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2100 COSTA DEL MAR RD; ; FS160008
9/21/23, 2:57 PM FS160008 Permit Data City of Carlsbad Fixed Systems Permit 2100 COSTA DEL Job Address: MAR RD Permit Type: F•IXSYS Parcel No: 2165900100 Lot #: 0 Permit No: FS160008 Status: ISSUED Applied 4/28/2016 Approved: 5/5/2016 11 Reference No.: PC #: Project Title: Issued: 5/5/2016 Inspector: OMNI LA COSTA KITCHEN NIGHT 11 NEW INSTALL OF A PYRO- CHEM, KITCHEN NIGHT II WET CHEMICAL FIRE SUPPRESSION SYSTEM Applicant: SIMPLEX GRINNELL 3568 RUFFIN ROAD SOUTH SAN DIEGO CA 858-583-0426 Owner: L C INVESTMENT 2010 L L C 1601 ELM ST DALLAS TX Fees •($) Add'I Fees ($) Total ($) Balance ($) 375 0. 375. 0 about:blank 1/1 NEC} POWER COMMUNICATION SYSTEMS, INC. pSER' IO T SALES - SERVICE - ENGINEERING Public Address •. Paging • Intercom • Fire Alarm • Nurse Call • CCTV SUBMITTAL FIRE ALARM SYSTEM WEST INN & SUITES T.I. 4970 AVENIDA ENCINAS CARLSBAD, CA 92008 FAI 60008 4970 AVENIDA ENCINAS OWNER: WEST DEVELOPMENT FIRE ALARM CONTRACTOR: POWER COMMUNICATION SYSTEMS, INC. P.O. Box 600066, San Diego, CA 92160-0066 • 4627-A Mission Gorge Place, San Diego, CA 92120-4133 (619) 583-7400 • Fax: (619) 583-0647 License No. 636431 -C7/CIO TABLE OF CONTENTS LIST OF MATERIAL 1 UL CERTIFICATE 2 BUSINESS LICENSE 3 CUT SHEETS 5054 MXL-IQ (EXISTING) 4 6179 T1U-D 5 C.S.F.M. LISTINGS 7165-0067:0144 MXL-IQ (EXISTING) . 6 7300-0067:0146 TRI-D 7 LIST OF MATERIAL MODEL NO....uFAcTuiR .DEscRIPTIoN QUAN.TITY MXL-IQ SIEMENS FIRE SAFETY FIRE ALARM CONTROL PANEL EXISTING TRI-D 64 " MONITOR MODULE - DUAL INPUT U L (9 Applicant ID No: 967165-001 Service Center No: 0 Expires: 2016-03-31 CERTIFICATE OF COMPLIANCE THIS IS TO CERTIFYthat the Alarm Service Company indicated below is' included by Underwriters Laboratories Inc (UL) in its Product Directories as eligible to use the UL Listing Mark in connection with Certificated Alarm Systems. The only evidence of compliance with UL's requirements is the, issuance of a UL Certificate for the Alarm System and the Certificate is current under UL's Certificate Verification Service This Certificate does not apply in any way to the communication channel between the protected property and any facility that monitors signals from the protected property unless the use of a UL listed or Classified Alarm Transport Company is specified on the Certificate. Listed Service From: SAN DIEGO, CA Alarm Service Company: (967165-001) POWER COMMUNICATION SYSTEMS INC SUITE A. 4627 MISSION GORGE PL SAN DIEGO CA 92120 Service Center: (967165-001) POWER COMMUNICATION SYSTEMS INC SUITE A 4627 MISSION GORGE RI SAN DIEGO CA $2120 The Alarm Service Company is Listed in the following Certificate Service Categories: File - Vol No. CCN Listing Category S36694 UUJS [Signal and Fire Alarm Equipment and Services] (Protective Signaling Services) Local, Auxiliary, Remote Station and Proprietary ***THIS CERTIFICATE EXPIRES ON 20160331*** "LOOK FOR THE UL ALARM SYSTEM CERTIFICATE" NEcg POWER COMMUNICATION SYSTEMS, INC. SALES - SERVICE - ENGINEERING Public Address • Paging • Intercom Fire Alarm • Nurse Call • .CCTV flSCR lUILDIM, co,jnsctloMr State Of California -- CONTRACTORS STATE LICENSE BOARD -- ACTIVE LICENSE Licomnobw 636431 CORP POWER COMMUNICATION SYSTEMS INC tco'(s) C-7 CIO 4lh E-Vabw Dine 01/31/2016 wvw.cslb.ca.gov P.O. Box 600066, San Diego, CA 92160-0066 • 4627-A Mission Gorge Place, San Diego, CA 92120-4133 (619) 583-7400 • Fax: (619) 583-0647 License No. 636431-C7/C1Q SIEMENS Fire Safety MXL-IQ EXISTING Advanced Life Safety System ENGINEER AND ARCHITECT SPECIFICATIONS FirePnnt Application Specific Fire Detection Capacity for up to 240 Intelligent Analog Detectors Expandable Up to a Stand Alone System Capacity of 998 Input and Output Points Dynamic Supervision of Intelligent Devices Security Device Monitoring Sprinkler Supervision Intelligent/Analog Detection Circuits, Style 6 (Class A) or Style 4 (Class B) Detector Sensitivity Read- out/Printout per NFPA 72 Chapter 7 Style D (Class A) or Style B (Class B) Conventional Initiating Circuits Style Z (Class A) or StyleY (Class B) Notification Appliance Circuits Degrade Mode Operation Distributed Processing 80 Character Backlit Alphanumeric Display Supervised Remote Printer 32 Character Device Custom Messages Multiple Command Stations Compare System-Software Fully Field Programmable Via Laptop Computer Menu Driven Operator Commands Central Architecture 800 Event History Logging With On Line & Off Line Reports User Help Screens Multiple Levels of Password Protection One Person Walkiest by Zone or System Automatic Environmental Compensation for Smoke Detectors Alarm Verification by Device or Zone Logic Controlled Output Functions Time Base Controlled Output Functions Holiday Schedule CityTie/Lease Line Coded Outputs Supervised Serial Annuncia- tor Driver/Input Interface Interactive VDT- Monochrome & Color Color Graphics Option Complies with NFPA 72 NEC 760 Power Limited Circuits (UL 864 Compliant) 16 Gauge Steel Enclosure Pre-action Releasing and Deluge (NFPA 13) FM Approved for Intrinsi- cally Safe Applications FM Approved for Sprinkler and Deluge Applications Pre-alarm Operation Halon and SinorixTM Releas- ing Approval (NFPA 12A and NFPA 2001) Intelligent Link to Air Sampling Detection Systems Multi-Language Display Intelligent Interface to Building Management Systems Operates as an Interactive Peer with Other MXL-lQs, MXLs or MXLVs in a LifeLINK Network CXL Command Center Monitoring ® Listed, ULC Listed, FM, CSFM, NYMEA, and City of Chicago Approved FireFinder Graphics Description The MXL-IQ is a microprocessor based advanced Life Safety system. Its Use of Unique multiprocessor "Net- work" design along with its ability to utilize both intelli- gent analog and conventional detection devices make it the most flexible and reliable system in the life safety field. The MXL-IQ is the system for projects such as schools, nursing homes, small office buildings, strip malls, hotels, apartment buildings and dormitories. MXL-IQ is designed for stand alone or networked special hazard applications that call for extinguishing agent releasing (Sinori)TM, Halon, Pre-Action Sprinkler or Deluge). MXL-IQ provides the earliest detection possible via its intelligent link to air sampling detection systems. It complies with the requirements of NFPA 72. It is UL 864 and UL 1076 security listed. It is also UL listed for agent releasing per NFPA 12A and NFPA 13. CATALOG NUMBER 5054 The basic MXL-IQ control unit consists of the following subassemblies: SMB-2 Main Control Board; MPS-6 Power Supply; MKB-4 Annunciator and Keyboard; MSE-3L Enclosure. Optional modules which can be installed with the MXL-IQ System include: MPS-12 Power Supply; MOM-2 or MOM-4 Expansion Card Cage; CRM4 Control- lable Relay Module; CZM-4 Conventional Zone Module; CSM-4 Controllable Signal Module; PIM-1 Peripheral Interface Module; CMI-300 CXL Modem Interface Module; NIM-1R LifeLINK Network Interface Module; MOD-16 Output Driver; MOl-7 Network Interface; MID-16 Input Module; MXL-VDT Interactive Video Display Terminal; MXL- G Color Graphic; MXL-GT ColorTerminal; a full range of intelligent/analog detectors and devices (see table 1). SMB-2 Main Control Board The