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PP - 11010 TUKWILA INTERNATIONAL BLVD - SIX ROBBLEES - PERMITS AND PLANS
11010 TUKWILA INTERNATIONAL BLVD ASSOCIATED PERMITS 04-S-228 94-F-249 Grinnell FIRE PROTECTION SYSTEMS COMPANY 1215 Central Avenue So., Suite 128 Kent, Washington 98032-7425 Tel: (206) 859-5066 Fax: (206) 859-5255 Contractor's License No. GRINNFP137LE May 14, 1997 Six Robblee's Inc. 11010 Pacific Highway So. Seattle, Wa 98168 Attn. Mr. Arine Blankers RE: Tire Storage at the above project r mai Dear Gentlemen: Your firm requested the existing fire sprinkler system be evaluated for the design density requirements for Tire Storage to a 12'-0" height. The design density from N.F.P.A. #231-D Storage of Rubber Tires, 1994 Edition, this application is also approved per City of Tukwila Fire Prevention Dept. Grinnell Fire Protection Systems Company has established a design density and area for 12'-0" height storage at .39/2600 sq. ft. The existing fire sprinklers are 1/2" orifice, 165 temp. and spaced at 80 sq. ft. The fire sprinkler system has treed branchlines and looped crossmains supplying the system. See attached sketch of existing fire sprinkler system. The Hydraulic analysis work sheets (see attached) show that required water supply is 59.12 psi @ 1826.3 gpm to provide the existing system with proper water demand per figure 4-1.2, see attached copy from N.F.P.A 231-D. Please be advise that City of Tukwila Fire Prevention is still reviewing the requirements for Fire Hose Stations within the building. This information will be provided to the City of Tukwila Fire Prevention Dept. Attn: Don Tomaso. Contact Ken Bryner at Grinnell Fire Protection 253-859-5066 ext.3036 with any questions and/or concerns. Thank you. Sincerely, Kenneth W. Bryner Service/Design cc. City of Tukwila Fire Prevention Dept. Mr. Don Tomaso A */SCO INTERNATIONAL LTD. COMPANY ENGINEERED FIRE SYSTEMS October 17, 1994 Tukwila Fire Department 444 Andover Park East Tukwila, Washington 98188 AF1'ENTION: Fire Protection Engineering SUBJECT: Six Robblees Fire Protection System Remodel Gentlemen: I would like to take a moment of your time to explain Engineered Fire System's scope of work as it relates to the above mentioned project. During the first stage of our work, we will remove the existing halon system electrical components, i.e. control panel, detectors, manual stations, etc. Second, using existing conduit, we will install a new Fenwal 2210 halon control panel, smoke detectors above and below the ceiling, indicating appliances, manual stations, and all new wiring. During stage three, we will test the interface of the new electrical system with the existing halon mechanical system. We will also inspect the integrity of the room, and any penetrations found will be sealed. The final stage of our work will include testing for approval from the Tukwila Fire Marshal. Please see the attached data submittals and drawings for equipment description, FM and UL Approvals, battery calculations, etc. Should you have any questions, please contact me at 575-3637. Thank you for your time and attention. Sincerely, ENGINEERED FIRE SYSTEMS, INC. Michael B. Myers MBM:gmd 1994/WPS/6ROBLEFS 3138 Commercial Drive • Anchorage, Alaska 99501 • (907) 274-7973 • Fax (907) 274-6265 1158 Industry Drive • Seattle, Washington 98188 • (206) 575-3637 • Fax (206) 575-3631 231D-1 Copyright 1994 NFPA. All Rights Reserved NFPA 231D Standard for Storage of Rubber Tires 1994 Edition This edition of NFPA 231D, Standard for Storage of Rubber Tires, was prepared by the Technical Committee on Rubber Tires and acted on by the National Fire Protection Associ- ation, Inc., at its Annual Meeting held May 16-18, 1994, in San Francisco, A. It was issued by the Standards Council on July 14, 1994, with an effective date of August 5, 1994. and supersedes all previous editions.. The 1994 edition of this document has been approved by the American National Standards Institute. Changes other than editorial are indicated by a vertical rule in the margin of the pages on which they appear. These lines are included as an aid to the user in identifying changes from the previous edition. Origin and Development of NFPA 231D A tentative standard on the storage of rubber tires was developed by a subcommittee of the Committee on General Storage and adopted by the National Fire Protection Asso- ciation, Inc. at its 1974 Annual Meeting in Miami Beach, FL. The first official edition of NFPA 231D was prepared by the Committee on General Stor- age. It included revisions made to the tentative standard and was adopted by the Associa- tion at its 1975 Fail Meeting in Pittsburgh, PA. The 1980 edition was a partial revision of the 1975 edition, and the 1986 edition was a partial revision of the 1980 edition. The 1989 edi- tion contained guidelines for outdoor storage of scrap tires in Appendix C. The 1994 edition of the standard incorporates findings from recent full-scale fire tests. The concept of miscellaneous storage was introduced, and the suggestions for fighting rubber tire fires in sprinklered buildings were revised. Additional changes were incorpo- rated to further enhance the document's user friendliness. NI;)ttaV:i•: >I Kl_iitirIt 11Kh, Storage height (ft) c a 0 c a to 20 15 10 <5 5000 4000 3000 2000 0t 03 04 05 Sprinkler density , gpm/tt2) ,Ordinary emp. 1 sprinklers High temp. sprinklers 06 Figure 4-1.2 Sprinkler system design curves for palletized portable rack storage and fixed rack storage with pallets over 5 ft to 20 ft (1.5 m to 6 m) in height. 4-2 High -expansion Foam Systems. 4-2.1* High -expansion foam systems installed in accor- dance with NFPA 11A, Standard for ,Medium -and High - Expansion Foam Systems, as modified herein, shall be permit- ted to be installed in addition to automatic sprinklers. Where so installed, a reduction in sprinkler discharge density to one-half the density specified in Table 4-1.2 or 0.24 gpm/ft2 [(9.78 L/min)/m], whichever is higher, shall be allowed. 4-2.2 High -expansion foam systems shall be automatic in operation. 4-2.3 Detectors shall be listed and shall be installed at the ceiling at one-half listed spacing in accordance with NFPA 72, National Fire Alarm Code. 4-2.4 Detection systems, concentrate pumps, generators, and other system components essential to the operation of the system shall have an approved standby power source. 1994 Edition 4-3 Water Supplies. 4-3.1 The rate of water supply shall be sufficient to pro- vide the required sprinkler discharge density over the required area of application plus provision for generation of high -expansion foam and in -rack sprinklers where used. 4-3.2 Total water supplies shall include provision for not less than 750 gpm (2,835 L min) for hose streams, in addi- tion to that required for automatic sprinklers and foam systems. Water supplies shall be capable of supplying the demand for sprinkler systems and hose streams for not less than 3 hours. Exception: For on -floor storage up to and including 5 ft (1.5 mi in height. hose stream requirements shall be permitted to be 250 gpm (946 L'mini, with a water supply duration of not less than 2 hours. 4-3.3* Where dry pipe systems are used, the area of sprinkler application shall be increased by not less than 30 percent. 4-4 Manual Inside Protection. 4-4.1 Where automatic sprinkler protection is provided, small hose [ 11/2 in. (38 mm)] shall be provided to reach any portion of the storage area. Small hose shall be supplied from one of the following: (a) Hydrants: (b) A separate piping system for small hose stations; (c) Valved hose connections on sprinkler risers where such connections are made upstream of sprinkler control valves; (d) Adjacent sprinkler systems. 4-4.2 Portable Fire Extinguishers. Portable fire extin- guishers shall be provided in accordance with NFPA 10, Standard for Portable Fire Extinguishers. Cp to one-half of the requirement complement of portable fire extinguishers for Class A fires shall be permitted to be omitted in storage areas where fixed, small hose lines [ 11/9 in. (38 mm)] are available to reach all portions of the storage area. 4-5 Hydrants. At locations without public hydrants, or where hydrants are not within 250 ft (76 m), private hydrants shall be installed in accordance with NFPA 24, Standard for the Installation of Private Fire Service .blains and Their Appurtenances. 4-6 Alarm Service. 4-6.1 Automatic sprinkler systems and foam systems, where provided, shall have approved central station. auxiliary, remote station, or proprietary waterflow alarm service. Exception: Local waterflow alarm service shall be permitted to be provided where recorded guard service also is provided. NOTE: See NFPA 601, Standard on Guard Service in Fire Loss Prevention. 1 4-6.2 Alarm service shall comply with NFPA 72, National Fire .4/arm Code. 4-7* Fire Emergency Organization. (Also see Appendix B.) FIRE PROTELTiU\ 231D -U Table 4-1.2 Piling Method Piling Height (ft) Sprinkler Discharge Density (gpm/ft2) (See Notes 1 and 2) Areas of Application (fe) (See Note 1.) Ordinary Temp. High Temp. (1) On -floor storage (a) Pyramid piles on -side (b) Other arrangements such that no hori- zontal channels are formed (See Note 3.) Up to 5 0.19 2,000 2.000 Over 5 to 12 0.30 2,500 2.300 Over 12 to 18 0.60 N/A 2.300 (c) Tires on -tread (See Note 4.) Up to 5 0.19 2.000 2.000 Over 5 to 12 0.30 2,500 2.500 (2) Palletized portable rack storage (a) On -side or on -tread Up to 3 0.19 2,000 2,000 Over 5 to 20 See Figure 4-1.2 Over 20 to 30 0.30 plus high -expansion foam 3,000 3.000 (b) On -side 20 to 25 0.60 and 0.90 (see .Vote 5); or NiA 3.000 N/A 3.000 0.60 with 1 -hr fireproofing of roof and ceiling assembly; or 0.75 N/A 4.000 N/A 4,000 (3) Open portable rack storage. on -side or on -tread Up to 5 0.19 2,000 2,000 Over 5 to 12 0.60 5,000 3.000 Over 12 to 20 0.60 and 0.90 (see Vote 5); or N/A N/A 0.30 plus high -expansion foam 3,000 (4) Single-, double-, and multi -row fixed rack Up to 5 0.19 2,000 storage on pallets, on -side or on -tread 5,000 3.000 3,000 2,000 Over 5 to 20 See Figure 4-1.2; or 0.40 plus one level in -rack sprinklers; or 3,000 3,000 0.30 plus high -expansion foam 3,000 3,000 Over 20 to 30 0.30 plus high -expansion foam N/A 3.000 (5) Single-, double-, and multi -row fixed rack storage without pallets or shelves. on -side or on -tread Up to 5 Over 5 to 12 Over 12 to 20 0.19 0.60 0.60 and 0.90 (see Vote 5); or 0.40 plus one level in -rack sprinklers; or 2,000 5.000 N/A N/A 3,000 2,000 3.000 5,000 3.000 3,000 0.30 plus high -expansion foam 3,000 3,000 Over 20 to 30 0.30 plus high -expansion foam N/A 3.000 (6) Laced tires in racks See A-4-1.2. NOTE 1: Sprinkler discharge densities and areas of application are based on a maximum clearance of 10 ft (3.1 m) between sprinkler deflectors and the max- imum available height of storage. The maximum clearance is noted from actual testing and should not be viewed as a definitive measurement. The authority having jurisdiction should use the appropriate judgement where this distance is modified. NOTE 2: The densities and areas provided in the table are based on fire tests using standard response, standard orifice [Ya in. (12.7 mm)]. and Targe orifice (17/32 in. (13.5 mm)] sprinklers. The use of extra large orifice (ELO) (5'8 in.) sprinklers shall be permitted where listed for such use, and where installed at a minimum operating pressure of 10 psi (69 kPa). In buildings where "old style" sprinklers exist, discharge densities shall be increased by 25 percent. For use of other types of sprinklers, consult the authority having jurisdiction. NOTE 3:• Laced tires on -floor, vertical stacking on -side (typically truck tires), and off-road tires. NOTE 4: Piles shall not exceed 25 ft (7.6 m) in direction of wheel holes. NOTE 5: Water supply shall fulfill both requirements. NOTE 6: N/A = Not applicable. For SI units: 1 sq ft = 0.0929 m!: I gpm/sq ft = 40.746 (Llmin)/m2. 