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Engineered Smoke Control System for Tracer Summit manual Custom bindings, MP580-A, MP580-B
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BAS-APG001-EN
Engineered Smoke Control System for Tracer Summit
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Specifications
Install
System riser diagrams
Dimension
Tracer MP581 to FSCS wiring
Analog output and universal input setup
Control of the FSCP Comm Fault LED
Alarm mode
Setting the I/O bus addresses
Audible trouble indicator
Page 137
Image 137
Custom bindings
Figure 71. Watchdog communication in a
hub-based
system
MP580-A
MP580-B
Mechanical
system
MP580-1
System hubs
Smoke control panel interface
MP580-2
MP580-3
MP580-4
BAS-APG001-EN
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Page 136
Page 138
Page 137
Image 137
Page 136
Page 138
Contents
Engineered Smoke Control System
Applications Guide
for TRACER SUMMIT
BAS-APG001-EN
Page
Engineered Smoke Control System
Applications Guide
for TRACER SUMMIT
BAS-APG001-ENSeptember
BAS-APG001-EN
NOTICE
Page
Contents
Contents
BAS-APG001-EN
BAS-APG001-EN
Contents
Contents
BAS-APG001-EN
Contents
BAS-APG001-EN
Contents
Chapter
Smoke control overview
Compartmentation method
Methods of smoke control
Dilution method
Pressurization method
Table 1: Recommended minimum pressure difference
Methods of smoke control
Figure 2: Sample airflow method
Airflow method
Chapter 1 Smoke control overview
Buoyancy method
Applications of smoke control methods
Zoned smoke control
Applications of smoke control methods
3.If the system has a return air damper, it closes
Chapter 1 Smoke control overview
Applications of smoke control methods
Stairwell smoke control
Compensated pressurization technique
Figure 5: Sample non-compensatedsystem
Non-compensatedpressurization technique
Chapter 1 Smoke control overview
BAS-APG001-EN
Elevator shaft smoke control
Applications of smoke control methods
Chapter 1 Smoke control overview
Atrium smoke control
Smoke exhausting technique
Smoke filling technique
Natural smoke venting technique
Applications of smoke control methods
Figure 8: Sample natural smoke venting technique
Chapter 1 Smoke control overview
Smoke detection and system activation
Underground building smoke control
Stairwell smoke control detection and activation
Zoned smoke control detection and activation
Elevator smoke control detection and activation
Atrium smoke exhausting detection and activation
Horizontal grid
Vertical grid
Chapter 1 Smoke control overview
Figure 9 Sample stratification
No-smokeapproach
Design approaches to smoke control
Tenability approach
Dedicated system approach
Chapter 1 Smoke control overview
Design considerations for smoke control
Plugholing
Design considerations for smoke control
Smoke feedback
BAS-APG001-EN
Chapter 1 Smoke control overview
Zone operating modes
Pre-installationconsiderations
Alarm mode
Associated equipment
Fire alarm system equipment
Chapter 2 Pre-installationconsiderations
Beam smoke detectors
Area smoke detectors
Duct smoke detectors
Manual pull stations
Sprinkler flow devices
Fire alarm control panel
Chapter 2 Pre-installationconsiderations
Manual switches
Audible trouble indicator
Smoke control system equipment
Lights
Smoke dampers
Chapter 2 Pre-installationconsiderations
Verification of operation equipment
Fans
Associated equipment
BAS-APG001-EN
Tracer MP581 programmable controller
Equipment supervision
Chapter 2 Pre-installationconsiderations
Alarm response
System testing
Automatic smoke control matrix
Automatic weekly self-testing
First smoke zone in alarm
Chapter 2 Pre-installationconsiderations
First smoke zone in alarm
Equipment
Cable distance considerations
Response times
Response times
Table 7. NFPA response time requirements
Table 8. Cabling practices and restraints
Chapter 2 Pre-installationconsiderations
Maximum distance
Type
Smoke control system overview
Installation diagrams
Chapter 3 Installation diagrams
System riser diagrams
Figure 12. Sample fan starter wiring diagram
System termination diagrams
