL www.internap.com Q DD o o_ N o0 I° W o r�N(I) • LLICt O CgD C °N 8 \T/c O Er�WZZ m1o/W � � '�� OC ntov <D • CALLISON cu co 0 cu r .1■1Q CV r CC) LOU" M ISSUED / REVISED DATE CD SET 03/08/10 REV 1 03/30/10 ESI 2 04/30/10 2008 CALLISON 3RD FLOOR SIGNAL /SECURITY PLAN E142 10 PHENOLIC LABEL, WHITE LETTERS ON RED BACKGROUND M.H. 56" 1 EMERGENCY SHUTDOWN 1 EPO -# r :/ -7\ / POLYCARBONATE ALARMED COVER STI MODEL #1100R PROVIDE NUMBER PER PLAN REMOVABLE COTTER PIN, CHAIN ATTACHED 4." SQUARE STAINLESS STEEL PLATE FLUSH 120V, 10A, 2 POLE HEAVY DUTY, NEMA -1 PUSHBUTTOM ALLEN - BRADLEY TYPE 800H WITH #800H -N140 LOCKING COVER E.P.O. PUSH BUTTON DETAIL NO SCALE EPO -3 CONTROL PANEL 1OA 120V (EMERGENCY, NON UPS) MAINT. ARM TEST° R103 T R103 111-•-•-•0 �o ---•` o • 0 EPo 4-1—Epo° EPO .--o 0-- SYSTEM RESET EPO STATION WITH COVER AND KEY RELEASE PUSHBUTTON (TYP.) WIRING TERMINAL (TYP.) RR101 01 a R101 R103 oRo 01 R101 b UNLATCH LATCH 0 R0f02o LATCH 10 R102 UNLATCH lo a °I0-ab R102 11 0 0 DBUPS3A BKR SHUNT TRIP PDU 3A1 - 3A5 R1I 2 0 0 R102 II 10 TEST RELAY DBUPS3B BKR SHUNT TRIP PDU 3B1 - 3B5 0 0 DBMECH3A BKR SHUNT TRIP RTU 3 -1 TO 3 -5 R102 2 O 0 R102 • 11 DBMECH3B BKR SHUNT TRIP RTU 3 -1 TO 3 -5 0 0 SPARE R102 R102 0 If 0 0 If 0 FIRE SMOKE DAMPER EPO ACTIVATED POWER CIRCUIT ALARM TO BMS R102 o ,k' 0 SPARE R102 0 if 0 SPARE FOR EPO CABINET "EPO -4" PROVIDE CABINET AND INTERNAL DEVICES AND WIRING ONLY. EPO BUTTONS AND WIRING TO EXTERNAL DEVICES INSTALLED IN FUTURE. EPO CONTROL CABINET SCHEMATIC (TYPICAL) SCALE : NONE EPO POWER ON EPO ARMED EPO ACTIVATED EPO TEST MODE TEST OK EPO MAINT. MODE' SURFACE MOUNTED NEMA 1 RELAY CABINET, SIZE AS REQUIRED MOUNTING HEIGHT AT 5' -0" A.F.F. TO TOP MOMENTARY SPST PUSH BUTTON ARM E.P.O. ZONE CONTROL PANEL X TEST MAI NT EPO POWER ON EPO ARMED EPO MAINT. MODE' MODE SELECTOR SWITCH ra TEST OK ENGRAVED PHENOLIC NAMEPLATES (TYP.) SEQUENCE OF OPERATION rsi a EPO TEST MODE EPO ACTIVATED ZONE NAME PER SCHEMATIC HINGED FRONT COVER MODE SELECTOR SWITCH (KEY OPERATED) E.P.O. CONTROL PANEL DETAIL (TYPICAL) NO SCALE (PROVIDE EPO CONTROL PANEL FOR EACH ZONE) COORDINATE EXACT LOCATION IN THE FIELD. AN EMERGENCY POWER OFF (E.P.O.) SHALL BE PROVIDED FOR ALL COMPUTER EQUIPMENT AREAS. THE SYSTEM SHALL BE CONTROLLED FROM AN EPO CONTROL PANEL E.P.O. CONTROL PANEL 1. POWER TO THE ECP SHALL BE SINGLE PHASE 120 VAC PROVIDED FROM A STANDBY POWER SOURCE. A WHITE INCANDESCENT LIGHT ON THE ECP SHALL INDICATE POWER IS AVAILABLE. ALL COMPONENTS; RELAYS, PUSHBUTTONS, ROTARY SWITCHES, PILOT LIGHTS...SHALL BE INDUSTRIAL GRADE BY SQUARE D. OR ALLEN BRADLEY. PROVIDE CONTACTS ON RELAYS AS NEEDED PLUS TWO SPARES EACH (MINIMUM). 2. THE ECP SHALL BE CAPABLE OF OPERATING IN THREE MODES, "ARMED" 'TEST" AND "MAINTENANCE'. OPERATIONAL MODE SHALL BE SELECTED FROM A KEY OPERATED SELECTOR SWITCH. STATUS OF THE SWITCH POSITION SHALL BE REPORTED TO THE BMS SYSTEM. 0. ARMED MODE b. c. A WHITE INCANDESCENT LIGHT ON THE ECP SHALL ILLUMINATE WHEN THE ECP IS PLACED IN ARMED MODE. DEPRESSING AN E.P.O. STATION'S RED, PUSHBOTTON SWITCH SHALL CAUSE THE FOLLOWING: RED INCANDESCENT LIGHT(S) ON THE ECP SHALL ILLUMINATE INDICATING AN E.P.O. SWITCH HAS BEEN ACTIVATED AND AC /UPS UNITS HAVE BEEN SHUT DOWN. "THE E.P.O. ACTIVATED" RELAY SHALL BE ENERGIZED AND SHALL SEND A SIGNAL TO THE BUILDING MONITORING SYSTEM AND SHALL ENERGIZE THE ASSOCIATED SHUT DOWN RELAY(S) IN THE ECP PANEL. CONTACTS FROM THE HVAC AND UPS SHUT DOWN RELAYS WITHIN THE RELAY PANELS SHALL SERVE TO ACTIVATE THE AFFECTED ZONE'S REMOTE EPO CONTACTS WITHIN UPS UNITS AND AIR CONDITIONERS WHICH SERVE THE DATA CENTER. THE ECP'S RED INDICATOR LIGHT(S) SHALL REMAIN ACTIVE UNTIL ALL EPO PUSHBUTTONS HAVE BEEN RESTORED TO THEIR NORMAL STATE BY MEANS OF A KEY RELEASED MECHANISM AND THE ECP'S RESET PUSH BUTTON IS DEPRESSED. TEST MODE PLACING THE MODE SELECTOR SWITCH IN THE TEST POSITION SHALL CAUSE THE TEST RELAY TO ACTIVATE. THE ACTIVATION OF ALL TEST RELAYS SHALL CAUSE AN AMBER INCANDESCENT LIGHT ON THE ECP TO ILLUMINATE. WHEN THE ECP IS PLACED IN TEST MODE, ALL ASSOCIATED SHUNT TRIP FUNCTIONS ARE DISABLED BY MEANS OF TEST RELAYS, THIS MODE ALLOWS THE E.P.O. PUSHBUTTON STATIONS TO BE TESTED WITHOUT REMOVING POWER TO THE ZONE. WHEN AN E.P.O. STATION IS ACTIVATED. THE "E.P.O. ACTIVATED" RELAY SHALL BE ENERGIZED. THE T.P.O. ACTIVATED" RELAY SHALL SEND A SIGNAL TO THE BUILDING MONITORING SYSTEM AND SHALL ENERGIZE THE ASSOCIATED SHUT DOWN RELAY(S) IN THE ECP PANEL ALTHOUGH ON THE ECP SHALL BE ILLUMINATED BY THE SHUNT TRIP RELAY, INDICATING PROPER SYSTEM OPERATION (TEST OK). MAINTENANCE MODE A GREEN INCANDESCENT LIGHT ON THE ECP SHALL ILLUMINATE WHEN THE ECP IS PLACED IN MAINTENANCE MODE. WHEN THE ECP IS PLACED IN MAINTENANCE MODE, ALL E.P.O. STATIONS, SHUNT TRIP FUNCTIONS AND TEST FUNCTIONS ARE DISABLED. THIS MODE ALLOWS FOR SERVICE TO THE E.P.O. SYSTEM WITHOUT RISK OF ACCIDENTAL POWER LOSS TO THE ZONE. E.P.O. STATION 1. E.P.O. STATIONS SHALL BE LOCATED AS INDICATED ON THE PLANS. 2. E.P.O. STATIONS SHALL CONSIST OF THE FOLLOWING COMPONENTS: a. RED, PUSHBUTTON WITH NORMALLY OPENED CONTACTS. THE PUSHBUTTON SHALL LOCK IN THE DEPRESSED POSITION THE PUSHBUTTON SHALL BE RELEASED TO ITS NORMAL STATE BY MEANS OF A KEY RELEASE MECHANISM. b. HINGED PUSHBUTTON COVER WITH SAFETY PIN AND HINGED LEXAN COVER GUARD TO PROTECT PUSHBUTTON STATION FROM INCIDENTAL CONTACT BY PERSONNEL OR EQUPMENT. 3. EPO STATIONS SHALL BE LOCATED IN THE FIELD AS DIRECTED BY ENGINEER /OWNER. 4. PROVIDE "STOPPER II" COVER PLATES ON ALL STATIONS. MODEL STI- 1100 -Y (S.TI -PHONE 248 - 673 - 9898). REVIEWED FOR COMPLIANCE WITH JUN 0 2010 City of Tukwila BUILDING DIVISION DESIGN$S PECI FICATION$$$$$$$$$ REVtSION OL ELO-OIS1 $$$DATE$$$$ $TIME cnrRO�n° A MAY `10 2010 PERMIT CENTER COPYRIGHT O 2008 CALLISON 2 w I- D M o I- co O U) M O J < —1 I— co >7 Z d' 0 , O ID I- < LL www.internap.com J Y 00 Q CC cn 0 < M000 In I� W p I N (n • Ct goer CL w0CDNU - () >O) CID m LJ< D U U w°w Z Z m10� :0wIo:0l —J: Ot cnrocnao_ : • 2 co Q CO cD U EL co CO w Q o� CO w N Q Q H — < M 11.1 co z 0 0 ISSUED / REVISED DATE CD SET 03/08/10 REV 1 1 03/30/10 ESI 2 2 04/30/10 EPO DIAGRAM E501 MOUNTING 208/120 IN PDU PANEL PHASE 4 WIRE MAIN 3AI B 10,000 A.I.C. SYM BUS 225 A VOLTS 3 225 A VOLT AMPS DESCRIPTION R C L G m r o B R C R C R BO R r E � y r R C DESCRIPTION VOLT AMPS 0 A 0 B 0 C OA 0 B 0 C 2000 CABINET 7 2 30 1 A 2 30 2 4 4 CABINET 2000 2000 CABINET 7 2 30 3 B 4 30 2 4 4 CABINET 2000 1000 CABINET 8 1 20 5 C 6 20 1 4 4 CABINET 1000 2000 CABINET 7 2 30 7 A 8 30 2 CABINET 2000 2000 CABINET 7 2 30 9 B 10 30 2 CABINET 2000 1000 CABINET 7 1 20 11 C 12 20 1 CABINET 1000 2000 CABINET 2 2 30 13 A 14 30 2 CABINET 2000 2000 CABINET 2 30 15 B 16 30 2 CABINET 2000 1000 CABINET 1 20 17 C 18 20 1 CABINET 1000 2000 CABINET 7 2 30 19 A 20 30 2 CABINET 2000 2000 CABINET 2 30 21 B 22 30 2 CABINET 2000 1000 CABINET 1 20 23 C 24 20 1 CABINET 1000 2000 CABINET 2 30 25 A 26 30 2 CABINET 2000 2000 CABINET 2 30 27 B 28 30 2 CABINET 2000 1000 CABINET 1 20 29 C 30 20 1 CABINET 1000 6814 Spare 2 30 31 A 32 30 2 Spare 443 6814 Spare 2 30 33 B 34 30 2 Spare 443 6814 Spare 1 20 35 C 36 20 1 Spare 443 Spare 2 30 37 A 38 30 2 Spare 5768 Spare 2 30 39 B 40 30 2 Spare 5658 Spare 1 20 41 C 42 20 1 Spare 4694 10000 10000 5000 VA /LINE 10000 10000 5000 0 A= 20000 0 B= 20000 0 C= 10000 CONTINUOUS LOADS NON - CONTINUOUS LOADS 50000 x1.25= 62500 UP TO 10 kVA RECEPTACLES REMAINDER 10000 x1.00= x0.50= 10000 OTHER x1.00= 2600 1300 14420 14420 TOTAL DESIGN kVA= 63 TOTAL DESIGN AMPS= 173 OWNER FURNISHED EQEUIPMENT. TYPICAL FOR EACH "B" PANEL IN PDU'S. LOADS SHOWN ARE FOR BASIS OF DESIGN, BRANCH CIRCUITING FROM PDU TO FUTURE EQUIPMENT NOT IN CONTRACT. MOUNTING 208/120 IN PDU PANEL PHASE 4 WIRE MAIN 3AIC 10,000 A.I.C. SYM BUS 225 A VOLTS 3 225 A V O L T AMPS DESCRIPTION R C L G r O E B R C R C R B R r O E L G R C DESCRIPTION VOLT AMPS 0 A 0 B 0 C OA 0 B 0 C 2000 CABINET 7 2 30 1 A 2 30 2 4 4 CABINET 2000 2000 CABINET 7 2 30 3 B 4 30 2 4 4 CABINET 2000 1000 CABINET 8 1 20 5 C 6 20 1 4 4 CABINET 1000 2000 CABINET 7 2 30 7 A 8 30 2 CABINET 2000 2000 CABINET 7 2 30 9 B 10 30 2 CABINET 2000 1000 CABINET 7 1 20 11 C 12 20 1 CABINET 1000 2000 CABINET 2 2 30 13 A 14 30 2 CABINET 2000 2000 CABINET 2 30 15 B 16 30 2 CABINET 2000 1000 CABINET 1 20 17 C 18 20 1 CABINET 1000 2000 CABINET 7 2 30 19 A 20 30 2 CABINET 2000 2000 CABINET 2 30 21 B 22 30 2 CABINET 2000 1000 CABINET 1 20 23 C 24 20 1 CABINET 1000 2000 CABINET 2 30 25 A 26 30 2 CABINET 2000 2000 CABINET 2 30 27 B 28 30 2 CABINET 2000 1000 CABINET 1 20 29 C 30 20 1 CABINET 1000 6814 Spare 2 30 31 A 32 30 2 Spare 443 6814 Spare 2 30 33 B 34 30 2 Spare 443 6814 Spare 1 20 35 C 36 20 1 Spare 443 Spare 2 30 37 A 38 30 2 Spare 5768 Spare 2 30 39 B 40 30 2 Spare 5658 Spare 1 20 41 C 42 20 1 Spare 4694 10000 10000 5000 VA /LINE 10000 10000 5000 0 A= 20000 0 B= 20000 0 C= 10000 CONTINUOUS LOADS NON- CONTINUOUS LOADS 50000 x1.25= 62500 UP TO 10 kVA RECEPTACLES REMAINDER 10000 x1.00= x0.50= 10000 OTHER x1.00= 2600 1300 14420 14420 TOTAL DESIGN kVA= 63 TOTAL DESIGN AMPS = 173 OWNER FURNISHED EQUIPMENT. TYPICAL FOR EACH "C" PANEL IN PDU'S. LOADS SHOWN ARE FOR BASIS OF DESIGN, BRANCH CIRCUITING FROM PDU TO FUTURE EQUIPMENT NOT IN CONTRACT. MOUNTING 208/120 IN PDU PANEL PHASE 4 WIRE MAIN 3AID 10,000 A.I.C. SYM BUS 225 A VOLTS 3 225 A V O L T AMPS DESCRIPTION R C L G m r o B R C R C R B R r O E L G R C DESCRIPTION VOLT AMPS 0 A 0 B 0 C OA 0 B 0 C 2000 CABINET 7 2 30 1 A 2 30 2 4 4 CABINET 2000 2000 CABINET 7 2 30 3 B 4 30 2 4 4 CABINET 2000 1000 CABINET 8 1 20 5 C 6 20 1 4 4 CABINET 1000 2000 CABINET 7 2 30 7 A 8 30 2 CABINET 2000 2000 CABINET 7 2 30 9 B 10 30 2 CABINET 2000 1000 CABINET 7 1 20 11 C 12 20 1 CABINET 1000 2000 CABINET 2 2 30 13 A 14 30 2 CABINET 2000 2000 CABINET 2 30 15 B 16 30 2 CABINET 2000 1000 CABINET 1 20 17 C 18 20 1 CABINET 1000 2000 CABINET 7 2 30 19 A 20 30 2 CABINET 2000 2000 CABINET 2 30 21 B 22 30 2 CABINET 2000 1000 CABINET 1 20 23 C 24 20 1 CABINET 1000 2000 CABINET 2 30 25 A 26 30 2 CABINET 2000 2000 CABINET 2 30 27 B 28 30 2 CABINET 2000 1000 CABINET 1 20 29 C 30 20 1 CABINET 1000 6814 Spare 2 30 31 A 32 30 2 Spare 443 6814 Spare 2 30 33 B 34 30 2 Spare 443 6814 Spare 1 20 35 C 36 20 1 Spare 443 Spare 2 30 37 A 38 30 2 Spare 5768 Spare 2 30 39 B 40 30 2 Spare 5658 Spare 1 20 41 C 42 20 1 Spare 4694 10000 10000 5000 VA /LINE 10000 10000 5000 0 A= 20000 0 B= 20000 0 C= 10000 CONTINUOUS LOADS NON- CONTINUOUS LOADS 50000 x1.25= 62500 UP TO 10 kVA RECEPTACLES REMAINDER 10000 x1.00= x0.50= 10000 OTHER x1.00= 2600 1300 14420 14420 TOTAL DESIGN kVA= 63 TOTAL DESIGN AMPS= 173 OWNER FURNISHED EQUIPMENT. TYPICAL FOR EACH "D" PANEL IN PDU'S. LOADS SHOWN ARE FOR BASIS OF DESIGN, BRANCH CIRCUITING FROM PDU TO FUTURE EQUIPMENT NOT IN CONTRACT. MOUNTING 208/120 SURFACE PANEL PHASE 4 WERE MAIN P31 10,000 A.I.C. SYM BUS 225 A VOLTS 3 225 A V O L T AMPS DESCRIPTION R C L G r O E B R C R C R B R r O E L G R C DESCRIPTION VOLT AMPS 0 A 0 B 0 C O A 0 B 0 C 1200 SG1 BAT CHGR 7 1 20 1 A 2 20 1 4 4 BMS PANEL 100 1200 SG2 BAT CHGR 7 1 20 3 B 4 20 1 4 4 BMS PANEL 100 1200 SG3 BAT CHGR 8 1 20 5 C 6 20 1 4 4 BMS PANEL 100 100 BMS PANEL 7 1 20 7 A 8 20 1 FSD 600 100 BMS PANEL 7 1 20 9 B 10 20 1 SWGR BATCHGR 1200 1260 GEN /SWGR RM 7 1 20 11 C 12 20 1 SWGR BAT CHGR 1200 1200 DAY TANK PUMP 2 1 20 13 A 14 20 1 Spare 864 1200 DAY TANK PUMP 1 20 15 B 16 20 1 Spare 864 1200 DAY TANK PUMP 1 20 17 C 18 20 1 Spare 1000 1260 UPS /SWGR RM 7 1 20 19 A 20 20 1 Spare 2000 5000 CTRL PWR UPS 1 60 21 B 22 20 1 Spare 2000 1000 Spare 1 20 23 C 24 20 1 Spare 1000 2000 Spare 1 20 25 A 26 20 1 Spare 2000 2000 Spare 1 20 27 B 28 20 1 Spare 2000 1000 Spare 1 20 29 C 30 20 1 Spare 1000 6814 Spare 1 20 31 A 32 20 1 Spare 443 6814 Spare 1 20 33 B 34 20 1 Spare 443 6814 Spare 1 20 35 C 36 20 1 Spare 443 Spare 1 20 37 A 38 100 3 PANEL 'P33' 5768 Spare 1 20 39 B 40 - - Spare 5658 Spare 1 20 41 C 42 - - Spare 4694 3760 7500 3660 VA /LINE 6468 6958 5994 0 A= 10228 0 B= 14458 0 C= 9654 CONTINUOUS LOADS NON- CONTINUOUS LOADS 7320 x1.25= 9150 UP TO 10 kVA RECEPTACLES REMAINDER 10000 x1.00= x0.50= 10000 OTHER x1.00= 2600 1300 14420 14420 TOTAL DESIGN kVA= 35 TOTAL DESIGN AMPS= 97 MOUNTING 208/120 SURFACE PANEL PHASE 4 WIRE MAIN P33 10,000 A.I.C. SYM BUS 100 A VOLTS 3 L.O. V O L T AMPS DESCRIPTION R C L G r O E B R C R 7y n B R r O E L G R C DESCRIPTION VOLT AMPS 0 A 0 B 0 C 0A 0B 0C 1260 RM 336 7 1 20 1 A 2 20 1 4 4 ROOF REC /LTG 1060 1260 RM 336 7 1 20 3 B 4 20 1 4 4 ROOF REC /LTG 1060 1440 RM 336 8 1 20 5 C 6 20 1 4 4 ROOF REC /LTG 1060 1260 RM333 7 1 20 7 A 8 20 1 HUM/3 -1 864 1260 RM333 7 1 20 9 B 10 20 1 HUM/3 -4 864 1080 RM333 6 1 20 11 C 12 20 1 HUM/3 -5 864 360 RM 334/335 2 1 20 13 A 14 20 1 HUM/3 -2 864 250 EPO PANEL 1 20 15 B 16 20 1 HUM/3 -3 864 250 EPO PANEL 1 20 17 C 18 20 1 Spare 1000 100 BMS PANEL 1 20 19 A 20 20 1 Spare 2000 100 BMS PANEL 1 20 21 B 22 20 1 Spare 2000 1000 Spare 1 20 23 C 24 20 1 Spare 1000 2000 Spare 1 20 25 A 26 20 1 Spare 2000 2000 Spare 1 20 27 B 28 20 1 Spare 2000 1000 Spare 1 20 29 C 30 20 1 Spare 1000 6814 Spare 1 20 31 A 32 20 1 Spare 443 6814 Spare 1 20 33 B 34 20 1 Spare 443 6814 Spare 1 20 35 C 36 20 1 Spare 443 Spare 1 20 37 A 38 20 1 Spare 6379 Spare 1 20 39 B 40 20 1 Spare 4751 Spare 1 20 41 C 42 20 1 Spare 2320 2980 2870 2770 VA/LINE 2788 2788 1924 0 A= 5768 0 B= 5658 0 C= 4694 CONTINUOUS LOADS NON - CONTINUOUS LOADS 1220 x1.25= 1525 UP TO 10 kVA RECEPTACLES REMAINDER 10000 x1.00= x0.50= 10000 OTHER x1.06= 80 40 4820 4820 TOTAL DESIGN kVA= 16 TOTAL DESIGN AMPS= 45 MOUNTING 208/120 IN PDU PANEL PHASE 4 WIRE MAIN 3AIA 10,000 A.I.C. SYM BUS 225 A VOLTS 3 225 A V O L T AMPS DESCRIPTION R C L G r O E B R C R C R B R r O E L G R C DESCRIPTION VOLT AMPS 0 A 0 B 0 C OA 0 B 0 C 2000 CABINET 2 30 1 A 2 30 2 CABINET 2000 2000 CABINET 2 30 3 B 4 30 2 48 CABINET 2000 1000 CABINET 1 20 5 C 6 20 1 55 CABINET 1000 2000 CABINET 2 30 7 A 8 30 2 CABINET 2000 2000 CABINET 2 30 9 B 10 30 2 CABINET 2000 1000 CABINET 1 20 11 C 12 20 1 CABINET 1000 2000 CABINET 2 30 13 A 14 30 2 CABINET 2000 2000 CABINET 2 30 15 B 16 30 2 CABINET 2000 1000 CABINET 1 20 17 C 18 20 1 CABINET 1000 2000 CABINET 2 30 19 A 20 30 2 CABINET 2000 2000 CABINET 2 30 21 B 22 30 2 CABINET 2000 1000 CABINET 1 20 23 C 24 20 1 CABINET 1000 2000 CABINET 2 30 25 A 26 30 2 CABINET 2000 2000 CABINET 2 30 27 B 28 30 2 CABINET 2000 1000 CABINET 1 20 29 C 30 20 1 CABINET 1000 6814 Spare 2 30 31 A 32 30 2 Spare 443 6814 Spare 2 30 33 B 34 30 2 Spare 443 6814 Spare 1 20 35 C 36 20 1 Spare 443 Spare 2 30 37 A 38 30 2 Spare 6379 Spare 2 30 39 B 40 30 2 Spare 4751 Spare 1 20 41 C 42 20 1 Spare 2320 10000 10000 5000 VA /LINE 10000 10000 5000 0 A= 20000 0 B= 20000 0 C= 10000 CONTINUOUS LOADS NON - CONTINUOUS LOADS 50000 x1.25= 62500 UP TO 10 kVA RECEPTACLES REMAINDER x1.00= xO.5■= OTHER x1.00= 67578 67578 TOTAL DESIGN kVA= 63 TOTAL DESIGN AMPS= 173 OWNER FURNISHED EQUIPMENT. TYPICAL FOR EACH "A" PANEL IN PDU'S. LOADS SHOWN ARE FOR BASIS OF DESIGN, BRANCH CIRCUITING FROM PDU TO FUTURE EQUIPMENT NOT IN CONTRACT. MOUNTING 480/277 SURFACE PANEL PHASE 4 WIRE MAIN L31 14,000 A.I.C. SYM BUS 100 A VOLTS 3 100 A V O L T AMPS DESCRIPTION R C L G r O E B R C R C R B R r O E L G R C DESCRIPTION VOLT AMPS 0 A 0 B 0 C 0 A 0 B 0 C 2058 Spare 1 20 1 A 2 20 1 Spare 2378 2025 Spare 1 20 3 B 4 20 1 48 1st FLRNL 2736 3000 Spare 1 20 5 C 6 20 1 55 1stFLR LTG 3135 3000 Spare 1 20 7 A 8 20 1 Spare 1943 3000 Spare 1 20 9 B 10 20 1 Spare 942 3000 Spare 1 20 11 C 12 20 1 Spare 942 3000 Space - - 13 A 14 - - Space 3878 3000 Space - - 15 B 16 - - Space 3878 3000 Space - - 17 C 18 - - Space 3878 3000 Space - - 19 A 20 - - Space 3878 3000 Space - - 21 B 22 - - Space 3878 3000 Space - - 23 C 24 - - Space 3878 6814 Space - - 25 A 26 - - Space 443 6814 Space - - 27 B 28 - - Space 443 6814 Space - - 29 C 30 - - Space 443 6814 Space - - 31 A 32 - - Space 443 6814 Space - - 33 B 34 - - Space 443 6814 Space - - 35 C 36 - - Space 443 Space - - 37 A 38 100 3 PANEL 'L33' 6379 Space - - 39 B 40 - - Spare 4751 Space - - 41 C 42 - - Spare 2320 2058 2025 25628 VA /LINE 6379 7487 5455 0 A= 6379 0 B= 7487 0 C= 5455 CONTINUOUS LOADS NON- CONTINUOUS LOADS 19321 x1.25= 24151 UP TO 10 kVA RECEPTACLES REMAINDER x1.00= x0.50= OTHER x1.00 67578 67578 TOTAL DESIGN kVA= 24 TOTAL DESIGN AMPS= 29 MOUNTING 480/277 SURFACE PANEL PHASE 4 WIRE MAIN L33 14,000 A.I.C. SYM BUS 100 A VOLTS 3 L.O. V O L T AMPS DESCRIPTION R C L G r O E B R C R C R B R r O E L G R C DESCRIPTION VOLT AMPS 0 A 0 B 0 C 0A 0B OC 2058 RM 336 N L 1 20 1 A 2 20 1 RM 336 LTG 2378 2025 RM 334 N L 1 20 3 B 4 20 1 RM 336 LTG 2726 3000 Spare 1 20 5 C 6 20 1 RM 334 LTG 2320 3000 Spare 1 20 7 ,A 8 20 1 RM 334 LTG 1943 3000 Spare 1 20 9 B 10 20 1 Spare 942 3000 Spare 1 20 11 C 12 20 1 Spare 942 3000 Spare - - 13 A 14 - - Spare 3878 3000 Spare - - 15 B 16 - - Spare 3878 3000 Spare - - 17 C 18 - - Spare 3878 3000 Spare - - 19 A 20 - - Spare 3878 3000 Spare - - 21 B 22 - - Spare 3878 3000 Spare - - 23 C 24 - - Spare 3878 6814 Spare - - 25 A 26 - - Spare 443 6814 Spare - - 27 B 28 - - Spare 443 6814 Spare - - 29 C 30 - - Spare 443 6814 Spare - - 31 A 32 - - Spare 443 6814 Spare - - 33 B 34 - - Spare 443 6814 Spare - - 35 C 36 - - Spare 443 Spare - - 37 A 38 - - Spare Spare - - 39 B 40 - - Spare Spare - - 41 C 42 - - Spare 2058 2025 25628 VA /L1NE 4321 2726 2320 0 A= 6379 0 B= 4751 0 C= 2320 CONTINUOUS LOADS NON- CONTINUOUS LOADS 13450 x1.25= 16813 UP TO 10 kVA RECEPTACLES REMAINDER x1.00= x0.50= OTHER x1.00= 67578 67578 TOTAL DESIGN kVA= 17 TOTAL DESIGN AMPS= 20 MOUNTING 480/ SURFACE PANEL PHASE 3 WIRE MAIN HP31 30,000 A.I.C. SYM BUS 225 A VOLTS 3 L.O. V O L T AMPS DESCRIPTION R C L G r O E B R C R C R B R r O E L G R C DESCRIPTION VOLT AMPS 0 A 0 B 0 C 0A 0B 0C 3000 SG1 WTR HTR 2 20 1 A 2 20 3 TF /3T -1 942 3000 SG1 WTR HTR - - 3 B 4 - - 942 3000 SG1 WTR HTR 2 20 5 C 6 - - 942 3000 SG1 WTR HTR - - 7 A 8 20 3 TF /3T -2 942 3000 SG2 WTR HTR 2 20 9 B 10 - - 942 3000 SG2 WTR HTR - - 11 C 12 - - 942 3000 SG2 WTR HTR 2 20 13 A 14 20 3 TF /3U -1 3878 3000 SG2 WTR HTR - - 15 B 16 - - 3878 3000 SG3 WTR HTR 2 20 17 C 18 - - 3878 3000 SG3 WTR HTR - - 19 A 20 20 3 TF /3U -2 3878 3000 SG3 WTR HTR 2 20 21 B 22 - - 3878 3000 SG3 WTR HTR - - 23 C 24 - - 3878 6814 DC /3 -1 3 35 25 A 26 20 3 TF /S -1 443 6814 - - 27 B 28 - - 443 6814 - - 29 C 30 - - 443 6814 DC /3 -2 3 35 31 A 32 20 3 TF /S -2 443 6814 - - 33 B' 34 - - 443 6814 - - 35 C 36 - - 443 Spare 3 20 37 A 38 20 3 Spare Spare - - 39 B 40 - - Spare Spare - - 41 C 42 - - Spare 25628 25628 25628 VA /LINE 10526 10526 10526 0 A= 36154 0 B= 36154 0 C= 36154 CONTINUOUS LOADS NON - CONTINUOUS LOADS 40885 x1.25= 51107 UP TO 10 kVA RECEPTACLES REMAINDER x1.00= x0.50= OTHER x1.00= 67578 67578 TOTAL DESIGN kVA= 1 19 TOTAL DESIGN AMPS= 143 REVISION N0.1 qLOOtS? $$$DESIGN$SPECI FICATION$$$$$$$$$$$$$ crrvo&n MAY 10 2010 PERMIT CENTER $$$DATE$$$$ $TIME COPYRIGHT© 2008 CALLISON �r Z yw t 3 W • co aca 2 J gt W O N 877.THE.PNAP www.internap.com -I Y 00 a Z O 0_ to 00 OD 0 Io W o �NVI • o ri 0 OQ00° W w o° N (n > (3) c0 m zw��< D O V W Z Z� • pp��HgO� I`r9 • z 0 ..1 J CALL /SON www.callison.com k W CD ilia D Z a W 2 0co u Q co v.