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424374253-Completofenwal-Net-8000

R
Protection Systems
FenwalNET 8000-ML™
Configuration Software
(FCS8000)
User’s Guide
P/N 06-237042-001
March 2012
FOREWORD
Note: This Manual, P/N 06-237042-001, is to be used by qualified and factory-trained personnel, knowledgeable
of NFPA standards and any other applicable standards in effect.
This Manual is intended to clearly and accurately describe how to use the FenwalNET 8000-ML Configuration
Software (FCS8000).
Kidde-Fenwal assumes no responsibility for the application of any systems other than those addressed in this
manual. The technical data contained herein is provided for informational purposes only, and should not be used
as a substitute for professional judgment. Although Kidde-Fenwal, Inc. believes this information to be true and
correct, it is published and presented without any guarantee or warranty whatsoever. Kidde-Fenwal, Inc. disclaims
any liability for any use of the data other than as set out in this manual, Foreword included.
Any questions concerning the information presented in this manual should be addressed to:
Kidde-Fenwal, Inc.
400 Main Street
Ashland, MA 01721
Phone: (508) 881-2000
Toll Free: (800) 872-6527
Fax: (508) 881-8920
P/N 06-237042-001
i
March 2012
TERMS AND ABBREVIATIONS
AAM:
Addressable Alarmline Module
LED:
Light Emitting Diode
AC:
Alternating Current
MEA:
Materials and Equipment Acceptance
Division of the City of New York
ADA:
Americans with Disabilities Act
NAC:
Notification Appliance Circuit
AH:
Ampere Hour
N.C.:
Normally Closed
AHJ:
Authority Having Jurisdiction
NEC:
National Electrical Code
AI:
Addressable Monitor Module
NFPA:
National Fire Protection Association
AIM:
AnaLASER Interface Module
N.O.:
Normally Open
AO:
Addressable Relay
PAS:
Positive Alarm Sequence
ASM
Addressable Signal Module
PCB:
Printed Circuit Board
AV:
Alarm Verification
pF:
Pico-farads
AWG:
American Wire Gauge
PMU:
Power Management Unit
BPM:
Beats per Minute
P/N:
Part Number
CPU:
Central Processing Unit
RAM:
Random Access Memory
CSFM:
California State Fire Marshal
RDCM:
Remote Display Control Module
DC:
Direct Current
RF:
Radio-Frequency
EOC:
Event Output Control
R-NAC
Release/NAC
EOLD:
End of Line Device
RRM
Remote Releasing Module
FCS8000
FenwalNET Configuration Software
SLC:
Signaling Line Circuit
FM/FMRC: Factory Mutual (Research Corporation)
SMPS:
Switching Mode Power Supply
Ft.:
Feet
TB:
Terminal Block
GAAL:
General Alarm Activation List
UI
User Interface
HSD
High Sensitivity Detector
V:
Volts
Hz:
Hertz (Frequency)
Vac:
Volts AC
IRI:
Industrial Risk Insurers
Vdc:
Volts DC
LAM:
LED Annunciator Module
VRMS:
Volts Root Mean Square
LCD:
Liquid Crystal Display
March 2012
ii
P/N 06-237042-001
SAFETY SUMMARY
This entire manual must be read and understood before installation.
Installation Precautions
WARNING
Adherence to the following will aid in problem-free installation with long-term
reliability:
Several different sources of power can be connected to this fire alarm control unit.
Disconnect all sources of power before servicing. Control unit and associated equipment
may be damaged by servicing while the unit is energized. Do not attempt to install,
service, or operate this control unit until this manual is read and understood.
CAUTION
System Re-acceptance Test after Re-Programming: To ensure proper system operation, this
system must be retested in accordance with NFPA 72 Chapter 10 after any programming
change. Re-acceptance testing is also required after any addition or deletion of system
components, and after any modification, repair or adjustment to system hardware or wiring.
All components, circuits and system operations known to be affected by a change must be
100% tested. In addition, to ensure that other operations are not inadvertently affected, at least
10% of initiating devices that are not directly affected by the change, up to a maximum of 50
devices, must also be tested and proper system operation verified.
CAUTIONS AND WARNINGS
CAUTION
WARNING
P/N 06-237042-001
A caution identifies a procedure, practice, or statement, which, if not strictly followed, could
result in programming errors, impairment of equipment operation, or equipment damage.
A warning identifies an operating or maintenance procedure, practice, condition or
statement, which, if not strictly followed, could result in personal injury or death.
iii
March 2012
NOTICE TO USERS, INSTALLERS, AUTHORITIES HAVING JURISDICTION AND ALL OTHER INVOLVED
PARTIES
This product incorporates field-programmable software. In order for the product to comply with the
requirements in the Standard for Control Units and Accessories for Fire Alarm Systems, UL 864, certain
programming features or options must be limited to specific values or not used at all as indicated below:
Program Feature or Option
Permitted in
UL 864(Y/N)
Possible Settings
Settings Permitted in
UL 864
Ionization Detectors reporting as
supervisory initiating devices
N
0.5 – 1.5% per foot
Report as alarm initiating
devices only
Photoelectric Detectors reporting as
supervisory initiating devices
N
0.5 – 3.5% per foot
Report as alarm initiating
devices only
Abort switches may be set up to
operate in any of the following ways:
1. Reset to initial delay setting.
Resume countdown for entire
delay period.
2. Count down to 10 seconds and
hold. Resume countdown at 10
seconds.
3. Hold at time remaining. Resume
countdown at remaining time
period.
4. Same as #2, except disable
abort function if countdown
timer has started.
5. Special New York City operation.
Y (#2 only)
1 – 300 second delay
1 – 60 second delay
Delayed off premises trouble transmissions for AC power loss.
Y
0 – 12 hours
0 – 3 hours
March 2012
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P/N 06-237042-001
Table of Contents
TABLE OF CONTENTS
Foreword ............................................................................................................................ i
Terms and Abbreviations ................................................................................................... ii
Safety Summary ................................................................................................................. iii
Table of Contents................................................................................................................ v
List of Figures..................................................................................................................... xi
List of Tables ...................................................................................................................... xv
CHAPTER 1
1-1
1-2
1-3
1-4
1-5
1-6
1-6.1
1-6.2
1-6.3
1-6.4
1-6.5
GENERAL INFORMATION
Introduction............................................................................................................ 1-1
PC Requirements .................................................................................................... 1-1
Previous Versions ................................................................................................... 1-1
Installing the FCS8000 software ............................................................................. 1-1
Starting the FCS8000 software ............................................................................... 1-5
Installing the USB Driver for Connection to Control Unit........................................ 1-6
Microsoft Windows 2000 Installation ...................................................................... 1-6
Microsoft Windows XP Installation ......................................................................... 1-6
Microsoft Windows Vista Installation ...................................................................... 1-7
Microsoft Windows 7 Installation ............................................................................ 1-7
Verifying the Installation of USB Drivers (with the Panel Connected to the PC) ....... 1-8
CHAPTER 2
2-1
2-2
2-3
2-4
2-5
2-5.1
2-5.2
2-5.3
2-5.4
2-5.5
2-5.6
2-6
2-7
2-8
2-8.1
2-8.2
2-8.3
2-8.4
2-8.5
2-8.5.1
2-8.5.2
2-8.5.2.1
2-8.5.2.2
2-8.5.3
2-8.5.4
2-8.5.5
2-8.5.6
2-8.5.6.1
CREATING A SYSTEM CONFIGURATION
Introduction............................................................................................................ 2-1
Before You Begin - Version Compatibility................................................................ 2-1
The Main Toolbar ................................................................................................... 2-1
The Side Toolbar .................................................................................................... 2-2
Drop-Down Menus .................................................................................................. 2-3
The FILE Drop-Down Menu .................................................................................... 2-3
The EDIT Drop-Down Menu ................................................................................... 2-4
The VIEW Drop-Down Menu ................................................................................... 2-4
The TOOLS Drop-Down Menu ................................................................................ 2-5
The WINDOW Drop-Down Menu ............................................................................. 2-6
The HELP Drop-Down Menu................................................................................... 2-6
Creating a New Configuration file............................................................................ 2-6
Opening an Existing Configuration File ................................................................... 2-6
The Configuration Editor ........................................................................................ 2-7
The <Apply> Button .............................................................................................. 2-7
The <Reset> Button............................................................................................... 2-7
The SUMMARY Tab ................................................................................................ 2-8
The SLC and EXPANSION I/O Tab.......................................................................... 2-9
Adding and Configuring a New Module ................................................................... 2-10
Adding and configuring a City-Tie Module .............................................................. 2-10
Adding A Relay Module ........................................................................................... 2-11
Configuring a Relay Circuit ..................................................................................... 2-12
Relay Circuit Configuration screen.......................................................................... 2-13
Adding and Configuring an SLC Module ................................................................. 2-14
Adding Network Interface Card ............................................................................... 2-14
Adding And Configuring A Power Management Unit (PMU) Module ........................ 2-16
Adding an R-NAC Module ....................................................................................... 2-17
Configuring An R-NAC module as NAC or Release Circuit....................................... 2-18
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March 2012
Table of Contents
TABLE OF CONTENTS (CONT.)
2-8.5.6.2
2-8.5.6.3
2-8.5.7
2-8.5.8
2-8.6
2-8.7
2-8.7.1
2-8.7.2
2-8.7.3
2-8.7.4
2-8.7.5
2-8.7.6
2-8.8
2-8.9
2-8.9.1
2-8.9.2
2-8.9.3
2-8.10
2-8.11
2-8.12
2-8.13
2-9
2-9.1
2-9.2
2-9.3
2-9.4
2-9.5
2-9.5.1
2-9.5.2
2-9.6
2-9.6.1
2-9.7
2-9.8
2-10
Release/NAC Module (R-NAC) as a NAC (Notification Appliance Circuit) Configuration
Screen .....................................................................................................................2-19
Release/NAC Module (R-NAC) as a Release Circuit Configuration Screen ................2-21
Adding And Configuring A DACT Module ................................................................2-22
Editing a Module .....................................................................................................2-23
The EOC (EVENT OUTPUT CONTROL) Tab ...........................................................2-24
The ON-BOARD Tab................................................................................................2-25
Configuring an On-Board Circuit.............................................................................2-25
Disabling a Circuit...................................................................................................2-26
Notification Appliance Circuit (NAC) Configuration Screen......................................2-27
R-NAC Circuit As A NAC Device Configuration Screen.............................................2-28
R-NAC Circuit As A Release Device Configuration Screen ........................................2-29
Relay Circuit Configuration Screen..........................................................................2-31
The DAY/NIGHT/WEEKEND Tab.............................................................................2-33
The DISPLAY Tab....................................................................................................2-34
Adding a Remote Display control Module (RDCM) ..................................................2-35
Adding an LED Annunciator Module (LAM).............................................................2-36
Adding an ATM Component ....................................................................................2-37
Deleting a Module....................................................................................................2-38
Editing Owner Location...........................................................................................2-38
Designating an RDCM Module as a Master ..............................................................2-39
Deselecting an RDCM as a Master ...........................................................................2-39
The IIM (INTELLIGENT INTERFACE MODULE) Tab..............................................2-40
Configuring IIM Tab Options ...................................................................................2-41
Adding an HSD........................................................................................................2-41
Deleting An HSD......................................................................................................2-42
The STRINGS Tab...................................................................................................2-43
The GLOBAL Tab ....................................................................................................2-44
Changing Timing Options ........................................................................................2-47
Creating Isolation Macros........................................................................................2-48
The SOFTKEYS Tab................................................................................................2-51
Programming Softkeys ............................................................................................2-52
The CALL FOR SERVICE Tab .................................................................................2-53
The RELEASE GROUP Tab.....................................................................................2-54
The OUTPUT GROUP Tab.......................................................................................2-55
CHAPTER 3
3-1
3-2
3-3
3-4
3-4.1
3-4.2
3-4.3
3-4.4
3-5
3-5.1
3-5.2
CONFIGURING SLC DEVICES
Introduction ............................................................................................................3-1
SLC and EXPANSION I/O Tab .................................................................................3-1
Adding an SLC Module (Circuit)..............................................................................3-2
Adding SLC Devices to an SLC Module (Circuit) .....................................................3-3
Editing the Configuration of an SLC Device .............................................................3-6
Editing the Owner Location of an SLC Device..........................................................3-6
Editing the Address of an SLC Device .....................................................................3-7
Editing the Type of an SLC Device...........................................................................3-7
Settings for SLC Devices..........................................................................................3-8
Addressable AlarmLine Module (AAM) Settings Screen ...........................................3-9
Addressable Relay Settings (AO) Screen ..................................................................3-10
March 2012
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P/N 06-237042-001
Table of Contents
TABLE OF CONTENTS (CONT.)
3-5.3
3-5.4
3-5.4.1
3-5.5
3-5.5.1
3-5.6
3-5.7
3-5.8
3-5.9
3-5.9.1
3-5.10
3-5.11
3-5.12
3-5.12.1
3-5.12.2
3-5.13
3-6
Addressable Sounder Module (ASM) Settings Screen ............................................. 3-11
Ion Smoke Detector (ION) Settings Screen.............................................................. 3-12
Application Definitions via Drop-Down Menu ......................................................... 3-13
Photoelectric Smoke Detector (PHOTO) Settings Screen......................................... 3-13
Application Definitions via Drop-Down Menu ......................................................... 3-14
Heat Detector (THERMAL) (Model THD-7252) Settings Screen............................... 3-15
AnaLASER Interface Module (AIM) Settings Screen ................................................ 3-17
Alarm (ALARM) Settings Screen ............................................................................. 3-18
Abort Station (ABORT) Settings Screen .................................................................. 3-18
Abort Station Settings Definitions ........................................................................... 3-19
Supervisory Input (SUPV) Settings Screen .............................................................. 3-20
Waterflow Input (WATER) Settings Screen .............................................................. 3-20
Remote Releasing Module (RRM) Settings Screen ................................................... 3-21
Configuring an RRM with an Initiator Releasing Device........................................... 3-21
Configuring an RRM with a Solenoid Releasing Device............................................ 3-22
Configuring An Isolation Macro Input ..................................................................... 3-24
Other SLC Initiating Devices ................................................................................... 3-24
CHAPTER 4
4-1
4-1.1
4-1.2
4-2
4-2.1
4-2.2
4-2.2.1
4-3
4-3.1
4-3.2
4-3.2.1
4-3.2.2
4-3.2.3
4-4
4-5
4-6
4-6.1
4-6.2
4-6.3
4-6.4
4-6.5
4-6.6
4-6.7
4-6.8
4-6.9
4-6.10
4-6.11
4-6.12
4-6.13
EVENT OUTPUT CONTROL (EOC)
Introduction............................................................................................................ 4-1
Before You Begin..................................................................................................... 4-1
Event Output Control.............................................................................................. 4-1
Constructing Arguments ......................................................................................... 4-1
Simple Arguments .................................................................................................. 4-3
Compound Arguments ............................................................................................ 4-3
“And” Operator ....................................................................................................... 4-4
Outputs................................................................................................................... 4-5
Physical Outputs ..................................................................................................... 4-5
Virtual Outputs ....................................................................................................... 4-6
Counting Identifiers (Ix) .......................................................................................... 4-6
State Variable (Cx) .................................................................................................. 4-7
Incrementing Variable (Qx) ..................................................................................... 4-8
Multiple Outputs..................................................................................................... 4-9
The "NOT" Operator................................................................................................ 4-10
Functions................................................................................................................ 4-10
Alarm Threshold Adjustment Function (Smoke Detectors Only)............................. 4-10
Pre-Alarm Threshold Adjustment Function (Smoke Detectors Only) ...................... 4-10
Delayed Output Activation Function (without explicit Abort Interruption)............... 4-11
Delayed Output Activation Function (with explicit Abort Interruption).................... 4-11
Trouble Function for Initiating Devices ................................................................... 4-12
General Trouble Function....................................................................................... 4-12
General Supervisory Function ................................................................................ 4-12
General Alarm Function.......................................................................................... 4-13
Pre-Alarm Function for Initiating Devices ............................................................... 4-13
Warning Function for AnaLASER II Detectors Reporting via the IIM ....................... 4-13
Level-2 Alarm Function for AnaLASER IIs reporting via the IIM ............................. 4-13
Notification Appliance Pattern Change Function to 60 BPM .................................... 4-14
Notification Appliance Pattern Change Function to 120 BPM .................................. 4-14
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March 2012
Table of Contents
TABLE OF CONTENTS (CONT.)
4-6.14
4-6.15
4-6.16
4-7
4-7.1
4-7.2
4-7.3
4-8
4-8.1
4-8.2
4-9
4-10
4-11
4-11.1
4-11.2
4-11.3
CHAPTER 5
5-1
5-2
5-3
5-3.1
5-3.2
5-3.3
5-3.3.1
5-3.3.2
5-3.4
5-3.4.1
5-3.4.2
5-3.5
5-3.6
5-3.6.1
5-3.7
5-3.7.1
5-3.7.2
5-3.7.3
5-3.7.4
5-3.8
5-3.8.1
5-3.9
5-3.9.1
5-3.10
5-3.11
5-3.12
March 2012
Notification Appliance Pattern Change Function to Temporal Coding......................4-15
Notification Appliance Pattern Change Function to Continuous Output...................4-15
Initiating Event Counting Function ..........................................................................4-16
Constructing Arguments for Initiating Events from Remote, Networked Control
Units .......................................................................................................................4-17
Remote-Node Simple Arguments .............................................................................4-17
Remote-Node Compound Arguments.......................................................................4-17
Remote State Variable (Fy:Cx) .................................................................................4-17
Creating Event Output Control (EOC Tab)...............................................................4-28
The <Apply> Button...............................................................................................4-30
The <Reset> Button ...............................................................................................4-30
Structuring Event Output Control ...........................................................................4-31
Event Output Control Examples ..............................................................................4-32
Additional Event Output Control Examples.............................................................4-34
Limited Water Supply Example ...............................................................................4-34
NAC that Tracks AnaLASER II Alarm State .............................................................4-35
External Maintenance Bypass Switch Example........................................................4-36
COMMUNICATIONS TO THE CONTROL UNIT
Introduction ............................................................................................................5-1
Hardware Connections ............................................................................................5-2
Communication Utilities..........................................................................................5-3
Selecting Node and Entering Password ...................................................................5-3
Communications Setup ...........................................................................................5-4
Sending a Configuration ..........................................................................................5-5
Selecting A File To Send..........................................................................................5-5
Sending a Configuration ..........................................................................................5-6
Receive a Configuration ...........................................................................................5-6
Selecting the File to Receive.....................................................................................5-7
Receiving a Configuration ........................................................................................5-7
Online .....................................................................................................................5-8
Get Sensitivity Levels...............................................................................................5-9
Retrieve Sensitivity Levels .......................................................................................5-9
Event Log ................................................................................................................5-10
Clearing The Event Log ...........................................................................................5-10
Receiving An Event Log ...........................................................................................5-12
The Event Log .........................................................................................................5-13
View Event Log ........................................................................................................5-13
Receive Test Log ......................................................................................................5-13
Receiving A TEST Log .............................................................................................5-13
Receive Walk Test Log .............................................................................................5-15
Receiving A Walk Test Log .......................................................................................5-15
Receive Network Node Map .....................................................................................5-16
Verify.......................................................................................................................5-16
Compare .................................................................................................................5-17
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Table of Contents
TABLE OF CONTENTS (CONT.)
Appendix A— System Example........................................................................................................A-1
A-1
Introduction............................................................................................................ A-1
Appendix B— NEW YORK CITY ABORT SEQUENCE........................................................................B-1
B-1
Introduction............................................................................................................B-1
B-2
General Discussion .................................................................................................B-1
B-2.1
Sequence of Operation ............................................................................................B-1
B-2.2
System Configuration..............................................................................................B-1
B-2.3
Program for N.Y.C. Abort Sequence ........................................................................B-2
Appendix C— Firmware Upgrade Instructions .................................................................................C-1
C-1
Before You Begin.....................................................................................................C-1
C-2
Prerequisites...........................................................................................................C-1
C-3
Software Installation ...............................................................................................C-1
C-4
Physical Connections ..............................................................................................C-2
C-5
Launching the Upgrade Utility.................................................................................C-2
C-6
Menu Options .........................................................................................................C-2
C-7
Specifying Language................................................................................................C-2
C-8
Updating the Firmware ...........................................................................................C-3
C-8.1
Specifying the COM port .........................................................................................C-3
C-8.2
Logging in to the panel ............................................................................................C-3
C-8.3
Upgrading the firmware ..........................................................................................C-4
C-9
Upgrading Additional Devices .................................................................................C-5
C-10
Reverting to a Previous Binary File .........................................................................C-5
C-11
Firmware Upgrade Utility Troubleshooting Guide...................................................C-6
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Table of Contents
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March 2012
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P/N 06-237042-001
List of Figures
LIST OF FIGURES
Figure
1-1
1-2
1-3
1-4
1-5
1-6
1-7
1-8
Name
Page Number
FCS8000 Welcome Screen ........................................................................................................ 1-2
Choose Destination Location Screen......................................................................................... 1-2
Choose Folder Screen............................................................................................................... 1-3
Select Program Folder Screen .................................................................................................. 1-3
Desktop Shortcut Screen.......................................................................................................... 1-4
InstallShield Wizard Complete Screen ...................................................................................... 1-4
Main Screen.............................................................................................................................. 1-5
Toolbar Icon Descriptions ........................................................................................................ 1-5
2-1
2-2
2-3
2-4
2-5
2-6
2-7
2-8
2-9
2-10
2-11
2-12
2-13
2-14
2-15
2-16
2-17
2-18
2-19
2-20
2-21
2-22
2-23
2-24
2-25
2-26
2-27
2-28
2-29
2-30
2-31
2-32
2-33
2-34
2-35
2-36
2-37
2-38
2-39
2-40
2-41
2-42
2-43
2-44
Main Toolbar ............................................................................................................................ 2-1
Side Toolbars (shown expanded).............................................................................................. 2-2
Drop-Down Menus.................................................................................................................... 2-3
File>Print Detailed Configuration Printout Screen ................................................................... 2-4
SUMMARY Tab ......................................................................................................................... 2-8
SLC and EXPANSION I/O Tab .................................................................................................. 2-9
Module Choices from SLC and EXPANSION I/O>Add... ........................................................... 2-10
City-Tie Module Physical Address Screen ................................................................................. 2-10
City-Tie Settings Screen ............................................................................................................ 2-11
Relay Module Physical Address Screen ..................................................................................... 2-11
Relay Module Setting Configuration Screen .............................................................................. 2-12
Relay Circuit Configuration Screen ........................................................................................... 2-13
Network Card Physical Address Screen .................................................................................... 2-14
Network Interface Card Settings Screen.................................................................................... 2-15
PMU Module Setting Configuration Screen ............................................................................... 2-16
R-NAC Module Physical Address Screen ................................................................................... 2-17
R-NAC Module Setting Configuration Screen ............................................................................ 2-17
R-NAC Type Configuration Screen ............................................................................................ 2-18
NAC Configuration Screen ........................................................................................................ 2-19
Release Circuit Configuration Screen........................................................................................ 2-21
DACT Module Physical Address Screen .................................................................................... 2-22
DACT Module Setting Configuration Screen ............................................................................. 2-22
EVENT OUTPUT CONTROL (EOC) Tab ................................................................................... 2-24
ON-BOARD Tab ........................................................................................................................ 2-25
Update Device State Screen ...................................................................................................... 2-26
DISABLED Cautionary Message................................................................................................ 2-26
NAC Configuration Screen ........................................................................................................ 2-27
Release Circuit Configuration Screen........................................................................................ 2-29
Programmable Relay Configuration Screen............................................................................... 2-31
DAY/NIGHT/WEEKEND Tab ..................................................................................................... 2-33
DISPLAY Tab............................................................................................................................ 2-34
RDCM Range Entry Dialog Box ................................................................................................. 2-35
RDCM Setting Configuration Screen ......................................................................................... 2-35
LAM Range Entry Dialog Box .................................................................................................... 2-36
LAM Setting Configuration Screen ............................................................................................ 2-36
ATM Range Entry Dialog Box.................................................................................................... 2-37
ATM Owner Location Dialog Box .............................................................................................. 2-38
Owner Location Dialog Box....................................................................................................... 2-39
IIM Tab..................................................................................................................................... 2-40
HSD Range Entry Dialog Box.................................................................................................... 2-41
STRINGS Tab........................................................................................................................... 2-43
Enter String... Dialog Box ......................................................................................................... 2-43
GLOBAL Tab ............................................................................................................................ 2-45
Global Timers Dialog Box from Global Tab .............................................................................. 2-47
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March 2012
List of Figures
LIST OF FIGURES (CONT.)
Figure
2-45
2-46
2-47
2-48
2-49
2-50
2-51
2-52
2-53
Name
Page Number
Isolation Macro Code Dialog Box...............................................................................................2-49
Select Type Dialog Box ..............................................................................................................2-50
Range Dialog Box ......................................................................................................................2-50
SOFTKEYS Tab ........................................................................................................................2-51
Softkey Dialog Box ....................................................................................................................2-52
Softkey Type List ......................................................................................................................2-52
CALL FOR SERVICE Tab ..........................................................................................................2-53
RELEASE GROUP Tab .............................................................................................................2-54
Output Group Tab ....................................................................................................................2-55
3-1
3-2
3-3
3-4
3-5
3-6
3-7
3-8
3-9
3-10
3-11
3-12
3-13
3-14
3-15
3-16
3-17
3-18
3-19
3-20
3-21
3-22
3-23
3-24
3-25
3-26
SLC and EXPANSION I/O Tab List ............................................................................................3-1
Select Type (of Module) Screen .................................................................................................3-2
Range Entry Dialog Box.............................................................................................................3-2
Signal Line Circuit (SLC) Settings Dialog Box ...........................................................................3-3
List of Registered SLC Devices Dialog Box and List...................................................................3-3
SLC Device Range Entry Dialog Box ..........................................................................................3-4
Select Type... (SLC Devices) Screen ..........................................................................................3-5
List of Registered SLC Devices ..................................................................................................3-5
Owner Location Dialog Box .......................................................................................................3-6
SLC Device Address Dialog Box ................................................................................................3-7
Select Type... (SLC Devices) Screen ..........................................................................................3-8
Addressable AlarmLine Settings Screen ....................................................................................3-9
Addressable Relay Settings Screen............................................................................................3-10
Addressable Sounder Module Settings Screen ..........................................................................3-11
Ion Smoke Detector Settings Screen .........................................................................................3-12
Photoelectric Smoke Detector Settings Screen ..........................................................................3-13
Heat Detector Settings Screen ...................................................................................................3-15
Thermal Cycling Settings Screen...............................................................................................3-16
AnaLASER Interface Module Settings Screen ............................................................................3-17
Alarm Settings Screen...............................................................................................................3-18
Abort Station Settings Screen ...................................................................................................3-18
Supervisory Input Settings Screen ............................................................................................3-20
Waterflow Input Settings Screen................................................................................................3-20
Remote Releasing Module Settings Screen (Using an Initiator as a Releasing Device) ................3-21
Remote Releasing Module Settings Screen (Using a Solenoid as a Releasing Device).................3-22
Isolation Macro Number Menu ..................................................................................................3-24
4-1
4-2
4-3
4-4
4-5
4-6
4-7
EOC Creation Screen ................................................................................................................4-28
EOC Text Editor Screen ............................................................................................................4-28
Saved EOC Code Screen ...........................................................................................................4-29
EOC Error and/or Warning Screen............................................................................................4-30
Limited Water Supply ...............................................................................................................4-34
Tracking NAC............................................................................................................................4-35
Maintenance Bypass Switch ......................................................................................................4-36
5-1
5-2
5-3
5-4
5-5
5-6
5-7
5-8
Tools Drop-Down Menu ............................................................................................................5-1
FenwalNET 8000-ML Configuration Software Main Toolbar .....................................................5-1
Hardware Connection from FenwalNET 8000-ML Control Unit to Laptop Computer................5-2
Non-Networked Panel Enter Password Screen ..........................................................................5-3
Networked Panel Choose Node and Enter Password Screen .....................................................5-4
USB Communication Setting Screen .........................................................................................5-4
RS232 Communication Setting Screen......................................................................................5-5
Select A Configuration Screen ...................................................................................................5-5
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List of Figures
LIST OF FIGURES (CONT.)
Figure
5-9
5-10
5-11
5-12
5-13
5-14
5-15
5-16
5-17
5-18
5-19
5-20
5-21
5-22
5-23
5-24
5-25
5-26
5-27
5-28
5-29
5-30
5-31
5-32
Name
Page Number
Send Configuration Progress Screen......................................................................................... 5-6
Send Configuration Complete Screen ....................................................................................... 5-6
Select A Configuration Screen................................................................................................... 5-7
Receive Configuration Progress................................................................................................. 5-8
Receive Configuration Complete ............................................................................................... 5-8
Online Terminal-Emulation Mode ............................................................................................ 5-9
Select A SLC Module Screen..................................................................................................... 5-9
Range Screen ............................................................................................................................ 5-10
Retrieving Sensitivity Levels...................................................................................................... 5-10
Event Log Query ....................................................................................................................... 5-11
Clear Event Log Progression ..................................................................................................... 5-11
Clear Event Log Complete......................................................................................................... 5-11
Clear Event Log Abort............................................................................................................... 5-11
Event Log Data Range ............................................................................................................... 5-12
Receive Event Log Progression.................................................................................................. 5-12
Event Log Received Confirmation ............................................................................................. 5-12
Event Log Screen ...................................................................................................................... 5-13
Receive Test Log Progress......................................................................................................... 5-14
Test Log Screen ........................................................................................................................ 5-14
Receive Walk Test Log Progress ................................................................................................ 5-15
Walk Test Log ........................................................................................................................... 5-15
Network Node Map ................................................................................................................... 5-16
Verification Summary............................................................................................................... 5-16
Configuration Compare Results Screen .................................................................................... 5-17
A-1
Example of Sequence of Operation ........................................................................................... A-1
B-1
New York City Installation ........................................................................................................B-4
C-1
C-2
C-3
C-4
C-5
Upgrade Utility Main Menu .......................................................................................................C-2
Select Port Window...................................................................................................................C-3
Login Authorization Screen ......................................................................................................C-3
Module Upgrade Screen............................................................................................................C-4
Success Screen .........................................................................................................................C-5
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List of Figures
THIS PAGE INTENTIONALLY LEFT BLANK.
March 2012
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List of Tables
LIST OF TABLES
Table
2-1
2-2
2-3
2-4
2-5
2-6
2-7
2-8
2-9
2-10
2-11
2-12
2-13
2-14
2-15
2-16
2-17
2-18
2-19
2-20
2-21
2-22
2-23
2-24
Name
Page Number
FILE Commands ...................................................................................................................... 2-3
VIEW Commands ..................................................................................................................... 2-5
TOOLS Commands .................................................................................................................. 2-5
WINDOW Commands................................................................................................................ 2-6
HELP Commands ..................................................................................................................... 2-6
SUMMARY Tab Options............................................................................................................ 2-8
SLC and EXPANSION I/O Tab Options ..................................................................................... 2-9
Relay Circuit Configuration Screen Options.............................................................................. 2-13
Network Interface Card Configuration Screen Options. ............................................................ 2-15
PMU Setting Configuration Screen Options............................................................................... 2-16
NAC Configuration Screen Options........................................................................................... 2-19
Release Circuit Configuration Screen Options .......................................................................... 2-21
DACT Setting Configuration Screen Options............................................................................. 2-23
NAC Configuration Screen Options........................................................................................... 2-27
Release Circuit Configuration Screen Options .......................................................................... 2-29
Relay Circuit Configuration Screen Options.............................................................................. 2-31
DAY/NIGHT/WEEKEND Screen Options ................................................................................... 2-33
DISPLAY Screen Options .......................................................................................................... 2-34
LAM Configuration Options ...................................................................................................... 2-37
IIM Screen Options ................................................................................................................... 2-41
GLOBAL Tab Options............................................................................................................... 2-45
Global Timers Dialog Box Options............................................................................................ 2-47
Isolation Macro Devices to be Selected ..................................................................................... 2-48
Isolation Macro Code Dialog Box Options ................................................................................. 2-49
3-1
3-2
3-3
3-4
3-5
3-6
3-7
3-8
3-9
3-10
3-11
3-12
3-13
3-14
3-15
3-16
3-17
3-18
3-19
3-20
3-21
SLC and EXPANSION I/O Tab Options ..................................................................................... 3-2
List of Registered SLC Devices Screen Options......................................................................... 3-4
Addressable AlarmLine Settings Screen Options ...................................................................... 3-9
Addressable Relay Settings Screen Options .............................................................................. 3-10
Addressable Sounder Module Settings Screen Options............................................................. 3-11
Ion Smoke Detector Settings Screen Options............................................................................ 3-12
Model CPD-7052 Ionization Smoke Detector Pre-Alarm/Alarm Ranges..................................... 3-13
Photoelectric Smoke Detector Settings Screen Options ............................................................ 3-13
Model PSD-7152 Photoelectric Smoke Detector Pre-Alarm/Alarm Range.................................. 3-14
Heat Detector Settings Screen Options ..................................................................................... 3-15
Thermal Detector Pre-Alarm/Alarm Ranges .............................................................................. 3-15
AnaLASER Interface Module Settings Screen Options .............................................................. 3-17
Alarm Module Settings Screen Options .................................................................................... 3-18
Abort Station Module Settings Screen Options ......................................................................... 3-19
Abort Definitions ...................................................................................................................... 3-19
Supervisory Input Module Settings Screen Options .................................................................. 3-20
Waterflow Module Settings Screen Options............................................................................... 3-21
Remote Releasing Module Settings Screen (with Initiator as Releasing Device) Options............ 3-22
Remote Releasing Module Settings Screen (with Solenoid as Releasing Device) Options........... 3-23
Isolation Macro Input Options .................................................................................................. 3-24
Configurable Parameters .......................................................................................................... 3-25
4-1
4-2
4-3
4-4
4-5
4-6
Initiating Devices ...................................................................................................................... 4-2
Input Symbolic Representations ............................................................................................... 4-3
Combining Operators for Initiating Arguments ......................................................................... 4-3
Control Unit-Based Outputs ..................................................................................................... 4-5
Combining Operators for Outputs ............................................................................................ 4-9
EOC Operators and Functions.................................................................................................. 4-18
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LIST OF TABLES (CONT.)
