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Permit M92-0054 - BOEING #9-101
M92-0054 BOEING #9-101 HVAC 9725 EAST MARGINAL WAY SOUTH 1 b0E11\16 4q---101 Community Development / Public Works • 6300 Southcenter Boulevard, Suite 100 • Tukwila, Washington 98188 Permit No: Type: Category: Address: 9725 EAST MARGINAL WY S Location: Parcel #: 000340 -0018 Contractor License No: BOEINC294ML TENANT OWNER CONTRACTOR ******************************************** * * * * * * * * * * * * * * * * * * * * * * * * * * * * * ** Permit Description: HVAC UPGRADE FOR EEIP PHASE 3 -E UMC Edition: 1988 **********'.**** * * * * * * * * * * * * * * * * * * * *4* * * * * * * ** Permit Center Authorized Signature I herebl: 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 for and obtain this building per Signature Print Name: M92 -0054 B -MECH NRES THE BOEING COMPANY *9 -101 PO BOX 3707 - M/S 1F -09, SEATTLE WA 98124 THE BOEING COMPANY PO BOX 3707 - M/S 1F -09, SEATTLE WA 98124 BOEING INC. Phone: 206 544 -2975 9725 EAST MARGINAL WY S, SEATTLE, WA 981242207 MECHANICAL PERMIT Valuation: Total Permit Fee: Date (206) 431 -3670 Status: ISSUED Issued: 06/18/1992 Expires: 12/15/1992 541,125.00 83.13 Date': 4 Title: This permit shall, ,become null and void if the work is not.,'com'menced 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 inspect,,i'on. PERMIT NO. CONTACTED e ` P L m - DATE READY DATE NOTIFIED (0_ l (', B (snit. PERMIT EXPIRES 2nd NOTIFICATION BY: (init.) AMOUNT OWING S3. 13 3RD NOTIFICATION BY: (init.) _ MECHANICAC PERMIT APPLICATION TRACKING PLAN CHECK NUMBER 'm qa 005 INSTRUCTIONS TO STAFF • Contacts with applicants or requests for information should be summarized in writing by staff so that any time the status of the project may be ascertained. • Plan corrections shall be completed and approved prior to sending on to the next department. • Any conditions or requirements for the permit shall be noted on the plans or summarized concisely in the form of a formal letter or memo, which will be attached to the permit. • Please fill out your section of the tracking chart completely. Where information requested is not applicable, so note by using "N /A ". DEPARTMENTAL REVIEW "X" in box indicates which departments need to review the project. `D1EwPe FIRE O OTHER O PLANNING PROJECT NAME SITE ADDRESS BUILDING - initial review up lct -- 1_ REVIEW COMPLETED 6 � (ROUTED) INIT: INIT BUILDING - (? ((s ft2._ final rAViAw �'�42- INIT: .. c-,_ Bb-ean5� �a q�� E, '(YlrnraJ' nal w65 CONSULTANT: Date Sent - 2 FIRE DEPT. LETTER DATED: / 5- /1 9 INIT: ,,Jbvir /IjU) ZONING: SCREENING REQUIRED? fYes [l No REFERENCE FILE NOS.: UMC EDITION (year): SUITE NO. U1REME N:::_. Date Approved - FIRE PROTECTION: S•rinklers Detectors N/A INSPECTOR: 5i 3 IBAR/LAND USE CONDITIONS? Yes ri SiTE ADDRESS SUITE # 9VS G 14 £. BLDG. / - /el VALUE OF CONSTRUCTION - $ s - �f a5"-- _ PROJECT NAM /TENANT BOEING MILITARY. AIRPLANE TYPE OF WORK: New /Addition Q Modifications 0 Repair Q Other: DE�E WORK OBE DONE: / _ ° NUMBER OF UNITS :.. . _ � RATING/SIZE :: ZIP WA. ST. CONTRACTOR'S LICENSE # Q e /A / 4, (.290,/ EXP. DATE 0/ %, %3 ARCHITECT 73 a g //t ; PHONE BUILDING USE (office, warehouse, etc. N E OF B SINES AIRPLANES WILL THERE BE A CHANGE IN USE ?,No 0 Yes IF YES, EXPLAIN: WILL THERE :E TORAGE OR USE OF FLAMMABLE, COMBUSTIBLE OR HAZARDOUS MATERIALS IN THE BUILDING? 12 No 0 Yes IF YES, EXPLAIN: PROPERTY OWNER BOEING MI ITARY AIRPLANES PHONE 544 -2925 ADDRESS PO BOX 3707 M/S 46 -87 SEATTLE, WA. 98124 -2207 ZIP CONTRACTOR PHONE ADDRESS - ZIP WA. ST. CONTRACTOR'S LICENSE # Q e /A / 4, (.290,/ EXP. DATE 0/ %, %3 ARCHITECT 73 a g //t ; PHONE ADDRESS ZIP CITY OF TUKWILA Department of Community Development - Building Division 6200 Southcenter Boulevard, Tukwila WA 98188 (206) 433 -1849 NAME JOB PLAN CHECK NUMBER CONTACT PERSON Oo TERRY L. BENNETT Mechanical Fee Worksheet must also be filled out and attached to this application. Li APPLICATION MUST BE FILLED OUT COMPLETELY MECHANICAL PERMIT APPLICATION FEES (for staff use only) DESCRIPTION BASIC PERMIT" FEE UNITS) FEE :" PLAN CHECK FEE:; AMOUNT RCPT # DATE f HEREBY CERTIFYTHAT 4 lAVf Rf AD ANI TRUE AND CORRECT, AND. I Af+ AUTHORIZ BUILDING OWNER SIGNATURE — OR '' AUTHORIZED PRINT NAME yy L AGENT ennp�cc PHONE 54 -2975 CITY /ZiP SEATTLE, 98124 PHONE 544 - 2975 APPLICATION SUBMITTAL In order to ensure that your application is accepted for plan review, please make sure to fill out the application completely and follow the plan submittal checklist on the reverse side of this form. A completed "Mechanical Permit Fee Worksheet" must accompany this permit application. Handouts are available at the Building counter which provide more detailud inforrnatioil or) applicaiiorl and plan submittal roquirements. ^,pplicatic:; aril clans must be complete in order to be accepted for elan review. BUILDING OWNER / AUTHORIZED AGENT If the applicant is other than the owner, registered architecVengineer, or contractor licensed by the State of Washington, a notarized letter from the property owner authorizing the agent to submit this permit application and obtain the permit will be required as part of this submittal. VALUATION OF CONSTRUCTION The valuation is for the work covered by this permit and must be filled in by the applicant. This figure is used for budget reporting purposes only and not to calculate your fees. 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 extend the time for action by the applicant for a period not exceeding 180 days upon written request by the applicant as defined in Section 304(d) of the Uniform Mechanical Code (current edition). No application shall be extended more than once. If you have any questions about our process or plan submittal requirements, please contact the Department of Community Development at 433 -1849. DATE APPLICATION ACCEPTED DATE APPLICATION EXPIRES 3 1 cia 04i29/139 n **** k*********, k* k* k*** k*** kk*********** k * * * ** * * * k * * * * *•k * * * * * * ** CITY or;.TUKWTLA, '.WA TRANSMIT, *** k**** *k * * **** * *k * * ** *k *k: *** *k *i(** **** * ***irir *khiirii** * * *** * **k TRANSMIT Number e, 9 20Q0583 Amount: 83.13 0 /18 /9 // f9 Permit No: M '32 -0.054 ,, Typex 8 .MECH MECHANICAL PC i4 Parcel `'.No: 00.0.3 40 -001.8 ; Site Address: : 9725•` EAST, 'MARGINAL 'WY, S Payment -Method:: CASH' = xrtit ' SLn ** h ik*** k** * *** * **** ***kk•k* ** ** * * * * ** Description Paid PLAN. CHECK - NONRES MECHANICAL - NONRES 66•.5() Total (This Payment) 83..13 T,at;al Peps: 83.13 Al l ' 83.13 3Ua1,ance: Q0 * *k ** * * * ** * * * *• * * * ** Account .Cadre;, 000%345.830;: ,000/322.100 16;.63 GENERA 83.13 TOTAL. 83.13 *CASH 100.00 CHANGE 16.87. '1.0878A0,00. 11:56:. Address: 9725 EAST MARGINAL WY S Tenant: THE BOEING COMPANY #9 -101 Type: B -MECH Parcel #:. 000340 -0018 CITY OF TUKWILA Permit No: M92 -0054 Status: ISSUED Applied: 03/17/1992 Issued: 06/18/1992 **************** * **** * * * *•k * * * ** * * * * * * * ** * * * * ** k ** * ** ** *fit **** * * ** * * * *** * * * ** Permit Conditions: 1. No changes will be made to the plans unless approved by the • Architect and the Tukwila Building Division. 2. Plumbing permit. shall be obtai,ne.d....th.rough the Seattle -King County Department :of Public 54.6alth ''a, Plu b .ng will be •inspected by that age it y, •i .iding , a�l1 % "ga';s tP P.1 (296 -4722) . ,•. .:,, -^ . 3: ° Electrical . permit ',"Shall,. be ` , o b taine V t hrow h. the -W as , i ton 4' � { .,d.. ; g .�,. g .t'�' �'X�' .? vt' i.3 +. �61 5{ � < <..:4+.� fi r W Ze. ,ca1 State Divislo'n o .Labo Ihdu.str•ies and1 a #1 ,nele`c;tri . work w 11 b '�'firsp.ected . that agency ) ( 277•- 72'r72)r;;ti `,", ?z . 4. All permiyyt�, in,speo,ti�on r,e an a pproved �p�lan s, 4 � sha',ll Yi @r r maintaint av,,ai��a 4 e at 'if) e rp p F rto.tthe st :: -.' any co s uc•tiotn. ' These dociain ri.t;s;.,re to bei °'main'tained avai 1 k b b 7 ' , u n t i l �`'f inal insp.'e�Ct ap proval is gPa9t'e940 ;4' 5 � 5. Any e.= osedinsula�tionsk;•b`a;cktii'ng material sha11 have a Flame; }\ Spre Rai4inig of '4.'25 or; ::°l'ess, `a.'nd, ..,.ma ter ial sha11 be:ar'`i tit i',;\ f i ca/ �'.0n :sh:oWi n,g the •f, ,r,'e per.1,armance�- rating thereof . •'.,.Y;. {f 6. All p nsvtru jtion to be'd.Ai conformance with approved ' s� p1a s and�3lre one. quirement:s'"•of„ th Unifor m B Code ‹(19 Ed i ion), Unitorm;:fechanli Code Edi ° t i on), and t e" �, • Wa ington State..- E Co tr,' ' (1�9 . f oof o`unted"' e. u i ment i #s E.'� =- 7. Reed 1y rac essi�i,la,,,aoc/ s-•,. rr r m r P a ; ,tii; r e d r, ? t .' 1,,"� . L i f r" . wr, , r e 8. Va, \i' i tsi a P4rm1+ The ;i's a n'ce \ a,,,p e,.Wt W 1 t. or appr'ova. o • pla n'', specifications' an.dr.'computa sha•l l not be .pon • str d to +b a, for, or an \a�ppr -of', -..any violation • of a ,9 t , of e p� ovisions of this c�rde- dr. of__and?: other 4 -.�,, ardi r "a� ce a�f th jurisdiction, o p` rmit pr ming tog g • autho i,i* 9,r vialgte or cancel t. pro44 s1 n,s' • thi chide sha11. va11d. . •• `1 % i � 0 Fire Department Review Control #M92 -0054 (513) Dear Sir: City of Tukwila FIRE DEPARTMENT 444 Andover Park East Tukwila, Washington 98188 -7661 (206) 575 -4404 June 11, 1992 John W. Rants, Mayor Re: Boeing Company Building #9 -101 - 9725 East Marginal Way South The attached set of building plans have been reviewed by The Fire Prevention Bureau and are acceptable with the following concerns: 1. Sprinkler protection shall be extended to all areas where required, including all enclosed areas, below obstructions and under overhangs greater than four feet wide. (NFPA 13- 4 -1.1, 4- 4.1.7.1.1, 4- 4.1.7.5, 4- 4.1.7.6.1) All new sprinkler systems and all modifications to existing sprinkler systems shall have fire department review and approval of drawings prior to installation or modification. New sprinkler systems and all modifications to sprinkler systems involving more than 25 heads shall have the written approval of the W.S.R.B., Factory Mutual, Industrial Risk Insurers, Kemper or any other representative designated and /or recbgnized by The City of Tukwila, prior to submittal to the Tukwila Fire Prevention Bureau. No sprinkler work shall commence without approved drawings. (City Ordinance #1528) All sprinkler system plans, calculations and the contractors Materials and Test Certificates submitted to The Tukwila Fire Prevention Bureau must be stamped with the appropriate level of competency seal. (WAC 212 -80) 2. H.V.A.C. units rated at 2,000 cfm require auto - shutdown devices. These devices shall be separately zoned in the alarm panel and local U.L. central station City of Tukwila FIRE DEPARTMENT 444 Andover Park East Tukwila, Washington 98188 -7661 (206) 575 -4404 John W. Rants, Mayor supervision is required. (City Ordinance #1528) Yours truly, .:4 v10 Project�� _ ,, � e _ � ta Type of fns n: , ; J A 1es tko: J R1__. \ . , Date Called: ) 1 _) b - 9 g_. Special Instructions: . (b..O D -1\-'n J Date Wanted: 11 -- 1 - q )___Alp . Requester: ^�Q-'I "Yl P R s Peen No.: 544 - 3qq: PECT ( INSPECTION RECORD l Retain a copy with permit CITY OF TUKWILA BUILDING DIVISION 6300 Southcenter Blvd., #100, Tukwila, WA 98188 Recap No.: Date: PERMIT 206) 431 -370 Approved per applicable codes. ❑ Corrections required prior to approval. Inspector: Date: / // Cl $30.00 REINSPECTION EE REQUIRED. Prior to reinspection, fee must be paid at 6300 Southcenter Blvd., Sqite 100. Call to schedule reinspection. — Prole I q_. I o 1 Type of Inspect �i, -c` A re iIl � ,JAL toy, �. Called: ; q2' nstructions: g D ate Wanted: Requester: Phone No.: 22A — t COMMENTS: I Inspector: O INSPECTION RECORD C Retain a copy with permit CITY OF TUKWILA BUILDING DIVISION 6300 Southcenter Blvd., #100, Tukwila, WA 98188 0 Approved per applicable codes. 7( ' r..J k c7k- J (206) 431 -3670 ❑ Corrections required prior to approval. Date: 7/z 9 I� 2. 1 ❑ $30.00 REINSPECTION FEE REQUIRED. Prior to relnspection, fee must be paid at 6300 Southcenter Blvd., Suite 100. Call to schedule reinspection. I Recept No.: Dale: CITY OF TUKWILA Id: ACTP125 Keyword: UACT Activity Table Processing Permit No: M92 -0054 Status: PENDING Base Information Parcel No: 000340 -0018 Owner: THE BOEING COMPANY SLB Plan Ck Approved: PENDING Applied: 3/17/1992 Issued: A Completed: / / To Expire: Validated By: Status: Active /Inactive: Nature of Work: Location: Category: NRES Inspector Area: Valuation: 541,125.00 UMC Edition (Yr): 1988 Fire Protection: Use Change (Y /N): Storage of Flammable /Hazardous Materials: HVAC UPGRADE FOR +FF:I <.?=>P.I#SE�n3°;E,.. dxv�*:s??1:KV�Y� - <u, xr:`.i�r�X�7i3':�,��t; cr (RES, NRES, STOV) F7= Update, F2= Previous Line, ESC = Cancel Update CITY OF TUKWILA Id: ROUT130 Keyword: UACT User: 1677 06/10/92 Activity document routing maintenance. MECHANICAL PERMIT Permit No: M92 -0054 Route: 1 Current Route Line: 2 of 5 Packet Units Description Station Status Received Assigned Complete aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa aaaaaaaaaaaaaaa Packet Units Action Station Initials Status Received Assigned Completed MECH 01 01 C BLDG KEN Approved 03/18/92 06/10/92 06/10/92 Priority (0 /low..9 /high): 0 Regular hours (HH.MM): Comments l�[TW 2J r 3[, 0... Overt , kt } "y �4� ' �r i� t i } ` �� -REVIEW sE.. �:4��T``.''";;.:i ���rr; ���'. r* �'�� `�3�ae1.:� ��.:��:�;:��tM'i ' AN ` - -- F1 =Help, ESC =Exit current screen. User: 1677 06/10/92 MECHANICAL PERMIT Tenant: THE pBOEZNG COMPANYv #8 .., 101 Address: 9725 EAST MARGINAL WY' S'` " ''' L;; Type: B -MECH Vers: 9101 Screen: 01 e Hours I1I - "MM, °: �� ; sRE Q UIRE � AUTO SHUT OFF 5 6[ 7[ 8 [ 9[ 10[ aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa BE &C ENGINEERS MECHANICAL CALCULATIONS FOR HVAC SYSTEMS: AH2EI6A, AH2E17A BUILDING 9 -101, SEATTLE, WA EEIP PHASE 3 -E MARCH 9, 1992 Prepared By: BE &C ENGINEERS P.O. Box 3707 Seattle, Washington 98124 -2207 Prepared For: BOEING SUPPORT SERVICES Seattle, Washington Document Number: 326 - 90133 - CALC -M -11 Prepared By: Checked By: Approved By: ` J L PP . Rosse /A Killip K. Ramsey, P. RECEIVED CITY OF TI IKWILA MAR 1 7 1992 PERMIT CENTER JOBNO. 9°13'3 (M-C-) q In 8c'-/y S.3 ( i"lA FIG. BY $' � dSS� CHECKED BY DATE 16/I7/9 SHEET�L OF -I, ,4 Hu Stzt ►.I, c.,', AA PROJECTE.VP) 3- ` � - 10 �, 2 BitA\ L--17.) 1 N61 Lc t k U „ VALIAE s'. A) Tcc : TZ VALUES ; INmoF‹Vt∎ c-,∎ %h." CONC. bEc. K 2Y Totem Nu., Slyd,� � tMt 1'kEt.t r..ttE . BE &C ENGINEERS C_ Ie\LC S REI oCoi -x -E G IADAT.PO4E _ Z � � ? L.`>' t C rAI S 1h" CoNc. SuRFAcE Ou i bE tA Yip Cc ►, �.-\ 1 K VnLv ;� . lt`1Doo� t t..r� R-14 'FIE Lh�S 6 CoKC u FILM tr Co IL.t,o (� (b. o s) ti = I5.33 P.O. Box 3707 Seattle, Washington 98124.2207 Mail Stop: OI p65 37u/ AkkRA a2, c -9 f- FLOORS INDOOR PARTITIONS R VALUES BE &C ENGINEERS P.O. Box 3707 Seattle, Washington 98124.2207 Mail Stop: PROJECT EE 1 t1 1'•'HA ?' E " IOI Z- JOB NO C IOCCqtt.cl 9 6 soy (BM ^) FIG. BY R° sSG CHECKED BY DATE I v /17 / I SHEET 3 OF FS Y 71971 0011 R ion CoNFEtz[: RK(6) GONFEIZE w,E RM (G) GENERA... b rFtCE 4 I0 AREA. ZE..VE Awe.. E i (o CONFERENCE' ' �l CONrE;<ENCE 504 FT Z40 FT Z.HO rN ` 2�10 Ff 1 6o '7 3.54 F? i BE &C ENGINEERS P.O. Box 3707 Seattle, Washington 98124.2207 Mail Stop: PROJECT RE-I FIG. BY IzcSSE JOB NO C / n /33(& fC ' /6 8 W &1 4 CHECKED BY DATE J// 7/'?/ SHEET OF.8 �-L PROJECT 3- c• FIG. BY CHECKED BY BE&C P.O. Box 3707 ENGINEERS Seattle, Washington 98124•2207 Mail Stop: k 1 4 \VAN_ U. \ 1 E 6 k s ‘.› O5P\ CF A (MT k Ac)( 10, 1 0 E74 :_ r ts ", )( z° FP \ iO3f3cl Fl \ 0 4190 7 Ai-1/4 2- E (D TC>1 t_ ARE/1/4 = A zviA - r6 - 14.L. -= Lot AzRA 5t\ 2. 0 77 c...r Mint Ak-kterik 2..,o8 c.1-- Co\L. Lc A) V•- - i00 Re C.tC ■.\ R.. f1/4 (-VC - 5 0" F blA% LID( INAC5CTEIA JOB NO. 9 DATE /e / I SHEET. OF S (Am. V0‘,..ur r...) SVET.c..■F t cAktiZ.C (PE •IS S pikce (TIME Wikr\t Low= °;384r12)(7- 0,241-k TI N ( I WK) loc. ) AVIITIO\ = MVII r LOT, I C A Erm => VAI.EnAWKKI-MF Lo 61, 0 6 misli A:v BE &C ENGINEERS P.O. Box 3707 Seattle, Washington 98124.2207 Mail Stop: PROJECT � 1 P 1-i A E. 3• E FIG. BY ' R • CHECKED BY DATE Iv(L� /9 I SHEET.fa. OF c_5. H EP. V % Nat" l... d +\ t� (c 1` oT�L u.) 1 = I, 7_ �--• ZD % 5 AT `t FAc cN "PE I ,..ps s _ �E \Z E 1G. A = 5 / � 69 / Biz %, ) E et-dK. s 42 t---7 = 5(0, o .6 TaTAt... Wa ' t p 4.■-'1 z.E.1(��, ..... Z 89 a t -I.L.■ AN2ElbA ._ . 3 'EA-1 G>'T a 11V AR M (i t` �o wAlz up Lc A.G F' ,bvZE1`7' = I.z E.:n.4 1. 56of0 248BT'N1.I ) x $M AH a E /7A /76 O , M5 H 7 babeA JOB NO. 9 U I FE:c. -� 5 / ) (TJ 1371414 1 13. �o aL P�t.rx,,= .,1,1 -A BE&C ENGINEERS P.O. Box 3707 Seattle, Washington 98124.2207 Mail Stop: . . ;'Huss C JOB NO. t10 t / � ' r ° F . !" PROJECT FIG. BY c �SS� CHECKED BY DATE 11/ 17:19 9 I SHEET OF f 4-r-EJ < &In LOA D-'E \T l i tC l.. L W 0 A• VE.AJ - r\ L-.t1: r i c *J L-0 At, -f- lq 1,4 _ �.si�~r'" LOA 0,5,AgE.14TI ►014 Loki = C 'M(I, Hl-1 1(AA l'E T l N.. (.g, L0)4\1j 201 C FA' -\ ∎ ,0 8 ) 806- Zo° 7 L tit (51) .671 .73rL4 H A tel A c E RK1 ih\Ci `u (zpaS cre.- ,)(1,0( -. e-: 4 )) . (5 ) OZE /q / , 3 ga �t 0. BE&C ENGINEERS P.O. Box 3707 Seattle, Washington 98124-2207 Mail Stop: PROJECT E //./ RA / 4"Z 3 FIG, BY CHECKED BY DATE / /// ) SHEET 3 OF 8 JOB NO c r 0 133 ( C: /1/1ZE/ Ce›A P4< Cr-w 1.-e->AD = 3M5H 72;7/1 77-'7A 4- IS / Bll 7:if L- 4/ Coa-- S = 407 Imciti 7 jU lamb be / 8,5 mem Us& 2. 10.5a.e.E 4 Wz/7A a C0/2__ 7/1 16 8. 7 /q "7 L. X . 7.€7VE - PRCCvaesi ki r czr U sC tUct"; P/C 5 3 0 MBH 7671( L Ibrac- 1 A K Ce` I I— Lomi., AF:s 3 8 , 0,RE - rvr 15 .1 5 2/.13 meH .5-Eosuv..E rane Air Conditioning Economics By: Trane Customer Direct Service Network ************************************ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * ** *fit * * * * * ** * * * * TRACE 600 ANALYSIS by Trane Customer Direct Service Network ************ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * ** ************** * * * * * * * * * * * * * * * * * * * * * * * * * * * * * ** BUILD s D CALCULATIONS FOR: NORTH UNIT) EEIP PROJECT, PHASE 3 -E BOEING MILITARY AIRPLANES FIG. BY: S.ROSSE H2E16 Weather File Code: Location: Latitude: Longitude: Time Zone: Elevation: Barometric Pressure: Summer Clearness Number: Winter Clearness Number: Summer Design Dry Bulb: Summer Design Wet Bulb: Winter Design Dry Bulb: Sumner Ground Relectance: Winter Ground Relectance: Air Density: Air Specific Heat: Density- Specific Heat Prod Latent Heat Factor: Enthalpy Factor: Design Simulation Period: System Simulation Period: Cooling Load Methodology: Time /Date Program was Run: Dataset Name: SEATTLE 47.0 (deg) 122.0 (deg) 8 386 (ft) 29.5 (in. Hg) 0.95 0.95 85 (F) 68 (F) 20 (F) 0,20 0.20 0.0749 0.2444 1.0988 4,836.9 4,4953 (Lbm /cuft) (Btu /lbm /F) (Btu- min. /hr /tuft /F). (Btu - min. /hr /cuft) (Lb- min. /hr /tuft) 12: 2:20 12/18/91 AH2E16A .TM ** * * ** ** • ** • July To September January To December CLTD /CLF (Transfer Function Method) V 60 PAGE I Trane Air Conditioning Economics By: Trane Customer Direct Service Network AIRFLOW - ALTERNATIVE 1 SYSTEM SUMMARY (Design Airflow Quantities) Main Auxil. Room Outside Cooling Heating Return Exhaust Supply Exhaust System System Airflow Airflow Airflow Airflow Airflow Airflow Airflow Number Type (Cfm) (Cfm) (Cfm) (Cfm) (Cfm) (Cfm) (Cfm) 1 VAV 2,077 14,390 0 14,390 14,390 0 0 Totals 2,077 14,390 0 14.390 14,390 0 0 CAPACITY - ALTERNATIVE 1 SYSTEM SUMMARY (Design Capacity Quantities) V. 600 PAGE 2 • Cooling Heating Main Sys. Aux. Sys. Opt, Vent Cooling Main Sys. Aux. Sys. Preheat Reheat Humidif. Opt. Vent Heating System System Capacity Capacity Capacity Totals • Capacity Capacity Capacity Capacity Capacity Capacity Totals Number Type (Tons) (Tons) ,(Tons) (Tons) (Btuh) (Btuh) (Btuh) (Btuh) (Btuh) (Btuh) (Btuh) 1 VAV 41,8 0,0 0.0 41.8 - 128,537 0 - 73,356 - 102,691 0 '� 0 - 201,893 Totals 41.8 0,0 0.0 41,8 - 128,537 0 - 73,356 - 102,691 0 0 -201,893 Trane Air Conditioning Economics By: Trane Customer Direct Service Network System 1 Block VAV - VARIABLE AIR VOLUME fi 7 -•• * * * * * * * * * * * * * * * * * * * ** COOLING COIL PEAK * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * ** ad at Time = => Mo /Hr: 7/14 * iitside Air = => OADB /WB /HR: 84/ 69/ 83.1 * Envelope Loads Skylite Solr Skylite Cond Roof Cond Glass Solar Glass Cond Wall Cond Partition Exposed Floor Infiltration Sub Total = => Internal Loads Lights People Misc Sub Total = => Ceiling Load Outside Air Sup. Fan Heat Ret. Fan Heat Duct Heat Pkup OV /UNDR Sizing Exhaust Heat Terminal Bypass Main Htg Aux Htg Preheat Reheat Humidif Opt Vent Total Space Sens. +Lat. (Btuh) 6,15 53,99 60,151 0 t . Total Capacity (Tons) (Mbh) li Clg 41.8 501.3 Aux Clg 0.0 0.0 Opt Vent 0.0 Totals 41.8 HEATING COIL SELECTION Ret. Air Sensible (Btuh) 0 0 18,836 0 0 0 18,836 51,965 17,322 118,286 121,844 16,000 292,094 33,322 6,260 -6,260 0 0 0 - 15,756 -4,342 0 Grand Total = => 358,506 25,800 Capacity Coil Airfl Ent (Mbh) -128.5 0.0 -73.4 -102.7 0.0 0.0 -201.9 (cfm) Deg F 0 0.0 0 0.0 2,077 20.0 7,788 52.1 0 0.0 0 0,0 Ret. Air Latent (Btuh) COOLING COIL SELECTION Sens Cap. Coil Airfl (cfm) 14,339 0 0.0 0 0 0 Net Total (Btuh) 0 0 18,836 0 6,154 53,997 0 78,987 Lvg Type Deg F Vent 0.0 lnfil 0.0 Supply 52.1 Mincfm 68.0 Return 0.0 Exhaust 0.0 Rm Exh Auxil Percnt Of Tot ( %) 0.00 0.00 3.76 0.00 0.00 0.00 1.23 10.77 0.00 15.76 * * 69,286 13.82 * 51,965 17.30 118,286 23.60 * 59,143 19.69 0 137,844 27.50 * 121,844 40.56 0 325,416 64.91 * 232,951 77.54 0 0.00 * 7,333 2.44 0 56,254 11.22 * 0 0.00 44,985 8.97 * 0.00 0 0.00 * 0.00 0 0.00 * 0.00 0 0.00 * 0 0.00 0 -4,342 -0.87 * 0.00 0 0 -0.00 * 0.00 * 0 501,300 100.00 * 300,436 100.00 Entering DB /WB /HR Deg F Deg F Grains 78.0 62.8 62.4 0.0 0.0 0.0 0.0 0.0 0.0 AIRFLOWS (cfm) Co. '• Heating 2,077 0 0 8 7,788 14,390 0 2,077 0 0 0 0 .0 * Space * Sensible * (Btuh) * 0 * 0 * 0 * 0 * 0 * 0 * 6,154 * 53,997 * 0 * 60,151 CLG SPACE PEAK * * * * * * * * * * ** HEATING COIL PEAK * * * * * * ** Mo /Hr: 7/17 * Mo /Hr: 13/ 1 OADB: 83 * OADB: 20 * Percnt Of Tot ( %) 0.00 0.00 0.00 0.00 0.00 0.00 2.05 17.97 0.00 20.02 Leaving DB /WB /HR Deg F Deg F Grains 52.1 50.5 52.9 0.0 0.0 0.0 0.0 0.0 0.0 * * Space Peak Space Sens (Btuh) -- ENGINEERING CHECKS- - Clg % OA 14.4 Clg Cfm /Sqft 1.39 Clg Cfm /Ton 344.47 Clg Sqft/Ton 248.57 Clg Btuh /Sqft 48.28 No. People 167 Htg % OA 0,0 Htg Cfm /SqFt 0.00 Htg Btuh /SqFt -19.44 -25,84 0 Coil Peak Tot Sens (Btuh) -25,84 -25,84 - 109,53 - 25,846 - 135,38 V 600 PAGE 3 Percnt Of Tot ( %) 0.00 0.00 19.09 0.00 0.00 0.00 0.00 0.00 0.00 19.09 0.00 0.00 0.00 0.00 0.00 80.91 0.00 0.00 0.00 0.00 0.00 0.00 100.00 AREAS Gross Total Glass (sf) ( %) Floor 10,384 Part 3,900 ExF1r 10,384 Roof 10,384 0 0 Wall 0 0 0 -- TEMPERATURES (F) - -- Type Clg Htg SADB 56.0 68.1 Plenum 76.9 60.1 Return 76.9 60.1 Ret /0A 78,0 49,4 Runarnd 75.0 68.0 Fn MtrTD 0.4 0.4 Fn B1dTD 1.0 1.0 Fn Frict 1.5 1,5 Trane Air Conditioning Economics 6y: Trane Customer Direct Service Network ENGINEERING CHECKS - ALTERNATIVE 1 ENGINEERING CHECKS Percent Cooling - -- Heating - - -- System Main/ System Outside Cfm/ Cfm/ Sq Ft Btuh/ Cfm/ Btuh/ Floor Area Number Auxiliary Type Air Sq Ft Ton /Ton Sq Ft Sq Ft Sq Ft Sq Ft 1 Main VAV 14.43 1.39 344.5 248.6 48.28 0.00 -19.44 10.384 MAIN SYSTEM COOLING - ALTERNATIVE 1 V 600 PAGE 4 PEAK COOLING LOADS (Main System) Space Coil Peak OA Rm Supp. Space Space Space Peak OA Rm Supp. Coil Coil Coil Time Cond. Dry Dry Air Sens. Lat. Time Cond. Dry Dry Air Sens. Lat. Room Mo /Hr DB /WB Blb Bulb Flow Load Load Mo /Hr DB /WB Blb Bulb Flow Load Load Number Description (F) (F) (F) (Cfm) (Btuh) (Btuh) (F) (F) (F) (Cfm) . (Btuh) (Btuh) 1 GENERAL OFFICE 7/17 83 65 75 56.0 11,450 239,057 32,518 7/14 84 69 75 56.0 11,405 331,458 63,140 Zone 1 Total /Ave. 83 65 75 56.0 11,450 239,057 32.518 84 69 75 56.0 11,405 e 3311-458 63,140 Zone 1 Block 7/17 83 65 75 56.0 11,450 239,057 32,518 7/14 84 69 75 56.0 11,405 331,458 63,140 2 LARGE CONF ROOM 7/17 83 65 75 56.0 1,080 22,553 10,650 7/14 84 69 75 56.0 1,078 28,157 12,335 Zone 2 Total /Ave. 83 65 75 56,0 1,080 22,553 10,650 84 69 75 56.0 1,078 28,157 12,335 Zone 2 Block 7/17 83 65 75 56.0 1,080 22,553 10,650 7/14 84 69 75 56.0 1,078 28,157 12,335 3 SMALL CONF RM A 7/17 83 65 75 56.0 630 13,146 5,325 7/14 84 69 75 56.0 628 16,176 6,127 Zone 3 Total /Ave. 83 65 75 56.0 630 13,146 5,325 84 69 75 56.0 628 16,176 6,127 Zone 3 Block 7/17 83 65 75 56.0 630 13,146 5,325 7/14 84 69 75 56.0 628 16,176 6,127 4 SMALL CONF RM B 7/17 83 65 75 56.0 630 13,146 5,325 7/14 84 69 75 56.0 628 16,176 6,127 Zone 4 Total /Ave. 83 65 75 56.0 630 13.146 5,325 84 69 75 56.0 628 16,176 6,127 Zone 4 Block 7/17 83 65 75 56.0 630 13,146 5,325 7/14 84 69 75 56.0 628 16,176 6,127 5 SMALL CONF RM C 7/17 83 65 75 56.0 600 12,534 5,325 7/14 84 69 75 56,0 599 15,477 6,127 5 Total /Ave. 83 65 75 56.0 600 12,534 5,325 84 69 75 56,0 599 15,477 6,127 5 Block 7/17 83 65 75 56.0 600 12,534 5,325 7/14 84 69 75 56.0 599 15,477 6,127 11 ;;sem 1 Total /Ave. 83 65 75 56,0 14,390 300,436 59,143 84 69 75 56.0 14,339 407,443 93,856 System 1 Block 7/17 83 65 75 56.0 14,390 300,436 59,143 7/14 84 69 75 56,0 14,339 407,443 93,856 Trane Air Conditioning Economics By: Trane Customer Direct Service Network COOLING LOADS AT COIL PEAK - ALTERNATIVE 1 Room Number Description 1 GENERAL OFFICE Zone 1 Total /Ave. Zone 1 Block 2 LARGE CONE ROOM Zone 2 Total /Ave. Zone 2 Block 3 SMALL CONF RM A Zone 3 Total /Ave. Zone 3 Block 4 SMALL CONF RM B Zone 4 Total /Ave. Zone 4 Block 5 SMALL CONE RM C Zone 5 Total /Ave. Zone 5 Block System 1 Total /Ave. System 1 Block Lights Room Sensible (Btuh) INTERNAL COOLING LOADS (At time of Coil Peak) Lights Ret. Air Lites Sensible CLF (Btuh) Misc. People People Peopl Space Sensible Latent. CLF Sensible (Btuh) (Btuh) (Btuh) 45,839 15,280 1.000 32,518 32,518 1.000 102,168 45,839 15,280 1.000 32,518 32,518 1.000 102.168 45,839 15,280 1.000 32,518 32,518 1.000 102,168 2,522 841 1.000 10,650 10,650 1.000 5,666 2,522 841 1.000 10,650 10,650 1.000 5,666 2,522 841 1.000 10,650 10,650 1.000 5,666 1,201 400 1.000 5,325 5,325 1.000 4,710 1,201 400 1.000 5,325 5,325 1.000 4,710 1.201 400 1.000 5,325 5,325 1.000 4,710 1,201 400 1.000 5,325 5,325 1.000 4,710 1,201 400 1.000 5,325 5,325 1.000 4,710 1,201 400 1.000 5,325 5.325 1.000 4,710 1,201 400 1.000 5,325 5,325 1.000 4,590 1,201 400 1.000 5,325 5,325 1.000 4,590 1,201 400 1.000 5,325 5,325 1.000 4,590 51,965 17,322 1,000 59,143 59,143 1.000 121,844 51,965 17,322 1.000 59,143 59.143 1.000 121,844 Misc. Space Latent (Btuh) Misc. Ret. Air Misc. Sensible CLF Total (Btuh) (Btuh) 16.00 16,00 16,00 16,00 16,00 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 •1- -.000 1.000 1.000 1.000 1.000 V 600 PAGE 5 244,323 244,323 244,323 30,328 30,328 30,328 16,961 16,961 16,961 16,961 16,961 16,961 16,842 16,842 16,842 325,416 325,416 Trane Air Conditioning Economics By: Trane Customer Direct Service Network COOLING LOADS AT SPACE PEAK- ALTERNATIVE 1 f Room Number Description 1 GENERAL OFFICE Zone 1 Total /Ave. Zone 1 Block 2 LARGE CONF ROOM Zone 2 Total /Ave. Zone 2 Block 3 SMALL CONE RM A Zone 3 Total /Ave. Zone 3 Block 4 SMALL CONF RM B Zone 4 Total /Ave. Zone 4 Block 5 SMALL CONF RM C Zone 5 Total /Ave. Zone 5 Block System 1 Total /Ave. System 1 Block INTERNAL COOLING LOADS (At time of Space Peak) Lights Lights Misc. Room Ret. Air Lites People People Peopl Space Sensible Sensible CLF Sensible Latent CLF Sensible (Btuh) (Btuh) (Btuh) (Btuh) (Btuh) 45,839 15,280 1.000 32,518 32,518 1.000 102,168 45,839 15,280 1.000 32,518 32,518 1.000 102,168 45,839 15,280 1.000 32,518 32,518 1.000 102,168 2,522 841 1.000 10,650 10,650 1.000 5,666 2,522 841 1.000 10,650 10,650 1.000 5.666 2,522 841 1.000 10,650 10,650 1.000 5,666 1,201 40D 1,000 5,325 5.325 1.000 4,710 1,201 400 1.000 5,325 5,325 1,000 4,710 1,201 400 1,000 5,325 5,325 1.000 4,710 1,201 400 1.000 5,325 5,325 1.000 4,710 1,201 400 1.000 5,325 5.325 1.000 4,710 1,201 400 1.000 5.325 5,325 1,000 4,710 1,201 400 1.000 5,325 5,325 1.000 4,590 1,201 400 1.000 5,325 5,325 1,000 4,590 1,201 400 1.000 5,325 5,325 1.000 4,590 51.965 17,322 1,000 59,143 59,143 1.000 121,844 51,965 17,322 1.000 59,143 59,143 1.000 121,844 Misc. Space Latent (Btuh) 16,00 16,00 16,00 16,00 16,00 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1,000 1.000 1.000 1.000 -MOD 1.000 1.000 1.000 1.000 V 600 PAGE 6 Misc. Ret. Air Misc. Sensible CLF Total (Btuh) (Btuh) 244,323 244,323 244.323 30,328 30,328 30,328 16,961 16,961 16,961 16,961 16,961 16,961 16,842 16,842 16,842 325,416 325,416 Room Number Trane Air Conditioning Economics By: Trane Customer Direct Service Network COOLING LOADS AT COIL PEAK - ALTERNATIVE 1 1 GENERAL OFFICE Zone 1 Total /Ave. Zone 1 Block 2 LARGE CONF ROOM Zone 2 Total /Ave. Zone 2 Block 3 SMALL CONF RM A Zone 3 Total /Ave. Zone 3 Block 4 SMALL CONF RM B Zone 4 Total /Ave. Zone 4 Block 5 SMALL CONF RM C Zone 5 Total /Ave. Zone 5 Block System 1 Total /Ave. System 1 Block �m r ,er Description 1 GENERAL OFFICE Zone 1 Total /Ave. Zone 1 Block 2 LARGE CONF ROOM Zone 2 Total /Ave. Zone 2 Block 3 SMALL CONF RM A Zone 3 Total /Ave. Zone 3 Block 4 SMALL CONF RM B Zone 4 Total /Ave. Zone 4 Block 5 SMALL CONF RM C Zone 5 Total /Ave. Zone 5 Block System 1 Total /Ave. System 1 Block 16,639 29.3 16,639 29.3 16,639 29.3 903 28.9 903 28.9 903 28.9 430 28.9 430 28.9 430 28.9 430 28.9 430 28.9 430 28.9 434 29.2 434 29.2 434 29.2 18,836 29.3 18,836 29.3 BUILDING E 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0,0 0.0 BUILDING ENVELOPE COOLING LOADS V 600 PAGE 7 (Roof - Skylight) (At time of Coil Peak) Roof Roof Skylight Skylight Return Air Roof Space Roof Skylight Skylight Skylt Return Air Skylt Space Skylt Sensible R.A. Sensible Space Return Air Space Solar Conduction R.A. Conduction Space Load CLTD Load CLTD Solar Solar CLF Load CLTD Load CLTD Description (Btuh) (F) (Btuh) (F) (Btuh) (Btuh) (Btuh) (F) (Btuh) (F) (At 31.2 31.2 31.2 30.8 30.8 30.8 30.8 30.8 30.8 30,8 30.8 30.8 31.1 31.1 31.1 31.2 31.2 VELOPE COOLING LOADS (Wall - Window) time of Coil Peak) 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0,0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 o.000 o:6 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 Wall Wall Wall Wall Glass Glass Glass Glass Glass Glass Glass Plenum Plenm Space Space Space Return Air Solar Space Space Return Air R.A. Load CLTD Load CLTD Solar Solar CLF Conduction CLTD Conduction CLTD (Btuh) (F) (Btuh) (F) (Btuh) (Btuh) (Btuh) (F) (Btuh) (F) 0 0.000 0.0 0.0 0 0.000 0.0 0.0 0 0.000 0.0 0,0 0 0.000 0.0 0.0 0 0.000 0.0 0,0 0 0.000 0.0 0.0 0 0.000 0.0 0,0 0 0.000 0.0 0.0 0 0.000 0.0 0,0 0 0.000 0.0 0.0 0 0.000 0.0 0.0 0 0.000 0.0 0.0 0 0.000 0,0 0.0 0 0.000 0.0 0,0 0 0.000 0.0 0.0 0 0.000 0.0 0.0 0 0.000 0.0 0.0 BUILDING ENVELOPE COOLING LOADS (Exposed Floor - Partitions - Infiltration) (At time of Coil Peak) Exposed Expsd Plenm Ceiling Floor Floor Partition Part. Infilt, Infilt. Infilt. Dry B Sensible Envelope Room Sensible CLTD Sensible CLTD Airflow Sensible Latent Temp. Load Total Number Description •(Btuh) (F) (Btuh) (F) (Cfm) (Btuh) (Btuh) (F) (Btuh) (Btuh) 1 GENERAL OFFICE 47,632 20.0 4,431 20.0 0 0 0 76.9 5,522 74,224 Trane Air Conditioning Economics By: Trane Customer Direct Service Network COOLING LOADS AT COIL PEAK - ALTERNATIVE 1 C BUILDING ENVELOPE COOLING LOADS. (Exposed Floor - Partitions - Infiltration) (At time of Coil Peak) Exposed Expsd Floor Floor Partition Part. Infilt. Room Sensible CLTD 'Sensible CLTD Airflow Number Description (Btuh) (F) (Btuh) (F) (Cfm) Zone 1 Total /Ave. 47,632 20.0 Zone 1 Block 47,632 20.0 2 LARGE CONF ROOM 2,621 20.0 Zone 2 Total /Ave. 2,621 20,0 Zone 2 Block 2,621 20.0 3 SMALL CONE RM A 1,248 20.0 Zone 3 Total /Ave. 1,248 20.0 Zone 3 Block 1,248 20.0 4 SMALL CONE RM B 1,248 20.0 Zone 4 Total /Ave. 1,248 20.0 Zone 4 Block 1,248 20.0 5 SMALL CONE RM C 1,248 20.0 Zone 5 Total /Ave, 1,248 20.0 Zone 5 Block 1,248 20.0 System 1 Total /Ave. 53,997 20.0 System 1 Block 53,997 20.0 4,431 20.0 4,431 20.0 739 20.0 739 20.0 739 20.0 492 20.0 492 20.0 492 20,0 492 20.0 492 20.0 492 20.0 0 0.0 0 0.0 0 0.0 6,154 20.0 6,154 20.0 V 600 PAGE Plenm Ceiling Infilt. Infilt, Dry B Sensible Envelope Sensible Latent Temp. Load Total (Btuh) (Btuh) (F). (Btuh) (Btuh) 0 0 76.9 5,522 74,224 0 0 76.9 5,522 74,224 0 0 76.9 304 4,566 0 0 76.9 304 4,566 0 0 76.9 304 4,566 0 D 76.9 145 2,315 0 0 76,9 145 2,315 0 0 . 76.9 145 2,315 0 0 76.9 145 2,315 0 0 76,9 . 145 2,315 0 0 76.9. 145 2,315 0 0 76.9 145 1,827 0 0 76.9 145- 1,827 0 0 76.9 ' 145 .1,827 0 0 76.9 6,260 85,247 0 .0 76.9 6,260 85,247 Trane Air Conditioning Economics By Trane Customer Direct Service Network COOLING LOADS AT SPACE PEAK - ALTERNATIVE 1 Room Number Description 1 GENERAL OFFICE Zone 1 Total /Ave. Zone 1 Block 2 LARGE CONF ROOM Zone 2 Total /Ave. Zone 2 Block 3 SMALL CONF RM A Zone 3 Total /Ave. Zone 3 Block 4 SMALL CONF P.M 8 Zone 4 Total /Ave. Zone 4 Block 5 SMALL CONF RM C Zone 5 Total /Ave. Zone 5 Block System 1 Total /Ave. System 1 Block 1 (7 3m er Description 1 GENERAL OFFICE Zone 1 Zone 1 2 LARGE Zone 2 Zone 2 3 SMALL Zone 3 Zone • 3 4 SMALL Zone 4 Zone 4 5 SMALL Zone 5 Zone 5 System 1 System I Total /Ave. Block CONF ROOM Total /Ave. Block CONF RM A Total /Ave. Block CONF RM B Total /Ave. Block CONE RM C Total /Ave. Block Total /Ave. Block Room Number Description 1 GENERAL OFFICE Roof Return Air Sensible Load (Btuh) 22,133 22,133 22,133 1,205 1,205 1,205 574 574 574 574 574 574 581 581 581 25,067 25,067 BUILDING ENVEL (Roof (At time Roof Roof Space Roof R.A. Sensible Space CLTD Load CLTD (F) (Btuh) (F) Wall Wall Plenum Plenm Load CLTD (Btuh) (F) Exposed Floor Sensible (Btuh) 47,632 39.0 39.0 39.0 38.6 38.6 38.6 38.6 38.6 38.6 38.6 38.6 38.6 39.1 39.1 39.1 38.9 38.9 BUILDING 'E (At 0.0 0.0 0,0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0,0 0.0 0.0 0.0 0.0 0.0 Expsd Floor CLTD (F) Wall Space Load (Btuh) 41.2 41.2 41.2 40.8 40.8 40.8 40.8 40.8 40.8 40.8 40.8 40.8 41.3 41.3 41.3 41.2 41.2 VELOPE COOLING LOADS (Wall - Window) time of Space Peak) Wall Space CLTD (F) 0.0 0.0 0.0 0.0 0,0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0,0 0.0 0.0 0.0 Partition Part. Sensible CLTD (Btuh) (F) OPE COOLING LOADS - Skylight) of Space Peak) Skylight Skylight Skylt Return Air Space Solar Solar Solar CLF (Btuh) (Btuh) Glass Glass Space Return Air Solar Solar (Btuh) (Btuh) 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 Glass Glass Solar Space CLF Conduction (Btuh) 0.000 0.000 0,000 0.000 0.000 0,000 0.000 0.000 0.000 0.000 0.000 0,000 0.000 0.000 0.000 0.000 0.000 BUILDING ENVELOPE COOLING LOADS (Exposed Floor - Partitions - Infiltration) (At time of Space Peak) Skylight Skylight Return Air Skylt Space Conduction R.A. Conduction Load CLTD Load (Btuh) (F) (Btuh) Glass Space CLTD (F) 0.0 0.0 0.0 0.0 0,0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 Glass Return Air Conduction (Btuh) V 600 PAGE 9 Skylt Space CLTD (F) Glass R.A. CLTD (F) 0.0 0.0 0.0 0.0 0,0 0.0 0.0 0,0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 Plenm Ceiling lnfilt. Infilt, Infilt. Dry 8 Sensible Envelope Airflow Sensible Latent Temp. Load Total (Cfm) (Btuh) (Btuh) (F) (Btuh) (Btuh) 20.0 4,431 20.0 0 0 0 77.2 6,469 80,664 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 Trane Air Conditioning Economics By: Trane Customer Direct Service Network COOLING LOADS AT SPACE PEAK - ALTERNATIVE I BUILDING ENVELOPE COOLING LOADS (Exposed Floor - Partitions - Infiltration) (At time of Space Peak) Exposed Expsd Plenm Ceiling Floor Floor Partition Part. Infilt. infilt. lnfilt. Dry B Sensible Envelope Room Sensible CLTD Sensible CLTD Airflow Sensible Latent Temp. Load Total Number Description (Btuh) (F) (Btuh) (F) (Cfm) (Btuh) (Btuh) (F) (Btuh) (Btuh) Zone 1 Total /Ave. 47,632 20.0 4,431 20.0 Zone I Block 47,632 20.0 4,431 20.0 2 LARGE CONF ROOM 2,621 20.0 739 20.0 Zone 2 Total /Ave. 2,621 20.0 739 20.0 Zone 2 Block 2,621 20.0 739 20.0 3 SMALL CONF RM A 1,248 20,0 492 20.0 Zone 3 Total /Ave. 1,248 20.0 492 20.0 Zone 3 Block 1,248 20.0 492 20.0 4 SMALL CONF RM B 1,248 20.0 492 20.0 Zone 4 Total /Ave. 1,248 20.0 492 20.0 Zone 4 Block 1,248 20.0 492 20.0 5 SMALL CONF RM C 1,248 20.0 0 0.0 Zone 5 Total /Ave. 1,248 20.0 0 0.0 Zone 5 Block 1,248 20.0 0 0.0 System 1 Total /Ave. 53,997 20.0 6,154 20.0 System 1 Block 53,997 20.0 6,154 20,0 77.2 6,469 80,664 77.2 6,469 80,664 77.2 356 4,921 77.2 356 4,921 77.2 356 4,921 77.2 169 2,484 77.2 169 2,484 77.2 169 2,484 77.2 169 2,484 77.2 169 2,484 77.2 169 2,484 77.2 169 1,999 77.2 169- 1,999 77.2 ' 169 1,999 77.2 7,333 92,551 77.2 7,333 92,551 V 600 PAGE 10 Trane Air Conditioning Economics By: Trane Customer Direct Service Network HEATING LOADS AT SPACE PEAK - ALTERNATIVE 1 Room Number Description Zone Zone 2 LARGE Zone 2 Zone 2 3 SMALL Zone 3 Zone 3 4 SMALL Zone 4 Zone 4 5 SMALL Zone 5 Zone 5 System 1 System 1 1 GENERAL OFFICE 1 Total /Ave. 1 Block ler Description CONF ROOM Total /Ave. Block CONF RM A Total /Ave. Block CONF RM B Total /Ave. Block CONF RM C Total /Ave. Block Total /Ave. Block 1 GENERAL OFFICE Zone 1 Total /Ave. Zone 1 Block 2 LARGE CONF ROOM Zone 2 Total /Ave. Zone 2 Block 3 SMALL CONF RM A Zone 3 Total /Ave. Zone 3 Block 4 SMALL CONF RM 8 Zone 4 Total /Ave. Zone 4 Block 5 SMALL CONF RM C Zone 5 Total /Ave. Zone 5 Block System 1 Total /Ave. System 1 Block Room Number Description BUILDING ENVELOPE HEATING LOADS (Roof - Skylight) (At time of Space Peak) Roof Roof Return Air Roof Space Roof Skylight Skylight Sensible R.A. Sensible Space Return Air Space Load CLTD Load CLTD Solar Solar (Btuh) (F) (Btuh) (F) (Btuh) (Btuh) - 22.799 -40.1 -48.0 - 22.799 -40.1 -48.0 - 22.799 -40.1 -48.0 -1,254 -40.1 -48.0 -1,254 -40.1 -48.0 -1,254 -40.1 -48.0 -597 -40.1 -48.0 -597 -40.1 -48.0 -597 -40.1 -48.0 -597 -40,1 -48.0 -597 -40.1 -48.0 -597 -40.1 -48.0 -597 -40.1 -48.0 -597 -40.1 -48.0 -597 -40.1 -48,0 - 25.846 -40.1 -48.0 - 25.846 -40.1 -48.0 Wall Plenum Load (Btuh) BUILDING E VELOPE H (Wall - Window) (At time of Space Wall Plenm CLTD (F) 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 Wall Space Load (Btuh) Wall Space CLTD (F) 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 Glass Space Solar (Btuh) EATING LOADS Peak) Glass Return Air Solar (Btuh) V 600 PAGE 11 Skylight Skylight Skylt Return Air Skylt Space Skylt Solar Conduction R.A. Conduction Space CLF Load CLTD Load CLTD (Btuh) (F) (Btuh) (F) 0.000 0.0 0.0 0.000 0,0 0,0 0.000 0.0 0,0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0,0 0.000 O:6 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 Glass Glass Glass Glass Glass Solar Space Space Return Air R.A. CLF Conduction CLTD Conduction CLTD (Btuh) (F) (Btuh) (F) 0.000 0.0 0.0 0.000 0,0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0,0 0.0 0.000 0.0 0.0 0.000 0,0 0.0 0.000 0.0 0.0 0.000 0.0. 0,0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 0.000 0.0 0.0 BUILDING ENVELOPE HEATING LOADS (Exposed Floor - Partitions - Infiltration) (At time of Space Peak) Exposed Expsd Plenm Ceiling Floor Floor Partition Part. Infilt. Infilt. lnfilt. Dry B Sensible Envelope Sensible CLTD Sensible CLTD Airflow Sensible Latent Temp. Load Total (Btuh) (F) (Btuh) (F) (Cfm) (Btuh) (Btuh) (F) (Btuh) (Btuh) 1 GENERAL OFFICE 0 0.0 0 0.0 0 0 0 60.1 - 22.799 - 45.598 Trane Air Conditioning Economics By: Trane Customer Direct Service Network HEATING LOADS AT SPACE PEAK - ALTERNATIVE 1 C Room Number Description Zone 1 Total /Ave. Zone 1 Block 2 LARGE CONF ROOM Zone 2 Total /Ave. Zone 2 Block 3 SMALL CONF RM A Zone 3 Total /Ave. Zone 3 Block 4 SMALL CONF RM B Zone 4 Total /Ave. Zone 4 Block 5 SMALL CONF RM C Zone 5 Total /Ave. Zone 5 Block System 1 Total /Ave. System 1 Block BUILDING ENVELOPE HEATING LOADS (Exposed Floor - Partitions - Infiltration) (At time of Space Peak) Exposed Expsd Plenm Ceiling Floor Floor Partition Part. lnfilt. Infilt. lnfilt. Dry B Sensible Envelope Sensible CLTD Sensible .CLTD Airflow Sensible Latent Temp. Load Total (Btuh) (F) (Btuh) (F) (Cfm) (Btuh) (Btuh) (F) (Btuh) (Btuh) 0.0 0.0 0.0. 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0,0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 V 600 PAGE 12 60.1 - 22,799 - 45,598 60.1 - 22,799 - 45,598 60.1 -1,254 -2,509 60.1 -1,254 -2,509 60.1 -1,254 -2,509 60.1 -597 -1,195 60.1 -597 -1,195 60.1 -597 -1,195 60.1 -597 -1,195 60.1 . -597 -1,195 60.1 -597 -1,195 60.1 -597 -1,195 60.1 -597 -1,195 60.1 -- -597 -1,195 60.1 - 25,846 - .•1 60.1 - 25,846 Room Number Trane Air Conditioning Economics By: Trane Customer Direct Service Network COOLING AIRFLOW HEAT GAIN /LOSS - ALTERNATIVE 1 1 r Duct Supply Heat Fan Pickup Heat Description (Btuh) (Btuh) 1 GENERAL OFFICE 12,532 35,781 Zone 1 Total /Ave. 12,532 35,781 Zone 1 Block 12,532 35,781 2 LARGE CONF ROOM 1,184 3,381 Zone 2 Total /Ave. 1,184 3,381 Zone 2 Block 1,184 3,381 3 SMALL CONF RM A 691 1,972 Zone 3 Total /Ave. 691 1,972 Zone 3 Block 691 1,972 4 SMALL CONF RM B 691 1,972 Zone 4 Total /Ave. 691 1,972 Zone 4 Block 691 1,972 5 SMALL CONE RM C 658 1,880 Zone 5 Total /Ave. 658 1,880 Zone 5 Block 658 1,880 System I Total /Ave, 15,756 44,985 System 1 Block 15,756 44,985 AIRFLOW HEAT GAIN AND LOSS (At time of Coil Peak) Return Fan Heat (Btuh) System Exhaust Heat Loss (8tuh) -3,830 -3,830 -3,830 -211 -211 -211 -100 -100 -100 -100 -100 -100 -100 -100 -100 -4,342 -4,342 Total (Btuh) 44,483 44,483 44,483 4,355 4,355 4,355 2,562 2,562 2,562 2,562 2,562 2,562 2,438 2,438 2,438 56,399 56,399 Cooling System Room Exhaust Exhaust Ducted Plenum Airflow Airflow Airflow Airflow (Cfm) (Cfm) (Cfm) (Cfm) 1,832 1,832 1,832 101 101 101 48 48 48 48 48 48 48 48 48 2,077 2,077 11,405 11,405 11,405 1,078 1,078 1,078 628 628 628 628 628 628 599 599 599 14,339 14,339 Run Around Airflow (Cfm) .1' Corridr Airflow (Cfm) V 600 PAGE 13 System Return Airflow (Cfm) 11,405 11,405 11,405 1,078 1,078 1,078 628 628 628 628 628 628 599 599 599 14,339 14,339 Trane Air Conditioning Economics By: Trane Customer Direct Service Network COOLING LOADS AT COIL PEAK - ALTERNATIVE 1 Room Number 1 GENERAL OFFICE Zone 1 Total /Ave. Zone 1 Block 2 LARGE CONF ROOM Zone 2 Total /Ave. Zone 2 Block 3 SMALL CONF RM A Zone 3 Total /Ave. Zone 3 Block 4 SMALL CONF RM B Zone 4 Total/Ave. Zone 4 Block 5 SMALL CONF RM C Zone 5 Total /Ave. Zone 5 Block System 1 Total /Ave. System 1 Block Ventilation Airflow Sensible Description (Cfm) (Btuh) 1,832 19,001 1,832 19,001 1,832 19,001 101 1,045 101 1,045 101 1.045 48 498 48 498 48 498 48 498 48 498 48 498 48 498 48 498 48 498 2,077 21,540 2,077 21,540 AIRFLOW COOLING LOADS (At time of Coil Peak) Latent Airflow (Btuh) (Cfm) 30,622 30,622 30,622 1,685 1,685 1,685 802 802 802 802 802 802 802 802 802 34,713 34,713 Optional Ventilation Sensible (Btuh) Latent Airflow (Btuh) (Cfm) Bypass Sensible Latent (Btuh) (Btuh) V 600 PAGE 14 Ov /Undr Sizing (Btuh) Trane Air Conditioning Economics By: Trane Customer Direct Service Network SYSTEM PSYCHROMETRICS - ALTERNATIVE 1 System Space Main System Return Air Heat Pickup Return Fan Return Air Outdoor Air Return /Outdoor Air Mix Blow through Fan Entering Coil Leaving Coil Draw Through Fan Duct Frictional Heat Supply Duct Heat Gain Cold Deck Supply Air Supply Air PSYCHROMETRIC STATE POINTS Percent Outside Air 14.43 (%) Sensible Heat Ratio (SHR) 0.836 Percent Supply Air Bypassing Coil 0.00 (%) Coil. Airflow 14,390 (Cfm) Dry Wet Relat. Humid. Temp. Bulb Bulb Humid. Ratio Enthalpy Diff. (F) (F) (%) (GR) (Btu /Lb) (F) 75.0 61.0 44.8 58.9 27.2 77.2 61.8 41.6 58.9 27.8 84.4 69.0 46.1 83.1 33.3 78.3 62.9 42.5 62.4 28.6 78.3 62.9 42.5 62.4 28.6 52.1 50.6 90.5 53.3 20.8 56.0 52.3 78.6 53.3 21.7 56,0 52.3 78.6 53.3 21.7 2.2 V 600 PAGE 15 Trane Air Conditioning Economics .By: Trane Customer Direct Service Network BUILDING U- VALUES - ALTERNATIVE 1 BUILDING U- VALUES Room U- Values Room Room (Btu /hr /sqft /F) Mass Capac. Room Summr Wintr Summr Wintr (lb/ (Btu/ Number Description Part. ExFlr Skylt Skylt Roof Windo Windo Wall Ceil. sqft) sqft /F) 1 GENERAL OFFICE 0.079 0.260 0.000 0.000 0.062 0.000 0.000 0.000 0.317 112.1 23.32 Zone 1 Total /Ave. 0.079 0.260 0.000 0.000 0.062 0.000 0.000 0.000 0.317 112.1 23.32 2 LARGE CONF ROOM 0.079 0.260 0.000 .0.000 0.062 0.000 0.000 0.000 0.317 141.1 29.12 Zone 2 Total /Ave. 0.079 0.260 0.000 0.000 0.062 0.000 0.000 0.000 0.317 141.1 29.12 3 SMALL CONF RM A 0.079 0.260 0.000 0.000 0.062 0.000 0.000 0.000 0.317 158.5 32.59 Zone 3 Total /Ave. 0.079 0.260 0.000 0.000 0.062 0.000 0.000 0.000 0.317 158.5 32.59 4 SMALL CONF RM B 0.079 0.260 0.000 0.000 0.062 0.000 0.000 0.000 0.317 158.5 32.59 Zone 4 Total /Ave. 0.079 0.260 0.000 0.000 0.062 0.000 0.000 0.000 0.317 158.5 32,59 5 SMALL CONF RM C 0.000 0.260 0.000 0.000 0.062 0.000 0.000 0.000 0.317 97.8 20.46 Zone 5 Total /Ave. 0.000 0.260 0.000 0.000 0.062 0.000 0.000 0.000 0.317 97.8 20.46 System 1 Total /Ave. 0.079 0.260 0.000 0.000 0.062 0.000 0.000 0.000 0,317 115.3 23.96 Building 0.079 0.260 0.000 0.000 0.062 0.000 0.000 0.000 0.317 115.3 23.96 ASHRAE 90 ANALYSIS - ALTERNATIVE 1 ASHRAE 90 ANALYSIS Overall Roof U -Value = 0.062 (Btu /Hr /Sq Ft /F) Overall Wall U -Value = 0.000 (Btu /Hr /Sq Ft /F) Overall Building U -Value = 0.062 (Btu /Hr /Sq Ft /F) not Overall Thermal Transfer Value (OTTVr) = 1.73 (Btu /Hr /Sq Ft) 1 (:... Overall Thermal Transfer Value ( OTTVw) = 0.00 (Btu /Hr /Sq Ft) V 600 PAGE 16 Trane Air Conditioning Economics By: Trane Customer Direct Service Network BUILDING AREAS - ALTERNATIVE 1 BUILDING AREAS Floor Number of Area /Dupl Room Duplicate • Room Number Description • Flr Rm (sqft) 1 GENERAL OFFICE 1 1 9,160 9,160 2,808 9,160 Zone 1 Total /Ave. 9,160 2,808 9,160. 2 LARGE CONF 'ROOM 1 1 '504 504 468 504 . Zone 2. Total /Ave. 504 .468 504 3 SMALL CONF RM A 1. 1 240 240. 312 240 Zone 3 Total/Ave. 240 312 240 4 SMALL CONF RM B 1 1 240 240 312 240 Zone. 4 Total /Ave. 240 312 240 5 SMALL CONF RM C 1 1 240 240 0 .240 .Zone '5 Total /Ave. • 240. . .0 • 240 System 1 Total /Ave. . 10,384 3,900 10,384 Building 10,384 3,900 10,384 Total Exposed Floor. Partition Floor Skylight Skl Net Roof Window Area Area Area Area /Rf Area Area (sqft) (sqft) (sqft) (sqft) (%) (sqft) (sqft) 9,160 9,160 504 504 240 240 240 240 240 240 10,384 10,384 Win (%) 0 0 0. 0. 0 0 0 0. 