1994 Edition SPRINKLER SYSTEM HYDRAULIC ANALYSIS Date: 04/28/1997 JOB TITLE: SIX ROBBLEES WATER SUPPLY DATA SOURCE NODE TAG I STATIC PRESS. (PSI) RESID. PRESS. (PSI) 150.0 102.0 FLOW (GPM) 4000.0 AGGREGATE FLOW ANALYSIS: TOTAL FLOW AT SOURCE TOTAL HOSE STREAM ALLOWANCE AT OTHER HOSE STREAM ALLOWANCES TOTAL DISCHARGE FROM ACTIVE SPRI AVAIL. TOTAL PRESS. @ DEMAND (PSI) (GPM) 138.7 1826.3 otection CRI Page 1 SIXROBBL.SDF REQ'D PRESS. (PSI) 59.1 26.3 GPM 750.0 GPM 0.0 GPM 4°1076.3 GPM NODE ANALYSIS DATA NODE TAG ELEVATION (FT) NODE TYPE PRESSURE (PSI) I 0.5 SOURCE 59.1 1 21.0 K= 5.60 31.0 2 21.0 K= 5.60 31.7 3 21.0 K= 5.60 32.7 4 21.0 K= 5.60 35.0 5 21.0 K= 5.60 36.2 6 21.0 39.6 7 21.0 K= 5.60 36.6 8 21.0 K= 5.60 35.4 9 21.0 K= 5.60 33.1 10 21.0 K= 5.60 32.0 11 21.0 K= 5.60 31.4 12 21.0 K= 5.60 31.0 13 21.0 K= 5.60 31.7 14 21.0 K= 5.60 32.7 15 21.0 K= 5.60 35.0 16 21.0 K= 5.60 36.2 17 21.0 39.6 18 21.0 K= 5.60 36.6 19 21.0 K= 5.60 35.4 20 21.0 K= 5.60 33.1 21 21.0 K= 5.60 32.0 22 21.0 K= 5.60 31.4 23 21.0 K= 5.60 31.1 24 21.0 K= 5.60 31.7 25 21.0 K= 5.60 32.8 26 21.0 K= 5.60 35.1 27 21.0 K= 5.60 36.3 28 21.0 39.7 29 21.0 K= 5.60 36.7 30 21.0 K= 5.60 35.5 31 21.0 K= 5.60 33.2 32 21.0 K= 5.60 32.1 33 21.0 K= 5.60 31.5 DISCHARGE (GPM) 1076.3 31.2 31.5 32.0 33.1 33.7 33.9 33.3 32.2 31.7 31.4 31.2 31.5 32.0 33.1 33.7 33.9 33.3 32.2 31.7 31.4 31.2 31.5 32.1 33.2 33.7 33.9 33.4 32.3 31.7 31.4 SPRINKLER SYSTEM HYDRAULIC ANALYSIS Page 2 Date: 04/28/1997 SIXROBBL.SDF JOB TITLE: SIX ROBBLEES NODE TAG ELEVATION NODE TYPE PRESSURE DISCHARGE (FT) (PSI) (GPM) 34 21.0 K= 5.60 37.0 34.1 35 21.0 K= 5.60 37.8 34.4 36 21.0 K= 5.60 39.0 35.0 37 21.0 41.7 38 21.0 42.5 39 21.0 44.0 40 21.0 44.0 41 21.0 44.0 42 21.0 44.0 43 21.0 44.0 44 21.0 44.0 A 20.0 45.0 B 20.0 44.7 C 20.0 44.6 D 20.0 44.6 E 20.0 49.5 F 20.0 50.0 G 5.7 56.3 H 3.0 58.0 SPRINKLER SYSTEM HYDRAULIC ANALYSIS Date: 04/28/1997 JOB TITLE: SIX ROBBLEES PIPE DATA Page 3 SIXROBBL.SDF PIPE TAG Q(GPM) DIA(IN) LENGTH PRESS. END ELEV. NOZ. PT DISC. VEL(FPS) HW(C) (FT) SUM. NODES (FT) (K) (PSI) (GPM) F.L./FT (PSI) Pipe: 1 -31.2 1.380 PL 8.00 PF 0.6 1 21.0 5.6 31.0 31.2 6.7 120 FTG ---- PE 0.0 2 21.0 5.6 31.7 31.5 0.078 TL 8.00 PV 0.3 Pipe: 2 -62.7 1.610 PL 8.00 PF 1.1 2 21.0 5.6 31.7 31.5 9.9 120 FTG ---- PE 0.0 3 21.0 5.6 32.7 32.0 0.134 TL 8.00 PV 0.7 Pipe: 3 -94.8 1.610 PL 8.00 PF 2.3 3 21.0 5.6 32.7 32.0 14.9 120 FTG ---- PE 0.0 4 21.0 5.6 35.0 33.1 0.287 TL 8.00 PV 1.5 Pipe: 4 -127.9 2.068 PL 8.00 PF 1.2 4 21.0 5.6 35.0 33.1 12.2 120 FTG ---- PE 0.0 5 21.0 5.6 36.2 33.7 0.148 TL 8.00 PV 1.0 Pipe: 5 -161.6 2.068 PL 5.00 PF 3.4 5 21.0 5.6 36.2 33.7 15.4 120 FTG T PE 0.0 6 21.0 0.0 39.6 0.0 0.228 TL 15.02 PV 1.6 Pipe: 6 162.5 2.068 PL 3.00 PF 3.0 6 21.0 0.0 39.6 0.0 15.5 120 FTG T PE 0.0 7 21.0 5.6 36.6 33.9 0.230 TL 13.02 PV 1.6 Pipe: 7 128.6 2.068 PL 8.00 PF 1.2 7 21.0 5.6 36.6 33.9 12.3 120 FTG ---- PE 0.0 8 21.0 5.6 35.4 33.3 0.149 TL 8.00 PV 1.0 Pipe: 8 95.3 1.610 PL 8.00 PF 2.3 8 21.0 5.6 35.4 33.3 15.0 120 FTG ---- PE 0.0 9 21.0 5.6 33.1 32.2 0.290 TL 8.00 PV 1.5 Pipe: 9 63.1 1.610 PL 8.00 PF 1.1 9 21.0 5.6 33.1 32.2 9.9 120 FTG ---- PE 0.0 10 21.0 5.6 32.0 31.7 0.135 TL 8.00 PV 0.7 Pipe: 10 31.4 1.380 PL 8.00 PF 0.6 10 21.0 5.6 32.0 31.7 6.7 120 FTG ---- PE 0.0 11 21.0 5.6 31.4 31.4 0.079 TL 8.00 PV 0.3 Pipe: 11 -31.2 1.380 PL 8.00 PF 0.6 12 21.0 5.6 31.0 31.2 6.7 120 FTG ---- PE 0.0 13 21.0 5.6 31.7 31.5 0.078 TL 8.00 PV 0.3 Pipe: 12 -62.7 1.610 PL 8.00 PF 1.1 13 21.0 5.6 31.7 31.5 9.9 120 FTG ---- PE 0.0 14 21.0 5.6 32.7 32.0 0.134 TL 8.00 PV 0.7 Pipe: 13 -94.8 1.610 PL 8.00 PF 2.3 14 21.0 5.6 32.7 32.0 14.9 120 FTG ---- PE 0.0 15 21.0 5.6 35.0 33.1 0.287 TL 8.00 PV 1.5 SPRINKLER SYSTEM HYDRAULIC ANALYSIS Date: 04/28/1997 JOB TITLE: SIX ROBBLEES PIPE DATA (cont.) Page 4 SIXROBBL.SDF PIPE TAG Q(GPM) DIA(IN) LENGTH PRESS. END ELEV. NOZ. PT DISC. VEL(FPS) HW(C) (FT) SUM. NODES (FT) (K) (PSI) (GPM) F.L./FT (PSI) Pipe: 14 -127.9 2.068 PL 8.00 PF 1.2 15 21.0 5.6 35.0 33.1 12.2 120 FTG ---- PE 0.0 16 21.0 5.6 36.2 33.7 0.148 TL 8.00 PV 1.0 Pipe: 15 -161.6 2.068 PL 5.00 PF 3.4 16 21.0 5.6 36.2 33.7 15.4 120 FTG T PE 0.0 17 21.0 0.0 39.6 0.0 0.228 TL 15.02 PV 1.6 Pipe: 16 162.5 2.068 PL 3.00 PF 3.0 17 21.0 0.0 39.6 0.0 15.5 120 FTG T PE 0.0 18 21.0 5.6 36.6 33.9 0.230 TL 13.02 PV 1.6 Pipe: 17 128.6 2.068 PL 8.00 PF 1.2 18 21.0 5.6 36.6 33.9 12.3 120 FTG ---- PE 0.0 19 21.0 5.6 35.4 33.3 0.149 TL 8.00 PV 1.0 Pipe: 18 95.3 1.610 PL 8.00 PF 2.3 19 21.0 5.6 35.4 33.3 15.0 120 FTG ---- PE 0.0 20 21.0 5.6 33.1 32.2 0.290 TL 8.00 PV 1.5 Pipe: 19 63.1 1.610 PL 8.00 PF 1.1 20 21.0 5.6 33.1 32.2 9.9 120 FTG ---- PE 0.0 21 21.0 5.6 32.0 31.7 0.135 TL 8.00 PV 0.7 Pipe: 20 31.4 1.380 PL 8.00 PF 0.6 21 21.0 5.6 32.0 31.7 6.7 120 FTG ---- PE 0.0 22 21.0 5.6 31.4 31.4 0.079 TL 8.00 PV 0.3 Pipe: 21 -31.2 1.380 PL 8.00 PF 0.6 23 21.0 5.6 31.1 31.2 6.7 120 FTG ---- PE 0.0 24 21.0 5.6 31.7 31.5 0.078 TL 8.00 PV 0.3 Pipe: 22 -62.8 1.610 PL 8.00 PF 1.1 24 21.0 5.6 31.7 31.5 9.9 120 FTG ---- PE 0.0 25 21.0 5.6 32.8 32.1 0.134 TL 8.00 PV 0.7 Pipe: 23 -94.9 1.610 PL 8.00 PF 2.3 25 21.0 5.6 32.8 32.1 14.9 120 FTG ---- PE 0.0 26 21.0 5.6 35.1 33.2 0.288 TL 8.00 PV 1.5 Pipe: 24 -128.0 2.068 PL 8.00 PF 1.2 26 21.0 5.6 35.1 33.2 12.2 120 FTG ---- PE 0.0 27 21.0 5.6 36.3 33.7 0.148 TL 8.00 PV 1.0 Pipe: 25 -161.8 2.068 PL 5.00 PF 3.4 27 21.0 5.6 36.3 33.7 15.5 120 FTG T PE 0.0 28 21.0 0.0 39.7 0.0 0.228 TL 15.02 PV 1.6 Pipe: 26 162.7 2.068 PL 3.00 PF 3.0 28 21.0 0.0 39.7 0.0 15.5 120 FTG T PE 0.0 29 21.0 5.6 36.7 33.9 0.231 TL 13.02 PV 1.6 SPRINKLER SYSTEM HYDRAULIC ANALYSIS Date: 04/28/1997 JOB TITLE: SIX ROBBLEES PIPE DATA (cont.) Page 5 SIXROBBL.SDF PIPE TAG Q(GPM) DIA(IN) LENGTH PRESS. END ELEV. NOZ. PT DISC. VEL(FPS) HW(C) (FT) SUM. NODES (FT) (K) (PSI) (GPM) F.L./FT (PSI) Pipe: 27 128.8 2.068 PL 8.00 PF 1.2 29 21.0 5.6 36.7 33.9 12.3 120 FTG ---- PE 0.0 30 21.0 5.6 35.5 33.4 0.150 TL 8.00 PV 1.0 Pipe: 28 95.4 1.610 PL 8.00 PF 2.3 30 21.0 5.6 35.5 33.4 15.0 120 FTG ---- PE 0.0 31 21.0 5.6 33.2 32.3 0.291 TL 8.00 PV 1.5 Pipe: 29 63.1 1.610 PL 8.00 PF 1.1 31 21.0 5.6 33.2 32.3 10.0 120 FTG ---- PE 0.0 32 21.0 5.6 32.1 31.7 0.136 TL 8.00 PV 0.7 Pipe: 30 31.4 1.380 PL 8.00 PF 0.6 32 21.0 5.6 32.1 31.7 6.7 120 FTG ---- PE 0.0 33 21.0 5.6 31.5 31.4 0.079 TL 8.00 PV 0.3 Pipe: 31 -34.1 1.380 PL 8.00 PF 0.7 34 21.0 5.6 37.0 34.1 7.3 120 FTG ---- PE 0.0 35 21.0 5.6 37.8 34.4 0.092 TL 8.00 PV 0.4 Pipe: 32 -68.5 1.610 PL 8.00 PF 1.3 35 21.0 5.6 37.8 34.4 10.8 120 FTG ---- PE 0.0 36 21.0 5.6 39.0 35.0 0.158 TL 8.00 PV 0.8 Pipe: 33 -103.5 1.610 PL 8.00 PF 2.7 36 21.0 5.6 39.0 35.0 16.3 120 FTG ---- PE 0.0 37 21.0 0.0 41.7 0.0 0.338 TL 8.00 PV 1.8 Pipe: 34 -103.5 2.068 PL 8.00 PF 0.8 37 21.0 0.0 41.7 0.0 9.9 120 FTG ---- PE 0.0 38 21.0 0.0 42.5 0.0 0.100 TL 8.00 PV 0.7 Pipe: 35 -103.5 2.068 PL 5.00 PF 1.5 38 21.0 0.0 42.5 0.0 9.9 120 FTG T PE 0.0 39 21.0 0.0 44.0 0.0 0.100 TL 15.02 PV 0.7 Pipe: 36 0.0 2.068 PL 3.00 PF 0.0 39 21.0 0.0 44.0 0.0 0.0 120 FTG T PE 0.0 40 21.0 0.0 44.0 0.0 0.000 TL 13.02 PV 0.0 Pipe: 37 0.0 2.068 PL 8.00 PF 0.0 40 21.0 0.0 44.0 0.0 0.0 120 FTG ---- PE 0.0 41 21.0 0.0 44.0 0.0 0.000 TL 8.00 PV 0.0 Pipe: 38 0.0 1.610 PL 8.00 PF 0.0 41 21.0 0.0 44.0 0.0 0.0 120 FTG ---- PE 0.0 42 21.0 0.0 44.0 0.0 0.000 TL 8.00 PV 0.0 Pipe: 39 0.0 1.610 PL 8.00 PF 0.0 42 21.0 0.0 44.0 0.0 0.0 120 FTG ---- PE 0.0 43 21.0 0.0 44.0 0.0 0.000 TL 8.00 PV 0.0 SPRINKLER SYSTEM HYDRAULIC ANALYSIS Date: 04/28/1997 JOB TITLE: SIX ROBBLEES PIPE DATA (cont.) Page 6 SIXROBBL.SDF PIPE TAG Q(GPM) DIA(IN) LENGTH PRESS. END ELEV. NOZ. PT DISC. VEL(FPS) HW(C) (FT) SUM. NODES (FT) (K) (PSI) (GPM) F.L./FT (PSI) Pipe: 40 0.0 1.380 PL 8.00 PF 0.0 43 21.0 0.0 44.0 0.0 0.0 120 FTG ---- PE 0.0 44 21.0 0.0 44.0 0.0 0.000 TL 8.00 PV 0.0 Pipe: 41 -103.5 2.469 PL 1.00 PF 0.5 39 21.0 0.0 44.0 0.0 6.9 120 FTG T PE 0.4 A 20.0 0.0 45.0 0.0 0.042 TL 13.00 PV 0.3 Pipe: 42 -324.5 2.469 PL 1.00 PF 4.5 28 21.0 0.0 39.7 0.0 21.7 120 FTG T PE 0.4 B 20.0 0.0 44.7 0.0 0.349 TL 13.00 PV 3.2 Pipe: 43 -324.1 2.469 PL 1.00 PF 4.5 17 21.0 0.0 39.6 0.0 21.7 120 FTG T PE 0.4 C 20.0 0.0 44.6 0.0 0.348 TL 13.00 PV 3.2 Pipe: 44 -324.1 2.469 PL 1.00 PF 4.5 6 21.0 0.0 39.6 0.0 21.7 120 FTG T PE 0.4 D 20.0 0.0 44.6 0.0 0.348 TL 13.00 PV 3.2 Pipe: 45 646.9 5.187 PL 10.00 PF 0.3 A 20.0 0.0 45.0 0.0 9.8 120 FTG ---- PE 0.0 B 20.0 0.0 44.7 0.0 0.034 TL 10.00 PV 0.6 Pipe: 46 322.4 5.187 PL 10.00 PF 0.1 B 20.0 0.0 44.7 0.0 4.9 120 FTG ---- PE 0.0 C 20.0 0.0 44.6 0.0 0.009 TL 10.00 PV 0.2 Pipe: 47 -1.8 5.187 PL 10.00 PF 0.0 C 20.0 0.0 44.6 0.0 0.0 120 FTG ---- PE 0.0 D 20.0 0.0 44.6 0.0 0.000 TL 10.00 PV 0.0 Pipe: 48 -325.9 5.187 PL 456.00 PF 4.9 D 20.0 0.0 44.6 0.0 4.9 120 FTG T4L PE 0.0 E 20.0 0.0 49.5 0.0 0.009 TL 521.12 PV 0.2 Pipe: 49 750.4 5.187 PL 64.00 PF 4.5 E 20.0 0.0 49.5 0.0 11.4 120 FTG TL PE 0.0 A 20.0 0.0 45.0 0.0 0.044 TL 101.70 PV 0.9 Pipe: 50 -1076.3 8.249 PL 34.75 PF 0.4 E 20.0 0.0 49.5 0.0 6.5 120 FTG L PE 0.0 F 20.0 0.0 50.0 0.0 0.009 TL 49.21 PV 0.3 Pipe: 51 -1076.3 8.249 PL 14.33 PF 0.1 F 20.0 0.0 50.0 0.0 6.5 120 FTG ---- PE 6.2 G 5.7 0.0 56.3 0.0 0.009 TL 14.33 PV 0.3 Pipe: 52 -1076.3 8.249 PL 2.50 PF 0.5 G 5.7 0.0 56.3 0.0 6.5 120 FTG LGA PE 1.2 H 3.0 0.0 58.0 0.0 0.009 TL 60.33 PV 0.3 FENWAL 30-2210.0 Effective: October 1993 Fire Protection Control Units Model 2210, 2410 Model 2212, 2412 GENERAL FEATURES • FULLY REGULATED POWER SUPPLY • BUILT IN BATTERY CHARGER • 6AH, SEALED, LEAD ACID BATTERY OPTIONS • GROUND FAULT SUPERVISION • TROUBLE ISOLATION FAULT INDICATORS • SOLID STATE CIRCUITRY • UL LISTED TO STANDARD 864; FM, CSFM APPROVED (2210 ONLY) • LISTED FOR PROPRIETARY USE • INCORPORATES I.R.I. FEATURE • TRANSIENT AND NOISE ISOLATION • AC OR DC OPTIONS ADDITIONAL FEATURES • Field Selectable, Style B or D Initiating Circuits • Supervised, Indicating Outputs for: Pre -Alarm Pre -Release Post -Release Signals • Supervised Relays for Trouble and Signaling Circuits • Two Releasing Circuits for Initiators/Control Heads — One Circuit for Cascaded, Control Head Operated Valves • Cascading Capability up to 10 Control Heads • Supervised Abort Circuit • Listed for Waterflow Service • Differentiates between Smoke Detectors and Contact Devices on same Initiating Circuit • Ease of Wiring • Voltmeter and Ammeter Options • Supervised Loop for Closed Circuit Contacts • Key Actuated, Release Circuit Disabling (optional) • Remote Reset Option • Available in 120 Volt or 240 Volt Models • Field Selectable Time Delays GENERAL These versatile Control Units supervise one or two Halon 1301 fire protection zones. They meet the requirements of NFPA Stan- dards 72A and 72D, are UL Listed per Standard 864 and function to I.R.I. Standards. State-of-the-art solid state circuitry provides increased protection from transients and noise while increasing reliability. Many programmable options permit variations in system design without changing the basic circuitry of the unit or adding additional modules. (See Programming Instructions.) DETECTION A special feature of these units is the ability to differentiate be- tween two -wire smoke detectors and contact -type detectors on the same initiating circuit, simplifying installation and reducing wir- ing costs. Each suppression module has two independent initiat- ing circuits which may be wired for either Style B or Style D oper- ation. Up to 40 Fenwal 24 VDC ionization or photoelectric smoke detectors may be connected to each circuit. Contact devices such as Fenwal's DETECT -A -FIRE® heat detectors or manual pull sta- tions may also be connected in the same circuit. Total lead -wire resistance of 50 ohms allows extended initiating - circuit wire runs. MODEL 2X10 MODEL 2X12 A single smoke detector alarm in either of the suppression mod- ule's two input circuits initiates a Pre -Alarm signal. When a smoke detector in both loops of one module alarms, a Pre -Release sig- nal is generated and time delay circuits, if used, activate. When the time delay is satisfied, agent is released and a Release signal is triggered, unless the system abort feature has been enabled. A contact device alarm in either detection circuit will trigger all the alarm signals simultaneously and will release the extinguishant. (See Programming Options section) ALARMS Three indicating circuits for each suppression module are Style Y supervised and operate polarized indicating appliances. One independent, dry, Form C relay is associated with each output circuit. Relay coils are supervised. EXTINGUISHING AGENT RELEASE The Control Units drive either initiator or control head operated agent release valves, so the units are compatible with either Fenwal Modular or Central Storage extinguishing systems. ABORT SWITCH Abort Switches may be connected to each module of the Control Unit to inhibit agent release. While the Abort Switch is held open, agent release is prevented, but alarms continue to sound. A pro- gramming procedure enables contact device actuation to override the Abort Switch, if desired. In addition, the unit incorporates a field programmable I.R.I. feature which allows the system to be aborted between Pre -Alarm and Pre -Release, but not after the Pre -Release stage. (See Programming Instructions on page 7.) SUPERVISION Each suppression module is fully