Table
4-7
4-8
4-9
Name
Page Number
EOC Tab Options ......................................................................................................................4-29
EOC, Example 1........................................................................................................................4-32
EOC, Example 2........................................................................................................................4-33
5-1
Locations of Communications Utilities Descriptions in Manual.................................................5-3
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General Information
CHAPTER 1
GENERAL INFORMATION
1-1
INTRODUCTION
FenwalNET 8000-MLTM Configuration Software (FCS8000) is a Microsoft® Windows-based
application that is used to create specific applications for FenwalNET 8000-ML control units.
FCS8000 enables the user to create a complete system configuration, including details for initiating
devices, output control and display messages.
1-2
PC REQUIREMENTS
Minimum computer requirements for the FCS8000 are listed below. System requirements vary
between operating systems. Refer to the appropriate section.
For computers with Microsoft Windows 7 installed:
•
1 gigahertz (GHz) or faster 32-bit (x86) or 64-bit processor
•
1 gigabyte (GB) of memory (RAM) (32-bit) or 2 GB RAM (64-bit) or higher recommended
For computers with Microsoft Windows Vista installed:
•
1 gigahertz (GHz) or faster 32-bit (x86) or 64-bit processor
•
1 gigabyte (GB) of memory (RAM) or higher recommended, 512 megabytes (MB) for Home Basic
For computers with Microsoft Windows XP installed:
•
300 MHz or higher processor clock speed recommended; 233 MHz minimum required (single or
dual processor system); Intel® Pentium®/Celeron® family, or AMD® K6®/Athlon®/Duron® family,
or compatible processor recommended
•
128 MB of memory (RAM) or higher recommended
For computers with Microsoft Windows 2000 installed:
1-3
•
133 MHz or higher Pentium-compatible CPU
•
64 MB of memory (RAM) or higher recommended
PREVIOUS VERSIONS
Please remove all previous versions of the software before installing the latest version. Remove the
older versions either through the Control Panel’s Add/Remove program window or using the Uninstall
utility.
1-4
INSTALLING THE FCS8000 SOFTWARE
1.
Insert the CD-ROM into drive.
2.
If AutoRun is enabled on the computer, InstallShield® begins automatically. If InstallShield does not
begin automatically, locate the drive and find the file titled "Setup.exe". Double-click on the file to begin
the InstallShield Wizard.
3.
After the InstallShield Wizard is finished processing, it displays the InstallShield Welcome
Screen (Figure 1-1). Select the <Next> button to proceed to the next screen.
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General Information
Figure 1-1. FCS8000 Welcome Screen
4.
The Choose Destination Location screen displays (Figure 1-2). Setup suggests a default
installation directory of C: \FCS8000. To choose another location to place the program, click the
<Browse> button; otherwise, click <Next>.
Figure 1-2. Choose Destination Location Screen
5.
March 2012
The Choose Folder screen displays (Figure 1-3) to allow the user to select a different installation
directory for the program. Click <OK> to proceed with your selection.
1-2
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Figure 1-3. Choose Folder Screen
6.
The Select Program Folder displays (Figure 1-4). Select the desired program folder. The
program folder is the folder where you can find a shortcut to the program underneath the “Start>
Programs” menu. Setup suggests a default program folder of C:\FCS8000. To choose another
folder, scroll down the list and double-click on the folder in which FCS8000 should be placed,
or type in a new folder name. Click <Next>.
Figure 1-4. Select Program Folder Screen
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General Information
7.
The Desktop Shortcut screen displays (Figure 1-5). Select <Yes> to add a desktop shortcut to
FCS8000 on your desktop.
Figure 1-5. Desktop Shortcut Screen
8.
The InstallShield Wizard Complete screen displays (Figure 1-6). Setup of FCS8000 is
complete.
Select the “I would like to start FenwalNET 8000-ML v x.x.x” (where x.x.x is the software version)
check box to start the software.
Select the “I would like to view the README file” check box to view the readme file.
After making selections, click <Finish> to close the installation wizard.
Figure 1-6. InstallShield Wizard Complete Screen
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General Information
1-5
STARTING THE FCS8000 SOFTWARE
Select Start>Programs>FCS8000 from the Start menu or double-click on the Fenwal FCS8000 icon
on the desktop.
The following screen displays.
Tools Menu
View Menu
File Menu
Status Bar
Figure 1-7. Main Screen
Figure 1-8 describes each of the icons located on the tool bar on the Main Screen (Figure 1-7). The
operation of the tool bar icons is described in Chapter 5.
Print File
Save File
Open File
New File
Compare Configuration
Verify Configuration
Receive Network Node Map
Send Configuration
Receive Configuration
Online
Clear Event Log
Receive Event Log
Figure 1-8. Toolbar Icon Descriptions
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General Information
1-6
INSTALLING THE USB DRIVER FOR CONNECTION TO CONTROL UNIT
A computer with FCS8000 installed is not able to communicate with the control unit using USB
until the USB driver has been installed. Instructions to install a USB driver are listed below.
For proper installation, the computer must be equipped with Microsoft Windows 2000, XP,
Vista, or Windows 7. Operating systems prior to Microsoft Windows 2000 should use the
computer’s RS-232 serial port to communicate with the control unit.
1-6.1
Microsoft Windows 2000 Installation
To install the drivers for the FenwalNET 8000-ML on Microsoft Windows 2000:
1.
Browse to the hard drive folder where the FenwalNET 8000-ML Configuration Software was
installed.
2.
Locate and unzip the file “USBdriverx86.zip” found in that directory.
3.
Connect the USB Cable to any available USB port.
4.
Connect the FenwalNET 8000-ML control unit to the USB cable with the control unit power
ON.
5.
A "Found New Hardware" screen opens the "Found New Hardware Wizard" screen on the
computer. Click <Next>.
6.
Select "Search for a suitable driver for my device (recommended)". Click <Next>.
7.
Select “Search for the best driver in these locations.”
8.
Check "Include this location in the search". De-select all other boxes. Provide the location where
the FenwalNET 8000-ML Configuration Software was installed. Click <Next>.
9.
The message “Windows found a driver for this device” should appear. To install the driver
Windows found, click <Next>. The driver name: “USBMCB.inf” should be displayed. Click
<Next> to continue.
10. When the file copy is complete, a screen saying “Windows has finished…” displays.
11. Click <Finish> to complete the installation.
12. If Microsoft Windows prompts for a reboot after installation, do so.
1-6.2
Microsoft Windows XP Installation
To install the drivers for the FenwalNET 8000-ML on Microsoft Windows XP:
1.
Browse to the hard drive folder where the FenwalNET 8000-ML Configuration Software was
installed.
2.
If you have 64-bit Windows, locate and unzip the file “USBdriver64-bit.zip” found in that
directory. Otherwise, locate and unzip the file “USBdriverx86.zip”.
3.
Connect the USB Cable to any available USB port.
4.
Connect the FenwalNET 8000-ML control unit to the USB cable with the control unit power
ON.
5.
A "Found New Hardware—USB Device" balloon displays followed by the "Found New Hardware
Wizard" screen.
6.
Select: "Install from a list or specific location (Advanced)" and click <Next>.
7.
Select “Search for the best driver in these locations.”
8.
Check "Include this location in the search". De-select all other boxes. Provide the location where
the FenwalNET 8000-ML Configuration Software was installed. Click <Next>.
9.
The next screen displays "Please wait while the wizard installs the software..." accompanied by a
prompt to install the driver even though it has not passed Windows Logo testing. Select
<Continue Anyway>.
10. Select <Finish> to complete the installation.
11. A "Found New Hardware: Your new hardware is installed and ready to use" balloon should
display, indicating that installation was performed successfully.
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1-6.3
Microsoft Windows Vista Installation
To install the drivers for FCS8000 on Microsoft Windows Vista:
1.
Browse to the hard drive folder where the FenwalNET 8000-ML Configuration Software was
installed.
2.
Locate and unzip the file “USBdriverVista.zip” found in that directory.
3.
Connect the USB Cable to any available USB port.
4.
Connect the FenwalNET 8000-ML control unit to the USB cable with the control unit power ON.
5.
A "Found New Hardware" screen opens. Click <Locate and install driver software
(recommended)> and click <Continue>.
6.
Windows will prompt you where to search. Click <Don't search online>.
7.
Select the option “Browse my computer for driver software (advanced)". Click <Browse> and
navigate to the hard drive folder where the FenwalNET 8000-ML Configuration Software was
installed. Select <Next> to continue.
8.
Windows will prompt you to proceed. Select <Install this driver software anyway> to continue.
9. A message should display stating “Found New Hardware-USB Serial Ports Driver”.
10. Click <Close> to exit.
1-6.4
Microsoft Windows 7 Installation
To install the drivers for the FenwalNET 8000-ML Configuration Software on Microsoft Windows 7:
1.
Browse to the hard drive folder where the FenwalNET 8000-ML Configuration Software was
installed.
2.
If you have 64-bit Windows, locate and unzip the file “USBdriver64-bit.zip” found in that
directory. Otherwise, locate and unzip the file “USBdriverx86.zip”.
3.
Connect the USB Cable to any available USB port.
4.
Connect the FenwalNET 8000-ML control unit to the USB cable with the control unit power ON.
5.
Windows 7 may attempt to automatically install the driver by connecting to Windows Update.
If that process fails, open the Device Manager from the Control Panel. With the Device Manager
open, locate the device under “Other devices” entitled “MLICUSBSerial”. Right-click on
“MLICUSBSerial” and choose “Properties”. In the Properties window, click the “Driver” tab. Click
<Update Driver...>.
6.
An "Update Driver Software" screen opens. Click <Browse my computer for driver software>.
7.
Browse to the hard drive folder where the FenwalNET 8000-ML Configuration Software was
installed. Click <Next>.
8.
Windows will prompt you to proceed. Click <Install this driver software anyway>.
9.
Click <Close> to complete the installation.
10. If Microsoft Windows prompts for a reboot after installation, do so.
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General Information
1-6.5
March 2012
Verifying the Installation of USB Drivers (with the Panel Connected to the PC)
1.
Open the "System" applet in the "Control Panel", click the "Hardware" tab and open the "Device
Manager".
2.
In the device tree, locate the "Ports (COM and LPT)" item and expand it. If "USB Serial Ports
Driver" does not display in the device list, or if there is an exclamation point next to it, then it is
not installed properly.
3.
Verify there are no other ports configured with the same COM#. If there are, that device's port
designation must be changed. (The Control Panel uses the Windows enumerator to find the first
available port. Port selection is beyond our control, and the conflict occurred because the other
device did not enumerate itself properly in the Windows registry.)
4.
After installing the FenwalNET 8000-ML Configuration Software, open it. Next, open the
"Communications Settings" dialog by choosing the "Tools>Communications Setup" menu
option.
5.
With the panel still connected via USB, the annotation: "[USB-FN8000-ML]" should accompany
one of the COM ports in the dialog. Otherwise the PC software does not recognize the port that
the panel is connected on. Call Technical Support if this is the case.
1-8
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Creating a System Configuration
CHAPTER 2
CREATING A SYSTEM CONFIGURATION
2-1
INTRODUCTION
The tasks required to create an FCS8000 configuration are as follows:
•
Assign an address and define the operating characteristics for each device on the SLC modules.
•
Define the operating characteristics for each on-board output circuit.
•
Define the operating characteristics for each expansion card.
•
Identify and assign an address to all associated peripheral components such as Remote Display
Control Module (RDCM), LED Annunciator Modules (LAM), and ATM-L/-R Modules.
•
Create the required initiating device to output circuit/device relationships via Event Output
Control (EOC). These relationships must be created for all initiating devices and outputs
associated with each FenwalNET 8000-MLTM system. EOC configuration is described in detail in
Chapter 4.
Note: All alarm events must be annunciated by public-mode notification.
The following requirements apply to special extinguishing systems: HSD
2-2
•
The pre-alarm state must be annunciated by distinctive public mode notification.
•
The pre-alarm state must be annunciated by public mode notification different from the prealarm state public notification mode.
•
The release state must be annunciated by public mode notification different from both the prealarm state and the pre-release public notification modes.
BEFORE YOU BEGIN - VERSION COMPATIBILITY
The configuration software version must match the control unit software version in the first two
digits. For example, if the control unit version is 1.2.0, the configuration software version must be
1.2.x where 'x' is 0 to 9. It is possible to open files saved with an older version of the configuration
program.
Note: It is not possible to communicate with or open saved configuration files for a control unit
version that is newer than the configuration software version. Refer to Appendix C for
instructions for upgrading the control unit version.
2-3
THE MAIN TOOLBAR
When the FenwalNET 8000-ML Configuration Software is launched, the program’s main toolbar
displays (see Figure 2-1). Icons may be selected for configuration file managment and printing,
sending/receiving configurations, communicating with the FenwalNET 8000-ML control panel, and
verifying/comparing configurations.
Note: The Configuration Editor launches only when a configuration file is opened (File>Open) or
created (File>New).
Figure 2-1. Main Toolbar
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Creating a System Configuration
2-4
THE SIDE TOOLBAR
An optional method to view icons is to use the program’s side toolbars. The File, Tools and Help
drop-down menu commands may be accessed by placing the mouse pointer on the desired icon.
Figure 2-2. Side Toolbars (shown expanded)
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Creating a System Configuration
2-5
DROP-DOWN MENUS
In addition to icons, menu commands may be selected via drop-down menus located at the top of the
main screen.
Figure 2-3. Drop-Down Menus
2-5.1
The FILE Drop-Down Menu
Use the FILE drop-down menu (see Figure 2-3) to create, load, unload, store and print configuration
files. In addition, use the FILE drop-down menu to exit the FenwalNET 8000-ML Configuration
Software.
The FILE commands from the main menu are shown in Table 2-1.
Table 2-1. FILE Commands
Command
Function
New
Select New or press <CTRL>-N to create a new configuration file with the extension “.fms”.
Open
Select Open or press <CTRL>-O to open an existing configuration file with the extension
“.fms”. Use the standard Windows dialog box to navigate to the desired directory, and doubleclick the file or select <Open> to load the file.
Close
Select Close to close the topmost configuration file. If the file has been modified since it was
last saved, a dialog box appears, requesting that the file be saved.
Save
Select Save to save the topmost configuration to disk with the existing filename.
Save As
Save As Text
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Select Save As to save the topmost configuration to disk, after a filename is entered.
Select Save As Text to save the topmost configuration to an ASCII text file. When Save As Text
is selected, the screen shown below in Figure 2-4 is presented. Select the desired configuration
settings to save to a textfile and select <OK>. A dialog box will appear requesting a filename
(with filename extension “.txt”).
Note: If either the Save, Save As, or Exit (with file save) commands are selected, a verification
of the current configuration is performed first. If errors are found, a list will generate on the
screen and settings will not be saved. All errors must be corrected before the software will save
the configuration file. However, the file will be saved if warnings are present.
2-3
March 2012
Creating a System Configuration
Table 2-1. FILE Commands (Continued)
Command
Function
Print
Select Print to print the current configuration (to a network or local printer). When Print is
selected, the screen shown in Figure 2-4 is presented. Select the desired configuration settings
to print and select <OK>. A dialog box will appear requesting printer settings. Select the
desired printer and <OK> to print the selected topics.
Print Preview
Select Print Preview to display hard copy pages of the current configuration.
Print Setup
Select Print Setup to display the printer settings dialog box where the desired printer may be
selected and configured.
Exit
Select Exit to close the FenwalNET 8000-ML Configuration Software. A message will prompt to
save any unsaved configurations before exiting.
Figure 2-4. File>Print Detailed Configuration Printout Screen
2-5.2
The EDIT Drop-Down Menu
Use the EDIT drop-down menu(see Figure 2-3) to navigate to the various tabs of the Configuration
Editor.
2-5.3
The VIEW Drop-Down Menu
Use the VIEW drop-down menu (see Figure 2-3) to enable or disable the use of the main toolbar and
status bar.
The VIEW commands from the main menu are shown in Table 2-2.
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Creating a System Configuration
Table 2-2. VIEW Commands
Command
Function
Toolbar
Select Toolbar to toggle on/off display of the FenwalNET 8000-ML Configuration Software’s
main toolbar.
Status Bar
Select Status Bar to toggle on/off display of the FenwalNET 8000-ML Configuration Software’s
status bar, a feature which describes the functionality of individual icons (located at the bottom
left of the main window).
2-5.4
The TOOLS Drop-Down Menu
Use the TOOLS drop-down menu (see Figure 2-3) to communicate back and forth to the
FenwalNET 8000-ML control panel. Refer to Chapter 5 for a detailed explanation of the commands
available in the TOOLS drop-down menu.
The TOOLS commands from the main menu are shown in Table 2-3.
Table 2-3. TOOLS Commands
Command
Function
Communications Select Communications Setup to configure the communications parameters to enable
Setup
communication with the FenwalNET 8000-ML control panel.
Send
Configuration
Select Send Configuration to send the topmost configuration to the control panel.
Receive
Configuration
Select Receive Configuration to receive a configuration from the control panel into the
topmost configuration.
On-line
Select On-line to connect to the FenwalNET 8000-ML control panel in a terminal-emulation
mode (as if accessing the control panel via its keypad/display).
Get Sensitivity
Levels
Select Get Sensitivity Levels to retrieve and display a current list of sensitivity levels for all
detectors.
Event Log
•
Select Event Log>Receive to receive the event log.
•
Select Event Log>Clear to clear the event log.
•
Select Event Log>Open Log File to open previously-saved Event Log File.
Receive Test Log
Select Receive Test Log to receive the contents of the current log of initiating device test
events.
Receive Walk
Test Log
Select Receive Walk Test Log to receive the contents of the current log of walk-test events to
a text file.
Receive Network
Node Map
Select Receive Network Node Map to view a listing of nodes networked with the local panel.
Each node occupies a unique address.
Verify
Compare
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Select Verify to check the entire configuration for errors or warnings.
Select Compare to compare two different configuration files.
2-5
March 2012
Creating a System Configuration
2-5.5
The WINDOW Drop-Down Menu
Use the WINDOW drop-down menu (see Figure 2-3) to manipulate files in the Configuration Editor.
The WINDOW commands from the main menu are shown in Table 2-4.
Table 2-4. WINDOW Commands
Command
Minimize All
Restore All
Configurations
2-5.6
Function
Select Minimize All to collapse all configuration files within the Configuration Editor.
Select Restore All to restore all configuration files within the Configuration Editor.
Select Configurations to create a new configuration file or switch to another previouslyopened configuration file within the Configuration Editor.
The HELP Drop-Down Menu
Use the HELP drop-down menu (see Figure 2-3) to open the user manual and view the current
software version.
The HELP commands from the main menu are shown in Table 2-5.
Table 2-5. HELP Commands
Command
Help Topics
About
2-6
Function
Select Help Topics to open the user manual.
Select About to view the version of FenwalNET 8000-ML Configuration Software currently in
use.
CREATING A NEW CONFIGURATION FILE
To create a new configuration file, select File>New or select the New File Icon on the main
toolbar (
).
2-7
OPENING AN EXISTING CONFIGURATION FILE
To open an existing configuration file, Select File>Open or select the Open File Icon on the toolbar
(
). Select a file and click <Open>. The Configuration Editor appears.
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2-8
THE CONFIGURATION EDITOR
The Configuration Editor constitutes the main substructure of the FenwalNET 8000-ML
Configuration Software. The user specifies all operating characteristics and settings for each device
and system component in the Configuration Editor.
As stated in Section 2-5.2, all Configuration Editor tabs are shown in Figure 2-5. They may be
accessed by placing the mouse pointer directly on the tab name and clicking the left mouse button
(or by using the EDIT drop-down menu).
2-8.1
The <Apply> Button
Click <Apply>, located at the bottom of the Configuration Editor screen, to accept all changes made
while in the Configuration Editor. (See Figure 2-5.)
Note: Clicking <Apply> does not automatically save settings to the configuration file.
configuration file must be saved before exiting the program, or settings will be lost.
2-8.2
The
The <Reset> Button
Click <Reset>, located at the bottom of the Configuration Editor screen, to cancel all changes made
to settings while in the Configuration Editor and return to the previously-saved settings. (See
Figure 2-5.)
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2-8.3
The SUMMARY Tab
The SUMMARY Tab includes fields for site-specific information to be entered by the end user. When
a configuration file is first created or opened, the Configuration Editor SUMMARY Tab displays by
default. (See Figure 2-5.)
Figure 2-5. SUMMARY Tab
The SUMMARY Tab options are shown in Table 2-6.
Table 2-6. SUMMARY Tab Options
Command
Site Name
Function
This optional field identifies the end-user site; a maximum of 40 characters is allowed.
Site ID
This optional field allows additional site ID information to be entered (for example, address,
building name, etc.); a maximum of 40 characters is allowed.
Standby Message
This optional field contains a message to display on the Control Unit LCD when the system
status is “normal.” A maximum of 40 characters is allowed.
Author
This optional field allows the creator of the configuration file to enter his name for reference;
a maximum of 40 characters is allowed.
Panel Version
The software version of the FenwalNET 8000-ML Control Unit is detected by the FCS8000
and displayed here. Refer to Section 2-2 Before You Begin - Version Compatibility for more
information about software versions.
Time Created
The date and time when the configuration was first created is displayed here.
Time Last
Changed
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The date and time when the configuration was last saved to disk is displayed here.
2-8
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2-8.4
The SLC and EXPANSION I/O Tab
The SLC and EXPANSION I/O tab allows the user to add, edit, delete, and move expansion module
configurations and SLC loop devices. After each module is added, edited, moved, or deleted, the
module configuration data becomes stored in this Map of Registered Modules. (See Figure 2-6.) The
<Add...>, <Edit...>, <Delete>, <Move...>, and <Edit SLC Devices...> buttons are located at the
top of the screen.
Figure 2-6. SLC and EXPANSION I/O Tab
The SLC and EXPANSION I/O tab options are shown in Table 2-7.
Table 2-7. SLC and EXPANSION I/O Tab Options
Command
Function
Add...
Click <Add...> to add a module. Figure 2-7 shows the module choices that appear. See
Section 2-8.5, Adding and Configuring a New Module.
Edit...
Select the module to edit. Click <Edit...> or double-click a module to edit its configuration.
Depending on the module selected, different screens appear. See Section 2-8.5.8, Editing a
Module.
Delete
Select the module to delete. Click <Delete> to delete the module’s configuration.
Move
Select the module to move. Click <Move> to move the module’s configuration to a new slot.
Edit SLC
Devices...
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Select the SLC module for which SLC devices will be edited. Click <Edit SLC Devices> to
open the SLC Device Editor window.
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Figure 2-7 shows the module choices that appear.
Figure 2-7. Module Choices from SLC and EXPANSION I/O>Add...
Figure 2-7 displays the types of available modules. The configuration screens for each type of module
are described in Section 2-8.5, Adding and Configuring a New Module, and in Chapter 3,
Configuring SLC Devices. (Adding and Configuring SLC Devices are not covered in this chapter.)
2-8.5
Adding and Configuring a New Module
Each module has a different series of configuration screens. This section describes the configuration
screens for each module except the SLC Module, which is described in Chapter 3, Configuring SLC
Devices. In addition, refer to Chapter 1 of the FenwalNET 8000-ML Installation, Operation and
Maintenance Manual, P/N 06-237041-001, for complete specifications on each of the modules (also
referred to as “expansion cards”.)
Note: In the sections which follow, the Physical Address described is the slot number where the
module is installed in the control unit. The Owner Location is user-specified text which
helps identify the location of the module or device. Logical Address is used in the Event
Output Control as a numerical identifier of the module. The logical address does not need to
change if a module needs to be moved to a different physical slot address.
2-8.5.1
ADDING AND CONFIGURING A CITY-TIE MODULE
Note: Only one (1) City-Tie Module may be selected per configuration.
To add and configure a City-Tie Module:
1.
On the SLC and EXPANSION I/O tab, click <Add...>.
2.
From the Select Type window, click the City-Tie Module icon, then click <OK>.
A dialog box asks you to enter the physical address (see Figure 2-8).
Figure 2-8. City-Tie Module Physical Address Screen
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3.
From the up/down arrows, select the physical address and click <OK>.
A dialog box asks you to enter Owner Location, Output Circuit Type, and Masterbox/City-Tie
Operation. (See Figure 2-9.)
Figure 2-9. City-Tie Settings Screen
4.
5.
6.
From the Output Circuit Type drop-down list, select one of the 3 types:
•
Local Energy Type
•
Shunt Type
•
Reverse Polarity Type
From the Masterbox/City Tie Operation drop-down list, select either of the 2 types:
•
Network-wide reporting
•
Local reporting only
Click <OK>.
For each module, this material displays on the SLC and EXPANSION I/O I/O tab in the Map of
Registered Modules.
2-8.5.2
ADDING A RELAY MODULE
To add a Relay Module:
1.
On the SLC and EXPANSION I/O tab, click <Add...>.
2.
From the Select Type window, click the Relay Module icon, then click <OK>.
The Relay Module (RELAY) Setting... dialog box asks you to enter the physical address(es) of
the range of the module(s) (see Figure 2-10).
Figure 2-10. Relay Module Physical Address Screen
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3.
Use the edit boxes and up/down arrows to select the range of the physical address(es) and click
<OK>.
4. The dialog box asks you to enter the Logical Address and Owner Location for each relay
module. (See Figure 2-11.) Click <OK> after entering this information for each relay module.
Logical Address is used in the Event Output Control as a numerical identifier of the module.
The logical address does not need to change if a module needs to be moved to a different physical
slot address.
Figure 2-11. Relay Module Setting Configuration Screen
5.
2-8.5.2.1
To configure the relay circuits in the relay module, see Section 2-8.5.2.1. Or, to close the Relay
Module (RELAY) Setting... screen without accepting input, click the “X” in the upper right-hand
corner of the dialog box or click <Cancel>.
Configuring a Relay Circuit
To configure a relay circuit:
1.
Edit a circuit by double-clicking it in the Relay Module (RELAY) Setting screen (see
Figure 2-11).
The Relay Circuit #X (RELAY) Setting... configuration screen appears (see Figure 2-12).
2.
Enter desired choices for each of the options in the relay circuit-configuring screen (see
Section 2-8.5.2.2), and click <OK>.
3. Close the Relay Module (RELAY) Setting... screen by clicking <OK>.
4. The SLC AND EXPANSION I/O tab list reflects the newly configured circuit information.
5. On the SLC AND EXPANSION I/O tab, click <Apply>.
6. From the main menu, click File>Save.
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2-8.5.2.2
Relay Circuit Configuration screen
This section describes each option on the Relay Circuit #X (1-4) (RELAY) Setting... Configuration
screen (see Figure 2-12).
Figure 2-12. Relay Circuit Configuration Screen
Select Relay Circuit configuration screen options as shown in Figure 2-12, then click <OK>. The
Relay Circuit configuration screen options are shown in Table 2-8.
Table 2-8. Relay Circuit Configuration Screen Options
Option
Owner Location
Enabled
Activate on:
General Alarm
Function
Reference location name for the Relay circuit. Up to 40 characters can be entered.
Use this check box to enable or disable the circuit.
Select this check box to enter the Relay into the General Alarm Activation List.
Select this check box to activate the Relay circuit on AC power loss only. A relay circuit
Activate on: Loss
configured to activate on “Loss of AC Power Only” activates 150 seconds after the loss of AC
of AC Power Only
power. It de-activates immediately when AC power is restored.
Activate on:
Prealarm
Select this check box to activate the Relay circuit on any pre-alarm condition.
Activate on:
Supervisory
Select this check box to activate the Relay circuit on any supervisory condition.
Activate on:
Trouble
Select this check box to activate the Relay circuit on any trouble condition.
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Table 2-8. Relay Circuit Configuration Screen Options (Continued)
Option
Function
ITLCO Time
These times are available only when no other setting has been selected (that is, either General
Alarm, Loss of AC Power Only, PreAlarm, Supervisory, or Trouble have NOT been checked).
Select the ITLCO/CTLCO checkbox and use the edit box and the up/down arrows to configure
the ITLCO time. The range of entry is from 1 to 180 seconds or 1 to 180 minutes.
CTLCO Time
These times are available only when no other setting has been selected (that is, either General
Alarm, Loss of AC Power Only, PreAlarm, Supervisory, or Trouble have NOT been checked).
Select the ITLCO/CTLCO checkbox and use the edit box and the up/down arrows to configure
the CTLCO time. The range of entry is from 1 to 180 seconds or 1 to 180 minutes.
Notes: 1. A programmable relay is configurable for thermal cycling according to the alarm or nonalarm states of its associated automatic heat detectors. Refer to Section 3-5.6 for a
description of thermal cycling via a Model THD-7252 Heat Detector.
2. The cyclical programmable-relay activation can be overriden by an alarm signal from any
associated alarm-initiating device other than a heat detector configured for thermal
cycling. The relay then latches into the activated state and remains activated until it is
deactivated by another alarm condition or until the control unit is reset.
2-8.5.3
ADDING AND CONFIGURING AN SLC MODULE
Note: See Chapter 3, Configuring SLC Devices, for complete information on configuring SLC
Modules and Devices.
2-8.5.4
ADDING NETWORK INTERFACE CARD
To add a Network Interface Card:
1. On the SLC AND EXPANSION I/O tab, click <Add>.
2. From the Select Type window, click the Network Card icon, then click <OK>.
3. Enter the physical address(es) of the modules in the dialog box (See Figure 2-3), then click
<OK>.
Figure 2-13. Network Card Physical Address Screen
4. Select Network configuration screen options as shown in Figure 2-4, then click <OK>. The
Network Interface Card configuration screen options are shown in Table 2-2.
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Figure 2-14. Network Interface Card Settings Screen
Table 2-9. Network Interface Card Configuration Screen Options.
Option
Node Number
Channel 1
Channel 2
Group Number
Time Synch Period
Network Reset
Event
Network Silent
Event
Log All Network
Events
Process Group 0
Channel 1 Left
Fiber
Channel 1 Right
Fiber
Channel 2 Left
Fiber
Channel 2 Right
Fiber
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Function
Reference local node of networked control units. Up to 64 nodes per network.
Check this box if the network messages will be transmitted over communication
channel 1 communication. Checking only Channel 1represents a single-channel
network communication configuration. Checking both Channel 1 and Channel 2
represents dual-channel network communication configuration.
Check this box if the network messages will be transmitted over communication
channel 2. Checking only Channel 2 represents a single-channel network
communication configuration. Checking both Channel 1 and Channel 2 represents
dual-channel network communication configuration.
Reference the autonomous sub-networks or groups that the local node belongs to.
There are 65 possible groupings, numbered 0 to 64.
Specify how often the system synchronizes the clock with the other panels in the
network.
Checking this box enables events from this node to be reset from a remote node.
Checking this box enables events from this node to be silenced from a remote node.
Checking this box enables events entire network to logged in local node event log
Checking this box assign a master node privileges to the local node.
Check this box if incoming network messages through channel 1 will be transmitted
over fiber optic cable
Check this box if outgoing network messages through channel 1 will be transmitted
over fiber optic cable
Check this box if incoming network messages through channel 2 will be transmitted
over fiber optic cable
Check this box if outgoing network messages through channel 2 will be transmitted
over fiber optic cable
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2-8.5.5
ADDING AND CONFIGURING A POWER MANAGEMENT UNIT (PMU) MODULE
Note: Four (4) PMU Modules may be selected per complete system configuration.
To add and configure a PMU Module:
1.
On the SLC AND EXPANSION I/O tab, click <Add...>.
2.
From the Select Type window, click the PMU Module icon, then click <OK>. The PMU
configuration screen appears.