0 0 0 0 V 600 PAGE 17 Net Wall Area (sqft) English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A PROJECT : BUILDING LOAD CALCULATIONS FOR: LOCATION : AHU AH2E16A (NORTH UNIT) CLIENT : 9 -101 BLDG EEIP PROJECT, PHASE 3 -E PROGRAM USER : BOEING MILITARY AIRPLANES COMMENTS : FIG. BY: S.ROSSE English INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A LOAD DESIGN 600 Card 08: Climatic Information Weather Code : SEATTLE. Summer Clearness Number : .95 Winter Clearness Number : .95 Summer Design Dry Bulb : 85 Summer Design Wet Bulb : 68 Winter Design Dry Bulb : 20. Building Orientation : Summer Ground Reflectance : .2 Winter Ground Reflectance : .2 Screen: 1 of 29 Sect: JOB Screen: 2 of 29 Sect: JOB English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A English INPUT FILENAME 1 E: \CDS \TULTRA \AH2E16A Card 09: Load Simulation Periods First Month Cooling Simulation : JUL Last Month Cooling Simulation : SEP Peak Cooling Load Hour : First Month of Summer Period : Last Month of Summer Period : First Month Daylight Saving : Last Month Daylight Saving : LOAD DESIGN 600 Card 10: Load Simulation Parameters (Optional) Cooling Load Methodology : CLTD -CLF Heating Load Methodology : UATD Ventilation Methodology : Airflow Input Units : ACTUAL Airflow Out ut Units : ACTUAL Room Circulation Rate : Put Wall RA Load into Room : NO Screen: 3 of 29 Sect: JOB Screen: 4 of 29 Sect: JOB English LOAD DESIGN 600 INPUT FILENAME : E: \CDS \TULTRA \AH2E16A z Card 19: Load Alternative Description Alternative Number : 1 Alternative Description : English INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A ROOM NUMBER : M ZONE REFERENCE NUMBER : 1 Room Description : Floor Length : Floor Width : Construction Type : 7 Plenum Height : 17 Acoustic Ceiling Resistance : 1.786 Floor -to -Floor Height : 26 Duplicate Vloor Multiplier : No. Duplicate Rooms /Zone : Sect: LOAD LOAD DESIGN 600 Card 20: General Room Parameters Screen: 5 of 29 Alt 1 of 1 Screen: 6 of 29 Alt : 1 of 1 Room : 1 of 6 Sect: LOAD English LOAD DESIGN 600 INPUT FILE NAME :'E: \CDS \TULTRA \AH2E16A Card 20: General Room Parameters ROOM NUMBER : 1 ZONE REFERENCE NUMBER : 1 Room Description : GENERAL OFFICE' Floor Length : 9160 Floor Width : 1 Construction Type : Plenum Height : Acoustic Ceiling Resistance : Floor -to -Floor Height : Duplicate Floor Multiplier : No. Duplicate Rooms /Zone : English LOAD DESIGN 600 INPUT FILE NAME : E:\CDS\TULTRA\AH2E16A ROOM NUMBER : 2 ZONE REFERENCE NUMBER : 2 Room Description : LARGE CONF ROOM. Floor Length : 28 Floor Width : 18 Construction Type : Plenum Height : Acoustic Ceiling Resistance : Floor -to -Floor Height : Duplicate Floor Multiplier : No. Duplicate Rooms /Zone : Card 20: General Room Parameters Screen: 6 of 29 Room : 2 of 6 Sect: LOAD Screen: 6 of 29 Alt 1 of 1 Ro Sect: LOAD 6 English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A Card 20: General Room Parameters ROOM NUMBER : 3 ZONE REFERENCE NUMBER : 3 Room Description : SMALL CONF RM A Floor Length : 12 Floor Width : 20 Construction Type : Plenum Height : Acoustic Ceiling Resistance : Floor -to -Floor Height : Duplicate Floor Multiplier : No. Duplicate Rooms /Zone : English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A ROOM NUMBER : 4 ZONE REFERENCE NUMBER : 4 Room Description : SMALL CONF RM B Floor Length : 12 Floor Width : 20 Construction Type : Plenum Height : Acoustic Ceiling Resistance : Floor -to -Floor Height : Duplicate Floor Multiplier : No. Duplicate Rooms /Zone Screen: 6 of 29 Alt 1 of 1 Ro Sect: LOAD �f 6 Card 20: General Room Parameters • Screen: 6 of 29 Room: i Sect: LOAD of 6 English INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A L^! English LOAD, DESIGN 600 Card 20: General Room Parameters ROOM NUMBER : 5 ZONE REFERENCE NUMBER : 5 Room Description : SMALL CONF RM C Floor Length : 16 Floor Width : 15 Construction Type : Plenum Height : Acoustic Ceiling Resistance : Floor -to -Floor Height : Duplicate Floor Multiplier No. Duplicate Rooms /Zone : INPUT. FILE NAME :..E: \CDS \TULTRA \AH2E16A ROOM NUMBER : Room Design Cooling Dry,Bulb : Room Design Relative Humidity Room Design Heating Dry Bulb Room Mass / No. Hrs Time Avg : Is There Carpet on the Floor. : LOAD DESIGN 600 Card 21: Thermostat Parameters,. Screen: 6 of 29 Alt 1 of 1 Room 6 6 Sect: LOAD Alteen: 7 of Room 1 of Sect: LOAD 29 1 1 English INPUT FILE NAME Is the'Roof LOAD DESIGN 600 : E: \CDS \TULTRA \AH2E16A Card 22: Roof Parameters ROOM NUMBER : M ROOF NUMBER : 1 Area = Floor Area : YES Roof Length : Roof Width : Roof U -Value : .062 Construct }on Type : 16 Roof Direction : Roof Tilt : Roof Alpha : .7 English INPUT FILENAME :.E \CDS \TULTRA \AH2E16A LOAD DESIGN 600 Card 22: Roof Parameters ROOM NUMBER : 1 ROOF NUMBER : 1 Roof Area = Floor Area : YES Roof Length : Roof Width : Roof U -Value : Construct }on Type : Roof Direction : Roof Tilt : Roof Alpha : Screen: 8 of 29 Roof 1 of 6 Sect: LOAD Screen: 8 of Alt 1 of Roof ' 2 of Sect: LOAD 29 6 English INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A English LOAD DESIGN 600 Card 22: Roof Parameters ROOM NUMBER : 2 ROOF NUMBER : 1 the Roof Area = Floor Area : YES Roof Length : Roof Width : Roof U -Value : Construction Type : Roof Direction : Roof Tilt : Roof Alpha : INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A LOAD DESIGN 600 Card 22: Roof Parameters ROOM NUMBER : 3 ROOF NUMBER : 1 Is the Roof Area = Floor Area : YES Roof Length : Roof Width : Roof U -Value Construction Type : Roof Direction : Roof Tilt : Roof Alpha : Screen: 8 of 29 Alt 1 of 1 Roof : 3 of 6 Sect: LOAD Screen: 8 of 29 Alt 1 of 1 Roof 4 of 6 Sect: LOAD English LOAD DESIGN 600 INPUT FILE NAME E: \CDS \TULTRA \AH2E16A Is the Roof Area = Floor Area : YES Roof Length : Roof Width : Roof U -Value : Construction Type : Roof Direction : Roof Tilt : Roof Alpha : Card 22: Roof Parameters ROOM NUMBER : 4 ROOF NUMBER : 1 English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A Card 22: Roof Parameters ROOM NUMBER : 5 ROOF NUMBER : 1 Area = Floor Area : YES Roof Length : Roof Width : Roof U -Value : Construction Type : Roof Direction : Roof Tilt Roof Alpha : Screen: 1 of 29 Roof 5 of 6 Sect: LOAD Screen: 8 of 29 Alt : 1 of 1 Ro Sect: LOAD 6 English INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A i 1 English LOAD DESIGN 600 Card 23: Skylight Parameters (Optional) ROOM NUMBER : ROOF NUMBER : Skylight Length : Skylight Width : # of Skylite /Pct Glass : Skylight U -V : Shading Coefficient : External Shading Type : Internal Shading Type : Percent Solar Load to Return Air INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A ROOM NUMBER : WALL NUMBER : Wall Length : Wall Height : Wall U -Value : Construction Type : Wall Direct.lon : Wall Tilt : Wall Alpha Reflectance Multiplier : LOAD DESIGN 600 Card 24: Wall Parameters Screen: 9 of 29 Alt 1 of 1 Skyylt. 1 of 1 Sect: LOAD Screen: 10 of 29 Alt. 1 of 1 Wall 1 of 1 Sect: LOAD English INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A Card 27: People and Lights ROOM NUMBER : M People Value : 100 People Units : SF -PERS People Sensible : 355 Leo le Latent : 355 Lig Value : 1.7 : WATT-SF Lightin : A Percent: Light Load to Return. Air : 25 English LOAD DESIGN 600 INPUT FILE NAME : E:\CDS\TULTRA\AH2E16A People Value : People Units : People Sensible : 1eo le Latent : Lighting Value : Lighting Units: Lighting Fixture Type : Ballast Factor : Percent Light Load to Return Air : LOAD DESIGN 600 Card 27: People and Lights ROOM NUMBER : 1 Screen: 13 of 29 Room : 1 of 6 Sect: LOAD Screen: 13 of 29 Alt : 1 of 1 Room LOAD 6 English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A Card 27: People and Lights ROOM NUMBER : 2 People Value : 30 People Units : PEOPLE People Sensible : Peo �.e Latent : Lighting Value : Lighting Units : Lighting Fixture Type : Ballast Factor : Percent Light Load to Return Air : English LOAD DESIGN 600 Screen: 13 of 29 Alt 1 of 1 Room : 4 of 6 Sect: LOAD INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A Card 27: People and Lights ROOM NUMBER : 3 People Value : 15 People Units : PEOPLE People Sensible : ;people Latent : Lighting Value : Lighting Units : Lighting Fixture Type Ballast Factor : Light Load to Return Air : Screen: .13 of 29 Alt : 1 of 1 Ro S e ct: LOAD 6 • English INPUT FILE NAME E: \CDS \TULTRA \AH2E16A English INPUT FILE NAME LOAD DESIGN 600 Card 27: People and Lights ROOM NUMBER : 4 People Value : 15 People Units : PEOPLE People Sensible : people Latent : Lighting Value : Lighting Units : Lighting Fixture Type : Ballast Factor : Light Load to Return Air : LOAD DESIGN 600 \CDS \TULTRA \AH2E16A Card 27: People and ROOM NUMBER : 5 People Value 15 People Units : PEOPLE. People Sensible : people Latent : Lighting Value : Lighting Units : Lighting Fixture Type : Ballast Factor : Percent Light Load to Return Air : Screen: 13 of 29 Alt l of 1 Room Sect: LOAD of 6 Screen: 13 of 29 Alt 1 of 1 Room 6 of 6 Sect: LOAD English INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A ILN T 1 LOAD DESIGN 600 Card 28: Miscellaneous Equipment (Optional) ROOM NUMBER : M Miscellaneous Equip Ref Number : 1 E i Equipment Descripption : MASTER Energy Consumptl.on Value : 3.268. Energy Consumption Units : WATT -SF Schedule Code : Percent of Load Sensible : 100 Percent Miscellaneous Load to Room : 100 Percent Misc Sens to Return Air : 0 Radiant Fraction : 0 English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A Card 28: Miscellaneous Equipment (Optional) ROOM NUMBER : 1 Miscellaneous Equip Ref Number : 1 Equipment Description : OFFICE EQUIPMENT; Energy Consumpt4.on Value : Energy Consumption Units : Schedule Code : Percent of Load Sensible : Percent Miscellaneous Load to Room : Percent Misc Sens to Return Air : Radiant Fraction : Screen: 14 of 29 Alt : 1 of 1 Ro Sect: LOAD 7 Screen: 14 of 29 Alt 1 of 1 Room : 2 of 7 Sect: LOAD English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A Card 28: Miscellaneous Equipment (Optional) ROOM NUMBER : 1 Miscellaneous Equip Ref Number : 2 Equipment Description : TRANSFORMERS Energy Consumption Value : 16000 Energy Consumption Units : BTUH Schedule Code : Percent of Load Sensible : 100 Percent Miscellaneous Load to. Room : 0 Percent Misc Sens to Return Air : 100 Radiant Fraction : 0 English LOAD DESIGN 600 Screen: 14 of 2 9 Room : 4 of 7 Sect: LOAD INPUT FILE NAME,: E: \CDS \TULTRA \AH2E16A Card 28: Miscellaneous Equipment (Optional) ROOM NUMBER : 2 Miscellaneous Equip Ref Number : 1 Equipment Description : LARGE CONF RM Energy Consumpt.on Value : 1660 Energy Consumption Units : WATTS Schedule Code : Percent of Load Sensible : Percent Miscellaneous Load to Room : Percent Misc Sens to Return Air : Radiant Fraction : Screen: 14 of 29 Alt : 1 of 1 o Se ct: LOAD 7 English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A f Miscellaneous Equip Ref Number : 1 Equipment De : SMALL CONF RM Energy Consumption Value : 1380 Energy Consumption Units : WATTS Schedule Code : Percent of Load Sensible : Percent Miscellaneous Load to Room : Percent Misc Sens to Return Air : Radiant Fraction : English INPUT FILE NAME : :E: \CDS \TULTRA \AH2E16A LOAD DESIGN 600. Card 28: Miscellaneous Equipment (Optional) ROOM NUMBER : 3 Card 28: Miscellaneous Equipment (Optional) ROOM NUMBER : 4. Miscellaneous Equip Ref Number : 1 Equipment Description : SMALL CONF RM Energy Consumpt }on Value : 1380 Energy Consumption Units : WATTS Schedule Code : Percent of Load Sensible : Percent Miscellaneous Load to Room : Percent Misc Sens to Return Air : Radiant Fraction : Screen: 14 of 29 Alt 1 of 1 Room Sect: LOA Screen: 14 of 29 Alt 1 of 1 Room 6 of 7 Sect: LOAD English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A Card 28: Miscellaneous Equipment (Optional) ROOM NUMBER : 5 Miscellaneous Equip Ref Number : 1 Equipment Description : SMALL CONF RM Energy Consumption Value : 1345 Energy Consumption Units : WATTS Schedule Code : Percent of Load Sensible : Percent Miscellaneous Load to Room : Percent Misc Sens to Return Air Radiant Fraction : English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A Card 29: Room Airflows ROOM NUMBER : M Ventilation Cooling Value : .2 Ventilation Units : FM -SF Ventilation Heating Value : .2 Ventilation Units : FM -SF, Infiltration Cooling Value : 0 Infiltration Units : Infiltration Heating Value : 0 Infiltration Units : Reheat Minimum : .75 Reheat. Minimum Units : CFM -SF Screen: 14 of 29 Room 7 of 7 Sect: LOAD Screen: 15 of 29 Alt . 1 of 1 Room : 1 of 6 Sect: LOAD English LOAD DESIGN 600 ''INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A " English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A Card 29: Room Airflows ROOM NUMBER : 1 Ventilation Cooling Value : Ventilation Units : Ventilation Heating Value : Ventilation Units : Infiltration Cooling Value : Infiltrat }on Units : Infiltration Heating Value Infiltration Units : Reheat Minimum : Reheat Minimum Units : Card 29: Room Airflows ROOM NUMBER : 2 Ventilation Cooling Value : Ventilation Units : Ventilation Heating Value : Ventilation Units : Infiltration Cooling Value : Infiltration Units : Infiltration Heating Value : Infiltration Units : Reheat Minimum : Reheat Minimum Units : Screen: 15 of 29 Alt : Room 2 of 6 Sect: LOAD r Screen: 15 of 29 Alt 1 of 1 Ro Sect: LOAD 6 English INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A ROOM NUMBER : 3 Ventilation Cooling Value : yentilat.on Units : Ventilation Heating Value : Ventilation Units : Infiltration Cooling Value : Infiltration Units : Infiltration Heating Value : Infiltration Units : Reheat Minimum Reheat Minimum Units : English LOAD DESIGN 600 Screen: 15 of 29 Alt : 1 of 1 Ro Sect: LOAD 6 INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A LOAD . DESIGN 600 ROOM NUMBER : 4 Ventilation Cooling Value : yentilat }on Units : Ventilation Heating Value : Ventilation Units : Infiltration Cooling Value : Infiltration Units : Infiltration Heating Value : Infiltration Units : Reheat Minimum : Reheat Minimum Units : Card 29: Room Airflows Card 29: Room Airflows Screen: 15 of 29 Alt 1 of 1 Ro Sect: LOAD 6 English LOAD DESIGN 600 INPUT FILE NAME : E:\CDS\TULTRA\AH2E16A Card 29: Room Airflows ROOM NUMBER : 5 Ventilation Cooling Value : Ventilation Units : Ventilation Heating Value : Ventilation Units : Infiltration Cooling Value : Infiltration Units : Infiltration Heating Value : Infiltration Units : Reheat Minimum : Reheat Minimum Units : English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A Main Main Main Main Auxiliary Auxiliary Auxiliary Auxiliary Card 30: Fan Airflows ROOM NUMBER : Cooling Supply Value : Cooling Supply Units : Heating Supply Value : Heating Supply Units : Cooling Supply Value : Cooling Supply Units : Heating Supply Value : Heating Supply Units : Room Exhaust Room Exhaust Units : Screen: 15 of Alt, : . 1 of Ro Se ct: LOAD of 29 6 Screen: 16 of Alt 1 of Room : 1 of Sect: LOAD 29 1 1 English LOAD DESIGN 600_ INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A Card 31: Partition Parameters (Optional) ROOM NUMBER : 2 PARTITION NUMBER : 1 Partition Length : 18 Partition Height : Partition U -Value : Construction Type : Temperature Flag : Cooling Temperature : Heating Temperature : English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A Card 31: Partition Parameters (Optional) ROOM NUMBER : 3 PARTITION NUMBER : 1 Partition Length : 12 Partition Height : Partition U -Value : Construction Type : Temperature Flag : Cooling Temperature : Heating Temperature Screen: 17 of 29 Pa Sect: LOAD of 5 Screen: 17 of 29 Alt 1 of 1 Partn : 4 of 5 Sect: LOAD English INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A Ito Card 31: Partition Parameters (Optional) ROOM NUMBER : 4 PARTITION NUMBER : 1 Partition Length : 12 Partition Height Partition U- Value : Construction Type : Temperature Flag : Cooling Temperature : Heating Temperature : English INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A LOAD DESIGN 600 LOAD DESIGN 600 Card 32: Exposed Floor Information (Optional) ROOM NUMBER : M EXPOSED FLOOR NUMBER : 1 SLAB ON -GRADE Perimeter Length : Loss Coefficient : EXPOSED FLOOR Exposed Floor Area : Exposed Floor U -Value : 260 Construction Type : .260 Temperature Flag : CONSTANT Cooling Temperature : 95 Heating Temperature 68 Screen: 17 of 29 Alt : 5 of 5 Sect: LOAD Screen: 18 of 29 Floor : 1 of 6 Sect: LOAD English INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A :.: English LOAD DESIGN 600 Card 32: Exposed,Floor Information (Optional) ROOM NUMBER : 1 EXPOSED FLOOR NUMBER : 1 SLAB -ON -GRADE Perimeter Length : Loss Coefficient : EXPOSED FLOOR Exposed Floor Area : 9160 Exposed Floor U -Value : Construction Type : Temperature Flag : Cooling Temperature : Heating Temperature : INPUT FILE NAME :.E: \CDS \TULTRA \AH2E16A LOAD DESIGN 600 Card 32: Exposed,Floor Information (Optional) ROOM NUMBER : 2 EXPOSED FLOOR NUMBER : 1 SLAB -ON -GRADE Perimeter :length : Loss Coefficient : EXPOSED FLOOR Exposed Floor Area : 504 Exposed Floor U -Value : Construction Type : Temperature Flag Cooling Temperature : Heating Temperature : Screen: 18 of 29 Al Flobr : 2 of 6 6 - •Sect: LOAD Screen: 18 of 29 Alt 1 of 1 Floor : 3 of 6 Sect: LOAD English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A C English Card 32: Exposed Floor Information (Optional) ROOM NUMBER : 3 EXPOSED FLOOR NUMBER : 1 SLAB -ON -GRADE Perimeter Length Loss Coefficient : EXPOSED FLOOR Exposed Floor Area : 240 Exposed Floor U -Value : Construction Type : Temperature Flag Cooling Temperature : Heating Temperature : INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A Card 32: Exposed,Floor Information (Optional) ROOM NUMBER : 4 EXPOSED FLOOR NUMBER : 1 SLAB -ON -GRADE Perimeter i : Loss Coefficient : EXPOSED FLOOR Exposed Floor Area : 240 Exposed Floor U -Value : Construction Type : Temperature Flag : Cool}.ng Temperature Heating Temperature LOAD DESIGN 600 Screen: 18 of 29 Floor : 4 of 6 Sect: LOAD Screen: 18 of 29 Alt 1 of 1 Floor : 5 of 6 Sect: LOAD English INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A LOAD DESIGN 600 Card 32: Exposed,Floor Information (Optional) ROOM NUMBER : 5 EXPOSED FLOOR NUMBER : 1 SLAB -ON -GRADE Perimeter length : Loss Coefficient : EXPOSED FLOOR Exposed Floor Area : 240 Exposed Floor U -Value : Construction Type : Temperature Flag : Cooling Temperature : Heating Temperature : English INPUT FILE NAME : E : \CDS \TULTRA \AH2E16A LOAD DESIGN 600 Card 33: External Shading (Optional) Shading Type : OVERHANG Glass Height : Height Above Glass : Projection Out : VERTICAL FINS Glass Width : Projection Left : Left Projection Out : Projection Right : Right Projection Out : Adjacent Building Flag : Screen: 18 of 29 Alt : 1 of 1 Floor t: LOAD 6 r ` Screen: 19 of 29 Alt 1 of 1 Extsh : 1 of 1 Sect: LOAD English English INPUT FILE NAME INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A LOAD DESIGN 600 Card 34: Internal Shading (Optional) Shading Type : Overall U-Value : Overall Shading Coeff Schedule Code : LOAD DESIGN 600 : E: \CDS \TULTRA \AH2E16A Card 39: System Alternative Description Alternative Number : 1 System Alternative Description : Screen: 2 0 of 29 Intsh : I of 1 Sect: LOAD r Screen: 21 of Alt : 1 of Sect: SYSTEM 29 English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS\TULTRA \AH2E16A Card 40: System Type SYSTEM SET NUMBER : 1 System Type : VAV Optional Ventilation System Ventilation Deck Location : ROADK Opt. Ventilation Cooling SADBVC : Opt. Ventilation Heating SADBVH : Cooling Schedule Code : Heating Schedule Code : Fan Static Pressure : English LOAD DESIGN 600 INPUT FILE NAME :. E : \CDS \TULTRA \AH2E16A Card 41: Zone Assignment SYSTEM SET. NUMBER : 1 System Serves These Zones Begin at : 1 End at : 5 Begin at : End at : Beg }n at : End at : Begin at : End at : Begin at : End at : Begin at : End at : Beg }n at : End at : Begin at End at : Begin at End at : Begin at : End at : Begin at : End at : Screen: 22 of 29 Alt : 1 of 1 System: e: SYSTEM 1 Screen: 23 of System: 1 of Sect: SYSTEM 29 1 English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A tr Card 42: Fan SP and Duct Parameters SYSTEM SET NUMBER 1 Cooling Supply Fan Static Pressure : 4.0 Heating Supply Fan Static Pressure : 4.0 Return Fan Static Pressure : Main Exhaust Fan Static Pressure : Auxiliary Supply Fan Static Pressure : Roop Exhaust Fan Static Pressure : Cooling Supply Fan Motor Location : SUPPLY Return Fan Motor Location : OMIT Supply Duct Temp Difference : 1 Supply Duct Location : RETAIR Return Air Path : PLENUM English INPUT FILE NAME E: \CDS \TULTRA \AH2E16A LOAD DESIGN 600 Card 43: Airflow Desi Optiona SYSTEM SET NUMBER : 1 41: 4inimum Cooling Supply Air Dry Bulb : 56 iximum Cooling Supply Air Dry Bulb : 56 Minimum Heating Supply Air Dry Bulb : 80 Maximum Heating Supply Air Dry Bulb : 95 Minimum Cooling Coil Leaving Dry Bulb : Maximum Cooling Coil Leaving Dry Bulb : Minimum Preheat Coil Leaving Dry Bulb : Maximum Preheat Coil Leaving Dry,Bulb : Minimum Room Relative Humidity : Dsgn Humidity Ratio Difference : n Temperatures Screen: 24 of 29 Alt 1 of 1 System: 1 of 1 Sect: SYSTEM Screen:. 25 of 29 Alt. 1 of 1 System: 1 of 1 Sect: SYSTEM English INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A SYSTEM SET NUMBER : 1 Economizer Type Flag : DRY -BULB Economizer On Point : Maximum Percentage of Outside Air : 100 English LOAD DESIGN 600 Screen: 27 of 29 System: : SYSTEM 1 INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A LOAD DESIGN 600 Card 44: System Options (Optional) Card 47: Fan Overrides (Optional) SYSTEM SET NUMBER : 1 Main Cooling Fan Motor Efficiency : 85 r"1 Main Heating Fan Motor Efficiency : 85 Return Fan Motor Efficiency : Main Exhaust Fan Motor Efficiency : Auxiliary Fan Motor Efficiency : Room Exhaust Fan Motor Efficiency : Opt Vent Fan Motor Efficiency : Fan Mechanical Efficiency : 60 Block Cooling Airflow Value : Block Cooling Airflow Units : Main Cooling Fan Sizing Method : BLOCK Main Cooling Fan Configuration : DRAW Screen: 26 of 29 Alt : 1 of 1 System: 1 of 1 Sect: SYSTEM English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E16A English People Variance Lights Variance Miscellaneous Loads Variance Main Cooling Coil Capacity Value Main Cooling Coil Capacity Units Main Cooling Coil Sizing Method Main Cooling Coil Level Location Aux Cooling Coil Capacity Value Aux Cooling Coil Capacity Units INPUT FILE NAME :.E: \CDS \TULTRA \AH2E16A Main Heating Main Heatin Main Preheat Main Preheat Reheat Reheat Humidification Humidification Aux Heating Aux Heating Card 48: Cooling Capacity Overrides (Optional) SYSTEM SET NUMBER : 1 Coil Coil Coil Coil Coil Coil Coil Coil Coil Coil SYSTEM SET NUMBER Capacity Value Capacity Units Capacity Value Capacity Units Capacity Value Capacity Units Capacity Value Capacity Units Capacity Value Capacity Units LOAD DESIGN 600 Card 49: Heating Capacity Overrides (Optional) Screen: 28 of Alt 1 of System: 1 of Sect: SYSTEM 29 1 Screen: 29 of 29 Alt 1 of 1 System: 1 of 1 Sect: SYSTEM rane Air Conditioning Economics By: Trane Customer Direct Service Network C Weather File Code: Location: Latitude: Longitude: Time Zone: Elevation: Barometric Pressure: Summer. Clearness Number: Winter Clearness Number: Summer Design Dry Bulb: Summer Design Wet Bulb: Winter Design Dry Bulb: Summer Ground Relectance: Winter Ground Relectance: TRACE 600 ANALYSIS BUI • • CALCULATIONS FOR: AH em SOUTH UNIT) 9 -1. • •• EEIP PROJECT, PHASE 3 -E BOEING MILITARY AIRPLANES FIG, BY: S.ROSSE Air Density: Air Specific Heat: Density- Specific Heat Prod: Latent Heat Factor: Enthalpy Factor: Time /Date Program was Run: • , Dataset Name: SEATTLE 47.0 (deg) 122.0., (deg) 8 386 (ft) 29.5 (in. Hg) 0.95 0.95 85 68 20 0.20 0.20 0.0749 0.2444 1.0988 4,836.9 4.4953 (F) (F) (F) (Lbm /cuft) (Btu /lbm /F) (Btu - min: /hr /cuft /F) (Btu- min. /hr /cuft) (Lb- min. /hr /cuft) Design Simulation Period: July To September System Simulation Period: January To December Cooling Load Methodology: CLTD /CLF (Transfer Function Method). 15 :34:11 12/13/91 AH2EI7A .TM ** by Trane Customer Direct Service Network ** ** ** ********************************************** * * * * * * * * * * * * * * * * * * * * * * * * * * * * * ** V 60 PAGE Trane Air Conditioning Economics By: Trane Customer Direct Service Network AIRFLOW - ALTERNATIVE 1 Main Auxil. Room Outside Cooling Heating Return Exhaust Supply Exhaust System System Airflow Airflow Airflow Airflow Airflow Airflow Airflow Number Type (Cfm) (Cfm) (Cfm) (Cfm) (Cfm) (Cfm) (Cfm) 1 VAV 2,088 13,456 0 13,456 13,456 0 0 Totals 2,088 13,456 0 13,456 13,456 0 0 CAPACITY - ALTERNATIVE 1 System Number Cooling SYSTEM SUMMARY (Design Airflow Quantities) SYSTEM SUMMARY (Design Capacity Quantities) Heating Main Sys. Aux. Sys. Opt. Vent Cooling Main Sys. Aux. Sys. Preheat Reheat .Humidif. Opt. Vent Heating System System Capacity Capacity Capacity Totals Capacity Capacity Capacity Capacity Capacity Capacity Totals Number Type (Tons) (Tons) (Tons) (Tons) (Btuh) (Btuh) (8tuh) (Btuh) (Btuh) (Btuh) (Btuh) 1 VAV 39.1 0.0 0.0 39.1 - 28,576 0 - 73,751 0 0 •r - 0 - 102,327 Totals 39.1 0.0 0.0 39.1 - 28,576 0 - 73,751 0 0 0 - 102,327 ENGINEERING CHECKS - ALTERNATIVE 1 ENGINEERING CHECKS Percent Cooling Heating - - -- Main/ System . Outside Cfm/ Cfm/ Sq Ft Btuh/ Cfm/ Btuh/ Floor Area Auxiliary Type Air Sq Ft Ton /Ton Sq Ft Sq Ft Sq Ft Sq Ft 1 Main VAV 15,52 1,29 344.5 267.3 44.89 0.00 -9.80 10,440 V 600 PAGE Trane Air Conditioning Economics By: Trane Customer Direct Service Network System 1 Block VAV - VARIABLE AIR VOLUME 7 1.********************* COOLING COIL PEAK * ** * * * * * * * * ** ** * * * ** * * * * * ** * * * ** Ir 'ed at Time = => Mo /Hr: 7/14 aide Air = => OADB /WB /HR: 84/ 69/ 83.1 Envelope Loads Skylite Solr Skylite Cond Roof Cond Glass Solar Glass Cond Wall Cond Partition Exposed Floor Infiltration Sub Total = => Internal Loads Lights People Misc Sub Total = => Ceiling Load Outside Air Sup. Fan Heat Ret. Fan Heat Duct Heat Pkup OV /UNDR Sizing Exhaust Heat Terminal Bypass Clg Aux Clg Opt Vent Totals Main Htg Aux Htg Preheat Reheat Humidif Opt Vent Total Total (Tons) 39.1 0.0 0.0 39.1 -28.6 0.0 -73.8 -0.0 0.0 0.0 -102.3 Space Sens. +Lat. (Btuh) 1,13 3,69 54,28 59,11 52,24 91,59 115,91 259,74 7,20 0 Grand Total = => 326,063 Capacity (Mbh) 468.7 0.0 HEATING COIL SELEC ION Ret. Air Sensible (Btuh) 0 0 18,721 0 0 2.047 20,768 17,415 16,000 33,415 -7,203 0 0 14,751 -4,996 0 27,234 Capacity Coil Air 1 Ent (Mbh) (cfm) Deg F 0.0 0.0 2,08 20.0 0.0 0.0 0.0 Ret. Air Latent (Btuh) 69.660 91,590 0 131,910 0 293,160 0 0 58,531 42,116 0 0 0 0 -4,996 0 0 0 468,695 COOLING COIL SELECTION Net Total (Btuh) 0 0 18,721 0 0 3.182 3,693 54,288 0 79,884 Sens Cap. Coil Airfl Entering DB /WB /HR (Mbh (cfm) Deg F Deg F Grains 13,424 78.3 62.7 61.5 0 0.0 0.0 0.0 0.0 0 0.0 0.0 0.0 Lvg Type Deg F Vent 0.0 Infil 0.0 Supply 52,1 Mincfm 0.0 Return 0.0 Exhaust 0.0 Rm Exh Auxil * * * Space * Sensible * (Btuh) Percnt Of Tot (%) 0.00 * 0.00 * 3.99 * 0.00 * 0.00 * 0.68 * 88 0.79 * 3,69 11.58 * 54,28 0.00 * 17.04 * 58,87 * 14.86 * 52,24 19.54 * 45,79 28.14 * 115,91 62.55 * 213,95 0.00 * 8,11 12.49 * 8.99 * 0.00 * 0.00 * 0.00 * -1.07 * -0.00 * * 100.00 * AIRFLOWS (cfm) Co Heating 2,088 0 13,456 3,456 2,088 0 0 0 280,932 Percnt Of Tot (%) 0.00 0.00 0.00 0.00 0.00 0.32 1.31 19.32 ' 0.00 * 20.96 * * 18.60 * 16.30 * 41.26 * 76.16 * 2.89 * 0.00 * 0.00 * 0.00 * 0,00 * 0.00 * 0.00 * 0.00 * * 100.00 * Leaving DB /WB /HR Deg F Deg F Grains 52.1 50.4 52.6 0.0 0.0 0.0 0.0 0.0 0.0 Space Peak Space Sens (Btuh -- ENGINEERING CHECKS- - Clg % OA 15.5 Clg Cfm /Sqft 1.29 Clg Cfm /Ton 344.52 Clg Sqft/Ton 267.30 Clg Btuh /Sqft 44.89 No. People 129 Htg % OA 0.0 Htg Cfm /SqFt 0.00 Htg Btuh /SqFt -9.80 -1,12 -27,45 0 Coil Peak Tot Sens (Btuh) -28,57 - 28,576 -28,57 V 600 _ PAGE 3 CLG SPACE PEAK * * * * * * * * * * ** HEATING COIL PEAK * * * * * * ** Mo /Hr: 7/16 * Mo /Hr: 13/ 1 OADB: 84 * OADB: 20 * * * * * * * - 25,69 * * * - 1.12 - 2,87 * Percnt Of Tot (x) 0.00 0.00 89.93 0.00 0.00 10.07 0.00 0.00 0.00 100.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0,00 0.00 100.00 AREAS Gross Total . Glass (sf) (%) Floor 10,440 Part 2,340 ExF1r 10,440 Roof 10,440 0 0 Wall 1,040 0 0 -- TEMPERATURES (F) - -- Type Clg Htg SADB 56.0 68.1 Plenum 77.2 59.7 Return 77.2 59.7 Ret /OA 78.3 20.0 Runarnd 75.0 68.0 Fn MtrTD 0.4 0.4 Fn B1dTD 1.0 1.0 Fn Frict 1.5 1.5 Irene Air Conditioning Economics By: Trane Customer Direct Service MAIN SYSTEM COOLING - ALTERNATIVE 1 Room Number Description 1 GENERAL OFFICE 7/16 Zone 1 Total /Ave. Zone 1 Block 7/16 2 SOUTH CONF ROOM 7/17 Zone 2 Total /Ave. Zone 2 Block 7/17 System 1 Total /Ave. System 1 Block 7/16 COOLING LOADS AT COIL PEAK - ALTERNATIVE Room Number Description 1 GENERAL OFFICE Zone 1 Total /Ave. Zone 1 Block C i 2 SOUTH CONF ROOM 2 Total /Ave. e 2 Block System 1 Total /Ave. System 1 Block PEAK COOLING LOADS (Main System) Space Coil Peak OA Rm Supp. Space Space Space Peak DA Rm Supp. Coil Coil Coil Time Cond. Dry Dry Air Sens. Lat. Time Cond. Dry Dry Air Sens. Lat. Mo /Hr DB /W8 Blb Bulb Flow Load Load Mo /Hr DB /WB Blb Bulb Flow Load Load (F) (F) (F) (Cfm) (Btuh) (Btuh) (F) (F) (F) (Cfm) (Btuh) (Btuh) Network 84 67 75 56.0 12,375 258,357 35,145 7/14 84 69 75 56.0 12,345 357,753 70,113 84 67 75 56.0 12,375 258,357 35,145 84 69 75 56.0 12,345 357,753 70,113 84 67 75 56.0 12,375 258,357 35,145 7/14 84 69 75 56.0 12,345 357,753 70,113 83 65 75 56.0 1,081 22,575 10,650 7/14 84 69 75 56.0 1,079 28,272 12,557 83 65 75 56.0 1,081 22,575 10,650 84 69 75 56.0 1,079 28,272 12,557 83 65 75 56.0 1,081 22,575 10,650 7/14 84 69 75 56.0 1,079 28,272 12,557 84 67 75 56.0 13,456 280,932 45,795 84 69 75 56.0 13,424 386,025 82,670 84 67 75 56.0 13,456 280,932 45,795 7/14 84. 69 75 56.0 13,424 386,025 82,670 Lights Room Sensible (Btuh) 49,543 49,543 49,543 2,702 2,702 2,702 52,245 52,245 1 INTERNAL COOLING LOADS (At time of Coil Peak) Lights Ret, Air Lites Sensible CLF (Btuh) 16,514 1.000 16,514 1.000 16,514 1.000 901 1.000 901 1.000 901 1.000 17,415 1.000 17,415 1.000 Misc. People People Peopl Space Sensible Latent CLF Sensible (Btuh) (Btuh) (Btuh) 35,145 35,145 1.000 109,915 35,145 35,145 1.000 109,915 35,145 35,145 1.000 109,915 10,650 10,650 1,000 5,995 10,650 10,650 1.000 5,995 10,650 10,650 1.000 5,995 45,795 45,795 1.000 115,910 45,795 45,795 1.000 115,910 Misc. Space Latent (Btuh) V 600 PAGE 4 Misc. Ret. Air Misc. Sensible CLF Total (Btuh) (Btuh) 16,00 1.000 262,262 16,00 1.000 262,262 16,00 1.000 262,262 1.000 30,898 1.000 30,898 1.000 30,898 16,00 1.000 293,160 16,00 1.000 293,160 Trane Air Conditioning Economics By: Trane Customer Direct Service. Network COOLING LOADS AT SPACE PEAK - ALTERNATIVE 1 Lights Room Room Sensible Number Description (Btuh) 1 GENERAL OFFICE '49,543 Zone 1 Total /Ave. 49,543 Zone 1 Block 49,543 2 SOUTH;CONF ROOM 2,702 Zone 2 Total /Ave. 2,702 Zone 2 Block 2,702 System 1 Total /Ave. 52,245 System 1 Block 52,245 Lights Ret, Air Lites Sensible CLF (Btuh) 16,514 1.000 16,514 1.000 16.514 1.000 901 1.000 901 1.000 901 1.000 17,415 1.000 17,415 1.000 INTERNAL COOLING LOADS (At time of Space Peak) Misc. People People Peopl Space Sensible Latent CLF Sensible (Btuh) (Btuh) (8tuh) 35,145 35,145 1.000 109,915 35,145 35,145 1.000 109,915 35.145 35,145 1.000 109.915 10,650 10,650.1.000 5,995 10,650 10.650 1.000 5,995 10,650 10,650 1.000 5,995 45,795 45,795 1.000 ' 115,910 45,795 45,795 1.000 115,910 Misc. Space Latent (Btuh) Misc. Ret. Air Sensible (Btuh) 16,000 16,000 16,000 0 0 0 16,000 16,000 Misc. CLF Total (8tuh) 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 V 600 PAGE 5 262,262 262,262 262,262 30,898 30,898 30.898 293,160 293,160 Trane Air Conditioning Economics By: Trane Customer Direct Service Network COOLING LOADS AT COIL PEAK - ALTERNATIVE 1 Room Number 1 GENERAL OFFICE Zone 1 Total /Ave. Zone 1 Block 2 SOUTH CONF ROOM Zone 2 Total /Ave. Zone 2 Block System 1 Total /Ave. System 1 Block Room Number Description 1 GENERAL OFFICE Zone 1 Total /Ave. Zone 1 Block 2 SOUTH CONF ROOM Zone 2 Total /Ave. Zone 2 Block tern 1 Total /Ave. em 1 Block Room Number Description 1 GENERAL OFFICE Zone 1 Total /Ave. Zone 1 Block 2 SOUTH CONF ROOM Zone 2 Total /Ave. Zone 2 Block System 1 Total /Ave. System 1 Block BUILDING ENVELOPE COOLING LOADS (Roof - Skylight) (At time of Coil Peak) Roof Roof Skylight Skylight Return Air Roof Space Roof Skylight Skylight Skylt Return Air Skylt Space Skylt Sensible R.A. Sensible Space Return Air Space Solar Conduction R.A. Conduction Space Load CLTD Load CLTD Solar Solar CLF Load CLTD Load - CLTD Description (Btuh) (F) (Btuh) (F) (Btuh) (Btuh) (Btuh) (F) (Btuh) (F) 17,753 28.9 17,753 28.9 17,753 28.9 968 28.9 968 28.9 968 28.9 18,721 28.9 18,721 28.9 31.1 31,1 31.1 31.1 31.1 31.1 31.1 31.1 2,047 46.3 1.135 48,5 0 2,047 46.3 1,135 48.5 0 2,047 46.3 1,135 48.5 0 0 0.0 0 0,0 0 0 0,0 0 0.0 0 0 0.0 0 0.0 0 2,047 46.3 1,135 48.5 0 2,047 46.3 1,135 48.5 0 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0,000 0,000 0,000 0,000 0,000 0.000 0.000 0,000 BUILDING ENVELOPE COOLING LOADS (Exposed Floor - Partitions - Infiltration) (At time of Coil Peak) Exposed Expsd Floor Floor Partition Part. lnfilt. Infilt, Sensible CLTD Sensible CLTD Airflow Sensible (Btuh) (F) (Btuh) (F) (Cfm) (Btuh) 51,480 20.0 3,693 20,0 51,480 20.0 3,693 20.0 51,480 20.0 3,693 20,0 2,808 20.0 0 0.0 2,808 20.0 0 0.0 2,808 20.0 0 0.0 54,288 20.0 3,693 20.0 54,288 20.0 3,693 20.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 V 600 PAGE 6 BUILDING E VELOPE COOLING LOADS (Wall - Window) (At time of Coil Peak) Wall Wall Wall Wall Glass Glass Glass Glass Glass.t Glass Glass Plenum Plenm Space Space Space Return Air Solar Space Space Return Air R.A. Load CLTD Load CLTD Solar Solar CLF Conduction CLTD Conduction CLTD (Btuh) (F) (Btuh) (F) (Btuh) (Btuh) (Btuh) (F) (Btuh) (F) 0.0 0.0 0.0 0.0 0.0 0,0 0.0 0.0 Plenm Ceiling lnfilt. Dry B Sensible Envelope Latent Temp. Load Total (Btuh) (F) (Btuh) (Btuh) 0 77,2 6,830 82,938 0 77.2 6,830 82.938 0 77.2 6,830 82,938 0 77.2 373 4,149 0 77.2 373 4,149 0 77.2 373 4,149 0 77.2 7,203 87,087 0 77.2 7.203 87,087 0.0 0.0 0.0 0.0 0,0 0.0 0,0 0.0 Trane Air Conditioning Economics By: Trane Customer Direct Service Network COOLING LOADS AT SPACE PEAK - ALTERNATIVE 1 Room Number 1 GENERAL OFFICE Zone 1 Total /Ave. Zone 1 Block 2 SOUTH CONF ROOM Zone 2 Total /Ave. Zone 2 Block System 1 Total /Ave. System 1 Block Room Number Description BUILDING ENVELOPE COOLING LOADS (Roof - Skylight) (At time of Space Peak) Roof Roof Skylight Skylight Return Air Roof Space Roof Skylight Skylight Skylt Return Air Skylt Space Skylt Sensible R.A. Sensible Space Return Air Space Solar Conduction R.A. Conduction Space Load CLTD Load CLTD Solar Solar CLF Load CLTD Load CLTD Description (Btuh) (F) (Btuh) (F) (Btuh) (Btuh) (Btuh) (F) (Btuh) (F) 22,924 22,924 22,924 1,301 1,301 1,301 24,225 24,174 37.3 37.3 37.3 38.8 38.8 38.8 37.4 37.3 0 39.8 0 39.8 0 39.8 0 41.3 0 41.3 0 41.3 0 39.9 0 39.8 1 GENERAL OFFICE 1,571 35.5 889 38.0 Zone 1 Total /Ave. 1,571 35.5 889 38,0 Zone 1 Block 1,571 35.5 889 38,0 2 SOUTH CONF ROOM 0 0.0 0 0.0 Zone 2 Total /Ave. 0 0.0 0 0.0 Zone 2 Block 0 0.0 0 0.0 frNtem 1 Total /Ave, 1,571 35.5 889 38.0 em 1 Block 1,571 35.5 889 38.0 1 GENERAL OFFICE 51,480 20.0 3,693 20.0 0 Zone 1 Total /Ave. 51,480 20.0 3,693 20.0 0 Zone 1 Block 51,480 20.0 3,693 20.0 0 2 SOUTH CONF ROOM 2,808 20.0 0 0.0 0 Zone 2 Total /Ave. 2,808 20.0 0 0.0 0 Zone 2 Block 2,808 20.0 0 0.0 0 System 1 Total /Ave. 54,288 20.0 3,693 20.0 0 System 1 Block 54,288 20.0 3,693 20.0 0 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 BUILDING ENVELOPE COOLING LOADS (Wall - Window) (At time of Space Peak) 0.000 0,000 0,000 0.000 0.000 0.000 0.000 0.000 0.0 0,0 0.0 0.0 0.0 0.0 0.0 0.0 V 600 PAGE 7 - Wall Wall Wall Wall Glass Glass Glass Glass Glass• Glass Glass Plenum Plenm Space Space Space Return Air Solar Space Space Return Air R.A. Room Load CLTD Load CLTD Solar Solar CLF Conduction CLTD Conduction CLTD Number Description (Btuh) (F) (Btuh) (F) (Btuh) (Btuh) (Btuh) (F) (8tuh) (F) 0,0 0 0.0 0,0 0 0.0 0.0 0 0.0 0.0 0 0.0 0.0 0 0,0 0.0 0 0.0 0.0 0 0.0 0.0 0 0.0 BUILDING ENVELOPE COOLING LOADS (Exposed Floor - Partitions - Infiltration) (At time of Space Peak) Exposed Expsd Plenm Ceiling Floor Floor Partition Part. Infilt. Infilt. Infilt. Dry 8 Sensible Envelope Sensible CLTD Sensible CLTD Airflow Sensible Latent Temp. Load Total (Btuh) (F) (Btuh) (F) (Cfm) (Btuh) (Btuh) (F) (Btuh) (Btuh) 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 77.5 7,693 88,250 77.5 7,693 88,250 77.5 7,693 88,250 77.5 420 4,528 77.5 420 4,528 77,5 420 4,528 77.5 8,113 92,778 77.5 8,113 92,728 Trane Air Conditioning Economics By: Trane Customer Direct Service Network HEATING LOADS AT SPACE PEAK - ALTERNATIVE 1 t Room Number 1 GENERAL OFFICE Zone 1 Total /Ave. Zone I Block 2 SOUTH CONF ROOM Zone 2 Total /Ave. Zone 2 Block System 1 Total /Ave. System 1 Block BUILDING ENVELOPE HEATING LOADS (Roof - Skylight) (At time of Space Peak) Roof Roof Return Air Roof Space Roof Skylight Skylight Sensible R.A. Sensible Space Return Air Space Load CLTD Load CLTD Solar Solar Description (Btuh) (F) (Btuh) (F) (Btuh) (Btuh) - 24,369 -39.7 - 24,369 -39.7 - 24,369 -39.7 -1,329 -39.7 -1,329 -39.7 -1,329 -39.7 - 25,698 -39.7 - 25,698 -39.7 -48.0 -48.0 -48.0 -48.0 -48.0 -48.0 -48.0 -48.0 BUILDING E VELOPE HEATING (Wall - Window) (At time of Space Peak) Wall Wall Wall Wall Glass Glass Glass Glass Glass": Glass Glass Plenum Plenm Space Space Space Return Air Solar Space Space Return Air R.A. Room Load CLTD Load CLTD Solar Solar CLF Conduction CLTD Conduction CLTD Number Description (Btuh) (F) (Stub) (F) (Btuh) (Btuh) (Btuh) (F) (Btuh) (F) 1 GENERAL OFFICE -1,755 -39.7 -1,123 -48.0 Zone 1 Total /Ave. -1,755 -39.7 -1,123 -48.0 Zone 1 Block -1,755 -39.7 -1,123 -48.0 2 SOUTH CONF ROOM 0 0.0 0 0.0 Zone 2 Total /Ave. 0 0.0 0 0.0 Zone 2 Block 0 0.0 0 0.0 "em 1 Total /Ave. -1,755 -39,7 -1,123 -48.0 em 1 Block -1,755 -39.7 -1,123 -48.0 IL Exposed Expsd Floor Floor Partition Part. Infilt. Room Sensible CLTD Sensible CLTD Airflow Number Description (Btuh) (F) (Btuh) (F) (Cfm) 1 GENERAL OFFICE 0 0.0 Zone 1 Total /Ave. 0 .0.0 Zone 1 Block 0 0.0 2 SOUTH CONF ROOM 0 0.0 Zone 2 Total /Ave. 0 0.0 Zone 2 Block 0 0.0 System 1 Total /Ave. 0 0.0 System 1 Block 0 0.0 BUILDING ENVELOPE HEATING LOADS (Exposed Floor - Partitions - Infiltration) (At time of Space Peak) 0.0 0.0 0.0 0.0 0.0 0.0 0,0 0.0 Infilt. Sensible (Btuh) 0 0 0 0 0 0 0 0 Skylt Solar CLF 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 LOADS 0.000 0.000 0.000 0.000 0,000 0.000 0.000 0,000 Skylight Skylight Return Air Skylt Space Skylt Conduction R.A. Conduction Space Load CLTD Load CLTD (Btuh) (F) (Btuh) (F) 0.0 0.0 0.0 0.0 0.0 0.0 0,0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 V 600 PAGE 8 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 Plenm Ceiling Infilt. Dry B Sensible Envelope Latent Temp. Load Total (Btuh) (F) (Btuh) (Btuh) 59.7 - 26,033 - 53,279 59.7 - 26,033 - 53,279 59.7 - 26,033 -53,279 59.7 -1,420 -2,749 59.7 -1,420 -2,749 59.7 -1,420 -2,749 59.7 - 27,453 -5 59.7 - 27,453 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 Trane Air Conditioning Economics By: Trane Customer Direct Service Network COOLING LOADS AT COIL PEAK - ALTERNATIVE 1 Room Number 1 GENERAL OFFICE Zone 1 Total /Ave. Zone 1 Block 2 SOUTH CONF ROOM Zone 2 Total /Ave. Zone 2 Block System 1 Total /Ave. System 1 Block Room Number Description 1 GENERAL OFFICE Zone 1 Total /Ave. Zone 1 Block 2 SOUTH CONF ROOM 2 Total /Ave. ne 2 Block System 1 Total /Ave. System 1 Block Airflow Sensible Description (Cfm) (Btuh) 1,980 1,980 1,980 108 108 108 2,088 2,088 Ventilation 20,536 20,536 20,536 1,120 1,120 1,120 21,656 21,656 COOLING AIRFLOW HEAT GAIN /LOSS ALTERNATIVE 1 AIRFLOW COOLING LOADS (At time of Coil Peak) Latent Airflow (Btuh) (Cfm) 34,968 34,968 34,968 1,907 1,90T 1,907 36,875 36,875 AIRFLOW Optional Ventilation Sensible (Btuh) 0 0 0 0 0 0 0 0 Latent Airflow (Btuh) (Cfm) HEAT GAIN AND LOSS (At time of Coil Peak) Duct Supply Return System Heat Fan Fan Exhaust Pickup Heat Heat Heat Loss Total (Btuh) (Btuh) (Btuh) (Btuh) (Btuh) 13,565 38,730 0 -4,737 47,558 1,980 13,565 38,730 0 -4,737 47,558 1,980 13,565 38,730 0 -4,737 47,558 1,980 1,186 3,385 0 -258 4,313 108 1,186 3,385 0 -258 4,313 108 1,186 3,385 0 -258 4,313 108 14,751 42,116 0 -4,996 51,871 2,088 14,751 42,116 0 -4,996 51,871 2,088 Cooling System Room Exhaust Exhaust Airflow Airflow (Cfm) (Cfm) Bypass Sensible (Btuh) 12,345 12,345 12,345 1,079 1,079 1,079 13,424 13,424 Latent (Btuh) 0 0 0 0 0 0 0 0 V 600 PAGE 9 Ov /Undr Sizing (Btuh) Run System Ducted Plenum Around Corridr Return Airflow Airflow Airflow Airflow Airflow (Cfm) (Cfm) (Cfm) (Cfm) (Cfm) 0 12,345 0 12.345 0 12,345 0 1,079 0 1,079 0 1,079 0 13,424 0 13,424 Trane Air Conditioning Economics By: Trane Customer Direct Service Network SYSTEM PSYCHROMETRICS - ALTERNATIVE 1 PSYCHROMETRIC STATE POINTS 1 (:: S ystem 1 BUILDING U- VALUES - ALTERNATIVE 1 BUILDING U - VALUES Room U- Values Dry Wet Relat. Humid. Temp. Bulb Bulb Humid. Ratio . Enthalpy Diff. (F) (F) ( %) - (GR) (Btu /Lb) (F) Space 75.0 60.7 43.8 57.6 27.0 Main System Return Air Heat Pickup Return Fan 0.0 Return Air 77.5 61.5 40.3 57.6 27.6 Outdoor Air 84.4 69.0 46.1 83.1 33.3 Return /Outdoor Air Mix 78.5 62.8 41.6 61.5 28.5 Blow through Fan 0.0 Entering Coil 78.5 62.8 41.6 61.5 28.5 Leaving Coil 52.1 50.6 90.1 53.1 20.7 Draw Through Fan 1.4 Duct Frictional Heat 1.5 Supply Duct Heat Gain 1:0 Cold Deck Supply Air 56.0 52.2 78.3 53.1 21.7 Supply Air 56.0 52.2 78.3 53.1 21.7 Percent Outside Air 15.52 (%) Sensible Heat Ratio (SHR) 0.860 Percent Supply Air Bypassing Coil 0.00 (%) Coil Airflow 13,456 (Cfm) 2.5 Room Room (Btu /hr /sqft /F) Mass Capac. Room Summr Wintr Summr Wintr (1b/ (Btu/ Number Description Part. ExF1r Skylt Skylt Roof Windo Windo Wall .Cell. sqft) sqft /F) 1 GENERAL OFFICE 0.079 0.260 0.000 0.000 0.062 0.000 0.000 0.065 0.317 109.4 22,72 Zone 1 Total /Ave. 0.079 0.260 0.000 0.000 0.062 0.000 0,000 0.065 0.317 109.4 22,72 2 SOUTH CONF ROOM 0.000 0.260 0.000 0.000 0.062 0.000 0.000 0.000 0.317 97.8 20.46 Zone 2 Total /Ave. 0.000 0.260 0.000 0.000 0,062 0.000 0.000 0.000 0.317 97.8 20.46 System 1 Total /Ave. 0.079 0.260 0.000 0.000 0.062 0.000 0.000 0.065 0.317 108.8 22.60 Building 0.079 0.260 0.000 0.000 0.062 0.000 0.000 0.065 0.317 108.8 22.60 ••r V 600 PAGE 10 Trane Air Conditioning Economics By: Trane Customer Direct'Service Network • BUILDING AREAS - ALTERNATIVE I ASHRAE 90 ANALYSIS - ALTERNATIVE 1 Overall Roof U -Value = 0.062 (Btu /Hr /Sq Ft /F) Overall Wall U -Value 0.065 (Btu /Hr /Sq Ft /F) Overall Building U -Value = 0.062 (Btu /Hr /Sq Ft /F) ASHRAE 90 ANALYSIS 'BUILDING AREAS 1 GENERAL OFFICE 1 .1 9,900 9,900 2,340 9,900 Zone 1 Total /Ave. 9,900 2,340 9,900 2 SOUTH CONF ROOM 1 1 540 540 0 540 Zone 2 Total /Ave. 540 0 540 System 1 Total /Ave. 10,440 2,340 10,440 Building 10,440 2,340 10,440 Roof Overall Thermal. Transfer Value (OTTVr) = 1.73 (Btu/Hr/Sq Ft) Wall Overall Thermal Transfer Value (OTTVw) = 3.01 (Btu/Hr/Sq Ft) 9,900 9,900 540 540 10,440 10,440 .r V 600 PAGE 11 Floor Total Exposed Number of Area /Dupl Floor Partition Floor Skylight Ski Net Roof Window Win Net Wall Room- Duplicate Room Area Area Area Area /Rf Area Area /W1 Area Number Description Flr Rm (sqft) (sqft) (sqft) (sqft) (sqft) (%) (sqft) (sqft) (%) (sqft) 1,040 1,040 0 0 1,040 1,040 English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E17A PROJECT : BUILDING LOAD CALCULATIONS FOR: LOCATION : AHU AH2E17A (SOUTH UNIT) CLIENT : 9 -101 BLDG EEIP PROJECT, PHASE 3 -E PROGRAM USER : BOEING MILITARY AIRPLANES COMMENTS : FIG. BY: S.ROSSE English LOAD DESIGN 600 Screen. -- 2 of 29 INPUT FILE NAME : E: \CDS \TULTRA \AH2E17A Card 08: Climatic Information Weather Code : SEATTLE Summer Clearness Number : .95 Winter Clearness Number : .95 Summer Design Dry Bulb : 85 Summer Design Wet Bulb : 68 Winter Design Dry Bulb : 20 Building Orientation : Summer Ground Reflectance : .2 Winter Ground Reflectance : .2 Screen: 1 of 29 Sect: JOB Sect: JOB ,x;�.:. • ...:, TOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E17A English Card 09: Load Simulation Periods First Month Cooling Simulation : JUL Last Month Cooling Simulation : SEP Peak Cooling Load Hour : First Month of Summer Period : Last Month of Summer Period : First Month Daylight Saving : Last Month Daylight Saving : English LOAD DESIGN 600 INPUT FILE NAME E: \CDS \TULTRA \AH2E17A Card 10: Load Simulation Parameters (Optional) Cooling Load Methodology : CLTD -CLF Heating Load Methodology : UATD Ventilation Methodol9gy : Airflow Input Units : ACTUAL Airflow Out Ott Units : ACTUAL Room Circulation Rate : Put Wall RA Load into Room : NO Screen: 3:of . 29 Sect: JOB - Sect:. JOB .:.._.. LOAD DESIGN 600 •:;..,.. INPUT FILE NAME : E: \CDS \TULTRA \AH2E17A Card 19: Load Alternative Description Alternative Number : 1 Alternative Description : English LOAD DESIGN 600 Screen: 6 of 2 9 INPUT FILE NAME : E: \CDS \TULTRA \AH2E17A Room : 1 of 3 Sect: LOAD Card 20: General Room Parameters ROOM NUMBER : M ZONE REFERENCE NUMBER : 1 Room Description : Floor Length : Floor Width : Construction Type : 7 Plenum Height : 17 Acoustic Ceiling Resistance : 1.786 Floor -to -Floor Height : 26 Duplicate Floor Multiplier : No. Duplicate Rooms /Zone Screen: : ; : 5, of ,: 29 - Alt : 1 of 1 Sect: LOAD English LOAD DESIGN 600 INPUT FILE NAME : E:\CDS\TULTRA\AH2E17A English LOAD DESIGN 600 Screen: 6 of 29 Alt : 1 of 1 Room : 3 of 3 Sect: LOAD INPUT FILE NAME : E:\CDS\TULTRA\AH2E17A Card 20: General Room Parameters ROOM NUMBER : 1 ZONE REFERENCE NUMBER : 1 Room Description : GENERAL OFFICE Floor Length : 9900 Floor Width : 1 Construction Type : Plenum Height : Acoustic Ceiling Resistance : Floor-to-Floor Height : Duplicate Floor Multiplier : No. Duplicate Rooms/Zone : Card 20: General Room Parameters ROOM NUMBER : 2 ZONE REFERENCE NUMBER : 2 Room Description : SOUTH CONF ROOM Floor Length : 30 Floor Width : 18 Construction Type : Plenum Height Acoustic Ceiling Resistance : Floor-to-Floor Height : Duplicate Floor Multiplier : No. Duplicate Rooms/Zone Screen: 6'of .29 Alt : 1 of 1 Room : 2 of 3 Sect: LOAD English _.., _, LOAD DESIGN - 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E17A ROOM NUMBER : Room Design Cooling Dry,Bulb Room Design Relative Humidity Room Design Heating Dry Bulb Room Mass / No. Hrs Time Avg : Is There Carpet on the Floor. : Card 21: Thermostat Parameters English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E17A Card 22: Roof Parameters ROOM NUMBER : M ROOF NUMBER : 1 Is the Roof Area = Floor Area : Roof Length Roof Width : Roof U -Value : 062 Construction Type : .062 Roof Direction : Roof Tilt : Roof Alpha : . Screen: 7 of 29 o Sect: LOAD 1 Screen: 8 of 29 Alt 1.of 1 RoSe 3 ct: LOAD English :A .: LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E17A Card 22: Roof Parameters ROOM NUMBER : 1 ROOF NUMBER : 1 Is the Roof Area = Floor Area : YES Roof Length : Roof Width : Roof U -Value : Construction Type : Roof Direction : Roof Tilt : Roof Alpha : English LOAD DESIGN 600 INPUT FILENAME : E: \CDS \TULTRA \AH2E17A ROOM NUMBER : 2 ROOF NUMBER 1 the Roof Area = Floor Area : YES Roof Length : Roof Width : Roof U -Value : Construction Type : Roof Direction : Roof Tilt : Roof Alpha : Card 22: Roof Parameters Screen: - - 8 of .. 