- 0 a co Q = F- -c 0) imill IRE U)WN> O < r =w .cv Q Z IX ceM� W 01 k Z _ Z 0 0 ti co 0 N 0 1- U w 0_ ISSUED / REVISED DATE CD SET REV 1 ESI 2 03/08/10 03/30/10 04/30/10 PANEL SCHEDULES E600 10 DISTRIBUTION BOARD MECH3B - LOAD SUMMARY TAG kVA A Load Cont Rec Other Total PANEL HP31(REDUNDANT) 866.7 Rec 1#1/0 AWG 866.7 1043 PANEL P31 (REDUNDANT) 866.7 40.9 1 #500 KCMIL 866.7 1043 PANEL L31 (REDUNDANT) 866.7 143 PANEL P31 866.7 1043 RTU 3 -1 (REDUNDANT) 113.0 14.4 34.9 113.0 136 COMP CIRCUIT 1 240.0 19.3 1 #250 KCMIL 240.0 289 COMP CIRCUIT 2 240.0 29 RTU 3 -1 (SINGLE POINT FEED) 240.0 289 CONDENSER FANS 240.0 - 1 #3/0 AWG 240.0 kVA SUPPLY FAN 2,713 kVA Total 2,713 kVA RETURN FAN 3 #350 KCMIL kVA Total 2713.2 kVA CONTROL CIRCUIT 3 #250 KCMIL 86.8 94.0 F -450 113 RTU 3 -2 (REDUNDANT) 2,132 - 1 #2 AWG 2,132 kVA RTU 3 -3 (REDUNDANT) 3 #500 KCMIL kVA Total 2131.6 kVA RTU 3 -4 (REDUNDANT) 3 #350 KCMIL 71.5 89.3 F -225 107 RTU 3 -5 (REDUNDANT) 3 #410 AWG - 1 #4 AWG F -225N 49.0 CAC 3 -1 (REDUNDANT) 3 #410 AWG 74 CONTROL CIRCUIT F -125 1 CAC 3 -2 (REDUNDANT) 3 #1 AWG 2.0 2.0 F -100 2 CAC 3 -3 (REDUNDANT) 3 #2 AWG - 1 #8 AWG F -100N 316.0 CAC 3 -4 (REDUNDANT) 3 #2 AWG 402 RTU 3 -3 F- 400000 10 RTU 5 -6 (REDUNDANT) 316.0 333.8 F- 300000 402 RTU 5 -8 (REDUNDANT) F -10000 316.0 RTU 5 -10 (REDUNDANT) 402 RTU 3 -5 (REDUNDANT) F -45000 1 SubTotal kVA 25% of Largest Motor kVA Total kVA 480V SB UPS3 - LOAD SUMMARY TAG kVA A Load Cont Rec Other Total* UPS 3 -1 866.7 Rec 1#1/0 AWG 866.7 1043 UPS 3 -2 866.7 40.9 1 #500 KCMIL 866.7 1043 UPS 3 -3 866.7 143 PANEL P31 866.7 1043 UPS 3 -4 (REDUNDANT)(BAT CHG) 113.0 14.4 34.9 113.0 136 PDU 3B5 (REDUNDANT) 240.0 19.3 1 #250 KCMIL 240.0 289 PDU 3B6 (REDUNDANT) 240.0 29 RTU 3 -1 (SINGLE POINT FEED) 240.0 289 PDU 3B7 (REDUNDANT) 240.0 - 1 #3/0 AWG 240.0 kVA SubTotal 2,713 kVA Total 2,713 kVA 25% of Largest Motor 3 #350 KCMIL kVA Total 2713.2 kVA *SYSTEM 100% RATED 3263.5 Amps at 480 V DB UPS3B - LOAD SUMMARY TAG kVA A Load Cont Rec Other Total* PDU 3B1 (REDUNDANT) 2,132 Rec 1#1/0 AWG Other Total PDU 3B2 (REDUNDANT) 240.0 40.9 1 #500 KCMIL 240.0 67.6 PDU 3B3 (REDUNDANT) 240.0 143 PANEL P31 240.0 7.3 PDU 3B4 (REDUNDANT) 12.6 14.4 34.9 240.0 42 PDU 3B5 (REDUNDANT) 240.0 19.3 1 #250 KCMIL 240.0 289 PDU 3B6 (REDUNDANT) 240.0 29 RTU 3 -1 (SINGLE POINT FEED) 240.0 289 PDU 3B7 (REDUNDANT) 240.0 - 1 #3/0 AWG 240.0 kVA 25% of Largest Motor 2,132 kVA Total 2,132 kVA 208 V 3 #350 KCMIL 113 COMP CIRCUIT 2 2131.6 kVA *SYSTEM 100% RATED 2563.9 Amps at 480 V 3 #250 KCMIL 86.8 94.0 F -450 113 SubTotal 2,132 - 1 #2 AWG 2,132 kVA 25% of Largest Motor 3 #500 KCMIL kVA Total 2131.6 kVA *SYSTEM 100% RATED 480 V PDU 3B1 -LOAD SUMMARY TAG kVA A Load Cont Rec Other Total PANEL 3B1A (REDUNDANT) 2,132 Rec 1#1/0 AWG Other Total PANEL 3B1B (REDUNDANT) 240.0 40.9 1 #500 KCMIL 240.0 67.6 PANEL 3B1C (REDUNDANT) 240.0 143 PANEL P31 240.0 7.3 PANEL 3B1D (REDUNDANT) 12.6 14.4 34.9 240.0 42 PANEL L31 240.0 19.3 1 #250 KCMIL 240.0 289 24.2 240.0 29 RTU 3 -1 (SINGLE POINT FEED) 240.0 289 SubTotal 240.0 - 1 #3/0 AWG 240.0 kVA 25% of Largest Motor 2,132 kVA Total 2,132 kVA 208 V DISTRIBUTION BOARD MECH3A - LOAD SUMMARY TAG kVA A Load kVA A Other Load Cont 2,132 Rec 1#1/0 AWG Other Total PANEL HP31 240.0 40.9 1 #500 KCMIL 240.0 67.6 118.7 240.0 143 PANEL P31 240.0 7.3 PDU 3A4 12.6 14.4 34.9 240.0 42 PANEL L31 240.0 19.3 1 #250 KCMIL 240.0 289 24.2 240.0 29 RTU 3 -1 (SINGLE POINT FEED) 240.0 289 PDU 3A7 240.0 - 1 #3/0 AWG 240.0 289 COMP CIRCUIT 1 2,132 kVA Total 2,132 86.8 94.0 3 #350 KCMIL 113 COMP CIRCUIT 2 2131.6 kVA *SYSTEM 100% RATED 2563.9 Amps at 480 V 3 #250 KCMIL 86.8 94.0 F -450 113 CONDENSER FANS 2,132 - 1 #2 AWG 2,132 19.9 20.4 3 #500 KCMIL 24 SUPPLY FAN 2131.6 kVA *SYSTEM 100% RATED 2563.9 Amps at 480 V 3 #350 KCMIL 71.5 89.3 F -225 107 RETURN FAN 3 #410 AWG - 1 #4 AWG F -225N 49.0 61.3 3 #410 AWG 74 CONTROL CIRCUIT F -125 1 1 1/4" 3 #1 AWG 2.0 2.0 F -100 2 RTU 3 -2 3 #2 AWG - 1 #8 AWG F -100N 316.0 333.8 3 #2 AWG 402 RTU 3 -3 F- 400000 10 3" 316.0 333.8 F- 300000 402 RTU 3 -4 F -10000 316.0 333.8 402 RTU 3 -5 (REDUNDANT) F -45000 1 3" CAC 3 -1 38.2 42.2 51 CAC 3 -2 38.2 42.2 51 CAC 3 -3 38.2 42.2 51 CAC 3 -4 (REDUNDANT) RTU 5 -6 215.3 223.6 269 RTU 5 -8 215.3 223.6 269 RTU 5 -10 (REDUNDANT) SubTotal 67.5 12.6 1,891 1986.8 kVA 25% of Largest Motor 17.9 kVA Total 2004.7 kVA 2411.3 Amps at 480 V DB UPS3OUT - LOAD SUMMARY TAG kVA A Load Cont Rec Other Total* DB UPS3A 2,132 - 1#1/0 AWG 2,132 2564 DB UPS3B 240.0 - 1 #500 KCMIL 240.0 289 PDU 3A3 240.0 - 1 #500 KCMIL 240.0 289 PDU 3A4 240.0 - 1 #350 KCMIL 240.0 289 PDU 3A5 240.0 - 1 #250 KCMIL 240.0 289 PDU 3A6 240.0 - 1 #4 /0 AWG 240.0 289 PDU 3A7 240.0 - 1 #3/0 AWG 240.0 289 SubTotal 2,132 kVA Total 2,132 kVA 25% of Largest Motor 3 #350 KCMIL kVA Total 2131.6 kVA *SYSTEM 100% RATED 2563.9 Amps at 480 V DB UPS3A - LOAD SUMMARY TAG kVA A Load Cont Rec Other Total* PDU 3A1 200.0 - 1#1/0 AWG 200.0 241 PDU 3A2 240.0 - 1 #500 KCMIL 240.0 289 PDU 3A3 240.0 - 1 #500 KCMIL 240.0 289 PDU 3A4 240.0 - 1 #350 KCMIL 240.0 289 PDU 3A5 240.0 - 1 #250 KCMIL 240.0 289 PDU 3A6 240.0 - 1 #4 /0 AWG 240.0 289 PDU 3A7 240.0 - 1 #3/0 AWG 240.0 289 FUTURE 491.6 kVA Total 491.6 591 693.9 Amps at 208 V 3 #350 KCMIL - 1 #1 AWG F -500 2 2" 3 #250 KCMIL - 1 #2 AWG F -450 1 SubTotal 2,132 - 1 #2 AWG 2,132 kVA 25% of Largest Motor 3 #500 KCMIL kVA Total 2131.6 kVA *SYSTEM 100% RATED 2563.9 Amps at 480 V PDU 3A1 -LOAD SUMMARY TAG kVA A Load Cont Rec Other Total PANEL 3AIA 50.0 - 1#1/0 AWG 62.5 173 PANEL 3AIB 50.0 - 1 #500 KCMIL 62.5 173 PANEL 3AIC 50.0 - 1 #500 KCMIL 62.5 173 PANEL 3AID 50.0 - 1 #350 KCMIL 62.5 173 3" 3 #600 KCMIL - 1 #250 KCMIL F -1600 4 3" 3 #600 KCMIL - 1 #4 /0 AWG F -1200 3 SubTotal 200.0 - 1 #3/0 AWG 250.0 kVA 25% of Largest Motor 3 #600 KCMIL kVA Total 250.0 kVA 693.9 Amps at 208 V REVIEWED FOR COMPLIANCE WITH NFPA 70 - NEC JUN 01 2010 City of Tukwila BUILDING DIVISION 120V CIRCUIT FROM PANEL CP FEEDER SCHEDULE TAG # RUNS CONDUIT PHASE CONDUCTORS NEUTRAL GROUND F -HV 1 6" 3 #4/0 AWG - 1#1/0 AWG F -4000 10 3" 3 #600 KCMIL - 1 #500 KCMIL F -3000 8 3" 3 #500 KCMIL - 1 #500 KCMIL F -2500 6 3" 3 #600 KCMIL - 1 #350 KCMIL F -2000 5 3" 3 #600 KCMIL - 1 #250 KCMIL F -1600 4 3" 3 #600 KCMIL - 1 #4 /0 AWG F -1200 3 3" 3 #600 KCMIL - 1 #3/0 AWG F -800 2 3" 3 #600 KCMIL - 1 #1/0 AWG F -600 2 2 1/2" 3 #350 KCMIL - 1 #1 AWG F -500 2 2" 3 #250 KCMIL - 1 #2 AWG F -450 1 3" 3 #600 KCMIL - 1 #2 AWG F -400 1 2 1/2" 3 #500 KCMIL - 1 #3 AWG F -300 1 2 1/2" 3 #350 KCMIL - 1 #4 AWG F -225 1 2" 3 #410 AWG - 1 #4 AWG F -225N 1 2 1/2" 3 #410 AWG 1 #410 AWG 1 #4 AWG F -125 1 1 1/4" 3 #1 AWG - 1 #6 AWG F -100 1 1 1/4" 3 #2 AWG - 1 #8 AWG F -100N 1 1 1/4" 3 #2 AWG 1 #2 AWG 1 #8 AWG F- 400000 10 3" F- 300000 8 3" F -10000 1 1 1/4" F -45000 1 3" NOTES: 1 SB -UPS3 NORMAL BREAKER POSITION CONTACT IN CLOSED POSITION WHEN BREAKER IS OPEN. UPS SYSTEM CONTROL I UPS SYSTEM CONTROL CABINET. CONTACT IN CABINET. CONTACT IN CLOSED POSITION CLOSED POSITION WHEN SYSTEM IS IN WHEN SYSTEM IS OFF. BYPASS. CDKEY RELEASE SOLENOID, OPERABLE WHEN CIRCUIT COMPLETED 1. PROVIDE WRING SHOWN FOR DB -UPS3B ALSO. 2. PROVIDE ENGRAVED LEXAN NAMEPLATE WITH SEQUENCE OF OPERATION AT SKRU UNIT. WHITE LETTERING ON RED BACKGROUND, )" HIGH LETTERING. DB UPS3A BYPASS SEQUENCE OF OPERATION WARNING: FAILURE TO FOLLOW PROPER PROCEDURE MAY RESULT IN HAZARDOUS CONDITION. AUTHORIZED PERSONNEL ONLY SHALL OPERATE BYPASS. DO NOT OPERATE WITHOUT PROPER UNDERSTANDING OF SYSTEMS. BYPASS ENERGIZED UPS SYSTEM 1. ENSURE UPS SYSTEM IS ON GENERATOR, BY OPENING DB -UPS3A NORMAL BREAKER. 2. FOLLOW UPS PROCEDURE AND PLACE UPS INTO BYPASS MODE. 3. CONFIRM GENERATOR SYSTEM IS OPERATIONAL AND BREAKER FOR SB- UPSBP3 IN SB -SG3 IS CLOSED. 4. CONFIRM BREAKER FOR DB -UPS3A IN SB- UPSBP3 IS CLOSED. 5. CONFIRM POWER AVAILABLE LIGHT FOR DB -UPS3A BYPASS BREAKER IS ILLUMINATED. 6. REMOVE KEY FROM SKRU FOR DB -UPS3A 7. INSERT KEY INTO DB -UPS3A BYPASS BREAKER. 8. OPERATE KEY TO ALLOW DB -UPS3A BYPASS BREAKER OPERATION 9. CLOSE DB -UPS3A BYPASS BREAKER. 10. OPEN DB -UPS3A NORMAL BREAKER. UPS SYSTEM FAILURE, UPS IS OFF 1. CONFIRM SB -UPS3 NORMAL BREAKER IS OPEN. 2. CONFIRM UPS SYSTEM IS OFF 3. OPEN DB -UPS3A NORMAL BREAKER. 4. CONFIRM GENERATOR SYSTEM IS OPERATIONAL AND BREAKER FOR SB- UPSBP3 IN SB -SG3 IS CLOSED. 5. CONFIRM BREAKER FOR DB -UPS3A IN SB- UPSBP3 IS CLOSED. 6. CONFIRM POWER AVAILABLE LIGHT FOR DB -UPS3A BYPASS BREAKER IS ILLUMINATED. 7. REMOVE KEY FROM SKRU FOR DB -UPS3A 8. INSERT KEY INTO DB -UPS3A BYPASS BREAKER. 9. OPERATE KEY TO ALLOW DB -UPS3A BYPASS BREAKER OPERATION 10. CLOSE DB -UPS3A BYPASS BREAKER. DB- UPS3A /DB -UPS3B SKRU WIRING DIAGRAM REV1S1GftO: uo -o�s7 877.THE.PNAP www.internap.com J Y 00 Q z 52 CL In 00 0 in I • w 0 �NV) LL 0 00 °� 0oAODo W 0 0 1%, U (n > m m ZW�r -< D 0 1-11 03 mW° go3: ceVW)I�ic�n<o_ • E 0 O c H 0 J = J ca a" v W v Q 0 a ft NTERGATE EAST CAMPUS 0 0 co rn 0 N H U w 0 0 ISSUED / REVISED DATE CD SET 03/08/10 REV 1 ESI 2 03/30/10 04/30/10 $$$DESIGN$SPECI FICATION$$$$$$$ DATE$$$ $TIME COPYRIGHT O 2008 CALLISON FEEDER SCHEDULE LOAD SUMMARY E700 10 GEN #8 2,250KW FUTURE (-62/ FUTURE GEN SWBD. "SB -SG3" 1 480V, 3PH, 3W + GND, 4000A BUS, 100AIC I∎ 4000AF 4000AT T I 4000AF \1 4000AT T'N 4000AF �1 4000AT GEN #7 2,250KW FUTURE 1 1 r Tt 4000AF �� 4000AF i 4000AT I, 4000AT J L r .r" T, 100AF A i 100AT T, 3000AF T∎ 4000AF i 3000AT ii 4000AT T LJ 1 1 FUTURE I LOAD BANK I I TAP BOX 1 "TB -LB4" 1 L 3000A (PPE) STANDBY GEN #6 2,250KW 4000AF 4000AT BUSSED TAP BOX 4000A 3PH 1 --- T■ 4000AF 4000AT (PPE) -1F -40001 I-I F -40001 I. 4000AF �) 4000AT -IF-40001 n T 4000AF �) 4000AT 1 ) 4000AF STANDBY GEN #5 2,250KW 4000AF 4000AT -IF-40001 T 4000AF y) 4000AT 1 ' 100AF 100AT -1F -30001 STANDBY GEN #4 2,250KW (PPE) -1F -40001 (PPE) GEN SWBD. "SB -SG3" 480V, 3PH, 3W + GND, 4000A BU T 4000AF I) 4000AT 1 1) 3000AF 3000AF 3000AT y) 3000AT v v F- 30001- T 3000AF �) 3000AT LOAD BANK TAP BOX "TB -LB3" 3000A 100KAIC FUTURE INDOOR UNIT SUBSTAION SS -6 F -3000 FOR CON11NUA11ON SEE SHEET E702 F- 30001- TT- 1 I1 T� 4000AF 4000AT GENERAL NOTES 1. ALL CONDUCTORS ARE COPPER 2. AIC VALUES SHOWN FOR BOARDS ARE BASED ON MAXIMUM FAULT VALUES (3PH, L -G, L -L -G) AVAILABLE FOR VARIOUS FEEDER SCENARIOS. KEY NOTES OWNER FURNISHED CONTRACTOR INSTALLED EQUIPMENT ,- --- - - - --� FUTURE INDOOR UNIT v INDOOR UNIT N SUBSTATION USS -5 SUBSTATION USS -3 600AS 600AS XFMR #6, Y -Y 2500/3325KVA 26.4KV- 480/277V AA /FA, 80t J ULU I A T� 4000AF 4000AT (PPE) XFMR #5, Y -Y 2500/3325KVA 26.4KV- 480/277V AA /FA, 80'C 600AS F -HV 27KV SWGR. MSG2 NEW CONDUIT AND CONDUCTORS MSG2 -A J. III 1200AF XXXAT T ND1 -1 v C 1200AF XXXAT 1200AF ' 1200AF XXXAT 200AT 1 ND1 -2 1r C T 1200AF XXXAT MSG2 -B INDOOR UNIT SUBSTATION USS -4 (PPE) XFMR #3, Y -Y 2500/3325KVA 26.4KV- 480/277V AA /FA, 80t n T 4000AF �) 4000AT ±40001 PPE) MECH DISTRIBUTION SWBD. "DB- MECH3B" 480V, 3PH, 3W + GND, 3000A BUS, 100KAIC 600AS XFMR #4, Y -Y 2000 /2660KVA 26.4KV- 480/277V AA /FA, 80'C n I. 3000AF 3000AT -IF -30001 1A 402000AT F 1200AF XXXAT 1200AF XXXAT BY OTHERS, N. INSTALL NEW CONDUCTORS IN EXISTING EXISTING CONDUIT PULL BOX REVIE1�JED FOR COMPLI/}NCE WITH NFPA 70 - NEC JUN 01 2010 (PPE) MECH SWBD. "SB- MECH3" 480V, 3PH, 3W + GND, 3000A BUS, 100KAIC 100AF ±TWAT T 3000AF �) 3000AT T 3000AF T 3000AF ) 3000AT ) 3000AT Y ATSCr City of Tukwila BUILDING DIVISION -IF -30001 T 3000AF 3000AT -IF -30001 600AF )450 —1 F -450 1 M 600AF ) 450AT -1 F -450 1 600AF 450AT -1 F -450 1 600AF 450AT -1 F -450 1 )450AT .100AF -1 F -450 1 (PPE) ALTERNATE FEEDER TO "DB- MECH3B" ABOVE (TYP) DOUBLE THROW DISC SW (TYP) MECH DISTRIBUTION SWBD. "DB- MECH3A" 480V, 3PH, 3W + GND, 3000A BUS, 100KAIC -1 F -100 1 T1 3000AF 3000AT 100AF 100AF ) SST -1 F -100 1 ) 3000AF ATSCr -1 F -100 1 80AT )1000AT -1 F -100 1 -1 F -100 1 100AF 100AF 80AT 100AT -IF -1001 200AF )125AT -1 F -125 1 400AF 350AT --1 F -400 1 •N 400AF 400AF -1 F -400 1 -I F -400 1 600AF 600AF ) 450AT ) 450AT -1F-450 k LAC: -� F -450 1 600AS —6600AS RJJ600AS VFD RTU 3 -2 VFD RTU 3 -3 1:CAAFT -1 F -450 1 'L1600AS VFD RTU 3 -4 600AF ) 450AT )1°°ArF )'ooAF FUT 100AF 100AF IN 100AF 100AF T )MAT 600AS VFD RTU 3 -5 -) F -100 1 100AS - 100AS PANEL HP31 )100 100AAF T XFMR XFR -L3, 50 KVA 480- 480/277V -1 F -100 1 PANEL L31 PANEL L33 1 F-100 1 200AF )125AT 400AF ) 350AT FOR CONTINUATION SEE SHEET E711 200AS rrYri XFMR XFR -P3 75 KVA 480- 208/120V -I F -225 I PANEL P31 PANEL P33 F -100 1 REVISION NO fiL\&-O 5*-7 $$$ DESIGN $SPECIFICATION$$$$$$$$$$$$$ 1 cirv��ict�u► MAY 10 2010 PERMIT CENTER M 0 C) 0 M 0 z J Q 877.THE.PNAP www.internap.com Q Oc o0 z rn lOo0p W 0 N N Vi 0 C°z CL WpCO00 C) (n > rn co m 0 wZ • (4.1, z 0 H 1 J E 0 • u. o= A 0 J = J co • " v a Q as • V CD U CL Op r W Q O< Cl)WN Q =W .c0 < Ce M W co F- z 0 ti co 0) 0 N I- U w 0 ISSUED / REVISED DATE CD SET 03/08/10 REV 1 i 03/30/10 ESI 2 2 04/30/10 $$$DATE$$$$ $TIME COPYRIGHTO 2008 CALLISON SINGLE LINE DIAGRAM PHASE 3 - HV DISTRIBUTIOP GENERATOR DIST, MECH DI E701 (PPE) (PPE) 1 2 n / L /4000AF 4000AT L_ ATSCr 3 10 FOR CONTINUATION SEE SHEET E701 1 L_ L L UPS INPUT SWBD. "SB -UPS3" 480V, 3PH, 3W + GND, 4000A BUS, 100KAIC T 4000AF �) 4000AT Y T 2000AF �� 1600AT I (PPE) 2000AF 4i 1 1600AT F -1600 750KVA MOD. 1 (PPE) 1 8 -MIN. BATTERY F -1200 T 2000AF �� 1200AT Y /N)■ II2000AF 1600AT -1F-16001 750KVA MOD. 2 (PPE) -1) 1_ 8 -MIN. BATTERY -1F -12001 n I. 2000AF �J 1200AT Y 4‘)■ 2000AF J � 600 TA v -I F -16001 750KVA MOD. 3 (PPE) 1 1 8 -MIN. BATTERY -1F -12001 n I. 2000AF 1J 1200AT Y y�2000AF 1600AT F -16001 750KVA MOD. 4 1 8 -MIN. BATTERY -1F -12001 ,N)\ 3000AF J 3000AT /� STATIC I. 2000AF SWITCH 1 1200AT -+F -30001 n ' 100AF 100AT 17 L__� 4# 250 MCM, 1# 2 GND, 3 "C, TYP OF 4 PER UPS MODULE 3000 AMP T 3000AF CONTINUOUS ) 3000AT UPS SYSTEM CONTROL CABINET AND SYSTEM POWER SECTION 480V, 3PH, 3W + GND, 3000A BUS, 100KAIC (PPE) UPS DISTRIBUTION SWBD. "DB- UPS3A" 480V, 3PH, 3W + GND, 3000A BUS, 100KAIC ,N)\ /N/ 3000AF 3000AF 3000AT 1 3000AT w T 3000AF �� 3000AT -J F -3000 7 (PPE) UPS MAIN BYPASS SWBD. "SB- UPSBP3" 480V, 3PH, 3W + GND, 3000A BUS, 100KAIC I. 3000AF �� 3000AT v T 3000AF �3000AT \I// 100AF 100AT UPS MAIN BYPASS SWBD. "SB- UPSBP4" 480V, 3PH, 3W + GND, 4000A BUS, 100KAIC E-� J_r I 4000AF ,\1/ 4000AT r i 4000AF I \ 100AF i 4000AT 1 100AT FI> LJ J n � NCE WITH A70 -NEC O 1 2010 L -I F -3000 -1F-30001 of Tukwila. G DIVISION 1 I100AF 100AT I600AAT F 500 I 600AF 500AT -1 F -500 1 PDU 3A1, 300 KVA 480- 208/120V 600A AMP PPE) 1000A T 1000A, 208/120V, 30, 4W Tip 225AT I 225AT I 225AT 225AT 225AF Op 225AF Op 225AF �P 225AF I r I P PANEL PANEL PANEL C PANEL 600AF 500AT -1 F -500 1 600AF 500AT -1 F -500 PDU 3A3, 300 KVA 480- 208/120V 600A XA3P PPE) 1000A T 1000A, 208/120V, 30, 4W P 225AT I 225AT 225AT L.‘ 225AF P 225AF I j3P 225AF I �P 225AF P PDU 3A2, 300 KVA 480- 208/120V 600A AKAP VV 1000A T 1000A, 208/120V, 30, 4W rip 225AT I 225AT I 225AT 225AT 225AF Op 225AF j3P 225AF Op 225AF � 1 3P PANEL PANEL (PPE) PANEL A PANEL PANEL PANEL - PANEL B PANEL PANEL -"Tr- PDU 3A4, 300 KVA 480- 208/120V 600A H F -500 1 600AF 500AT L7 3000AF L _ j SKRU1-- �- 3000AT PDU 3A5, 300 KVA 480- 208/120V 600A -I F -500 1 1000 1000A, 208/120V, 30, 4W 3P 600AF 500AT (PPE) 225AT I •225AT I 225AT I 225AF Op 225AF Op 225AF Op 225AF r 3P PANEL PPE) 1000Y Y\/\ 1000A, 208/120V, 30, 4W T3P 225AT I 225AT I 225AT 225AT 225AF P 225AF r3p 225AF Op 225AF r3p I Eit4L PANEL r PANEL PA NEL PANEL PANEL _ C PANEL 6OO .0AF -� F -500 1 -1 F -500 1 PDU 3A7, 300 KVA 480- 208/120V 600A APAP 1000A T; 1000A, 208/120V, 30, 4W J3P (PPE) UPS DISTRIBUTION SWBD. "DB- UPS3B" 480V, 3PH, 3W + GND, 3000A BUS, 100KAIC T 3000AF J 3000AT T 3000AF - _ ) 3000AT 7 FUTURE MECH SWBD. "SB- MECH4" 480V, 3PH, 3W + GND, 4.000A BUS, 100KAIC T L I- A ■ 100AF 4000AF Il100AT \i/ i �r Y LL] 1 I 4000AF L (PPE) 225AT I 225AT I 225AT 225AT I 225AF P 225AF lP 225AF OP 225AF r3p I PDU 3A6, 300 KVA 480- 208/120V 600A _(_P 1000M1000A, 208/120V, 30, 4W 3P PANEL (PPE) 225AT I 225AT I 225AT 225AT L.