Figure 2-15. PMU Module Setting Configuration Screen
3.
Select PMU Setting configuration screen options as described in Table 2-10, then click <OK>
(for each PMU).
The PMU Setting configuration screen options are shown in Table 2-10.
Table 2-10. PMU Setting Configuration Screen Options
Option
Owner Location
2 PSUs
Charge Batteries
Function
Reference location name for PMU module.
When selected, this check box signals the system that the PMU contains 2 Power Supply Units
(maximum number allowable).
Depending on the application, the battery-charging circuit may be shut off. Select this check
box to automatically charge batteries.
Note: Only one (1) PMU can charge batteries and charging is only available if “Supervise
Batteries” is checked in the GLOBAL tab.
Aux 1 Resettable When selected, this check box supports Auxiliary 1 power output as a resettable circuit.
Aux 2 Resettable When selected, this check box supports Auxiliary 2 power output as a resettable circuit.
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2-8.5.6
ADDING AN R-NAC MODULE
To add an R-NAC Module:
1.
2.
On the SLC AND EXPANSION I/O tab, click <Add...>.
From the Select Type window, click the R-NAC Module icon, then click <OK>.
A dialog box asks you to enter the physical address(es) of the module(s) (see Figure 2-16).
Figure 2-16. R-NAC Module Physical Address Screen
3.
Use the edit boxes and up/down arrows to select the range of the physical address(es) and click
<OK>.
The Release/NAC (R-NAC) Setting... configuration screen appears. A dialog box asks you to
enter the Logical Address and Owner Location for each R-NAC module. (See Figure 2-17.) Click
<OK> after entering this information for each R-NAC module.
Figure 2-17. R-NAC Module Setting Configuration Screen
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2-8.5.6.1
Configuring An R-NAC module as NAC or Release Circuit
To configure the R-NAC module as NAC or Release circuit:
1.
Edit a circuit by double-clicking it in the Release/NAC Module (R-NAC) Setting... configuration
screen (see Figure 2-17).
A dialog box appears to configure the R-NAC as a NAC or Release Circuit (see Figure 2-18).
Figure 2-18. R-NAC Type Configuration Screen
2. Double-click NAC, DISABLED, or RELEASE or left-click <OK>.
The appropriate circuit-configuring screen appears for NAC or Release circuits.
3. Enter desired choices for each of the options in the circuit-configuring screen (see
Section 2-8.5.6.2 and Section 2-8.5.6.3).
Note: A circuit must be enabled by selecting the Enabled check box to be configured.
4. Click <OK>.
5. The Release/NAC Module (R-NAC) Setting... screen reflects the newly configured circuit
information.
6. Click <OK>.
7. On the SLC AND EXPANSION I/O tab, click <Apply>.
8. From the main menu, click File>Save.
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2-8.5.6.2
Release/NAC Module (R-NAC) as a NAC (Notification Appliance Circuit) Configuration Screen
This section describes each option on the NAC Configuration screen (see Figure 2-19).
Figure 2-19. NAC Configuration Screen
Select NAC configuration screen options as shown in Figure 2-19, then click <OK>. The NAC
configuration screen options are shown in Table 2-11.
Table 2-11. NAC Configuration Screen Options
Option
Owner Location
Enabled
Function
Reference location name for the NAC circuit. Up to 40 characters can be entered.
Use this check box to enable or disable the circuit.
General Alarm
Activation
Select this check box to enter the NAC into the General Alarm Activation List.
Intelligent NAC
From the drop-down list, select from: none or Wheelock.
Code Pattern
Silenceable
Walk Test
Activation
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From the drop-down list, select from: 60 bpm, 120 bpm, temporal per ANSI S3.41,
continuous, or thermal cycling.
Select this check box to enable the NAC to be silenceable.
Select this check box to enable the NAC to be Walk Tested.
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Table 2-11. NAC Configuration Screen Options (Continued)
Option
Function
Drill Activation
Select this check box to enter the NAC into the Outputs List activated by Fire Drill.
Silence Inhibit
Select entries in this drop-down list to make the NAC non-silenceable for the amount of time
specified after the NAC is activated.
Select entries in this drop-down list to make the NAC automatically silence after the amount
of time specified.
Cutoff Delay
Note: a NAC configured for Cutoff Delay turns off and remains off until a new alarm event
causes it to resound. The NAC cannot be manually resounded via the Silence Key on the
display.
ITLCO/CTLCO
Activation
To enable thermal cycling, select “none” from the “Intelligent NAC” drop-down list, and select
“thermal cycling” from the “Code Pattern” drop-down list. A NAC is configurable for thermal
cycling according to the alarm or non-alarm states of its associated heat detectors. Refer to
Section 3-5.6 for a description of thermal cycling via Model THD-7252 Heat Detectors. The
cyclical NAC activation is overridden by an alarm signal from any associated alarm-initiating
device other than a heat detector configured for thermal cycling. The NAC then latches into
the activated state, and remains activated until it is subsequently silenced, deactivated by
another alarm condition, or the control unit is reset.
ITLCO Time
Use the edit box and the up/down arrows to configure the ITLCO time. The range of entry is
from 1 to 180 seconds or 1 to 180 minutes.
CTLCO Time
Use the edit box and the up/down arrows to configure the CTLCO time. The range of entry is
from 1 to 180 seconds or 1 to 180 minutes.
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2-8.5.6.3
Release/NAC Module (R-NAC) as a Release Circuit Configuration Screen
This section describes each option on the Release Circuit Configuration screen (see Figure 2-20).
Figure 2-20. Release Circuit Configuration Screen
Select Release Circuit configuration screen options as shown in Figure 2-20, then click <OK>. The
Release Circuit configuration screen options are shown in Table 2-12.
Table 2-12. Release Circuit Configuration Screen Options
Option
Owner Location
Enabled
Function
Reference location name for the Release circuit. Up to 40 characters can be entered.
Use this check box to enable or disable the circuit.
Release Device
From this drop-down list, select Solenoid or Initiator.
Activation Time
These times apply to solenoid-activated discharge valves. From the drop-down list, select
from: 90 seconds, 10 minute soak, 15 minute soak, on until reset, thermal cycling, or
custom time. If custom time is chosen from this drop-down list, its edit box and up/down
arrows appear immediately below “Activation Time.” Use the edit box and up/down arrows to
enter between 2 to 18,000 seconds.
Non-Power
Limited
Select this check box to disable short-circuit detection.
ITLCO Time
Use the edit box and the up/down arrows to configure the ITLCO time. The range of entry is
from 1 to 180 seconds or 1 to 180 minutes.
CTLCO Time
Use the edit box and the up/down arrows to configure the CTLCO time. The range of entry is
from 1 to 180 seconds or 1 to 180 minutes.
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2-8.5.7
ADDING AND CONFIGURING A DACT MODULE
Note: Only one (1) DACT Module may be selected per configuration.
To add and configure a DACT Module:
1.
On the SLC AND EXPANSION I/O tab, click <Add>.
2.
From the Select Type window, click the DACT Module icon, then click <OK>.
3. With the up/down arrows, select the physical address of the module(s) and click <OK>.
(See Figure 2-1).
Figure 2-21. DACT Module Physical Address Screen
4. The DACT Setting configuration screen appears. (See Figure 2-2).
Figure 2-22. DACT Module Setting Configuration Screen
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5.
Select DACT Setting configuration screen options as described in Table 2-1, then click <OK>.
Table 2-13. DACT Setting Configuration Screen Options
Option
Function
Owner Location
Reference location name for DACT module.
Select either local only communicator or network-wide communicator.
Style
Channel 2
Enabled
By selecting this check box, the DACT module will immediately attempt to dial out on the
secondary phone line if the primary phone line fails.
Call is Forwarded
By selecting this check box, the DACT module performs a test on both the Primary and
Secondary phone lines at least once every 4 hours.
Blind Dialing
By selecting this check box, the DACT module will dial regardless of whether the it detects a
dial tone.
Two protocols are available from the drop-down list:
Protocol
•
SIA DC-05-1999.09 Ademco Contact ID
•
SIA DC-03-1990.01(R2003.10)
Primary Phone # Enter the primary phone number. 20 characters are allowed.
Secondary
Phone #
Account Number
1
Enter the secondary phone number. 20 characters are allowed.
10 alphanumeric characters are allowed.
Country Code
Select United States, Canada, or India.
Periodic Test
24 hours, 12 hours, 4 hours. Use the up/down arrows to set the Periodic Test Start (H:M):
time.
2-8.5.8
EDITING A MODULE
To change any of the options for any of the modules:
1.
Select the desired module in the Map of Registered Modules, and click <Edit>.
The configuration screen for the selected module appears.
2.
Make the desired edits in the configuration screen.
3. Click <OK>.
4. Click <Apply>.
5. From the File menu, click Save.
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2-8.6
The EOC (EVENT OUTPUT CONTROL) Tab
The EOC (EVENT OUTPUT CONTROL) tab (see Figure 2-23) allows viewing and editing of the EOC
(see Figure 2-23).
Refer to Chapter 4, Event Output Control (EOC), for complete information on using the EOC tab.
Figure 2-23. EVENT OUTPUT CONTROL (EOC) Tab
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2-8.7
The ON-BOARD Tab
The ON-BOARD tab is used to configure control unit-based outputs. It displays a list of all enabled
and disabled circuits of the following types (see Figure 2-24):
•
NAC
•
R-NAC as NAC
•
R-NAC as Release Circuit
•
Relay
•
Trouble Relay (not configurable)
Figure 2-24. ON-BOARD Tab
2-8.7.1
CONFIGURING AN ON-BOARD CIRCUIT
This section provides brief general configuration instructions. For detailed individual NAC, R-NAC as
NAC, R-NAC as Release Circuit, or Relay Circuit configuration options information, see
Section 2-8.7.3, through Section 2-8.7.6.
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To configure a circuit on the ON-BOARD tab:
1.
Edit a circuit by double-clicking it in the ON-BOARD tab list.
The Update Device State screen appears. (See Figure 2-25.) A circuit must be in the ENABLED
state to be configured. If the R-NAC circuit type is selected, the second screen in Figure 2-25
appears.
Figure 2-25. Update Device State Screen
2.
For the NAC and Relay circuit types, double-click ENABLED or left-click <OK>.
The appropriate circuit-configuring screen appears for NAC or Relay circuits.
3.
For the R-NAC as NAC and R-NAC as Release circuit types, double-click NAC or RELEASE or
left-click <OK>.
The appropriate circuit-configuring screen appears for NAC or Release circuits.
4. Enter desired choices for each of the options in the circuit-configuring screen.
5. Click <OK>.
The ON-BOARD tab list reflects the newly configured circuit information.
6. On the ON-BOARD tab, click <Apply>.
7. From the main menu, click File>Save.
2-8.7.2
DISABLING A CIRCUIT
This section describes how to DISABLE a circuit. To disable a circuit on the ON-BOARD tab:
1.
Edit a circuit by double-clicking it in the ON-BOARD tab list.
2. On the Update Device State Screen, double-click DISABLED or click <OK>.
The following cautionary message appears (see Figure 2-26):
Figure 2-26. DISABLED Cautionary Message
3.
Click <Yes>. The ON-BOARD tab list shows the circuit as DISABLED.
4. On the ON-BOARD tab, click <Apply>.
5. From the main menu, click File>Save.
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2-8.7.3
NOTIFICATION APPLIANCE CIRCUIT (NAC) CONFIGURATION SCREEN
This section describes each option on the NAC Configuration Screen (see Figure 2-27).
Figure 2-27. NAC Configuration Screen
Select NAC configuration screen options as shown in Figure 2-27, then click <OK>. The NAC
configuration screen options are shown in Table 2-14.
Table 2-14. NAC Configuration Screen Options
Option
Owner Location
In General Alarm
Activation List
Intelligent NAC
Code Pattern
Silenceable
Walk Test
Activation
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Function
Reference location name for the NAC circuit. Up to 40 characters can be entered.
Select this check box to enter the NAC into the General Alarm Activation List.
From the drop-down list, select from: none or Wheelock.
From the drop-down list, select from: 60 bpm, 120 bpm, temporal per ANSI S3.41,
continuous, or thermal cycling.
Select this check box to enable the NAC to be silenceable.
Select this check box to enable the NAC to be Walk Tested.
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Table 2-14. NAC Configuration Screen Options (Continued)
Option
Function
Drill Activation
Select this check box to enter the NAC into the Outputs List activated by Fire Drill.
Silence Inhibit
Select entries in this drop-down list to make the NAC non-silenceable for the amount of time
specified after the NAC is activated.
Select entries in this drop-down list to make the NAC automatically silence after the amount
of time specified.
Cutoff Delay
Note: a NAC configured for Cutoff Delay turns off and remains off until a new alarm event
causes it to resound. The NAC cannot be manually resounded via the Silence Key on the
display.
ITLCO/CTLCO
Activation
To enable thermal cycling, select “none” from the “Intelligent NAC” drop-down list, and select
“thermal cycling” from the “Code Pattern” drop-down list. A NAC is configurable for thermal
cycling according to the alarm or non-alarm states of its associated heat detectors. Refer to
Section 3-5.6 for a description of thermal cycling via Model THD-7252 Heat Detectors. The
cyclical NAC activation is overridden by an alarm signal from any associated alarm-initiating
device other than a heat detector configured for thermal cycling. The NAC then latches into
the activated state, and remains activated until it is subsequently silenced, deactivated by
another alarm condition, or the control unit is reset.
ITLCO Time
These times apply when the Code Pattern chosen is thermal cycling. Use the edit box and the
up/down arrows to configure the ITLCO time. The range of entry is from 1 to 180 seconds or
1 to 180 minutes.
CTLCO Time
These times apply when the Code Pattern chosen is thermal cycling. Use the edit box and the
up/down arrows to configure the CTLCO time. The range of entry is from 1 to 180 seconds or
1 to 180 minutes.
2-8.7.4
R-NAC CIRCUIT AS A NAC DEVICE CONFIGURATION SCREEN
These screen options are identical to those of the NAC configuration screen described in
Section 2-8.7.3.
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2-8.7.5
R-NAC CIRCUIT AS A RELEASE DEVICE CONFIGURATION SCREEN
This section describes each option on the Release Circuit Configuration Screen (see Figure 2-28).
Figure 2-28. Release Circuit Configuration Screen
Select Release Circuit configuration screen options as shown in Figure 2-28, then click <OK>. The
Release Circuit configuration screen options are shown in Table 2-15.
Table 2-15. Release Circuit Configuration Screen Options
Option
Function
Owner Location
Reference location name for the Release circuit. Up to 40 characters can be entered.
Release Device
From this drop-down list, select Solenoid or Initiator.
Activation Time
These times apply to solenoid-activated discharge valves. From the drop-down list, select
from: 90 seconds, 10 minute soak, 15 minute soak, on until reset, thermal cycling, or
custom time. If custom time is chosen from this drop-down list, its edit box and up/down
arrows appear immediately below “Activation Time.” Use the edit box and up/down arrows to
enter between 2 to 18,000 seconds.
Non-Power
Limited
ITLCO Time
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Select this check box to disable short-circuit detection.
These times apply to solenoid-activated discharge valves using thermal cycling activation
times. Use the edit box and the up/down arrows to configure the ITLCO time. The range of
entry is from 1 to 180 seconds or 1 to 180 minutes.
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Table 2-15. Release Circuit Configuration Screen Options (Continued)
Option
Function
CTLCO Time
These times apply to solenoid-activated discharge valves using thermal cycling activation
times. Use the edit box and the up/down arrows to configure the CTLCO time. The range of
entry is from 1 to 180 seconds or 1 to 180 minutes.
Notes: 1. Use the “Release Device” drop-down list to select either initiator assemblies or solenoidactivated discharge valves. The fixed activation times in the “Activation Time” drop-down
list apply to solenoid-activated discharge valves.
2. A release circuit is configurable for thermal cycling according to the alarm or non-alarm
states of its associated automatic heat detectors. Refer to Section 3-5.6 for a description
of thermal cycling via a Model THD-7252 Heat Detector. A thermal-cycling release circuit
is configured by selecting thermal cycling from the Activation Time drop-down list.
3. The cyclical release-circuit activation is overridden by an alarm signal from any associated
alarm-initiating device other than a heat detector configured for thermal cycling. The
release circuit then latches into the activated state and remains activated until it is
deactivated by another alarm condition or until the control unit is reset.
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2-8.7.6
RELAY CIRCUIT CONFIGURATION SCREEN
This section describes each option on the Programmable Relay Setting... Configuration Screen (see
Figure 2-29).
Figure 2-29. Programmable Relay Configuration Screen
Select Relay Circuit configuration screen options as shown in Figure 2-29, then click <OK>.
The Relay Circuit configuration screen options are shown in Table 2-16.
Table 2-16. Relay Circuit Configuration Screen Options
Option
Owner Location
In General Alarm
Activation List
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Function
Reference location name for the Relay circuit. Up to 40 characters can be entered.
Select this check box to enter the Relay into the General Alarm Activation List.
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Table 2-16. Relay Circuit Configuration Screen Options (Continued)
Option
Function
Loss of AC Power
Only
Select this check box to activate the Relay circuit on AC power loss only. A relay circuit
configured to activate on “Loss of AC Power Only” activates 150 seconds after the loss of AC
power. It de-activates immediately when AC power is restored.
Prealarm
Supervisory
Service
Trouble
Activation
Select this check box to activate the Relay circuit on any pre-alarm condition.
Select this check box to activate the Relay circuit on any supervisory condition.
Select this check box to activate the Relay circuit on any trouble condition.
ITLCO Time
These times (for thermal cycling) are available only when no other setting has been selected
(that is, either Loss of AC Power Only, PreAlarm, Supervisory Service or Trouble Activation,
have NOT been checked). Select the ITLCO/CTLCO checkbox and use the edit box and the up/
down arrows to configure the ITLCO time. The range of entry is from 1 to 180 seconds or 1 to
180 minutes.
CTLCO Time
These times (for thermal cycling) are available only when no other setting has been selected
(that is, either Loss of AC Power Only, PreAlarm, Supervisory Service or Trouble Activation,
have NOT been checked). Select the ITLCO/CTLCO checkbox and use the edit box and the up/
down arrows to configure the CTLCO time. The range of entry is from 1 to 180 seconds or 1
to 180 minutes.
Notes: 1. A programmable relay is configurable for thermal cycling according to the alarm or nonalarm states of its associated automatic heat detectors. Refer to Section 3-5.6 for a
description of thermal cycling via a Model THD-7252 Heat Detector.
2. The cyclical programmable-relay activation can be overriden by an alarm signal from any
associated alarm-initiating device other than a heat detector configured for thermal
cycling. The relay then latches into the activated state and remains activated until it is
deactivated by another alarm condition or until the control unit is reset.
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2-8.8
The DAY/NIGHT/WEEKEND Tab
Use the DAY/NIGHT/WEEKEND tab to determine the times that smoke detectors configured for day/
night/weekend operation have their alarm thresholds updated (see Figure 2-30).
Figure 2-30. DAY/NIGHT/WEEKEND Tab
Select DAY/NIGHT/WEEKEND tab screen options as shown in Figure 2-30, then click <Apply>.
Click <Reset> to reject the current settings and restore the previously applied settings. The Day/
Night/Weekend screen options are shown in Table 2-17.
Table 2-17. DAY/NIGHT/WEEKEND Screen Options
Option
Use Night-time
Settings at Night
Use Night-time
Settings on the
Weekend
Function
Select this check box to enable night-time settings at night.
Select this check box to enable night-time settings on the weekend.
Day Start
Use the up/down arrows to provide hour and minute (in military time format) to tell the
system when the Day starts.
Day End
Use the up/down arrows to provide hour and minute (in military time format) to tell the
system when the Day ends.
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2-8.9
The DISPLAY Tab
Use the DISPLAY tab to configure peripheral components (see Figure 2-31).
Figure 2-31. DISPLAY Tab
To configure DISPLAY tab options:
1.
Select DISPLAY tab screen options as described in Table 2-18, then click <Apply>.
2.
Click <Reset> to reject the current settings and restore the previously applied settings.
The DISPLAY tab screen options are shown in Table 2-18.
Table 2-18. DISPLAY Screen Options
Option
Function
Add RDCM(s)
Click <Add RDCM(s)> to add Remote Display Control Module components. See
Section 2-8.9.1, Adding a Remote Display control Module (RDCM).
Add LAM(s)
Click <Add LAM(s)> to add LED Annunciator Module components. See Section 2-8.9.2,
Adding an LED Annunciator Module (LAM).
Add ATM(s)
Click <Add ATMs(s)> to add ATM Annunciator Driver Module Component. See
Section 2-8.9.3, Adding an ATM Component.
Delete
To delete any component in the Display tab list, highlight the desired component, then click
<Delete>. See Section 2-8.10, Deleting a Module.
Edit Owner
To change the Owner Location of any component in the Display tab list, highlight the desired
component, then click <Edit Owner>. See Section 2-8.11, Editing Owner Location.
Make Master
To designate a component as a secondary master, highlight the desired RDCM, then click
<Make Master>. See Section 2-8.12, Designating an RDCM Module as a Master.
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2-8.9.1
ADDING A REMOTE DISPLAY CONTROL MODULE (RDCM)
To add an RDCM component:
1.
Click <Add RDCM(s)>.
A dialog box appears, asking for the range to be entered (see Figure 2-32).
Figure 2-32. RDCM Range Entry Dialog Box
2.
Use the edit boxes and the up/down arrows to enter the Range Start and Range End.
3. Click <OK>.
The RDCM Setting... configuration dialog box appears (see Figure 2-33).
Figure 2-33. RDCM Setting Configuration Screen
4.
In the optional Owner Location box, enter its location.
5. Select the Master check box to designate this component as secondary master.
6. Select the PSU Supervision check box to enable this RDCM module to perform Power Supply
Unit (PSU) supervision.
7. Click <OK>.
The Display tab list reflects the newly added RDCM configuration settings.
8. On the Display tab, click <Apply>.
9. From the main menu, click File>Save.
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2-8.9.2
ADDING AN LED ANNUNCIATOR MODULE (LAM)
To add a LAM component:
1.
Click <Add LAM(s)>.
A dialog box appears, asking for the range to be entered (see Figure 2-34).
Figure 2-34. LAM Range Entry Dialog Box
2.
Use the edit boxes and the up/down arrows to enter the Range Start and Range End.
3. Click <OK>.
The LAM Setting... configuration dialog box appears (see Figure 2-35).
Figure 2-35. LAM Setting Configuration Screen
4.
March 2012
Select LAM configuration options as described in Table 2-19, then click <OK>. The Display tab
list reflects the newly configured LAM information.
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5. On the Display tab, click <Apply>.
6. From the main menu, click File>Save.
The LAM configuration options are shown in Table 2-19.
Table 2-19. LAM Configuration Options
Option
Function
Owner Location
Reference location name for LAM module.
Buzzer Enabled
Select this check box to enable audible notification by the buzzer of system status. The default
status of this check box is enabled.
PSU Supervision
Select this check box to enable this LAM component with Power Supply Unit supervision.
System Alarm
LED
System PreAlarm LED
Use the edit box and up/down arrows to select the LED that will indicate System Alarm.
Use the edit box and up/down arrows to select the LED that will indicate System Pre-Alarm.
System
Use the edit box and up/down arrows to select the LED that will indicate System Supervisory.
Supervisory LED
System Abort
LED
System Ground
Fault LED
Select the
LED(s) that
should show in
red
2-8.9.3
Use the edit box and up/down arrows to select the LED that will indicate System Abort.
Use the edit box and up/down arrowsto select the LED that will indicate System Ground
Fault.
Select any of the check boxes 1-48 to set the default color for that LED to RED. If the box is
not selected, the default color is YELLOW. Any LED numbers 1 through 48 selected as a
system LED will not be configurable. The EOC can be used to override the color or pattern of
LEDs. For more information on the EOC, see Chapter 4.
Note: The LED color for the System Alarm, System Pre-Alarm, System Supervisory, System
Abort, and System Ground Fault LEDs are predetermined and cannot be changed.
ADDING AN ATM COMPONENT
To add an ATM component:
1. On the Display tab, click <Add ATM(s)>.
A dialog box appears, asking for the range to be entered (between 1-16 ATMs). See Figure 2-5.
Figure 2-36. ATM Range Entry Dialog Box
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2.
Use the up/down arrows to enter the Range Start and Range End.
3. Click <OK>.
The ATM Owner Location configuration dialog box appears see Figure 2-5.
Figure 2-37. ATM Owner Location Dialog Box
4.
Enter the ATM Owner Location.
5. Click <OK>.
The Display tab list reflects the newly added ATM configuration settings.
6. On the Display tab, click <Apply>.
7. From the main menu, click File>Save.
2-8.10
Deleting a Module
To delete any module on the Display tab list:
1.
Select the desired module in the Display tab list.
2.
Click <Delete>.
3. Click <OK>.
The deleted module is no longer reflected on the Display tab list.
4. On the Display tab, click <Apply>.
5. From the main menu, click File>Save.
2-8.11
Editing Owner Location
To change the Owner Location for any module on the Display tab list:
1.
2.
Select the desired module in the Display tab list.
Click <Edit Owner>.
The Owner Location dialog box appears (see Figure 2-38).
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Figure 2-38. Owner Location Dialog Box
3. Enter new Owner Location.
4. Click <OK>. The Display tab list reflects the changed Owner Location (in the Owner column).
5. On the Display tab, click <Apply>.
6. From the main menu, click File>Save.
2-8.12
Designating an RDCM Module as a Master
Typically, the main Keypad/Display of the FenwalNET 8000-ML is the master user interface. Operator
intervention via the Keypad/Display always takes priority over operator-control commands issued
from any other user interface (RDCM peripheral components). The FenwalNET 8000-ML allows an
RDCM to be configured as a secondary master.
Note: Operator intervention via an RDCM configured as a master always takes priority over
operator-control commands issued from any other RDCM peripheral component, but not
those issued from the Control Unit Keypad/Display.
Whenever an operator issues commands from a user interface (Control Unit Keypad/Display or
RDCM), the system locks out all other user interfaces—other than the Control Unit Keypad/Display
and RDCM master (if configured), preventing operator intervention from any other RDCM.
To make an RDCM a master:
1.
In the Display tab list, select the desired RDCM.
2.
Click <Make Master>.
The Display tab list reflects the changed master (in the Setting column).
3. On the Display tab, click <Apply>.
4. From the main menu, click File>Save.
2-8.13
Deselecting an RDCM as a Master
To deselect an RDCM as a master:
1.
In the Display tab list, double-click the desired RDCM.
2.
Uncheck the Master check box. Click <OK>.
3. On the Display tab, click <Apply>.
4. From the main menu, click File>Save.
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2-9
THE IIM (INTELLIGENT INTERFACE MODULE) TAB
Use the IIM tab to register High Sensitivity Smoke Detectors (see Figure 2-6).
Figure 2-39. IIM Tab
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2-9.1
Configuring IIM Tab Options
1.
Select IIM tab screen options as described in Table 2-3, then click <Apply>.
2.
Click <Reset> to reject the current settings and restore the previously applied settings.
3. From the main menu, click File>Save.
The IIM tab screen options are shown in Table 2-20.
Table 2-20. IIM Screen Options
Option
Function
IIM Enabled
Select this check box to enable the IIM to register HSDs.
Non Latching
Alarms
The default is latching alarm. Select this check box to enable non-latching alarms.
Click <Add...> to add an HSD. See Section 2-9.2, Adding an HSD.
Add...
Click <Delete...> to delete an HSD. Section 2-9.3, Deleting An HSD.
Delete...
2-9.2
Adding an HSD
To add an HSD component:
1.
Click <Add...>.
A dialog box appears, asking for the range to be entered (see Figure 2-40) for between 1-127
HSDs.
Figure 2-40. HSD Range Entry Dialog Box
2.
Use the up/down arrows to enter the Range Start and Range End.
3. Click <OK>.
The IIM tab registry reflects the newly added HSD configuration settings.
4. On the IIM tab, click <Apply>.
5. From the main menu, click File>Save.
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2-9.3
Deleting An HSD
To delete an HSD:
1.
2.
Select the desired HSD in the IIM tab registry.
Click <Delete...>.
The IIM tab registry reflects that the HSD has been deleted.
3. On the IIM tab, click <Apply>.
4. From the main menu, click File>Save.
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2-9.4
The STRINGS Tab
A string displays on the second line of the control unit’s display in lieu of the normal event message
that would ordinarily be displayed as a result of the system event. The text in the string can be up to
40 alphanumeric characters in length.
A string is activated via an Event Output Control (EOC) statement (by using Sx on the right-hand side
of an EOC line). An EOC statement is also required to deactivate a string (by using NSx on the righthand side of an EOC line). Refer to Chapter 4 for more information on the EOC. String variables are
defined in the STRINGS tab (see Figure 2-41).
Figure 2-41. STRINGS Tab
To enter a string:
1.
Double-click the string name from the String Identifier column.
The Enter String... dialog box appears (see Figure 2-42).
Figure 2-42. Enter String... Dialog Box
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2.
Enter alphanumeric text.
3. Click <OK> to accept your entered text.
The STRINGS tab list reflects the newly entered string in the String column.
4. Enter the string in the EOC (by using Sx on the right-hand side of an EOC line). Refer to
Chapter 4 for more information on the EOC.
5. Click <Apply>.
6. From the main menu, click File>Save.
The 16 configurable strings are prioritized for display by the string’s number (i.e., String #16 is the
highest priority and String #1 is the lowest priority). The active string with the highest string number
is the one displayed.
2-9.5
The GLOBAL Tab
Use the GLOBAL Tab (see Figure 2-43) to access the following settings (see Table 2-21 for details):
March 2012
•
Selecting City of Chicago sets the Output Circuit Type of the registered City Tie module to Local
Energy.
•
Selecting Global Acknowledge allows the Acknowledge key to acknowledge up to 30 trouble or
supervisory events with a single key press.
•
Selecting Global Alarm Acknowledge allows the Acknowledge key to acknowledge up to 30
alarm and discharge events with a single key press.
•
Set Expected Battery Replacement Date (Optional)
•
Set Drill Notification Pattern
•
Selecting Supervise Batteries determines whether or not all PMU modules can supervise
batteries.
•
Select the Delay Interval between Sequential Deactivations for Addressable Relays (Use the
Timers button.)
•
Define Nightly SLC Test Time
•
Set Timing Options for AC Fail Delay, Alarm Verification, and Positive Alarm Sequence (Use the
Timers button.)
•
Select Port attached to Printer
•
Select Modbus 1 and Modbus 2 Port and assign Modbus ID.
•
Select ICM Port.
•
Select IIM Port.
•
Create Isolation Macros
•
Select the format to display the Time and Date.
•
View the General Alarm Activation (GAA) List.
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Figure 2-43. GLOBAL Tab
To configure GLOBAL tab options:
1.
Select GLOBAL tab screen options as described in Table 2-21, then click <Apply>.
2.
From the main menu, click File>Save.
The GLOBAL tab options are shown in Table 2-18.
Table 2-21. GLOBAL Tab Options
Option
Function
City of Chicago
If selected, this check box sets the Output Circuit Type of the registered City Tie module to
Local Energy.
Global Acknowledge
If selected, this check box programs the panel to allow a single press of its Acknowledge key
to acknowledge up to 30 trouble and supervisory events.
Global Alarm
Acknowledge
If selected, this check box programs the panel to allow a single press of its Acknowledge key
to acknowledge up to 30 alarm and discharge events.
Expected Battery
Replacement Date
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Enter the expected standby battery replacement date in MMDDYY form.
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Table 2-21. GLOBAL Tab Options (Continued)
Option
Function
From this drop-down list, select from:
Drill Notification
Pattern
•
60 beats per minute
•
120 bpm
•
temporal per ANSI S3.41
•
continuous
All control unit-based NACs programmed for a coded drill signal utilize the pattern selected
here.
Note: The same drill notification pattern should be used for all control
units in a networked system.
Supervise Batteries
Select this check box to activate battery supervision by all registered PMUs. This is a
prerequisite to allowing one (1) PMU to charge the battery(-ies).
Timers
Click the <Timers> button to select timing options. See Section 2-9.5.1, Changing Timing
Options.
GAA List
Click the General Alarm Activation List button to view all components in the GAA list. The
GAA List consists of the set of outputs that are activated by any alarm initiating device.
Nightly SLC Test
Time
The Nightly SLC Test Time sets the time that the control unit performs a daily test on all
of the configured testable SLC devices (inputs). Use the Nightly SLC Test Time edit boxes
and up/down arrows to select the hour and minute (military time).
Time/Date Display
From this drop-down list, select either AM/PM or 24HR/MIL.
