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Trane BAS-APG001-EN manual Installation diagrams, Tracer MP581 to FSCS wiring

Models: BAS-APG001-EN Engineered Smoke Control System for Tracer Summit

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Figure 14. Tracer MP581 to FSCS wiring

Chapter 3 Installation diagrams

Figure 14. Tracer MP581 to FSCS wiring

36	BAS-APG001-EN

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Trane BAS-APG001-EN, Engineered Smoke Control System for Tracer Summit Installation diagrams, Tracer MP581 to FSCS wiring

Contents

Applications Guide Engineered Smoke Control Systemfor TRACER SUMMIT BAS-APG001-ENPage Applications Guide Engineered Smoke Control Systemfor TRACER SUMMIT BAS-APG001-ENSeptemberBAS-APG001-EN NOTICE Page Contents ContentsBAS-APG001-EN Contents BAS-APG001-ENContents Contents BAS-APG001-ENContents BAS-APG001-ENSmoke control overview ChapterMethods of smoke control Compartmentation methodDilution method Pressurization methodMethods of smoke control Table 1: Recommended minimum pressure differenceAirflow method Chapter 1 Smoke control overviewFigure 2: Sample airflow method Applications of smoke control methods Buoyancy methodZoned smoke control Applications of smoke control methodsChapter 1 Smoke control overview 3.If the system has a return air damper, it closesStairwell smoke control Compensated pressurization techniqueApplications of smoke control methods Non-compensatedpressurization technique Chapter 1 Smoke control overviewFigure 5: Sample non-compensatedsystem Elevator shaft smoke control Applications of smoke control methodsBAS-APG001-EN Atrium smoke control Smoke exhausting techniqueChapter 1 Smoke control overview Natural smoke venting technique Smoke filling techniqueApplications of smoke control methods Figure 8: Sample natural smoke venting techniqueSmoke detection and system activation Underground building smoke controlChapter 1 Smoke control overview Zoned smoke control detection and activation Stairwell smoke control detection and activationElevator smoke control detection and activation Atrium smoke exhausting detection and activationVertical grid Horizontal gridChapter 1 Smoke control overview Figure 9 Sample stratificationDesign approaches to smoke control No-smokeapproachTenability approach Dedicated system approachDesign considerations for smoke control PlugholingChapter 1 Smoke control overview Smoke feedback Design considerations for smoke controlChapter 1 Smoke control overview BAS-APG001-ENPre-installationconsiderations Zone operating modesAssociated equipment Alarm modeFire alarm system equipment Chapter 2 Pre-installationconsiderationsArea smoke detectors Beam smoke detectorsDuct smoke detectors Manual pull stationsFire alarm control panel Chapter 2 Pre-installationconsiderationsSprinkler flow devices Audible trouble indicator Manual switchesSmoke control system equipment LightsChapter 2 Pre-installationconsiderations Smoke dampersFans Verification of operation equipmentAssociated equipment BAS-APG001-ENEquipment supervision Chapter 2 Pre-installationconsiderationsTracer MP581 programmable controller System testing Alarm responseAutomatic smoke control matrix Automatic weekly self-testingChapter 2 Pre-installationconsiderations First smoke zone in alarmFirst smoke zone in alarm EquipmentResponse times Cable distance considerationsResponse times Table 7. NFPA response time requirementsChapter 2 Pre-installationconsiderations Table 8. Cabling practices and restraintsMaximum distance TypeInstallation diagrams Smoke control system overviewSystem riser diagrams Chapter 3 Installation diagramsSystem termination diagrams System termination diagramsFigure 12. Sample fan starter wiring diagram Tracer MP581 to FSCS wiring Chapter 3 Installation diagramsFigure 13. Sample FSCS panel System termination diagrams •Tracer MP581 and FSCS must be in the same roomChapter 3 Installation diagrams Figure 14. Tracer MP581 to FSCS wiringTracer MP581 to FACP wiring System termination diagramsFACP Chapter 3 Installation diagrams Figure 15. Tracer MP581 to FACP wiringInstalling