‘ 225AF Op 225AF Op 225AF Op 225AF P PANEL PANEL PA �L, PANEL PANEL PANEL PANEL 600AF 500AT H F-500 1 600AF 600AF 500AT 1 F -500 1- -I F-500 1 PDU 3B2, 300 KVA 480- 208/120V 600A AMP 1000A \ 1000A, 208/120V, 30, 4W J3P (PPE) 225AT I -) 225AT L) 225AT 225AT I, 225AF 3p 225AF 1•13p 3P 225AF 225AF 3P I PDU 3B1, 300 KVA 480- 208/120V 600A _1_P PANEL A PPE) 1000A T 1000A, 208/120V, 30, 4W )P 225AT LI 225AT LI 225AT LI 25ATI 225AF r3p 225AF r3p 225AF r3p 225AF �P PANEL. A PANEL PANEL PANEL PANEL B PANEL PANEL 11 600AF 500AT H F -500 600AF 500AT -I F -500 1 1:)65M I T 600AF 500AT 600AF 500AT PDU 3B4, 300 KVA 480- 208/120V 600A \3P PPE) 1000A T-N 1000A, 208/120V, 30, 4W 1 3P 225AT LI I I-) 225AF r3p 225AF �P 225AF 3P 225AF r3p I I PDU 3B3, 300 KVA 480- 208/120V 600A P 1000YYYN 1000A, 208/120V, 30, 4W si3p A PANEL PANEL PPE) PANEL PANEL 225AF r3p 225AF -.13p 225AF r3p 225AF r3p PANEL PANEL PANEL C PPANEL PDU 3B6, 300 KVA 480- 208/120V -1 F -500 1 600A 1000A T, 1000A, 208/120V, 30, 4W J3P 225AT I 225AT I 225AT ') 225AT 225AF �P I 225AF Op 225AF 3P 225AF PDU 3B5, 300 KVA 480- 208/120V 600A l_P PANEL (PPE) VAf 1000A T 1000A, 208/120V, 30, 4W 225AT I I 225AT 225AT 225AF Op 225AF Op 225AF Op 225AF j I P PANEL A PANEL PANEL PANEL PANEL PANEL PPE) 3P PANEL PDU 3B7, 300 KVA 480- 208/120V 100AF 1 MCI -1 F -500 600A 1000A T 1000A, 208/120V, 30, 4WP REVISION N01.LL fLtOO i s1 PPE) 225AT I 225AT I 225AT 225AT 225AF �P I r3p I 225AF �P 225AF 225AF 3P PANEL PANEL $$ DESIGN$SPECIFICATION$$'. $'•$', $ PANEL PANEL $$ DATE $TIME FOR CONTINUATION SEE SHEET E703 crtvROCeilEALn MAY 10 2010 PERMIT CENTER 2 W H M O � M coo �a Q0 J J 1- >< o -I LO N a J Z 0 www.internap.com Q 00 0_ r0 000 ri) I o 1+1 0 'N V) • Corr co cZ- °- woc�r_ Zw >a) com O c,.) w Z Z 0_ m5°� goy cn M cn Q a • z 0 N J J w 2 0 00 a 03 U co r CD CI) 4C CD LL CV a M f- 1 CO z 0 0 ti co rn N 1- 0 0 w 0_ ISSUED / REVISED DATE CD SET 03/08/10 REV 1 i 03/30/10 ESI 2 2 04/30/10 COPYRIGHT O 2008 CALLISON SINGLE LINE DIAGRAM PHASE 3 - UPS DISTRIBUTI( E702 10 1 -t FOR CONTINUATION SEE SHEET E702 'N 4000AF NI/ TWAT k 2000AF �/ XXXXAT Y 1 r I ■ 2000AF / )00-1-FCC ■ I 0 800KVA MOD. 1 1) 7 (PPE) QI E� -I-I I EI� I 1 BATTERY I.\ 2000AF 1/ XXXXAT Y (PPE) FUTURE UPS INPUT SWBD. "SB -UPS4" 480V, 3•, 3W + GND, 4000A BUS, 100KAIC 1 1, 4000AF �/ XXXXAT L T, 2000AF XXXXAT 800KVA MOD. 2 I) E1- I ^-1-1 II11 I BATTERY QQ (PPE) T\ 2000AF �/ XXXXAT r A LN 2000AF 1/ MAT 1 800KVA MOD. 3 1) 7 I El] 11 L B -MIN. I BATTERY Io 1∎ 2000AF 1/ XXXXAT (PPE) FUTURE UPS DISTRIBUTION SWBD. "DB- UPS4A" 480V, 3PH, 3W + CND, 3000A BUS, 65KAIC 7 -\ 600AF / 600AT ✓ 600AF I/ 600AT 1 PDU 4A1, 300 KVA 480- 208/120V 600A - P T 6004E / 600AT 10004 1000A, 208/120V, 30, 4W J3P = =r= = =r = = =Irlff= = =r= 225AT ■ 225AT I , 225AT I , 225AT I , 225AF 13p 225AF 130 225AF 13P 225AF 13P IPANELI IPANEI IP ELI IPANEL1 I A I IB I I "c" I 11 11 I I 1 L__J L__J L_J L__J PDU 4A2, 300 KVA 480- 208/120V 6004 1 AM-1 1 0004 1 - 1000A, 208/120V, 30, 4W J3p = =r= = =r===ill.= = =r= 225AT - 225AT , 225AT I , 225AT 225AF 13P 225AF 13P 225AF 13P 225AF 13P PA PANEL I PANEL r_ r_ PA L 1 A I 1 B I 1 B I I B I I I I I I I 1 L- _ J L- _ J L_ _ J L- _ J r T r 7 T \ 2000AF T\ 4000AF / XXXXAT / XXXXAT T 1-v)-1 1 1 LLJ 1 O SP4RE 4 z 100AF /10WAT 800KVA 4MOD. 4 I)-1 IEI] 11 L f 8 -MIN. 1 BATTERY I Q Tik STATIC r -1 IN. 'N 20004E SWITCH 1 I / �/ XXXXAT LIJ Y T I '\ 600AF ■ 600AF / 600AT 1 600A 1 1 ✓ J PDU 4A3, 300 KVA 480- 208/120V 600A P 2000AF XXXXAT I∎ 2000AF y /X(�XXAT 1F-4000001- ■ 600AF 1 600AT 10004 T 1000A, 208/120V, 30, 4W J3P = =r== =r- = =71,= ant =r_ 225AT I , 225AT 1, 225AT I , 225AT 1■ 225AF 13P 225AF 13P 225AF 13P 225AF 13P ELI IPA ELI I PANEL I I PANEL I I I I -B -I I I I I 1 I I I I I 1 L- _ J L- _ J L- _ J L- _ PDU 4A4, 300 KVA 480- 208/120V 600A P 1000M 1000A, 208/120V, 30, 4W 13P = =r = = =r = = =� = = =r= 225AT 1 ■ 225AT , 225AT 1 ■ 225AT 1- 225AF 13P 225AF 13P 225AF 13P 225AF 13P I PANEL 1 IPANEL PA PA L I I A I I B I I B I I B I I I I I I I 1 L_J L__J L__J T� XXXXAF 1' XXXXAT IL I s\ 600AF / 600AT 1 k 2000AF I/ XXXX IF- 400000I- -IF-4000001 - IF- 4000001 FUTURE MECH DISTRIBU11ON SWBD. "DB- MECH48" 480V, 3PH, 3W + GND, 4000A BUS, 100KAIC Z I. 600AF 1 450AT 600AF 11 450AT T ■ 600AF / 4 -\ 600AF / 450AT 1 -' 600AF 11 450AT -1 T.\ 4000AF 4000AT L .r 100AF /BO1 MIT FUTURE MECH DISTRIBUTION SWBD. "DB- MECH4A" 480V, 3PH, 3W + GND, 4000A BUS, 100KAIC ALTERNATE FEEDER TO "DB- MECH4B" ABOVE (TYP) DOUBLE THROW - DISC SW (TYP) - - -r ■ 600AF / 450AT 600AS -450C r-I wo 1 FUT 1 RTU 4-1 L _ _ _J T L 600AF / 450AT r I, 600AF I/ 450AT I TI L 600AS -450C r1 rLFPLT 1 FUT RTU 4-2 1 L___J 600AS -450C I- -L 1 FUT 1 RTU 4-3 L___J T L -r IN 600AF / 450AT I 600AS -450C r� F_ J!F L 1 FUT 1 RTU 4-4 L__J T L I -\ 600AF / 450AT f T� 4000AF �/ 4000AT L T T L 600AS -450C 1- -I VFD 1 FUT 1 RTU 4-5 1 1 L__J I.� 4000AF I/ 4000AT TI - 100AF 11 80AT 600AS -450C r -1 1 FUT 1 RTU 4-6 I L _ _ _J T L 1- Tk 4000AF 4000AT -T1 REVIEWED .FOR COMPLIANCE WITH NFPA 70 - NEC JUN 012010 City of •Tukwila BUILDING DIVISION I. 100AF / 80I�T T - 100AF / 80AT - 100AF 1.1 100AT I. 100AF 11 80AT T 400AF 11 400AT T I ■ 400AF / 400AT T I -' 400AF / 400AT 7 J 600AS -450C I- L�� 7 1 FUT I RTU 4-7 I L__J IN 100AF / 80AT 100AS FUT CAC 4-1 I L__J T� XXXXAF XXXXAT 1 T 600AF I .\ 600AF / 600AT / 600AT 1 L _ L_ _ _1 PDU 4A5, 300 KVA 480- 208/120V 600A NIV1P 1000A \i /Y\ 1000A, 208/120V, 30, 4W J3P INE INK = = =r == =7 = = =rElm 225AT 1■ 225AT , 225AT 1 ■ 225AT ■ 225AF 3P 3 PANEL1 225AF PPANEL p 1 I- 1 1B" PDU 4A6, 300 KVA 480- 208/120V 600A 1-■ _ I J3P 225AF 13p 225AF 13P [A NL I IP ELI I I II 11 11 1 L_J L_ _ J L_ - L_ _ J 10004 T 1000A, 208/120V, 30, 4W J3P = =r = = =r = =��. = = =r_ 225AT 225AT I , 225AT 1 ■ 225AT I , 225AF 13P 225AF 13P 225AF 13P 225AF 13P IPA EL 1 IPAN 1 IPA ELI IP EL I -"A"- I I B I I B I I 1 I I 1 I I I 1 L__J L__J L_J L-_J I -\ 600AF / 600AT T PDU 4A7, 300 KVA 480- 208/120V 600A I"I3P 1000A T FUTURE UPS DISTRIBUTION SWBD. "DB- UPS4B" 480V, 3PH, 3W + GND, 3000A BUS, 65KAIC 1000A, 208/120V, 30, 4W J3P = =r = = =r = = =in= = =r= 225AT 1-■ 225AT - 225AT ■ 225AT I , ■ 225AF 13P 225AF 3P ELI I PANEL 1 I A I I PDU 4A8, 300 KVA 480- 208/120V 60041-, .IV1P 225AF 13p 225AF 13P ELI I PANEL I I I I I I II II II I L__J L__J L__J L__J 1000A T 1000A, 208/120V, 30, 4W J3P = =r = = =r= = =irl. = = =r= 225AT I , 225AT I , 225AT ■ 225AT 1 225AF 13P 225AF 13p 225AF 13P 225AF 13P IPA ELI ELI IPANEL I IPA ELI IA" I I I I I I Q I I I I I I I I I L__J L-_J L__J L-_J r I, 600AF I, 600AF I, 600AF I 1 600AT I / 600AT / 600AT 1 1 1 r_- L__1 L__7 PDU 482, 300 KVA 480- 208/120V 600A AilV1P 100014 1 1000A, 208/120V, 30, 4W J3P - =r= = =r = ==irli== =r, 225AT - 225AT , 225AT I , 225AT ■ ■ 225AF 13P 225AF 13P 225AF 13P 225AF 13P PA L I IPA ELI PA L I PA T I A I I B I I c I I o I I I I I I 1 L__J L_J L__J L__J PDU 4B1, 300 KVA 480- 208/120V 600A 1 ■ P 1000A I - 1000A, 208/120V, 30, 4W J3P = =r= = =r= = =Tii== =r_ 225AT - 225AT - 225AT 1■ 225AT ■ 225AF 13P 225AF 13P 225AF 1-1-43, 225AF 13P IPA EL 1 IPANELI I PANEL IPANEL-I ICI I I ICI ICI I I I I I I I 1 L__J L-_J L__J L-_J T L 100AS T FUT 1 CAC 4-2 L _ _ _J T\ XXXXAF LN XXXXAF / XXXXAT / XXXXAT 1r I ■ 600AF ■ 600AF 1 ∎ 600AF / 600AT 11 600AT / 600AT 1 L- L 1 PDU 4B4, 300 KVA 480- 208/120V I 600A1-\ P f L _I 1 T 100AS FUT CAC 4 -3 L___J ■ 100AF -, MU T L 100AS T L r 1 100AF / 100AT 100AS 1 FUT I FUT CAC 4 -4 ' PANEL 1 1 HP41 L___J L___J 11 400AF I/ 400AT I TI L,I 100AS r)� FUT XFMR XFR -L4, 145 KVA 1 1 1 480- 480/277V i L_I =J T 1 FUT T T FUT PANEL I I PANEL L41 I I L43 L__J L__J -\ 6004E -\ 6004E I/ 600AT I/ 600AT 1 L I % 600AF I/ 600AT L 10004 I 1000A, 208/120V, 30, 4W J3P - =r = = =r= = =� = = =r= 225AT - 225AT - 225AT I -. 225AT I - 225AF 13P 225AF 13P 225AF 13P 225AF 13P �p -I PPPANEL -I p LI q LI 1 A I I B I l c l 1 1 1 11 I I I L__J L__J L_J L__J PDU 4B3, 300 KVA 480- 208/120V 60041.-N 10004 T 1000A, 208/120V, 30, 4W J3P = =r== =r = = =71.= = =r= 225AT 1 225AT ■ 225AT - 225AT ■ ■ 225AF 13P 225AF 13P 225AF 13P 225AF 13P IPANEL I IPANELI I PANEL I IPANELI I I I "_ I I 3_ I I B I 1 I I I I I I I L-_J L-_J L__J L__J 1 PDU 4B6, 300 KVA 480- 208/120V I 60041-N P 10004 T 1000A, 208/120V, 30, 4W 11-13p 225AT I - 225AT 1, 225AT ■ 225AT I , ■ 225AF 1-13p 225AF 1--i-40 225AF 3p 225AF 1-13p IPANELI I PANEL -I IPANELI IPANELI I I I I I I I I I I I I I I I PDU 4B5, 300 KVA 480- 208/120V 600A AA/1P L__J L__J L__J L-_J 10004 T 1000A, 208/120V, 30, 4W J3P = =r= = =r = = =T. = = =r= 225AT , 225AT , 225AT I , 225AT I , 225AF 13P 225AF 13P 225AF 13P 225AF 13P ELI IPET IPAEL I ELI 11 I I I I 11 1 I I I I I I I L-_J L_J L__J L__J I, 600AF 11 600AT L T L r 1 400AF / 400AT f 200AS I (7 • 1 FUT XFMR XFR -P4 I III 75 KVA L _ =_1 480- 208/120V 1 FUT PANEL 1 P41 L __J 1 FUT PANEL P43 1 1 L-__J T PDU 488, 300 KVA 480- 208/120V 600A - P 1000A 1 - 1000A, 208/120V, 30, 4W J3P = =r = = =r= = =i1= - =r_ 225AT 1--N 225AT , 225AT - 225AT • 225AF 130 225AF 130 225AF 13P 225AF 13P IPEL IP ELI IP ELI IPA ELI I I IB" I I B I I B I 1 1 1 1 1 1 I 1 L__J L__J L__J L__J PDU 4B7, 300 KVA 480- 208/120V . 0 600A 1 J P 10004 T 1000A, 208/120V, 30, 4W J = =r = = =r= = =r= 225AT - 225AT , 225AT I , iL\O-OIS7 NE-7- 225AT 1 225AF 3p 225AF 1 3P 225AF 3P IPANELI IPANELI 1ANELI I I I I I I I L- _ J L_ _ J L_ _ J 225AF I3p A171 I L__J cnvoIINIu+ MAY T 0 2010 PERMIT CENTER ogt cc w 1-- OD H M 00 o C) (0 < J Q J I- 'S Q O J 111 F." N < I- LL Cl. o< 0 0) N O M I- V N. ON. uct c0 www.internap.com J YQ 00 Z CD O < a, (2 ( N1 I U W p N)N00 • 0 � Q � Zp 0_ W 8 0r,U cn > o) (o m -bJ -< : O V Z W Z� LO 0 awl- ) =i- =3: fa' CALL /SON www.ca11ison.com INTERGATE EAST CAMPUS 0 0 ti co 0) O N 0 U w 0_ ISSUED / REVISED DATE CD SET 03/08/10 REV 1 i 03/30/10 ESI 2 a 04/30/10 $$ $DESIGN$SPECIFICATION',$$$$$$$' '.$$ $$$DATE$$$$ $TIME COPYRIGHT O 2008 CALLISON SINGLE LINE DIAGRAM PHASE 4 - UPS DISTRIBUTI( E703 GEN #1 2000KW DAY 1 GEN. SWBD. #1 480 /277V, 3-, 4W + GND, 6000A BUS, 100KAIC n IN 3000AF 3000AF � 3000AT 11 3000AT TERMINATION BUS SECTION 3000A BUS 2000KW LOAD BANK (F) E L UPS BYPASS SWBD. "SB- UPSBP1" 480V, 3PH, 3W + GND, 3000A BUS, 100KAIC TRANSFER BREAKER CONTROLS FOR EXISTING MAINTENANCE BYPASS BREAKER TO NEW MAINTENANCE BYPASS BREAKER FOR C0N11NUA110N SEE SHEET E701 /N T 3000AF 3000AT 4000A ATS #1, 3P, 3W, 480V GEN #2 2000KW DAY 1 GEN #3 2000KW DAY 1 T 3000AF 3000AF 3000AT 11 3000AT / / / / / / I- — _)3000AF ) 3000AF / 3000AT 3000AT / / / ) -0 OAT / / / ) 3000AT / / 3000AF ) )3000AF + 3000AT SKRU 3000AT sT sT T 3000AF 1) 3000AT /T \. 3000AF 3000AT (EXISTING) 27KV SWGR. MSG1 MSG1 -A XXXAT LT_ ND1 -1 ND1 -2 c 1200AF XXXAT c 1200AF XXXAT 1200AF 1200AF XXXAT ❑ 200AT 1 INDOOR UNIT SUBSTATION USS -1 26.4KV, 1200A BUS SERVICE SWBD #1 480/277V, 3N, 3W + GND, 4000A BUS. 100KAIC T 600AS XFMR #1, Y -Y 2500/3333KVA 26.4KV- 480/277V AA, 100'C N 4000AF 4OOOAT Y K 1 3000AF 3000AF 3000AT , 3000AT UPS INPUT SWBD. 480/277V, 3N, 3W + GND, 4000A BUS, 100KAIC t\ 4000AF �) 3200AT FOR CONTINUATION SEE SHEET E712 M L 2000AF � 1600AT 800KVA MOD. 1 UPS OUTPUT SWBD. 1-C) 8 -MIN. BATTERY )1200AT T) 2000AF L 2000AF I_ ) 1200AF 1200AF , 1600AT � T ) 1600AT IJ 1200AT I 1200AT � � � W�I SPARE SPARE 800KVA MOD. 2 M1 800KVA SOOKVA MOD. 3 MOD. 4 1-C) 1 - ST 1 ST 8 -MIN. 8 -MIN. BATTERY BATTERY 8 -MIN. BATTERY )1200AT ) 1200AT 3N, 3W, 3000A BUS )1200AT 100AF 100AT GF 4000AF 4000AT CF -ND�> 0 MSG1 -B 1200AF 600AT 1200AF XXXAT 1200AF XXXAT 27KV SWGR. MSG2 1200AF XXXAT MSG2 -A 1200AF XXXAT ND1 -1 C 1200AF 200AT 1200AF XxXAT 10 ND1 -2 C Y 1200AF MAT 120 200AT 0AF 4 INDOOR UNIT SUBSTATION 600AS USS -2 (N) 26.4KV, 1200A BUS (NEW) XFMR #2, Y -Y (NEW) 2500/3333KVA 26.4KV- 480/277V AA, 100'C NC 4000AF GF 4000AT ® ATS #2 4000A, 3P, 480V 3000AF J 3000AT 3000AF 3000AT ATS #3 3000A, 3P, 3W, OVERLAPPING NUETRAL, 480V, W/ BYPASS ISOLATION 400AF 400AF 400AT 400AT 400AS CAF VFD RTU -5 -6 400AS 400AF 400AF 400AT VFD 400AF 400AT w 400AT 400AS 400AF RTU -5 -8 400AS 400AS 400AF 47 600AF 600AT 600AF 800AT UPS DISTRIBUTION SWBD. 480V, 3 -, 3W + GND, 3000A BUS, 65KAIC 600AF 600AT 600AF 600AT 600AF 600AT 600AF 600AT 600AF 600AT 600AF 600AT 600AF 600AT 600AF 600AT 600AF 600AT 600AF 600AT 600AF 600AT 600AF 600AT REVIEWED FOR COMPLIANCE WITH NFPA 70 - NEC JUN 01 2010 City of Tukwila BUILDING DIVISION_ DISCONNECT EXISTING RTU FEEDER AND INSTALL NEW FEEDER SHOWN (TYP OF 3) MECH. DISTRIBUTION SWBD. 480V, 3w, 3W + GND, 3000A BUS, 65KAIC 400AF 400AT HV -1 250A 45KVA 480v- 208/120V 200AF 150AT w 150AT 75KVA 75KVA 480V- 480V- 480/277V 120/208V HV -2 70A 70A rrTn RP /GEN -1 uu 45KVA 480V- 480/277v LP /GEN -1 225AF 225AT SPARE MSG2 -B 1200AF ® 1200AF XXXAT XXXAT TI BY OTHERS, N.I.C. REVISIN NO L ELtO- 0 l �� CRYOPTUKVNLA MAY 10 2010 PERMIT CENTER Rkt cc www.internap.com Q < 00 Q O CL In 000 0 IU • w 0 OM N o) 0 rX paoo o 11 wo °N_ (� >rn com < 0 wZZ� cr Lo 1= g p s • It W C/) ▪ D Z Q. W - c) V Q co CD ,v- 0 EL co Q _ILrn rim CO 4- Q git .COWN� WI < W co ▪ a. 114 4C Z �cn= M W M W co I— H Iva' Z Z 0 0 op 0 CV 1— 0 U w 0_ ISSUED / REVISED DATE CD SET 03/08/10 REV 1 1 03/30/10 ESI 2 a 04/30/10 $$$DESIG N$SPECI FICATION$$$$$$$$$$$$$ $$$DATE$$$$ $TIME COPYRIGHT@ 2008 CALLISON SINGLE LINE DIAGRAM EXISTING UTILITY, STANDB MECHANICAL AND UPS E711 1 2 3 4 6 8 9 10 FOR CONTINUATION SEE SHEET E711 T -1A u- JJ 300KVA 480V- MrY1 208/120V T -2A 300KVA 480V- MM 208/120V DP- CPP -3A 800A, 120/208V, 3N, 4W + GND, 42KAIC T -3A uJ._u 300KVA 480V- (TM 208/120V 800AF 1 800AT 225AF 225AF 225AF -1225AF 225AT ) 225AT ) 225AT ,1 225AT CPP -3A -1 42KAIC CPP -3A -2 42KAIC CPP -3A -3 42KAIC (FUTURE) • 800AF • 800AT SPARE DP- CPP -4A 800A, 120/208V, 4W + GND, 42KAIC 25AF ) 2� ) 225AF 5AT ) 225AT , ) 225AT CPP -4A -1 42KAIC CPP -4A -2 42KAIC CPP -4A -3 42KAIC (FUTURE) SPARE T -4A Ldu 300KVA 480V- r -rr 208/120V DP- CPP -5A 800A, 120/208V, 3N, 4W + GND, 42KAIC T -5A 300KVA 480V- Tl 208/120V (NEW) 800AF 800AT T -6A 300KVA 480V- r rn 208/120V (NEW) 225AF 225AF 225AF 225AF 1 225AT ) 225AT ) 225AT , ) 225AT CPP -5A -1 42KAIC CPP -5A -2 42KAIC CPP -5A -3 42KAIC (FUTURE) SPARE 800AF 800AT DP- CPP -6A 800A, 120/208V, 3N, 4W + GND, 42KAIC 225AF 225AT , ) 222 T ) 225AT -\ 225AT CPP -6A -1 42KAIC CPP -6A -2 42KAIC DP-CPP-1A 800A, 120/208V, 3N, 4W + GND, 42KAIC 800AF OOAT 225AF 225AF 25AT ) 225AT , .1225AT CPP -1A -1 42KAIC CPP -1A -2 42KAIC CPP -1A -3 42KAIC (FUTURE) SPARE 225AF 225AT CRP -2A -1 42KAIC CPP -6A -3 42KAIC (FUTURE) 800AF 800AT SPARE DP- CPP -2A 800A, 120/208V, 3N, 4W + GND, 42KAIC 225AF -N 225AF 225AF 1 725A J 225AT ) 225AT CPP -2A -2 42KAIC CPP- 2A-3 42KAIC (FUTURE) SPARE T -7A �} 300KVA 480V- MM 208/120V (NEW) T -7B LLA.kJ 300KVA 480V- Mir 208/120V (NEW) T -6B 300KVA 480V- TTf 208/120V (NEW) T -5B 300KVA 480V- 208/120V (NEW) T -4B 300KVA 480V- 1208/120V rnT T -3B 300KVA 480V- (TT l 208/120V T -26 ll� 300KVA 480V- r-rr i 208/120V T -1B 300KVA 480V- MM 208/120V DP- CPP -7A 800A, 120/208V, 3N, 4W + GND, 42KAIC 800AF 800AT 225AF 225AF 225AF 225AF ?25A "T ) 225AT ) 225AT ) 225AT CPP -7A -1 42KAIC CPP -7A -2 42KAIC CPP -7A -3 42KAIC (FUTURE) SPARE 800AF 800AT DP- CPP -7B 800A, 120/208V, 3N, 4W + GND, 42KAIC 225AF 3 225AT .1 225AT ) 22 CPP -7B -1 42KAIC CPP -7B -2 42KAIC CPP -7B -3 42KAIC (FUTURE) SPARE DP- CPP -6B 800A, 120/208V, 3w, 4W + GND, 42KAIC 800AF 800AT 225AF 225AF 225AF ) 225AT 1225AT ) 225AT CPP -6B -1 42KAIC CPP -6B -2 42KAIC CPP -6B -3 42KAIC (FUTURE) ▪ 225AF 225AT SPARE 800AF 1 800AT DP- CPP -5B 800A, 120/208V, 3N, 4W + GND, 42KAIC 225AF 225AF 225AF T ) 2 ) 225AT CPP -5B -1 42KAIC CPP -5B -2 42KAIC DP- CPP -2B 800A, 120/208V, 3-, 4W + GND, 42KAIC CPP -5B -3 42KAIC (FUTURE) 225AF ▪ 225AT SPARE DP- CPP -4B 800A, 120/208V, 3,-, 4W + GND, 42KAIC 800AF 800AT -) 225AF 225AF 225AF ▪ 225AT ) 225AT NI •N 225AF CPP -4B -1 42KAIC CPP -4B -2 42KAIC CPP -4B -3 42KAIC (FUTURE) SPARE NI 800AF • 800AT DP- CPP -3B 800A, 120/208V, 3,-, 4W + GND, 42KAIC ▪ 225AF -‘ 225AF 225AT ) 225AT .2225AT CPP -3B -1 42KAIC 800AF BOOAT -N 225AF 225AF 225AF 225AF ) 225AT 1 225AT ) 225AT ,) 225AT CPP -2B -1 42KAIC CPP -2B -2 42KAIC CPP -2B -3 42KAIC (FUTURE) SPARE CPP -3B -2 42KAIC CPP -3B -3 42KAIC (FUTURE) -\ 225AF • 225AT SPARE C0 IEE/DpbH. LIANCE WITH NF A�O-NEC JuV0I2010 BUILDING of Tukwila D1VjSlp�� 800AF • 800AT DP- CPP -1B 800A, 120/208V, 3-, 4W + GND, 42KAIC -\ 225AF 225AF 225AF 225AF 225AT ) 225AT -N 225AT ) 225AT CPP -1B -1 42KAIC CPP -1B -2 42KAIC CPP -1B -3 42KAIC (FUTURE) SPARE $$$DESIGN$SPECI FICATION$$$$$$$$$$$$$ REVISION N0,1 ELIo-o (S7 CITY OF�IIIIA MAY `1b 2010 PERMIT CENTER 2 W I- D co O � M CI) O M cna a0 J Q J I- < O J M F- N < www.internap.com z 0 10 J J V W W Q q Q W CL a a) U 03 O W < CD V) W tV Q 2W ca < Lc.) 'S � M � W c')~ Z 0 0 co 0 0 N 1- 0 w 3- ISSUED / REVISED DATE CD SET 03/08/10 REV 1 03/30/10 ESI 2 2 04/30/10 $$$DATE$$$$ $TIME COPYRIGHT 2008 CALLISON SINGLE LINE DIAGRAM EXISTING UPS DIST E712 GENERAL NOTES FIRE ALARM SYMBOL LIST WIRING / EQUIP CONNECT SYMB LIST SINGLE LINE SYSTEM SYMBOL LIST LIGHTING SYMBOL LIST 1. ALL WORK SHOWN IS NEW UNLESS NOTED EXISTING. 2. REMOVE ALL CONDUCTORS, DEVICES, AND CONDUIT RENDERED UNUSED BY THIS PROJECT. 3. VERIFY CIRCUITRY OF EXISTING DEVICES TO BE REMOVED PRIOR TO DEMOLITION AND PERFORM SPLICES AS REQUIRED TO MAINTAIN CONTINUITY OF CIRCUITS TO EXISTING DEVICES TO REMAIN. 4. SEAL ALL CONDUIT PENETRATIONS OF FLOORS AND FIRE RATED ASSEMBLIES WITH U.L. APPROVED MATERIALS AND METHODS TO MAINTAIN FIRE RATING. 5. PROVIDE NEW TYPEWRITTEN DIRECTORIES REFLECTING WORK PERFORMED FOR ALL EXISTING PANELBOARDS MODIFIED BY THIS PROJECT. 6. PROTECT ALL OPENINGS FOR STEEL ELECTRICAL BOXES IN FIRE RATED WALLS WITH U.L. APPROVED MATERIALS AND METHODS TO MAINTAIN THE FIRE INTEGRITY. SYMBOL —LK F—X] 11Q Ell F—LD DESCRIPTION SYMBOL DESCRIPTION SYMBOL DESCRIPTION SYMBOL DESCRIPTION RECESSED WALL FIRE ALARM AUDIO DEVICE, MOUNTED 9" BELOW CEILING, UNLESS NOTED OTHERWISE. 0 CEILING MOUNTED JUNCTION BOX. INTEGRAL KILOWATTHOUR METER. El RECESSED FLUORESCENT LIGHTING FIXTURE. SURFACE WALL FIRE ALARM AUDIO DEVICE, MOUNTED 9" BELOW CEILING, UNLESS NOTED OTHERWISE. JUNCTION BOX, FLUSH MOUNTED AT +18" UNLESS NOTED OTHERWISE. KWH KILOWATTHOUR METER WITH CTS. • RECESSED FLUORESCENT NIGHT LIGHTING FIXTURE, PANEL SWITCHED ONLY. RECESSED WALL FIRE ALARM MANUAL REPORTING STATION, MOUNTED AT +48" AFF. JUNCTION BOX, SURFACE MOUNTED AT +18" UNLESS NOTED OTHERWISE. CURRENT TRANSFORMER. SURFACE MOUNTED FLUORESCENT STRIP LIGHTING FIXTURE. SURFACE WALL FIRE ALARM MANUAL REPORTING STATION, MOUNTED AT +48" AFF. JUNCTION BOX WITH FLEXIBLE CONDUIT CONNECTION. 3 POTENTIAL TRANSFORMER. SURFACE MOUNTED FLUORESCENT STRIP NIGHT LIGHTING FIXTURE, PANEL SWITCHED ONLY. RECESSED WALL FIRE ALARM AUDIO /VISUAL DEVICE, MTD. 9" BELOW CEILING, UNLESS NOTED OTHERWISE. BRANCH CIRCUIT CONDUIT, CONCEALED IN WALL OR CEILING. FUSE. tot EXIT LIGHTING FIXTURE WITH DIRECTIONAL ARROWS INDICATED. DARKENED AREA(S) INDICATES FACE(S) LIT. SURFACE WALL FIRE ALARM AUDIOVISUAL DEVICE, MTD. 9" BELOW CEILING, UNLESS NOTED OTHERWISE. BRANCH CIRCUIT CONDUIT, CONCEALED. IN FLOOR OR UNDERGROUND. FUSED CUTOUT ,❑ POLE MOUNTED AREA LIGHTING FIXTURE. CEILING MTD. FIRE ALARM AUDIO /VISUAL DEVICE. BRANCH CIRCUIT CONDUIT, RUN EXPOSED. FUSIBLE ELEMENT. RECESSED WALL FIRE ALARM VISUAL DEVICE, MID. 9" BELOW CEILING, UNLESS NOTED OTHERWSE. 