29 Alt : 1 of 1 Ro Sect: LOAD of 3 Screen: 8 of 29 Alt : 1 of 1 Roof : 3 of 3 Sect: LOAD English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E17A Percent Card 23: Skylight Parameters (Optional) ROOM NUMBER : ROOF NUMBER : Skylight Length : Skylight Width : # of Skylite/Pct Glass : Skylight U -V : Shading Coefficient : External Shading Type : Internal Shading Type : Solar Load to Return Air : English LOAD DESIGN 600 INPUT NAME ': E:, \CDS \TULTRA \AH2E17A Card 24: Wall Parameters ROOM NUMBER : 1 WALL NUMBER : 1 Wall Length : 40 Wall Height : 26 Wall U- Value : 0.065 Construction Type : 71 Wall Direction : 180 Wall. Tilt : Wall Alpha : Reflectance Multiplier : Screen: 9 of 29 S ' Sect: LOADof 1 Screen: 10 of 29 Alt 1 of 1 Wall : 1 of 1 Sect: LOAD English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E17A ROOM NUMBER : WALL NUMBER : Glass Length : Glass Width : of Windows /Pct Glass : Glass U -Value : Shading Coefficient : External Shading Type : Internal Shading Type : Percent Solar Load to Return Air : Card 25: Wall Glass Parameters English LOAD DESIGN 600 INPUT FILE NAME.: E: \CDS \TULTRA \AH2E17A Card 26: Schedules (Optional) ROOM NUMBER : People : Lights : Ventilation : Infiltration : Reheat Minimum : Cooling Fans Schedule Code : Heating Fan Schedule Code : Auxiliary Fan Schedule Code : Room Exhaust Schedule Code : Screen: 11 of 29 Glass : 1 of 1 Sect: LOAD Screen: 12 of 29 Alt : 1 of 1 Room : 1 of 1 Sect:. LOAD English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E1 Card 27: People and Lights ROOM NUMBER : M People Value : 100 People Units : SF -PERS People Sensible : 355 people Latent : 355 Lig Value : 1.7 ihting Units : WATT-SF Lightin Ballast r Factor : 1.: 1R5AE2 Light Load to Return Air : 25 English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E Card 27: People and Lights ROOM NUMBER : 1 People Value People Units : People Sensible : people Latent : Lighting Value : Lighting Units Lighting Fixture Type : Ballast Factor Light Load to Return Air : Screen: 13 of 29 Room : 1 of 3 Sect: LOAD Alteen: 11 of Room .2 of Sect: LOAD 29 3 English INPUT FILE NAME : E: \CDS \TULTRA \AH2E17A (7 lam.` English LOAD DESIGN 600 Card 27: People and Lights ROOM NUMBER 2 People Value : 30 People Units : PEOPLE People Sensible : ieo le Latent : Lighting Value : Lighting Units : Lighting Fixture Type Ballast Factor : Percent Light Load to Return Air : INPUT FILENAME : E: \CDS \TULTRA \AH2E17A LOAD DESIGN 600 Card 28: Miscellaneous Equipment (Optional) ROOM NUMBER : M Miscellaneous Equip Ref Number : 1 Equipment Description : Energy Consumption Value : 3.253 Energy Consumption Units : WATT -SF Schedule Code : Percent of Load Sensible : 100 Percent Miscellaneous Load to Room : 100 Percent Misc Sens to Return Air : 0 Radiant Fraction : 0 Screen: 13 of 29 Alt 1 of 1 Room 3 of 3 Sect: LOAD Screen: 14 of 29 Alt 1 of 1 Room 1 of 4 Sect: LOAD English INPUT FILE NAME : E: \CDS \TULTRA \AH2E17A 417 LOAD DESIGN 600 Card 28: Miscellaneous Equipment (Optional) ROOM NUMBER : 1 Miscellaneous Equip Ref Number : 1 Equipment Description : OFFICE EQUIPMENT Energy Consumption Value : Energy Consumption Units : Schedule Code : Percent of Load Sensible : Percent Miscellaneous Load to Room : Percent Misc Sens to Return Air : Radiant Fraction : English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E17A Card 28: Miscellaneous Equipment (Optional) ROOM NUMBER : 1 Miscellaneous Equip Ref Number : 2 Equipment Description : TRANSFORMERS Energy Consumption Value : 16000 Energy Consumption Units : BTUH Schedule Code : Percent of Load Sensible : 100 Percent. Miscellaneous Load to Room : 0 Percent Misc Sens to Return Air : 100 Radiant Fraction : 0 Screen: 14 of 29 Room 2 of . 4 Sect: LOAD Screen: 14 of 29 Alt : 1 of 1 Room : 3 of 4 Sect: LOAD English - LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E17A English Card 29: Room Airflows ROOM . NUMBER : 1 Ventilation Cooling Value : yentilati.on Units : Ventilation Heating Value : Ventilation Units : Infiltration Cooling Value : Infiltration Units : Infiltration Heating Value : Infiltration Units : Reheat Minimum : Reheat Minimum Units : INPUT FILE NAME :•E: \CDS \TULTRA \AH2E17A Ventilation Cooling Value : yentilati.on Units : Ventilation Heating Value : yentilat4.on Units : Infiltration Cooling Value : Infiltrati.on Units : Infiltration Heating Value : Infiltration Units : Reheat Minimum : Reheat Minimum Units : LOAD DESIGN 600 Card 29: Room Airflows ROOM NUMBER : 2 Screen: 15 of 29 Alt • 1 of 1 Room : 2 of 3 Sect: LOAD Screen: 15 of 29 Alt 1 of 1 Ro Sect: LOAD 3 English INPUT FILE NAME : E: \CDS \TULTRA \AH2E17A Main Cooling Supply Value : Ma4.n Cooling Supply Units : Main Heating Supply Value : Main Heating Supply Units : Auxiliary Cooling Supply Value : Auxiliary Cooling Supply Units : Auxiliary Heating Supply Value : Auxiliary Heating Supply Units : Room Exhaust : Room Exhaust Units : •• LOAD DESIGN_600 1,.. Card 30: Fan Airflows r•^�� ,. A�!' �1A!" rt+ Yfe" l' tPirF A3iz' �ti'%' u.( i": tEF" riki4,ft �i .rpC .. , .:... a • , v�Mi . •.+h� Y.:c s�.(:i::..'.,._. u hc.; 4.'.��- ��:«es: °_:...::,' • it NUMBER ... +.t �'AA1•, ...: w... .. ... .: .1. !< . i .. • ROO BER . English LOAD DESIGN 600 INPUT FILE NAME E:\CDS\TULTRA\AH2E17A Card 31: Partition Parameters (Optional) ROOM NUMBER : M PARTITION NUMBER : 1 Partition Length Partition Height : 26 Partition U -Value .0789 Construction Type : 104 Temperature Flag : CONSTANT Cooling Temperature : 95 Heating Temperature : 68 Screen: 16 of 29 Alt : 1 of 1 Ro Sect: LOAD 1 Screen: 17 of 29 Alt 1 of 1 Partn : 1 of 2 Sect: LOAD English... LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E17A Card 31: Partition Parameters (Optional English INPUT FILE NAME ROOM NUMBER : 1 PARTITION NUMBER : 1 Partition Length : 90 Partition Height : Partition U -Value : Construction Type : Temperature Flag : Cooling Temperature : Heating Temperature : LOAD DESIGN 600 : E: \CDS \TULTRA \AH2E17A Card 32: Exposed Floor Information (Optional) ROOM NUMBER : M EXPOSED FLOOR NUMBER : 1 SLAB -ON -GRADE Perimeter length : Loss Coefficient : EXPOSED FLOOR Exposed Floor Area : Exposed Floor U -Value : 0.260 Construction Type : 116 Temperature Flag : CONSTANT Cooling Temperature : 95 Heating Temperature : 68 Screen: 17 of 29 Alt 1 of 1 Partn : 2 of 2 Sect: LOAD Screen: 18 of 29 Floor : l of 3 Sect: LOAD English-. INPUT FILE NAME : E: \CDS \TULTRA \AH2E17A Card 32: Exposed Floor Information ,.�.j (Optional) 'x ommq€mAthrf' -fir i0,41 .4\t N t' ,,,4' * :a:r.:,W4T. . r`v... 4M f? - T4If tt4tAl ii _rnr4ila 7 r�z�4,. �'4�»p:i ' ' J: ROOM NUMBER : 1 EXPOSED FLOOR NUMBER : 1 SLAB -ON -GRADE Perimeter I,,ength : Loss Coefficient : English LOAD DESIGN 600- EXPOSED FLOOR Exposed Floor Area : 9900 Exposed Floor U -Value : Construction Type : Temperature Flag : Cooling Temperature : Heating Temperature : LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E17A Card 32: Exposed Floor Information (Optional) ROOM NUMBER : 2 EXPOSED FLOOR NUMBER : 1 SLAB -ON -GRADE Perimeter Length : Loss Coefficient : EXPOSED FLOOR Exposed Floor Area 540 Exposed Floor U -Value : Construction Type : Temperature Flag : Cooling Temperature : Heating Temperature : Alteen:'. 18 of 29 Floor : 2 of 3 Sect: LOAD Screen: 18 of 29 Alt 1 of 1 Floor : 3 of 3 Sect: LOAD English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E17A Card 33: External Shading (Optional) �1+lei 41010 .0rx4wie?4.nti! w .tiev - c4,r"th a: kr- ..- :'d7,s:4.;. # r,,g . p ya cSJvTS :yt Shading Type : English OVERHANG Glass Height : Height Above Glass : Projection Out : VERTICAL FINS Glass Width : Projection Left : Left Pvojection Out : Projection Right : Right Projection Out : Adjacent Building Flag : LOAD DESIGN 600 INPUT FILE NAME ::E: \CDS \TULTRA \AH2E17A Card 34: Internal Shading (Optional Shading Type : Overall U -Value : Overall Shading Coeff Schedule Code : Screen: 19 of 29 Extsh : 1 of 1 Sect: LOAD Screen: 20 of 29 Alt 1 of 1 In Sect: LOAD of 1 English FILE NAME : E: \CDS \TULTRA \AH2E17A 4:'' LOAD DESIGN 600 }� �µayy�} '�y�(�qp R�� ) }..} Card 39: System Alternative Description ;4} 1.-K 3 ,.` " :- • `•V ' .R ^�"2.1�31.it�A�Vi.%�!" � f^�u .'y Y+i• «.: ........ �. w :. Fi:. a�� Y. Y •���"I •� Yl4-. ! .. r. _' $i#,;., � .;`'�:::. - r.' {: YP ; ' .401 Alternative Num2?er : 1 System Alternative Description English LOAD DESIGN 600 INPUT FILE NAME : E:\CDS\TULTRA\AH2E17A Card 40: System Type SYSTEM SET NUMBER : 1 System Type : VAV Optional Ventilation System Ventilation Deck Location : ROADK Opt. Ventilation Cooling SADBVC : Opt. Ventilation Heating SADBVH : Cooling Schedule Code : Heating Schedule Code : Fan Static Pressure : Screen: 21 of 29 Sect: SYSTEM Screen: 22 of Alt : 1 of System: 1 of Sect:. SYSTEM 29 1 English INPUT FILE NAME : E: \CDS \TULTRA \AH2E17A SYSTEM Main Cooling Fan Motor Main Heating Fan Motor Return Fan Motor Main Exhaust Fan Motor Auxiliary Fan Motor Room Exhaust Fan Motor Opt Vent Fan Motor Fan Mechanical Block Cooling Airflow Value Block Cooling Airflow Units Main Cooling Fan Sizing Method Main Cooling Fan Configuration SET NUMBER Efficiency Efficiency Efficiency Efficiency Efficiency Efficiency Efficiency Efficiency Pgopple Variance Lights Variance Miscellaneous Loads Variance Main Cooling Coil Capacity Value Main Cooling Coil Capacity Units Main Cooling Coil Sizing Method Main Cooling Coil Level Location Aux Cooling Coil Capacity Value Aux Cooling Coil Capacity Units LOAD DESIGN 600 Card 47: Fan Overrides (Optional) : 1 : 85 85 60 : BLOCK : DRAW English LOAD DESIGN 600 INPUT FILE NAME : E: \CDS \TULTRA \AH2E17A Card 48: Cooling Capacity Overrides (Optional) SYSTEM SET NUMBER : 1 : BLOCK Screen: 27 of 29 System: 1 of 1 Sect: SYSTEM Screen: 28 of Alt of System: 1 of Sect: SYSTEM 29 1 1 English LOAD DESIGN INPUT FILE NAME': E: \CDS \TULTRA \AH2E17A Main Heating Main Heatin Main Preheat Main Preheat Reheat Reheat Humidification Humidification Aux Heating Aux Heating Card 49: Heating apacity Overrides (Opt •• .,. , . . SYSTEM SET NUMBER Coil Coil Coil Coil Coil Coil Coil Coil Coil Capacity Capacity Capacity Capacity Capacity Capacity Capacity Capacity Capacity Capacity Value Units Value Units Value Units Value Units Value Units 600 Screen: 29 of System: 1 of Sect: SYSTEM 29 ,�cua,a..ny MS -85(R) CUSTOMER NAME ( UENCE NUMBERS: 1 & McQUAY ' FAN DESIGN EXT. SP. MODEL SIZE TYPE (ACTUAL) 'ACTUAL) NO. ACFM INCHES WC 36 MSL128 OPT AF 14390. 3.76 DRAW -THRU UNIT SINGLE ZONE UNIT ARRANGEMENT - HORIZONTAL FAN DISCHARGE - TOP HORIZ. VAV METHOD INLET VANES INTERNAL AIR PRESSURE DROPS: COOLING COIL HEATING COIL BAG FILTER SECTION WITH 85- 95 %EF.BAG FILTERS WITH 35% EFF. PREFILTERS MIXING BOX DAMPER C OF INTERNAL STATIC PRESSURE DROP R FER TO AIR HANDLER UNIT CATALOG FOR MAXIMUM COIL DEPTH OF COIL SECTIONS (IN THE DIRECTION OF AIRFLOW). OCTAVE BANDS 1 . 2 TOTAL PWL 92 94 AIR HANDLER SELECTION B.E. & C. JOB NAME REP NAME & CITY EEIP PHASE 3 -E - NORBY 2 JOB ITEM• H2E16A TOTAL SOUND POWER LEVELS AS CALCULATED BY ASHRAE METHOD(REF.10EXP -12 WATTS) 3 TOTAL BRAKE FAN SP INCHES WC HP RPM A. � 17.4 x874. 2A3S� 54% 5.11 16.30 1571. 1646. 57. 4 TO OBTAIN RADIATED SOUND POWER AS CALCULATED BY ASHRAE, SUBTRACT 15 dB FROM EACH OCTAVE BAND AND FROM dB A. 5 6 SnyderGeneral Systems VERSION 3.41 SALESMAN JIM RUN: 12/16/91 OUTLET ALTITUDE FPM FT . 88 .07 . 19 . 17. .04 1.35 7 dB A 95 90 89 84 76 93 MS-85(R) CUSTOMER NAME BMA McQUAY MODEL NO. AIR HANDLER SELECTION B.E. & C. 411 NUMBERS: 3 & 4 JOB ITEM: INTERNAL AIR PRESSURE DROPS: JOB NAME REP NAME & CITY EEIP PHASE 3-E ORBY SnyderGeneral Systems VERSION 3.41 F A N DESIGN EXT. SP. TOTAL BRAKE FAN OUTLET ALTITUDE SIZE TYPE (ACTUAL) (ACTUAL" SP VEL ACFM INCHES WC INCHES WC HP RPM . FPM FT MSL128 OPT AF 13455. 3.50 4.71 13.96 1494. DRAW-THRU UNIT SINGLE ZONE UNIT ARRANGEMENT - HORIZONTAL FAN DISCHARGE - TOP HORIZ. VAV METHOD - INLET VANES COOLING COIL .79 HEATING COIL .06 BAG FILTER SECTION WITH 85-95%EF.BAG FILTERS .17 WITH 35% EFF. PREFILTERS .15 MIXING BOX DAMPER .04 1539. /1 OF INTERNAL STATIC PRESSURE DROP 1.21 EFER TO AIR HANDLER UNIT CATALOG FOR MAXIMUM COIL DEPTH OF COIL SECTIONS (IN THE DIRECTION OF AIRFLOW). SALESMAN JIM RUN: 11/22/91 57. TOTAL SOUND POWER LEVELS AS CALCULATED BY ASHRAE METHOD(REF.10EXP-12 WATTS) OCTAVE BANDS 1 ., • 2 3 4 5 6 7 dB A TOTAL PWL 91 93 94 89 88 83 75 92 TO OBTAIN RADIATED SOUND POWER AS CALCULATED BY ASHRAE, SUBTRACT 15 dB FROM EACH OCTAVE BAND AND FROM dB A. qviloprely.lit'r.,e, I -,C�� .1 0•64 nrU1•Sr.44i4fig,UN)T 81 Z�,,13, 9ral4 41464 .= . 1;.‘ • :I ' ';$.* : .. (� - � Y ' r : •): 1 • • Y.."131:1>1,t4: , 1•A.r 4 �iY.` t37i,..,F 12000 -32000 ;+0: st41a�''n"( Y 14000 -36000 -: u ?..160 !t . 16000- 45000 O T 1 0 M r • •S,F ;.. " 7 . -. .•7t• .a't44 „r;a, t rr Mu • , 16 ...r .: ..vv 8000 -19000 8000 -25000 10 ^, �r;R;rm• 20000 -56000 n EP LYF Ventilating CFM Range By Unit Type 8000 -19000 8000 -25000 Agirp;!4, `i!ft3r: 12000 -32000 14000 -36000 18000 - 45000 20000 -56000 . ^'!:•• ';1.a ", LHD Heating & Ventilating 8000 -15700 8000 - 19800 8000-19800 12000 -32000 14000 -36000 10000- 45000 20000- 56000 30000-50000 LSL Lo Press. Drew•thru 8000 -15700 8000 -19800 8000 -19800 12000 - 32000 14000- 38000 10 000 - 45000 20000- 56000 30000 -50000 MSL Mad. Press. Draw•thru 6000 -13800 - 8000 -17500 !' .4. 1: 10000 -23300 12000 -28300 15000 -32000 16000 -40800 r1„ ' „ -, -;•• HSH HI Prep. Orow•thrU .. �' ... 4 , ...',T@nr.. ° 97/'•;.., .. • •. . FAN DATA 20 221 221 '27 30 33 381 381 Diameter (In.) FO • g • . LYF .LHD LSL MSL 5.19 6.29 6.29 9.36 11.31 13.05 1801 16.81 Outlet Mee (Sq.Ft.) 1r /,, 1" /u 1" /u II% 2' /,, 1u /, 2' A. 2' /u 2' /,, 2 /,. 2+y 2'A, 2 Shaft & Bearing (In.) 211 /„ 24 24 27 30 33 38 3644 Diameter (In.) AF 5.93 f,7.13 ';a 7.13 9.38 11.31 13.85 16.81 1881 Outlet Area (Sq.Ft.) 1 2'A. 2'A. 2'A6 2'A, 2'A6 2"A, 2 Shaft & Bearing (In.) 221/6 241 241/2 30 33 361 40% 401 Diameter (In.) FC ; 8.29 7.85, 7.65 1131 13.85 16.81 2052 2032 Outlet Area (Sq.FI.) 1 /,. 1 n /16 111 06 1 2'/, 2'A6 2% 2'/16 2"A4 2%,6 2"0. 2 2 "!,, Shaft & Bearing (In.) 24 P - 26'/„ • 26'/„ • 30 • 33 381/2 401 40% Diameter (In.) Alf. ` 7.13 r• (8.7{,). j 8.74 1131 13.85 18.81 20.52 20.52 Outlet Area (Sq.Ft.) 2%6 VA, 2' /6 2'A4 2'A6 2 2 2'y, Shaft a Bearing (In.) 3 %fliittw4fio 41;11(pi> (ji k!ziOi•tt.:V\:?.1:'' ;*'vf'.•§ 0.1 t{i4.,, :iV4.1 i ° air .! 4.401t r'::t:... r ;. . - .;.•4 ilil.t ` +fit Olsme', Om) FC .- 10 11 111 MSL t.11iT tat (' i41A7±!r:" 41: 1:i +>1,Ift r I t ;� r4'. tt.:t,(e2c ibq�. . 'T/' I'l. .c { ;:: ,"' �ji '.�R u't: , ,• • •" • Outl Area (Sq.Ft.) ty��.,.,�.,,��,, ? 'na'.u''s'�'?: 1f� IC M'.n�.1.nv.",U'yj(� i1A °,' ' iig#O'i'Q)'111.431 Gni ::�- • '.1 it r -:Y, k •C' - Shaft A Bearing (In.) 21% /, 24 ' d ( A , l 1 ; > ; 29 2 9 1/4 32'% 35%6 • " j , • • , . , 4 4 . • • y+ Diameter (In.) AF STD HSH 4.13 5.13 1 O4k 7.55 7.55 9.30 11.25 . ..,. t i • Outlet Ana (Sq.Fl.) 2 , 2'A, 00401044 2'A, 2'/„ 21'0, 2'y, . ' Shaft A Bearing (In.) I 4 • . i° . '9 0' . �1.'ll 1447di'ilt(,2t ti,LV:h '' 7 : trine ` .• .. � .J.. ,: , Y ': Yt >•4t . •.•u Y '.. .:r,i r ' :r . . d's�.tlzlll',�.h ' r},.V . '' • + b+ 1sw11�! 1t} 1: ik444+eFd +: /.:_ir::1 , �'•, •.n .COIL DATA • (1) 39x 69.5 (1) 39.1125 • • ii (2) 24.112.5 (2) 27.1125 (2) 33.1125 (2) 42.112.5 (3) 30.1125 (Number) Size (In.) EXTRA LARGE FACE AREA 24.2 30.5 •; ''r:,.I r. , , 37.5 • , 42.2 51.8 85.6 70.4 Face Am. (Sq.Ft.) (1) 36x84.5 (1) 36.1075 (1) 45.137.5 (2) 24x107.5 (2) 27.1075 (2) 33 .1075 (2) 42.1375 . • _. 4io• • t (Number) Size (In.) LARGE FACE AREA 21.2 28.9 33.8 35.9 40.4 493 62.8 I Face Ana (Sq.Ft.) (1) 27.84.5 (1) 27.1073 (1) 39.1075 (1) 42.1075 (2) 24.1073 (2) 33x1075 r :•1 ..- (Number) Size (In.) SMALL FACE AREA 15.9 20.2 /4iN' 4i 29.2 31.4 35.9 49.3 01011r8VIN Face Area (Sq.ft.) (1) 39.93 (1) 39.118 G°4'}! ',It',(h (1) 51 x1155 (1) 60x115$ (1) 69.115.5 (1) 87.1155ble~ (Number) Size (In.) LAC CASED CONDENSER COIL 25.2 31.4 'rrl`r'14Y,'`.,i'Ma 40•9 48.1 553 69.6 IX,rogat Face Area (Sq.Ft.) • .. '. , ?io. , ..:f.t - ,''..... :,.r.i:',w i;.•{.I..,:.•i; .. ., . ... v _ ..,..:.a.'.:iG ;Iitts;r;Vif... ... ., ,, .. •' FILTER DATA (12) 16.20.2 `,sS: ; ., r{)1 (12) 20.20.2 14 ;vo 0:,44j (6) 20.20x2 (12) 20.25.2 T+'i ±l ttm' •1! (18) 20.20.2 0 Ci, V ^` (12) 20.25.2 ( 6) 20.25.2 (36) 16.20.2 +1 re, A44.2.1 (Number) Size (tn.) FLAT FILTER SECTION (6) 20.25x2 ( 8) 20x20.2 (18) 20x20.2 287 33.4 37.5 41.8 50.0 585 70.8 800 Filter Ana (Sq.Ft.) (12) 16.25.2 (12) 20.25.2 (12) 20.25.2 (16) 20.25.2 (24) 20.20.2 (24) 20.25.2 (30) 20.25.2 (30) 20.25.2 Number Size 1n. (Number) ( ) ER ANGULAR FILTER SECTION Itri . J t;.%. '' '.1`fli .:..l+ iX:n.i.:"S x�lf iy,1i"j'r",1�.i''!+ ! +�L'W'i�u�: K': ',''�!•` •:,' .'....,• ..' r ,. , 1,..,r•;, .• 1J , .f ; 33.4 41.8 41.6 55.5 687 83.3 104.0 1040 Fitter Area (Sq,Ft.) (24) 18.20.2 Sa ` (24) 20.20.2 UAW:. 1 Y , (24) 20.20.2 213. , ?'�O! Alf0. (24) 20.25.2 (36) 20.20.2 (36) 20.25.2 al",'.;r.i;,-.• ,..• (36) 20.25x2 '. ,:}:{:V1.4'4ri r (36) 20.25.2 ,.. `'�� (Number) 8124 (In.) FILTER SECTION 53.3 68.6 66.6 833 100.0, 125.0 125.0 125.0 Filter Area (Sq.Ft ) 12 10 10 8 8 8 6 8 1.0 a Med Pees Structural Frame BLOWER SECTION 12 10 10 10 10 10 10 10 HI Press 14 14 14 14 14 14 14 14 is & Med Prep [Recharge Panel 16 16 +N+ S:?ti{'.Yti•••644 14 14 14 14 14 H1 Prep 18. 16 18.16 18, 18 14 14 14 14 14 1.0 a Med Pees Removable Panels 18 1B .45V;;`):; ,T;iii 18 16 16 16 _•it :Ub. t',;¢4 N1 Press 12, 14 12, 14 12, 14 10 10 10 10 10 • All Structural Frame DRAW. THRU COIL SECTION 14 14 14 18 18 18 18 18 All Bottom Panel 16 16 16 14 14 14 14 14 Horizontal Drain Pen 14 14 14 14 14 14 ''.'.7.0'. : ?ZirliV 5i;'h:; Wn1ca) 18 18 18 18 18 16 16 18 A11 Removable Penile Table 17. Draw- through Air Handier Physical Data (Continued) U NOTES: 'Extra large lace area not available In LHD units and auxiliary heating coil sections. "MSL•108 & 111 only. t Low pressure units only. Refer to air handier Sales & Engineering Dale Sheet 1009 for high static fan wheels In unit sizes 103 & 104. NOT AVAILABLE MEDIUM PRESSURE Catalog 500 / Page 35 MS-85(R) CUSTOMER NAME P C UENCE NUMBER: 5 14390. 62.0 180.0 MS-85(R) TWO ROW ALT. SELECTION WB0602B 2807.71. vzilS AND ROWS SPECIFIED 10 4W 110114 376219. JOB NAME REP NAME & CITY EEIP PHASE 3-E HEATING COIL SELECTIONS B.E. & C. 472 79.0 472 STANDARD FIN AND STANDARD TUBE. # SPECIFIED WPD EXCEEDED JOB ITEM: HC2E16A 9.3 119.4 NORBY INPUT DATA <---- AIR HANDLER ----> < COIL DIMENSIONS > MAX FV AHU SECTION QTY TYPE FH FL <---SPECIFIED---> FA FPM SIZE SIZE IN IN FIN ROW SERP FTA2 128 XL 1 W 39.0 112.5 6 1 B 30.47 <--- ENTERING CONDITIONS ---> <-- LEAVING CONDITIONS --> <---- MISC ----> A-FLOW EDB EWT FLOW LDB LWT TOTAL ALT GLY WPD ACFM F F GPM F F BTUH FT % FT 80.0 140.0 185200.0 57. 1. OUTPUT DATA ARI CERTIFIED SEL COIL MODEL CAPACITY FV LDB W-FLOW LWT WV WPD APD CONN • BTUH FPM F GPM F FPS F-H20 I-H20 NPT MOST ECONOMICAL SELECTION 403 5WB0601G 212161. 472 75.5 9.3 134.2 1.5 .07 1.5 ONE ROW ALT. SELECTION I • • - SnyderGeneral Systems VERSION = 3.40 .10 2.50 " • • 111 e • SALESMAN JIM PECK RUN: 12/16/91 MS -85(R) OUTPUT DATA ARI CERTIFIED VERSION = 3.40 SEL COIL MODEL TOTAL SENSIBLE FV LDB LWB W -FLOW LWT WV WPD APD CONN BTUH BTUH FPM F F GPM F FPS F- H2O.I -H20 NPT MOST ECONOMICAL MS - 85(R)_ COOLING COIL SELECTIONS SnyderGeneral Systems B.E. & ifITOMER NAME JOB NAME REP NAME & CITY SALESMAN EEIP PHASE 3 -E NORBY JIM PECK SEQUENCE NUMBER: 6 JOB ITEM: CC2E16A RUN: 12/16/91 < -- AIR HANDLER - -> < COIL DIMENSIONS > < - - -- MISC - - - -> MX FV AHU SECT # TYPE FH FL <- SPECIFIED -> FA GLY WPD ALTI FPM SIZE SIZE IN IN FIN ROW SRP FTA2 % FT FT 128 XL 1 W 39.0 112.5 12 8 M 30.47 0 10.0 0 < ENTERING CONDITIONS > < LEAVING CONDITIONS > A -FLOW EDB EWB EWT FLOW LDB LWB TOTAL SENSIBLE LWT ACFM F F F GPM F F BTUH BTUH F 14390. 78.0 62.5 42.0 - 576500. 468500. 55.0 +•�►3 5WM1208B 579091. 470395. 472 48.1 47.9 88. FINS AND ROWS SPEC 5.6': .88 2.50 • -5-90044-24441- 6 5WM1208B 579091. 470395. 472 48.1 ADDITIONAL ROWS 7 5WM1008C 586267. 473667. 472 47.9 47.7 88.7 55.2 2.4 5.6 1.16 2.50 * 8 4WD1010H 588789. 474820. 472 47.8 47.6 88.7 55.3 2.9 7.6 1.03 2.5! 9 5WM0910B 588650. 474756. 472 47.8 47.6 88.7 55.3 2.4 6.4 .85 2.50 ITIONAL ROWS ,10 5WM0710C 585424. 473282. 472 47.9 47.7 88.7 55.2 2.4 6.4 1.11 2.50 11 4WD0712H 578953. 470332. 472 48.1 47.9 88.7 55.1 2.9 8.6 .95 2.50 12 5WM0712B 593462. 476961. 472 47.7 47.5 88.7 55.4 2.4 7.2 .89 2.50 ALT. SEL. WPD ABOVE SPEC 13 5WL1106C 580109. 470859. 472 48.1 47.9 88.7 55.1 4.9 18.2 .93 2.50 14 4WM1208H 583164. 472251. 472 48.0 47.8 88.7 55.2 3.8 11.6 .94 2.50 &15 5WS1008B 576500. 468479. 472 48.2 48.0 88.7 55.0 3.7 12.1 .75 2.50 ALT. SEL. W -FLOW ABOVE SPEC 16 5WS1006C 586920. 473966. 472 47.9 47.7 115.3 52.2 4.8 15.7# .91 2.50 17 4WD1008H 579011. 470359. 472 48.1 47.9 115.3 52.0 3.7 10.6# .82 2.50 18 5WM0908B 579379. 468645. 472 48.2 47.9 115.3 52.0 3.2 9.1 .73 2.50 ALT. SEL. LOAD BELOW SPEC 19 5WS1206C 576500. 469217. 472 48.2 48.0 88.7 55.0 3.7 9.8 .99 2.50 &20 5WM1108B 568755. 465705. 472 48.4 48.2 88.7 54.8 2.4 5.6 .82 2.50 47.9 88.7 55.1 2.4 5.6 .88 2.50 MS-qi5 (R) (STOMER NAME SEQUENCE NUMBER: 7 < - - -- AIR HANDLER - - - -> MAX FV AHU SECTION FPM SIZE SIZE 13455. 62.0 180.0 MS -85 (R) MOST ECONOMICAL SELECTION HEATING COIL SELECTIONS B.E. & C. JOB NAME REP NAME & CITY EEIP PHASE 3 -E NORBY JOB ITEM: INPUT DATA QTY TYPE FH COIL DIMENSIONS SnyderGeneral Systems FL <--- SPECIFIED - - -> OUTPUT DATA ARI CERTIFIED VERSION = 3.40 SEL COIL MODEL CAPACITY FV LDB W -FLOW LWT WV WPD APD CONN BTUH .FPM F GPM F FPS F -H20 I -H20 NPT -*3 5WB0601G 210939. 441 76.4 9.6 135.9 1.6 .7 .06 1.50.04- SALESMAN JIM PECK RUN: 12/16/91 IN IN FIN ROW SERP FT"2 128 XL 1 W 39.0 112.5 6 1 B 30.47 < - -- ENTERING CONDITIONS - - -> < -- LEAVING CONDITIONS - -> < - - -- MISC - -- -> A -FLOW EDB EWT FLOW LDB LWT TOTAL ALT GLY WPD ACFM F F GPM F F BTUH FT % FT 80.0 140.0 191300.0 57. 1. MS -85(R) CUSTOMER NAME IC- lUENCE NUMBER: 8 AIR HANDLER - -> MX FV AHU SECT FPM SIZE SIZE A -FLOW ACFM 13455. 128 XL ENTERING CONDITIONS EDB EWB EFT 78.3 62.5 42.0 COOLING COIL SELECTIONS B.E. & C. JOB NAME EEIP PHASE 3 -E < JO COIL E DI # TYPE F'H FL IN IN 1 W 39.0 112.5 FLOW GPM 5WM1208B 546679. 445718. 442 47.9 FINS AND ROWS SPEC 671'l8. 45550 . > < LDB SALESMAN JIM PECK RUN: 12/16/91 > < - - -- MISC - - -> <- SPECIFIED -> FA GLY WPD ALTI FIN ROW SRP FTA2 % FT FT 12 8 S 30.47 0 10.0 MS -85(R) OUTPUT DATA ARI CERTIFIED VERSION = 3.40 SEL COIL MODEL TOTAL SENSIBLE FV LDB LWB W -FLOW LWT WV WPD APD CONN BTUH BTUH FPM F F GPM F FPS F -H20 I -H20 NPT MOST ECONOMICAL 47.7 6 . 2 - 821 4-7. 0 8 2 . REP NAME & CITY NORBY SnyderGeneral Systems LEAVING CONDITIONS 82.9 55.2 57 LWB BU BTUH SENSIBLE LWT 539000. 443900. 55.0 2.3 5.0 .79 2.50.4- DUCT SYSTEM INPUT DATA FOR DUCT DESIGN SYSTEM 2942 5 2e- . r /Fr I4 t2.r4, // 4.3o . btz3 1/ - )2c• ''' 8 ' b:Z C l / 4,6 v o *Ltz // : 3o - .,. . -- 8,. .134 Z4 )8?o il'.:.. /Z D tz / 7 Zr /rx661Rf• 8 ,. .614A z4 I o 8 v 1-7 r; /Z ' Dld.g 1/ 630 s'' . 17144 2.4 1 (' 2 ..17--- --- INx: / ,z ' � 17cs.b Z4 I SR, o ::!! / b lac:: a 15-0C? ;.,.: ., D(Sli / 480 6, (b is-i3, 24 .I Sv o G ; .. 11 ., . ply 24 J So o nG f - 4 - :: I Z ,, /43 ?o BE&C ENGINEERS P.O. Box 3707 Seattle, Washington 98124.2207 'Mall Stop: 4r- , PROJECT /.. , e 1 Ili S1' s 4 at - I 0 FIG. BY 4 ' K • CHECKED BY DATE 1 / 2. - q8 T v c i S'J S ,; ,,.- /V/7 24 7 4 /(1. !) 6 c i c•--'s / <. /t/ - D I Zc �' %/ 4th X ivi/G 4 u 43o t `T, 2#4v#14L /i �. Iz1 G3o - ❑ f Dtz3 - 72..0 • D(zL • 480 ❑ - -- /6 /: ) ___A7 b 1 3t3 - Z� .18 i2 D r z'' ,A l._J 2 � 3 `. 5 0/ , / 2, r< /4 — 146 . tsoo Ad e. C /64 ( S '26 4- '\ JOB NO SHEET. OF * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network e TRUNK DUCT DATA TRUNK UPSTRM CFM DUCT DUCT MAX # # TRNK DIAM LNGTH SPACE CNSTR ELBOWS 1 -1 14850. 32. 60. 0. 0 0 1 2 4 494. 10. 10. 0. 0 1 0 3 4 1530.. 14. 10. 0. 0 1 0 4 1 2025. 16. 6. 0. 0 0 0 5 1 12826. 30. 12. 0. 0 0 0 6 5 11307. 28. 14. 0. 0 0 0 7 6 10164. 28. 5. 0. 0 0 0 8 7 9522. 26. 5. 0. 0 0 0 9 11 1109. 14. 10. 0. 0 0 0 10 11 1536. 14. 10. 0. 0 0 0 11 8 % 9522. 26. 6. ' 0. 0 2 0 12 11 6877. 24. 6. 0. 0 0 .0 13 12 5348. 22. 18. 0. 0 0 0 14 16 1996. 16. 1 10. 0. 0 1 0 15 16 771. 12.. 10. 0. 0 1 0 16 13 2767. 18. 60. 0. 0 1 0 17 13 2581. 18. 40. 0. 0 1 0 18 17 2079. 16. 4. 0. 0 0 0 19 18 1327. 14. 4. 0. 0 0 0 20 19 666. 12.' 8. 0. 0 0 1 FITTING FIRE STATIC INS DIVEI DAMP (ALT) SITY REDUCER Y FTG 1 Y FTG 2 45 90 T REDUCER REDUCER COUPLING REDUCER 45 90 T 45 90 T COUPLING REDUCER REDUCER Y FTG 1 Y. FTG 2 Y FTG 1 Y FTG 2 REDUCER REDUCER REDUCER 1.00 1.08 1.00 1.04 .94 1 .93 . 90 . ▪ 96 .90 . 97 . 92 97 1. 00 .1.03 I NO I NO I NO I NO I NO I NO I NO I NO I NO I NO I NO I NO I NO I NO I . NO * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** .s' r exclusive use by: Trane Customer Direct Service Network RUN -OUT DATA DUCT UNIT UNIT ELEC COIL DESIRED NC DIAM LNGTH FITTING ORIF SP tt CFM SPEC KW STGS NC ACTUAL DIAM ALT 2 494. VCCDE1100 .00 35 21 8. 2. 45 T .00 .95 3 1530. VCCDE2400 .00 35. 24 12. 2. 45 T .00 .81 5 1519. VCCDE2400 .00 35 25 12. 2. 45 T .00 1.01 6 1143. VCCDE2400 .00 35 22 12. .2. 45 T .00 1.03 7 641. VCCDE1100 .00 35 24 8. 2. 45 T .00 1.01 9 1109. VCCDE2400 .00 35 20 12. 2. 45 T .00 .81 10 1.536. VCCDE2400 .00 35 24 12. 2. 45 T .00 .70 12 1529. VCCDE2400 .00 35 24 12. 2. 45 T .00 .91 14 1996. VCCDE2400 .00 .35 27 12. 2. A5 T. .00 .48 15 771. VCCDE1100 .00 35 27 8. 2. 45 T .00 .60 17 501. VCCDE1100 .00 35 21 ' 8. 2..45 T .00 .93 18 752. VCCDE1100 .00 35 26 .8. ' 2. 45 T .00 .71 19 660. VCCDE1100 .00 35 25. 8. 2. 45 T .00 .78 20 ' 666. VCCDE1100 .00 35 25 8. 2. 45 T .00 ..76 * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network VARITRANE DUCT DESIGN PROGRAM PROGRAM VERSION: 8.04 EEIP - PHASE 3E. (9 -101 BLDG.) DC - SEATTLE BMC AL KILLIP 2 \12 \92 FRUN FOR AH2E16A RUN DATE: 02/12/92 * * * * * * * * ** CUSTOMER SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network PROGRAM INPUT GENERAL SPECIFICATIONS OF THE SYSTEM ALL STATICS AND CFMs SHOULD BE INPUT AT ALTITUDE AIR TOTAL APPROX EST SP MAX FAN DISCHARGE DENSITY CFM DESIGN LOSS SP FAN VEL .075 14390. 4.75 3.75 4.80 1646. FAN DESIGN MAX NC CEILING FAN FITTINGS DESIRED TYPE METHOD LEVEL EFFECT(DB) EFF% NOT USED VELOCITY DRAW THRU MAX. H.P. 35 10 80. NO LIMIT M CALCULATE INSULATE MAX % RATIOED FIXED RUNOUT DUCT HEAT ALL SUP AIR DOWNSTREAM DOWNSTREAM PRESSURE PICK UP DUCTS INCREASE STATIC PRES. STATIC PRES. BALANCE YES YES 0. .50 .00 .70 • * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network el TRNK UP LENG NO. TKOFF DIVER MAX # CON FIRE SP VEL OUT TEMP INS LIM # STRM ELBOW90ANGLE SITY ASPC STRICT DAMP LOSS DUCT RATIO DUCTS FIT TRNK 45 1 -1. 60. 0 1 0 NO 0. 0 .00 50. 1.10 I 0 2 4. 10. 0 0 90 NO 0. 0 .00 50. 1.10 I 0 3 4. 10. 0 0 90 NO 0. 0 .00 50. 1.10 I 0 .00 50. 1.10 I 0 . 00 50. 1.10 I 0 . 00 50. 1.10 I 0 .00 50. 1.10 I 0 . 00 50. 1.10 I 0 .00 50. 1.10 I 0 . 00 50. 1.10 I 0 . 00 50. 1.10 I 0 . 00 50. 1.10 I 0 . 00 50. 1.10 1 0 . 00 50. 1.10 I 0 . 00 50. 1.10 I 0 . 00 50. 1.1Q- I 0 .00 50. 1.10 I 0 . 00 50. 1.10 1 0 . 00 50. 1.10 I 0 . 00 50. 1.10 I 0 PROGRAM INPUT TRUNK DUCT DATA 4 1. 6. 0 0 90 NO 0. 0 5 1. 12. 0 0 0 NO 0. 0 6 5. 14. 0 0 0 NO 0. 0 7 6. 5. 0 0 0 NO 0. 0 8 7. 5. 0 0 0 NO 0. 0 9 11. 10. 0 0 90 NO 0. 0 10 11. 10. 0 0 90 NO 0. 0 11 8. 6. 0 0 90 YES 0. 0 12 11. 6. 0 0 0 YES 0. 0 13 12. 18. 0 0 0 NO 0. 0 14 16. 10. 0 0 90 NO 0. 0 15 16. 10. 0 0 90 NO 0. 0 16 13. 60. 0 0 90 NO 0. 0 17 13. 40. 0 0 0 NO O. 0 18 17. 4. 0 0 0 NO 0. 0 19 18. 4. 0 0 0 NO 0. 0 20 19. 8. 0 1 0 NO 0. 0 20 TRUNKS SPECIFIED FOR THIS SYSTEM * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network PROGRAM INPUT r RUN -OUT DATA DUCT CONN TAG UNIT UNIT RUN -OUT FITTING UNIT .DESIRED ROOM -NC ADDTL NUMBER CFM TYPE LENGTH TYPE (SIZE) ROOM NC CORRECT SP LOSS 2 D15A 480. VCCDE 2. 0 1100 35 0 .00 3 D15C 1500. VCCDE 2. 0 2400 35 0 .00 5 D15B 1500. VCCDE 2. 0 2400 35 0 .00 6 D14C 1125. VCCDE 2. 0 2400 35 0 .00 7 D14B 630. VCCDE 2. 0 1100 35 0 .00 9 D14A 1080. VCCDE 2. 0 2400 35 0 .00 10 D14E 1500. VCCDE 2. 0 2400 35 0 .00 12 D14D 1500. VCCDE 2. 0 2400 35 0 .00 14 D13A 1890. VCCDE 2. 0 2400 35 0 .00 15 D13B 725. VCCDE 2. 0 1100 35 0 .00 17 D12C 480. VCCDE 2. 0 1100 35 0 .00 18 D12B 720. VCCDE 2. 0 1100 35 0 .00 19 D12A 630. VCCDE 2.. 0 1100 35 0 .00 20 D12C 630. VCCDE 2. 0 1100 35 0 .00 14 RUN -OUTS SPECIFIED FOR THIS SYSTEM * * * * * * * ** *CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network ERROR AND DIAGNOSTIC MESSAGES * UNIT STATIC PRESSURE REQUIREMENT AND SOUND POWER PERFORMANCE BASED ON AUGUST 1987 CATALOG. * NOTE: THE ROOM NC OUTPUT IS VALID ONLY IF THREE PARAMETERS ARE MET. 1) THE ACTUAL SOUND POWER LEVEL OF THE FAN IN THE THIRD OCTAVE BAND IS-AT LEAST AS LOW AS THE LEVEL OUTPUT. 2 A 90 DEGREE ELBOW IS INCLUDED IN MAIN TRUNK BETWEEN FAN AND FIRST RUNOUT. 3) NON -METAL FLEX DUCT IS USED BETWEEN THE VARITRANE UNIT AND THE DIFFUSER. IF VFCD VFWD OR VFED UNITS WERE USED, THE SOUND OUTPUT IS FOR THE PRIMARY SIDE ONLY *TRUNK AND RUNOUT DUCT STATIC PRESSURES ARE ADJUSTED FOR ALTITUDE. UNIT SPECIFICATION TABLE HAS SEA LEVEL STATIC AND ALTITUDE STATIC IF BELOW .072 AIR DENSITY. * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer - Direct Service Network ir OPTIMIZED AIR DISTRIBUTION SYSTEM BLOCK CFM FROM THE FAN ((INCLUDES DUCT HEAT PICKUP) FAN TOTAL STATIC PRESSURE(IN) ) AT SEA LEVEL EL LEVEL 5.72 AT ALTITUDE... EQUIPMENT H D TAVEBAND REQUIRED IN FAN SOUND ABSORBER........ BASED ON ASSUMED FAN THIRD OCTAVE BAND SOUND POWER LEVEL OF.......... TOTAL PEAK CFM AS INPUT 14391. AFTER DUCT HEAT PICKUP... DIVERSITY OF THE SYSTEM 100% 14850. 5.22 3.75 6 DB 96 DB 14850. * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network "�'� TRUNK DUCT DATA TRUNK UPSTRM CFM DUCT DUCT MAX # # FITTING FIRE STATIC INS DIVER # TRNK DIAM LNGTH SPACE CNSTR ELBOWS DAMP (ALT) SITY 45 90 1 -1 14850. 32. 60. 0. 0 0 1 REDUCER 1.00 I NO 2 4 494. 10. 10. 0. 0 1 0 Y FTG .1 1.08 I NO 3 4 1530. 14. 10. 0. 0 1 0 Y FTG 2 1.00 I NO 4 1 2025. 16. 6. 0. 0 0 0 45 90 T 1.04 I NO 5 1 12826. 30. 12. 0. 0 0 0 REDUCER .98 I NO 6 5 11307. 28. 14. 0. 0 0 0 REDUCER .94 I NO 7 6 10164. 28. 5. 0. 0 0 0 COUPLING 1.01 I NO 8. 7 9522. 26. 5. 0. 0 0 0 REDUCER .93 I NO 9 11 1109. 14. 10. 0. 0 0 0 45 90 T .90 I NO 10 11 153G. 14.- 10. 0. 0 0 0 45 90 T .89 I NO 11 8 9522. 26. 6. 0. 0 2 0 COUPLING .86 I NO 12 11 6877. 24. 6. 0. 0 0 0 REDUCER .96 I NO 13 12 5348. 22. 18. 0. 0 0 0 REDUCER .96 I NO 14 16 1996. 1G. 10. 0. 0 1 0 Y FTG 1 .90 I NO 15 16 771. 12. 10. 0. 0 1 0 Y FTG 2 ,.97 I NO 16 13 2767. 18. 60. 0. 0 1 0 Y FTG 1 .92 I NO 17 13 2581. 18. 40. 0. 0 1 0 Y FTG 2 .98 I NO 18. 17 2079. 16. 4. 0. 0 0 0 REDUCER .97._ I NO 19 18 1327. 14. 4. 0. 0 0 0 REDUCER 1•x00 I NO 20 19 666. 12. 8. 0. 0 0 1 REDUCER 1.03 I NO * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network RUN -OUT DATA DUCT UNIT UNIT ELEC COIL DESIRED NC DIAM LNGTH FITTING ORIF SP it CFM SPEC KW STGS NC ACTUAL DIAM ALT 2 494. VCCDE1100 .00 35 21 8. 2. 45 T .00 .95 3 1530. VCCDE2400 .00 35 24 12. 2. 45 T .00 .81 5 1519. VCCDE2400 .00 35 25 12. 2. 45 T .00 1.01 6 1143. VCCDE2400 .00 35 22 12. 2. 45 T .00 1.03 7 641. VCCDE1100 .00 35 24 8. 2. 45 T .00 1.01 9 1109. VCCDE2400 .00 35 20 12. 2. 45 T .00 .81 10 1536. VCCDE2400 .00 35 24 12. 2. 45 T .00 .70 12 1529. VCCDE2400 .00 35 24 12. 2. 45 T .00 .91 14 1996. VCCDE2400 .00 35 27 12. 2. 45 T .00 .48 15 771. VCCDE1100 .00 35 27 8. 2. 45 T .00 .60 17 501. VCCDE1100 .00 35 21. 8. 2. 45 T .00 .93 18 752. VCCDE1100 .00 35 26 8. 2. 45 T .00 .71 19 660. VCCDE1100 .00 35 25 8. 2. 45 T .00 .78 20 666. VCCDE1100 .00 35 25 8. 2. 45 T .00 .76 • * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network STATIC PRESSURE ANALYSIS OF RUNOUTS C RUNOUT TRUNK RUNOUT RUNOUT RUNOUT RUNOUT STATIC ORIFICE DIST. SP SP REQUIRED UNIT DWNSTM OVER DIA FROM AVAILABLE SP SP SP PRESSURE FAN 2 1.08 .95 .35 .03 .32 .60 .00 76. 3 1.00 .81 .35 .07 .28 .46 .00 76. 5 .98 1.01 .35 .0G .29 .66 .00 72. 6. .94 1.03 .35 .04 .31 .68 .00 86. 7 1.01 1.01 .35 .05 .30 .66 .00 91. 9 .90 .81 .35 .03 .32 .46 .00 112. 10 .89 . .70 .35 .07 .28 .35 .00 112. 12 .96 .91 .35 .06 .29 .56 .00 108. 14 .90 .48 .46 .11 .35 .02 .00 196. 15 97 .60 .35 .07 •.28 .25 .00 196. 17 .98 .93 .35 .03 .32 .58 .00 166. 18 .97 .71 .35 .07 .28 .36 .00 170. 19 1.00 .78 .35 .05 .30 .43 .00 174. 20 1.03 .76 .35 .05 .30 .41 .00 ,182. NOTE: ORIFICE INTERVAL CAUSED STARRED OVER PRESSURES TO BE GREATER THAN STATIC PRESSURE BALANCE TOTAL PRESSURES AT SEA LEVEL WITHIN TRUNK DUCTS TRNK #. TP TRNK # TP TRNK "# TP TRNK # TP TRNK # TP 1 1. 2 1. 3 1. 4 1. 5 1. 6 1. 7 1. 8 1. 9 1. 10 • 1. 11 1. 12 1. 13 . 1. 14 1. 15 1. 16 1. 17 • 1. 18 1. 19 1. 20 • 1.. * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** c For exclusive use by: ROUND DUCT LENGTH SURF AREA THICKNESS DIAM (IN) FT SQ FEET GAUGE 10 10.0 26.2 26 12 18.0 56.5 26 14 34.0 124.6 26 16 20.0 83.8 24 18 100.0 471.2 24 22 18.0 103.7 24 24 6.0 37.7 24 26 11.0 74.9 24 28 19.0 139.3 22 30 12.0 94.2 22 32 60.0 502.7- 22 TOTALS 308.0 1714.8 NOTE -THE DUCT WEIGHT IN LBS DOES NOT INCLUDE A WASTE FACTOR. GAUGE THICKNESS BASED ON SMACNA RECOMMENDATIONS CHECK PROGRAM PREFAB DUCT LBS /LINEAR FT AGAINST ACTUAL PREFAB DUCT WEIGHT. FEET OF INSULATED TRUNK DUCTS 308.0 Trane Customer Direct Service Network TRUNK DUCT MATERIAL SUMMARY GALVANIZED STD GAUGE DUCT STEEL LBS LBS /LINEAR FT 23.7 2.55 51.2 3.04 112.9 3.50 96.8 5.10 544.8 5.73 119.8 7.00 43.6 8.42 195.8 11.07 132.5 11.86 706.7 12.65 2114.5 QUANTITY OF INSULATION ON TRUNK DUCTS 1795.4 SQ FEET UPSTREAM TRNK DIAM 10 12 14 16 18 26 28 32 TOTALS TRUNK CONNECTION MATERIAL SUMMARY 90 DEGREE ELBOWS 0 1 0 0 0 0 0 1 45 DEGREE FIRE ELBOWS DAMPS 1 0 1 0 1 0 1 0 2 0 2 0 0 0 0 0 COUPLERS 0 0 0 0 0 1 1. 0 PREFAB WT DUCT LBS 25.50 54.72 119.00 102.00 573.00 126.00 46.62 92.62 210.33 142.32 759.00 2251.11 * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network. TRUNK TRANSITION MATERIAL SUMMARY ..REDUCER.... ..45 DEGREE.. ..45 -90 DEGREE.. ..Y FITTING.... UPSTRM # DWNSTRM # DWNSTRM # DWNSTRM #� DWNSTRM DWNSTRM DIAM DIAM DIAM DIAM DIAM 1 DIAM 2 24 22 18. 16 14 FAN 1 32 32 1 30 30 1 28 28.. .1 26 26 1 24 1 22 0 0 1 , 16 1 14 1 • 12 TOTALS 8 REDUCERS` O 0. 1 16 0 0. 0 O 0 0 0 0 0 0 O 0 0 0 0 0 0 O 0 2 14 0 0 0 O 0 0 0 0 0 0, O 0 0 0 1 18 18 O 0. 0 0 1 16 12 O 0 0 0 ' 1 10 . . .14 p p 0 0 0 '0 0 0 45 DEGREE 3 45-90'T 3 Y.- FITTINGS ********** CUSTOMER DIRECT SERVICE NETWORK ********** For exclusive use by: Trane Customer Direct Service Network CONICAL CROSS TRUNK TRANSITIONS UPSTRMHTRNK FIRST TAKE-OFF SECOND TAKEOFF STRAIGHT THRU DUCT TRNK W DIA TRNK # ANGLE DIAM TRNK # ANGLE DIAM TRNK W DIAM 11 26. 9 .45790 14. 10 45-90 14. 12 24. • * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network RUNOUT DIAMETER TOTALS 12 FLEX DUCT FEET 14 14 RUNOUT MATERIAL SUMMARY 90 DEGREE C 90 DEGREE 45 DEGREE TAKEOFFS TAKEOFFS TAKEOFFS 0 0 7 7 0 0 28. 0. 0. 14. VARITRANE UNIT MATERIAL SUMMARY 600 1100 1700. `.2400 3200 4200 0 7 O STRAIGHT OR REDUCER.. 0 0 * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** - For exclusive use by: Trane Customer Direct Service Network VARITRANE UNIT SCHEDULE DUCT UNIT TAG MODELS# UNIT IE DIAM(IN) CONTROL DESIGN MUNITUM PROJECTED D C PRESSURE LEVEL DROP (SEA LEVEL) 2 D15A VCCD 1100. 8. ELEC 494. .03 3 D15C VCCD 2400. 12. ELEC 1530. .07 5 D15B VCCD 2400. 12. ELEC 1519. .06 6 D14C VCCD 2400. 12. ELEC 1143. .04 7 D14B VCCD 1100. 8. ELEC 641. .05 9 D14A VCCD 2400. 12. ELEC 1109. .03 10 • D14E VCCD 2400. 12. ELEC 1536. .07 12 D14D VCCD 2400. 12. ELEC 1529. .06 14 D13A VCCD 2400. 12. ELEC 1996. .11 15 D13B VCCD 1100. 8. ELEC 771. .07 17 D12C. VCCD 1100. 8. ELEC 501. .03 18 D12B VCCD 1100. 8. ELEC 752. .07 19 D12A. VCCD 1100. 8. ELEC 660. .05 20 D12C VCCD 1100. 8. ELEC 666. .05 * ADJUSTED FOR DUCT HEAT PICKUP • 21. 24. 25. 22. 24. 20. 24. 24. 27. 27. 21. 26. 25. 25. / / q /-1.,4 G/7 'V6U 7 c/ G Sinv ( L .)A "'5''C c ' " t 1rGA it 7S"2) bit r3 /1 720 "b ! G c 24- /.foo (11C. l7 24 / 5 Lb 0 Q Z4 138o !7 IBC Z4- f500, 1b 17 b Z¢ 15 0 0 1711 l-: Z4- • ( I ZS" 1 igA 1 I 'no IL.18l /1 49a ; 1813 i 1 460 i r ia 4 2 .4 / 08 0 / 3 ¢s • ILIA log PROJECT L 71-7674 ( ) • 7 ix 3 L IU JOB NO p FIG. BY 4 • CHECKED BY DATE SHEET L OF /o r /2 r 0 1) 17A j7 '•6 - 1.7i3 S' s ys =1 4// D ICA - 7S0 b 16c. -- /.Soo 4112. - ri EE 48 o 4 \`' ( D 16b - isvo � 2 a /v � b J6� - ��� (z). ASoc?ts !Z' /o Z'O' BE &C ENGINEERS 4 G e 4 P.O. Box 3707 Seattle, Washington 98124.2207 Mail Stop: D ICA - 7ro ®- 4-- 4 - 16E - 720 .D T»1713- /33o BE&C ENGINEERS P.O. Box 3707 Seattle, Washington 98124.2207 Mail Stop: PROJECT 112.--6-1141 • 44 s — q- /0( FIG. BY /4-' /4" \ b 16 c / Oo r 1 G V , Q /4i r O " (7} d s °c zs /v 22 JOB NO CHECKED BY DATE S'vS //v,ei/ 474 Ave -b t ic...7 �. ---s -- s ys % I-1 /9/12 4 1)114- /Joo 60,4 , g 460 460 r7 ., 18 . /0( 6 /6„ /6' / ¢ 1 112-S /n42-4 12 /n42 -4 IGc bl)� bo t8 A C'Iv6 it 1 ( z4- 24 _ /1 // /1 i t -7.5S 7zo 1 .S'o / S`o - 22o 1360 / o o Z4 jSoo - 2Za 48o 480 z 4 /vao i t.. 18/4 L SHEET OF_ t /ft °licr S/ ? C-ro / 3 4-S //i/Gt =r` II /1) ■ �. v,f �� • � ( -1.1 - * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network VARITRANE DUCT DESIGN PROGRAM PROGRAM VERSION: 8.04 RUN DATE: 02/20/92 EEIP - PHASE 3E (9 -101 BLDG.) DC - SEATTLE BMC AL KILLIP 2 \12 \92 RUN FOR AH2E17A1 * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network PROGRAM INPUT GENERAL SPECIFICATIONS OF THE SYSTEM ALL STATICS AND CFMs SHOULD BE INPUT AT ALTITUDE AIR TOTAL APPROX EST SP MAX FAN DISCHARGE DENSITY CFM DESIGN LOSS SP FAN VEL .075 13455. 4.75 3.75 4.80 1646. FAN DESIGN MAX NC CEILING FAN FITTINGS DESIRED TYPE METHOD LEVEL EFFECT(DB) EFF% NOT USED VELOCITY DRAW THRU MAX. H.P. 35 10 80. NO LIMIT M CALCULATE INSULATE MAX % RATIOED FIXED RUNOUT DUCT HEAT ALL SUP AIR DOWNSTREAM DOWNSTREAM PRESSURE PICK UP DUCTS INCREASE STATIC PRES. STATIC PRES. BALANCE YES YES 0. .50 .00 .70 * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network c PROGRAM INPUT TRUNK DUCT DATA TRNK UP LENG NO. TKOFF DIVER MAX .# CON FIRE SP VEL OUT TEMP INS LIM # STRM ELBOW ANGLE SITY SPC STRICT DAMP LOSS DUCT RATIO DUCTS FIT TRNK 45 90 AVIL 1 -1. 18. 0 0 0 NO 0. 0 .00 50. 1.10 I 0 2 1. 30. 2 1 0 NO 0. 0 .00 50. 1.10 I 0 3 2. 4. 0 0 0 NO 0. 0 .00 50. 1.10 I 0 4 3. 6. 0 0 0 NO 0. 0 .00 50. 1.10 I 0 5 4. 10. 0 0 90 NO 0. 0 .00 50. 1.10 1 0 6 4. 12. 0 0 90 NO 0. 0 .00 50. 1.10 I 0 7 1. 30. 0 1 90 NO 0. 0 .00 50. 1.10 I 0 8 7. 12. 0 0 90 NO 0. 0 .00 50. 1.10 I 0 9 8. 18. 0 1 0 NO 0. 0 .00 50. 1.10 I 0 10 9. 5. 0 0 0 NO 0. 0 .00 50. 1.10 I 0 11 10. 8. 0 0 90 YES 0. 0 .00 50. 1.10 I 0 12 10. 10. 0 0 90 YES 0. 0 .00 50. 1.10 I 0 13 10. 5. 0 0 0 NO 0. 0 .00 50. 1.10 I 0 14 13. 5. 0 0 90 NO 0. 0 .00 50. 1.10 I 0 15 13. 10. 0 0 90 NO 0. 0 .00 50. 1.10 I 0 16 7. 16. 0 0 90 NO 0. 0 .00 50. 1.10__ I 0 17 16. 20. 0 0 0 NO 0. 0 .00 50. 1•:10 I 0 18 17. 8. 0 0 0 NO 0. 0 .00 50. 1.10 I 0 18 TRUNKS SPECIFIED FOR THIS SYSTEM * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network PROGRAM INPUT RUN -OUT DATA DUCT CONN . .TAG. UNIT UNIT RUN -OUT FITTING UNIT DESIRED C A R M NPD L SS L NUMBER CFM TYPE LENGTH TYPE 2 D16B 720. VCCDE 2. 0 1100 35 0 .00 3 D16D 1500. VCCDE 2. 0 2400 35 0 .00 5 D16A 750. VCCDE 2. 0 1100 35 0 .00 6 D16C 1500. VCCDE 2. 0 2400 35 0 .00 8 D18A 720. VCCDE 2. 0 1100 35 0 .00 9 D17E 1125. VCCDE 2. 0 2400 35 0 .00 11 D17B 1380. VCCDE 2. 0 2400 35 0 .00 12 D17D 1500. VCCDE 2. 0 2400 35 0 .00 14 D17A 720. VCCDE 2. 0 1100 35 0 .00 15 D17C 1500. VCCDE 2. 0 2400 35 0 .00 16 E18A 480. VCCDE 2. 0 1100 35 0 .00 17 E18B 480. VCCDE 2. 0 1100 35 0 .00 18 F18A 1080. VCCDE 2. 0 2400 35 0 .00 13 RUN -OUTS SPECIFIED FOR THIS SYSTEM * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network ERROR AND DIAGNOSTIC MESSAGES * UNIT STATIC PRESSURE REQUIREMENT AND SOUND POWER PERFORMANCE * NOTE: TH AUGUST TCUTPUT IS 9O CATALOG. THE ROOM NC VALID ONLY IF THREE PARAMETERS ARE MET. 1) THE ACTUAL SOUND POWER LEVEL OF THE FAN IN THE THIRD OCTAVE BAND IS AT LEAST AS LOW AS THE LEVEL OUTPUT. 2) A 90 DEGREE ELBOW IS INCLUDED IN MAIN TRUNK BETWEEN FAN AND FIRST RUNOUT. 3) NON -METAL FLEX DUCT IS USED BETWEEN THE VARITRANE UNIT AND THE DIFFUSER. *:IF VFCD VFWD OR VFED UNITS WERE USED, THE SOUND OUTPUT IS FOR THE PRIMARY SIDE ON±JY * TRUNK AND RUNOUT DUCT STATIC PRESSURES ARE ADJUSTED FOR ALTITUDE. UNIT SPECIFICATION TABLE HAS SEA LEVEL STATIC AND ALTITUDE STATIC IF BELOW .072 AIR DENSITY. * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network OPTIMIZED AIR DISTRIBUTION SYSTEM BLOCK CFM FROM THE FAN (INCLUDES DUCT HEAT PICKUP) FAN TOTAL STATIC PRESSURE AT SEA LEVEL 4.89 AT ALTITUDE.. . EQUIPMENT AVEBAN SP 7 FAN SOUNDABSO ABSORBER BASED ON ASSUMED FAN THIRD OCTAVE BAND SOUND POWER LEVEL OF TOTAL PEAK CFM AS INPUT 13456. AFTER DUCT HEAT PICKUP... DIVERSITY OF THE SYSTEM 100% 13783. 4.89 5�DB 96 DB 13783. * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network TRUNK DUCT DATA CRUNK UPSTRM CFM DUCT DUCT MAX # # FITTING FIRE STATIC INS DIVER # TRNK DIAM LNGTH SPACE CNSTR ELBOWS DAMP (ALT) SITY 45 1 -1 13783. 30. 18. 0. 0 0 0 REDUCER .75 I NO 2 1 4565. 20. 30. 0. 0 3 1 Y FTG 1 .73 I NO 3. 2 3834. 20. 4. 0. 0 0 0 COUPLING .80 I NO 4 3 2310. 16. 6. 0. 0 0 0 REDUCER .81 I NO 5 4 772. 12. 10. 0. 0 1 0 Y FTG 1 .87 I NO 6 4 1538. 14. 12. 0. 0 1 0 Y FTG 2 .79 I NO 7 1 9218. 26. 30. 0. 0 1 1 Y FTG 2 .64 I NO 8. 7 7110. 24. 12. 0. 0 1 0 Y FTG 1 .61 I NO 9 8 6379. 22. 18. 0. 0 0 1 REDUCER .47 I NO 10 9 5233. 22. 5. 0. 0 0 0 COUPLING .57 I NO 11 10 1414. 14. 8. 0. 0 0 0 45 90 T .57 I NO 12 10 1538. 14. 10. 0. 0 1 0 45 T .57 I NO 13 10 2282. 16. 5. 0. 0 0 0 REDUCER .63 I NO 14 13 740. 12. 5. 0. 0 1 0 Y FTG 1 .70 I NO 15 13 1541. 14. 10. 0. 0 1 0 Y FTG 2 .62 I NO 16 7 2107. 16. 16. 0. 0 1 0 Y FTG 2 .78 I . NO 17 16 1617. 16. 20. 0. 0 0 0 COUPLING .81 I NO 18 17 1121. 14. 8. 0. 0 0 0 REDUCER .81 I NO *. * * *. * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network RUN -OUT DATA CUCT UNIT UNIT ELEC COIL DESIRED NC DIAM LNGTH FITTING ORIF SP CFM SPEC KW STGS NC ACTUAL DIAM ALT 2 731. VCCDE1100 3 1523. VCCDE2400 5 772. VCCDE1100 6 1538. VCCDE2400 8 731. VCCDE1100 9 1146. VCCDE2400 11 1414. VCCDE2400 12 1538. VCCDE2400 14 740. VCCDE1100 15 1541. VCCDE2400 16 491. VCCDE1100 17 496. VCCDE1100 18 1121. VCCDE2400 . • 00 . 00 . 00 .00 . ▪ 00 .00 .00 . 00 35 2 24 35 27 35 24 35 22 35 23 35 24 35 24 35 21 35 21 35 21 8. 2. 45 T 12. 2. 45 T 8. 2. 45 T 12. 2. 45 T 12. 2. 45 5 T 12. 2. 45 T 12. 2. 45 T 8. 2. 45 T 12. 2. 45 T 8. 2. 45 T 8. 2. 45 T 12. 2. 45 T .r . ▪ 00 . 00 . 00 .00 . ▪ 00 .00 . 00 . 00 .68 . 50 . 60 .54 .41 .38 . ▪ 4 3 . 72 . 71 * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network e STATIC PRESSURE ANALYSIS OF RUNOUTS RUNOUT TRUNK RUNOUT RUNOUT RUNOUT RUNOUT STATIC ORIFICE DIST. SP SP REQUIRED UNIT DWNSTM OVER DIA FROM AVAILABLE SP SP SP PRESSURE FAN 2 .73 .62 .35 .06 .29 .27 .00 48. 3 .80 .68 .35 .06 .29 .33 .00 52. 5 .87 .50 .35 .07 .28 .15 .00 68. 6. .79 .60 .35 .07 .28 .25 .00 70. 8 .61 .53 .35 .06 .29 .18 .00 60. 9 .47 .54 .35 .04 .31 .19 .00 78. 11 .57 .41 .35 .06 .29 .06 .00 91. 12 .57 .38 .35 .07 .28 .03 .00 93. 14 .70 .36 .35 .06 .29 .01 .00 93. 15 .62 • .43 .35 .07 .28 .08 .00 98. 16 .78 .74 .35 .03 .32 .39 .00 64. 17 .81 .72 .35 .03 .32 .37 .00. 84. 18 .81 .71 .35 .03 .32 .36 .00 92. * NOTE: ORIFICE INTERVAL CAUSED STARRED OVER PRESSURES TO BE GREATER THAN STATIC PRESSURE BALANCE TOTAL PRESSURES AT SEA LEVEL WITHIN TRUNK DUCTS TRNK # TP TRNK # TP TRNK # TP TRNK # TP TRNK # TP 1 1. 2 • 1. 3 1. 4 1. 5 1. 6 1. 7 1. 8 1. 9 1. 10 1. 11 1. 12 1. 13 1. 14 1. 15 • 1. 16 1. 17 1. 18 1. * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK - * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network TRUNK DUCT MATERIAL SUMMARY ROUND DUCT DIA 16 22 24 26 30 UPSTREAM TRNK 14 16 20 22 24 26 LENGTH 15.0 48.0 47.0 34.0 23.0 12.0 30.0 18.0 TOTALS 227.0 SURF AREA SQ FEET 47.1 175.9 196.9 178.0 132.5 75.4 204.2 141.4 1151.4 NOTE -THE DUCT WEIGHT IN LBS DOES NOT INCLUDE A WASTE FACTOR. GAUGE THICKNESS BASED ON SMACNA RECOMMENDATIONS CHECK PROGRAM PREFAB DUCT LBS /LINEAR FT AGAINST ACTUAL PREFAB DUCT WEIGHT. FEET OF INSULATED TRUNK DUCTS 227.0 QUANTITY OF INSULATION ON TRUNK DUCTS TRUNK CONNECTION MATERIAL SUMMARY 90 DEGREE ELBOWS 0 0 1 1 0 1 45 DEGREE ELBOWS 2 3 1 3 0 1 1 TOTALS 3 11 THICKNESS GAUGE 26 26 24 24 24 24 24 22 FIRE DAMPS 0 0 0 0 0 GALVANIZED STEEL LBS 42.7 159.4 227.6 205.8 153.1 87.2 236.1 198.8 1310.6 1210.8 SQ FEET COUPLERS 0 0 1 1 1 0 0 0 0 0 3 STD GAUGE DUCT LBS /LINEAR FT 3.04 3.50 5.10 6.37 7.00 7.77 8.42 11.86 PREFAB WT DUCT LBS 45.60 168.00 239.70 216.58 161.00 93.24 252.60 213.48 1390.20 * * * * * * * ** *..CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network TRUNK TRANSITION MATERIAL SUMMARY ....REDUCER.... ..45 DEGREE.. UD # DW DIAM M # DIA FAN 1 30 30 ' 0 0 0 0 0 26 0 0 0 0 0 24 1 22 0 0 0 22 1 16 1 14 1 20 1 16 0. 0 0 16 1 14 0 0 0 16 0 0. 0 0 0 TOTALS 4 REDUCERS 1 45 DEGREE ..45 -90 DEGREE. # DWNSTRM 0 0 0 14 0 ' 0 0 1 45 -90 T 1 20 1 24 0 0 0 0 0 1 12 1 12' 26 16 0 0 0 14 14 4 Y- FITTINGS ...Y FITTING.... DWNSTRM DWNSTRM DIAM 1 DIAM 2 * * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * ** For exclusive use by: Trane Customer Direct Service Network CONICAL CROSS TRUNK TRANSITIONS UPSTRM TRNK FIRST TAKE -OFF SECOND TAKEOFF STRAIGHT THRU DUCT TRNK # DIA TRNK # ANGLE DIAM TRNK # ANGLE DIAM TRNK # DIAM 10 22. 