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Report (2) ,c S2o/9-oo(sy gevo ufisif sQge OSID by Xtralis OSID Product Guide 4.2.6 DIP Switch Settings Sw10-1 10 - 1 - z (Switch 1,2) I Fire Alarm — 00=Not configured 2 Im Thresholds _10=Low,01=Medium.11=High 3 I= — (Switch 3,4,5) Number of 000=Not Configured 4 pm I EtnfiterY 100=1,010=2,110=3,001=4 5 I_ _ 101=5,011=6,111=7 e = -La l� I ]Alarm Latching 191=LatcNonhingtching 7 I= I ]Dust Rejection 0=Disabledbled 1=Fsa 8 0 ] Industrial Mode ODisabled 1=Always Enabled 9 I— 1 ] Enhanced Mode 0=Disabled 1=Enabled 1e I— 1 ] Industrial Mode {0=Disabled Trigger L 1=Enabled in conjunction with activated Reset Input. (ela if Switch 8 is sotto On) Figure 4-7: DIP Switch Table 4-1: DIP Switch Configuration Settings Function Switch Positions Description A.Fire Alarm Thresholds 00 Not Configured(Trouble/Fault signaled) (Switch no.1 &2) 10 Low(highest sensitivity) 01 Medium(medium sensitivity) 11 High(lowest sensitivity) B.Number of Emitters 000 Not Configured(Trouble/Fault signaled) (Switch no.3,4&5) 100 1 Emitter present 010 2 Emitters present 110 3 Emitters present 001 4 Emitters present 101 5 Emitters present 011 6 Emitters present 111 7 Emitters present C.Alarm Latching 0 Non-latching (Switch no.6) 1 Latching D.Dust Rejection 0 Disabled (Switch no.7) 1 Enabled(Increased tolerance to dust events resulting in fewer Faults signaled) E.Enhanced Mode 0 Disabled(EN54-12 Approved 6dB Alarm enabled) (Switch no.9) For UL 268 Approved units,leave on 0.The UL version is permanently in Enhanced Mode. 1 Enabled(Not EN54-12 approved.Object intrusion producing 6dB attenuation gives a Fault instead of Alarm) F.Industrial Mode 0 Disabled (Switch no.8) 1 Always Enabled(Provides Increased tolerance to condensation,water vapors and dust events.) G.Industrial Mode Trigger 0 Disabled (Switch no.10) 1 Trigger(Reset input acts as a switch for enabling the Industrial Mode.When 24V applied to the Reset Input, there is increased tolerance to condensation,water vapors and dust events.) www.xtralis.com 21 OSID Product Guide OSID by Xtralis Industrial Mode The Industrial functionality can be obtained by upgrading the Imager to firmware version V5 and selecting the Industrial Operation by DIP switch 8. The Industrial Mode and Sensitivity setting are non-approved settings that can be used in challenging environments where extreme dusts,steam levels etc.can temporarily cause unwanted alarms.When setting DIP switch 8 to Industrial Mode the sensitivity of both the Al (flaming)and A2(smouldering)alarm channels are set to a 65%obscuration level. When the industrial mode is selected with DIP switch 8, it can be set permanently or toggled by the Reset switch if DIP switch 10 is set to 1. Refer to Section 4.2.7 for further information. If DIP switch 10 is set to`Trigger'without having DIP switch 8 set to Industrial Mode and/or DIP switch 6 is set to latching,OSID will generate the fault"Incorrect DIP switch configuration". It is preferred that the Industrial Mode is used through the Reset input and only for the time a high level event is anticipated.The input can be triggered by a key switch,timer,intrusion panel Day/Night setting.The permanent setting,should only be used if a manual reset of the alarm is mandatory and hence the toggle function is not available. The Industrial Mode should only be used with the written approval of the AHJ or auditing agency, Insurance Company, Fire Brigade and end-user. A standard beam smoke test,conform to the local installation rules,should be successfully performed for every Imager that has been set to Industrial Mode. Note: When selecting the Industrial Mode,the installer must obliterate the NF and CE logos as well as all other certification logos and numbers from other bodies where the 65%alarm levels are not certified. 22 www.xtralis.com OSID by Xtralis OSID Product Guide 4.2.7 External Reset / Industrial Mode Trigger The physical external reset input has two functions depending on the setting of Switch 10. Reset functionality This mode is selected when the Switch 10 is set to O. The RESET terminals enable an external signal to unlatch the system Alarms. This function is required when the dip switch n°6 at the imager is set to'Latching'. The system is unlatched on a rising or falling edge voltage of 5 to 32 VDC.The rise or fall time at the terminal has to be for a period of at least 350ms or more. The system alarm relay and LED are also unlatched when there is a power loss to the Imager of greater than 5 seconds.At this time the imager will perform a re-initialization sequence of several minutes. During the re-initialization sequence,the fault relay will be activated. The system also resets when there is a power loss to the Imager. Industrial Mode Trigger This toggle mode is selected when the Switch 10 is set to 1 and Industrial Operation is selected through dipswitch 8. The reduced sensitivity in the Imagerwill run for as long as the input is activated, meaning as long as a voltage of 5 to 32 VDC is applied to the input contact. When the voltage is removed,the sensitivity will return to the approved mode threshold values set by Fire Alarm Thresholds(Switch no. 1 &2). Cr) Q Legend 1 External reset input m n+ + r 2 Activate Industrial Mode rn J L J O Figure 4-8: Connection for externally resetting the system. 4.2.8 Fault and Fire Relay Terminals Fault(Trouble)and Fire(Alarm)relays are provided on the Termination Card. The FAULT relay is energized during normal operation while the FIRE relay is only energized when a Fire is detected.The operation of the relays are summarized in the following table: Table 4-2: Fault and Fire Relay Operation FAULT Relay FIRE Relay Normal Operation Fault Normal Operation Fire (Energized) (De-energized) NC 0 NC NC NC i 0 C c C A C C NO ' O NO I 0 NO I 0 m NO I Q Four-wire Detector Connections The Termination Card provides FIRE and FAULT relay terminals for the Initiating Device Circuit(IDC)wiring, and POWER terminals for external power supply connections. www.xtralis.com 23 OSID Product Guide OSID by Xtralis Some typical wiring connections for the detector can be seen in the following diagrams. The specifications of the End-Of-Line-Device(EOLD)and series resistor for the FIRE relay connection will vary according to the fire panel to which the detectors are connected. Note: For all relay connections,break wire run to allow monitoring. (A) Legend Loop/IDC and Power ---f' NO Connections from Fire Alarm ® NC Control Panel(FACP)or previous detector o NO 0 2 Loop/IDC Connections to next detector,EOLD or return path RESET O back to the FACP �i JJ . 3 Power Connections to next POWER detector - t� 4 Series Fire relay resistor POWER O - 5 Reset signal to next/Industrial Mode to next FAULT NO C NO Schematic Symbols (B) Fine O — Internal connections Installer wiring connections I 0 Terminal point POWER• POWER• "o— Resistor �— 0 O ► ]O POWER- POWER- 0 Figure 4A: Four-wire connections with Fault(Trouble)relay terminals connected in series between detectors. (A)shows the connections required for wiring the terminal blocks, (B)shows a schematic representation of the wiring. The IDC in Figure 4-9 can be connected to the next detector,an EOLD,or may be returned back to the fire alarm control panel(if supported). An IDC that is looped back provides a redundant connection to ensure that all devices have an alternate path for communications(for example,when a device fault relay is activated). 24 www.xtralis.com OSID byXtralis OSID Product Guide The next wiring diagram demonstrates a way of connecting the system so that the activation of a fault relay will not interfere with the communications of any other device on the IDC. (A) 0 NC ��,e NC ...�...� a NC .-�¢.'r F. LL , f.. i ® NO 0 NO 0Li, ® NC ! N ® NO 0 �'� 0 LOOP 0 u ® C u_ 0 C -__ '" 0 CFSET ® ___ ' ESETn nn n + POWER ® POWER ® POWER 4j POWER RESET O PoWER POWER POWER VOLT46E O ®- ® �__ ® - , I O ID (B) 1 NO -.O — NO-_.vC NO C FAULT I FAULT I FAULT •C be be \s t FIRE \ FIRE FIRE N 0 NO O © NO NO $ $ — _ r POWER+ POWER POKER+ POWER+ POWER+ POWER+ 0 0 ♦ 0 --- 0 0 POWER- POWER- PCMER- POWER- POWER- POWER- RESET VOLTAGE 0 (13 Schematic Symbols -" Internal connections 0 Terminal point — Installer wiring connections — — Resistor Legend 1 Fire Alarm Control Panel 3 Series Resistor 5 Reset Voltage/Industrial Mode 2 Detectors 4 EOLD:End of Line Device Figure 4-10: Wiring Diagram with Fault(Trouble) relay terminals connected in parallel to main IDC. (A)shows terminal block wiring, (B)shows a schematic representation of the wiring. www.xtralis.com 25 OSID Product Guide OSID by Xtralis Analog Addressable Input Module Connection An example for wiring analog addressable input modules may be found in the following diagram. • INPUT• 111111111EI ri O 0 m 0 INPUT• LLI 0 • - // RESET /i • VOLTAGE • • • • RESET � •INDUSTRIAL / MODE LOOP • / -MIMS . PdAER LOOP+• - • AUX+0 O / Nc INPUT• �I / • fj N W • - INPUT • ry NO • RESET 0 0 • • RESET . VOLTAGE + i . • INDUSTRIAL MODE POWER • pPOKER Legend 1 Fire Alarm Control Panel 3 Detectors 2 Analog addressable input modules 4 Reset Voltage/Industrial Mode Figure 4-11: Wiring diagram for connecting analog addressable input modules Relay configurations for NO or NC contacts should be made according to the control panel manufacturers specifications. Power for the detector may be taken from the loop(I DC)if the panel is approved for use with the OS I D system. If not,then power should be taken from an external power source or from the Auxiliary power output from the control panel. Refer to the control panel's specifications before using the Auxiliary power output. Remote Indicator A Remote Indicator can also be connected to the detector via the+and-pins on the FIRE LED interface. MI m 11• '.v r si _ Figure 4-12: Example wiring for a Remote Indicator The LED output is suitable for direct connection to a RED LED and will supply 17mA nominal. 26 www.xtralis.com OSID by Xtralis OSID Product Guide Heater An internal heater rated at 400mW for a nominal voltage of 24 VDC is provided to prevent condensation in the detector optics.To power the heater,a 24 VDC external power supply may be connected to the HEATER terminals.These pins are not polarity sensitive. 0 0 Legend 1 Internal Heater B '*-� 2 24 VDC External Power Supply 7,7 Figure 4-13: Example wiring for Internal Heater 4.2.9 Emitter Wiring Connections This section describes the wiring for the Termination Card in Emitters that are powered by an external power supply.The battery-powered Emitter component does not require connections to any other device. Caution: Ensure that all wiring is in compliance with all applicable local codes and standards. Representations of the Termination Card and wiringfor the Emitter are shown in the following diagrams. V 0 +Vin -Vin 0 +Vout 0 -Vout 0 \O 0 Figure 4-14: Termination Card for the Emitter O k 111 : ...0.1. _FS n r Legend 1 Fire alarm control panel or approved power supply 2 Detector Figure 4-15: Wiring diagram for externally powered Emitters Power can be taken from an external power source or from the Auxiliary power output of the control panel. Refer to the control panel's specifications before using the Auxiliary power output. www.xtralis.com 27 OSID Product Guide OSID byXtralis 4.2.10 Re-secure the Front Cover After the wiring has been completed, re-secure the front cover to the rear assembly by engaging the left-hand straight edge(1)and then engaging the curved edge(2). 1 ems•\, Is ` i ,,----------) , II �` 2 Figure 4-16: Re-attach the Front Cover of the unit 28 www.xtralis.com OSID by Xtralis OSID Product Guide 4.2.11 Coarse Alignment Once the Imager and Emitter units have been mounted,the optical spheres must be manually adjusted to align the Emitter and Imager within the coarse limits shown in the following diagrams, Legend 1 Emitter 0 2 Imager Figure 4-17: Alignment guidelines for 10° Imager to Emitter Note: Emitter alignment follows the same guidelines as 10°Imager alignment.The Emitter must be positioned with the Laser Alignment Tool to within D/120 of the Imager,where D in Figure 4-17 is the distance between the Emitter and Imager. Legend 1 Emitter (150 2 Imager 19/ 38 ( f4 ,i., 0 Figure 4-18: Alignment guidelines for the 45° Imager to Emitter www.xtralis.com 29 OSID Product Guide OSID by Xtralis Legend 63/ 1 Emitters JJJ 2 Imager 48°/ / Q 48` 1011 Figure 4-19: Alignment guidelines for the 90° Imager to Emitter Manual alignment of the system is easily achieved by using the OSID Laser Alignment Tool.The alignment tool can be ordered from Xtralis.To align the Emitter to the Imager using the laser alignment tool, please follow these steps: Warning: The laser alignment tool incorporates a 635-655 nm laser with an average power less than 5 mW. Avoid exposure from the laser radiation emitted by the alignment tool. Caution: Do not rotate the laser alignment tool beyond 1/4 turn as excessive force may cause internal damage. Emitter or 10° Imager Alignment 1. Switch ON and insert the laser alignment tool(1)into the 'ter alignment hole(2). 4caT 3 Co» 2. Use the laser tool to move the optical sphere(3)until the f(/ d laser beam is pointing towards an area within the (( specified limits as shown in Figure 4-17. 3. Rotate the tool 90°clockwise to lock the sphere into place.A STOP position will be felt when locked.This will also activate the Emitter. 4. After locking the Emitter/Imager, confirm the alignment. 5. Remove and switch OFF the laser tool. 2 Figure 4-20: 45° Imager or 90° Imager Alignment 1. Switch ON and insert the appropriate laser alignment tool(1)into the alignment hole(2). n� _\ 3 2. Use the laser tool to move the optical sphere(3)until the • laser beam is pointing at a position in the gravitational of center of all Emitters in the system as shown in Figure 4-18 and Figure 4-19. 