2# 12, 1/2 "C. 111 II 5# 12, 1/2 "C. CIRCUIT BREAKER. CONTROLS SYMBOL LIST SYMBOL DESCRIPTION SURFACE WALL FIRE ALARM VISUAL DEVICE, MID. 9" BELOW CEILING, UNLESS NOTED OTHERWISE. 111 3# 12, 1/2"c. 111 I I I 6# 12, 1/2"C. SWITCH SWITCH MOUNTED IN SURFACE BOX, +48" UNLESS NOTED OTHERWISE. RECESSED WALL FIRE ALARM BELL. 1111 4# 12, 1/2"C. 1111 I I I 7# 12, 3/4 "C. • 1• TRANSFER SWITCH. SWITCH— RECESSED, +48" UNLESS NOTED OTHERWSE. SURFACE WALL FIRE ALARM BELL DISCONNECT SWITCH, "F" INDICATES FUSED TYPE, MOUNTED AT +54" UNLESS NOTED OTHERWISE. GENERATOR. a,b,c ABBREVIATIONS SUFFIX DESCRIPTION 4S 4" SQUARE BY 2 1/8" DEEP BOX. ADA AMERICAN WITH DISABILITIES ACT. AFF ABOVE FINISH FLOOR. AFG ABOVE FINISH GRADE. AWG AMERICAN WIRE GAUGE. AMP, A AMPERE. A.I.C. AMPERES INTERRUPTING CAPACITY (SYMMETRICAL). AF /AT AMP FRAME, AMP TRIP. AS /AF AMP SWITCH, AMP FUSE. ATS AUTOMATIC TRANSFER SWITCH. AUX AUXILIARY CONTACTS. BR BRANCH. BLDG BUILDING. CIRC., CKT. CIRCUIT. CB CIRCUIT BREAKER. SFD COMBINATION SMOKE FIRE DAMPER. C CONDUIT. C.O. CONDUIT ONLY, COMPLETE WITH PULLSTRING. CONN CONNECTED. CT CURRENT TRANSFORMER. SPST WALL SWITCH. LETTERS INDICATE THE NUMBER OF SWITCHES AND CPT CONTROL POWER TRANSFORMER. OUTLETS THEY CONTROL MOUNTED FLUSH IN BOX AT +48" U.O.N. WALL MOUNTED FIRE ALARM REMOTE TROUBLE ANNUNCIATOR +48" UNLESS NOTED OTHERWISE. MAGNETIC MOTOR STARTER, MOUNTED AT +54" UNLESS NOTED OTHERWISE. TERMINATOR. WALL BOX DIMMER, +48" UNLESS NOTED OTHERWISE. FIRE ALARM OVERHEAD DOOR RELEASE DEVICE. COMBINATION MOTOR STARTER, MOUNTED AT +54" UNLESS NOTED OTHERWISE. APPARATUS BUSHING. REMOTE DIMMER SWITCH, +48" UNLESS NOTED OTHERWISE. FIRE ALARM MAGNETIC DOOR HOLDER. E EMERGENCY SYSTEM CONDUIT. T CONTACT. K KEYED WALL SWITCH, +48" UNLESS NOTED OTHERWISE. FIRE ALARM FLOW SWITCH OUTLET. A ALARM SYSTEM CONDUIT, 3/4" C.O. UNLESS NOTED OTHERWISE. GROUND. MANUAL MOTOR STARTER, +48" UNLESS NOTED OTHERWISE. 0 OA © A FSD FIRE ALARM POST INDICATOR VALVE OUTLET. FA FIRE ALARM SYSTEM CONDUIT. KIRK KEY INTERLOCK. P WALL SWITCH WITH PILOT LIGHT, +48" UNLESS NOTED OTHERWISE. FIRE ALARM TAMPER SWITCH OUTLET. T TELEPHONE SYSTEM CONDUIT, 3/4" C.O. UNLESS NOTED OTHERWISE. SHEET NOTE REFERENCE. SPDT WALL SWITCH, MOMENTARY CONTACT, CENTER MAINTAINED, +48" UNLESS NOTED OTHERWISE. CEILING MOUNTED FIRE ALARM IONIZATION SMOKE DETECTOR. PA PUBLIC ADDRESS SYSTEM CONDUIT. MOTOR. DPST WALL SWITCH, +48" UNLESS NOTED OTHERWISE. CEILING MOUNTED FIRE ALARM ADDRESSABLE IONIZATION SMOKE DETECTOR. INTERCOM SYSTEM CONDUIT. FEEDER SIZE REFERENCE. THREE —WAY WALL SWITCH, +48" UNLESS NOTED OTHERWISE. CEILING MOUNTED FIRE ALARM PHOTOELECTRIC SMOKE DETECTOR. TV TELEVISION SYSTEM CONDUIT. CEILING MOUNTED FIRE ALARM ADDRESSABLE PHOTOELECTRIC SMOKE DETECTOR. D DATA SYSTEM CONDUIT. DRAW —OUT DEVICE. 4 FOUR —WAY WALL SWITCH, +48" UNLESS NOTED OTHERWISE. JUNCTION BOX, FLUSH MOUNTED AT +18" UNLESS NOTED OTHERWISE. FIRE SMOKE DAMPER. G BARE COPPER GROUND CONDUCTOR. CEILING MOUNTED FIRE ALARM HEAT DETECTOR. LV LOW VOLTAGE CIRCUIT. DRAW —OUT MEDIUM VOLTAGE CIRCUIT BREAKER. JUNCTION BOX, SURFACE MOUNTED AT +18" UNLESS NOTED OTHERWISE. CEILING MOUNTED JUNCTION BOX. CEILING MOUNTED FIRE ALARM ADDRESSABLE HEAT DETECTOR. CONDUIT RUN TURNED UP. DUCT MOUNTED SMOKE DETECTOR. CONDUIT RUN TURNED DOWN. TRANSFORMER. JUNCTION BOX PLEX. JUNCTION BOX WITH FLEXIBLE CONDUIT CONNECTION. DH ELECTRO — MAGNETIC DOOR HOLDER. CONDUIT RUN STUBBED OUT. FIREFIGHTERS TELEPHONE OUTLET +52" AFF. UON. BRANCH CIRCUIT HOMERUN WITH PANEL AND CIRCUIT DESIGNATED. FUSED SWITCH. THERMOSTAT OUTLET, MOUNTED AT +60" UNLESS NOTED OTHERWISE. PUSHBUTTON STATION. CEILING MOUNTED FIRE ALARM SMOKE DETECTOR / STROBE DEVICE. XN INDICATES NEW CONDUCTORS IN EXISTING CONDUIT. ANN REMOTE ANNUNICATOR PANEL FLEXIBLE CONDUIT W/ POINT OF CONNECTION. DRAW —OUT FUSED SWITCH. T IT WALL CLOCK /INTERVAL TIMER, MOUNTED AS INDICATED ON PLANS. CONTACTOR. FACP FIRE ALARM CONTROL PANEL • POINT OF CONNECTION. SNAC SECONDARY NAC EXTENDER PANEL CABLE TRAY. TRANSFER SWITCH WITH BYPASS ISOLATION. <8> PHOTOCELL MOUNTED AS NOTED ON PLANS. SOLENOID VALVE. FILE COPY Permit No. ELIDZILIS 1 Plan review approval is subject to errors and omiss. Approval of construction documents does not authorize the violation of any adopted code or ordinance. Receipt of approved F.= Id Copy and I ., + : is acknowledged: a By Date: City Of 1 ikwila BUILDING DIVISION REVISIONS No changes shall be to the scope of work without prior approval of Tukwila Building Division. NOTE: Revisions will require a new plan submittal and may include additional plan review fees. REVIEWED FOR COMPLIANCE WITH NFPA 70 - NEC MAR 15 2010 cN City of Tukwila BUILDING DIVISION POWER SYMBOL LIST SYMBOL Alk CFI .pS •-e DESCRIPTION DUPLEX CONVENIENCE OUTLET MOUNTED IN FLUSH BOX AT +18" UNLESS NOTED OTHERWSE. DUPLEX CONVENIENCE OUTLET MOUNTED IN SURFACE BOX AT +18" UNLESS NOTED OTHERWISE. PANELBOARD. PANELBOARD WITH DOUBLE LUG. PP OCCUPANCY SENSOR POWER PACK AND RELAY INFRARED OCCUPANCY SENSOR. RECESSED WALL SWITCH OCCUPANCY SENSOR. SURFACE WALL SWITCH OCCUPANCY SENSOR. DOUBLE DUPLEX CONVENIENCE OUTLET, +18" UNLESS NOTED OTHERWISE. CONVENIENCE OUTLET W /INTEGRAL GROUND FAULT INTERRUPTER, +18" UNLESS NOTED OTHERWISE. SECURITY SYMBOL LIST U ULTRASONIC OCCUPANCY SENSOR. SYMBOL DESCRIPTION ®DT DUAL TECHNOLOGY OCCUPANCY SENSOR. CONVENIENCE OUTLET WITH INTEGRAL SURGE SUPPRESSOR, +18" UNLESS NOTED OTHERWISE. MAGNETIC DOOR ALARM SWITCH. 0 RELAY. SINGLE CONVENIENCE OUTLET, +18" UNLESS NOTED OTHERWISE. SECURITY KEY PAD. DUPLEX CONVENIENCE OUTLET, TOP HALF SWITCHED, +18" UNLESS NOTED OTHERWISE. ELECTRIC DOOR STRIKE. DIA DIAMETER. DISC DISCONNECT. DIST DISTRIBUTION. E.C. ELECTRICAL CONTRACTOR. EMS ENERGY MANAGEMENT CONTROL SYSTEM. EMT ELECTRICAL METALLIC TUBING. EWC ELECTRIC WATER COOLER. E.P.O. EMERGENCY POWER OFF. EF EXHAUST FAN. FT or ' FEET. FA FIRE ALARM. FLA FULL LOAD AMPS. GRND GROUND. GFCI GROUND FAULT CIRCUIT INTERRUPTER. HOA HAND —OFF —AUTO. HACR HEATING AIR CONDITIONING REFRIGERATION. HVAC HEATING, VENTILATING AND AIR CONDITIONING. HEIGHT, WIDTH, DEPTH, LENGTH. HID HIGH INTENSITY DISCHARGE. HP HORSEPOWER. HPS HIGH PRESSURE SODIUM. IN. or .. INCHES. IG ISOLATED GROUND. JBOX JUNCTION BOX. K DEGREE KELVIN. KAIC KILOVOLT AMPERES AVAILABLE INRUSH CURRENT. KVA KILOVOLT AMPERES. KW KILOWATT. KWH KILOWATT HOUR. L.F. LINEAR FEET. LTG, LTS LIGHTING. LPS LOW PRESSURE SODIUM. MAX. MAXIMUM. MOCP MAXIMUM OVERCURRENT PROTECTION. MCB MAIN CIRCUIT BREAKER. MLO MAIN LUGS ONLY. M METER. M/M METER MAIN. MV MERCURY VAPOR. MH METAL HALIDE. MIN. MINIMUM. MCA MINIMUM CIRCUIT AMPS. MCM THOUSAND CIRCULAR MILS. MFR. MANUFACTURER. MTD MOUNTED. MCP MOTOR CIRCUIT PROTECTOR. MW MICROWAVE. NEC NATIONAL ELECTRICAL CODE. NEMA NATIONAL ELECTRICAL MANUFACTURER'S ASSOCIATION. NC NORMALLY CLOSED. NO NORMALLY OPENED. NF NON— FUSED. NIC NOT IN CONTRACT. NL NIGHT LIGHT. N.T.S. NOT TO SCALE. TELECOMMUNICATIONS SYMBOL LIST � � , NIGHT �w SYMBOL DESCRIPTION DUPLEX CONVENIENCE OUTLET WITH ISOLATED GROUND, +18" UNLESS NOTED OTHERWISE. ELECTRIC DOOR LOCK. TELEPHONE OUTLET, +18" UNLESS NOTED OTHERWISE. FLOOR MOUNTED DUPLEX CONVENIENCE OUTLET. SECURITY SYSTEM CARD ACCESS READER. w WALL TELEPHONE OUTLET, +48" UNLESS NOTED OTHERWSE. CONDUIT MOUNTED DUPLEX CONVENIENCE OUTLET. SECURITY SYSTEM PROXIMITY READER. COMBINATION TELEPHONE AND DATA OUTLET, +18" UNLESS NOTED OTHERWISE. LIB FLUSH FLOOR BOX W/ DUPLEX RECEPTACLE. SECURITY SYSTEM PANIC BUTTON. DATA SYSTEM OUTLET, +18" UNLESS NOTED OTHERWISE. MULTI SERVICE FLUSH FLOOR BOX. WALL MTD PANIC BUTTON. �a D DICTATION SYSTEM OUTLET, +18" UNLESS NOTED OTHERWSE. FLUSH FLOOR POWER SYSTEM FURNITURE FEED. SECURITY CEILING MOUNTED M0110N DETECTOR. WALL MOUNTED TELECOMMUNICATION SYSTEM FURNITURE FEED. CLOCK HANGER OUTLET, MOUNTED AS INDICATED ON PLANS. SECURITY CEILING MOUNTED M0110N DETECTOR — 2 WAY. FLOOR MOUNTED TELEPHONE OUTLET. •-,co SPECIAL PURPOSE RECEPTACLE, +18" UNLESS NOTED OTHERWISE, NEMA CONFIGURATION AS NOTED ON THE PLANS. SECURITY WALL MOUNTED M0110N DETECTOR +96" UNLESS NOTED OTHERWISE. FLOOR MOUNTED COMBINATION TELEPHONE AND DATA OUTLET. WALL MOUNTED POWER SYSTEM FURNITURE FEED. CLOSED CIRCUIT TELEVISION CAMERA. FLOOR MOUNTED DATA SYSTEM OUTLET. MA TYPE "A" SURFACE MTD. MULTI OUTLET ASSEMBLY, MOUNTING HEIGHT AS NOTED ON PLANS. SURFACE MTD CLOSE CIRCUIT TELEVISION CAMERA. POKE THRU DATA SYSTEM OUTLET. SA TYPE "A" SURFACE MTD. METAL RACEWAY, MOUNTING HEIGHT AS NOTED ON PLANS. �4 CCTV CLOSED CIRCUIT TELEVISION OUTLET. FLUSH FLOOR TELECOMMUNICATION SYSTEM FURNITURE FEED. FLUSH MOUNTED BRANCH CIRCUIT PANELBOARD. _Q TV TELEVISION SYSTEM OUTLET, +18" UNLESS NOTED OTHERWISE. TELEPHONE BACKBOARD, SIZE AS NOTED ON PLANS. SURFACE MOUNTED BRANCH CIRCUIT PANELBOARD. D DOOR CONTACT SWITCH. DISTRIBUTION BOARD. REX REQUEST TO EXIT DEVICE. ►� DISTRIBUTION PANELBOARD. SECURITY MONITOR. TERMINAL CABINET. SCP SECURITY CONTROL PANEL GROUND ROD. GLASS BREAK SENSOR. GROUNDING BUS BAR W /MINIMUIN #6 COPPER WIRE TO EQUIPMENT GROUND BUS. 0 RELAY EL\O- 011 $$$DESIGN$SPECI FICATION$$$$$$$$$$$$$ OFCI OWNER FURNISHED, CONTRACTOR INSTALLED. %Z PERCENT IMPEDANCE. PH. or N PHASE. PC PHOTOCELL P POLE. PVC POLY VINYL CHLORIDE. PDU POWER DISTRIBUTION UNIT. PRIMARY OVER 600 VOLTS. PROVIDE FURNISH, INSTALL AND CONNECT. PT POTENTIAL TRANSFORMER. PA PUBLIC ADDRESS. REC, RECEPT RECEPTACLE. REF REFRIGERATOR. RGS RIGID GALVANIZED STEEL RL RUNNING LIGHT. S SINGLE LINE DIAGRAM. SCC SHORT CIRCUIT CURRENT. SFD SMOKE FIRE DAMPER. SQ. SQUARE. STB SHUNT TRIP BREAKER. SU SITE UTILITIES. TC 11MECLOCK. TEL /DATA TELEPHONE AND DATA. TV TELEVISION. T.V.S.S. TRANSIENT VOLTAGE SURGE SUPPRESSION. TYP TYPICAL U.G.P.S. UNDERGROUND PULL SECTION. U.O.N. UNLESS OTHERWISE NOTED. U.P.S. UNINTERRUPTABLE POWER SYSTEM. VAV VARIABLE AIR VOLUME. V VOLTS. RECEIVED VA VOLT AMPERES. VD VOLTAGE DROP. MAR 0 2 2010 WP WEATHERPROOF. W WIRE. XFMR TRANSFORMER. X INDICATES EXISTING TO REMAIN. XR INDICATES EXISTING TO BE REMOVED. XL INDICATES EXISTING TO BE RELOCATED. XN INDICATES NEW LOCATION OF RELOCATED EQUIPMENT. V) 2 J J 0 N co 0 M 0 c+,0 Q U rn Q N 0 1- co Z o H < I- L.L. 877.THE.PNAP Z v- PROFESSIONAL SE www.internap.com l+' Cn w � V � Q U 11 co I— L G7 w I CO W C• < T =W .ca 0_ I—(n— Q 0 Lo M C 1— h 1— Z 0 0 co rn 0 N 1- U w 0 a ISSUED / REVISED DATE PERMIT SET 02/26/10 $$$DATE$$$$ $TIME COPYRIGHT (c) 2008 CAI 1 ISnN SYMBOL LIST GENERAL NOTES E001 uP DT. (FRONT) DT -2 0T-0 USS-1 2500KVA XFMR RI II U SWSD. put Cab (FRONT) GEN ROOM 150 1 (FRONT) USS -2 2500KVA XFMR it (FRONT) 600A 26 IKV UPS MOD-1 LJ FI (FRONT) UPS MOD-2 TTERY -2 ki A 7 I1 ACA (FRONT) CD 1 UNIT SUBSTATION "USS -4 PIER SWIT (FRONT) ATS 01 FRONT cal LL� 1 ZN 1 L3 UPS/4C UPS M00-3 (F NN (FRONT) UPS ROOM 0 0 GEN ROOM 1521 11 1111 \III �I UNIT S mum • LOAD I 1Il! �IlI UPS 1 154 1 n EXISTING 12 "X12 "X60 "H HIGH VOLTAGE PULL BOX EXTEND NEW EXPOSED CONDUIT FROM EXISTING BOX J FE FE 01' 4 0553"426 52x7..452' 212:4 3iS ia!i 1_245524'0 2a2i2MMS :4 ROOM I1Da1 11 FE 33 1ST FLOOR PARTIAL PLAN - POWER SWITCH GEAR ©CJ I=© CD I=EDCD Mme. i C3 CM 11 11 s 1 R WORK IN THIS AREA E SHEET E -114 D 3 EXISTING 6" HV CONDUIT UNDER EXISTING SLAB SECURITY 1 144 33 y _ I 1 = II HARDENED I I13Hi' I 145_1 VEST DEL CORRIDOR 1 146 1 C3 - 3 ET F] COMM I _141 VEST 1 143 I CORRIDOR 1 146 1 \ w fE SPARE BREAKER HUGH VOIIAC LOUD' [-rnil MAIN SWITCHGEAR "MSG2" MEN Lr58- N 1 gt r'i t z A E 3J CORFIDOE LarA FE 3J LUNLR j) /] SEATTLE CITY 11711 LIGHT EXISTING MV SERVICE ELECTRICAL ROOM SECURITY VESTIBULE 1)1 ';IAII) N0. CUSTOMER STAGING 1 1227] mum" 11111111 =1 11III1I1 I SHIPPING RECEIVING 1 122 1 FE a EXISTING UNDER GROUND FUEL TANKS (40,000 GAL EACH) FE 33 E111 SCALE: 1 /16 " =1' -0" 4. NORTH 33 LOADING DOCK 1 123 1 OFFICE 1 121H STOR OFFICE 1 121K 1 33 CONE STOR COP` MAIL CONE 1121DI £LO' oisi 10 REVIEWED FOR COMPLIANCE FA 70 - NEC MAR 15 2010 Cit�l of.TUkW1I BUILDING DIVISION RECEIVED MAR 0 2 2010 PERMIT CENTER CO O y I O cc w� kg W - Z 2 co 4 Qa ZJ J W � 10 Z L ) 1� N 877.THE.PNAP www.internap.com O 0- to co 0 U) 0 0 N • Ld p r7N(n pF pF pc 0Q00 O a W O N U cn > rn co 00 Z w < O 0 LL wZZ• mCC°10� xcnrncn¢a.� Q W W 0 W w ( 2 0 INTERGATE EAST CAMPUS W co m� _ r co L a N . fn — CO Ln Y LL) = M ~ O O ISSUED / REVISED DATE PERMIT SET 02/26/10 TIME CO w G• c 70 CAI R(lN 1ST FLOOR POWER PLAN E111 A15113W) BYPASS� 3GItVl G..YJEID �,I_ 1] ®■ cal LL� 1 ZN 1 L3 UPS/4C UPS M00-3 (F NN (FRONT) UPS ROOM 0 0 GEN ROOM 1521 11 1111 \III �I UNIT S mum • LOAD I 1Il! �IlI UPS 1 154 1 n EXISTING 12 "X12 "X60 "H HIGH VOLTAGE PULL BOX EXTEND NEW EXPOSED CONDUIT FROM EXISTING BOX J FE FE 01' 4 0553"426 52x7..452' 212:4 3iS ia!i 1_245524'0 2a2i2MMS :4 ROOM I1Da1 11 FE 33 1ST FLOOR PARTIAL PLAN - POWER SWITCH GEAR ©CJ I=© CD I=EDCD Mme. i C3 CM 11 11 s 1 R WORK IN THIS AREA E SHEET E -114 D 3 EXISTING 6" HV CONDUIT UNDER EXISTING SLAB SECURITY 1 144 33 y _ I 1 = II HARDENED I I13Hi' I 145_1 VEST DEL CORRIDOR 1 146 1 C3 - 3 ET F] COMM I _141 VEST 1 143 I CORRIDOR 1 146 1 \ w fE SPARE BREAKER HUGH VOIIAC LOUD' [-rnil MAIN SWITCHGEAR "MSG2" MEN Lr58- N 1 gt r'i t z A E 3J CORFIDOE LarA FE 3J LUNLR j) /] SEATTLE CITY 11711 LIGHT EXISTING MV SERVICE ELECTRICAL ROOM SECURITY VESTIBULE 1)1 ';IAII) N0. CUSTOMER STAGING 1 1227] mum" 11111111 =1 11III1I1 I SHIPPING RECEIVING 1 122 1 FE a EXISTING UNDER GROUND FUEL TANKS (40,000 GAL EACH) FE 33 E111 SCALE: 1 /16 " =1' -0" 4. NORTH 33 LOADING DOCK 1 123 1 OFFICE 1 121H STOR OFFICE 1 121K 1 33 CONE STOR COP` MAIL CONE 1121DI £LO' oisi 10 REVIEWED FOR COMPLIANCE FA 70 - NEC MAR 15 2010 Cit�l of.TUkW1I BUILDING DIVISION RECEIVED MAR 0 2 2010 PERMIT CENTER CO O y I O cc w� kg W - Z 2 co 4 Qa ZJ J W � 10 Z L ) 1� N 877.THE.PNAP www.internap.com O 0- to co 0 U) 0 0 N • Ld p r7N(n pF pF pc 0Q00 O a W O N U cn > rn co 00 Z w < O 0 LL wZZ• mCC°10� xcnrncn¢a.� Q W W 0 W w ( 2 0 INTERGATE EAST CAMPUS W co m� _ r co L a N . fn — CO Ln Y LL) = M ~ O O ISSUED / REVISED DATE PERMIT SET 02/26/10 TIME CO w G• c 70 CAI R(lN 1ST FLOOR POWER PLAN E111 WWW.RUBICONPS.COM 111111111111! 4111116-1, INTERNAP* INTERNAP NETWORK SV1 250 WILLIAMS ST., SUITE M- ATLANTA, GA 30303 T 404.302.9700 F 877.THE.PNAP www.internap.com i ,P� 1 a■ ■■■ �m. ��■ ■ l III■1■ ■F��■ ■■■■ ■1 ■■�P33 ■■ ■■I■ ■■■■■ ■ ■ ■■ ■ ■... ■■ ■■■m � ■ ■■ ■ ■i■ ■ ■1 ■■■■�I n • ■�■ -iv= firamorrin------ ■I■ ■ r Hil . _.._._ ■ �ND \ _- ...._. 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' - , Illy ■■ ■■1■ =■ ■ ■ ■1■■■■ ■m ■■ IiA [ �'[1C1M = , .i i, ; mu ■ mai■ ■ ■ ■ter ■ ■ ■ ■ ■■ ■■ ■ ■■ ■■ ■� ■� ■ ■■ ■ � . � RM CALLISON CALLISON www.callison.com ■ ■ ■■ _N_ ■ �F ■� ■E C! I I I I o ?I .1 o > o 0 i- l � im It ■.■ .. ■ ■.■ ■■ ■ ■■ ■■ ■■I■ I ■ m ■ ■ ■ ■� ■ ■. ■ ■ ■� ■ ■ ■I■ PDU ■ I . ■.. ■N PDU "3B2" ■ =,GM■ l■ ■ ■ ■ ■.� ■ ■■ ■ ■ ■■ •■ m. ■■I■ ■1■ ■■ ■■ I1 I ■•u ■ ■E. ■ ■•■ ■■ ■u. ■� I ! €. _....:......._.._..__..�.,._._ _a....._ _ __.... ICI■ I........uu.........�I_._ I ■�■■. ■ ■■ ■ ■■ ■ ■ N ■■■ 1111111111 - _. rr.�rl�ft•I� ■■ i ■MM .1�� Alr•I■t•M �� t ��� ■■ ■ ._ NM ■ ■U•■ . ■■ ■■UUU ■ .■I�■■ ■ ■■■ ■U■ ■■ ■ ■ ■■�■� ■ ■■I IMMIL. ■1 I AIM'S ■■ ■ �I ■■�■ M■.■ IIM / _,._._..__..__,._... — o i- ■■ ■1 ■ --I. �■ _.__. _ _._.,_. - . ■.�J.■ J 1 fru ■ ■t 1 ■ ■ ■ ■■ ■■ m ., . ° ■■ ■.mamma■■ ■ ■■■. ■■ ■Ir AVON MiLlOCIIIV 8 al.001 <: V Mil milm MIIIMMOMMEMM um • m mill m MMINIMMA MN -- 1 ■■I�, ■■■■.li..lr.Wo 11 11 ■EM ■■ ■■ ■ ■■ ■ ■ ■ ■ ■■I ■ MOO ■ 0111� � I■ pm ■■ ■t ■ ■ ■• ■• ■ ■M ■ ■ ■ ■ ■■ 111111111111111 M ■ ■■1 ■■I■ ■I ■■■' ■� ■■ ■ MN ■ uu■ ■ s ■■ ■ ■• ■ • ■•L ■ pi ■1..... If ■ m ■ ■■ ■ ■■■ ■•■ ■�■. -■ t V4. INTERNAP DATA CENTER PHASE III INTERGATE EAST CAMPUS 3355 S. 120th Place Tukwila, WA 98168 c c ; cr i_ ■�_. "3B3" ■�■ U■U ■■ ■• ■ ■ ■■ ■ ■ ■■ ■ ■ ■U ■■ ■■ ■m ■ • DU " is-marr.mui-manui 111111111111111111111111111 OWE U PDU _.e.__..... __ _ _ 1 III III ■ . ■ ■ ■ ■■ ■■ O lr■I■' '■ ■ ■t uu••■u■1 ■Ii1�■�; ■� ■m III ■■ l 1111111111 ■■■ ■ ■�■ ■ ■ ■ ■U ■ ■■1 ■■I u ■ ■m ■UU• ■ ■ 3 e. ■■•u �-.���-�--�-� �.■ ■ --------- kr �\ "367" a P DL ... �.Mw.�_ __ __ . • N'■ ■� !!■ ■ __._ 7 .■ �� _ �.. -_.r -. ■ ■rim 111 ■ ■ ■m i■■■ " _ II i x 11 11111 W ■■�Im�I■r MI ■■iii ■OMM ■■ ■ ■ ■■ I 11■ ■ ■■1■1■ ■■■ ■ ■■ ■ ■■ i Ilii�..i:■■ ■.■ ■..�#■■.■ ■mu■•a. ■rl■ ■■ ��.■.�I.. ■ . ■■m■ ■m ■� . P33-7 PDU ■ ■� ■ ■11■mI■I1 ■11� ■I II ■■■■M■ ■t ■ ■ ■ ■J1 ■ ■■■MU ■ ■■■■■■ ■ ■■ ■■ ■■■mm ■ ■�II ■� ■� ■E ■ ■._ _II. III ■■■ ■� � 1 ■ U■■ �■ EMEM I ■■ I� IU I ■ ■m�' ■l■ q "3a6" ■ ■ ■ ■� ■I■� 1 __ 1 ■I ■II■M■■■■ ■■ ■. ■ ■ ■ 111111101110111111 ■� ■u• ■ ■ _. _ ■ ■ UM ■I■■■ ■I■■ ■, MI ■ ■mI�■■WA .I ■ ■ ■ ■ ■■■ ■:■■■ �� ■MOOS I■■ ■. I GENERAL NOTES ■III■ 11... ■ ■� ■■III mum ■� �� �■11111161 iil t•��.i�i.■I■�■�■..■.■.■.■■..■ !!I ■I 111 MI 1. ROUTE ALL PDU FEEDER UNDER THE RAISED FLOOR. MAKE CONNECTION TO PDU WITH LIQUID TIGHT FLEX. 2. GENERAL BUILDING POWER SHALL NOT BE RUN UNDER FLOOR, ROUTE CONCEALED IN WALLS AND CEILING. I ■■■ ■■ .1111111111 .■ - I -.�.._ ." PDU "�■ "3B4" „, PDU �A7 " PDU ■■ ■ ■ mm ■.■ ■ ■■ ■ ■■m� STA �� '- m. ■ _ .� ini ■ ■ ■ 11"111111111 ■ ■ ■■ ■.m ■ ■ ■■ ■■ • .• �!!P!I ■.� lil� ■■ ■■ - - - ■■ - -� ■■ \ / REVIEWED . FOR COMPLIANCE WITH NEV / N P # ■■ ■■ m a ■■■ __. I ■ ■ ■� ; , ■■ ISSUED 1 REVISED DATE PERMIT SET 02/26/10 ■ ■■ ■■ ■ WIMEMEMMUMI ■11 ■� ■ mlli , ��■ �i� ■ ■■ ■■ ......,..,_..�...�..�. ■■ ■.■ ■ ■ NFPA 70 - ■��i (6 MAR 15 2010 ■`■ ■u■ ._.. ■ (-----;-\\ , \ 7t IUl■■■ •!ii•m••uiuuu•i•uuu_- �■ ■■ ■ ■I ■ ■ ■ ■� ■ ■ ■�' ■ ■l■ ■ ■ •a1 ■ ■■■m■ _.a._. ■•a _ -7 ' • ■■ ■i P33 • NOTES O B S PANEL, PROVIDE DEDICATED NEUTRAL FOR BUILDING DIVISION ■ ■. I ■ I ■■ I _ _ \ Z\ t ■ ■■ ..... • D " ■ ■■■ J �m. ■U■■ ■■ ■_IUU.U.