supervised. Supervision in- cludes, but is not limited to, the following: • AC power • releasing outputs • battery voltage • remote reset • battery connections • relay coils • alarm initiating circuits • ground fault • signaling circuits • alarm silence • abort switch circuit • low pressure switch (NC) Each suppression module includes an annunciator bank as de- picted in Figures 1, 2 and 3. The top row of indicators is visible with the enclosure door closed. Additional LED trouble indicators are located on the module printed circuit boards as shown in Figure 1. TROUBLE INDICATION Trouble conditions in one or both modules result in an audible signal and illumination of an LED annunciator on the affected module indicator panel. The audible signal may be silenced by the Trouble Silence Switch on the indicator panel. Additionally, trouble conditions are identified by nine trouble indicators per module and a trouble ringback. A trouble condition activates a set of dry, Form C contacts. POWER SUPPLY The power supply is conservatively rated at 3.0 amperes, 24 VDC, and all outputs are regulated. Overload protection is pro- vided by electronic current limiting. A fuse is utilized in the battery circuit only. A circuit breaker protects the AC input. Each control module contains a built in battery charger and can accommodate a set of 6 ampere -hour, sealed, lead acid batteries housed within the control unit enclosure (see Battery Standby Table). A Trouble Signal is generated if battery voltage drops below the acceptable level. ENCLOSURE Panel enclosures are rugged, 18 -gauge steel. Enclosures are painted beige. Steel doors are secured to the back box by full length, piano -type hinges and are held closed by a key lock. The following LED indicators are visible with the door closed: Alarm Circuits 1 and 2, Agent Release, AC On, System Trouble and Supervisory Trouble. Additional indicators and all of the function switches are located behind the locked door. Models 2212 and 2412 are dual panel enclosures. The panel on the left is called the Master and the panel on the right, the Slave. 2 OPERATING INSTRUCTIONS NORMAL STANDBY Green — AC "On" indicator illuminates on Master module. DC "On" indicator illuminates on Slave module. All other indicators should be off. ALARM — CIRCUIT 1 Red — ALARM CIRCUIT 1 indicator illuminates to indicate activa- tion of detection device or pull station connected to alarm initiating Circuit 1. ALARM — CIRCUIT 2 Red — ALARM CIRCUIT 2 indicator illuminates to indicate activa- tion of detection device or pull station connected to alarm initiating Circuit 2. PRE -ALARM SIGNAL — Audible or Visual Alarm Activates when alarm signal detected on initiating circuit 1 or in- itiating circuit 2. Terminal 24 switches to + 24 VDC, Terminals 20 and 22 transfer. PRE-RELEASE SIGNAL — Audible or Visual Alarm Activates when both initiating circuit 1 and initiating circuit 2 are activated by smoke detectors. Also activates when a contact type device (i.e., Manual Pull Station, D -A -F, etc.) alarms on either in- itiating circuit. Terminal 16 switches to + 24 VDC, Terminals 17 and 19 transfer. POST -RELEASE SIGNAL — Audible or Visual Alarm Activates immediately upon agent release. Terminals 9 and 11 switch to + 24 VDC, Terminals 12 and 14 transfer. AGENT RELEASE ANNUNCIATOR Red indicator illuminates immediately upon agent release. Re- mains latched until System Reset switch is activated. SYSTEM TROUBLE ANNUNCIATOR Amber indicator illuminates when a trouble condition exists in any of the supervised circuits. GROUND FAULT ANNUNCIATOR Amber indicator on panel (Master Module Control on Dual Module Model 2X12) illuminates when a ground fault that could interfere with system operation exists. To determine which module of a dual module system has the ground fault, disconnect blue wire between Master and Slave modules, remove black lead from ter- minal 45 of the Slave module, and operate the system reset switch. If the LED extinguishes, the ground fault is in the Slave unit. If the LED remains illuminated, the fault is in the Master module. RELEASE CIRCUIT TROUBLE ANNUNCIATOR Amber indicator illuminates when a trouble condition exists in the supervised agent release circuit. ALARM SILENCE ANNUNCIATOR Amber indicator illuminates when alarm silence switch has been used to deenergize the alarm indicating circuits. BATTERY TROUBLE ANNUNCIATOR Amber indicator illuminates when a fault exists in the supervised battery circuit. Also illuminates if battery voltage falls below the acceptable low limit either in normal operation or during battery test. BATTERY POLARITY ANNUNCIATOR Amber indicator illuminates if battery is connected with improper polarity, extinguishes when polarity is corrected. See CAUTION on installation wiring diagram. ALARM TEST SWITCH Activates Pre -Alarm and Pre -Release signaling circuits and dry contacts. Momentary action switch returns to Normal position when released. BATTERY TEST SWITCH Activates battery test function and tests battery under load. Momentary action switch returns to Normal position when re- leased. See Battery Maintenance Section for ammeter or volt- meter operation during test. OPERATING INSTRUCTIONS (continued) ALARM SILENCE SWITCH Silences each of the signaling circuits, but does not affect dry contacts. Receipt of a subsequent alarm will reactivate the alarm - signalling outputs. Momentary action switch returns to its original position when re- leased, but alarm signalling outputs remain silenced until sub- sequent alarm is received. Alarm Silence switch will not silence signalling circuits when sys- tem is programmed for waterflow service. RESET SWITCH Momentary type reset switch cancels all alarm annunciators and reinitializes panel. When resetting an alarm condition, depress the reset switch and hold for at least 5 seconds to ensure that smoke detectors reset. TESTING RECOMMENDATIONS At least once a week, or as required by local authorities having jurisdiction, the following testing program should be conducted. 1. Depress Alarm Test Switch to "Test" position and observe op- eration of Audible and Visual Alarm devices and equipment interlocks connected to pre -alarm and pre-release circuits and dry contacts. 2. Perform Battery Maintenance procedure as outlined below. FUSE REPLACEMENT This control unit is equipped with a manual reset circuit breaker on AC input. To reset, depress the push button. The battery circuit is protected by a 5A, Type 3 -AG, glass cartridge fuse. Replace only with a fuse of the same rating. Should service be required, contact your local service representative. BATTERY MAINTENANCE The following testing program should be conducted at least once a week, or as required by local authorities having jurisdiction. Actuate battery test switch to test position. Ammeter, if used, should momentarily deflect to full scale, and Battery Trouble indi- cator should not light. If voltmeter is used, voltmeter should read 21.5 volts minimum and then return to 24 volts minimum. Failure of the ammeter to deflect to full scale and/or failure of the voltmeter to register 21.5 volts minimum, or illumination of the Battery Trouble indicator, indicates insufficient battery capacity. NOTE: If prolonged AC power failure has occurred within 10 hours of battery test, allow at least 10 hours for the battery to recharge before taking further action. If, after 10 hours total recharge, a failure indication occurs, re- place the batteries with the same type and capacity. Batteries originally furnished by Fenwal are: 2 ea. Fenwal Cat. 30-220070- 001, rated 12V, 6AH. Replace in pairs to assure maximum capac- ity. (Note Fenwal Cat. 30-220070-001 denotes a pair of batteries.) BATTERY STANDBY TABLE Batteries should provide 24 hours standby supervision, plus 5 minute, 3A alarm load at the end of that time, to comply with NFPA Standards 72A and 72D. 3 To determine battery operation time (in supervisory mode): A. Determine load by adding control panel current (75 mA per module) to load current of detectors. (No. of detectors x 77pA for Fenwal PSD-71XX photoelectric detectors or 66pA for Fenwal CPD-70XX ionization detectors.) B. Derate batteries by 12%: (6AH x .88) = 5,280 mAH. C. Dlivide 12% derated battery rating by total current load (see examples below). EX. 1: 2210 Panel-6AH batteries, and 80 CPD -7021 ionization detectors 75 mA (module current) + (80 detectors x 66µA) = 80.3 mA 5,280 mAH/80.3 mA = 65 hours battery -operating time. EX. 2: 2212 Panel-6AH batteries, and 160 CPD -7021 ionization detectors 150 mA (modules current) + (160 detectors x 66µA) = 160.6 mA 5,280 mAH/160.6 mA = 32 hours battery operating time. EX. 3: 2212 Panel -two 6AH batteries per module, and 160 PSD -71 XX photoelectric detectors 150 mA (module current) + (160 detectors x 77µA) = 162.3 mA 10,560 mAH/162.3 mA = 65 hours battery operating time. Each 2210 Module draws 300 mA on alarm. INITIATING CIRCUIT CLASS SELECTION For initiating circuit 1, install Jumper W3 for Style D wiring. For initiating circuit 2, install Jumper W4 for Style D wiring. Remove jumpers for Style B wiring. Style B selection is required to get "ring back" when servicing. CAUTION To avoid damaging the power supply, first connect DC power, observing proper battery polarity. Should the battery polarity reversal LED be illuminated, correct battery polarity before applying AC power. Before servicing batteries, disconnect AC power. Batteries should be replaced at least once every 48 months, or as directed by the local authorities having jurisdiction. RECOMMENDED WIRING COLOR CODE FOR HALON 1301 FIRE SUPPRESSION INSTALLATIONS WIRING COLOR CODE *Black = BLK *White = WHT *Green = GRN *mandatory per N.E.C. WIRE SIZES AC power feed DC control (in panel) Proprietary Interlock DC to field AC control AC to field SINGLE CONDUCTOR WIRES for AC power hot or 220 VAC & up AC neutral ground #14 minimum (#12 may be required) #18 minimum (#12 may be required) #14 minimum (#12 may be required) #14 minimum (#12 may be required) #18 minimum (#12 may be required) #16 minimum (#12 may be required) #14 minimum (#12 may be required) RELEASE CIRCUIT CONFIGURATIONS FIGURE 1A Release Circuit 1 used to fire single Control Head, P/N 486500 or 897494 and Circuit 2 used to fire Initiators. NOTE: P/N 486500 is a polarized control head. Improper wiring will result in failure of this device to operate. FIGURE 1B Two Control Heads, P/N 486500 and/or 897494 (Cir. #1 & Cir. #2) NOTE: P/N 486500 is a polarized control head. Improper wiring will result in failure of this device to operate. FIGURE 1C Release Circuit 1 used for Initiator. Circuit 2 not used. NOTE: Circuit 2 may be substituted for Circuit 1. Circuit 1 to be completed with 2K ohm, 1W simulator between Terminals 1 and 5. See Figure 1D for Circuit 2 configuration with Initiators. CIRCUIT1 SOLENOID INITIATORS CIRCUIT2 COMPENSATING RESISTOR CUT CO JUMPER REQUIRED SEE NOTES BELOW CIRCUIT 1 SOLENOID CIRCUIT2 SOLENOID COMPENSATING RESISTOR (SEE NOTES BELOW) INITIATORS (SEE NOTES BELOW) SIMULATOR 2K OHMS 1W FIGURE 1D Release Circuits 1 and 2 used to fire Initiators. Initiator Circuit Supervisory Current: 2.5 mA D.C. Total Energy: 0.8 Joules CUT CO JUMPER REQUIRED JUMPER REQUIRED COMPENSATING RESISTOR CIRCUIT 1 (SEE NOTES BELOW) INITIATORS CIRCUIT1 (SEE NOTES BELOW) INITIATORS CIRCUIT2 (SEE NOTES BELOW) COMPENSATING RESISTOR CIRCUIT2 (SEE NOTES BELOW) JUMPER REQUIRED FIGURE 1E Release Circuit 1 used to fire single Control Head with Cascade Switch, P/N 890181 or 895630. (See note C below.) SWITCHED(-) 2K, 1W SIMULATOR (P/N 30-221070-021) FIGURE 1F Release Circuit 1 used to fire two Control Heads with Cascade Switches, P/N 890181 and/or 895630. (See note C below.) SWITCHED(-) 2K, 1 W SIMULATOR (P/N 30-221070-021) FIGURE 1G Release Circuit 1 used to fire an odd number of Control Heads with Cascade Switches, up to a maximum of nine, P/N 890181 and/or 895630. (See note C below.) 2K, 1W SIMULATOR (P/N 30-221070-021) FIGURE 1H Release Circuit 1 used to fire an even number of Control Heads with Cascade Switches, up to a maximum of ten, PM 890181 and/or 895630. (See note C below.) 2K. 1W SIMULATOR (P/N 30-221070-021) FIGURE 1J Configuration with Unused Release Circuits 1 and 2 Simulators 2KS2 1W +24 VDC .75A Max. on Post Release for Power Relay Connections 3.0K S2 0.5W Supervised Post Release Signal Output (Non Coded) Power Limited Circuit INSTALLATION WIRING DIAGRAM • • Circuit 1 2 3 4 Circuit 2 5 6 7 8 3.0K SZ 0.5W 24-25 VDC .75A. D.C. Max. Post Release Aux. Relay Output (See Note 14) 1 24-25 VDC .75A. D.C. Max. Pre Release Supervised Pre -Release Aux. Relay Signal Output Output (Non Coded) (See Note 14) Power Limited Circuit 3.0K 02 0.5w Pre -Alarm Aux. 1 24-25 VDC .75A. D.C. Max. Supervised Pre -Alarm Signal Output (Non Coded) Power Limited Circuit **End of Line Device Fenwal Part. No. 30-220070-006 (Supervisory Current: 3.5mA D.C.) NOTES: ungrounded conductors shall not exceed 150 volts. 