1 U The OSID Positioning Assistant tool will help to determine the gravitational centre. 3. Rotate the tool 90°clockwise to lock the sphere into place.A STOP position will be felt when locked. 2 •° 4. After locking the Imager,confirm the alignment. Figure 4-21: 5. Remove and switch OFF the laser tool. 30 www.xtralis.com OSID by Xtralis OSID Product Guide 5 Commissioning and Maintenance 5.1 Starting Up After installing the detector, it is necessary to initiate Training Mode to allow the system to learn the locations of the Emitters and specific characteristics of the installation. Follow these steps to initiate Training Mode: 1. Ensure that all Emitters are activated. Battery-powered Emitters are activated automatically by locking the optical sphere in place,while externally powered Emitters activate after locking-in and powering the unit as described in Section 4.2.11. 2. Apply power to the Imager to initiate Training Mode. 3. After powering-up the Imager,the Imager automatically searches for Emitters in its field of view to record their position and timing. During this time the Trouble LED on the Imager will indicate that the detector is in Training Mode.Training Mode takes a maximum of 10 minutes before the detector either enters normal operation or reports a Trouble(Fault). 4. From Imager units with firmware version 4 or greater,aftera successful system commissioning,the Imager will retain the location of the Emitter(s). From Imager units with firmware version 5 or greater, aftera successful system commissioning,the Imager will retain the reference levels.A partial commission of power cycling will not clear the location of the Emitter(s)or the reference level. In order to clear the stored Emitter locations and the reference levels, DIP switches 3,4 and 5 should be set to 0 for a period exceeding 10 seconds,while the Imager is powered.During this period,the Imager will flash the yellow Fault LED rapidly.To commence a new System commissioning,set DIP switches 3,4 and 5 to a valid setting.After period of 10 seconds,where the front cover can be re-attached,the Imager will commence commissioning. 5. If OSI D is used in an environment where there may be substantial levels of background attenuation,the system should be commissioned when there is minimal attenuation,such as during night time or weekends where there is little activity at the site.This will ensure the system commissions the correct power levels and operates as intended. Note: After a power failure to the system(lasting 10 seconds or more),the system will re-initiate Training Mode. During power-up,the Fire relay will be in the non-fire states;and the Fault relay will indicate fault until commissioning has successfully completed. For Imager units with firmware version 5 or greater,a power failure will not clear the reference levels. Instead,a full commissioning is required to clear the reference levels. 5.2 Acceptance Testing After start up,the sensitivity of the detector should be tested using a calibrated method such as a smoke test, or inserting a special optical filter into the beam path(s).This filter can be ordered from Xtralis.Testing can be done by putting the filter in front of the imager or in front of the emitter(s). Putting the filter in front of the imager is the fastest way and a double blink indicates that all Emitters are in Alarm. Applying the filter in front of each emitter in a multi-emitter system will, particularly at initial start-up,guarantee that all emitters are aligned with their proper imager. Prior to testing,ensure that the detector is isolated and the proper fire authorities and building maintenance personnel are notified. Components that do not pass the sensitivity tests should be cleaned or replaced. Refer to Section 5.3 for preventative maintenance instructions. Note: The OSID system will not respond to test smoke from aerosol cans nor to filters supplied with traditional third party beam detectors,as it recognizes that these are not real smoke. www.xtra l is.com 31 OSID Product Guide OSID by Xtralis 5.3 Maintenance Although the OSI D detector is highly tolerant to dust and dirt,a regular schedule of maintenance should be implemented to ensure the best possible detector performance.Visual inspection and maintenance testing similar to the sensitivity test performed during the commissioning process should be performed yearly or in accordance to local codes and standards or as indicated by the Contamination fault in Table 2-1. Preventative maintenance simply includes wiping optical surfaces using a damp lint-free cloth.Make sure that during the cleaning of the detector its alignment remains unchanged. If the alignment was changed,it is advised that Training Mode is re-initiated.Training Mode may be initiated by powering down the Imagerfor 10 seconds or more,then powering up to re-initiate system alignment. The only serviceable part in the OSID detector is the alkaline battery,which can be replaced. Refer to Section 7.3 for instructions on replacing the alkaline battery. 5.4 Troubleshooting Imagers with firmware version 4.00.03 or greater have an internal onboard event log.Connecting the OSID Diagnostic Tool, refer to Section 7.6,will allow this event log to be downloaded for further Alarm and Fault analysis and troubleshooting. 32 www.xtralis.com OSID by Xtralis OSID Product Guide 6 Emitter Replacement and Addition After the system has been installed it may be necessary to replace or add another Emitter into the system. For replacing or adding an Emitter,please follow these steps: 1. Select an appropriate position for the Emitter,ensuring that the position complies with the guidelines (Section 4.1). 2. Mount the Emitter in the appropriate position either by using supplied mounting brackets(Section 4.2.2) or direct surface mounting(Section 4.2.3). 3. Wire the Emitter(if required)as shown in Section 4.2.9. 4. Manually align the Emitter to the Imager within the guidelines shown in Section 4.2.11. 5. If extra Emitters are being added to the system,the number of Emitters must be configured via the DIP switch located on the Imager(Section 4.2.5). In order to clear stored Emitter locations from the Imager,a full commission is required.Set DIP switches 3,4 and 5 to 0 for a period exceeding 10 seconds. During this period,the Imager will flash the yellow Fault LED rapidly.To commence a new system commissioning,set DIP switches 3,4 and 5 to represent the new number of Emitters in the system. 6. Initiate Training Mode as described in Section 5.3. 7. Perform sensitivity tests as described in Section 5.2 to ensure the correct functioning of the detector. www.xtra lis.com 33 OSID Product Guide OSID byXtralis This page is intentionally left blank. 34 www.xtralis.com OSID by Xtralis OSID Product Guide 7 Installation Kit The OSID Installation Kit(OSID-INST)is used in commissioning and maintaining the correct operation of the OSID Smoke Detector. The kit contains the following items: . OSID Installation and Maintenance Manual . OSID commissioning aid(reflector) . Blu-Tack adhesive ▪ OSID smoke simulating test filter . OSID cleaning cloth • OSID serial PC interface cable • OSID laser alignment tool,with three LR44 button cell batteries pre-installed The following sections describe how to use each component in this kit. 7.1 Use of Commissioning Reflector When the OSID system is installed over very large distances and in brightly lit areas,it may be difficult to see the output laser from the OSID Laser Alignment Tool when commissioning the system.To aid in the alignment of the Imager and Emitter,the Commissioning Aid(reflector)is provided.The reflector should be attached to the opposing unit that is not being aligned. For example,if the Emitter is being aligned,the reflector should be attached to the front cover of the Imager. Returning light to the user,off the reflector,from the laser alignment tool will be brighter and make it easier to determine if the unit being commissioned has been aligned correctly. To attach the reflector to a unit,use a suitable amount of Blu-Tack adhesive. Insert two pieces of the adhesive through the two holes in the reflector such that the adhesive material becomes rivet shaped on both sides. Press the reflectorfirmly onto the unit as shown in Figure 7-1. I trot ram..---•' • • Figure 7-1: Attachment of reflector onto OSID unit Note: A string can be connected to the reflector via the hole at the bottom so that once commissioning is completed,the reflector can be removed from the ground by pulling on the string attached to the reflector. Refer to Section 4.2.11 for further information. www.xtralis.com 35 OSID Product Guide OSID by Xtralis 7.2 Changing Laser Alignment Tool Batteries When the laser alignment tool is switched onto be used and no light source is emitted,the batteries need to be replaced.The OSID Laser Alignment Tool uses three LR44 button cell batteries. To change the batteries, unscrew the front half of the tool(1)from the back part of the alignment tool.Take out the three existing batteries and insert the new batteries,with the positive(+)battery terminal facing out of the laser tube.When the new batteries have been inserted, screw the two halves of the tool back together. Legend \` 1 Front part of alignment tool �,.. 1 2 Switch part of alignment tool 2 "-- --- 0 Figure 7-2: Laser Alignment Tool Notes: • Used batteries should be disposed of according to local codes and standards. ▪ Ensure that the laser alignment tool is left switched off when not in use.A piece of adhesive tape over the switch in the off position will ensure it does not switch on inadvertently. 7.3 Removing OSID Emitter Battery The OSID Battery Emitter(OSE-SP-01, OSE-HP-01)contains an alkaline battery pack.When the battery has been drained and the Emitter is no longer functioning,the battery must be removed from the Emitter and disposed of according to local codes and standards. To remove the batteries,first take the front cover off the Emitter using a flat blade screwdriver as shown in Figure 7-3. Ali ! J Figure 7-3: Remove front cover from Emitter Unplug the battery from the power connector. Detach the Velcro retaining strap and remove the battery pack. Insert new battery pack(OSE-RBA), plug back into the power connector and reattach the Velcro retaining strap. Notes: ▪ Do not attempt to open or service batteries. ▪ Do not dispose of the battery along with general waste.Contact your local waster disposal agency for the address of the nearest battery deposit site. 36 www.xtralis.com OSID by Xtralis OSID Product Guide 7.4 Use of Commissioning Test Filter After the OSID system has completed Training Mode,acceptance testing is initiated by simulating a smoke condition to the system and verifying that an Alarm is initiated.The use of an OSID Smoke Simulating Test Filter is the preferred method of conducting the Acceptance Test. Testing can be done by placing the filter in front of the Imager or in front of the Emitter(s). Placing the filter in front of the Imager is the fastest way.A double blink indicates that all Emitters are in Alarm.Applying the filter in front of each Emitter in a multi-emitter system will,particularly at initial start-up, guarantee that all Emitters are aligned with their proper Imager. Keep the filter in place(up to 40s)until an Alarm has been generated by the OSID Imager.When an Alarm has been generated, remove the filter from the beam path and wait for the Imager to indicate a Normal functioning system before testing the next Emitter/Imager in the system. Note: Prior to Acceptance Testing,the OSI D detector should be Isolated to prevent false alarms from being signaled to the fire authorities and building maintenance personnel. Refer to Section 5.2 for more information. 7.5 Maintenance Cleaning Regular maintenance on the OSID detector should be performed yearly or in accordance to local codes and standards or as indicated by the Contamination Fault.Dampen the OSID Cleaning Cloth and wipe the optical surface thoroughly, removing all dust and contaminants,leaving a visibly clean surface. Ensure that during the cleaning of the detector,its alignment remains unchanged. If the alignment was changed,it is advised that Training Mode is re-initiated.Training Mode may be initiated by powering down the Imager for 10 seconds or more,then powering up to re-initiate system alignment. Note: Prior to cleaning,the OSID detector should be Isolated or de-energised to prevent false alarms or faults from being signalled to the fire authorities and building maintenance personnel. Refer to Section 5.3 for more information. www.xtralis.com 37 OSID Product Guide OSID by Xtralis 7.6 Using OSID USB FTDI Cable and OSID Diagnostic Tool Software The OSID Serial PC Interface Cable can be used to aid with commissioning of the OSID system during Training Mode, and to diagnose any subsequent Faults in the system. The Interface Cable is connected to the Imager via the jack plug socket on the underside of the Imager.The USB connector end of the cable is connected to a computer's USB port. Replace the nylon plug after the FTDI cable is removed. Notes: • If the cable(1.5 m)is of insufficient length,up to two 10m active USB 2.0 extension cables can be used to extend the length. . The cable is used in conjunction with the OSID commissioning software called OSID Diagnostic Tool. • Before connecting the OSID Serial PC Interface Cable to a computer,the USB FTDI drivers should be installed.These drivers and OSID Diagnostic Tool software can be obtained from the Xtralis website, along with software installation instructions. Refer to Section 5.1 for further information. 