• _ PDU "3B5" I I _ 1 cc RECEIVED �G G�VGD U•Ao- MAR 0 2 2010 HERMIT CENT ��■ ■ ■ ■� ME ■■■ ■■u■1 ■■u■ ■■■ ■■ ■ ■■•■ ■l■ ■■ •■a ■ INIMIMMEIMI ■ ■■ ■ ■■■ ■ I ■ ■ ■I ■•U■ ■••uuu�■ ■•�� �■ 1• ■ ■ ■� ■ • 111 M ■M II 11.111111111111111. ■ ■. • ■■ ■ ■ ■.. ■I■■. ■m� ■■■ ■ ■■ 1 ■ ■ �■r�, I� ■M ■■ ■ 1 ■�� ■� I III i _ ■ ■ ■ ■ ■1 ■ ■.. ""I■■ 1■■ - - - 3RD FLOOR POWER PLAN El12 \ IMMIALmAMMUM , , �,_ / 3RD FLOOR POWER PLAN \\ ></ ■I \ / 1 MEM \ / -7 m. ■1a E112 NORTH FIE... INIMMIEr7 M SCALE: 1/8 " =1' -0" EIMMINIEMMENI i a • iss ___,,, - WWW.RUBICONPS.COM 3 10 4" C.O. TO 3RD FLOOR ELECTRICAL ROOM FOR FUTURE HUMIDIFIER CIRCUITS LIGHT FIXTURE W /PHOTOCELL CONDUIT MOUNTED 24" ABOVE TOP OF RTU P33 -4 (FUTURE) ® ®(FUTL RE) P33 -4 P33-2 P33-2 ON #10, 1 TIME SWITCH AND RECEPTACLE MOUNTED IN WP BOX AT +54" ABOVE ROOF LEVEL Liov- TYP RTU LTG FIX MOUNTING DET SCALE: 1/4".1'-0" 11 PROVIDE NE REFLECT NE - SUPPLY '(HP3 11,33,35 N..FI FLOOR ,_.. _3 ..#1O; .1_-#1O 0, j "C J P33 -4 (FUTL RE) 3" C.O. FOR F RTU UNIT FEET TO ROOM 155 ON 1ST (TYP JI 7) d P33 -401 w (FL TORE) P33-1,4 P3 P3 1 ABEL T EDER 1P33-6 (Fun RE) 1 ELE�SfR 3RD FLOOR ICAL ROOM FOR JMIDIFIER CIRCUIT EXTERIOR LTG SHUT OFF SCHED. DEVICE IT LIGHT FIXTURE WITH PHOTOCELL SWITCH TIME SWITCH SET TO 30 MIN ON, AUTO OFF BATTERY BACK UP NOT REQUIRED, SWITCH PROGRAMMING NOT AFFECTED BY POWER LOSS LITHONIA ACCESSORY # RK1 PEB1 WATTSTOPPER TS -400 L I_ REVIEWED .FOR COMPLIANCE WITH NFPA 70 • NEC 7 w LU LAJ an uJ m Ci E 0 2 w 1— H 2 J J O 877.THE.PNAP www.internap.com 1NTERNAP DATA CENTER PHASE III INTERGATE EAST CAMPUS 3355 S. 120th Place Tukwila, WA 98168 ISSUED / REVISED DATE 0 0 0 ti op 0) 0 N 1- U w 0 a PERMIT SET 02/26/10 MAR 15 2010 PROVIDE NEW LABEL TO REFLECT NEW FEEDER SUPPLY City of Tukwila BUILDING DIVISION • GENERAL NOTES 1. ROUTE ALL CONDUITS FOR RTU'S IN 3RD FLOOR CEILING SPACE. CONDUITS SHALL BE STUBBED UP IN SIDE ROOF CURB. FOR FUTURE UNITS, CAP CONDUITS. RECEIVED MAR 02 2010 PERMITCENTER ROOF POWER PLAN SCALE: 1 /8 " =1' -0" (7) r1' -01/2' l 6' -0• 6' -0' 5-1' 13' -6• 6'4 Y- 101/2' 6'-8 1/16' 6' -O' 15' -1 1/2' 0157 10'...1 1/2' 6`-•2 1/2' ( -8' t t 15-31/2' 1 $$$ DESIGN $SPECIFICATION$$$$$$$$$$$$$ $$$UAI E$$$$ $l IME COPYRIGHTU 2008 CALLISON ROOF POWER PLAN E113 11--w-h7:.40-4._-_10.li'm mil M�� iiiniik-___Ifiiiihnni ="417 (FRONT) USS -1 2500KVA XFMR. #1 600A 26.4KV HV SWITCH INSTALL (6) 3" C.O. FOR PHASE 4 SPARE CONDUIT RISERS DISCONNECT EXISTING FEEDER "ATSLUPSO "� FROM BREAKER Q3BP IN UPS OUTPUT BOARD. BUTT SPLICE NEW CONDUCTORS WITH COMPRESSION CONNECTOR AND INSULATE WITH HEAT SHRINK AND EXTEND TO (FRONT) uypass GEN ROOM lips upY1 (1 -RON f) (FRONT) INPtJI input cab y v y 0 W Q W co O co 0 ¢ H Z —J 1— 0 O ¢ O Z fL d CA CV w 0I CO I- I' N- O 1• O H L www.internap.com mod 1 ctrl DIST BD "DB- UPSBP1" ROUTE CONDUCTORS FROM EXISTING UPS OUTPUT BUS TO DB- UPSBP1 _—: rw� . - _ — 111 1 _ ,11111llilla ' n n a 9 USS -2 2500KVA XFMR. #1 (FRONT) 26 4K HV DISCONNECT FEEDER "FUPi6V0ib" FROM UPS OUTPUT BUTT SPLCE NEW CONDUCTORS WITH COMPRE T ONNECTOR AND INSULATE WITH HEAT i ' I: • "DB- UPSBP1 FER S "MTS- UPS3B" UPS MOD 2 ZuI w ugQ w U SIAC -4 24 "W X48 "D X48 "H PULL BOX WITH WEST SIDE OPEN, MOUNTED ADJACENT TO EXISTING PULL BOX. (FRONT) TERMINATION BUS TEMP GEN TAP - UPS3AA UPS /AC-2 (FRONT) FRONT MANUAIRCI NSER SWITd-1 "MTS- UPS3A" .>4 " moon Kamm INEIMI IIUI�1•' (FROM I ) UI "S MOD -;3 B FFF.RY 3 (!)i I) (FRONT) EXISTING PULL BOX. REMOVE EAST COVER FOR CONNECTION TO NEW PULL BOX. Q J Y 00 Z Cn O a X000 in I W p re) (I) 0 Z tZ W 0 ° NU (n > rn co m 0UE ` -ZWD �(Wnr (ten <a_ BATTERY 4 ATS #1 ATS #3 W/ BYPASS main -1 SERVICE SWBD ats tie main -2 U_ PS ROOM 151_ HP31 -2,4,6 HP31 -} ,10,12 HP31 -17,19 P31 -7 0 4 P31 -1, P31 -11 SUBSTATION "USS -J" P31 -11 P31 -8 P31 -8 SD ?31- 14.16,18 P31 -19 HP31- 20,22,24 P31 -19 HP31 -9,11 GEN ROOM SWITCH GEAR P31 -11 153 L NIT1 SUBSTATION "USS -4" UPS SYSTEM CONTROL CABINET & SYSTEM POWER SECTION • BATTERY 1 UPS MODULE 1 BATTERY 2 UPS MODULE 2 HP31 -1,3 P31 -11 P31 -11 P31 -19 P31 -11 BATTERY 3 UPS MODULE 3 BATTERY 4 UPS MODULE 4 P31 -19 P31 -10 } P31 -12 HP31- 32,34,3 P31 -6 TEMP GEN TAP BOX "TB- MECH3A" TEMP GEN TAP BOX "TB- MECH3B" (10) 3" C.O. FOR FUTURE PHASE 4 DB -UPS4B BYPAS FEEDER P31-4 (10) 3" C.O. FOR FUTURE PHASE 4 DB -UPS4B FEEDER (FRONT) 0 0 (9) 3" C.O. FOR FUTURE PHASE 4 RTU FEEDERS AND PANEL HP4R AT ROOF AND PANEL P43 AT THIRD FLOOR (10) 3" C.O. FOR FUTURE PHASE 4 DB -UPS4A BYPASS FEEDER (10) 3" C.O. FOR FUTURE - PHASE 4 DB -UPS4A FEEDER SWITCH GEAR 155 P31 -2 P31 -19 PANEL "HP31" DISC SW "DS -HP3" DISC SW "DS -P3" XFMR "XFR -P3" PANEL "P31" ELIO- 0157 P31 -19 NOTES Q1 BMS CONTROL PANEL CONNECT TO CIRCUIT SHOWN. PROVIDE DEDICATED NEUTRAL co rn 0 N 1-- U w 0 a Q2 RELOCATE (2) BMS FAN CONTROL PANELS AND (2) 120 MANUAL MOTOR STARTERS TO ADJACENT WALL TO ALLOW NEW DOOR INSTALLATION. INSTALL BOXES AND EXTEND WIRING AS REQUIRED TO ACCOMMODATE NEW INSTALLATION ® CONNECT TO ENGINE JACKET WATER HEATER. ® GENERATOR BATTERY CHARGER, CONNECT CIRCUIT SHOWN. ® FUEL OIL PUMP CONTROL PANEL EXTEND 120V CIRCUITS TO DAY TANK PUMPS AS REQUIRED. REVIEWED FOR COMPLIANCE WITH NFPA 70 - NEC MAR 15 2010 ISSUED / REVISED PERMIT SET DATE 02/26/10 1ST FLOOR ENLARGED POWER PLAN SCALE: 1/8"=1I-0" NORTH City of Tukwila BUILDING DIVISION RECEIVED MAR 0 2 2010 PERMIT CENTER MAC rnnvt�ini 1ST FLOOR ENGLARGED POWER PLAN E114 1 E121 C� C • I -Il -I lowp,M1111111 tIIl I I I III 1111 111*i AIM IIII PLL 1L,1 uur ili IYI�11.).01•0•111 11111111111111111111111101111111 lui'UU 1 li maws mama iii rrrin DT -3 (FRONT) AI s 0 0 .. 6d — 1-H - -- \6d 0 0 6 ROOM (FRONT) ATS #1 1+1 GEN. PARALLELING SWGR, TERMINATION BUS (FRONT) (FRONT) ATS #3 W/ BYPASS FrA USS -1 2500KVA XFMR. #1 GEN ROOM 150 600A 26.4KV HV SWITCH (FRONT) (FRONT) USS -2 2500KVA XFMR. #1 600A 26.4KV HV SWITCH 6f 6f r - • • • (FRONT) main -1 ats SERVICE SWBD ata tie 1 #1 ats maln -2 6d 3 1 [ I i \6d 4 6d 4� �U 6d 4 1 o, I / 0 -1- , / T '� 6d 61 I //1 --- H41 - - - -u *r of "NI 6d 4 6d 3 d 6e 6e /6e \- GENERAL NOTES 4 4 6d I 01 6c 4 9U 6c I I I II J_o 01 6c JE-FF - - 4 3 - _ 4 ....._. 6c H H- / f IE PANEL "L31" C) %l UPS /AC -1 (.) (FRONT) (FRONT) 0 4 0 Op 'I Y,( 6a 6a 4 �.� El upI F IN U1 3/4 SWBD. ats It)NT) I UPS MOD -1 .1- ti��,i� 000 000 000 o° 1 ii1 )1.11. Cali (FI ()I )[ UPS ROOM 151 -- fH 6a - -- - -+H sa -- - lH-fH 6a -• q. t!5 6a 1 (1 =10 NI) FE i__� mod ctrl ss. � , t]y• I I / 1 tpll u ut (FRONT) lift MCI1 -2 000 000 a "ow JP B ITERY -2 II.:I:'C)N? ") iI / /_? t,):4;) :1 I B 1TTERY -4 UI VAC-4 _U 6a 4 6a - -�H� - - - -- - --HH -- N` U 6a 4 6a _.UPS A I I On L- 154 -� -H I1= er-= -�i- -EH-11+ - U 6a 4 /- -- - -- -\ - -�-ftf fib 6 _. 4� U 6b 01 1,4 �— — i 4 SWITCH GEAR N \ 155 0 \\ T �� L31 -4,6 \ I /- -- 411+ - -- ---� -- 4 6b 4 6b �1 6b 01 i4 I [_ -1 1-.__ [ I [::�. -El b \ \ 6b 4 6b 4 )U 6b \%* I \ I -I-H- I- -- 1.1:Hi. 6b }}M 6 1 - 6 4 - 4 1 61 —OS� 1- .1 I: i — — -H }I- — — — — — -. `� — -H �I-�.._— . =..— -∎ 6b e,-d 6b�c�, —� �U 6b OI 18 4 f f1 `4 "0,/ 0,1 1. SEE SHEET E122 FOR FIXTURE SCHEDULE. 2. MOUNT ALL FIXTURES AT +10' AFF. MOUNT FIXTURE TO CHANNEL SUPPORTED FROM STRUCTURE. PROVIDE SWAY CABLE TO PREVENT MOVEMENT. 3. FIXTURES SHOWN AS NIGHT LIGHT SHALL BE UNSWITCHED. PROVIDE DEDICATED NEUTRAL FOR CIRCUIT. 4. SWITCHED FIXTURES SHALL BE CIRCUITED AS SHOWN ON DETAIL 2/E122 5. SET OCCUPANCY SENSORS FOR 30 MINUTE TIME OFF. COMMISSION LIGHTING CONTROL PER WASHINGTON STATE NON RESIDENTIAL ENERGY CODE 1513.7. 1ST FLOOR LIGHTING PLAN SCALE: 1 /8 " =1' -0" 0 xt 4`HI� I II I: NORTH 10 ELc!» ol s7 REVIEWED FOR COMPLIANCE WITH NFPA 70 - NEC MAR 15 2010 City of Tukwila BUILD G DIVISION RECEIVED MAR 02 2010 PERMIT CENTER SUITE M -10 Zv, U CC (04 w J u LU CO 6 0. CC 8 www.internap.com Q CALL /SON www.callisoI 0 W w a NTERGATE EAST CAMPUS 0 0 ISSUED / REVISED PERMIT SET DATE 02/26/10 IME OPYR G" c 2008 • 1ST FLOOR LIGHTING PLAN E121 a 8e 6a 2 FillarmiMen =FM Dim Nummimmommuommimmaiiiir-stotemm ■ 5 ° 2a ° 2a ME 11111 1011 mom Iii_ . .. ms. =am O • ° ° 2a wow 2a • 111111 ���_� ,JAI ■ 1 O ° • II 1 LJ I 2a 2a IM Ci Milli . . Soli 2b iiiiiiiirlowni 2b .I zr .... ....... . ... 0 � ° ° M�I 2b -- 2b -- 2b MI 2b --I= 11111111111111111 111111111111111111111111111111111111111111 MIMI' OS EMINIIIMI■■IIPIrIMMIll . -M Will 2b -- 111111111111.11 —11111 336 --11111--1111111M11111111 1111111111111111111111111111111111111111111111111111I1111111■ ■ ° ° 1 2b 2b ___Iiimidsta ■ -" ° -- ° ..�I ° ■ 1. ........ 1�- 4c..I 4c ■ EN - - -� - -- ..ICI' ..,.......I =1■ ■i_ .... . --IIIIII -- 1 -Fill ■ --- -- ---�-�-- -�r ----- -- U 111m EMI _-- --... � ,... !iNPO Ii --mom 1 mmilm 4d M liallifig ■1■II■■II/IM1�������I p ■1■I o i wo Imo., rim 11■IIg ■II��IN °S �� �`� _ i 4d MIME I■ ■CM■IMI I • MIMI 0 WM 0 ��I�I ll ■Iii�I ■■II 1 M� 4d MEI 4d 111111111m al ■ '�II■■II 111111111111111111111111 W I= I ■MIMIC 111111111111111111111111111111111111111 I_ in - -� �1 c d'e • �- ° -- • --I ■ '-- 41M1111 1-.I 11111111111 EMI IIIIIMIIIMIIIIIIMMIIIIEIIIIIIMIM ■■� =IMOMI a IIE■IIIII MIMI 4 M■■rn ■■IRMI N NMI 1111111111111111111111•111111111111111 NMI 1111111111111111111111MIIIIIM II 11111111111111111 IIIIIIIMIIIII ■ 4e -- 4e MIN MI-- OS -r l.11-N MEM 1 e 1111111111111111 MS ■ ■ 0 IN 0 0 0 - • ■ 1 4e- 4e-- 4e-- 4e n ■ I MIN 1111111=11111M "7 IN Mill I. 0 4e 4e III 2b ° 2b ° ° 2b miniklalp11161:111171LIMIllin ° ■ ° • D\. STAIR #4 I ° ° ale- 14111m1oim1m111111iirli i .�..I. �1�...11 __� _ ■E° °1 • 111 6b 6b I Emiiii1111111111111 ■�' ■- rm�� WA ■� rI ■I■ . rg.. L...■7 NI °I,M�I,r■I_ -. .A�■r■■■■�Irl.l 6b M iii' !irii'r"" 111111.11111111111111111111111111111111 NM am= API ■D■■I■ " LION111 ° ■ ■ ■U■ ° ■ - I*JMN III 111111 III11� I ormiailkimmom All■ ■Iu■•ummii■ ■ ° IMIMPT,111111•11MMIIIIII NM 6c sc �� 6c �� ■_ .11__ _ 111111111111111111111 ! MI ■ ■ ■111■ ° Iu1_ a 6c I 6c MIMI Agnmaimmmil l•iir!��lifiIENi■ . 1 IIII dim ` M Li il.- ■m I immomm • ■ ■■I1 ■■■ U IIIIIIIi • ,�. 1■ I■ 1, ■. Nam • lam oparnimmum itammoimomm • 3 MIME EMI MEM 8d MN IMMIE 3 • o II womPam—Taii Mlawrim. All MR II I 0 I 8d MN WIMEI =ii ■ ■ ■ ■111■ 11111 8d I IN 11111111111 111111.1111111111.1 la 13 1 0 ad IIIIIIIIIIIIIIIIN NMI 0 Mil • i 4 1 1 o O 8d • ° 4e • • !11.1 nr7111111111111111111111111MIal MIll o r1 11111i110MEMMIE ■■ iminlia ME Ell ........ ■�.....■ 8e 3 a 8e • 3 ° IIII %11U■ O I I 8e O 8e LZ 11 10 INTERIOR LIGHTING CONTROL /LOAD SCHEDULE ROOM # OCCUPANCY DESRIPTION SWITCH ID LOCAL AUTO OFF DESCIRPTION LOAD FIXTURE VOLTAGE 1ST FLOOR ELECTRICAL AREA f • ® U ULTRASONIC OCC SENSOR 342 -- 1ST FLOOR ELECTRICAL AREA e 11 --6r9e ® U ULTRASONIC OCC SENSOR OR 114 152 GENERATOR ROOM d *44- ® U ULTRASONIC OCC SENSOR 684 153 SWITCHGEAR ROOM c ♦ ® U ULTRASONIC OCC SENSOR 456 154 UPS ROOM a ♦ -6�9a- ®U ULTRASONIC OCC SENSOR 684 155 SWITCHGEAR ROOM b 58 ®U ULTRASONIC OCC SENSOR 855 333 NETWORK EQUIPMENT ROOM a 944- ® U ULTRASONIC OCC SENSOR 260 333 NETWORK EQUIPMENT ROOM b •--6 ® U ULTRASONIC OCC SENSOR 928 333 NETWORK EQUIPMENT ROOM c S (/f ®U ULTRASONIC OCC SENSOR 754 333 NETWORK EQUIPMENT ROOM d • (4 ® U ULTRASONIC OCC SENSOR 1015 333 NETWORK EQUIPMENT ROOM e e *44 ® ULTRASONIC OCC SENSOR 928 334 ELECTRICAL CLOSET f *409 ® U OULTCC RASONIC SENSOR 116 335 ELECTRICAL CLOSET 9 v ® U ULTRASONIC OCC SENSOR 232 336 NETWORK EQUIPMENT ROOM a tea- ® U OULTRASONOIC CC SENSR 1015 336 NETWORK EQUIPMENT ROOM b •--64- °U U OCC SENSR 1363 336 NETWORK EQUIPMENT ROOM c S-69� ® U OCASOC R 1102 336 NETWORK EQUIPMENT ROOM d S (4 ®U ULTRASONIC OCC SENSOR 638 336 NETWORK EQUIPMENT ROOM e ®U ULTRASONIC 986 LIGHTING FIXTURE SCHEDULE SYMBOL LABEL DESCRIPTION MANUFACTURER # BALLAST ACCESSORIES LAMPS QTY /W /TYPE /COLOR MANUFACTURER FIXTURE VOLTAGE INPUT WATTS 0 2'x4' 3 LAMP FLUORESCENT FIXTURE WITH 18 CELL PARABOLIC LOUVER UTHONIA , 2PM3GB 3 32 18 LD MVOLT GEB10IS ELECTRONIC -- 3 F32T8 3500K 277 V 87 0 v 0 2'x4' 3 LAMP FLUORESCENT FIXTURE WITH 18 CELL PARABOLIC LOUVER AND EMERGENCY BALLAST LITHONIA 2PM3GB 3 32 18 LD MVOLT GEB1OIS EL14 ELECTRONIC EMERGENCY BATTERY PACK 3 F32T8 3500K 277 V 87 • V7 B 2'x2' 2 LAMP FLUORESCENT FIXTURE WITH 9 CELL PARABOLIC LOUVER LITHONIA 2PM3GB 2 U316 9 LD MVOLT GEB10IS ELECTRONIC -- 2 FB32T8 U6 3500K 277 V 58 0 v B 2'x2' 2 LAMP FLUORESCENT FIXTURE WITH 9 CELL PARABOLIC LOUVER AND EMERGENCY BALLAST LITHONIA 2PM3GB 2 U316 9 LD MVOLT GEB101S EL14 ELECTRONIC EMERGENCY BATTERY PACK 2 FB32T8 U6 3500K 277 V 58 • v AEL HID AREA LIGHT SUITABLE FOR CONDUIT MOUNTING WITH PHOTOCELL CONTROL UTHONIA 1WL 70S 120 RK1 PEB1 REACTOR HIGH POWER FACTOR PHOTO CELL KIT 70W HPS 120 85 v 1----(31 D 4' 2 LAMP FLUORESCENT STRIP LIGHT FIXTURE WITH TUBE GUARD LITHONIA UNS 2 32 MVOLT GEB10IS ELECTRONIC -- 3 F32T8 3500K 277 V 58 �� D 4' 2 LAMP FLUORESCENT STRIP LIGHT FIXTURE WITH TUBE GUARD AND EMERGENCY BALLAST LITHONIA UNS 2 32 MVOLT GEB10IS EL14 ELECTRONIC EMERGENCY BATTERY PACK 3 F32T8 3500K 277 V 58 v ® EXIT LIGHT WITH LED LAMPS QM °SIW X G 12zn EL N BACKUP BATTERY LED 277 V 0.66 Q E122 GENERAL NOTES 1. ALL LIGHTING CIRCUITING SHALL BE ROUTED ABOVE CEILING IN CONDUIT. 2. ALL LIGHTING FIXTURES SHALL BE CIRCUITED TO PANEL L33. 3. FIXTURES SHOWN AS NIGHT LIGHT SHALL BE UNSWITCHED. PROVIDE DEDICATED NEUTRAL FOR EACH CIRCUIT. 4. SWITCHED FIXTURES SHALL BE CIRCUITED AS SHOWN IN DIAGRAM 2/E122 5. OCCUPANCY SENSORS SHALL BE SET FOR 30 MINUTE TIME DELAY OFF. COMMISSION LIGHTING CONTROL SYSTEM PER WASHINGTON STATE NON RESIDENTIAL ENGERGY CODE 1513.7 3RD FLOOR LIGH11NG PLAN SCALE: 1 /8 " =1' -0" NORTH MANUAL OFF LIGHT SWITCH OCCUPANCY SENSOR POWER PACK AND SWITCH RELAY allth TO ADDI110 OCC SENSORS TO ADDITIONAL FIXTURES ON SAME SWITCH CIRCUIT AND SWITCH ID X= CIRCUIT NUMBER PANEL L33 y= SWITCH CONTROL • REVIEWED FOR COMPLIANCE WITH NFPA 70 - NEC MAR 15 2010 City of Tukwila BUILDING DIVISION TO ADDITIONAL SWITCHES ON SAME CIRCUIT LTG CONTROL WIRING DIAGRAM NO SCALE ECEIVED MAR 0 2 2010 PERMIT CENTER EL10-- 0 157 I• v•a SUITE M -10 u) 2 J O U, N 8 www.internap.com Q' 0 J CALLISON www.caIllsoI INTERGATE EAST CAMPUS O O I- co rn O N 0 I— U w tY a ISSUED / REVISED DATE PERMIT SET 02/26/10 • TI COP •IGHT O 2008 C LIS N 3RD FLOOR LIGHTING PLAN LTG FIXTURE SCHED E122 1 1 ilmI'� II i I Ni WIC ■ ili it IN 1 ■I.I.I. II. Its IIKY: 6.11111 imam Imo 1 1 I l i WI c �, luIt'U I U i MI•i� NI�iU[M I I I I I I DT -3 (FRONT) EXISTING GROUND BUS "GB -GE DT -1 (FRONT) ATS #1 G GB -GEN3 LLELING SWGR 0 W 0 TERMINATION BUS (FRONT) 1" (FRONT) ATS #3 W! BYPASS x USS -1 2500KVA XFMR. #1 GEN ROOM 150 USS -2 2500KVA XFMR. #1 600A 26.4KV HV SWITCH (FRONT) (FRONT) 600A 26.4KV HV SWITCH • • N • • (FRONT) G 0 ain -1 UIIINGS TO BLDG STEEL STANDBY GERATOI __ ® TO GB -GEN3 r___ ///7 _ 7r0 GB -GEN3 `' 1 STANDBY G RATOV " TO BLDG STEEL TO GB -GEN3 TO BLDG STEEL "GB -GI GROUND BUS "GB -U 3" 3" GEN ROOM 152 r SWBD #1 tie ats TO BUILDING STEE TO BLDG STEEL GB -USS3 UNIT SUBSTATION "US PHAS TO GB -USS3 \ / / (A • \ V TO GB -USS3 B -USS3 T SU:S PHASE 3 ME AN C TO GB -USS3 SWITCH GEAR 153 \ / / TO GB -USS3 V ..i ,. — L u. CONDUCTOR SIZE ‘ti t 1 L_ TO-GB -USS3- 1ST FLOOR GROUNDING PLAN s -- L C C _. Iitip:�s FRONT) (FRONT) iI PONT) UPS MOD-1 11 1 0 [IJ I'MIBD. ats 000 00 (FH(tNl) (1-R. I ) U5-10 (IR()l,r ) UPS ROOM 151 TO BUILDING STEEL GROUND BUS "GB -UPS3" _I 1UPS INUT S BD TO GB UPS3 TO BLDG STEEL PANEL HP3 DIS SW HP3 DIS SW P3 TO BLDG STEEL TO GB UIP BATTERY 1 0 GB -UPS3 TO GB UPS3 r UPS -A1 154 1 BATTERY 3 GROUND BUS "GB —SG3" TO GB SWITCH GEAR 155 X-FkiP3 PANEL P31 EL UPS3 OJ .; itiOC) •1 B 1- iERY-4 - I UPS OUTPUT /SS SW BOARD BATTERY 2 TO GB -UPS3 9 UPS MOD 2 ' TO GB -UPS3 TO GB -UPS3 BATTERY 4 UPS MOD 4 TO GB -UPS3 TO GB -SG3 R 3-4 RTU3 -3 RTU3 -2 R1U3 -1 I...11 C:: :J [111. [1.1 R 3-5 RTU5 -6 RTU5 -8 RT -MECH K TO GB -UPS TS MTS H3B EC TO GB -SG3 DE T \' D -MECH TO GB-7W 3_1 CAC 3-2 ED 1E1 CAC 3-3 CAC 3-4 GB -SG3 TO GB -SG3 DEi. -UP' SB' TO GB -SG3 L E131 SCALE: 1 /8 " =1' -0" NORTH 10 GROUND CONDUCTOR SCHEDULE SYMBOL CONDUCTOR SIZE TYPE © BC #2/0 AWG SRG © BC 500 KCMIL, 1 -h" C SBC © BC #2 AWG, Y4" C SBC 0 BC #4/0 AWG, 1" C GEC G5 BC 1/6 AWG, X" C GEC ® BC #2 AWG, Y4" C GEC © BC #2 AWG, ?" C SGE CO G9 ABBREVIATIONS CONDUCTOR CONDUCTOR CONDUCTOR ELECTRODE CONDUCTOR GRID COPPER BC BARE COPPER GEC GROUNDING ELECTRODE IGC INSULATED GROUND SBC SUPPLEMENTARY BONDING SGE SUPPLEMENTARY GROUNDING SRG SIGNAL REFERENCE STBC SOLID TINNED BARE GENERAL NOTES 1. ALL CONNECTIONS AT GROUND BUS SHALL BE MADE USING TWO HOLE, LONG BARREL COMPRESSION LUG WITH INSPECTION HOLE. 2. ALL CONNECTIONS TO BUILDING STEEL SHALL BE MADE WITH EXOTHERMIC WELD. 3. WHERE AVAILABLE, USE TWO HOLE, LONG BARREL COMPRESSION LUG WITH INSPECTION HOLE TO MAKE MECHANICAL CONNECTION. LOO 157 REVIEWED FOR COMPLIANCE WITH NFPA 70 - NEC MAR 1 5 2010 City of Tukwila BUILDING DIVISION RECEIVED MAR 02 2010 PERMIT CENTER v O T- 2 w I- 877.THE.PNAP www.internap.com Z 0 H V CALL /SON www.callison.com co co co r s Q (V CO L 3 LC) M M ~ 0 O ti CO CT) 0 N 1- U w a ISSUED / REVISED DATE PERMIT SET 02/26/10 1ST FLOOR GROUNDING PLAN E131 11 GB -GEN3 ITO ON 1ST FLOOR s ` ej TO GB -GEN3 BUS TYP OF (14) PDU (fl TO GB -3ER TYP OF (10) PDU ffi TO GB -1ER ff/ TO GB -1 ER IiA I F RI]UM EPO z w Z 117 EXISTING G I EL [XiS I ING ELECTRICAL RUUM >y O 1 O H > H cl 0 OH >w 0 O H T •30• V i001' VA B T -1B 11 1 1E1'01 'DI 13E i chi I S "GB -1ER" I TO GB -1ER TO GB -1ER NOTES 10 ELOD ls`7 Q1 MOUNT GROUND BUS BELOW RAISED FLOOR, 12" ABOVE SLAB. 0 MOUNT GROUND BUS 24" ABOVE RAISED FLOOR. REVIEWED FOR COMP RCN WITH MAR 15 2010 City of Tukwila BUILDING DIVISION 3RD FLOOR GROUNDING PLAN RECEIVED MAR 02 2010 PERMIT CENTER SCALE: 1/8"71'-0" NORTH 877.THE.PNA uw.internap.c Q Z co) 0 J v w U) 2 INTERGATE EAST CAMPUS U NCO co Q CV CO CD 7 M ~ ISSUED / REVISED DATE PERMIT SET 02/26/10 TIME COPYRI TO 2008 S•" 3RD FLOOR GROUNDING PLAN E132 CID i1IP_L_. rl a 11ii1mia. I 1 I �1 1 NI ■I�1■ IND11111111 ,.�.� ■I■I ■I■ R 1 DT -3 (FRONT) DT -2 DT -1 o_ LU w C.9 TERMINATION BUS (FRONT) USS -1 2500KVA XFMR, #1 GEN ROOM 150 600A 26.4KV HV SWITCH (FRONT) (FRONT) USS -2 2500KVA XFMR. #1 600A 26.4KV HV SWITCH 1 (4)" C.O. TO 3RD FLOOR ELECTRICAL ROOM FOR FUTURE PHASE 4 SKRU CONTROL AND EPO -4 WIRING • • inl t l I 11N I ■I ■I•11 STANDBY GEAERATOF _0 " (FRONT) ATS #1 (FRONT) ATS #3 WI BYPASS (FRONT) Hain -1 SERVICE SWBD #1 ats tie ats main -2 2 # 12, )" C TO EPO -3 ON 3RD FLOOR STANDBY GARATOr ll! 0 1111 " STANDBY GERATQfi _® r GEN ROOM ` 152 h— CZI UVIT SUBSTATION "USS PHASF 3 UPS UP TO DB -UPS3A FOR SKRU CONTROL UP TO DB -UPS3B FOR SKRU CONTROL 71 U tL UPS' U LL UPS /A C. 2 3 12, )¢" C TO EPO -3 ON 3RD FLOOR SWITCH GEAR 153 U NIT SUBSTATION "USS -4" PHASE 3 MFCHANICAI. 