11 45 -90 14. 12 45 14. 13 16. TOTALS. 26. 0. 0. * * * * * * * ** CUSTOMER DIRECT SERVICE NETWORK * * * * * * * * * * .,..: -T r .: ugtMni v..2 __.. ..�.dw.:.irLt «1. _,... s .. ..ti �.w «M f..; a�4:.: .xn:. i S a . • a: a± aL. For exclusive use by: Trane Customer Direct Service Network RUNOUT MATERIAL SUMMARY RUNOUT FLEX DUCT 90 DEGREE C 90 DEGREE 45 DEGREE STRAIGHT OR DIAMETE F ET TAKE TAKE TAKE REDUCER 12 14 0 0 7 0 13. 0. VARITRANE UNIT MATERIAL SUMMARY RATED CFM. 300 600 1100 1700 2400 3200 4200. TOTAL UNIT TYPE VCCDE 0 0 6 0 7 0 0 13 * * *_ * * * * * * *.. CUSTOMER DIRECT SERVICE NETWORK ********** For exclusive use by: Trane Customer Direct Service Network VARITRANE UNIT SCHEDULE DUCT UNIT TRANE UNIT INLET CONTROL DESIGN MAXIMUM PROJECTED CONN TAG MODEL # SIZE DIAM(IN) TYPE CFM* PRESSURE RONC LEVEL DROP (SEA LEVEL) 2 D16B VCCD 1100. 8. ELEC 731. .06 26. 3 D160 VCCD 2400. 12. ELEC 1523. .06 24. 5 D16A VCCD 1100. 8. ELEC 772. .07 27. 6 D16C VCCD 2400. 12. ELEC 1538. .07 24. 8 D18A VCCD 1100. 8. ELEC 731. .06 26. 9 D17E VCCD 2400. 12. ELEC 1146. .04 22. 11 D17B VCCD 2400. 12. ELEC 1414. .06 23. 12 D17D VCCD 2400. 12. ELEC 1538. .07 24. 14 D17A VCCD 1100. 8. ELEC 740. .06 26. 15 D17C VCCD 2400. 12. ELEC 1541. .07 24. 16 E18A VCCD 1100. 8. ELEC 491. .03 21. 17 E18B VCCD 1100. 8. ELEC 496. .03 21. 18 F18A VCCD 2400. 12. ELEC 1121. .03 21. * ADJUSTED FOR DUCT HEAT PICKUP �YL'JNW b.r..�r ; • 1.:.0 . �}..1. '. .. • 9Nk //� 1/ go?‹ N awl Si Z G"'S c 6 11 z 4 z¢ 32 Z G/VVV/LA icz C z 7 attwe) Applications Engineering Manual 3cr ) 3Z :in.iw:.c•'L,�.Iryl«...,_ •�..iLirt.�V.i(�.Sti;�.{.,.:.w v' v, vi+. ie) ta•: s7: lwhEJ '�t:.'!}'�«'s�N:'j"S..t_Y.L�::V �"' i' Ji�k' l�frai',.' µIr +r�:;�i�RiJ�ti:- !!.,.;•...�i. TRANE'~ •l L z� S yS , / f 4iC', y'/ , ' z i r- l s y S% Err► /r,A)‹ _� - Dow - / S'&"GG -? -v ,/ V�' ✓\ i CrXekr ..t'p? J- LA. /77.1 4“/ t ��L /�/ /K'_ .Sd�L .4 Af G Vf x.s L' f SG= (e/P a'? VL- S"'i ? J VariTrane Duct Design Input Manual (Version V3100) A/72.-0 ivA L . te ssc.; so A/U fI r1ii ,,ilc r � S . / 5 _ /47 A/ i 4'L6 / /Se// , z - D/A, r y t / cr -s (3 h C et-i/iv /4 -3..) / • ) J co ►C 5 (Coc•L /1/%"'4 / • l U • 3 -7 S -- .. i .Zv 1P.O0110- c.) , r' Gli���,ov.s cro 5 Z S DSN -AM -1 14861 AIR TEMPERATURE 55 F (12.8 C) ALTITUDE (FI.) AIR DENSITY (Ib1F1') AIR DENSITY (kg/m') 0 .078 1.22 1000 .075 1.20 2000 .072 1.15 3000 .069 1.11 4000 .066 1.06 5000 .063 1.01 6000 .061 .977 7000 .059 .945 8000 .057 .913 9000 .055 .801 10000 .053 .849 Completing The .Input Forms . Table 2 _ Air Density A3Approximate Design Static Pres- sure (Inches H2O or Pa) c A2.BIock Fan Cfm Input the total block Toad cfm (m /s), cor- rected for density. This air volume should not be corrected for heat pick -up in the duct system. The program will cal- culate this. Determine the estimated maximum actual total static pressure losses, cor- rected for air density, which occur when operating the system under various conditions. For example, when oper- ating on 100% fresh air, the total static pressure loss of a system may exceed anticipated Toss under mixed air conditions. This should be done carefullyto provide the optimum design. Input the sum of the actual static pres- sure losses, corrected for air density, for the following: a. Supply duct: Use total length of the longest duct (feet x .005" w.g.) (meters x 4.08 a NOTE: For very simple layouts, reduce the multiplier to .004" w.g. .440 (3.27 Pa). For complex systems, in- crease the multiplier to .006" w.g. ,6/00 (4.90 Pa). b. Terminal unit static pressure loss: Use 0.80" w.g. (199. Pa) for cooling only units and 1.10" w.g. (274. Pa) for reheat units. NOTE: This includes static pressure drop downstream from the unit. r.1 .. t'. 1.. '.ah' 4 I / 8 c. Supply air equipment losses, includ - .. r _ ing filters, coils, dampers, etc. - NOTE: Trane rooftop unit coil and casing pressure losses are already ac- counted for in the rooftop unit fan curve. \• ( d. Return air or fresh air losses, which- ever is greater, including ducts, shafts, coils, dampers, louvers, etc. Credit must be taken for static pres- sure rating of return air fan, if used. NOTE: When calculating static pres- sure losses for c. and d. above, use block load cfm + 10% because of cfm increase with heat pickup. A4.Estimated Static Pressure Loss Through Central Equipment and J' Return Ductwork Input the total actual static pressure lo- sses, corrected for air density, calcu- lated for items c. and d. under "Approxi- mate Design Static Pressure." If a return air fan is used, do not input return duct static pressure. This static pressure loss will generally be between 1" and 2 -1/2" w.g. (249 and 623 Pa) for a central system and from 0.4" to 0.8" w.g. (100 to 200 Pa) for a rti oftop -VAV system. A5.Maximum Desired Fan Static Pressure Add 10 %to the air volume used in "A2 ". This represents an estimate of the addi- tional air which will be required to offset temperature gain. Use this figure even if the actual may be more or less. Then, pick a fan based on this cfm and the actual static pressure corrected for den- sity from "A3'. above. Consider the air volume modulation, fan efficiency and outlet velocity desired. Normally this fan should be selected for 1000 to 4000 fpm (5 to 20.3 m /s) outlet velocity for a central system or800 -1300 fpm (4 -6.6 m/ s) for a Trane rooftop unit. If the fan selected will allow increased static pressure without change in con- struction or motor horsepower, input the maximum static pressure at this condition. This will allow the computer to reduce the duct size. The maximum desired static pressure "A5" should be between .3" (75) and .75" w.g. (187 Pa) • �r .� 1 TYPE OF • USER NC RANGE TYPE OF USER NC RANGE Private Homes 20.30 School Classroom 30.40 Conference Rooms 25.35 Restaurant 35.45 Pnvato Office 30-40 Retail Store 40.50 General Office Area 35.45 Kitchens (Com• morclal) 40.50 Computer Room 40-60 Gymnasium 35.45 Lecture Hall 30.35 Mlg. Area • Light 45.75 Church Sanctuary 20.30 Mlg. Area • Heavy 55.75 _ ;._.... •'X�riul'.�'l. :�..i- -..ma �•.- . •. .. ., .r.a.s alp i Y 1rRi�LT�i6I�YN� • H`�➢6" 'r+C � u`LI'd" . �4�{+I.... .... .. ... 4u1 L sLi greater than the approximate design Table 3 - Recommended NC Levels static pressure "A3 ". A6.Estimated Discharge Velocity (fpm or m /s) Input the discharge velocity from the fan selected in "A5 ". This value can range from 1,000 to 4,000 fpm (5 to 20 m /s) with approximately 3,000 fpm (15 m /s) as an average for a central system. Trane rooftop discharge velocity ranges from 800 to 1300 fpm (4 to 6.6 m /s). Cal- culate by dividing the air volume by the unit discharge area. A7.Type of Fan Input a zero (0) for draw -thru. Input a one (1) for blow -thru. The computer ac- counts for the different sound absorbing characteristics of the two systems. A8Design Method Input a one (1) for systems with one duct system per fan. The program will design a system within the maximum static pressure capabilities of the selected fan and motor. When different duct systems are com- bined on the same fan, or to a plenum at the discharge of the same fan, input a zero (0) for fixed static pressure. For ex- ample, a single duct constant volume and single duct variable volume system on a single fan. This requires that each of the trunk duct systems be designed so that they have the same static pres- sure at the fan. When this duct config- uration is used, a higher than input static pressure may result. A9.Maximum NC Level (Optional) Input the Maximum NC level allowable 5 feet from the outlets. Table 3 can be used to determine the allowable level for different applications based on ASHRAE recommendations. Input the maximum NC level desired in the major part of the building. This will be the design standard unless superseded by the specific requirement of a given space which is input on the runout forms. For example, in a large office building, much of the space is used for general offices and stenographic areas. Table 3 recommends NC 35-45. There- fore,. input NC 35. Corrections for non- 9 standard areas or other NC levels de- sired will be input with runout data. If this field is left blank, the program as- sumes an NC of 35. A10.No Duct Heat Gain (Optional) If duct heat gain calculations have al- ready been made, input a one (1) in Field A10. The duct design will then be based on no duct heat gain. The output will state "calculations based on no duct heat gain." NOTE: Columns Al2, A13, B12 and B13 need not be input when a one (1) is input in Field A10. A11.Desired Velocity (Optional) Leave blank, or input an "H" if a stan- dard high velocity (low pressure) duct design is desired. Figure 7 shows the typical duct size for a given air volume. High velocity designs (Le., duct veloci- ties of 3000 -6000 fpm, 15 -30 m /s) are rec- ommended because higher velocities give higher velocity pressures, which in turn, give the program more flexibility in balancing trunk static pressures. Input an "M" for a medium velocity de- sign. Medium velocity is approximately 33% below that of high velocity. In addi- tion, medium velocity design will also have higher fan static pressures and larger duct sizes (thus requiring more sheet metal). Al2.Maximum Increase in Supply Air (Optional) The program will calculate the air tem- Completing The Input Forms ; � pQrature ris, n t , . e.he u yst samArl 111-4 A16.Fitting Limiter (Optional) The fitting routines can be crippled if space limitations prevent the optimized fitting from being used. Use this feature only when necessary. Input a one (1) to eliminate optional Y fittings. Input two (2) to eliminate 45-45 and optional Y fittings. Input three (3) to eliminate 45 -90, 45-45, and optional Y- fittings. c • crease the air volume at the runouts in order to handle the load. Unless A13 or B14 is flagged, the program will not in- sulate ducts until the maximum air in- crease is exceeded. Input any value be- tween 10% and 25 %. Some increase will occur even with insulation, therefore the minimum increase is established at 10 %. When left blank, the program de- h faults to 10 %. L A13.Insulate All Ducts (Optional) If all trunk ducts are to be thermally insu- lated, input a one (1). A14.Ratioed Downstream Static Pres- sure Drop (Optional) When this field is left blank, the program assumes 0.5" w.g. (125 Pa) pressure drop downstream of the control unit at nominal air flow. This value represents the pressure drop through 10 feet of flex duct and a diffuser. This 0.5" w.g., or input, pressure drop, will be reduced in the event the design cfm is less than the nominal cfm of the selected diffuser(s). The reduction factor is calculated on the basis of the square of the design cfm over the nominal cfm of the diffuser(s). A15.Fixed Downstream Static Pressure Drop (Optional) When left blank, the program assumes 0.0" w.g. (0.0 Pa) pressure drop down- stream of the control unit. If the system design includes an obstruction down- stream of the control unit whose pres- sure drop is independent of air flow, ' input a value in this field. This value will be added to the ratioed pressure drop B. Trunk Duct Input (FIGURE 6) B1. Duct Section Number The trunk ducts are identified by posi- tive numbers. Each duct must have a dif- ferent number. It is not required that they be in any specific order other than duplicated trunks must be the last trunks input. Duplicated trunks are limited to two digits (1 -99). (See B16.) A section begins after each takeoff and may contain only one fire damper. If 10 A17.Runout Balance Tolerance (Optional) When this field is left blank, the program will iterate the static pressure design until the variation of static pressure at each runout is Tess than 0.75" w.g. (187 Pa). If a tolerance other than 0.75Y w:g. (187 Pa) is desired, input a value be- tween 0.01" and 1" w.g. (2.5 to 250 Pa). If too small a tolerance is used, the desired balance may not be achieved within the 10,000 program iterations. A18.Ceiling Plenum Effect (dB) (Optional) The program assumes 10 dB ceiling at- tenuation for radiated sound. Input 1 dB for no ceiling. Input from 1 dB to 20 dB for an attenuating effect other than that of the standard T-bar ceiling. A19.Fan Efficiency (Optional) Input fan efficiency as a decimal. When left blank, the program assumes .80 efficiency. there are multiple fire dampers in one section, the section must be divided such that each subdivision contains only one fire damper. Also, any runout which exceeds 15 feet in length should be input as a trunk duct. B2.Upstream Connection Number Input the section number of the up- stream section to which this section is to 0 tt NOTE: EACH LINE OF INPUT EXCEPT JOB CARD MUST BE PRECEDED BY 01, 02. 03 OR 04. 1.30 xbS -Nat) truo•rw••. 1.30 34.1.3 -0111 be connected. For connections to the fan, input any negative number. More than one duct connection can be made to the same fan provided the "fixed static pressure" method of design is used and a (0) was input in Column „ B3.Length Input the total length in feet (meters) rounded to the nearest whole number. If the section includes flexible high pres- sure duct, input 1.5 times the length of flexible duct, B4.Number of 45 Degree Elbows (Optional) Input the number of 45 degree elbows in VARITRANE TRUNK DUCT INPUT FORM VERSION 3000 STATIC REGAIN DUCT DESIGN FOR 114C MANE COUeurc, .0 CAUL. WOCONON 14401 Figure 6 11 b SHADED FIELDS B34,135 AND 07 16) ARE OPTIONAL the duct section. B6.Direction of Duct Takeoff Page Date Input elbows of 45 degrees, or less, as45 degree elbows. B5.Number of 90 Degree Elbows (Optional) Input the number of 45 - 90 degree elbows in the duct section. This column must be filled in only for trunk sections which start from a "Y" or a tee. Input 45 or 90 if there is a direction change. The program assumes no direc- tion change when this column is blank, Also, direction changes specified should not appear as fittings in the 2 10 1 e Se m m 2 m m m m te Ste Stet tel e3erinN NOUO3S Iota UPSTREAM CONNECTION NION31 SMOel3 .Sr • 90' ELBOWS ►foa vl Iola I AO NOUO3b10 NO DIVERSITY MAXIMUM Dm AVAILABLE • CONSTRICTIONS I FIRE DAMPERS I OTHER STATIC PRESSURE LOSSES VELOCITY OC AIR OUTSIDE DUCT I t ACTUAL TO I DESIGN TO _ I r2 a v LL�o 3LY IldnO O1 SbOO11 13LWH1 7NLUL 31YIOSrU I 11 1 1 "I/ I F 1 1 1 1 1 1 1 I I ifGeP 14 1 1 1 I 1 1 I 1 1 I 1 1 1 I _°L' _ ° L ' ° l' I /0 1 l 11 l /l'/ 1 /l 1 tap 1 1 4 1 1/10 I I I 1 I I 71 91a 1 1 1 1 1 1 1 1 1 1 1 1 1 1 ROlo l I lP 1 /1.1/ l /I.I/ I 1 1 1 1 I 1 I 1 I I 1 I 1 I 1 I 1 1 1 I 11 I 1 11 1 _ 1 1 1 Qi R 1 /l3 l 1 1 1 I 1 1 1 1 1 1 I I 1 1 1 1 1 1 1 1 1 1 I I I 1 I _ ° I' 1 /I 1 /P 1 1/1 I 11 111 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 1/1q, 1 1 9 I I 11 I/QID I L 1 / 1 1 1 1 1 1 l III 1 1 1 11 1 I I 1 I t t 1 1 1 1 1 1 1 1 1 1 1 1 III 1 I 1 1 1 1 1 1 1 1 I 1 1 1 1 I 1 I 1 11 1 1 I 1 1 1 1 I I.1 1 1 1 I 1 1 I 1 I 11 1 1 1 1 1 0 1 3 1 /IO I /Pl`/_J 16A6I 1 1S 1i3 ° I' 1/101 0 1 3 1/1019 I'G ?III/ 1 1 1 1 I I 1 11 1 1 1 1 11 1 1 I I 1 1 1 1 1 1 1 1 1• • 1 ° 1 3 1 / 1 0 1 8 V 0 1 7 1 . 1 5 - I 9p 1 1 I 1 I I 1 1 1 1 11 1 1 1 1 J 1 1 1 1 I 1 1 1 11 ° 3 IJl /f IAN 1 1 17 1 1 710 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 11 ° I' 1/1/1/ I/91 I I too 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 1 1 1 1 1 °I' 1442 I /I /t/ l 116 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1• 0 1 3 14/0 1/1/1 l 1 le 'I I 1 1 1 I 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 0 1 3 1 /1/r9 I /1 /t3 1 1 to 1 1 I 1 1 1 1 1 1 1 1 1 1 •I i I • 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 0 1 3 I' /tS144 /f' 1 1 0 1 1 1 'I "1'1' ! I. 'I•I 1 1 1 1 1 1 1 1 1 1 1' 1 1 1 1 1 1 1 1 1 1 0 1 3 I /I /I4 I /l /45 1 1 l 1 1 1 / 1 - • ' 1 ' 1 - - . 1 IS1C 14.i/ 1 t 1 1, J , 1" 1 1 1 1 1 1 1 1 1 1 1 1 L 1 1 _ 1 I 1 1 ° I' 1/1/17 1 1 1 116 1 1 9 • 1 • 1 . 1. ' I' • 1 'I • IPIO 14.1/ ' '1 1 1 1 013 I /I /Ig .IL. 14/19 1 1 /6' 1 I 1 I•1'a• I' -I 1'1• 1 1 1 11 'C' 1 1' 1 I' I I I I I 11 I I ° I' 111/19 l //is 1 I /M. tI'I* I' 11 I` 'i'1 I 1 1 1 I 11 i' 11 I 1 11 I I 11 t/1'ai I/I/19 1 t /P I I I 1 ' I r i . ' 1 . . I 1 I l 1 l I I I I I 1. 1 I l I 1 1 1 1 1 I l L tt NOTE: EACH LINE OF INPUT EXCEPT JOB CARD MUST BE PRECEDED BY 01, 02. 03 OR 04. 1.30 xbS -Nat) truo•rw••. 1.30 34.1.3 -0111 be connected. For connections to the fan, input any negative number. More than one duct connection can be made to the same fan provided the "fixed static pressure" method of design is used and a (0) was input in Column „ B3.Length Input the total length in feet (meters) rounded to the nearest whole number. If the section includes flexible high pres- sure duct, input 1.5 times the length of flexible duct, B4.Number of 45 Degree Elbows (Optional) Input the number of 45 degree elbows in VARITRANE TRUNK DUCT INPUT FORM VERSION 3000 STATIC REGAIN DUCT DESIGN FOR 114C MANE COUeurc, .0 CAUL. WOCONON 14401 Figure 6 11 b SHADED FIELDS B34,135 AND 07 16) ARE OPTIONAL the duct section. B6.Direction of Duct Takeoff Page Date Input elbows of 45 degrees, or less, as45 degree elbows. B5.Number of 90 Degree Elbows (Optional) Input the number of 45 - 90 degree elbows in the duct section. This column must be filled in only for trunk sections which start from a "Y" or a tee. Input 45 or 90 if there is a direction change. The program assumes no direc- tion change when this column is blank, Also, direction changes specified should not appear as fittings in the r a N R a i•• 1 1i•iit1111uitllflfl■i.ii1 6 mum. 2600 win 9 ■.m.mI�r.uulimum�� 11 / =II1 u� _ Nu mmenun�melnesel mr 1 women 16 rruro . === ■. 19 r 22 • ' di 28 30 32 11 I al11111111111111111111111111111• 1111111•01•1111111 7 .0o1+ ddf I�� ■ Mi l 11111111111•11111111111111111111111111 u.i . 1 gE■E 1 6 F.s12..A1� P'�� /_--11111 E • I1 i UM rr■ ...u. 1111111111111111•1111111•11111111111 MIN tu1•iI11 i � = ruiva rr■ ■ '�E IN limn 6 7.1 Nummirmow oning 11 u1. Taw °•° 30 : ' •• ---- �• ■ ■.•M■■MM.i _ ■...• • ...err rr....111.,* lr.r Ira n1�u uui ii �Af�1��It11�rr��1��I111 mu 11111111 A/ 9 F.HIs §s s$ § ERN §1 / §§ 11(11(11(€ gngggz 000'09 000129 000'05 000121/ 00012c 000•5c 000 000'51 000 0009 0009 000s E Ism: Completing The Input Forms "Number of Elbows" columns (B4 and B5). See Figure 4 for specific design re- quirements of all fittings used. B7.No Diversity Flag (Optional) By inputting a one (1) in this column, the program assumes that there is no load diversity downstream of that trunk and sizes that trunk and all downstream trunk ducts for peak air. Any remaining ducts (with diversity) have a diversity factor applied to the trunk duct air vol- ume. This diversity factor is based on the ratio between block air and down- stream peak air volumes. A situation may arise when the total flagged (no diversity) trunk duct air volume exceeds the block air volume from the fan. The program will note this condition and will permit a discontinuity in the air flowto exist. This discontinuity will be at the junction of the diversified ducts and nondiversified ducts. Table 4 -- Circular Equivalent of Oval Ducts OVAL MAJOR AXIS 12 60 S 40 g 30 o2 W 20 16 12 x 10 o e 0 6 4 .,The no diversity feature should be used sparingly. The general effect of using this feature is to enlarge the flagged trunk ducts closest to the fan. Closer to the end of the trunk ducts, the effect of diversity is less and trunk sizes tend to remain the same diameter. AIR FLOW. MI6 0 AIR FLOW, CFM Figure 7 APPROXIIAATE DUCT DIAMETER DAM) OVAL MINOR AXIS 6 7 8 9 10 11 12 13 14 15 16 17 16 19 20 22 24 26 28 30 32 34 OVAL MAJOR AXIS _.____ _ J 7 6.6 6 7.1 7.7 9 7.5 8.2 8.7 • 10 8.0 8.6 9.2 9.6 11 8.4 9.1 9.7 10.1 12 6.8 9.5 10.1 10.6 11.1 11.6 13 9.2 9.9 10.5 11.1 10.6 12.1 12.6 14 9.6 10.3 11.0 11.6 12.1 12.6 13.1 13.6 15 9.9 10.7 11.4 12.1 12.6 13.1 13.7 14.2 14.7 16 10.2 11,1 11.8 12.5 13.1 13.6 14.2 14.7 15.2 15.7 17 11.4 12.2 12.9 13.5 14.2 14.7 15.2 15.7 16.2 16.7 16 11.7 12.5 13.3 13.9 14.6 15.2 15.7 16.2 16.7 17.2 17,7 19 12.0 12.9 13.6 14.3 15.0 15.6 16.1 16.7 17.2 17.7 18.2 18.7 20 13.2 14,0 14.7 154 16.1 166 17.2 17.7 182 18.7 19.2 19.8 22 13.8 14.7 15.5 16.2 16.9 17.5 18.2 18.7 19.3 19.6 20.3 20.8 21.3 24 15.3 16.1 17.0 17.7 18 3 19.0 19.6 20.2 20 7 21.3 21.6 22.3 23.4 26 15.9 16 8 17.7 18.4 19.2 19.8 20.5 21.1 21.7 22.3 22.6 23.3 24.4 25.3 28 17.4 18.3 191 19.8 20.5 21.4 22.0 22.5 23.2 23.7 24.3 25.4 26.3 27.3 30 19.0 19.8 20.5 21.2 22.1 22.8 23.4 24.1 24.7 25.3 26.4 27.3 2R.3 29.3 32 20,4 21.2 22.0 22.8 23 6 24.2 25.0 25.5 26 1 27.4 28.3 19.5 30.4 31.3 34 21.9 22.7 23.6 24.3 25.0 25.8 26.4 27.1 28.4 29.4 30.4 31.4 32 4 33.4 36 22 6 23 3 24.2 25.0 25.7 26.5 27.3 27.9 29.2 30.3 31.4 32.4 33 4 34.4 35.5 38 24.0 24 8 25.7 26.5 27.2 28 0 28.7 30.1 31.2 32.3 33.4 34 4 35.5 36.6 40 25 4 26 4 27.2 28.0 28.8 29 4 30.9 32.1 33.3 34.5 35 4 36.5 37.6 42 27.0 27.8 28 7 29.5 30.3 31.8 33.0 34.2 35.4 36 5 37.5 38.6 44 27.6 28.0 29.3 30.3 31.0 32.4 33.8 35.1 36.3 37.3 38.5 39.6 46 29.1 29.9 30.9 31.7 33.1 34.6 36.0 37.2 38 3 39.5 40.6 48 30.5 31.5 32.3 34.9 35.5 36.7 38.0 39 2 40 4 41.6 50 32.2 33.0 34.6 36.2 37.5 38.9 40.1 41.2 42.6 52 33 6 35.3 36.9 38.3 39.7 41.0 42.2 43.6 54 34.2 36.0 37.6 39.2 40.5 41 8 43.2 44 4 56 36.5 38.3 39.8 41.2 42 7 44.2 45.6 56 37.2 38.9 40.5 42.0 43.5 45.2 46.5 60 39.5 41.1 42.8 44.5 46.0 47.4 Completing The Input Forms "Number of Elbows" columns (B4 and B5). See Figure 4 for specific design re- quirements of all fittings used. B7.No Diversity Flag (Optional) By inputting a one (1) in this column, the program assumes that there is no load diversity downstream of that trunk and sizes that trunk and all downstream trunk ducts for peak air. Any remaining ducts (with diversity) have a diversity factor applied to the trunk duct air vol- ume. This diversity factor is based on the ratio between block air and down- stream peak air volumes. A situation may arise when the total flagged (no diversity) trunk duct air volume exceeds the block air volume from the fan. The program will note this condition and will permit a discontinuity in the air flowto exist. This discontinuity will be at the junction of the diversified ducts and nondiversified ducts. Table 4 -- Circular Equivalent of Oval Ducts OVAL MAJOR AXIS 12 60 S 40 g 30 o2 W 20 16 12 x 10 o e 0 6 4 .,The no diversity feature should be used sparingly. The general effect of using this feature is to enlarge the flagged trunk ducts closest to the fan. Closer to the end of the trunk ducts, the effect of diversity is less and trunk sizes tend to remain the same diameter. AIR FLOW. MI6 0 AIR FLOW, CFM Figure 7 APPROXIIAATE DUCT DIAMETER DAM) 1 4.4 ,BEI.Maximum Diameter Available - ...,.. (Optional) `, Leave this space blank unless there is a reasonable possibility that the program will specify ducts larger than can be tol- erated. See Figure 7 to estimate the duct size the computer will try to select for a given cfm. If there is a space limitation, indicate the maximum allowable d� ameter in inches (mm). Keep in mind that rectangular or oval duct can be used in place of round where space require- ments dictate. See Table 4. Input the equivalent round duct diameter. NOTE: Tight space limitations can dra- matically increase the required supply fan static pressure. A warning message will be printed out for any trunks having velocities above 6000 fpm (30.5 m /s). B9.Number of Constricted Points (Optional) If a constriction, such as a pipe or beam, requires smaller duct at one or more points, input the maximum diameter in "B8 ". Also, input a positive number in "B9" to indicate the number of points in the section at which the constrictions occur. See Figure 4 for constriction fit- ting design. If a value is input in "B9 ", the program assumes a larger diameter than the number in "B8" and that oval duct can be used at the constriction. If this is not the intent, leave "B9" blank. 810. Fire Damper (Optional) If the duct section has no fire damper, leave this column blank. If the section contains a fire damper, input an "F ". Remember that each trunk section may have only one damper. 811. Other Static Pressure Losses (Optional) If the trunk duct section contains a booster coil, sound trap or other un- usual obstruction, estimate the addi- tional static pressure loss and input this value in inches w.g. (Pa). B12. Velocity of Air Outside Duct (Optional) Input the approximate velocity in fpm (m /s) of the air surrounding the duct. 13 Examples of typical air velocities are:' Return air shaft near fan 1,000 fpm (5 m /s) Far end of return air shaft 400 fpm (2 m /s) Plenum above hall ceiling 200 fpm (1 m /s) Large plenums or exposed ducts ....50 fpm (.25 m /s) Furred ducts 1 fpm (.005 m /s) NOTE: A blank is interpreted to be 50 fpm (.25 m /s). If duct heat gain calculations are not re- quired and a one (1) is input in Field A10, Fields B12 and B13 may be left blank. B13.Actual TD _ Design TD (Optional) This field references the ratio. between the actual temperature difference (ATD) and design temperature difference (DTD). Actual TD is the temperature dif- ference between the inside of the duct and the plenum on the design summer day. Design TD is the temperature differ- ence between the inside of the duct and the conditioned space. In ceiling return plenum designs, the plenum temperature is influenced by lighting and roof heat loads. The follow- ing can be used to approximate plenum heat gain from lighting: Heat removal fixtures = 1 F Temp. IncreaseiWatt /Ft Slotted return air fixture = 3/4 F Temp. Increase/Watt1Ft Standard ceiling fixtures = 1/2 F Temp. Increase/Watt/Ft Example: 20 degree design air temperature differ- ence (DTD) and standard light fixtures @ 4 Watts /sq. ft. ATD = DTD + Plenum Heat Therefore, the ratio is: ATD 20 +2 DTD = 20 _ If this column is left blank, the computer assumes a ratio of 1.1. If the supply duct is in a supply plenum (as above a per- forated ceiling), input .05. If the supply duct is in an unconditioned space, input the actual ratio. Completing The Input Forms B14.Thermal Insulation (Optional) The computer program will specify in- sulation when the air volume increase, offsetting duct heat pickup, exceeds the limit set by field Al2. The designer can specify insulation if desired by inputting one (1) here. If all ducts are to be insu- lated, input a one (1) on the general input form "A13" and leave this column h blank. The program uses insulation with a U factor of 0.27 (1 inch (25 mm) of glass fiber blanket with aluminum foil exterior.) NOTE: The program does not consider conditions that might result in the for- mation of condensate on the exterior surfaces of the ductwork. This is the re- sponsibility of the duct designer. B15.Fitting Limiter (Optional) The fitting optimization routines can be cripplied if space limitations prevent the optimum fitting from being used. Use this feature only when necessary. Input C. Runout Input (Figure 8) C1.Duct Connection Number Input the trunk duct identification number to which the runout is to be con- nected. Two runouts may be connected at the same point. Three runouts may be connected at the end of the trunk sec- tion. Input non - duplicated runouts first. Duplicate runouts must have 2 digits or Tess. (See B16.) C2.Unit Cfm Input the terminal design air volume, corrected for density in cfm (m Occa- sionally, the terminal unit cfm is in- creased above load requirements for fast response. Remember that the pro- gram can increase the terminal air volume to compensate for duct heat gain. This air volume increase will be greatest for terminals near the end of the trunk runs. C3.Length of Runout Input the actual length of runout that connects the terminal unit with the trunk 14 a one (1) to eliminate optional Y fittings. Input two (2) to eliminate 45-45 and op- tional Y fittings. Input three (3) to elimi- nate 45 -90, 45-45, and optional Y fittings. B16.Floors to Duplicate (Optional) When the same trunk duct system ap- pears on more than one floor, the system may be duplicated up to 15 times by inputting the floor number here. The program prefixes the floor number to the beginning of the 2 -digit trunk duct number in columns B1 and B2. The first take -off from the riser cannot be dupli- cated. Only positive floor numbers are permitted. NOTE: All duplicate trunks and runouts must be input last —after all of the non - duplicated sections have been input. (See "Duplicate Floor Example ", Page 29). duct. The minimum length that can be input is one (1) foot (.3 m). NOTE: Any runout over 15 feet (4.6 m) in length is generally input as a trunk duct. C4.Fitting Type "Fitting type" refers to the fitting on the trunk duct. Allow this to remain blank unless a special fitting is required. This will give the program more flexibility in the selection of fittings that will satisfy static pressure loss and sound require- ments. Figure 4 illustrates the fittings used by the program. NOTE: If a special fitting is required, input the following: Straight Connection —1 90 Degree Takeoff — 90 45 Degree Takeoff — 45 For a straight takeoff, the computer will specify the size of the reducer fitting needed. • c� VARITRANE RUNOUT DUCT INPUT FORM VERSION 3000 STATIC REGAIN DUCT DESIGN FOR NOTE EACH UNE OF INPUT EXCEPT JOB CARD MUST BE PRECEDED BY 01.02.03 OR 04, $.. w•. —wa» C5.Unit Tag (Optional) If unit tags are input in this field, the unit specification output will be printed. Any 6 -digit alpha /numeric tag can be input. For duplicated floor tags, put an asterisk ( *) in front and fill in all 5 digits. The output will be preceded by the floor number. Example: *A -101 will be 01 *A- 101, 02 *A -101, etc. C6.Terminal Unit Type From Table 5, select and input the letters and/or numbers that identify the type of VariTrane unit desired. Do not indicate size of unit because the program will make this determination. FINE' 111[ 11M A COMPANY. IA 010144. WISCONSIN 11101 Figure 8 15 Papa Date SHADED COLUMNS (C5 AND C10•C111 ARE OPTIONAL Remember that if a desired room NC level cannot be obtained with a control diffuser, a control unit may be substi- tuted. Lower sound levels are possible with control units, since the ultimate sound level is influenced by the attenu- ating effect of the low velocity con- necting duct and remote diffuser. The computer assumes a 10 foot (3 m) length of lined non - metallic duct when calculating the room NC level of a con- trol unit. The program will select a larger terminal if, 1) a larger VariTrane unit is available (see Table 5), 2) the nominal cfm (m after duct heat pickup is ex- ceeded by 2 %, or 3) the desired sound level has been exceeded by 2 NC. 6 C 8 u u u° 0 u u u u 9t0 tl3BnnN NOt33NNOD Iona 1 113BnnN 3NOZ NO nil Awn RUNOUT LENGTH FITTING TYPE Ovl twn 3dAL LINn lvNIrf31 CONTROL TYPE 1 NUMBER OF SLOTS HOT WATER COIL TYPE ELECTRIC COIL KW • TAGES HEAT TERMINAL UNIT SIZE ADOITIONAL STATIC PRESSURE LOSSES OES:REO ROOM NC ROOM NC CORRECTION 800 LENGTH LOWNEDNIGNI AiLLNvno NOLLdO lOIS 04 1� [J:Jr'r „AI ■IL��in /L:/'fl �,L .!.1! °L �y •i • ` 1 11+3' • .. • lr�.� _-��� IC�gInllmin ..,c, r�.L s� 1 I r . mgramusa clnln5lnlninnI5 i! ,. 0a • : 9LInE1a.�� �J . •:Inl�Flnnl"i� r / , 9 E*:.'.;.� . - ; Inln:"Cle • • F,*�^ ' LR,i III ....fl 1111 1 " 1111111111 0 a � 111MA' ..:�:1� 1�E MC111 04 IQIS inE TIMEM:1 11159 Inln nnwn 04 1KETIIM J�' IEUM Im InlllrtIr 04 04 moutimormalerm irampIUI lle 04 04 Immummanoinumesullimom . . 0 a lc l nl 1 1 nlr �_ nn n & gilt. 04 Ir121l66nr�� C1n11__? MI12 04 l In ' • ___ _ , .._ EIN Plnl 0 a IG�F EIME' •." �:1 1 ITIM ll'l: CIE 0 . , , e .' IIEMF1' :In1EIN • ' NW; c� VARITRANE RUNOUT DUCT INPUT FORM VERSION 3000 STATIC REGAIN DUCT DESIGN FOR NOTE EACH UNE OF INPUT EXCEPT JOB CARD MUST BE PRECEDED BY 01.02.03 OR 04, $.. w•. —wa» C5.Unit Tag (Optional) If unit tags are input in this field, the unit specification output will be printed. Any 6 -digit alpha /numeric tag can be input. For duplicated floor tags, put an asterisk ( *) in front and fill in all 5 digits. The output will be preceded by the floor number. Example: *A -101 will be 01 *A- 101, 02 *A -101, etc. C6.Terminal Unit Type From Table 5, select and input the letters and/or numbers that identify the type of VariTrane unit desired. Do not indicate size of unit because the program will make this determination. FINE' 111[ 11M A COMPANY. IA 010144. WISCONSIN 11101 Figure 8 15 Papa Date SHADED COLUMNS (C5 AND C10•C111 ARE OPTIONAL Remember that if a desired room NC level cannot be obtained with a control diffuser, a control unit may be substi- tuted. Lower sound levels are possible with control units, since the ultimate sound level is influenced by the attenu- ating effect of the low velocity con- necting duct and remote diffuser. The computer assumes a 10 foot (3 m) length of lined non - metallic duct when calculating the room NC level of a con- trol unit. The program will select a larger terminal if, 1) a larger VariTrane unit is available (see Table 5), 2) the nominal cfm (m after duct heat pickup is ex- ceeded by 2 %, or 3) the desired sound level has been exceeded by 2 NC. ( Completing The Input Forms C7.Control Type Input the type of controls that will be used on the VariTrane unit. P = Pneumatic E = Electric S = System powered C8.Number of Slots For control diffuser units identified by a "T" in the 2nd digit of the VariTrane model number (VTCC, VTDC), input one (1) or two (2) to indicate the discharge arrangement for integral diffusers as follows: "1" 1 slot, 1 way discharge "2" 2 slot, 1 way discharge "2" 2 slots, 2 way discharge C9.Hot Water Coil Type For VCWC hot water coil units, input the hot water coil type: S5 - Standard Capacity, Sigma -flo (1 Row -80 finslfoot) S8 - High Capacity, Sigma -flo (1 Row - 144 finslfoot) HS - Heat Recovery Capacity, Sigma -flo (2 Row -144 fins/foot) Parallel fan powered units (VFWC) use S8 coils only. C10.Electric Coil KW (Optional) This field is used only for the bill of ma- terial output for units with electric heat- ing coils. Input the electric coil KW, from 0.50 to 44.0 KW. C11. Number of Stages of Heat (Optional) This field is also used only for the bill of material output for electric heating units. Input the number of stages of heat, from 1 to 3. C12.Specify Terminal Unit Size (Optional) This field may be used to specify a par- 16 ticular size unit. Input the unit size de- sired. The computer will not resize the unit to meet required sound levels. Runout cfm must be less than 102 per- cent of the nominal cfm of the unit specified. C13.Additional Runout Static Pressure Loss (Optional) Use this field to input a runout S.P. if dif- ferent from the master data input in A14 and A15. Do not input a negative value greater than A14 + A15. This field can be used to increase the runout static to handle terminals other than those listed in Table 5. C13 static pressure is consid- ered "fixed ", similar to field A15. C14.Diffuser Type (Optional) This field is used only for the bill bf ma- terial output. Input the type of diffuser desired. (See Table 9). C15.Desired Room NC (Optional) If the desired NC level for this room is different from that input on the General Form "A9 ", input the desired level here. If it is the same, leave this blank. See Table 3. C16.Room NC Correction (Optional) If the room is not a "typical" room of 1,000 sq. ft, requiring 1.25 cfm/sq. ft., with average surface, input the com- bined correction factors from Tables 6 and 8. Consider a room with a floor area of 500 sq. ft., 1.5 cfmisq. ft and medium -dead acoustical properties. Also, assume this room is to be an executive office. From Table 3, the recommen- ded NC range is30to40. Use NC35 and input in "C15 ". From Table 6, 1 dB must be subtracted because of the high air delivery rate. Using Table 8, a medium -dead room with a 500 sq. ft. floor area requires the addition of 2 dB to correct for the non - standard conditions. Therefore, input + 1 dB ( +2 - 1) in "C16 ". C17.Duplication of Floors This is handled the same as trunk duct duplication. UNIT TYPE OUTPUT DESCRIPTION NOMINAL CFM MIN. NO. REMOTE DIFFUSERS INLET DIA. (IN.) MODEL NO. CONTROL TYPE P = PNEUMATIC E = ELECTRIC S = SYSTEM POWERED NUMBER OF SLOTS IN INTEGRAL DIFFUSER (VTCC & MC) HOT WATER COIL TYPE S =SIGMA•FLO Control Unit "CC^ P, E, or S 5 (Cooling Only) P, E, or S 6 VCC P, y E, or S ti PorE 88 m N 8 10 PorE 12 P 10x18 P 10x24 P • 10x36 Cooling VFCC P, E 400 6 Only P, E 800 8 Fan P, E 1,200 10 Powered P, E 2,000 12 Unit P 4,000 10 x 18 Control Diffuser VTCC P, E, or S 1 200 0 5 (Cooling Only) 400 1 6 (1-Slot 400 2 6 Diffuser) 400 3,_ 6 800 • r 3 8 Control VTCC P, E, or S 2 200 0 5 Diffuser 400 0 6 (Cooling Only) 400 1 6 (2-Slot 800 1 8 Diffuser) 800 2 8 Electric VCEC P or E 5 Heating P or E 6 Coil P or E 8 (Reheat) P or E 0 0 N 10 Control P or E 12 Unit P 10 x 18 P 10x24 P 10x36 Electric VFEC P, E 6 Heating P, E 8 Coil P, E 8 N 10 Fan P, E 12 Powered P 10 x 18 Control Unit Hot Water VCWC P or E S5 = 5 Heating P or E Standard 6 Coll Capacity (Reheat) P or E 8 Control P or E S8 = 8 N 10 Unit P or E High Capacity 12 P HS= 10x18 P Heat Recovery 10 x 24 P Capacity 10 x 36 Hot Wafer VFWC P, E 6 Coil Fan P, E 8 Powered P, E 8 N 10 Control Unit P, E 12 P 10 x 18 Dual Duct VCDC P, E. or S 5 Control P, E. or S 6 Unit P. E, or S Fa 8 PorE 10 PorE 12 Dual Duct VTDC P, E, or S 1 0 5 Control 1 6 Diffuser 8 2 6 (1-Slot 3 6 Diffuser) Dual Duct VTDC P. E. or S 2 8 8 N C R L 0 5 Control 0 6 Diffuser 1 6 (2-Slot Diffuser) Table 5 — Unit Specifications and Identification Symbols 17 ROOM TYPE ABSORPTION COEFFICIENT ABSORBING SURFACES FLOOR AREA Fl 100 500 1,000 5,000 20;000 10 50 100 500 2,000 Dead .40 Clg, Flr, Walls, Soft-Furnishings +4 +4 +3 +3 +3 Medium- Dead .25 Cig, Walls, Soft Fum., or Flr, Walls, Soft Fum. +3 +2 +2 +1 +1 Average .15 Clg, Soft Furnishings or Fir, Soft Furnishings +1 +1 0 0 0 Medium- IJve .10 Walls, Soft Furnishings +1 0 •1 •2 -3 Live .05 All Hard Surfaces •2 •2 •3 .3 -4 Lengths: 2 = 2' 4 =4' 3 =2.5' 5 =5' Plenum Height L = Low M = Medium H = High Discharge Option A = 1 slot, 1 way D= 2 slot, 2 way A = 1 slot, 1 way 0= 2 slot, 1 way C = 2 slot, 2 way C = 3 slot, 1 way D= 2 slot, 2 way E = 1.2 slots, 2 way F = 2.1 slot, 2 way G = 4 slot, 2 way Cfm/Sq. Ft. .5 .65 .60 1.00 1.25 _ 1.50 2.0 3.0 5.0 10.0 m /s&Sq. Meter .0025 .0032 .004 .005 .006 .0075 .01 .015 ' .025 .05 Correction +4 +3 +2 +1 0 •1 •2 -4 -6 -8 Completing The Input Forms Table 6 - Cfm Corrections Table 7 - Cfm to mils Conversions Table 8 - Room Absorption Corrections Table 9 - Diffuser Options Input Procedure The following is an example of the step -by -step procedure required to input the computer program. Step No. 1. Complete a survey of the building and note the following: 1. Building location and orientation with re- spect to the sun. 2. Shading effect of adjacent buildings. • Cfm (Cubic feet/Minute) m'ls (Cubic meters/Second) 200 .094 400 .189 600 .376 1200 .566 2000 .944 3000 1.42 4000 1.89 2.63 18 3. Type of building construction including walls, windows, glass type and shading. 4. Dimensional information including floor -to- floor, window size, suspended ceiling height, maximum space for ductwork, etc. 5. Modular size. Assume the probable par- tition layout if it is not known. This deter- mines location of terminal units. 6. Lighting load and location of fixtures. This is necessary to determine the amount of heat pickup to the ceiling plenum return air system and influences the aesthetic layout of terminal units. 7. The occupancy of the building in square feet per person. If this varies between perimeter and the core area of the building, it should be noted. 8. Miscellaneous Toads such as computer equipment, electric typewriters, etc 9. Possible equipment room locations and type of service available such as electrical or gas. 10. Possible locations for duct and pipe risers and specification restrictions. This basic data is required to understand the building sufficiently to properly input the com- puter program. Step No. 2. Determine the air loading quantities in cfm per square foot for the various modules. Usually, the building columns will dictate the perimeter depth and module layout. However, when this is not the case, the perimeter is usually assumed to be from 10 to 20 feet (3 -6 m) deep. Loading should be separated for each of the fou r sides of the building, corners and for the core area. Any special use areas should be noted which might have higher cfm requirements or where diver- sity should not be used. Where a separate system is used to handle the transmission losses or transmission and solar effect, these loads should be isolated and tabulated sepa- rately by cfm per module per linear foot of pe- rimeter wall. Step No. 3. Rough -in the terminal units. This requires that a terminal be selected for the desired sound level, air throw, and aesthetic effect. Consideration must be given to the slot length, 2, 2 -1/2, 4 or 5 foot increments, and whether slots should be one or two way discharge. If at all possible, this should be coordinated with the lighting fixture layout. Also, in making this preliminary selec- tion, keep in mind the probable cfm increase due to heat pickup, the desired NC level, and the room sound absorbing characteristics. Locate the main supply equipment. It is im- portant to determine duct arrangement, length of longest run, and compatibility of the system with space available for equipment. Use good design practice. For example, allow 3/4 of a fan diameter space between the fan inlets and the nearest wall or bulkhead. Draw -thru fan dis- charges should be designed for maximum static 19 regain and coils should be located to prevent air stratification. Filters should be located to pro- vide uniform air flow over the entire bank. All losses in the upstream side of the fan and be- tween the fan and main riser must be accounted for. Step No. 5. Once the terminal units are located, the trunk duct layout should be determined. This is merely a single line sketch of the duct centerline from the fan to the main riser to all terminal units. If at all possible, do not have any cross- overs where one trunk line must cross another. Also, whenever possible, use two or more shorter lengths to each side rather than one long duct extending all the way around the building. Step No. 6. The next step is to number the ductsystem lay- out. This should always begin at the fan using a negative number and continue from there to the last terminal in the system. Numbers do not have to be consecutive, although some con- venient plan should be used for easy identi- fication of all parts of the duct system. This is easily done by placing a dot just after each runout or fitting. This fitting or runout should be at the end of the section. Where typical floor plans are used, it is convenient to use a constant coding system and input only one floor. Other floors are then duplicated as indicated on the input forms. An easy -to- follow system involves numbering trunk sections from 1 to 99 and the floors 1, 2, etc., for first, second, etc., floors. Step No. 7. When the computer output is received, it should be checked for completeness and logic. Re- member that the duct system is normally sized for diversity unless input otherwise. Total pres- sure losses, velocity pressure conversion fig- ures and the bill of material and unit schedule should be spot checked by hand to satisfy the designer of the accuracy of the program. NOTE: The accuracy of the bill of material is to- tally dependent upon the user's care in inputting the actual duct lengths. Step No. 8. Once the job has been bid, and the final design established when the tenant requirements are known, installation drawings can be made. For minor changes in terminal unit location and air distribution, no changes in the trunk duct system are required. When major changes are required, a second input may be desirable for final production drawings. Output Data • FAN TYPE BLOW THRU CALCULATE DUCT HEAT PICT( UP YES • GENERAL SPECIFICATIONS OF THE SYSTEM ALL STATICS AND CFMS SHOULD BE INPUT AT ALTITUDE •': AIR •• TOTAL AF'PROX EST:, SP . ` M )(,,FAN . DISCHARGE , . 0.075 13656. 2.50 1.20 " 3.00 943. DESIGN MAX NC CEILING METHOD .. LEVEL EFFECT(DB) MAX. H.P. 35 10 INSULATE MAX Z. RATIOED ALL SUP AIR DOWNSTREAM DUCTS INCREASE STATIC PRES NO 10. 0.50 PROGRAM INPUT TRUNK DUCT DATA TRNK UP LENG NO. TROFF DIVER MAX 4 CON FIRE SP VEL OUT TEMP INS LIM STRM ELBOW ANGLE SITY SPC STRICT DAMP LOSS DUCT RATIO DUCTS FIT TRNK' 45 90 AVIL ,38. - 0 ' 0' 0• YES 101'''' 1 .. 30. 0 0 90 YES 102 .101 6. 0 0 90 YES 103 '.10. 0 0 0 YES 104 . 103 "' .10... 0 0 0 YES 105 104 8. .': 0 1 90 • ; NO 106 104 5. 0 0 O'..YES 107 106 3. 0 0 0 NO 109..107 1 . 0 0 0 ' YES 108 107 . 5. 0 0 90 YES 110 101 7. 0 0 90 YES 111 110 6. 0 0 0 YES 112 111 6. 0 0 0 YES 113 112 8. 0 0 0 YES 114 113 6. 0 The output of the VariTrane duct program con- sists of five sections: 1. The first is a print -out of the input data (see Figures 9 and 10). This serves as a convenient record for checking the accuracy of the input. 2. The second section lists the general specifica- tions of the system. 3. The third prints out the calculated data for both the trunk duct and runout sections. 4. The fourth section is a critical run analysis of the duct system. 5. The fifth section is a print -out of the complete bill of material. 0. 0. 0. 0. 0 0 0. 0 0. 0. 0. 0. 0. r• 20 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Figure 9 FAN FITTINGS DESIRED EFFY. NOT USED VELOCITY 80. NO LIMIT H FIXED RUNOUT DOWNSTREAM PRESSURE STATIC PRES. BALANCE 0.00 0.75 0.00 1000. 1.10 0.00 200. 1.10 0.00 50. 1.10 0.00 50. 1.10 0.00 50. 1.10 0.00 50. 1.10 0.00 50. 1.10. 0.00 50. 1.10 0.00 50. 1.10 0.00 50. 1.10 0.00 50. 1.10 0.00 50. 