38 www.xtraIis.com OSID by Xtralis OSID Product Guide A Drilling Dimensions A.1 Imager Mounting Bracket Drilling Dimensions 0 136 mm (5.24") I I I 0 Figure A-1: Imager Mounting Bracket Drilling Dimension Note: Not to scale. www.xtralis.com 39 OSID Product Guide OSID by Xtralis A.2 Imager Rear Assembly Drilling Dimensions 104 mm (4.09") 0 0 0 I— io E E co co 94 mm(3.70") Figure A-2: Imager Rear Assembly Drilling Template Note: Not to scale. 40 www.xtralis.com OSID by Xtralis OSID Product Guide B Geometric Calculations This section is intended to provide estimates for horizontal width and vertical height measurements for the fields of view of each type of Imager. The values listed in this section are based upon simple rectangular room geometries,with fields of view aligned along the horizontal plane. Horizontal and vertical planes are oriented with respect to the Imager. �1� v Legend �' k�� H Horizontal plane V Vertical Plane \ Y$ H s Figure B-1: Horizontal and vertical planes with respect to the Imager B.1 10° Imager Notes: ▪ The minimum distance between the 10°Imager and Emitter(D)is 30 meters(98.4 ft). ▪ Refer to the figure below for information on 10°Imager geometric calculation. Legend 1 Emitter 0 i ��'- i 2 Imager p, ^. D Distance between Imager and t1 Emitter �d 1 `F ; j Figure B-2: 10° Imager Alignment Note: Emitter alignment follows the same guidelines as 10°Imager alignment.The Emitter must be positioned with the laser Alignment Tool to within D/120 of the Imager,where D in Figure B-2 is the distance between the Emitter and Imager. www.xtralis.com 41 OSID Product Guide OSID by Xtralis B.2 45° Imager: 38° FOV B.2.1 Horizontal Plane Measurements - FOV Width Notes: ° The FOV widths listed on the table below are calculated using the equation:W= L x 0.781 Room Length(L)(m) FOV width(W)(m) A Standard Power Emitter �l 10 m(32.8 ft) 7.8 m(25.6 ft) 20 m(65.6 ft) 15.6 m(51.1 ft) 30 m(98.4 ft) 23.4 m(76.7 ft) 40m(131.1 ft) 31.3 m(102.6 ft) 50 m(163.9 ft) 39.1 m(128.2 ft) ,I W 60 m(196.7 ft) 46.9 m(153.8 ft) High Power Emitter* 70 m(229.5 ft) 54.7 m(179.3 ft) 80 m(262.3 ft) 62.5 m(204.9 ft) 61 co 90 m(295.1 ft) 70.3 m(230.5 ft) y se° 11 y 100 m(327.9 ft) 78.1 m,(256.1 ft) 110 m(360.6 ft) 85.9 m(281.6 ft) L 120 m(393.4 ft) 93.8 m(307.5 ft) Figure B-3: 45°Imager Horizontal Alignment (*)Maximum distance for OSE-HP-01 is 100 m(327.9 ft) B.2.2 Vertical Plane Measurements - FOV Height Notes: ° The FOV widths listed on the table below are calculated using the equation:H = D x 0.335 Distance between Imager FOV height(H)(m) and Emitter(D)(m) Standard Power Emitter --0..�- 10 m(32.8 ft) 3.4 m(11.0 ft) 20 m(65.6 ft) 6.7 m(22.0 ft) It 19° 'I H 30 m(98.4 ft) 10.0 m(32.8 ft) 40 m(131.1 ft) 13.4 m(43.9 ft) 1F0.'1 r1 50 m(163.9 ft) 16.7 m(54.8 ft) [c L4.1 60 m(196.7 ft) 20.1 m(65.9 ft) High Power Emitter* Figure B-4: 45°Imager Vertical Alignment 70 m(229.5 ft) 23.4 m(76.2 ft) 80 m(262.3 ft) 26.8 m(87.9 ft) 90 m(295.1 ft) 30.1 m(98.7 it) 100 m(327.9 ft) 33.5 m(109.8 ft) 110 m(360.6 ft) 36.8 m(120.7 ft) 120 m(393.4 ft) 40.2 m(131.8 ft) (*)Maximum distance for OSE-HP-01 is 100 m(327.9 ft) 42 www.xtralis.com OSID by Xtralis OSID Product Guide B.3 90° Imager: 80° FOV B.3.1 Horizontal Plane Measurements - FOV Width The 90°Imager will suit all rectangular room • A configurations(length(L)x width(W))as long as the maximum distance specified between the emitter and imager(D)is not exceeded. i Notes: i Path lengths(D)which are greater than the ranges in the table below require High Powered Emitters. i Imager Maximum Angular Offset Maximum ; 7 W from center Field of View Range 90° 5° 34 m(111 ft.) i 10° 33 m(108 ft.) �✓ /� 20° 32 m(105 ft.) 30° 30 m(98 ft.) 40° 27 m(89 ft.) Ito 80° L Y Figure B-5: 90°Imager Horizontal Alignment B.3.2 Vertical Plane Measurements Table Notes: . The FOV heights listed on the table below are calculated using the following equation: H = D x 0.890 Distance between imager OV rseigh (Vf)(m) ': end tter(D)(m) F, il Standard Power tinter — 10 m(32.8ft) .... 8.9m(29.4ft) 20 m(65.6 ft) 17.8 m(58.4 ft) 30 m(98.4 ft) 26.7 m(87.5 ft) 48° 'I H 34 m(111.5 ft) 30.2 m(99.0 ft) High:Power Emitter*„. 40m(131.1ft) 35.6m(116.7ft) 50m(163.9ft) 44.5m(145.9ft) �I 60 m(196.7 ft) 53.4 m(175.1 ft) W (*)Maximum distance for OSE-HP-01 is 50 m(163.9 ft) L > Figure B-6: 90°Imager Vertical Alignment www.xtralis.com 43 OSID Product Guide OSID by Xtralis This page is intentionally left blank. 44 www.xtralis.com SIEMENS Data Sheet Fire Safety Products Notification Appliances SEFH - High-Fidelity Speakers and Speaker Strobes Application: Indoor t . • it J Y •*1**1 •••1•1•Y • HRE SEFH-HMC-CW SEFH-MC-CW-ALERT SEFH-HMC-W SEFH- Speaker Strobe Speaker Strobe Speaker Strobe Speaker Product Overview — Siemens Series'SEEN'of High-Fidelity(HiFi)speakers I speaker-strobes are comprised of high-efficient design for maximum output(at minimum wattage)across an extensive frequency range, 300 to 8000 Hz — Current Siemens Series'SEF'of speakers I speaker-strobes can easily be upgraded into the'SEFH'HiFi series appliance of the existing back box in which it resides — Siemens Series'SEFH'of High-Fidelity(HiFi) speakers/speaker-strobes provides a polished look with a regular flush-mount appearance using a durable metal cover — The strobes portion of Siemens Series'SEFH'appliances can be synchronized using the following: • Siemens Dual-Sync Control Modules(Model DSC-series with built-in sync protocol) • Siemens 252/504-point addressable fire-safety systems • Siemens Modular systems and FireFinder®XLS control panels • The Siemens PAD-series of NAC Extenders — Faceplates for Siemens Series'SEFH'speaker-strobe appliances contain "FIRE"and"ALERT"text • "ALERT"strobes orderable in either Clear or in Amber — Siemens Series'SEFH'meets the requirement for low-frequency signal tone [as described in the Section for Determination of Low Frequency Signal Format in the Standard for Audible Signal Appliances, per®UL464} when used with: • One(1)Amplifier Card{Model VCI2001-U1}with Siemens 252-point/504-point addressable FACPs • One(1) Booster Amplifier{Model EBA200x Series}with Siemens 252-point 1504-point addressable FACPs • One(1)40W Zone Amplifier Card{Model ZAC-40}with Siemens Modular systems and FireFinder XLSV — Fast installation with In I Out screw terminals using#12 to#18 AWG wires — Field-selectable taps for 25 or 70 VRMS operation from 118 Watt to 2 Watts — Siemens Series'SEFH'HiFi speaker-strobes produce one (1)flash per second — HiFi ceiling-mount models are available with six(6)field-selectable Candela settings of: • 1 5130/7 519 5cd for single-Candela strobes • 1 5130/7 519 5cd or 1151177cd multi-Candela strobes — HiFi wall-mount models are available with six(6)field-selectable Candela Settings of: • 1 5130/7 511 1 0cd or 1351185cd for multi-Candela strobes — ®UL 1480 and 1971 Listed, •ULC-S526,-S541 Listed; CSFM (#7125-0067:0272 for Strobes;#7125-0067:0273 for Speakers)Approved — ADA, NFPA and ANSI Compliant Complies with OSHA 29 Part 1910.165 `SEFH' Series Notification Appliances 2590 SIEMENS Industry,Inc. Building Technologies Division Specifications - Siemens Series'SEW High-Fidelity speaker appliances are Siemens Series'SEFH'HiFi Speakers, and the HiFi speaker-strobe appliances are Siemens Series'SEFH'HiFi Speaker Strobes or approved equals - HiFi speakers are®UL Listed under Standard 1480 for Fire Protective Service, and speakers equipped with strobes are listed under®UL Standard 1971 for Emergency Devices for the Hearing-Impaired - Siemens Series'SEFH'HiFi speakers are designed for a field-selectable input of either 25 or 70 VRMS, and with field-selectable power taps from 1/8 Watt to 2 Watts - Selector switch,which is used to manually selecting the candela setting, is tamper-resistant by design - Siemens Series'SEFH'HiFi models have listed sound outputs of up to 87dBA at 10 feet, and a listed frequency response of 300 to 8000 Hz - Speaker appliances feature sealed-back construction for optimum audibility - All inputs employ terminals that accept#12 to#18 AWG wire sizes - Strobe intensity,where HiFi Candela appliances are specified, have field-selectable settings,and are rated, per®UL Standard 1971 for Emergency Devices and for the Hearing-Impaired,for the following: • 1 513017 511 1 0cd(wall mount, single-Candela strobes) -or- • 1351185cd (wall mount, multi-Candela strobes) • 1 513017 519 5cd (ceiling mount,single-Candela strobes)-or- • 115/177cd (ceiling mount,multi-Candela strobes) - Strobe portion of each HiFi appliance produces a flash rate of one(1)flash per second, and incorporates a Xenon flashtube enclosed in a rugged Lexan®lens - Strobes are of low-current design - When synchronization is required,the strobes portion of Siemens Series 'SEFH'appliances is synchronized using the following: • Siemens Dual-Sync Control Modules->Model DSC-series with built-in sync protocol • Siemens 252 1504-point addressable fire-safety systems • Siemens Modular systems and FireFinder®XLS control panels • The Siemens PAD-series of NAC Extenders - Siemens Series'SEFH'meets the requirement for low-frequency signal tone [as described in the section for Determination of Low Frequency Signal Format in the Standard for Audible Signal Appliances, per®UL464] When used with: • One(1)Amplifier Card{Model VCI2001-U11 with Siemens 252-point 1 504-point addressable FACPs • One(1) Booster Amplifier{Model EBA200x Series}with Siemens 252-point 1 504-point addressable FACPs • One(1)40W Zone Amplifier Card{Model ZAC-40)with Siemens Modular systems and FireFinder XLSV - The strobes will not drift out of synchronization at any time during operation - Siemens'SEFH'Series strobes revert to a non-synchronized flash-rate, if the dual-sync module or the Siemens PAD-series NAC Extenders should fail to operate (i.e. -contacts remain closed) - HiFi ceiling speakers and speaker-strobe appliances are designed for indoor-surface or flush mounting - HiFi speakers and speaker-strobes incorporate a speaker-mounting plate with a grille cover,which is secured with two(2) screws for a level finish • Grille cover mounts to standard electrical hardware requiring no additional trim plate or adapter - Series'SEFH'HiFi speakers and speakers strobes are available for ordering in either white or red - All speaker and speaker-strobe appliances are listed for Special Applications: • Strobes are designed to flash at 1-flash-per-second minimum over their"Regulated Input Voltage Range" ➢ Note: NFPA-72 specifies a flash rate of 1-to-2 flashes per second,and ADA Guidelines specify a flash rate of 1-to-3 flashes per second • All candela ratings represent minimum-effective Strobe intensity, based on CUL Standard 1971 SIEMENSIndustry,Inc. Building Technologies Division Mounting Diagram 524 524 268 2.68 ti -iL A ;Tore . M. 1111.1 v 5.13 O i sad:;s i J le.i '�lliglil^iii 7.27n. 5.13 ..... DIA ^:L'.".:.^.`*:."' s�is a%°ee•: '�R lliiiih:155'S• r,• a.°o°<':�;•'°*ie •,.r O FIRE (Shown In Inches) Mounting Options E rL MOUNTING AA $VRP4 M cc OUhrrelo saareseJemaina IILM SMACRE tlImeNMAI E RUSH OAOUIYnPIri VERGER) wnmaesrAaINn MAME rissq uiii w eup� `oal .. '�e1'rrc. snce¢Naacea r $(4.12 I ,..A.EA 7,....„ IIIIV 0 -)A1.4 . 0 pli,'"Will 1,4,„tcallift.. GRILL ' *� 0 `� sly Orau^...�a Me11° �S eanCw FATE SCCF ,VtElt bQPN UMW,/NO1410i ca e'YC.:!Ji IMXa#UP4.WS 7M4,441,00 WaM/NNW r C"...,CV:FoRS tWo.1NL*W CO CMOUGToB Jars dare sir su IFan_ N+'esr (opal() &AEI wqr- MLA !Mil sir, ADM Sara . .tl.. J'+es+E 4 4 4 4 4 4 4 4 0 0 0 0 0 I I I Note: Backbox is compatible with wire mob and conduit mountings. Holes are for single-gang,double-gang, 4"sq.,3-112°and 4"octagon or round Technical Data backboxes. SEFH Series: Speakers Only SEFH-MC Series: Speaker-Strobes 6V UL andI ULC Listed Models and Ratings ®UL andOULC Listed Models and Ratings Operating dBA at 10 Feet Anechoic dBA Operating dBA at 10 Feet Anechoic dBA Model* Voltage (Rated Watts) (per.CAN l NUC-Ssal-07j. Model* Voltag (Paled Walls) (Per CAN(NULe554107) minus) 1/8 114 1/2 1 2 118 1/4 1/2 1 2 IUKiasi 118 1/4 1/2 1 2 118 114 1/2 1 2 SEFH 25/70 72 75 78 81 83 74 77 80 83 85 SEFH-MC 25/70 71 75 78 81 83 73 76 79 82 85 SEFH-C 25/70 72 75 78 81 82 73 76 79 82 85 SEFH-HMC 25/70 71 75 78 81 83 73 76 79 82 85 *All models available in red or white. SEFH-MC-CW 25/70 74 77 80 82 85 74 77 80 82 85 SEH-HMC-CW 25/70 74 77 80 82 85 74 77 80 82 85 OULC Directional Characteristics *All models available in red or white. r •3dBA +1-19 degrees horizontal;+/-35 degrees vertical Ii ULC Directional Characteristics g. axis,; •6dBA +/-40 degrees horizontal;+/-45 degrees vertical 25V/ -3dBA +/-33 degrees horizontal;+I-18 degrees vertical 70V -6dBA +/-41 degrees horizontal;+I-31 degrees vertical SEFH-MC Series: Ceiling-Mount Strobes Only SEFH-HMC Series: Ceiling-Mount Strobes Only Current Ratings(AMPS) Current Ratings(AMPs) MAXIMUM RMS Current-Per®UL andlULC MAXIMUM RMS Current-Per®UL and¢ULC Operating Operating Input Voltage Range Voltage 15cd 30cd 75cd 95cd input Voltage Range Voltage 115cd 177cd (Spada Application! (Special Appicallon) DC 16.0-33.0VRMS @ 24 VDC 0.069 0.111 0.200 0.264 DC 16.0-33.0VRMS @ 24 VDC 0.318 0.445 FWR 16.0-33.0VRMS Q24VDC 0.117 0.180 0.297 0.398 FWR 16.0-33.OVRMS @24VDC 0.482 0.683 SIEMENS Industry,Inc. Building Technologies Division Technical Data — (continued) Speaker Voltage&Wattage Connection Chart 2.Strobes meet the required light distribution Position, 25V 70V patterns defined in®UL 1971 A2 B 1 --- 3. Models are ®UL Listed for indoor use with a C 1/2 — temperature range of +32°F to +120°F (0°C to D 1/4 2 +49°C) and maximum humidity of 95%RH.The E 1/8 1 effect of shipping and storage temperatures will F ---- 1/2 not adversely affect the performance of the G 1/4 appliance when it is stored in the original H I 1/8 cartons and is not subjected to misuse or abuse Notes: 1.Strobe will produce 1 flash per 4.Frequency range of speakers is 300-8000Hz second over the Input Voltage