function control of the MXL-IQ is contained on the SMB-2 Main Control Board. The on board 16 bit micro- processor along with nonvolatile EPROM and Flash memory allow the system to be custom configured to meet a wide range of customer requirements. The SMB-2 controls operating sequences and monitors input device identity, detector sensitivity, network communication and operator commands entered through the MKB-4 Annuncia- tor/Keyboard. The SMB-2 also provides 2 ALD (Analog Loop Driver) circuits. Each ALD loop can be configured as Style 4 (Class B) or Style 6 (Class A) and can monitor and control up to 60 Siemens Fire Safety intelligent input devices and 60 programmable device output relays. The SMB-2 is equipped with 2 programmable and codeable Style Y (Class B) or Style Z (Class A) notification appliance circuits. Each circuit can activate up to 1.5 amps of listed audible or visual notification appliances. Auxiliary relays are provided for external monitoring for Common System Alarm, and Common System Trouble. The SMB-2 includes a built-in battery charger and transfer circuit. The charger is microprocessor controlled and incorporates a brown out circuit which switches the system to optional standby batteries during loss or reduction of the primary source AC. Upon command, the system is capable of displaying the real time battery voltage, AC voltage, charge current and other power data on the MKB-4 Alphanumeric display. It also includes a 1 Amp, 24 VDC, output. The SMB-2 is fully FIELD PROGRAMMABLE off line using a laptop computer. Complete system configuration can be easily uploaded, downloaded or edited using CSGM custom programming software. Program options include but are not limited to smoke detector environmental compensation, Detector Pre-alarm, History Logging, Output Control by Event; Check and Change Time Based SMB2 Control, Detector Sensitivity, Alarm Verification by Device or Zone, 32 Character Custom Alphanumeric Messages• per device, System Operation Passwords and NAC Coding. The SMB-2 provides a port for connection of the programming laptop computer. MKB-4 Annunciator/Keypad The MKB-4 mounts on a hinged frame in the MSE-3L enclosure and provides an 80 character backlit LCD alphanumeric annunciator which continuously scrolls to display information concerning system status along with 32 character user defined device messages. When multiple events occur, the MKB-4 displays the last event of the highest priority. Additional data can be viewed by depressing the NEXT key. At any time, the display scroll can be stopped by depressing the HOLD button. Switches are provided for acknowledging fire alarms, supervisories, security conditions, and system troubles. An individual switch is also provided for silencing the system notification appliance circuits. A separate switch is used for resetting the control panel. A 10 digit numeric keypad is supplied to allow entry of the user passwords, as well as perform a wide variety of specific menu driven operation, programming and mainte- nance functions. A set of 12 user assignable "Function" keys provide single button access to a variety of system commands. These switches may be used to perform system operation such as "Drill:' manual relay control, zone disconnect, etc. Contained on the MKB-4 annunciator are system status indicator LED's which can function even if the main system microprocessor fails. They provide indication of Main Power On, Fire Alarm, Security Condition, System Trouble, Supervisories, System Audibles Active/Silenced and Partial System Disable. The MKB-4 Annunciator .communicates with the SMB-1 Main Control Board through the system network link. MPS-6 Power Supply The MPS-6 is a fully supervised power Supply which provides the system with primary DC power. It is rated at 6.5 Amps and is unfiltered and unregulated. It supplies the MXL-IQ Control Unit and its expansion modules with power required for normal operation. The unit incorporates a resettable circuit breaker on the primary input and includes a built in AC line filter for surge and noise sup- pression. The MPS-6 mounts in the MXL-IQ enclosure backbox. (MSE-3L) MOM-2 or MOM-4 expansion card cage. It provides four fully programmable relays. Each relay contains one set of SPDT contacts rated at 2 Amps 30 VDC/120 VAC resistive. MPS-6 MPS-12 Power Supply The MPS-12 is a fully supervised power supply which provides the system with primary DC power. It is rated at 12 Amps. and is unfiltered and unregulated. It supplies the MXL-IQ Control Unit and their expansion modules with power required for normal operation. The unit incorporates a resettable circuit breaker on the primary input and includes a built-in AC line filter for surge and noise suppression. The MPS-12 mounts in the MXL enclosure backbox. MPS-12 CSM-4 Controllable Signal Module The Controllable Signal Module CSM-4 provides two fully supervised, programmable notification appliance circuits. The CSM-4 supplies two Class B (StyleY) or Class A (Style Z) type output circuits for the supervision and control of listed audible or visual notification appliances such as horns, bells, strobes, etc. Each circuit, can provide up to 1.5 Amps (24VDC) of current to power notification appliances. CSM-4 is also used for pre-action or deluge application as well as for applications that call for municipal tie or leased line operation. SinorixTM and Halon cylinder solenoid activation is also controlled by the CSM-4. CRM-4 Controllable Relay Module The Controllable Relay Module CRM-4 is designed to provide auxiliary control of building functions such as door holder release, elevator capture, smoke control, lock release, etc. The CRM-4 plugs into one of the slots in the CRM-4 CZM-4 Conventional Zone Module The Conventional Zone Module CZM-4 is used with the MXL-IQ to provide four Class A (Style D) or Class B (Style B) conventional initiating device circuits. Each circuit can monitor up to 30 Siemens Buildinglechnologies, Inc. Fire Safety two wire photoelectric or ionization smoke detectors and an unlimited number of normally open contact devices. Projected Beam Detectors may also be used. The CZM-4 circuits will support the use of detector relay bases, and remote indicator lamps. Activation of any device on a circuit will initiate a zone alarm condition resulting in the operation of programmed functions. The CZM-4 module plugs into one full slot in the MOM-2 or MOM-4 expansion card cage. CMI-300 CXL/MXL Interface Module The CMl-300 is an MXL-lQ option module which provides modem communication between an MXL-lQ and a CXL system. The CM 1-300 plugs into one of the slots on a MOM-2 or MOM-4 card cage. This interface board trans- lates signals between the MXL-lQ and the CXL and fully supervises the signals. CMI-300 PIMi Interface Module The PIM-1 is an MXL-IQ option module which provides a bi-directional isolated RS-232 port for connection to peripheral devices such as printers, CRT's, VDT's, diagnos- tics, pocket pagers and Color Graphics. The PIM-i mounts on the MKB-4. It connects to the SM B-i and provides a screw terminal block for connection of RS-232 devices. A number of supervised and non-supervised formats are available. ALD-21 Analog Loop Driver The ALD-21 