From this drop-down list, select from:
Printer Port
•
Disabled
•
RS-232A or RS-232B for serial printer
•
USB-Host for USB printer
From this drop-down list, select from:
Modbus 1/Modbus 2
Port
•
Disabled
•
RS-232A for Modbus RTU
•
RS-232B for Modbus RTU
From this drop-down list, select from:
ICM Port
•
Disabled
•
RS-232A for internet connectivity configuration
•
RS-232B for internet connectivity configuration
From this drop-down list, select from:
IIM Port
Modbus ID
Isolation Macro
Codes
March 2012
•
Disabled
•
RS-232A for IIM connectivity configuration
•
RS-232B for IIM connectivity configuration
Use the up/down arrow to select the Modbus ID.
Initiating and/or output control devices can be assigned to isolation Macros 1-4. See
Section 2-9.5.2, Creating Isolation Macros. Also see Chapter 3, Configuration and
Programming, of the FenwalNET 8000-ML Installation, Operation and Maintenance
Manual, P/N 06-237041-001 for an overview of isolation macros.
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2-9.5.1
CHANGING TIMING OPTIONS
To change the timing options:
1.
On the GLOBAL tab, click <Timers>.
The Global Timers dialog box appears (see Figure 2-44):
Figure 2-44. Global Timers Dialog Box from Global Tab
2.
Select for the options shown in Table 2-22.
Table 2-22. Global Timers Dialog Box Options
Option
Function
AC Fail Delay
Sequential
Deactivation
Timer
The off-premises transmission of an AC-power failure to a central station via the trouble relay
can be delayed by selecting the Central Station check box on the Global tab.
Note: Setting this value to less than 60 minutes when using a DACT or other means to
connect to the central station does not meet UL requirements.
A delay from 5 to 15 seconds can be inserted between successive deactivations of addressable
relays (AOs) configured for Sequential Deactivation. See Section 3-5.2, Addressable Relay
Settings (AO) Screen.
Note: Do not use alarm verification for special extinguishing system applications.
Alarm
Verification (AV)
The period of time (after an initial alarm report) that a smoke detector attempts to verify that
the smoke signature at its location actually exceeds its alarm threshold can be programmed
to confirm that the initial alarm report was valid. The alarm verification period is
programmable from 30 to 180 seconds in one-second increments, or 0 (zero).
Note: Do not use the PAS for special extinguishing system applications.
Positive Alarm
Sequence (PAS)
Timer
The PAS investigation period can be programmed from 0 to 180 seconds in one-second
increments. The initial PAS alarm report must be acknowledged within 15 seconds to activate
the investigation period.
Note: Do not use alarm verification for special extinguishing system applications.
3.
Click <OK>.
4. Click <Apply> on the GLOBAL tab.
5. From the main menu, click File>Save.
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2-9.5.2
CREATING ISOLATION MACROS
Up to 4 lists (Isolation Macros) of initiating devices and/or output control devices/circuits can be
created, which can then be isolated or deisolated via a single menu selection. The list of inputs and/
or outputs to be isolated are assigned to Isolation Macros 1-4. The 4 macros are independent of each
other. The specific isolation commands are executed when the appropriate Soft Key is pressed, or the
menu is used to execute the macro.
Selecting the Isolation Macro for a second time will execute a de-isolation routine for all the devices
and/or circuits that were isolated by the execution of the isolation macro. The isolation macros toggle
the devices in the command lists between the isolated and non-isolated states.
The Isolation Macros can contain up to 10 commands, each of which can include the following types
of devices:
Table 2-23. Isolation Macro Devices to be Selected
Devices that are Programmable
in Isolation Macros
March 2012
Example of an
Abbreviation
On-board NACs
NAC1-2
On-board R-NACs
R-NAC1-2
On-board Relays
RELAY1-3
RDCMs
RDCM1-15
LAMs
LAM1-16
SLC Loop Devices
SLC1:1-255
R-NAC Module Circuits
RNAC1:1-3
Relay Module Circuits
RELAY1:1-4
Power Management Units
PMU1-4
RRM Groups
RG1-7
City-Tie
CITY
ATMs
ATM1-16
DACT
DACT
Network Interface Card
NIC
Network Node
NODE#
SLC Output Groups
OG#-#
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To create an Isolation Macro:
1.
On the GLOBAL tab, in the Isolation Macro Codes window, double-click the numbered macro
that you want to assign.
The Isolation Macro Code dialog box appears (see Figure 2-45).
Figure 2-45. Isolation Macro Code Dialog Box
2.
In the Description box, enter a name, up to 40 characters of any type.
This name displays when the macro is invoked.
The Isolation Macro Code dialog box options are shown in Table 2-24.
Table 2-24. Isolation Macro Code Dialog Box Options
Option
Function
Add...
Click <Add...> to add devices or circuits to the Isolation Macro.
Delete...
Click <Delete...> after selecting desired device/circuit to delete.
Clear...
Click <Clear...> to clear all entered devices/circuits from the Isolation Macro.
<OK>
Click <OK> after making lists of devices/circuits to be assigned to Isolation Macros.
Cancel
Click <Cancel> to negate non-saved entries and return to the previous screen.
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3.
Click the <Add...> button.
The Select Type dialog box appears (see Figure 2-46).
Figure 2-46. Select Type Dialog Box
4.
Select the devices to be assigned to the isolation macro by double-clicking, or by highlighting and
clicking <OK>.
The Range dialog box appears (see Figure 2-47).
Figure 2-47. Range Dialog Box
5.
Enter the range of devices and/or circuits to be added.
6.
Click <OK>.
7.
Repeat steps 3-6 for each type of device/circuit to be added.
8.
In the Isolation Macro Codes window, click <OK> to create the macro.
9.
10.
March 2012
On the GLOBAL tab, click <Apply>.
From the main menu, click File>Save.
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2-9.6
The SOFTKEYS Tab
Use the SOFTKEYS tab to program the 4 Soft Keys. (See Figure 2-48.)
The keypad/display of both the FenwalNET 8000-ML Control Unit and the Remote Display Control
Module (RDCM) contains 4 programmable keys. These “soft keys” can be programmed using the
FenwalNET 8000 menu system or the FCS8000 software. (Refer to the FenwalNET 8000-ML
Installation, Operation and Maintenance Manual, P/N 06-237041-001, for more information.)
These 4 keys will execute commands programmed by the operator.
Figure 2-48. SOFTKEYS Tab
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Creating a System Configuration
2-9.6.1
PROGRAMMING SOFTKEYS
To program any of the 4 numbered Softkeys:
1.
On the SOFTKEYS tab, double-click the number of the Softkey that you want to program.
The Softkey dialog box appears (see Figure 2-49).
Figure 2-49. Softkey Dialog Box
2.
Click the Softkey Type drop-down list.
The Softkey Type drop-down list appears (see Figure 2-50). Available Softkey Types are:
Figure 2-50. Softkey Type List
3.
From the Softkey Type list, select the desired type.
4. Click <OK>.
5. The Softkeys tab list is updated to reflect the settings assigned to each Softkey.
6. On the Softkeys tab, click <Apply>.
7. From the main menu, click File>Save.
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2-9.7
The CALL FOR SERVICE Tab
Use the CALL FOR SERVICE tab (see Figure 2-51) to record call for service telephone numbers and
email address. All of the following fields allow a maximum of 40 characters of any type:
•
Line #1 is for a user-assigned label.
•
Line #2 is for a telephone number.
•
Line #3 is for a telephone number.
•
Line #4 is for an email address.
The text entered in Lines1-4 will be applied to a Softkey if the Call for Service Softkey type is chosen
(see Section 2-9.6, The SOFTKEYS Tab).
The call for service information is displayed on the Main Display (and all user interfaces) when a
Softkey (that has been programmed as a Call for Service button) is pressed.
Figure 2-51. CALL FOR SERVICE Tab
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2-9.8
The RELEASE GROUP Tab
Use the RELEASE GROUP tab (see Figure 2-52) to enter the Owner Locations of Remote Release
Modules Groups 1-7. Up to 40 characters of any type are allowed in each RG# text box.
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Figure 2-52. RELEASE GROUP Tab
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2-10
THE OUTPUT GROUP TAB
Use the OUTPUT GROUP tab (see Figure 2-10) to enter the Owner Locations of up to 8 SLC (signaling
line circuit) Output Groups, which may be made up only of (up to) 20 AOs (Addressable Relay
Modules) and/or ASMs (Addressable Sounder Modules), Groups 1-8. Up to 40 alphanumeric
characters are allowed in each RG# text box.
The Owner Location text is displayed on the User Interface Display and the Remote User Interface
Display.
Figure 2-53. Output Group Tab
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Configuring SLC Devices
CHAPTER 3
CONFIGURING SLC DEVICES
3-1
INTRODUCTION
The FenwalNET 8000-MLTM supports various signaling line circuit (SLC) devices and modules in
many configurations.
For complete information on the SLC and module capacity of the FenwalNET 8000-ML, refer to
Chapter 1, General Information, of the FenwalNET 8000-ML Installation, Operation and Maintenance Manual, P/N 06-237041-001.
3-2
SLC AND EXPANSION I/O TAB
The SLC and EXPANSION I/O tab allows the user to add, edit, delete, and move module
configurations. (See Chapter 2, Section 2-8.4, The SLC and EXPANSION I/O Tab, for complete
information.)
After each module is added, edited, deleted, or moved, the module configuration data is displayed
in this Map of Registered Modules on the SLC and EXPANSION I/O tab. (See Figure 3-1.) The
<Add...>, <Edit...>, <Delete>, and <Move...> buttons are located at the top of the screen.
Figure 3-1. SLC and EXPANSION I/O Tab List
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The SLC and EXPANSION I/O tab options are shown in Table 3-1.
Table 3-1. SLC and EXPANSION I/O Tab Options
Command
Function
Add...
Click <Add...> to add a module. Figure 3-2 shows the module choices that appear. See
Section 2-8.5, Adding and Configuring a New Module.
Edit...
Select the module to edit. Click <Edit...> to edit its configuration. Depending on the module
selected, different screens appear. See Section 2-8.5.8, Editing a Module.
Delete
Select the module to delete. Click <Delete> to delete the module’s configuration.
Move
Select the module to move (from one physical address to another). Click <Move> to move the
module. Note: PMU #1 and SLC #s 1 and 2 are fixed.
Select any SLC Module. Clicking this button brings up the List of Registered SLC Devices
Edit SLC Devices screen, where they may be reconfigured. (See Section 3-4, Adding SLC Devices to an SLC
Module (Circuit), for full details.)
3-3
ADDING AN SLC MODULE (CIRCUIT)
To add an SLC module:
1.
On the SLC and EXPANSION I/O tab, click <Add...> to add a module.
Figure 3-2 shows the module choices that appear.
Figure 3-2. Select Type (of Module) Screen
2.
Double-click the SLC Module icon, or left-click it and click <OK>.
The Range Entry dialog box appears (see Figure 3-3).
Figure 3-3. Range Entry Dialog Box
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3.
Enter the physical address(es) of the SLC Modules (up to 8 of them per control unit).
4. Click <OK>.
The SLC Settings dialog box appears (see Figure 3-4).
Figure 3-4. Signal Line Circuit (SLC) Settings Dialog Box
5.
Select configuration settings:
a. Enter the SLC module’s logical address using the Logical Address edit box and the up/
down arrows.
b.
c.
Enter Owner Location—up to 40 characters of any type are allowed.
Select Wiring type—Class A or Class B.
d. Select (optional) NAC Circuit Fail Safe Activation #1 or #2.
6.
Click <OK>.
The SLC and EXPANSION I/O tab list (Map of Registered Modules) reflects the newly
configured SLC circuit information.
7. On the SLC and EXPANSION I/O tab, click <Apply>.
8. From the main menu, click File>Save.
3-4
ADDING SLC DEVICES TO AN SLC MODULE (CIRCUIT)
To add an SLC device to a SLC module:
1.
In the Map of Registered Modules (see Figure 3-1), double-click the SLC module to which you
want to add an SLC device.
2.
On its SLC Setting screen (see Figure 3-4), click <Add/Edit/View devices>.
The List of Registered SLC Devices dialog box and list appears (see Figure 3-5).
Figure 3-5. List of Registered SLC Devices Dialog Box and List
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The SLC options are shown in Table 3-2.
Table 3-2. List of Registered SLC Devices Screen Options
Option
Function
Accept and Close Click <Accept and Close> after all SLC devices have been selected and configured.
Add Device(s)
Click <Add Device(s)> to select the types of SLC devices to be added to a SLC module. See
Section 3-4, Adding SLC Devices to an SLC Module (Circuit).
Delete Device(s)
To delete any SLC device from the Map of Registered Modules, select the SLC device, then
click <Delete Device(s)>.
Edit
Configuration(s)
To edit any SLC device, select the SLC device, then click <Edit Configuration(s)>. See
Section 3-4.1, Editing the Configuration of an SLC Device.
Edit Owner
To edit the Owner Location of any SLC device, click <Edit Owner>. See Section 3-4.2,
Editing the Owner Location of an SLC Device.
Edit Address
To change an SLC device’s address, click <Edit Address>. See Section 3-4.3, Editing the
Address of an SLC Device.
Edit Type
To change the type of SLC device, click <Edit Type>. See Section 3-4.4, Editing the Type of
an SLC Device.
Reject and Close
3.
Enter <Esc> or click the “X” in the upper right corner to quit without saving changes.
Click <Add Device(s)> to select the type(s) of SLC device(s) to be registered to an SLC module.
The SLC Device Range Entry dialog box appears (see Figure 3-6).
Figure 3-6. SLC Device Range Entry Dialog Box
4.
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Enter the Range Start and Range End for the new SLC device(s), and click <OK>.
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The Select Type... (SLC Devices) screen appears (see Figure 3-7).
Figure 3-7. Select Type... (SLC Devices) Screen
5.
Double-click the desired SLC device icon, or left-click it and click <OK>.
The Setting... screen appears for whatever type of SLC device was chosen.
6.
Fill in the Setting... screen options for the SLC device. For complete information on Settings
screens for all types of SLC devices, see Section 3-5, Settings for SLC Devices.
The SLC Device options are updated in the List of Registered SLC Devices (see Figure 3-8).
Figure 3-8. List of Registered SLC Devices
7.
Click <Accept and Close>.
8. In the SLC Settings dialog box, click <OK>.
9. On the SLC and EXPANSION I/O tab, click <Apply>.
10. From the main menu, click File>Save.
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3-4.1
Editing the Configuration of an SLC Device
To edit the configuration of any SLC device:
1.
In the SLC and EXPANSION I/O tab Map of Registered Modules, double-click the SLC module
in which the SLC device is registered.
The SLC Settings dialog box for the SLC module appears.
2.
Click <Add/Edit/View devices>.
The List of Registered SLC Devices appears.
3.
To edit its configuration, select the desired SLC device, and click <Edit Configuration>.
4.
Make any required changes in the SLC device’s Setting.. dialog box, and click <OK>. See
Section 3-5, Settings for SLC Devices, for full information on settings (configuration) screens for
each type of SLC device.
The List of Registered SLC Devices reflects the changes just made.
3-4.2
5.
Click <Accept and Close>.
6.
In the SLC Settings dialog box, click <OK>.
7.
On the SLC and EXPANSION I/O tab, click <Apply>.
8.
From the main menu, click File>Save.
Editing the Owner Location of an SLC Device
To edit the owner location of any SLC device:
1.
In the SLC and EXPANSION I/O tab Map of Registered Modules, double-click the SLC module
in which the SLC device is registered.
The SLC Settings dialog box for the SLC module appears.
2.
Click <Add/Edit/View devices>.
The List of Registered SLC Devices appears.
3.
To edit its owner location, select the desired SLC device, and click <Edit Owner>.
The Owner Location dialog box appears (see Figure 3-9).
Figure 3-9. Owner Location Dialog Box
4.
Make any desired changes in the Owner Location dialog box, and click <OK>.
The List of Registered SLC Devices reflects the changes just made.
March 2012
5.
Click <Accept and Close>.
6.
In the SLC Settings dialog box, click <OK>.
7.
On the SLC and EXPANSION I/O tab, click <Apply>.
8.
From the main menu, click File>Save.
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3-4.3
Editing the Address of an SLC Device
To edit the address of any SLC device:
1.
In the SLC and EXPANSION I/O tab Map of Registered Modules, double-click the SLC module
in which the SLC device is registered.
The SLC Settings dialog box for the SLC module appears.
2.
Click <Add/Edit/View devices>.
The List of Registered SLC Devices appears.
3.
To edit its address, select the desired SLC device, and click <Edit Address>.
The SLC Device Address dialog box appears (see Figure 3-10
Figure 3-10. SLC Device Address Dialog Box
4.
Make any desired changes in the SLC Device Address dialog box, and click <OK>.
The List of Registered SLC Devices reflects the changes just made.
5.
3-4.4
Click <Accept and Close>.
6.
In the SLC Settings dialog box, click <OK>.
7.
On the SLC and EXPANSION I/O tab, click <Apply>.
8.
From the main menu, click File>Save.
Editing the Type of an SLC Device
To edit the Type of any SLC device:
1.
In the SLC and EXPANSION I/O Map of Registered Modules, double-click the SLC module in
which the SLC device is registered.
The SLC Settings dialog box for the SLC module appears.
2.
Click <Add/Edit/View devices>.
The List of Registered SLC Devices appears.
3.
To edit its Type, select the desired SLC device, and click <Edit Type>.
The Select Type... (SLC Devices) screen appears (see Figure 3-11).
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Figure 3-11. Select Type... (SLC Devices) Screen
4.
Double-click the desired SLC device icon, or left-click it and click <OK>.
The Setting... screen appears for whatever type of SLC device was chosen.
5.
Fill in the Setting... screen options for the SLC device.
The SLC Device options are updated in the List of Registered SLC Devices (see Figure 3-8).
6.
Click <Accept and Close>.
7. In the SLC Settings dialog box, click <OK>.
8. On the SLC and EXPANSION I/O tab, click <Apply>.
9. From the main menu, click File>Save.
3-5
SETTINGS FOR SLC DEVICES
This section describes the Setting... screen for each of the SLC devices that may be selected in the
List of Registered SLC Devices.
The following sections in this manual describe each SLC device setting.
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3-5.1
Addressable AlarmLine Module (AAM) Settings Screen
Select Addressable AlarmLine Settings screen options as shown in Figure 3-12, then click <OK>.
The Addressable AlarmLine Settings screen options are described in Table 3-3.
Note: The AAM initiates an “Overheat” message on the control unit display when it is configured
for an “Overheat” response. The control unit buzzer sounds, but no LEDs illuminate.
Figure 3-12. Addressable AlarmLine Settings Screen
Table 3-3. Addressable AlarmLine Settings Screen Options
Option
Temperature
Units
Function
From the drop-down list, choose ºF/ft or ºC/m (English or Metric) temperature/unit.
Switch Setting
From the drop-down list, choose appropriate switch settings. Refer to Addressable Alarm
Line Manual,
P/N 06-235820-001.
Pre-Alarm
Reporting
Select this check box to enable Pre-Alarm Reporting. Also see Table 3-21, Configurable
Parameters, for more information.
Cable Length
Enter length of cable using up/down arrows. Unit of cable will reflect settings selected in
Temperature Units box.
Alarm Response
OK
Cancel
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From the Alarm Response drop-down list, select Alarm or Overheat Display.
After Settings are completed, click <OK> to apply Settings to device.
Click <Cancel> to negate entered Settings and return to previous screen.
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Configuring SLC Devices
3-5.2
Addressable Relay Settings (AO) Screen
Select Addressable Relay Settings screen options as shown in Figure 3-13, then click <OK>. The
Addressable Relay Settings screen options are described in Table 3-4.
Note: AOs configured for "Sequential De-Activation" have a programmable delay of between 5 and
15 seconds between successive de-activations. The delay interval is set in the Globals tab. Up
to 16 AOs can be programmed for sequential de-activation.
An AO configured for "Fan Re-Start" only de-activates after the FenwalNET 8000-ML Control
Unit is reset following an alarm condition and after an AI Monitor Module configured for "Fan
Re-Start" is activated.
Figure 3-13. Addressable Relay Settings Screen
Table 3-4. Addressable Relay Settings Screen Options
Option
Function
Silenceable
Select this check box to make the AO silenceable. Also see Table 3-21, Configurable
Parameters, for more information.
In General Alarm
Activation List
Select this check box to enter the AO into the General Alarm Activation list. Also see
Table 3-21, Configurable Parameters, for more information.
Drill
Select this check box to activate the AO on Fire Drill. Also see Table 3-21, Configurable
Parameters, for more information.
Walk
Select this check box to activate the AO for initiating signals created during Walk Test. Also
see Table 3-21, Configurable Parameters, for more information.
Sequential
Deactivation
Select this check box to configure the AO for Sequential Deactivation. Also see Table 3-21,
Configurable Parameters, for more information.
Fan Restart
Select this check box to configure the AO for Fan Restart. Also see Table 3-21, Configurable
Parameters, for more information.
Output Groups
Select the check boxes corresponding to the output groups to which this AO belongs. An AO
can belong to none, one, some, or all 7 output groups. Each output group can contain at most
20 AO and/or ASMs.
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Table 3-4. Addressable Relay Settings Screen Options (Continued)
Option
Function
After Settings are completed, click <OK> to apply Settings to device.
OK
Click <Cancel> to negate entered Settings and return to previous screen.
Cancel
3-5.3
Addressable Sounder Module (ASM) Settings Screen
Select Addressable Sounder Module Settings screen options as shown in Figure 3-14, then click
<OK>. The Addressable Sounder Module Settings screen options are shown in Table 3-5.
Figure 3-14. Addressable Sounder Module Settings Screen
Table 3-5. Addressable Sounder Module Settings Screen Options
Option
Function
Silenceable
Select this check box to make the ASM silenceable. Also see Table 3-21, Configurable
Parameters, for more information.
In General Alarm
Activation List
Select this check box to enter the ASM into the General Alarm Activation list. Also see
Table 3-21, Configurable Parameters, for more information.
Drill
Select this check box to activate the ASM on Fire Drill. Also see Table 3-21, Configurable
Parameters, for more information.
Walk
Select this check box to activate the ASM for initiating signals created during Walk Test. Also
see Table 3-21, Configurable Parameters, for more information.
Output Groups
Select the check boxes corresponding to the output groups to which this ASM belongs. An
ASM can belong to none, one, some, or all 7 output groups. Each output group can contain at
most 20 AO and/or ASMs.
OK
Cancel
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After Settings are completed, click <OK> to apply Settings to device.
Click <Cancel> to negate entered Settings and return to previous screen.
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3-5.4
Ion Smoke Detector (ION) Settings Screen
Select Ion Smoke Detector Settings screen options as shown in Figure 3-15, then click <OK>. The
Ion Smoke Detector Settings screen options are described in Table 3-6.
Figure 3-15. Ion Smoke Detector Settings Screen
Table 3-6. Ion Smoke Detector Settings Screen Options
Option
Function
Non-Latching
Input
The Ionization Smoke Detector can be configured as a “Non-Latching Input” only when
“supervisory-service (open area)” is selected as Application type. Select this check box to
enable non-latching input when the text is available (not dimmed).
Optional Relay
Select this check box if the ion smoke detector has an Optional Relay. When this check box is
selected, the further options to activate 1) on EOC, or 2) upon alarm, become available.
Day/Night/
Weekend
Select this check box to enable Day/Night/Weekend operation. Ionization detectors can be
programmed to automatically change alarm thresholds by time of day (or on the weekend) if
they are configured for Day/Night/Weekend operation. When this option is selected, the “Night/
Weekend” alarm threshold becomes available. The “Night/Weekend” alarm level must be less
than or equal to the “Day” alarm level.
Alarm
Verification
Select this check box to activate Alarm Verification. Also see Table 3-21, Configurable
Parameters, for more information.
PAS Delay
Select this check box to activate PAS (Positive Alarm Sequence). Also see Table 3-21,
Configurable Parameters, for more information.
Application
This Application selection drop-down list offers 5 options: 1) open-area, 2) in-duct, 3) DH2000, 4) supervisory service (open-area), and 5) supervisory service (DH-2000/in-duct). See
Section 3-5.4.1, Application Definitions via Drop-Down Menu (below).
Pre-Alarm Level
Alarm Level
OK
Cancel
March 2012
Use the Pre-Alarm Level edit box and the up/down arrows to increase/decrease levels.
Use the Alarm Level edit box and the up/down arrows to increase/decrease levels.
After Settings are completed, click <OK> to apply Settings to device.
Click <Cancel> to negate entered Settings and return to previous screen.
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3-5.4.1
APPLICATION DEFINITIONS VIA DROP-DOWN MENU
Table 3-7. Model CPD-7052 Ionization Smoke Detector Pre-Alarm/Alarm Ranges
Application
Pre-Alarm Range (%/foot)
Alarm Range (%/foot
Night Range (%/foot
Open Area
0.5 - 1.4
0.6 - 1.5
0.6 - 1.4
In-Duct
0.5 - 0.9
0.6 - 1.0
0.6 - 0.9
DH-2000
0.5 - 0.9
0.6 - 1.0
0.6 - 0.9
Supervisory Service
(Open-Area)
N/A
0.6 - 1.5
0.5 - 1.4
Supervisory Service
(DH-2000/In-Duct)
N/A
0.6 - 1.0
0.5 - 0.9
3-5.5
Photoelectric Smoke Detector (PHOTO) Settings Screen
Select Photoelectric Smoke Detector Settings screen options as shown in Figure 3-16, then click
<OK>. The Photoelectric Smoke Detector Settings screen options are described in Table 3-8.
Figure 3-16. Photoelectric Smoke Detector Settings Screen
Table 3-8. Photoelectric Smoke Detector Settings Screen Options
Option
Function
Non-Latching
Input
The Photoelectric Smoke Detector can be configured as a “Non-Latching Input” only when
“supervisory-service (open area)” is selected as Application type. Select this check box to
enable non-latching input when the text is available (not dimmed).
Optional Relay
Select this check box if the photoelectric smoke detector has an Optional Relay. When this
check box is selected, the further options to activate 1) on EOC, or 2) upon alarm become
available.
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Table 3-8. Photoelectric Smoke Detector Settings Screen Options (Continued)
Option
Function
Day/Night/
Weekend
Select this check box to enable Day/Night/Weekend operation. Photoelectric detectors can be
programmed to automatically change alarm thresholds by time of day (or on the weekend) if
they are configured for Day/Night/Weekend operation. When this option is selected, the “Night/
Weekend” alarm threshold becomes available. The “Night/Weekend” alarm level must be less
than or equal to the “Day” alarm level.
Alarm
Verification
Select this check box to activate Alarm Verification. Also see Table 3-21, Configurable
Parameters, for more information.
PAS Delay
Select this check box to activate PAS (Positive Alarm Sequence). Also see Table 3-21,
Configurable Parameters, for more information.
Application
This Application selection drop-down list offers 5 options: 1) open-area, 2) in-duct, 3) DH2000, 4) supervisory service (open-area), and 5) supervisory service (DH-2000/in-duct). See
Section 3-5.5.1, Application Definitions via Drop-Down Menu (below).
Pre-Alarm Level
Alarm Level
Use the Alarm Level edit box and the up/down arrows to increase/decrease levels.
After Settings are completed, click <OK> to apply Settings to device.
OK
Click <Cancel> to negate entered Settings and return to previous screen.
Cancel
3-5.5.1
Use the Pre-Alarm Level edit box and the up/down arrows to increase/decrease levels.
APPLICATION DEFINITIONS VIA DROP-DOWN MENU
Table 3-9. Model PSD-7152 Photoelectric Smoke Detector Pre-Alarm/Alarm Range
Application
Pre-Alarm Range (%/foot)
Alarm Range (%/foot
Night Range (%/foot
Open Area
0.2 - 3.4
0.5 - 3.5
0.5 - 3.4
In-Duct
0.2 -1.9
0.5 - 2.0
0.5 - 1.9
DH-2000
0.2 -1.9
0.5 - 2.0
0.5 - 1.9
Supervisory Service
(Open-Area)
N/A
0.5 - 3.5
0.5 - 3.4
Supervisory Service
(DH-2000/In-Duct)
N/A
0.5 - 2.0
0.5 - 1.9
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3-5.6
Heat Detector (THERMAL) (Model THD-7252) Settings Screen
Select Heat Detector Settings screen options as shown in Figure 3-17, then click <OK>. The Heat
Detector Settings screen options are described in Table 3-10.
Figure 3-17. Heat Detector Settings Screen
Table 3-10. Heat Detector Settings Screen Options
Option
Function
Optional Relay
Select this check box if the heat detector has an Optional Relay. When this check box is
selected, the further options to activate 1) on EOC, or 2) upon alarm become available.
Spacing
Pre-Alarm Level
Alarm Level
ITLCO/CTLCO
Activation
OK
Cancel
From this drop-down list, select 50-ft or 70-ft.
Use the Pre-Alarm Level up/down arrows to increase/decrease levels.
Use the Alarm Level up/down arrows to increase/decrease levels.
Select this check box to use this heat detector for Thermal Cycling.
After Settings are completed, click <OK> to apply Settings to device.
Click <Cancel> to negate entered Settings and return to previous screen.
The pre-alarm/alarm ranges for the thermal detectors are listed in Table 3-11.
Table 3-11. Thermal Detector Pre-Alarm/Alarm Ranges
P/N 06-237042-001
Spacing (ft.)
Pre-Alarm Range (°F)
Alarm Range (°F)
50
80-135
135-155
70
80-135
135-145
3-15
March 2012
Configuring SLC Devices
A heat detector is configurable for thermal cycling as shown in Figure 3-18. The first alarm signal
from a heat detector is used to activate control unit-based outputs for a user-configurable period of
time known as the Initial Time Limit Cutoff Interval (ITLCO). The outputs silence or de-energize upon
expiration of the ITLCO interval. The outputs reactivate using the ITLCO time cycle if the system has
not been reset and at least one heat detector remains in the alarm state. If no heat detectors are in
the alarm state when the ITLCO time expires, the programmed outputs shall deactivate. If a heat
detector subsequently registers a temperature in excess of its alarm-threshold and the system has
not yet been reset, the outputs reactivate. The reactivated outputs silence or deactivate again after the
expiration of a second user-configurable period of time known as the Cyclical Time Limit Cutoff
(CTLCO)
The outputs only cycle and reactivate if the temperature at a heat detector subsequently exceeds the
detector's alarm threshold after the outputs silence or de-activate. All subsequent reactivation occur
for the CTLCO duration.
Valid entries for the ITLCO and CTLCO time periods are 0 to 180 seconds or 0 to 180 minutes,
configurable in either 1-second or 1-minute increments, respectively. These time periods are
specified in the screens that configure the various control unit-based outputs.
ITLCO
CTLCO
CTLCO
CTLCO
CTLCO
0
Ext. Sys & Outputs
Subsequent Shutoff
Ext. Sys & Outputs
Subseq. Shutoff
Heat Detector
Subsequent Alarm
Heat Detector
Subsequent Alarm
Ext. System &
Outputs Initial Shutoff
Heat Detector
Initial Alarm
Ext. Sys &
Out. Shutoff
Heat Detector
Subsequent Alarm
Ext. System & Outputs
Subsequent Shutoff
Heat Detector
Subsequent Alarm
System Reset
Time
Figure 3-18. Thermal Cycling Settings Screen
March 2012
3-16
P/N 06-237042-001
Configuring SLC Devices
3-5.7
AnaLASER Interface Module (AIM) Settings Screen
Select AnaLASER Interface Module Settings screen options as shown in Figure 3-19, then click
<OK>. The AnaLASER Interface Module Settings screen options are described in Table 3-12.
Figure 3-19. AnaLASER Interface Module Settings Screen
Table 3-12. AnaLASER Interface Module Settings Screen Options
Option
Function
Non-Latching
Input
The AnaLASER Interface Module can be configured as a “Non-Latching Input” only when
“Supervisory Initiating Device” is selected as Reporting Device Type. Select this check box to
enable non-latching input when the text is available (not dimmed).
Alarm Initiating
Device
Select this option to configure the AIM to create an alarm condition in the system when it
activates. Also see Table 3-21, Configurable Parameters, for more information.
Supervisory
Initiating Device
Select this option to configure the AIM for Supervisory Reporting (Not UL Listed or FM
Approved). Non-Latching Input is then available as a selectable option.
OK
Cancel
P/N 06-237042-001
After Settings are completed, click <OK> to apply Settings to device.
Click <Cancel> to negate entered Settings and return to previous screen.
3-17
March 2012
Configuring SLC Devices
3-5.8
Alarm (ALARM) Settings Screen
Select Alarm (ALARM) Module Settings screen options as shown in Figure 3-20, then click <OK>.
The Alarm Module Settings screen options are described in Table 3-13.
Note: The unpowered alarm contact can be either normally-open or normally-closed. Use
P/N 70-4070X8-001 for normally-open contacts and P/N 70-407018-002 for normallyclosed contacts.
Figure 3-20. Alarm Settings Screen
Table 3-13. Alarm Module Settings Screen Options
Option
Function
ITLCO/CTLCO
Activation
OK
Cancel
3-5.9
Select this check box to use this alarm module for Thermal Cycling.
After Settings are completed, click <OK> to apply Settings to device.
Click <Cancel> to negate entered Settings and return to previous screen.