range Details for Ordering — (Including Mounting Options & Agency Approvals) Agency Approvals Part Wall Ceiling Mounting Model Description Text UL ULC CSFM Number Mount Mount Options SEFH-CR S54360-F2-A1 SEFH HiFi Series: Speaker,Red — YES NIA Q,U V ✓ ✓ SEFH-CW S54360-F2-A2 SEFH HiFi Series: Speaker,White — YES NIA Q,U V ✓ V SEFH-HMC-CW S54360-F3-Al SEFH HiFi Series: Hi Multi-Candela,White — YES FIRE Q,U ✓ ✓ ✓ SEFH-HMC-CR 554329-A35-A1 SEFH HiFi Series: Hi Multi-Candela,Red — YES FIRE Q,U ✓ ✓ ✓ SEFH-HMC- 554329-A33-Al SEFH HiFi Series: Hi Multi-Candela,Red — YES ALERT Q,U ✓ ✓ ✓ CR-ALERT SEFH-HMC- 554329-A34-A1 SEFH HiFi Series: Hi Multi-Candela,White — YES ALERT Q,U V V ✓ CW-ALERT SEFH-HMC-R S54360-F3-A2 SEFH HiFi Series: Hi Multi-Candela,Red YES — FIRE P,Q,R,U,Y V ✓ ✓ SEFH-HMC-W S54360-F4-Al SEFH HiFi Series: Hi Multi-Candela,White YES — FIRE P,Q,R,U,Y V ✓ ✓ SEFH-AMC- 554329-Al -Al SEFH HEFT Series: YES — ALERT P,Q,R,U,Y V ✓ ✓ W-ALERT Amber Multi-Candela,White SEFH-AMC- S54329-A14-Al SEFH H[FI Series: — YES ALERT Q,U V ✓ ✓ CW-ALERT Amber Multi-Candela,White SEFH-AHMC- SEFH HIFI Series: ✓ ✓ ✓ CW-ALERT S54329-Al 5-Al Hi Amber Multi-Candela,White — YES ALERT Q,U SEFH-MC-CW S54360-F4-A2 SEFH HiFi Series: Multi-Candela,White — YES FIRE Q,U ✓ ✓ V SEFH-MC- S54329-A36-Al SEFH HiFi Series: Hi Multi-Candela,White — YES NIA Q,U ✓ ✓ ✓ CW-BLANK SEFH-MC-CR S54329-A32-A1 SEFH HiFi Series: Multi-Candela,Red — YES FIRE Q,U V ✓ ✓ SEFH-MC- 554329-A31-Al SEFH HiFi Series: Multi-Candela,White — YES ALERT Q,U ✓ ✓ ✓ CW-ALERT SEFH-MC- 554329-A28-A1 SEFH HiFi Series: Multi-Candela,White YES — ALERT P,Q,R,U,Y ✓ V ✓ W-ALERT SEFH-MC- 554329-A29-A1 SEFH HiFi Series: Multi-Candela,White YES — N/A P,Q,R,U,Y V V ✓ W-BLANK SEFH-MC-R S54360-F5-A1 SEFH HiFi Series: Multi-Candela,Red YES — FIRE P,Q,R,U,Y V V ✓ SEFH-MC- 554329-A27-A1 SEFH HiFi Series: Multi-Candela,Red YES — ALERT P,Q,R,U,Y ✓ ✓ ✓ R-ALERT SEFH-MC- S54329-A30-Al SEFH HiFi Series: Multi-Candela,Red — YES ALERT Q,U V ✓ ✓ CR-ALERT SEFH-MC-W S54360-F5-A2 SEFH HiFi Series: Multi-Candela,White YES — FIRE P,Q,R,U,Y V V ✓ SEFH-R S54360-F6-Al SEFH HiFi Series: Speaker,Red YES — N/A Q,U ✓ V 1 SEFH-W S54360-F6-A2 SEFH HiFi Series: Speaker,White YES — N/A Q,U V V ✓ s. NOTE There are no regulatory restrictions in if Notice: This marketing data sheet is not intended to be, ., mounting siemens series sEFH =listed!approved used for system design or installation purposes , f a speaker-only appliances to either wall Yi i••'it orceiling applications. * =Refer to data sheet For the most up-to-date information,refer '�iy a 2585 for detailed I' to each product's installation instructions - 'i mounting options ) Fire Safety Fire Safety 8 Fernwood Road 1577 North Service Road SIEMENSIndustry,Inc. Florham Park,Ni 07932 East Oakville,Ontario August 2018 Building Technologies Division Tel:(973)593-2600 (sii L6H OH6I Canada Supersedes shot dated 9/1017 FAX:(908)547-6877 Printed in U.S.A. Tel:[905]465-8000 URL:www.usa.Siemens.comlFire URL:www.Siemens.CA Peripheral and Detection Devices ; SIEMENS Initiating Devices I``�` if-7�'� ' Cite_ Intelligent Device Interface Modules Model XTRI-D I XTRI-R I XTRI-S Architect&;En•ineer S.ecifications Product Overview 0 Built-in dual isolators: The Siemens — Fire Safety XTRI-series Intelligent Interface Modules are designed to - Modern technology supports comprehensive system-and- provide the means of interfacing direct shorting devices to the fire-alarm control panel interface communication (FACP) loop circuit. All modules take up one(1)address on the loop. - Allows up to 190 isolators per loop and Each XTRI-series interface module provides built-in, intelligent dual isolation, and 30 devices between isolators meets Class X(Style 7)wiring requirements. Up to 190 isolators per loop and up to 30 ❑ Dual input on Model XTRI-D, via a devices between isolators (wired in polarity-insensitive mode). Additionally, the single address devices between isolators can either be 'H'-series or the more contemporary 'X'-series detection devices. ❑ Integral single-pole,double-throw(SPOT) relay on Model XTRI-R: S.ecifications - Up to 4 Amps- The Siemens—Fire Safety XTRI-series Intelligent Interface Modules are available in three ❑ Meets Class X (Style 7) (3) individual types: survivability requirements > One (1) Dual-Input: XTRI-D O Low current draw - Two(2)Single-Inputs: XTRI-R(with relay)I XTRI-S — The single-input versions are each designed to monitor a normally ❑ Polarity insensitive(in non-isolation mode) open (N.0)or(N.C) normally closed dry contact via SureWirer""technology: Modern technology supports XTRI-D I XTRI-R I XTRI-S incorporates configurable, built-in dual isolators. Additionally, comprehensive system and an XTRI-series interface module has Class X (Style 7) survivability requirements for interface communication shorts while providing reliable alarm communication to the Siemens FACP. The isolation 0 Multi-color light-emitting diode(LED) feature found on the XTRI-series Intelligent Interface Modules gives information as to indicates system status: the location of the fault. When a short occurs, the panel can identify the fault - GREEN I AMBER RED automatically, and the module recognizes the short location (in front of the device or behind the device). ❑ Mounts ine4-inchle-ga go square,2--'!," Overall, the built-in isolators improve the diagnostics and location of the problem, (5.7 cm.)deep single-gang or double-gang P 9 back box including a short. ❑ Non-obstructive front-end access to The modules are configurable by a Siemens compatible FACP(or panels) in an isolator programming port and wiring terminals (polarity sensitive) or non-isolator (polarity insensitive) mode. When a XTRI-series interface module is configured as an isolator, that module has the capacity of ❑ Device Programmer I Test Unit programs and functioning as both an inlout device,as well as an isolator. verifies address,as well as tests device functionality Advanced troubleshooting is provided by compatible # 1 t ❑ Restriction of Hazardous Substances panels by identifying when a XTRI-series interface a ,. (RoHS)compliant module is configured as an isolator, but is wired r.t ❑ UL864 I UL2572 I UL2017 Listed;CAN/ULC-5527 incorrectly in a polarity-insensitive mode. &CANfULC-S576 Listed - File S24304,Vol.3 tx ~- - Each Model XTRI-series device has a multi-color LED that flashes when GREEN operating in Normal mode;AMBER if the unit is in a 'Trouble'condition,and RED to indicate a change of status. Model XTRI-S This single-input interface module can only monitor and report the status of a N.O. or N.C. contact. Model XTRI-D XTRI-R XTRI-S Intelligent Device Interface Module Siemens Data Sheet 6167 Smart Infrastructure— Building Products usa.siemens.com/fire ...r `h am$ a x�.� ---.4 „ , � , , . ''dd -r.E� �� t 4"(10.2 cm.) ` 'l _ .F °b , i square box 2-1/8" a + 1 2 470., (5.4cm.)back box ik i 11 " € � S 2. 3.5"(89an)double t 0 4 �rl 3 -gang back box 3� � �. 3. 5"(12.7 cm.) , "-y "';* - square switch 1 Model = plate,(supplied) c; XTRInt Intelligent DXTRI- XTRI-S .,_/ 0 Intelligent Device A00 Interface Module S.ecifications- continued) Mountin. Data PRCGRAMMINGHOLES NOTES: Each interface module Model XTRI-R ,_.. mounts directly to a user- ] (+ supplied switchbox. Through the use of an addressable 'Form C' relay, the E The electrical boxes,seen Model XTRI-R relay and contact device input are above,are supplied-by-others (BO). controlled at the same address. The relay and input contact can be controlled as a separate function from a Models XTRI-D, XTRI-R and XTRI-S Siemens compatible FACP. The relay is typically used SLOTFOR mount directly onto a 4-inch (10.2 cm.) where control or shunting of external equipment is LOCATING square, 2 '/i' (5.7 cm.) deep box back TAE box.or to a user-supplied double-gang 3 required. Loh"deep back box. Model XTRI-D THER " A 5"(12.7 cm.)square,off-white faceplate Model XTRI-D is a dual-input module that is designed DIRECTMTY g is XThded n eriesmeach i dine. faSiemens OESIGN FOR DP0 �t -T-1 Model XTRI-series module. to supervise and monitor two(2)sets of dry contacts. Co'MIECTOkrtf Model XTRI-D only requires one (1) address, but is aowEDTo PLUG FROM responds independently to each input. Model XTRI-D INSERTTHEPLOG PRGR0 I PR OGAAMMER7 is ideal for monitoring a water-flow switch and its AT EDER DIRECTOR I TESTER respective valve tamper switch. it 0.eration Field-Device Programmer!Test Unit Siemens-Fire Safety innovative technology allows Model XTRI-series intelligent interface modules to be programmed via the Siemens field-device programmer I test unit (Model DPU), which is a compact, portable and menu-driven accessory for electronically programming and testing Siemens peripheral modules and devices promptly and reliably. For instance, the field technician selects the accessory's program mode,and enters the desired address. Vibration, corrosion and other conditions that deteriorate mechanical-addressing mechanisms are no longer a cause for concern. Model XTRI-series interface module is connected to Model DPU with the programming cable provided with the tester. NOTE: Since the XTRI-series of interface modules are advanced initiating devices,the latest Model DPU firmware update is required. Model DPU eliminates the need for cumbersome, unreliable mechanical programming methods (e.g. - dials and rotary switches), and reduces installation and service costs by electronically programming and testing the module prior to installation. When set in 'test'mode, Model DPU will perform a series of diagnostic tests without altering the address or other stored data,allowing technicians to determine if the module is operating properly. Each field-device programmer I test unit operates on AC power or rechargeable batteries, providing flexibility and convenience in the programming I testing of fire-safety equipment from practically any location. Additionally,with the use of a Model DPU unit,there is no longer a cause for concern with any vibration,corrosion and other deteriorating conditions that can accompany the vitality of a mechanical-addressing mechanism. Siemens Smart Infrastructure - Building Products -2- usa.siemens.com/fire Corn•atibilities Siemens 'X' modules may be used along with Model 'H'-series intelligent detectors; Model 'HMS'-series addressable manual stations,or any other'H'-series addressable intelligent module (e.g. Model HZM or Model HCP). Additionally the X- series modules are compatible with all Desigo and Cerberus Pro detectors and peripherals o the same circuit. Interspersing 'X' & 'H'-series devices on the same loop is mostly permitted, but there are exceptions: Models HUM (isolation module)and SBGA-34(audible base)cannot be used with'X' devices on the same loop. Ter •erature and Humidit Ranse Models XTRI-D I XTRI-R I XTRI-S intelligent interface modules are UL Listed I ULC Listed. Environmental operating conditions for each interface module is 32°F(0°C)to 120°F(49°C)with a relative humidity of no greater than 95%,non-condensing. Electrical Ratin.s Electrical Ratin•s OPERATING FLASH INTERVALS VOLTAGE RANGE: 13VDC-32VDC FLASH COLOR CONDITION [in seconds] RELATIVE 0-95°/ Normal supervisory operation. 10 HUMIDITY: (non-condensing) - YELLOW: Device is in trouble and needs to be 4 'ACTIVE'OR'STANDBY' 500 A replaced. CURRENT,MAX.: p Locate I 'Alarm' 1 LINE SIZES RED: AMERICAN WIRE 14 AWG,max. Output Device(XTRI-R only) 10 GAUGE(AWG) 18 AWG,min. Power is not being CURRENT DRAW, XTRI-S: 650pA NO FLASH: received.Replacement is - MAX I AVG. XTRI.R: 750pA needed. XTRI-D: 950pA RELAY RATINGS I Details for Orderin• for Model XTRI-R) MODEL PART 4 Amps 1125 VAC OR TYPE NUMBER PRODUCT RESISTIVE: 4 Amps 130 VDC XTRI-S S54370-B3-A1 Single Input Module 3.5A,120 VAC(0.6 pF) 3.0A,30 VDC(0.6 pF) XTRI-R 554370-B1-A1 Single Input Module INDUCTIVE: 2.OA,120 VAC(0.4 pF) (with relay) 2.0A,120VAC(0.35 pF) XTRI-D S54370-B2-A1 Dual Input Module 2.OA,30 VDC(0.35 pF) DPLI 500-033260 Device Programmer Test Unit NOTE: Refer to installation manual: P/N - A6V101055479 to ensure Model XTRI-D I XTRI-R I XTRI-5 compatibility with the Siemens FACPs intended for use in the given Siemens -3- usa.siemens.comlfire Smart Infrastructure- Building Products NOTICE- The information contained in this data-sheet document is intended only as a summary,and is subject to change without notice. The product(s)described here has/have a specific instruction sheet(s) that cover various technical,limitation and liability information. Copies of install-type,instruction sheets-as well as the Genera!Product Warning and Limitations document,which also contains important data, are provided with the product,and are available from the Manufacturer. Data contained in the aforesaid type of documentation should be consulted with a fire-safety professional before specifying or using the,product. Any further questions or assistance concerning particular problems that might arise,relative to the proper functioning of the equipment,please contact Siemens Industry,Inc. the Manufacturer. Smart Infrastructure-Building Products 8 Fernwood Road • Florham Park, NJ 07932 SIEMENS Tel:(973) 593-2600 April 2019- Rev.1 FIRE ALARM CONTROL PANEL BATTERY AND VOLTAGE DROP 2 CALCULATIONS FACP-01 BATTERY CALCULATIONS SIEMENS FIRE ALARM SUBMITTAL EMBASSY SUITES HOTEL � • •_ FIRE ALARM UPGRADE V J r i XIS Required Battery Capacity with 20%Reserve[AM: Power Calculations Battery Calculations 24V 6.2V Screw Terminal 24V Module Device Description 051 Backplane Backplane Current(mA) Standby 24 VOC Current Current Current (mA) (nA) Standby Alarm AUG i Audio Input Caro 1 25.0 85.0 50.0 ALCC I Audio Level Conversion Card 0.0 0.0 0.0 CDC4A Conventional Detector Go to the CDC-1 sheet(double click) 0.0 0.0 0,0 0.0 0.0 0.0 CRCS ''Conrol Relay Car 0.0 0,0 0.0 Relay Active Porr,C Relay - 0.0 0.0 0.0 02300CP Fiber Optic Interface 00 00, _.