9 10 11+ 12 13 20- 40 - CO K6 K6 14 15 16+ 17 1 18 19 20 21 K3 22 23 24+ 0 L1 TIME DELAY CIRCUIT 1 TROUBLE T/D ADJUST TR CD FENWAL IN RP ALARM AGENT AC SYSTEM SUPV 0 0 0 O O O CKT1CK-2 RELEASE ON TROUBLE TROUBLE ALARM 0 SILENCE RELEASE 0 0 DSBL TBL BATTERY 0 TROUBLE BATTERY 0 POLARITY REVERSED GROUND 0 FAULT ALARM TEST ALARM SILENCE SYSTEM RESET NORMAL SILENCE TROUBLE BATTERY TEST WATER FLOW CL ASHLAND, MA. 01721 ABORT TROUBLE AO �0L TP1 BATT IRIS ALARM BELL 4"."1 TROUBLE L2 0 Green Black Input Rating 120 VAC 50/60 Hz 1.5 Amp AC Max. or 240 VAC 50/60 Hz. 1 Amp A.C. Max. On Master Module Panel Only Slave Module Panel will Operate from D.C. Supply Only 0 I I • 1 AC W3 0 CIRCUIT 1 CLASS A CIRCUIT 2 TROUBLE W4 CIRCUIT 2 CLASS A V2 W2 A2 - Al W1 V1 ro Circuit Breaker 3A for 120 VAC Input 1.5A for 240 VAC Input FIGURE 1 30-186 Rev. 6 K2 25 26+ Style D Supervised Initiating Circuits' 27 28 29- 5.6 KS2 0.5W Initiating Circuit 1 (Power Limiied Circuit) 30 - 31 32 33+ End -of -Line Device Fenwal Cat. No. 30-220070-005 5.6 K S2 0.5W Initiating Circuit 2 34 35+ 36 (Power Limited Circuit) Abort (N.C.) Switch - Use Only Momentary Type Switch U.L. Listed for min. 1A @ 26 VDC (See NOTE: 6 and IRI Feature) (Power Limited Circuit) 37 Key Switch Terminals 38 39 40 41 L -O FUSE 42 43 44 +27 VDC Power Supply .75A DC Max. Jumper Required Figure 1A, 8, C & D Only Remote Reset - Closed Circuit 1 Contacts Rated 24V (When not used, Jumper Terminals No. 38 & 39)' (Power Limited Circuit) 45 46 47 Trouble Contacts (See Note 14) Supervised Loop For Closed Circuit Contacts. Rated 24V 2.5 mA (Where not used, Jumper Terminals No. 43 8 44)' (Power Limited Circuit) } D.C.(-)Minus + RED 5A 3AG Connect J ropers to V1 & V2 For Voltmeter Function or to Al & A2 for Ammeter Function NOTE: The maximum voltage to ground on any A. When using Initiator P/N 31-199932-004: 1. Acompensating resistor (0.5W min.) for each release circuit should chosen such that the total Release Circuit resistance is 10 ohms ± 1 ohm. 2. The maximum number of initiators per release circuit is 12. B. When using Initiator P/N 31-199932-012: 1. Acompensating resistor (1.0W min.) for each release circuit is required to provide between 3 ohms min. and 4 ohms max. total release circuit resistance. 2. The maximum number of initiators per release circuit is 3. C. If using diagrams 1 E through 1H with control heads P/N 890181 or P/N 895630, you must reset all control heads after every system activation. The release circuit trouble LED will not be active after the control panel is reset even though the control heads are not reset. CAUTION: Do not intermix different types of initiators in the same release circuit. When measuring the total release circuit resistance, use an ohmmeter with a current output of 10 mA maximum. 4 12V 12V - BLK Red - 0-1)110 0111F0 - 1.5A 111F0 -- 1.5A Max. Charging Current Batteries (2 regtl) 12V., 6AH Connected in series. Replace at minimum 48 month intervals or in accordance with requirements of local authorities. Use only Fenwal Cat. No. 30-220070-001 (Consists of 2 Batteries) TIME (SECONDS) TIME CUTJUMPERS 1 None 1-15 None 20 Yellow 40 Blue 60 Blue & Yellow 75 Blue & Yellow CAUTION: To avoid damaging the power supply, first connect DC power, observing proper battery. Should the battery polarity reversal LED be illuminated, correct battery polarity before applying AC power. T/D Adj. CCW T/D Adj. T/D Adj. CW 0 Denotes Light Emitting Device 8Denotes Toggle Switch (Normal Position up as Shown) Alarm Initiating Circuits Denotes Fenwal Smoke Detectors 2 Denotes Contact -Type Detection gs Devices or Manual Pull Stations Power Limiting Circuit CAUTION: 1. Before Installing a control head on a 487 Series Halon cylinder valve, ensure control head Is In "SET" position (e.g., actuating pin Is on the fully retracted or "SET" position). Failure to position control head on "SET" position will result In accidental Halon 1301 cylinder discharge when control head Is Installed on cylinder valve. 2. Electric Control Head, P/N 486500, Is designed for Installation on a 487 Series Halon cylinder valve only. Installation of this control head to any other device (e.g., pressure operated control head) will result in failure of device to operate when control head Is actuated. 3. All solenoid control heads must be removed from Halon 1301 cylinders prior to testing to prevent accidental cylinder discharge. 4. P/N 486500 Is a polarized control head. Improper wiring will result In failure of this device to operate. NOTES: A. In Figures 1 E through 1 H, Release Circuit 2 may be used to fire initiators. B. Use Pressure Switch, P/N 486536 or P/N 981332, located on the common manifold or on each section of divided manifolds, to signal and activate the control panel in the unlikely event of local manual release of a control head. The control panel will then release the entire cascaded system. Style B Supervised Initiating Circuits Alarm Init'ating Circuit 1 Alarm Initiating Circuit 11 End of Line Resistor 5.6K11, 0.5W Fenwal Cat. No. 30-220070-005 End of Line Resistor 5.6100, 0.5W Fenwal Cat. No. 30-220070-005 Each Initiating Circuit Characteristics Output Voltage: 24-26.5 VDC (18V Min. Battery) Max., Less than 10 mV RMS Ripple. Standby Current Loading: 3 mA DC Max. Max. Wiring Resistance: 50 Ohms Contact Devices Alarm Current: 100 mA DC Max. Smoke Detectors Equivalent Resistance in Alarm: 180 to 950 Ohms Max. Number Two Wire Smoke Detectors Per Circuit: 40, any combination DETECTOR TYPES: Fenwal 24 VDC MODEL CPD -7051 PSD -7155 PSD -7156 2 -WIRE 2WRLT 2WRB 2WRB with Model RAI -2 Alarm Indicator DH -51 (Max. 1/Circuit) 70-201000-001' 70-201000-002' 70-201000-003' 70-201000-005' DH -22' (Max. 1/Circuit) COMPATIBILITY IDENTIFIER 151 FE1 P55FE1 P56FE1 FE51A FE52A FE53A FE55A DH22FE5 FE01A FE02A FE03A FE05A DH22FE1 'Model MA -001 Detector Accessory must be used to adapt Detector to Base. (-) IN (-) OUT (+) IN (+) OUT Prop ietary System Hook -Up (-) IN (-) OUT (+)IN (+) OUT To Initiating Device Circuit To Initiating Device Circuit of Proprietary System of Proprietary System (Provides Alarm Signal) (Provides Trouble Signal) Battery Simulator Resistor 2.0KS21W t5% Fenwal Cat. No. 30-220070-021 NOTES: Alarm Outputs: 1. Use only polarized signaling devices. 2. Polarities shown are for alarm conditions. 3. Total system alarm current shall not exceed 2.25A DC at 24 VDC. 4. Supervisory current: 3.5 mA per circuit. Relay Outputs: 5. All relay contacts shown with power applied in nor- mal, standby condition. Time Delay and Abort Switch: 6. This unit may be field programmed for release time delays of 0 to 75 seconds. When abort switch is not used, jumper terminals No. 33 and No. 34. Remote Reset: 7. Resets the latched conditions in the control panel. When not used, jumper terminals No. 38 and No. 39. (See Note 15.) Wiring: 8. All wiring to release circuit output, manual pull and initiating circuit may be run in the same conduit; however, they must be shielded or electrically iso- lated from all other wiring. Shielded conductors, MI cable, EMT, or rigid conduit may be used. Com- pliance with all national and local fire codes is re- quired. DO NOT RUN AC WIRING AND DC WIR- ING IN THE SAME CONDUIT. Power Options: 9. 120 VAC 50/60 Hz with Battery Standby (Model 221X) 240 VAC 50/60 Hz with Battery Standby (Model 241X) 120 VAC 50/60 Hz only: Install 2K Ohm Battery Simulator Resistor (Fenwal Cat. No. 30-220070-021) across terminals No. 47 and No. 48. Module to Module Connections: 10. Connect the blue wire between the TP1 pins on the Master and Slave board. Connect the red wire be- tween terminals No. 44 of the Master and Slave board. Connect the black wire between terminals No. 46 of the Master and Slave board. Initiators/Cascading-Solenoid, Control Head Release Circuits: 11. The release circuits will energize for approximately 100 milliseconds on initiator release system, unless C.O. option is used. See paragraph 12. At the end of the 100 ms, the release circuits will de -energize if C.O. is not cut and jumper between terminals 36 and 37 is installed. When using solenoid control heads for release, the release circuit will de -ener- gize 100 ms after the last switch is activated. Cas- cading, control head release shall only be con- nected to one circuit per module. Control Head Without Cascading Release: 12. Cut Constant Output resistor (C.0.); See Figures 1A and 1B. When only one release circuit is used, the other must be completed with a simulator resis- tor, 2K ohms, 1 W; Fenwal P/N 30-221070-021. Release Circuit Disable (optional): 13. Key switch operation of optional release circuit -dis- able function electrically inhibits actuation of re- lease relay. Key in disable mode cannot be re- moved from key switch. Control unit door cannot be closed and additionally, release circuit-DSBL LED will flash at 1 second intervals until key is re- turned to normal position. Removing key from key switch will permit control unit door to be closed. Dry Contacts: 14. K2, K3, K4 and K6 contacts not supervised. 5A Max. @ 24 VDC and 240 VAC (resistive). 15. When resetting an alarm condition, the reset switch should be depressed and held for a minimum of 5 seconds to ensure smoke detector reset. 16. When detectors employ remote relay options, all detectors on a loop must be equipped with this op- tion, and all must be interconnected to perform a common function. INSTALLATION INSTRUCTIONS The 2X10 and 2X12 Fire Protection Control Units can be flush or surface mounted to any solid wall. For flush mounting, a special adaptor kit (P/N 30-220070-010 for Model 2X10, and P/N 30- 220070-012 for Model 2X12) is required. Instructions for Flush Mounting (reference Figure 2) 1. Remove control module(s) (a) from box (b) to facilitate flush mounting. The doors (c) of the box may also be removed if desired. (Hinge pin must be removed.) 2. Remove knockouts (d) at top and bottom of box. 3. Frame wall opening between studs (e) (14-1/4" wide x 25-1/ 4" high for Model 2X10, and 28-3/4" wide x 25-1/4"high for Model 2X12). 4. Position long side trim piece (f) so the three smaller holes align with the three holes on back of box (as shown), and fasten trim to box with one bolt and nut in center hole. (Note: all bolt heads should be inside box unless wall opening depth prevents this.) 5. Install second long side trim piece (f) as in Step (4). 6. Install short side trim pieces (g) (top and bottom) as shown, inserting and tightening all nuts and bolts. 7. Using the three larger holes in each long side trim piece as guides, drill three 3/16" -diameter holes through both long sides of box. 8. Insert box (b) into framed opening and fasten securely to studs with number 10 screws (not provided) inserted through holes drilled in side of box. 9. Reinstall control module(s) (a). 10. See Installation Wiring Diagram for further instructions. Instructions for Surface Mounting (reference Figure 3.) 1. Remove knockouts (d) at top and bottom of box. 2. Insert number 10 screws (not provided) into wall, spaced to match key holes on back of box. 3. Mount box onto the screws. 4. Insert number 10 screws in each remaining hole in back of box and tighten all screws. 