the Tracer Summit BMTX BCU Mounting the hardwareAvoid equipment damage Operating environment requirementsChapter 4 Installing the Tracer Summit BMTX BCU Clearances12 in. 30 cm Figure 17. BMTX BCU enclosure dimensions Mounting the hardwareMounting the back of the enclosure Chapter 4 Installing the Tracer Summit BMTX BCUFigure 18. Enclosure mounting holes Wiring high-voltageac power Wiring high-voltageac powerHazardous voltage Chapter 4 Installing the Tracer Summit BMTX BCU Use copper conductors onlyHazardous voltage Wiring high-voltageac power Figure 19. AC wiringBAS-APG001-EN EMI/RFI considerations Chapter 4 Installing the Tracer Summit BMTX BCUChecking the earth ground Hazardous voltageEMI/RFI considerations Figure 20. Checking the earth groundConnecting the main circuit board Chapter 4 Installing the Tracer Summit BMTX BCUConnecting the main circuit board Figure 22. Connecting the framesInstalling the door Chapter 4 Installing the Tracer Summit BMTX BCUFigure 23. Installing the door BAS-APG001-EN Chapter 4 Installing the Tracer Summit BMTX BCU LonTalk connections Ethernet connectionInstallation guidelines Specifications Table 13. Tracer MP581 specificationsSelecting a mounting location Equipment damageOperating environment requirements Selecting a mounting locationClearances and dimensions Figure 26. Minimum clearances for enclosure12 in. 30 cm Figure 27. Tracer MP581 enclosure dimensions Selecting a mounting locationTop view Left viewMounting the back of the enclosure Figure 28. Enclosure mounting holesWiring high-voltageac power Wiring high-voltageac powerCircuit requirements Table 15. Tracer MP581 modelsWiring high-voltagepower Hazardous voltageUse copper conductors only Wiring high-voltageac power Hazardous voltageBAS-APG001-EN EMI/RFI considerations Checking the earth groundHazardous voltage To check the quality of the earth groundEMI/RFI considerations Figure 31. Checking the earth groundBAS-APG001-EN Wiring inputs and outputs Input/output wiring guidelinesWire routing Providing low-voltagepower for inputs and outputsWiring inputs and outputs Figure 32. Wire routingScrew terminal locations Figure 33. Screw-terminallocationsWiring universal inputs Wiring binary inputsWiring inputs and outputs Wiring analog outputs Figure 35. Wiring analog outputsWiring binary outputs Wiring inputs and outputsChecking binary inputs Equipment damageChecking outputs Checking binary outputsEquipment damage Checking 0–10Vdc analog outputsEquipment damage Checking 0-20mA analog outputsChecking outputs BAS-APG001-ENWiring LonTalk to the Tracer MP581 Wiring LonTalk to the Tracer MP581 3.At the last controller on the LonTalk linkInstalling the circuit board Figure 39. Connecting the cablesInstalling the circuit board Figure 40. Connecting the framesFigure 41. 24 Vac power-supplycable connection 24 Vac power connectorService Pin button Figure 42. Service Pin button and LED locationsInterpreting LEDs Service LED Table 19. Red Service LEDBinary output LEDs Table 18. Binary output LEDsStatus LED Comm LEDTable 20. Green Status LED Table 21. Yellow Comm LEDInstalling the door Removing the doorFigure 43. Aligning the enclosure door Installing the door BAS-APG001-ENBAS-APG001-EN Installing the EX2 expansion module Table 22. Operating environment specificationsStorage environment Mounting locationChapter 6 Installing the EX2 expansion module Terminal strips Mounting the metal-enclosuremoduleTerminal strips Figure 45. Terminal strip locationsAC-powerwiring Chapter 6 Installing the EX2 expansion moduleHazardous voltage Hazardous voltageWiring AC-powerto the metal-enclosuremodule AC-powerwiringEquipment damage Equipment damageChapter 6 Installing the EX2 expansion module Figure 47. Power and ground terminalsI/O bus wiring I/O bus wiringFigure 48. I/O bus wiring example Chapter 6 Installing the EX2 expansion module Figure 49. I/O bus wiring exampleSetting the I/O bus addresses Input/output terminal wiringSetting the I/O bus addresses Figure 50. DIP switch on boardAnalog output and universal input setup Chapter 6 Installing the EX2 expansion moduleUniversal