__0_0 02325CP5 00 001 0.0 DAC Dgitel Audio Card 0.0 0.0 DOC I Digital Dialer Card 0.0 OP 0.0 DFM ID-NET Fiber Optic Module 0.0 OO 0.0 DLC I Device Loop Card 2 400.0 200.0 2000i 2900 I1F13-11 Photo-thermal detector 0.0 00. 0.0 I1FPT-11 Thermal detector 1 08 08 0.8 OOHC941 Dual eplcaldhennal/CO detector 0.0 00I 0.0 OOH941 Dual optical/thermal detector 0.0 00, 0.0 OH921 Photo-thermal detector 0.0 00 0.0 OP921 Photo detector 0.0 0.0: 0.0 Ht921 Thermal detector 0.0 D OI 0.0 FOOOTC441 Dual optical/thermal/CO detector 0.0 O0i 0.0 FDOOT441 Dual optical/thermal detector 00 MO! 0.0 FOOT421 Photo-themlal detector 163 47.3 4731 42.3 F00421 Photo detector 0.0 0d 0.0 FOT421 Thermal detector 33 02 0.2 02 FOCIDA 2-inpuv4output module, 1 1.0 09 0.0 H2B a 4 tt module 1 0 10 00 HMSMsas Manual stationn 0.0 n 0 o 0 HMS-S Manual station 0.0 00 - -0a HMO-MI Manual station 0.0 f10 00 HMS-SA Manual station 0.0 00 0.0 HMS-D Manual elation 24 21 8 216 21 6 HTRI-5 Single Input module a.0 00 00 HTRI-D Duet input module 18 234 23A 234 HTRI-R Sirgl input/single relay module 1 1.3 1.3 1 3 HTRI-M Single input mini module 0.0 0.0 0.0 H2M Conventional zone module 0.0 0.0 0.0 HOP Addressable ontrol point _ 0.0 0.0 0.O ILED-HC I telligent LED 0.0 00 0.0 ILED-HW Intelligent LED 0.0 0.0 0.0 Other 0.0 0.0 00 FCM Fan Control Module 3 - 42.0 42.0 42.0 Active FCM S',uilches 18 �_ 18.0 18.0 18.0 FMT Firefighter Master Telephone 1 1500 1500� 70.0 FN2006 Fiber Optic Module 0.0 001- 0.0 FN2002 Fibe/Optic Module 0.0 0.0 0.0 HUB-4 Communication Module-4 ports 0.0 0.0 0.0 DO LCM LED Control Module 0.0 00 0.0 LED Active I Ms 0.0 0.0 0.0 LPB Local Page Board 1 25.0 95.0 50.0 LVM Live Voice Modue 1 51.0 51.0 51.0 Active Switch 5 60 60 60 MLC 00 0.0 00 0.0 0.0 CZM-1 Remote Conventional Zone Module 0.0 0.0 0.0 FP-11 Photosensenser detector 0.0 0.0 0.0 FPT-t1 I Photo and thermal detector 0.0 0.0 0.0 CP25 I Intelligent control point 0.0 0.0 0.0 CP70 0.0 0.0 0.0 D-501 Intel'igent thermal detector 0.0 0.0 0.0 0-6OIA 0.0 0.0 0.0 0-60IH 0.0 0.0 0.0 0-60IAH • 0.0] 0.0 00 9-60l13 I 0.0I 0.0 0.0 0-60IBH 0.0 0.0 0.0 0.6OP 0.0 0.0 0.0 D-60PD 00 0.0 0.0 D-SOPT 0.0 0.0 0.0 0-60T 0.0 0 0 0.0 LI-1/-11-1 Ionization detector(0-300ft/min.) 0.0 0.0 00 LI4A/'AH 0.0 00 00 LI-18/-1BH 00 00 0.a LP-1/ILPT-1 Photoelectric detector 0.0 00 0.0 LP-2 0.0 0.0 0.0 M51-1/-2 Intelligent manual station 0.0 0.0 0.0 TRI-60 Interface single-input module 0.0 0.0 0.0 TRI-Soil Addressable de into lsce module module __ 0.0 0.0 0.0 TRI-60R Atldressahla inicdace module 0.0 0.0 0.0 -Other 0.0 0.0 MLC Eat Mxl.Line Card Est 0.0 0.0 0.0 Power Calculations Battery Calculations 24V 6.2V Screw Terminal 24V Module Device Description My Backplane Backplane Current(mA) Standby 24 VDC Current Current Current (mA) (mA) Standby Alarm NIC Network Interface Card 1 120.0 ___ 120.0 NIC Xnet Nehwork Interface Card Xnet 0.0 _ 0.0 NIM 1W Network Interface Module-Wide Area CO 0.0 00 NRC Network Ring Card 0.0 D.0' 0.0 OCM Output Control Module 0.0 0.0 0.0 Active Open Collector 0.0 0.0 0.0 PMI Control Panel _ 1 230.0 230.0 TSP-40A Thermal Strip Printer 0.0 0.0 0.0 PMI-2 [Control Panel 0.000 TSP-40A !Thermal Strip Printer 0.0 0.0 - - 0.0 RNI 'Remote Network Interlace U.S 00 00 RPM See Note 2 'Remote Printer Module I 150.0 150.0 1500 SCM _Switch Control Module 4 560, 56.0 56.0 Switch Active Pushbutton Switch 32 32.0: 32.0 32.0 SIM Supervised Input Module 0.0' 0.0 0.0 SIM device SIM Input _ 0.0 0.0 0.0 SIM Relay Relay - 00 0.0 0.0 SSD System Status Display 1 200.0 200.0 200.0 TZC Telephone Zone Card 1 315.0 315.0 280.0 VPM See Note 2 Vesda Peripheral Module 0.0 0.0 0.0 HLI(See Note 2) High Level Interlace card 0.0 p.0' 0.0 XDMC. JCS Diesel Message Card 00 0.0 0.0 ZAC40 Zone Amplifier Card-40W 3 _ _ ,.. _ 450.0 450.0 453.0 Total Speaker Wattage 3/.5 1087.8 ZAC405ackop Zone Amplifier Card-40W 0.0 0.0 ZAM120 Zone Amplifier Card-120W... 0.0 0.0 0.0 Total Speaker Wattage • 0.0 ZAM1206ackup Zane Amplifier Card-120W 0.0 0.0 Total Lies Zone Indicating Cards CO to lne.>IC sheet ldouble click) 723.0 0.0 0.0 5000.0 315.0 PSC-12 Power Supply Card 288 Watts 1 150.0 PSC Relay Active Relay en the PSC 3 60.0 See Note 1 AUX Standby Current(mA]on A.C. _-_ 1.0 See Note 1 AUX Alarm Current[mA]on A.C. 1.0 See Note l AUX Standby Currentof Battery [mA] 1.0 Sec Nate AUX Alarm Current on Battery[mA] ' PSX-12 Power Supply Extender 289 Watts I 00 See Note l '',AUX Standby CurrentstjmA]on AC. I 1.0 See Note 1 ''AUX Alarm Current[mA]en A . I 10 _ See Notes AUX Standby n of onBerV[] 10 See Note 'AUX Alarm Current on Battery[mA] Total[A] .1 1.1230 0.0800 1.7767 8.7942 2.7297 Power Supply Limits Parameter Max value Actual value Rnoult 24V Backplane Current 2A 1.123 OK 6.2V Backplane Current 2A (1.580 _ _OK Total 24V Standby Current 5 2.177 -- DK Tnlal 24V Alarm Current 12A•Number of PS 9.887 OK Battery Calculation Max Standby]H¢) t iirk.ra l.,: n _ arwwo prcrvw444• _ 24 Max Alarm[Min] 15 Battery capacity reserve]%] 20 Required Battery Capacity IAHj: 67.70 Required Battery Capacity with 20%Reserve[AH1: 81.24 Note 1:For each HCP.HZM,CZM-1,ICP25&ICP70 add the following current to each PSC-121PSX-12 AUX power entry it these devices are receiving power from this PSC-12/PSX-12. HCP HZM CZM-1 ICP25 ICP70 AUX Standby Current(mA] 30 mA 76 mA 12.5 mA 10 mA 10 mA AUX Mann Ct.rrent[n]A] 30mA 100 mA 50 mA 10 mA 10mA AUX Standby Current on Battery[mA] 30mA 76 mA 12.5 mA 10 nth 10 mA AUX Alarm Current on Battery[mA( 30mA 10D InA 50 mA 10 mA 10 mA Nate 2.Only Include this modu cif it is being powered by a PSC-12 or PSX-12 in this enclosure,otherwise leave the quantity as D. FACP-01 SIEMENS VOLTAGE DROP CALCULATIONS FIRE ALARM SUBMITTAL EMBASSY SUITES HOTEL FIRE ALARM UPGRADE FACP-01 PANEL ZIC-812 CARD 15%Design Voltage Drop(20%Max Voltage Drop) 2.00 Amp Max Current Draw Per Output 16.00 Amp Max Current Draw Per Card 14 AWG Wire Gauge 20.4 Volt Voltage at First Device' 2IC-8B LOADS PANEL MODEL STANDBY ALARM ZIC-8B 0.105 AMP 0.195 AMP FACP-01 VOLTAGE DROP CALCULATION RESULTS PERCENT STANDBY ALARM PERCENT OUTPUT VOLTAGE CURRENT CURRENT CURRENT LABEL VOLTAGE DROP DROP DRAW DRAW DRAW OUTPUT-1 21-007-1- 0.07 Volt 0.35% 0.00 Amp 0.06 Atop 3.20% Stair-1 Strobe OUTPUT-2 21-007.2- 0.02 Volt 0.11% 0.00 Amp 0.06 Amp 3.20% Stair-2 Strobe OUTPUT-3 Z1-007-3- 0.56 Volt 2.74% 0.00 Amp 0.19 Amp 9.60% 2nd Floor Strobe OUTPUT-0 21-007-4- 0.56 Volt 2.73% 0.00 Atop 0.19 Amp 9.60% 3rd Floor Strobe OUTPUTS Z1-007-5- 0.57 Volt 2.80% 0.00 Amp 0.19 Amp 9.60% 4th Floor Strobe OUTPUT-6 Z1-007-6- 0.58 Volt 2.86% 0.00 Atop 0.19 Amp 9.60% 5th Floor Strobe OUTPUT-7 Z1-007-7- 0.59 Volt 2.91% 0.00 Amp 0.19 Amp 9.60% 6th Floor Strobe OUTPUT-8 Z1-007-8- 0.61 Volt 2.97% 0.00 Amp 0.19 Amp 9.60% 7th Floor Strobe Total Current Draw 0.00 Amp 1.28 Amp 8.00% FACP-01 VOLTAGE DROP CALCULATIONS OUTPUT-1 LABEL CD MODEL STANDBY ALARM DISTANCE Alarm Volta•e Dro•=VD=RxIa FACP-01 - -- Y.is>..®.�(L)Total Circuit Length(One Leg) Z1-007-1-01 t Wire Resistance Per 1000 Feet - ----1[1= Total Circuit Resistance Both Lees -_----0.00 Amp Is Total Current Draw 5tandb -__-BOB Amp -- --�(20.4-(lax R))Applied Voltage at Last Device' ------0.07 Volt (VD)Voltage Drop --- ®Percent Volta•e Drop ------®Percent Current Draw OotPot-1 --- -__ -- 11 .1111111111 PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/5/2019 FACP-01 VOLTAGE DROP CALCULATIONS CONTINUED a: OUTPUT-2 LABEL CD MODEL STANDBY ALARM DIS1ANCE Volta•e Drop=VD=L'R'Ia FACP-01 :: ZIC-8B (L)Total Circuit Length(One Leg) 21.007.2-01 ®® 0.06a ® "®Wire Resistance Per 1000 Feet -_--- '®(R)Total Circuit Resistance Both Logs) --- 0.00 Amp Is Total Current Draw(Standby) 1 .11111.11111 ------ (20.4-(lax RI)Applied Voltage at Lest Device' ------0.02 Volt (VO)Volta r e Drop -_- _- S. Percent Velte,e Drop --- --®Percent Current Drew Output-2 1 .11.1111111111111 MEM OUTPUT-3 LABEL CD MODEL STANDBY ALARM DISTANCE Voltage Drop=VD=L*R1a FACP-01 ZIC-8B 43C4 470.08 Ft (L)Total Circuit Length(One Leg) Z1-007.3-01 15cd SEFH-MC-W 0 06< 151 75 ft 3.10 Ohm Wire Resistance Per 1000 Feet _ Z1-0073-02 15cd SEFH-MC-W 0.06' 170.50 ft 2.91 Ohm (R)Total Circuit Resistance(Both Legs) 21-007-3-03 15cd SEFH-MC-W 0.064 147.83 ft OM Amp (Is(Total Current Draw(Standby) 0.19 Amp (Ia)Total Current Draw(Alarm) 19.84 Volt (20.4-(lax R)(Applied Voltage at Last Device' 0.56 Voll (VD)Voltage Drop 2.74% Percent Voltage Drop 9.60% Percent Current Draw Output-3 OUTPUT-9 LABEL CD MODEL STANDBY ALARM DISTANCE Voltage Drop=VD=L'R•la FACP-01 ZIC-86 ' ra(` •ax ;468.42 Ft (L)Total Circuit Length(One Leg) 21-007-4-01 15cd SEFH-MC-W 0.064 153.92 ft 3.10 Ohm Wire Resistance Per 1000 Feet Z1-007-4-02 15cd SEFH-MC-W 0.064 168.58 ft 2.90 Ohm (R)Total Circuit Resistance(Both Legs) Z1-007-4-03 15cd SEFH-MC-W 0.064 145.92ft 0.00 Amp (Is)Total Current Draw(Standby) 0.19 Amp (Ia)Total Current Draw(Alarm) _ 19.84 Volt (20.4-(lax R))Applied Voltage at Last Device' 0.56 Volt (1N)Voltage Drop 2.73% Percent Voltage Drop 9.60% Percent Current Draw Output-4 OUTPUT-5 LABEL CD MODEL STANDBY ALARM DISTANCE Voltage Drop=VD=R x le FACP•01 £,,;," ZIC-86 -,7=-'+�'d 479.75 Ft )L)Total Ctrcutt Length(One Leg) Z14307d-01 15cd SEFH-MC-W 0.064 163.92 ft 3.10 Ohm Wire Resistance Per 1000 Feet 21.0075-02 15cd SEFH-MC-W 0.064 169.25 ft 2.97 Ohm (R)Total Circuit Resistance(Both Legs) 21.0075-03 15cd SEFH-MCW 0.064 146.58ft 0.00 Amp (Is)Total Current Draw(Standby) 0.19 Amp (la)Total Current Draw(Alarm) 19.83 Volt (20.4-(la x R))Applied Voltage al Last Device' 0.57 Volt (VD)Voltage Drop 2.80% Percent Voltage Drop 8.60% Percent Current Draw Output-5 PROPRIETARY DOCUMENT FOR APPROVAL ONLY 1215/2019 FACP-01 VOLTAGE DROP CALCULATIONS CONTINUED OUTPUT-6 LABEL CD MODEL STANDBY ALARM DISTANCE Voltage Drop=VD=L'R'la FACP-01 ZIC-8B �•A..489.75 Ft (L)Total Circuit Length(One Leg) Z1.007.6.01 15cd SEFH-MC-W 0.064 175.58 ft 3.10 Ohm Wire Resistance Per 1000 Feet Z1-007.6.02 15cd SEFH-MC-W 0.064 168.42 ft 3.04 Ohm (R)Total Circuit Resistance(Both Legs) Z1-007-6-03 15cd SEFH-MC-W 0.064 145.75 ft 0.00 Amp (Is)Total Current Draw(Standby) 0.19 Amp (la)Total Current Draw(Alarm) 19.82 Volt (20.4-(lax R))Applied Voltage at Last Device' 0.58 Volt (VD)Voltage Drop 2.86% Percent Voltage Drop 9.60% Percent Current Draw Output-6 OUTPUT-7 LABEL CD MODEL STANDBY ALARM DISTANCE Voltage Drop a Vito L•R•la FACP-01 ZIC-8B ir!"=e 498.92 Ft (L)Total Circuit Length(One Leg) 21.007.7-01 15cd SEFH-MC-W 0.C44 18567ft 3.10 Ohm Wire Resistance Per 1000 Feet 21.007.7-02 15cd SEFH-MC-W 0064 168.00ft 3.09 Ohm (R)Total Circuit Resistance(Both Legs) 21-007.7.03 15cd SEFH-MC-W 0.064 145.25 ft 0.00 Amp (Is)Total Current Draw(Standby) 0.19 Amp (la)Total Current Draw(Alarm) 19.81 Volt (20.4-(la x R))Applied Voltage at Last Device' 0.59 Volt (VD)Voltage Drop 2.91% Percent Voltage Drop 9.60% Percent Current Draw Output-7 OUTPUT-8 LABEL CD MODEL STANDBY ALARM DISTANCE Voltage Drop=VD=L'R90 FACP-01 ZIC-8B _®.. `� '�q? he y�(ty,�?C1()ywi 508.92 Ft (I.)Total Circuit Length(One Leg) 21-007-8-01 15cd SEFH-MC-W 0.064 195.58ft 3.10 Ohm Wire Resistance Per 1000 Feet Z1-0074-02 15cd SEFH-MC-W 0.064 168.00ft 3.16 Ohm (R)Total Circuit Resistance(Both Legs) Z1-007-8-03 15cd SEFH-MC-W 0.064 145.33 ft 0.00 Amp (Is)Total Current Draw(Standby) 0.19 Amp (la)Total Current Draw(Alarm) 19.79 Volt (20.4-(la x R))Applied Voltage at Last Device' 0.61 Volt (VD)Voltage Drop 2.97% Percent Voltage Drop 9.60% Percent Current Draw Output-8 Note-1;24 Volt derated by 15%to 20.4 Volts. Note-2;Not Used. Note-3;Line Voltage Drop Calculation PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/5/2019 FACP-01 SIEMENS VOLTAGE DROP CALCULATIONS FIRE ALARM SUBMITTAL EMBASSY SUITES HOTEL FIRE ALARM UPGRADE FACP-01 PANEL 21C-8B CARD 15%Design Voltage Drop(20%Max Voltage Drop) 2.00 Amp Max Current Draw Per Output 16.00 Amp Max Current Draw Per Card 14AWG Wire Gauge 20.4 Volt Voltage at First Device' 21C-8B LOADS PANEL MODEL STANDBY ALARM ZIC-86 0.105 AMP 0.195 AMP FACP-01 VOLTAGE DROP CALCULATION RESULTS PERCENT STANDBY ALARM PERCENT OUTPUT VOLTAGE CURRENT CURRENT CURRENT LABEL VOLTAGE DROP DROP DRAW DRAW DRAW OUTPUT-1 Z1-008-1- 0.84 Volt 4.10% 0.00 Amp 0.26 Amp 12.80% 8th Floor Strobe OUTPUT-2 Z1-008-2- 0.85 Volt 4.17% 0.00 Amp 0.26 Amp 12.80% 9th Floor Strobe OUTPUT-3 Z1-008-3- 0.00 Volt 0.00% 0.00 Amp 0.00 Amp 0.00% Spare OUTPUT-4 Z1-008d- 0.00 Volt 0.00% 0.00 Amp 0.00 Amp 0.00% Spare OUTPUT-5 Z1-008-5- 0.00 Volt 0.00% 0.00 Amp 0.00 Amp 0.00% Spare OUTPUT-6 21-008-6- 0.00 Volt 0.00% 0.00 Amp 0.00 Amp 0.00% Spare OUTPUT-7 21-008-7- 0.00 Volt 0.00% 0.00 Amp 0.00 Amp 0.00% Spare OUTPUT-8 Z1-008-8- 0.00 Volt 0.00% 0.00 Amp 0.00 Amp 0.00% Spare Total Current Draw 0.00 Amp 0.51 Amp 3.20% FACP-01 VOLTAGE DROP CALCULATIONS OUTPUT-1 LABEL CD MODEL STANDBY ALARM DISTANCE Alarm Voltage Drop=VD=Rx la FACP-01 ZIC-BB '_� Yt'JC '«'S;x r 1,. )Lrj 527.50 Ft (L)Total Circuit Length(One Leg) Z1-008-1-01 15cd SEFH-MC-W 0.064 205.58ft 3.10 Ohm Wire Resistance Per 1000 Feet 21-008-1.02 15cd SEFH-MC-W 0.064 169.42ft 3.27 Ohm (R)Total Circuit Resistance(Both Legs) 21-008-1-03 15cd SEFH-MC-W 0.064 86.67 ft 0.00 Amp (Is)Total Current Draw(Standby) 21-008-1-04 15cd SEFH-MC-W 0,064 65.83ft 0.26 Amp (la)Total Current Draw(Alarm) 19.56 Volt (20.4-(lax R))Applied Voltage at Last Devices 0.84 Volt (VD)Voltage Drop 4.10% Percent Voltage Drop 12.80% Percent Current Draw Output-1 PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/5/2019 FACP-01 VOLTAGE DROP CALCULATIONS CONTINUED OUTPUT-2 LABEL CD MODEL STANDBY ALARM DISTANCE Voltage Drop=VD=L'R'la FACP.01 ®IBIEMIIM®I lEMEM(L)Total Circuit Length(One Leg) Z1-008.2.01 ®SEFH-MC-W 0.064 215.58 ft "®Wire Resistance Per 1000 Feet Z1-008-2-02 ®SEFH-MC-W 0.064 168.75 ftEECEMII Z1-008-2-03 II'EEM®-0.064 86.00 0 0.00 Amp Z1-008-2-04 ®ME r r. '®' - ------�(20A- la x R ••lied Volta•a at Last Device' ------ • Volta•e Drop --1 EIE Percent Volta,a Dro• MM..