5. See Installation Wiring Diagram for further instructions. TECHNICAL SPECIFICATIONS Compatibility Identifier: Model 2210 Model 2212 Model 2410 Model 2412 C1OFE1 C12FE1 C4OFE1 C42FE1 Power Supply: Input: 120 VAC, 50/60 Hz, 1.5A max. 240 VAC, 50/60 Hz, 1A max. Output: 24 VDC, 3.0A max. regulated Outputs per Suppression Module: Polarity Reversing Alarm (3): 0.75A @ 24 VDC Alarm Relay Contact (3): Form C rated 5A max. @ 24 VDC or 240 VAC (resistive) Trouble Relay Contact (1): Form C rated 5A max. @ 24 VDC or 240 VAC (resistive) Solenoid Output: 0.5A max. continuous, 2.5A momentary @ 24 VDC (10 cascaded devices max.) Initiator Output: Total Loop Resistance: 10.0 ohms for P/N 31-199932-004, 3 ohms to 4 ohms for P/N 31-199932-012 Total Energy Available: 1.8J minimum (both circuits) Supervisory Current: 2.5 mA Release Simulator: 2.0K ohms, 1W Detection Circuits per Module: Output Voltage: 24-26.5 VDC Max. number two -wire smoke detectors per circuit: 40 Detector Types: Fenwal 24VDC, 70XX, 71 XX Max. Number Contact Devices: Up to 50 ohms wire resistance 6 Max. Contact Device Alarm Current: 100 mA End -of -Line Resistors: Detection Circuits: 5.6K ohms 1/2W, 2 furnished Alarm Output Circuits: 3.0K ohms 1/2W, 3 furnished Standby Batteries: Sealed, Lead Acid: 2-12V 6AH (std.) Single set - 2X10 and 2X12 Double set - 2X12 options Battery Recharge Time: 10 hours from deep discharge Battery Standby Time: See Battery Standby Table Time Delays per Module: 0 to 75 seconds, field selectable. See Programming Instructions. Dimensions (nominal): Single Module: 26"H x 14'W x 4"D Dual Module: 26"H x 29"W x 4"D ORDERING INFORMATION Description Part Number Model 2210 Single Control Panel Unit 30-221000-000 w/120 VAC input, w/Enclosure and two Battery Brackets Model 2410 same as above except 30-221001-000 w/240 VAC input Model 2210 Single Control Panel 30-221000-001 w/120 VAC input, w/o Enclosure, w/Two Battery Brackets Model 2410 same as above except 30-221001-001 w/240 VAC input Model 2210 Enclosure Back Box Ass'y 30-220070-009 Model 2210 Enclosure Cover Ass'y 30-221070-008 Model 2210 Flush Mounting Frame Ass'y 30-220070-010 Adapter Kit Model 2212 Dual Control Panel Unit 30-221000-200 w/Enclosure and Four Battery Brackets Model 2212 Dual Control Panel Unit 30-221000-201 w/120 VAC input, w/Enclosure and Two Battery Brackets Model 2412 same as above except 30-221011-201 w/240 VAC input Model 2212 Master Control Panel Ass'y 30-221000-202 w/120 VAC input, w/o Enclosure, w/Two Battery Brackets Model 2412 same as above except 30-221011-202 w/240 VAC input Model 2212 Slave Control Panel w/o Enclosure, 30-221000-203 w/Two Battery Brackets Model 2212 Slave Control Panel w/o Enclosure, w/o Battery Brackets Model 2212 Enclosure Back Box Ass'y Model 2212 Enclosure Cover Ass'y (2 Doors) Model 2212 Flush Mounting Frame Ass'y Adapter Kit PROGRAMMING Feature Waterflow (WF) IRI Diode Abort Override (AO) Timer Reset (TR) Contact Delay (CD) Contact Latch (CL) AC Override (AC) Battery Override (BA) Time Delay (TD) OPTIONS Jumper/Diode Cuts Grey Jumper CR67 CR66 (CR78 must also be cut and time delay selected) CR97 CR78 CR63 CR17 CR27 - T.D. Potentiometer - Yellow Jumper - Blue Jumper - Blue & Yellow Jumper - Blue & Yellow Plus T.D. Potentiometer Constant Output (CO) R138 30-221000-204 30-220070-013 30-221070-014 30-220070-012 Accessories for Both Models Two 12V, 6AH, Sealed, Lead Acid Batteries Battery Harness for Above Battery Set Plug -In Ammeter Plug -In Voltmeter Transformer (220/115 VAC Stepdown) Battery Harness for External Batteries (Consult Factory) Battery Simulator Resistor Resistor Kit Accessory (2X10) Resistor & Hardware (2X10) Resistor Kit Accessory (2X12) Resistors & Hardware (2X12) Release Circuit Simulator Resistor Master -Slave Cable Ass'y Release Disable Switch Ass'y Recommended Spare Parts for Both Models E.O.L. Resistor (5.6K ohms) E.O.L. Resistor (3.0K ohms) 5 Amp Fuse Circuit Breaker (3 Amp for 120 VAC input) Circuit Breaker (1.5 Amp for 240 VAC input) Alarm Output Relay Part Number 30-220070-001 30-221070-002 30-220070-050 30-220070-004 30-220070-015 30-220070-016 30-220070-021 30-221070-011 30-221070-007 30-221070-019 30-221070-020 30-221070-021 30-221070-031 30-992131-001 30-220070-005 30-220070-006 06-115917-071 06-117111-001 06-117111-002 06-115902-110 Function Cut to silence signalling devices Cut to disable IRI function Cut to abort contact -type devices (Manual pull station) Cut for non -reset of timer after abort Cut for delay of contact -type devices Cut for alarm non -latching of contact -type devices Cut to override trouble condition when control is powered from DC supply only Cut to override trouble condition when control is powered from AC supply only Adjusted from 1-15 second delay Cut for 20 second delay Cut for 40 second delay Cut for 60 second delay Cut blue & yellow jumper plus adjust T.D. potentiometer fully clockwise for 75 -second delay Cut to provide constant voltage output of release circuit for single control head operation per Figures 1A or 1 B. ARCHITECTURAL AND ENGINEERING SPECIFICATIONS The contractor shall furnish and install a Fenwal (Model 2X10 Single Module) (Model 2X12 Dual Module) (specify which one), Fire Protection Control Unit. The control unit shall be U.L. Listed per Standard 864. Two Style D, supervised, initiating circuits shall be provided per module. Circuits shall be compatible with contact -type detection devices and any combination of up to 40 Fenwal 70XX ionization and 71 XX photoelectric smoke detectors. The first alarm initiation by a smoke detector connected to either initiating circuit in a module zone shall cause a Pre -Alarm output. A subsequent alarm initiation by a smoke detector connected to the second initiating circuit in a module zone shall cause Pre -Re- lease Alarm output. 7 An alarm initiation by a contact device connected to either alarm - initiating circuit shall cause both a Pre -Alarm and Pre -Release output. A time delay, field selectable for 0 to 75 seconds, shall be initiated with the generation of the Pre-Flelease output. Upon expiration of the time delay, a Release output and a Release Alarm output shall occur. An Abort Switch shall be provided to inhibit the Release output originated by smoke detector alarm initiations. A field program- mable feature shall insure that, where specified, release outputs originated by contact devices shall override the Abort Switch function. A programmable abort feature shall permit system abort after Pre - Alarm outputs have been actuated, but not after Pre -Release out- puts. ARCHITECTURAL AND ENGINEERING SPECIFICATIONS (continued) The Pre -Alarm, Pre -Release and Release Alarm outputs shall be individually supervised, polarity reversal, signaling circuits, each rated at 24 VDC, 0.75A. The Alarm outputs shall deactivate when the Alarm Silence Switch is activated, and visual and audible trouble signals shall result except when the waterflow option is enabled. Alarm signals cannot be silenced when panel is used for waterflow service. Four individual, dry, Form C, auxiliary relay contacts (one relay per function) shall transfer under Pre -Alarm, Pre -Release, Post - Release and Trouble conditions. Each of these contacts shall be rated 5A, 24 VDC and 240 VAC resistive. There shall be provisions for driving initiator or solenoid control head actuated extinguishing agent release valves. The initiator output shall be supervised and be compatible with Fenwal Modu- lar Suppression System release valves. The control head output shall be supervised and shall be compat- ible with Fenwal 487 Series electrically operated solenoid control heads. All connections to the initiating, signaling and releasing circuits shall be supervised for open circuits and ground faults. All relay coils, battery connections and plugs shall be supervised for open circuits. Battery voltage, polarity and AC power input shall be supervised. Trouble conditions shall be indicated by a silenceable audible signal and illumination of a LED trouble annunciator. Alarm conditions shall override all trouble indications except Alarm Silence and Abort. Sixteen (16) LED annunciators per module shall be provided as follows: This literature is provided for informational purposes only. Actual performance is based on proper application of the product by a qualified professional. 30-2210.0 10/93 1M ©1993 Kidde-Fenwal, Inc. Printed in U.S.A. 1. Power On (Green) 2. System Trouble (Amber) 3. Battery Trouble (Amber) 4. Circuit 1 Trouble (Amber) 5. Circuit 2 Trouble (Amber) 6. Ground Fault (Amber) 7. Release Trouble (Amber) 8. Alarm Circuit 1 (Red) 9. Alarm Circuit 2 (Red) 10. Agent Release (Red) 11. Alarm Silence (Amber) 12. Battery Polarity (Amber) 13. Abort Trouble (Amber) 14. Alarm Output Trouble (Amber) 15. Supervisory Trouble (Amber) 16. Release -Circuit Disable (White) The alarm and trouble indications shall be reset by a single Sys- tem Reset Switch. The control unit shall contain a single 3.0 ampere, 24 VDC regu- lated power supply incorporating electronic overload protection and a manually reset circuit breaker. No fuses shall be utilized except in the battery circuit. A self-contained battery charger shall be provided along with automatic transfer to battery standby in case of AC power loss. The control unit shall be equipped with two optional 6 ampere hour, sealed, lead acid batteries (4 bat- teries optional on Models 2X12) or shall be adaptable for connec- tion of external standby batteries (specify which). A battery test switch shall be provided and an optional ammeter or voltmeter, self-contained within the control unit, shall be (available or fur- nished) (specify which one). The control unit shall be housed in a painted, steel enclosure equipped with a hinged cover held closed by a keylock. All control switches and indicators, with the exception of the Power On, Mas- ter Trouble, Loop 1 Alarm, Loop 2 Alarm and Release indicators, shall be concealed and inaccessible behind the locked cover. All circuitry shall be mounted to a reimovable subpanel. KIDDE FENWAL KIDDE-FENWAL, INC. 400 MAIN STREET ASHLAND, MA 01 721 TEL: (506) 861-2000 FAX: M081881-8920 FENWAL 29-3200.50 Series 3200 Manual Pull Station P/N 29-320000-28X Effective: August 1992 FEATURES • U.L. LISTED, FM APPROVED • DOUBLE ACTION OPERATION • KEYLOCK FOR TEST AND RESET • POSITIVE INDICATION OF OPERATION • SURFACE OR SEMI -FLUSH MOUNTING • SHOCK AND VIBRATION RESISTANT • TERMINAL CONNECTIONS FOR EXTERNAL WIRING • BREAK ROD • OPTIONAL INSTITUTIONAL MODEL • OPTIONAL PRESIGNAL OPERATION • OPTIONAL DPST SWITCH DESCRIPTION These manual Pull Stations are non -coded double action devices which may be utilized for a variety of emergency signalling applications. They are constructed of aluminum (6063/T5) and employ a highly reliable action to activate the enclosed toggle switch, providing exceptionally high re- sistance to accidental operation. OPERATION FIRE ALARM AND HALON RELEASE STATIONS These double action standard units require that the outer door be lifted to expose the actuation door. The actuation door is then pulled forward to operate the alarm toggle switch. The actuation door is now locked in the readily observable "alarm" position. To reset the station, a key must be inserted and turned 1/4 turn clockwise, opening the station. Closing the station resets the toggle switch auto- matically. For optional DPST switch, see "Ordering Information" on back page. PRESIGNAL STATION This optional system works similar to that of the standard unit, with the addition of a key -operated switchlock mounted on the lower door. This switchlock may be utilized for "general alarm" signalling. For optional DPST switch, see "Ordering Information" on back page. INSTITUTIONAL STATION This optional station requires that a special key be used to release the actuation door before it can be operated. This lock may be keyed as required by the particular application. For optional DPST switch, see "Ordering Information" on back page. SPECIFICATIONS Material: 6063/T5 aluminum Finish: Body — red electrostatic epoxy Doors — clear anodize Switch: Type — enclosed toggle Contact material — silver plated bronze Contact ratings — 6 amp max. @ 125 VACNDC Dielectric breakdown — > 1000 VRMS Dimensions: Body — 5" H x 3.4" W x 1.5" D Overall -5"H x 3.4"W x 2.8"D ORDERING INFORMATION: Description Double Action Station (SPST) Double Action w/DPST Switch Presignal Station Presignal Station w/DPST Switch Institutional Station Institutional Station w/DPST Switch Surface Back Box (No Legend) Additional Break Rods (Pkg. of 4) "Existing Work" Switchbox (11/2" min. depth) 29 -320000 -XXX Suffix Number Fire Halton Alarm Release -280 -281 -282 -286 -287 NA -283 NIA -284 NA -285 NIA -288 -289 This literature is provided for informational purposes only. Actual performance is based on proper application of the product by a qualified professional. 