Abort Station (ABORT) Settings Screen
Select Abort Station (ABORT) Module Settings screen options as shown in Figure 3-21, then click
<OK>. The Abort Station Module Settings screen options are described in Table 3-14.
Note: Address all abort stations within the range of 1 to 32 (if possible).
The unpowered abort switch can be either normally-open or normally-closed. Use P/N
70-4070X8-001 for normally-open contacts and P/N 70-407018-002 for normally-closed
contacts.
Figure 3-21. Abort Station Settings Screen
March 2012
3-18
P/N 06-237042-001
Configuring SLC Devices
Table 3-14. Abort Station Module Settings Screen Options
Option
Function
Setting
Device Operation Settings. See Section 3-5.9.1, Abort Station Settings Definitions,
below, for complete information.
After Settings are completed, click <OK> to apply Settings to device.
OK
Click <Cancel> to negate entered Settings and return to previous screen.
Cancel
3-5.9.1
ABORT STATION SETTINGS DEFINITIONS
An AI Monitor Module configured as an abort station can be programmed to operate in any of the
following ways:
Table 3-15. Abort Definitions
Abort Type
Reset to Full Time
Delay (Non-UL Listed)
Definition
The countdown timer restores to the full delay period after the abort station is
activated. The timer resumes the full countdown if the abort station is de-activated.
The timer restores to the full delay period if the abort station is re-activated with
any time remaining in the countdown. A system reset is required to clear the
countdown timer.
NOTE: The following abort-station operations are available, and are to be utilized at
the discretion of, and with the approval of, the applicable Authority Having
Jurisdiction.
Underwriters
Laboratories Style
The countdown timer continues to count down after the abort station is activated,
and halts with 10-seconds remaining. The timer resumes the countdown from 10
seconds if the abort station is de-activated. The timer restores to 10 seconds if the
abort station is activated or re-activated with less than 10 seconds remaining in the
countdown. A system reset is required to clear the countdown timer.
New York City (Not UL
Listed)
The countdown timer restores to the full delay period, plus 90 seconds, after the
abort station is activated. The timer resumes the countdown from the full delay
period, plus the 90 seconds, if the abort station is de-activated. The timer restores
to the full delay period plus 90 seconds if the abort station is re-activated with any
time remaining in the countdown. A system reset is required to clear the countdown
timer.
NOTE: EOC programming is required to implement the New York City abort station
operation. Refer to Appendix B.
Freeze and Hold at
Time Remaining (NonUL Listed)
The countdown timer halts at the time remaining to expiration after the abort
station is activated. The timer resumes the countdown at the time remaining to
expiration if the abort station is de-activated. The timer again halts at the time
remaining to expiration if the abort station is re-activated with any time remaining
in the countdown. A system reset is required to clear the countdown timer.
Industrial Risk Insurers
(Non-UL Listed)
This option functions in a similar manner to the Underwriters Laboratories style,
except that countdown timer interruption is not allowed after the countdown timer
has begun to count down.
P/N 06-237042-001
3-19
March 2012
Configuring SLC Devices
3-5.10
Supervisory Input (SUPV) Settings Screen
Select Supervisory (SUPV) Module Settings screen options as shown in Figure 3-22, then click
<OK>. The Supervisory Module Settings screen options are described in Table 3-16.
Note: The unpowered supervisory switch can be either normally-open or normally-closed. Use
P/N 70-4070X8-001 for normally-open contacts and P/N 70-407018-002 for normallyclosed contacts.
Figure 3-22. Supervisory Input Settings Screen
Table 3-16. Supervisory Input Module Settings Screen Options
Option
Function
Non-Latching
Input
Select this check box to enable non-latching input. Also see Table 3-21, Configurable
Parameters, for more information.
OK
Cancel
3-5.11
After Settings are completed, click <OK> to apply Settings to device.
Click <Cancel> to negate entered Settings and return to previous screen.
Waterflow Input (WATER) Settings Screen
Select Waterflow (WATER) Module Settings screen options as shown in Figure 3-23, then click
<OK>. The Waterflow Module Settings screen options are described in Table 3-17.
Note: The unpowered waterflow contact can be either normally-open or normally-closed. Use
P/N 70-4070X8-001 for normally-open contacts and P/N 70-407018-002 for normallyclosed contacts.
Figure 3-23. Waterflow Input Settings Screen
March 2012
3-20
P/N 06-237042-001
Configuring SLC Devices
Table 3-17. Waterflow Module Settings Screen Options
Option
Function
Silenceable
Select this check box to enable Silenceable operation. Also see Table 3-21, Configurable
Parameters, for more information.
After Settings are completed, click <OK> to apply Settings to device.
OK
Click <Cancel> to negate entered Settings and return to previous screen.
Cancel
3-5.12
Remote Releasing Module (RRM) Settings Screen
This section is divided into two parts:
3-5.12.1
•
Configuring an RRM with an Initiator releasing device
•
Configuring an RRM with a Solenoid releasing device
CONFIGURING AN RRM WITH AN INITIATOR RELEASING DEVICE
Select Remote Releasing Module (RRM) Settings screen options as shown in Figure 3-24, then click
<OK>. The Remote Releasing Module Settings screen (with Initiator as Release Device) options are
described in Table 3-18.
Figure 3-24. Remote Releasing Module Settings Screen
(Using an Initiator as a Releasing Device)
P/N 06-237042-001
3-21
March 2012
Configuring SLC Devices
Table 3-18. Remote Releasing Module Settings Screen (with Initiator as Releasing Device) Options
Option
Function
Release Device
Releasing
Group(s)
OK
Cancel
3-5.12.2
From the drop-down list, select Initiator.
Use the edit boxes and the up/down arrows to configure the RRM to be in none, some, or all of
the 7 release groups. Each release group can contain only 20 RRMs.
After Settings are completed, click <OK> to apply Settings to device.
Click <Cancel> to negate entered Settings and return to previous screen.
CONFIGURING AN RRM WITH A SOLENOID RELEASING DEVICE
Select Remote Releasing Module (RRM) Settings screen options as shown in Figure 3-25, then click
<OK>. The Remote Releasing Module Settings screen (with Solenoid as Release Device) options
are described in Table 3-19.
Figure 3-25. Remote Releasing Module Settings Screen
(Using a Solenoid as a Releasing Device)
March 2012
3-22
P/N 06-237042-001
Configuring SLC Devices
Table 3-19. Remote Releasing Module Settings Screen (with Solenoid as Releasing Device) Options
Option
Function
Release Device
From the drop-down list, select Solenoid.
Activation Time
These times apply to solenoid-activated discharge valves. From the drop-down list, select
from: 90 seconds, 10 minute soak, 15 minute soak, on until reset, thermal cycling, or
custom time. These times apply to solenoid-activated discharge valves. If custom time is
chosen from this drop-down list, its edit box and up/down arrows appear immediately below
“Activation Time.” Use the edit box and up/down arrows to enter between 2 to 18,000
seconds.
Non-Power
Limited
Select this check box to disable short-circuit detection.
2 Solenoids
Connected
Select this check box if 2 Solenoids Connected are connected.
Releasing
Group(s)
ITLCO Time/
CTLCO Time
Use the edit boxes and the up/down arrows to configure the RRM to be in none, some, or all of
the 7 release groups. Each release group can contain only 20 RRMs.
If applicable, the release circuit is configurable for thermal cycling according to the alarm or
non-alarm states of its associated automatic heat detectors. Refer to Section 3-5.6, Heat
Detector (THERMAL) (Model THD-7252) Settings Screen, for a description of thermal cycling
via a Model THD-7252 Heat Detector. A thermal-cycling release circuit is configured by
selecting “Thermal Cycling” from the Activation Time drop-down menu.
Note: The cyclical release-circuit activation is overridden by an
alarm signal from any associated alarm-initiating device
other than a heat detector configured for thermal cycling.
The release circuit then latches into the activated state and
remains activated until it is deactivated by another alarm
condition or until the control unit is reset.
OK
After Settings are completed, click <OK> to apply Settings to device.
Cancel
Click <Cancel> to abandon changes and return to previous screen.
P/N 06-237042-001
3-23
March 2012
Configuring SLC Devices
3-5.13
Configuring An Isolation Macro Input
Select Isolation Macro icon and select the desired Macro number from the settings dialog as shown
in Figure 3-26. Click OK and the device address is assigned to the Isolation Macro.
When activated, an Isolation Macro input causes the control unit to execute the isolations defined by
the macro. Deactivating the Isolation Macro Input will deisolate all circuits isolated by the macro. A
'switch fault' is indicated if the Isolation Macro Input is left active and the keypad is used to execute
the macro deisolation. The unpowered Isolation Macro input can be either normally-open or
normally closed. Use P/N 70-4070X8-001 for normally-open contacts and P/N 70-407018-002 for
normally-closed contacts.
Figure 3-26. Isolation Macro Number Menu
Table 3-20. Isolation Macro Input Options
Option
Function
Isolation Macro
Number
Select the macro number (1-4) executed by activating this device. To be assigned, the macro
must exist.
Click to apply settings to the selected device.
OK
Click to cancel and return to the previous screen.
Cancel
3-6
OTHER SLC INITIATING DEVICES
The following SLC initiating devices do not have specific screens to further define functionality. They
are all represented by an AI Monitor Module that is monitoring an unpowered switch.
March 2012
•
Manual Alarm. A manual alarm station initiates an alarm when pulled.
alarm stations within the range of 1 to 32 (if possible).
•
Manual Release. A manual release switch is used to initiate release circuits.
•
Normal Input. A normal is a Non-Latching initiating device. Point-specific outputs can be
assigned to a normal device in the EOC section of the configuration program. The unpowered
normal device can be either normally-open or normally-closed. Use P/N 70-4070X8-001 for
normally-open contacts and P/N 70-407018-002 for normally-closed contacts.
•
Trouble Input. A trouble input creates a trouble condition and is a Non-Latching initiating
device. Point-specific outputs can be assigned to the trouble input in the EOC section of the
configuration program. The unpowered trouble input can be either normally-open or normallyclosed. Use P/N 70-4070X8-001 for normally-open contacts and P/N 70-4070X8-002 for
normally-closed contacts.
•
Fan Restart. A fan-restart point is used to de-activate specific addressable relays (i.e., AOs) after
the control unit has been reset. The AOs must be configured for fan-restart operation. The
unpowered fan-restart switch must be a Non-Latching normally-open contact. Use P/N
70-4070X8-001 to monitor the fan-restart switch.
3-24
Address all manual
P/N 06-237042-001
Configuring SLC Devices
•
Drill. A drill switch is used to initiate a fire drill via an external, field-installed switch. The fire
drill begins when the drill switch is activated, and stops when the drill switch is de-activated. The
Drill process can also be canceled using the Silence or Reset buttons. A 'switch fault' will be
indicated if the Drill Input is left active after a silence or reset operation. The unpowered drill
input can be either normally-open or normally closed. Use P/N 70-4070X8-001 for normallyopen contacts and P/N 70-407018-002 for normally-closed contacts.
•
Alarm Silence. An alarm silence switch is used to duplicate the functionality of the control unit's
alarm silence switch via an external, field installed switch. The alarm silence switch de-activates
silenceable outputs when the alarm silence switch is activated, and re-activates silenced outputs
when the alarm silence switch is de-activated. A 'switch fault' will be indicated if the Silence Input
is left active. The unpowered silence input can be either normally-open or normally closed. Use
P/N 70-4070X8-001 for normally-open contacts and P/N 70-407018-002 for normally-closed
contacts.
•
Reset. A reset switch is used to duplicate the functionality of the control unit's reset switch via
an external, field installed switch. A 'switch fault' will be indicated if the Reset Input is left active.
The unpowered reset input can be either normally-open or normally closed. Use P/N 70-4070X8001 for normally-open contacts and P/N 70-407018-002 for normally-closed contacts.
•
Acknowledge. An acknowledge switch is used to duplicate the functionality of the control unit's
acknowledge switch via an external, field installed switch. A 'switch fault' will be indicated if the
ACK Input is left active. The unpowered ACK input can be either normally-open or normally
closed. Use P/N 70-4070X8-001 for normally-open contacts and P/N 70-407018-002 for
normally-closed contacts.
Note: This feature does not meet UL requirements unless there is a visible display at the
acknowledge switch that indicates what is being acknowledged.
Table 3-21. Configurable Parameters
CONFIGURABLE
PARAMETER
EXPLANATION
Alarm Initiating Device
A device such as a smoke detector or manual station configured to create an alarm
condition in the system when it activates. Input devices that can cause an alarm include:
1) Ion Smoke Detector (not configured for “Supervisory Service”); 2) Photo Smoke
Detector (not configured for “Supervisory Service”); 3) Heat Detector (also referred to as
a Thermal Detector); 4) Alarm; 5) Manual Alarm; 6) Manual Release; 7) Waterflow; 8)
Addressable Alarm-Line Module (not configured for “Overheat Display”); and 9)
AnaLASER Interface Module (not configured as a “Supervisory Initiating Device”).
Alarm Verification
Alarm verification allows a fire alarm system to delay an evacuation signal from being
generated as the result of an alarm report from a smoke detector. The fire alarm system
waits for a second alarm report from the smoke detector that issued the initial alarm
report or from any other alarm-initiating device before it generates the evacuation signal.
The fire alarm system resumes normal operations if it does not receive a second alarm
report within the alarm configuration time period. See Chapter 6 of NFPA 72, National
Fire Alarm Code, 2002 Edition, for details.
Day/Night/Weekend
The periods of time during which smoke detector sensitivities can be automatically
adjusted by the control unit. Day and night periods are defined in the Globals Tab.
Fan Restart
A switch connected to a monitor module designed to de-energize control modules that
do not resume normal operation after a system reset. The monitor module and control
modules must be configured for fan-restart operation. The control modules only deenergize and resume normal operation after the fan restart switch is activated.
General Alarm List
P/N 06-237042-001
The set of outputs that are activated by any alarm initiating device.
3-25
March 2012
Configuring SLC Devices
Table 3-21. Configurable Parameters (Continued)
CONFIGURABLE
PARAMETER
Non-Latching Input
EXPLANATION
Some SmartOne alarm initiating devices can be configured for Non-Latching operation.
Non-Latching operation refers to the special way that “Alarm-Off” messages from
initiating devices are processed by the FenwalNET 8000-ML Control Unit. Each
SmartOne alarm initiating device transmits an “Alarm-On” message when, in the case of
an automatic initiating device, it detects a fire signature in excess of its configured
threshold value, and, in the case of an AI Monitor Module for a normally-open contact, it
detects a contact closure from the switch that it is monitoring. The SmartOne automatic
alarm-initiating devices and monitor modules also transmit “Alarm-Off” messages when
the detected fire signature drops below the configured threshold value and when the
contact closure is removed, respectively. The FenwalNET 8000-ML Control Unit always
displays every “Alarm-On” message, but does not display an “Alarm-Off” message unless
the alarm-initiating device is configured for Non-Latching operation.
Note:
Only inputs configured for supervisory service have the option of being
configured for Non-Latching. Inputs configured for Thermal Cycling are
automatically configured for Non-Latching.
PAS
Positive Alarm Sequence (i.e., PAS) allows a fire-alarm system to delay an evacuation
signal from being generated as the result of an alarm report from a smoke detector. The
operator must acknowledge the initial alarm report within 15 seconds of its receipt, or
the normal evacuation signals activate. Personnel have a user-programmable period of
up to 3 minutes to investigate the nature of the alarm and reset the system if they
acknowledge the initial alarm within 15 seconds. The evacuation signal activate if the
system is not reset during the investigation period. The fire-alarm system also generates
the evacuation signal if a second smoke detector configured for PAS or any other
initiating device transmits an alarm signal during either the initial-acknowledgement
period or the investigation period. The fire-alarm system resumes normal operations if
it is reset within the investigation period. See Chapter 6 of NFPA 72, National Fire Alarm
Code, 2002 Edition, for details.
Pre-Alarm Reporting
The Pre-Alarm State occurs when a SmartOne automatic initiating device such as a
smoke detector senses a fire signature that is below its configured alarm threshold value
but above a lower threshold value called the “pre-alarm” threshold.
Sequential Deactivation
A method of scheduling the de-activations of control modules that have been
activated as the result of an alarm condition. The system can be programmed
to insert a delay of up to 15 seconds between the de-activation times of control
modules that resume normal operations following either a system reset or a
fan-restart command. The control modules must be configured for sequential
deactivation and the delay period is defined in the Globals Tab. Up to 16
control modules can be programmed for sequential deactivation.
Silenceable
An output that changes its state of activation upon commands issued by the control
unit's SILENCE Switch. The output de-energizes if an alarm condition exists and if it is
activated when the SILENCE Switch is pressed, and re-activates if the alarm condition
still exists and it is de-energized when the SILENCE Switch is pressed.
Walk Test
A test mode in which the control unit responds to alarm-initiating signals by pulsing
designated notification-appliance circuits for one second and recording the alarminitiating device's alarm report in the Walk Test Log. This is referred to as a normal walk
test. The alarm-initiating devices must be activated for Walk Test via the control unit's
Test sub-menu, and the NACs must be configured for Walk Test activation. A Silence
Walk Test does not activate the NACs, but records each alarm-initiating device's alarm
report in the Walk Test Log.
March 2012
3-26
P/N 06-237042-001
Event Output Control (EOC)
CHAPTER 4
EVENT OUTPUT CONTROL (EOC)
4-1
INTRODUCTION
The procedures in Chapter 2 discussed defining the scope of a specific application and assigning
operating characteristics and functionality to SLC-based initiating and control devices and to control
unit-based output circuits. This chapter discusses how to create the operating sequence (i.e., the
relationships between the output device(s) and the initiating point(s) for a FenwalNET 8000-ML™
system).
4-1.1
Before You Begin
Before reading the pages which follow, refer to Table 4-6 to familiarize yourself with the look of Event
Output Control (EOC) operators and lines of code. Every operator and associated concepts involved
in building an EOC program are explained in logical order in the next paragraphs.
Note: In many examples of EOC code throughout this chapter, comments are preceded by a “$”.
For example: “$ necessary to set C1 to zero when I1 goes to zero.” Regular use of embedded
comments in EOC code is highly recommended for ease of programming.
4-1.2
Event Output Control
Event Output Control (EOC) is the set of instructions that are be executed in response to pointspecific alarm, supervisory, or trouble events. The objective is to trigger physical outputs (i.e.,
notification appliance circuits, release circuits and control modules) as the result of one or more
initiating event(s) in accordance with the approved sequence of operations.
The general form of an EOC instruction is “expression=designated outputs”. An expression can be
a simple argument (see Section 4-2.1) or an compound argument (see Section 4-2.2).
“Designated outputs” activate whenever:
•
the “expression” becomes True (when it had been False);
•
whenever the “expression” becomes non-Zero (when it had been Zero);
•
whenever the “expression” becomes greater than its value on the previous pass through the EOC
program (a pass is made whenever an event happens on the system).
If the expression satisfies the above rules, then activate “designated outputs”.
4-2
CONSTRUCTING ARGUMENTS
The constituents (i.e., variables) of the "expression" are of two general types:
•
Independent variables that consist of physical initiating devices (automatic detectors or
monitor modules). The types of physical initiating devices that are supported were
discussed in Chapter 2.
•
Dependent variables (i.e., Counting Identifiers, State Variables, and Incrementing Variables)
assume values during program execution. Dependent variables are incremented or change state
as the result of some prior independent variable activation, or their initial state. They are
placeholders either for the arguments that changed them, or for the execution of a specific EOC
command.
P/N 06-237042-001
4-1
March 2012
Event Output Control (EOC)
Table 4-1 summarizes the types of initiating devices and their effects on the system's physical
and virtual outputs.
Table 4-1. Initiating Devices
Initiating Device
Physical Outputs
Virtual Outputs
Event Created
Latching
Initiating
Device
Latching*
NonLatching**
Counting
Logical
Identifier**
State
Variable*
(Cx)
Incrementing
Variable
(Qx)
Ion. Det.
Pre-Alarm
No
No
Yes
Yes
Yes
Yes
Ion. Det.
Alarm
Yes
Yes
No
Yes
Yes
Yes
Ion. Det.
Supervisory
Prog (Y/N)
No
Yes
Yes
Yes
Yes
Photo. Det.
Pre-Alarm
No
No
Yes
Yes
Yes
Yes
Photo. Det.
Alarm
Yes
Yes
No
Yes
Yes
Yes
Photo. Det.
Supervisory
Prog (Y/N)
No
Yes
Yes
Yes
Yes
Heat Det.
Pre-Alarm
No
No
Yes
Yes
Yes
Yes
Heat Det.
Alarm
Prog (Y/N)***
Yes
No
Yes
Yes
Yes
Heat Det.
Cycling
No
No
Yes
Yes
Yes
Yes
CPDI Duct Det.
Pre-Alarm
No
No
Yes
Yes
Yes
Yes
CPDI Duct Det.
Alarm
Yes
Yes
No
Yes
Yes
Yes
CPDI Duct Det.
Supervisory
Prog (Y/N)
No
Yes
Yes
Yes
Yes
PSDI Duct Det.
Pre-Alarm
No
No
Yes
Yes
Yes
Yes
PSDI Duct Det.
Alarm
Yes
Yes
No
Yes
Yes
Yes
PSDI Duct Det.
Supervisory
Prog (Y/N)
No
Yes
Yes
Yes
Yes
HSD with AIM
Pre-Alarm
No
No
Yes
Yes
Yes
Yes
HSD with AIM
Alarm
Prog (Y/N)
Yes
No
Yes
Yes
Yes
HSD with AIM
Supervisory
Prog (Y/N)
No
Yes
Yes
Yes
Yes
Manual Station
Alarm
Yes
Yes
No
Yes
Yes
Yes
Manual Release
Alarm
Yes
Yes
No
Yes
Yes
Yes
Alarm Contact
Alarm
Prog (Y/N)***
Yes
No
Yes
Yes
Yes
Abort Station
Abort
No
No
Yes
Yes
Yes
Yes
Waterflow Switch
Alarm
Yes
Yes
No
Yes
Yes
Yes
Supv. Switch
Supervisory
Prog (Y/N)
No
Yes
Yes
Yes
Yes
Normal
None
No
No
Yes
Yes
Yes
Yes
Trouble
Trouble
No
No
Yes
Yes
Yes
Yes
AAM
Pre-Alarm
No
No
Yes
Yes
Yes
Yes
AAM
Alarm
Yes
Yes
No
Yes
Yes
Yes
AAM
Overheat.
No
No
Yes
Yes
Yes
Yes
HSD with IIM
Pre-Alarm
No
No
Yes
Yes
Yes
Yes
HSD with IIM
Supervisory
Prog (Y/N)
No
Yes
Yes
Yes
Yes
HSD with IIM
Alarm
Prog (Y/N)
Yes
No
Yes
Yes
Yes
Device Type
* Does not track initiating devices.
** Tracks initiating devices.
*** Heat Detectors and AI’s configured for “Thermal Cycling” are automatically configured as
“Non- Latching Input.”
March 2012
4-2
P/N 06-237042-001
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Table 4-2. Input Symbolic Representations
SLC Initiating Device
4-2.1
Lx:y where x = SLC Loop number (1-8) and y is the SLC
Device address (1-255)
State Variables
Cx where x = variable number (1-255)
Incrementing Variables
Ix where x = variable number (1-255)
Counting Variables
Qx where x = variable number (1-255)
Simple Arguments
A simple argument consists of a single independent or dependent variable. The physical initiating
devices are represented by their SLC address or IIM address. The designator “HSD” prefixes HSSD
addresses when an IIM Card is used to network AnaLASER II smoke detectors.
4-2.2
Compound Arguments
A compound argument consists of a combination of two or more simple arguments. Both
independent and dependent variables can be combined in a compound argument. The combining
operators used to create compound arguments are shown in Table 4-3.
Table 4-3. Combining Operators for Initiating Arguments
Operator
Symbol
And
*
Or
+
THRU
#
Each simple argument component of a compound argument constructed with "OR" or the
"THRU" Operators, is capable of causing execution (or re-execution) of a particular EOC
instruction. The 'OR' and '#' operators actually perform addition operations with the result
being the sum of all terms that are active. This type of EOC instruction is executable or reexecutable until all the simple argument components become true if the initiating devices are
programmed for latching operation. Virtual outputs are capable of triggering the activation of
physical outputs in another EOC statement when their value is changed. They are also capable
of continuously reactivating these outputs when their value subsequently changes again if the
outputs have been reactivated or silenced.
All simple argument components of a compound argument constructed with the "AND" Operators
must be true for the compound argument to be true.
The truth or falsehood of a compound argument follows the rules of ordinary Algebra. More than one
type of combining operator can be used to construct a particular compound argument. The hierarchy
for operator execution is as follows:
•
“THRU” operators
•
Compound arguments in parenthesis
•
“NOT” operators
•
“AND” operators
•
“OR” operators
Note: The "THRU" operator is the most tightly bound, even more than parentheses (i.e., one cannot
code 3#(…) or (…)#4 in an EOC line).
Compound arguments are evaluated sequentially from left to right on an EOC statement when
all operators are of equal hierarchy.
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Event Output Control (EOC)
4-2.2.1
“AND” OPERATOR
In versions of some previous control units, the ‘*’ “AND” operator was strictly a logical operator
resulting in a TRUE (1) or FALSE (0) value.
The “AND” operator has been modified and enhanced to provide support for resounding. The result
of the ‘X*Y’ operation shall be the value of the greater of the two factors as long as both factors are
non-zero. If more than two factors are involved, the factors are read and processed from left to right.
For example,
L1:1#10=I1
L1:20#30=C2
L1: 50#60=C3
I1*C2*C3=SG1,I4
If detector 1 activates, and detectors 25 and 26 activate and device 52 activates, then SG1
turns ON and I4 is set to 2. I2 is the greatest of the 3 non-zero variables.
Subsequently if detector 5 alarms, only the outputs of line 1 are processed, and I1 is set to
2. The result of line 4 remains equal to 2, so SG1 does not reactivate once it has been
silenced.
If an additional device from the range L1: 50#60 activates, the C3 variable remains TRUE
(equal to 1), so the right hand side of line 4 again does not get processed.
Should another detector from L1:1#10 or L1:20#30 alarm, then line 4 result, and I4,
becomes 3 and SG1 re-activates if it had been silenced.
When there’s no change in state on the left hand side of the equation, the right hand side
does not get processed. In order to assure processing of every change of state, additional
‘C’ variables or ‘Q’ variables are necessary, and extra lines of EOC are necessary.
The ‘C’ variables are limited to being set to the values of 0(FALSE) or 1(TRUE), while ‘I’
variables are set to values representing the result of evaluating the left hand side. The ‘Q’
variables are incremented, when on the right hand side, whenever the left hand side
evaluates to a value that is greater than the value to which it had evaluated for any of the
previous passes on the EOC program. These concepts along with the new “AND” definition
are used to provide support for resounding crossed-zone applications.
Refer to the following example, using non-latching initiating devices.
1. L1:1#10=I1,C1
2. L1:20#30=I2,C2
3. L1:50#60=I3,C3
4. NI1=NC1
$ necessary to set C1 to zero when I1 goes to zero
5. NI2=NC2
$ necessary to set C2 to zero when I2 goes to zero
6. NI3=NC3
$ necessary to set C3 to zero when I3 goes to zero
7. I1*C2*C3=SG1,I4
8. C1*I2*C3=SG1,I5
9. C1*C2*I3=SG1,I6
Since the ’C1’ & ‘C2’ & ‘C3’ variables can only be 0 or 1, lines 7, 8 and 9 result in the value
of I1, I2 and I3 respectively, when all three ‘C’ variables are non-zero. Therefore, any
changes of state in the three ranges are processed and SG1 resounded whenever necessary,
once at least one detector in each zone has become active, at some time.
March 2012
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Event Output Control (EOC)
4-3
OUTPUTS
An output can be a physical output or a virtual output. Refer to Table 4-1 for how physical outputs
track or do not track the activation states of their associated initiating devices.
4-3.1
Physical Outputs
Physical outputs can be any of the following types:
1. Control Unit-Based Circuits. The types of outputs that are supported, with symbolic
representations, are listed in Table 4-4 below.
Table 4-4. Control Unit-Based Outputs
Output Type
Symbolic Representation
NAC No. 1
SG1
NAC No. 2
SG2
Combo Number 1:
Release Circuit
AR1
NAC
SG3
Combo Number 2:
Release Circuit
AR2
NAC
SG4
Programmable Relay No. 1
RY1
Programmable Relay No. 2
RY2
Programmable Relay No. 3
RY3
Expansion RNAC Circuits configured as NACs
SGx:y where x = the RNAC module Logical address
(1-24) and y = the RNAC circuit number (1-3)
Expansion RNAC Circuits Configured for Release
ARx:y where x = the RNAC module Logical address
(1-24) and y = the RNAC circuit number (1-3)
Expansion Relay Circuits
RYx:y where x = the Relay module Logical address (1-24)
and y = the Relay circuit number (1-4)
SLC Output Device
Lx:y where x = SLC Loop number (1-8) and y is the SLC
Device address (1-255)
LAM Output
LEDx:y where x = the LAM address (1-16) and y = the
LED output (1-48)
State Variables
Cx where x = variable number (1-255)
Incrementing Variables
Ix where x = variable number (1-255)
Counting Variables
Qx where x = variable number (1-255)
2. SLC-Based Modules. The types of modules that are supported are as follows:
–
Addressable Control Modules (AOs)
–
Addressable Signal Modules (ASMs)
–
Remote Releasing Modules (RRMs)
Note: Each SLC-based module is referenced by its signaling line circuit address.
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Event Output Control (EOC)
3. Remote LAM Modules. A specific LAM output is referenced as follows:
LEDy:z where:
y is the module address, 1 to 16
z is the specific LED output circuit, 1 to 48.
4. Remote ATM-LED/ATM-Relay Modules. A specific ATM output is referenced as follows:
AMy:z where:
y is the module address, 1 to 16
z is the specific LED or Relay output circuit, 1 to 32.
4-3.2
Virtual Outputs
Virtual outputs consist of:
–
State Variables
–
Incrementing Variables
–
Counting Identifiers
Counting Identifiers (Ix) follow the result of evaluating the left hand side of the EOC equation which
can include being set to zero. Saved State Variables (Cx) and saved Incrementing Variables (Qx) are
zeroed ONLY at reset and system initialization or when a subsequent “NOT” operation is executed to
reset them (i.e., such as “...=NCx”, or “...=NQx”).
4-3.2.1
COUNTING IDENTIFIERS (IX)
A Counting Identifier, symbolized by Ix, is initially activated by the execution of a specific EOC
statement. The Counting Identifier becomes a placeholder for the expression that activated it. They
can then be used as a substitute for the triggering argument in a subsequent EOC statement to
activate additional physical outputs or to operate on other dependent variables. Each can also be
used as a substitute for its triggering parameter in an EOC function (see Section 4-6). Counting
Identifiers assume the initiating device type identities in the expressions that activated them and track
the activation or non-activation states of their associated initiating device type arguments as shown
in Table 4-1.
The values assigned to a Counting Identifier depend upon the type of argument that activated it. They
assume the value of a counter when it is associated with a compound argument constructed with "OR"
or "THRU" Operators. They assume the value of “One” (“TRUE) or “Zero” (“FALSE”) when they are
associated with a simple argument, with an argument constructed exclusively with a saved State
Variable (see Section 4-3.2.2) or a saved Incrementing Variable (see Section 4-3.2.3), or with an
argument constructed exclusively with the Initiating Event Counting Function (see Section 4-6.16).
Consider the following example of the use of a Counting Identifier as a substitute for a set of 100
alarm initiating devices addressed from 1 to 100, and therefore used as a counter:
L2:1#100=I1 $ Equation (4-1)
The value of I1 could range anywhere from 0 to 100 depending upon the number of concurrent and
active alarm initiating events that occur within the set of 100 alarm initiating devices. Equation 4-1
represents a common application for a Counting Identifier where it triggers the initial activation and
subsequent resounding of a notification appliance circuit via a statement like the following upon the
receipt of one or more alarm initiating events:
I1=SG1 $ Equation (4-2)
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Any subsequent alarm increments the Counting Identifier, which creates the ability to resound
notification appliance circuit SG1 if silenced.
Now consider the following example of the use of a Counting Identifier as a substitute for the activation of
two groups of alarm initiating devices, one in the address range 1 to 50 and the other in the address range
51 to 100:
L1:1#50*L1:51#100=I1 $ Equation (4-3)The value of I1 shall be “zero”’, “one”, or more depending
on how may detectors in the ranges of L1:1#50 and L1:51#100 are in alarm. This equation is not
sufficient to handle resounding, please refer to section 3-2.2.1 for proper programming. Equation 33 represents a common application for a Counting Identifier where it triggers the activation of a Delay
Function (see Section 4-6.3 or Section 4-6.4) for subsequent activation of outputs:
D(I1,30)=AR1 $ Equation (4-4)
The output AR1 is not activated by the Delay Function in Equation 4-4 if I1 becomes "Zero" prior to
the expiration of the 30-second delay period. I1 returns to “Zero” if and when there are no longer
detectors in alarm in the range L1:1#50 or the range L1:51#100.