= M.1.11111111==.11111IEEMIME Percent Current Draw Output-2 ------ OUTPUT-3 LABEL CD MODEL STANDBY ALARM DISTANCE Voltage Drop=VD=L'R'la FACP-01 ZIC-8B 0.00 Ft I(L)Total Circuit Length(One Leg) 3.10 Ohm Wire Resistance Per 1000 Feet 0.00 Ohm (R)Total Circuit Resistance(Both Legs) 0.00 Amp (Is)Total Current Draw(Standby) 0.00 Amp (la)Total Current Draw(Alarm) 20.40 Volt (20.4-(la x R))Applied Voltage at Last Device' 0.00 Volt (VD)Voltage Drop 0.00% Percent Voltage Drop 0.00% Percent Current Draw Output.3 OUTPUT-4 ,,•• ..__<. .... .. LABEL CD MODEL STANDBY ALARM DISTANCE Voltage Drop=VD=L'R'la FACP-01 {;ZIC-88 0.00 Ft (L)Total Circuit Length(One Leg) 3.10 Ohm Wire Resistance Per 1000 Feel 0.00 Ohm (R)Total Circuit Resistance(Both Legs) 0.00 Amp (Is)Total Current Draw(Standby) 0.00 Amp (la)Total Current Draw(Alarm) 20.40 Volt (20.4-(lax R)(Applied Voltage at Last Device' 0.00 Volt (VD)Voltage Drop 0.00% Percent Voltage Drop 0.00% Percent Current Draw Outpubd OUTPUT.5 LABEL CD a MODEL STANDBY ALARM DISTANCE Voltage Drop•VD•R x la FACP-01 ib ZIC-8B :?:- " _` € 0.00 Ft (L)Total Circuit Length(One Leg) 3.10 Ohm Wire Resistance Per 1000 Feet 0.00 Ohm (R)Total Circuit Resistance(Both Legs) 0.00 Amp (Is)Total Current Draw(Standby) 0.00 Amp (la)Total Current Draw(Alarm) 20.40 Volt (20.4-(la x R))Applied Voltage at Last Device' 0.00 Volt (VD)Voltage Drop 0.00% Percent Voltage Drop 0.00% Percent Current Draw Output-5 PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/5/2019 FACP-01 VOLTAGE DROP CALCULATIONS CONTINUED OUTPUT-0 LABEL CD MODEL STANDBY ALARM DISTANCE Voltage Drop•VD•L•Rla FACP-01 ZIC-88 _. 000 Ft (L)Total Circuit Length(One Leg) 3.10 Ohm Wire Resistance Per 1000 Feet 0.00 Ohm (R)Total Circuit Resistance(Both Legs) 0.00 Amp (Is)Total Current Draw(Standby) 0.00 Amp (la)Total Current Draw(Alarm) 20.40 Vol (20.4-(lax R))Applied Voltage at Last Device' 0.00 Volt (VD)Voltage Drop 0.00% Percent Voltage Drop 0.00% Percent Current Draw Output-8 OUTPUT-7 LABEL CD MODEL STANDBY ALARM DISTANCE Voltage Drop•VD=L`R'la FAOP-01 ZIC-SB 0.00 Ft (L)Total Circuit Length(One Leg) 3.10 Ohm Wire Resistance Per 1000 Feet 0.00 Ohm (R)Total Circuit Resistance(Both Legs) 0.00 Amp (Is)Total Current Draw(Standby) 0.00 Amp (la)Total Current Draw(Alarm) 20.40 Volt (20.4-(la x R))Applied Voltage at Last Device' 0.00 Volt (VD)Voltage Drop 0.00% Percent Voltage Drop 0.00% Percent Current Draw Output-7 OUTPUT-8 LABEL CD MODEL STANDBY ALARM DISTANCE Voltage Drop•VD L`R9a FACP-01 ZIGBB 0.00 Ft (L)Total Circuit Length(One Leg) 3.10 Ohm Wire Resistance Per 1000 Feet 0.00 Ohm (R)Total Circuit Resistance(Both Legs) 0.00 Amp (Is)Total Current Draw(Standby) 0.00 Amp (la)Total Current Draw(Alarm) 20.40 Volt (20.4-(la x R))Applied Voltage at Last Device. 0.00 Volt (VD)Voltage Drop 0.00% Percent Voltage Drop 0.00% Percent Current Draw Output-8 Note-1;24 Volt derated by 15%to 20.4 Volts. Note-2;Not Used. Note-3;Line Voltage Drop Calculation PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/50019 FARP-02 BATTERY CALCULATIONS SIEMENS FIRE ALARM SUBMITTAL i EMBASSY SUITES HOTEL _-- '( r nderXLs FIRE ALARM UPGRADE Requited Battery Capacity with 20%Reserve(AH]'. 61.95 Power Calculations Battery Calculations 24V 6.2V Screw Terminal 24V Module Device Description Dry Backplane Backplane Current(mA) Standby 24 VDC Current Current Curren) Standby Alarm (mA) (mA) AIC Audio Input Card • 0.0 0.0' 0.0 ALCC Audio Level Conversion Card 0.0 0.0 0.0 CDC/A Conventional Detector 5o'.0 the CDC-0 cheer(daub e click) 0.0 0.0 0.0 0.0 0.0 0.0 ORC6 Control Relay Card 0.0 0.0 0.0 Relay Active Farm C Relay 0.0 0.0 0.0 D2300CP Fiber Opr.v Interface 00 0.0 0.0 D2325CP5 00 00 00 DAC Digital Audio Card 00 OP DM Digital Dialer Optic 0.0 0.0 00 DEM D-NET Fiber Optic Module 0.0 0.0 0.0 OLC Device Loop Card 0.0 00, 0.0 00 HFP-11 Phote-therrnal detector 001 0.0 00 IHFPT-11 Thermal detector 0.0i 0.0 00 IOOHC941 Dual opticalbhemrel/CO detector I On] 0.0 0.0 100H941 Dual optical/thermal detector 1 00 0.0 00 OH921 Photo-tnennal detector 001, 0.0 0.0 0P921 Photo detector cl.a 0.0 00 H1921 Thermal detector 00 0.0 0.0 FDOOTC441 Dual optical/themtaltCO detector 00 0.0 00 FDOOT441 Dual optical/thermal detector 0.0 00 00 FDOT421 Photo-thermal detector 00 00 0.0 FD0421 Photo detector 00 00 0.0 FDT42t Thermal detector 0.0 0.0 0.0 FOLIO A 2-Inputl4output module 0.0 0.0 0.0 FDCIOB 4-Input/4-output module 0.0 PC 0.0 HMS-25 Manual station 0.0 00 no HMS-5 Manual station 0.0 0.0 0.0 HMS-M Manual station 0.0 0.0 0.0 HMS-SA Manual station 0.0 DC 0.0 HMS-0 Manual station 00 00 00 HTRI-S Sinole input module 00 0.0 0.0 HTRI-D Dual Input module 0.0 0.0 0.0 HTRI-R Singl input/single relay module 00 00 0.0 HTRI-M Singleirrput mini module 0.0 0.0 0.0 HZM Conventional zone module 0.0 0.0 0.0 HCP Addressable control point _ 0.0 0.0 0.0 ILED-HO Intelligent LED 0.0 0.0 0.0 Intelligent LED _ 0.0 0.0 0.0 Other 0.0 0.0 0.6 ECM Fan Control Mpdule. 0.0 0.0 0.0 Active FCM SVAtcnee 0.0 0.0 0.0 EMT Firefighter Mester Telephone 00 00 0.0 FN2006 Fiber Optic Module 00 00 0.0 HUB-4] Fiber ommuniOptic Module 00 00 D.0 HUB-4 Communication Module-4 ports 00 0.0 0.0 0.0 LCM LED Control Module 0.0 00 00 LED Active l_ED's 0.0 0.0 0.0 LPB Local Page Board 0.0 0.0 0.0 LVM Live Voice Module 0.C, 0.0 0.0 Active Switch 0.0 0.0 00 MLC 0.0 0.0 OO, 0.0 0.0 CZM-1 Remote Conventional Zone Module 00' 0.0 0.0 FP-11 Photosensensor detector O.Oi 0.0 0.0 FPT-11 Photo and thermal.detector PO i 0.0 0.0 CP25 Intelligent control point 0.0' 0.0 0.0 CPA) 0.0 0.0 0.0 D-001 Intelligent thermal detector 0.0 0.0 0.0 10-001A 0.0 0.0 0.0 i0-601H 0.0 0.0 0.0 D-6OIAH 0.0 0.0 0.0 0-6010 00 0.0 00 0-6OIBH 00 0.0 00 0-CoP 00 00 0.0 D-COED 00 0.0 0.0 D-COPT i 00 00 0.0 0-60T 0.0 0.0 0.0 LI-1)-1H Ionizaton detector(0-300 ft./min.1 0.0 00 0.0 LI-1A/-1AH 0.0 0.0 0.0 LI-10/-1BH 00 0.0 0.0 LP-1/1LPT-1 Photoe`ectric detector I 00 00 0.0 LP-2 i 0.0 CO 0.0 MSI-11-2 Intelligent manual station 0 0 0 0 0.0 TRI-60 Interface single-input module 00 00 00 TRI-600 InteAddressable i dual-input a 0 0 0.0 0.0 TRI-60R Addressable interace module 00 00 00 Other 0.0 0.0 C.0 MLC E# M%I.Line Card FM O.D 0.0 C.0 Power Calculations Battery Calculations 24V 6.2V Screw Terminal 24V Module Device Description qty Backplane Backplane Current(mA) Standby 24 VDC Current Current Current (NA) (mA) Standby Alarm SIC Network Interface Card 1 120.0 120.0 SIC Xnet Network Interface Card Xnet 0.0 00 NIM 1W Network interface Module-Wide Area 0.0 0.0 0.0 NRC Network Ring Card 0.0 0.0 0.0 OCM Output Control Module - _ 0.0i 0.0 0.0 Active Open Cnllnetor 0.0 0.0 0.0 PMI Control Panel 0.0 0.0 TSP-40A Thermal Strip Printer 00 0.0 0.0 PMI-2 Control Panel _ 0.0 0.0 _TSP-40A Thermal Strip Primer 0.0 D.0 0.0 RNI Remote Network Interface 0.0 0.0, 0.0 RPM See Note 2 Remote Printer Module 0.0 0.0 CO SCM Switch Control Module 0.0 0.0 0.0 Switch Active Pushbutton 5wntch 0.0 0.0 00 SIM .Supervised Input Module 0.0 0.0 0.0 SIM device .SIM Input __ 0.0 0.0 0.0 SIM RelaylayRelay 0,0 0.0 0.0 SSD System Status Display 0.0 0.0 0.0 TZC Telephone Zone Card CO 0.0 0.0 VPM See Note2 Vesda Peripheral Module 0.0 0.0 0.0 iHLI(See Note 2) Nigh Level Interface card , 0.0 0.0 0.0 XDMC XLS Digital Message Card 0.0: 0.0' 0.0 ZAC40 i Zone Amplifier Card-40W 8 _ 1200.0 1200.0 1206.0 Total Speaker Wattage 256 13568.0 ZAC40Backup Zone Amplifier Card-40W 0.0 0.0 ZAM120 Zone Amplifier Card-120W 0.0 0.0 0.0 Total Speaker Wattage 0.0 ZAM120Beckup Zone Amplifier Gard-120W 0.0 0.0 Total ZICs Zone Indicating Cards Go to Ihs ZIC client!double click) 723-0 0.0 0.0 5000.0 315.0 PSC-12 Power Supply Curd 288 Walls 1 _._ 150.0 i-..... PSG Relay Active Relay on the PSG 0 _ 0.0 See Note AUX Standby Current(nAl on A.C. 1 1.0 __- -- SeeNotel AUX Alarm Current[I on A.C. 1.0 See Note l AUX Standby Cu nt nn Battery lmAl _ 1.0 See Note 1 AUX Alarm Curren.on Battery(mA] 1 PSX-12 ,Power Supple Extender 298 Watts 1 150.0 See Natal i A UX Standby Current[mAl on A.C. 1.0 See Note __.. AUX Alarm CucentfmAl on A.G. 1.0 See Note 1 AUX Ala of on Battery) 1.0 See Note AUX Alarm Current on Rattervy ImA) ! - -- Total(A] 1 0.8430 0.0000 1.2020 107700 1.9450 Power Supply Limits Parameter Max value Actual value I Result 24V Backplane Current 2A 0.843 OK 6.2V Backplane Current 2A 0.000 I OK Total 24V Standby Current 10 1322 _ _ OK Total 24V Alarm Current 12A•Numbered PS 20.613 OK Battery Calculation Max Standby[Hrn) __. _ 24 Max Alarm Win] 15 Battery capacity reserve 1%1 20 Required Battery Capacity[ANI: 51.02 Required Battery Capacity with 20%Reserve[AU]: 61.95 Note 1:For each HCP,HZM,CZM-1,ICP25 6,ICP70 add the tollovimg current to each PSC-12IPSX-12 AUX power entry if these devices are receiving power tram this PSC-12IPSX-12. HCP HZM CZM-1 ICP25 ICP70 AUX Standby Cerrent(nrA] i1 30mA 76 mA 12.5 mA 10mA 10 mA AUX Alarm CurrentlmAl 30mA 100 mA 50mA 10mA 10mA AUX Standby Curren:on Battery(mA] 30 mA 78 mA 12.5 mA 10 mA 10 mA AUX Alarm Current on Battery[mA] 30 mA 100 mA 50 teA 10 mA 10 mA Note 2:Only include ills module if it is being powered by a PSC-12 or PSX-12 in this enclosure,otherwise leave the quantity as 0. FIRE ALARM SYSTEM 3 AUDIO db LOSS CALCULATIONS FACP-01 SIEMENS db LOSS CALCULATIONS FIRE ALARM SUBMITTAL EMBASSY SUITES HOTEL FIRE ALARM UPGRADE FACP-01 AMP Panel ZAC-40 AMP Model ZAC-40 AMP Model 40 Watt Max Wattage Per Output 0.50 dB Max dB Loss 40 Watt Max Wattage Per AMP 14 AWG Wire Gauge 70 VRMS (V)Audio Voltage db LOSS CALCULATION RESULTS PERCENT OUTPUT TOTAL OUTPUT LABEL db LOSS WATTS LOAD OUTPUT 1 A1-08A- 0.00 dB 1.50 Watts 3.75% Elevator-1,2,3 Speakers OUTPUT 2 A1-068- 0.00 dB 0.50 Watts 1.25% Elevator-4 Speaker Total Watts 2.00 Watts 5.00% db LOSS CALCULATIONS LABEL WATT MODEL db LOSS db Loss=201o910(RLI(RL+RW)) FACP-01 ZAC-40 A1-06A-01 uu'1/2W SEFH-W .001 dB 70 VRMS (V)Audio Voltage A1-06A-02 1/2W SEFH-W 001 dB 3.14 Ohm (R)Wire Resistance Per 1000 Feet A1-06A-03 1/2W SEFH-W .002 dB 101.92 Ft (L)Total Circuit Length(One Leg) 3268.67 (RL)Load Resistance=V"2IW 1.02 Ohm (FM)Circuit Resistance=R`122(Both Legs) 1.50 Watt (W)Total Circuit Wattage 0.00 dB Total Circuit Signal Loss dB Loss=20log10(RL/(RL+RW)) 3.75% Percent Output Load PROPRIETARY DOCUMENT FOR APPROVAL ONLY 1 2/612 01 9 db LOSS CALCULATIONS CONTINUED LABEL WATT MODEL db LOSS db Loss=201og10(RU(RL*RW)) FACP-01 'I ZAC-40 A1-06B.01 1/2W SEFH-W .001 dB 70 VRMS (V)Audio Voltage 3.14 Ohm (R)Wire Resistance Per 1000 Feet 187.83 Ft (L)Total Circuit Length(One Leg) 9800.00 (RL)Load Resistance=V=2/W 1.18 Ohm (RW)Circuit Resistance=R'L'2(Both Legs) 0.50 Watt (W)Total Circuit Wattage 0.00 d8 Total Circuit Signal Loss dB Loss=2glog10(RU(RL+RW)) 1.25% Percent Output Load PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/6/2019 FACP-01 db LOSS CALCULATIONS SIEMENS FIRE ALARM SUBMITTAL EMBASSY SUITES HOTEL FIRE ALARM UPGRADE FACP-01 AMP Panel ZAC.40 AMP Model ZAC-40 AMP Model 40 Watt Max Wattage Per Output 0.50 dB Max dB Loss 40 Watt Max Wattage Per AMP 14 AWG Wire Gauge 70 VRMS (V)Audio Voltage db LOSS CALCULATION RESULTS PERCENT OUTPUT TOTAL OUTPUT LABEL db LOSS WATTS LOAD OUTPUT I A1-07A.: -0.09 dB 10.50 Watts 26.25% 1st Floor Speakers West OUTPUT 2 AI-0713- -0.02 dB 4.50 Watts 11.25% Stair-1 Speakers Total Watts 15.00 Watts 37.50% db LOSS CALCULATIONS LABEL WATT MODEL db LOSS db Loss=20logl0(RLI(RL+RW)) FACP-01 sM ZAC-40 A1-07A-01 i/2W SEFH-CW 000 dB 70 VRMS (VI Audio Voltage A1-07A-02 1!2W SEFH-CW 001 dB 3.14 Ohm (R)Wire Resistance Per 1000 Feet A1-07A-03 1/2W SEFH-CW .002 dB 742.33 Ft (L)Total Circuit Length(One Leg) AI-07A-04 1/2W SEFH-CW .004 dB 466.67 (RL)Load Resistance=V"21W A1-07A-05 1/2W SEFH-CW .005 dB 4.66 Ohm (RW)Circuit Resistance=R*L'2(Both Legs) AI-07A-06 12W SEFH-CW .007 dB 10.50 Watt ON)Total Circuit Wattage A1-07A-07 1/2W SEFH-CW .011 dB Total Circuit Signal Loss A1-07A-08 1/2W SEFH-CW .014 dB -0.09 dB dB Loss=201og10(RLJ(RL+RW)) AI-07A-09 1/2W SEFH-CW .017 dB 26.25% Percent Output Load AI-07A-10 1/2W SEFH-CW .020 dB A1-07A-11 1/2W SEFH-CW .025 dB Af-07A-12 1/2W SEFH-CW .028 dB A1-07A-13 1/2W SEFH-CW .036 dB A1-07A-14 1/2W SEFH-CW .040 dB A1-07A-15 1/2W SEFH-CW .044 dB A1-07A-16 1/2W SEFH-CW .049 dB A1-07A-17 1/2W SEFH-CW .054 dB AI-07A-18 1/2W SEFH-CW .064 dB A1-07A-19 1/2W SEFH-CW .070 dB A1-07A-20 1/2W SEFH-CW .076 dB AI-07A-21 1/2W SEFH-CW .086 dB PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/6/2019 db LOSS CALCULATIONS CONTINUED LABEL WATT MODEL db LOSS db Loss=201og10(RL!