System termination diagrams
Figure 13. Sample FSCS panel
Tracer MP581 to FSCS wiring
Chapter 3 Installation diagrams
•Tracer MP581 and FSCS must be in the same room
System termination diagrams
Figure 14. Tracer MP581 to FSCS wiring
Chapter 3 Installation diagrams
FACP
Tracer MP581 to FACP wiring
System termination diagrams
Figure 15. Tracer MP581 to FACP wiring
Chapter 3 Installation diagrams
Mounting the hardware
Installing the Tracer Summit BMTX BCU
Avoid equipment damage
Operating environment requirements
12 in. 30 cm
Chapter 4 Installing the Tracer Summit BMTX BCU
Clearances
Mounting the hardware
Figure 17. BMTX BCU enclosure dimensions
Figure 18. Enclosure mounting holes
Mounting the back of the enclosure
Chapter 4 Installing the Tracer Summit BMTX BCU
Hazardous voltage
Wiring high-voltageac power
Wiring high-voltageac power
Hazardous voltage
Chapter 4 Installing the Tracer Summit BMTX BCU
Use copper conductors only
BAS-APG001-EN
Wiring high-voltageac power
Figure 19. AC wiring
Chapter 4 Installing the Tracer Summit BMTX BCU
EMI/RFI considerations
Checking the earth ground
Hazardous voltage
Figure 20. Checking the earth ground
EMI/RFI considerations
Chapter 4 Installing the Tracer Summit BMTX BCU
Connecting the main circuit board
Figure 22. Connecting the frames
Connecting the main circuit board
Figure 23. Installing the door
Installing the door
Chapter 4 Installing the Tracer Summit BMTX BCU
BAS-APG001-EN
LonTalk connections Ethernet connection
Chapter 4 Installing the Tracer Summit BMTX BCU
Installation guidelines
Table 13. Tracer MP581 specifications
Specifications
Equipment damage
Selecting a mounting location
Operating environment requirements
Selecting a mounting location
12 in. 30 cm
Clearances and dimensions
Figure 26. Minimum clearances for enclosure
Selecting a mounting location
Figure 27. Tracer MP581 enclosure dimensions
Top view
Left view
Figure 28. Enclosure mounting holes
Mounting the back of the enclosure
Wiring high-voltageac power
Wiring high-voltageac power
Circuit requirements
Table 15. Tracer MP581 models
Use copper conductors only
Wiring high-voltagepower
Hazardous voltage
BAS-APG001-EN
Wiring high-voltageac power
Hazardous voltage
Checking the earth ground
EMI/RFI considerations
Hazardous voltage
To check the quality of the earth ground
BAS-APG001-EN
EMI/RFI considerations
Figure 31. Checking the earth ground
Input/output wiring guidelines
Wiring inputs and outputs
Providing low-voltagepower for inputs and outputs
Wire routing
Wiring inputs and outputs
Figure 32. Wire routing
Figure 33. Screw-terminallocations
Screw terminal locations
Wiring inputs and outputs
Wiring universal inputs
Wiring binary inputs
Figure 35. Wiring analog outputs
Wiring analog outputs
Wiring inputs and outputs
Wiring binary outputs
Equipment damage
Checking binary inputs
Checking binary outputs
Checking outputs
Equipment damage
Checking 0–10Vdc analog outputs
Checking 0-20mA analog outputs
Equipment damage
BAS-APG001-EN
Checking outputs
Wiring LonTalk to the Tracer MP581
3.At the last controller on the LonTalk link
Wiring LonTalk to the Tracer MP581
Figure 39. Connecting the cables
Installing the circuit board
Figure 40. Connecting the frames
Installing the circuit board
24 Vac power connector
Figure 41. 24 Vac power-supplycable connection
Interpreting LEDs
Service Pin button
Figure 42. Service Pin button and LED locations
Table 19. Red Service LED
Service LED
Binary output LEDs
Table 18. Binary output LEDs
Comm LED
Status LED
Table 20. Green Status LED
Table 21. Yellow Comm LED
Figure 43. Aligning the enclosure door
Installing the door
Removing the door
BAS-APG001-EN
Installing the door
BAS-APG001-EN
Table 22. Operating environment specifications
Installing the EX2 expansion module
Chapter 6 Installing the EX2 expansion module
Storage environment
Mounting location
Mounting the metal-enclosuremodule
Terminal strips
Terminal strips
Figure 45. Terminal strip locations
Chapter 6 Installing the EX2 expansion module
AC-powerwiring
Hazardous voltage
Hazardous voltage
AC-powerwiring
Wiring AC-powerto the metal-enclosuremodule