7 •\01 r L -I i L L PANI I t st L3 DIS SW L3 MEN NEM IV= J UP 1 1ST FLOOR SIGNAL PLAN �F EXISTING DOOR SECURITY PANEL EXISTING FIRE ALARM PANEL ...il i WJ on 1 ups ul, l ' IN UT SWDD ?14 ats b pass up 1/2 (1=t4.0111 (FRONT) .....{..._-______. UPS MOD -1 joit,„1:1 1 B1"1EI Y -.1 (FRONT) ._ 0000 UPS MOD-3 o, B TTERY -,3 12 "X12 "X4" TEL /DATA PULLBOX input cab rnodJtrl (FRONT) (FRONT) UPS MOD -2 000 s -s. B ,TT _: RY -2 utpul UPS /AC -3 1 1 \I UC{'SIAC -4 (FRONT) (FRONT) UPS MOD -4 1 r (FRONT) UPS ROOM I 151 I B TTERY 1-\,, ..1..)11 1I UPS OUTPUT/SS S HOARD I.-r(' ... MOD ,1_ • )3 O� I0 ggg (4)" C.O. TO 3RD FLOOR ELECTRICAL ROOM FOR FUTURE PHASE 4 SKRU CONTROL AND EPO -4 WIRING • • inl t l I 11N I ■I ■I•11 STANDBY GEAERATOF _0 " (FRONT) ATS #1 (FRONT) ATS #3 WI BYPASS (FRONT) Hain -1 SERVICE SWBD #1 ats tie ats main -2 2 # 12, )" C TO EPO -3 ON 3RD FLOOR STANDBY GARATOr ll! 0 1111 " STANDBY GERATQfi _® r GEN ROOM ` 152 h— CZI UVIT SUBSTATION "USS PHASF 3 UPS UP TO DB -UPS3A FOR SKRU CONTROL UP TO DB -UPS3B FOR SKRU CONTROL 71 U tL UPS' U LL UPS /A C. 2 3 12, )¢" C TO EPO -3 ON 3RD FLOOR SWITCH GEAR 153 U NIT SUBSTATION "USS -4" PHASE 3 MFCHANICAI. 7 •\01 r L -I i L L PANI I t st L3 DIS SW L3 MEN NEM IV= J UP 1 1ST FLOOR SIGNAL PLAN �F EXISTING DOOR SECURITY PANEL EXISTING FIRE ALARM PANEL ...il i WJ on 1 ups ul, l ' IN UT SWDD ?14 ats b pass up 1/2 (1=t4.0111 (FRONT) .....{..._-______. UPS MOD -1 joit,„1:1 1 B1"1EI Y -.1 (FRONT) ._ 0000 UPS MOD-3 o, B TTERY -,3 12 "X12 "X4" TEL /DATA PULLBOX input cab rnodJtrl (FRONT) (FRONT) UPS MOD -2 000 s -s. B ,TT _: RY -2 utpul UPS /AC -3 1 1 \I UC{'SIAC -4 (FRONT) (FRONT) UPS MOD -4 1 r (FRONT) UPS ROOM I 151 I B TTERY 1-\,, ..1..)11 1I UPS OUTPUT/SS S HOARD I.-r(' ... MOD ,1_ BArEF Y.1_ )3 UPS OUTPUT/SS S HOARD I.-r(' ... MOD ,1_ BArEF Y.1_ )3 t; z, MOD 3 BATTERY Y 3 )3 1 PMCt-11P3 DIS SW HP3 ]DIS SW P3 r P3 PANEL P31 NNE SWITCH GEAR 155 1 UPS -A 154 BAIILRY 2 UPS MOD 2. BAIILRY 4 H11.0- 4 I411.15 a 81113 2 RTt13 -1 MIS MTS MECH3I3 MECI°13A 8111,1 -5 R1u5- ti R1U5 - -8 R1U5 -10 CONNECT TO RTU BREAKERS SHUNT ,( TRIP, WIRE IN SERIES • tIAC 3 -1 AC .1 -- 2 Q � D I AC 3 -3 CAC 3 -4 DE -UPSE3 )3 —i MECH3I3 DB- MECH3A tIAC 3 -1 AC .1 -- 2 Q � D I AC 3 -3 CAC 3 -4 DE -UPSE3 )3 )4" C.O. TO DOOR SECURITY PANEL )¢" C.O. REX 10 REX LOCATED ON INTERIOR SIDE OF DOOR )¢" C.O. TO DOOR POSITION CONTACT )Z" C.O. TO DOOR JAMB FOR DOOR LOCK OR STRIKE REVIEWED FOR COMPLIANCE WITH NFPA 70 - NEC MAR 15 2010 City of Tukwila BUILDING DIVISION E141 SCALE: 1 /8 " =1' -0" NORTH LlOO I57 TYP DOOR SECURITY DETAIL SCALE: NTS NOTES 314" C.O. TO EXISTING DOOR SECURITY PANEL THIS FLOOR. AT EACH CARD READER LOCATION PROVIDE BOXES AND CONDUIT SHOWN ON DETAIL 2/E141 Q2 34" C TO TEL/DATA PULLBOX THIS FLOOR, (2) CAT5e CABLES IN CONDUIT TO PNAP EQUIPMENT ON 3RD FLOOR Q3 3i" C TO TEL /DATA PULLBOX THIS FLOOR, (1) CAT5e CABLE IN CONDUIT TO PNAP EQUIPMENT ON 3RD FLOOR. ® 1 -)¢" C TO PNAP EQUIPMENT ON 3RD FLOOR, ROUTE (8) CAT5e CABLES FROM OUTLETS IN CONDUIT. RECEIVED MAR 02 2010 PERMIT CENTER e dot ce LAI los SUITE M -10C 2 J 0 w� 877.THE.PNAP www.internap.com >: —I Y CO Q Z CL In 00 0 tr) IU W p N NU z U) > o) co m OU O Z co LC) 0 tZ'U)N)(nQD_'s l+ W Z W V 'c Q W INTERGATE EAST CAMPUS 0 0 ti 0 rn 0 N I- U LU 0 0 ISSUED / REVISED DATE PERMIT SET 02/26/10 • TIM C S. YR 'T O 2008 A 1ST FLOOR SIGNAL PLAN E141 6 9 10 U) www.internap.com 0 cn CALL /SON www.callison.com a a. w 0 INTERGATE EAST CAMPUS PROJECT # 209871 ISSUED / REVISED DATE PERMIT SET 02/26/10 3RD FLOOR SIGNAL/SECURITY PLAN E142 E) -I • A, wr (Th r C.O. TO EPO-4 o ' ME Miii • • MMUMBIENN M MEMONEMNIIMMEMM ''. 0 • EPO - \/0 )( / 111. I NE mom MN •MIME MN Num 11111011111111111111 ....mmlim I 01110211111111111111101111111.1111111 Lim LIELI 11 ' EXISTING EPO CONTROL PA_NiE3L, 111 III In 111 mom I III • IMMIMMINMOMMINIIIIIINginE MEM •mmummaimummu r. " I • •II 1 E I I._ , MIMI 1— 1 •orammimillaimml MU iiMEMEIMIUMni ii \\,,/ x , , I . IN im - • Pr , m .. ME Mill • „ _ . _ _ .. .1 _._ , LL_ __,_ . ti EOM • NM MEM= 011111 MMINIMMIN •II . 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'-iimm MOM MEM MINI • mom NUMMI IIMIMIIIIMIIMIIIIMMII 111111111111111111061111111111111 III •IIIMIIIMII MIMI NM im ' ---- NM - - -I IIIIM INIIII ri •I III 1 II I , LIIELI ii ii i ME INN Rs DU . -D I I 'I 111111111111111111111111111111.111 111111111111 ENE • NEEMEINE MU= ImmEmmil 1111.11111111111011.6111111r" NMEMIEMPIN MI •=MEM mmummimmma MIME mia nu milimErnii 111 1111110111111 111111111111 • EMU •MM • MOM 7 1- HIE dEd--- I 1 I g ll En 11111 III r,,, K 1 STAIR C X, EIMMIEMMIMMIMMI IMMIll OM II 111 a M M 1 I 11 1 -I mal SCP SCP FACP #4 u9c1- ( •III g MO= 1 ---7 XISTING FACP -- mill.111111110111111 ...A.110111 MI a • •MI . - EXISTING SECURITY ir r---;'\\ Fl MN 11111111111111111111111111 U P • IIMMININIMMINIM IA i [ PANELS • IIII IIINIMIIIIIIIIIIIMIIIIIIIIIII 111161111.0 MUM ..., MS II MIN 11111111111•11111 .. 1111111111111111111 Mk MIME Elk 11111111111111111 NM Elm I I •1111 1 I NM NOM , / , L_ .t \ II STAIR #3 DN. 0 EIVED ANN Mal ilillIMINIMIN Ira 1 NM NMI NMI MEN •MI 11111111111111111 ;,_ ,Ti...rtip II RE [ I II • iNFBPA :70 mil Imo muraTiam - NEC MAR 1 5 2010 MAR o 2 2010 PERMIT CENTER 1101111 I 1111 II IIII 111111111111111111. III 1111111111111MIN IMI •II IM NEI III NM OM NM •NMOM MN= IMO 111.11 • • • MI I i City of ,Tukvfilit 1111111111117 'I IIIIIIIIIIIIII r-,--------- , \ , \ , , , ---------_-_-„- \/ ' 1 3RD FLOORMML-Pat'URITY mum MIME mum. PLAN IMM • , 1 Nummumn. A E142 NORTH in M•M , Z N • SCALE: 1/8".1'-0" 111111111111111111111111111 I NI is 1 I NI I U) www.internap.com 0 cn CALL /SON www.callison.com a a. w 0 INTERGATE EAST CAMPUS PROJECT # 209871 ISSUED / REVISED DATE PERMIT SET 02/26/10 3RD FLOOR SIGNAL/SECURITY PLAN E142 EPO MAINT. MODEI PHENOLIC LABEL, WHITE LEI I ERS ON RED BACKGROUND M.H. 56" I EMERGENCY SHUTDOWN - POLYCARBONATE ALARMED COVER STI MODEL #1100R PROVIDE NUMBER PER PLAN REMOVABLE COTTER PIN, CHAIN ATTACHED 4" SQUARE STAINLESS STEEL PLATE FLUSH 120V, 10A, 2 POLE HEAVY DUTY, NEMA -1 PUSHBUTTOM ALLEN - BRADLEY TYPE 800H WITH #800H -N140 LOCKING COVER E.P.O. PUSH BUTTON DETAIL NO SCALE EPO -3 CONTROL PANEL 1OA 120V (EMERGENCY, NON UPS) MAINT0 R10 ARM TE sT° is R103 0 0 SYSTEM RESET R103 o,Ko EPO STATION WITH COVER AND KEY RELEASE PUSHBUTTON (TYP.) WIRING TERMINAL (TYP.) R101 0i10 oRo R101 R103 8101 LATCH Oro R101 E0 UNLATCH R102 LATCH 4 R102 UNLATCH 10 a °b—ab 10 TEST RELAY O R102 R102 I I 0 0 DBUPS3A BKR SHUNT TRIP PDU 3A1 - 3A5 R102 I I O 0 DBUPS3B BKR SHUNT TRIP PDU 3B1 - 3B5 R102 I I R102 R102 O 0 DBMECH3A BKR SHUNT TRIP RTU 3 -1 TO 3 -5 O 0 DBMECH3B BKR SHUNT TRIP RN 3 -1 TO 3 -5 R102 0 X 0 0 X 0 FIRE SMOKE DAMPER EPO ACTIVATED POWER CIRCUIT ALARM TO BMS 0 0 SPARE R102 O K' 0 SPARE R102 O ,�' 0 SPARE FOR EPO CABINET "EPO -4" PROVIDE CABINET AND INTERNAL DEVICES AND WIRING ONLY. EPO BUTTONS AND WIRING TO EXTERNAL DEVICES INSTALLED IN FUTURE. EPO CONTROL CABINET SCHEMATIC (TYPICAL) SCALE : NONE EPO POWER ON L EPO ARMED EPO ACTIVATED EPO TEST MODE TEST OK SURFACE MOUNTED NEMA 1 RELAY CABINET, SIZE AS REQUIRED MOUNTING HEIGHT AT 5' -0" A.F.F. TO TOP MOMENTARY SPST PUSH BUTTON ENGRAVED PHENOLIC NAMEPLATES (TYP.) ZONE NAME PER SCHEMATIC HINGED FRONT COVER MODE SELECTOR SWITCH (KEY OPERATED) E.P.O. CONTROL PANEL DETAIL (TYPICAL) NO SCALE (PROVIDE EPO CONTROL PANEL FOR EACH ZONE) COORDINATE EXACT LOCATION IN THE FIELD. SEQUENCE OF OPERATION AN EMERGENCY POWER OFF (E.P.O.) SHALL BE PROVIDED FOR ALL COMPUTER EQUIPMENT AREAS. THE SYSTEM SHALL BE CONTROLLED FROM AN EPO CONTROL PANEL. E.P.O. CONTROL PANEL 1. POWER TO THE ECP SHALL BE SINGLE PHASE 120 VAC PROVIDED FROM A STANDBY POWER SOURCE. A WHITE INCANDESCENT LIGHT ON THE ECP SHALL INDICATE POWER IS AVAILABLE. ALL COMPONENTS; RELAYS, PUSHBUTTONS, ROTARY SWITCHES, PILOT LIGHTS...SHALL BE INDUSTRIAL GRADE BY SQUARE D. OR ALLEN BRADLEY. PROVIDE CONTACTS ON RELAYS AS NEEDED PLUS TWO SPARES EACH (MINIMUM). 2. THE ECP SHALL BE CAPABLE OF OPERATING IN THREE MODES, "ARMED" 'TEST" AND "MAINTENANCE'. OPERATIONAL MODE SHALL BE SELECTED FROM A KEY OPERATED SELECTOR SWITCH. STATUS OF THE SWITCH POSITION SHALL BE REPORTED TO THE BMS SYSTEM. a. ARMED MODE b. C. A WHITE INCANDESCENT LIGHT ON THE ECP SHALL ILLUMINATE WHEN THE ECP IS PLACED IN ARMED MODE. DEPRESSING AN E.P.O. STATION'S RED, PUSHBOTTON SWITCH SHALL CAUSE THE FOLLOWING: RED INCANDESCENT LIGHT(S) ON THE ECP SHALL ILLUMINATE INDICATING AN E.P.O. SWITCH HAS BEEN ACTIVATED AND AC /UPS UNITS HAVE BEEN SHUT DOWN. "THE E.P.O. ACTIVATED" RELAY SHALL BE ENERGIZED AND SHALL SEND A SIGNAL TO THE BUILDING MONITORING SYSTEM AND SHALL ENERGIZE THE ASSOCIATED SHUT DOWN RELAY(S) IN THE ECP PANEL. CONTACTS FROM THE HVAC AND UPS SHUT DOWN RELAYS WITHIN THE RELAY PANELS SHALL SERVE TO ACTIVATE THE AFFECTED ZONE'S REMOTE EPO CONTACTS WITHIN UPS UNITS AND AIR CONDITIONERS WHICH SERVE THE DATA CENTER. THE ECP'S RED INDICATOR LIGHT(S) SHALL REMAIN ACTIVE UNTIL ALL EPO PUSHBUTTONS HAVE BEEN RESTORED TO THEIR NORMAL STATE BY MEANS OF A KEY RELEASED MECHANISM AND THE ECP'S RESET PUSH BUTTON IS DEPRESSED. TEST MODE PLACING THE MODE SELECTOR SWITCH IN THE TEST POSITION SHALL CAUSE THE TEST RELAY TO ACTIVATE. THE ACTIVATION OF ALL TEST RELAYS SHALL CAUSE AN AMBER INCANDESCENT LIGHT ON THE ECP TO ILLUMINATE. WHEN THE ECP IS PLACED IN TEST MODE, ALL ASSOCIATED SHUNT TRIP FUNCTIONS ARE DISABLED BY MEANS OF TEST RELAYS, THIS MODE ALLOWS THE E.P.O. PUSHBUTTON STATIONS TO BE TESTED WITHOUT REMOVING POWER TO THE ZONE. WHEN AN E.P.O. STATION IS ACTIVATED. THE "E.P.O. ACTIVATED" RELAY SHALL BE ENERGIZED. THE 'E.P.O. ACTIVATED" RELAY SHALL SEND A SIGNAL TO THE BUILDING MONITORING SYSTEM AND SHALL ENERGIZE THE ASSOCIATED SHUT DOWN RELAY(S) IN THE ECP PANEL. ALTHOUGH ON THE ECP SHALL BE ILLUMINATED BY THE SHUNT TRIP RELAY, INDICATING PROPER SYSTEM OPERATION (TEST OK). MAINTENANCE MODE A GREEN INCANDESCENT LIGHT ON THE ECP SHALL ILLUMINATE WHEN THE ECP IS PLACED IN MAINTENANCE MODE. WHEN THE ECP IS PLACED IN MAINTENANCE MODE, ALL E.P.O. STATIONS, SHUNT TRIP FUNCTIONS AND TEST FUNCTIONS ARE DISABLED. THIS MODE ALLOWS FOR SERVICE TO THE E.P.O. SYSTEM WITHOUT RISK OF ACCIDENTAL POWER LOSS TO THE ZONE. E.P.O. STATION 1. E.P.O. STATIONS SHALL BE LOCATED AS INDICATED ON THE PLANS. 2. E.P.O. STATIONS SHALL CONSIST OF THE FOLLOWING COMPONENTS: a. RED, PUSHBUTTON WITH NORMALLY OPENED CONTACTS. THE PUSHBUTTON SHALL LOCK IN THE DEPRESSED POSITION THE PUSHBUTTON SHALL BE RELEASED TO ITS NORMAL STATE BY MEANS OF A KEY RELEASE MECHANISM. b. HINGED PUSHBUTTON COVER WITH SAFETY PIN AND HINGED LEXAN COVER GUARD TO PROTECT PUSHBUTTON STATION FROM INCIDENTAL CONTACT BY PERSONNEL OR EQUPMENT. 3. EPO STATIONS SHALL BE LOCATED IN THE FIELD AS DIRECTED BY ENGINEER /OWNER. 4. PROVIDE "STOPPER II" COVER PLATES ON ALL STATIONS. MODEL STI- 1100 -Y (S.TI -PHONE 248 - 673 - 9898). 10 F:zjoolS1 FOR REVIEWED COMPLIANCE WITH NFPA 70 - NEC MAR 15 2010 City of Tukwila BUILDING DIVISION RECEIVED MAR 02 2010 PERMIT CENTER u v > w r Ua Z 0 w 0 0 N- rn N 0 0 H IL 877.THE.PNAP www.internap.corn r —J CO 0 Cr) Z O PI) 07) 3 in 1 U) 0 o rn ~i N 0 p w 0 N (!> >_ rn cO Ed zO O Z W l+ E 0 Zi U 0 A o J w J ca 0 V 3 3 3 INTERGATE EAST CAMPUS 00 CO _ r 0- 00 a) a N (0 — LO LID M 0 a co rn 0 N 4t I-- U W 0 0. ISSUED / REVISED DATE PERMIT SET 02/26/10 TIM COPY G 018 A EPO DIAGRAM E501 E.P.O. ZONE CONTROL PANEL - X ra EPO POWER ON TEST ri EPO ARMED ARM MAINT la EPO MAINT. MODE) al EPO TEST MODE MODE SELECTOR SWITCH la EPO ACTIVATED iii RESET la TEST OK ENGRAVED PHENOLIC NAMEPLATES (TYP.) ZONE NAME PER SCHEMATIC HINGED FRONT COVER MODE SELECTOR SWITCH (KEY OPERATED) E.P.O. CONTROL PANEL DETAIL (TYPICAL) NO SCALE (PROVIDE EPO CONTROL PANEL FOR EACH ZONE) COORDINATE EXACT LOCATION IN THE FIELD. SEQUENCE OF OPERATION AN EMERGENCY POWER OFF (E.P.O.) SHALL BE PROVIDED FOR ALL COMPUTER EQUIPMENT AREAS. THE SYSTEM SHALL BE CONTROLLED FROM AN EPO CONTROL PANEL. E.P.O. CONTROL PANEL 1. POWER TO THE ECP SHALL BE SINGLE PHASE 120 VAC PROVIDED FROM A STANDBY POWER SOURCE. A WHITE INCANDESCENT LIGHT ON THE ECP SHALL INDICATE POWER IS AVAILABLE. ALL COMPONENTS; RELAYS, PUSHBUTTONS, ROTARY SWITCHES, PILOT LIGHTS...SHALL BE INDUSTRIAL GRADE BY SQUARE D. OR ALLEN BRADLEY. PROVIDE CONTACTS ON RELAYS AS NEEDED PLUS TWO SPARES EACH (MINIMUM). 2. THE ECP SHALL BE CAPABLE OF OPERATING IN THREE MODES, "ARMED" 'TEST" AND "MAINTENANCE'. OPERATIONAL MODE SHALL BE SELECTED FROM A KEY OPERATED SELECTOR SWITCH. STATUS OF THE SWITCH POSITION SHALL BE REPORTED TO THE BMS SYSTEM. a. ARMED MODE b. C. A WHITE INCANDESCENT LIGHT ON THE ECP SHALL ILLUMINATE WHEN THE ECP IS PLACED IN ARMED MODE. DEPRESSING AN E.P.O. STATION'S RED, PUSHBOTTON SWITCH SHALL CAUSE THE FOLLOWING: RED INCANDESCENT LIGHT(S) ON THE ECP SHALL ILLUMINATE INDICATING AN E.P.O. SWITCH HAS BEEN ACTIVATED AND AC /UPS UNITS HAVE BEEN SHUT DOWN. "THE E.P.O. ACTIVATED" RELAY SHALL BE ENERGIZED AND SHALL SEND A SIGNAL TO THE BUILDING MONITORING SYSTEM AND SHALL ENERGIZE THE ASSOCIATED SHUT DOWN RELAY(S) IN THE ECP PANEL. CONTACTS FROM THE HVAC AND UPS SHUT DOWN RELAYS WITHIN THE RELAY PANELS SHALL SERVE TO ACTIVATE THE AFFECTED ZONE'S REMOTE EPO CONTACTS WITHIN UPS UNITS AND AIR CONDITIONERS WHICH SERVE THE DATA CENTER. THE ECP'S RED INDICATOR LIGHT(S) SHALL REMAIN ACTIVE UNTIL ALL EPO PUSHBUTTONS HAVE BEEN RESTORED TO THEIR NORMAL STATE BY MEANS OF A KEY RELEASED MECHANISM AND THE ECP'S RESET PUSH BUTTON IS DEPRESSED. TEST MODE PLACING THE MODE SELECTOR SWITCH IN THE TEST POSITION SHALL CAUSE THE TEST RELAY TO ACTIVATE. THE ACTIVATION OF ALL TEST RELAYS SHALL CAUSE AN AMBER INCANDESCENT LIGHT ON THE ECP TO ILLUMINATE. WHEN THE ECP IS PLACED IN TEST MODE, ALL ASSOCIATED SHUNT TRIP FUNCTIONS ARE DISABLED BY MEANS OF TEST RELAYS, THIS MODE ALLOWS THE E.P.O. PUSHBUTTON STATIONS TO BE TESTED WITHOUT REMOVING POWER TO THE ZONE. WHEN AN E.P.O. STATION IS ACTIVATED. THE "E.P.O. ACTIVATED" RELAY SHALL BE ENERGIZED. THE 'E.P.O. ACTIVATED" RELAY SHALL SEND A SIGNAL TO THE BUILDING MONITORING SYSTEM AND SHALL ENERGIZE THE ASSOCIATED SHUT DOWN RELAY(S) IN THE ECP PANEL. ALTHOUGH ON THE ECP SHALL BE ILLUMINATED BY THE SHUNT TRIP RELAY, INDICATING PROPER SYSTEM OPERATION (TEST OK). MAINTENANCE MODE A GREEN INCANDESCENT LIGHT ON THE ECP SHALL ILLUMINATE WHEN THE ECP IS PLACED IN MAINTENANCE MODE. WHEN THE ECP IS PLACED IN MAINTENANCE MODE, ALL E.P.O. STATIONS, SHUNT TRIP FUNCTIONS AND TEST FUNCTIONS ARE DISABLED. THIS MODE ALLOWS FOR SERVICE TO THE E.P.O. SYSTEM WITHOUT RISK OF ACCIDENTAL POWER LOSS TO THE ZONE. E.P.O. STATION 1. E.P.O. STATIONS SHALL BE LOCATED AS INDICATED ON THE PLANS. 2. E.P.O. STATIONS SHALL CONSIST OF THE FOLLOWING COMPONENTS: a. RED, PUSHBUTTON WITH NORMALLY OPENED CONTACTS. THE PUSHBUTTON SHALL LOCK IN THE DEPRESSED POSITION THE PUSHBUTTON SHALL BE RELEASED TO ITS NORMAL STATE BY MEANS OF A KEY RELEASE MECHANISM. b. HINGED PUSHBUTTON COVER WITH SAFETY PIN AND HINGED LEXAN COVER GUARD TO PROTECT PUSHBUTTON STATION FROM INCIDENTAL CONTACT BY PERSONNEL OR EQUPMENT. 3. EPO STATIONS SHALL BE LOCATED IN THE FIELD AS DIRECTED BY ENGINEER /OWNER. 4. PROVIDE "STOPPER II" COVER PLATES ON ALL STATIONS. MODEL STI- 1100 -Y (S.TI -PHONE 248 - 673 - 9898). 10 F:zjoolS1 FOR REVIEWED COMPLIANCE WITH NFPA 70 - NEC MAR 15 2010 City of Tukwila BUILDING DIVISION RECEIVED MAR 02 2010 PERMIT CENTER u v > w r Ua Z 0 w 0 0 N- rn N 0 0 H IL 877.THE.PNAP www.internap.corn r —J CO 0 Cr) Z O PI) 07) 3 in 1 U) 0 o rn ~i N 0 p w 0 N (!> >_ rn cO Ed zO O Z W l+ E 0 Zi U 0 A o J w J ca 0 V 3 3 3 INTERGATE EAST CAMPUS 00 CO _ r 0- 00 a) a N (0 — LO LID M 0 a co rn 0 N 4t I-- U W 0 0. ISSUED / REVISED DATE PERMIT SET 02/26/10 TIM COPY G 018 A EPO DIAGRAM E501 MOUNTING IN P U PANEL 3A1B 208/120 VOLTS 3 PHASE 4 'WM VOLT AMPS 0 A OB 0 C DESCRIPTION B. L 0 L MAIN 225 A B B. C I C I R K 0 L E 10,000 A.I.C. SYM BUS 225 A L B. C DESCRIPTION VOLT AMPS OA OB OC 2000 CABIN ET 2 30 A 30 2 CABIN ET 2000 2000 ET 2 30 3 B 4 30 2 CABINET 2000 1000 CABIN ET 20 5 C 6 20 CABINET 1000 2000 CABINET 2 30 7 A 30 2 CABINET 2000 2000 CABINET 2 30 9 10 CABINET 2000 1000 CA3INE 20 11 C 12 20 CABINET 1000 2000 CABINET 2 30 13 A 14 30 2 CABIN ET 2000 2000. CABINET 30 15 16 30 2 CAB IN El 2000 1000' CABINET 20 17 18 20 CABINET 1000 2000 CABINET 2 30 19 A 20 30 2 CABINET 2000 2000 CABINET 2 30 21 22 30 2 CABIN ET 2000 000 CABINET 20 23 C 24 20 CABINET 1000 2000 CABINET 2 30 25 A 26 2 CABINET 2000 2000 CABINET 2 30 27 B 28 30 2 CABINET 2000' 1000 CABINET 20 29 C 30 20 CABINET 1000 Spare. 