29-3200.50 11/92 2.5M "1992 Kidde-Fenwal, Inc. Printed in U.S.A. Model BB -2 Surface Backbox FENWAL KIDDE-FENWAL. INC. 400 MAIN STREET ASHLAND. MA 01 721 TEL: (508) 881-2000 FAX: (508) 881-8920 FENWAL 70.51.1 Effective: September 1992 Ionization Smoke Detector CPD7051 Installation & Technical Data P/N 70-510000-001 FEATURES • INPLACE SENSITIVITY MEASUREMENT IN PERCENT (%) PER FOOT OBSCURATION • REMOTE FUNCTIONAL TEST CAPABILITY • LOCAL FUNCTIONAL TEST CAPABILITY (MAGNET TEST) • WIDE RANGE INPUT VOLTAGE 10.2 TO 36.8 VDC • LOW PROFILE APPEARANCE • SMT — SURFACE MOUNT TECHNOLOGY • MECHANICALLY AND ELECTRICALLY COMPATIBLE WITH ALL FENWAL DETECTORS AND BASES • 3 -YEAR WARRANTY • OPTIONAL 2- AND 4 -WIRE RELAY BASES • UNIVERSAL RELAY MODULES • NONPOLARIZED • DUAL CHAMBER TECHNOLOGY • 2- AND 4 -WIRE, LOW -CURRENT DESIGN • INTERCHANGEABLE BASES • FLASHING LED FOR VISUAL SUPERVISION • LOCKING FEATURE FOR TAMPER RESISTANCE • UL 268 AND UL 268A LISTED • EMI/RFI RESISTANT • IMPROVED FINE MESH INSECT SCREEN • NOMINAL SENSITIVITY 1.3°o/FT DESCRIPTION The CPD7051 is a dual-chamber. ionization -type detector designed to sense both visible and invisible products of combustion. This detector incorporates all advanced solid- state, low -voltage circuitry featuring SMT (Surface Mount Technology) and is designed for 2 -wire and 4 -wire installa- tion. The 360° smoke entry characteristic permits maximum smoke response from any direction. A unique sensing chamber design permits operation in air velocities up to 2000 FPM. The detector is designed for Open Area Protection and Duct Housing Applications. It may be in- stalled in systems intended for Releasing Device Service through use of a compatible control unit. Detector base options are available to provide for auxiliary test, indication, and/or control functions. To assure that the detector is functioning. a pulsing LED (approximately every 4 seconds) allows for visual supervi- sion of the detector. Under alarm condition, the LED lights continuously at full brilliance. An optional base is available to provide remote LED function. A unique gated output circuit design provides improved stability and transient suppression. Special signal proces- sing techniques verify the presence of smoke before the detector will alarm. detector head is installed into the base with a simple .ist-lock action. A locking feature is provided for vandal resistant security. A test magnet can provide a full func- tional test which simulates the effect of smoke (approxi- mately 1.3% per foot obscuration) entering the sensing chamber. This magnet test meets the requirements of the U.L. Sensi- tivity Test Feature. An optional base is available for remote functional testing. In addition, the actual sensitivity of the detector may be monitored with a standard voltmeter and a special sensitiv- ity tester that allows direct readout in % per foot obscura- tion without the necessity of removing the detector. A new, improved fine mesh insect screen protecting the chamber area is used to avoid potential nuisance alarms. Optional bases are available for supplementary 2- or 4 -wire relay functions. TECHNICAL SPECIFICATIONS TABLE 1 Detection Standby voltage Maximum ripple Standby current Start-up current Alarm current Alarm indicator Radioactive source material activity Normal operating temperature range Dual ionization chambers 10.2 to 36.8 VDC 50% of DC input 45µA (typical) 100µA peak 24 VDC 0.1 mA max. 100mA max. LED internal Americium 241 (sealed) 0.7 µCi (microcuries) 32°F (0°C) to 100°F (38°C) TABLE I continued Operating relative humidity range 'eset voltage reset time Start-up time Alarm voltage (detector voltage in alarm condition) Finish Weight Spacing (smooth ceiling) Approvals UL sensitivity Compatibility ID 0 to 93% (Noncondensing) 3V (typical) min. 1.0 sec. max. 20 sec. max. 5.5V (typical) Off white, smooth, high impact plastic 3.53 oz. without base 30 ft. center (900 sq. ft.) max. UL (Std. 268, 268A) Contact Kidde-Fenwal for information on other approvals 0.85 -1.75%/ft. I51 FE1 DIMENSIONAL DATA Detector height Diameter Base height Diameter 35mm, 1.38" 99mm, 3.90" 11 mm, 0.43" 150mm, 5.90" 3.44' 5.90' w mm ENVIRONMENTAL SPECIFICATIONS The CPD7051 has been tested by Underwriters Laboratories for environmental stability. Some of the basic conditions that must be met for compliance are listed below and are presented to help serve as application guidelines: CONTROL UNIT The CPD7051 detector is compatible with the Fenwal con- trol units and interface modules listed below. Consult Fenwal for information regarding other control units for which compatibility has been established. BASE/CONTROL UNIT SE TABLE II CONTROL UNIT MODEL NUMBER COMPATIBILITY IDENTIFIER NUMBER MAXIMUM NUMBER OF DETECTORS PER LOOP 2210 2212 2220 3210 C1OFE1 C12FE1 C2OFE1 ZDM01, VZMO1, ZDMD01 40 40 5 25 Contact KlddF e-enwal for information on compatability for other manufacturers' panels. BASE Various base options are available to provide auxiliary relay and/or remote indication and remote test feature. MODEL Auxiliary Relay 2WRB 2 -wire SPDT 1A C 30 VDC 0.5A C 125 VAC 4WRB 4 -wire SPDT 2A 30 VDC 1A C 125 VAC DETECTOR BASE OPTIONS TABLE I11 PART NUMBER/ MODEL COMPATIBILITY IDENTIFIER NUMBER 70-501000-001 FE51A Connects to 2 -wire de - 2 Wire tection circuit via screw terminals. 70-501000-002 FE52A Same as above plus 2WRLT provision for remote LED indicator and remote functional test. Observe polarity when using remote test feature. See Fig. 4. Min. alarm current: 19mA, 24 VDC. 70-501000-005 FE55A Connects to 2 -wire de- 2WRB tection circuit via pigtail leads. Equipped with SPDT supplementary relay. Min. alarm cur- rent: 15mA, 24 VDC. Remote LED and test capable. 70-501000-101 N/A Connects to 4 -wire de- 4WRB tection circuit via pigtail leads. Equipped with SPDT supplementary relay. Min. alarm cur- rent: 35mA, 24 VDC. 70-500000-004 N/A 2 -wire relay module 2WRM component of 70-501000-005 above. TABLE 111 continued 70-500000-102 N/A 4 -wire relay module 4WRM component of 70-501000-101 above. 70-501000-003 MAFE1 Mechanical retrofit MA -001 adapter a/lows CPD 7051 to physically connect to all Fenwal Series 70 (-001) bases. LOCATION Per UL Listing, open area smoke detectors are intended for mounting on a ceiling not less than 6 inches from a wall, or on a wall not less than 4 inches nor more than 6 inches from the ceiling. CAUTION The following locations should always be avoided: areas with excessive exhaust fumes, kitchen areas, near fire- places or furnace rooms, within 3 feet of air supply ducts or air diffusers. SPACING (OPEN AREA LOCATION) The CPD7051 is to be installed on maximum 30 -foot cen- ters, typically on smooth ceilings up to 15 feet high and will operate with minimum air circulation. Resultant maximum 900 square foot spacing may be used as a reasonable guide for comparable applications. Where special condi- tions exist (ceiling obstructions, high air exchange rates, etc.), reduced square footage spacing must be used to achieve adequate protection. Computer rooms and other such installations may require spacing with a maximum of 200 square feet due to high air exchange rates. For addi- tional information, consult National Fire Protection Association Standard 72E and the Fenwal Automatic Fire Detection Application Engineering Manual. SPECIAL APPLICATIONS For further assistance in the application of the CPD7051, consult your Fenwal technical representative. ELECTRICAL SPECIFICATIONS This detector is designed for operation with control units and releasing devices having specific voltage -current char- acteristics which are compatible with the detector circuitry. The information provided under the headings CONTROL UNIT and TABLE II are intended to assist in proper applica- tion of the detector in a system. Reference the UL compata- bility listing for other panels listed with this detector. TYPICAL WIRING DIAGRAMS Figures 1, 2, 3, and 4 are typical wiring diagrams of 2 -wire detector system, and Figure 5 is a wiring diagram of 4 -wire detector system. 3 FIRST DETECTOR BASE TO CONTROL PANEL INMATING CIRCUIT LAST DETECTOR BASE Fig. 1 Using 2 -Wire Base (Less Options) P/N 70-501000-001 FIRST DETECTOR BASE LAST DETECTOR BASE TO CONTROL PANEL INITIATING C'RCUIT REMOTE LED ... REMOTE LED,g� Fig. 2 Using 2WRLT Base with Remote Indicator Option P/N 70-501000-002 END OF UNE DEVICE END OF UNE DEVICE FIRST D= ECTOR BASE LAST DETECTOR BASE TO CONTROL PANEL INITIATING CRCUIT REMOTE LED REMOTE TEST SWITCH REMOTE TEST SWITCH ENO OF UNE DEVICE Fig. 3 Using 2WRLT Base with Remote Indicator and Remote Test Switch Options P/N 70-501000-002 TEST $,TITCH io TOINIiIA'.G CIRCUIT C= CONTRC. °A11E_ ELK PE: FRS CETECTOR BASE %MOTE TEST SWITCH /ELK/ PINK Y ORN EL A;;X CONTACT LAST CETECTOR BASE IRED \ / F=�CiE� !ELK/PINK REMOTE LE: BROWNI -= IT' ELLE YEL ALX :CONTACT Fig. 4 Using 2WRB Base with Relay Module P/N 70-501000-005 Notes: 1. All relays shown in normal position (Power -On). REMOTE ,F TO USTE: CONTROL . EL DC oc F=S:EECTOR BASE LAST BASE FE:, !RED PINK -EVCTE,. +. :ARMLE: Z -E -I SN' ro TO INITiA'1G _ CIRCUIT -;.NE_ W I GRAY YEL ORN REMOTE. TEST MITCH REMOTE LEC AUX BLUE) CONTACT Q Q ENC 0= UNE DEVICE ENO OF JNE RELAY RED IP=D PIN BROWN 16 WHTi 1GRAY END CF UNEI DEVICE AUX LCE CONTACT PN Fig. 5 Using 4WRM 4 -wire Base with Relay Module P/N 70-501000-101 NOTES 1. To insure proper installation of the detector head to the base, be sure wires are properly dressed at installation: a. Position all wires flat against the base. b. Take up all slack in the outlet box. c. Route wires away from connector terminals. 2. If you have installed a jumper between terminals 6 and 7 to test detector loop continuity, be sure to remove the jumper before installing detector head. 3. CAUTION - Do not use looped wire under terminal 2. Break wire runs to provide supervision of connections. 4. Observe uniform polarity of detector circuit connections when using direct return wire for LED connections. 5. When utilizing common return for remote LED indica- tors, test detector circuit for supervisory continuity. Removing detector circuit terminal connections must initiate control panel trouble sequence. 6. Observe polarity (Fig. 3 and 4) when using remote test option. 7. When detectors employ relay or remote indicator option, all detectors on a loop must be equipped with this option and all must be interconnected to perform a common function. 8. 2 -wire detectors must be U.L. Listed with control panels. NOTES (4WRB Base) 1. All replays shown in normal position (power ON stand- by). 2. Alarm current @ 24VDC = 35mA with remote LED. 3. Auxiliary contacts rated 2A, 24VDC for Canadian application. 4. The end -of -line supervisory relay utilized shall be a listed end -of -line power supervisory relay rated for the DC supply voltage used. 5. The end -of -line supervisory device shall be compati- ble with the control unit used. INSTALLATION BASE Detector bases are directly mounted on the electrical junc- tion boxes (3, 3.5, and 4 inch octagonal; 3 inch round; 4 inch square) without any type of mechanical adaptor. GENERAL 1. Route all leads outward from the junction box. 2. For bases equipped with pigtail leads, make all pigtail connections using approved connection means. Be sure to insulate any unused pigtails and the end -of -line resis- tor. Refer to INSTALLATION WIRING INFORMATION for color code and interconnect details. 3. Position wires and connectors in the junction box so as to leave the center of the box as clear as possible. 4. Dress wires terminating at detector base terminals. 5. After all detector bases are installed, including the end - of -line relay and resistor, check loop continuity. To make the continuity check, a jumper must be in place. An open circuit condition exists unless jumper or detector is installed in the base (See Fig. 6). 6. If loop continuity is acceptable, remove the jumper wire connecting base terminals 6 and 7 at each detector loca- tion. 7. Proceed to detector head installation. 1. BODY 5. JUMPER WIRE 2. CONTACT ARM 6. TERMINAL SCREW 3. CONTACT SPRING 7. R1: RESISTOR 4. TERMINAL PLATE (WITH COVER) Fig 6. INSTALLATION OF DETECTOR HEAD WARNING TO PREVENT DETECTOR CONTAMINATION AND SUBSEQUENT WARRANTY CANCELLATION, SMOKE DETECTORS MUST RE- MAIN COVERED UNTIL AREA IS CLEAN AND DUST FREE. 1. Push the detector head into the base and rotate until the detector key tabs drop into- place. Rotate clockwise about 1/2" travel to engage electrical connections.The head will automatically lock into place. 2. To remove, insert a maximum 1/4" wide screwdriver blade into the lock access slot and push with moderate pressure while rotating the detector head counterclock- wise. Once rotation starts, remove the screwdriver. Continue to rotate the detector head counterclockwise until a stop is reached. Then pull downward to disen- gage from base. NOTE: The locking feature may be removed by breaking away the lock tab. See illustration below and INSTALLA- TION WIRING INFORMATION. LOCKING FEATURE These detector bases also include an optional locking fea- ture that prevents removal of the detector without use of a tool. To eliminate this feature, simply break off the locking tab shown in Fig. 7A, then install the detector. To remove the detector from the base once the locking fea- ture has been activated, insert a small -bladed screwdriver into the slot on the base to push the plastic tab while simul- taneously turning the detector head counterclockwise (see Fig. 7B) 4 5 flash approximately once every 4 seconds. No flash indicates a nonfunctioning detector or faulty wiring. Steady illumination indicates an alarm state. 