Equipment damage
Equipment damage
Figure 47. Power and ground terminals
Chapter 6 Installing the EX2 expansion module
Figure 48. I/O bus wiring example
I/O bus wiring
I/O bus wiring
Figure 49. I/O bus wiring example
Chapter 6 Installing the EX2 expansion module
Input/output terminal wiring
Setting the I/O bus addresses
Setting the I/O bus addresses
Figure 50. DIP switch on board
Chapter 6 Installing the EX2 expansion module
Analog output and universal input setup
Universal inputs
Binary outputs
BAS-APG001-EN
Analog output and universal input setup
Chapter 6 Installing the EX2 expansion module
Interpreting EX2 LEDs
Binary output LEDs
Figure 52. LED locations on the EX2
Communications LEDs
Status LED
Interpreting EX2 LEDs
Table 25. Status LED
BAS-APG001-EN
Chapter 6 Installing the EX2 expansion module
Table 27. Time response requirements
Programming
Response times
Chapter 7 Programming
Operational priority
Table 28. Operational priority
Subsequent alarms
Subsequent alarms
Chapter 7 Programming
Figure 53. Subsequent alarms—Firstreaction
Figure 54. Smoke alarm annunciation
Smoke alarm annunciation
Smoke alarm annunciation
Chapter 7 Programming
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
Figure 55. Triggering the automatic self-testAST
Weekly self-testof dedicated systems
Weekly self-testof dedicated systems
Figure 56. Mechanical reactions during AST
Chapter 7 Programming
Figure 57. ast overridesense
Weekly self-testof dedicated systems
Figure 57 needs to be introduced
Figure 58. Effect of AST on damper control
Chapter 7 Programming
Figure 59. Sample TGP showing fail test technique
End process verification
End process verification
Figure 60. ast actuator fail checka
BAS-APG001-EN
End process verification
Figure 61. ast actuator fail checkb
Chapter 7 Programming
Communication watchdog
BAS-APG001-EN
Communication watchdog
Chapter 7 Programming
BAS-APG001-EN
Figure 67. Control of the FSCP Comm Fault LED
Communication watchdog
Chapter 7 Programming
Lamp test and audio alarm silence
BAS-APG001-EN
Lamp test and audio alarm silence
Controlling damper actuators
Nondedicated smoke purge
Chapter 7 Programming
Constant-volumesystem
Variable-air-volumesystem
UL-testedprograms
Variable-air-volumesystem
BAS-APG001-EN
Chapter 7 Programming
Binding network variables
Network variable bindings
Overview
Receiving data
Tracer MP580/581 bindings
Sending data
Heartbeated network variables
Custom bindings
Custom bindings
UUKL binding list watchdog communication
Function
Chapter 8 Network variable bindings
Originator
Network
MP580-A
Custom bindings
MP580-B
Mechanical system
Chapter 8 Network variable bindings
UUKL binding list smoke alarm status
Table 32. Smoke alarm custom bindings
Table 33. FSCP override custom bindings
UUKL binding list FCSP override control
Custom bindings
On/Off status
UUKL binding list actuator Open/Close or
Chapter 8 Network variable bindings
Table 34. Actuator status custom bindings
UUKL binding list FSCP control
UUKL binding list actuator failure status
Custom bindings
Table 35. Actuator failure status bindings
Chapter 8 Network variable bindings
Understanding bindings
Custom binding report
Binding types
Node
Basic binding shapes and the hub/target system
Network Address
Chapter 8 Network variable bindings
Address table
Figure 72. Rovers view of a fan-outbinding
Figure 73. Rovers view of a fan-inbinding
Understanding bindings
Designing bindings
Binding rules and limits
Chapter 8 Network variable bindings
Stacking bindings on unique binding paths
Figure 74. One-waysubnet/node binding
Understanding bindings
Figure 75. Two-waysubnet/node bindings
BAS-APG001-EN
Figure 76. Group binding
Chapter 8 Network variable bindings
BAS-APG001-EN
Understanding bindings
Figure 77. Group binding uniqueness
Chapter 8 Network variable bindings
BAS-APG001-EN
Understanding bindings
Figure 79. Mixed subnet/node and group bindings
BAS-APG001-EN
Chapter 8 Network variable bindings
Appendix A
References
BAS-APG001-EN
Appendix A References
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