2 30 31 A 32 30 2 Spare Spare 2 30 33 B 34 30 2 Spare Spare 20 35 C 36 20 Spare Spare 2 30 37 A 38 30 2 Spare Spare 2 30 39 B 40 30 2 Spare Spare 20 41 C 42 20 Spare 10000 10000 5000 VA/LINE 10000 10000 5000 0A— 20000 007, :20000 C= 10000 CONTINUOUS LOA IgOZKONTINIJOLISLOADS 50000 x125= 62500 UP TO IOWA 'RECER TA !CLES REMAINDER x1.00= 0.50= OTHEIt x1.00= TOTAL DESIGN kVA= 63 TOTAL DESIGN AMPS= 173 OWNER FURNISHED EQEUIPMENT. TYPICAL FOR EACH "B" PANEL IN PDU'S. LOADS SHOWN ARE FOR BASIS OF DESIGN, BRANCH CIRCUITING FROM PDU TO FUTURE EQUIPMENT NOT IN CONTRACT. MOUNTING IN PDu 208/120 VOLTS 3 FIJA SE 4 PANEL 3A WIRE IC MAIN 22$ A 10,000 A.I.C. SYM BUS 225 A VOLT AMPS OA 0B OC DESCRIPTION B. E C L I 0 1, K K I B. I B. K 0 L L R B C DESCRIPTION VOLT AMPS OA �:B 0 C 2000 CABIN ET 2 30 30, 2 CABINET 2000 2000 CASINO" 3 4 30 CABINET 2000 1000 CABINET 20 5 20 CABINET 1000 2000 CABINET 2 30 A 30 2 CABINET 2000 2000 CABINET 2 30 10 30 .2 CABINET 2000 1000 CABINET 20 11 C 12 20 CABINET 1000 2000 CABINET 2 30 13 A 14 2 CABINET 2000 2000 CABINET 2 30 15 B. 16 30 2 CABINET 1000 CABINET 20 17 18 20 1 CABINET 2000 1000 2000 CABINET 2 30 19 A. 30 2 CABIN ET 2000 2000 CABINET 2 30 21 30 2 CABIN ET 2000 1000 CABINET 20 24 20 CABIN ET 1000 2000 2000 CABINET CABINET 2 2 1 000 CABINET 30 30 20 25 27 29 A B 26 30 30 30 20 2 2 CABINET CABINET 2000 2000 1 CABINET 1000 Spare 2 30 31 A 32 30 Spare. Spare 2 30 30 2 Spare Spare 20 35 36 20 Spare Spare 2 30 37 A 38 30 2 Spare Spare 2 30 39 B 40 30 2 Spare Spare 20 41 42 20 Spare 10000 113000 5000 VA/LINE 10000 10000 5000 0 A= 20000 �B= 20000 10000 CONTINUOUS LOA DS NON-CONTINLTOUS LOADS 50000 x1.25= 62500 UP TO 10 kVA RECEPTA'CTPS: REN11:AINDER. x1.00= x0.50= OTHER TOTAL DESIGN kVA= 63 TOTAL DESIGN AMPS= 173 OWNER FURNISHED EQUIPMENT. TYPICAL FOR EACH "C" PANEL IN PDU'S. LOADS SHOWN ARE FOR BASIS OF DESIGN, BRANCH CIRCUITING FROM PDU TO FUTURE EQUIPMENT NOT IN CONTRACT. MOUNTING IN POU PANEL 3AID 208/120 VOLTS 3 PHASE 4 WIRE MAIN 225 A 10,000 ALC. SYM BUS 25A VOLT A MPS �A �B �C DESGPIPTION B. 0 B. B. 0 B. DESCRIPTION VOLT A MPS 0A �B 0C 2000 CABIN ET 2 30 30 2 CABIN ET 2000 2000 CABINET 2 3 4 30 2 CABINET 2000 1000 CABIN ET 20 5 6 CA1311‘IET 1000 2000 CABIN ET 2 30 A 30 CABINET 2000 2000 CABIN ET 2 30 I 0 30 2 CABINET 2000 1000 CABINET 20 11 20 CABINET 1000 2000 CABIN ET 2 30, 13 A 2 CABIN ET 2000 2000 CABIN ET 2 30, 15 30 2 CABINET 2000 I 000 CABINET 20 17 18 20 CAINEJ 1000 CABINET 2 19 20 30 2 CABIN ET 2000 2000 CABIN ET 2 30 21 22 30:: CABIN ET 2000 too CABINET 23 24 20 CABIN ET 000 2000 CABIN ET 2 30 25 A 26 30 2 CABINET 2000 000 CABINET 2 30 30 CABINET 2000 1000 CABIN ET 20 29 20 CABIN ET 1000 Spare 2 30 31 A 32 30 2 Spare Spare 2 30 33 34 30 2 Spam Spare:: 35 36 Spare: Spare:: 2 30 37 A 38 30 2 Spare Spare 2 30 39 40 Spare 20 41 42 20 Spare 1 0000 10000 5000 VA/LINE 10000 10000 5000 A= 0000 �B= 20000 C= 10000 -Ci3NTiStIOTI8 LOADS : NON-CONIDRIOUS LOADS 50000 x11.25= 62500 VOTOJOAVIk RECEPTACLES_ .REMAINDa. x0.50= OTHER x1 .0C TOTAL DESIGN :kV . A= 63 TOTAL DESIQN AMPS= 173 OWNER FURNISHED EQUIPMENT. TYPICAL FOR EACH "D" PANEL IN PDUIS. LOADS SHOWN ARE FOR BASIS OF DESIGN, BRANCH CIRCUITING FROM PDU TO FUTURE EQUIPMENT NOT IN CONTRACT. ING MOUNT208/120 S SURFACE PHA SE 4 PwiREANET , P31 10,000 10,000 A.I.0 . SYM BUS 226 A MAIN VOLTS 3 225 A DESCRIPTION VOLT AMPS DESCRIPTION R ET : L GER P O LK B C 1 R B K REGC C 1 R H KL RE P O L T GC R E DESCRIPTION VOLT AMPS OA OB OC OA OB OC 1200 IRM 336, SG1 BAT CH GR 1 1 24 1 A 2 20 1 4 ROOF RECiLTG BMS PANEL 100 1260 1200 R M 336 8G2 BAT CH GR 1 1 20 B B 4 20 1 4 ROOF REC/LTG BMS PANEL 1060 100 '1440 1200 SG3 BAT CH GR 1 1 20 5 C 6 20 1 4 ROOF RFC/LTG B MS PAN EL 1060 100 100 RIO 333 BMS PANEL 1 1 20 7 A 8 20 1 HUM/3-1 FSD. 600 1260 100 R M 333 13MS PAN EL 1 1 20 9 B 10 20 1 H.0 M/3-4 SWOR BAT CH GR 864 1200 1080 1260 •GEN/SWGR RM 7 1 1 20 11 c 12 20 1 HU M/3-5 SWGR BAT CH GR 864 1200 1200 RM 334/335 DAY TANK PUMP 1 20 13 A 14 20 1 HUM/3-2 Spare 250 1200 EPO PANEL DAYTANK PUMP 1 1 20 15 B 16 20 1 FILI M/3-3 Spare 864 250 1200 DAYTANK PUMP j 1 20 17 C 18 20 1 Spore Spare 100 1260 BMS PANEL •U PS/SWGR Ft M 7 1 1 20 19 A 20 20 1 Spare Spare 100 BMS PM EL 1 1 20 21 B 22 20 1 Spare Spare Spare 1 20 20 23 C 24 20 1 Spare Spare Spare 1 I 20 25 A 26 20 1 Spare Spare Spare 1 1 20 27 B 28 20 1 Spare Spare Spare Spare 1 1 20 29 C 30 24 1 Spare Spare Spare Spare 1 1 20 31 A 32 20 1 Spare Spare Spare Spare 1 1 20 33 B 34 20 1 Spare Spare Spare Spare 1 1 20 35 C 36 20 1 Spare Spare Spare Spare 1 1 20 37 A 38 100 3 Spare PANEL 'P33 5768 Spare Spare 1 1 20 39 B 40 - - Spare 5658 Spare Spare 1 1 20 41 C 42 - - Spare 4694 3760 2500 3660 VA LINE 6468 6958 5994 0 A= 10228 0W: 9458 0 C= 9654 CONTINUOUS LOA DS NON-CONTINUOUS LOADS 2320 xL25 = 2900 UP TO 10 kVA RECEPTACLES REMAINDER UP TO 10 kVA RECEP TA CIES REMAINDER 10000 x1.00= x0.50= 10000 OTHER OTHER 14420 x1.00 14420 2600 1300 TOTAL DESIGN kVA= 16 TOTAL DESIGN AMPS= TOTAL DESIGN kVA= 29 TOTAL DESIGN AMPS= 79 MOUNTING 208/120 SURFACE PAIN EL PHA SE 4 wIRE MAIN P33 10,000 A.I.C. SYM BUS 100 A VOLTS 3 LO. VOLT AMPS DESCRIPTION R ET CIDER L P 0 LK B C I R C I R B K REGC O LT L R E DESCRIPTION VOLT AMPS OA OB OC 0 A 0 B 0 C 1260 IRM 336, 7 1 20 1 A 2 20 1 4 4 ROOF RECiLTG 1Q60 1260 R M 336 7 1 20 3 B 4 20 1 4 4 ROOF REC/LTG 1060 '1440 RM 33 8 1 20 5 C 6 20 1 4 4 ROOF RFC/LTG 1060 1260 RIO 333 7 1 20 7 A 8 20 1 HUM/3-1 864 1260 R M 333 7 1 20 9 B 10 20 1 H.0 M/3-4 864 1080 RM 333 6 1 20 11 C 12 20 1 HU M/3-5 864 360 RM 334/335 2 1 20 n A 14 20 1 HUM/3-2 864 250 EPO PANEL 1 20 15 B 16 20 1 FILI M/3-3 864 250 EPO PAN EL j 20 17 C 18 20 1 Spore 100 BMS PANEL 1 20 19 A 20 20 1 Spare 100 BMS PM EL 1 20 21 B 22 20 1 Spare Spare 1 20 2• C 24 20 1 Spare Spare 1 20 25 A 26 20 1 Spare Spare 1 20 27 B 28 20 1 Spare Spare 1 20 29 C 30 20 1 Spare Spare 1 20 31 A 32 20 1 Spare Spare 1 20 33 B 34 20 1 Spare Spare 1 20 35 C 36 20 1 Spare Spare 1 20 37 A 38 20 1 Spare Spare 1 20 39 B 40 20 1 Spare Spare 1 20 41 C 42 20 1 Spare 2980 2870 2770 VA:LINE 2788 2788 1924 0 A= 5768 0 B= 5658 0 C= 4694 CONTINUOUS LOA DS NON-CONTINUOUS LOA DS 1220 x125= 1525 UP TO 10 kVA RECEPTACLES REMAINDER 10000 x1,00= x0.50= 10000 OTHER 4820 xl.00 4820 80 40 TOTAL DESIGN kVA= 16 TOTAL DESIGN AMPS= 45 MOUNTING IN PIU 208/120 VOLTS 3 PANEL 3A1A PHASE 4 WIRE MAIN 225A 10000 A.I.C. SYM BUS 225A VOLT AMPS �A B 0C DESCRIPTION B. a 0 R. B. 0 B. DESCRIPTION VOLT AMPS OA OB C 2000 CABIN ET 2 30 A 30 2 CABINET 2000 2000 CABIN ET 2 30 3 4 30 2 CABINET 2000 1000 CABIN ET 20 5 6 20 CABINET 1000 2000 CABINET 2 30 7 A 8 30 2 CABINET 2000 2000 CABIN ET 2 30 9 10 30 2 CABINET 2000 1000 CABINET 20 11 12 20 CABINET 100 2000 CABIN ET 2 30 13 A 14 30 2 CABINET 2000 2000 CABINET 2 •30 15 16 30 2 CABINET 2000 1000 GAM FT 20 17 18 20 CABINET 1000 2000 CABINET 2 30 19 A 20 30 2 CABINET 2000 2000 CABIN ET 2 30 21 22 30 2 CABINET 2000 1000 CABINET 20 23 24 20 CABINET 1000 2000 CABIN ET 2 0 25 A 26 30 2 CABIN ET 2000 2000 CABINET 2 30 27 28 30 2 CABINET 2000 1000 CABINET 20 29 30 20 1 CABINET 1000 Spare 2 30 31 32 30 2 Spare Spare 2 30 33 34 30 2 Spare Spare 1 20 35 36 20 Spare Spare 2 30 37 A 38 30 2 Spare Spare 30 39 40 30 2 Spare Spare 20 41 42 20 Spare 10000 10000 5000 VA LINE 10000 10000 5000 OA= 20000 �B= 20000 C= 10000 CONTINUOUS LOADS NON-CONTINUOUS LOADS 50000 x1,25= 62500 UP TO 10 WA RECEPTACLES REMAINDER x1.00= x0.50= OTHER x1 .0C.= TOTAL DESIGN kVA= 63 TOTAL DESIGN AMPS= 173 OWNER FURNISHED EQUIPMENT. TYPICAL FOR EACH "A" PANEL IN PIXI'S. LOADS SHOWN ARE FOR BASIS OF DESIGN, BRANCH CIRCUITING FROM PDU TO FUTURE EQUIPMENT NOT IN CONTRACT. 10 MOUNTING SURFACE PANEL L31 480/277 VOLTS 3 PHASE 4 WIRE. MAIN 100 A 14000 Ai SYM BUS 10 A VOLT AMPS OA �B DC DESCRIPTION B. L. 0 B. R. 0 1. B. DESCRIPTION VOLT AMPS 0A �B �C Spare 20 A 20 Spare Spare 20 4 20 48 IstFLRNL 2736 1 Spare 20 5: 6 20 55 1 st FLR LTG Spare 7 8 20 Spare 3135 Spare 20 10 20 Spare Spare 20 11 12 20 Spare Space 13 A 14 Space Space 15 16 Space Space 17 18 Space Space 19 A 20 Space Space 21 22 Space Space 28 24 Space Space 25 A 26 Space Space 27 28 Space Space 29 30 Space Space 31 A 32 Space Space 33 34 Space Space 85 36 Space Space 37 A 38 100 PANEL *L33' 6379 Space 39 40 4751 Space 41 42 2320 VA/LINE 6379 7487 5455 �A= 6379 013= 7487 C= 5455 CONTINUOUS LOADS mil.coNTINuousLoADs 19321 x1.25= 24161 UP TO 10 kVA RECEITIA CLES REMAINDER OTHER x1.0 TOTAL DESIGN kVA= 24 TOTAL DESIGN AMPS= 29 MOUNTING SURFACE PANEL 480/277 VOLTS 3 PHASE 4 win L33 14,000 A.I.C. SYM BUS 100 A VOLT AMPS OA OB C DESCRIPTION B. a 0 B. 0 B. DESCRIPTION VOLT AMPS OA 0B C 2058 RA/13361%1i_ 20 A 20 1 RM 336 LTG 2378 2025 RM 334 ML 20 20 RM 336 LTG 2726 Spare 20 20 RM 334 LTG 2320 Spare 20 A 20 PIM 334 LTG 1943 Spare 20 9 10 20 Spare Spare 20 1 12 20 Spare Spare 13 A 14 Spare Spare 15 16 Spare Spare 17 18 Spare Spare 19 A 20 Spare Spare 21 22 Spare Spare 23 24 Spare Spare 25, 26 Spa Spare 28 Spare Spare 29 30 Spare Spare 31 A 32 Spare Spare 33 34 Spare Spare 35 36 Spare Spare 37 A 38 Spare Spare 39 Spare Spare 41 42 Spare 2058 2025 �A= 6379 VAILINE 4321 2726 2320 B= 4751 �C= 2320 CONTINUOUS LOADS NON-CONTINUOUS LOADS 13450 x125-= 16813 1:V.!'17010: kVA RECEPTACLES REMAINDER x0.50= OTHER TOTAL DESIGN WA= 17 TOTAL DESIGN AMPS= 20 MOUNTING SURFACE PANEL HP31 480/ VOLTS 3 PHASE 3 WIRE MAIN 30,000 Y BUS 22M5 A VOLT AMPS �A 013 C DESCRIPTION B. II 0 B. B. a. B. DESCRIPTION VOLT AMPS �B 0j0 3000 801 INTR 111.11 2 20 A 2 2 3 TH3T-1 42 3000 Sal WIR HUI 3 4 942 3000 SG1 WTR HTR 2 20 5 3000 SG1 VVTR I-1TR A 8 20 3 TF/312 942 3000 502WER-1TR. 2 2 10 942 3000 802 WTR.HTR 11 12 942 3000 802 WFR HTR 2 20 13 A 14 20 3 TF/31.1-1 3878 3000 802 tAITR HTIR 15 13 16 3878 3000 SG3 Will IITR 2 17 18 387 3000 SG3 WFR HTIR A 20 20 3 TF/311-2 3878 3000 SC3WUR FITR 2 20 21 22 3878 3000 SG3 WTR HTR 28 24 3878 6814 DC/3-1 3 35 25 26 2 3 IF/S-1 443 814 27: 28 443 6814 DC/3-2 Spare Spam Spare 25628 25628 25628 VA/LINE 0A= 36154 O B.= '3.0154 CONTINUOUS LOADS NON-CONTINUOUS LOADS 44BEVIEWED FOR COMPLIANCE WITH NFPA 70 - NEC 443 MAR 1 5 2010 10526 10526 C= 36154 ri5:51i 7t ity of Tukwila DING DIVISION 40885 x1.25= 51107 UP TO 10 kVA RECEPTACLES REMAINDER x0.50= OTHER TOTAL DESIGN kVA= 119 TOTAL DESIGN AMPS= 143 tim•-to 0151 ME 67578 xl .00= 676 CRE EIVED MAR 02 2010 PERMIT CENTER CO YR 2008C I 0 Co a. 877.THE.PNAP Www.internap.cam 0 INTERGATE EAST CAMPUS CNI LU —3 0 Cl ISSUED / REVISED DATE PERMIT SET 02/26/10 PANEL SCHEDULES E600 DISTRIBUTION BOARD MEC T3B LOAD STOMA Y kVA Load Coot Other Totals PA NEL P31(REDUNDANT) PANEL P31 (REDUNDANT) PANEL L31 (REDUNDANT) RTU 31 DUNDAN COMP CIRCUIT 1 COMP CIRCUIT 2 CONDENSE: E.. FANS SUPPLY FAN RETURN FAN CONTROL CIRCUIT RTU 3-2 (REDUN] .ANT) RTU 3 -3 (REDUNDANT)' RTU 3 (REDUNDANT) RTU 3 -5 (REDUNDANT) CAC 3- 1 (REDUNDANT) CAC 3 -2 (REDUNDANT) CAC 3 -3 (REDUNDANT) CAC 3-4 (REDUNDANT), :RTU 5 -6 (REDUNDANT)'. RTU 5 -8 (REDUNDANT) RTU 5 -10 (REDUNDANT) Sub Total kVA 25% of Largest Motor kVA Total kVA 480 V SB UPS 3 - LOAD S MARY kVA Load Cont Rec Other Total* UPS 3 -1 866.7 866.7 1043 UPS 3 -2 866.7 866.7 1? UPS 3 -3 866.7 866.7 1043 UPS 3-4 (REDUNDAN [)(BAT C14 113.0 113.0 136 SubTotal 2,713. WA. 25% ofLargest Motor kVA Total, 2713.2 kVA *SYSTEM 100% RATED 3263.5 Amps at 480 V DB UPS3B - LOAD SUMMARY kVA Load Cont Rec Other Total *' PDU 3B1(REDUNDANT): PDl7 3B2 (REDUNDANT). PDU 3133 (REDUNDANT) PDU 3B4 (REDUNDANT) PDU 3B5 (REDUNDANT) PDU 3B6 (REDUNDANT). PDU 3137 (RF.DUNLIANT)! SubTotal kVA. 25'% ofLargest Motor. kVA Total kVA *SYSTEM 100% RATED 480" V PDU" 3 -LO.D STJ 1M AIRY kVA Load Coot Rec Other Total PANEL, 3131Ai (REDI< CANT) PANEL 3B 1B (REDUNDANT): PANEL 3B 1C (REDUNDANT); PANEL 3B 1D ;(REDUNDANT) SubTotal kVA 25% ofLargest M of or kVA Total' kVA 208 V INFIRM TTTION BOARD MECH3A - LOAD SUMMARY kVA Load Co ►t Other Total PANEL HP31 40.9 67.6' 118.7 143 PANEL P31 2,3 12.6 14.4 28.6 34 PANEL L31' 19=3 24.2 29 R'T'U 3 -1 (SINE PC T FEED) COMP CIRCUIT 1 86.8 94.0 113 COMP' CIRCUIT 2 86.8 94.0 113 CONDENSER FANS 19.9 20A 24 St PPLYFAN 71.5 89.3 107 RETURN FAN 49.0 61.3 74 CONTROL CIRCUIT 2. 0 2.0 RTU 3-2 316.0 333.8 402 RTU 3-3 316.0 333.8 402 RTU 3-4 316.0 333.8 402 3 -5 (REDUNDANT) 3 -1 38.2 42.2 51 CAC 3 -2 38.2 42.2 5 1 CAC 3 -3 38.2 42.2. 1 CAC 3-4 (REDUNDANT) RTU 5 -6 215.3 223.6 269 RTU 5 -8 215.3 223.6 269 RTU i -10 (REDUNDANT) SubTotal 62.5 12.6 1,891 1980.6 WA 25% ofLargest Motor 17.9 kVA Total 1998.4 kVA 2403.7 Amps at 480 V DB UPS3OUT' - LOAD SUMMARY kVA Load Coat' Rec Other Total* A DB UPS3A 2,132' 2,132 2564 DB UPS3B SubTotal 2,132 2,132 kVA 25% ofL€trgest Motor kVA Total. 2131.6 kVA *SYSTET 4 100% RATED 2563.9 Amps a 480 V DB TJPS3,AJ - LOAD SUMMARY kVA Load. Coat Other Total* A PDU 3A1 200.0 200.0 241 PDU 3A2 240.0 240.0 289 PDU 3A3 240.0 240.0, 289 PDU 3A4 240.0 240.0 289 PDU 3A5 240.0 240.0 289 PDU 3A6 240.0 240.0 289 PDU 3A 7 240.0 240.0 289 FUTURE 491.6 491.6 591 SubTotal 2,132 2,132 kVA 25% ofLargest otor WA Total 2131.6 kVA *SYSTEM 100% RA `1LD. 2563.9 Amps at 480 V PDU 3A1 -LOAD SUMMARY kVA Load Coat Rec Other Total. PANEL 3AIA 50.0 62.5 173 PANEL 3AIB! 50:0 62.5 173 PANEL 3AIC 50.0 62.5 173 PANEL 3AID 50.0 62.5 173 SubTotal 200.0 250.0 kVA 25% of Larges t Motor WA Total 250.0 kVA 693.9 Amps at 208 V 10 FEEDER SCHEDULE LE TAG ;' # RUNS CONDUIT PHASE CONDUCTORS NEUTRAL GROUND F -HV 3#410 AWG 1 #110 AWG F -4000 10 3' V 3 #800 KC M IL 1 #500 KCMI L F -3000 3 #500 KC MIL 1 #500 KCMI L F -2500 3 #600 KCMIL 1 #350 KCMIL F- 2000 3 #600 KCMIL III #250 KCMIL F-1600 3 #600 KCMI L 1 #4/0 AWG F -1200 3 #600 KCMIL 1 #3/0 AWG F -8 00 3't, 3 #600 KC M IL 1 #1/0 AWG F-600 2 112" 3 #350 KCMIL 1 #1 AWG F -500 3 #250 KCMIL 1 #2 AWG F -450 3 #600 KCMIL 1 #2AWG F -400 2 112 3 #500 KCMIL 1 #3 AWG F-300 1 2 1 /2" 3 #350 KCMIL 1 #4 AWG' F -225 3 #410' AWG 1 #4 AWG. F -225 N 2 1/2" #410! AWG 1 #4/0 AWG 1 #4 AWG F -125 1 1/4" 3 #1 AWG 1 #6 AWG. F -100 ............... 114" 3#2AWG 1 #8 AWG F -100 N 1 �4". 3##2AWG 1 #2 AWG 1 #8 AVVG F-400000 10 F- 300000 F -HVCO F -45000 EL�O -0 �5`i REVIEWED FOR COMPLIANCE WITH NFPA70 - NEC MAR 15 2010 City of Tukwila BUILDING DIVISION RECEIVED MAR 02 2010 PERMIT CENTER 0 w I- D � M 0 H co �o M cn< J < J 1- < 9 J N <1.1 I- LL 0 0 ti 0) N 0 M 0 www.internap.corrm J Y 00 Z rY rn O o_ pr) 00 0 O W 0 inNU) LC5 "31 cc 0 <oo° D- w00NU (i) >rn com ©0 t-Li]ix f wZZ . m�°lg0� Q PHASE II aft INTERGATE EAST CAMPUS 0 0 N. co 0 0 CV I- U w 0 ISSUED / REVISED DATE PERMIT SET 02/26/10 FEEDER SCHEDULE LOAD SUMMARY E700 GEN #8 2,250KW FUTURE -62/ FUTURE GEN SWBD. "SB -SG3" I 480V, 3PH, 3W + GND, 4000A BUS, 100AIC �\ 4000AF \i// 4000AT T T-\ 4000AF 4000AT A\ 4000AF I/ 4000AT GEN #7 2,250KW FUTURE k 4000AF 4000AT L L T (PPE) STANDBY GEN #6 2,250KW -,4000AF 4000AT BUSSED TAP BOX 4000A 3PH 4000AF Ni; 4000AT - - - -I-- -r 100AF " I/ 100AT 3000AF r i 1' 3000AT LJ FUTURE I I LOAD BANK I I TAP BOX "TB -LB4" I L 3000A T- - -�-1 4000AF �/ 4000AT I/ T� 4000AT 4000AF (PPE) F -40001 rI F -40001 T1 4000AF 11 4000AT Y STANDBY GEN #5 2,250KW 4000AF 4000AT -1F-40001 n T 4000AF 1J 4000AT Y STANDBY GEN #4 2,250KW (PPE) -IF -40001 (PPE) ADD ALTERNATE "ADD E -XXX" TEMP GEN TAP BOX I 'TB- MECH3A" 3000A GEN SWBD. "SB -SG3" 480V, 3PH, 3W + GND, 4000A BUS, 100KAIC n T1 4000AF 1J 4000AT Y T 4000AF �� 4000AT v -IF-40001 r T 11 4000AF 3000AT ��100AF 100AT -IF -30001 .)30 �.30 )30 Y v F -3000 LOAD BANK TAP BOX "TB -LB3" 3000A F- 3000I- L MANUAL TRANSFER SWITCH MTS- MECH3A 3000 A F- 30001- FOR CONTINUATION SEE SHEET E702 F -3000 TEMP GEN TAP BOX 'TB- MECH3B14 3000A --I F -3000 F -3000 _J FU IURE INDOOR UNIT ,— - - - - -� UBSTA11ON USS -6 i I i FUTURE INDOOR UNIT MANUAL TRANSFER SWITCH MTS- MECH3B 3000 A F -3000 SUBSTATION USS -5 600AS XFMR #6, Y -Y 2500/3325KVA 26.4KV- 480/277V AA/FA, 80'C k 4000AF 4000AT J GENERAL NOTES 1. ALL CONDUCTORS ARE COPPER 2. AIC VALUES SHOWN FOR BOARDS ARE BASED ON MAXIMUM FAULT VALUES (3PH, L -G, L -L -G) AVAILABLE FOR VARIOUS FEEDER SCENARIOS. KEY NOTES OWNER FURNISHED CONTRACTOR INSTALLED EQUIPMENT N i INDOOR UNIT N SUBSTATION USS -3 TT- rTtn lJl...�lJ I �� 4000AF � / 4000AT Y 600AS (PPE) XFMR #5, Y -Y 2500/3325KVA 26.4KV- 480/277V AA /FA, 80'C 600AS (PPE) XFMR #3, Y -Y 2500/3325KVA 26.4KV- 480/277V AA/FA, 80'C F -HV I 27KV SWGR. MSG2 MSG2 -A ND1 -1 V C 1200AF XXXAT I III 1200AF ❑ 1200AF XXXAT XXXAT NEW CONDUIT AND CONDUCTORS T T T INDOOR UNIT SUBSTA110N USS -4 I 4000AF 4000A1` J (PPE) MECH DISTRIBUTION SWBD. "DB- MECH3B" 48OV, 3PH, 3W + GND, 3000A BUS, 100KAIC 600AF 450AT -I F -450 1 I F AT -1 F -450 1 600AF 450AT -1F-450 I F -450 1 600AF 450AT -I F -450 1 -IF -40001 I 3000AF I 3000AF 3000AT ) 30 rATSC _ -� -1 F -100 1 (PPE) ALTERNATE FEEDER TO "DB- MECH3B" ABOVE (TYP) DOUBLE THROW DISC SW (TYP) MECH DISTRIBUTION SWBD. "DB- MECH3A" 480V, 3PH, 3W + GND, 3000A BUS, 100KAIC 600AF 450AT 600AF 450AT -I F -450 600AS VFD RTU 3 -2 600AF 450AT 600AF 1600AF 450AT ) 45OAT 600AS XFMR #4, Y -Y 2000 /2660KVA 26.4KV- 480/277V AA/FA, 80'C I.1 3000AF 1J 3000AT -IF -30001 1200AF 200AT ND1 -2 V ❑ 1200AF XXXAT 10 MSG2 -B 1 12% F 1200AF 400AT 0 XXXAT EXISTING PULL BOX Y F -HV BY OTHERS, N.I.C. INSTALL NEW CONDUCTORS IN EXISTING CONDUIT (PPE) 1200AF XXXA MECH SWBD. "SB- MECH3" 480V, 3PH, 3W + GND, 3000A BUS, 100KAIC 100AF 10ITA I. 3000AF 30 T -IF -30001 T1 3000AF 1J 3000AT -IF- 30001 100AF 1100AF BOAT f 80AT -1 F -100 1 M I 3000AF I 3000AF 000AT Y— « ATSCr F -100 I 10F 1.;22FA)T BO -I F -100 1 -I F -100 1 100AF 80AT -I F -100 I '•/ 100010 T I 200AF 125AT -I F -125 1 400AF 350AT -I F -400 1 400AF 350AT -1 F -400 I 400AF 350AT -I F -400 I tIA0-- 0151 -I F -450 I -1 F -450 I -1 F -450 I 11600AS 600AS 600AS VFD RTU 3 -3 VFD I IVFD RTU 3 -4 RTU 3 -5 100AF I 100AF I 100AF I I BOAT 100AT BOAT 1) 100AT .'125AT ./ 350AT 1 350AT ./ 350AT XFMR XFR -L3, 50 KVA 480- 480/277V FOR CONTINUATION SEE SHEET E711 PANEL HP31 PANEL HP3R XFMR XFR -P3 75 KVA - 480- 208/120V ti avoesasamosipok REVIEWED FOR COMPLIANCE WITH NFPA70 -NEC MAR 15 2010 City of Tukwila BUILDING DIVISION ECEIVED MAR 0 2 2010 ERMIT CENTER 60 V 0) ct 0 it W a IL Q cc W c�) 0 co 0 m 0 Q Z I- J 0 0 ti rn N 0 CD • 0 H LL 877.THE.PNAP www.internap.com a 00 Q Z rn J 0 0 U) N CC 00000 CL W 0 O N U V) > rn co m z Li < 0 wZZ CO ix Q z 0 N J J C.) CALL /SON www.callison.corn C/) CL - oo Q U [L 00 I- -c Co }/ QO< W CV < =W .ca LO MF- W CO I— z 0 0 ti co 0) 0 N I— U w 0 Ce a ISSUED / REVISED DATE PERMIT SET 02/26/10 ME CO" RIG c 20 RCA SINGLE LINE DIAGRAM PHASE 3 - HV DISTRIBUTION GENERATOR DIST, MECH DIS E701 3 10 (PPE) (PPE) / / 11`` 4000AF �4000AT NI,- 1 1 L L- ATSCr FOR CONTINUATION SEE SHEET E701 1 L L L UPS INPUT SWBD. "SB -UPS3" 480V, 3PH, 3W + GND, 4000A BUS, 100KAIC I. 4000AF ' I) 4000AT Y 1‘) 2000AF y� 1600AT Y (PPE) �J2000AF 1600AT �J2000AF 1600AT 4‘)■ 2000AF 4/ IN 1600AT F -1600 750KVA MOD. 1 F -1600 750KVA MOD. 3 (PPE) 8 -MIN. BATTERY F -1200 ��2000AF 1600AT F -1600 750KVA MOD. 4 (PPE) 8 -MIN. BATTERY F -1200 T 2000AF �� 1200AT Y T 2000AF �� 1200AT Y 8 -MIN. BATTERY F -1200 �J3000AF 3000AT STA11C T 2000AF SWITCH J 1200AT ' 100AF ▪ 100AT 3000 AMP CONTINUOUS UPS SYSTEM CONTROL CABINET AND SYSTEM POWER SECTION 480V, 3PH, 3W + GND, 3000A BUS, 100KAIC (PPE) UPS DISTRIBUTION SWBD. "DB- UPS3A" 480V, 3PH, 3W + GND, 3000A BUS, 100KAIC J3000AF 3000AF 3000AT 3000AT W I T 3000AF � 3000AT - JF -3000I L___ T L (PPE) UPS MAIN BYPASS SWBD. "SB- UPSBP3" 480V, 3PH, 3W + GND, 3000A BUS, 100KAIC T 3000AF �� 3000AT T 3000AF � 3000AT NI/ I I I.