inputs Binary outputsAnalog output and universal input setup BAS-APG001-ENInterpreting EX2 LEDs Chapter 6 Installing the EX2 expansion moduleBinary output LEDs Figure 52. LED locations on the EX2Status LED Communications LEDsInterpreting EX2 LEDs Table 25. Status LEDChapter 6 Installing the EX2 expansion module BAS-APG001-ENProgramming Response timesTable 27. Time response requirements Operational priority Chapter 7 ProgrammingSubsequent alarms Subsequent alarmsTable 28. Operational priority Figure 53. Subsequent alarms—Firstreaction Chapter 7 ProgrammingSmoke alarm annunciation Smoke alarm annunciationFigure 54. Smoke alarm annunciation From requirements 33.2.1 and 33.2.2, we can see that there is a decoupling between annunciation and reaction. The series of network variables shown in Figure 54, nvoSwitch05 through nvoSwitch12, are used to directly control the smoke alarm LEDs on the FSCP. For example, a smoke alarm for floor 1 is received. The mechanical system reacts by pressurizing floor 2 and exhausting floor 1. Following that, floor 2 goes into smoke alarm. The alarm needs to be annunciated even though the mechanical system does not react. In this case, nvoSwitch06 passes the smoke alarm state to MP580-3by using a custom binding. At MP580-3,the binary output that controls the floor 2 smoke alarm LED is turned on Chapter 7 ProgrammingWeekly self-testof dedicated systems Weekly self-testof dedicated systemsFigure 55. Triggering the automatic self-testAST Chapter 7 Programming Figure 56. Mechanical reactions during ASTWeekly self-testof dedicated systems Figure 57 needs to be introducedFigure 57. ast overridesense Chapter 7 Programming Figure 58. Effect of AST on damper controlEnd process verification End process verificationFigure 59. Sample TGP showing fail test technique Figure 60. ast actuator fail checka End process verification Figure 61. ast actuator fail checkbBAS-APG001-EN Communication watchdog Chapter 7 ProgrammingCommunication watchdog BAS-APG001-ENChapter 7 Programming Figure 67. Control of the FSCP Comm Fault LED Communication watchdogBAS-APG001-EN Lamp test and audio alarm silence Chapter 7 ProgrammingLamp test and audio alarm silence BAS-APG001-ENNondedicated smoke purge Chapter 7 ProgrammingControlling damper actuators Variable-air-volumesystem Constant-volumesystemUL-testedprograms Variable-air-volumesystemChapter 7 Programming BAS-APG001-ENNetwork variable bindings OverviewBinding network variables Tracer MP580/581 bindings Receiving dataSending data Heartbeated network variablesCustom bindings UUKL binding list watchdog communicationCustom bindings Chapter 8 Network variable bindings FunctionOriginator NetworkCustom bindings MP580-AMP580-B Mechanical systemUUKL binding list smoke alarm status Table 32. Smoke alarm custom bindingsChapter 8 Network variable bindings UUKL binding list FCSP override control Custom bindingsTable 33. FSCP override custom bindings UUKL binding list actuator Open/Close or On/Off statusChapter 8 Network variable bindings Table 34. Actuator status custom bindingsUUKL binding list actuator failure status UUKL binding list FSCP controlCustom bindings Table 35. Actuator failure status bindingsUnderstanding bindings Custom binding reportChapter 8 Network variable bindings Node Binding typesBasic binding shapes and the hub/target system Network AddressAddress table Chapter 8 Network variable bindingsFigure 72. Rovers view of a fan-outbinding Figure 73. Rovers view of a fan-inbindingDesigning bindings Binding rules and limitsUnderstanding bindings Stacking bindings on unique binding paths Chapter 8 Network variable bindingsUnderstanding bindings Figure 74. One-waysubnet/node bindingFigure 75. Two-waysubnet/node bindings BAS-APG001-ENChapter 8 Network variable bindings Figure 76. Group bindingUnderstanding bindings Figure 77. Group binding uniquenessBAS-APG001-EN Chapter 8 Network variable bindings Understanding bindings Figure 79. Mixed subnet/node and group bindingsBAS-APG001-EN Chapter 8 Network variable bindings BAS-APG001-ENReferences Appendix AAppendix A References BAS-APG001-ENPage Trane