1.10 0 0 0 0 0 0 0 0 0 0 0 6. The final section is a unit schedule list, con- taining terminal performance and tagging information. The input summary serves as a convenient ref- erence to all input data. Note that when dupli- cate floors are input, the number sequence is on a floor basis rather than connecting series. The trunk ducts, fittings, terminals by type and ter- minal cfm are summarized to double check input accuracy. The output summary sheet includes the general specifications of the system. See Figure 11. This includes: • Cfm (m delivered by the fan at the air density input. • 10y` RM -102 102V;,,' : RW -102 103; ?,•''�'':':• RM -103 . 03 t RW -103 1041; `:;: RM -104 ' RM -105 t04tk -;i; RM.106 loaf: • x1 '' :.113.• RW -113 ; i.144* RM -114 �c .1.15:i•:,, RM - 4 S ' RM -109 `, RM -108 110F >;, RM -110 RM -1 12 RM -113 ucONNV TAG UNIT UNIT . RUN -OUT FITTING CFM -' TYPE.' LE NGTH yo TYPE 550. 249. 550. 249. 249. 750. 684. 397. 397. 249. 700. 249. 125. 725. 125. 604. VCCCP VFECP VCCCP VFECP VFECP VCCCP VFECP VFECP VFECP VFECP VCCCP VFECP VFECP VCCCP VFECP VFECP 't� THE FAN (INCLUDES DUCT HEAT PICKUP) yf -FAN;Tt).TAL'' STATIC PRESSURE(IN) AT SEA LEVEL 3.09 AT ALTITUDE... ry "AEQUIPMENTAND RA SP, LOSS(IN) AT SEA LEVEL 1.20 AT ALTITUDE... ;,,THIRDOCTAVE BAND ATTENUATION REQUIRED IN FAN SOUND ABSORBER ..BASED::ON•ASSUMED FAN THIRD OCTAVE BAND SOUND POWER LEVEL OF ' :TOTAkO PEAK CFM AS INPUT 15634 AFTER DUCT HEAT PICKUP.... ` THE SYSTEM B77 1 .;••4 � "1 i7 "i'; • Static pressure developed by the fan at the air density input and at sea level. • Static pressure loss, through equipment and return air system at the air density, input and at sea level. • Estimated attenuation, in third octave band, re- quired of fan sound absorber. • Assumed fan sound power level in third octave band. •Total "peak" cfm (m through the runouts, as input. The cfm (m indicated in the General Specifi- cations of the system, may be greater than the PROGRAM 'INPUT RUN -OUT DATA 2. 90 3. 90 2. 90 3. 90 3. 90 1. 1 4. 45 1. 1 3. 1 3. 90 2. 90 3. 90 3. 90 10. 90 3. 90 4. 45 Figure 10 OPTIMIZED AIR' DISTRIBUTION SYSTEM Figure 11 21 UNIT, DESIRED ROOM-NC ADDTL (SIZE), BROOM, NC COftRE,G LOSS O 35 0 O 35 0 O 35 0 O 35 0' O 35 0 O 35 0 O 35 0 O 35 0 O 35 0 O 35 0 O 35 0.. . O 35 0 O 0' 35 0 35 0 O 35 0 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 n n^ . 15243. 3.09 1.20 0 DB 88 DB 17451. total cfm (m input in Column "A2" by the amount necessary to offset the duct heat gain. (If no duct heat gain was flagged, this value will equal the value input in Column "A2 ".) The static pressure developed by the fan, cor- rected to input density, includes that required by the supply duct system, plus the estimated Toss through the central system and return air sys- tem, input in Column "A4 ". The fan attenuator, when required, should be lo- cated either in the equipment room or in the main riser before the first trunk duct takeoff. The program does not make allowance for pressure Toss through such an attenuator. The estimated attenuator pressure Toss can be input in the first trunk duct section in field B11 or in field A4. Output Data Trunk Duct Design Output (Figure 12) M111,7 . . y.- ..r!OaDf., .,. • TRUNK DUCT DATA TRUNK UPSTRM CFM DUCT DUCT MAX, T,.... 4 FITTING FIRE STATIC INS :DIVER" ' TRNK DIAM, LNGTH,, SPACEt ,ELBOWS . .� ',:•; S.:DAMF�a (ALT) ';,, ; ` SIT.Y'% �\°`•' a•.Yi�)y' s.: i" r x �'•r '';.. � ;; t .' ' ',r,9 :r�Aj,'t,.5:T+ 745 90 . `:;f r +. 1 -1 15243. 32. 38. 0. .0. 0 0 REDUCER i.39 10i 1 7380. 24. 30: 0. 0.' 1 0 Y FTG 1 1.35 102 101 4055. 20. 6:`; 0. 0. 1 0 Y FTG 1 1.40 103 102 3295. i8. 10. 0. 0..• 0 0 REDUCER •' 1.37. '104 103 2529. 16. 10. 0. .0. 0 0 REDUCER 1.36 105 104 852. 8. 8: 0. 0. 0 1 45 90 T 0.94 106 104 1540. 14. 5: 0. 0. 0 0 REDUCER 1.42 107 106 911. 8. 3. 0. 0. 0 0 REDUCER 1.09 108 107 460. 7. 5. • 0. 0. i 0 Y FTG 1 1.20 109 107 451. 7. 1. • 0. . 0. 1 0 Y FTG 2 1.23 110 101 3398. i8. 7. 0., 0. 1 0 Y FTG 2 111 110 3161. 18. 6. 0. 0. 0 0 COUPLING CZIlb 112 111 2485. 12. 6. 0. 0. 0 0 REDUCER 0.92 113 112 2246. 12. 8. 0. 0. 0 0 COUPLING 0.96 114 113 1394. 10. 6. 0. 0. 0 0 REDUCER 0.99 115 114 1274. 10. 4. 0. 0. 0 0 COUPLING 1.03 116 115 699. 8. 2. 0. 0. 0 0 RFn" .4-7 1 7Q 94, A ,' A. The trunk duct number and upstream section to which it connects are repeated for reference purposes. The total cfm (mils) in that section of the duct is indicated. This includes the effects of duct heat gain and diversity. The heat gain tends to increase the value, while the diversity effect decreases it. The duct design program uses di- versity based on the ratio of the trunk cfm and the sum of the downstream unit cfm's. Because of the diversity effect, it is noted that the sum of the air flowing away in two sections of a tee may be more than the duct supplying the tee. The next column indicates the trunk duct di- ameter the program selected. If the duct di- ameter in this column is equal to the maximum space available (2 columns to right), check the trunk static pressure in the second to last col- umn. If low, in relationship to the other trunk ducts, the trunk space limitation is too small and must be increased. Remove or increase the space limitation. Consider substituting oval ducts that give an equivalent larger round duct area. The type and number of elbows and fittings se- lected and optimized by the program to satisfy the input directional requirements, are then specified. The elbows selected will always make the needed directional change. On accasion, the 90 degree takeoff will be accomplished using a Figure 12 22 YES YES YES YES YES NO YES NO NO NO YES YES YES YES YE YES 4590T However, if it is found that there is not sufficient room to install the 4590T, a machine fitted 90 degree conical tee with smooth en- trance may be substituted. This fitting has ap- proximately the same pressure loss character- istics as the 4590T Also, a "Y" fitting with two 45 degree elbows rather than one 90 degree tee or one 45 degree tee and one 45 degree elbow may be specified for a main riser (Figure 13). This duct config- uration reduces pressure loss and thus helps minimize the total system pressure requirement. Fittings are specified in both the trunk duct and runout output. These fittings are at the begin- ning of the duct section. When a "Y" fitting is specified, the computer prints out "YFTG1" for the first branch and "YFTG2" for the second branch. When the program specifies a "Y ", it as- sumes a 45 degree takeoff. An elbow is specified as needed. The duct length (DUCT LNGTH), Maximum Space Limitation (MAX SPACE), and Number of Restrictions (# CNSTR), is a repeat of the input data for reference purposes. When the computer prints 4590T, this means a 45 degree takeoff from the trunk duct plus a 45 degree elbow to be assembled as a single fit- ting. In actual practice, this may be built as two separate fittings. The program may specify two types of tees. 'They are the 45T and 90T. • -`r- Trunk duct fitting optimization can be restricted through the use of fields B15 or A16. If the re- stricted fittings were located on the critical trunk run, the fan static pressure would be increased. Occasionally, this increase in static may be great enough to prevent the program from iterating to a solution. In these situations; it is necessary to remove all fitting and trunk space restrictions, run the program and get a good, clean design. Then slowly add the restrictions until a balance is reached between increased static pressure and physical limits imposed by the building structure. ,.,The column headed "Static (ALT) is the static, . preigiirethat iiiiiasured in the duct — section under the design conditions, as input. Experience has indicated that when the fan is producing design cfm, little duct static variation is experienced due to shifting building diversity. This is because of the static regain method of design. When thermal insulation "INS" is required in the ductwork, either because it was input on the general input form, the trunk duct form, or be- cause it is required due to heat pickup, an "1" will appear in this column. INPUIt 90 °UINTA Y flITINC, 4S 1111101V C Output Data Runout Output Data (Figure 14) : /•�,.'�, N'^„•'1f�•. fi r . . F "DUCT • a UNIT:'' UNIT, x :CFM:prri SPEC 102.. 603. VCCCP 800 • VFECP 400 i 03:;'. "608. VCCCP 800 103 ;;' 277.:,. VFECP 400 .• VFECP 400' ` 105, • 852. VCCCP1200 106 • ?774. VFECP 800 1087 ;460. VFECP 800 109;i'451 •VFECP 800 110 ; 275. VFECP 400 111•: 772. VCCCP 800 112 279: VFECP 400 113' .'142. VFECP 400 113 826. VCCCP1200 114 ..143. VFECP 400 115 690. VFECP 800 116 346. VFECP 400 '•.354. VFECP 400 "4.. VFCr' The trunk duct number indicates the trunk sec- tion that the runout is connected to. Two run - outs may be connected to a trunk section at the same point. Three may be connected at the end of the trunk duct. When three takeoffs are con- nected to a trunk -end the center takeoff should consume no Iess'than 33% of the total airflow. If less air is required by the center takeoff, an ex- cessively high friction loss will result. The runout air volume shown includes the effect of duct heat pickup. It may be greater than the cfm input to handle the load by the percentage in column "Al2" of the General Input Form. The next column indicates the unit type and size selected. The unit specification includes the model number, control type, whether 1 slot or 2 slot diffusers are used on control diffuser units and the type of coil selected for fan powered reheat control units. When a control diffuser unit is specified, the unit size, inlet connection size and the number of diffusers necessary to meet the input sound level are printed out. For example, a VTCCP2800 -1 indicates that an 800 cfm VTCC pneumatic control diffuser with an in- tegral 2 -slot diffuser and 1 remote 2 -slot diffuser are required. For complete unit descriptions, see Table 5. At times, the unit selection may not match the terminal unit type input. For example, if the input calls for a control diffuser (VTCC) and it is impossible to meet the sound level requirement RUN -OUT DATA . ELEC COIL DESIRE D NC DIAM LNGT r nF,� TING ;'ORIF SP,..-7, K W'f STGS: • NC ACTUAL:' ? .�+,. ,. t. ,fi.: ,. ��� ;a, :�.• , � , � Z "�'r i " " °" �4 ,••� .DI AMrAL'T- :�,.;r:•ti.s.�;■ 30 8!.' 2:• 90 T 0.00 1.15 24 - 6,``;:t4:- 3 •..90: T.,-. 0.00 1.22 31 .. 8 ''• ;'i x T l'rY:' ;•+. 0.00 ..1'.12 . 24 .: 6i' 3:. i.,,,,:::/., 0.00 1.19 24 . •6 3 , 90 T'. 0.00. 1 .17 29 _ 10 1 - 1 REDUCER; 0.00 1.15 35 • 8:;'`'? 4.:45 T. . 0.00'.1 10 28 8":-.! " "3: 5.50 '0.77 28 . 8.,. `' 1 : REDUCER 5.50 0.83 24 6 3. 90.:T..',. 0.00 1.20 33 '; 90 T.�.{ :. 0.00 0.97.•., 26 :r'3 90.:.T. :.... : 0.00 0.74 21 3 : : . 0.00 0.92 30 10' ;'. 10.' 90 T 0.00 0.74 20 • 6.;.:.2; - : 3. 90 T 0.00 0.95 33 8;" .." 4:•. 45' T • 0.00 0.97 1 26 6'.' : ' 2. REDUCER 0.00 1.09 - 27 6..‘: . 8., 90 • T ' 0.00 n 77 T. ._.n"''''_.,1 ;.90.. ... 1.00 2 2.50 . ' 2 2.00 2 2.00 1 .50.'' ; 2 1 .50 • 2 1.00; . 2 1.00 '2 .50 2 .50 2 2.00 2 1.50 2 1.50 .2 2.00 ' '' 35 35 "1 35, 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 Figure 14 24 using this type, the program will try to select the unit with additional remote diffusers or the next larger size VTCC terminal. If this is not satis- factory, it will pick the smallest size control unit (VCCC) that will satisfy the sound level requirement. Following is the desired NC level for the room and the actual NC level produced by the equip- ment selected. If the computed NC level exceeds the specified NC level by more than 2 NC, an- other selection with additional satellites, larger size or different type is output. Occasionally, the regenerated noise within the trunk and runout sections is more than can be attenuated by the terminal unit and still meet the desired sound level. In this case, the actual sound level is printed out and the need for attenuation is indi- cated by an asterisk. Additional attenuation can be achieved by adding a sound absorber be- tween the terminal unit and the satellite terminal. Keep in mind that the sound level printed out for the VTCC and VTDC unit is an estimate based on an assumed number of remote diffusers and equal air distribution. If the number of diffusers or air distribution used is other than that output, manual sound level correction is necessary. Notice that no remote diffusers are indicated for the control units or reheat units. This is because of the numerous application possibilities of this equipment. The operating sound level of these units is based upon the controlling sound com- f�l C� ponent, which is usually radiated sound. The runout diameter is based on the air flow and the inlet sizes available for the terminal unit select- ed. The program output will indicate if transi- tions from round or flat oval duct are required. It is assumed that the high velocity runout is of the flexible metal type with relatively smooth inner surface. If a different type is used, any ad- ditional static pressure Toss must be accounted for in the runout input data sheet Column "C13 ". The runout length (LNGTH) is a repeat of the input data. The fittings specified are those shown in Figure Critical Path (Total Pressure) Output A RUNOUT 102 102 . 103. 103 104. 105 • 106 108 109 110 111 112 . 113 111 1.15 .58 .97 .42 1.12 , .59 .94 .43 1.40 1.40 1.38 1.38 1.36 1.18 .43 - .96 1.17 .43 1.42 1.11 .96 1.21 .81 .35 :' 1.24 .86 .35 .95 .43 1.1.39 .97 .95 .76 .44 :98 .93 .35 The critical path or total pressure analysis of the duct system is an optional output. It follows the runout data output and contains the information shown in Figures 15 and 16. The micro - computer version provides this infor- mation if the answer is yes to the total pressure question presented at the start of a run. For the La Crosse mainframe version, change the first input line to read "VARITRANEITP ". ��0 V t ' � 7 lbw & og p2 Q4 ST� C PRE �S E AN YSIS %RUNO 6 RUNOUT STATIC, DWNSTM . OVER SP PRESSURE TRUNK RUNOUT RUNOUT. RUNOUT SP SP .'REQUIRED UNIT AVAILABLE ',; SP SP TOTAL PRESSURES AT SEA LEVEL TRNK 4 TP TRNK A TP TRNK # TP 1 1.84 101 1.69 102 1.61 105 1.32 106 1.54, 107 1.51 110 1.60 111 -'1.59 112 1.54 115 1.37 116T 34 117 1.74 120 1.64 121 1.57 122 1.46 125 1.40 126 1.34 127 1.17 .30 .28 .57 .00 .19 .24 . .55 4.50 .30 .29 .53 .00 . 19 .24 .51 4.50 . 19 .24 .75 .00 .19 .24 .73 .00 .51 .45 .14 .00 .17 .18 .46 5.50 .17 .18 .51 5.50 .19 .24 .52 4.50 .48 .47 .02 .00 .Y9 .24 .32 .00 .05 .30 .58 .00 ,.^ oA ,aa Figure 15 Figure 16 25 4. The program will specify one of the three types. They are the 45T, 90T and reducer. When the computer prints out 4590T, it means a 45 degree takeoff from the trunk duct plus a 45 degree elbow. The next column, "ORIF DIAM ", indicates the inside diameter (ID) of the orifice in inches. If no orifice is required, a zero (0.0) is printed. The final column gives the static pressure within the runout just ahead of the terminal unit. This value should not exceed the terminal unit pres- sure drop by more than .50 inches w.g. (125 Pa). Occasionally, however, it may be necessary to exceed this slightly for optimum design. Cory n 'T WITHIN TRUNK DUCTS TRNK * TP TRNK A 103 1.59 104 108 1.39 113 1.47 118 1.70 123 1.33 128 1.02 ORIFICE DIA 109 114 119 124 129 TP 1.56 1.41 1.40 1.66 1.53 .96 DIST. FROM FAN 74. 74. 84. 84. 94. 102. 99. 107. 103. 75. 81. 87. 95. The trunk and runout outputs identify the static losses within the system. (Figure 17) For example, considering trunk 111, the trunk total pressure (TP), static + velocity pressures, Figure 16, equals 1.59 inches wc. The static pressure (SP), Figure 15, equals 1.39 inches wc. The difference, or .20 inches wc, is the velocity pressure (VP) component within the trunk. Bill Of Material (Figures 18 -23) YL :•' • i ^, . ROUND ,. DUCT LENGTH y`: D (IN) 'FT 6.0 ;'•37.0. 15.0 A7" WC )F) OVERPRESSURE )O) _ .9r WC )C) - .95" WC ID) • .02" WC 33.0 Al A(3 .v ..�;rw •32 38.0 ." :..:• . 318.3 TOTALS 284.0.,,:•:1312.1 .95" WC )D) Figure 17 (Figure 15) The runout static pressure available &tthe inlet of the VariTrane Unit is .97 inch wc (C) while the runout static requirement is .95 inch wc (D). This requirement is the total of the static losses through the VariTrane Unit, .48 inch wc (E), and the runout downstrearn connection, .47 inch wc (F). The difference between the runout static avail- able, .97 inch wc (C), and the runout static re- The bill of material phase of the program pro- vides a printout of the trunk duct system specifi- cations, trunk connection summary, runout system specifications and unit types and sizes. FEET OF INSULATED TRUNK DUCTS 0.0 QUANTITY OF INSULATION ON TRUNK DUCTS (Figure 18) The trunk duct system specifications give the user: quirement, .95 inch wc (D), equals the over- pressure at the inlet of the VariTrane Unit, .02 inch we (G). If the runout is not orificed, 0.00 (H), this is the true overpressure at the unit. However, if the runout is orificed, the overpressure is after the orifice and, by definition, the runout is not critical. If the system designer wishes to optimize the duct system beyond that produced by the pro- gram optimization routines, all of the critical runouts with 0.00 orifices and overpressures less than .3 inch wc are identified. The program is then forced manually to use larger VariTrane Units in the selected runouts. This is accom- plished by specifying unit sizes in field C12. The static pressures in fields A3 and A5 are reduced by .3 inch wc and the program is re -run. The new fan static pressure will usually be lower. As a general rule, a good duct design is achieved when 35 percent, or Tess, runouts are orificed. TRUNK DUCT MATERIAL SUMMARY SURF AREA THICKNESS GALVANIZED STD, GAUGE DUCT SQ FEET GAUGE STEEL.LBS LBS /LINEAR FT 11.0 26 26 °39.3 26 Figure 18 26 10.0 35.6 93.9 24 261.5,. 22 447.6 1.79 2.06 2.55 1.04 7.7r 12.65 1508.3 NOTE •THE DUCT WEIGHT IN LBS DOES NOT INCLUDE A WASTE FACTOR. GAUGE ,THICKNESS BASED ON SMACNA RECOMMENDATIONS '.'.CHECK PROGRAM PREFAB DUCT LBS /LINEAR FT AGAINST ACTUAL PREFAB DUCT WEIGHT. 0.0 SQ FEET PREFAB WT DUCT LBS. 10.74 76.22'' 38.25 480.70 1606.5 1. Diameters of ducts used 2. Length (feet) of ducts of each diameter 3. Surface area (sq. ft) of ducts of each diameter 4. Duct thickness (gauge), in accordance with SMACNA recommendations 5. Duct weight (Ibs) of galvanized steel 6. Prefab. ductwork/lbs, per linear foot 7. Prefab. duct weight (Ibs.) 8. Total running feet of insulation, plus total area of insulation required. . - Output Data -....REDUCER.... UPSTRM T DWNSTRM DIAM, DIAM 1. 90° elbows 2. 45° elbows 3. Fire dampers, if used 4. Couplers -ea . 7:91i1'1.:: = ... .. .w!c:;.;. .!.;INT::L't,.t vlj!, 'fS >r, '.•., ;;7 ?`t r:'ti •' 1'J7�4 Jas {. . TRUNK TRANSITION MATERIAL' SUMMARY '•.f`: { : 45 .DEGREE.. ..45 -90 DEGREE...... T;. DWNSTRM • DWNSTRM - r " • DIAM' DIAM' TOTALS 15 REDUCERS Figure 19 0. 45, • DEGREE (Figure 19) In the trunk connection summary, the program lists, for each upstream diameter, the number of: Figure 20 8 :Y .. '-''•DWNSTRM DWN 1RM DIAM 2' .T 2 45 -90 T ^.`r 3 Y— FITTINGS (Figure 20) 5. Reducers, with downstream diameter 6. 45° tees, with downstream diameter 7. 45 ° -90° tees, with downstream diameter 8. "Y" fittings, with downstream diameters (Figure 21) The runout specifications list, for each runout di- ameter, the number of: 1. Feet of flexible duct 2. 90° takeoffs 3. C9OT fittings 4. 45° takeoffs 5. Straight takeoffs or reducers (Figure 22) 6. Number and size of units required The unit statistics portion of the printout sum- marizes the number of each type of unit used in o f ?.4 .444 At Figure 21 Figure 22 Figure 23 28 • (Figure 23) 603. 0.30 1.0`.2 275. 0.19 608. . 0.30 2.5''2 277. 0.19 2.0 2 280. 0.20 852. 0.20 2.0 2 774, 0.52 1.5 2 460. 0.19 1.5 2 451. 0.18 1.0 2 275. 0.19 772. 0.48 1.0 2 279. 0.19 c n • • n t1 AR 7. VariTrane Unit Schedule 30.. 24.- • 31. 24.. 24.. 29. 35. 28.. 28. 24. 33.. 26. 21 . • f VARITRANE UNIT SCHEDULE 4 .. , DUCT': UNIT TRANE. UN'IT�' INLET UNIT HEATING',COIL: DESIGN MAX PROJECTED.. CONN•. TAG MODEL"SIZE''.'DIAH :''" TYPE ' ° <:i , :: CFM* UNIT • ROOM NC . =:,r ;+. : • HOT H2O: `'. ELEC . .` .' . • PRESS LEVEL . r Y�� 1,,, ' .•,,,..., • COIL KW ' STGS DROP . (FINS /FT)'•• (SEA L) the design. This includes both the nominal cfm and type designation. This portion also includes the total number of diffusers that were input in column C14. Finally, if the individual units were identified by a "Unit Tag" in field "C5 ", a " VariTrane Unit Schedule" is printed -out. This schedule recaps the unit specifications and performance charac- teristics by room or intended location, or in ac- cordance with any other tagging method used. • Duplicate Floor Example VARITRANE TRUNK DUCT INPUT FORM VERSION 3000 STATIC REGAIN DUCT DESIGN FOR NOTE: EACH LINE OF INPUT EXCEPT JOB CARD MUST BE PRECEDED BY 01. 02, 03 OR 04 1.00 343 .1-44471 e- 0MN041 1.30 017.3-4$711 1,N ?MIA COUIW,. U C71OU( +AK0.yw $4101 As discussed in item B16 under "Trunk Duct In- put", page 14, and item C17 under "Runout In- put", page 16, when the same system appears on more than one floor, the system may be du- plicated up to 15 times. For example, using the trunk duct input form, Figure 24, and the illustration, Figure 25, the non - duplicated portions of the system must be input first. In this example, the vertical trunk sec- tions from the rooftop unit and the floor -by -floor takeoff trunks are not duplicated. Using the same trunk duct numbering sequence from the previous example, Figure 6, the dupli- cated portion of the system begins where trunk 102 joins upstream trunk 101, Figure 25. Note that the last two digits of the trunk num- bers are input in column R1 and B2, Figure 24, And, in the "Floors to Duplicate" field, B16, the floor numbers are entered. In this example, 3 Figure 24 29 Pepe Date SHADED FIELDS (B4, BS AND B7 181 ARE OPTIONAL Figure 25 m m C __... re t$ m m m m 0 li m B Fri m U3Bnf N NO1103S 1311O UPSTREAM CONNECTION LENGTH SMO813 At • I SMO813 .06 • AlISH3A4 ON 310311/1 1O110 i0 NO11331110 MALMUM DIA AVA6,ABLE SU3d11YO 3U11 SNOUOw15NOO OTHER STATIC PRESSURE LOSSES J VELOCITY OF AIR OUTSIDE DUCT Ol NO1S30 011V 1113V INSULATE FITTING LIMITER tit. 1 999� 111 11 I 11111 I � cr 99 moo nnn1nnn1nnnnnnv1nnnnnnnnnnnnnnn nI Elm Annnnnnnnnnn 111 a' CP. CC CLE CSC EMI CSC MUM CC €1 6C - 11111 11 CC 11 1 LC = ggq.8 111 A °79 9q 9 8 9,9.8 qgq -f I , NhhI n n n� nn n� nn nnnniinnnnnnnnnnnnnnn n nnnlnnn�nnnn nnnlnnfInnnnnnIInnnnnnnnnnnnnnn nnnennnlnnnnnniinnnnnnnnnnnnnnn nnunnn�nn"nnnn��nnnnnnnnnnnnnnn nn Winn 11111111111111111111111111111111 rnnninnnnnnirnnnnnnnnnnnnnnn nn nnunnnnnnnnnnnnn nnlnn nl Innnllnnnnnnnnnnnnunn 11nnnnnnnnnnnnnnnnnnnnnnnnnn 11 111 cm wncaggg7, Is it oz ° 3 n 2.0/ 217; f 117 03 •4 05 01 . 02� .03 : o4 1 l 1° 111 II ; 061 n 1 NIIIUNNINIIRNANANNNNIIIRNN 1m cu 09 07 n�nnnn� • : • nnnnnumninnnnnnIInnnn nnnnnnnnnnn in ner QE�nl ° I 3 ii/ �0 / ne mnnrnnnnnnunnnn wi min 1 1/12 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I nnnnnnnnnn 1 1 1 1 1 1 I 1 1 I • Duplicate Floor Example VARITRANE TRUNK DUCT INPUT FORM VERSION 3000 STATIC REGAIN DUCT DESIGN FOR NOTE: EACH LINE OF INPUT EXCEPT JOB CARD MUST BE PRECEDED BY 01. 02, 03 OR 04 1.00 343 .1-44471 e- 0MN041 1.30 017.3-4$711 1,N ?MIA COUIW,. U C71OU( +AK0.yw $4101 As discussed in item B16 under "Trunk Duct In- put", page 14, and item C17 under "Runout In- put", page 16, when the same system appears on more than one floor, the system may be du- plicated up to 15 times. For example, using the trunk duct input form, Figure 24, and the illustration, Figure 25, the non - duplicated portions of the system must be input first. In this example, the vertical trunk sec- tions from the rooftop unit and the floor -by -floor takeoff trunks are not duplicated. Using the same trunk duct numbering sequence from the previous example, Figure 6, the dupli- cated portion of the system begins where trunk 102 joins upstream trunk 101, Figure 25. Note that the last two digits of the trunk num- bers are input in column R1 and B2, Figure 24, And, in the "Floors to Duplicate" field, B16, the floor numbers are entered. In this example, 3 Figure 24 29 Pepe Date SHADED FIELDS (B4, BS AND B7 181 ARE OPTIONAL Figure 25 floors are assumed with each floor sharing the layout illustrated in Figure 28. program prefixes each trunk number with the floor number (102 -- upstream 101, 202 — upstream 201, etc.) and then calculates and out- Notts puts individual data for each trunk section. The C1, C2 and C17 columns of the " Runout Duct Input Form" are similarly input, inputting the non - duplicated portions first, to duplicate the runout duct systems by floor. .r FACE SIZE 6 CFM. 80 100 120 140 160 180 200 235 275 315 TP .026 • .040 258 .060 .104 .131 .190 262 .350 .500 71 1.0 1.3 1.5 1.8 2.0 2.2 3.0 35 4.5 5.0 T2 1.5 1.7 2.0 3.0 4.0 4 4 50 60 7.0 8.0 73 4.0 5.0 6.0 7.0 80 8.5 9.0 100 12.0 13.0 NC 20 20 20 20 20 21 22 27 33 38 6 CFM 140 175 210 24.5 280 1 315 350 420 490 560 TP .043 .06: .092 .125 .165 .210 257 .400 .540 .740 71 1.0 1.5 2.0 30 35 4.0 41 5.5 60 6.5 72 2.5 3.0 3.5 4.0 4.5 5.0 6.6 7.0 80 90 73 5.0 60 7.0 8.0 90 10.0 11.0 13.0 14.0 15.0 NC 20 20 20 20 25 27 30 37 42 47 10 CFM 220 270 330 380 435 490 545 655 765 870 TP .046 .070 .100 .140 .160 .230 280 .430 560 .790 71 1.0 1.5 2.0 35 40 4.5 5.0 GO 6.5 7.0 • 72 2.5 3.0 3.5 4.0 4.5 5.5 6.5 80 82 90 T3 60 7.0 8.0 10.b 10.5 11.0 12.0 140 150 16.0 11.0 12.5 90 20 54 78 32 35 40 14.0 50 12 CFM 315 15 390 470 550 G3_• 705 785 4 1100 03 1255 TP 046 .0)0 .100 .140 .180 .230 280 .437 560 790 71 30 35 4.0 4 5 50 5.5 60 7.0 80 90 72 4.0 50 5.5 60 7.0 8.0 8.5 100 10.5 12.0 73 7.0 8.0 10.0 11.0 11.5 .12.0 130 150 IGO 17.0 NC ' 20 70 23 26 29 32 34 41 . 46 51 14 CFM 425 530 635 745 850 955 1060 1270 1490 1695 TP .047 .072 .104 .145 .185 240 265 440 .590 .805 71 30 35 4 0 50 55 60 65 80 9.0 100 72 40 50 55 65 7.5 85 95 11.0 120 130 T3 70 90 100 110 120 130 140 150 16D 17.0 NC 79 21 23 26 31 34 37 43 53 57 15 CFM 490 615 735 860 995 1110 1230 1470 1720 1970 TP 046 075 110 .150 .195 .250 303 455 .610 .825 1) 35 40 50 55 60 65 75 90 100 11D 12 4 5 55 65 7.5 90 95 100 115 125 13.5 13 80 100 11.0 120 130 14 150 160 17.0 180 NC 70 __ 21 74 29 3;it 36 39 45 56 60 FACE SIZE NECK SIZE Facia NECK VELOCITY. rpm 400 500 600 700 603 900 1000 1200 1403 1600 12 a 12 4 CFM 35 45 SO 60 70 80 90 105 120 140 TP .18 026 .035 .048 .063 .080 .100 .137 .182 240 71 1.0 1.2 1.5 20 2.5 30 3.5 4.0 4.5 5.5 72 1.5 2.5 30 3.5 4.0 4.5 5.5 65 7.5 90 T3 2.5 50 6.0 7.5 90 10.0 10.5 11.5 12.0 115 NC 20 70 70 70 70 70 71 23 25 30 5 CFM 55 68 82 95 110 120 135 165 100 218 TP .020 .028 .040 .055 .072 .092 .113 .155 .200 270 T1 1.0 1.5 1.5 7.0 30 40 45 60 6.5 70 72 1.5 2.5 35 45 50 55 7.0 85 9.5 130 T3 4.0 6.5 80 95 10.5 11.5 12.0 135 14.0 150 NC 20 20 70 20 20 20 20 20 24 31 6 CFM 80 103 120 140 160 180 200 235 775 315 TP D21 .032 .045 .060 .080 .100 .120 .167 .220 290r T1 1.0 1.5 2.0 2.5 30 4.0 50 65 . 7.0 90 72 2.0 2.5 4.0 55 60 65 8.5 10.5 11.0 12.5 73 6.0 85 100 11.5 12.5 . 13.5 14.0 15.0 16.5 17.5 NC 20 20 20 20 70 20 20 20 24 34 8 CFM 140 175 210 245 280 315 350 420 490 560 TP .025 .037 052 D70 D91 .113 .138 .195 260 . 340 71 1.5 2.5 3.5 50 65 8.0 9.0 11.0 13.0 14.5 77 3.5 60 8.0 90 110 12.5 14.0 15.5 16.5 18.0 73 10.5 115 15.5 165 17.5 18.5 200 715 230 260 NC 20 20 20 20 20 20 20 _ 2; 27 ,_ 34 Naca Ram. M. Nampa' Overall Face Sets Facia V +I •D m b 02 0 N. h 12.12 0736 12 a 12 .0928 12 a 12 1576 12 a 12 2325 24 a 24 . 1850 24a24 .226 24 a 24 .285 74 a 24 .382 24 a 24 .505 24 a 24 .577 CFM cubic leet per minute FPM feet per minute velocity total pressure • inch W.G. 7 throw in leet or radius of ditluslon *, 1 T @° 1501pm terminal velocity at 9 -0" ceiling height T (a? 100 tpm terminal velocity at 9'•0" cell ng elg I T @.-15.0.11:1111 terminal velocity at 9 -0" ceiling height noise values based on 10 db room absorption NC Bury SI. Edmunds, England (0) 284- 7013 Fax (0) 284. 70135 51ANUAKU LVtvc rincu Lvu vcn r#- uirruocn Model Series 4600 Performance Data AIR FLOW MEASUREMENTS 1. Place the Anemometer Probe on the centre of • the lour sides o1 the unit as shown. 2. Record and average the lour velocity readings. 3. The flow rate in ctm = lactor X average velocity, Note: For ADC certification, only low tacla data ob. tamed *,m ex AIrWt velorneter are renewed t riall ■lissainumonnallollimain■•■•••• 1 1 1 1 11011 ■ 11 ■ 1111111 =Mag. Toronto, Canada Calgary, Canada (416) 744-3300 (403) 279 -8619 Fax: (416) 744-3360 Fax: (403) 279.5035 Pompano Beath, Florida (305) 782.7666 Fax: (305) 946-3322 • ALNOR 6006P VELOMETER C/W 6060AP PROBE Units Ratings Tesarp rn accordance dim ADC Test Code 1062•GRO.64 and 150 Standards 5219.5135. t. Testing Conducted in Independent ADC Certified Laborala,/ 4f• Houston, Texas (713) 590-1172 Fax: (713) 590.3086 \Jv Nailor -Hart Industries Inc IIIIIIII � f1 4600. 919 A member of the Nailor -Hari International Group of Companies ,,,,, Inc nnram.% a nnficv nr continuous nrndurl development and we therefore reserve the riohl to chanoe any of the inlormalion in this publication without notice, (ENVIRD -TEC) SINGLE DUCT TERMINALS • Model SSD -II Terminals are manufactured of zinc - coated steel: 24 -gauge casing, 16 -gauge damper and 20 -gauge damper seat. (Heavier casing gauges are available at extra cost.) Assembly of the casing is by means of a mechanical lock, insuring the tightest possible construction: maximum air leakage — 2% at 3" water gauge. The basic Terminal is 13" in length and 10" in height. Units may be provided with round, oval or rectangular inlet and outlet collars. Round or oval inlets and slip- and -drive discharge are standard. Model SSD -II units are available as system pressure -inde- pendent or system pressure- dependent. The thermostat controls the SSD -II in either case, providing desired tempera- ture by varying the air volume to the space served, Pressure - independent models are equipped with minimum /maximum air volume dials for rapid field setting; set points are main- tained, regardless of system pressure fluctuations. Pressure- INLET EFFECT —M SSD models are tested wth stregnt inlet connection: II installed with other than straight connection, a shift in the set point may result. Units include an averaging probe to assist in o ercoming poor inlet ettett however the controller may require held tnm adjustmenL Model SSD -II should be selected in the mid to upper - mid range of the performance table (CFM) to insure maximum operating efficiency. Published performance values have MODEL 990-11 CONSTRUCTION PERFORMANCE SELECTION DESCRIPTION Model SSD -H Terminals are designed for use in low, medium or high pressure, variable air volume, single duct systems. The SSD -It's many control sequences represent the broadest range of standard control options in the industry, providing infinite design flexibility to meet any system requirement. The Model SSD -II throttling -type Terminal incorporates a single damper blade, which operates through a 45° arc, providing throttling capability in all damper positions — a feature not possible with 90° arc single or multi -blade dampers used in competitive equipment. r Pressure - independent units are furnished with an inlet Averag- ing Sensor which may be removed without disconnecting the inlet duct or flex. All other control components are accessible outside of the Terminal casing. All SSD -II casings are internally lined with 1/2", 4 #dual density, coated fiberglass, complying with N.F. P.A. 90 -A and U.L. 181. No raw edges are exposed to the air stream. Special insulation coatings are available for clean -room, hospital and laboratory applications. dependent models operate only in response to the room thermostat demand, and may fluctuate through their range as the system pressure changes. Pressure dependent models are not recommended for large systems. SSD•II units will operate efficiently at pressures from as low as .03" AP (pneumatic) and .015" AP (electronic). been established by actual test with the max (CFM) set for the rated value. The recommended selection range will produce the quietest possible system. Testing —all ENVIROTEC"' Terminals are tested and rated in accordance wth ADC, ARI and ASHRAE standards as applicable. CONTROLS Terminals are available with pneumatic or electronic controls. Control sequence descriptions and reproducible schematics are shown in Control Sequence Guide CSP 187 -1 (pneumatic) and CSE 287-1 (electronic). PAGE 6 Size D Dim. 4 8" 4" 5 8" 5" 6 8" 6" 8 12" 8" 10 14" 11" 12 18" 14W 14 22" 171/4' 16 26" 203'e" 18 32" 23Viie" 20 40" 263/4" 24 40" 33" m ! Model BBD•ll Terminal Size CFM Min LPt Room Noise Criterion (NCB Min. LPs Min. APB +0.75" Min. QPs +1.50" MIn.LPs +3.0" Disch. Rad. Disch. Rad. Disch. Rad. Disch. Rad. 4 100 .11 - - - - 25 - 31 - • • 150. r,s.• .. • .22:.: - - x•'22 - 31 - 35:.: .. -. 200 .37 - - 31 - 37 21 41 27 5 175 .09 - - - - 30 - 36 - 265..:.. ■; .20 - - • 25 - 33 • - 39 • 20 350, .33 - - 28 - 35 - 44 25 T11p -' 6 250 .05 - - - - 28 - 33 20 375• • ..,• .13 - - •24 - 31 - 37 24 500 .23 - - 25 - 33 23 40 28 p V 0 0 8 500 .06 - - - -• 30 - 38 23 750 • .16 - - 24 - 32 20 39 . ' 25 1000 .27 - - 28 - 34 23 40 28 12 O a 10 750 .05 - - - - 30 - 35 22 • 1125:.::..•. 10 - - •... P4 - :.. 31 21 :'37...x. .. 25 1500 .18 • - - 30 21 33 25 38 28 / f� V 1{! 12 1000 .05 - - - - 31 - 37 22 1500 11 -- 25 - 33 21 40' • 25 2000 19 23 - 33 21 36 24 42 30 2. COO 14 1250 .04 - - 22 - 30 - 36 26 1875 ,08 - - • 31 - 35 23 40 27 2500 .14 24 - 33 24 38 26 44 31 16 1600 .04 - - 24 - 32 - 37 26 2400 .08 - - 28 20 34 24 40 31 3200 .15 25 - 32 26 36 28 42 34 18 1900 .04 - - 28 - 35 23 40 30 2850 • .10 23 - • 31 22 37 28 42 ' 35 3800 .16 31 - 33 27 39 33 46 37 20 2300 05 - - 29 - 33 21 38 26 3450 .12 20 - 30 20 35 26 40 31 4600 .22 25 - 32 25 38 31 45 34 24 2900 .05 - - 30 - 35 24 41 29 4350 .10 23 - 31 24 37 30 45 34 5800 .19 30 21 33 30 40 35 48 39 J AIR FLOW AIR FLOW a AIR FLOW SENSOR L W INSULATION AIR FLOW CONTROLLER IAU. INTERIOR SURFACES) CFM ADJUSTMENT I PR E S S U R E •INDEPENDENT) PNEUMATIC ACTUATOR (OPTIONAL) 8' M AX. r 13' INLET COLLAR (ROUND OR OVAL STANDARD) DIMENSIONS ELECTRIC ACTUATOR (OPT ONAL) w -- OUTLET (SLIP Si DRIVE STANDARD) 3W' 10' PERFORMANCE DATA • • • • • • • • • oval inlet •• rectangular inlet MODEL SSD -II Perlormanco data is based on tests conducted in accordance with Industry Standard 880. LPt is the total pressure difference between the terminal inlet and discharge. This value does not include pressure losses downstream of the terminal unit. Discharge NC levels are based on 10dB room attenuation, five feet of Tined duct downstream, and a maximum of 300 CFM per diffuser. Refer to page 8 for sound power correction factors it system conditions vary greatly from these assumptions. ) Radiated NC levels are based on 10dB room absorption and ceiling sound transmission class 35.39. Blank space ( -) indicates NC level Tess than 20. PAGE 7 Table 1 -B dB Reduction Per Foot of Lined Downetreeni Duct OCTAVE BAND 2 3 4 5 ..6 UNIT SIZE 33 50 • 100 NUMBER OF DIFFUSERS PER TERMINAL 4-5 -6 .53 2.3 4,4 6.0 6.3 8 .4 1.8 3.3 4.5 4.8 10 .39 1.7 3.2 4.2 4.4 12 .35 1.5 2.8 3.8 4.0 14 .32 1.4 2.6 3.5 3.8 16 .32 1.4 2.6 3.5 3.8 18 .30 1.3 2.4 3.3 3.6 20 .29 1.3 2.4 3.2 3.4 24 .29 1.3 2.4 3.2 3.4 Table 1 -A Sound Power Level Division for Multiple Diffusers % OF TOTAL AIR OF THE TERMINAL HANDLED BY EACH DIFFUSER ' 5 7 10 15 20 25 33 50 75 100 NUMBER OF DIFFUSERS PER TERMINAL 20 14 10 7 5 4 3 2 2 1 dB REDUCTION 13 12 10 8 7 6 5 3 1 0 MODEL SSD -II PERFORMANCE DATA dB REDUCTIONS - Shown above are approximate values compiled through a combination of laboratory testing and extrapolation of empirical formulas published in the ASHRAE manual. These values are based on ductwork approximately the same size as the terminal discharge opening. The above sound performance tables are provided to approximate the discharge NC level where system conditions vary significantly from the assump• Lions shown below the respective performance tables for each product. The following example illustrates the proper use of Tables 1.A and 1.B. SELECTION - Size 12 SSD.II, 1500 CFM, min Ps + 0.75" w.g., 150CFM /Diffuser, four feel of lined downstream duct and only 7d8 room absorption. CALCULATIONS - 1. 1500 divided by 150 = 10 Diffusers from Table 1.A we find a correction of 10dB 2. From Table 1•B we find the following dB reduction per loot of lining: OCTAVE BAND NO. 2 3 4 5 6 dB Reduction /Ft. .35 1.5 2.8 3.8 4.0 4 Ft. (rounding off) 1 6 11 15 16 SOLUTION - From Table 1 .0 (pg. 9) we find the following uncorrected Discharge Sound Power Levels and then apply the corrections calculated above: OCTAVE BAND NO. 2 3 4 5 6 RAW SOUND POWER 65 63 62 58 54 ROOM ABSORPTION .7 .7 •7 .7 .7 MULTIPLE DIFFUSERS •10 .10 .10 .10 .10 DUCT LINING .1 .6 .11 .15 •16 CORRECTED SOUND PRESSURE 47 40 34 26 21 Plotting these calculated sound pressure levels on a NC chart we determine a predicted sound pressure level of NC 28. PAGE 8 • Table 1 -C Model 880-11 Discharge sound Power Levels dB re; 1 pW Min. A Ps OCTAVE BAND NUMBERS Min LPs +0.75" Min,L Ps +1.5" Min.21Ps +3.0 1 CM 2 45 3 46 4 43 5 40 6 37 7 2 2 4 51 5 49 6 47 7 42 2 56 3 4 H21 5 7 46 2 58 2 1-* 4 5 6 100 35 52 60 53 150 51 52 47 44 41 38 54 57 54 52 50 45 61 65 57 56 33 49 64 68 61 63 59 55 203 56 57 51 47 44 40 63 65 58 56 53 47 47 68 70 63 64 53 54 70 74 IS+ 65 64 57 5 175 44 45 43 40 37 36 50 52 57 49 43 56 63 60 58 53 50 60 69 67 CO 56 265 48 50 48 45 42 39 56 60 58 54 51 47 60 66 62 60 56 52 64 72 70 69 63 60 350 52 53 50 48 44 40 59 62 59 57 53 48 61 69 65 63 59 54 68 75 72 71 67 62 6 250 43 44 42 39 36 35 49 52 48 46 45 41 55 62 58 57 53 49 59 67 68 64 60 58 375 47 48 47 44 41 38 55 60 54 48 48 45 59 66 63 59 55 51 64 72 71 69 71 64 60 500 51 52 49 47 43 39 58 62 56 54 51 48 63 68 64 61 57 53 68 75 73 66 61 8 503 46 47 44 42 39 36 48 52 50 50 49 44 58 63 61 61 56 51 65 70 71 71 65 60 750 50 52 50 48 45 40 60 60 57 55 52 47 66 67 39 63 58 53 69 73 71 72 66 60 1000 54 55 54 56 49 43 64 65 62 60 51 55 49 50 45 69 58 70 61 _ 65 68 63 65 61 56 52 73 66 75 69 73 70 73 70 68 62 10 750 46 47 46 45 42 38 52 54 54 60 56 61 60 1125 53 53 52 48 44 43 62 62 60 57 51 50 66 67 66 63 59 55 7t 73 72 70 66 62 1500 56 56 58 58 52 46 67 66 64 61 58 53 69 70 69 66 62 58 73 75 73 72 68 63 12 1000 47 48 48 44 41 37 57 56 58 52 50 44 63 67 65 62 57 52 68 72 72 71 66 60 1500 56 54 53 49 44 43 65 63 62 66 58 63 54 58 50 53 69 72 71 73 68 71 65 67 60 62 55 57 73 76 76 78 75 77 73 74 69 69 62 63 2000 62 61 61 59 53 47 71 69 14 1250 49 48 46 41 39 37 59 59 57 53 52 47 66 66 65 63 58 55 69 71 70 70 65 61 1875 57 57 56 53 47 41 69 66 63 59 56 52 56 71 74 71 75 6 66 62 58 75 76 74 73 68 64 2500 67 49 60 63 62 55 51 72 71 66 65 60 73 69 65 60 78 81 77 75 70 66 16 1600 49 46 41 40 39 64 62 60 56 53 52 68 68 68 64 58 54 71 74 73 72 66 61,_ 63 2400 56 54 52 55 49 42 fig 67 65 61 56 52 71 72 70 66 62 57 76 78 76 75 69 3200 65 51 64 52 66 47 63 55 51 72 72 69 67 60 56 74 76 74 69 65 59 78 81 78 76 71 66 18 1903 43 41 40 66 65 61 57 54 51 71 71 69 65 61 57 74 75 75 74 69 65 2850 62 57 61 59 52 50 71 68 66 62 58 53 74 75 74 69 65 59 77 79 77 76 72 68 3800 68 67 70 67 58 59 74 73 70 68 62 57 77 79 78 72 68 61 79 84 79 72 74 71 20 2300 49 52 49 47 41 40 64 64 66 60 54 51 70 70 70 68 61 55 75 76 75 73 73 65 3450 64 58 55 53 50 50• 70 67 68 65 58 53 73 74 73 72 65 57 78 79 77 75 74 68 4600 69 68 66 67 56 56 73 72 72 71 62 57 76 78 78 75 68 59 80 85 79 76 76 71 24 2900 57 55 49 47 41 38 68 67 67 60 56 49 74 73 71 71 62 56 78 79 77 75 73 69 4350 67 61 56 53 52 50 73 70 69 65 60 53 76 77 76 75 66 58 80 83 79 76 76 71 5800 72 71 67 63 58 56 76 75 73 71 64 57 79 81 79 78 69 60 82 87 81 79 77 73 Table 1 -0 Model 880 -11 Radiated Sound Power Levels dB re: 1 pW OCTAVE BAND NUMBERS Unit Size CFM Min. Min.LPs +0.75" Min.LPs+ .5" Min. Ps +3.0" 2 3 4 5 6 7 2 3 4 5 6 7 2 3 4 5 6 7 2 3 4 5 6 7 4 100 41 36 30 25 22 - 50 44 41 36 32 27 53 47 44 40 36 33 55 52 52 48 44 39 150 47 41 36 32 28 24 53 50 46 40 36 31 59 54 51 45 39 36 62 57 56 51 46 41 200 52 44 40 37 32 29 58 54 50 42 39 34 62 56 46 54 43 46 40 42 33 39 32 66 54 62 50 60 48 56 48 42 5 175 41 32 26 22 20 - 47 41 39 33 30 25 52 48 42 41 265 45 35 30 29 28 24 52 47 44 36 34 31 57 52 49 43 36 33 CO 55 53 52 45 42 350 50 39 36 33 33 28 54 50 46 38 37 33 58 53 57 44 40 38 f.1 57 1212 1 2 1 2 55 47 42 42 6 250 44 35 32 27 26 26 53 43 42 32 31 28 55 47 47 40 38 34 48 45 375 48 40 36 31 29 27 58 50 45 38 35 31 61 55 52 45 41 36 63 57 57 51 47 43 500 53 46 42 36 33 29 62 56 52 42 39 32 64 58 56 47 43 36 65 62 61 54 50 43 8 500 43 36 30 27 25 22 53 44 40 37 35 30 55 51 49 43 39 33 59 55 56 51 46 40 750 47 39 34 32 30 26 55 48 45 39 36 32 58 55 53 47 41 35 62 58 58 53 47 40 1000 52 44 41 38 37 32 60 55 51 44 40 33 63 58 56 50 44 36 65 62 61 55 49 41 10 750 43 36 30 27 25 22 55 48 42 36 34 29 58 52 49 43 40 35 61 57 55 58 49 47 45 1125 50 41 36 30 27 23 60 53 48 40 35 32 64 57 51 46 42 37 66 62 52 49 45 1503 59 49 44 34 31 26 66 59 51 44 39 34 68 61 58 50 44 39 70 65 61 54 50 45 12 1000 42 35 3t 26 25 23 51 47 43 35 34 30 57 51 48 41 38 34 62 56 55 50 45 40 1500 49 41 36 30 29 24 61 52 49 39 35 33 66 58 54 46 43 41 67 60 58 53 47 43 2003 57 47 44 34 33 28 61 57 54 44 !7=1 1'4 IlR _ 68 60 61 57 57 51 46 46 44 40 42 37 71 65 1o1G 62 59 49 43 14 - _ _ 16 18 1250 44 36 33 29 26 24 57 50 43 38 46 1(Rjw121z, 45 45 46 :a 1875 42 48 34 40 47 31 33 37 28 18144 26 29 24 12181i1 1 . I 56 61 45 51 57 41 44 48 37 37 '40 36 I I RiAlA 66 70 61 61 61 57 SI812 50 52 37 39 44 47 69 _ 73 - 65 64 67 65 212:2 57 60 52 j21212 259 16.1) 2403 _ _ _. 44 . 54 54 ' 36 4) .y 51 - Sc 29 _ 33 2 4 65 _ f+ 5.1 59 CO G3 55 2;.5112 47 S i 43 43 46 36 C•41.-', 67 7 1 . 69 *01 57 G? 56 45 i 38 44 If, 34 72 78 7) _ 76 _ t1()_ 67 .112 12 1 ,2;c41,74F212 50 5: 46 46 .1 40 45 - Co - 45 2850 52 62 45 55 41 41 52 Si' 8191R 1 @1q - k 66 69 60 60 1813i2 12121w 46 52 42 if I IgR1 8;41A 72 74 63 IsI212 312;2 14! 46 a8 47 44 au 37 531212 5612 _ 38 0) - - 20 .__ _..___ 24 2300 48 3450 ��<60.3 — rz!.2 i I 47_ 53 43 1;121-9; 1gir* 31 36 29 64 . 6/ 62 57 62 51 21212 42 47 ' 39 14,c1R 67 70 6C> ,212121 52 55 '5i 46 5■ 44 47 50 42 48 4a 46 . 48 _ 72 76 67 75 _ 82 67 70 64 54 58 5 5 50 55 4 6 - _ 4350 58.U� 57_ C.1 1 47 54 41 45 34 37 _ _67 71 61 66 57 62 44 48 44 46 71 ..1 ^ 76 70 70 _ 66 71 12131 57 59 15721 PERFORMANCE DATA MODEL SSD -II PAGE 9 U 0 2000 NI PFAIIIIIIPPral IP 1111111111I1115111111 11 i!IiII 1 it 1000 11 mimmINIPIP- 300 280 2 150 7 ENVIRO -TEC TM SUBMITTAL DATA L1 P sensor Vs. CFM .03 .04 .05 .06 .07 .06 .09 .t o .15 .20 .25 .30 .40 .50 .90 .70 .50 .901 0 A P Across Sensor SIZE 10 SIZE 8 SIZE 6 SIZE 5 SIZE 4 ENVIRONMENTAL TECHNOLOGIES, A CORPORATION AIR FLOW CALIBRATION GRAPH UNIT SIZES 4,5,6,8 &10 DRAIN ' D ADAMS 01 /MAO= roN 06 116 14 JAN 80 an 14 aEP ee 6 am" M 11916 c 6 IN EMMA 111 A I ill sot MEI 11111 30 t ' 111 Illidgeli &- HINIMIMBIll u _ 1. , 4 !Ii!II II- . 11.111/%111111/2111111110 IIIIIII CL ".-<- ° %1Wiiil■ I III „OPP" 3 .03 .04 .06 .00 .07 .06 .09 .15 .10 .20 .25 .30 .40 .60 .50 .70 .50 .90 1.0 ENVIRO -TEC Th' SUBMITTAL DATA A P sensor Vs. CFM L P Across Sensor ENVIRONMENTAL TECHNOLOGIES, A CORPORATION AIR FLOW CALIBRATION GRAPH UNIT SIZES 12,14,16,18,20 &24 ° "o ADAMS .Al21 SIZE 24 SIZE 20 SIZE 18 SIZE 16 SIZE 14 SIZE 12 • 14 JAN 88 My Ma 00 w� o,►w� � woo Nu 119 n U BE&C ENGINEERS P.O. Box 3707 . Seattle, Washington 98124.2207 Mail Stop: - PROJECT ice - - FIG. BY 9 de 4/v' �C: �/%/ar 5 , T ' S /4"4. /1/ _ •t/ 2-ova r(TL/Z o , G t -r / 20-7/711 S Cl 1,-;e beet c" / /¢N, 4 ► / 4 / - /ce4zz.t "14.4 ? z� 70. GAT Berle ( ,9 s- Z IcG/1.. eot ' (r m / r _o (� 7aw c) JOB NO /. �F�'f _... , r1 n , 4'4 / e �✓ , , 4. / / 4,4 ���' ?, ( , C!'r 1 .s CHECKED BY DATE // 4' 9/ SHEET_._4 OF ■✓o M,t -ir's 7/2 70 D e �••+ cl. .J4'✓ ce) ZCF,., / = / f Cis, e-A. = / ¢ err) esm 2"`' � f1 ,AFT Rah M OO ° 7..e ' 740 o @ I 11714 /1480 `/`N Womb-Axis -ri ; f6 t6 z c'''/S r // 9 .6 C/r1 '574 44-6 c -" API / ?"9. s`,tlj ( / Cls.�r /y6 / 6 (At ✓ 9►✓c� . tG 0zee.../ . / 3'0 � r n . /,� s , -3 .3‘o S.T ; 9s c' ply ..� �. of / tr) 1 A. • CHECKED BY DATE / / — S / / SHEET 2 .-OF S; /t . bu cr" - -----� A� , �"K/St l A / Da c -) ZG) Y/arti r 2 / 1 ' C ae = c e (- � = (' i)C / ) (2o d (4) 'Fe C /') (16 //v)(2./z) sTGt• t��e-" 41' e PROJECT FIG. BY BE&C ENGINEERS JOB NO ' 1) I 1 ' i) ffsb f ib✓ r F. Z 4-//0 g% R )✓c-j �C ,h x d - ` ( 0 Q F . / N L r / -. s 4=5 ( /0) + z•o y 1 r / Frc�J C�4w/NS // -- /. 0 13 5 T/Io • ∎• S o .6) P.O. Box 3707 Seattle, Washington 98124.2207 Mail Stop: . ,Q9 vS ,zc.) 7o II 4- 84- :'4 :'$A, M ° '- ' '/ DRIVEt •,( ��RAN0E + • ',' :aHP :% " RPM ,• 4'• i :' TS ' •':''''" ..,t : • . .. .,..• • STATIC PRESSURE : >., •r4 ... ...:nr . "..t. ,,• . i•0.000 0.125 0.250 0.375• -• • 0.600 • 0.625 0.750. . ^0.875':•:: •.1.250 SoneIBHP SonelBHP SonelBHP SonelBHP SonelBHP SoneIBHP SoneIBHP SoneIBHP SoneIBHP SoneIBHP i •r ;K;t ; ` . yC G B 4 ;' 300 .S ;'r if a ,i = R it ,y,•4y... '''54,. ' ''\,. 'Q+:: -, t^ • • : ;;, • . , � • y 113 250 _,,.. ' 1 996'. '.4049 .• • 28.75 ..5 l •,. 45 .., • ,. :; ,••••: rw rr.O., <saoex , r4e•;'':;,■:... .7 10.10 4.7 1 1 1 1 4 ( • ... is Kt: .g.::, (,.. :„ 1 ,,,• • I. . 280 2235 :. . , 4535 3567 ' \y \ rr . 1 9.4 (0.15 5.0 10.16 1 1 1 1 ■�, 310 . ..., . `247 1 • • 5021 4175 • 2616 . . ... ..... � \ \\ \ o � 9.3 10.20 5.4 10.21 4.7 10.19 1' .. . .. 1 "..- 1 1 .. r. .'..IUi F.;tif «I':�:iv, 4, '0:::1 - 3 35. - ' ' 267 4 . . 5426 • 46 3579 - . I , r.:.'.%1.• i•r.t• •:y 92 1025 5.81027 52 1026 1 ' 1' 1 1 •. ' 1 ' : •.'r ;i'1 .r1, • .u.:is v, : » . ••'.s• L ...', 3 65 2914 .' - 5912 • 5222 4339 •' 9.2 10.33 6.2 10.35 5.7 (0.35 ' ••.1. . 1' 1 1 •`b �. +k' : >:1 •:F;: , 4•.,1.. .. . i'• • ?. ;. 300- .,:r.;rt MIK .� v.. • 1 't' ! f?.?, H _ ; - .. f ' 4,c, c -.. ; 1 . 5'314 r,: 395 .3154 1 '' 6398 • 5771 5023 • ,' 3851 :. .. •••• •. • ,: .4..- .::= :40'i' %.>: : .•i 9.2 10.41 6.9 10.44 6.2 10.44 5.9 (0.41 • " 1 ' - ' • 1 • 1 '' x't ..jsl ✓ :: :.� 'rte: a' : 420' 450 . A '3353 ,- " • ' , ..6803 •• • 6221 5536 ' ''. 4640 "..t. • . ..at - ..**4 *." :.....•u'1;t.P. :: : : ,;.; ,...7 = ; 1 9.6 10.50 '+'7289 8.0 10.52 • 6758 •' 7.0 10.53 6135 6.5 10.52 ,•. 5383.. ,•, 1 •'4192'•: - '1 1 ••" . • ;'ir • '1 + fiFYdrlv!t'01S •.?1'yt.4414..d! ''' -ri•'1S.7i'.n :.1''' . r -•': •, • . •.`,ii. ;` G : '300.7 10.510.61 9.3 10 8.3 10.65 7.6 10.85 7.1 10.60 1 1 ..'"'