It is good practice to use a separate Counting Identifier as a substitute for one and only one
expression. A Counting Identifier being used as a counter and activated and incremented by multiple
expressions is separately and independently incremented by each expression, which can be
confusing.
Increments for the Counting Identifier that are triggered by different expressions, are not cumulative.
A Counting Identifier’s current value is determined by the value assigned to it on the most recently
executed EOC command line, in the EOC program. Likewise, the truth or falsehood assigned to a
Counting Identifier is the value assigned to it on the most recently executed EOC command. It is a
dangerous practice to use a Counting Identifier as a logic variable (True or False variable) for two or
more expressions, particularly where fire extinguishing systems and critical process control
interlocks are concerned.
All Counting Identifiers are re-initialized either to zero or "FALSE" upon a system reset.
4-3.2.2
STATE VARIABLE (CX)
A State Variable, symbolized by Cx, is a binary, True or False, variable that is initialized to the
"FALSE" (= 0) value upon EOC file upload. It can be subsequently set to the "TRUE" (= 1) value by
the execution of a particular EOC statement. Like the Counting Identifier, the State Variable becomes
a placeholder for the argument that activated it. Accordingly, it can then be used as a substitute for
the triggering argument in a subsequent EOC statement to activate additional physical outputs or to
operate on other dependent variables. It can also be used as a substitute for its triggering argument
in an EOC function (see Paragraph 3-6).
State Variables assume the initiating device type identities of the arguments that activated them, but
do not track the activation or non-activation states of their associated initiating device type arguments
as shown in Table 4-1. A State Variable, once activated and assigned a "TRUE" value, can only be reassigned to its initial "FALSE" value by the subsequent execution of another EOC statement that reinitializes it to "FALSE" via the “NOT” Operator (see Section 4-5) or a successful system reset
operation.
Do not use State Variables as counters to be associated with a compound argument constructed with
"OR" or "THRU" Operators. They do not count, but only become “TRUE” (1).
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March 2012
Event Output Control (EOC)
Consider the following example of the use of a State Variable as a substitute for the activation of two
alarm initiating devices anywhere in the address range 1 to 100 (see Section 4-6.16 for a description
of the Initiating Event Counting Function):
(L3:1#100)>1=C1 $ Equation (4-5)
The value of C1 is either "TRUE" or "FALSE" depending upon the truth or falsehood of the left hand
side of Equation 4-5. The equation represents a common application for a State Variable where it
triggers the activation of a Delay Function (see Section 4-6.3 or Section 4-6.4) for subsequent
activation of outputs:
D(C1,30)=AR1 $ Equation (4-6)
The output AR1 is activated unconditionally by the Delay Function in Equation 4-6 unless the State
Variable C1 is re-initialized to "FALSE" by the execution of a subsequent EOC statement with an
output "NC1" prior to the expiration of the 30-second delay period. See Section 4-5 for a description
of the "NOT" Operator.
All State Variables are re-initialized to "FALSE" upon a system reset.
4-3.2.3
INCREMENTING VARIABLE (QX)
An Incrementing Variable, symbolized by Qx, is a variable that is initialized to the value Zero upon
EOC file upload. It can be subsequently incremented by One (new value = old value + 1) by the
execution of a particular EOC statement. Like the Counting Identifier, the Incrementing Variable
becomes a placeholder for the argument that activated it. Accordingly, it can then be used as a
substitute for the triggering argument in a subsequent EOC statement to activate additional physical
outputs or to operate on other dependent variables. It can also be used as a substitute for the
triggering argument in an EOC function (see Paragraph 4-6). It is most useful in counting the # of
times that something happens.
Incrementing Variables assume the initiating device type identities of the arguments that activated
them, but do not track the activation or non-activation states of their associated initiating device type
arguments as shown in Table 4-1. An Incrementing Variable, once activated and assigned a non-Zero
value, can only be reassigned to its initial Zero value by the subsequent execution of another EOC
statement that re-initializes it to Zero via the “NOT” Operator (see Paragraph 4-5) or a successful
system reset operation.
Do not use Incrementing Variables as counters to be associated with a compound argument
constructed with “OR” or “THRU” Operators. They do not count, in the same manner as do Counting
Identifiers, but only increments (counts by one more).
Consider the following example of the use of a Incrementing Variable to count the number of cycles
of alternating a period of Releasing followed by a period of non-Releasing:
March 2012
(L8:1#10>1)*NC4=C1
$ Equation (4-7) The State Variable C1 goes True when at least two
detectors are in alarm
C1=NC2
$ Equation (4-8) The State Variable C2 goes False when C1 goes True
D(C1,20)=C2
$ Equation (4-9) C2 goes True after a delay of 20 seconds after C1 goes
True
C2=NC3
$ Equation (4-10) The State Variable C3 goes False when C2 goes True
C2=AR1
$ Equation (4-11) Release starts when C2 goes True
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D(C2,90)=C3
$ Equation (4-12) C3 goes True after a delay of 90 seconds after C2 goes True
C3=NC1
$ Equation (4-13) The State Variable C1 goes False when C3 goes True
C3=NAR1
$ Equation (4-14) Release stops when C3 goes True
C3=Q1
$ Equation (4-15) The Incrementing Variable Q1 increments by One when C3
goes True
Q1>4=C4
$ Equation (4-16) The State Variable C4 goes True when Q1 reaches the value
of 5
$ The State Variable C4 going True Stops any further execution of this EOC
program
The value of Q1 increments by one every time the 90-second Release stops. After five cycles, the
system quits cycling by setting the State Variable C4 to True, which prevents C1 from ever going True
again.
All Incrementing Variables are re-initialized to Zero upon a system reset.
4-4
MULTIPLE OUTPUTS
A simple output consists of the activation or de-activation of one physical or virtual output. A
compound output consists of the activation or de-activation (or some combination of both operations)
of two or more physical or virtual outputs.
The operators used to create compound outputs are listed in Table 4-5.
Table 4-5. Combining Operators for Outputs
Operator
Symbol
And
*
THRU
#
Outputs activated by alarm events latch into the activated state regardless of whether the initiating
device is configured for latching or Non-Latching operation, except when they are programmed for
thermal cycling or time limit cutout operation. Outputs activated by either supervisory or trouble
events follow the activation state of the initiating device or fault condition that activated them (i.e.,
they de-activate when the initiating device restores or the fault condition is corrected).
Exception: Cyclical alarm outputs can only be activated for the ITLCO and CTLCO periods as
discussed in Section 3-5.6.
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Event Output Control (EOC)
4-5
THE "NOT" OPERATOR
Physical outputs can be deactivated with the "NOT" (N) Operator triggered subsequently by the
execution of another EOC statement. An activated (i.e., set to "TRUE") State Variable (Cx) can also be
de-activated (i.e., re-initialized to "FALSE") by the "NOT" (N) Operator. An Incrementing Variable (Qx),
can be re-initialized to Zero by the “NOT” Operator. A Counting Identifier (Ix)cannot be preceded on
the right hand side with the “NOT” Operator as a negated virtual output. It is re-initialized at Reset
only. It can however, be set to Zero, if that is what the value on the left hand side evaluates to..
The "NOT" Operator can be used in an argument where it checks for the absence of an initiating signal
from a physical device or for the falsehood of a Counting Identifier (Ix) or a State Variable (Cx), as
shown in the following: “N4 = designated outputs”, or “N1#100 = designated outputs”.
4-6
FUNCTIONS
An EOC Function activates outputs for a particular set of initiating conditions, delays execution of
outputs for a certain period of time, modifies automatic initiating device thresholds, or alters outputs
in a specific way when an argument activates. The following EOC functions are available:
4-6.1
Alarm Threshold Adjustment Function (Smoke Detectors Only)
The Alarm Threshold Adjustment Function changes the alarm thresholds of one group (argument2)
of smoke detectors as the result of an alarm signal from any smoke detector in a second group
(expression) of detectors. The format of this function is:
“expression=x.y=A argument2” $, or
“expression=x.y=A argument2” $ (spaces are not required)
where:
x.y is the new alarm threshold in percent per foot obscuration
“argument2” is the range of smoke detectors whose alarm thresholds are to be
adjusted
The adjusted alarm thresholds revert to programmed, standby thresholds upon system reset, or
when ”expression” is a Non-Latching initiating device(s) or a Counting Identifier that subsequently
goes false.
4-6.2
Pre-Alarm Threshold Adjustment Function (Smoke Detectors Only)
The Pre-Alarm Threshold Adjustment Function changes the pre-alarm thresholds of one group
(argument2) of smoke detectors as the result of a pre-alarm signal from any smoke detector in a
second group (expression) of detectors. The format of this function is:
“expression=x.y=P argument2” $, or
“expression=x.y=P argument2” $ (spaces are not required)
where:
x.y is the new pre-alarm threshold in percent-per-foot obscuration
“argument2” is the range of smoke detectors whose pre-alarm thresholds are to be
adjusted
The adjusted pre-alarm thresholds revert to programmed, standby thresholds upon system reset or
when ”expression” subsequently goes false.
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4-6.3
Delayed Output Activation Function (without explicit Abort Interruption)
The Delayed Output Activation Function delays the activation of outputs being activated by an
alarm initiating condition (“expression”) for a specified period of time (delay). The format of
this function is:
“D(expression,delay)= outputs
$ (repeatable)
where:
“expression” is an initiating event or a combination of initiating events
“delay” is the delay in seconds before outputs are activated
Note: The control unit automatically adds 3 seconds to the period of time specified in the delay
parameter.
“outputs” are SLC-based modules, control unit-based circuits, a string or
virtual outputs.
The Delayed Output Activation Function tracks the validity of the “expression” and interrupts its
countdown, resets the “delay” period, and performs no actions if the ”expression becomes either
“Zero” or “FALSE” .
An alarm argument latches the physical outputs associated with the Delayed Output Activation
Function when the time delay period expires. Virtual Outputs and all other physical outputs not
activated by alarm initiating events track the validity of the “expression”, and either are “Zero”
or "FALSE" in the case of Virtual Outputs or de-energize in the case of physical outputs if the
argument becomes either non-incremental (e.g., in the case of tracking non-latching
supervisory events) or "FALSE" (e.g., in the case of an explicit simple or compound trouble
argument).
4-6.4
Delayed Output Activation Function (with explicit Abort Interruption)
The Delayed Output Activation Function with Abort Interruption delays the activation of outputs
being activated by an alarm initiating condition (exp) for a specified period of time (delay). The
activation of any abort switch (abort addresses) interrupts the countdown delay and prevent outputs
activation while the abort switch is active (see Section 3-5.9.1 for exception when IRI Abort Option is
selected). The format of this function is:
“D(expression, delay, abort address, abort address, ... , abort address)=outputs”
$ (non-repeatable)
where:
“expression” is an initiating event or a combination of initiating events
“delay” is the delay in seconds before outputs are activated
“abort address” is an SLC-based module
Note: The control unit automatically adds 3 seconds to the period of time specified in the delay
parameter.
“outputs” are SLC-based modules, control unit-based circuits, a string or
virtual outputs.
The Delayed Output Activation Function (with Abort Interruption) tracks the validity of the
“expression” and interrupts its countdown, resets the “delay” period, and performs no actions if the
“expression” becomes either “ZERO” or "FALSE".
An alarm argument latches the physical outputs associated with the Delayed Output Activation
Function when the time delay period expires. Virtual Outputs and all other physical outputs not
activated by alarm initiating events track the validity of the “expression”, and either are “Zero” or
“False” in the case of Virtual Outputs or de-energize in the case of physical outputs if the argument
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Event Output Control (EOC)
becomes either non-incremental (e.g., in the case of tracking non-latching supervisory events) or
“False” (e.g., in the case of an explicit simple or compound trouble “expression”).
The activation of any abort switch in the abort switch list prior to the expiration of the
countdown timer interrupts the countdown of the timer in accordance with the operating
characteristics of the abort switch. Refer to Section 3-5.9.1 for abort switch operating
instructions.
Note: Countdown timer interruption is not allowed after the countdown timer has begun to count
down if the IRI option is selected.
All outputs associated with the Delayed Output Activation Function (with Abort Interruption) latch
upon expiration of the time delay period.
4-6.5
Trouble Function for Initiating Devices
The Trouble Function for Initiating Devices activates outputs when a trouble condition occurs as
defined in exp.
“T(expression)=outputs”
where:
“expression” is a trouble report from an initiating device or a combination of
trouble reports from initiating devices
“outputs” are SLC-based modules, control unit-based circuits, a string or virtual
outputs.
The Trouble Function for Initiating Devices tracks the validity of the expression (“expression”) and
de-energizes its associated outputs if the expression becomes either “ZERO” or "FALSE".
4-6.6
General Trouble Function
The General Trouble Function activates outputs when any system trouble condition occurs.
“GT=outputs”
where:
“outputs” are SLC-based modules, control unit-based circuits, a string or
virtual outputs.
The General Trouble Function tracks the Trouble State of the control unit and de-energizes its
associated outputs when the Trouble State clears.
4-6.7
General Supervisory Function
The General Supervisory Function activates outputs when any system supervisory condition
occurs.
“GS=outputs”
where:
“outputs” are SLC-based modules, control unit-based circuits, a string or
virtual outputs.
The General Supervisory Function tracks the Supervisory State of the control unit and de-energizes
its associated outputs when the Supervisory State clears.
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4-6.8
General Alarm Function
The General Alarm Function activates outputs when any system alarm condition occurs.
“GA=outputs”
where:
“outputs” are SLC-based modules, control unit-based circuits, a string or
virtual outputs.
The General Alarm Function tracks the Alarm State of the control unit and de-energizes its associated
outputs when the Alarm State clears.
4-6.9
Pre-Alarm Function for Initiating Devices
The Pre-Alarm Function for Initiating Devices activates outputs when a pre-alarm condition occurs
as defined in expression.
“P(expression)=outputs”
where:
“expression” is a pre-alarm initiating event or a combination of pre-alarm initiating
events.
“outputs” are SLC-based modules, control unit-based circuits, a string or
virtual outputs.
The Pre-Alarm Function for Initiating Devices tracks the validity of the expression (“expression”) and
de-energizes its associated outputs if the expression becomes either “ZERO” or "FALSE".
4-6.10
Warning Function for AnaLASER II Detectors Reporting via the IIM
The Warning Function for AnaLASER II detectors reporting via the IIM activates outputs when a
Level-1 Pre-Alarm condition occurs as defined in expression.
W(expression)=outputs
where:
expression is an AnaLASER II Level-1 Pre-Alarm initiating event or a combination
of AnaLASER II Level-1 Pre-Alarm initiating events
outputs are SLC-based modules, control unit-based circuits or virtual outputs.
The Warning Function for AnaLASER II detectors reporting via the IIM tracks the validity of the
expression (expression) and de-energizes its associated outputs if the expression becomes either nonincremental (e.g, in the case of tracking warning signals from HSSDs via a counting identifier) or
"FALSE" (e.g., in the case of an explicit compound argument representing an HSSD warning event).
4-6.11
Level-2 Alarm Function for AnaLASER IIs reporting via the IIM
The Level-2 Alarm Function for AnaLASER II detectors reporting via the IIM activates outputs when
a Level-2 Alarm condition occurs as defined in expression.
X(expression)=outputs
where:
expression is an AnaLASER II Level-2 Alarm initiating event or a combination of
AnaLASER II Level-2 Alarm initiating events
outputs are SLC-based modules, control unit-based circuits or virtual outputs.
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Event Output Control (EOC)
The Level-2 Alarm Function for AnaLASER II detectors reporting via the IIM latches the physical
outputs associated it. Virtual outputs track the validity of the expression and is non-incremental or
"FALSE" in the case of Non-Latching Identifiers if the expression becomes either non-incremental
(e.g., in the case of tracking non-latching HSSDs) or "FALSE" (e.g., in the case of an explicit simple or
compound expression or a Non-Latching Identifier substituting for a non-latching, compound HSSD
Level-2 alarm event).
4-6.12
Notification Appliance Pattern Change Function to 60 BPM
This function changes a NAC's signal pattern to 60 beats per minute.
SGx/60
where:
SGx is a control unit-based notification appliance circuit.
An alarm event or an irrevocable event such as the expiration of a delayed-alarm output activation
function (with abort interruption) latches the associated notification appliance circuit to 60 BPM via
the Notification Appliance Pattern Change Function. The NAC in all other cases tracks the validity of
the argument and de-energizes if the argument becomes either non-incremental (e.g., in the case of
tracking non-latching supervisory events) or "FALSE" (e.g., in the case of an explicit simple or
compound argument or a Virtual Output substituting for a compound trouble argument).
Exception: Cyclical alarm outputs activate only for the ITLCO and CTLCO periods as discussed in
Section 3-5.6.
Note: Do NOT use this function for Intelligent NACs.
4-6.13
Notification Appliance Pattern Change Function to 120 BPM
This function changes a NAC's signal pattern to 120 beats per minute.
SGx/120
where:
SGx is a control unit-based notification appliance circuit.
An alarm event or an irrevocable event such as the expiration of a delayed-alarm output activation
function (with abort interruption) latches the associated notification appliance circuit to 120 BPM via
the Notification Appliance Pattern Change Function. The NAC in all other cases tracks the validity of
the argument and de-energizes if the argument becomes either non-incremental (e.g., in the case of
tracking non-latching supervisory events) or "FALSE" (e.g., in the case of an explicit simple or
compound argument or a Virtual Output substituting for a compound trouble argument).
Exception: Cyclical alarm outputs are activated only for the ITLCO and CTLCO periods as discussed
in Section 3-5.6.
Note: Do NOT use this function for Intelligent NACs.
March 2012
4-14
P/N 06-237042-001
Event Output Control (EOC)
4-6.14
Notification Appliance Pattern Change Function to Temporal Coding
This function changes a NAC's signal pattern to the temporal code.
SGx/T
where:
SGx is a control unit-based notification appliance circuit.
An alarm event or an irrevocable event such as the expiration of a delayed-alarm output activation
function (with abort interruption) latches the associated notification appliance circuit to temporal
coding via the Notification Appliance Pattern Change Function. The NAC in all other cases tracks the
validity of the argument and de-energizes if the argument becomes either non-incremental (e.g., in
the case of tracking non-latching supervisory events) or "FALSE" (e.g., in the case of an explicit
simple or compound argument or a Virtual Output substituting for a compound trouble
argument).
Exception: Cyclical alarm outputs are activated only for the ITLCO and CTLCO periods as discussed
in Section 3-5.6.
Note: Do Not use this function for Intelligent NACs.
4-6.15
Notification Appliance Pattern Change Function to Continuous Output
This function changes a NAC's signal pattern to a steady (i.e., non-coded) output.
SGx/C
where:
SGx is a control unit-based notification appliance circuit.
An alarm event or an irrevocable event such as the expiration of a delayed-alarm output activation
function (with abort interruption) latches the associated notification appliance circuit to continuous
output via the Notification Appliance Pattern Change Function. The NAC in all other cases tracks the
validity of the argument and de-energize if the argument becomes either non-incremental (e.g., in
the case of tracking non-latching supervisory events) or "FALSE" (e.g., in the case of an explicit
simple or compound argument or a Virtual Output substituting for a compound trouble
argument).
Exception: Cyclical alarm outputs are activated only for the ITLCO and CTLCO periods as discussed
in Section 3-5.6.
Note: Do NOT use this function for Intelligent NACs.
P/N 06-237042-001
4-15
March 2012
Event Output Control (EOC)
4-6.16
Initiating Event Counting Function
A special EOC Function is the Counting Function for Initiating Devices and Counting Variables (>n)
whose general form is illustrated below. Outputs activate when the number of single or combinations
of alarm initiating events as defined in “expression” exceeds Ix, Qx, or “n”.
“(expression)>Ix = outputs”, or
“(expression)>Qx = outputs”, or
“(expression)>n = outputs”
where:
“expression” is an initiating event, a combination of initiating events or a virtual
output.
Ix, Qx, or “n” is the number of initiating events required to activate the outputs.
“outputs” are SLC-based modules, control unit-based circuits, a string or virtual
outputs.
Note: The above initiating expression, (i.e., (expression)>Ix, (expression)>Qx, or (expression)>n),
can be used with other simple arguments and the “OR” and “AND” Operators discussed in
Paragraph 4-2.2 to create compound arguments.
It can also be used as all or part of the arguments described in Paragraph 4-6.1 through Paragraph
4-6.15. Refer to Table 4-5 for special requirements when creating compound arguments with the
Initiating Event Counting Function.
An alarm argument latches the physical outputs associated with the Initiating Event Counting
Function when the designated count is exceeded.
March 2012
4-16
P/N 06-237042-001
Event Output Control (EOC)
4-7
CONSTRUCTING ARGUMENTS FOR INITIATING EVENTS FROM REMOTE, NETWORKED
CONTROL UNITS
Arguments that consist of initiating events from remote, networked control units must be prefixed
with the letter F, the network node number, and a colon (i.e., :).
4-7.1
Remote-Node Simple Arguments
A remote-node simple argument consists of the network-node prefix and the SLC or HSSD address
of the initiating device on the remote node. For example, a simple argument using the initiating device
at Address 21 on Node 3 would be referenced in any other node as follows:
•
F3:L1:021
Note: The designator "HSD" prefixes HSSD addresses when an IIM is used for the remote
node.
4-7.2
Remote-Node Compound Arguments
A remote-node compound argument consists of a combination of two or more simple arguments.
However, there is one instance where it is not necessary to prefix all the simple arguments with the
letter F, the network node number, and a colon. The "THRU" Combining Operator should be used as
follows to reference all initiating points at addresses 1 through 20 on Node 2 in any other node:
•
F2:L1:1#20
All other compound arguments that reference remote-node initiating devices require that all the
remote-node initiating devices be prefixed with the letter F, the network node number, and a colon.
For example, references to initiating points 8, 12, and 15 on Node 1 would be entered in any other
node as follows:
•
F1:L1:8+F1:L3:12+F1:L5:15
•
F1:L1:8*F1:L3:12*F1:L5:15
A complete summary of EOC operators and functions, with specific examples of usage, is presented
in Table 4-6.
4-7.3
Remote State Variable (Fy:Cx)
The Cx State Variables described above can be used across networked control units. The proper
usage of this feature is an operator ‘Fy:Cx’, where ‘y’ is a valid node number and ‘x’ is a valid ‘C’
variable number used on the ‘y’ node. These network state variables are processed the same way nonnetworked state variables are processed by the control unit. Whenever the state variable changes on
the originating node, a network message is generated with the new value, “TRUE” or “FALSE”, of the
variable. When control units receive the C variable network messages, the local EOC is processed.
There is no verification between control unit configurations, so it is imperative that the EOC
programs for different nodes sharing state variables are manually and thoroughly reviewed to be sure
there are no errors.
Note: ‘Fy:Cx’ cannot be used on the right hand side of EOC equations. Control units cannot change
state variables originating on other nodes. Networked state variables are read only.
P/N 06-237042-001
4-17
March 2012
Event Output Control (EOC)
Table 4-6. EOC Operators and Functions
Operator or Function
Symbol or General
Form
Typical Examples
Execution
=
L1:45=SG1
(i.e., "equal" symbol)
"AND" for Outputs
,
*
Turn on SG1 if initiating device
45 activates.
L1:4=AR1,SG1
Turn on AR1 and SG1 if initiating device
4 activates.
L1:1*L1:3
1 and 3
(i.e., comma)
"AND" for Initiating
Devices and/or Initiating
Conditions
Description
Note: Arguments may be enclosed
within parentheses if used with other
operators (e.g., "+" or "#") in a
compound conditional activation
statement. Arguments in parenthesis are
evaluated first.
(i.e., "multiplication"
symbol)
For example:
(L1:1*L1:3)+L1:10=SG1
This statement translates to "Turn on SG1
if 1 and 3 activate or if 10 activates".
"OR" for Initiating
Devices and/or Initiating
Conditions
+
L1:10+L1:12
10 or 12
Note: Arguments may be enclosed
within parentheses if used with other
operators (e.g., "*" or "#") in a
compound conditional activation
statement. Arguments in parenthesis are
evaluated first.
(i.e., "addition" symbol)
For example:
(L1:1+L1:3)*L1:10=SG1
This statement translates to "Turn on
SG1 if 1 or 3 activates and if 10 also
activates".
"THRU" for Initiating
Devices, Counting
Identifiers and Outputs
#
L1:1#20
Any initiating device 1 through 20.
Note: Arguments for initiating devices
may be enclosed within parentheses if
used with other operators (e.g., "*" or
"+") in a compound conditional
activation statement. Arguments in
parenthesis are evaluated first.
(i.e., "pound" symbol)
For example:
(L1:1#20)+L1:50=SG1,SG4
This statement translates to "Turn on
SG1 and SG4 if any address 1 through
20 activates or if address 50 activates".
March 2012
4-18
P/N 06-237042-001
Event Output Control (EOC)
Table 4-6. EOC Operators and Functions (Continued)
Operator or Function
Alarm Threshold
Adjustment
(smoke detectors only)
Symbol or General
Form
Typical Examples
Description
exp1=x.y=Aarg2
L1:1#20=1.0=AL1:21#40
Change the alarm threshold to 1.0% per
foot for each detector in the address
range 21 through 40 if any detector in
the address range 1 through 20 reports
an alarm.
where:
exp1 is an alarm
initiating event or
combination of alarm
initiating events
Note: The alarm initiating condition (i.e.,
exp1) and the adjusted smoke detector
range (i.e., arg2) can be any valid simple or
compound arguments using multiple
operators or types of operators. Commas
are required to delimit the simple or
compound outputs for alarm threshold
adjustment.
x.y is the new alarm
threshold for each
detector in arg2.
arg2 is the range of
smoke detectors whose
alarm thresholds are to
be adjusted.
For example:
L1:1+L1:10#20=1.0=AL1:2,1.0=
AL1:21#30
This statement translates to "Change the
alarm threshold to 1.0% per foot for the
detector at address 2 and for each
detector in the address range 21
through 30 if the detector at address 1
or any detector in the address range 10
through 20 reports an alarm".
Delayed Output
Activation
D(exp,delay)= outputs
D(L1:2*L1:3,30)=RY1
where:
Note: Parentheses as shown are
required. The initiating condition
(i.e., exp) for the delay operator can
be any valid simple or compound
argument using one or more operator
types such as "+", "#", or ">n". EOC
continuously loops back to the initial
program statement and rerun entirely
until the last activated delayed output
activation statement has successfully
executed.
exp is an initiating
event or combination of
initiating events
delay is the delay is
seconds before outputs
are activated (max.
3600 seconds)
outputs are SLC-based
modules, control unitbased circuits, a string
or virtual outputs
P/N 06-237042-001
Turn on RY1 after a 30-second delay
if both initiating devices 2 and 3
activate.
4-19
March 2012
Event Output Control (EOC)
Table 4-6. EOC Operators and Functions (Continued)
Operator or Function
Counting Identifier
(Max. 255 identifiers)
Symbol or General
Form
Typical Examples
Description
Ix
L1:5#10=I1
Counting Identifier I1 increments its
current value and cause execution or reexecution of any subsequent statement
using it as a conditional input trigger if
any initiating device 5 through 10
activates. Counting Identifiers must be
assigned to specific initiating
expressions before they can trigger
outputs in subsequent execution
statements. Relay 1 and Relay 3 activate
if any initiating device in the address
range 5 to 10 activates.
I1=RY1,RY3
where:
x is any number from 1
to 255
Note: Use one Counting Identifier for
each unique initiating expression.
Counting Identifiers cannot be used with
the NOT Operator on the output side of
an EOC statement.
NOT
N
L1:1*N2=SG1
(1)
L1:5=NSG1,SG4 (2)
Checks for the absence of an initiating
signal in a conditional execution
statement as in Example (1). Turns off
previously activated outputs in a
conditional execution statement as in
Example (2).
Note: The negated initiating condition
can be any valid simple or compound
argument using multiple operators or
types of operators. Parentheses are
required to delimit the argument.
For example on the left input side:
N(1+5) is equivalent to N1+N5.
March 2012
4-20
P/N 06-237042-001
Event Output Control (EOC)
Table 4-6. EOC Operators and Functions (Continued)
Operator or Function
Pre-Alarm Threshold
Adjustment
(smoke detectors only)
Symbol or General
Form
Typical Examples
Description
exp1=x.y=P arg2
L1:1#20=1.0=P L1:21#40
Change the pre-alarm threshold to 1.0%
per foot for each detector in the address
range 21 through 40 if any detector in
the address range 1 through 20 reports
a pre-alarm condition.
where:
exp1 is a pre-alarm
initiating event or
combination of prealarm initiating events
Note: The initiating condition (i.e.,
exp1) and the adjusted smoke detector
range (i.e., arg2) can be any valid
expression using multiple operators or
types of operators. Commas are
required to delimit the simple or
compound outputs for pre-alarm
threshold adjustment.
x.y is the new prealarm threshold for
each detector in arg2
arg2 is the range of
smoke detectors whose
pre-alarm thresholds
are to be adjusted
For example:
L1:1+L1:10#20=1.0=P L1:2,1.0
=P L1:21#30
This statement translates to "Change the
pre-alarm threshold to 1.0% per foot for
the detector at address 2 and for each
detector in the address range 21
through 30 if the detector at address 1
or any detector in the address range 10
through 20 reports a pre-alarm
condition".
State Variable
(Max. 255 Variables)
Cx
L1:5#10=C1
C1=RY1,RY3,NC1
where:
x is any number from
1 to 255
State Variable C1 is "TRUE" and causes
execution of any subsequent statement
using it as a conditional input trigger if
any initiating device 5 through 10
activates. All State Variables are initially
"FALSE" until changed to "TRUE" by the
execution of a program statement. A
State Variable can be re-initialized to
"FALSE" by the NOT Operator during
the execution of a subsequent program
statement. Relays 1 and 3 activate and
C1 is re-initialized to “FALSE” in this
example.
Note: Use one State Variable for each
unique system state condition.
P/N 06-237042-001
4-21
March 2012
Event Output Control (EOC)
Table 4-6. EOC Operators and Functions (Continued)
Operator or Function
Delayed Output
Activation
(with Abort
Interruption)
Symbol or General
Form
Typical Examples
Description
D(exp,delay,abort
addresses)=outputs
D(L1:2*L1:3,30,L1:9,L1:10)
= AR1,SG1
Turn on AR1 and SG1 after a 30-second
delay if both initiating devices 2 and 3
activate. Interrupt the countdown if
either 9 or 10 activate before the
expiration of the time delay.
where:
exp is an alarm
initiating event or a
combination of alarm
initiating events
Note: Parentheses as shown are
required. Counting Identifiers, State
Variables and Saved Incrementing
Variables can be used for the delay
function's initiating condition. The
initiating condition (i.e., exp) for the
delay function can be a compound
argument using the "+", "#", or ">n"
Operators. Do not use the "+" or "#"
Operators in the Abort Field. EOC
continuously loops back to the initial
program statement and rerun entirely
until the last activated delayed output
activation statement has successfully
executed.
delay is the delay is
seconds before outputs
are activated (max. 300
seconds)
addresses is the
comma delimited list of
abort switch addresses
(including remote)
outputs are SLC-based
modules, control unitbased circuits, a string
or virtual outputs
Counting Zone for
Initiating Devices
(exp)>n=outputs
(L1:5#15)>1=SG1
where:
Turn on SG1 if more than one of the
alarm initiating devices in the address
range 5 through 15 activates.
Note: Parentheses as shown are
required. The alarm initiating condition
(i.e., exp) for the Counting Zone
Function can be any valid simple or
compound argument using one or more
operator types such as "+" or "*". The
Counting Zone Function can be
combined with other operators (e.g., "+"
or "#") to create a compound conditional
activation statement.
exp is an initiating
event or a combination
of initiating events
outputs are SLC-based
modules, control unitbased circuits, a string
or virtual outputs
N is the threshold
above which the
function activates.
For example:
I1+(L1:5#15)>1=AR1
Counting Zone operations should be
enclosed in parenthesis, for clarity, but
it is not necessary.
For example:
((L1:5#15)>1)+I1=AR1
The above statements are equivalent,
and translate to "Turn on AR1 if
Counting Identifier I1 becomes “TRUE”
or if any two initiating devices in the
address range 5 through 15 activate".
March 2012
4-22
P/N 06-237042-001
Event Output Control (EOC)
Table 4-6. EOC Operators and Functions (Continued)
Operator or Function
Notification Appliance
Pattern Change to 60
BPM
Symbol or General
Form
Typical Examples
SGx/60
L1:1#20=SG1/60
where:
SGx/120
L1:1#20=SG1/120
where:
SGx/T
L1:1#20=SG1/T
where:
SGx/C
L1:1#20=SG1/C
where:
T(exp)=outputs
T(L1:1#20)=L1:100
where:
outputs are SLC-based
modules, control unitbased circuits, a string
or virtual outputs
GT=outputs
Activate Addressable Output (AO) 100 if
any initiating device in the address
range 1 through 20 issues a trouble
report.