(RLtRW)) FACP-01 R';2AC-40 At-07B-01 ti `12W SEFH-MC-W 001 dB 70 VRMS m(V)Audlo Vogage At-07B-02 1/2W SEFH-W .002 dB 3.14 Ohm (R)Wire Resistance Per 1000 Feet Al-g7B-3 1/2W SEFH-W .004 dB 328.00 Ft (L)Tot I Circuit Length(One Leg) Ai-07B-04 1/2W SEFH-W .005dB 1088.89 (RL)Loed Resistance=V"2/W At-07B-05 1/2W SEFH-W .007dB 2.06 Ohm (RW)Circuit Resistance.R'L'2(Both Legs) At-07B-08 1/2W SEFH-W .008 dB 4.50 Watt (W)Total Circuit Wattage At-07B-07 1/2W SEFH-W .010 dB Total Circuit Signal Loss A7-g7B-08 112W SEFH-W .012 dB -0.02 de dB Loss=20log10(RL/(RL+RW)) A1-078-09 1/2W SEFH-W .014 dB 11.25% Percent Output Load PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/6/2019 . FACP-01 SIEMENS db LOSS CALCULATIONS FIRE ALARM SUBMITTAL EMBASSY SUITES HOTEL FIRE ALARM UPGRADE FACP-01 AMP Panel ZAC40 AMP Model ZAC-40 AMP Model 40 Watt Max Wattage Per Output 0.50 dB Max dB Loss 40 Watt Max Wattage Per AMP 14 AWG Wire Gauge 70 VRMS (V)Audio Voltage db LOSS CALCULATION RESULTS PERCENT OUTPUT TOTAL OUTPUT LABEL db LOSS WATTS LOAD OUTPUT 1 Al-08A-; -0.19 dB 16.00 Watts 40.00% 1st Floor Speakers East OUTPUT 2 Al-08B- -0.01 dB 4.50 Watts 11.25% Stair-2 Speakers Total Watts 20.50 Watts 51.25% db LOSS CALCULATIONS LABEL WATT MODEL db LOSS db Loss=20Iog10(RLI(RL+RW)) FACP-01 .... ZAC-40 A1-08A-01 12W SEFH-CW 007 dB 70 VRMS (V)Audio Voltage A1-08A-02 1/2W SEFH-CW .001 dB 3.14 Ohm (R)Wire Resistance Per 1000 Feel A1-08A-03 1/2W SEFH-CW .002 dB 1,050.00 Ft (L)Total Circuit Length(One Leg) A1-08A-04 1/2W SEFH-CW .004 dB 306.25 (RL)Load Resistance=V^21W A1-08A-05 1/2W SEFH-CW .006 dB 6.59 Ohm (RW)Circuit Resistance=R1122(Both Legs) A1.08A-06 1/2W SEFH-CW .008 dB 16.00 Watt (W)Total Circuit Wattage A1-08A-07 1/2W SEFH-CW .011 dB Total Circuit Signal Loss A1-08A-08 1/2W SEFH.CW .014 dB -0.19 dB dB Loss=201og10(R1../(RL+RW)) Al-08A-09 1/2W SEFH-CW .017 dB 40.00% Percent Output Load A1.08A.10 1/2W SEFH-CW .022 dB A1.00A-11 1/2W SEFH-CW .025 dB A1.06A-12 1/2W SEFH-CW .029 dB A7-08A-13 1/2W SEFH-CW .032 dB Al-08A-14 1/2W SEFH-CW .036 dB A7-06A-15 1/2W SEFH-CW .041 dB A1-08A-16 1/2W SEFH-CW .046 dB A7-08A-17 1/2W SEFH-CW .052 dB A1-08A-18 1/2W SEFH-CW .058 dB A1418A-19 1/2W SEFH-CW .065 dB A1-08A-20 1/2W SEFH-CW .070 dB A1-08A-21 1/2W SEFH-CW .076 dB A1-08A-22 112W SEFH-CW .083 dB AI-08A-23 1/2W SEFH-CW .091 dB Al-08A-24 1/2W SEFH-CW .098 dB AI-0BA-25 1/2W SEFH-CW .108 dB A1-08A-26 12W SEFH-CW .116 dB A1-08A-27 1/2W SEFH-CW .125 dB A1-08A-28 1/2W SEFH-CW 136 dB A1-08A-29 1/2W SEFH-CW .146 dB A1-08A-30 1/2W SEFH-CW .160 dB Al-08A-01 12W SEFH-CW .170 dB A1-08A-32 1/2W SEFH-CW .185 dB PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/6/2019 db LOSS CALCULATIONS CONTINUED LABEL WATT MODEL db LOSS db Loss=20Iog10(RU(RL+RW)) FACP-Bt ZAC-40 I ._ sa g t i1'§1 d t3{1i1s`,ei+lirT $1 AIABB-0i ti 1/2W SEFH-MC-W 000 dB 70 VRMS (V)Audio Voltage At-OBB-02 1/2W SEFH-W .001 dB 3.14 Ohm (R)Wlre Reslstance Per 1000 Feet A7-OBB-03 1/2W SEFH-W .001 dB 203.08 Ft (L)Total Cir oit Length(One Leg) A7.080-04 1/2W SEFH-W .002 dB 1088.89 (RL)Load Resistance=V"2/W A7-OBB-0S 1/2W SEFH-W .003 dO 1.28 Ohm (RW)Circult Reslstance=R•L•2(Both Legs) A7-OBB-06 1/2W SEFH-W .004 dB 4.50 Watt (N)Total Circuit Wattage A7.0813-07 1/2W SEFH-W .005 dB -0.01 dB Total Circuit Signal Loss A7-OBB-OB 1/2W SEFH-W .006 dB dB Loss•281og10(RU(RL•RV/)) Al-OBE-09 1/2W SEFH-W 007 dB 11.25% Percent Output Load PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12l6/2019 FACP-02 SIEMENS db LOSS CALCULATIONS FIRE ALARM SUBMITTAL EMBASSY SUITES HOTEL FIRE ALARM UPGRADE FACP-02 AMP Panel ZAC-40 AMP Model ZAC-40 AMP Model 40 Watt Max Wattage Per Output 0.50 dB Max dB Loss 40 Watt Max Wattage Per AMP 14 AWG Wire Gauge 70 VRMS M Audio Voltage dh LOSS CALCULATION RESULTS PERCENT OUTPUT TOTAL OUTPUT LABEL dh LOSS WATTS LOAD OUTPUT 1 A2-01A- -0.14 dB 9.50 Watts 23.75% 2nd Floor Speakers East OUTPUT 2 A2-018- -0.13 dB 8.50 Watts 21.25% 2nd Floor Speakers West Total Watts 18.00 Watts 45.00% dh LOSS CALCULATIONS LABEL WATT MODEL rib LOSS dh Loss=20log1011,1I I(RL+RW)) FACP-02 1,32AC-40 A2411A-01 1/2W G-'SEFHCW 00h OH 70 VRMS (V)Audio Voltage A2-01A-02 1/2W SEFH-W 011 dB 3.14 Ohm (R)Wire Resistance Per 1000 Feet A2-01A-03 1/2W SEFH-MC-W .017 dB 1,316.00 Fl (L)Total Circuit Length(One Leg) A2-01A-04 1/2W SEFH-CW .023 dB 515.79 (RL)Load Resistance=Vs2/W A2-01A-05 1/2W SEFH-CW .030 dB 8.26 Ohm (RW)Circuit Resistance=R*L•2(Both Legs) A2-01A-06 1/2W SEFH-CW .036 dB 9.50 Walt (W)Total Circuit Wattage A2-01A-07 1/2W SEFH-CW 043 dB Total Circuit Signal Loss A2-01A-08 1/2W SEFH-CW .049 dB -0.14 dB dB Loss=201og10(RU(RL+RW)) A2.01A-09 1/2W SEFH-CW .057 dB 23.75% Percent Output Load A2-01A-10 1/2W SEFH-CW .063 dB A2-01A-11 1/2W SEFH-CW .071 dB A2-01A-12 1/2W SEFH-CW .078 dB A2-01A-13 1/2W SEFH-CW .086 dB A2-01A-14 1/2W SEFH-CW .093 dB A2-01A-15 1/2W SEFHCW .101 dB A2.01A-16 1/2W SEFH-CW .108 dB A2.01A-17 1/2W SEFH-CW .117dB A2.01A-18 1/2W SEFH-W .127 dB A2-01A-19 1/2W SEFH-MC-W .136 dB PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/6/2019 db LOSS CALCULATIONS CONTINUED LABEL WATT MODEL db LOSS db Loss=201og10(RL/(RIA-RW)) FACP-32 ,� ZAC-40 A2-01B-01 1/2W SEFH-CW .006 dB 70 VRMS (V)Audio Voltage A2-01B-02 1/2W SEFH-CW .012 dB 3.14 Ohm (R)Wire Resistance Per 1000 Feet A2-018-03 1/2W SEFH-CW .018 dB 1,394.42 Ft (L)Total Circuit Length(One Leg) A2-01B-04 1/2W SEFI+CW .024 dB 576.47 (RL)Load Resistance•V"2/W A2-0113-05 1/2W SEFH-CW .031 dB 8.76 Ohm (RW)Circuit Resistance=R1L12(Both Legs) A2-01B-06 1/2W SEFH-CW .038 dB 8.50 Watt (W)Total Circuit Wattage A2-0113-07 1/2W SEFH-CW .044 dB Total Circuit Signal Loss A2-01B-08 1/2W SEFH-CW .052 dB -0,13 dB dB Lossn2olog10(RLI(RL+RW)) A2-01B-09 1/2W SEFH-CW .060 dB 21.25% Percent Output Load A2-01B-10 1/2W SEFH-CW .068 dB A2-01B-11 1/2W SEFH-MC-W .075 dB A2-0113-12 12W SEFH-CW .085 dB A2-01B-13 1/2W SEFH-CW .094 dB A2411B-14 1/2W SEFH-CW .102 dB A2-018-15 1/2W SEFH-CW .112 dB A2-01B-16 1/2W SEFH-CW .120 dB A2.01B-07 1/2W SEFH-CW .130 dB PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/6/2019 FACP-02 SIEMENS db LOSS CALCULATIONS FIRE ALARM SUBMITTAL EMBASSY SUITES HOTEL FIRE ALARM UPGRADE FACP-02 AMP Panel ZAC.40 AMP Model ZAC-40 AMP Model 40 Wall Max Wattage Per Output 0.50 dB Max dB Loss 40 Watt Max Wattage Per AMP 14 AWG Wire Gauge 70 VRMS (V)Audio Voltage db LOSS CALCULATION RESULTS PERCENT OUTPUT TOTAL OUTPUT LABEL db LOSS WATTS LOAD OUTPUT 1 A2-02A- -0.14 dB 9.50 Watts 23.75% 3rd Floor Speakers East OUTPUT 2 A2-02B:-:: -0.13 dB 8.50 Watts 21.25% 3rd Floor Speakers West Total Watts 18.00 Watts 45.00% db LOSS CALCULATIONS LABEL WATT MODEL db LOSS db Loss=20Iog10(RL/(RL+RW)) FACP-02 ••y ZAC-40 A2-02A-01 1/2W SEFH-CW 005 dB 70 VR MS [V)Audio Voltage A2-132A412 1/2W SEFH-W 011 dB 3.14 Ohm (R)Wire Resistance Per 1000 Feet A2-02A-03 1/2W SEFH-MC-W .017 dB 1,329.08 Ft (L)Total Circuit Length(One Leg) A2-02A-04 1/2W SEFH-CW .023 dB 515.79 (RL)Load Resistance=Va2AN A2-02A-05 1/2W SEFH-CW .030 dB 8.35 Ohm (RW)Circuit Resistance=R'L`2(Both Legs) A2-02A-06 1/2W SEFH-CW .037 dB 9.50 Watt (W)Total Circuit Wattage A2-02A-07 1/2W SEFH-CW .043 dB Total Circuit Signal Loss A2-02A-08 1/2W SEFH-CW .050 dB -0.14 dB dB Loss=20Iog10(R1../(RL«RW)) A2-02A-09 1/2W SEFH-CW .057 dB 23.75% Percent Output Load A2-02A-10 1/2W SEFH-CW .064 dB A2-02A-11 12W SEFH-CW .071 dB A2-02A-12 1/2W SEFH-CW .078 dB A2-02A-13 1/2W SEFH-CW .086 dB A2-02A-14 12W SEFH-CW .094 dB A2-02A-15 1/2W SEFH-CW .102 dB A2-02A-16 1/2W SEFH-CW .109 dB A2-02A-17 1/2W SEFH-CW .118 dB A242A-18 1/2W SEFH-W .128 dB A2-02A-19 1/2W SEFH-MC-W .137 dB PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/6/2019 db LOSS CALCULATIONS CONTINUED LABEL WATT MODEL db LOSS db Loss=201og10(RU(RL+RW)) FACP-02 ZAC-40 A2-028.O1 1:,1/2W SEFH-CW OlIN dB 70 VRMS (V)Audio Voltage A2-028-02 1/2W SEFH-CW .012 dB 3.14 Ohm (R)Wire Resistance Per 1000 Feet A2-02B-03 1/2W SEFH-CW .018 dB 1,404.42 Ft (L)Total Circuit Length(One Leg) A2-02B-04 1/2W SEFH-CW .024 dB 576.47 (RL)Load Resistance=V12IW A2-0213-05 1/2W SEFH-CW .031 dB 8.82 Ohm (FAN)Circuit Resistance=R•L12(Both Legs) A2-02B-06 1/2W SEFH-CW .036 dB 8.50 Watt (W)Total Circuit Wattage A2-02B-07 1/2W SEFH-CW 045 dB -0 t3 dB Total Circuit Signal Loss A2-02B-08 1/2W SEFH-CW .052 dB dB Loss=201og10(RU(RLtRW)) A2-02B-08 1/2W SEFH-CW .060 dB 21.25% Percent Output Load A2-02B-10 1/2W SEFH-CW .068 dB A2-02B-11 1/2W SEFH-MC-W .077 dB A2-02B-12 1/2W SEFH-CW .086 dB A2.02B-13 1/2W SEFH-CW 095 dB A2-02B-14 1/2W SEFH-CW .103 dB A2-02B-15 1/2W SEFH-CW 113dB A2-02B-16 112W SEFH-CW .121 dB A2-0261-17 1/2W SEFH-CW .131 dB PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/6/2019 FACP-02 SIEMENS db LOSS CALCULATIONS FIRE ALARM SUBMITTAL EMBASSY SUITES HOTEL FIRE ALARM UPGRADE FACP-02 AMP Panel 2AC-40 AMP Model ZAC-40 AMP Model 40 Watt Max Wattage Per Output 0.50 dB Max dB Loss 40 Watt Max Wattage Per AMP 14 AWG Wire Gauge 70 VRMS (V)Audio Voltage db LOSS CALCULATION RESULTS PERCENT OUTPUT TOTAL OUTPUT LABEL db LOSS WATTS LOAD OUTPUT 1 Ic A2-03A- -0.14 dB 9.50 Watts 23.75% 41h Floor Speakers East OUTPUT 2 A2-0313- -0.13 dB 8.50 Watts 21.25% 4th Floor Speakers West Total Watts 18.00 Watts 45.00% db LOSS CALCULATIONS LABEL WATT MODEL db LOSS db Loss=20log10(RL!(RL+RW)) FACP-02 ZAC-40 A2-03A-01 112V1/ SEFH-CW 036 dB 70 VRMS (V)Audio Voltage A2-03A-02 1/2W SEFH-W .011 dB 3.14 Ohm (R)Wire Resistance Per 1000 Feet A2-03A-03 1/2W SEFH-MC-W 018 dB 1,339.25 Ft (L)Total Circuit Length(One Leg) A2-03A-04 1/2W SEFH-CW .024 dB 515.79 (RL)Load Resistance=V"2/W A2-03A-05 1/2W SEFH-CW .030 dB 8.41 Ohm (RW)Circuit Resistance=R'C2(Both Legs) A2-03A-06 1/2W SEFH-CW .037 dB 9.50 Watt (W)Total Circuit Wattage A2-03A-07 1/2W SEFH-CW .044 dB -0.14 dB Total Circuit Signal Loss A2-03A-08 1/2W SEFH-CW .050 dB dB Loss=201og10(RL/(RL+RW)) A2-03A-09 1/2W SEFH-CW .058 dB 23.75% Percent Output Load A2-03A-10 1/2W SEFH-CW .064 dB A2-03A-11 1/2W SEFH-CW .072 dB A2-03A-12 1/2W SEFH-CW .079 dB A2-03A-13 12W SEFH-CW .087 dB A2-03A-14 12W SEFH-CW .094 dB A2-03A-15 1/2W SEFH-CW .103 dB A2-03A•16 1/2W SEFH-CW .110 dB A2-03A-17 1/2W SEFH-CW .119 dB A2-03A-18 1/2W SEFH-W .129 dB A2-03A-19 12W SEFH-MC-W .138 dB PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/62019 db LOSS CALCULATIONS CONTINUED LABEL WATT MODEL db LOSS db Loss=20Iog10(RLI(RL+RW)) FACP-02 ZAC-40 w , A2483641 i`1/2W SEFH-CW .006 dB 70 VRMS (V)Audio Voltage A2.038-02 1/2W SEFH-CW .012 dB 3.14 Ohm (R)Wire Resistance Per 1000 Feel A2-038-03 1/2W SEFH-CW .018 dB 1,414.42 Fl (L)Total Circuit Length(One Leg) A2-03B-04 1/2W SEFH-CW .025 dB 576.47 (RL)Load Resistance=V•21W A2-03B-05 1/2W SEFH-CW .031 dB 8.88 Ohm (RW)Circuit Resistance=R122(Both Legs) A2-036-06 1/2W SEFH-CW .038 dB 8.50 Walt (W)Total Circuit Wattage A2-038-07 1/2W SEFH-CW .045 dB -0.13 dB Total Circuit Signal Loss A2.638-08 1/2W SEFHCW .053 dB dB Loss=20Iog10(RU(RL+RW)) A2-03B-09 1/2W SEFH-CW .061 dB 21.25% Percent Output Load A2-03B-10 112W SEFH-CW .069 dB A2.03B-11 1/2W SEFH-MC-W .078 dB A2-036-12 1/2W SEFH-CW .086 dB A2-03B-13 1/2W SEFH-CW .096 dB A2-036-14 1/2W SEFH-CW .104 dB A2-036-15 1/2W SEFHCW .114 dB A2-036-16 1/2W SEFH-CW .122 dB A2-03B-17 1/2W SEFH-CW .132 dB PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/812019 FACP-02 SIEMENS db LOSS CALCULATIONS FIRE ALARM SUBMITTAL EMBASSY SUITES HOTEL FIRE ALARM UPGRADE FACP-02 AMP Panel ZAC-40 AMP Model ZAC-40 AMP Model 40 Watt Max Wattage Per Output 0.50 dB Max dB Loss 40 Watt Max Wattage Per AMP 14 AWG Wire Gauge 70 VRMS (V)Audio Voltage db LOSS CALCULATION RESULTS PERCENT OUTPUT TOTAL OUTPUT LABEL db LOSS WATTS LOAD OUTPUT 1 A2-04A- -0.14 dB 9.50 Watts 23.75% 5th Floor Speakers East OUTPUT 2 A2-04B- -0.13 dB 8.50 Watts 21.25% 5th Floor Speakers West Total Watts 18.00 Watts 45.00% db LOSS CALCULATIONS LABEL WATT MODEL db LOSS db Loss=201og10(RL/(RL+RW)) FACP-02 .-'.ZAC-40 A2-04A-01 1/2W SEFH-CW TOO dC 70 VRMS (V)Audio Voltage A2-04A-02 1/2W SEFH-W .012 dB 3.14 Ohm (R)Wire Resistance Per 1000 Feet A2-04A-03 1/2W SEFH-MC-W .018 dB 1,351.42 Ft (L)Total Circuit Length(One Leg) A2-04A-04 1/2W SEFH-CW .024 dB 515.79 (RL)Load Resistance=Ve2/W A2-04A-05 1/2W SEFH-CW .031 dB 8.49 Ohm (RW)Circuit ResIstance=R'L.2(Both Legs) A2-04A-06 112W SEFH-CW .037 dB 9.50 Watt (W)Total Circuit Wattage A2-04A-07 1/2W SEFH-CW .044 dB Total Circuit Signal Loss A2.04A-08 1/2W SEFH-CW .051 dB -0.14 dB dB Losse201og10(RL/(RL*RW)) A2-04A-09 1/21A/ SEFH-CW .058 dB 23.75% Percent Output Load A2-04A-10 1/2W SEFH-CW .065 dB A2-04A-11 1/2W SEFH-CW .073 dB A2-04A-12 1/2W SEFH-CW .080 dB A2-04A-13 1/2W SEFH-CW .088 dB A2-04A-14 12W SEFH-CW .095 dB A2-04A-15 12W SEFH-CW .104 dB A2-04A.16 12W SEFH-CW .111 dB A2-04A-17 1/2W SEFH-CW .120 dB A2-04A-18 1/2W SEFH-W .130 dB A2-04A-19 1/2W SEFH-MC-W .139 dB PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/8/2019 db LOSS CALCULATIONS CONTINUED LABEL WATT MODEL db LOSS db Loss=20Iog10(RLI(RL+RW)) FACP-02 L ZAC-40 A2-04B-01 1/2W SEFH-CW OOS dB 70 VRMS (V)Audio Voltage A2.048-02 1/2W SEFH-CW .012 dB 3.14 Ohm (R)Wire Resistance Per 1000 Feet A2-048-03 1/2W SEFH-CW .018 dB 1,426.08 Ft (L)Total Circuit Length(One Leg) A2-048-04 1/2W SEFH-CW .025 dB 576.47 (RL)Load Resistance=V^21W A2-04B-05 1/2W SEFH-CW .031 dB 8.96 Ohm (RW)Circuit Resistance=R12'2(Both Legs) A2-048-06 1/2W SEFH-CW .039 dB 8.50 Watt (W)Total Circuit Wattage A2-04B-07 1/2W SEFH-CW .045 dB Total Circuit Signal Loss A2-04B-08 1/2W SEFH-CW .053 dB -0.13 de dB Lass=20Iog10(RL/(RL+RW)) A2-04B-09 1/2W SEFH-CW .061 dB 21.25% Percent Output Load A2.048.10 1/2W SEFH-CW .070 dB A2-04B-11 1/2W SEFH-MC-W .078 dB A2-048-12 1/2W SEFH-CW .087 dB A2-048-13 1/2W SEFH-CW 096 dB A2.048-14 1/2W SEFH-CW .105 dB A2.04B-15 1/2W SEFH-CW .114 dB A2.048.16 1/2W SEFH-CW .123 dB A2-048-17 1/2W SEFH-CW .133 dB PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/6/2019 . FACP-02 db LOSS CALCULATIONS SIEMENS FIRE ALARM SUBMITTAL EMBASSY SUITES HOTEL FIRE ALARM UPGRADE FACP.02 AMP Panel ZAC40 AMP Model ZAC-40 AMP Model 40 Watt Max Wattage Per Output 0.50 dB Max dB Loss 40 Watt Max Wattage Per AMP 14 AWG Wire Gauge 70 VRMS (V)Audio Voltage db LOSS CALCULATION RESULTS PERCENT OUTPUT TOTAL OUTPUT LABEL db LOSS WATTS WAD OUTPUT 1 A2-05A- -0.14 dB 9.50 Watts 23.75% 6th Floor Speakers East OUTPUT 2 A2-05B- -0.13 dB 8.50 Watts 21.25% 6th Floor Speakers West Total Watts 18.00 Watts 45.00% db LOSS CALCULATIONS LABEL WATT MODEL dh LOSS db Loss=201og10(RL/(RL+RW)) FACP-02 ZAC-40 A2.05A-01 1/2W SEFH-CW 000 dP 70 VRMS (V)Audio Voltage A2415A-02 1/2W SEFH-W 012 d0 3.14 Ohm (R)Wire Resistance Per 1000 Feet A2-05A-03 1/2W SEFH-MC-W .018 dB 1,362.42 Ft (L)Total Circuit Length(One Leg) A2-05A-04 1/2W SEFH-CW .024 dB 515.79 (RI.)Load Resistance=V"21W A2-05A-05 1/2W SEFH-CW .031 dB 8.56 Ohm (RW)Circuit Resistance=R*L*2(Both Legs) A2-05A-06 1/2W SEFH-CW .038 dB 9.50 Watt (W)Total Circuit Wattage A2-05A-07 1/2W SEFH-CW .045 dB -0A4 dO Total Circuit Signal Loss A2-05A-08 1/2W SEFH-CW .051 dB dB Loss=20log10(RL/(RL+RW)) A2.05A-09 1/2W SEFH-CW .059 dB 23.75% Percent Output Load A2-05A-10 1/2W SEFH-CW .066 dB A2-05A-11 1/2W SEFH-CW .073 dB A2415A-12 1/2W SEFH-CW .081 dB A2-05A-13 1/2W SEFH-CW .089 dB A2-05A-14 1/2W SEFH-CW .096 dB A2-05A-15 1/2W SEFH-CW .105 dB A2-05A-16 1/2W SEFH-CW .112 dB A2415A.17 1/2W SEFH-CW .121 dB A2-05A-18 1/2W SEFH-W .131 dB A2-05A.19 1/2W SEFH.MC-W .140 dB PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/6/2019 db LOSS CALCULATIONS CONTINUED LABEL WATT MODEL db LOSS db Lnnuc20log10(RL/(RL♦RW)) FACP-02 ZAC-40 'eiilik i 9 ti2it 42/21 6622aa .n s s 2 rcn?