•' ;: V . 1 1 1 :t. ':'. ..Is [:i:'• , r;• . 7i I ••' • ` 4 75 , . : 3792' :40321 • • •,"' ,":7694 '' 7197• > 6615-• • a • .• 5094 "r . ..•, •,4,.!..N. t,'s"•r::t' 44 •:. +,,; }Xq ... • . • •,•: - 11.4 (0.72 • .8180 •' 10.610.75 ' 7722':. 9.6 10.77 •.7177' 8.8 10.77 •• 6591:•.' 8.1 10.74 :5876..'. . • 1 4766. 1 . . ..:47 •'' :' ., t • • ti I- 1 1 %iayx 1.`,'i + ti : ∎'.1td4,g( u•::=�s'::►'. 4 - 0 , 1 ; n..r i:'t,%.t.jt:j 6. !.G13 ), , 300.10: :..,: 12.510.66 12.1 (0.90 11210.92 10.610.93 9.8 10.91 9.2 10.85 ' ("•'x: '40N *1`.44' ' . . t " ? : 1 , J • ' . F ' , ' , ' '' 530 . • " ' : ''8584 8149" 7639•' , '7094 '.' •' 6455'•'' . :'5667.• - • + 4194Y`' 4 : +•.'4� l'Crtr :e;:n¢i�'w' ;. . . . . 13.4 1 1.00 12.9' 1.03 12.2 t11.06 11.5 1 1.07 10.7i nl, 4 „� 4 .24.14, a of .... -1.. 1... - • ',•"'-`,41*''' • G13:1; 30015 :1 ' G B •: 300.20 • ,t, iL� '' r R'S 1. r :> • 1 .112 _. . v , : 9151 • . 87 82 1 711 (4 :'. ;.•6579 ' -• 5711 +. , 4004 i:.•':c.r..cwr.r . r:. 14.6 1.21 14.1 1.25 13.5 128 12.9 129 12.3 1.30 11.4 1.28 r RI 1 �5 'r'"' '14 .r\: ":4 •• - ' •. '•' ''4780 = • 507 ;WI, •': 9718 ^ "- 9334. 8906' - •.:8445 ♦' ;':•7951.'+` ' ?'' •'. .•■6721'2' _ k •' 7581 57431 1 .'nl i 4 ....4 4 ::•".''. 15.9 1.45 . 102: .. 15.4 1.49 ' .•• y ,• 14.9 1 " 9530" _ .•.9096 : .1 '. 8648 '4.' _ _ _tw41R1 ... 8163'. �ik,4� • ' Pi ._• /a x: .., •• .' "h 't • • • . �� , ,•_ R4a :;;:. i•a �� t ':4.' ; ' " I ' • . 2 17.4 11.72 16.81 1.76 16.3 11.80 15.811.83 15.41.1.84 14.811.65 14.2 11.83 . : 11.6 1.67 ::+'A' I "'•' • 5309.4 5548 '10771 10424 10059•. •:'t9648••• -. : •9228 •- 8772' • .''8268'x : u 7698::''!Al 7025�tt: , ' -, 18.8 1.97 11257 18.212.02 10925 17.7 12.06 10586 ' 17.2 12.10 '= 10192 , 16.812.11' ' • 9792 • 16.312.12 ' 9373 15.7 12.11 '8929 ' 14.812.08 13.712.03 '' 8399' ', t . ' ' • ''•' 1 '• ' 5928 ,.� • GB ' - 300.30 'i `•-• _ p . CC 695 -20 12.25 19.512.30 19.012.35 18.612.38 18.212.40 17.8 12.41 17212.42 16.5 (2.40 15.5 12.36 12212.12 • •'- 7398 730. • • •• 5828 ; • •'•.11824' 11508 11192 w 10822'♦ . 10444 .• 10061 9641 "' • • 9196'::+ ."•• 8679• -. 21-1 2.61 21.1 2.66 20 12.71 19.812.75 19.512.78 19.1 12.79 18.612.80 18.012.80 17.312.77 15.012.64 ' 76 . ; + 12310• _ '•12007z., 11703: =':11357.9 '10996 •: 10629 .10241 ••• • 9835 ?4 : :•19369 "8293'••• '23 'I 2.94 22'•1 3.00 21 13.05 21'.13.D9 21%13.13 20 13.14 19.8J 3.15 10932 - 19.313.17 18,613.15 . 10544. •• 10156: 16.813.06 9206 ir ' ' ` GB'.' 300.50 :* •3 •. , ,fit =h ," t'....i •, -' • ' .' -; • + :11.811,, ': • - ; ? .. �;'y' ; {' k , *=jyt ' ' i ' f ' ,, f • �. !'iiv 4No: • 795 ' ' +} 6347:,' .12877. 12587'• 12297 ' '119771 11633 ' 11284 24.1 3.37 2413:42 23 13.48 23.13.53 22.1 3.57 22 13.59 21 13.60 21 13.62 20..13.83 18.813.56 825 • . 65 8 7;.' •.. r '13363 13083"• • 12804 '12508. 12174 ' 11840 11501 ' 11143' ''10789' 9908 25 1 13.76 2513.82 24'13.88 ' 24 '13.93 24 •1 3.97 23 14.01 23 14.02 '22 .14.03 22 1 4.05 •20 -14.01 •: 860 ..'r'awr� , 686 6 : .• - 'X13930' - ' ''+13662'" '13393 -y:• :w13119 "12601 •'; 12483 , 12158 ...• • '•11633 ;' N411475 0 :' 10708 • . 27 -4 4,28 26.14.32 26 (4.38 3 26 1 .1 4.44 '25 :l 4.49 25 14.53 24 14.55 24.14.56 23' 14.58 2214.57 • 890 ., • 17106 *: ; 28.14.73 '28 '284.85 27.0(491 27:44.96 26 15.01 26 "25u15.05'_;25 '24 1 ,\ \ 1 \ - 1'� - \ "�1 \ \ t \ \ \ Damper; , \ \ \ Wkd� .040 ShrouA :Motor, ' ComparL __ Y-:32W \ - i i }ri Su RPM I BHP - - - 1 C o ..5 45 _ q \ y \ \ \1 \y \ 1 \ 1 ■�, I� �∎ � \ \\ \ o � "1 1i 't M I - a % lb . � ' / 1���ILJ� 1 4 111111111 1 ' 11 MIK �i ANINIIIII„\_,� MIK \ NM: .∎ \ iiniN \ '''s X111\ \ 2Sa DIMENSIONAL DATA •;;' METAL THICKNESS ' Approx. Weight • MO Damper; ' (tool ' Y opMl • Curb . • Wkd� .040 ShrouA :Motor, ' ComparL .' 30 :)' Y-:32W ".O64" GB• ►0 50 MAXIMUM BHP AT A GIVEN RPM - (RPM /517)' MAXIMUM RPM - 890 (RPM above 600 must have a relntorced wheel) MAXIMUM MOTOR FRAME SIZE - 184T 36 2'/2 1.75 1,50 1.25 ro N1.00 ro 0. m 0.75 N 0.50 0.25 0.00 0 1 erf ormance shown Is tor Modal GB without inlet or outlet ducts. BHP does not include drive losses. The sound ratings shown were obtained In accordance with AMCA Standard 300,Fig. 12. Loudness values in Bones al a distance of 5 feel were calculated In accordance with AMCA Standard 301. The AMCA Certilied Ratings Sound Seal applies to sone ratings only. 25 4 5 6 7 8 9 10 11 12 13 14 15 CFM x 1000 r THGREENHECK 1 1 i 1 1 1 1 1 1 1 � 0 2000 4000 6000 8000 , CONVERTER MODEL • • • ' E RANG:' " " ' HP. . ;z .RPM "' :,.y , i .; ; TS ' ••'SoneIBHP STATIC PRESSURE ••• 0.000 0.125 0.250 0.375 0.500 0.825 0.750 0.875 1.000 1.250• -.1208 SoneIBHP SoneIBHP SoneIBHP Sone1BHP.SoneIBHP SoneIBHP SoneIBHP SoneIBHP SoneIBHP GB 300-3 i : , ' - ". . !;1/3.,x; a''`.. • a 2 50 • . � 1 996 •••4049 • 2875. y A 9.710.10'4.710.1 1 1 1. 1 1 1 1 1 280 :2235 ' 4535' 9.4 0.15 5.0 0.1 • �� . 310 ,- ;.2475. 5021 4175 2616 1 Bg 9.3' 0.20 5.4 0.21 4.7 0.19 p. L „Ne \ . ::• • ` ' 2674 ....5428 'i 4661 ' ' 3579 , ,. 9.2 10.25 5.8 10.27 5.3 10.26 1 1 1 1 1 1 '.'365 • .2914 •• 5912 0- • 5222 :•• • 4339 III Ilil, 9.2 10.33 6.2 10.35 5.7 10.35 1 1 1 1 1 1 1 GB 300.5 : - , rR2 ; q: • . , ' '' � •; '3 95 9 : ',31 6398 ' 5771 5023 3851 • P1111111� \ 9.2"10.41 6.910.44 6.2 10.44 52 10.41 1 '1 1 1 1 •I • '' •42l) • • ,,, , '"6803 '• • 6221' '.. • 5536 4640 • •• • • • ■ 9.6 10.50 •8.0 10.52 7.0 1023 6.5 10.52 1 1 • 1 1 1 1 • "' GB 300-7 ' ' ;, • L !«.:`f': � ' 314:: r,, . ... 450 3593 7289 6756 6135 5383 4192 • 10.510.61 9.3 10.64 8.3 10.65 7.6 10.65 7.1 10.60 1 '" 1 1 1 • 1 " • • ti . 475 • 3792 =' " 7694 i' 7197 '. • 6615 5954. 5094 .• 11.4 0.72 10.6 0.75 9.6 0.77 8.8 0.77 8.1 0.74 • • • ' GB ': 30010 • R • . 11 . y r •: '!� i;5►•;: ." r t : � :.. `i 505 '-e4032 :: ' 8180 , :. 7722 '.•. '• 7177 • 6591 5876 •• •• "'4766 - • 12.510.86 12.1 10.90 112 10.92 10.610.93 9.6 10.91 9.2 10.85 1 1 1 1 ''' `' • 530 4231 • 84 • 855 13.4 8149 7639 7094 6455 5667 4194 f " 11.00 12.911.03 12.211.06 11.511.07 10.7 11.07 10.01_1.03 9.4 10.91 1 1 1 GB 300.15 R 5 .. .ii : ; ; .1.1,2" .., . :;.... 565 ' 4511 1 11.21 7 1 7 9 7 1 54 1.29 14. 14. 125 135 .28 12 12 3 °30 11 41 1.28 10 6 1 9.5 11.04 1 • 1 ' '600. • .4790 9718 " 9334 8906 8445 7951 7387 "' 6721 ' 5743 15.9 1.45 15.4 1.49 14.9 1.52 14.3 1.54 13.8 1.55 13.2 1.55 12.2 1.52 11.1 1.43 ;•14.8 •., j ` " , ? 1 • . . ..,2 �: • 1 '635 . :.5070 ; `10285 . 9922 9530 9096 8648 8163 7581 6915 5870 17.411.72 16211.76 163 11.80 15211.83 15.4 11.84 14.81 1.85 14.211.83 13.1 11.78 11.611,67 1 665 ' '' 5309 10771 10424 10059 9648 9228 • 8772 8268 7698 7025 18.811.97 18.212.02 17.7 12.06 17.212,10 16.8 12.11 16.312.12 15.7 12.11 14.812.08 13.712.03 1 GB 300-30 . ..... 1 11'7 ' ••• 3 - 695 5549 11257 10925 10586 10192 9792 9373 8929 8399 7817 5928 20 12.25 19.512.30 19.0 12.35 18.6 12.38 18.2 12.40 17.812.41 17.212.42 16.512.40 15.512.36 12.212.12 730 582 8 11824 11508 11192 10822 10444 10061 9641 9196 8679 7398 21 2.61 21 2.66 20 2.71 19.8 2.75 19.5 2.78 19.1 2.79 18.6 2.80 18.0 2.80 17.3 2.77 15.0 2.64 760 •. 12310 ' 12007 11703 11357 10996 10629 10241 9835 9369 8293'. 23 2.94 22 3.00 21 3.05 21 3.09 21 3.13 m® 19.8 3.15 3.17 18.6 3.15 16.8 3.06 C7X ' R4 - • •.' 5 • • 795 6347. 12877 12587 12297 11977 11633 11284 10932 10544 10156 9206 24 13.37 24 1 3.42 23 1 3.48 23 1 3.53 22 1 3.57 22 1 3.59 21 1 3.60 21 1 3.62 20 13.63 18.813.56 825 6587 13363 13083 12804 12506 12174 11840 11501 11143 10769 9908 25 3.76 25 3.82 24 3.88 24 3.93 24 3.97 23 4.01 23 4.02 22 4.03 22 4.05 20 4.01 860 6866 13930 13662 13393 13119 12801 12483 12158 11833 11475 10708 27 14.26 26 14.32 26 14.38 26 14.44 25 14.49 25 14.53 24 14.55 24 14.56 23 14.58 22 14.57 890 7106 16 14157 13897 13638 13335 . 13027 16 12402 12072 11379 218414 . 73 28 14 28 14.85 27 1 4.91 .. 5 . 03 27 1496 26 1501 261271 25 15 25 15.06 24 1 6 \ < < \ N \ , \ \ APProc• Webhl MO Damper Roof Opanhrg -� \ -- \ - 1 - N' \ L SFKOUd Motor Comport 1 3214 : ;• 'f I RPM BHP - - -� .;.080 . ..040 •. -.1208 ■ ■ i y A \ \ ■ ■ \ 1 Bg p. L „Ne \ \ 1 ,- III Ilil, 1 ; 1111 I P1111111� \ , \ n \ �\ \ \ ■ DIMENSIONAL DATA - . METAL THICKNESS APProc• Webhl MO Damper Roof Opanhrg Curb Cap W b - SFKOUd Motor Comport 30 3214 : ;• •.054 r 't' . ' .;.080 . ..040 •. -.1208 GB -300 t 1 50 araw .aaaara Croc07= 44 III % 4 h r { , :I 1,11 • ,ti •�.�: „ \a( .' II • t1:rT+i cCco N!r1i42�!Sa �'� `U'1t • •, �•`� t `c- : �1 ;y . • :fir: aaema• 3 �. 40 MAXIMUM BHP AT A GIVEN RPM - (RPM /517)' MAXIMUM RPM - 890 (RPM above 600 must have a reinforced wheel) MAXIMUM MOTOR FRAME SIZE - 184T 36 2'h 1.75 1.50 1.25 m N 1.00 `) n. 'i✓c 0.75 0.50 0.25 0,00 Perlormance shown Is for Model GB without inlet or outlet duds. BHP does not include drive losses. The sound rating shown were obtained In accordance with AMCA Standard 300,Fig. #2. Loudness values n sones al a distance of 5 feel were calculated In accordance with AMCA Standard 301. The AMCA Certified Ratings Sound Seal applies to Lone ratings only. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 CFM x1000 •t 25 INGREENHECK (:) • PROJECT EL 0 ` ! "le/ FIG. BY 1- BE&C ENGE{NEERS Mail Stop: t_ L JOB NO. CHECKED BY DATE // 24. 9( SHEET OF ?x,r4i6-7 1. t s,r e 4 e A/ o./ 774 C_ �G -LSE F 4) /074e. _ S . X9 X (/oa /0. ,1. .A) /5 /4* s / / - (3,/- c, ,2 - C / 3.c b ) /o /go 4 a / Gv /3 *10 /L / c 2 /S S s`ty 4 Gdv /4C o 90 / So3 0 / 3 ,6r / Z3 ,os�` P-6, 464toS /.2 cfiv = 7 tC S. A'C viAL /=~ • !a G ooa •qc��s .4. 0r . 3 000 /!/Zoff !" nice 264.0 ,1tci4 .Lw 4,00✓ /oCeie ScA P.O. Box 3707 Seattle, Washington 98124.2207 oao ! 4 .7 / as„ (J 1 BE&C ENGINEERS P.O. Box 3707 Seattle, Washington 98124.2207 Mail Stop: PROJECT FIG. BY e iP - ! - /V / 7 1 '-3r JOB NO. 1< . CHECKED BY DATE /4 ZG. Q � SHEETZ OF _. c F f " 5�� C.c, = �i - t ) C /.""S%. •N4f% ,ce c %f C/J ,4i1 Ce Y' oF s%4-( '4i 14 Ti Pr-re (a p "s.'. CZ) 44-12 sc- . .0z4e' aP J 4g0y..-, ✓ac .9 go/ire 1- "A.ox !i!i/ se- ea) s a'.S = "d1 c r„. f O 2 '7 o t ? 7 f_ 32 ro /Z�goa p(- p. '6 ' z tI 4 s .� ,,=-c - r i 2 4, 7 -4) vi 2iP yi 6-3v = / Z / erra C/4.1 • • • ...'f • / r 1 I 1 z £ /9 . 1 EE / f /� C PROJECT 47761; P .. " 4d E 36. JOB NO DATE �• Z G• f SHEET OF— FIG. BY CHECKED BY g cc g. g ',✓ TA T° em(s) S - c.c =ter LA,Z (c-9 7 c fA € ,'v6 •v r-; /e tic 4 F (PA �c.- c4/".-ri9 61,0 " C¢) or i /4c -5 w' Rcei6 - 4= 47,4/0 C,•i o f 7"; % ; - C.• /4) ( 474, 74,cort of, 49 G) (A2 O F , 7 t Cr ' aff,4c 7 Cppr.: / ?'{¢,rc= 3 , BE&C ENGINEERS } 11 Va • Cult c3 ear TO J Tb aria P.O. Box 3707 Seattle, Washington 98124.2207 Mail Stop: Oar — 1 - ,4 It a 41r.7 v4.-.- 5 Lt�Kd --------- feA N's'' �eSi) r Y iv. c c_ s t ✓�= - . 9�v9 c <.d f se' ib 9./'L.c%c �i C TL G 49 -Zta 48o iv Tf6.t3'b6414 drar Cc/itc3 /t 0 Aeeffir ?4.91Ir a 414*Ct= / 6? 7? C/C• h 14 *? i s 1 Sifi - /. f 321,,c, 5 0 04 - / Z, C¢ DIMENSIONAL DATA METAL THICKNESS Approx. Weight'. (Ibs.) • Damper Root Opening 9 Curb Cap Windband Shroud • Motor. Compartment 48 • 50'/ .100 .051 .080 .051 (9 � GB -48 LL ' MAXIMUM BHP AT A GIVEN RPM — (RPM /245) t have r MAXIMUM MOTOR FRAME SIZE -- 213T Consult factory regarding larger frame sizes) Performance shown is for Model GO without net or outlet ducts. BHP does not include drrve losses. /►7017.4_ 4 ' .Sc) ' 'May vary deponding on motor sizo. 47V • 2/2 2526 2716 '9917 10518 ' 11419 • 12020 &.: Os • 11116 8545 411 ;•11811 _9500;: G.31: ;4 14424 • 12838 10848• 10`,1 MION4 . 1'. 15025• '13516 •11662 ';12922 7Ut13522e 16227 akl • 7269 8102 • •14855 13249 14379 •11107 • 12517 3916 9015 am rim nu malliMATIMIM Ak�:tiiL•sS�L: I 122656 r. AMEIEEKEllaig 2 ,02 18631 M E5�7�� ] fl:�EL��7 F 9 E 1 iC E 1F2c �7 1itk MTE111 :145L'1 L'',fi~AE1J:t>rll KFv'1�3MI IMERM REZIESEIMMEIMEEEEMEEM 21035 23139 24040 24641 .25:6 25542 CAfdu] list.! -1'l71F. V1hII.1 16797 17437 19978 21551 22177 23115 23739 24672 15437' 16135 17171 17855 1 19548 20552 EOEFEIFINIMMIEEIM FIT L731 21216 ELEIMEMEEN 190 21164 BEM KIICKEIMMITSI ��, ; 2 �� 1 y 8 ,, 4 yy 99 yy MIMIC 22868 23801 13782 15781 17678 18385 20131 14073 11749 31.`6.,9 3:89 t1,'..9 5.20 2923 3;a? 4'10 AP 3'70 '16,,4 Ta ff 4`. 5' ;1 Q5 5;x2 20.8 3. 2b.0 GB' 48-5'; • • 48 -.10 'GBH ; 48;15i t'GB 48 -20: GB: 48-30 • GB 48 -50 '` Static Preaaure /Capacity 0.375' 0.500' 9587.. 16205 4979 7010 18200 18984 201 18 20828 21883 . ` 0.625 13030 4 14476 15420 16785 17605 18818 19616 20799 0.750 11896 13507 15052 16009 17418 18321 19550 Qa 0.875 12352 13974 3;61- 15770 16734 18156 a ;' 1.000' a :a 14685 4 ' 16604 5.00' 1.250 BFIF • G REEN H ECK FAN CORPORATION :. ' • . L • - i ref • f LI:q771"..1 • ; M • i4 . i ' i.r :• j• - • e;r2.4F7 0. . ,e ;lo t::1147 -!• 1 V. . • • .C.t.:. LI - i •trt ' .., • .4 W � :$irr`! f Jr .' i. 4 65 r r 4 76 : : 1 695 `. ii st .rt, . `' f . l r , ;' ?'�1r7;t;•..R\ '•.,lt: , °ti: 'i „ w` 565 ' :; t\ i 7•` igif 7 . • ...Al At �� ' :.lk..... . , . :•..;. • :. ���! "• 11 ' ; 11! t rr:;d n• '•fit'. ) ." i' .•‘ . r;; - � : -a: ' ill )-11 ' FX —4, E. :. ' • . L • - i ref • f LI:q771"..1 • ; M • i4 . i ' i.r :• j• i-•04,••:! e;r2.4F7 . ,e ;lo t::1147 -!• 1 V. . • • .C.t.:. LI •, .. •trt ' .., • .4 W � I 7.'a. : e} ' r r 4 76 : : 1 1 - 4F:I '..A -, • , ;' .7Z4E-f..1 :`'4 ' 415 :. 500 w` • , I ' 1 ,. • r x,:.325 1t.jT: '�rr 560 • :. ���! "• ..;: . .. �•� .... ;\ :-7 .. , , p sf-,. 240 ) ." i' .•‘ . r;; - � : -a: ' ill )-11 ' t+x \T� If Z.:7i p •t. :. 1 .fltr; •;:s•si.94. • ,. f•. ; ! • ; M y;- i.r :• j• i-•04,••:! e;r2.4F7 . ,e ;lo t::1147 -!• 1 V. . • • .C.t.:. LI •, .. •trt ' .., • .4 W � I 7.'a. r • e} ' r r 4 76 : : 1 . :,,.z'' '..A -, • , ;' .7Z4E-f..1 \. -. yY.••' .fit •r :::�`�.. 1t.jT: '�rr 560 57 ';;!: ■� , -Z lh ;\ :-7 .. , , p sf-,. :•. ) ." i' .•‘ . r;; - � : -a: ' ill )-11 ' t+x \T� If Z.:7i •-• •t. :. 1 .fltr; •;:s•si.94. W'. • ; M y;- i.r :• j• e;r2.4F7 . ,e ;lo t::1147 -!• 1 rn • •, .. .,'. t' .''7tt • .4 W � •1:i : t 1335 1100 •. • . , .1,. i 880 • , ;' . , :o., 1 . • \. -. yY.••' 77 4i. i f •425' 57 ';;!: ` ' 55 -.11.Y-et : �r J ir.� , , p sf-,. ) ." i' .•‘ . r;; - � : -a: ' ill )-11 ' t+x \T� If Z.:7i •t. :. 1 .fltr; •;:s•si.94. W'. • ; M y;- i.r :• j• e;r2.4F7 . • -!• 1 rn • ' .,'. • fin ), • '• .4 ' :�' + •1:i : t 1335 1100 •. • . , .1,. i : i e i 4 k ' . • -. ) ) • C-Fit.V • '0(7. �r • ) ." i' .•‘ . r;; - � : -a: ' ill )-11 ' t+x \T� If Z.:7i •t. :. 1 .fltr; •;:s•si.94. W'. ' : 17,WC :L.. µv r. :• j• e;r2.4F7 rn f• ", :: }trr� • Wri 'A4?;•. •1:i : t ) ) • C-Fit.V • '0(7. GB -18 1.4 1.4 1.2 • 0 1.0 .52. c c 0.6 c co 0.4 0.2 0 1.2 N 0.4 « S 1.4 0.2 0 1.2 • 1.0 • a 0.8 • w u O.6 3 e N 0.4 0.2 0 1.0 o = ` 0 0.8 a 2 0.6 r N 0.4 1 1 1.4 1.4 GB -48 1.2 0.2 0 0 2 3 4 5 6 CFM x 1000 2 3 4 5 6 7 CFM x 1000 CFM x1000 7 8 8 9 9 2 4 6 8 10 12 14 , 16 18 CFM x 1000 410 10 15 20 25 30 35 40 45 1.2 , 2 u 0.6 :° c • - 0.4 0.2 0 1.2 E 1.0 _ 0 0.8 • M u0.6 iv 0.4 0.2 1.2 ` 1.0 � N • 0 0.8 a :°c N - 0.4 1.4 0.2 0 2 3 4 5 CFM x 1000 2 4 GB -42 1.4 6 8 10 12 CFM x 1000 5 10 15 20 25 30 CFM x 1000 14 35 16 18 40 45 0 5 10 15 20 25 30 35 40 45 CFM x 1000 i r. � ,� •, P R PM* ' a c ' \ , ,,�� � �{ (1 • • 'CA. � , . HP , I , ' ) ���'����Nf�+�'�SOUND PQM►Ei�,r�Ar,..�► Ar7�7:s � , . ,::•:(4t'i ;t' •• "�� ��o'i�s�' ' t tic.' - + ' OGT V BA DS '' ".` ..42.).;4?...,!,. Y4 ` "d 4.24 3' 1 �Y441410 tiliV5744 itNi6M 4c- F- ', •�,. ? +8*+n. ! ;"¢' 1 :,:: '::::.;111.,' 215 ,'O 12'16k - . r azo + g % .IiO 11,±V.67:50 S+ 67:5 i 3156?'S14 53ib* ?x„42 :5' ?: •; • U;34 : 0 a�65:5 'i; .'•0250 :k ciA82Ioal 0.c0e.; :!.'66 :0;' � • y 64 :0!`l ', r5Q!0 14 ?.';42.5::.+ 1f 4 ..: •34.014, �. r4Y55 :5% . ‘•':'''- ( 4.4V: i t 0.. 1 ' ' ° i' X0:25 '. 1 i ' i*85:0 77.03:•t I•^ r z�+ '�; X0 it�'i:�68 :5' ,62. Z .61* tb +. %48 :0 :: ' '...K41.02 t106.U?'M�� ,t, l$F83 6' .'iY3 76 :0 3 ;fit68:0)4 T<67 :0?',�'. i)1040.446 Wb : r?•47;O ';i'i 40.011 'i „'�68 :5:3 •& 285 e7d71.r `►41;0125'x' ' ; ?4 i?84'.5,; BO.6* IP, 5:0 :i� ;i` 1:70.0:1 " 1 66;O ►63. • !0' y : �? %53.0' t 4 ! 5:53}• ' iMF;y3di'1"?A} r 'a�i0250 . 4 8370 %* '4 • :.' 1...72:0* i'.it.68:5t ; . f 4 *61! ! °' '''' L' ti .i• . 14 1 8, r . i 7,1;:5 1iil ki: 68 5 54 . 60:0'�: •,,,.' 56.0 • ' `%49.0 •1' `7.5 ?'. 1 0 :500 5i? '82.004 i i 7 7 � 0 i 69.0" ' 661'01 M./64.0A �' 55.0 • 48.0'X• '4 1 i ;� ••4:�h. 45: �; is 0.250„'" - t Tii'8 AI p85'.59 W;' 79.0 4 ': 74.04* 0187.2:0: t 1` Et68 0'A' "e::59.5 C , .52.0"011; •t�irSC78 :0 '1'77:5 '40.500. t ,.. ) '. ?+'86.0Ali.:1184.0 ",'�' :a ':79.0 ,,;� *;!• 73.01, ',fQ?70 :5. 'r.70 :0•\ 60.5 ..' 53.5':t. ' •'.*: ) $ ?1, '','-'0250 2 ta i k a 3., 1"90.0 y.» '� 88 :5.�r.. ^' .�,+1 '".�i .4 82.0 � � 4 '77 .Or.� , \ 75:5;�`� b. '+].•�:D' .. ; 63.0 •. '': :. � . 56.0 ` • :� " Ie : ` 81 0 - :.y0,750 :.:•- .Y+` 1 !4;:.9101t4 a t; ? 84.0 3 78.0i ; :yt•75.5'? :+'2Z�7.1.0N2'+; VI.'69.0.k•? •'. '61.5' ':55.0'451'. ',m78.0 2 , ,: 'I ; 4;0.250 *V!? 444'840 •" 92:0; 84.0 3 t, , f ,80.5: . ;79 ".0,'!�y `t4�(t4'O\a` - •', >66.5 a ": ::59.5 :i 384:t . 0.750 , ' , ,P. k...,p 0 . ,i1' x i 4):.§ o.. " .,78A s ptil *mod . 65 :0 59.0. 81 . PROJECT FIG. BY 4' le 5dt -"Ted 0F /q Coo 57 a 5/7472., e✓ GB - 48 -� Y ')'4771 ;IF \/ F /Q(4 BE&C ENGINEERS P.O. Box 3707 Seattle, Washington 98124.2207 Mail Stop: B NO CHECKED BY DATE / 2 ' 9 / SHEET_ OF_ tro ds' ftY,a'f 1.01 ri---1_ II( c k% �. 44_4_ A4 C ZOO/ / ; 1 z Z y-t Rc''T. 4'A pair CNeezi srer- 01,6 /4440 /7.4 sowers" 00(4.1 SUMMARY R. A. = C FM CHECK FIGURES SF/ TON c SF T,1 O.A. = CFM S.A //F 0 CFM EX11 AIR 0 CFM O.A. / /.A. = • REF EQUIP s TONS SHEET DATE PREPARED BY NAME OF JO ' LOCATION SPACE USED F R �\ ,3a x 30 . EM AREA OR QUANTITY GLASS GLASS GLAss GLASS ;KYLIGHT Sou WALL WALL WALL WALL OOF —SUN '00E—SHADED TRA ALL GLASS ARTITION :EILING LOON NFILTRATION INTERNAL HEAT EOPLE PEOPLE X 02 CO OWER HP oR KW X r / WATTS X 3.4 X v / ( nCES. ETC. S,c-G: 477.4a e) DDITIONAL HEAT GAINS rORAGE AFETY FACTOR 'PPLT .CT (AT GAIN % UTDOOR AIR EFFE AFILTRATION EOPLE TEAM •PLIANCES. E 1DITIONAL HE APOR TRANS. ■FETY FACTOR JPPLY DUCT IT000R AIR .E: TENT: TUNE CY AT GAIN E 1 / OFFIC AIR CONDITIONING I D ESTIMATE •::•:� BE &C ENGINEERS MC. /2-F-97 JOB NO. 625 Andover Park West Tukwila. Washington 98188 R & TRANS. GAIN —WALLS b ROOF So FT X x SOFTX X SOLAR GAIN—GLASS SoFT SOFTX SoFTX SoFTX SoFTX So FT x SOFTX So FT x 50 FT X NS. GAIN — EXCEPT WALLS v ROOF SO FT X X 12 at, SUPPLY DUCT } LcAK• Loss C. T GAINS SO FT X So FT X So FT X CFM X SO FT X So FT X 1/100 X /04, SeFTX SUN GAIN OR TEMP. DIFF. • X lo x _47) LEAKAGE LOSS RETURN DUCT % + LIAR. GAIN CFM X Gm/Ls X FACTOR x Sus TOTAL X (— SUS TOTAL ROOM SENSIBLE HEAT • FAN % + H. P. % IF X 1.01 CFM X F x CTIVE ROOM SENSIBLE HEAT • LATENT HEAT CFM X Gm/Ls X 0.55 0■ P1011.1 X ,Q .S o LN /HN X 1050 Gs/Le X SUS TOTAL X ROOM LATENT HEAT IF X 0.511 EFFECTIVE ROOM LATENT HEAT FECTIVE' ROOM TOTAL HEAT .OUTDOOR AIR HEAT NO 0 4, CFM X F X (1 CFM X GR/L1 X (1 — BF) X l.os BF) X o. /5 Sus TOTAL 01NVN. A % + PIPE Loss % NP % + Purr GRAND TOTAL HEAT R ESTIMATE FOR Cu FT BTU /HOUR 4 Lou 0 twomMI HOUR / OF OPERATION CONDITIONS OUTDOOR (OA) Room (RM) DIFFERENCE VENTI• LATION INFIL- TRATION ESHF ADP TEMP. RISE DEHUM OUTLET TEMP. DIFF. SUPPLY BYPASS EDB LOB EFFECTIVE SENS HEAT = FACTOR T -1• DB OUTDOOR AIR PEOPLE X CFO /PERSON So VT X CFM /So FT CFM VENTILATION II SWINGING REVOLVING DOORS OPEN DOORS EXHAUST FAN CRACK CFM OUTDOOR INDICATED ADP = F SELECTED ADP DEHUMIDIFIED AIR QUANTITY (1— BF) x (T F — TAD, F) EFFECTIVE ROOM SENS. HEAT 1.08 X F TEN►. RISE 1.08 x 1.08 X CFM SA — LOCAL TINE ( SUN TINE PEAK LOAD WB x xx PEOPLE X Dooes X' % RH xxx FEET X Cry /FT CFM INFILTRATION ■ AIR THRU APPARATUS - APPARATUS DEWPOINT EFFECTIVQ MOON SENS. H EFFECTIVE ROOM TOTAL H Room SENS. HEAT CFM OA SUPPLY AIR QUANTITY ROOM SENS. HEAT F DESIsto oIPI CFMOA = (4 ner45,1? t✓rc d �� DP x x X CFN /PERSON CPM DOOR FINN RESULTING ENT 6 LVG CONDITIONS AT AP GEN CFMt X (T —F TAD -1- _ —BF X ( T[DN --F — T FROM PSYCH. CHART: T F T LWI F •I/ 5111 AT 11 5O1 NINR. III IIIPIT CIO 101 11*11115 101NVLA. NINON 151* /111 A N111V11 01 OV1 /001 AmI 111111 AII, VII CIN. ■MEN 11PA11111 111111 All 05L1, VII 01NVN1 /111 CAM. AT LOCAL TINE RUN TINE GR /Ls CFM O EAT — _F CFMDA — OUTLET AIN) �, NOTES VeCe c 'in--- _L3 4/ F CFM IA CFM NA PARATUS ) = T cD1 —F TLDs —F 1 11 E1 1115 III PREPARED BY: G. STRATTON TELEPHONE: 393 -2107 OTY LAYOUT VENDOR MODEL VOLT PH AMPS KVA /EA HERTZ RECEPTACLE BTUH A EA BTUH it EA ED DIM WEIGHT EA HUMIDITY TEMPERATURE REMARKS CODE DESCRIPTION KVA /TOT CONNECTOR BTUH A TOT BTUH V TOT INCHES WEIGHT TOT 70 A01 IBM 3174 -011 203 1 2.4 0.49 60 RS 3913U2 CONTROLLER - CHANNEL ATTACHED 34.30 60 A02 BTH 710E 120 1 0.3 0.04 5 -15R SWITCH DEVICE 2.40 A03 SYO 3000 120 1 .3 0.00 60 :REMARKS: LATTISNET CONCENTRATOR 0.00 1 A04 FAR FM B92 120 1 .0B 0.01 60 MULTIPLEIER 0.01 2 A05 XYP 5000 TERMINAL SERVER .:..� GENERAL NOTES: OTHER SPECS: TOTALS • (I) 4*Jo9i -4 36cc c.AR:aal) ( &.) 6AprEzi4 5 ((i I tj I � Ag,Ne 3G G f L ( (M gqZ MIJi 11 E az c At3,tJE i) (4 ) r3,ti�} I1 L1 ti�ZcL = 5 r� I c c� FACILITIES HARDWARE DATA SHEET SYSTEM: IDF ROOM ##2 LOCATION: 9- 101.2 AREA E 120 1 2.30 0.20 60 0.40 37.11 5 -15R 42 0 H 3 5 470*--- 0 W 13.25 5 D 7.5 5 -15R ACi 450 0 31500 0 123 73 .e-- 225 675-- 100 39797 574c 4 S/Y-/ 3 i � Pc-it . r H 140 9800 D 0 H 0 201-801 50 -104F 0 W 0 D 0 H 0 0 W 0 D 0 H 4.6 0 20 -BOX 50 -110F 0 W 19.3 0 D 12.6 9805 DATE: November 25, 1991 PAGE 1 OF 1 BCS FR #: EEIP 20Z -80X 60F -90F ALSO AVAILABLE: WITH UNDERFLOOR W GHT RECEPTACLE-RS 3743U2. 20X -80X 50 -104F POWERED FROM EOM CDT POWER SUP? 87.-80Z 50E-110F / ((IV we - 5 s ,r (N0 ♦TOF)', / 1 BCS FACILITIES HARDWARE DATA SHEET PREPARED BY: G. STRATTON. SYSTEM: IDF ROOM #2 TELEPHONE: 393 -2107 LOCATION: 9- 101.2 AREA E QTY LAYOUT VENDOR MODEL VOLT CODE DESCRIPTION 70 A01 IBM 3174 -011 CONTROLLER - CHANNEL ATTACHED 60 A02 BTH SWITCH DEVICE 1 A04 FBR MULTIPLEXER 2 A05 IYP 5000 TERMINAL SERVER GENERAL NOTES: OTHER SPECS: A03 SYO 3000 LATTISNET CONCENTRATOR 710E 120 1 0.3 0.04 2.40 FM 892 120 1 .3 0.00 60 0.00 120 1 .0B 0.01 60 0.01 i26w (1) 4 yt,=one.er 3 to (1 4:061Aii GAf5,Ner6) 120 1 2.30 0.20 60 0.40 TOTALS 37.11 ( & ) ) !AY e , >J (O ( M sqZ Mt) -fl aaz (i C:3,,JEi') (40) x'74 ec> 64c -A (1,1 , - PH AMPS KVA /EA HERTZ RECEPTACLE BTUH A EA BTUH N EA EO DIM KVA /TOT CONNECTOR BTUN A TOT BTUN N TOT INCHES 208 1 2.4 0.49 60 RS 391302 450 34.30 31500.= - 0 c 0);3 /kierM) 5 -15R 123 7320.e -- *REMARKS* 225 675s --� 5 - 15R 42 4:d- -- 5 -15R 100: mot _ :.20Q4 H W D 0 N 0 W D 0 0 W D 0 N3 0 W 13.25 D 7.5 0 H 4.6 0 W 19.3 D 12.6 54 * d DATE: November 25. 1991 PAGE 1 OF 1 PCS FR #: EEIP WEIGHT EA HUMIDITY TEMPERATURE REMARKS WEIGHT TOT 140 20X -80% 60F -90F ALSO AVAILABLE WITH UNDERFLOOR WATER TI 9800 6HT RECEPTACLE-RS 374302. 9805 0 201 -80X 50 -104F 0 0 20X -80X 50 -104F POWERED FROM COMM CBT POWER SUPPLY 0 5 8X -80Z 50F -110F 5 0 20 -80X 50 -110F • 0 P w, ( (I ,CCU ; ) 4)) 5 f S rr1 /& , frr v AKu Utz It.vL,', Ag z E t too t,.;2 E. ci PROJECT ~ • k ) t L. E 9`(J I 2 5• oss FIG. BY Z. U �) R ; R VA LME L� W ALE CHECKED BY - BE&C ENGINEERS YR, Moe DATE Cz, t- s - 1 AttE. C c JOB NO 90 (3 - (t7 -c.) 16/17/9 I P.O. Box 3707 Seattle, Washington 98124.2207 Mail Stop: = I(40 .23 o, c: (b. te.:Au o :. ti 4^ P K - vt\ v t. t1.4.tx-..c>kFtL-M O " z K,E CNKC (0.0ezS) OU=cstt) FILM o , t7 = 1 5.33 u k; I O, �( �+ ` : WTU Ho z T' Cl 1:1 SCYI (SM ,k) SHEET OF • PROJECT F' E I "1 v FIG, By :15, *., C CHECKED BY DATE I° /17 ( SHEET_ 7 OF— X•23771 A:15V. 5/90 C 17: LO 11417xlic_. T1 , — 5 ( 0,08) • ' ' LA -= BE&C ENGINEERS - JOB NO. ( — 4 -1 k.mov..x: ...mom. • .••• • • • • • •••■•■ ' t N' • 7 ) t 0 - Tc) 1.Z.• 'IL'-A 15- •. F‘ R"' Lj 1 $;:c 17 0 1 • • 6 1 /P .coe) , I , P.O. Box 3707 Seattle, Washington 98124.2207 Mail Stop: IDF ROOM LOCATION EEIP PHASE 3E Model CEMC - I 03 P `�05. 75 10C 12 _ 15 20 25 30 Net Cooling 72° DB /50% R.H. ENT. AIR Total MBH 36.6 F..'43:53.3 M- 93.4 115.6 140.6 175.8 242.9 281.2 351.6 Sensible MBH 33.1 ;=4-r 53.3.0'= 83.7 110.4 126.7 152.6 208.3 253.4 305.2 Net Cooling 72° DB /45% R.H. ENT. Air Total MBH 34.1 1. 53.31 84.3 102.6 127.6 154.0 211.5 255.2 308.0 Sensible MBH 34.1 0,83.04: 84.3 102.6 127.6 154.0 211.5 255.2 308.0 Net Cooling 75° DB /50% R.H. ENT. Air Total MBH 42.2 ':66.8 106.8 132.9 161.3 202.2 280.0 322.6 404.4 ible MBH 36.1 58.i � 91.1 109.9 137.6 165.4 225.7 275.2 330.8 Chilled Water Flow Rate 45° E.W.T - GPM 7.2 iR 4.42 Y; "' 18 25 32 36 50 64 72 Pressure Drop si/FT.O es p p 8.3/19.0 " 6.5/1 ... 6.5/15.0 6.0/13.8 7.9/18.2 8.3/19.0 8.1 18. / 5 7.9/18.2 8.3/19.0 Airflow - Nominal CFM at 0.5" E.S.P. 1750 2900M 4350 5000 6600 7500 10,000 13,500 15,000 Blower Motor(s) HP 1 *: = 4 11 2 3 3 5 (2) @ 3 (2) @ 5 (2) @ 5 Motor(s) F.LA. @ 460V 1.7 f 2.3f4,:i 3.1 4.0 4.0 0 6.7 0 8.0 13.4 13.4 Coil Face Area - SQ. FT. 3.3 :: - 5.5 8.1 9.1 12.0 13.7 18.3 24.0 27.3 # of Rows/Fins per Inch 5/8 15/8. i" 5/8 6/12 5/12 6/12 6/12 5/12 6/12 Standard Electric Humidifier0- LBS/H.R. 12.5 ' 112.5x . 12.5 12.5 12.5 12.5 25.0 25.0® 25.0® Humidifier F.L.A. @ 46OV 5.0 : '-.5.0 = 5.0 5.0 5.0 5.0 10.0 10.7 10.7 Standard Electric Reheat - MBH® 23.4 24.8:Y -: 27.3 29.2 48.5 56.0 59.0 96.9 117.4 Standard Electric Reheat - K.W. 6 ; _it 6. ' 6 6 12 12 12 18 24 Reheat F.L.A. @ 460V 7.5 . . - .5:'_. 7.5 7.5 15.0 15.0 15.0 22.5 30.0 Unit Max. F.LA. Mode ' ' ; ' _ Dehumidification with Standard Electric Reheat Unit Max. F.LA. @ 460V0 9.2 1 :: 9.8 . I 10.6 11.5 I 19.0 I 21.7 I 23.0 I 35.9® I 43.4 Physicial Dimensions - Inches Modules are 34" Wide x 73" High00 Length - Single Cabinet 39 ' 39 • ' 53.5 53.5 77 92 106 106 106 Length - Split Cabinet N/A N/A N/A N/A 53 +39 53 +39 53 +53 77 +39 77 +39 Approx. Crated Weight - LBS. 820 : `. 875 - 1020 1110 1510 1580 1740 1940 2040 Chilled Water Conn. (2) - F.P.T. 1" - :1" ;" 1 - 1 -1" 1 -1/2" 2" 2" 2" 2 -1" Chi ed Water Module P formance Data Notes: 0 All F.L.A.'s based on 460V/3 ph/60 Hz. service, to obtain approximate F.LA. at other voltages use the following: x 2.2 @ 208V., X 2.0 @ 230V., X 0.8 @ 575V. 0 Pressure drops are for valve + coil combined 0 Models 25 +30 equipped with electronic cyclinder type humidifier Q Includes blower heat 0 Split systems: Add 0.6A on model 12, add 1.3A on model 15 0 Upflow plenum unit height, add: 10" for up to Model 20, 22" for Model 25, 24" for Model 30 0 Model 25 +30 upflow units are 44" wide 0 See floor plan drawing for connection sizes and location 25.2387(5/1/87) FILTERS QTY SIZE 1 16x25 1 20x25 NOTES: 1 ALL DIMENSIONS IN INCHES 2 ALL DECORATIVE PANELS ARE 9fe" THICK 3 FRONT AND RIGHT SIDE ACCESS REQUIRED • ( O tNTI (MP O �a�caa�IERH�c� UNIT OF ZERO C OR PO RATION TITLE: MODEL 03 AND 05 FREE /DUAL COOLING SYSTEM DOWNFLOW MODULE DRAWING No.: B Y : 25 -4343 D•C. DATE: 1 -1 -87 REV DATE: JOB No.: BY-PASS REGULATING VALVE COIL 1 AIRFLOW 0 TITLE: 1110=1 11■11.. CONTEMPO ENG INEERING UNIT O C ORPORATION PIPING BY CONTEMPO 4 UNIT BASEPAN PIPING BY OTHERS TYPICAL CHILLED WATER PIPING SCHEMATIC DRAWING No.: IJOB No,: 25- 4166 B Y DATE: REV OATE: 2-14 -80 6- 29-87 CJ PROJECT 1 I$1 s 3C • 9.10/ /4 FIG. BY 4' CHECKED BY 0 - yc• 4 :v / Jr jR,,,vrc BE&C ENGINEERS JOB NO. DATE /. s.77/it er c/ ✓'" ,VZ W Z# L A-cog o / 4 41VS ,('5•#'t' S s44wr4s Z4s wetri s. sit STamee ,c z;74 .: 2. 5774 * -fir' - Z 0'b ,* /av = zoo (4 L P.O. Box 3707 Seattle, Washington 98124.2207 Mail Stop: /Z .2_ T f SHEET.___ OF _... 4 r %t Ze - ""Pea-7.14#vi �t S : 4/4r fit sett ,44:4 761 es) t.r 4.1e-ex- 7774 4- X78 ap t'',Abl r 1t . S to :: .34 serr.., •��G' <r4/ .54 - /00 r,'Pd .4. /.e ° Irn .f .vb Caf = /. ` 7 •.*i / der. % se? x Svo : 85 loss o4 ,/oft/ •.S 0 . ..D,:;'m /I,4 diroveiTe 401 TS" 7 / s 4. /1 -� �t �E• s / , i#C. Cry �o (S.) S/Lrwts a 30 (/4)4vs et Z. : 45 C ' t ) s, Soy ieS C ZO 40 (4) w. /ri ✓w_ . e /0 a � �. _ s•wK 0 Zo - iv Or) siA,00.1-fur 4 ?eg-v te-)n ftv-s r ikoLocit-S 4 &Do0,4, ■NI4544 1. S cout 1 3_ , k vc "-y 54.14 I. Basins, private lavatory 2. Basins, public lavatory 3. Bathtubs 4. Dishwashersa 5. Foot basins 6. Kitchen sink 7. Laundry, stationary tubs 8. Pantry sink ,9. Showers 10. Service sink Table 7 Hot Water Demand per Fixture for Various Types of Buildings (Gallons (litres) of water per hour per fixture, calculated at a final temperature of 140 °F (60 °C)I I I. Hydrotherapeutic showers 12: Hubbard baths 13. Leg baths 14. Arm baths 15. Sim baths 16. Continuous flow baths 17. Circular wash sinks 18. Semicircular wash sinks 19. DEMAND FACTOR 20. STORAGE CAPACITY FACTORb Apartment House 2 (7.6) 2 (7.6) 4(15) 6(2 20 (76) 20 (76) 15 (57) 50.150 (190.570) 3 (11) 3 (11) 10 (38) 20 (76) 2(1 (76) 28 (106) 5 (19) 10 (38) 30 (114) 150 (568) 10775) - 20176) 0.30 Club 0.30 0,40 1.25 0.90 1.00 flow control valves are recommended, since they reduce the flow rate and maintain it regardless of fluctuations in water pressure. The manufacturer's maximum flow rating can usually be reduced up to 50% without adversely affecting the spray pattern of the shower head. Flow control valves are commonly available in sizes from 1.5 to 4.0 gpm (94 w 250 mL /s). If the manufacturer's flow rate for a shower head is not available and a flow control valve is not used, the following will serve as a guide for sizing the water heater: _ Small shower' head: 2 to 3 gpm (130 to 190 tnL /s). Medium shower head: 4 to 6 gpm (250 to 380 mL /s). Large shower head: 7 to 9 gpm (440 to 570 mL /s). Food Service In a restaurant, bacteria are usually killed by rinsing the washed dishes with 180 to 195 °F,(82 to 90 °C) water for several seconds. In addition, an ample supply for general purpose hot water, usually 140 to 150 °F (60 to 65 °C), is required for the wash cycle of dishwashers. Although a water temperature of 140 °F (60 °C) in private dwellings is reasonable for dishwashing, in public places, sanitation regulations by the National Sanitation Foundation make 180 to 195 °F (82 to 90 °C) water mandatory in the rinsing cycle. However, the National Sanitation Founda- tion allows lower temperatures when certain types of machines and chemicals are used, Because of the two - temperature need, the hot water requirements for food service establishments pre- sent special problems. The lower temperature water is distributed for general use, but the 180 °F (82 °C) water should be confined to the equipment requiring it and should be obtained by boosting the temperature. It would be dangerous to distribute 180 °F (82 °C) water for general use. NSF Standard 26 -80 covers the design of dishwashing machines and water heaters used by restaurants. The American Gas Association has published a recommend- ed procedure for sizing gas -fired water heaters for restaurants that consists of determining the following: 1. Types and sizes of dishwashers used. 2. Required quantity of general purpose hot water (manufac- turers' data should be consulted to determine the initial fill requirements of the wash tanks). 3. Duration of peak hot water demand period. CHAPTER 54 Industrial Gym- nasium Hospital Hotel Plant C0h/il►ry / 1987 HVAC Handbook Office Private Building Residence School YMCA 2 (7.6) 2 (7.6) 2 (7.6) 2 (7.6) 2 (7.6) 2 (7.6) 2 (7.6) 2 (7.6) - 15 (57) 8 (30) 20 (76) - 30 (t 14) 15 (57) 20.100 20.100 (76-380) (76.380) - 3 (11) 3 (11) 12 (46) 20 (76) 10 (38) 20 (76) 20 (76) - 20 (76) - 28 (106) 10 (38) 5 (19) 10 (38) 10 (38) 225 (850) 75 (284) 75 (284) 225 (850) 30 (114) 30 (114) 225 (850) 225 (850) - 20 (76) 0 (76) 15 (57) 20 (76) 20 (76) 30 (114) 20 (76) 20 (76) - - 50.150 50.200 20.100 (190-570) (190.760) (76-380) 12 (46) 3 (11) 3 (I I) 12 (46) - 20 (76) 30 (114) 20 (76) - 28 (106) 28 (106) - - 10 (38) 10 (38) - 400 (1520) 600 (2270) 100 (380) 35 (130) 30 (114) 165 (625) 20 (76) 10 (38) 0.25 0.60 20 (76) 10 (38) 0.25 0.80 30 (114) 20 (76) 15 (57) 10 (38) 0.40 1 0.30 1.00 2.00 0.30 0.70 30 (/ 14) , 15 (57) 0.40 0.40 1.00 1.00 r aDishwasher requirements should be taken from this table or from manufacturers' data for the mod el to be ued, if this s known. bRatio of storage tank capacity to probable maximum demand /h. Storage capacity may be reduced where an unlimited supp y of steam is available from a central street steam system or large boiler plant. 4. Inlet water temperature. 5. 'type and capacity of existing water- heating system. '! 6. Type of water - heating system desired. Equation (4) may be used to size the required heater(s) after allowing for the quantity of hot water withdrawn from the storage tank each hour. The general purpose and 180 to 195°F 1 I d n it f' u is Legionella Pneumophila ( Legionaires' Disease) The bacteria that causes Legionaires' Disease has been discovered in the service water systems of various buildings in this country and abroad. Infectation has often been traced to Legionella Pneumophila colonies in shower heads. Ciesielki et al. (1984) determined that the Lejionella Pneumophila can col- I onize in hot water systems maintained at 115 °F (46 °C) or less. i Unrecircufaied segments of the service water systems provide ideal breeding locations, e.g., shower heads, faucet aerators, and uncirculaied sections of storage type water heaters. — To liiiijjtThe potential of Legionella Pneumophila growth, ser- vice water temperatures in the 140 °F (60 °C) range are recom- mended. This high temperature, however, increases the poten- tial r scalding, so care must be taken. Supervised p re iodic flushing of fixture heads with 170 (76.6 °C) water is recom- mended in hospitals and health care facilities, since already weakened patients are generally more susceptible to infection. Utilization Temperatures Typical temperature requirements for some services are shown \ in Table 3. In some cases, slightly lower temperatures may be satisfactory. Service Water Heating or nonferrous alloys may be considered but should be compati- ble with the elements in the water. Extreme caution should be taken with stainless steel in the presence of chlorides or with copper in the presence of ammonia or CO Many water heating applications (such as a laundry or car wash) require water supplies relatively low in hardness. If water is naturally hard, water treatment is recommended for satisfactory final results (see Chapter 53). Table 3 Representative Hot Water Utilization Temperatures Use SPECIAL CONCERNS Lavatory Hand washing Shaving Showers and tubs Therapeutic baths Commercial and institutional laundry Residential dishwashing and laundry Surgical scrubbing Commercial Spray Type Dishwashing as required by N.S.F. Single or multiple tank hood or rack type Wash Final rinse Single tank conveyor type Wash Final rinse Single tank rack or door type Single temperature wash and rinse Chemical sanitizing types (see Manufacturer for actual temp. required) Multiple Tank Conveyor Type Wash Pumped rinse Final rinse Chemical Sanitizing Gtasswasher Wash Rinse Temperature °C 105 40 115 45 110 43 95 35 180 82 140 60 110 43 150 min. 65 min. 180 to 195 82 to 90 160 min. 71 min. 180 to 195 82 to 90 165 min. 74 min. 140 60 150 min. 65 160 min. 71 min. 180 to 195 82 to 90 ' 140 60 75 min. 24 min. 54.7 Hot Water from Tanks and Storage Systems With storage heaters, it is common to assume that 60 to 80 of the hot water in a tank is usable before dilution by cold water lowers the temperature below an acceptable level. Thus, the hot water available from a self- contained storage heater is usually considered to be: Q,= R +MS, /d — (1) where Q, = available hot water, gph (L /s) R = recovery rate at the required temperature, gph (L /s) M = ratio of usable water to storage tank capacity S, = storage capacity of the heater tank, gal (L) d = duration of peak hot water demand, h (s) Usable hot water from an unfired tank in gal (L) is calculated from: Q = MS„ (2) where Q = usable water available from an unfired tank, gal (L) S = capacity of unfired tank, gal (L) -_ NOTE: Assumes tank water at required temperature. ' Hot water obtained from a water - heating system using a storage heater with an auxiliary storage tank can be determined by: Q dQ, +Q R•d +M(S, +S (3) where Q. = total hot water available from system during one peak, gal (L) CODES AND STANDARDS Codes and standards that have special significance to water heating applications follow. ANSI Z- 21.10.1 -84. American National Standard for Gas Water Heaters, Volume I: Automatic Storage Water Heaters with In- puts of 75,000 Btu per Hour or Less. (Also AGA 1631- 0008.) ANSI Z- 21.I0.3 -84. Gas Water Heaters, Volume III: Circulating Tank, Instantaneous and Large Automatic Storage Water Heaters. (Also AGA 1631- 0110.) ANSI Z- 21.56 -83. Gas -Fired Pool Heaters. ANSI Z- 21.22 -79. Relief Valve and Automatic Gas Shutoff Devices for Hot Water Supply Systems. UL 174 -83. Household Electric Storage Tank Water Heaters. UL 1453 -82. Electric Booster and Commercial Storage Tank Water Heaters. UL 1261 -81. Electric Water Heaters for Pools and Tubs. UL 732 -74. Oil -Fired Water Heaters. ASME Boiler and Pressure Vessel Code Section IV (H and HLW) Code Construction. H label governs low pressure heating boilers, and HLW label governs low pressure, fired, potable hot water heaters. ASME Boiler and Pressure Vessel Code Section VIII. U label governs unfired water heaters and pressure vessels. (Note: Some states, cities, and counties require ASME- stamped equipment.) NFPA Standard 54 -84 (ANSI Z223.1- 1984). National Fuel Gas Code. Governs installation of gas -fired water heaters. NFPA 31 -83. Installation of Oil Burning Equipment. ANSI Standard 119 governs water heating installation in mobile homes and recreational vehicles. ASH RAE Standard 90 and 100 series provide recommended guidelines for energy conserving design for service water heating. ASPE publishes a data book on plumbing and service water heating. ao no 6t1M5Ta Designed for use as a recovery heater having its own storage tank or booster for supplying sanitizing rinse water for dishwashing. FEATURES ASME TANK CONSTRUCTION — 125 psi working pres- sure (65 thru 120 gallons), 150 psi working pressure (5 thru 50 gallons). R -16 FOAM INSULATED - To meet rigorous state codes. GLASS -LINED TANK — Ten tank sizes available; 5 to 120 gallon capacity. Tank interior is coated with glass specifi- cally developed for water heater use. Tank cabinet has bonderized undercoat with baked enamel finish. INCOLOY IMMERSION HEATERS — Heavy -duty medium watt density elements (three /immersion heater) have incoloy sheathing and prewired leads: provide excellent protection against oxidation and scaling. Input ranges from 6KW to 54KW available (see accompanying chart). STANDARD VOLTAGES — 208, 240 and 480 volt single and three phase. Single phase 208 and 240 volt are con- vertible to three phase, 208 and 240 volt at 24KW and below are phase convertible (three to single and vice versa). 277 volt single phase also available. MEETS OR EXCEEDS THE REQUIREMENTS OF ASHRAE 90A -1980 STANDARD FOR ENERGY EFFICIENCIES ASME TERMINAL BLOCK • To accept copper or aluminum conduit. IMMERSION THERMOSTAT — Close differential immer- sion type thermostat provides the accurate temperature control required for commercial applications (adjustable through a range of 95° to 180 °F). 120 VOLT CONTROL CIRCUIT — 120 volt control circuit powered by fused transformer. MAGNETIC CONTACTORS — Heavy -duty UL rated for 100,000 cycles. POWER CIRCUIT FUSING (120 amp current draw and above) — Meets National Electric Code and UL require- ments that ASME tanks must have internal fusing when current draw exceeds 120 amps. ICJ Li Ira - I'v)wer SUPREME COMMERCIAL E WATER HEATERS DSE -5 thru 120 OTHER STANDARD FEATURES • Simplified circuitry, color coded for ease of service • Anode rod for corrosion protection • Manual reset high limit • Brass drain valve • Hinged control compartment door • ASME T & P relief valve, LIMITED WARRANTY OUTLINE If the tank should leak any time during the first three years, under the terms of the warranty, A. 0. Smith will repair or replace the heater; installation, labor, handling and local delivery extra. THIS OUTLINE IS NOT A WARRANTY. For complete information, consult the written warranty or A 0. Smith Water Products Company. STANDARD KW INPUT BTU / HOUR 30 40 50 60 70 80 90 100 110 120 130 140 3 10,239 41 31 24 20 17 15 13 12 11 10 10 9 6 20,478 82 62 49 41 35 31 27 25 22 21 19 18 9 30,717 123 92 74 62 53 46 41 37 34 31 28 26 12 40,956 164 123 98 82 70 61 55 49 45 41 38 35 15 51,195 205 154 123 102 88 77 68 61 56 51 47 44 1 18 61,434 246 184 148 123 105 92 82 74 67 62 57 53 24 81,912 328 246 197 164 140 123 109 98 90 82 76 70 30 102,390 410 308 246 205 176 154 137 123 112 103 95 88 36 122,868 492 369 295 246 211 184 164 148 134 123 113 105 45 163,585 615 461 369 307 263 230 205 184 168 154 142 132 54 184,302 738 554 443 359 316 277 246 221 201 185 170 158 t A. O. Smith Model Nominal Gallon Capacity Maximum KW Input Maximum Number of • Immersion Heaters Height A Width (Dia.) B Depth C D Inspection Opening Inlet Outlet Opening Relief Opening Approx. I Ship. Wt. (Lbs.) DSE -5 5 3 1 201/2 161/4 211/2 51/4 Optional 4" x 6" 3/4 3/4 82 DSE -10 10 6 26 1/4 18 3/4 24 5 1/4 106 DSE -20 20 18 2 27 1/4 20 1/2 27 5 3/4 130 DSE•30 30 24 35 3/4 20 1/2 27 5 3/4 150 DSE-40 40 36 453/4 201/2 27 53/4 190 DSE -50 50 45 3 54 3/4 20 1/2 27 5 3/4 221 DSE-65 65 54 50 1/2 24 1/2 30 1/4 7 1 1 /4 267 DSE-80 80 54 49 1/4 26 1/2 32 1/4 7 285 DSE -100 —' 100 54 58 1/4 26 1/2 32 1/4 7 354 DSE -120 119 54 63 1/4 28 33 3/4 7 1/2 420 DRAIN VALVE ALL DIMENSIONS IN INCHES A 202.2 DSE -5 thru 50 i oa 3/4 NPT / OUTLET. 3/4 NPT RELIEF VALVE OPENING INLET HI -LIMIT ACCESS FIELD WIRE ENTRANCE HINGED ACCESS DOOR 3/4 NPT INLET ac h immersion heater contains three electric elements • Figured at 1 KW (3413 Btu) - 4.1 Gallons at 100 ° F temperature rise. To determine recovery rate per minute, divide recovery rate per hour by 60. NSF ratings maybe obtained by multiplying above figures by 0.98. 1) DSE -65 thru 120 e t . CRAIN VALVE 1 V4 NPT - OUTLET �� L4 NPT RELIEF VALVE OPENING INLET FIELD WIRE ENTRANCE RECOVERY RATE IN GALLONS PER HOUR• — Temperature Rise ° F 0 HI-LIMIT ACCESS HINGED ACCESS DOOR 1 1/4 NPT INLET • e ) Standard KW Immersion Heaters•• Number of 50A Contactors Full Load Current in Amperes Single Phase Three Phase Ratings No. of Wattage 208V 240V 480V 208V 240V 277V 480V 208V 240V 480V 3,000 14.4 12.5 10.8 6.3 8.3 7.2 3.6 6,000 1 28.8 25.0 21.2 12.5 16.7 14.4 7.2 o) 9,000 1 43.3 37.5 32.5 18.8 25.0 21.7 10.8 12,000 1 57.7 50.0 43.3 25.0 33.3 28.9 14.4 15,000 72.1 62.5 54.2 31.3 41.6 36.1 18.0 18 •1 18,000 86.5 75.0 65.0 37.5 50.0 43.3 21.7 24 2 12,000 2 115.4 100.0 86.6 50.0 66.6 57.7 28.9 30 2 15.000 2 144.2 125.0 108.3 62.5 83.3 72.2 36.1 36 •2 18,000 173.1 160.0 130.0 75.0 99.9 86.6 43.3 45 3 15,000 3 216.3 187.5 162.5 93.8 124.9 108.3 54.1 54 3 18,000 3 2 N/A 225.0 194.9 112.5 149.9 129.9 65.0 STANDARD -KW INPUTS •208V models use one additional immersion heater. ••Each immersion heater contains three electric elements. piping diagrams FUSED DISCONNECT SWITCH THERMOMETER UNION WATER OUTLET 'TEMPERATURE AND PRESSURE RELIEF VALVE TO OPEN DRAIN 'PIPE TO OPEN DRAIN INSTALL IN ACCORDANCE WITH ALL LOCAL CODES TWO TEMPERATURE WITH MIXING VALVE CHECK VALVE TSD°F RATER OUTLET TEMPERED WATER OUTLET MIXING VALVE FUSED DISCONNECT SWITCH CONDUIT OPENING IT" TO 1S•" HINGED ACCESS PANEL SHUTOFF VALVE COLD RATER SUPPLY THREADED CONNECTION PREHEATED OR COLD WATER INLET L1 L • PIPE TO OPEN DRAIN UNION INSTALL IN ACCORDANCE WITH ALL LOCAL CODES ONE TEMPERATURE CIRCULATING LOOP TEMP. CONTROL (NEUTRAL) CIRCULATING PUMP WIRING DIAGRAM HOT WATER OUTLET • TEMPERATURE AND PRESSURE RELIEF VALVE SHUT VALVE DRAIN LINE RETURN LINE FROM CIRCUL• ATING LOOP (IF USED). THIS CIRCULATING LOOP CAN ALSO GE USED FOR THE 110°F LINE OF A Z TEMP SYSTEM W /MIXING VALVE ,., f • k:! CIRCULATING PUMP ALL BRONZE CIRCULATING 1 1 / LOOP C • ; dr ) T•T • • LINE TEMP I A. CON 1RDL i% 1 •' • CHECK �y % VALVE PLUG COCK n •or%'T 7 OPTIONAL EQUIPMENT & CONSTRUCTION: SILICON BRONZE TANK — Available for special applica- tions or very corrosive water conditions. STAINLESS STEEL TANK — Available for special applica- tions or unique water conditions. 150 OR 160 PSI WORKING PRESSURE — Available when required. Must be specified at time of order. HANDHOLE CLEANOUT — 4" x 6" size. COMBINATION TEMPERATURE /PRESSURE GAUGE — Dial type combination gauge (shipped loose ). CONTROL OPTIONS: LOW WATER CUTOFF — Probe type electric low water cutoff prevents energizing of elements in the event of low water condition. OVERRIDE SWITCHES — A simple form of load control allows all or part of unit input to be controlled manually. Up to one override switch per contactor is available. INDICATING /PILOT LIGHTS — For indicating element operation and /or switch closure. Up to one indicating light available for each switch and /or contactor is available. THERMOSTAT STEP — The simplest form of modulation. Allows elements to be stepped on in groups or individually by specifying additional thermostats (up to 1 per con- tactor). SUGGESTED SPECIFICATION SEQUENCER — Two or three step time delay sequencer provides for stepping of elements in groups or individually (maximum of 1 step per contactor). MODULATING STEP — Solid state electronic control device that modulates input to match load through progres- sive sequencing of steps (up to 3 steps with maximum of 1 per contactor). Contact factory for availability. TIME CLOCK — Seven day clock may be programmed for up to 14 on /off operations per week. Skip a day feature allows for weekend shutdown. IMMERSION RESET HIGH LIMITS — Adjustable auto- matic or manual reset type. Provides additional protection against high temperature conditions. Specify type and operating range. SAFETY DOOR INTERLOCK — Prevents opening of con- trol panel door when heater power supply is • ene gized. NOTE: Once door is open, the heater may be energized if necessary for service diagnosis. PRESSURE LIMIT SWITCHES — Both high and low pressure limit switches available. POWER CIRCUIT FUSING — Sub - divides internal circuitry with maximum of 60 amp fuses. Supplied as standard when required by NEC and UL. ALARM HORN — Horns may be furnished to warn of any condition in the heater for which sensors have been speci- fied. The heater shall be a glass -lined dura-power supreme commercial electric model No, as manufactured by A. O. Smith Corporation, Heater should be rated at KW volts phase, 50/60 cycle AC and constructed in accordance with ASME code shall bear appropriate symbol and listed with the National Board as required. Heater shall be listed with Underwriters' Laboratories and approved by National Sanitation Foundation. All internal surfaces of the tank shall be glass-lined with an alkaline borosilicate composition that has been fused•to•steel by firing at a temperature of 1600 Tank shall be cathodically protected with adequate extruded magnesium anode. The entire veSseel is to be enclosed in a round steel enclosure with baked enamel finish. Control compartment to be hinged and shall house 120 volt control circuit transformer, transformer fusing, magnetic contactorls), immersion style operating thermostat(s), element fusing per, N.E.C., and commercial grade incoloy sheathed flange mounted elements with prewired terminal leads, Temperature controls include limiting switch which will require resetting manually in the event the temperature reaches 190 ° F. Foam insulation, (R -16), shall exceed latest requirements of ASHRAE, (currently 90A•1980) for heat loss efficiency, Heater shall Include ASME T & P relief valve and drain valve. A, 0, Smith Water Products Company El Paso, TX A Division of A, 0, Smith Corporation A. O. Smith Corporation reserves the right to make product changes or Improvements at any time without notice. McBee, South Carolina Stratford, Ontario Seattle, Washington Veldhoven, The Netherlands • MECHANICAL MASTER HVAC SECOND FLOOR PLAN HVAC SECOND FLOOR PLAN i I BUILDING RELIEF FAN �I2A CONVERTER STATION #3 EXHAUST THIS DESIGN AND/OR SPECIFICATION IS APPROVED RECEIVED C fYOFTIiKWfA MAR 17 1992 I. ALL BUILDING FIXTURES AND MECHANICAL SERVICES ARE EXISTING UNLESS OTHERWISE NOTED. REMOVE EXISTING EXHAUST FAN MOUNT NEW ADAPTER CURB AND EXHAUST FAN. REMOVE OUTSIDE AIR PENTHOUSE AND CAP OPENING AS PER ARCHITECTURAL DRAWINGS. PENTHOUSE TO BE USED FOR EXTENDING OSA REMOVE EXISTING CAP OVER ROOF OPENING AND MOUNT NEW ADAPTER CURB AND RELIEF FAN, CHILLED WATER SUPPLY CHILLED WATER RETURN GATE VALVE, OPEN /CLOSED LIFT CHECK VALVE PIPE REDUCER BUTTERFLY VALVE -07/90 133 • . ":.. ✓.,.Y .�.::o =...,, __:. a .. ..�.:... ..:. * ^' ra»..tia».:.�.i.:+m : w. c,...,. 2a:: n;:+an.wa,�.na•ur."......x3. ":x �Afin.;.7: r'u:Y.iti�� ?& .F..9. ROOF PLAN RECEIVED F 7t tkWILA CITY n MAR 1.7.1992 PERMIT CENTER EEP PHASE flE MECHANICAL MASTER GENERAL NOTES I. ALL BUILDING FIXTURES AND MECHANICAL SERVICES ARE EXISTING UNLESS OTHERWISE NOTED. REMOVE EXISTING CAP OVER ROOF OPENING, AND MOUNT NEW ADAPTER CURB AND RELIEF FAN. [aEXTENO OUTSIDE AIR INTAKE PENTHOUSES FOR /1-412\ AND AH2 USING PENTHOUSE FROM ABANDONED AHU . SEE SHEET RM23 AND DETAILS CHILLED WATER SUPPLY .CHILLED WATER RETURN GATE VALVE, 'OPEN /CLOSED LIFT CHECK VALVE PIPE REDUCER BUTTERFLY VALVE POINT OF .CONNECTION REPLACE EXISTI 3 "CHWS AND CHWR TO AH2 AND / 74-42 \ WITH NEW 4" LINES, REFER TO SHEET 2M79. ACCEPTAB I L I TY THIS DESIGN ANO /OR SPECIFICATION IS APPROVED APPROVED BY LAST REVISION ' ,M EM &C Elieritianfla HVAC SECOND FLOOR PLAN ACCEPTABILITY OD STATIC PRESSURE SENSOR --� T -STAT LOCATED IN RETURN GRILL E. DIFFUSER (I) 90.''BLANK - OFF SE CIO DIFFUSER (2) 90' BLANK-OFF SECT I`Ott RECEIVED - CITY OF TUKWILA 1AR 17 199 - PERMIT CENTER MEDIUM PRESSURE EXTERIOR INSULATED SPIRAL DUCTWORK 2M2j510 �,..� MEDIUM PRESSURE NORTH /SOUTH DUCT HANGER. SEE DETAIL HANGER. SEE DETAIL 2M23 M510 BEAM CLAMP AND STRAP DUCT HANGER, SEE DETAIL 2M23 M5I0 MEDIUM PRESSURE 12xI8 ACCESS PANEL. SEE DETAIL PANEL. SEE DETAIL I. SIZE OF FLEX RUNOUT IS SAME AS'DIFFUSER NECK UNLESS INDICATED OTHERWISE. INSTALL EARTHQUAKE TABS (2 PER DIFFUSER)-ON ALL DIFFUSERS AND ATTACH WITH 12 GA WIRE TO UNISTRUT GRID. ACCESS PANEL ABOVE WYE OR ELBOW`' TYPICAL. CENTER AT KID PONT OF' DUCT DROP. CONSTRUCTION NOTES INSTALL ALL DUCTWORK .VAV'S, DIFFUSERS RETURN GRILLS FROM AHZ AS SHOWN. KEYPLAN NO SCal.£ COL Gt-J /II --I5 D.C. 2M23.M5f0 [&c EMBOWERS 0AKMO232 KHn / 03 Q4 ; 9 A% Y • Y ' SK =OAKB0232 BK =02,25.92 , . Rv s 1 ON RELItT'A11? REVISION Bbb EL O'-O AFF . SEE DETAI 2129 1 M5 12 r4 240 CFM rnwT (AH2 a1es.= V2 20 EL 10' -6'i NT AHU ACCESS LLTTTTiW aIU6 4 . 1110111 . 11 .AWL TTr 3 . 09 92 ir \540 CFMJ — 2 (2 .----- j_____ 'V*VVA V Vj'V WA V VVVj. £V4 . '-DUCT — 7 ACCESS E/ PANEL • 0 IOTHSIHCH 2 06 6Z BL L 9; 4 .T - ' EZ Iriit ,i i 1 H t 1 11 h 1 1 i h , l , 1 i u i1d idt ,uhi t e f •? - 1 ttttekee 7, — eaou 1I tai wtrs w0 r enea, an wsr 0•_ — wrew — — , .e — ., .w yr twan w yea raav ew .. — w ariw r w I51 i .a w _____ ! I . . p,- ;f S. . EXISTING 17x24 EXHAUST DUCT W1TH £JQAMLAI FLOOR O AUBURN, WA98OO2 O BELLEVUE ,WA . 98007 D EVERETT, WA. 98201 D KENT. WA. 98031 .0 PORTLAND, OR 97220 0 RENTON, WA.98055 UJSEATTLE, WA98i24 +. I � I ^ :.. (I I,' � , ._ I I i 1 �� i 1 �, � . � i 1r :.�:, I ,�: ::.� I}1� ,I, • _. 4 5 6 • 7 8. NOTE: • If the n1crof1Ied document is iesa clear than this notice, it 18 due to the quality of the original docment. ACCEPTABIL . THIS DESIGN AND/OR SPEC IFI GAT O?4 I s A1PR�VEO PPT . 1 DATE KRAMSEY IIILE BLDG 9.lOJ.2 -..' 0' ' RECEIVED CITY OF TUKWILA MAR 1 7 192 PRMT CENTE HVAC SECOND FLOOR PLAN EE' PHA8E 3E MECHANIGAL MASTER coi DJ/t5-2O STATIC PRES$URE SEN$QR:..»:: T-STAT LOCATED It j ITURN GRILLE DIFFUSER (1) 90' BLANKOFF SECTION DIFFUSER (2) 90 F3LANK-.OFF SECflQ RETURN GR1LLE INT-13ARCEL1NG FLEXIBLE DUCT WITH VOLUME DAMPER MEDIUM PRESSURE EXTERIOR INSULATED SPIRAL DUCTWORK LOW PRESSURE SOUNDLINED tUC1WRK VAV TERM 1NAL JJNIT MEDIUM PRESSURE EAST/WEST DUCT HANGER SEE DETAIL 4 2M2j5i0 . 1 MED 1 UM • PRESst)IE NORTH /SOUTH D(!CT HANGER. SEE DETAIL ,f7\ , 0 ' MEDIUM PRESSURE 12x18 "ACCESS. — PANEL. SEE DETAII.. 2M2j5lI - Lr 41 LOW PRESSURE 12x18 ACCESS , PANEL. SEE DETAIL /'\ GENERAL NOTES: 1 SIZE OF FLEX RUNOUT IS SAME AS DIFFUSER' NECK UNLESS INDICATED OTHERWISE 2 FOR VAV UNIT DUCTWORK, SEE DETAIL' 2M29 M5O ..- 3, FOR AHU DETAILS AND SECTION, SEE DETAILS4 2M29 M5 O 4 INSTALL EARTHQUAKE TABS (2 PER DIFFUSER) ON ALL DIETUSEPS AND ATTACH WITH I2 GA WIRE TO UNISTRUT GRID ACCESS PANEL ABOVE WYE CENTER AT M1DPON OF DUCT DROP j RUGUNQIj Ej::: INSTALL ACOUSTIC ELBOW SEE DETAIL 8 2M29 M51 1 INSTALL NEW AHU'S .ANDS WITH ALL DUCTWORK , VAV' S. DI 'FUSERS ,AND RETURN GRILLS AS SHOWN. iHWITH DUCTWORK 15 EXISTING AND TO REMAIN L:::;:. 1 NSTAL 1 NEW F 1 RE DAMPER AT F L OOR 1 EXISTING DUCT WITH 16 GA SLEEVE AND 'S -CLIPS ON TOP AND BOT1OM REMOVE MAN BARS AND INSTALL ACCESS DOOR ABOVE FIRE DAMPER. FIRE SEALDAMPER TO FLOOR WITH CEMENT GROUT 1.=-> COORDINATE DUCT LOCATION TO CLEAR ELECTRICAL FEEDER RISERS TO ELECTRICAL PLATFORM SEE ELEC DWGS 3E57 3E117 . 2M291 M510 2M2!M5l 0 2M2 M51 DATE BK=OAKO292 BK=O22692 1 I /4" D UP THRU I DF RM FLOOR. - I DF AREA ABOVE SEE SHEET M400 'UP FROM I RST FLOOR- SEE SHEET M551 FOR TOILET RM #5 PLUMB I I BOP 20 AFF • DRAIN FLOOR . BOP 20'-8"AFF BOP 2C-3'AFF MATCHLINE - FOR CONTINUATION SEE SHEET 2M79 1%1%1/2" TEE WITH PLUG --- NEW PIPING --- EXISTING PIPING - -- EXISTING ANCHOR FLOW DIRECTION --- CONDENSATE RETURN (STEAM) --- COMPRESSED AIR --- CONDENSATE DRAIN --- DOMESTIC COLD WATER --- HOT WATER (DOMESTIC) --- CHILLED WATER SUPPLY --- CHILLED WATER RETURN --- HEATING WATER SUPPLY --- HEATING WATER RETURN --- RAIN WATER LEADER --- STEAM SUPPLY --- VENT --- VENT THRU ROOF --- WASTE --- INDIRECT DRAIN , POINT OF CONNECTION 2 WAY BRACE, FOR DETAILS SEE C 2M7,3 GENERAL NOTE:S : 1. TOP OF FINI SHED SECOND FLOOR EL EVAT I ON I s AT 4O'6' ABOVE SEA LEVEL. 2 . ALL PIPING i S E X I S T I N G UNLESS NOTED OTHERW I SE . CONSTRUCT 1 ON NOTES: 1 . WORK WI THIN PHASE 3-E BOUNDARIES ONLY INSTALL S E I S M I C SWAY BRAC . i x > REROUTE E X I S T I N G 2 Ij2 CHILLED WATER L NES BELOW i DF ROOM. COORDINATE WI TH ELECTRICAL . . [3:b RUN 1 /2» CH 1 L ED WATER SUPPLY AND RETURN TO I DF ROOM AC U N I T P.- SLOPE 1 I/4" I D 1 4 , 4 / N I MUM I /8"/F T I N THE D RECT ION OF FLOW. RECEIVED CITY OF TUKWILA MAR 1 7 1992 PERMIT CENTER rh ACCEPTABILITY Y THIS DESIGN AND/OR SPECIFICATION IS APPROVED APPROVE.D BY TiiiTTITATE N7k)SSE 9 , 10 BK=OAKB0232 BK=02 27 . 92 OAKM0732 KHB/03. 01,1,:iNs REVISION BOP EL 17' -6" 2 "SAN DN THROUGH FLOOR SEE DWG NO. FROM ROOF AMMO 4 "STEAM VE CONNECT TO EXISTING V 4 "CI-IWS & R FROM ROOF EL 6I'-2" BOP EL 6I'-9" I " •DUPLEX OUTLET AND CONTROL AIR LINES, SEE - DETAIL 4 2M79 M509 AY' a AhVAV■VAV■■■■•■ ,Va7.O.X1M'IA.1AlLVAr'AY■ AYa i. 1 ' 423 N A OE a• ?Yw hxt,� ANCHOR 1/2" EXISTING I" DRAIN (COPPER), FOR CONTINUATION, SEE DWG 109 -10I- 4545 -M2 EXISTING I "CW (COPPER) REDUCED TO 1 /4'TUBING AFTER 1" VALVE ABOVE FLOOR LEVEL, FOR CONTINUATION SEE DWG 109 -101 -4545 MI I/2 "VTR I/2 "SAN DN FOR COIL AND CONDENSATE CONNECTIONS SEE DETAIL 2M79 M5I0 APPROVED DATE f p; I111I11.1II 1 I 1 1 1 I 1 1 1 1 1 1 1 I 1 1 1 I 1 1 1 I 1 1 1 I 1 I I O t6 THS INCH 2 3 HUMIDIFIER 2 1 /2"CHWS AND CI-VR FROM ROOF SZ hZ ' EZ II IIIil111111I1lIII 11111111 11 ,411„!..,19. 1 111�111lI11111 I I 1 11111111111111111111II WPM OBI kw ®a R MIAI OO Mt mum as a se ands as mpg stow Y Y anew a1a as wpm Oa P) MOOe N Oa MVO A ON , , S. w !A = .s M! in Y O MIMI OM IM WPM 0 &: MAIO A ON MOO et xa MOM OM 91 Ism• m r .fs' ea Wm Memo" era ei ® se 10 fib UM Q9 MINIM IIS IPA" WWII !O MI O AUBURN, WA. 98002 O BELLEVUE ,WA . 98007 0 EVERETT, WA . 98201 0 KENT, : WA . 98031 D PORTLAND, OR ..97220 0 RENTON , WA 98055 • SEATTLE, WA 98124 f j n . r ICI, [ 1 . 1 1 I I I + , 1 1 I ll I I . I ! I I I . L , I , . , f III` ; I 11611 . 11 I I Li I I ^! 4 5 6 7 8 WWI: If the microfilmed document is less clear than this I notice, it is due to the quality of the *Mane' document. zz lZ 0? 6t 9t LL 91 GI ht et _ + i z t "'" 0 11. 111111 l II 1 l)J li�illllllll� llll111it�IIIII 10111 111Z 11011111 11111M! I�(1l�IIIIIIII{ I ' ' •fTLE BLDG 9.101.2 1 1/2» TO SINK & FD 1 1/2" FOR SINK AND FD ACCEPTABILITY THIS DESIGN AND/OR SPECIFICATION IS APPROVED APPROVED BY COL D-aJ/ 1 524 -W-�-- CD ---- CHWS ----�- --�- CHWR ------ HWS HWR RWL --- V --VTR -� W GENERAL NOTES :: I OTHERWISE. PIPING IS EXISTING UNLESS NOTED SE. CONSTRUCTION NOTES I. WORK WITHIN PHASE 3 -E ONLY. INSTALL SEISMIC SWAY BRACING, CONNECT NEW AIR HANDLERS TO E X I S T I N G PIPING LOOPS. 4 INSTALL NEW I" COMPRESSED AIR LINE FROM EXISTING SOURCE AS SHOWN. []>. CW CONNECTION FOR VENDING 'MACHINE. USE CHICAGO #1015 STOP VALVE AT WALL fi FOR INSTALLATION OF CW AND HW` SINK SEE DETAIL 2M79 M556 [7..›-CW CONNECTION BELOW COUNTER FOR COFFEE MAKERS. USE CHICAGO 11015 STOP VALVE AT WALL. RECEIVED CITY OF TUKWILA LIAR 1 7 Z92 PERMIT CENTER 2 WAY BRACE, FOR DETAILS SEE �1 2M79 M507 4 WAY BRACE, FOR DETAILS SEE 2M7f M507 NEW PIPING EXISTING PIPING EXISTING ANCHOR FLOW DIRECTION COMPRESSED CONDENSATE IRA IN HOT WATER (DOMESTIC) CHILLED WATER SUPPLY. CHILLED WATER RETURN: HEATING WATER SUPPLY HEATING WATER RETURN RAIN WATER LEADER VENT VENT THRU ROOF WASTE NDIRCT DRAIN 9 I I I 2M793' LAST R£V I S ON shtty BK =4AKB0292 S K= O 2 1Z6 92 AKM079 O 2 .. 1 ,y•.,. xu�;_.s... � i ;. Stitt... �'. f. aCuy_ Kia�- J�s�wv :s:��tk`".:�WRtw'la:,`��'� BLEED i PHASE IC RELEASE TRU PHAE: 2C RELEASE APPROVED f DATE CATWALK (TYP) FROM 415. CEILING LEVEL PENDENT SPRiNKLER HEAD, ' AND UPR HEAD AT ROOF LEVEL 'PENDENT SPRINKLER HEAD UPRIGHT SPRINKLER 'HEAD . . UPRIGHT SPRINKLER HEAD BELOW AHU AND CATWALK SPRINKLER RISER ALARM VALVE ON FIRST FLOOR SPRINKLER PIPING SVXXX SPRINKLER VALVE NUMBER (FOR EXAMPLE.: SV907) 17V 01--.0- 2 WAY BRACE, FOR DETAILS SEE( I) 2M266 M507 4 WAY BRACE, FOR DETAILS SEE All 2M266 M507 rgiERAL NOTE THIS AUTOCAD DRAWING IS DRAWN BASED ON DATA TAKEN FROM THE FOLLOWING HAND DRAFTED EXISTING DRAWINGS: SPRINKLER SYSTEMS ON THIS DRAWING HAVE BEEN HYDRAULICALLY CALCULATED USING A DENSITY OF 0.16 GPM/SQFT AND A DESIGN AREA OF 3000 SOFT. A HOSE STREAM ALLOWANCE OF 500 GPM AT THE SOURCE HAS BEEN MADE, 0 RECtitirD CITY OF TUKWILA MAR 17 199Z PERIVIITCEINITER COL Ar-E/6 .11 ' • [Lc 101 -4320-Mf9, REV. D, (6-18-90) • CONT. NO.26-FP-313, LAST REV. DATE: 4-28-83 CONT. NO 26-FP-313, LAST REV. DATE 9-2O-77 101-4320-M13, REV. 0,12-4-86 101-4320-M-11, REV. L,I2-13-88 ORIFICE SIZE 165' I/2 155' I/2* 155' I/2' 8K=07.25..91 TOTAL NO. OF HEADS ACCEPTABILiTY • THIS DESIGN AND/OR SPECIFICATION IS APPROVED • rp 0 1,-*21126 504 ' 0 e, .. . i:171: .. ... ...,. -, E,I:n . p 2U26 N261 1 ALg] . t:::. <,,,, :7 . [::::1! .... ..: ..... ::„ ...... .„.„ ,:., ........ .,., .....: .. ::::;: .. ; i 4:::1 . , '..- . :: .. -... (41J: . . . .. ..... .... 'MEN R -157 :::: . , .4'4 .,, ,,„„ .. ... . ... ....... •. , ....... ......... . .. . . ........ ,,„ . ..... . ... - ., .... , 4::11:: ,.., • ..s.: ::11....11:1:1] ,.... ., • ., .... .---- , ...: ' .....-- ...,,.. =1 .2; ,;.: ......: ,,,..,,,,, • ii...i...iii„ ...',,,.::,.:.,„:: - :i:::::::.... :. :, „...,.....,.. Ci...j; ,::: . ,:: -- ,..; i 1 I i .... . . .., -..' . ., : 1 M21 '4 AIR BLEED 1 -0 BLEED Pi E fli _ 00- . , IWO i11■1111110W, ,94111. elbow yIqw, " '1& ilk Nit 4 11R4. It 4, "t N i PHASE IC RELEASE TRU PHAE: 2C RELEASE APPROVED f DATE 1 2 1/2 44foe CFiS_N1M5lilt55 I AIR BLEED1 0 AUBURN , WA . 98002 0 BELLEVUE , WA . 98007 0 EVERETT WA 96201 0 KENT , WA . 98031 0 PORTLAND , OR 97220 0 RENTON WA . 98055 SEATTLE WA, 98124 NOTE: if iinaiairefillueddocutaent isreas clear than this notice, it le due to the quality of the original document, tz o e 61 91 LL 9t 91, VI Et Zt 01, 6 8 Z. 1 .1111 . 1y4111 1 1111 1 1111!1rnilljiliiiilllidattblili111111111111i11101111 „ 1111111111,1101)11111111J1111101111111111)1h1111110LUIli411 , CATWALK (TYP) FROM SV907 WiWalfiMMAMUMNEM BLDG 9.101.2 IJEWILA151102L5 415. CEILING LEVEL PENDENT SPRiNKLER HEAD, ' AND UPR HEAD AT ROOF LEVEL 'PENDENT SPRINKLER HEAD UPRIGHT SPRINKLER 'HEAD . . UPRIGHT SPRINKLER HEAD BELOW AHU AND CATWALK SPRINKLER RISER ALARM VALVE ON FIRST FLOOR SPRINKLER PIPING SVXXX SPRINKLER VALVE NUMBER (FOR EXAMPLE.: SV907) 17V 01--.0- 2 WAY BRACE, FOR DETAILS SEE( I) 2M266 M507 4 WAY BRACE, FOR DETAILS SEE All 2M266 M507 rgiERAL NOTE THIS AUTOCAD DRAWING IS DRAWN BASED ON DATA TAKEN FROM THE FOLLOWING HAND DRAFTED EXISTING DRAWINGS: SPRINKLER SYSTEMS ON THIS DRAWING HAVE BEEN HYDRAULICALLY CALCULATED USING A DENSITY OF 0.16 GPM/SQFT AND A DESIGN AREA OF 3000 SOFT. A HOSE STREAM ALLOWANCE OF 500 GPM AT THE SOURCE HAS BEEN MADE, 0 RECtitirD CITY OF TUKWILA MAR 17 199Z PERIVIITCEINITER COL Ar-E/6 .11 ' • [Lc 101 -4320-Mf9, REV. D, (6-18-90) • CONT. NO.26-FP-313, LAST REV. DATE: 4-28-83 CONT. NO 26-FP-313, LAST REV. DATE 9-2O-77 101-4320-M13, REV. 0,12-4-86 101-4320-M-11, REV. L,I2-13-88 ORIFICE SIZE 165' I/2 155' I/2* 155' I/2' 8K=07.25..91 TOTAL NO. OF HEADS ACCEPTABILiTY • THIS DESIGN AND/OR SPECIFICATION IS APPROVED • rp 0 1,-*21126 504 APPROVED DATE PHASE IC . CONSTRUCTION CONVERTER STATION FACILITIES DEPARTMENT 'TITLE BLDG 9.101.2 FIRE PROTECTION 2ND FLOOR PLAN EE1P PHASE 3-E MECHANICAL MASTER CO. E.-J/8-11 D.C. .10172M26' D.KLOTZ 'ACCEPTABILITY THIS DESIGN AND/OR SPECIFICATION IS APPR • OZ 6t W M 9 St IA Et 'al' 4 pl. 9 fjO 4)4) ; /1 7 - • 2 11111111 1 9 10 11 MADE °ERMMY 12 'iai,46WWWWWI26 l t CEILING LEVEL PENDENT SPRINKLER HEAD' ' AND UPRIGHT HEAD AT ROOF LEVEL . PENDENT SPRINKLER HEAD 41 0* UPRIGHT SPRINKLER HEAD 40-- SPRINKLER RISER 0 ALARM VALVE ON FIRST FLOOR SPRINKLER PIPING ' SVXX SECTIONAL VALVE NUMBER (FOR EXAMPLE: SV907) "'" 2 WAY BRACE, FOR DETAILS SEE 411101k 2M267 M507 >0( 4 WAY BRACE, FOR DETAILS SEE A1011 2M267 -M507 ()> NODE OR HEAD IDENTIFICATION FOR HYDRAULICS ANALYSIS <S> UPPER LEVEL NODE 49> LOWER LEVEL NODE GENERAL NOTES I. THIS AUTOCAD DRAWING IS DRAWN BASED ON DATA TAKEN FROM THE FOLLOWING HAND DRAFTED EXISTING DRAWINGS A. DWG NO. 109-101-4320-M19, REV. D, 6-18-90 B. DWG NO. 22, CONT. NO.26 -FP -313, LAST REV. DATE : 4-28-83 C. DWG NO. 23, CONT. NO 26 -FP -313, LAST REV. DATE:'9 -20-77 D. DWG NO.109 -101 -4320-Mi3, REV. G, 12-4-86 E. DWG N0,109 -101 -4320 -M-11, REV. L, 12-13-88 2 SPRINKLER SYSTEMS ON THIS DRAWING HAVE BEEN HYDRAULICALLY CALCULATED USING A DENSITY OF 0.16 GPM/SOFT AND A DESIGN AREA OF 3000 SOFT.. A HOSE STREAM ALLOWANCE OF 500 GPM AT THE SOURCE HAS BEEN MADE. CON$TRT I UC ON NOTES : UPRIGHT OR PENDENT SPRINKLER HEADS VIKING MODEL (NEW) ORIFICE SIZE M I 155' 1 1/2" U 1 5.5 * QTY TO BE COMPLETED FOR PHASE I-D BK=OAKB0172 BK=12.05,91 155° 1 1/2 1 P 1 5.5 TOTAL NO. OF HEADS KEYPLAN RECEIVED ND SC WY (W TI WV/91.A kiAI 1 7 j992 P8R1VOT CENTER I LAST REVISION SHEET EXIST ING SPRINKLER SHOWN N TOILET ROOM AREA I'S I N THE OVERHEAD OF THE CONVERTER ROOM . '29M740 41/4/04CFZKVIAILW EX I ST I NG UNDE PUMP PLATFORM EXP JOINT ACCEPTABILITY THIS DESIGN AND/OR SPECIFICATION'IS APPROVED COL D--# I -15 LEMEJ1 to. CE L I NG LEVEL PENDENT SPOiNi<LEk' HEAP AND UPRIGHT HEAD AT ROOF LEVEL , • PENDENT SPRINKLER HEAD . 40* UPRIGHT SPR INKLER HEAD. • • UPR I GHT SPRINKLER HEAD IstELOYe Adqu CATWALK SPRINKLER RISER 1P I ALARM VALVE ON , F I RST FLOOR. SPR I Nkl ER P I P (NG . SVXXX SPRINKLER VALVE NUMBER (FOR EXAMPLE: SV907 ) SPRINKLER L I N E PLUGGED ABOVE OE) LI 2 WAY BRACE, FOR DETA I LS SEE. 2M273* MO7 >< 4 WAY BRACE , FOR DETAILS SEE 4101k 2M273 M507 <X> • NODE OR HEAD I D E N T I F I C A T I O N FOR HYDRAULIC C ANALYSIS. <I t! UPPER LEVEL NODE. 4 LOWER LEVEL NODE , GENERAL NOTES: I T H I S AUTOCAD DRAWING I S DRAWN BASED ON DATA TAKEN FROM THE FOLLOWING HAND DRAFTED E X I S T I N G DRAWINGS A) DWG NO . 109-101-4320-M I 9 , REV . D, .0-18-90) B) DWG NO . I I CONT . NO . 26-FP -- I 313 , REV. I (6-23-83) C) DWG NO 26 CONT NO 26-FP- 1717 ! , RECEIVED CITY OF TUKVVILA 'AR 1 7 t92 PERMITCENTER FIRE PROTECTION SECOND FLOOR PLAN A , - 0- Fgl Ia l k l g th 3 L L*Mj7M 1 4 3 1W4 REV.9 • (3-10-86) ) DWG NO . I09-101-4161-M7 , REV H 2. SPRINKLER SYSTEMS ON THIS S DRAWING HAVE BEEN HYDRAULICALLY CALCULATED USING A DENSITY OF 0.20 GPM/SOFT AND A `DESIGN AREA OF 1500 SQFT . A HOSE STREAM. AL LOWANCE OF 500 GPM AT TI-IE SOURCE HAS BEEN MADE. CO ON NOTES IN THE FUTOAE WILL BE COMPLETED INSTALL NEW PIPING AND HEADS BELOW CATWALK 1:Z:>. INSTALL NEW PENDENT HEADS (TYPICAL THROUGHOUT PHASE 3-E AREA ON THI S 'DR ) . WORK WITHIN PHASE 3-E AREA ONLY., BALANCE OR I F I CE SIZE VIKING MODEL (NEW) • LAST REVISION SHEET SECOND FLOOR PLAN FACILITIES DEPARTMENT WEND 1 "DRAINI - VALVE 1N DUCT CHASE THIS DESIGN A N D / O R S P E C I E I CAT I O N I S APPROVED TITLE BLDG 9.41.2 PERMIT CENTER CEILING LEVEL PENDENT SPRINKLER HE AND `IIDR I GHT HEAD AT ROQF LEVEL, �i 'PENDENTNSPRINKLER HEAD UPRIGHT SPRINKLER : ,. BEAD UPRIGHT SPRINKLER'' HEAD BELOW AHU'' A CATWALK . 0~e° SPRINKLER RISER ALARM VALVE ON FIRST FLOOR SPRINKLER PIPING: SPR "I NKLER VALVE NICER (FOR EXAMPLE: SV0O1) . SPRINKLER LINE PLUGGED ABOVE CE I L' I 2 WAY BRACE FOR DETAILS SEE, 21027$5(?' 4 WAY BRACE , FOR DETAILS SEE 2M27� M5O7 NODE OR HEAD !DENT IF'I CAT ION FOR HYDRAULIC ANALYS1S. UPPER LEVEL NODE. LOWER LEVEL NODE, �. E RA� I. THIS AUTOCAD DRAWING 1S DRAWN BASED ON DATA TAKEN FROM THE FOL LOW I NG'HAND DRAFTED EXISTING DRAWINGS: A) DWG NO. 109-101-4320—M 19 , REV . D , ( 6- 1 -90 B) DWG NO. I I , CONT. NO. 26 —FP -1313, RED /. l (6 . C) DWG NO 26, CONT . NO 26—FP-1313 , REV .9 (3— I0 -86) D) DWG NO I09-101-4161—M7 , REV , H 2 . SPRINKLER SYSTEMS ON THIS DRAWING HAVE BEEN HYDRAULICALLY CALCULATED USING A DENSITY OF 0.20 GPM/SOFT AND A DESIGN AREA OF 1500 SOFT , A HOSE STREAK! ALLOWANCE OF 500 GPM AT THE SOURCE HAS BEEN MADE. 110. INSTALL NEW PIPING AND ''HEADS BELOR K CATWAL © - INSTALL NEW PENDENT HEADS (TYPICAL THROUGHOUT PHASE 3—E AREA ON THIS DRAW ING PROVIDE I" DRAIN VALVE AND ACCESS DOOR I N WALL 4 . WORK WI TH1 N PHASE 3—E AREA ONLY .: BALANCE OF WORK WILL BE `COMPLETED IN THE FUTURE. SSP— I EN PHASE 3—E FIRE PROTECTION' SECOND FLOOR PLAN MASTER 1/2" I U I. 5.5 I '156 TOTAL NO. OF HEADS ;PHASE 3 —E ONLY).j,324 DATE BX OAKB0292 BK=02. 26 '92 fi • Mg .. • ups _ aim ay r_V.► wi.AvA £VA V4� � I: LI.� v va v r.►s i<.' • VAV. Y �J. _s/ArA7 �� 2 I /2 (EXIST 3" iv 3 I, lie emu set e• we ea as aeeR an m — p s slam as as saes as ens era s sa as me s R pia ®l as an se fa REVISION AREA OF PHASE 3 CATWALK 1 I. A JJ 4 2 " sw___ r � i rrrri� � �r V/ / / /i�/ /./.�ri,�x , u1 r ]/� iff ,/.�►,� I -- ici 1 , fr L o ik o r 46y ./ SECOND FLOOR PLAN 18 —I —0 �- •. ':fir. >. :irk. .�. FACILITIES DEPARTMENT WEND 1 "DRAINI - VALVE 1N DUCT CHASE ewes as as was as s see as s norm s s . ®s awn a° ,a ems as a as sa ems as ee Naar s ass asap s sit s . a>vt r s esrpe s s n as as w w. a es ea so as en soon ea ea mass w ieo awe s w+ arse ea s se cI ask a see a s wan ea H { = ,,� vipros Armour AP* a w.r r�rvvY►� DEPT. 0 AUBURN,. WA O BELLEVUE , WA O EVER�e l T , WA. O KENT, WA . 0 PORTLAND, OR , O RENTON , WA. ki SEATTLE.. ''A p ee M ca es some an as cape no M 98002 98007 98201 98031 97220 98055 98124 STS' �. ^ ✓•S J. " I I I it III L 5 6 7 , ' . .: : . a:..:. �w�..';<.+. c.:.. �_. u: �w+: i' �..:+ t... r+.. <s�;.::.:..�.;::.- .:x.^...:cr _:._ Ho t if ._ the e�icraf'ilmed document is leas clear than this notice, it is due to the quality of the original document, � C LZ 81 Lt '$L 5l + L £L ZL Ll 01, 1 61 11,1 iili11I1I1i h)11J(1111iu1 !1iii! 1II1II)IIIIIIIIIIIIIMI 111 ,111CIIjll1111!ii ti t r +, .rr •.: i d. _:;a,.: [.. �. .. ... �%p'.�..r, r��� s D^ rt' i.•.~�. rt: tv. aa"�'i `'.... -..' :i1n vr.r/ '.wo i I_ll�ll Iil�l±l ��IIIIfJ����IIIIIIIiill� ►�i�Illlill�Iili��l% ACCEPTA�3 i L 1 TY THIS DESIGN A N D / O R S P E C I E I CAT I O N I S APPROVED TITLE BLDG 9.41.2 SVXXX RC I C VE CITY - c,I TUKVV LR OAR 1 7 1992 PERMIT CENTER CEILING LEVEL PENDENT SPRINKLER HE AND `IIDR I GHT HEAD AT ROQF LEVEL, �i 'PENDENTNSPRINKLER HEAD UPRIGHT SPRINKLER : ,. BEAD UPRIGHT SPRINKLER'' HEAD BELOW AHU'' A CATWALK . 0~e° SPRINKLER RISER ALARM VALVE ON FIRST FLOOR SPRINKLER PIPING: SPR "I NKLER VALVE NICER (FOR EXAMPLE: SV0O1) . SPRINKLER LINE PLUGGED ABOVE CE I L' I 2 WAY BRACE FOR DETAILS SEE, 21027$5(?' 4 WAY BRACE , FOR DETAILS SEE 2M27� M5O7 NODE OR HEAD !DENT IF'I CAT ION FOR HYDRAULIC ANALYS1S. UPPER LEVEL NODE. LOWER LEVEL NODE, �. E RA� I. THIS AUTOCAD DRAWING 1S DRAWN BASED ON DATA TAKEN FROM THE FOL LOW I NG'HAND DRAFTED EXISTING DRAWINGS: A) DWG NO. 109-101-4320—M 19 , REV . D , ( 6- 1 -90 B) DWG NO. I I , CONT. NO. 26 —FP -1313, RED /. l (6 . C) DWG NO 26, CONT . NO 26—FP-1313 , REV .9 (3— I0 -86) D) DWG NO I09-101-4161—M7 , REV , H 2 . SPRINKLER SYSTEMS ON THIS DRAWING HAVE BEEN HYDRAULICALLY CALCULATED USING A DENSITY OF 0.20 GPM/SOFT AND A DESIGN AREA OF 1500 SOFT , A HOSE STREAK! ALLOWANCE OF 500 GPM AT THE SOURCE HAS BEEN MADE. 110. INSTALL NEW PIPING AND ''HEADS BELOR K CATWAL © - INSTALL NEW PENDENT HEADS (TYPICAL THROUGHOUT PHASE 3—E AREA ON THIS DRAW ING PROVIDE I" DRAIN VALVE AND ACCESS DOOR I N WALL 4 . WORK WI TH1 N PHASE 3—E AREA ONLY .: BALANCE OF WORK WILL BE `COMPLETED IN THE FUTURE. SSP— I EN PHASE 3—E FIRE PROTECTION' SECOND FLOOR PLAN MASTER 1/2" I U I. 5.5 I '156 TOTAL NO. OF HEADS ;PHASE 3 —E ONLY).j,324 DATE BX OAKB0292 BK=02. 26 '92 STUBOUT 120 3' -0 LONG FOR FUTURE CONNECTION - REVISION I PROVIDE 1/2 MESH ' B I RDSCREEN OVER BOTH I SIDES OF EXISTING I 24 /24 OPENING IDF ROOM AT D IA, UPPER LEVEL FOSR ROOM HVAC PARTIAL PLAN i 1 ----EXISTING 24/16 WITH EXTERNAL INSULATION & VAPOR BARRIER 9' -6 ° . AFF -- 600 CFM f 20/20 OPENING THRU WALL WITHIN 24" OF ROOF DECK, . PROVIDE I/2 MESH BIRSCREEN BOTH SIDES OF OPENING ATTACH NEW 16/14 DUCTWORK TO EXISTING 24/16 WITH 24/16 TO 18/14 SOUNDLINED RADIUSED ELBOW INSTALL EXISTING 16/ I 1 DOUBLE DEFLECTION GRILLES IN BOTTOM OF EXISTING 90 DEGREE SQUARE ELBOW, INSTALL GR`I LIES POSSIBLE AS HIGH AS REMOVE EXISTING BRANCH DUCT AND GRILLES BELOW 24/16 ELBOW I I III' II 111I! I I'11I1 { I I II I I`I I I I I I I I, L11' I I tp TKS INLH 1 2 .4'.. t 1 kr.' 'Sr 1 ik'.��'J`&•..s ..Y_% AUBURN , WA 98002 BELLEVUE, WA 93007 KENT , WA WA . .` 9�32�J ! 98031 PORTLAND, OR 97220 RENTON , 980 5 SEATTLE., . (WA . 98124 f •r1, t'11 t H II ` ' ,', ` . 111 1111/111 141 I NOT :: If the microfilmed document is less clear than this notice, it is due to the quality of the original document. oz mmamm LL 01, 6 8 £ IEIIIJIIIIl11111I� ,,1111111 IIIIILIJ. dub II! I !ill I UH J Ililli llill1 rl:llllilill1�111111iII Illill�I�IIIIIJ'l( {IIIi�iIJ111 � IDF ROOM AT E/5 UPPER LEVEL PARTIAL FLOOR PLAN I '� - zuiiuw� -� i -0 2M I I M400 ACCEPT.4B I I. i T Y THIS DESIGN AND /Q1 SPECIFICATION I S APPROVED IIIIIIIIIIIII111III11111IIIIIIIIII 1!11111111 9 t 10 11 mot OERMbUY 12 SAWYR LSA ER Tine BLDG 9.101.2 RECENED CI1{ o 1uK wi ' OAR 1 7 1S92 PERMIT CENTER PARTIA PLANS, IDF 8, FOSR ROOMS MP PHASE a -E, MECHANICAL MASTER oaKMaoo KID /03 ,` G14' w'. wi�Rex REVISION D (RE AWN) E- FOR OR 3 , AHU PURCHASE SECOND FLOOR, B2.5 Al—C6 I NTER I OR SECOND FLOOR, B5.5 A1 PERIMETER SECOND FLOOR, B/8 5 A8 — :CII INTERIOR SECOND FLOOR, C2.5 AI -JI PERIMETER EI -G6 INTERIOR C6-Ell INTERIOR OPT AF ONDI STD AF DWDI OPT AF DWD I OPT AF . DWDI OPT AF DWD I 88 90 • 91 86 85 .80 72 2 94 5 90 89 84 76 9I :93 94 89 88. 83 75 101 98 99 94 89 87 83 96 15 95 91 85' 82 77 15350 14090 1710 1656 YES YES 2" DEFL INTL DEFL INTL DEFL 4NTL EFL INTL 2 "'DEFL INTL 2" DEFL INTL 4603 . 460/3 460/3 460/3 460/3 460 3 CC2CBA CC2E3A HC2BBA HC2C2A HC2J2A AF2B2A AF2B5A AF2B8A AF2C2A AF2G3A AF2J2A 24.13/111.38 24. 1 3/1 138 MCQUAY MSLII4D, LH AIR I NTAKE. 4250 MCQUAY MSL 122D, RH A INTAKE MCQUAY MSL128D, LH AIR INTAKE MCQUAY MSL 122D, RH AIR INTAKE MCQUAY MSL I14D, LH AIR INTAKE MCQUAY MSL 122D', RH AIR INTAKE MCQUAY MSLI22D, LH AIR INTAKE MCQUAY MSLII4D, RH AIR INTAKE 2" DEFT INTL CC2C2A I. WITH INLET �RYANESEOPO4�IERS � EDISCHARGE FAN (NO DUCT) ARE FAN DISCHARGE OUTLET, 2. AHU OPTIONS: STAINLESS STEEL DOUBLE CONDENSATE DRAIN PANS WITH INSULATION EXTENDED LUBE FITTINGS TO DRIVE SIDE OF AHU INTERNALLY INSULATED FILT /MIX BOX AND RIGID FILTER N 3 �' FACTORY PNEUMATIC ACTUATORSANDLINKAGELOW LEAK EXTRUDED RUDED ALUMINUM DAMPERS AHU'S TO BE SHIPPED BROKEN DOWN INTO FAN /COIL, RIGID FILTER, AND FILT/MIX BOX SECTIONS 3 LB /SQ FT INSULATION DENSITY INTERNAL INSULATION IN FAN CABINET ,, MOTOR STARTERS WITH AND PERF SHT MTL LINER ALLEN BRADLEY AND DISCONNECTS MARK NUMBER LEATED THROWA AY LASS II 2 PLEATED THROWAWAY CLASS II 2" PLEATED THROWAWAY, CLASS I 2 PLEATED THROWAWAY, CLASS I AH2G3A AH2J2A RIGID THROWAWAY, CLASS I 12" RIGID THROWAWAY, CLASS I L " RIGID THROWAWAY, CLASS I 12" RIGID THROWAWAY, CLASS 24x24 24x24 24x24 FAR • 30/30 ILTER, FINAL FILTER' S-CTIOIJ WIT T "RE ILTER'RAILS FARR '30/30 PPEFI TER, FARR RIGA —F 0 1 iO FINAL Fl TER, FINAL TER T ` L F ( ER SECTION VV (THOU . PREF LTER RAiLS LS FARR 30/30 PREFILTER, FARR RIGA—FLO 100 FINAL FILTER, FINAL FILTER SECTION WITHOUT. PREFILTER 2 PLEATED THROWAWAY CLASS I 2" PLEATED THROWAWAY CLASS I 2" PLEATED THROWAWAY CLASS II 2" PLEATED THROWAWAY, CLASS I SUPPLY FAN SECTION 12" RIGID THROWAWAY, CLASS I 12" RIGID THROWAWAY, CLASS I 12" RIGID THROWAWAY, CLASS I Ir RIGID THROWAWAY, CLASS I 12" RIGID THROWAWAY, CLASS Ia_ "`RIGID THROWAWAY, CLASS I 0 AUBURN , WA . 98002 0 BELLEVUE , WA . 98007 0 EVERETT , WA. 98201 0 KENT , : OVA . 98031 0 PORTLAND, OR . 97220 0 RENTON , WA . 98055 II SEATTLE , WA . 98! 24 I . I � i � I I l :.'-',: 11 NOTE: If the microfilmed document is legs clear than this notice, it is due to the quality of the original document. OC 6z ee Gz 9z sz 1 7z ` CZ zz le OZ 6l 81 Lt 91 S4 4 71 CI zl « 01. 6 9 f ; : _.': ... 1ti ;IIIIIIII Iii 1II{Il11111111 {lihuil ! cuIIU�I IIIllu I{ ',.1 I I i It.1l .,, ! {IIl�,IL�I!lI111I11�1111�J1 11�,LI 11111{ III11111111 111111 {II11I11iiii�l111111111 11 iIl {I 11111 -' '... ".. Y. .,e' .�i • _ .� =', -.r J ii�113�..- _ —_._. PRESSURE DROP IN WG CLEAN DIRTY ACCEPTABILITY TNIS`DESICN AND /OR SPECIFICATION IS APPROVED FARR 30/30 PREFILTER, FARR RIGA—FLO 100 FINAL FILTER, FINAL FILTER SECTION WITHOUT PREFILTER RAILS' FARR 30/30 PREFILTER, FARR RIGA —FLO 100 FINAL FILTER, FINAL FILTER SECTION FARR 30/30 PREF I I. TER , FARR RIGA 100 FINAL FILTER, FINAL FILTER SECTION FARR 30 /30 PREFILTER, FARR RIGA —FLO 100 FINAL FILTER, FINAL FILTER SECTION FARR 30/30 PREFILTER, FARR RIGA =-FLQ 100 FINAL FILTER, FINAL FILTER SECTION FARR 30/30 PREFILTER, FARR RIGA —FLO 100 FINAL 'FILTER, FINALTILTER'SECTION FARR 30/30 PREFILTER, RIGA IOO FINAL .FILTER, FINAL FILTER SECTION • REMARKS RECEIVED CITY OF TUSWILA 1� I ?1 : :� .. • �l; ''EF1MITCENTER t 4 WI THOUT PREFILTER. RAILS PREFILTER RAILS PREFILTER PREFILTER 0 AKM5 h (� V� FARR 30/30 PREFILTER, FARR RIGA --FLO 100 FINAL FILTER, FINAL FILTER SECTION WITHOUT PREFILTER RAILS e. - I FM PURCHASE op PHASE HEATING COIL HC SCHEDULE COIL FACE TOTAL WATER FINS COIL MAX PRESSURE. DROP MARK UNIT CONN, NUMBER' SERVED CFM AREA MIN, MBH EAT 'F LAT 'F ROWS PER INCH REMARKS SO FT MIN. MIN EWF UNTT GPM INCH (SUP-RET) AIR-IN WG TUBE-FT H2O _ . .. . . HC2B2A AH2B2A 10180 24.24 108.5 62 7 75.5 180.0 127.0 5.4 6 1 2 ! 1/2 0.08 0.10 MCQUAY 5WHO601H HC2B5A AH2B5A 6160 13 65 119.0 . 62.7 80.6 180.0 139.4 5.9 6 1/2 I 1/2 0.08 0.10 MCQuAy 5wH06011-1 Hc2B8A AH2B8A 12160 24.24 161.6 62.7 74.9' 180.0 130.8 6.6 6 1/2-1 1/2 0.03 0.10 MCQUAY 5wB060111 HC2C2A AH2C2A 4900 13.65 138.6 642. 84.8 180.0 139.7 6 . 9 6 I/2-I 1/2 0.07 0.70 MCQUAY 5WQ060IH . . HC2C5A AH2C5A. 13420 2424 152 6 62.7 76.5 180.0 142.6 10.2 6 1/2-1 1/2 0.11 0.30 MCQUAY 5WHO601H HC2C8A AH2C8A 15350 30.47 227.0 62.7 76.2 180.0 136.0 10.3 6 1/2 1 1/2• 0.10 0.80 MCQUAY 5WB060IH HC2E3A AH2E3A 12600 24.24 190.2 62.7 76.5 180.0 142.6 10.2 6 1/2-1 1/2 0.11 0.70 MCQUAY 50W060IH ... _,..-. ...... • - . . - IP- - 'ar HC2EI6A AH2EI6A 14390 30 47 212.1 62 0 75,5 180.0 134.2 9.3 1 6 I 1/2 0.07 0.70 MCQ AY 5WB060IG ......_ HC2EI7A AH2EI7A 13455 30..47 210.9 62.0 76.4 180.0 '135.9 9 6 1 6 I/2-1 1/2 0.06 0.70 MCQUAY 5A60601G -,,,- - ...410. ......- ...... - r , law mow . -is.- . AH2J4A 5510 62, 7 .9 160.0 2-1 1/2 0, 9 0 10 AY 5* 470 HC2C3A DATE OK KR GS KR REVISION Riagaii00446464ma APPROVED 1 DATE ACCEPTAB 1 1_ TY THIS DESIGN AND/OR SPECIFICATION IS APPRCNED D. KLOT MPRUQW"' K.RAmSEY-to 11311111 111111111111411111 I1 Ft 0 AUBURN , WA . 98002 0 BELLEVUE WA . 98007 El EVERETT , WA . 98201 0 KENT , WA . 98031 0 PORTLAND OR . 97220 0 RENTON 1 WA . 98055 114 SEATTLE, WA 98124 ji• • 4 5 6 7 . NOTE: - - irthe micr"ofilmedliocument is less clear than this notice, i.t is due to the .quality of the Original document, 8 LL 91 • st vt et • zt tt • 01, • f IIII101411111j1] OIJI0 4t,g!.0..A 11 MADE antANY 12 4 1 1111 1)7LE '44 RECEIVED CITY OF TUKWILA AR 17 1992 PERMITCENTER BE&C ENQUIRERS' 4 CONTROL VALVE (C SCHEDULE . . MARK NUMBER COIL SERVED FLUID - CV 47.0 4.4 GPM SIZE TYPE ROM 2-WAY EQUAL PERCiNTAGE 5.4 I/2" 3-WAY EQUAL PERCENTAGE OPERATOR 9-13 PSIG PNEUMATI kTUATOR REMARKS VA282A CC2B2A CHILLED WATER JOHNSON CONTROLS V7416-4523, FAIL CLOSED, U-CUP PACKING VA2B2B HC2B2A HOT WATER 4-8 PSIG PNEUMATIC ACTUATOR JOHNSON CONTROLS V4324-1002, FAIL OPEN, U-CUP PACKING VA2B5A CC2B5A CHILLED WATER 27.5 47.8 1 I/2" 2-WAY EQUAL PERCENTAGE 9-13 PSIG PNEUMATIC ACTUATOR JOHNSON CONTROLS V3974-10I2, FAIL CLOSED, U-CUP PACKING VA2B5B HC2B5A HOT WATER 4.4 5.9 24,/68 3-WAY EQUAL PERCENTAGE 4-8 PSIG PNEUMATIC ACTUATOR JOHNSON CONTROLS V4324-1002 FAIL OPEN, U-CUP PACKING VA2BBA CC2BBA CHILLED WATER 83 96.9 18/69 2-WAY EQUAL PERCENTAGE 9-13 PSIG PNEUMATIC ACTUATOR JOHNSON CONTROLS V-5462-8, FAIL CLOSED, U-CUP PACKING VA2888 HC2B8A HOT WATER 4.4 6.6 1/2" 3-WAY EQUAL PERCENTAGE 4-8 PSIG PNEUMATIC ACTUATOR JOHNSON CONTROLS V4324-1002, FAIL OPEN, U-CUP PACKING VA2C2A VA2C2B CC2C2A HC2C2A CHILLED WATER HOT WATER IMES 4.4 42.1 6.9 I I/2" I/2" 2-WAY EQUAL PERCENTAGE 3-WAY EQUAL PERCENTAGE 9-13 PSIG PNEUMATIC ACTUATOR JOHNSON CONTROLS V3974-1012, FAIL CLOSED, U-CUP PACKING 4-8 PSIG PNEUMATIC ACTUATOR JOHNSON CONTROLS V4324-I002, FAIL OPEN, U-CUP PACK INC VA2C5A CC2C5A CHILLED WATER 47.0 93.0 2" 2-WAY EQUAL PERCENTAGE 9-13 PSIG PNEUMATIC ACTUATOR JOHNSON CONTROLS V7416-4523, FAIL CLOSED, U-CUP PACKING VA2C5B HC2C5A HOT WATER 8.6 10.2 3/4" 3-WAY EQUAL PERCENTAGE 4-8 PSIG PNEUMATIC ACTUATOR JOHNSON CONTROLS V4324 FAIL OPEN, U-CUP PACKING VA2C8A CC2C8A CHILLED WATER 83 118.6 3" 2-WAY EQUAL PERCENTAGE 9-13 PSIG PNEUMATIC ACTUATOR JOHNSON CONTROLS V-5462-8, FAIL CLOSED, U-CUP PACKING VA2C8B HC2C8A HOT WATER 8.6 10.3 3/4" 3-WAY EQUAL PERCENTAGE 4-5 PSIG PNEUMATIC ACTUATOR JOHNSON CONTROLS V4324-1005, FAIL OPEN, U-CUP PACKING ------------- VA2E3A CC2E3A CHILLED WATER 54,0 93.0 2 1/2" 2-WAY EQUAL PERCENTAGE 3-15 PSIG PNEUMATIC ACTUATOR JOHNSON CONTROLS VB-3970-11, FAIL OPEN, U-CUP PACKING VA2E3B HC2E3A HOT WATER 8.6 10 2 3/4" 3-WAY Eb AL PERCENTAGE 3-15 PSIG PNEUMATIC ACTUATOR JOHNSON CONTROLS VB-4324-4, FAIL OPEN, U-CUP PACKING VA2 I8A CC2EI6A CHILLED ATER 54 13.1 IIIIIIIIMMIIIIIIIIIMNIIMI 2-WAY EQUAL P RCENTAGE 9-13 PSIG PNEUMATIC ACTUATOR JOHNSON CONTROLS V-5462-6, FAIL CLOSED, U-CUP PACKING VA2E16B CC2EI6B HOT WATER 8.6 9.2 3/4" 3-WAY EQUAL PERCENTAGE 4-8 PSIG PNEUMATIC ACTUATOR JOHNSON CONTROLS V4324-1005, FAIL OPEN, U-CUP PACKING VA2E)7A CC2EI7A CHILLED WATER 54 82.9 2 1/2" 2-WAY EQUAL PERCENTAGE 9-I3 PSIG PNEUMATIC ACTUATOR JOHNSON CONTROLS V-5462-6, FAIL CLOSED, U-CUP PACKING VB2EI7B . CC2EI7B' HOT WATER 8.6 ' 9.6 3 3 WAY EQUAL PERCENTAGE a. - - A 4 . 4 4- PSIG PNEUMATIC ACTUATOR JOHNSON CONTROLS V 324-1005, FAIL OP N, U-CUP PACKING • VA2G3A CC2G3A CHILLED WATER 54 0 93,0 2 1/2" _ 2-WAY EQUAL PERCENTAGE 3-15 PSIG PNEUMATIC ACTUATOR JOHNSON CONTROLS VB-3970-II, FAIL OPEN, U-CUP PACKING VA2G3B HC2G3A HOT WATER 8 6 10,2 3/4" 3-WAY EQUAL PERCENTAGE 3-15 PSIG PNEUMATIC ACTUATOR JOHNSON CONTROLS VB-4324-4, FAIL OPEN, U-CUP PACKING VA2J2A CC2J2A CHILLED WATER 17.0 41.9 1 1 /2" 2-WAY EQUAL PERCENTAGE 3-15 PSIG PNEUMATIC ACTUATOR JOHNSON CONTROLS VB-3970 7, FAIL CLOSED, U-CUP PACKING VA2J2B HC2J2A HOT WATER 1/2" 3-WAY EQUAL PERCENTAGE 3 PSIG PNEUMATIC ACTUATOR. JOHNSON CONTROLS VB 4324 3, FAIL OPEN, U-CUP PACKING NNW IIIIIIIIIIIIIIII NMI 111111111111111 11 1111111 IIIIIIIII I , ' 111.111 arillIN . . . . AIR M ARK NUMBER MON 1 TOR UNIT SERVED AM -AIR FL6; CFM SCHEDULE MONITOR SIZE I N X iN MAXIMUM PD ' • # MAX FV FPM MIN FV FPM SYSTEM ACCURA CY RE MARKS AM2B2A AH 10260 24/88 0.001 700 120 ±(2% OF READING + 20 FPM) EBTRON SERIES 2100 ETR, 4-20mA OUTPUT, FLANGED FRAME, 24 VAC POWER SOURCE AM2B5A AH2B5A 6160 18/69 0.001 710 105 ±(2% OF READING + 20 FPM) EBTRON SERIES 2100 ETR, 4-20mA OUTPUT, FLANGED FRAME, 24 VAC POWER SOURCE . AM2B8A AH2B8A 12160 24,/68 0.001 830 130 +(27. OF READING + 20 FPM) EBTRON SERIES 2100 ETR, 4-20mA OUTPUT, FLANGED FRAME, 24 VAC POWER SOURCE AM2C2A AH2CZA 5780 18/69 0.001 670 110 ±(2% OF READING + 20 FPM) EBTRON SERIES 2100 ETR, 4-20mA OUTPUT, FLANGED FRAME, 24 VAC POWER SOURCE AM2C5A AH2C5A 12600 • 24/88 0.001 860 140 ±(2% OF READING + 20 FPM) EBTRON SERIES 2100 ETR, 4-20mA OUTPUT, FLANGED FRAME, 24 VAC POWER SOURCE ' AM2C8A AH2C8A 15350 24/111 0 830 160 ±(2% OF READING + 20 FPM) EBTRON SERIES 2100 ETR, 4-20mA OUTPUT, FLANGED FRAME, 24 VAC POWER SOURCE -AM2E3A- . AM2EI6A AH2E3A . AH2EI6A 12600 143'O 24/88 .. 24/ 11 0.001 • 0 860 • 830 140 130 ±(2% OF READING + 20 FPM . ±(2% OF RE DING + 20 PM) EBTRON SERIES 2100 ETR 4-20mA OUTPUT FLANGED FRAME 24 VAC POWER SOURCE EBTRON SEES 21 m 0 ETR, 4-20A OUTPUT, FLANGED FRAME, 24 VAC POWER SOUR E AM2EI7A AM2G3A AH2EI7A AH2G3A 13455 12600 24/88 0.001 0.001 830 860 130 " 40 ±(2% OF READING + 20 FPM ±(2% .- OF READING + 20 FPM) EBTRON SERIES 2100 ETR, 4 OUTPUT, FLANGED FRAME, 24 VAC POWER SOURC E, . , .."1"- EBTTiOITSERIS 2100 ETR 4-i0A •UTPUT, FLA FRAME724 VAC POWER SOURCE . ANIMA • AH2J2A • 5780 . 18/69 0.001 670 110 ±(2% OF READING + 20.FPM) EBTRON SERIES 2100 ETR, 4-20mA OUTPUT, FLANGED FRAME, 24 VAC POWER SOURCE al= i , . 111111 • ' IIIIIIIIMMIIIIIIIIIMNIIMI . 4;:^:a1,3■kil - RECOR61)RRN1NP•(REDRON). ..• 1SPE:FOR..'3AHPFU.RCHAS . SSUE.iFOR.griPPHASE.17E:' • DATE 08,23.1 16EigWitI II 0 1671451V:14 1 9Z 1 7Z OE 11 ,!. 1 H. 1 , 1 1 4 . 1 . 1 . 1 f 71 1, 1 11.0 1 . ANAMEWIOA7 FACILITIES DEPARTMENT 0 AUBURN , WA ;98002 98002 O BELLEVUE , WA . 98007 O EVERETT WA . 98201 O KENT , 98031 O PORTLAND , OR . 97220 O RENTON , WA . 98055 SEATTLE WA 98124 • rir IfI III I1 I 11 ttf 1 - the micicitilmed document is less clear than this notice, it 16 due to the quality of the original document. Ze iz C)8 6l 81. 41 91. GI. lit et V. IL ()L 6 8 4i99VCZ I it! Ipj pi PP pp pp Intliphip,tii,tp ppInn.ijpilip.ppkolifoilpilinnipplifillppippiPPIPPIPPIPPIffil If I il-1 - Lui 0 'IT I Hi I I ACCEPTAB THIS DESIGN AND/OR SPECIFICATION IS APPROVED APPRCA BY DEPT. DATE TITLE RECtIVED CITY OF TUKWILA MR 1 7 1;182 PERMIT CENTER tossalliimatAleadINWIPOIMMINIM10401 ..4?•••• 'VAR !ABLE A I a VOLUME UNIT (VV) PARK SCHEDULE 'MARK , 'NUMBER VAV-/ AIR F LOW CFM ' NARK "NUMBER VAV- #- A!R FLCN1 CFM MARK NUMBER VAV -/ AIR FLOW CFM MAR NUMBER VAV -/ AIR fltXN (�M MARK NUMBER VAV -/ MR FLUN CFM MARK NUMBER VAY -,� alit FLOW CFM MARK �U.. R VAV -�! dimbhAili AIR FLOW �K N UMBER M VAV -/ aiR FLUN M CFM MARK NUMBER VAV -� AIR FLdMI' 8 10 01282A 10 I w 2 A 8 A 0 . 260 630 ; VV2HIA VAV -•10 309 VV2C60 VAV -8 740 VV2F4A VAV -12 1400 12 VAY -10 870, W2D17A VAV -10 720 6 50 Il lim JIIMIIII I NM MI OM W2AIC VAY-8 lab ,i VV2A9A VAV -10 630 .' 1 600 USED FOR RETURN AIR GRILLE, NAILOR-HART 51 ECC � W2C7A VAV -12 1480 1480 1480 VV2F5A I I dAV -12 1400 �Ir ��� ~ � WZD12A AHZEI6AI � VAV -8 630 W2D17A VV2U17C I W2DI7D VAV -12 VAV -t2 VAV -12 138(! 11111111111 Hir I500 I�� I$OQ W2A1.9 YAV-10 9E30 I MI W2C18 VV2C2A �� VAV-12 � 1050 I050 VV2C8A I W VV2C9A VAV -12 VAV�12 VV2A36 W2A46 VV2A5B W2818 VAV -10 VAY -10 VAV7-10. VAV =10 710 880 880 600 I �� I W2A68 ( W2A76 1 VV2A8B I W2A9B I VV2B6A 41208A VAV -1U VAV -10 VAV -10 VAV-12 VAV -12 VAV -12 VAV -f ?. VAV -IL 960 I W2CIOA VAV -12 . 1480. I VV2G2A VAV -10 1050 J W20126 VAV -i0 720 I W2D17E VAV -12 1125 960 ' 960 I 1470 I 1520 I i520 I 15g0 1620 f VV2C3A bAV -IL 1500 VV2D6A VA/40' 1000 I VV2G2B VA-10 1050 I VV2DI2C VAV -8 480 I VV2DI8A VAV -10 720 HI! VV2C4A. W2C5A VAV -12 VAV -12 1400 1400 VV2D66 VV2D7A VAV -8 0 ( W2G3A I VAV -12 VAV -12' 1400 ,{ 1400 11 W2D12D VVZDI3A VAV -B 630 VAV -14 1890 I VV2EiBA I VV2E189 VAV -8 VAV -8 480 490 MP - R11111111 I111.11 I VAV -I 1000 VV262A. W2B2B W28SA W263B VAW12 VAV -10 VAV - 12 VAV-6 . 950 660 1400 170 VY2DlB W2D2A , • VV2D3A VV2D38 VAV -12 VAV -12 VAV -12 VaV - to 1050 1050 100 820 VV2D7B f W2D9A W2D9A 'VAV -10 VAV - 10 VAV -10 540 1080 � 1080 VV2GSA W2HIB VN2H2A VAV -12 1400 1360 VV2D136 VV2D14A NA4 -10 725 I W2F18A I VAV -16 1080 I � I� l I ' MN _�� � VAV -12 11111 VAV -10' 1080 VAV-8 630 Ilt J VV2B7A I VV2B8A I VV2B9A l VAV -10 600 �I W2D148 N/2DIOA VAV -10 1080 I W2H26 1111111111 VAV - 10 VAV -AO 830 I VV2D14C VAV -12 1125 I � " I 11111111111111 111111 W284A VAV12 1400 800 4 N12D14D 1500 W265A VAV -12 . 1400 I 020 0A. .VAV-d0 IO20 W2D3C VAV -6 210 W2E9A VAV-12 1200 VAV -12 1500 I' AH285A' I W28IOB , VAY -B IIH2C2A 710 = } W2D3C YV 2p4A W2046 VAV-6 VAV -10 bAV -8 160 '' 970 420 ' V12E2A AN2E3A VAV -10 W2N3A w2k4n W2N5A VAV -12 1400 il W2D14E VAV -12 VAV -12 1400 ,I 1400 ,) WZDISA VAV-8 480 1 VV20156 VAV -12 150 � IIIIIIIII- NM= MN MN MIMI 1050 1N2AIA VAY -B 350 1fV2A1D VAV-6 280 YV2A16 VAV -B YAV -10 320 1 520 I VV2D4C YAV -8 350 W2E26 VAV -10 1050 INN III 800 It VV2D15C bAV -i2 1500 J I NM 1111111 VV2D5A VAV -12 1290 VV2E3A VAV -12 1400 AH2J2A VAV -10 W2A2A VAV -B 280 VV2BIA AM2f17A 111E1 W2A3A VAV -10 630 W281C VVA - 6 240 I VV2E4A VAV -12 1400 W2JIA IMMO .1111111 W2A4A VAV -10 630 VV2CIA VAV -10 790 I VV2C6A IWZCBA VAV -6 � 230 VV2ESA W2F2A VAV -12 1400 W2JIB VAV -10 1050 III VV2D16A VAV -10 750 I VAV -10 1050 W2J2A VAV -12 1310 411 VV2DI6B VAV -10 720 i 1111 111111111111111 1 V1f2A5R VAV -10 630 W2DIA VAV -10 790 J I Mill ME W2A6A VAV -10 630 W2FIA VAV -12 1150 I WZCfiB VAV -6 230 W 2F26 VAV -f0 1050 VV2KIA VAV -10 780 411 W2D16C VAV -12 1500 VAV -12 1500 I W1111110 I W2,47A VAV -10 630. VV2GIA VAV -10 790 I VV2C6C VAV -6 360 VV2F3A VAV -12 1400 . VV2KIB VAV -B 700 1Q W2DI6D I MINN :AI R DIFFUSER i f REGISTER it GRILL (AIR) SCHEDULE • 'MARK NUMBER TYPE M ATERIAL FINISH : ' INLET ` NECK SIZE, INCHES FLEX DUCT SIZE, INCHES FACE SIZE INCHES MAXIMUM NOISE COEFFICIENT MAXIMUM TP INCH WG MAXIMUM SET CFM REMARKS CD-6 L A Y I N T -BAR 6 PAINTED 6 6 24/24 35 0.06 120 NAILOR-HART SERIES 4600, TYPE RNS2 CD-8 CD-I0 LAY IN T -BAR LAY IN T -BAR 11111111111 PAINTED PAINTED 8 10 8 10 24/24 24/24 10 0.13 260 NAILOR -HART SERIES 4600, TYPE RNS2 VAV-12. 0.18 4 35 NAILOR -HART SERIES 4600, TYPE RNS2 12 LAY IN TEAR: 18/10 PAINTED 12 12 24/24 35 0.20 6 50 NAILOR-HART SERIES 4600, TYPE RNS2 ENVIRO-TEC MDL SSD --1I, 1/2" DIAM SHAFT MIN 3 LONG, 90 DEG TURN, NO CONTROLS OR SENSORS EGGCRATE ,PAINTED 24/24 __. 24/24 1 600 USED FOR RETURN AIR GRILLE, NAILOR-HART 51 ECC - EGGCRATE 11110111111 PAINTED 12/24 -- 12/24 800 USED FOR RETURN AIR GRILLE', NAILOR -HART 51 ECC • MI VAR I ABLE AIR VOLUME TERMINAL UNIT VAV SCHEDULE • VAV -# ` QUANT . RANGE CFM PRIMARY AIR SURE DROP PRESSURE AT MAXIMUM CFM INCH WG MAX. 1 vC LEVEL @ 1.5" WG INLET TERMINAL SIZE INLET SIZE VAV BOX ` OUTLET INCHES R REMARKS VAV -6 0 -400 0.17 6 60 8/10 ENVIRO-TEC MDL SSD -II, I/2" DIAM SHAFT MIN 3" LONG, 90 DEG TURN, NO CONTROLS OR SENSORS VAV -8 0--700 0.16 8 80 12/10 ENVIRO-TEC MDL SSD -II, 1/2" Dl,4M SHAFT MIN 3" LONG, 90 DEG TURN, NO CONTROLS OR SENSORS VAV -I0 0 -1200 0.14 11111101111 10 1Ix8* 14 /I0 ENVIRO-TEC MDL SSD -II, 1/2" DIAM SHAFT MIN 3" LONG, 90 DEG TURN, NO CONTROLS OR SENSORS, VAV-12. 0 -1600 0.15 12 14x8* 18/10 ENVIRO -TEC MDL SSD -II, I/2" DIA,M SHAFT MIN 3 LONG, 90 DEG TURN, NO CONTROLS OR SENSORS VAV --I4 0-2000 0.11 36 14 I7x8 22/10 ENVIRO-TEC MDL SSD --1I, 1/2" DIAM SHAFT MIN 3 LONG, 90 DEG TURN, NO CONTROLS OR SENSORS 2 { t- 4 r +. lc u ,, k r fi� ' . iI ..N 4 1 4 IY , I. , RECD. DP WI NG (REDRAW I SS ' FOR tE UP PHAtE 314E .4 Igv isio1N I OVAL SIZE r ..t ,cr:: e rr. a. '• +> -'4 f APPROVED DK KR ...wt GS KR I IIIIIIIIIIIIIIIIIIIIII MUM orciftwoloosanformormincoth REVISION fr: • - p1. : u . _,i J1':- CI AUBURN, WA 98002 0 BELLEVUE , WA . 98007 4.4e4iMia EVERETT, WA 98201 FACILITIES DEPARTMENT 0 KENT , WA 98031 0 PORTLAND OR .'97220 0 RENTON, WA . 9 M SEATTLE, ,; 98124 .tk ! .E at a. w . . r:t ti :AL Wait, t ± j c . .sc• ✓j f''`r !:,'2 y'ti'ltj�'s"!- . "'t'R'..r:.�"' Y- ,•'' ;mo r.co'.i;. °. ;;: • ACCEPTAR I L I l'Y THIS DESIGN AND OR SPECIFICATION IS Ai `°.OVER APPROVED 3Y tit'x cif •'� } 1 1111 ' 11 1 I I 0 ,emst.c. 1 I I �IIIIl1l11llll�lIIII�ili II i trifFi 1`I 2 :3 4_ 5 6 7 r ' NOTE: if the asicrefilmed document is less clear than this notice, it is due to the quality of the original document. 1 111 9 11 1111111111111 I I WI I 11 MADE"(RRMANY 12 0e 1111111 OZ t St •it £I Zt Lt ()1, 6 8 L 6 se LZ 9Z SZ VZ £Z ZZ tZ 61 ,. 91 Lt 9 :. II � 11111 1 � II `` ! 9 1111 1111 111f11111111I111 111Ui111111111111111111111111� 1 111141111111Ill-11f1141 )1111111111111111111111111111 � 111111111111111111111111111 11 11 1111 1 1111(111 f 1 i' 1 1 1 .-_-. II 1 ° .I� l ,.. _. 1 I- l 1 ! 111 . tl. 1 .... , _i 1 11 i 11l. Ilil ++�, 111.1 f1�f. 1111111111II111111lII111�1+ lI111111111111lllllll ,ll�1111111111 .11! - ., :,. <: .. ... - .,.. :;.. .. .., i.. .. .., ..; •.. R .:,. ,, .. Z t yin' 0 TITLE BLDG 9.101 2 SCHEDULES MECHAMCAL 7 MASTER Cam.. N/A firicOvrp ITYOFTIili/ALA f 1 7 1`.ic, PEHa!'f CENTER S 0 ,., M OAKM50 RU inleattEER SHEET .0 NO. 910804 -07/ t 3 3 ' 9.101 Fg , • n. t .T T 4 1 asotomoramsseratsmonessamortisarsos 1 BELT TOTAL PANEL I PLEAT- PLEAT -2" VOLTS /PHASEI F,L.A. SENSIBLE 22 CONTEMPO MOOEL CEMC -05 SPLIT CAB NET , "UP" ARRANGEMENT, CYLINDE - HUMIDIFIER e „ e DRIVE TYPE SCHEDULE REVISION APPROVED DATE 0 16 ?MS INCH 1 2 FLOW GPM �111111IIiill11111111111Ilii11IIIf11 11 I F! 111111'I`G111"11 3 TYPE & DEPTH O AUBURN, ,WA 98002 0 BELL EVUE , VGA 98007 O EVERETT , WA . 982O 1 0 KENT', WA . 98031 O PORTLAND, OR. 97220 0 RENTON , WA . 98055 SEATTLE ,� A 98124 AIR COND 1 T ION 1 NG UNIT AC SCHEDULE s moK Y- NOMINAL FAN � FAN MOTOR COIL COOLING CAPACITY CHILLED WATER PD 41 MAX OIL LOCA710N TYPE CAPACITY DRIVE CAPACITY .ESP CAPACITY MBH RM TEMP 'F FLOW MAX CONN REMARKS NUMBER HP VOLTAGE PHASE FLA TONS TYPE CF�1 IN WG " , GPM � FLOW FT H2O SIZE RC2A10� TELEPHONE ROOM SPOT COOLER 2 DIRECT 880 0 5 - 1/3 208/230 I 3.2 24.1 36.0 80 67 � 42 5.4 I /2 "MPT BSC MODEL CW2, EXIST UNIT TO BE REUSED EXHAUSL . EF SCHEDULE . ., EXHAUST FAN MARK SERVED NUMBER (ROOM NO LOCATION AREA TOTAL S1IZE WHEEL ARRNGMT. STATIC PRESS. APPROX. DRIVE MOTOR VOLTS/PH '" REMARKS � DESIGN NUMBER CF1�� SIDE HP ::. f► ► . 4 � . A1�• lam: .. ...■ r► N .' - .fi , ili. .river J�r i( _ *.!�*�!!w•.. _ ... _.. _ . . .. _. _ . .. - .41%. .�• �w � .� � .. �IIY ,w;41.: ,:M�i. .■'rte. /i�► �... .w11 EFRDIIA ROOF, E12.2 2ND FLOOR CLG PLENUM 48 16100 0.25 310 V -BELT 480/3 GREENHECK GB 48--2 D, CENTRIFUGAL ROOF EXHAUSTER EFRDISP ROOF, E16.2 2ND FLOOR CLG PLENUM 48 --� 16100 0.25 310 V -BELT 480/3 GREENHECK GB 48-20, CENTRIFUGAL ROOF EXHAUSTER EFREJIA ROOF, E12 2ND FLOOR CLG PLENUM 48 -- 16100 0.25 310 V -BELT 2 460/3 GREENHECK GB 48 -20, CENTRIFUGAL ROOF EXHAUSTER CO VER E SON #3 EFRErI2A ROOF, E .5J 25' XH A T TATI - 3600 0.125 280 V -BELT 1/3 120/1 GREENHECK GB -300 -3, CENTRIFUGAL ROOF EXHAUSTER EFRE I2B ROOF, E . 9 ,12 , 8 TOILET ROOM EXHAUST 30 -- 6400 0. 600 V - BELT 480/3 GREENHECK GB -300-15, CENTRIFUGAL ROOF EXHAUSTER EFRE$SA ROOF, E16 2ND FLOOR CLG PLENUM 48 = 16100 0,25 300 V - BELT pilippl 480/3 GREENHECK GB 48 --20 CENTRIFUGAL ROOF EXHAUSTER WW ✓ �pr +.�7v!' y!�nr • v "+r,wr �,r *MP" '' :°' . fir! 'UMW Vii . \..► ' • �.�' ;, k .; 1411 ... :. .�' _ r �� ..�- ! IMF 'yl �' 4111111. . ' . "1"." . .... ► fi 14111.1w +. ..rr -"+.� • "�,�.w .1411111P * 111111. : ..,.wF III." III." �si • +,v► ..�► •4111111r r . . w. EFRFSA ROOF, E5.5 2_ FLSIR LG LEI 3 D65NV 4 18700 0. 5 11 • DIRECT 4 BUFFA s S i t E " r- L�`' S = VENT, WITH EXTENDED GREASE FITTINGS CFRFSB ROOF, F5.5 2ND FLOOR CLG PLENUM 36 D65NV 4 18700 0.25 1170 DIRECT 5 480/3 BUFFALO STYLE 'V" S0- L01NSKY- -VENT, WITH EXTENDED GREASE FITTINGS f .,EFRFSC ROOF, E5.5 2ND FLOOR CLG PLENUM 36 D65N1� ' 4 18700 0,25 1170 DIRECT Ma 460/3 BUFFALO STYLE s V" SO --LOW SKY-VENT, WITH EXTENDED GREASE FITTINGS E'RFSD ROOF, F5.5 2ND FLOOR CLG PLENUM 36 D65NV 4 18700 0,25 1170 DIRECT 5 460/3 BUFFALO STYLE "V" SO -LOW SKY - VENT, WITH EXTENDED GREASE FITTINGS DRAWL REi1 A ' 08.23.91 GPM TITLE sHEtT Exeines ivito . . . ittilitilmtf . pp I li j 1 1 1 .... < _ 5 , 6 w. :. � 7 8 ., ... ' 9 1 10 NOTE: if the i1crofilmed document is less clear than this ' i • _ notice, it is due to the Quality of the original document. OE: 6Z BG LZ 9Z GZ *iZ ' ee ee LZ OZ 6L SL GL 91 9L hl £L ZL LL 01, 6 I ` f 1 l li!( lli1111�IIIIIlif1ill) IIIIIIillill )_lI�II ii1ll lydi i!I i 11 iii l lllllllli�lllllllli1 llifll !!l+!!11l11! lltl�ll)Il Ilillllll1 11llil III i11l111111i 11:.1II)III ilil 'I ti , � , . .. ,: .�,:.... 1. l . 1I .�i_ ti.... �.. r O':iru. ,: I r.;' I � �% ��9. ) ) ACCEPTAB i i+ 1 TY THIS DESIGN AND/0R SPECIFICATION IS APPROVED APPROVED BY IDEPT Vi" Q 1i 11I11)11 TIIIi111111111111l1)11111 I UNIT ELECTRICAL DATA 480/3 1 22 1 CONTEMPO MODEL CEMC -05 SPLIT CABINET, "UP" ARRANGEMENT, CYLINDER NUM REMARKS RECEIVED CITY OF TUKWILA FAR 17 M2 PEHAMT CENTER Y XinF:;.M .r. ., FAN IIIIIIIIIIIIIIII BELT TOTAL PANEL I PLEAT- PLEAT -2" VOLTS /PHASEI F,L.A. SENSIBLE 111.1411C1.1.1.4111111111 22 CONTEMPO MOOEL CEMC -05 SPLIT CAB NET , "UP" ARRANGEMENT, CYLINDE - HUMIDIFIER e „ e DRIVE TYPE SCHEDULE REVISION APPROVED DATE 0 16 ?MS INCH 1 2 FLOW GPM �111111IIiill11111111111Ilii11IIIf11 11 I F! 111111'I`G111"11 3 TYPE & DEPTH O AUBURN, ,WA 98002 0 BELL EVUE , VGA 98007 O EVERETT , WA . 982O 1 0 KENT', WA . 98031 O PORTLAND, OR. 97220 0 RENTON , WA . 98055 SEATTLE ,� A 98124 AIR COND 1 T ION 1 NG UNIT AC SCHEDULE s moK Y- NOMINAL FAN � FAN MOTOR COIL COOLING CAPACITY CHILLED WATER PD 41 MAX OIL LOCA710N TYPE CAPACITY DRIVE CAPACITY .ESP CAPACITY MBH RM TEMP 'F FLOW MAX CONN REMARKS NUMBER HP VOLTAGE PHASE FLA TONS TYPE CF�1 IN WG " , GPM � FLOW FT H2O SIZE RC2A10� TELEPHONE ROOM SPOT COOLER 2 DIRECT 880 0 5 - 1/3 208/230 I 3.2 24.1 36.0 80 67 � 42 5.4 I /2 "MPT BSC MODEL CW2, EXIST UNIT TO BE REUSED EXHAUSL . EF SCHEDULE . ., EXHAUST FAN MARK SERVED NUMBER (ROOM NO LOCATION AREA TOTAL S1IZE WHEEL ARRNGMT. STATIC PRESS. APPROX. DRIVE MOTOR VOLTS/PH '" REMARKS � DESIGN NUMBER CF1�� SIDE HP ::. f► ► . 4 � . A1�• lam: .. ...■ r► N .' - .fi , ili. .river J�r i( _ *.!�*�!!w•.. _ ... _.. _ . . .. _. _ . .. - .41%. .�• �w � .� � .. �IIY ,w;41.: ,:M�i. .■'rte. /i�► �... .w11 EFRDIIA ROOF, E12.2 2ND FLOOR CLG PLENUM 48 16100 0.25 310 V -BELT 480/3 GREENHECK GB 48--2 D, CENTRIFUGAL ROOF EXHAUSTER EFRDISP ROOF, E16.2 2ND FLOOR CLG PLENUM 48 --� 16100 0.25 310 V -BELT 480/3 GREENHECK GB 48-20, CENTRIFUGAL ROOF EXHAUSTER EFREJIA ROOF, E12 2ND FLOOR CLG PLENUM 48 -- 16100 0.25 310 V -BELT 2 460/3 GREENHECK GB 48 -20, CENTRIFUGAL ROOF EXHAUSTER CO VER E SON #3 EFRErI2A ROOF, E .5J 25' XH A T TATI - 3600 0.125 280 V -BELT 1/3 120/1 GREENHECK GB -300 -3, CENTRIFUGAL ROOF EXHAUSTER EFRE I2B ROOF, E . 9 ,12 , 8 TOILET ROOM EXHAUST 30 -- 6400 0. 600 V - BELT 480/3 GREENHECK GB -300-15, CENTRIFUGAL ROOF EXHAUSTER EFRE$SA ROOF, E16 2ND FLOOR CLG PLENUM 48 = 16100 0,25 300 V - BELT pilippl 480/3 GREENHECK GB 48 --20 CENTRIFUGAL ROOF EXHAUSTER WW ✓ �pr +.�7v!' y!�nr • v "+r,wr �,r *MP" '' :°' . fir! 'UMW Vii . \..► ' • �.�' ;, k .; 1411 ... :. .�' _ r �� ..�- ! IMF 'yl �' 4111111. . ' . "1"." . .... ► fi 14111.1w +. ..rr -"+.� • "�,�.w .1411111P * 111111. : ..,.wF III." III." �si • +,v► ..�► •4111111r r . . w. EFRFSA ROOF, E5.5 2_ FLSIR LG LEI 3 D65NV 4 18700 0. 5 11 • DIRECT 4 BUFFA s S i t E " r- L�`' S = VENT, WITH EXTENDED GREASE FITTINGS CFRFSB ROOF, F5.5 2ND FLOOR CLG PLENUM 36 D65NV 4 18700 0.25 1170 DIRECT 5 480/3 BUFFALO STYLE 'V" S0- L01NSKY- -VENT, WITH EXTENDED GREASE FITTINGS f .,EFRFSC ROOF, E5.5 2ND FLOOR CLG PLENUM 36 D65N1� ' 4 18700 0,25 1170 DIRECT Ma 460/3 BUFFALO STYLE s V" SO --LOW SKY-VENT, WITH EXTENDED GREASE FITTINGS E'RFSD ROOF, F5.5 2ND FLOOR CLG PLENUM 36 D65NV 4 18700 0,25 1170 DIRECT 5 460/3 BUFFALO STYLE "V" SO -LOW SKY - VENT, WITH EXTENDED GREASE FITTINGS DRAWL REi1 A ' 08.23.91 GPM TITLE sHEtT Exeines ivito . . . ittilitilmtf . pp I li j 1 1 1 .... < _ 5 , 6 w. :. � 7 8 ., ... ' 9 1 10 NOTE: if the i1crofilmed document is less clear than this ' i • _ notice, it is due to the Quality of the original document. OE: 6Z BG LZ 9Z GZ *iZ ' ee ee LZ OZ 6L SL GL 91 9L hl £L ZL LL 01, 6 I ` f 1 l li!( lli1111�IIIIIlif1ill) IIIIIIillill )_lI�II ii1ll lydi i!I i 11 iii l lllllllli�lllllllli1 llifll !!l+!!11l11! lltl�ll)Il Ilillllll1 11llil III i11l111111i 11:.1II)III ilil 'I ti , � , . .. ,: .�,:.... 1. l . 1I .�i_ ti.... �.. r O':iru. ,: I r.;' I � �% ��9. ) ) ACCEPTAB i i+ 1 TY THIS DESIGN AND/0R SPECIFICATION IS APPROVED APPROVED BY IDEPT Vi" Q 1i 11I11)11 TIIIi111111111111l1)11111 I UNIT ELECTRICAL DATA 480/3 1 22 1 CONTEMPO MODEL CEMC -05 SPLIT CABINET, "UP" ARRANGEMENT, CYLINDER NUM REMARKS RECEIVED CITY OF TUKWILA FAR 17 M2 PEHAMT CENTER Y XinF:;.M .r. ., IIIIIIIIIIIIIIII BELT TOTAL PANEL I PLEAT- PLEAT -2" VOLTS /PHASEI F,L.A. SENSIBLE 111.1411C1.1.1.4111111111 22 CONTEMPO MOOEL CEMC -05 SPLIT CAB NET , "UP" ARRANGEMENT, CYLINDE - HUMIDIFIER e „ e DRIVE TYPE SCHEDULE REVISION APPROVED DATE 0 16 ?MS INCH 1 2 FLOW GPM �111111IIiill11111111111Ilii11IIIf11 11 I F! 111111'I`G111"11 3 TYPE & DEPTH O AUBURN, ,WA 98002 0 BELL EVUE , VGA 98007 O EVERETT , WA . 982O 1 0 KENT', WA . 98031 O PORTLAND, OR. 97220 0 RENTON , WA . 98055 SEATTLE ,� A 98124 AIR COND 1 T ION 1 NG UNIT AC SCHEDULE s moK Y- NOMINAL FAN � FAN MOTOR COIL COOLING CAPACITY CHILLED WATER PD 41 MAX OIL LOCA710N TYPE CAPACITY DRIVE CAPACITY .ESP CAPACITY MBH RM TEMP 'F FLOW MAX CONN REMARKS NUMBER HP VOLTAGE PHASE FLA TONS TYPE CF�1 IN WG " , GPM � FLOW FT H2O SIZE RC2A10� TELEPHONE ROOM SPOT COOLER 2 DIRECT 880 0 5 - 1/3 208/230 I 3.2 24.1 36.0 80 67 � 42 5.4 I /2 "MPT BSC MODEL CW2, EXIST UNIT TO BE REUSED EXHAUSL . EF SCHEDULE . ., EXHAUST FAN MARK SERVED NUMBER (ROOM NO LOCATION AREA TOTAL S1IZE WHEEL ARRNGMT. STATIC PRESS. APPROX. DRIVE MOTOR VOLTS/PH '" REMARKS � DESIGN NUMBER CF1�� SIDE HP ::. f► ► . 4 � . A1�• lam: .. ...■ r► N .' - .fi , ili. .river J�r i( _ *.!�*�!!w•.. _ ... _.. _ . . .. _. _ . .. - .41%. .�• �w � .� � .. �IIY ,w;41.: ,:M�i. .■'rte. /i�► �... .w11 EFRDIIA ROOF, E12.2 2ND FLOOR CLG PLENUM 48 16100 0.25 310 V -BELT 480/3 GREENHECK GB 48--2 D, CENTRIFUGAL ROOF EXHAUSTER EFRDISP ROOF, E16.2 2ND FLOOR CLG PLENUM 48 --� 16100 0.25 310 V -BELT 480/3 GREENHECK GB 48-20, CENTRIFUGAL ROOF EXHAUSTER EFREJIA ROOF, E12 2ND FLOOR CLG PLENUM 48 -- 16100 0.25 310 V -BELT 2 460/3 GREENHECK GB 48 -20, CENTRIFUGAL ROOF EXHAUSTER CO VER E SON #3 EFRErI2A ROOF, E .5J 25' XH A T TATI - 3600 0.125 280 V -BELT 1/3 120/1 GREENHECK GB -300 -3, CENTRIFUGAL ROOF EXHAUSTER EFRE I2B ROOF, E . 9 ,12 , 8 TOILET ROOM EXHAUST 30 -- 6400 0. 600 V - BELT 480/3 GREENHECK GB -300-15, CENTRIFUGAL ROOF EXHAUSTER EFRE$SA ROOF, E16 2ND FLOOR CLG PLENUM 48 = 16100 0,25 300 V - BELT pilippl 480/3 GREENHECK GB 48 --20 CENTRIFUGAL ROOF EXHAUSTER WW ✓ �pr +.�7v!' y!�nr • v "+r,wr �,r *MP" '' :°' . fir! 'UMW Vii . \..► ' • �.�' ;, k .; 1411 ... :. .�' _ r �� ..�- ! IMF 'yl �' 4111111. . ' . "1"." . .... ► fi 14111.1w +. ..rr -"+.� • "�,�.w .1411111P * 111111. : ..,.wF III." III." �si • +,v► ..�► •4111111r r . . w. EFRFSA ROOF, E5.5 2_ FLSIR LG LEI 3 D65NV 4 18700 0. 5 11 • DIRECT 4 BUFFA s S i t E " r- L�`' S = VENT, WITH EXTENDED GREASE FITTINGS CFRFSB ROOF, F5.5 2ND FLOOR CLG PLENUM 36 D65NV 4 18700 0.25 1170 DIRECT 5 480/3 BUFFALO STYLE 'V" S0- L01NSKY- -VENT, WITH EXTENDED GREASE FITTINGS f .,EFRFSC ROOF, E5.5 2ND FLOOR CLG PLENUM 36 D65N1� ' 4 18700 0,25 1170 DIRECT Ma 460/3 BUFFALO STYLE s V" SO --LOW SKY-VENT, WITH EXTENDED GREASE FITTINGS E'RFSD ROOF, F5.5 2ND FLOOR CLG PLENUM 36 D65NV 4 18700 0,25 1170 DIRECT 5 460/3 BUFFALO STYLE "V" SO -LOW SKY - VENT, WITH EXTENDED GREASE FITTINGS DRAWL REi1 A ' 08.23.91 GPM TITLE sHEtT Exeines ivito . . . ittilitilmtf . pp I li j 1 1 1 .... < _ 5 , 6 w. :. � 7 8 ., ... ' 9 1 10 NOTE: if the i1crofilmed document is less clear than this ' i • _ notice, it is due to the Quality of the original document. OE: 6Z BG LZ 9Z GZ *iZ ' ee ee LZ OZ 6L SL GL 91 9L hl £L ZL LL 01, 6 I ` f 1 l li!( lli1111�IIIIIlif1ill) IIIIIIillill )_lI�II ii1ll lydi i!I i 11 iii l lllllllli�lllllllli1 llifll !!l+!!11l11! lltl�ll)Il Ilillllll1 11llil III i11l111111i 11:.1II)III ilil 'I ti , � , . .. ,: .�,:.... 1. l . 1I .�i_ ti.... �.. r O':iru. ,: I r.;' I � �% ��9. ) ) ACCEPTAB i i+ 1 TY THIS DESIGN AND/0R SPECIFICATION IS APPROVED APPROVED BY IDEPT Vi" Q 1i 11I11)11 TIIIi111111111111l1)11111 I UNIT ELECTRICAL DATA 480/3 1 22 1 CONTEMPO MODEL CEMC -05 SPLIT CABINET, "UP" ARRANGEMENT, CYLINDER NUM REMARKS RECEIVED CITY OF TUKWILA FAR 17 M2 PEHAMT CENTER Y XinF:;.M .r. ., REVISION L ONGITUDINAL BRACE --- ---° -- LONGITUDINAL BRACE ---. -. --�'" BOLT DIA PER SCHEDULE 4- WAY /2 -WAY BRACING 2M60 M507 2M267 , 21273 , 2M2 2�6G,2M73,2M . 9 t.. � . ALL BRACING MATERIALS LISTED ARE THE MINIMUM FOR EACH PIPE SIZE AND BRACE LENGTH. STRONGER MATERIALS MAY BE SUBSTITUTED. ON 60 AND LARGER PIPES ANY P1546 ANGULAR FITTINGS ` USED WILL REQUIRE TWO BOLTS FOR FASTENING THE FITTING TO .THE UNISTRUT TO PREVENT SLIPPAGE. A TWO -WAY LATERAL BRACE WOULD FOLLOW THE SAME BRACING SCHEDULE, BUT NO LONGITUDINAL MEMBER WOULD BE.USED.:A`TWO WAY LONGITUDINAL BRACE WOULD NOTREQIJIRE THE LATERAL MEMBER. .m._ a . Tana. VA. w AO. -a.w lama a u+.aa. a _ •_ "fie. pm. looms sa %a 1t. NT. NOT ALL LONGITUDINAL BRACING REQUIRES TV MEMBERS REFERENCE ABOVE SCHEDULE FOR APPLICATIONS REQUIRING . ONLY ONE LONGITUDINAL MEMBER. REVISION LATERAL BRACE -- LONGITUDINAL BRACE 2�• it'R6C DIAMETER � OF LENGTH�� OF PIPE BRACE LATERAL BRACE MATERIALS LONGITUDINAL BRACE MATERIALS BOLT DIA L 8 UN I STRUT P ! 000 P100 0 0 4' 8' --IO' UNISTRUT Pa540, L 3x3xI/4 P5500 3/8" 0 --I5' 3 ` PIPE 3" PIPE 5 -6� L I0' UNISTRUT P5500, L 3x3xl /4 P5500 MEMBERS RQD I "� IO --15' 3"0 PIPE 3 PIPE � S / 5' UT PSOO P5500 2 MEMBERS RQD 5/8 "� UN I S'f R 8-120 5,....10, 2"0 PIPE, L 3 I /2x3 I /2x1/4 2"o PIPE 2 MEMBERS RQD FOR 8 "o PIPE I0' -I5 . 3 "o PIPE 3'0 PIPE 2 MEMBERS RQD . GREATER THAN GREATER THAN CONSULT W ENGINEER CO 12� - 15' - / CONSULT W /ENGINEER FOR LARGER CROSSMEMBER r I - II IIL � II . IL , 1 � I �, IIII �. IILI � I ...,.; iI0I+II � LIII ' 1 . .. FF11 O toTHsINCH 1 2 DETAIL LATERAL DUCT BRACING NTS 6" U -BOUT ACCEPTABILITY THIS DESIGN ANDAX SPECIFICATION IS APPR D . KLO1 Z TITLE BLDG 9.101.2 3 4 5 NOTE; If the !aicrofi tined document is less clear than this I notice, it is due to the quality of the Original. document. EXIST CEILING BEAM aria ... a .ems.. _ S aal. a a "Nola Villa arta a ++a wma a a. v..�w a n w a aa. a. a as U -BOLTS ARE OVERSIZED TO ALLOW FOR THERMAL EXPANSION D ETA 1 L. 2 -WAY BRACING FOR HWS, MNR AT LOCATION D -2.3 HWS IS ANCHORED. AT LOCATION D.7-3 IMR I S ANCHORED AT THESE LOCATIONS BRACE UNANCHORED PIPE INDIVIDUALLY WITH A LOOSE PIPE CLAMP AND ONE LATERAL UNISTRUT BRACE. O AUBURN, O BELLEVUE O EVERETT, O KENT, O PORTLAND O RENTON Al SEATTLE, 1'1'1 I:1111IWI1[ I OZ et et Lt 9l St Oil VARIES 2M10,2MIIM507 2M12,2M 2M60,2M6I,2M62 2M66 , 2M73 , 2M7 8 L 01, 6 f ! I+ II IIJIIIJJI tl 1 I 1111111 11it11111111111(ll11111111; )IIIIII 111 1110, I (III1IIII1 1 APPROVED BY } i "' ¢... + q,a.,� Y tr � , ' 1. ^, .a- - �,!:.;> ✓ ' 8" U -BOLT EXISTING HANGER EXISTNG BEAM nr cE:vr-.D CITY OP TUKW'ILA iAk 171 2 PERMIT CENTER BOLTS:'I /2 "0, 2 REQUIRED ON UNISTRUT TO PREVENT SLIPPING. U -BOLT OVERSIZED TO ALLOW THERMAL EXPANSION 2M60,2M66 M507 PLATE 3 112x1/4 -TYP MICHIGAN HANGER NO.450. 12>0 OR SUITABLE- "SUBST. NATURAL GAS PIPES 1" IN DIA AND LARGER SHALL BE-; LATERALLY..".: B RACED AT 20'7 ON CENTER :MAX AND LONG) " TUD I NALLV�' BRACED_ AT 0 0 ON CENTER MAX AS'PER DRAWINGS. 2. ALL OTHER PIPES AND CONDUIT 2.1/2" IN DIA. AND LARGER (OTHER THAN FIRE SPRINKLER PIPING) SHALL DE LATERALLY, BRACD: AT 40 ON CENTER MAX AND LONGITUDINALLY BRACED AT SC -O ON CENTER MAX AS PER DRAWINGS. BRACING IS NOT REQUIREp TOP OF THE PIPE IS SUSPENDED 12" OR LESS FROM THE SUPPORTING STRUCTURAL MEMBER. 3 ALL FIRE EY SIKLER CROSS MAINS AND FEED MAINS SHALL :BE; BRACED T 40 ON CENTER MAX AND LONGITUDINALLY BRACED 801-0" ON CENTER MAX AS PER DRAWING. LATERAL BRACING MAY BE OMITTED I F PIPES ARE SUPPORTED BY RODS' LESS 'THAN 6" LONG. SEE NFPA 13 FOR FURTHER DETAILS. DUCT 28 DIA AND LARGER AND LARGER AND:ROUND 4. ALL RECTANGULAR DUCTS Eft OF AREA w D L RGER. ALL SHALL BE LATERALLY' BRACED AT 30 -0 O N CENTER MAX LONGITUDINALLY BRACING SHALL OCCUR AT 6Q -0 O N CENTER MAX AS PER DRAWINGS. NO BRACING IS'REQUIRED IF THE TOP OF THE DUCT IS SUSPENDED 12" OR LESS FROM THE SUPPORTING STRUCTURAL MEMBER AND ATTACHED TO THE TOP OF THE DUCT, LAST' REV ISI4N 9;'161 -4,1507 0 7N OAKM : KH 5 B 3 I . 9 0 4 2 . •�✓Y L".2+.l�tie:4'sLw{ (.Su'MY6: T•7:4� } H. W'!.%! di�ws�l,l'I W' H,../ m,. Y' WR..Y`Ta.+^.S #y����•...y.....�. ' ` �I J i ACCEPTABILITY THIS DESIGN AND /CR SPECIFICATION IS APPROVED CONSTRUCTION NOT S: PIPING DETAILS DUPLEX AIR CONNECTION STEAM LINE nem USE 3* • SPACERS UNDER AIR HANDL UNIT TO PROVID E CLEARANCE BETWEEN N ACCESS DOORS AND CATWALK ACCESS DOOR . LOCAT I ON FAN 'MOTOR * SUPPLY AI SMOKE DETECTOR LOCATION FAN 'SECTION SUPPORT FLEXIBLE DUCT FROM . UN I STRUT. TO PROV I CE 18" ,MINIMUM STRAIGHT DUCT TO • DIFFUSERS DtO `NOT LAY FLEX ON CE ILING TILE SUPPORT FLEX ' DUCT ' 24 " ON CENTER WITH . 2 " WI DE''GALV SHEET METAL STRAPS ATTACHEDTO ;EMT TUBING SECURED TO UN 1 STRUT GRID= --1 DIFFUSER FAN SECTION * ACCESS DOOR *,MOTOR LOCATION UHPLAN DETAIL REDUCING WYE SHOWN, FITTINGS VARY AT END OF SUPPLY DUCT, SEE PLANS --\ TYPICAL 45' BOOT FITTINGS BRANCHES UNISTRUT L --VAV UN I T RUNOUT DUCT REDUCE TO SAME SI ZE J AS VAV UN I T 1 NL ET VAV TERM!NAL UN --- * ACCESS DOOR BOTH ENDS COOLING COIL TEE - SHOWN VARY AT SEE PLANS REVISION : OUTSIDE AIR 2MIO,2M14SIO 2MI6,2M29 ' * LOCATE ON SERVICE PLATFORM SIDE OF UNIT. SEE PLAN VIEW. . `-LOW PRESSURE SOUNDLINED'SHEET METAL DUCTWORK, FABRICATED WITH DUCTMATE JOINTS -TRANSITION, SL' I P AND DRIVE - FILTER /MIXING BOX - -SOUND LINED SHEET METAL DUCT UP 1U ROOF OPENING - -FLEXIBLE CONNECTION --AIR "MONITOR - FILTER /MIXING BOX 1 RETURN AIR SMOKE SENSOR LOCATION. SENSING PROBE TO EXTEND ACROSS WIDTH OF UNIT BEHIND RETURN AIR DAMPERS IN MIXING PLENUM RETURN AIR 06 6Z se Le 9Z 9Z +7Z 1tuI1140iriT66666661iii 1 1111 I I I I 1 I 1 I Er I T rfrr I f 1pTil'1'11 3 4 : NOTE: If the _: • notice. it is EXISTING BALL VALVE STRAINER (TYP) SUPPLY DUCT BOLT 22 GAUGE GALV STRAPS. AROUND NEW OR EXISTING UNISTRUT CHANNEL AND ROUND OR RECTANGULAR DUCTWORK t8 GAUGE DUCT BAND 3/4" DRAIN VALVE (TYP) PRESSURE AND TEMPERATURE TAP (TYP) PROVIDE 4" MIN WATER SEAL IN TRAP DETAIL — MEDIUM PRESSURE EASLLID1JCT HANGER EXISTING BALL VALVES (INSTALL NEW AS REQUIRED) THERMOMETER (TYP) • EXISTING CONCRETE BEAMS • ife $TUDN UTS .AND. NUTS TO , F I T EXISTING' ON I STRUT EMBEDDED I N CONCRETE BEAM ( TYP) - -- � ----� 1 5/8" UNISTRUT P5500 CHANNEL ---� f T iri 0 AUBURN , WA . 98002 O BELLEVUE , WA . 98007 D E ERETT , WA .• 98201 0 KENT , 98031 O PORTLAND OR . 97220 0 RENTON, WA . 98055 . SEATTLE WA , 98 124 UNISTRUT P 1 047 "t1 SHAPE FITTING WITH UNISTRUT P238I -4 STUDNUT AND I/2" NUT rtti'mr trrpwiripTfririltritrttlifil microfilmed document is less clear than this due to the quality of the original document. INSTALL PIPING CLEAR OF FAN AND FILTER ACCESS DOORS. USE SCHEDULED 40 BLACK STEEL PIPE WITH VICTAULIC COUPLINGS FOR CHW. USE SCHEDULED 40 .BLACK STEEL PIPE WITH SCREWED COUPLINGS FOR CONDENSATE DRAIN. USE SCHEDULED 40 BLACK STEEL PIPE WITH SCREWED OR.WELDED COUPLINGS FOR HW. INCREASE PIPE SIZE TO NEXT LARGER°'DIAMETER AT THERMOMETERS. PIPE AUTOMATIC AIR VENTS TO FUNNEL DRAIN WITH I /4" COPPER TUBING AND COMPRESSION FITTINGS. DETAIL — AH COIL CONNECTION DIAGRAM rs 2 7/16" UNISTRUT P5500 - UNISTRUT P238I --4 STUDNUT AND I/2" NUT (TYP) EXPIRES 9/1$1 ACCEPTABILITY 1 THIS DESIGN AND AR L EECIFICATION IS APPROVED APPROVED BY 10.09:91 SIMISAIS $jl.�r�"' f�.`X•d!'GtJJdiKitS9t� uR'i7e�c$ilfi�fC1�111� AHU'COIL SECTION LOCATE PIPING AND TRAP BELOW CATWALK SLOPE 1/8" PER FT TO EXISTING CONNECTION TROL VALVE BOLT NEW MEMBER TO BOTTOM OR TOP OF EXISTING 6'__O ON CENTER UNISTRUT MEMBER WITH UNISTRUT P238! -4 STUDNUTS AND I /2" NUT TO BOTTOM OR I/2"' A306 BOLTS, . NUTS AND LOCK WASHERS ON TOP 2M O,2MI 1 ,2M16 M510 2MI7,2M23,2M2 I�•I 11 y 111111 1111111111111111111 i 11 1111 11 1 0 11 hwx.GER.vo 12 18 GAUGE DUCT BAND `EXTEND STRAPS UNDER DUCT AND TEK SCREW- =mama TITLE BLDG 9.101.2 -TEK SCREW 22 GAUGE GALV STRAPS TO ROUND OR RECTANGULAR DUCTWORK EXISTING CONCRETE BEAM WITH EMQEDDED UNISTRUT CHANNEL UN l STRUT P3008 NUT WITH PI063 FLAT PLATE AND 3/8" BACKUP NUT DETAIL - MEDIUM PRESSURE NQRIISQUTH DUCT HANGER 2M10,2M11 M510 2M16,2Mf 2M23,2M29 EXISTING UNISTRUT GRID (OR BUILDING STRUCTURAL MEMBER) - BOLT 22 GAUGE GALV '.STRAPS AROUND,NEW EXISTING UNISTRUT CHANNEL AND ROUND OR RECTANGULAR DUCTWORK RECEIVED CITY OF TUKWIIA MAR 1 7 1 "92 PERMIT CENTER DETAILS EZIP PHASE a-e MECHANICAL MASTER ---EXISTING CATWALK ` CHANNEL OR HORIZONTAL STRUCTURAL 'I -BEAM .UNISTRUT ;. P 1649S BEAM _. CLAMP WITH 15/I6 "' BOLT, WASHER AND LOCK WASHER (TYPICAL) EXTEND STRAPS UNDER DUCT AND TEK SCREW (TYPICAL) Etelignitt LAST .,.,! -.: SHEET .. d� 101 1C ors1111111111l11 7,4 • nem USE 3* • SPACERS UNDER AIR HANDL UNIT TO PROVID E CLEARANCE BETWEEN N ACCESS DOORS AND CATWALK ACCESS DOOR . LOCAT I ON FAN 'MOTOR * SUPPLY AI SMOKE DETECTOR LOCATION FAN 'SECTION SUPPORT FLEXIBLE DUCT FROM . UN I STRUT. TO PROV I CE 18" ,MINIMUM STRAIGHT DUCT TO • DIFFUSERS DtO `NOT LAY FLEX ON CE ILING TILE SUPPORT FLEX ' DUCT ' 24 " ON CENTER WITH . 2 " WI DE''GALV SHEET METAL STRAPS ATTACHEDTO ;EMT TUBING SECURED TO UN 1 STRUT GRID= --1 DIFFUSER FAN SECTION * ACCESS DOOR *,MOTOR LOCATION UHPLAN DETAIL REDUCING WYE SHOWN, FITTINGS VARY AT END OF SUPPLY DUCT, SEE PLANS --\ TYPICAL 45' BOOT FITTINGS BRANCHES UNISTRUT L --VAV UN I T RUNOUT DUCT REDUCE TO SAME SI ZE J AS VAV UN I T 1 NL ET VAV TERM!NAL UN --- * ACCESS DOOR BOTH ENDS COOLING COIL TEE - SHOWN VARY AT SEE PLANS REVISION : OUTSIDE AIR 2MIO,2M14SIO 2MI6,2M29 ' * LOCATE ON SERVICE PLATFORM SIDE OF UNIT. SEE PLAN VIEW. . `-LOW PRESSURE SOUNDLINED'SHEET METAL DUCTWORK, FABRICATED WITH DUCTMATE JOINTS -TRANSITION, SL' I P AND DRIVE - FILTER /MIXING BOX - -SOUND LINED SHEET METAL DUCT UP 1U ROOF OPENING - -FLEXIBLE CONNECTION --AIR "MONITOR - FILTER /MIXING BOX 1 RETURN AIR SMOKE SENSOR LOCATION. SENSING PROBE TO EXTEND ACROSS WIDTH OF UNIT BEHIND RETURN AIR DAMPERS IN MIXING PLENUM RETURN AIR 06 6Z se Le 9Z 9Z +7Z 1tuI1140iriT66666661iii 1 1111 I I I I 1 I 1 I Er I T rfrr I f 1pTil'1'11 3 4 : NOTE: If the _: • notice. it is EXISTING BALL VALVE STRAINER (TYP) SUPPLY DUCT BOLT 22 GAUGE GALV STRAPS. AROUND NEW OR EXISTING UNISTRUT CHANNEL AND ROUND OR RECTANGULAR DUCTWORK t8 GAUGE DUCT BAND 3/4" DRAIN VALVE (TYP) PRESSURE AND TEMPERATURE TAP (TYP) PROVIDE 4" MIN WATER SEAL IN TRAP DETAIL — MEDIUM PRESSURE EASLLID1JCT HANGER EXISTING BALL VALVES (INSTALL NEW AS REQUIRED) THERMOMETER (TYP) • EXISTING CONCRETE BEAMS • ife $TUDN UTS .AND. NUTS TO , F I T EXISTING' ON I STRUT EMBEDDED I N CONCRETE BEAM ( TYP) - -- � ----� 1 5/8" UNISTRUT P5500 CHANNEL ---� f T iri 0 AUBURN , WA . 98002 O BELLEVUE , WA . 98007 D E ERETT , WA .• 98201 0 KENT , 98031 O PORTLAND OR . 97220 0 RENTON, WA . 98055 . SEATTLE WA , 98 124 UNISTRUT P 1 047 "t1 SHAPE FITTING WITH UNISTRUT P238I -4 STUDNUT AND I/2" NUT rtti'mr trrpwiripTfririltritrttlifil microfilmed document is less clear than this due to the quality of the original document. INSTALL PIPING CLEAR OF FAN AND FILTER ACCESS DOORS. USE SCHEDULED 40 BLACK STEEL PIPE WITH VICTAULIC COUPLINGS FOR CHW. USE SCHEDULED 40 .BLACK STEEL PIPE WITH SCREWED COUPLINGS FOR CONDENSATE DRAIN. USE SCHEDULED 40 BLACK STEEL PIPE WITH SCREWED OR.WELDED COUPLINGS FOR HW. INCREASE PIPE SIZE TO NEXT LARGER°'DIAMETER AT THERMOMETERS. PIPE AUTOMATIC AIR VENTS TO FUNNEL DRAIN WITH I /4" COPPER TUBING AND COMPRESSION FITTINGS. DETAIL — AH COIL CONNECTION DIAGRAM rs 2 7/16" UNISTRUT P5500 - UNISTRUT P238I --4 STUDNUT AND I/2" NUT (TYP) EXPIRES 9/1$1 ACCEPTABILITY 1 THIS DESIGN AND AR L EECIFICATION IS APPROVED APPROVED BY 10.09:91 SIMISAIS $jl.�r�"' f�.`X•d!'GtJJdiKitS9t� uR'i7e�c$ilfi�fC1�111� AHU'COIL SECTION LOCATE PIPING AND TRAP BELOW CATWALK SLOPE 1/8" PER FT TO EXISTING CONNECTION TROL VALVE BOLT NEW MEMBER TO BOTTOM OR TOP OF EXISTING 6'__O ON CENTER UNISTRUT MEMBER WITH UNISTRUT P238! -4 STUDNUTS AND I /2" NUT TO BOTTOM OR I/2"' A306 BOLTS, . NUTS AND LOCK WASHERS ON TOP 2M O,2MI 1 ,2M16 M510 2MI7,2M23,2M2 I�•I 11 y 111111 1111111111111111111 i 11 1111 11 1 0 11 hwx.GER.vo 12 18 GAUGE DUCT BAND `EXTEND STRAPS UNDER DUCT AND TEK SCREW- =mama TITLE BLDG 9.101.2 -TEK SCREW 22 GAUGE GALV STRAPS TO ROUND OR RECTANGULAR DUCTWORK EXISTING CONCRETE BEAM WITH EMQEDDED UNISTRUT CHANNEL UN l STRUT P3008 NUT WITH PI063 FLAT PLATE AND 3/8" BACKUP NUT DETAIL - MEDIUM PRESSURE NQRIISQUTH DUCT HANGER 2M10,2M11 M510 2M16,2Mf 2M23,2M29 EXISTING UNISTRUT GRID (OR BUILDING STRUCTURAL MEMBER) - BOLT 22 GAUGE GALV '.STRAPS AROUND,NEW EXISTING UNISTRUT CHANNEL AND ROUND OR RECTANGULAR DUCTWORK RECEIVED CITY OF TUKWIIA MAR 1 7 1 "92 PERMIT CENTER DETAILS EZIP PHASE a-e MECHANICAL MASTER ---EXISTING CATWALK ` CHANNEL OR HORIZONTAL STRUCTURAL 'I -BEAM .UNISTRUT ;. P 1649S BEAM _. CLAMP WITH 15/I6 "' BOLT, WASHER AND LOCK WASHER (TYPICAL) EXTEND STRAPS UNDER DUCT AND TEK SCREW (TYPICAL) Etelignitt LAST .,.,! -.: SHEET .. d� 101 1C ors1111111111l11 7,4 INSTALL 16 "x22" PANEL CUT FROM DUCT OF IDENTICAL SIZE, SECURE WITH TEK SCREWS 3 ", ON CENTER AND SEAL WITH FOAM GASKETING INSTALL 14"x2O" * PANEL OF IDENTICAL GAUG METAL AS DUCT,.GLUE ALL EDGES OF SOUNDLINING WITH HARDCAST DUCT SEALER, ALLOW DUCT SEALER TO DRY COMPLETELY BEFORE SECURING PANEL WITH TEK SCREWS 4" ON CENTER AND FOAM GASKETING RECORD ; 0 ` (RENUMBERED WAS M503) SR UE FOR E E I P PHASE 3-E SR (i)• DUCT HEIGHTS LESS THAN 14", MAKE PANEL HEIGHT 2 LESS THAN DUCT HEIGHT. SUPPORT DUCTWORK FROM UNISTRUT GRID WITH STRAP SHEET METAL. DATE pt1v.'N+�eatAi INSULATION CONTRACTOR TO MARK OUTLINE OF RECTANGULAR AOCESS PANEL WITH BLACK PERMANENT FELT TIP MARKER AND CROSS HATCH INTERIOR OUTLINE. 8.23.91 CUT 12" HIGH BY I,B» WIDE RECTANGULAR HOLE IN DUCT AND LINING REV 1SION 2M1 I ,2M12,2M16 M51 1 2M 17 , 2M23 , 2M2 X..u• � .� •7 1�r� ADD 12 EXTENTION AND SEPARATION SHEET TO SPOT COOLER. HANG FROM UNISTRUT GRID USING EXISTING HANGER BRACKETS ON UNIT COFFEE AREA PLUMBING 12'.4 ``���. Y,ti.•.t} t�St�� K , 't 2M16,2M66 O AUBURN , WA ..98002 O BELLEVUE , WA . 98007 0 EVERETT, . WA . 98201 0 KENT , WA . 98031 0 PORTLAND OR 97220 i RENTON, WA 98055 • SEATTLE WA 98124 !! l , l Ill l III li11111 11111I11111I111111J111!II I L(IJIfI , � IIL � LI , I - L r . I . I II 1 �'!'' ,f a) f r ! f ' 0 18 INS INCH 1 I 2 1 3 4 5 6 7 . > ..:. ...... .:. . ..Y =:r NOx'Rr If the microfilmed document is less clear than this notice, it is due to the quality of the Original document. tZ OZ 6t B. L 9t St <A et z� a 01. 6 8 G IIIII!1 !I1 11111111111 111111II1l l�l .41161!1IIf!Illi II! I 1.1. lit - 1! (11 ! i1111 3 f ACCEPTABILITY THIS DESIGN AND /OR SPECIFICATION IS APPROVED APPROVED BY DEPT. DATE e z I t W W p !!!!Ill'1{lllllllll I1!!111111llIIIII IIIIIIIfl l llll L.SAWYER DETAIL TITLE CHWR �°--�- CHWS CD BLDG 9.101.2 "FPT. CHWS AND CHWR T I O ONS UP 3/4"HW CONNEC- TION UP BALL VALVES (TYP) DETAIL -AIR CONDITIONER PIPING CONNECTIONS 4 AFTER REMOVING TWO SECTIONS FROM EXISTING PENTHOUSE AT GRID E -6) AS SHOWN, SCRAP REMAINING PENTHOUSE SECTIONS AND CAP ROOF OPENING AT LOCATION SHOWN ON ARCHITECTURAL DRAWINGS. - DETAILS PERMIT CENTER RM 17 ; RM2.3 M5 I I r....... CWIWO >� L} �M : P AO A OAKM5IIN K. t — y - 4 h . � �-.:` t' �' r ��c; ° ,' r Xf.S�."r�>- .`u,.,'�.,. ., � ,,,`•.: «..,$ '' is, 1"' �"'' �r '`.'�:':�°.�,'.'i'�:`�.�i's�,f �,- .'.1��*r' NEB FOIGINEERS �, ttttvw:'prti UNISTRUT SUPPORT BELOW ROOF SILICONE SEALANT -- RAIN LOOK GIRDER rcurbr�^ ' --- EXISTING NAILER -----2 CONCRETE PAVERS BALLAST .Aa :• 2" T & G INSULATION WITH 3 /8" CONCRETE WALKING SURFACE N _ 3 LIGHTWEIGHT CONCRETE RM23,RM29 M512 2M23,2M Aglik DUCT ELBOW UNDER ROOF UNISTRUT SUPPORT BELOW ROOF 512 — FAN SHEET METAL BASE SECTION 1/2.= R E L I E F FAN 60" ',INSIDE 0€ 6Z Be LZ 9Z GZ CZ ZZ 111111111111101110011111111111111;1116 11111111i 11161 J1111111111 �'r`;r;s;�,�✓4 s ti;:_.,• ;?" E X#'.'4.r<n''!:`+" � >r..s ��k .. :;3'�. `,fr'•`: SEE DETAIL O AUBURN, WA ..98002 O BELLEVUE ,'WA .: 98007 0 EVERETT , WA . 9820 I • 0 KENT , WA e 9803 I O PORTLAND, CSR., '97220 O RENTON, . , WA .''98055 • SEATTLE WA. 081 ?4 crROER .A � YY «Si'4 r ''3�,�'r, �'L>�� . �! • .4Yt�Jf ti,.;r 1` ; (° (` (- -I `I 11 ti' 1 I 11.1,'1' 1` ;" ` 11 4 5 6 ? 8 NOTE: If the microfilmed document is less clear than this notice, it is due to the quality of the priginal document, t oe, 61 91 Lt 91 SI t 1 CI el It p( 6 9 L I 9 I 1 Iulll1i 1111111111111111111 i111111�1111111Ii111 i11�111111111f11lfifilli . li !�ril nifililll I1 �1 1111.1 � L I L � 1 i f l 1il II llll1111n111111n11I 111I . nJ'. .. , ..... t.�.. ... . . ,..>,r .. , :.,.' , .c .:�. ` t?',.. _': J. 1,, .:-�• 'f, :!'S - . -tiz4 d .. r'•. +�_-'M , : 5 :.:I 1 M_' SECTION 4111i 1 II 1111111111111 ,1 1 . 11 1111 : 10 11 M GERM,ln 12 e \ I a 30 k60"1 SEE DETAIL SOUND LINING OLD 9.IOI,2 ':7rsfn.,res?.a+'gci: n: RECEIVED CITY OF TUC M A MAR t '7 1992. PERMIT CENTER ELBOW TO BE IS1' AETRI CAL' ABOUT ` COL E . ONE FACING EAST, ONE .FACING WEST (OPENINGS) OPENING TO FACE AWAY .FR COLUNM LINE E. DUCT ELBOW TO BE PREFABRICATED, BY SHEET METAL CONTRACTOR, AND INSTALLED BY BOEING. NEW FAN ADAPTER'CURBS FABRICATED AND INSTALLED BY BOEING (GCU). CONSTRUCTED OF WELDED 16 GAUGE SHEET METAL, PREDRILL ALL HOLES FOR ATTACHMENT TO EXIST (!G CURBS AND NEW FAN BASES. CAREFULLY.. . ; .r REMOVE EXISTING CURB CAPS. PAINT ADAPTERS WITH TWO COATS OF ZINC CHROMATE. ATTACH TO CURB WITH I /2 "x2" GALVANIZED LAG SCREWS, NOT MORE THAN 12" ON CENTER. VERIFY CURB ADAPTER DIMENSIONS ''AGA'I NS EXISTING CURB DIMENSIONS. A.CCEPTAB 11. i TY THIS DESIGN AND /OR SPECIFICATION IS APPROVED M'. Aa 41 ABOVE ROOF SEE SHEET RM23 ACCEPTAB1L I TY THIS DESIGN ANIVOR SPECIFICATION 15 AITROVED TOILET ROOM EXHAUST DUCT 33/33 TO 0 SEE SHEET 't gliERAtmi CONSTRUCT I ON NOTES : TOILET ROOM 85 HVAG PLANS UP PHASE 3-E MECHANICAL MASTER 101.2 COL E -Fill -3 r, PROV I DE FLOOR SUPPORT TO M A I N T A I N DUCT 12 ABOVE FLOOR (CONVERTER STATION LEVEL ) . WEIVED NO SCALE CITYOFTLIKOLA 1 7 t92 PER m UNTO . E X I S T I N G 20/35 EXHAUST DUCT TO REMA (CLEAN EXTERIOR AND INTERIOR AND SEAL ALL LONGITUD AN L) TRANSVERSE DUCT JOINTS WITH DUCT SEALANT REMOVE E X I S T I N G bUCKWORK SHOWN BY CROSS HATCH I NG RUN DUCT 1 N TRUSS SPACE [>• RUN DUCT BELOW TRUSS SEE SECTION A . M550 SASE 15> COORDINATE DUCT INSTALLATION TO AVOID . E X I S T I N G 3" SAN SEWER COORDINATE WITH EXISTING SPR:i NkL ER • PIPING. • uksl !try's* OAKM5502-. EXIST 1/2" 'HW UP & DN-- EXIST I 1/2" 44W & CW UP AND DOWN WATER HAMMER ARR PDI SIZE C WATER HAMMER ARRESTER PDI SIZE C WATER HAMMER ARRESTER PDI SIZE C ACCEPTABILITY Y DESIGN At40/OR SPECIFICATION IS APPROVED ' ABOVE CEILING — 2" BELOW FLOOR r-EX I ST 2"FD -EXIST 4 BELOW FLOOR TOILET ROOM 05 PLUMBING PLAN PHASE 'T:E MECHANICAL MASTER PERNWICENTER VENT . SANITARY WASTE PELOWFLOoR SANITARY WASTt.ABOVE FLOOR'. INDIRECT DRAIN DOMESTIC COLD WATER DOMESTIC HOT WATER DOMESTIC HOT WATER cmcuLAfIN CLEAN OUT WALL CLEAN OUT CONNECT TO EXISTING 3" SAN BELOW FLOOR UN CONNECTION BELOW COUNTERTOR MAKERS. USE CHICAGO #1015 STOP . VALVE AT WALL. CW CONNECTION FOR VENDING MACH1NE. CHICAGO /1015 STOP VALVE AT THERMOSTATIC TEMPERING VALVE, LEONARD MODEL II0B. 0 . OAKM551 2 MdC/03. 04.92 J.4 /12.45 atom%54-4,1,,,,,e41111464Awuvowoncwootoatioommimoil040410114-,—,,- BE&C FOR ADDITIONAL SPRINKLER PIPING IN THIS AREA SEE SHEET 2M273 EXTENT OF PHASE 34 ACCEPTAB I L I TY THIS DESIGN AhD SPECiFICATiCti IS APPROVCB APPRovED BY 1 OEFFTITZI t iMairgagt s fil r 4 e cEILING LEVEL PENDENT SPRINKLig HI AND UPRIGHT HEAD BELOw' E THER iDr FLOOR OR CONVERTER 'ROOM FLOOR . PENDENT SPRINKLER HEA: UPRIGHT SPRINKIIR CONVERTER ROOM' FLOOR TRUSS .LEVEL IN TOILETS AND BELOWJDF:ROCWI FLR SPRINKLER RISER . . ALARM VALVE' ON FIRST FLOOR SPRINKLER PIPING SECTIONAL VALVE NUMBER *- GENERAL NOTES: I. FIRE PROTECTION PIPING IS SIZED BASED ON NFPA 13, 1991 EDITION ORDINARY HAZARD OCCUPANC I ES, TABLE 6-5.3,3. ORIFICE SIZE 1 " UPRIGHT OR PENDENT tlECEIVF.I) CITY 171592 pawn CENTER CONNECT TO EXISTING 6" RISER. CAP- EXISTING 2' CONNECTION. ' CONNECT TO EXISTING 3 AT WALL. OAKM5522' MiC/03-04 .(1ST FLOOR) NOTES: ALL PIPING SLAB iS IN ALL PIPING SLAB iS IN ABOVE CORED TOILET ROOM #5. BELOW CORED TOILET ROOM #1 ACCEPTABILITY THIS DESIGN AIDjD#n SPEC I F I GAT ION I S APPROVED APPROVED BY TOILETROOM#5SCHEMAT1C_PIPJiNG D & VENT nrs TOILET ROOM bb PLUMBING DIAGRAM EEP PHASE 3—E MECHANICAL MASTER T,CCEIVED CITY OF TUKWI!A OAR 17 1592 PERMIT CENTER LAST REVISION !SHEET AS of • aau i ' Oft M. MEN'S TOILET ROOM FD 9 2ND FLOOR UP TO SECOND FLOOR WOMEN'S SOWER CONTINUED DN TO MEZZANINE SECTION! ONLY 'RADIUS ELBOWS PERMITTED. MINIMUM c RADIUS AT Ix DUCT HEIGHT TITLE rDG 9.101.2 COI. GENERALNEEL FIRE DAMPER MOUNTED IN 16 GA. SHEET METAL SLEEVE, FIREPROOF OPENING AROUND DUCT Its FLOOR WITH CEMENT GROUT. . TOILET ROOM HVAC PARTIAL PLAN AND SECTION ACCEPTABILITY THIS DESIGN AND /OR SPECIFICATION IS APPROVED A,K1LLIP1, G. MIH COORDINATE DUCT CLEARANCES WITH EXISTI SPRINKLER AND DRAINAGE P.I P I NG zBEL.GN' TRUSS SPACE. COORD I NATE DUCT CLEARANCES WITH 'EX 'STING 3NSAN SEWER IN TRUSS SPACE, €',4•ri bI• Tl oII-A APPROV E Y a N .. G.eRE?�1� ., OAKM554N CONNECT TO WI FAUCET INLiNE FLOW CONTROL (FURN WITH WH) — REVISION COUNTER TOP CONNECT TO C FAUCET r - CW SUPPLY I (BEHIND WALL) I/2" 3-WAY ANGLE STOP VALVE AT WALL 2M79 M555 R.!VIS!ON i 1/2 NOTE: .0 SET TANKS TO OPERATE AT 120 . ( CONNECT TO EXISTING DRAIN. PRV RELIEF LINE SIZE TO BE NOT LESS THAN PRV DISCHARGE PORT SIZE. (PRV'S FURNISHED WITH WATER HEATER). QOMETIQHOT.ATER DIAGRA - DETA /z1 DATE PLUMBING DETAILS ENGINEERS LAST REVIStQH ' ACCEPTABILITY THIS DESIGN AND /OR SPECIFICATION IS APPROVED CIRCULATION PUMP W, W. GRAINGER #1P761, TEEL ; CAST IRON BODY WITH CERAMIC IMPELLER, /20 HP, II5V -I PHASE, 4.8 GPM AT 7' HD. MAGNETIC DRIVE. CONSTRUCTII ON NOTES : RECEIVI-a) CITY OF TUKWILA MAR 17 i PEHMIT CENTER 101-M555 . . . . DOMESTle HOT WATER HEATER SCHEDULE -------- ,.,.MARK AqumBEIR LocATION Om) TYPE DELIVERY RATE ELECTRICAL DATA STORAGE CAP (GAL) • REMARKS , MODEL NO. ,,,,D " OPERATING PRES. INPUT RATING VOLTS MAX. MIN. KW /PHASE WH2AOIA A I INSTANTANEOUS S-801 I,Q 150 45 8 38 208/1 0 CHRONOMITE WITH 1.0 'GPM FLOW CONTROL VALVE WKAIOA A-IO INSTANTANEOUS S-801 1.0 150 45 .. 8 38 208/1 0 CHRONOMITE WITH I 0 GPM FLOW CONTROL VALVE WH2D63A D-3 INSTANTANEOUS 01 1:0 150: ' 8 38 .208/1 0 CHRONOMITE WITH 1.0 CPM FLOW C' TR VALVE WH2DI8A::. WH2H04A D-I8 '4 INSTANTANEOUS INSTANTANEOUS S S4301 1.0 TO 150 . 150' . 45 ,.. 8 8 38 38 20' I .20 1 0 CHRON0i#11TE WITH 1.0 CPM FLOW CONTROL VALVE CHRONOMITE 4.1Th TO CPM FLOW CO RS VALVE WH2t12A E-12 STORAGE DSE-I00 . 16 15 18 480/3 100 CONVERTER STATION NO.3 - A.O. SMITH -qr -- bitH2E120 mmw E STORAGE _ Ilmw 115E-100 150. . -- 15 ---- 18 .morlimr, 480/3 100 CONVERTER STATION NO.3 - A.O. SMITH WATER CLOSET WATER CLOSET URINAL LAVATORY REVISION ,CONNECTIONS INCHES VENT ON p) SCHEDULE 1/2 1. 3/4 - 1 WALL HUNG, FLUSH VALVE WALL HUNG, FLUSH VALVE I BARRIER-FREE cogi5M OVAL SELF RIMMING COUNTER TOP, VITREOUS CHINA STAINLESS STEEL VITREOUS ENAMELED CAST IRON OE er WofiltifiholhifihifihmhdiffihmilifihodinOm • 3 4 • ; 1 1 —I I 2 " 3 0 AUBURN, WA. 98002 0 BELLEVUE , WA . 98007 0 EVFRFTT , WA . 98201 0 KENT , WA . 98031 0 PORTLAND , OR . 97220 0 RENTON , WA . 98055 II SEATTLE , WA. 98124 f lir Ili 4 5 6 7 „E3 NOTE: the microfilmed document is less clear than this notice, it is due to the quality of the original document. OZ el 91 LI, 91 91 in et Zt 1.1. 01, 1 . . . 014163ing 11 WDEINKnWft 12 ACCEPTABILITY T H I S DES! GN - ANIVCR SPECIFICATION IS APPROVED TITLE BLDG 9.101.2 LE>. NEW COMPONENTS WITH EEIP tircEIWO artolt.ToomA MAR 1 7 1992 PERIVIIICENTiR TOILET FIXTURE SCHEDULES -___- MECHANICAL MASTER PHASE 3-E. BESIC EBIGNIEERS otilincesentlp.Mswastowsatowevemi. LAST nvistow SWEET.- ? fi Mff .t_ y.. 4 REVISION M570 M572 150 PSI DRIP LEG-- I 1/2" STM 50'PSI 3/4" 3/4" UP 87,50 psi STM HEADER I,/2" BUCKET RAP 3/4" I" DRAIN 2 I/2" DRAIN PUMPED HEADER CONDENSATE • PT PLUG PT PLUG R S PT PLUG WOOD DECK CONDENSATE PUMPED CP2EI3A CONDENSATE PUMPED CP2EI3B PRV PILOT VALVE I0000 # /HR PRESSURE REDUCING STATION M57 ! M573 3/4 150 PSI CONDENSATE WOOD DECK ' 6" HOT WATER RTN HEADER " 70 CONVERTER PU2FI3A oc 6Z ed IX 9Z GZ iiIII,i 11fIiiII , IIllilh IIIIIII1It !IIllIIIIIIJI0illlil� aj IU w Imo COPPER TUBING BACKFLOW PREVENTER B RAIN LINE HUB DRAIN • �'1l,� x.ti!t3F"'a3 � S�`,';�} x,�n � k �:.x �1 . r. PU2FI3B PU2FI3C REMOVED PU2FI3D 4 "HOT WATER RETURN BYPASS -- r-- - - - - -- -- 0 AUBURN WA . 98002 O BELLEVUE , WA . 98007 O EVERETT , " WA . 98201 O KENT, WA 9803 O PORTLAND , OR 97220 0 RENTON . ; WA -98055 • SEATTLE`, WA. 98124 2 "HUB DRAIN M570 --LINE OF PLATFORM ABOVE AUTOMATIC 3-WAY CONTROL VALVE I /2 "V 4 "HWS PRESSURE GAGE 0 TO I ±0 PS1 L 1i i1 . I1I I , I I1r tI lin i L I , '.' 1 ' Ii I 3 4 5 6 7 .a ' NO`1'B: If the microfilmed ...... d document is less clear than this notice, it is due to the quality of the priginai document. IL O1 6 1 ill�iilllllllllllllilllliillllli�iill EXPIRES. Wei I w eat; o . v. 34 + '•� ,.4 lI � ll 9 10 ACCEPTABILITY THIS DESIGN AND /OR SPECIFICATION IS AOPR IED 'NILE G DATE DEPT. BLDG 9 M 2 COL E4/1 2-- 13 rer:.xw - R"CE t) CITY OF TUKWILA i'IAN 1 7 f:t 2 PERMIT CENTER GENERAL NOTES: I. ALL COMPONENTS ARE EXISTING UNLESS NOTED OTHERWISE . CONSTRUCT I ON NOTE REMOVE EXISTING I 0 " STEAM LINE AS "SNCWN. REFER TO SHEET M57 I R FOR CONTINUATION. OF LINE FROM SOURCE AFTER DO ESTIC HOT WATER' PRV STATiON. TAP INTO BOTTOM OF EXISTING 8 "' , STEAM . HEADE F AND EXTEND. NEW SUPPLY DOWN TO�EXISTING 1 1/2" STEAM LINE, ST A M PI P'INO STEAM CONDENSATE P I PI HEATING WATER SUPPL HEATING WATER RETURN - DOMESTIC HOT WATER DOMESTIC HOT WATER C t RCULAT; U DOMESTIC COLD °WATER GATE VALVE CHECK VALVE BALL VALVE BALANCE VALVE GLOBE VALVE POINT OF CONNECTION 9 10140 k > ...1 �, �.. .., x�:C .w r �:•)::. .1 .w w`'it.14. .M.�.G':.i:: +�.4 .t' Y'' r?Y �7t✓���. a�.��J:'S lad,` _, . '„ter.; +:,> r.tvFT,taY: lti' f'M7 2"HWS TO HIGH BAY 3 "I-I VR FROM 2ND FLOR AHU M571 M572 M571 M572 NEW AGUASTAT NEW I "PVR RELIEF NEW I I/2" 3/4" . DRIP PAN BELOW 5" GLOBE VALVE CONVERTER HX2F 13B 2 I/4" it BUCKET TRAP 200 # /HR 47 h :011 ;,.4. ,111; 11= BOP EL 21' -3 AFF FOR CONTINUATION OF ALL LINES, . SEE SHEET 2M79 FOR CONTINUATION SEE SHEET 2M73 M57I M574 11111 11II111111I 11 11111 0 16THSINCH NEW TEMPERATURE SENSOR TO CMCS 4"CIRC SETTER NEA- TEMPERATURE SENSOR TO r _ CMCS r'Y 6" HOT WATER SUPPLY HEAD R -- --PLUG COCK OPERATION FROM PLATFORM ID AGE GLAS VALVE IN VE'TIC•L NEW TEMPERATURE SENSOR TO CMCS ,�,. ..;:c - ^l " -.' , .q .'i :CP.r. a ..�5':<rw. *:frif-. )k'•; Y}.• ".:'�: OF BEAM ENGINgiteg O AUBURN , WA 98002 O BELLEVUE , WA . 98007 O EVERETT , WA . 9820 O KENT , < VGA 98031 0 PORTLAND , OR . 97220 • RENTON WA . 98055 • SEATTLE , WA 98124 M571 M573 TOILET ROOM EXHAUST DUCT 33x33 TO EFREI2B SEE SHEET RM23 1 /2 "STM 50 PSI 4 "HWS TO 2ND FLOOR AHU ACCEP'IABI,L I TY THIS DESIGN AND/OR SPECIFICATION IS APPROVED 9 5 tl £ Z t W W 0 II 1111I f1111111111111i11 Ili1111!11111111 likilliih l l) TITLE BLDG 9.101 2 GENERAL NU_ T S .nECENE D CItY CFTI II(`r'JILA '1Ar. 1 7 1 PI' twri CENTER STEAM PIPING STEAM CONDENSATE PIPING HEATING WA - SUPPLY HEATING WA''ER RETURN DOMESTIC HOT WATER I REST I C HOT WATER: C I RCULAti O DomESTIC COLD. WATER INDIRECT DRAIN GATE VALVE CHECK VALVE BALL VALVE BALANCE VALVE GLOBE VALVE POINT OF CONNECTION I. XL- COMPONENTS ARE EXISTING UNLESS NOTED OTHERWISE. CONSTRUCTION NOTES REPLACE EXISTING 3' PRV•STATION WITH, NEW 2" PRV AND 3 BACKFLON PREVENTER' AS SHOWN (NEW VALVES, STRAINER: AND REDUCERS INCLUDED). D>. INSTALL NEW PRESSURE GAUGE WITH `51 PHt AND NEEDLE VALVE. INSTALL AND PLUMB(2) NEW'D WATER HEATERS AS SHOWN, NEW I/2 "STEAM LINE TO COMPUTER ROOM HUMIDIFIERS SEE SHEET M571R. D522›. NEW I 1/2" 50 PSI STEAM " SUPPLY. REFER . TO FLAG NOTE 2 ON SHEET M570. TAP INTO 'UNDERSIDE OF EXISTING`8 ° STEAM HEADER. Lam NEW WORK GENERAL AREA. iY!.a�.A• REVISION 2 "HWS TO HIGH`BAY 2 I/2` ` 10 PSI CONDENSATE M571 M572 M57I M572 4 Yci..w, -a %J CONVERTER HX2FI3A I /2" THERM TRAP 3 4" I CONVERTER HX2F 13B . I/2 " SUPPLY TO CONDENSATE PUMP REVISION BOP EL 21 ' -3" AFF 6" HOT WATER RETURN HEADER r w 4" RAI GAGE GLASS M57 M573 E M57 M574 (j Zfi 111111111 11 0 IS THS INCH 1 3/4 CONDENSATE I" CITY WATER MAKE UP CONNECT TO VALVED CONNECTION I /2 "PRV 60 TO 12 PSI WITH BUILT IN STRAINER TO DRAIN 4 " rk 4 ' j RELIEF VAL S 'r 4 CONTROL V ' E THERMOSTAT --AIR VENT QUICK FEE VALVE M57 ACCEPTAB 1 L I TY THIS DESIGN AND/OR SPECIFICATION I S APPROVED APPROVED BY O AUBURN, WA. 98002 O BELLEVUE , WA 98007 O VERET i WA . 9820 • KENT A. 98031 0 PORTLAND, OR . 97220 O RENTON , WA . 98055 O SEATTLE , WA . 98124 THERMOSTAT t'' F' c '.-, ti ky e t.r. [OTT I (.�T 1 1 ' I I, I I I I ' I I , 11 I . I , , I'll 4 5 6 NOT I f the microfilmed document is less clear tha►. this notice, it is due to the quality -of the original document, 1z ()Z 61 El LA 9! 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CAP RELIEF VENT THROUGH EI2> REMOVE CONDENSATE LINES AND CAP AT TERMINATION. 42:1 REMOVE 1/2" STEAM LINE AS SHE, INSTALL NEW 1/2" STEAM LINE, FROM EXISTING SUPPLY TO CONDENSATE PUMPS TO POINT OF • REMOVAL AS SHOWN. REFER TO SHEET M57I. BECEIVeD CITY OF Tt.I<, a,I.A iiAW 1 ► i .;2 pE I I CENTER ey' .`SV.4r; • 2 I/?" PUMPED CONDENSATE ACCEPTAGILITY THIS DESIGN A.' 1'��C_f�? SPECIFICATION I S AWED APPROVED BY I" 150 PS I CONDENSATE 2 1 /2" : PL IPED CONDENSATE TO 1100- -1210 PSI O 10 PILOT VALVE 6 -0" MIN COOLING LEG • 8" 50 PSI STEAM HEADER 1/2" THERMOSTATIC TRAP 5" GLOBE VALVE Zi Ohl'•+ 2" WOOD SLEEPER SECTION THERMOMETER 6 "STM 50 PSE — BUCKET TRAP 550 # /HR M570,M571 M572 GAGE GLASS TEMPERATURE SENSOR ___J RELIEF VALVE (EACH CONVERTER) 15-GPM --SET 60 PSI -RUN TO DRAIN B M57j572 10 'MS INCH 1 2 1 . 1 i !.Z 9Z 9Z t' EZ ZZ IIIIIIIi!III IIIIIIIl IIIIIIIH F4[l1J.IIdIIiIbl hi COMPRES TANK • TOILET ROOM 05 BELOW - 3/4 „ DRAIN "AIR TROL" FITTING TOILET ROOM # BELOW AQUASTAT 24/20 TOILET ROOM EXHAUST DUCT O AUBURN , WA 98002 O BELLEVUE, WA . 98007 O EVERETT, WA . 98201 0 KENT WA . 98031 O PORTLAND, OR : 97220 El RENTON , WA 98055. SEATTLE , WA. 98124 lx41. Ko fit. • i I± : f ' ; 4 • j � 1 i [I,1. ( ,1 , • , a:: f l I! l III 4 5 5 7 S . ... n-.... .J::....^.. - »•. °r- <i.;.'.. sit- a ".t r c ^.l: �. c�..... :r. ... NOTE: i f the microf filmed document is less clear than this notice, it is due•to the quality of the Original document. 1Z Q Z 6l fit a 9 `` l 91 VI EL Zl I i 0 1 1111UI, IIIlIII1 1111111111.111111111.1111! IIIIIIIIIIIIIIIIII 11Y11I11i 111 11 11111 0011111 111 111111111111 9/18/ ,yX1, p NEW . � ► ugi (REFER TO STRUCTURAL DRAWINGS FOR SUPPORT OF WATER HEATERS) NEW HOT WATER `RECIRCULATION FROM TOILET ROOM BELOW a L ww IIIIIIII ' �II1111111� 1I11111111ll llll'1 I�ii4111`�rl 1�f RECEIVED CITY OF'TUKW LA it Ai 't 7 1i2 PEHMIT CENTER I. ALLCOMPONENTS ARE EXISTING UNLESS NOTED OTHERWISE. STEAM CONDENSATE I i P I NG HEATING ,WATER SUPPLY HEATING WATER AEIRN DOMESTIC HOT WAT DOMESTIC HOT WATER- CIRCULAfi DOMESTIC COLD WATER GATE VALVE CHECK VALVE BALL VALVE BALANCE VALVE GLOBE VALVE POINT OF ' CONNECTION NEW WATER HEATER REFER TO DRAWSNG §HEE M571. Cl'",>. NEW WORK GENERAL AREA E hi DRIP PAN ELBOW 3/4" RUN TO DRAIN 1/4 CHECK VALVE PRESS GAGE I F O - Q to 4 " ..,., ;is :4 . ., -M: Y. ..o. N.Rrr -..., w5 3RM �eSi 9d e. prKiv., .'x .vy,r�<<i�aye EPRE'I2A SEE SHEET RM23 rr-AUTOMAT I C CONTROL VALVE -5" GATE VALVE AUTO AIR VENT 3» HOT WATER `RUN TO CONVERTER 1 PRESS REDUCE VALVE 5000#/HR ' 150-125 PSI TO 10 PSI PILOT VALVE TO DRAIN 9 ViV � :f 1 y2j` . f fMC t'S� I 3 "'HWR 'PT PLUG -- 3 "VENT RtvPSION •.4 ROOF EL 66'-- I/2" .-1 /2u BUCKET TRAP 2 1/2 6 "CONDENSATE RETURN HEADER Ill ►IIIItIII1IIllII1111 0 i6THSIHCH 1 RUN TO DRAIN 6" HOT WATER SUPPLY HEADER HOT WATER CIRCULATING PUMP— PU2FI3D PUMP BASE, SEE ORIG AUSTIN CO DWG 6130D-101-227 2" WOOD DECK ACCEPTABILITY ' THIS DESIGN AND /OR SPECIFICATION I S APPROVED. oc 6Z 9c /.Z 9Z SZ $7Z 111111111(I111 iiiIIIII tIIliii ii nll�l i I I M570,M571 CONVERTERS HX2F 13A & ,B 5/8" PLYWOOD DECK FLOOR EL 53'-4 3/4" M570 , M571 NEW I "PRV RELIEF NEW 5 GALON EXPANSION TAK M573 r' 8 "HEADER 3/4" RELIEF VALVE S 60 P I TOILET ROOM #5 BELOW DRIP TRAP 3/4" 50 PSI CONDENSATE .2 1 /2" PRESSURE REDUCING TAT,I( N • rF:tt x i. f'RR't� L >•r TOILET'ROOM #5 BELOW I l 111 l I I rJ1 j l : I , i f rill l E 1 I 3 4 5 6 • =i.:� 4..��:,� -... ._ �C1' tii v4: . .aY ::•wXi:i� �>4' ."Yki.Y:' NOTE: If the �sicrofilmed document is 0;, AUBURN WA . 98002 O BELLEVUE WA 98007 Q EVERETT , WA . 98201 a KENT', WA : 98031 O PORTLAND , OR , 97220 O RENTUN , WA 98055 •. SEATTLE:, WA . 98124 �% ' ,1 N v --st _r� ..:.��,....P. ,sA„ t. rte a`J. -a. less clear than this notice, it is due to the quality of the original document. Ll 91. Si hl El Zl It OL 6 p ilU11iIIIIIIIti iI II x iii1III I i iI IUII 1 111 ?I I II llIIII x f y tl:. E)( RES a:19/ ?ir DRIP PAN ELBOW RELIEF VALVE — 1/2" PUMPED CONDENSATE ,--- 3 "HWR 2 1/2" 10 PSI CONDENSATE I" 150 PSI CONDENSATE 3/4 DRAIN 2 "DRAIN HEADER .::1'.Y. ni, . J; •�7�,. -• ;�y! J. 7�t?Ch 11l.t T::.l 1111111b CONVERTER STATION NO.3 SECTIONS TIT4E PHASE �_C DG T MECHANICAL MASTER COL I2 -13t4 GLNERA NQTES I ..ALL_COMPONENTS ARE EXISTING ' UNLESS NOTED OTHERWISE STEAM PIPING STEAM CONDENSATE P'IPI HEAT I NG' WATER` SUPPLY HEATING WATER'RETURN DOMESTIC HOT WATER DOMESTIC HOT WATER CIRCULAI1 DOMESTIC COLD WATER GATE VALVE CHECK VALVE BALL VALVE BALANCE VALVE GLOBE VALVE POINT OF CONNECTION CONSTRUCT aN N °TS �- CAP EXISTING 2 ". STEAM LINER REFER TO DEMOLITION DRAWING M571R. .INSTALL 2 NEW DOMESTIC WATER HEATERS AS SHOW REFER TO DWG SHEET;M571 RECEIVED CITY OF T(J (WILP NAk 171 i2 pEkmIT CENTER OAKM5 7 t'° a KH t 03. HX2FI3D MANUAL AIR VENT REVISION NEW 1/2 STEAM --- 2 I /2 "HWS 6 "I-IWS HEADER 'HWR HEADER _. - PT PLUG PRESSURE GAGE 0- -100 PSI PT PLUG ROOF EL 66 '-' 5/8" PLYWOOD DECK FLOOR EL 53' -4 3/4" M571 M574 CI SETTER SETTER -- 3 "HWR CI RC SETTER AND THERMOMETER IN HORIZONTAL RUN THERMOMETER STRAINER GATE VALVE 2 "DRAIN HEADER O AUBURN, WA. 98002. 0 Br' L EVI IE , WA . 98007 O EVERETT, WA. 98201 0 KENT, WA, 98031 0 PORTLAND, OR . 97220 O RENTON, WA. 98055 ▪ SEATTLE, WA .- 98124 't . � "; <J t�'. �^ ?. `^. �� n" "+ J gr:±•ix F 3 ': ,::.; .,�. - n� . S "a y;; Y ta:r �'G ;>b KG r 1.. t� -; r+a •fi•.� 'i7.;. 111 I + !' 1, :, i . l 1 1 q 1 r I 1 I i L 111 .111 i 1 . I , a 141 I} I .... 4 5 6 . .... 7. ._ ... a . . NOTE: if the microfilmed document is less clear than this notice, it is due to the. quality of the original document. I3 OZ 61 81 Lt 91 Sl bl CI et II p I i. 6 111 iti! 11i!1I! il1111 i11U lIIIIJIII1IIIIIIIIIIIIIIIIIIIIii iJ iIII I 1IIIIIII! I i I II1i ii q v 11iI1IIIIIIiti Ili 'x'..Y it i X J9 . A' J .L ,t `r^ - :.P3•(`K`f exPia ' 9V18// 9 S E z l ww Q 1111 ( 1111 i 1111 111111111111 111111 1111111 11111 I I I 11 11111111111111 01111 1 1111111111111 11 MADE IN GERMAN 12 ACCEPTABILITY THIS DESIGN ANl /QR SPECIFICATION I S APPROVED TITLE BLDG 9.101.2 CO, E$/!2I3 GENERAL . ALL_ COMPONENTS ARE EX I STING UNLESS NOTED OTHERWISE. RECEIVE CITY RECEIVED TUK WILA i41.1 7 1 r f V V PERMIT CENTER CONVERTER STATION NO.3 SECTION E€iP FHA 3-E MECHANICAL STEAM P I P ING STEAM CONDENSATE P 10 HEAT 1 NG WATER SUPPLY HEATING WATER ACTON DOMESTI Hat WATER.,. DOMESTIC HOT WATER GIRCULAT`1 DOMESTIC COLD`WATER GATE VALVE CHECK VALVE BALL VALVE BALANCE VALVE GLOBE VALVE POINT OF CONNECTI Ei ne ISIGIONEVIS 141 Py 7 P-T PLUG (TYP) 40 - 260°F CIRCUIT SETTER MARK SETTING AFTER SYSTEM is BALANCED 6" l/2 " TO DRAIN - DRIP TRAP 200 # /HR CONVERTER 2 I /2N`._. -,„ BUCKET TRAP I5,000, /HR 1 HX2F 13,c AUTO 3-WAY PU ?F 13A 6 "HWS HEADER C I R C U I T SETTER- - E 0 -100 PSI TEMPERATURE SENSOR Q JYERTr R 'T0 DRAIN . 4" FLANGE UNION N-- .0.9 1 LIENSAIL ,QO9LE 4O 2a0'F 100'PS1 -7 1 /2"V 0 I5 THS INCH 1 DRIP TRAP 200 /HR 40' TO 260'F 1/2" THERMOSTATIC. I TRAP 2 Iz , HX FI LOOP, TO MAINTAIN CONDENSATE COOLER HALF FULL '6" AIR TRAP TO 2ND FLOOR AHU NEW 1 /2* 5Q PSI STEAM TO COMPUTER ROOM HUMIDIFIERS TO STRUCTURAL TEST AREA TO 1ST FLOOR UNIT HEATER CONVERTER STATION N0.3 HOT WATER FLOW D I AGRAM (LOCATED ON SOUTH MEZZANINE OVER SECOND FLOOR TO I LET ) LZ 9Z 9Z 4 /Z EZ Z tZ OZ 61 61 Lt 91 9l VI. III)IIIIIIL11111111I1111j iI)d�L1Jll ltlll111.11111IIl�1111 l llllllilIhllJll U11111011101111111111111 -..._ a. rJ..• ._ .. y..�. ..._ i...:t_S A.��N'ff:'}. ..Vbty. 4 �n xr / y 3/4 40' -260'F 2 1/2" BUCKET TRAP. 15,000 # /HR -- 6" CONDENSATE HEADER ROOM TRAP TO DRA I N---- , O AUBURN , WA 98002 O BE L i EVUE WA . 98007 O EVERETT a WA. 98201 O KENT , WA ::98031 O PORTLAND 0R . 97220 RENTON WA , 98055 SEATTL , WA , 98 124 r� :Y . : . 1I ; I ! IilL . I . I ; . : , 1 I I , I '1.111 I,I1 4 5 6 7 _.....�.._..... e ..... NOtE: If the microfilmed document is less clear than this notice, it is due to the quality of the original document. �w r S.v.: , :.r•N +({S�t.: ,. �.�Sx.iYNb � <r.3S�.C .�:CYr %. "t � l r Et Zl tt OL 6 8 G �,,l� I n�l111I ns�IIII� Illl lill�I �11 lI�11iulilllllln�� (�IiII)if . .: Y. _ ...:�� _ • � /��..YHxrr'�' -�'L ,Y µ, W )r 1 PR. ' Nis ACGE UESI A1L /oR ilITY SPEC i F I GAT f ON IS A . PROVED LmY mv}sto QUICK FILL GAGE GLASS 1 IIIIIIIlIIIIIIIiIIIIIIII. 111111111 111111 I 10 11 MADENOEMOW 12 BLDG • 9.101 2 Cam. E-0711 13 LEGEN. I ° ------ HWS HEATING WATER, SUPPLY --- H M HEATING WATtR RE1i)RN. 64 GATE VALVE. --- CHECK VALVE — ----K 1 ' BALL VALVE BALANCE VALVE GLOBE VALVE POINT Of CONNECT'I ON SAL NOTES: I.-ALL—COMPONENTS ARE EXISTING UNLESS NOTED OTHERWISE. 11EC;EtVED CITY OF TU KWE1A �Y` 4st. .�w.�Y .. �JY�dM.� - ; r : L'.'�'. f..�.:?. ,`Yr7/skPX? `��. /•'.` •••••..... . :`... „ 4!„ iS� *[�^.'#SSfi[rtti'yY+'+.,{'.'aP_ /.s :.ttii PROVIDE NEW 50 ,PSI ' STEAM , SOURCETO EXISTING HUMIDIFIERS, REFER M57 I . x: CONTROLS CONTRACTOR `TO "REPLACE EX I ST I NG: ; � THERMOSTATS WITH 'NEW TEMPERATURE :SENSORS (5 LOCATIONS). CONTROLS CONTRACTOR,WILL PROVIDE AND INSTALL NEW : � > THERLLS AS REQUIRED. .TNT' I( �..' 1 AKI<r� �t3 O a �5 I� � I . t PIPING MECHANICAL MASTER AUTOCLAVE NO 5 ADDITION TUNNEL NO 1 UTILITY PIPING AND DETAILS FIRST FLOOR PLAN SECTION