Note: Parentheses as shown are
required. The initiating condition (i.e.,
exp) for the Trouble Operator can be
any valid simple or compound argument
using one or more operator types such
as "+", "#", or "*"
exp is a trouble report
or a combination of
trouble reports from
initiating devices
General Trouble
Turn on SG1 with a continuous output
(and override the current pattern, if
activated) when any device in the
address range 1 through 20 activates.
Note: Do Not use this function for
Intelligent NACs
SGx is a control unitbased notification
appliance circuit.
Trouble for Initiating
Devices
Turn on SG1 with the temporal pattern
(and override the current pattern, if
activated) when any device in the
address range 1 through 20 activates.
Note: Do Not use this function for
Intelligent NACs
SGx is a control unitbased notification
appliance circuit.
Notification Appliance
Pattern Change to
Continuous Output
Turn on SG1 with a 120 BPM pattern
(and override the current pattern, if
activated) when any device in the
address range 1 through 20 activates.
Note: Do Not use this function for
Intelligent NACs.
SGx is a control unitbased notification
appliance circuit.
Notification Appliance
Pattern Change to
Temporal Coding
Turn on SG1 with a 60 BPM pattern
(and override the current pattern, if
activated) when any device in the
address range 1 through 20 activates.
Note: Do Not use this function for
Intelligent NACs.
SGx is a control unitbased notification
appliance circuit.
Notification Appliance
Pattern Change to 120
BPM
Description
Do not use the Trouble for Initiating
Devices Function for an AI Monitor
Module programmed as a trouble
initiating device.
GT=L1:100
Activate Addressable Output (AO) 100 if
any system trouble event occurs.
where:
outputs are SLC-based
modules, control unitbased circuits, a string
or virtual outputs
P/N 06-237042-001
4-23
March 2012
Event Output Control (EOC)
Table 4-6. EOC Operators and Functions (Continued)
Operator or Function
Symbol or General
Form
Typical Examples
Description
General Supervisory
GS=outputs
GS=L1:100
Activate Addressable Output (AO) 100 if
any system supervisory event occurs.
P(L1:1#20)=SG1
Activate SG1 if any initiating device in
the address range 1 through 20 issues a
pre-alarm report.
where:
outputs are SLC-based
modules, control unitbased circuits, a string
or virtual outputs
Pre-Alarm
P(exp)=outputs
where:
Note: Parentheses as shown are
required. The initiating condition (i.e.,
exp1) for the Pre-Alarm Function can be
any valid simple or compound argument
using one or more operator types such
as "+", "#", or "*".
exp is a pre-alarm
initiating event or a
combination of prealarm initiating events
outputs are SLC-based
modules, control unitbased circuits, a string
or virtual outputs
Activating a Single LAM
LED
LEDx:y
LED/Bx:y
LED/Sx:y
LED/Rx:y
LED/Yx:y
(1) GT=LED2:3
(2) GS=NLED16:43
(3) GT=LED1:1,LED/B1:2,
LED/S1:3,LED/R1:4,LED/
Y1:5
(4) GT=LED/B/R1:6,
LED/R/B1:7,LED/B/Y1:8,
LED/Y/B1:9
(5) GT=LED/S/R1:14,
LED/R/S1:15,LED/S/Y1:16,
LED/Y/S1:17
Note: 44 thru 48 are
Reserved.
(1) Annunciator circuit #3 on LAM
module #2 becomes active when the
General Trouble activates.
(2) Annunciator circuit #43 on LAM
module #16 deactivates when the
General Supervisory activates.
For lines (3), (4), and (5), when the
General Trouble activates, then on LAM
module #1:
(3) Annunciator circuit #1 goes on as
configured; circuit #2 goes on Blinking
(color as configured); circuit #3 goes on
Steady (color as configured); circuit #4
goes on Red (pattern as configured);
circuit #5 goes on Yellow (pattern as
configured).
(4)Annunciator circuits #6 and #7 go
on Blinking Red; circuits #8 and #9 go
on Blinking Yellow.
(5) Annunciator circuits #14 and #15
go on Steady Red; circuits #16 and #17
go on Steady Yellow.
Mapping Multiple LAM
LEDs
March 2012
MLP list=
LEDw:x#y:z,
LEDs:t#u:v
MLP C2,GT,L1:1#3=
LED2:10#2:14
4-24
Maps C2 to LED2:10, GT to LED2:1,
inputs1 to LED2:12, 2 to LED2:13, and
3 to LED2:14. These mapping lines
would normally be at the end of an EOC
program, but could appear anywhere,
especially if one wanted to find out the
intermediate value of a Counting
Identifier or State Variable (possibly for
EOC debugging purposes).
P/N 06-237042-001
Event Output Control (EOC)
Table 4-6. EOC Operators and Functions (Continued)
Operator or Function
Symbol or General
Form
Activating a Single
ATM-L (LED)
or ATM-R (Relay)
AMx:y
AM/Bx:y
AM/Sx:y
Typical Examples
Description
(1) GT=AM2:3
(1) Annunciator circuit #3 on ATM
module #2 becomes active when the
General Trouble activates.
(2) GS=NAM16:43
(2) Annunciator circuit #43 on ATM
module #16 deactivates when the
General Supervisory activates.
(3) GT=AM1:1,AM/B1:2,
AM/S1:3,
For line (3), when the General Trouble
activates, then on ATM module #1:
Annunciator circuit #1 goes on as
configured; circuit #2 goes on blinking
(ATM-L only).
Mapping Multiple
ATM-L (LEDs)
or ATM-R (Relays)
MAP list=
AMw:x#y:z,
AMs:t#u:v
MAP C2,GT,L1:1#3=
AM2:10#2:14
Maps C2 to ATM2:10, GT to ATM2:1,
inputs1 to ATM2:12, 2 to ATM2:13, and
3 to ATM2:14. These mapping lines
would normally be at the end of an EOC
program, but could appear anywhere,
especially if one wanted to find out the
intermediate value of a Counting
Identifier or State Variable (possibly for
EOC debugging purposes).
Warning for AnaLASER
II Detectors Reporting
via IIM
W(exp)=outputs
W(HSD1#HSD5)=SG1
Activate SG1 if any AnaLASER II in the
address range 1 through 5 issues a
warning report. This is a Pre-Alarm
Level 1 for AnaLASER IIs).
where:
Note: Parentheses as shown are
required. The initiating condition (i.e.,
exp) for the Warning Function can be
any valid simple or compound argument
using one or more operator types such
as "+", "#", or "*".
exp is an AnaLASER II
Level-1 Pre-Alarm
initiating event or a
combination of
AnaLASER II Level-1
pre-alarm initiating
events
outputs are SLC-based
modules, control unitbased circuits or
virtual outputs
Alarm Level 2 for
AnaLASER II Detectors
Reporting via IIM
X(exp)=outputs
X(HSD1#HSD5)=SG1
where:
Note: Parentheses as shown are
required. The initiating condition (i.e.,
exp) for the Level-2 Alarm Function can
be any valid simple or compound
argument using one or more operator
types such as "+", "#", or "*".
exp is an AnaLASER II
Level-2 Alarm initiating
event or a combination
of AnaLASER II Level-2
Alarm initiating events
outputs are SLC-based
modules, control unitbased circuits or
virtual outputs
P/N 06-237042-001
Activate SG1 if any AnaLASER II in the
address range 1 through 5 issues a highlevel-alarm report. This is an Alarm
Level 2 for AnaLASER IIs).
4-25
March 2012
Event Output Control (EOC)
Table 4-6. EOC Operators and Functions (Continued)
Operator or Function
Remote Control Unit
Initiating Event
Symbol or General
Form
Typical Examples
Description
Fx:Ly:arg=outputs
F5:L1:1#50=SG1
Activate SG1 if any initiating device in
the address range 1 through 50 on SLC
1 of Node No. 5 issues an alarm report.
F3:L1:7*F2:L1:10=AR1
Activate AR1 if initiating device 7 on
SLC 1 of Node No. 3 AND initiating
device 10 on SLC 1 of Node No. 2 issue
alarm reports.
F5:L1:1+F3:L1:7=RY1
Activate RY1 if initiating device 1 on
SLC 1 of Node No. 5 OR initiating device
7 on SLC 1 of Node No. 3 issue an alarm
report.
F15:C1=RY1,RY3
If the State Variable C1 defined on node
15 becomes "TRUE", then RY1 and RY2
shall activate.
where:
x is the remote control
unit node number from
1 to 64
y is the SLC Loop
number from 1 to 8
arg is an alarminitiating event or a
combination of alarminitiating events from
the remote control unit
of the following
generalized types:
start address#end
address
or,
The "OR" Operator (+)
and the “AND”
Operator (*) cannot be
used to construct a
compound argument.
The "OR" Operator (+)
and the “AND”
Operator (*) create
separate terms that
must be prefixed with
Fx:.
outputs are outputs
activated by the control
unit that received the
remote initiating
event(s)
Networked Saved State
Variable (Max. 255
Variables for each node)
Fy:Cx
Where:
x is any number from
1 to 255 and y is any
number from 1 to 64
Comment
$
Note: A networked State Variable cannot
be changed and as such cannot be used
on the right hand side of EOC equations.
$ General Alarm Condition
or
(any of the above) $ comment
March 2012
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Used to indicate a non-operational
program line or end of statement on a
line.
Note: Use the minimum number of
comment lines to properly document the
flow and logic of the EOC application.
Each comment line counts toward the
limit of 256 EOC lines, and negligibly
extends the time required to execute the
specific application.
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Event Output Control (EOC)
Table 4-6. EOC Operators and Functions (Continued)
Operator or Function
RRM Grouping
Activation
Symbol or General
Form
Typical Examples
Description
RGx
L1:100*L1:200=RG1
Activate Release Group 1 when
addresses 100 and 200 report an alarm
condition.
L1:1#50=OG5
Activate Output Group 5 when any
device in the Address range of 1 to 50 on
SLC 1 report an alarm condition.
Where:
RG is the release group
in which RRM’s are
assigned to via the
configuration software
x is the group number
between 1 and 4
SLC Output Grouping
Activation
OGx
Where:
x is the SLC Output
group in which AO and
ASM devices are
assigned to via the
configuration software
x is the group number
between 1 and 7
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Event Output Control (EOC)
4-8
CREATING EVENT OUTPUT CONTROL (EOC TAB)
The section of the program that stores EOC execution statements is invoked when the EOC Tab is
selected. Figure 4-1 shows the EOC Tab. Use the <Edit> button to enter EOC code.
Figure 4-1. EOC Creation Screen
Figure 4-2 shows lines of EOC code that have been entered via the program's free-form text editor.
Figure 4-2. EOC Text Editor Screen
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The EOC Tab Text Editor screen options are shown in Table 4-7.
Table 4-7. EOC Tab Options
Command
EOC Toolbar
Function
Save, Print, Cut, Copy, Paste, Find and Verify Icons
File Menu
Save As Text, Print, Exit
Edit Menu
Undo, Cut, Copy, Paste and Delete
Find Menu
Searches EOC Code
Verify Menu
Verifies EOC Code
Help Menu
Opens PDF file of FCS8000 User’s Guide and shows the application version.
Follow these steps to create an EOC file:
5.
Enter EOC execution statements in free-form format just as if using a standard word processing
program. Note that it is not necessary to create line numbers for EOC statements.
6. Select <OK> when done.
7. Edit the EOC code as necessary to remove all errors and warnings.
8. Select <Apply> to apply changes.
9. Save your configuration file.
Figure 4-3 shows the saved EOC code in the EOC Summary Window. Click <Edit...> to edit the
EOC Code.
Figure 4-3. Saved EOC Code Screen
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Event Output Control (EOC)
If the program detects an undefined SLC device or a syntax error, the Error and/or Warning Screen
appears (see Figure 4-4) after exiting the text editor.
Figure 4-4. EOC Error and/or Warning Screen
4-8.1
The <Apply> Button
Click <Apply>, located at the bottom of the EOC tab, to accept all changes made. (See Figure 4-1.)
Note: Clicking <Apply> does not automatically save settings to the configuration file.
configuration file must be saved before exiting the program, or settings will be lost.
4-8.2
The
The <Reset> Button
Click <Reset>, located at the bottom of the EOC tab, to cancel all changes made to settings while in
the EOC tab and return to the previously-saved settings. (See Figure 4-1.)
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4-9
STRUCTURING EVENT OUTPUT CONTROL
In general, one EOC statement needs to be written for each input-to-output operating sequence
required for the specific application. Up to 256 EOC statements can be used for any application, and
an EOC statement can have up to 128 characters. Use the following guidelines to construct an EOC
application:
1.
Arrange the sequence of EOC statements from the start to the end of the application according
to the following event priority:
–
Alarm
–
Supervisory
–
Trouble
Note: All alarm events must be annunciated by public mode notification.
2.
Put the most likely to be executed statements at the start of the prioritized segments above. This
means that statements with simple arguments or compound arguments constructed with either
"OR" ( + ) or "THRU" ( # ) Operators should be entered first in each prioritized segment.
3.
Use a separate Counting Identifier or State Variable for each compound argument that is used
on more than one EOC statement.
4.
Never use a Counting Identifier to trigger outputs unless it has been defined first in a prior EOC
statement.
5.
If possible, activate physical and virtual outputs in the same EOC statement to keep the number
of statements to as few as possible.
6.
Write the pre-release, release, and post-release EOC statements on consecutive lines for each
special extinguishing system. A separate pre-release statement is typically required because
release outputs are not activated until after the expiration of a time delay. Enter these statements
in ascending order according to the more progressively serious alarm condition (i.e., write the
pre-alarm statement first, the pre-release statement second, and the release statement third).
Note: The following requirements apply to special extinguishing systems:
–
The pre-alarm state must be annunciated by distinctive public mode notification.
–
The pre-release state must be annunciated by public mode notification different from the
pre-alarm state public notification mode.
–
The release state must be annunciated by public mode notification different from both
the pre-alarm state and pre-release state public notification modes.
7.
The manual release station(s) for a special extinguishing system must appear in the arguments
of the pre-alarm, pre-release, and release statements for the system if required interlocks such
as door closures, airflow shutoff, and power down procedures are distributed throughout these
three alarm stages.
8.
Place the least likely to be executed statements at the end of the prioritized segments in 1). For
example, open area smoke detectors are more likely to activate before duct detectors because of
the high smoke dilution factors associated with duct detection. Therefore statements associated
with duct detectors should be entered after the statements associated with open area detectors
and after any special extinguishing system execution statements.
9.
Add in remote alarm-initiating events from other networked control units according to the
guidelines 2) through 7), but add them after the control unit's local events. Arrange remote alarminitiating events in ascending order by network node number.
10. It is recommended that the terms involved in contiguous "ANDing" be limited to only one term
that can have a value of more than 1, and the rest limited to logical “TRUE” or “FALSE” only.
For example, 'I1 * NI2 * N(L1:10#40)' is good because only I1 can have a value greater than 1
(NI2 and N(L1:10#40) is always “TRUE” or “FALSE). However, 'L1:10#40 * I3' is not acceptable
because both factors can be greater than 1.
Refer to section 3-2.2.1 for more information.
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4-10
EVENT OUTPUT CONTROL EXAMPLES
Table 4-8 illustrates specific example of event output control. This is a two-zone waterless
suppression system with associated pre-action sprinkler systems. Refer to Appendix A for the
sequence of operation and device/circuit configuration associated with this application.
Table 4-8. EOC, Example 1
$ Head End Room Pre-Alarm
L1:1#3=SG1,LED1:1,I1, C1
NI1=NC1
L1:1#3=1.5=A4#6
L1:4#6=SG1,LED1:1,I2, C2
NI2=NC2
L1:4#6=3.0=L1:A1#3
$ Power Room Pre-Alarm
L1:14#15=SG3,LED1:4,I3, C3
NI3=NC3
L1:14#15=1.5=L1:A16#17
L1:16#17=SG3,LED1:4,I4, C4
NI4=NC4
L1:16#17=3.0=AL1:14#15
$ Head End Room Waterflow
L1:11=SG2,LED1:6,RY3
$ Power Room Waterflow
L1:20=SG4,LED1:12,RY3
$ Head Room Tamper
L1:12=LED1:5,L1:25
$ Power Room Tamper
L1:21=LED1:11,L1:25
$ Head End Room Low Pressure
L1:13=LED1:4
$ Power Room Low Pressure
L1:22=LED1:10
$ Pre-Action System Low Air
L1:26=LED1:13
$ Head End Room Pre-Release
I1*C2 + L1:7 + L1:8= SG1/120,23
C1*I2 + L1:7 + L1:8=SG1/120,23
$ Head End Room Release
D(I1*I2,30,L1:9,L1:10)+L1:7+L1:8=NSG1,NLED1:1,AR1,SG2,24,RY2,LED1:3
L1:9+10=LED1:2
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Event Output Control (EOC)
Table 4-8. EOC, Example 1 (Continued)
$ Power Room Pre-Release
I3*C4+L1:18= SG3/120, 23
C3 * I4+L1:18=SG3/120, 23
$ Power Room Release
D(I3*I4,30,L1:19)+L1:18=NSG3,NLED1:7,AR2,SG4,24,RY2,LED1:8
L1:19=LED1:8
Table 4-9 is an example of a networked fire-alarm system monitoring three school buildings. The
sequence of operations for all three buildings is shown in Appendix A. The details are shown in
Table 4-8 and Table 4-9 for the first building. The specifics for Buildings No. 2 and 3 are similar.
Table 4-9. EOC, Example 2
$ Building No. 2 Smoke Detectors
F2:L1:1#15=SG4,S1
$ Building No. 2 Manual Stations
F2:L1:16#23=SG4,S2
$ Building No. 2 Waterflow
F2:L1:24#27=SG4,S2
$ Building No. 2 Kitchen Hood
F2:L1:28=SG4,S4
$ Building No. 3 Smoke Detectors
F3:L1:1#15=SG4,S6
$ Building No. 3 Manual Stations
F3:L1:16#23=SG4,S7
$ Building No. 3 Waterflow
F3:L1:24#27=SG4,S8
$ Building No. 3 Kitchen Hood
F3:L1:28=SG4,S9
$ Building No. 2 Supervisory
F2:L1:29#32=S5
$ Building No. 3 Supervisory
F3:L1:29#32=S1
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Event Output Control (EOC)
4-11
ADDITIONAL EVENT OUTPUT CONTROL EXAMPLES
The examples in this section illustrate special EOC topics of interest.
4-11.1
Limited Water Supply Example
A four-zone deluge sprinkler system is being designed according to the following water supply
constraints:
Active Zone
Allowable Subsequent Zone Activation
Disallowable Subsequent Zone Activation
1
2
3 and 4
2
1 or 3
4
3
2 or 4
1
4
3
1 and 2
Note: In order to cover 4 zones, there must be an expansion RNAC with 2 circuits configured
for release.
No more than two deluge sprinkler zones can be active concurrently. Figure 4-5 illustrates the
application.
Sprinkler Zone 1
Sprinkler Zone 2
HD1
HD2
Sprinkler Zone 3
Sprinkler Zone 4
HD3
HD4
Figure 4-5. Limited Water Supply
State Variables are used in the code that follows to signify the activation of each zone and to apply the
required constraints:
“(Zone 1)”*NC3*NC4*NC5=AR1,C1
“(Zone 2)”*NC4*NC5=AR2,C2
“(Zone 3)”*NC1*NC5=AR1:1,C3
“(Zone 4)”*NC1*NC2*NC5=AR1:2,C4
C1*(C2+C3+C4)=C5
C2*(C1+C3+C4)=C5
C3*(C1+C2+C4)=C5
C4*(C1+C2+C3)=C5
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Event Output Control (EOC)
4-11.2
NAC that Tracks AnaLASER II Alarm State
The system shown in Figure 4-6 is to be designed according to the following criteria:
•
Activate NAC if either one of AnaLASER II detectors alarm
•
Deactivate NAC if all alarmed HSSDs issue alarm off reports
•
Latch the NAC into the active state if any spot type smoke detector alarms.
SD1
SD2
SD3
SD5
SD6
AIM20
SG1
SD4
AIM21
Figure 4-6. Tracking NAC
The EOC code required to accomplish this design requirement is shown below:
L1:20+L1:21=SG1
L1:1#6=SG1,C1
NL1:20*NL1:21*NC1=NSG1
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Event Output Control (EOC)
4-11.3
External Maintenance Bypass Switch Example
An end user wants to provide service personnel with a simplistic way to prevent the activation of
notification appliances during facility maintenance periods. The user wants to use an externally
mounted switch to accomplish this requirement. The necessary sequence of operation is as follows:
•
The NAC shall activate if an automatic detector alarms and the maintenance bypass switch has
not been activated
•
The NAC shall not activate if an automatic detector alarms subsequently to the activation of the
maintenance bypass switch
•
The NAC shall deactivate if the maintenance bypass switch is activated subsequently to an
automatic detector alarm.
The AI monitor module for the maintenance bypass switch is configured as a non-latching
supervisory initiating device. Figure 4-7 illustrates the application.
SD1
SG1
Keyed Maintenance Bypass with AI 2
Figure 4-7. Maintenance Bypass Switch
The required lines of EOC code are as follows:
L1:1*NL1:2=SG1
L1:2=NSG1
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Communications to the Control Unit
CHAPTER 5
COMMUNICATIONS TO THE CONTROL UNIT
5-1
INTRODUCTION
A configuration created as described in Chapters 2 through 4 must lastly be uploaded to the
FenwalNET 8000-MLTM Control Unit to establish a working fire protection system. The utilities
provided in the Tools drop-down menu (refer to Section 5-2 and Section 5-3) are used to upload the
configuration and communicate with the FenwalNET 8000-ML Control Unit.
Figure 5-1. Tools Drop-Down Menu
Most of the utilities in the Tools drop-down menu can also be accessed via the main or side toolbars.
Figure 5-2 identifies the icons in the main toolbar.
Print File
Save File
Open File
New File
Compare Configuration
Verify Configuration
Receive Network Node Map
Send Configuration
Clear Event Log
Receive Configuration
Receive Event Log
Online
Figure 5-2. FenwalNET 8000-ML Configuration Software Main Toolbar
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Communications to the Control Unit
5-2
HARDWARE CONNECTIONS
Use either a laptop or desktop computer to upload the applications program to the FenwalNET 8000ML Control Unit. The computer must have a USB or RS-232 communications port:
•
Use a standard USB communications cable to connect to the FenwalNET 8000-ML Control Unit
via the computer's USB port.
•
Set the serial-port baud rate to 38400, and use communications cable P/N 74-100016-003 to
communicate with the FenwalNET 8000-ML Control Unit via the computer's serial port.
Note: See Section 5-3.2for full Communications Setup information.
Figure 5-3 illustrates a typical control unit-to-laptop configuration.
To USB printer
(optional)
J11
J6
To serial printer
(optional)
RS232 A
RS232 B
Printer
Main Controller Board
Standard USB Communications Cable
RS-232 Serial Communications Cable
To laptop USB port
To laptop serial port
Laptop Computer
Figure 5-3. Hardware Connection from FenwalNET 8000-ML Control Unit to Laptop Computer
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Communications to the Control Unit
5-3
COMMUNICATION UTILITIES
This section describes the various communication operations available in the Tools drop-down
menu. Each one is listed in Table 5-1 with its descriptive info location in the manual.
Table 5-1. Locations of Communications Utilities Descriptions in Manual
Communication Utility
5-3.1
Description Location
Communications Setup
Section 5-3.2
Send Configuration
Section 5-3.3
Receive Configuration
Section 5-3.4
On-Line
Section 5-3.5
Get Sensitivity Levels
Section 5-3.6
Event Log
Section 5-3.7
Receive Test Log
Section 5-3.8
Receive Walk Test Log
Section 5-3.9
Receive Network Node Map
Section 5-3.10
Verify
Section 5-3.11
Compare
Section 5-3.12
Selecting Node and Entering Password
When communicating with the panel, a password is required. The options presented for entering a
password depend on whether accessing a non-networked panel or a networked system with multiple
nodes. A non-networked panel only requires a password. A networked system requires choosing the
node and entering the password.
For a non-networked panel, the Enter Password screen is similar to Figure 5-4. Enter the password
and press OK.
Figure 5-4. Non-Networked Panel Enter Password Screen
For a networked panel, the Choose Node and Enter Password screen is similar to Figure 5-5. Choose
either the Local Node connected to the PC or select Network Node and pick the specific node. Next,
enter the password and press OK.
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Communications to the Control Unit
Figure 5-5. Networked Panel Choose Node and Enter Password Screen
5-3.2
Communications Setup
Select Tools>Communication Setup from the main screen to select the communication port
and define options. Do this to set up the computer to transfer data to the FenwalNET 8000-ML
Control Unit. Alternatively, you may select the Communication Setup Icon (
).
In response, the communication settings screen is displayed (see Figure 5-6 and Figure 5-7).
Figure 5-6. USB Communication Setting Screen
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Figure 5-7. RS232 Communication Setting Screen
5-3.3
Sending a Configuration
Select Tools>Send Configuration to send one particular configuration (created via the methodology
described in Chapters 2 through 4) to a FenwalNET 8000-ML Control Unit. The FenwalNET 8000ML Control Unit then assumes the responsibility of monitoring the SLC and other peripheral devices
that have been specified in the configuration file, and carries out the instructions that are encoded in
the EOC statements. Alternatively, you may select the Send Configuration Icon (
).
5-3.3.1
SELECTING A FILE TO SEND
If only one configuration file is open, the software assumes that this is the configuration to be sent
to the FenwalNET 8000-ML control panel. If more than one configuration file is open, the Select
Configuration dialog box (see Figure 5-8) is displayed when Tools>Send Configuration is selected.
The appropriate configuration file must be selected in this screen before proceeding.
Note: A configuration file must be open before the process can proceed.
Figure 5-8. Select A Configuration Screen
With the desired configuration file selected, the FenwalNET 8000-ML Configuration Software will
attempt to send the configuration to the USB or RS-232 connected panel.
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5-3.3.2
SENDING A CONFIGURATION
To send a configuration after specify which configuration to send:
Note: When sending a configuration to a remote networked node, the time to complete the
operation is considerably longer than sending to the local control node. When a
networked node is executing a local upload of the configuration, the node does not
communicate on the network.
1.
Select the node if applicable and enter the password. For details on choosing the node and
entering the password, refer to Section 5-3.1. Refer to the FenwalNET 8000-ML Installation,
Operation and Maintenance Manual, P/N 06-237041-001, for an explanation on setting
passwords.
2. Select <OK>. In response, a status bar showing the progression of the configuration upload to
the control unit is displayed (see Figure 5-9). After the upload is complete, the Send
Configuration Complete screen appears (see Figure 5-10).
Figure 5-9. Send Configuration Progress Screen
Figure 5-10. Send Configuration Complete Screen
After sending the configuration to the control unit, the control unit will restart, in order to begin using
the new settings. The USB cable should be disconnected upon completion of an upload to the control
unit.
5-3.4
Receive a Configuration
Select Tools>Receive Configuration to retrieve the configuration from a FenwalNET 8000-ML
Control Unit for review, analysis and/or modification as necessary. Alternatively, select the Receive
Configuration Icon (
). In response, the prompt shown in Figure 5-9 is displayed.
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5-3.4.1
SELECTING THE FILE TO RECEIVE
The process of receiving a configuration is similar to sending one. You must have at least one
configuration open when receiving a configuration. If more than one configuration is open when
Receive Configuration is selected, a prompt appears requesting a file in which to store the
downloaded configuration data (see Figure 5-11).
Note: A configuration file must be open before the process can proceed.
Figure 5-11. Select A Configuration Screen
With the configuration file selected, the FenwalNET 8000-ML Configuration Software will attempt to
receive the configuration of the selected panel.
5-3.4.2
RECEIVING A CONFIGURATION
To receive a configuration after specify which configuration to receive:
Note: When receiving a configuration to a remote networked node, the time to complete the
operation is considerably longer than receiving the local control node configuration.
When a networked node is executing a download of the configuration, the node does not
communicate on the network.
1.
Select the node if applicable and enter the password. For details on choosing the node and
entering the password, refer to Section 5-3.1. Refer to the FenwalNET 8000-ML Installation,
Operation and Maintenance Manual, P/N 06-237041-001, for an explanation on setting
passwords.
2.
Select <OK>. In response, a status bar showing the progression of the configuration download
(see Figure 5-12). After the download has finished, a notification (see Figure 5-13).
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Communications to the Control Unit
Figure 5-12. Receive Configuration Progress
Figure 5-13. Receive Configuration Complete
5-3.5
Online
Select Tools>Online to connect the FenwalNET 8000-ML Configuration Software to a control unit
via a terminal-emulation mode. This allows the software to run the control unit as if it were being
accessed via its front panel keypad/display. To enter terminal emulation mode:
1. Select the Online Icon (
).
2. Select the node if applicable and enter the password. For details on choosing the node and
entering the password, refer to Section 5-3.1. Refer to the FenwalNET 8000-ML Installation,
Operation and Maintenance Manual, P/N 06-237041-001, for an explanation on setting
passwords.
3.
March 2012
Select <OK>. The Online window displays (see Figure 5-14).
5-8
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Figure 5-14. Online Terminal-Emulation Mode
Refer to the FenwalNET 8000-ML Installation, Operation and Maintenance Manual
(P/N 06-237041-001) for a complete explanation of display messages and for guidance in navigating
through the control unit system menus.
5-3.6
Get Sensitivity Levels
Select Tools>Get Sensitivity Levels to retrieve the current readings of photoelectric, ionization,
thermal, and other types of detectors from the control unit. The results are populated in the
Sensitivity Levels dialog box.
5-3.6.1
RETRIEVE SENSITIVITY LEVELS
1.
Select Tools>Get Sensitivity Levels.
2.
Select the node if applicable and enter the password. For details on choosing the node and
entering the password, refer to Section 5-3.1.
3.
Click <OK>. The Select A SLC Module screen appears (see Figure 5-15).
Figure 5-15. Select A SLC Module Screen
4. Enter the password and click <OK>.
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5. Select the desired SLC module, and click <OK>. The Range screen appears (see Figure 5-16).
Figure 5-16. Range Screen
6.
Enter the range of sensitivity desired.
7.
Select <OK>. The following Sensitivity Levels screen appears.
Figure 5-17. Retrieving Sensitivity Levels
Within the Sensitivity Levels Print menu, there are two menu options: Save As and Print.
5-3.7
–
Select Save As to save the test log as a .txt file.
–
Select Print to send the test log to a printer.
Event Log
Select Tools>Event Log to transfer the contents of the log of system events to a text file. There are
three options: Clear, Receive and Open Log File.
5-3.7.1
CLEARING THE EVENT LOG
1.
March 2012
Select Tools>Event Log>Clear to remove all currently-recorded events from the system event
log. Alternatively, you may select the Clear Event Log Icon (
). In response, a dialog box asks
to continue or not (see Figure 5-18).
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Figure 5-18. Event Log Query
2. Click <Yes> to continue.
3. Select the node if applicable and enter the password. For details on choosing the node and
entering the password, refer to Section 5-3.1.
4. Click <OK>.
The progression of the event log clearance is displayed (see Figure 5-19).
Figure 5-19. Clear Event Log Progression
After the event log has been cleared, a notification is displayed (see Figure 5-20).
Figure 5-20. Clear Event Log Complete
Note: If the control unit is in alarm, trouble or supervisory condition, clearing the event log is
aborted and a notification (see Figure 5-21) is displayed.
Figure 5-21. Clear Event Log Abort
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5-3.7.2
RECEIVING AN EVENT LOG
1.
Select Tools>Event Log>Receive to copy the entire contents of the system event log to a
text file or copy a range of system events within the log based on occurrence dates.
Alternatively, you may select the Receive Event Log Icon (
). In response, the prompt
shown in Figure 5-22 is displayed.
Figure 5-22. Event Log Data Range
2. Select either the All or Range radio button. If Range is selected, enter the range of dates to receive.
Select <OK>.
3. Select the node if applicable and enter the password. For details on choosing the node and
entering the password, refer to Section 5-3.1.
4. Select <OK> to download the event log from that node. In response, the progression of the
download (Figure 5-23) is displayed.
Figure 5-23. Receive Event Log Progression
When it is complete, the Event Log Retrieved Confirmation Screen displays (see Figure 5-24).
Figure 5-24. Event Log Received Confirmation
5.
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Select <OK>. In response, the event log (see Figure 5-25) is displayed.
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5-3.7.3
THE EVENT LOG
Within the Event Log Screen, there are four menu options: Open, Save, Save As Text, Print, and
Close.
•
Select Open to open an existing saved event log.
Note: Because the current event log will be overwritten, do not select Open to retrieve an existing
event log before saving or printing the current retrieved event log.
•
Select Save to save the event log as a .log file.
•
Select Save As Text to save the event log as a .txt file.
•
Select Print to send the event log to a printer.