5. Follow the detailed operating and sensitivity measure- ment instructions provided with the Fenwal Sensitivity Tester ST -001 P/N 70-500000-002 (Ref. Fig. 8). This sensitivity tester will allow conversion to % per foot obscuration. 6. Sensitivity readings outside the given ranges indicate a shift in sensitivity and the need for corrective action. a. Clean the detector as outlined under maintenance and repeat Steps 2 through 5. b. If readings are still out of the allowable range, replace the detector. Except in cases of suspected terminal or cable problems. 7. After all the tests are complete, be certain that com- plete system is returned to normal. DIGITAL VOLTMETER O DETECTOR SENSITIVITY TESTER IST.00tI Fig. 8 General Equipment Connection Notes: 1) Digital voltmeter not supplied. 2) For more information, see instructions suppliec with Sensitivity Tester. Data Sheet No. 70.50.A. MAINTENANCE 1. The recommended requirement for detector maintenance consists of an annual cleaning of dust from the detector head by using the suction of a vacuum cleaner. Cleaning programs should be geared to the individual environment in conformance with NFPA 72E Standard. CAUTION: DO NOT ATTEMPT DISASSEMBLY OF THE FACTORY SEALED SMOKE DETECTOR. THIS ASSEMBLY IS SEALED FOR YOUR PROTECTION AND IS NOT INTENDED TO BE OPENED FOR SER- VICING. OPENING OF THE DETECTOR WILL VOID THE WARRANTY. 2. Perform the Sensitivity Metering Test as outlined in this document. Confirm that the sensitivity readings are with- in specified limits on detector label. 3. If sensitivity readings are out of limits specified on detec- tor label, contact the factory customer service depart- ment for details concerning the detector EXCHANGE PROGRAM. 4. The detector EXCHANGE PROGRAM offers the cus- tomer new product of the latest design as direct replace- ment for existing detectors. The EXCHANGE PROGRAM is available to all customers for a nominal fee, regardless of the age of the detector. SPARE PARTS None. Unit is factory repairable only. No field repair should be attempted. RADIOACTIVE MATERIAL Total radioactivity: .7 microcuries (maximum) Americium is241 shielded by stainless steel housing. For service, return detector head, intact to: Fenwal. ARCHITECT/ENGINEER SPECIFICATIONS The contractor shall furnish and install where indicated on the plans, dual-chamber, ionization smoke detectors, Fenwal CPD7051. The combination detector head and twist -lock base shall be UL Listed compatible with a UL Listed fire alarm panel. CPD705X series ionization detectors and PSD715X series photoelectric detectors shall share an inter- changable base. The smoke detector shall have a flashing status indicat- Ohoing LED for visual supervision. When the detector is actu- This literature is providea for informational purposes only. Actual performance is based on proper application of the product by a Qualified professional. 51.1 1/93 5M ' ?2 Kidde-Fenwal. Inc. - ';ea in U.S.A ated, the flashing LED will latch on steady and at full bril- liance. The detector may be reset by actuating the control panel reset switch. The sensitivity of the detector shall be monitored without removal of the detector head. Metering test points shall be accessible on the exterior of the detector head. It shall be possible to measure the sensitivity level of the detector without removal from' the base. Measurement shall be accomplished with a commercially available volt- meter and a Fenwal Sensitivity Tester (ST -001) allowing direct measurement in percent per foot obscuration. It shall also be possible to perform a functional test of the detector without the need for generating smoke. The test method must simulate effects of products of combustion in the chamber to ensure testing of all detector circuits. This test can be performed locally and/or remotely. The vandal -resistant, security Pocking feature shall be used in those areas as indicated on the drawings. The locking feature shall be field removable when not required. By using a furnished wire jumper, it shall be possible to check circuit loop continuity prior to installing the detector head. The detector shall be listed and approved for wall and ceiling mounting. Model CPD7051 shall operate over an input voltage range from 10.2 to 36.8VDC. Voltage and RF transient suppression techniques to with- stand up to 20 volt/meter to be employed to minimize susceptibility to false alarms. Supplementary SPDT relays, remote test, and/or remote LED alarm indicators may be installed where indicated. KII —•••• FENWAL KICOE.FENWAL- INC. 400 MAIN STREET ASi-ILANO, MA 01 721 TEL. (50E0881-2000 FAX. (508) 881 -8920 SERIES MB/MBS Motor Bells & Strobe Bells Wheelock's Series MB/MBS Motor Bells and Strobe Bells provide a better engineered motor bell for fire and life safety alarm systems: Higher dBA; low current draw; built-in trimplate for semi -flush mounting; low frequency aluminum shells for better audibility; low RFI noise; high torque, permanent magnet motor for durable, reliable performance. a,ATURES SERIES MB FIRE w eelock 1 UL Listed for fire Protective Service • 6" and 10" shell sizes in 12- or 24 -volt DC models • Mounting options for surface, semi -flush, outdoor, and concealed conduit installation • Integral RFI suppression minimizes induced noise on alarm lines DERING INFORMATION AND SPECIFICATIONS • Polarized for DC supervision of alarm • Screw terminals permit fast in -out field AWG wire • 12,000 peak candlepower strobe bells to save wiring time for 2 -wire, tandem and strobe lines wiring of 12-22 have single input operation of bell Model Number Order Code Shell Size ut YDlf a g Y I Input Current dBA @ 10 R. Mounting Options p Approvals' DC VIBRATING MOTOR BELLS DC VIBRATING MOTOR MBS -G6 -12 -W -HF -R MB -G6 -12-R 3942 6" 12 0.060 92 A (Note 1) B, C, D UL, CFM, ULC, NYC, FM MB -G6 -24-R 3941 6" 24 0.030 1 MB -G10 -12-R 3944 10" 12 0.060 MB -G10 -24-R 3943 10" 24 0.030 DC VIBRATING MOTOR MBS -G6 -12 -W -HF -R 3938 6" 12 0.110 4.... 92 E F UL, CFM, ULC, FM MBS -G6 -24 -W -HF -R 3937 6" 24 0.055 MBS -G10 -12 -W -HF -R 3940 10" 12 0.110 MBS -G10 -24 -W -HF -R 3939 10" 24 0.055 *See Note 5 NOTES (see page 4 for general information and technical notes): 1. Built-in trimplate eliminates need for SFP plate. 2. Typical dBA at 10 ft. is measured in anechoic chamber. 3. All 12 VDC models are UL rated for 9.0 to 15.6 VDC and all 24 VDC models for 18.0 to 31.0 VDC. All DC models can be used with filtered or unfiltered (full wave rectified) voftage. 4. Strobe bell models have single input for fast wiring on continuous alarm systems. UL rated light output 1.5 candela. 5. Approvals: UL = Underwriters Laboratories; CFM Califomia Fire Marshal: ULC = Underwriters Laboratories of Canada (24 VDC strobes rated 3.0 candela for ULC strobe bells); NYC = New York City, FM = Factory Mutual. MOUNTING OPTIONS A SEMI -FLUSH • SFP ,� Standard aM Oa 8 SURFACE o l o 0 8810 O C CONCEALED CONDUIT '1 AP D OUTDOOR O �, N We' WBB ; ,1 E SEMI -FLUSH (Strobe Bells) •�C Sdnaaro i ✓ a• spwre a % O .0/1�' F SURFACE (Strobe o Bells) SB 13 • wheebcFc SERIES EH/EHS Electronic Horns & Strobe Horns Wheelock's EH -Series Electronic Homs and EHS-Series Electronic Strobe Homs offer outstanding advantages over conventional electro -mechanical homs in performance, packaging, and economical installation. FEATURES • Broadband horn sound output with 103 peak dB for high audibility. • Low current draw (0.017 Amps at 24 VDC) to minimize power supply and wiring costs. • Wide input voltage range ensures system compatibility and allows 24 VDC horns to work on 12 VDC also, using filtered or unfiltered voltage. • Strobe horn models with single input for fast tandem wiring or dual inputs for independent operation of horn and strobe. • UL listed for Fire Protective Service. • 117 candela models for ADA applications. ORDERING INFORMATION AND SPECIFICATIONS ELECTRONIC HORNS SERIES Eli -D EHS-D All models shown with optional strobe SERIES EH -E EHS-E Model Number EH-DL1-R EH-DL2-R EH-EL1-R EH-EL2-R Order Code 4027 4026 4025 4024 Input Voltage (VDC) 12/24 12 Input Current (AMPS) 12 VDC 12/24 12 0.015 0.040 d8A at 10 Feet 12 VDC 24 VDC 0.017 Typical Peak 24 VDC Typical Peak Mounting Options Approvals* 90 98 96 96 103 103 B, F 0.015 0.040 ELECTRONIC STROBE HORNS (Single Input) 0.017 90 98 96 103 96 103 A, C, D, E FM, UL CFM, ULC NYC, BFP Model Number EHS-DL1-W-VF-R EHS-DL2-W-VF-R EHS-EL1-W-VF-R EHS-EL2-W-VF-R Order Code 4033 4032 4029 4028 Input Voltage (VDC) 24 12 24 12 Input Current (AMPS) MIA at lO Feet Typical Peak Rated Candela Mounting Options Approvals* 0.035 96 103 1.5 0.090 0.035 96 103 1.5 B, F 96 103 1.5 ELECTRONIC STROBE HORNS (Dual Input) 0.090 96 103 1.5 A, C,D,E FM UL, CFM BFP Model Number EH-DL1-WS-24-VF-R EH-DL2-WS-12-VF-R EH-EL1-WS-24-VF-R EH-EL2-WS-12-VF-R EH-DL1-WH-24-VF-R EH-EL1-WH-24-VF-R EH-DL1-WM-24-VF-R EH-EL1-WM-24-VF-R Order Code 4035 4034 4031 Horn Input Voltage (VDC) 4030 4556 4553 4912 4913 24 12 24 12 24 24 24 24 Input Current (AMPS) 0.017 0.040 0.017 0.040 0.017 0.017 0.017 0.017 dBA at 10 Feet Typical Peak Input Voltage (VDC) Strobe Input Current (AMPS) Rated Candela Mounting Options Approvals' 96 103 24 0.025 96 103 12 0.050 96 103 24 0.025 96 103 12 0.050 96 103 24 0.075 96 103 24 0.075 96 103 24 0.088 1.5 1.5 1.5 1.5 15.0 15.0 96 103 24 0.088 117 117 B, F A, C, 0, E FM, UL, CFM, ULC 8, F A, C, D. E NOTES (see page 4 for genera information and technical notes): 1. Horn models with 12/24 input voltage are UL listed for use on 12 VDC or 24 VDC systems. 12 VDC horn models e 5 are UL listed for 9.0 to 15.6 VDC. 12 VDC strobe hom models are UL tested for 9.6 to 14.4 VDC. All 24 VDC models are UL listed for 18.0 to 31.0 VDC. All models can be used with filtered or unfiltered (full wave rectified) voltage. 2. dBA is measured in an anechoic chamber with fast meter response (typical) and peak meter response (peak). 3. Standard strobe horns have white lens with red "Fire" lettering. UL rated Tight output 1.5 candela for 12,000 peak candlepower and 15.0 candela for 70,000 peak candlepower, and 117 candela for ADA requirements. 4. Single input strobe horns are recommended for fast wiring when horn and strobe operate in unison on continuous alarm systems. Dual input strobe horns are recommended for coded alarm systems and for independent control of the kom and strobe. 5. Approvals: UL = Underwriters Laboratories, CFM = California Fire Marshal, ULC = Underwriters Laboratories of Canada (24 VDC, 0.050 A strobes for all ULC strobe horns), NYC = New York City, FM = Factory Mutual, BFP = City of Chicago. B, F A, C, D. E FM, UL, CFM NYC, BFP UL, CFM NYC, BFP MUUN I ING OPTIONS A SURFACE EHS-E �- D88 m 0 0 B SURFACE SEDES EHS-D S68 110I, upp C SURFACE k,-..e',,,�_ 1 �� SERIES "'G DBB EH -E EHS-E `, •, Y�a AP D OUTDOOR SERIES EH -E EHS-E `' I —, �� \ WBB .� E SEMI SERIES EH -E EHS-E -FLUSH II a• 4•x" o backbox co to� pSESERIE SFP 2/ F FLUSH SERIES EH EHS-D 4• backbox x 21/e" 7 DATE: ACCEPTANCE TEST PROCEDURE SON SYSTEM JOB NAME: SIX ROBBLEES JOB NO. 2248 LOCATION: 1011 PACIFIC HIGHWAY SOUTH SEATTLE, WASHINGTON I 1. This Acceptance Test Procedure describes the functional test required to verify that the Fire Protection System functions as intended by its design. 2. The Fire Protection Contractor shall provide all materials and equipment required to perform the test. 3. Notify remote station, or Fire Dept., that the system test is going to be performed. Circuit may be disconnected for test period (only if remote signal is applicable). 4. Notify building personnel that the test is going to be performed. Building fire alarm system audible circuit or zone circuit may be disconnected for test period (only if building fire alarm is applicable). 5. Disconnect the control head from halon valve, verify that all detectors have been properly adjusted and that a record of the setting for each detector has been submitted to the owner. 6. Visually inspect the installation and wiring of all. equipment prior to starting the test procedures. Verify proper installation. II ACCEPTANCE TESTS - TROUBLE CONDITIONS Description of Events: Verify trouble responses specified in Table II. For each condition listed, the appropriate system response should To verify control panel trouble conditions, perform the steps: 1. Perform conditions listed in Table II 2. Verify indicated response(s) 3. Push control panel trouble silence switch to "silence" position. Audible trouble alarm will silence. 