% 600AF I 600AF I 600AF T 100AT 500AT 500AT 500AT ) 500AT ) 500A I I -1 F -500 PDU 3A1, 300 KVA 480- 208/120V 600A 1000A i 1000A, 208/120V, 30, 4WP 225AT I , 225AT I 225AT 225AT I 225AF 3P 225AF �P 225AF Op 225AF P I I I (PPE) POP DEL -I F -500 -I, F -500 PDU 3A3, 300 KVA 480- 208/120V 600A AMP 1000A T 1000A, 208/120V, 30, 4W rip 225AT I 225AT I 225AT 225AT 225AF r3p 225AF Op 225AF Op 225AF jP I (PPE) PDU 3A2, 300 KVA 480- 208/120V 600A P PANEL A 1000YYYN 1000A, 208/120V, 30, 4W Tip 225AT I 225AT I 225AT 225AT 225AF I � 225AF OP 225AF I �P 225AF P PANEL A PANEL PANEL (PPE) 3P PANEL PANEL PANEL PANEL I.\ 600AF 5 -I F -500 L� L - 3000AF 3000AT F -3000 1:)652AAFT MANUAL TRANSFER SWITCH MTS -UPS3B 3000 A MANUAL TRANSFER SWITCH MTS -UPS3A 3000 A -JF -30001 ▪ 100AF • 100AT UPS MAIN BYPASS SWBD. "SB- UPSBP4" 480V, 3PH, 3W + GND, 4000A BUS, 100KAIC r -F Is\ 4000AF �i 4000AT T� 4000AF Ii 4000AT Y 1 I\ 100AF I� 100AT LJ J L P L J ADD ALTERNATE "ADD E -XXX" TEMP GEN TAP BOX "TB- UPS3A" 3000A TEMP GEN TAP BOX "TB- UPS3B" 3000A -I F -500 PDU 3A5, 300 KVA 480- 208/120V 600A AX;ZP 1000 1000A, 208/120V, 30, 4W 3P 225AT I 225AT I 225AT 225AT 225AF OP 225AF OP 225AF �P 225AF r P I I I 600AF 500AT (PPE) PDU 3A4, 300 KVA 480- 208/120V 600A 1_P PANEL A (PPE) 1000A T 1000A, 208/120V, 30, 4W Tip 225AT I 225AT I 225AT ' 225AT 1.'1 225AF Op 225AF Op 225AF r3p 225AF P I PANEL PANEL PANEL C PANEL D PANEL PNEL L JL ' 600AF 500AT F-500I -i F -500 I PDU 3A7, 300 KVA 480- 208/120V 600A P PPE) UPS DISTRIBUTION SWBD. "DB- UPS3B" 480V, 3PH, 3W + GND, 3000A BUS, 100KAIC T 3000AF J 3000AT t- T300 SKRU - - 3000AT 0AF FOR CONTINUATION SEE SHEET E703 FUTURE MECH SWBD. "SB- MECH4" 480V, 3PH, 3W + GND, 4000A BUS, 100KAIC - r - r . 100AF r� 4000AF T� 4000AF I� 100AT +J 4000AT ' 4000AT LJ L- L J PPE) 1000A i - 1000A, 208/120V, 30, 4W P 225AT I 225AT I 225AT 225AT I") 225AF Op 225AF Op 225AF �P 225AF P I I PDU 3A6, 300 KVA 480- 208/120V 600A _1_P PANEL 1000A T 1000A, 208/120V, 30, 4W Tip 225AT 1..1 P 225AT I 225AT 225AT 225AF 225AF r313 225AF �P 225AF PANEL PANEL PANEL -wer- (PPE) 3P PANEL PNL P lAgrF T H F -500 600AF 500AT 600AF 500AT I F -500 I- -I F -500 PDU 3B2, 300 KVA 4.80- 208/120V 600A _l_P PDU 3B1, 300 KVA 480- 208/120V 600A 3P 1000A T 1000A, 208/120V, 30, 4W ISp 225AT I.) P 225AT I 225AT 225AT 225AF 225AF 3p 225AF OP 225AF I PANEL 1000A T, 1000A, 208/120V, 30, 4W J3P PPE) 225AT I..) 225AT L.) 225AT 225AT 225AF P 225AF P 225AF OP 225AF r3p I I I PANEL A PANEL PANEL PANEL P MP- PANEL PPE) 3P PANEL PDU 3B3, 300 KVA 480- 208/120V 1:)652AAFT -� F -500 600AF I.\ 600AF 50 H F -500 600AF 500AT I 600AF AT I 500 PDU 3B4, 300 KVA 480- 208/120V 600A AA;ZP 600A _l_13 1000 1000A, 208/120V, 30, 4W 3P 1000 1000A, 208/120V, 30, 4W 3P 225AT I 225AT I 225AT 225AT 225AF jP 225AF r3p 225AF j3P 225AF I I PANEL (PPE) 225AT 225AT I 225AT 225AT I 225AF OP 225AF OP 225AF OP 225AF r P I I I PANEL PANEL PANEL C PANEL D PANEL PANEL PPE) 3P PANEL F -500 PDU 3B6, 300 KVA 480- 208/120V 600A AMP 1000M1000A, 208/120V, 30, 4W 3P PPE) 225AT I 225AT I 225AT 225AT I 225AF j3P 225AF Op 225AF Op 225AF ." I I PDU 3B5, 300 KVA 480- 208/120V 600A _P 1000Y Y\!) 1000A, 208/120V, 30, 4W rip PANEL 225AT LI 2 25AT I 225AT LI 225AT 225AF P 225AF Op 225AF Op 225AF �P I PANEL A PANEL PANEL C PANEL D PANEL P PANEL 717 F-500 3B7, 300 KVA 480- 208/120V 600A _ 3P 1 100 J 100 AA �L10- 0 l57 (PPE) 1000YYYN 1000A, 208/120V, 30, 4WP 225AT I 225AT I 225AT 225AT l'.•% 225AF is; 225AF OP 225AF r3p 225AF 3P I I I PANEL A PANEL B PANEL -,77r- PANEL REVIEWED FOR COMPLIANCE WITH NFPA 70 - NEC MAR 15 2010 City of Tukwila BUILDING DIVISION RECEIVED MAR 0 2 2010 PERMIT CENTER 2 12 w u IX LU /Lij CA memo Ca W O a, D L 877.THE.PNAP www.internap.com 0 04_ Mco oo 10 W00 toNV) • fx 0 <000 LU 0 N - Zw >o) (Dj 0- wZZ . mx° go� Q z 0 N J J V 0 O c y 0 J • m Q U t1 INTERGATE EAST CAMPUS ISSUED / REVISED DATE PERMIT SET 02/26/10 TIME COPYRIG O 2008 SO SINGLE LINE DIAGRAM PHASE 3 - UPS DISTRIBUTIO E702 1 -t FOR CONTINUATION SEE SHEET E702 TN 4000AF 1.1 XXXXAT - -� FUTURE UPS INPUT SWBD. "SB -UPS4" 480V, 3N, 3W + GND, 4000A BUS, 100KAIC IN 4000AF 1' XXXXAT r 1 r IN 2000AF :k 2000AF l XXXXAT / XXXXAT 1 1 1 O 1 0 1800KVA 1800KVA _MOD.2 j MOD.3 1 El] 1 (PPE) 1 rI]1 (PPE) I El] 1 (PPE) (PPE) Q ^-I-I 1 H„+1 1 1 -"---1 1EI]II 1E1] 11 1EI� II L . L . L . 1 BATTERY 1 BATTERY 1 BATTERY 1 O 1 O I 1 T, 2000AF �k 2000AF l XXXXAT i / XXXXAT J IN 2000AF I 2000AF 1 XXXXAT I I 1800KVA MOD. 1 I T\ 2000AF 1' XXXXAT L FUTURE UPS DISTRIBUTION SWBD. "DB- UPS4A" 480V, 3PH, 3W + GND, 3000A BUS, 65KAIC I, 600AF /TO-0--cf r_J r I.N 600AF 11 PDU 4A1, 300 KVA 480- 208/120V 600A _A-P T I, 600AF 11 WWI 1000\A/Y\\/ 000A 1 1000A, 208/120V, 30, 4W J3P 225AT 1, 225AT I.\ 225AT 1■ 225AT 1, 225AF 130 225AF 13P 225AF 13P 225AF 13P O rP -1 r PRT i PANE I A 1 1 1 1 1 1 3_ 1 PDU 4A2, 300 KVA 480- 208/120V 600A1-., AMP VNi 1000A T -\ 1 1 1 1 1 1 1 1 1000A, 208/120V, 30, 4W J3P __r___r___illm___T_ 225AT 1 ■ 225AT 1- 225AT 1- 225AT I - ■ 225AF 13P 225AF 13P 225AF 13P 225AF 13P PAEL PQrEL 1 PANEL PANEL 1 1 1 11 11 1 L- _ J L- _ J L- _ J L- _ J L__J L__J L__J r T r r 1 1 2000AF 1. 4000AF - 100AF J XXXXAT T l XXXXAT 1l 0� OAT [1 1 1 LJ 1 SPIRE IO O 1800KVA _MOD. 4 I� IEI] Ii L f 8 -MIN. I BATTERY IO 1N 2000AF 1 ' )00-1-kg -r ■ 600AF 1\ 600AF Il 11 600AT J STATIC r I T.\ SWITCH L L r IN 600AF 16000AT PDU 4A3, 300 KVA 480- 208/120V 600A 1 AMP 1000A T 1000A, 208/120V, 30, 4W J3P _r___r___TIN___T_ 225AT 1, 225AT 1, 225AT I, 225AT I, 225AF 13P 225AF 13P 225AF 1313 225AF 13P PL-I raj rQNLT PL-1 I A I I I I I I I I I I I I 1 L- _ J L- _ J L_ _ J L- _ PDU 4A4, 300 KVA 480- 208/120V 600A1-\ tP 1000M 1000A, 208/120V, 30, 4W J3P =_r = = =r = = =71.= = =T= 225AT 1-■ 225AT 1 ■ 225AT -N 225AT 11 225AF 13P 225AF 13P 225AF 13P 225AF 13P PANEL PA L1 PAN LI PA EL I _A° I I a 1 I c I I 70_7 1 1 1 I I I I I I L-_1 L__J L-_1 L-_J 2000AF XXXXAT T-N 2000AF �i XX Y k 2000AF 1" XX L_ 1 XXXXAF 1' XXXXAT 1600AT 600AF .J 600AF l 600AT PDU 4A5, 300 KVA 480- 208/120V 600A - FUTURE MECH DISTRIBUTION SWBD. "DB- MECH4B" 480V, 3PH, 3W + GND, 4000A BUS, 100KAIC r 600AF 11 450AT r , 600AF 11 450AT I, 600AF 11 450AT r , 600AF 1 450AT r ■ 600AF 11 450AT J- Tk 4000AF �i 4000AT Y ■ 100AF 1 80AT ALTERNATE FEEDER TO "DB- MECH3B" ABOVE (TYP) DOUBLE THROW J DISC SW (TYP) FUTURE MECH DISTRIBUTION SWBD. "DB- MECH4A" 480V, 3PH, 3W + GND, 4000A BUS, 100KAIC 600AF 1 450AT 600AS T L 11 600AF 1 450AT 600AS 1 RTU 4 -2 L__J T L 11 600AF 1 450AT 600AS T L r . 600AF 1 450AT 600AS 1 RTU 4 -4 L__J T L r 600AF l 450AT 7 A 1, 4000AF 1 4000AT - N 4000AF 1" 40 OAT 100AF 1 80AT T L 600AS 600AS r1-i VFD 1 RTU 4 -6 L-__J 1 r \ 100AF 1 BOAT \ 100AF 11 80AT S. r r ■ 100AF - 100AF 1100AT 180AT S. 1-N 400AF 1 400AT r 400AF I1400AT - r 400AF -/ 400AT J T, 4000AF 1- 4000AT r 100AF 8OAT l Ti LEI 600AS 100AS T L 100AF 180AT 100AS r1- VFD � 1 RTU 4-7 CAC 4 -1 CAC 4 -2 1 1 I I I I I I I 1 L-__J L__J L-__J I XXXXAF z\11 XXXXAT ■ 600AF 11 600AT 1000A T 1000A, 208/120V, 30, 4W J3P __r___r___i.___T_ 225AT 1, 225AT 1, 225AT 1, 225AT I , 225AF 130 225AF 13P 225AF 13P 225AF 13P - PANET PAN- I T P I A I I L I I I I I 1 I I I I I I 1 L__J L-_J L__J L-_J PDU 4A6, 300 KVA 480- 208/120V 600A1-\ A1/1P 1000A T -\ 1000A, 208/120V, 30, 4W J3P __r_ __r___irl.___T_ 225AT 1-N 225AT 1-■ 225AT 1-N 225AT 1-■ 225AF 1 3P 225AF 13P 225AF 13P 225AF 13P PANE P6NELI PANE P EL I-A"- I I e" I I-'e- I I-r- I L- _ J L_ _ J L- _ J 600AF 1 600AT L PDU 4A7, 300 KVA 480- 208/120V 600A - - I J3P FUTURE UPS DISTRIBUTION SWBD. "DB- UPS4B" 480V, 3PH, 3W + GND, 3000A BUS, 65KAIC 1000A i 1000A, 208/120V, 30, 4W J3P =_r = = =r ===Tli= ==T= 225AT 1 ■ 225AT I , 225AT 1 ■ 225AT 1■ 225AF _L 1- 1 P 225AF P 225AF 13P 225AF 13P PANP. I _ AE PAN- L r L-1 A I I I I I I Q I I I 1 I I I I L- _ J L- _ J L- _ J L- _ J PDU 4A8, 300 KVA 480- 208/120V 600A I - P 1000A T 1000A, 208/120V, 30, 4W J3P __r___r___irl.___T_ 225AT I 225AT I , 225AT I , 225AT 1-N 225AF 130 225AF 130 225AF 13P 225AF 130 PANEL I PANEL PANES PANES IA" I I "B I I "C I I "E" I 1 1 I 1 1 1 1 1 L__J L-_J L__J L-_J r r T r_J 1 600AF I .\ 600AF 1\ 600AF 1 600AT I1600AT 11 600AT L__ L 1 -1 PDU 462, 300 KVA 480- 208/120V 600A - -I-P 1000M 1000A, 208/120V, 30, 4W J3P __r___r___ TIN ___T_ 225AT I, 225AT I, 225AT 1, 225AT 1, 225AF 13P 225AF 13P 225AF 13P 225AF 13P PONE'. PANEL PO-N I PANLT I A" 1 1 1 1 1 1 1 I I I I I I I I L__J L_J L-_J L__J PDU 461, 300 KVA 480-208/120V 600A 1 - P 1000A T 1000A, 208/120V, 30, 4W J3P 225AT 1 225AT 1- 225AT 1- 225AT 1-N ■ 225AF 13P 225AF 13P 225AF 130 225AF 13P PANEL P EL PA EL PA ELI I -"A"- I ICI I- c"- I I C I I I I I I I 1 L-_J L-_J L_1 L-_J 600AF 1 600AT T� XXXXAF J/l XXXXAT Y 600AF I1 600AT XXXXAF 1./ XXXXAT Y I, 600AF 11 WV r ■ 100AF 1 80AT T L 100AS CAC 4-3 I I L__J r I r 100AF 11 80AT 100AF 11 100AT 1 1- Ti Ti L ,I L ,I 100AS CAC 4 -4 L__J 100AS I- 1 PANEL 1 RP -4 L__ J 11 600AF 1-\ 600AF 11600AF 11 WO II 600AT 11 600AT I I I L L L L 1 PDU 484, 300 KVA 480- 208/120V 1 600A 1- AM-1 P 1000A T 1000A, 208/120V, 30, 4W J3P = =r =- =r= = =irl.= = =T= 225AT 1■ 225AT 1 ■ 225AT I - 225AT I , ■ PDU 4B3, 300 KVA 480- 208/120V 600A 1 ^N -l_P VV 1000A T 225AF 13P 225AF 13P 225AF 13P 225AF 13P PANEL- T PQ -I I-P 1 1-4111 I A I I I I I I 1 I I I I I I I I L- _ J L- _ J L- _ J L- _ 1000A, 208/120V, 30, 4W J3P - _r = = =r = = =lia = = =T= 225AT - 225AT -N 225AF 13P 225AF 13P PANEL I PANEL I A I I e 225AT -. 225AT - 225AF 1 3P 225AF 13P PACE PA EL I I I I o I I II II I I 1 L- _ J L- _ J L- - L _ PDU 4B6, 300 KVA 480- 208/120V I 600A1- AM-1 P 1000A 1-� 1000A, 208/120V, 30, 4W J3P 225AT 1, 225AT 1 225AT 1.-N 225AT I , 225AF 130 225AF 13P 225AF 13P 225AF 13P PANE= PANS I r - 1 r 1_ Li' I A 1 1 1 1 1 1 1 I I , I I I I 1 L__1 L__i L-_J L-_J PDU 4B5, 300 KVA 480- 208/120V 600A P 1000A T 1000A, 208/120V, 30, 4W J3P __r___r___TI.___T_ 225AT 1■ 225AT 1- 225AT 1 225AT 1, 225AF 13P 225AF rim), 225AF 13P 225AF 13P P EL 1 PANEL PANEL PE AN e" 1 1 "c" I I- 1- 1 I I I I I I 1 L-_J L__J 400AF I J 400AT I, 600AF 1 60� L I, 400AF 11 400AT PDU 488, 300 KVA 480- 208/120V 600A -� "./OP 1000A T 1000A, 208/120V, 30, 4W J3P __r___r___�___T_ 225AT I , 225AT 1 225AT 1, 225AT 1, 225AF 13P 225AF 13P 225AF 13P 225AF 13P PQN- 1 r L-1 1-4-1,-1 f Li I A I I& I I I I I I I I I I I I I L- _ J L- _ 1 PDU 4B7, 300 KVA 480- 208/120V 600A I -. NIV1P 1000A 1000A, 208/120V, 30, 4W J3P 225AT 1-N 225AT 11 225AT I , 225AT 1 225AF 13P 225AF 13P 225AF 13P 225AF 1 3P PANEL I PANEL I PA EE PAN L I I I I "e I I� I I "D I I I I I I I I I L- _ J L- _ J L_ 1 L_611 $$$ DESIGN $SPECIFICATION$$$$$$$$$$$$$ E .� ' OR TH NFPA 70 - NEC MAR 1 5 2010 City of Tukwila BUILDING DIVISION RECEIVED MAR 022010 PERMIT CENTER �L1- 0151 $$$DATE$$$$ $TIM E COPYRIGHT U 2008 CALLISON • rc www.internap.com J 00 Q cn _ P0003 IU W 0 to c'N D_ Ct 0�000 Lip N- (n > v- ) (O Z W�. Q OU WZZ� 00 X° o� 0 N 1 0 •c• INTERGATE EAST CAMPUS Wel a• co CID _ r 0 00 CY) -F-+ Q N . LO 1_ M O ISSUED/REVISED DATE PERMIT SET '02/26/10 SINGLE LINE DIAGRAM PHASE 4 - UPS DISTRIBUTIO E703 GEN. SWBD. #1 480/277V, 3-, 4W + GNI), 6000A BUS, 100KAIC TERMINATION BUS SECTION 3000A BUS GEN #1 2000KW DAY 1 GEN #2 2000KW DAY 1 GEN #3 2000KW DAY 1 • GF 3000AF l\-\ gt;00AF 1 3000AT 11 3000AT •\/ kv/ GF 3000AF ) 3000AT IN) 3000AF 3000AT 1/ 2000KW LOAD BANK (F) 1\-- 3000AF 1) 3000AT UPS BYPASS SWBD. "SB-UPSBP1" 480V, 3PH, 3W + GND, 3000A BUS, 100KAIC TRANSFER BREAKER CONTROLS FOR EXISTING MAINTENANCE BYPASS BREAKER TO NEW MAINTENANCE BYPASS BREAKER FOR CONTINUATION SEE SHEET E701 4000A ATS #1, 3P, 3W, 480V ////////// - - —)3000AF 3000AT )3000AF I3000AT / / / 3000AF -\ SKRU 3000AT 6.1) 11\\- 3000AF 3000AT 3000AF 1 3000AT UPS INPUT SWBD. 480/277V, 3N, 3W + GND, 4000A BUS, 100KAIC 1\- 4000AF 2000AF I\ 2000AF 1-\ 2000AF \l/ 11 1600AT 11 J 3200AT 1600AT 1600AT -s\ 3000AF 13000AT 3000AF 13000AT -‘3000AF )3000AT 800KVA MOD. 1 UPS OUTPUT SWBD. 800KVA 800KVA MOD. 2 MOD. 3 1•] 8-MIN. 8-MIN. 8-MIN. BATTERY BATTERY BATTERY 1200AF 11200AT "11200AF 11200AT ")1200AF 11200AT )2000AF 1600AT 1/ 800KVA MOD. 4 3-, 3W, 3000A BUS 8-MIN. BATTERY 1200AF )1200AT 1\\-\ 1200AF 1.1 1200AT \\k/ 1200AF I 1200AT SPARE SPARE r-■ - 400AF LS S9-3400AT 400AS 400AF .(EXIS-1ING) 27KV SWGR. MSG1 MSG1-A NDi 1 „r 1?op,9 XxXA1 .....719.1.1714 131111511... .{1116$1.1=1.11.911ii, .05132.s XXXAT [- Lt I200AF VAT 1200AF J MO12, JAW AT INDOOR UNIT SUBSTATION USS-1 26.4KV, 1200A BUS sERvicr SWOD #1 480/277V, ;ivtr cND, 4000A BUS, 100KAIC 1- 400AF 400AT _1400AS 400AF RTU-5-6 RIU-5-' •\ 3000AF I • 3000AF J 3000AT ,J 3000AT - • NO ND1-2 C 27KV SWGR. MSG2 ND1-1 10 ND1-2 MSG1-13 MSG2-A 1200AF XXXAT C 1200AF XXXAT C 1200AF XXXAT MSG2-B 7 600AS 1200AF 1200AF 1200AF 600AT L1.J XXXAT Y XXXAT T ri 1200AF 1---1 XXXAT 1200AF 200AT [I] 1200AF 200AT 600AS (N) INDOOR UNIT SUBSTATION USS-2 26.4KV, 1200A BUS (NEW) XFMR #1, Y--Y XFMR #2, Y-Y (NEW) 2500/3333K VA 2500/3333KVA 26 4KV -480/271V 26.4KV-480/277V AA, 10M; AA, 100"C 4000A1 GF NC ) ., -4r 11-oo 4100AF 4DOCTAT NO (i) 400AI 400A-1 )460AT 4O0/ s tio0As • 400AF -' 400AF RTU-5-8 'AD Riu-1 ATS #2 4000A, 3P, 480V \ 400AF 7 400AT SI) .100Ar 400A1 J400AS VAJ 400AF 400A1 iyfT)-1 RTU--2 R1.I 3 ) 4000AF GE NC j 4000AT ST E 1w 400AF 400AT RTU-4 400AS 400AF Cl\\-\ 3000AF J .3000AT ATS #3 3000A, 3P, 3W, OVERLAPPING NUETRAL, 480V, W/ BYPASS ISOLATION DISCONNECT EXISTING RTU FEEDER AND INSTALL NEW FEEDER SHOWN (TYP OF 3) MECH. DISTRIBUTION SWBD. 480V, 3-, 3W + GND, 3000A BUS, 65KAIC )400AF - 400AF 400AT ke'- 400AT L:: FOR CONTINUATION SEE SHEET [712 -\ 600AF J 600AT -\ 600AF 600AT UPS DISTRIBUTON SWBD. 480V, 3-, 3W + GND, 3000A BUS, 65KAIC -\ 600AF )600AT 600AF )600AT .)600AF 600AT "*•\ 600AF • 600AT -\ 600AF J 600AT 600AF )600AT N 600AF 600Ai- .)600AT 600AF 600AT -600AF )600AT 400AS 400AF 45KVA 480V- 208/120V FIV-1 250A 200AF 150AT 150AT BY OTHERS, N.I.C. 1200AF 1200AF XXXAT XXXAT 200AF 75KVA 75KVA 480V- 480V- 480/277V 120/208V HV-2 70A 70A RP/GEN-1 LP/GEN-1 45KVA 480V - 480/277V 225AF 400AF 225AT 400AT SPARE 400AS 400AF RTU-5-9 400AF 400AT 400AT 400AF 400AS 400AF RTU-5-10 400AS 400AF RTU-5-11 REVIEWED FOR COMPLIANCE WITH NFPA 70 - NEC MAR 1 5 2010 City of Tukwila BUILDING DIVISION RECEIVED MAR 02 2010 PERMIT CENTER EL10--9151 L.J 2 w I- CI) n 2 -J 0 CV 877.THE.PNAP www.internap.com Y g C:.< Ina) 6-29 3 ul to (3 (f) 0 0, • LLI 0 to Na_ 0 v) to Li ct cc 0 <00' 6 CL IjJO 0 N > - Fa Li] < -O Li- w -C2 5 0 Z M if) 0 410 w 0 INTERGATE EAST CAMPUS CD co C.) CD CO 0- CO 0, 4-a < (NJ (/) co N- 0) CO 0 4kI- 0 w -3 0 ISSUED / REVISED DATE PERMIT SET 02/26/10 $$$DESIGN$SP CAT1ON$$$$$$$$$$$$$ $$$DA I E$$$$ $TIME COPYRIGHT (9) 2008 CALLISON SINGLE LINE DIAGRAM EXISTING UTILITY, STANDBY MECHANICAL AND UPS E711 1 2 FOR CONTINUATION SEE SHEET E711 T -1A 300KVA 480V- rim 208/120V DP- CPP -3A 800A, 120/208V, 3-, 4W + GhD, 42KAIC T -2A Lida) 300KVA 480V- 208/120V 800AF 1800AT -\ 225AF 225AF 225AF 225AF 225AT -\ 225AT 7 225AT ) 225AT CPP -3A -1 42KAIC CPP -3A -2 42KAIC CPP -3A -3 42KAIC (FUTURE) SPARE T -3A 300K VA 480V- Yl 208/120V T -4A l� 300KVA 480V- r rrn 208/120V 800AF 800AT DP- CPP -4A 800A, 120/208V, 3-, 4W + GND, 42KAIC 225AF 225AF 225AF 5AF 225AT ) 225AT ) 225AT .1 225AT CPP -4A -1 42KAIC CPP -4A -2 42KAIC CPP -4A -3 42KAIC (FUTURE) SPARE DP- CPP -5A 800A, 120/208V, 3-, 4W + GND, 42KAIC 4 T -5A J 300KVA 480V- (_n_•n 208/120V (NEW) 800AF 800AT T -6A U 300K VA 480V- 208/120V (NEW) 1 225AT , -\ 225AT 1 225AT -) 225AT CPP -5A -1 42KAIC CPP -5A -2 42KAIC 800AF 800AT CPP -5A -3 42KAIC (FUTURE) SPARE DP- CPP -6A 800A, 120/208V, 3-, 4W + GND, 42KAIC 225AF 225AF 225AF 225AF 225AT ) 225AT ) 225AT ) 225AT CPP -6A -1 CPP-6A-2 CPP 42KAIC 42KAIC DP- CPP -1A 800A, 120/208V, 3-, 4W + GND, 42KAIC 800AF 800AT -\ 225AF 225AF 225AF 225AT ) 225AT -s% 225AT ) 225AT CPP-1A-1 42KAIC CPP -1A -2 42KAIC CPP -1A -3 42KAIC (FUTURE) SPARE -6A -3 42KAIC (FUTURE) • 800AF • 800AT SPARE DP- CPP -2A 800A, 120/208V, 3 -, 4W + GND, 42KAIC 225AF -)225AF 225AT ) 225AT ) 225AT -\ 225AT CPP -2A -1 42KAIC CPP -2A -2 42KAIC CPP -2A -3 42KAIC (FUTURE) SPARE T -7 300KVA 480V- n-m 208/120V (NEW) T - -7 DP- CPP -7A 800A, 120/208V, 3-, 4W + GND, 42KAIC 300KVA 480V- 208/120V (NEW) T -6B 300KVA 480V- ,J8/120V (NEW) T -58 300K VA 480V. -. 20x1/1 20V (NEW) 1=4 300KVA ... k) 480V- .E ' 208/120V E - -3B 300KVA 4801/- 208/12() 800AF 800AT -t% 225AF 225AF 225AF •\ 225AF 225AT .1 225AT , 225AT 225AT CPP -7A -1 42KAIC 225AF 225AT CPP -7A- -2 CPP -7A -3 42KAIC 42KAIC (FUTURE) RICE) CPP -7B -1 42KAIC 800AF 800AT SPARE DP- CPP -7B 800A, 120/208V, 3-, 4W + GND, 42KAIC 225AF -,225AF 225AF 225AT 225AT ) 225AT L 42KAIC CPP -78 -3 42KAIC (FUTURE) SPARE OP-CPP- 6B 800A, 120/208V, 3,•-, 4W -I GND, 42KAIC 225AF 225AT J 225AF 225AT CPP-6B-1 CPP -6B -2 42KAIC 42KAIC 800AF 1 BOAT 225AF 225A1 225AF 225AT CPP -58 CPP -5B -2 42KAIC 42KAIC DP - CPP - -2B 800A, 120/208V, 3 -, 4+/V 1- GND, 42KAIC 225AF 225AT 225AF -/ 225AT CPP- 2.B - -1 CPP-2B- 2 42KAIC 42KAIC T -213 I ,JIJ 300KVA 480V -- ,Y.Y Y..} 208/120V 8 T -1B 300KVA 480V n-r) 208/120V 9 10 800AF 1800AT ;25AF 225AF 275AT , ) 225AT CPP - -60 -3 42KAIC. (FU (UM ) SPARE DP - CPP -5B 800A, 120/208V, 3-, 4W + GND, 42KAIC 25AF 225AF 225AT .1 225AT CPP -58 .3 42KAIC ( FUTURI ) 800AF 806AT SPARE 225AF 225AF 225A1 ) 225AT CPI'. --28. -3 42KAIC (FUTURE-) SPARE OP- CPP -48 800A, 120/208V, 3',, 4W + GND, 42KAIC 225AF ) 225AT L P -4E1 -1 42KAIC 800AF 800AT 225AF 225AF 225AF 225AT 7 225AT ) 225AT CPP -4B -2 42KAIC CPP -4B -3 42KAIC (FUTURE) SPARE DP- CPP -3B 800A, 120/208V, 3N, 4W + GND, 42KAIC 225AF l225AF 225AF 225AT J 225AT ) 225AT CPP -38 - -1 42KAIC CPP -3B -2 42KAIC CPP -3B -3 42KAIC (FUTURE) 225AF 225AT SPARE 800AF 800AT 225AF ll 225AF 225AT . J 225AT CPP -1B -1 CPP -1B -2 42KAIC 42KAIC DP- CPP -1B 800A, 120/208V, 3 -, 4W + GND, 42KAIC 225AF 225AF 225AT , ) 225AT CPP -1B -3 42KAIC (FUTURE) SPARE t \o- 0 151 REVIEWED .FOR COMPLIANCE WITH NFPA 70 - NEC MAR 15 2010 City of Tukwila BUILDING DIVISION RECEIVED MAR 02 2010 PERMIT CENTER U) V iti 40 cc y ikvat Z 4 Q 2 W II'l• co O M 0 co O Q O N- O co <0 co Z • J • O I- • I- LL 877.THE.PNAP www.internap.com J Y 00 Q C-15 In %- to 00 0 I0 LA 0 co a- w 0 0 0 O > 0) (D 0D ZLLI��< OV wZZ• • � Cl) Cl) E 0 o c A 0 = v m v ✓ 3 C/) CL 2 U� Q co ") U a- CO - I- C/) 4 - W 0 (/) W N W Q = W . CO 0_ I` < (r Lo - LL W M~ I- z CO O N- CO rn 0 It I- U LU 0 0 ISSUED / REVISED DATE PERMIT SET 02/26/10 TI E COPYRIGH O 2008 •1 SINGLE LINE DIAGRAM EXISTING UPS DIST E712