•
Select Close to close the Event Log screen.
Figure 5-25. Event Log Screen
5-3.7.4
VIEW EVENT LOG
Select Tools>Event Log>Open Log File to view a previously-downloaded event log offline. Enter the name
of the log file and select <OK>. All event log options in the Event Log Screen are available when viewing
event logs offline.
5-3.8
Receive Test Log
Select Tools>Receive Test Log to copy the contents of the most recent log of initiating device
test events to a text file.
5-3.8.1
RECEIVING A TEST LOG
1.
Select Tools>Receive Test Log.
2.
Select the node if applicable and enter the password. For details on choosing the node and
entering the password, refer to Section 5-3.1.
3.
Select <OK>. In response, the progression of the test log download (see Figure 5-26) is
displayed.
P/N 06-237042-001
5-13
March 2012
Communications to the Control Unit
Figure 5-26. Receive Test Log Progress
4. When the download is complete, the test log is displayed (see Figure 5-27).
Figure 5-27. Test Log Screen
5. Within the Test Log Screen, there are two menu options: Save As Text, Print, and Close.
March 2012
•
Select Save As Text to save the test log as a .txt file.
•
Select Print to send the test log to a printer.
•
Select Close to close the Test Log screen.
5-14
P/N 06-237042-001
Communications to the Control Unit
5-3.9
Receive Walk Test Log
Select Tools>Receive Walk Test Log to copy the contents of the log of walk-test events created via
the "Walk-Test" procedure in the Test Menu to a text file.
5-3.9.1
RECEIVING A WALK TEST LOG
1.
Select Tools>Receive Walk Test Log.
2.
Select the node if applicable and enter the password. For details on choosing the node and
entering the password, refer to Section 5-3.1.
3. Select <OK>. In response, the progression of the test log download is displayed (see
Figure 5-28).
Figure 5-28. Receive Walk Test Log Progress
4. When the download is complete, the test log is displayed (see Figure 5-29).
Figure 5-29. Walk Test Log
5. Within the Walk Test Log Screen, there are three menu options: Save As Text, Print, and Close.
•
Select Save As Text to save the test log as a .txt file.
•
Select Print to send the test log to a printer.
•
Select Close to close the Walk Test Log screen.
P/N 06-237042-001
5-15
March 2012
Communications to the Control Unit
5-3.10
Receive Network Node Map
Select Tools> Receive Network Node Map to view a listing of nodes networked with the local panel.
Each node occupies a unique address.
Note: When receiving a network node map, the software does not actively communicate to each node
on the map. It is possible for a listed node to no longer be connected or communicating.
Nodes must be added or removed manually from the panels.
Figure 5-30. Network Node Map
5-3.11
Verify
Select Tools>Verify to check the syntax of EOC code and verify that the device and circuit addresses
are used properly. Alternatively, select the Verify Icon from the toolbar (
). In response, the
verification summary (see Figure 5-31) is displayed.
Figure 5-31. Verification Summary
March 2012
5-16
P/N 06-237042-001
Communications to the Control Unit
Remove errors and warnings where possible. For assistance in removing as many as possible, contact
Fenwal Technical Support.
Note: The FenwalNET 8000-ML Configuration Software will not allow the configuration file to be
saved if it contains EOC verification errors, although warnings are permissible.
5-3.12
Compare
Select Tools>Compare to compare two different configuration files. Note that both files must
be open to compare them. Alternatively, select the Compare Icon (
) from the toolbar. An
example of the comparison results is shown in Figure 5-32.
Figure 5-32. Configuration Compare Results Screen
P/N 06-237042-001
5-17
March 2012
Communications to the Control Unit
THIS PAGE INTENTIONALLY LEFT BLANK.
March 2012
5-18
P/N 06-237042-001
System Example
APPENDIX A
SYSTEM EXAMPLE
A-1
INTRODUCTION
This appendix is intended to provide an example of a typical system and sequence of operation.
Control-Unit Outputs
NAC 1
NAC 2
Combo 1
Combo 2
Release 1
Release 2
Relay 1
Relay 2
Relay 3
Trouble Relay
Activate / De-Activate
Trouble LED
Activate / De-Activate LowAir LED
Power Shutoff
A
A
A
A
A
D
D
D
D
A
A
A
A
A
A
D
D
A
A
A
A
A
A
A
A
D
D
D
D
A
A
D
D
A
A
A
A
A
A
A
A
D
D
D
D
A
A
A
A
A
A
A
A
A
A
A
A
A
A
Z-1
Z-1
Z-2
Z-2
Z-1
Z-1
Z-2
Z-2
Z-1
Z-2
Z-1
Z-2
SLC Outputs
AO
X
ATM Outputs
Output No. 1
Output No. 2
Output No. 3
Output No. 4
Output No. 5
Output No. 6
Output No. 7
Output No. 8
Output No. 9
Output No. 10
Output No. 11
Output No. 12
Output No. 13
A = Activate Output
D = De-Activate Output
Z = Zone Defined Below
X = Output Activated
HVAC Shutdown
Facility Equipment
Interlocks
Activate / De-Activate
Waterflow LED
Activate / De-Activate
Tamper LED
Activate / De-Activate LowPressure LED
Activate / De-Activate
Release LED
Activate / De-Activate
Abort-Station LED
Activate / De-Activate
Smoke-Detector LED
Open Pre-Action-Sprinkler
Valve
A
Interrupt Impending Waterless System Discharge
A
A
Activate Waterless
Extinguishing System
Activate / De-Activate
Strobes
Activate / De-Activate
Horns @ 120 BPM
Activate / De-Activate
Temporal-Coded Horns
Waterflow Switch
Head-End Room (Zone 1)
Power Room (Zone 2)
Sprinkler Tamper Switch
Head-End Room (Zone 1)
Power Room (Zone 2)
One Area Smoke Detector
Head-End Room (Zone 1)
Power Room (Zone 2)
Two Area Smoke Detectors Alarm
(Immediate Response)
Head-End Room (Zone 1)
Power Room (Zone 2)
Two Area Smoke Detectors (30Sec. Delayed Response)
Head-End Room (Zone 1)
Power Room (Zone 2)
Manual Station (Immediate
Response)
Head-End Room (Zone 1)
Power Room (Zone 2)
Abort Station
Head-End Room (Zone 1)
Power Room (Zone 2)
Auxiliary Supervisory
Low FM-200 Pressure Sw.
Head-End Room (Zone 1)
Power Room (Zone 2)
Low Air (Pre-Action Sys)
Trouble
Any Condition
Activate / De-Activate
Horns @ 60 BPM
Room-of-Origin
Alarms/Actions
Sequence of Operation
X
Z-1
Z-1
Z-1
Z-1
Z-1
Z-1
Z-2
Z-2
Z-2
Z-2
Z-2
Z-2
X
Note: Central Station reporting is handled by the DACT or City Tie modules.
Figure A-1. Example of Sequence of Operation
P/N 06-237042-001
A-1
March 2012
System Example
THIS PAGE INTENTIONALLY LEFT BLANK.
March 2012
A-2
P/N 06-237042-001
System Operations
System Outline
Signaling-Line-Circuit Configuration
Application
N
A ddr.
Initiating and Control Points
Owne r Location
Type
App'n
Pre-Alm
Pre-Al m
Alarm
Alarm
(Leve l 1)
(Level 2)
(Leve l 1)
(Leve l 2)
Verify
PA S
D /N
L/N- L
Associated Releasing-Zone
Alarm / Supervisory / Trouble Outputs
I TLCO
CTLCO
(sec/min)
(sec/min)
Drill
Silence
Walk
Seq.
Fa n
G roup
Pt . Sp.
Gr. Sp.
Gen.
Gen.
De-Ac t
R e-S tart
Alm/Sup/Tr
Outputs
Outputs
Tbl.
Supv.
Iden.
Release
Rel. Zn.
Rel. Zn.
Zone
Pre-Al m
P re-Rel
Counting
C rossed
Execution Statements
Iden.
Grou p
Rel. Zn.
I den.
Release
Concurrent
Rel . Z n.
$ Head-End-Room Pre-Alarm
L1:1#3=SG1,AM1:1,C1
L1:1#3=1.5=AL1:4#6
L1:4#6=SG1,AM1:1,C2
---
1
Head-End-Room Photo
Photo
Open-Area
-----
1.5
2.0
3.0
No
No
No
L
-----
-----
-----
-----
-----
-----
-----
AI-1A
-----
ATM-1
-----
-----
C1
1
Yes
Ye s
No
AI-1B
-----
Ye s
-----
Z-1 P re-Action
L1:4#6=3.0=AL1:1#3
$ Power-Room Pre-Alarm
---
2
Head-End-Room Photo
Photo
Open-Area
-----
1.5
2.0
3.0
No
No
No
L
-----
-----
-----
-----
-----
-----
-----
AI-1A
-----
ATM-1
-----
-----
C1
1
Yes
Ye s
No
AI-1B
-----
Ye s
-----
Z-1 P re-Action
---
3
Head-End-Room Photo
Photo
Open-Area
-----
1.5
2.0
3.0
No
No
No
L
-----
-----
-----
-----
-----
-----
-----
AI-1A
-----
ATM-1
-----
-----
C1
1
Yes
Ye s
No
AI-1B
-----
Ye s
-----
Z-1 P re-Action
L1:14#15=SG3,AM1:7,C3
---
4
Head-End-Room Ion
Ion
Open-Area
-----
0.8
1.0
1.5
No
No
No
L
-----
-----
-----
-----
-----
-----
-----
AI-1B
-----
ATM-1
-----
-----
C2
1
Yes
Ye s
No
AI-1A
-----
Ye s
-----
Z-1 P re-Action
L1:14#15=1.5=AL1:16#17
---
5
Head-End-Room Ion
Ion
Open-Area
-----
0.8
1.0
1.5
No
No
No
L
-----
-----
-----
-----
-----
-----
-----
AI-1B
-----
ATM-1
-----
-----
C2
1
Yes
Ye s
No
AI-1A
-----
Ye s
-----
Z-1 P re-Action
L1:16#17=SG3,AM1:7,C4
---
6
Head-End-Room Ion
Ion
Open-Area
-----
0.8
1.0
1.5
No
No
No
L
-----
-----
-----
-----
-----
-----
-----
AI-1B
-----
ATM-1
-----
-----
C2
1
Yes
Ye s
No
AI-1A
-----
Ye s
-----
Z-1 P re-Action
L1:16#17=3.0=AL1:14#15
---
7
Head-End-Room Man Rel
AI
Man. Rel
-----
-----
-----
-----
-----
-----
-----
L
-----
-----
-----
-----
-----
-----
-----
-----
-----
-----
-----
-----
-----
1
No
No
-----
-----
-----
Ye s
-----
Z-1 P re-Action
$ Head-End-Room Waterflow
---
8
Head-End-Room Man Rel
AI
Man. Rel
-----
-----
-----
-----
-----
-----
-----
L
-----
-----
-----
-----
-----
-----
-----
-----
-----
-----
-----
-----
-----
1
No
No
-----
-----
-----
Ye s
-----
Z-1 P re-Action
---
9
Head-End-Room Abort
AI
Abort/UL/30 s ec
-----
-----
-----
-----
-----
-----
-----
N-L
-----
-----
-----
-----
-----
-----
-----
-----
-----
ATM-2
-----
-----
-----
1
-----
-----
-----
-----
-----
-----
-----
-----
---
10
Head-End-Room Abort
AI
Abort/UL/30 s ec
-----
-----
-----
-----
-----
-----
-----
N-L
-----
-----
-----
-----
-----
-----
-----
-----
-----
ATM-2
-----
-----
-----
1
-----
-----
-----
-----
-----
-----
-----
-----
L1:20=SG4,AM1:12,RY3
---
11
Head-End-Room Waterflow
AI
Wa terflow
-----
-----
-----
-----
-----
-----
-----
L
-----
-----
-----
-----
-----
-----
-----
-----
ATM- 6
-----
-----
-----
-----
1
-----
-----
-----
-----
-----
-----
-----
-----
$ Head-End-Room Tamper
L1:11=SG2,AM1:6,RY3
$ Power-Room Waterflow
---
12
Head-End-Room Tamper
AI
Supervisory
-----
-----
-----
-----
-----
-----
-----
N-L
-----
-----
-----
-----
-----
-----
-----
-----
ATM-5
-----
-----
Y
-----
1
-----
-----
-----
-----
-----
-----
-----
-----
L1:12=AM1:5,L1:25
---
13
Head-End-Room Low Press
AI
Tr ouble
-----
-----
-----
-----
-----
-----
-----
N-L
-----
-----
-----
-----
-----
-----
-----
-----
ATM-4
-----
Y
-----
-----
1
-----
-----
-----
-----
-----
-----
-----
-----
$ Power-Room Tamper
---
14
Power-Room Photo
Photo
Open-Area
-----
1.5
2.0
3.0
No
No
No
L
-----
-----
-----
-----
-----
-----
-----
AI-2A
-----
ATM-7
-----
-----
I3
2
Yes
Ye s
No
AI-2B
-----
Ye s
-----
Z-2 P re-Action
L1:21=AM1:11,L1:25
---
15
Power-Room Photo
Photo
Open-Area
-----
1.5
2.0
3.0
No
No
No
L
-----
-----
-----
-----
-----
-----
-----
AI-2A
-----
ATM-7
-----
-----
I3
2
Yes
Ye s
No
AI-2B
-----
Ye s
-----
Z-2 P re-Action
$ Head-End-Room Low Pressure
L1:13=AM1:4
---
16
Power-Room Ion
Ion
Open-Area
-----
0.8
1.0
1.5
No
No
No
L
-----
-----
-----
-----
-----
-----
-----
AI-2B
-----
ATM-7
-----
-----
I4
2
Yes
Ye s
No
AI-2A
-----
Ye s
-----
Z-2 P re-Action
---
17
Power-Room Ion
Ion
Open-Area
-----
0.8
1.0
1.5
No
No
No
L
-----
-----
-----
-----
-----
-----
-----
AI-2B
-----
ATM-7
-----
-----
I4
2
Yes
Ye s
No
AI-2A
-----
Ye s
-----
Z-2 P re-Action
$ Power-Room Low Pressure
---
18
Power-Room Man Rel
AI
Man. Rel
-----
-----
-----
-----
-----
-----
-----
L
-----
-----
-----
-----
-----
-----
-----
-----
-----
-----
-----
-----
-----
2
No
No
-----
-----
-----
Ye s
-----
Z-2 P re-Action
L1:22=AM1:10
---
19
Power-Room Abort
AI
Abort/UL/30 s ec
-----
-----
-----
-----
-----
-----
-----
N-L
-----
-----
-----
-----
-----
-----
-----
-----
-----
ATM-8
-----
-----
-----
2
No
No
-----
-----
-----
-----
-----
-----
$ Pre-Action-System Low Air
---
20
Power-Room Waterflow
AI
Waterflow
-----
-----
-----
-----
-----
-----
-----
L
-----
-----
-----
-----
-----
-----
-----
-----
ATM-12
------
-----
-----
-----
2
-----
-----
-----
-----
-----
-----
-----
-----
L1:26=AM1:13
---
21
Power-Room Tamper
AI
Supervisory
-----
-----
-----
-----
-----
-----
-----
N-L
-----
-----
-----
-----
-----
-----
-----
-----
ATM- 11
-----
-----
Y
-----
2
-----
-----
-----
-----
-----
-----
-----
-----
$ Head-End-Room Pre-Release
---
22
Power-Room Low Press
AI
Tr ouble
-----
-----
-----
-----
-----
-----
-----
N-L
-----
-----
-----
-----
-----
-----
-----
-----
ATM-10
-----
Y
-----
-----
2
-----
-----
-----
-----
-----
-----
-----
-----
(C1*C2)+L1:7+L1:8=SG1/120,L1:23 $cross-zone or manual pull
---
23
HVAC Shutdown
AO
-----
-----
-----
-----
-----
-----
-----
-----
N-L
-----
-----
-----
-----
-----
-----
-----
-----
-----
-----
-----
-----
-----
1 a nd 2
-----
-----
Ye s
-----
-----
-----
-----
-----
$ Head-End-Room Release
---
24
Power Shutdown
AO
-----
-----
-----
-----
-----
-----
-----
-----
N-L
-----
-----
-----
-----
-----
-----
-----
-----
-----
-----
-----
-----
---- -
1 and 2
-----
-----
-----
-----
-----
Ye s
-----
-----
D(C1*C2,30,L1:9,L1:10)+L1:7+L1:8=NSG1,NAM1:1,AR1,SG2,L1:24,RY2,AM1:3
---
25
Pre-Action Low Air
AI
Trouble
-----
-----
-----
-----
-----
-----
-----
N-L
-----
-----
-----
-----
-----
-----
-----
-----
ATM-13
-----
Y
-----
-----
-----
-----
-----
-----
-----
-----
-----
-----
-----
L1:9+L1:10=AM1:2 $aborts
$ Power-Room Pre-Release
(C3*C4)+L1:18=SG3/120,L1:23 $cross-zone or manual pull
$ Power-Room Release
D(C3*C4,30,L1:19)+L1:18=NSG3,NAM1:7,AR2,SG4,L1:24,RY2,AM1:8
L1:19=AM1:8 $abort
P/N 06-237042-001
A-3 (Page A-4 blank)
March 2012
NEW YORK CITY ABORT SEQUENCE
APPENDIX B
NEW YORK CITY ABORT SEQUENCE
B-1
INTRODUCTION
The following EOC program example demonstrates a typical method of supporting the unique N.Y.C.
suppression system abort sequence. Use of this program negates the need for any external equipment
to control the notification appliances.
B-2
GENERAL DISCUSSION
This discussion is based on a typical single suppression zone, as illustrated in Figure B-1. The room
contains: six smoke detectors, one manual release station, one abort station, one power shutdown
and one HVAC shutdown.
B-2.1
B-2.2
Sequence of Operation
•
Any detector–Activate the bell.
•
Second smoke detector alarm–Turn off bell, turn on horn (pulsing), turn on strobe (steady),
begin (30 second) discharge delay, shut down power, shut down HVAC.
•
When timer counts down–Discharge agent, turn on strobes (steady) and horn/strobe (steady).
•
Abort Active–Turn off horn, turn off strobe, turn on bell and add 90 seconds to initial time
delay.
System Configuration
The configuration of the system depicted in Figure B-1 contains the following hardware with assigned
addresses:
•
Six Smoke Detectors (1 through 6)
•
One Abort Station (7)
•
One Manual Release Station (8)
•
One Bell (SG1)
•
One Horn Circuit (SG2)
•
Two Strobes on one circuit (SG3)
•
Two Release Devices on one circuit (AR1)
P/N 06-237042-001
B-1
March 2012
NEW YORK CITY ABORT SEQUENCE
B-2.3
Program for N.Y.C. Abort Sequence
Note: When using N.Y.C. Abort, all initiating devices must be set to the default of latching. NonLatching must not be used or improper operation of this sequence results.
$ ---------- EOC PROGRAM FOR NYC ABORT ---------$
$ SAMPLE PROGRAM FOLLOWS (SOME PARENTHESES ARE INCLUDED TO EASILY FOLLOW THE GENERIC
PROGRAM):
L1:1=I1
$ check Aborts
NC5*(L1:86)=C5,NSG1,L1:196
$ check manual release pulls; also set output(s), if any manual
releases
NC5*I1=C6,C1
$ start Aborting (any abort is active)
NC5*NI1=NC6,NC4
$ stop Aborting (all aborts are inactive)
NC5*(F2:L2:1#3)=C2,I2
$ first alarm
NC5*C2*NC6=SG1
$ signal first alarm, if not aborting
NC5*I2>1=C3
$ second alarm
C3*NC1=NSG1,SG2/60,SG3
$ signal second alarm (Pre-Release), if abort never happened
D(NC5*C3*NC1,30,L1:1)=C5,AR2
$ Release in 30 seconds, if abort never happens
NC5*C6=NSG1,NSG2,NSG3
$ stop signals, if presently aborting
NC5*C1*NC6*C2=SG1
$ Re-signal first alarm, if stopped aborting and at least in First
Alarm
D(NC5*C1*C3*NC6,90,L1:1)=C4
$ after 90 seconds,
C4=NSG1,SG2/60,SG3
$ then Re-signal second alarm (Pre-Release)
D(NC5*C1*C3*NC6,120,L1:1)=C5,AR2
$ Release in 120 seconds, if no more aborts go active
C5=AR2,SG3,SG2/C
$ signal that Release has happened
$ GENERIC PROGRAM FOLLOWS:
Fz:La:h#i+Fy:Lb:j#k=I1
$ check Aborts
NC5*(Fx:Lc:m#n+Fw:Ld:o#p)=C5,NSG1,Lg:l,L_:-
$ check Manual Release Pulls; also set Output(s), if any manual
releases
NC5*I1=C6,C1
$ start Aborting (any abort is active)
NC5*NI1=NC6,NC4
$ stop Aborting (all aborts are inactive)
NC5*(Fv:Le:q#r+Fu:Lf:s#t)=C2,I2
$ first alarm
NC5*C2*NC6=SG1
$ signal first alarm, if not aborting
NC5*I2>1=C3
$ second alarm
C3*NC1=NSG1,SG2/60,SG3
$ signal second alarm (Pre-Release), if abort never happened
D(NC5*C3*NC1,30,...)=C5,AR2
$ Release in 30 seconds, if abort never happens
NC5*C6=NSG1,NSG2,NSG3
$ stop signals, if presently aborting
NC5*C1*NC6*C2=SG1
$ Re-signal first alarm, if stopped aborting and at least in First
Alarm
D(NC5*C1*C3*NC6,90,...)=C4
$ after 90 seconds,
C4=NSG1,SG2/60,SG3
$ then Re-signal second alarm (Pre-Release)
D(NC5*C1*C3*NC6,120,...)=C5,AR2
$ Release in 120 seconds, if no more aborts go active
C5=AR2,SG3,SG2/C
$ signal that Release has happened
$
March 2012
B-2
P/N 06-237042-001
NEW YORK CITY ABORT SEQUENCE
$ THE ABOVE IS A TEMPLATE FOR THE DELAY (WITH "NEW YORK CITY" ABORTS, INCLUDING MULTIPLE ABORTS)
$
$ MUST NOT USE NON-LATCHING ALARMS (THIS WARNING REMAINS THE SAME)
$
$
$
$
$
$
$
$
$
$
$
$
$
Alarm #’s are: 'q' through 'r' on Loop 'e' on Node 'v', and 's' through 't' on Loop 'f' on Node 'u'
Abort #’s are: 'h' through 'i' on Loop 'a' on Node 'z', and 'j' through 'k' on Loop 'b' on Node 'y'
Manual Release #’s are: 'm' through 'n' on Loop 'c' on Node 'x', and 'o' through 'p' on Loop 'd' on Node 'w'
Output #’s associated with Manual Release are: 'l'(ell) on Loop 'g', & '-' on Loop '_'
C1 goes True only once, due to the first time that any abort goes active; Stops 30 second countdown
C2 goes True only once, due to the first alarm; Signals the first alarm
C3 goes True only once, due to the second alarm; Signals the second alarm
C5 goes True only once, due to the release; Prevents any further EOC activity
C4 goes True 90 seconds after all aborts are inactive; and goes False when all aborts go inactive
DO NOT COMBINE LINES; THIS PROGRAM IS ALREADY OPTIMIZED
$ ---------- EOC PROGRAM FOR REMOTE NODE NYC ABORT ---------$ SAMPLE PROGRAM FOLLOWS FOR A REMOTE NODE (SOME PARENTHESES ARE INCLUDED TO EASILY FOLLOW
THE GENERIC PROGRAM):
F1:L1:1+(T(F1:L1:1)*F1:C6)=I1
$ check Aborts (requires at least the 2 EOC lines in the Node
with Aborts)
NC5*(L1:86)=C5,NSG1,L1:196
$ check manual release pulls; also set output(s), if any manual
releases
NC5*I1=C6,C1
$ start Aborting (any abort is active)
NC5*NI1=NC6,NC4
$ stop Aborting (all aborts are inactive)
NC5*(F2:L2:1#3)=C2,I2
$ first alarm
NC5*C2*NC6=SG1
$ signal first alarm, if not aborting
NC5*I2>1=C3
$ second alarm
C3*NC1=NSG1,SG2/60,SG3
$ signal second alarm (Pre-Release), if abort never happened
yet
D(NC5*C3*NC1,30,L1:1)=C5,AR2
$ Release in 30 seconds, if abort never happens
NC5*C6=NSG1,NSG2,NSG3
$ stop signals, if presently aborting
NC5*C1*NC6*C2=SG1
$ Re-signal first alarm, if stopped aborting and at least in First
Alarm
D(NC5*C1*C3*NC6,90,L1:1)=C4
$ after 90 seconds,
C4=NSG1,SG2/60,SG3
$ then Re-signal second alarm (Pre-Release)
D(NC5*C1*C3*NC6,120,L1:1)=C5,AR2
$ Release in 120 seconds, if no more aborts go active
C5=AR2,SG3,SG2/C
$ signal that Release has happened
P/N 06-237042-001
B-3
March 2012
NEW YORK CITY ABORT SEQUENCE
AGENT STORAGE
CONTAINER
AR1
STROBE
Address
SG3
ABORT STATION
Address
7
INTELLIGENT
SMOKE
DETECTORS
MANUAL RELEASE
STATION
Address
8
Address
1
POWER
SHUTDOWN
Address
10
Address
2
HVAC CONTROL
Address
9
Address
3
BELL
Address
SG1
FenwalNET 8000-ML
CONTROL UNIT
THIS PAGE INTENTIONALLY
Address LEFT BLANK.
4
HORN
Address
SG2
AGENT STORAGE
CONTAINER
AR1
Address
5
STROBE
Address
SG3
Address
6
Figure B-1. New York City Installation
March 2012
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Firmware Upgrade Instructions
APPENDIX C
FIRMWARE UPGRADE INSTRUCTIONS
C-1
BEFORE YOU BEGIN
Updates to the firmware of the FenwalNET 8000-MLTM control unit and expansion modules may be
required. An upgrade utility is provided to ease the update process. This utility is a PC-based
application included with the configuration software capable of loading firmware to all applicable
components on the FenwalNET 8000-ML control unit and backplane.
The following components can have their firmware upgraded using this utility:
C-2
•
CityTie Card
•
Communications Process Controller
•
DACT Card
•
Hand-Held Programmer
•
LED Annunciator Module
•
Main Controller Board
•
Network Interface Card
•
Power Management Unit Board
•
Relay Card
•
R-NAC Card
•
SLC Card
•
User Interface (Keypad//Display) Board
PREREQUISITES
The Upgrade Utility requires the NET 4.0 Client be installed on the user's system. If the .NET 4.0
Client is not already installed, run the file:
dotNetFx40_Client_setup.exe
This file is distributed with the Upgrade Utility and can also be downloaded from Microsoft.
C-3
SOFTWARE INSTALLATION
The Upgrade Utility is distributed as a .zip file, UpgradeUtility<rev>.zip.
To install the utility, follow these steps:
1. Unzip the file UpgradeUtility<rev>.zip.
2. Double click to run UpgradeUtility.msi and follow the instructions present on screen. The utility
should automatically remove old components when installing a new version. Should this be a
problem, however, manually remove the application via the Windows® Control Panel>Add or
Remove Programs and run the utility again.
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March 2012
Firmware Upgrade Instructions
C-4
PHYSICAL CONNECTIONS
Depending on the module being upgraded, different physical connections are required:
C-5
• MCB:
Connect a USB cable between the PC and the USB port (upper right corner of
main board).
• CPC:
Use an RJ45 connector plugged into J3 (also labeled “RS232B”), located on the
right side of the Main Controller Board to the PC via a serial connection. If the
PC does not have a serial connection, use a USB to Serial converter.
• All others:
Use a 4 pin TTL FSP to serial cable. If the PC does not have a serial connection,
use a USB to Serial converter.
LAUNCHING THE UPGRADE UTILITY
To open the utility, click: Start>All Programs>United Technologies Corporation>Upgrade Utility
C-6
MENU OPTIONS
The Main Menu of the Upgrade Utility is shown below (Figure C-1):
Figure C-1. Upgrade Utility Main Menu
The Upgrade Utility includes the following menu options:
C-7
•
File: Contains the Exit option used to exit the utility.
•
Settings: Contains the COM Ports option used to specify the COM port and the Allow Revert
option, used to enable reverting to an older firmware version.
•
Help: Contains the About option, used to view the version information for the Upgrade Utility.
SPECIFYING LANGUAGE
Use the language dropdown menu, located in the right upper corner, to specify the language to be
used by the utility.
March 2012
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P/N 06-237042-001
Firmware Upgrade Instructions
C-8
UPDATING THE FIRMWARE
The steps below outline the process to follow to update firmware:
1. Specify the COM port.
2. Login to the panel.
3. Specify the binary file used for the upgrade and begin the upgrade.
C-8.1
Specifying the COM port
From the menu bar, Click Settings>COM Port. The Select Port window opens: (Figure C-2)
Figure C-2. Select Port Window
•
The Upgrade Utility indicates which COM port is connected to the MCB.
•
To determine which COM port to use for modules other than MCB, use the Device Manager.
Click <OK> after specifying the COM port.
C-8.2
Logging in to the panel
1. Click Login.
The Field Upgrade Login Authorization screen is displayed: (Figure C-3)
Figure C-3. Login Authorization Screen
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March 2012
Firmware Upgrade Instructions
2. Select a module from the Select Programmer dropdown list.
Note: The Upgrade Utility is customized for end users. As such, only certain modules may
be selectable. Additionally, the utility does not communicate with the panel at this point
so does not know if a module is present in the Control Panel. Selecting a module that
is not present, generates an error when upgrading.
3. Enter the password: 672431.
4. Click <OK>.
The Upgrade button is now enabled.
C-8.3
Upgrading the firmware
After selecting the COM port and logging into the panel, use the following procedure to upgrade the
firmware:
1. Click Upgrade.
The screen title displays "<module selected> Upgrade" . See Figure C-4 for an example.
Figure C-4. Module Upgrade Screen
2. Click Select File to Load.
The Upgrade Utility selects the latest binary file to load.
Note: To install an older binary, use the Allow Revert option under the Settings menu.
3. Click Start Upgrade and follow any instructions that appear.
4. When done, click <OK>.
After a successful upgrade, the Upgrade Utility displays a success message similar to Figure C-5.
Note: In the case of upgrading the MCB, if the panel being upgraded has firmware version
1.0.9 or earlier already loaded on the panel, then the user MUST select the “Manual
Power Cycle...” checkbox. Selecting Start Upgrade will then guide the user through
the steps which follow.
March 2012
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P/N 06-237042-001
Firmware Upgrade Instructions
Figure C-5. Success Screen
C-9
C-10
UPGRADING ADDITIONAL DEVICES
•
To upgrade another device of the same type, connect to that device and click Start Upgrade.
•
To upgrade a different type of device, click the Login button and select the appropriate device
programmer.
REVERTING TO A PREVIOUS BINARY FILE
To revert to an earlier binary file, click Settings>Allow Revert and continue as instructed in
Section C-8.3.
After clicking Select File to Load button, the Upgrade Utility presents a file open dialog box enabling
selection of the binary file to load. Select the file and continue on as instructed.
Revert Mode automatically cancels after each upload.
P/N 06-237042-001
C-5
March 2012
Firmware Upgrade Instructions
C-11
FIRMWARE UPGRADE UTILITY TROUBLESHOOTING GUIDE
Below are listed some reported problems with their suggested workarounds.
PROBLEM: Message appears indicating files are missing when installing.
Occurs after double clicking UpgradeUtility.msi from within WinZip program.
SOLUTION:
After opening the .zip file from the FTP site, the files MUST be extracted to a local directory before
installing. The install will NOT work when double clicking UpgradeUtility.msi from WinZip.
WinZip creates temporary files that InstallShield may not recognize.
Do the following to EXTRACT files from WinZip:
1.
After downloading the zip file, click “Extract” and select any location on the local PC to
store the file.
2.
When the files have finished extracting, a new window will open to the folder with the files.
3.
Inside this folder, double click on UpgradeUtility.msi.
PROBLEM: Upgrade Utility asks to “Modify, Remove or Repair Program”.
SOLUTION: If this happens, select Remove. Once completed, double click “UpgradeUtility.msi”
to re-start installation.
March 2012
C-6
P/N 06-237042-001
FenwalNET 8000-ML is a trademark of Kidde-Fenwal, Inc.
All other trademarks are the property of their respective owners.
R
Protection Systems
These instructions do not purport to cover all the details or variations in the equipment described,
nor do they provide for every possible contingency to be met in connection with installation, operation
and maintenance. All specifications are subject to change without notice. Should further information
be desired or should particular questions arise which are not covered sufficiently for the purchaser’s
purposes, the matter should be referred to KIDDE-FENWAL INC., Ashland, Masssachusetts, 01721.
P/N 06-237042-001 Rev. BB
Copyright ©2012 Kidde-Fenwal, Inc.
All Rights Reserved.