„* Ikea t (s. .....5._ _ .,.. A2-05B-01 1!2W SEFH-CW .006 dB 70 VRMS ( Audio Voltage A2-05B-02 1l2W SEFH-OW .012 de 3.14 Ohm (R)Wire Resistance Per 1000 Feet A2-05B-03 0/2W SEFH-CW .018 de 1,436.08 Fl (L)Total Circuit Length(One Leg) A2-058-04 1!2W SEFH-CW .025 dB 576.47 (RL)Load Resistance=V"2)W A2-058-05 1!2W SEFH-CW .032 dB 9.02 Ohm (RW)Circuit Resistance=R'L'2(Both legs) A2-058-06 1/2W SEFH-CW .039 dB 8.50 Welt (6 Talal Circuit Wattage A2-058-07 1/2W SEFH-CW .046 dB -0.13 dB Total Circuit Signal Loss A2-05B-08 1/2W SEFH-CW .054 dB dB Loss=20log10(RL/(RL+RW)) A2-058-09 1/2W SEFH-CW .062 dB 21.25% Percent Output Load A2-05B-10 1/2W SER4CW .070 dB A2-058-11 1/2W SEFH-MC-W .079 dB A2-058-12 1/2W SEFH-CW .088 dB A2-058-13 1/2W SEFH-CW .097 dB A2-05B-14 1/2W SEFH-CW .106 dB A2-05B-15 1/2W SEFH-CW .115 dB A2-05B-16 1/2W SEFH-CW .124 dB A2-05B-17 1/2W SEFH-CW .134 dB PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/6/2019 FACP-02 SIEMENS db LOSS CALCULATIONS FIRE ALARM SUBMITTAL. EMBASSY SUITES HOTEL FIRE ALARM UPGRADE FACP4I2 AMP Panel ZAC-40 AMP Model ZAC-40 AMP Model 40 Watt Max Wattage Per Output 0.50 dB Max dB Loss 40 Watt Max Wattage Per AMP 14 AWG Wire Gauge 70 VRMS (V)Audio Voltage db LOSS CALCULATION RESULTS PERCENT OUTPUT TOTAL OUTPUT LABEL db LOSS WATTS LOAD OUTPUT 1 A2-06A- -0.14 dB 9.50 Watts 23.75% 7th Floor Speakers East OUTPUT 2 A2-06B- -0.14 dB 8.50 Watts 21.25% 7th Floor Speakers West Total Watts 18.00 Watts 45.00% db LOSS CALCULATIONS LABEL WATT MODEL db LOSS dh Loss=20Iog10(RL/(Rt+RW)) FACP-02 ZAC-40 A2-06A-01 1/2W SEFH-CW 006 dF 70 VRMS (V)Audio Voltage A2-06A-02 1/2W SEFH-W 012 dB 3.14 Ohm (R)Wire Resistance Per 1000 Feat _ A2-06A-03 1/2W SEFH-MC-W 018 dB 1,371.83 Ft (L)Total Circuit Length(One Leg) A2-06A-04 1/2W SEFH-CW .024 dB 515.79 (RL)Load Resistance=V"2/W A2-06A-05 1/2W SEFH-CW .031 dB 0.62 Ohm (RW)Circuit Resistance=R'L'2(Both Legs) A2-06A-06 1/2W SEFH-CW .038 dB 9.50 Walt (W)Total Circuit Wattage A2-06A-07 1/2W SEFH-CW 045 dB Total Circuit Signal Loss A2-06A-08 112W SEFH-CW .052 dB -0.14 dB dB Loss=201og10(RL/(RL+RW)) A2.06A-09 1/2W SEFH-CW .058 dB 23.75% Percent Output Load A2-06A-10 1/2W SEFH-CW .066 dB A2-06A-11 1/2W SEFH-CW .074 dB A2-06A-12 1/2W SEFH-CW .081 dB A2-06A-13 12W SEFH-CW .089 dB A2-06A-14 1/2W SEFH-CW .097 dB A2-06A-15 1/2W SEFH-CW .105 dB A2-06A-16 1/2W SEFH-CW .113dB A2-06A-17 1/2W SEFH-CW .122 dB A2-06A-18 1/2W SEFH-W .132 dB A2-06A-19 1/2W SEFH-MC-W .141 dB PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/6/2019 db LOSS CALCULATIONS CONTINUED LABEL WATT MODEL db LOSS db Loss=20Iog10(RLI(RL+RW)) A2-06B.01 -1/2W SEFH-CW 006 dB 70 VRMS (V)Audio Voltage A2-006-02 1/2W SEFH-CW .012 dB 3.14 Ohm (R)Wire Resistance Per 1000 Feet A2.06B-03 1/2W SEFH-CW .019 dB 1,446.08 Ft (L)Total Circuit Length(One Leg) A2.06B-04 1/2W SEFH-CW .025 dB 576.47 (RL)Load Resistance=V"2/W A2.066.05 1/2W SEFH-CW .032 dB 9.08 Ohm (RW)Circuit Resistance=R'L'2(Both Legs) A2.O66-06 1/2W SEFH-CW .039 dB 8.50 Watt (W)Total Circuit Wattage A2.06B-07 1/2W SEFH-CW 046 dB Total Circuit Signal Loss 40,14 dB A2-068-08 1/2W SEFH-CW .054 dB dB Loss=201og10(RLARLtRW)) A2.06B-09 1/2W SEFH-CW .062 dB 31.25% Percent Output Load A2.06B.10 1/2W SEFH-CW .071 dB A2.06B.11 1/2W SEFH-MC-W .079 dB A2.0613.12 1/2W SEFH-CW .089 dB A2.06B-13 1/2W SEFH-CW 098 dB A2.066-14 1/2W SEFH-CW .106 dB A2.06B-15 1/2W SEFH-CW 116 dB A2.066.16 1/2W SEFH-CW 125 dB A2-060.17 1/2W SEFH-CW .135 d6 PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/6/2019 FACP-02 db LOSS CALCULATIONS SIEMENS FIRE ALARM SUBMITTAL EMBASSY SUITES HOTEL FIRE ALARM UPGRADE FACP-02 AMP Panel ZAC-40 AMP Model ZAC-40 AMP Model 40 Watt Max Wattage Per Output 0.50 dB Max dB Loss 40 Watt Max Wattage Per AMP 14 AWG Wire Gauge 70 VRMS (1/)Audio Voltage db LOSS CALCULATION RESULTS PERCENT OUTPUT TOTAL OUTPUT LABEL db LOSS WATTS LOAD OUTPUT 1 A2-07A- -0.14 dB 9.50 Watts 23.75% 81h Floor Speakers East OUTPUT 2 A2-07B- -0.15 dB 9.00 Watts 22.50% 8th Floor Speakers West Total Watts 18.50 Watts 46.25% db LOSS CALCULATIONS LABEL WATT MODEL db JOSS db Loss=201og10(RL/(RL+RW)) FACP-02 ZAC-40 A2-07A-01 1/2W SEFH-CW 006 dB 170 VRMS (V)Audio Voltage A2-07A-02 1/2W SEFH-W .012 dB 3.14 Ohm (R)Wire Resistance Per 1000 Feet A2-07A-03 1/2W SEFH-MC-W .018 dB 1,382.25 Ft (L)Total Circuit Length(One Leg) A2.07A-04 1/2W SEFH-CW .025 dB 515.79 (RL)Load Resistance=V"2/W A2-07A-05 1/2W SEFH-CW .031 dB 8.68 Ohm (RW)Circuit Resistance=R'L•2(Both Legs) A2.07A-06 1/2W SEFH-CW .038 dB 9.50 Watt (UV)Total Circuit Wattage A2-07A-07 1/2W SEFH-CW .045 dB -0.14dB Total Circuit Signal Loss A2-07A-08 1/2W SEFH-CW .052 dB dB Loss=201og10(RU(RL*RW)) A2-07A-09 1/2W SEFH-CW .060 dB 23.75% Percent Output Load A2-07A-10 1/2W SEFH-CW .067 dB A2437A-11 1/2W SEFH-C W .075 dB A2417A-12 1/2W SEFH-CW .082 dB A2-07A-13 1/2W SEFH-CW .090 dB A2-07A-14 1/2W SEFH-CW .098 dB A2-07A-15 12W SEFH-CW .106 dB A2-07A.18 12W SEFH-CW .114 dB A2-07A-17 1/2W SEFH-CW .123 dB A2-07A-18 12W SEFH-W .133 dB A2-07A-19 1/2W SEFH-MC-W .142 dB PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/6/2019 db LOSS CALCULATIONS CONTINUED LABEL WATT MODEL db LOSS db Loss=20Iog10(RL/(RL+RW)) FACP-02 - 'ZAC-40 - A2-07B-01 1/2W SEFH-CW .006 dB 7D VRMS (V)Audio Voltage A2-07B-02 1/2W SEFH-CW .012 dB 3.14 Ohm (R)Wire Resistance Per 1000 Feet A2-07B-03 1/2W SEFH-CW .019 dB 1,532.25 Ft (L)Total Circuit Length(One Leg) A2-07B-04 1/2W SEFH-CW .025 dB 544.44 (RL)Load Resistance=V"2/14/ A2-07B-05 1/2W SEFH-CW .032 dB 9.62 Ohm (RW)Circuit Resistance=R122(Both Legs) A2-070-06 1/2W SEFH-CW .040 dB 9.00 Watt (W)Total Circuit Wattage A2-07B-07 1/2W SEFH-CW .047 dB Total Circuit Signal Loss A2-07B-08 1/2W SEFH-CW .054 dB -0.15 dB dB Loss=20Iogi0(RLI(RL+RW)) A2-07B-09 1/2W SEFH-CW .063 dB 22.50% Percent Output Load A2-07B-10 112W SEFH-CW .071 dB A2-07B-11 1/2W SEFH-MC-W .080 dB A2-07B-12 1/2W SEFH-CW .089 dB A2-07B-13 1/2W SEFH-CW .099 dB A2-07B-14 112W SEFH-CW .107 dB A2-07B-15 1/2W SEFH-MC-W .119dB A2-07B-16 1/2W SEFH-CW .131 dB A247B-17 1/2W SEFH-CW .140 dB A2-07B-18 1/2W SEFH-CW .151 dB PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/6/2019 FACP-02 SIEMENS db LOSS CALCULATIONS FIRE ALARM SUBMITTAL EMBASSY SUITES HOTEL FIRE ALARM UPGRADE FACP-02 AMP Panel ZAC40 AMP Model ZAC40 AMP Model 40 Watt Max Wattage Per Output 0.50 dB Max dB Loss 40 Watt Max Wattage Per AMP 14 AWO Wire Gauge 70 VRMS (V)Audio Voltage db LOSS CALCULATION RESULTS PERCENT OUTPUT TOTAL OUTPUT LABEL db LOSS WATTS LOAD OUTPUT 1 A2-08A- -0.15 dB 9.50 Watts 23.75% 9th Floor Speakers East OUTPUT 2 A2-088- -0.15 dB 9.00 Watts 22.50% 9th Floor Speakers West Total Watts 18.50 Watts 46.25% db LOSS CALCULATIONS LABEL WATT MODEL db LOSS db Loss=201og10(RL)(RL+RW)) FACP-02 [lF--_ZAO-40 A2-08A-01 1/2W SEFH-CW 006 7B 70 VRMS (V)Audio Voltage A2-08A-02 1/2W SEFH-W .012 dB 3.14 Ohm (R)Wire Resistance Per 1000 Feet A2-08A-03 1/2W SEFB-MC-W 018 dB 1,392.58 Ft (L)Total Circuit Length(One Leg) A2-08A-04 1/2W SEFH-CW .025 dB 515.79 (RL)Load Resistance=V"21W A2-08A-05 1/2W SEFH-CW .032 dB 8.75 Ohm (RW)Circuit Resistance=R•L*2(Both Legs) A2-08A-06 1/2W SEFH-CW .039 dB 9.50 Watt (W)Total Circuit Wattage A2-08A-07 1/2W SEFH-CW .046 dB Total Circuit Signal Loss A2.08A-08 1/2W SEFH-CW .053 dB -0.15 dB dB Loss=20log10(RL/(RL+RW)) A2-08A-09 1/2W SEFH-CW .060 dB 23.75% Percent Output Load A2-08A.10 1/2W SEFH-CW .067 dB A2.08A-11 1/2W SEFH-CW .075 dB A2-08A-12 1/2W SEFH-CW .083 dB A2-08Ad3 1/2W SEFH-CW .091 dB A2438A-14 1/2W SEFH-CW .098 dB A2418A-15 1/2W SEFH-CW .107 dB A2-08A-16 1/2W SEFH-CW .115dB A2-08A-17 1/2W SEFH-CW .124 dB A2.08A-18 1/2W SEFH-W .134dB A2.O8A-19 1/2W SEFH-MC-W .144 dB PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/6/2019 db LOSS CALCULATIONS CONTINUED LABEL WATT MODEL db LOSS db Loss=20Iog10(RLI(RL+RW)) A2.00B-01 1/2W SEFH-CW .006 dB 70 VRMS (V)Audio Voltage A2-08B-02 1/2W SEFH-CW .012 d0 3.14 Ohm (R)Wire Resistance Per 1000 Feet A2.088-03 1/2W SEFH-CW 019 de 7,542,42 Ft (L)Tatal Circuit Length(One Leg) A2-08B-04 1/2W SEFH-CW .026 dB 544.44 (RL)Load Resistance=V^2/W A2-0BB-05 1/2W SEFH-CW .032 dB 9,69 Ohm (RW)Circuit Resialance=R'L'2(Both Legs) A2-08B-06 1/2W SEFH-CW .040 dB 9.00 Walt (W)Total Circuit Wattage A2-088-07 1/2W SEFH-CW .047 dB Total Cireuit Signal Loss A2-08B-08 1/2W SEFH-CW .055 dB -0.15 d8 dB Losse20Iog10(RLI(RL+RVJ)) A2-088-09 1/2W SEFH-CW .063 dB 22.50% Percent Output Load A2-086-10 1/2W SEFH-CW .072 dB A2-088-11 1/2W SEFH-MC-W .081 dB A2-08B-12 1/2W SEFH-CW .090dB A2-088-13 1/2W SEFH-CW .099db A2.08B-14 1/2W SEFH-CW .108dB A2-08B-15 1/2W SEFH-MC-W .120db A2-088-16 1/2W SEFH-CW .132 dB A2-08B-17 1/2W SEFH-CW .141 dB A2-088-18 1/2W SEFH-CW .152 dB PROPRIETARY DOCUMENT FOR APPROVAL ONLY 1216/2019 0z � z Qo I- rva w w J CI ~ V a < wma m >- " 2 a o Len. Ce aMo acnw ww < ° o a > 24VDC RISER IN I a+POWER IN 24VDC RISER OUT I' +POWER OUT TO NEXT EMITTER I%,- DETAIL NOTES: EMITTER TERMINATION CARD I. CONTROL RELAY MODULE FOR EXTERNAL RESET. 2. FAULT RELAY SHOWN IN NORMAL OPERATION, ENERGIZED. 1 FIRE RELAY SHOWN IN NORMAL OPERATION, DE-ENERGIZED. 478 Ohm Q�NC SIGNALING LINE CIRCUIT ® COM FAULT 02 NO TO NEXT INTELLIGENT DEVICE NC °+POWER IN 470 Ohm 000M FIRE O3 I.XTRI-R XTRI-D I NO 24VDC 1� ' +POWER OUT 0-IN /U 0-IN N. ®+RESET RISETO R NEXT SIGNALING LINE CIRCUIT ® OUT 0 OUT 24VDC —L..°+ EMITTER FROM FACP OR PREVIOUS RISER IN ®_POWER IN INTELLIGENT DEVICE - �'� 'F O O ®+POWER OUT o o' EMITTER TERMINATION CARD (SPARE) 470 Ohm ©S 1 -F-0S l ®- it Vc [a! SPDT RELAY ±-0 NOT USED®® r-1 r-, _-07 4A 0 24VDC x + - + - 4A 0 120VAC 52 (® ®I® ®I ®07 IMAGER TERMINATION CARD ISOLATOR ISOMIOADE R • OSID SERIES OPEN-AREA SMOKE IMAGING DETECTION SCALE; NONE SIEMENS OPEN-AMODELSREA SMOKEOSI-70 IMAGINGANDOSI-DETECTION �.,� 0 121164019 INITIAL SETUP W WITH CONTROL/MONITOR ISOLATION MODULES Siemens Industry,Inc. wu.keGreentnerNNANNW n�nne. 3Jm,,,s� ra e[es[s n Building Technologies Division seems.,Ongm9M06 rnn:[s�imO-ism Omen:UP [Date:06.06.161 Engineer: iDete: IAA'paad: Date jScale:NONE IJob No:- I FA-DETLBEAM_OS ID-XTRI NMIS GROWING AND DESIGNS THEREON SMALL N01 SE LLSOCArED.USED OR OISQQ .D TO CT5ERS SCR FRL.UR[M[NI OR ONi [.<¢vi AS OWERw;Lr NOSH IZED BY C2u*RASS.wf r EXP5rsr Ntii CONSENT OS SEVEN NS I J FAPS-T9 SIEMENS BATTERY & VOLTAGE DROP CALCULATIONS FIRE ALARM SUBMITTAL EMBASSY SUITES HOTEL WASHINGTON SQUARE FAPS-T9 SPECIFICATIONS FAPS-T9 BATTERY CALCULATIONS FAPS-T9 PANEL 24 Hours(A)Requirement for Standby Charge: AL602ULADA MODEL 15 Minutes(B)Requirement for Alarm Charge: 15%Design Voltage Drop(20%Max Voltage Drop) 20%(C)Spare Battery Capacity: 1.00 Amp Max Current Draw Per Output 0.11 Amp(F)Standby Total Current Draw 1.00 Amp Max Current Draw Per AUX Output 0.11 Amp(G)Alarm Total Current Draw 6.50 Amp Max Current Draw Per Panel 2.5 Amp Hr(H)Design Standby Charge=(A x F) 14 AWG Wire Gauge 0.0 Amp Hr(J)Design Alarm Charge=(B x G)I60 20.4 VOC Voltage at First Device' 0.5 Amp Hr(H)Additional Capacity Charge=(C x((Ax F)*(B x G)I60)) 0.05 Amp Panel Standby Current Draw 3.1 Amp Hr(AH)Battery Amp Hour requirement=(H+J+N) 0.05 Amp Panel Alarm Current Draw 7.0 Amp Hr Battery Size 40.0 Amp Hr Max Battery Charging Capacity FAPS-T9 VOLTAGE DROP CALCULATION RESULTS PERCENT STANDBY ALARM PERCENT OUTPUT VOLTAGE CURRENT CURRENT CURRENT LABEL VOLTAGE DROP DROP DRAW DRAW DRAW OUTPUT-1 BO-EM- 0.02 Volt 0.10% 0.02 Amp 0.02 Amp 2.40% 9th Floor Beam Detector Emitters OUTPUT-2 BO-IM- 0.03 Volt 0.17% 0.03 Amp 0.03 Amp 3.10% 9th Floor Beam Detector Imager AUX OUTPUT BD-AX- 0.00 Volt 0.00% 0.00 Amp 0.00 Amp 0.00% Not Used Total Current Draw 0.06 Amp 0.06 Amp 0.85% FAPS-T9 VOLTAGE DROP CALCULATIONS OUTPUT-1 LABEL CD MODEL STANDBY ALARM DISTANCE VOLTAGE' Alarm Voltage Drop=VD•R x la FAPS-TB AL602ULADA c t ' s)j 'E."e' 20.400 140.42 Ft (L)Total Circuit Length(One Leg) BD-EM-01 OSE-SPW 0.008 0.008 5242 ft 20.400 3.14 Ohm Wire Resistance Per 1000 Feet BD-EM-02 OSESPW 0.008 0.008 36.33It 20.391 0.88 Ohm (R)Total Circuit Resistance(Both Legs) BD-EM-03 OSE-SPW 0.008 0.008 33,67 ft 20.384 0.02 Amp (Is)Total Current Draw(Standby) 0.02 Amp (la)Total Current Draw(Alarm) 20.38 Volt (20.4-(la x R))Applied Voltage at Last Device' 0.02 Volt (VD)Voltage Drop 0.10% Percent Voltage Drop 2.40% Percent Current Draw Output-1 OUTPUT-2 LABEL CD MODEL STANDBY ALARM DISTANCE VOLTAGE' Voltage Drop=VD=L'R'la FAPS-T9 AL602ULADA - 20.400 176.50 Ft (L)Total Circuit Length(One Leg) BD-IM-01 OSI-90 0.031 7.031 170.5013 70 400 3.14 Ohm Wire Resistance Per 1000 Feet 1.11 Ohm (R)Total Circuit Resistance(Both Legs) 0.03 Amp (Is)Total Current Draw(Standby) 0.03 Amp (la)Total Current Draw(Alarm) 20.37 Volt (20.4-(lax R))Applied Voltage at Last Device' 0.03 Volt (VD)Voltage Drop 0.17% Percent Voltage Drop 3.10% Percent Current Draw Output-2 AUX OUTPUT LABEL CD MODEL STANDBY ALARM DISTANCE VOLTAGE' Voltage Drop=VD=L'R9a FAPS-T9 AL602ULADA 20.400 0.00 Ft (L)Total Circuit Length(One Leg) 3.14 Ohm Wire Resistance Per 1000 Feet 0.00 Ohm (R)Total Circuit Resistance(Both Legs) 0.00 Amp (Is)Total Current Draw(Standby) 0.00 Amp (la)Total Current Draw(Alarm) 20.40 Volt (20.4-(la x R))Applied Voltage at Last Device' 0.00 Volt (VD)Voltage Drop 0.00% Percent Voltage Drop 0.00% Percent Current Draw Aux Output Note-1;24 Volt derated by 15%to 20.4 Volts. Note-2;Point to Point Voltage Drop Calculation. Note-3;Line Voltage Drop Calculation PROPRIETARY DOCUMENT FOR APPROVAL ONLY 12/6/2019