is an MXL-IQ Network option module which supplies two intelligent analog circuits utilizing Fire Safety "I" type intelligent devices. It occupies two addresses on the MXL-IQ local network and through the use of a unique communication protocol, devices connected to the ALD-21 circuits are dynamically supervised by the MXL-IQ control panel. Up to 60 programmable input and output devices may be connected to each of its two circuits. Each circuit may be wired as Style 4 or Style 6. SeeTable 1 for a list of compatible devices. The M01-7 is an MXL-IQ RS-485 Network module which provides a fully programmable serial interface to the MOD-16 output drivers and MID-16 input drivers. When used with the MOD-16's, it provides a serial annunciator or relay driver. When used with MID-16, it provides program- mable inputs. Each M0I-7 can operate up to eight MOD- 16's and eight MID-16's simultaneously. Each MOD-16 output and MID-16 input is independently programmable via the MXL-IQ custom software. MOD-16 Output Driver MOI-7 The MOD-16 is an output driver module used in conjunction with the M0I-7 as a part of the Fire Safety MXL-IQ System. ,Up to eight (8) MOD-16s can be connected to an M01-7 interface module. Each MOD-16 provides 16 open collector current sinking outputs rated at 24VDC, 50mA. MOD-16 outputs are programmable through the MXL-IQ custom software. MID-16 Programmable Input Driver The MID-16 is an input module used in conjunction with the M01-7 as a. part of the Fire Safety MXL-IQ System. Up to eight MID-16s can be connected to a single M0I-7 along with eight MOD-16 output driver modules. Each MID-16 provides a non-supervised input which can monitor contact devices. Each individual MID-16 input can be separately used as a part of the MXL-IQ custom program- ming logic. These inputs can be individually set for either Alarm, Supervisory,Trouble, Security or Status usage. They can also be configured to provide supervision for lamps driven by MOD-16 outputs. Screw terminals and connec- tors are provided on the MID-16 modules for interface to monitored devices. I MID-16 I MXL-VDT Interactive Video DisplayTerminal The MXL-VDT is a 14" amber monitor with detachable keyboard. It provides an interactive terminal for secondary display of MXL-IQ information, and operation of MXL-IQ functions such as Acknowledge, Silence and Reset, as well as arming and disarming devices. It also provides a means for generating system reports such as listing smoke detector sensitivity settings and voltages, battery and power supply voltages and current and displaying the history event log. An unsupervised printer may be connected to the MXL-VDT . LIJj LI.Iv1 i;• MXL-VDT RCC-1 Remote Command Console The RCC-1 is a remotely located MXL-IQ annunciator display module. The RCC-1 contains an 80 character LCD display and control keypad (MKB) and a PS-5N7 network interface. RCC-1 s can be located anywhere that control or annunciation is required. RCC-1 can be programmed for display only or can provide display and system control. If a PIM-1 is added to the RCC-1, remote printers, VDT or graphics computers can be located throughout a facility. RCC1 RCC-2 Remote Command Console The RCC-2 is a remotely located MXL-IQ annunciator display module mounted in a small enclosure (8-1/2"W x 7" H x 2-7/8" D). The RCC-2 can be located anywhere that control or annunciation are required. It contains an 80 character LCD display, a control keypad for system controls, and a PS-51\17 network interface. No function keys are included with the RCC-2. It can be programmed for display and control or display only. If a PIM-1 is added to the RCC-2, remote printers, VDT or graphics computers can be located throughout a facility. RCC-2 RSE-1 Remote Serial Enclosure The RSE-1 is a remotely located MXL-IQ module that allows a connection to a printer, video display terminal, alphanumeric pager interface, or remote diagnostic module. It contains an annunciator board and a PS-5N7 interface board, with space in the enclosure for a PIM-i printer driver board. RSE-i PIM-2 Parallel Printer Interface The PIM-2 is an MXL-IQ or CXL parallel printer interface module. PIM-2 connects to PIM-1 to allow MXL-IQ connec- tion and supervision of any EDP listed printer. PAL-1 UL Listed Parallel Printer The PAW is a UL listed supervised parallel system printer for MXL-IQ or CXL. The PAL-1 connects to the PIM-2 and PlM-i to provide MXL-IQ with a UL listed parallel printer that is supervised. ICP-B6 Intelligent Control Point The ICP-136 is a field mounted output module capable of being programmed to be either a remote bell, horn, or strobe circuit. The ICP-136 communicates with the MXL-IQ via the ALD loop. IcP LIM-1 Une Isolator Module The LIM-i is a short circuit isolator module for use on the MXL-IQ's analog loops. The LlM-i is capable of providing Style 4, Style 6 wiring of ALD loops. Multiple short circuit isolators can be used on a singleALD loop to prevent loss of protection in the event of a short circuit. MOM-2 Network Option Module Card Cage The MOM-2 provides the MXL-IQ main unit with card slots for optional modules. Each MOM-2 provides space for one full-width (ALD-21, NIM-1W or CZM-4) or two half-width option modules (CSM-4, CRM-4, CMI-300. REP-1). MOM-4 Network Option Module Card Cage The MOM-4 Card Cage provides the MXL-IQ with card slots for option modules. Each MOM-4 supplies connec- tion space for either two full width option modules (ALD-21, CZM-4, NIM-iW) or four half width option modules (CSM-4, CRM-4, CMI-300, REP-11) or combina- tion of one full and two half width modules. FireFinder - Network Color Graphics FireFinder is a PC based color graphics display and control package designed for use with the LifeLINK network and provides full control and annunciation for a LifeLINK network of up to 63 MXL-IQ or MXL systems. The NCC-G is used to monitor and control alarms, troubles, security, supervisory and all system events from one of many MXL series systems. The NCC-G maintains an extensive history log of all system events and has extensive report generation capabilities. User programmable function buttons are programmable to allow site specific control function configuration. Mul- tiple NCC-Gs may be connected to a LifeLINK network. The NCC-GL serves as a graphical command center for a single MXL-IQ system. All of the FireFinder controls utilize a friendly design which intuitively guides the operator through all system conditions. NCC-G NIM-1W Network Interface Module The NIM-iW is a full sized slot MXL-IQ module that allows the interconnection or networking of up to 63 MXL/MXL-IQ systems. The NIM-1W provides an RS-485 communication path in either Style 4 or Style 7 wiring configurations. The NIM-iW allows MXL/MXL-10s to have interpanel logic and communicate in a peer to peer fashion. The NIM-iW can be programmed via CSGM logic as an FSI (Foreign System Interface) to communi- cate with external building control and annunciation systems. The NIM-1W is programmable to serve as an intelligent link to the air sampling detection system. MOM-4 PS-51\17 5 Volt Power Supply/Network Interface The PS-5N7 is a 5V power supply and MXL-IQ local network interface module. The PS-51\17 is an integral part of the RCC-1. NIM-1W MSE-31 MXL-IQ, Enclosure/Door The MSE-3L is a sheetmetal backbox for the MXL-lQ system. The MSE-3L supports mounting for the SMB-2, MPS-6, MPS-12, MPS-12-220, MPS-12-240, MKB-4 and either one MOM-2 or one MOM-4 cardcage. The MSE-3L dimensions are 271/16"H x 211/8"W x 6"D.The IQ-DFL plate (500-695436) is also available for use with the MSE-3L to provide full deadfront construction. The MET- 3L (500-695437) flush trim mounting kit is also available for use with the MSE-3L enclosure. The MET-3L pro- vides an optional 1" trim mounting ring around the MSE-3L. The MSE-3L enclosure also has provision for mounting a PSR-i remote power supply, for use in place of the SMB-2 for MXL and MXLV applications. When the PSR-i is mounted in the MSE-3L enclosure the IQ- BLANK (500-695438) blank plate is available to cover the cutout in the MSE-3L door. Other versions of the MSE- 3L include; MSE-3LR - Red version of the MSE-3L and the MET-3LR - Red version of the MET-3L trim ring kit. CCU/M Alphanumeric Pager Interface The CCU/M is a ancillary module that connects to the PIM-i to transmit MXL-IQ status information in text message format to an alphanumeric pocket pager. The CCU/M can be connected to an existing phone line and can dial out to a pager using its onboard modem to transmit information via a paging service. The CCU/M can also connect directly to an existing on-site paging system. Through programming the CCU/M can send different types of events to different pagers. Up to 8 different messages can be sent to pagers directly from the CCU/M. Alarms, Troubles, Supervisory, Security, Arm/Disarm, Status Points, Audible Status, and Reset can be directed to all or only certain alphanumeric pocket pagers. RDM-MXL, RDM-PC The RDM-MXL in combination .with the RDM-PC pro- vides the ability to call up an MXL, MXL-IQ or MXLV system to check on the system status. The RDM-PC connects a remote computer to the MXL equipped wit the RDM-MXL. The RDM-PC initiates a call to the MXLs RDM-MXL module. The RDM-MXL answers the call. The RDMPC identifies itself with the login name. As a built-insecurity measure, when the login name is recognized by the RDM-MXL, it then hangs up and initiates a call back to verify the login and password. Once the login and password is verified, the operator is on-line with the MXL. The operator can list system status, alarms, troubles, supervisories, and/or security events! CCU/M and RDM-MXL REM The REP-1 is an optional MXL module that extends the distance of the MXLs RS-485 network. The REP-1 provides the ability to support various wiring configu- rations, including series and star configurations. The REP-1 provides the ability to support NFPA Style 4 or Style 7 network communications wiring. The REP-1 can be used to provided network wiring between MXL panels or MXLR panels. The REP-1 is a one -half slot card that plugs into a MOM-4 or MOM-2 cardcage. The REP-1 allows MXL network distances to be expanded to allow greater application flexibility. The REP-1 is an RS-485 repeater module capable of being configured as one Style 7 or two Style 4 net- work communication lines. Electrical Specifications SMB-2 Analog Device Loops (TB2 and T133) 1. Electrical Ratings: Supervisory 30VDC max, 66mA max. Alarm 30VDC max, 66mA max. (60 devices in alarm) All wiring must be in accordance with Article 760 of NEC or local building codes. 3. Only the following list of devices may be used. A maximum of 60 devices in any combination may be connected to a single analog loop. The UL identifiers for compatibility are the same as the model names specified in Table 1. TABLE 1 COMPATIBLE DEVICES Devices CiMi Base - thstrucliou P/N 3JOfl PIN 3'15-085355 fP'11/FPT.'115 DO-35 wtb DBADPT 041 PIN 315-0921 P/N 3154521 ICP - P/N 315-0.92471 ICP'AG - P/N 3154$36 i1f1/114 ILl-1A/1i%H IL(-1 P/1 OH 00.3sn DD-130S 0e.4 DB43RS AO'( .AD4X1fl P/N 313.07 P/N 150-35387 P/N 31431 P/N 3153135 ip1/ILpr-1 0113$. 00-X1a PIN 35,4 iLP Altr AD'3XR(LP PIN 316493234 P/N 3149335 IIP-2" DOLOO.301S P/N 3154502 ILP-Z'q A0-31 LP AD-3.XHILP PIN 315493234 PIN 3 151,093235 Ill-i 083S WN5093336 LIM-1 . P/N 31S-l1l235 MSl-Q/2J) - P/N 31S49Q3 MSI 1Ut/2DO PIN 315-693329 MSl-Me - P/N315-OL3E13 Tffl-96/B&D/RGR - P/N -O315 T11'86M - P/N 310$4547 '.S.THI.D,iHi-fi P/N 31543642 The FP-11/FPT-11 is only compatible with MXL-10 Rev. 6.0 or greater firmware. The ILP-2 is only compatible with MXL-IQ Rev. 3.0 or greater firmware. t When the CSG-M is configured, the DUCT application must be selected when the device is used in an sir duct housing or in a spot duct application. NOTICE: The use of other than Fire Safety detectors and bases with Fire Safety equipment will be considered a misapplication of Fire Safety equipment and as such void all warranties either expressed or implied with regard to loss, damage, liabilities and/or service problems. No end of line device is required. Both circuits are power limited to NFPA 70/NEC 760. Each detector, or group of detectors, requires a two wire circuit of minimum 18 AWG thermoplastic fixture wire. Total circuit resistance must not exceed 100 ohms. Maximum capacitance: 0.4uF, between loopi- and loop- 0.8uF, between loop+ and chassis 0.8uF, between loop- and chassis 7 T-tapping is not allowed on Style 6 loops. 8. See P/N 315-092772 for more information on wiring. SMB-2 AUX Power (TB5. 9-12) AUX power is available onTB5 terminals 9-12. All wiring must be in accordance with Article 760 of NEC or local building codes. Aux power is power limited to NFPA 70/NEC 760. Electrical Ratings: 18-31 VDC, 1A max. See P/N 315-092772 for more information on wiring. SMB-2 Notification Appliance Circuits (TB-5, 1-4 and TB5, 5-8) These notification appliance circuits are for alarm notification appliances only (NFPA 72). For Municipal Tie (NFPA 72, Chapter 4), Releasing (NFPA 13) or Leased Line (NFPA 72, Chapter 4), use model CSM-4 All wiring must be in accordance with Article 760 of NEC or local building codes. Both notification appliance circuits are power limited o NEPA 70/NEC 760. Electrical Ratings: Supervisory 18-31 VDC, 12mA max. Alarm . 18-31 VDC, 1.5A max. End of Line Device: Use Siemens Fire Safety EOL 2.2K, 1/2W, P/N 140-820380 .6.. Line Resistance: Not to exceed 3 ohms total. 7 See P/N 315-092772 for more information on wiring. Siemens Building Technologies Fire Safety Fire Safety Fire Safety 8 Fernwood Road 2 Kenview Boulevard Florham Park, NJ 07932 1/06 Brampton. Ontario Tel: (973) 593-2600 5M Canada L6T 5E4 FAX: (973) 593-6670 SFS-IG Tel: (905) 799-9937 Website: www.abt.siemens.com/fis Printed in U.S.A. FAX: (905) 799-9858 January2006 Supersedes sheet dated 6103 SIEMENS TRI Series Intelligent Initiating Devices Interface Modules for MXL Fire Detection Panels TRI-S,TRI-D,TRI-R ENGINEER AND ARCHITECT SPECIFICATIONS Interfaces and Supervises Normally Open Contacts Integral SPDT Relay (up to 4 amps) onTRl-R Model Dual Input onTRl-D Model 131 Fire Safety Multi-color L.E.D. indicates status (green, amber, red) Easy front access to programming port and wiring terminals Mounts in 4 inch square 21,4 deep box, or double gang box Dynamic Supervision Comes with 5x5 inch faceplate Two wire operation SensorLink Model FPI-32 Programs and Verifies Device's Address and Tests Device's functionality Electronic Address Programming is Easy and Dependable • cj UL Listed, ULC Listed CFSM, FM, NYMEA Approved Introduction The TRI Series Intelligent interface modules are designed to provide the means of interfacing direct shorting devices to the MXL system's ALD loop circuit. The TRI Series Intelligent interface modules provide the market's most advanced method of address programming and supervision, combined with sophis- ticated control panel communication. Each TRI Series interface module incorporates a microcomputer chip. The TRI Series microcomputer chip technology and its sophisticated bi-directional communication capabilities with the control panel, achieve the state of an "Intelli- gent Device." Description The TRI Series Intelligent interface modules are avail- able in three models. The TRI-S and TRI-R are designed to monitor a normally open dry contact. The interface module reports the contact's status to the control panel. The TRI-S model can only monitor and report the status of the contact, while the TRI-R incorporates an addressable Form C relay. The TRI-R relay and contact device input are controlled at the same address. For the MXL system, the relay and input contact can be controlled as a separate function. The relay is typically used where control or shunting of external equipment is required. The TRI-D is a dual input module and is designed to supervise and monitor two sets of dry contacts. This interface module requires two address settings. The TRI-D is ideal for monitoring a waterf low switch and its respective valve tamper switch. The TRI has a multi-color Light Emitting Diode that flashes green when operating normally, amber if unit CATALOG NUMBER 6179 is in trouble condition, and red to indicate a change of state. The TRI-D flashes twice, once for each address, the TRl-R red L.E.D. indicates a change of state in the relay. The device's microcomputer chip has the capacity of storing, in memory, identification information as well as important operating status information. SIEMENS Fire Safety's innovative technology allows all TRI Series intelligent interface modules to be programmed by using the SensorLink model F P1-32 Programmer/Tester. The F P1-32 Programmer/Tester is a compact, portable, menu driven accessory that makes programming and testing an interface device faster, easier and more dependable than previous methods. The F P1-32 eliminates the need for mechanical addressing mechanisms, such as program jumpers, DIP switches or rotary dials, because the FPI-32 electronically sets the TRI interface's address into the interface's microcomputer chip nonvolatile memory. Vibration, corrosion and other conditions that deterio- rate mechanical addressing mechanisms are no longer a cause for concern. The TRI Series is fitted with screw terminals for connection to an addressable circuit. The TRI Series is fully compatible on the same MXL circuit with all intelligent FP IL and ID-60 Series detectors, MSI Series addressable manual stations or any other addressable intelligent modules, such as the CZM or ICR All TRI Series intelligent interface modules are UL listed. Environmental operating conditions for all TRI Series modules are 32°F (°C) to 120°F (49°C) with a relative humidity of not greater than 93% non-condensating. Ordering Information Model Description Shipping Wt. Lb. Kg. TRI-S Single Input loz. 2 TRI-R Single Input w/Relay 7oz. 2 TRI-D Dual Input loz. 2 Mounting Data Addressable interface Model TRI-S, TRI-D, TRI-R mounts directly into a 4 inch square 21/4 deep box or a double gang box (user supplied). A 5 inch square off-white faceplate is included with each TRI. MOUNTING SLOTS FORA INCH SWltCHBOX TRI-S/-DI-R MODULE OUNTING )LES FOR VITCHPLATE MOUNTING SLOTS FOR DOUBLEGANG SWITCHEOX Figure A Mounting the TRI-S/-R/-D Siemens Building Technologies Fire Safety Fire Safety 8 Fernwood Road Florham Park, NJ 07932 Tel: (973) 593-2600 FAX: (973) 593-6670 Website: www.cerbpyro.com Fire Safety 2 Kenview Boulevard 4/02 Brampton. Ontario 10M Canada L6T 5E4 SFS-IG Tel: (905) 799-9937 Printed in U.S.A. FAX: (905) 799-9858 April 2002 Supersedes sheet dated 6lO1 CALIFORNIA DEPARTMENT OF FORESTRY & FIRE PROTECTION OFFICE OF THE STATE FIRE MARSHAL I FIRE ENGINEERING - BUILDING MATERIALS LISTING PROGRAM LISTING SERVICE LISTING No. 7165-0067:0144 EXISTING Page 1 of 2 CATEGORY: 7165-- FIRE ALARM CONTROL UNIT (COMMERCIAL) LISTEE: Siemens Industry, Inc. Building Technologies Division8 Fernwood Road, Florham Park, NJ 07932 Contact: Peter Pawchak (973) 593-2662 Fax (973) 593-6652 Email: Peter.pawchak©siemens.com DESIGN: Model MXL and MXL-IQ fire alarm control units. Coded or noncoded; local, auxiliary, remote and central station proprietary service; automatic, manual waterflow, releasing service and sprinkler supervisory service when used as a remote station (protected premise) unit or proprietary fire receiving unit. Refer to listee's data sheet for additional detailed product description and operational considerations. Basic components: *MMB..1 -2, -3; Main Control Board (For use with Model MXL only) *SMB..1 -2, -3; Main Control Board (For use with Model MXL-IQ only) *MKB..1 -2, -5; Keyboard/Annunciator Panel (For use with Model MXL only) *MKB..46; Keyboard/Annunciator Panel (For use with Model MXL-IQ only) MPS-6, -12; Power Supply CRM-4; Relay Module CSM-4; Signal Module CZM-4; Conventional Zone Module BTX-1, BP-61; Battery Set Module *MSE..2; Enclosure (For use with Model MXL only) MSE -3, -3M; Enclosure (For use with Model MXL-IQ only) MSE-3M-D; Enclosure Door Silent Knight 5128, 5129; Dialer/DACT (Listing No. 7300-0559:120) INSTALLATION: In accordance .with listee's printed installation instructions, applicable codes and ordinances and in a manner acceptable to the authority having jurisdiction. MARKING: Listee's name, model number, electrical rating, and UL label. APPROVAL: Listed as fire alarm control units for use with listee's listed Model VoiceCom system (CSFM Listing No. 6911-0067:173) and separately listed compatible initiating and indicating devices. See (CSFM Listing No. 7300-0067:172) for optional control unit accessories. Also suitable for high-rise applications. Refer to listee's Installation Instructions Manual for details. These control units can generate the distinctive three-pulse Temporal Pattern Fire Alarm Evacuation Signal as required per NFPA 72, 2002 Edition. This control unit meets the requirements of UL-864, 9th Edition Standard NOTE: 1. For Fire Alarm Verification Feature (Delay of fire alarm), the maximum *Rev. 04-03-13 gt This listing is based upon technical data submitted by the applicant. CSFM Fire Engineering staff has reviewed the test results and/or other data but does not make an independent verification of any claims. This listing is not an endorsement or recommendation of the item listed. This listing should not be used to verify correct ftV operational requirements or installation criteria. Refer to listee's data sheet, installation instructions and/or other Date Issued: July 01, 2015 Listing Expires June 30, 2016 Authorized By: JAMES PARSEGIAN, Program Coordinator Fire Engineering Division Listing No. 7165-0067:0144 Page 2 of 2 Retard/Reset/Restart period must be adjusted to 30 seconds or less. 2. Combined with 7170-0067:154 *Rev. 04-03-13 gt This listing is based upon technical data submitted by the applicant. CSFM Fire Engineering staff has reviewed the test results and/or other data but does not make an independent verification of any claims. This listing is not an endorsement or recommendation of the item listed. This listing should not be used to verify correct operational requirements or installation criteria. Refer to listee's data sheet, installation instructions and/or other Date Issued: July 01, 2015 Listing Expires June 30, 2016 Authorized By: JAMES PARSEGIAN, Program Coordinator Fire Engineering Division CALIFORNIA DEPARTMENT OF FORESTRY & FIRE PROTECTION OFFICE OF THE STATE FIRE MARSHAL FIRE ENGINEERING - BUILDING MATERIALS LISTING PROGRAM LISTING SERVICE LISTING No. 7300-0067:0146 . Page 1 of 1 CATEGORY: 7300— FIRE ALARM CONTROL UNITACCESSORIES/MISC. DEVICES LISTEE: Siemens Industry, Inc. Building Technologies Division8 Fernwood Road, Florham Park, NJ 07932 Contact: Peter Pawchak (973) 593-2662 Fax (973) 593-6652 Email: Peter. pawchak@siemens.com DESIGN: Models TRI-2, TRI-213, TRI-2R, TRI-60, TRI-601), TRI-60R, TRI-136, TRI-13613, TRI-136R, TRI-136M, TRI-D, TRI-R and TRI-S addressable modules and TRI-CB supervisory module. Refer to Iistee's data sheet for additional detailed product description and operational considerations. INSTALLATION: In accordance with listees printed installation instructions, applicable codes & ordinances and in a manner acceptable to the authority having jurisdiction. MARKING: Listee's name or Cerberus Pyrotronics, model number and UL label. APPROVAL: Listed as control unit accessories for use with Model XI-3 (CSFM Listing No. 7165-0067:104 and 7170-0067:151), Model MXL (CSFM Listing No. 7165-0067:144 and 7170-0067:154) or IXL (CSFM Listing No. 7165-0067:138 and 7170-0067:153) fire alarm control units. The TRI-CB module is designed for use with the TRI-2, TRI-21) and TRI-2R modules when interfaced with the INX module. *Rev. 10-26-2002 This listing is based upon technical data submitted by the applicant. CSFM Fire Engineering staff has reviewed !\ the test results and/or other data but does not make an independent verification of any claims. This listing is not 14 an endorsement or recommendation of the item listed. This listing should not be used to verify correct operational requirements or installation criteria. Refer to listee's data sheet, installation instructions and/or other Date Issued: July 01, 2015 Listing Expires June 30, 2016 Authorized By: JAMES PARSEGIAN, Program coordinator Fire Engineering Division 9/2016 Enclosure Integrity Test Report In compliance with NFPA 2001 (2012 Edition)Annex C Enclosure Integrity Procedure (using FSSA peak pressure equations) INSERT COMPANY LOGO Schmidt Fire Protection Co., Inc. Tested building: WEST INN & SUITES Tested enclosure: PBX SERVER ROOM Building Address: 4970 AVENIDA ENCINAS CARLSBAD, CA 92008 Performed for: Performed by: James Inahara Certification level 3 Test date: 2016-02-19 Associated Test file: C:\Documents and Settings\Scgh\My Documents\Retrotec\Tests\WEST INN FINAL.fxml Summary - PBX SERVER ROOM version:5.8.32 licensed to: Schmidt Fire Protection FanTestic Integrity Co., Inc. Test date: 2016-02-19 By: James Inahara Certification: 3 Location: 4970 AVENIDA ENCINAS CARLSBAD, CA 92008 Building: WEST INN & SUITES Witness: SCHMIDT FIRE PROTECTION 8582796122 Enclosure conditions prior to discharge Extinguishing agent details Net protected volume, V [cu ft] 1,140 Agent FM200 (NFPA) [HFC-227ea] Max flooded height, H. [ft] 10.0 Quantity [lb] 39.0 Required protected height, H [ft] 7.0 Type Halocarbon Design temp, I [°F] 70.0 Discharge time, [s] 10 Enclosure pressure limit, [Pa] 500 Mixing during hold time No Specified Hold Time, [mm] 10 Initial concentration, cl 7.0148% Elevation, [ft] .50 Design concentration, c 7.0% Minimum design humidity 30% Bias during Hold, Pbh [Pa] 0 Maximum design humidity 60% Test equipment Fan make/model Retrotec 3000SR Fan serial # PH000127 Fan calibration date 10/12 Gauge make/model DM-2 Gauge serial # 201406 Gauge calibration date 10/12 Hold time results Leakage exponent, In 0.639 Leakage constant, k1 [CFM/Pa] 13.50 Total Leakage Area, [sq in] 17 Predicted Hold Time, t [mm] 19.2 Hold Time compliance based on Annex C of NFPA 2001 (2012 Edition) Calculations predict that the enclosure will maintain the minimum concentration of 5.95%at the required protected height of 7.0ft for 19.2 minutes. The enclosure PASSES this acceptance procedure becausethis hold time is greater than the specified minimum of 10 minutes. Peak Pressure compliance using FSSA equations Calculations predict a maxim u m positivepea k pressure of 139 Pa. This pressure is less than the specified maximum enclosure pressure limit of 500 Pa, therefore the enclosure PASSES this part of the procedure Calculations predict a maximumnegative peak pressure of 310 Pa. This pressure is less than the specified maximum enclosure pressure limit of 500 Pa, therefore the enclosure PASSES this part of the procedure. Page 2 of 11 2/19/2016 C:\Documents and Settings\Scgh\My Documents\Retrotec\Reports\WEST INN FINAL [2016-02-19 1827].docx Assumptions and warnings While Fanlestic Integrity software may identify clean agent peak pressure and hold time risks, use of this software does not in any way guarantee the elimination of those risks. Enclosure Integrity (hold time) The enclosure was tested in compliance with NFPA 2001 (2012 Edition)Annex C Enclosure Integrity Procedure. These tests only address potential failures in maintaining extinguishing agent concentration due to excessive enclosure leakage. The following assumptions were made: The initialextinguishing agent concentration as indicated in the test report will be achieved. Ductwork connected to air-handling systems that are outside this enclosure will be either isolated with dampers or will be shut down during the hold time. If air handlers are used to provide continuous mixing, they will be dedicated to this enclosure and will not create significant flows across the 6nclosure boundaries. An adequate return path for the air flow was provided during the enclosure integrity door fan tests. All intentional openings will be sealed during the enclosure leakage for hold time tests. Design temperature inside the tested enclosure during discharge is 70.0°F. There are NO fans that continue running during the hold timeor heat sources that will produce enough air circulation to cause a 'continuous mixing' condition within the entire enclosure. All other non-integrity tests, as outlined in the NFPA standard, will be satisfactorily completed. Enclosure Integrity (peak pressure) Enclosure integrity tests and calculations were performed to determine that the enclosure has adequate venting to provide peak pressure relief as required by NFPA 2001 (2012 Edition)section 5. Calculations for peak pressure were performed using equations from the Fire Suppression Systems Association (FSSA) "Pressure Relief Vent Guide". The following assumptions were made: All intentional openings will be set to the operating condition expected during the agent discharge for positive peak pressure relief when enclosure leakage is tested for positive vent area. In addition, for halocarbons only, all intentional openings will be set to the operating condition expected during the agent discharge for negative peak pressure relief when enclosure leakage is tested for negative vent area. Adequate air flow was provided along a path leading to outdoors for the test fan but the doors surrounding the enclosure were set in the position that provide the lowest air flow required to establish the required test pressures. Design temperature inside the tested enclosure during discharge is 70.0°F. Relative humidity in the enclosure will range between 30% and 60%. Page 3ofll 2/19/2016 C:\Documents and Settings\Scgh\My Documents\Retrotec\Reports\WEST INN FINAL [2016-02-19 1827].docx Background Hold time prediction, Descending Interface Model This procedure predicts the hold time for the extinguishing agent/air interface to drop to the specified minimum protected height, based on the variables shown in this report. Due to the conservative assumptions regarding leakage distribution, this prediction model usually predicts a shorter retention time as compared to an actual discharge, but not always. This prediction only applies to conditions as found at the time of the test. Additional penetrations, weather, open doorways, HVAC modifications, malfunctions and the inherent assumptions in the enclosure integrity procedure could all combine to give very different results in a real discharge. Leakage area defined for hold time The Total Enclosure Leakage test measures all unintentional holes in the enclosure, the sub-floor and the above- ceiling space, whether or not extinguishing agent will leak out of these holes. All intentional openings (such as installed pressure relief vents) must be held in their closed positionbut not sealed.The measurement is performed over a range of pressures so that the exact leakage rate at lower pressures for agent loss will be known. The predicted hold time is worst case since it is assumed that half of the measured leakage is located in the ceiling and the other half is located in the floor. Leakage area defined for Peak Pressure Leakage for peak pressure does not depend on leak location, making the Total Enclosure Leakage test accurate for peak pressure prediction.All intentional openings (such as installed pressure relief vents) must held in the positions they are expected to be in during the positive peak pressure spike during discharge. For halocarbons, this test must be repeated where all intentional openings (such as installed pressure relief vents) must held in the positions they are expected to be in during the negative peak pressure spike during discharge. The measurement is performed over a range of induced test pressures so that the exact leakage rate at the higher reference pressure of 125 Pa for venting will be known. The predicted peak pressure will then be based on an enclosure leakage that accurately represents the free vent area faced by the agent discharge. Page 4 of 11 2/19/2016 C:\Documents and Settings\Scgh\My Documents\Retrotec\Reports\WEST INN FINAL [2016-02-19 1827).docx Discussion of Results - PBX SERVER ROOM Hold Time Compliance with Annex C of NFPA 2001 (2012 Edition) It is predicted that a Total Enclosure Leakage measurementof 17sq in maintains the minimum concentration of 5.95%at the minimum protected height of 7.0ft for 19.2 minutes. This hold time is greater than the specified minimum of 10 minutes, therefore the enclosure PASSES this acceptance procedure. It wasassumed that there was no 'continuous mixing' conditionduring the hold time. Predicted hold timewas therefore calculated based on a descending interface model. Peak Pressure Compliance with section 5 of NFPA 2001 (2012 Edition) 5.3.7: The protected enclosure shall have the structural strength and integrity necessary to contain the agent discharge. If the developed pressures present a threat to the structural strength of the enclosure, venting shall be provided to prevent excessive pressures. And that the following shall be submitted for approval to the authority having jurisdiction: 5.1.2.2 (10): maximum positive and the maximum negative pressure... expected to be developed upon the discharge of agent 5.1.2.2 (28): pressure relief vent area... to prevent development of a pressure difference across the enclosure boundary that exceeds a specified enclosure pressure limit. Calculations for peak pressure, based on leakage area of Enclosure Onlyat a standard reference condition of 125 Pa and using no pressure relief vent (PRy), determined: The enclosure would represent a free vent area during discharge of 25sq inwith the enclosure set up in the condition expected to occur during the positive pressure pulse caused by the agent discharge which is predicted to be139 Pa. This pressure is less than the specified maximum of 500 Pa, therefore the enclosure PASSES this part of the procedure The enclosure would represent a free vent area during discharge of 25sq in with the enclosure set up in the condition expected to occur during the negative pressure pulse caused by the agent discharge which is predicted to be310 Pa. This pressure is less than the specified maximum of 500 Pa, therefore the enclosure PASSES this part of the procedure. Vents should be installed high in the enclosure so that mostly air is exhausted, instead of the heavier extinguishing agent. Additionally, the vents should be rated to fully open between 80-130 Pa. Once a vent is installed or it is decided to use leakage of the enclosure only to relieve pressures during discharge, the chosen venting situation is used to calculate expected peak pressure, and the available free vent area must be enough to relieve this peak pressure in order to pass. All leakage areas are extrapolated to a standard reference condition of 125 Pa which is representative of conditions where most of the peak pressure will be relieved. Peak pressure calculation detail Using the leakage area of Enclosure Onlyand equations from the Fire Suppression Systems Association (FSSA) "Pressure Relief Vent Guide": At the highest humidity of 60%, a peak positive pressure of approximately 139 Pa would form. . At the lowest humidity of 30%, a peak negative pressure of approximately —310 Pa would form. Page of 11 2/19/2016 C:\Documents and Settings\Scgh\My Documents\Retrotec\Reports\WEST INN FINAL [2016-02-19 1827].docx Free vent area required calculation detail Assuming an Enclosure Pressure limit of ±500 Pa, this enclosure requires a total vent free area of 5sq in in the positive direction and 17sq in in the negative direction to maintain the enclosure's structural integrity. Free vent area available calculation detail The leakage area during discharge will be: 25sq in for the Enclosure Only with the enclosure set up in its Positive Discharge Period Condition, where any dampers or installed PRV were fixed in the position they would assume under +125 Pa. 25sq in for the Enclosure Only with the enclosure set up in its Negative Discharge Period Condition, where any dampers or installed PRV were fixed in the position they would assume under -125 Pa. Additional PRY area required detail The Enclosure 0n1yprovides25sq in of positive venting area. Since this is more than the required total of 5sq in, this enclosure does not require any additional PRV areato maintain structural integrity and pass the peak pressure procedure in the positive direction. The Enclosure 0n1yprovides25sq in of negative venting area. Since this is more than the required total of 17sq in, this enclosure doesnot require any additional PRV areato maintain structural integrity and pass the peak pressure procedure in the negative direction. Test Data Appendix- PBX SERVER ROOM (add notes here) Enclosure Construction Data The maximum flooded heightused in the calculations isl0.0ft. The equipment was installed in the room, and the top of the rack was measured to be 7.Oft, so 7.0ft was taken as the minimum height for protection. Net protected volume used is 1,140cu ft. Building elevation used is Soft, and the elevation correction factor used in the calculations is 0.998. Total Enclosure Leakage test data Based on measured values, the enclosure alone has an equivalentleakage area of 17sq in at a reference pressure of lOPa. (add notes here) The following table represents the results from the enclosure integrity procedure carried out on the whole enclosure, with all intentional openings sealed. Test conditions Test date 2016-02-19 Inside temperature, 68 OF TO [OF Test time 12:04 Outside temperature, 68 OF TO [OF Operator location Inside Bias pressure, Pbt [Pa] 0.00 Pressurize Data Depressurize Data Induced pressure [Pa] 10.0 50.0 -10.0 -50.0 Fan Pressure [Pa] 19.8 134 II_ ,.. c 21.1 142 Page 6 of 11 2/19/2016 C:\Documents and Settings\Scgh\My Documents\Retrotec\Reports\WEST INN FINAL 12016-02-19 1827].docx Flow [CFM] 58 162 60 167 Total Flow rate [CFM] 57.6697 161.6636 59.8187 166.9151 Leakage exponent, n 0.640 0.638 Leakage characteristic, k1[CFM/Pa] 13.197 13.780 Leakage area at 10Pa[sq ml 16.96 17.59 Correlation, r 1.000 1.000 Hold Time DcercgIntfaEe HddUme ......HO ......H ....... 6--- 4--- 2--- o -1 O 1 2. 3 4 5 6 7 8 9 10 11 12 13 14 1 16 17 18 19 20 21 line (rnn) Page 7 of 11 2/19/2016 C:Documents and Settings\Scgh\My Documents\Retrotec\Reports\WEST INN FINAL [2016-02-19 1827].docx üissure øDepressurne Pressurize 1 3 .49 20 0.1 -s--- -20 -40 I . 0 1 2 Th vs?ded ure - prsue Pressurize 10 20 30 40 SO 60 70 80 90100 Induced pressure (Pa) Page 8 of 11 2/19/2016 C:\Documents and Settings\Scgh\My Documents\Retrotec\Reports\WEST INN FINAL [2016-02-19 1827].docx Venting data for Enclosure Only There was no PRV installed for pressure relief so the Total Enclosure Leakage measured was extrapolated to the reference pressure of 125 Pa and used in further calculations as the only available leakage for peak pressure relief. In the case where the leakage area of the PRV only was to be used for pressure relief, but leakage area for enclosure and vent was entered as the venting area dataset, to determine leakage area for pressure relief by PRV alone, the leakage of the enclosure would have been subtracted from the leakage of the venting dataset. In the case where the leakage area of the enclosure and PRV was to be used for pressure relief, but leakage area for vent only was entered as the venting area dataset, to determine leakage area for pressure relief by the enclosure and PRV, the leakage of the enclosure would have been added to the leakage of the venting dataset. Positive direction data The positive free vent area provided by the Enclosure Only is 25sq in, for the enclosure set up in its Positive Discharge Period Condition, withall dampers or installed PRV fixed in the position they would assume under +125 Pa. The leakage of the Enclosure Only in the positive direction was obtained bymeasuring, and this leakage was manipulated as necessary to determine the leakage area of the Enclosure Only required for positive pressure relief. Negative direction data The negative free vent area provided by the Enclosure Only is 25sq in, for the enclosure set up in its Negative Discharge Period Condition, with all dampers or installed PRV fixed in the position they would assume under - 125 Pa. The leakage of the Enclosure Only in the negative direction was obtained by measuring, and this leakage was manipulated as necessary to determine the leakage area of the Enclosure Only required for negative pressure relief. Peak Pressure data Peak pressure was calculated using the leakage of the Enclosure Onlyand equations from the Fire Suppression Systems Association (FSSA) "Pressure Relief Vent Guide". FSSA equations depend on experimentally derived curves for peak pressure based on a Leak to Volume ratio for the enclosure. I Design details - 7 Enclosure pressure limit, [Pa]: 500 Discharge time, [s]: 10 Pressure relief vent type: no pressure relief vent (PRV) Peak Pressure relief using: - Enclosure Only Peak Positive Pressure Peak positive pressure, [Pa] 139 Leak to volume ratio, LVRPOS [sq in/cu 21.5 ft] Venting summary - Positive Direction Minimum required leakage, [sq in] 5 Venting area used, [sq in], 25 (describesEnclosure Only) [Additional PRV area needed, [sq in] 0 Page 9 of 11 2/19/2016 C:\Documents and Settings\Scgh\My Documents\Retrotec\Reports\WEST INN FINAL [2016-02-19 1827].docx Peak Negative Pressure Peak negative pressure, [Pa] 310 Leak to volume ratio, LVRneg [sq in/cu 21.5 ft] Venting summary -..Negative Direction Minimum required leakage, [sq in] 17 Venting area used, [sq in], (describes Enclosure Only) 25 Additional PRV area needed, [sq in] 0 Page 10 of 11 2/19/2016 C:\Documents and Settings\Scgh\My DocumentsRetrotec\Reports\WEST INN FINAL [2016-02-19 18271.docx Test Equipment The following test equipment was used in the performance of the enclosure integrity tests. Fan Fan serial Fan location Gauge Gauge Gauge Calibration serial #1 Retrotec 3000SR PH000127 DM-2 201406 10/12 Fan Calibration Certificate Retrotec 3000SR: Retrotec 3000SRPH000127Fan last calibrated: 10/12 (Flow Equation Parameters - Bi) .Published Flow Equation Parameters, Round B1CFM Range n K Ki K2 K3 K4 MF Open(22) 0.5214 519.6183 -0.07 0.8 -0.115 1 8.6 A 0.503 264.9959 -0.075 1 0 1 12 B 0.5 174.8824 0 0.3 0 1 10 C8 0.5 78.5 -0.02 0.5 0.016 1 10 C6 0.505 61.3 0.054 0.5 0.004 1 10 .C4 0.5077 42 0.009 0.5 0.0009 1 10 C2 0.52 22 0.11 0.5 -0.001 1 10 Ci 0.541 11.9239 0.13 0.4 -0.0014 1 10 14 0.48 4.0995 0.003 1 0.0004 1 10 12 0.502 2.0678 0 0.5 0.0001 1 10 Li 0.4925 1.1614 0.1 0.5 0.0001 1 10 Fan Pressure (FP) is the measured fan pressure when using a self-referenced fan or when Room Pressure is negative. If using a fan which is not self-referenced, and Room Pressure is positive, Fan Pressure is calculated by subtracting the measured Room Pressure from the Absolute Value of the Fan Pressure. If PrA>0 and fan is not self-referencing: FP = I PrB I -PrA If PrA<0 or fan is self-referencing: FP = PrB Flow calculations are not valid if Fan Pressure is less than either MF or (K2 x ICR I). Flow in CFM using the flow equation parametersshown above is calculated as follows for standard Ranges: flow= (FP-CRxK1) x (K+K3xFP)xK4 FP = fan pressure, CR = corrected room pressure Page ii of ii 2/19/2016 C:\Documents and Settings\Scgh\My Documents\Retrotec\Reports\WEST INN FINAL [2016-02-19 1827].docx