4. Return condition in step 1 to normal condition. III trouble occur. following ACCEPTANCE TESTS - ALARM CONDITIONS Description of Events: Verify alarm conditions as specified in Table III for each alarm condition listed, the appropriate system response should occur. After initiation of each alarm condition, the following steps should be completed: 1. Alarm condition - silence audible alarms by placing the alarm silence switch in the "silence" position. 2. Reset the control panel after the alarm condition system responses have been verified. 3. Verify that the control panel is in normal supervisory condition and all trouble indications have cleared. TABLE II X = desired response 0 = undesired response SYSTEM CONDITION DISCONNECT AUDIBLE CKT. DISCONNECT DET. CKT. 1A SYSTEM TROUBLE CONDITIONS SYSTEM RESPONSE S S Y Y S S T T R R B B L L L B A U M Z P Z E R X X X X DISCONNECT DET. CKT. 1B DISCONNECT MANUAL RELEASE CKT. DISCONNECT ABORT CKT. T R 0 U B L E C 0 N T A ' C T X X C K T T R B L L A M P X X 1 X X X X X X X X X X X X DISCONNECT RELEASE CKT. DISCONNECT BATTERY CKT. DISCONNECT 120 VAC POWER X X X X X X X X X X X GROUND ANY POSITIVE TERMINAL GROUND ANY NEGATIVE TERMINAL X X X X X X X TABLE III SYSTEM ALARM CONDITIONS X = desired response 0 = undesired response A = response that is to be aborted TD = desired response after 60 time delay period DET. CKT. lA SYSTEM RESPONSE S Y S A L M L A 14 P S Y S A L M C 0 N T A C T C K T A L M L A M P A L A R M B E L L A L A R 14 H 0 R N H V A C S H U T D 0 W N P 0 W E R S H U T D 0 W N S T A R T T I M E D E L H A L 0 N D I S C H A R G E X X X X DET. CKT. 1B X X X X DET. CKT. 1A & 1B X X X X X TD X TD MANUAL RELEASE CKT. X X X X X X X ABORT CKT. (TEST NEXT STEP) A A A 0 DET. CKT. 1A & 1B, OPER. ABORT SWITCH (RESET PANEL AFTER NEXT STEP) X X X X A A A 0 RELEASE ABORT SWITCH X X TD X TD OPER. ABORT SWITCH, VERIFY MANUAL RELEASE OVERRIDES ABORT X X X X X X X Iv ACCEPTANCE TESTS - BATTERY POWER CONDITIONS 1. Switch the circuit breaker supplying power to the Halon control panel to its "off" position. Verify the following events: The system trouble lamp is "on" and the trouble sonalert is sounding. The system trouble relay contacts transfer. 2. Actuate detector. Verify Table III response occurs Reset the control panel 3. Actuate manual station. Verify Table III response occurs Reset the control panel 4. Return circuit breaker supplying power to the Halon control panel to its "normal" position. BATTERY CALCULATIONS ,N JOB NAME: SIX ROBBLEES JOB NUMBER: 2248 DATE: 10/24/94 CALC. BY. MBM CIRCUIT SUPV. CURRENT NO. TOTAL ALARM CURRENT NO. TOTAL FENWAL 2210 CTRL. PNL. . 075 1 . 075 3.000 1 3.000 CPD 7051 ION DET. .000045 4 .0002 .100 4 .400 BELL/STROBE --- --- .055 1 .055 HORN/STROBE --- --- .105 1 .105 STROBE --- --- .088 1 .088 RELEASING SOLENOID --- --- .200 1 .200 TOTAL SUPV. .0752 TOTAL ALARM 3.848 TOTAL SUPV. CURRENT .0752 + ALARM CURRENT 3.848 = 3.923 A.H. TOTAL SUPV. CURRENT .0752 x 24 HR'S. = 1.805 A.H. TOTAL ALARM CURRENT 3.848 x .1667 HR'S. .641 A.H. SUBTOTAL = 2.447 A.H. SUBTOTAL 2.447 A.H. x 1.2 SAFETY FACTOR = 2.936 A.H. BATTERY SIZE USED 7.0 A.H. TOTAL REQUIRED 3.0 A.H. SECURE FROM TEST Notify interested parties that the Acceptance Tests are complete and the system is being placed in operating conditions. Instruct the operating personnel in the proper operation of system. Install control head on Halon tank valve. Verify that Control Panel is in normal supervisory condition. DATE: JOB NO. 2248 TEST PERFORMED BY: TEST WITNESSED BY: EXCEPTION OR COMMENTS: FOLE 1UKWILA Please call: 5i4-44+» and give this job Na_C)y-S�ZZ4 and exact address for dawn or restoration) a pkifovol; EXISTING SHOP AREA • PROTECTED W/ UPRIGHT i SPRINKLER HEADS BATH DROP --I BRACED TO a WALL W/ UNI—STRUT 114x1 HOOKER GYP 0 8.-0° SCALE 1 » _ » 440 Y8 NORTH ACCE TE Without Comments 0 AsNotedlnRed ❑ Per The Attached Letter These plans have hen reviewed by The Tukwila Fire Prevention, Sure,:t:Iu for caTittrnian,r:,:c with current city 7tandard s. Ai:c;t;pzerige is s..) jeot to errors and orniss ions ',.hth ;;:.. }thonze violations of adopted C Cart 4,a o� _,r;d r 7•....}._ :: ;„„ ibility for the r' �r(jn•, F fi adequacy c$ ties ;i;; i >:._ ; ?Try with ttFln e ' u u�':;f:1ri,..i. Additions, _.,lithese drawings after date vgiil iii!' this,accep2;f.ce and wild require a resubmittal of revised drawings for subsequent approval. Final acceptance is subject to field test and inspection by The Tukwila Fire Prevention Bureau, Date: `//9/DBy: ZkiSID GENERAL NOTES 1. ALL MATERIAL AND INSTALLATION PER NFPA 13 2. ALL REQUIRED ACCEPTANCE TESTING SHALL BE PERFORMED BY THE INSTALLER IN ACCORDANCE WITH NFPA13 AND THE AUTHORITY HAVING JURISDICTION. 3. ALL NEW PIPING IS ALLIED SCHED. 40 WITH C.I. FITTINGS. ,SPRINKLER LEGEND: • A— ADDED GEM TY -8 PENDENT HEAD W/ 401K 2 PIECE TRIM QTY= 1 O — EXISTING UPRIGHT HEADS AT ROOF 0 FIRE PROTECTION SYSTEMS, INC. 23220 MAPLE VALLEY/BLACK DIAMOND RO. S,E. - MAPLE VALLEY, WA 98038 MITE 3-0 425-432-4401 CONTR. UC. ACERPS147P1 ACE SYSTEM DESIGN CRITERIA PER NFPA 19-HAZA1iD DP rd0►f PROJECT SIX ROBBLES 11010 TUKWILA INT. BLVD TUKWILA. WA CONTRACT WITH SIX ROBBLES 11010 TUKWILA INT. BLVD TUKWILA. WA DRWG. TITLE FIRE SPRINKLER T.I. PLANS DATE 11-3-04 REVISED DRAWN BY MU SCALE AS NOTED - CONTR. / 04-2144 APPROVALS BY CITY OP TUKRIIA _A,9szu,ICD' 0,1 .. 3 'L'1;4, i� Z ,'75 L s ILE - IC . i TRUE COut . -' TC9 - A.o4CIION BOY -� CEILING FLUSH MOUNTING ALE: DETAIL(NTS SC Q Prov;cl e re610+e L. t. o'S -Cop- ci&Dvc Cet 1 � s�ltok� do �Alfo�s. FuhCi+FOrut t etcc p-k,r ce 41,44- rTtG LA- ie .(b44c4 71' .;19 F. h. +o .0a-4 .4 -0J.Ks.1-aI( kn,cc. kimrclz.l 1oc.kvv'4- dcvl-L.c Co - olecli4 -ed t`4. S e(/•t-- CC n4-ket I Sts -J-; » Hwy. -r re(„t iri c-; -TUKWILA FIRE DEPARTMEn Please call: 575-4407 i` and give this job No. y -F."1v y ; and exact address for shute, 1 -down or restoration approva0 ACCEPTED WITHOUT COMMENTS. en AS NOTED IN RED 0 PER THE ATTACHED LETTER The drawings affixed hereto have been reviewed and accepted by the City of Tukwila Fire Dept. Additions, deletions or revisions to these -drawings after this date will void this acceptance and will require a resubmittal of revised drawings. Final acceptance is subject to field - inspection by a representative of this 'department ATE: /%J4 _BY: ,4&i 5/) .9, CITY OF TUKWILA 575'4407 V; i T -o 6'-0• MnIJNTIF:G HEIGHT DETAIN. 147 10 SCLE N SEQUENCE OF EVENTS ALARM ONE SMOKE DETECTOR: ACTIVATION OF ANY ONE OF THE SMCxE DETECTORS ON CEIUTIG OR UP IER FLOOR SHALL: I. ACTIVATE THE GENERAL ALARM CONTACTS IN THE FMCP. 2. ACTIVATE, THE BELLYSTROBE ALARM. ALARM 3. INDICATEFROMCROSS.'tOCAT14NZONE OF ALARM EY ZCNE IN FMCP. ACTIVATION OF ANY ONE OF THE SMOKE DETECTORS FROM EACH OF THE TWO ZONES SHALL: 1. ACTIVATE THE GENERAL ALARM CONTACTS IN THE FMCP. 2. ACTIVATE THE HORN/STROBE 3. INDICATE LOCATION OF ALARM BY ZONE IN FMCP. 4. START 60 SECOND TIMER FOR RELEASEE OF FM -200 AGENT. 5. SHUT DOWN HVAC ANO CLOSE AIR DAMPERS. 6. COMPLETION OF 60 SECOND DELAY FIRES CONTROL. HEAD ON y1lLON BOTTLE FCR AGENT RELEASE. ALARM MANUAL STATION: ACTIVATION OF MANUAL STATION S. 1. ACTIVATE THE GENERAL ALARM CONTACTS IN THE FMC?. 2. ACTIVATE THE BELL/STROBE AND M:CRN/STROEES. 3. INDICATE LOCATION OF ALARM IN r AC?. 4. RELEASE HAI.ON 1301. 5. SHUT DOWN HVAC ANO CLOSE THE AIR DAMPERS. ABORT SITUATION: ACTIVATION OF ABORT. STATION 1. STOP COUNTDOWN PERFORMED BY FIRING 14000LE FOR AGENT RELEASE FUNCTION DUPING II 3VAL THAT THE ABORT STATION IS BEING OPERATED (MIST eE HELD IN). RESET: SYSTEM CAN BE RESET BY ACTUATION OF RESET BUTTON IN FMCP WHEN THE DETECTING ZONE! ARE NO LONGER IN ALARM CONDITION. TROUBLE: SYSTEM TROUBLE. ACTIVATION CF ThE '*ILON TAMPER SNITCH, GROUNOING. pPEN CIRG:T CF SUPERVISED CIRCUITS OR POWER SYSTEM FAIL:=E SMALL 1. ACTIVATE THE GENERAL TRCU� E CC!ITACTS IN THE FIRE CONTROL PANEL 2. INDICATE LOCATION OF TROUBLE BY ZONE IN THE FtACP. 3. ACTIVATE VISUAL ANO AUDIELE TROUBLE SIGNAL IN THE FMC?. TROUBLE ACKNOWLEDGE: USER ACXNOKtEDGE OF A TROUBLE IN THE FMCP WILL SILENCE THE AUDIBLE TROUP.LE SIGNAL. v:9;.:AL SIGNAL WILL REMAIN UNTIL SYSTEM TROU2LE IS CLEARED. ORMMNG INDEX °ATE (SHEET N IRE JQN DRAWING TITLE :5/27/94 FPI A NOTES. DETAILS. B.O.M. 3S/27/94I FP2 I A :5/27/941} FP3 1 A FIRST FLOOR POWER ROOM FLOOR PLAN PANEL AND FIELD YARING L u 11 rt L(_T P.r..A.__I (',Tw 1. tISTALLA11OI1 SHAi.. C:111-17 nY sFrUC4PiC 5 :7.:1S OF !KP: FIRE; CCOES INCLUL.7:6 `IvA 7C. 72A 111%,1 7:E. A•:D 7. ALL 1.110140 SNAIL K !.Uri 111 E 14n4 i'1•.ANDE0. 3. INSTALLATION SHALL I:CIIPL1 '.1:(n A9110.2 7r.0. '.2,1.241 'A' 919) SECTION 'C.. a ALL OEVACE5 SHILL 62 Run it: 7..E 2.9UE SEC::C` :ci: Ai 5.10911. 9. PCN.ARIrt Cr ALL "e9111.2 st10 06.1.0:5 t1US1 DDE :e6EA.TD. E. ALL FIELD 9181110 5„ALL EE 0.t• 967 FOP. SHC915 A1.7 rAwNoS 86909E COta1EC1uI� 10 co'TP: PANEL 7. ALL MARE TO BE CG_^5 +•IO VC•EIE7. ala :an, 111111. B. NO PARALLEL aRm.callo 7; v;PE+•:1<C:.1.199 9. 120 VOLT 919.1114 :`..u. SE R -N 71 SEPA9A TF C2a10CIT 9.1711 O.C. 11791/10 10. ArTEF. F11AL CH6017U1. FET.": 0114 7707 CF F,ELD C3=a1NCS FOR ASBIATS. 1t. 0676070k5 SNAt1 :ffiC EE L02.7.0 CLC -EP. r =•I : 9714 ANY SUPPLY MR WFN`ZP 12. 0(160T09S SMALL 11.E u *MCC :' (7911 710.11 CE•1a:75 01: 96995. 13. DETECTORS MAT AsE • t'7 9 11i1GC •:.=••t•i S,H%li BE most160 .7 t 42 F:`E Of :"= SP:CQ:G Ia, NOTIFr 64U1:E-EREr Fv: SiS7Z•12 Cr Alf.' A, Ir. •7:t. 9RC.11 THESE 9(9115 I 1 5 Y1.4 OTY NO. DESCRIPTION =ART NUmGER IMANUFACTURET 1 12210 PANEL -221000-000 • FENwAL 2 2 1 BATTERY 220070 -GG: i FENWAL 3 1 SATTERY HARNESS 23-22107C-032 i FENWAL A 1 AUXILIARY RELAY SPOT POTTER-ERU`.1 5 I RELAY BASE -B5 POTI_i-BR L'`A IC 2 6 1 ICNIZATICN DETECTOR 7.•=2-7051 ! PCI 2 7 I CETECTOR BASE • :F:-001 FC 5 MORN MECHANISM I 901 2 9 i SELL PLATE - STROBE ___ct IFC 2 10 i SELL MECH c - FCi 11 Er BELL 90: 12 10' BELL 1: I ST08E COVER FOR HORN -5. /HSL I 7C1 O-:° ! FO 14 STROBE -5L I FC: 16 I RELEASE STA TAN 16 SURFACE BACK BOX 2 ! FCI __-. ! FC: 17 I ABORT SWITCH E.F.S. CC U Z < uz o1- z L7 OHA.r: R.=.- Ci1ECRE: DATE:OS/7/5- REVISIONS. :CE N0.:22 PERMIT N0. DWc. 1171: !IclES. DETA:_- 8.0.14. 09'G. No. FP -1 = ti 0.01 f'et — 10 BEhOW CE/LING- .0g TLC TOR (8) ABOVE CE/1../NG OE TECTO/9 — 5 F 0 (2)1A-1 P IB -I FKISTlNGHALOW PYP N( NozzLLES /A /^15I Eos I 2 Eos ►°1 - 1 CN) COMPUTER RM. F -I AO R P LA R Airs T C0 o z;Ccn W z < O i 'r7 Z• < N0 IC" <1..,, CC^ C7 2 I I-- ' <, O w v <C !tea a :W� O f.. CC Li.1 WW • .0 E ac W in W -Z 1 .- .51.56 C(IAIA DRAWN: R.B. CECKED: G.?_ DA E 06/28/ - REVISIONS_ OB NO.. PERMIT NO. DWG. TITLE: FIRST FLOGR POWER ROC. DWG. NO. FP -2 4 $ A - 10 — A -a - 7 6 -5 4 -- 3 - 2 - 1 PANE: EFL x 101t ELF D 1 G s M -x -10 ✓ A .east • FENWAL INCORPORATED 1e11." �• •. I NSSr, • ae 1 a r OS sa+ 1 . 0112.121.2222e • i • 112ela21 aars 1 svAlt: Mt Pr1 Y(Yrloael VOWS • 1• •. • I • I • a..a• anssa :MOT O r... NMI 1 awl • SIMI 11220120. Iearn I,e1Li1 powER J771Y1MMOI - 7 171-- A - 35 i 5.64 0 L11..2 AAA 99.22 �`IrG 12 YR o c IFIs~:. 0 ?e — 11 TROUBLE i l 6T,1a 7.... a J NO. MO•1 wear � I H N AS8UILT BATTERY IERY CALCULATIONS IPTION --.. P1 a - 2AiT (+) 11 9417 (-) 12 - 0AJANT0TY' SUPERMSOI. I ALARM 12 5.57. @D11AIING CRC::- INIT1AT1IC c .r 4 -- i 2 ABORT PRESSURE SWITC`= 3.01.• EG_ BELL/STROEE HORN /STROE_ (—) (+) '-c•••"- SOLENOID •"- SOLEN OID — P1-46 6 Art EATTE-I_S 6 Ar �r = 01 II r — P1 -17 D r i •• Ri SHUTDOWN (HVAC AND DANPE.e• 0 z W Z W zV W2 W 0.- z CC 0 <LJ 2O -J ac DRAYP: R.E.W. CHE^v.__: G.P.. 0A7F4CE/ 5r 4 REPS 9: 408 ND. PERM:: NC. DWG. TITLE: PAI` AND FIE= 511RING DWG. NC. FF -3 7: AIPER0 TOTAL AMPERES TOTAL }cN1IIIWALL 7051 TqR I 2 .000045 .000049 .000045 .000049 N5 NNC Ij 1 N 0 0 .035 .035 L/a a -N ( 1 0 0 .055 .555 F�'eRF1EWAL 1 CNTL PANEL I 1 .075 .075 .3 .3 FENWAL ELECTRIC CONTROL s0LCv100 I 1 .5 .5 TOTALS .0739 .890 ANP TOTAL TOTAL STAND-BY CURRENT .0759 H(4RS 1.821 TOTAL ALARM CURRENT .890 O.C63 _.07387 SE Q-YATTERY 1.895 RSATTERY 0E -RATING PLUS 20% 4.8AH BATTERY SUPPLIED 6AM 12 5.57. @D11AIING CRC::- INIT1AT1IC c .r 4 -- i 2 ABORT PRESSURE SWITC`= 3.01.• EG_ BELL/STROEE HORN /STROE_ (—) (+) '-c•••"- SOLENOID •"- SOLEN OID — P1-46 6 Art EATTE-I_S 6 Ar �r = 01 II r — P1 -17 D r i •• Ri SHUTDOWN (HVAC AND DANPE.e• 0 z W Z W zV W2 W 0.- z CC 0 <LJ 2O -J ac DRAYP: R.E.W. CHE^v.__: G.P.. 0A7F4CE/ 5r 4 REPS 9: 408 ND. PERM:: NC. DWG. TITLE: PAI` AND FIE= 511RING DWG. NC. FF -3 7: