MODEL
IFP-2000/
RPS-2000
Analog/Addressable
Fire System
Installation and
Operations Manual
Part Number 151430 Rev A
Installation Procedure
Adherence to the following will aid in problem-free installation with long-term reliability:
Installation Precautions - Adherence to the following will aid in problem-free installation
with long-term reliability: WARNING - Several different sources of power can be connected
to the fire alarm control panel. Disconnect all sources of power before servicing. Control unit
and associated equipment may be damaged by removing and/or inserting cards, modules, or
interconnecting cables while the unit is energized. Do not attempt to install, service, or operate
this unit until manuals are read and understood. CAUTION - System Re-acceptance T est after
Software Changes: To ensure proper system operation, this product must be tested in
accordance with NFPA 72 after any programming operation or change in site-specific
software. Re-acceptance testing is required after any change, addition or deletion of system
components, or after any modification, repair or adjustment to system hardware or wiring. All
components, circuits, system operations, or software functions 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. This
system meets NFP A requirements for operation wi thin the range of 0°C-49°C (32°F-120°F) or
humidity within the range of 10%-93% at 30°C (86°F) noncondensing. However, the useful
life of the system's standby batteries and the electronic components may be adversely affected
by extreme temperature ranges and humidity. Therefore, it is recommended that this system
and its peripherals be installed in an environment with a normal room temperature of 15-27º
C/60-80º F. V erify that wir e sizes are adequate for all initiating and indicating device loops.
Most devices cannot tolerate more than a 10% I.R. drop from the specified device voltage.
Like all solid state electronic devices, this system may operate erratically or can be damaged
when subjected to lightning induced transients. Although no system is completely immune
from lightning transients and interference, proper grounding will reduce susceptibility.
Overhead or outside aerial wiring is not recommended, due to an increased susceptibility to
nearby lightning strikes. Consult with the Technical Services Department if any problems are
anticipated or encountered. Disconnect AC power and batteries prior to removing or
inserting circuit boards. Failure to do so can damage circuits. Remove all electronic
assemblies prior to any drilling, filing, reaming, or punching of the enclosure. When possible,
make all cable entries from the sides or rear. Before making modifications, verify that they
will not interfere with battery, transformer, or printed circuit board location. Do not tighten
screw terminals more than 9 in-lbs. Over-tightening may damage threads, resulting in
reduced terminal contact pressure and difficulty with screw terminal removal. Silent Knight
fire alarm control panels contain static-sensitive components. Always ground yourself with a
proper wrist strap before handling any circuits so that static charges are removed from the
body. Use static suppressive packaging to protect electronic assemblies removed from the
unit.
Follow the instructions in the installation, operating, and programming manuals. These
instructions must be followed to avoid damage to the control panel and associated equipment.
FACP operation and reliability depend upon proper installation.
While installing a fire alarm system may make lower insurance rates possible, it is not a
substitute for fire insurance! An automatic fire alarm system - typically made up of smoke
detectors, heat detectors, manual pull stations, audible warning devices, and a fire alarm
control with remote notification capability - can provide early warning of a developing fire.
Such a system, however, does not assure protection against property damage or loss of life
resulting from a fire. Any fire alarm system may fail for a variety of reasons: Smoke
detectors may not sense fire where smoke cannot reach the detectors such as in chimneys, in
walls, or roofs, or on the other side of closed doors. Smoke detectors also may not sense a fire
on another level or floor of a building. A second floor detector, for example, may not sense a
first floor or basement fire. Furthermore, all types of smoke detectors, including ionization
and photoelectric types, have sensing limitations. No type of smoke detector can sense every
kind of fire caused by carelessness and safety hazards like smoking in bed, violent explosions,
escaping gas, improper storage of flammable materials, overloaded electrical circuits, children
playing with matches, or arson.
IMPORTANT! Smoke detectors must be installed in the same room as the control panel and
in rooms used by the system for the connection of alarm transmission wiring,
communications, signaling, and/or power. If detectors are not so located, a developing fire
may damage the alarm system, crippling its ability to report a fire. Audible warning devices
such as bells may not alert people if these devices are located on the other side of closed or
partly open doors or are located on another floor of a building. A fire alarm system will not
operate without any electrical power. If AC power fails, the system will operate from standby
batteries only for a specified time. Rate-of-Rise heat detectors may be subject to reduced
sensitivity over time. For this reason, the rate-of-rise feature of each detector should be tested
at least once per year by a qualified fire protection specialist. Equipment used in the system
may not be technically compatible with the control. It is essential to use only equipment listed
for service with your control panel. Telephone lines needed to transmit alarm signals from a
premise to a central monitoring station may be out of service or temporarily disabled. The
most common cause of fire alarm malfunctions, however, is inadequate maintenance. All
devices and system wiring should be tested and maintained by professional fire alarm
installers following written procedures supplied with each device. System inspection and
testing should be scheduled monthly or as required by National and/or local fire codes.
Adequate written records of all inspections should be kept.
Contents
Contents
Section 1
Introduction ..............................................................................................................................................1-1
1.1 Overview of Basic System ....................................................................................................................... 1-1
1.1.1 Hardware Features ............................ ................................................................................................ 1-1
1.1.2 Network System Hardware Features ................................................................................................1-2
1.1.3 Software Features ............................................................................................................................. 1-2
1.2 About this Manual .................................................................................................................................... 1-3
1.2.1 Terms Used in this Manual ............................................................................................................... 1-3
1.3 Compatible Products ................................................................................................................................ 1-4
1.4 How to Contact Silent Knight .................................................................................................................. 1-5
Section 2
Agency Listings, Approvals, and Requirements ...................................2-1
2.1 Federal Communications Commission (FCC) ......................................................................................... 2-1
2.2 Underwriters Laboratories (UL) ..............................................................................................................2-2
2.2.1 Requirements for All Installations .................................................................................................... 2-2
2.2.2 Requirements for Central Station Fire Alarm Systems .................................................................... 2-3
2.2.3 Requirements for Local Protected Fire Alarm Systems ...................................................................2-3
2.2.4 Requirements for Remote Station Protected Fire Alarm Systems - Digital Alarm Communicator Transmitter (DACT) 2-3
Section 3
Before You Begin Installing ...............................................................................................3-1
3.1 What’s in the Box? ................................................................................................................................... 3-1
3.2 Environmental Specifications .................................................................................................................. 3-1
3.3 Electrical Specifications ........................................................................................................................... 3-2
3.4 Wiring Specifications ........................................................ ....................................................................... 3-4
3.5 Board Assembly Diagram ........................................................................................................................ 3-6
3.6 Calculating Current Draw and Standby Battery ......................................................................................3-7
3.6.1 Current Draw Worksheet Requirements ................................ ........................................................... 3-7
3.6.2 Current Draw Worksheet for IDP SLC Devices ...............................................................................3-7
3.6.3 Maximum Battery Standby Load ....................................................................................................3-10
3.7 Installation Tasks Overview ................................................................................................................... 3-10
Section 4
Control Panel Installation ......................................................................................................4-1
4.1 Mounting the Control Panel Cabinet .......................................................................................................4-1
4.1.1 Preventing Water Damage ................................................................................................................4-1
4.1.2 Removing the IFP-2000 Assembly from the Housing ...................................................................... 4-1
4.1.3 Ethernet Connection ......................................................................................................................... 4-1
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4.2 AC Connection ......................................................................................................................................... 4-2
4.3 Battery Connection .................................................................................................................................. 4-3
4.3.1 Battery Accessory Cabinets .............................................................................................................. 4-4
4.3.1.1 Installing the RBB or AB-55 Accessory Cabinet and Batteries ............................................ 4-4
4.4 SBUS Wiring ........................................................................................................................................... 4-7
4.4.1 Calculating Wiring distance for SBUS modules ..............................................................................4-7
4.4.2 Wiring Configurations ............................ .......................................................................................... 4-9
4.5 Configuring SBUS Modules ..................................................................................................................4-11
4.5.1 Assigning SBUS Module IDs ......................................................................................................... 4-11
4.5.2 SBUS Bandwidth Considerations ................................................................................................... 4-12
4.6 RA-2000 Remote Annunciator Installation ........................................................................................... 4-13
4.6.1 Mounting the RA-2000 ................................................................................................................... 4-14
4.6.1.1 Flush Mounting .................................................................................................................... 4-14
4.6.1.2 Surface Mounting .................................................................................................................4-16
4.6.2 Model RA-2000 Connection to the Panel ....................................................................................... 4-17
4.7 5815XL Installation ............................................................................................................................... 4-18
4.7.1 5815XL Connection to the Panel ....................................................................................................4-19
4.8 5824 Serial/Parallel Interface Module Installation ................................................................................ 4-20
4.8.1 Selecting 5824 Options ...................................................................................................................4-21
4.9 5880 LED I/O Module ...........................................................................................................................4-23
4.9.1 5880 Board Layout ......................................................................................................................... 4-23
4.9.2 FACP Connection ........................................................................................................................... 4-24
4.9.3 LED Wiring ....................................................... ............................................................................. 4-25
4.9.4 Dry Contact Wiring ........................................................................................................................4-26
4.10 5865-3 / 5865-4 LED Annunciator Installation ..................................................................................... 4-27
4.10.1 FACP Connection ...........................................................................................................................4-28
4.10.2 5865 Mounting ................................................................................................................................4-29
4.11 Vip Module Installation ...................................... ... ................................................................................ 4-30
4.12 Telephone Connection ......................................................................................................
4.13 Flexputs
™
I/O Circuits ...........................................................................................................................4-31
.....................4-30
4.13.1 Conventional Notification Appliance ............................................................................................. 4-31
4.13.1.1 Regulated Class B Notification Wiring ............................................................................... 4-31
4.13.1.2 Class A Notification Wiring ...............................................................................................4-33
4.13.2 Conventional Input Switch Circuits ................................................................................................4-34
4.13.2.1 Class B Inputs ................................................. ..................................................................... 4-34
4.13.2.2 Class A Inputs ...................................................................................................................... 4-35
4.13.3 Installing 2-Wire Smoke Detectors .................................................................................................4-36
4.13.3.1 Installing 2-Wire Class B Smoke Detectors ........................................................................ 4-36
4.13.3.2 Installing 2-Wire Class A Smoke Detector .........................................................................4-37
4.13.4 Installing 4-Wire Smoke Detectors .................................................................................................4-38
4.13.4.1 Installing a Class B 4-Wire Smoke Detector ....................................................................... 4-38
4.13.4.2 Installing 4-Wire Class A Smoke Detectors ........................................................................ 4-39
4.13.5 Auxiliary Power Installation ...........................................................................................................4-40
4.13.5.1 Door Holder Power ..............................................................................................................4-40
4.13.5.2 Constant Power .................................................................................................................... 4-41
4.13.5.3 Resettable Power ........................................................................................ .......................... 4-41
4.14 On-Board Relays (Conventional) ........................................................................................................... 4-41
4.14.1 Trouble Relay ................................................................................................................................. 4-41
4.14.2 Programmable Relays ..................................................................................................................... 4-41
4.15 Remote Station Applications .................................................................................................................4-42
4.15.1 Keltron Model 3158 Installation ..................................................................................................... 4-42
4.15.2 City Box Connection Using the 5220 Module ................................................................................4-44
4.15.3 Using the IDP-Relay Addressable Relay Module for City box Connecti on .................................. 4-45
4.15.4 NFPA 72 Polarity Reversal .............................................................................................................4-46
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Contents
4.15.4.1 Using the 5220 Module ........................................................................................................4-46
4.15.4.2 Using the 7644 Module ........................................................................................................4-47
4.15.5 Transmitter Activated by Dry Contacts .......................................................................................... 4-48
Section 5
Networking ................................................................................................................................................ 5-1
5.1 Network System Hardware Features ........................................................................................................ 5-1
5.1.1 Networked Sites ................................................................................................................................ 5-1
5.1.2 Wiring Options to Connect Networked Panels .................................................................................5-1
5.2 Model RPS-2000 ...................................................................................................................................... 5-1
5.3 Direct Connect Wiring Option ................................................................................................................. 5-2
5.3.1 Installing using Direct Connection within a Site: .............................................................................5-2
5.4 Repeater Wiring Options ......................................................................................................................... 5-4
5.4.1 Network Repeater Types ...................................... ............................................................................ 5-5
5.4.2 Network Repeater Installation .......................................................................................................... 5-6
5.4.2.1 Network Repeater Cable Requirements ................................................................................. 5-8
5.4.2.2 Unshielded Twisted Pair Wiring between Multiple Panels ................................................ ...5-8
5.4.2.3 Fiber Optic Repeater Wiring ..................................................................................................5-9
5.4.2.4 Fiber Optic and Twisted Pair Repeater Wiring between Multiple Panels ...........................5-10
5.5 Using Both Repeaters and Direct Connect Wiring on a Networked System ......................................... 5-11
5.5.1 Setting the Network Terminators at Panel DIP Switches and Repeater Jumpers ........................... 5-12
5.6 Setting the Network ID for each Panel ..................................................................................................5-13
Section 6
Network Management ................................................................................................................. 6-1
6.1 Network Diagnostics ................................................................................................................................6-1
6.1.1 Ping Panel .........................................................................................................................................6-1
6.1.2 Network Status .................................................................................................................................. 6-1
6.2 Network Programming ............................................................................................................................. 6-1
6.2.1 Learn Network ..................................................................................................................................6-1
6.2.2 Edit Network ............................. ........................................................................................................6-2
6.2.2.1 Edit Panel ................................................................. ... ...........................................................6-2
6.2.2.2 Edit Site Name ....................................................................................................................... 6-3
6.2.3 Edit Panel ID ..................................................................................................................................... 6-3
6.2.4 Computer Account ............................................................................................................................ 6-3
6.2.5 Access Codes ....................................................................................................................................6-4
6.2.5.1 Edit Name .............................. ................................................................................................6-6
6.2.5.2 Edit Access Code ................................................................................................................... 6-6
6.2.5.3 Panel Functions ...................................................................................................................... 6-6
6.2.6 Dialer ................................................................................................................................................6-6
6.2.6.1 Dialer Assignments ................................................................................................................ 6-7
6.2.6.2 Dialer Miscellaneous .............................................................................................................. 6-7
6.2.6.3 Receiver Configuration ..........................................................................................................6-7
6.2.6.4 Dialer Report Table ................................................................................................................6-7
6.3 Network Management Quick Reference .................................................................................................. 6-8
Section 7
IDP SLC Device Install ............................................................................................................... 7-1
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Contents
7.1 List of IDP SLC Devices ......................................................................................................................... 7-1
7.2 Maximum Number of Devices ................................................................................................................. 7-2
7.3 Wiring Requirements for SLC Devices ..................................... .............................................................. 7-2
7.3.1 Wiring 5815XL in Style 4 (Class B) Configuration ......................................................................... 7-2
7.3.2 Wiring 5815XL in Style 6 & 7 (Class A) Configuration .................................................................. 7-4
7.4 Wiring IDP SLC Detectors ...................................................................................................................... 7-5
7.5 Addressing IDP SLC Devices .................................................................................................................. 7-6
Section 8
Programming Overview ...........................................................................................................8-1
8.1 JumpStart AutoProgramming .................................................................................................................. 8-1
8.1.1 Input Points ....................................................................................................................................... 8-1
8.1.2 Output Points ..................................................... ............................................................................... 8-2
8.1.3 Running JumpStart AutoProgramming ............................................................................................8-2
8.2 Mapping Overview ..................................................................................................................................8-4
8.2.1 Input Point Mapping .........................................................................................................................8-5
8.2.2 Output Circuit Mapping ............................................................................................. ....................... 8-6
8.2.3 Event Mapping ............................................................. .................................................................... 8-7
8.2.4 Mapping LED Points ...................................................................................................................... 8-11
8.2.5 Mapping LED Points for a Networked System ..............................................................................8-12
8.3 Programming Using the 5655 Silent Knight Software Suite-2 .............................................................. 8-13
8.4 Programming Using an Annunciator ....................................................... ... ...........................................8-13
8.4.1 Entering & Exiting Panel Programming ......................................................................................... 8-13
8.4.1.1 Moving through the Menus ..................................................................................................8-13
8.4.1.2 Selecting Options and Entering Data ................................................................................... 8-14
8.4.1.3 Editing Keys ......................................................................................................................... 8-15
8.5 Programming Menu Quick Reference ...................................................................................................8-16
Section 9
Programming ......................................................................................................................................... 9-1
9.1 UL 864 Programming Requirements .......................................................................................................9-1
9.2 Modules ....................................................................................................................................................9-2
9.2.1 Edit Modules .....................................................................................................................................9-2
9.2.1.1 Naming Modules .............................................................. ......................................................9-2
9.2.1.2 Setting the 5815XL Wiring Class .......................................................................................... 9-3
9.2.2 Adding a Module ............................................ .................................................................................. 9-4
9.2.3 Deleting a Module .................................... ........................................................................................ 9-4
9.2.4 View Module List ............................. .............................................................. ..................................9-5
9.3 Zone .........................................................................................................................................................9-5
9.3.1 Edit Zone ........................................... .............................................................. .................................. 9-5
9.3.1.1 Edit Zone Name ...................................... .............................................................. ... .............. 9-5
9.3.1.2 Edit Zone Properties ...............................................................................................................9-6
9.3.1.3 Zone Accessory Options ........................................................................................................9-8
9.3.2 Add Zone ..................................................... ..................................................................................... 9-8
9.3.3 Delete Zone ......................... ... .............................................................. .............................................9-9
9.3.4 View Zone Points ....................................................................................................... ....................... 9-9
9.4 Group ..................................................................................................................................................... 9-10
9.4.1 Edit Group ............................................ .............................................................. ............................. 9-10
9.4.1.1 Edit Group Name ................................................................................................................. 9-10
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Contents
9.4.1.2 Edit Group Properties ......................................... ......................................................... ......... 9-11
9.4.2 Add Group ...................................................... ................................................................................ 9-12
9.4.3 Delete Group ...................................................................................................................................9-13
9.4.4 View Group Points .......................................................................................................................... 9-14
9.5 Point ....................................................................................................................................................... 9-15
9.5.1 Point Programming For 5815XL Module .......................................................................................9-15
9.5.2 Point Programming For Internal or External Power Module (RPS-1000) .....................................9-18
9.5.3 Point Programming For 5880, and 5865 Modules .......................................................................... 9-20
9.5.3.1 Assigning a Name to Points .................................................................................................9-21
9.5.4 Point Programming For VIP-50/VIP-CE4 ......................................................................................9-21
9.6 System Options ......................................................................................................................................9-23
9.6.1 Auto Test Time ............................................................................................................................... 9-23
9.6.2 Phone Lines .....................................................................................................................................9-23
9.6.2.1 Dialing Prefix ....................................................................................................................... 9-24
9.6.2.2 Number of Answer Rings ....................................................................................................9-25
9.6.2.3 Dial Option (TouchTone or Pulse) .......................................................................................9-25
9.6.2.4 Rotary Format ...................................................................................................................... 9-25
9.6.2.5 Line Monitor ........................................................................................................................ 9-25
9.6.2.6 Answering Machine Bypass ........................................... ......................................................9-26
9.6.2.7 Phone Line Unused ..............................................................................................................9-26
9.6.3 Daytime/Nighttime Sensitivity ....................................................................................................... 9-26
9.6.4 Holiday Days ..................................................... ............................................................................. 9-28
9.6.5 Miscellaneous Options 1 ................................................................................................................. 9-28
9.6.5.1 Water Flow Delay ............................. ................................................................................... 9-28
9.6.5.2 Low AC Report Time ..........................................................................................................9-30
9.6.5.3 Automatic Daylight Savings Adjustment ............................................................................ 9-30
9.6.5.4 Clock Display Format (AM/PM or Military) .......................................................................9-30
9.6.5.5 Change AC Line Frequency .................................................................................................9-31
9.6.6 Miscellaneous Options 2 ................................................................................................................. 9-32
9.6.6.1 Strobes Active when Silenced ..............................................................................................9-32
9.6.6.2 Auto Display Oldest Event .................................................................................................. 9-32
9.6.6.3 IFP-RPT Repeater Installed .................................. ...............................................................9-32
9.6.6.4 Both Ports Used ...................................................................................................................9-33
9.6.7 Miscellaneous Options 3 ................................................................................................................. 9-33
9.6.7.1 Alarm Verification Time ......................................................................................................9-33
9.6.7.2 Daylight Saving Time Start and End ................................................................................... 9-34
9.6.8 Edit Banner Message ...................................................................................................................... 9-35
9.6.9 Edit Voice Commands .................................................................................................................... 9-36
9.7 JumpStart Autoprogramming ................................................................................................................. 9-36
9.8 Restore Defaults ....................................... .............................................................................................. 9-37
9.9 VIP-VCM Maintenance .........................................................................................................................9-38
9.9.1 PC Connection ........................................................................................ ........................................9-38
9.9.2 Local Recording .............................................................................................................................. 9-38
Section 10
System Operation ..........................................................................................................................10-1
10.1 User and Installer Default Codes ........................................................................................................... 10-1
10.2 Annunciator Description ................................................. ....................................................................... 10-2
10.2.1 LCD Displays ................................................................................................................................. 10-3
10.2.2 Banner ............................................................................................................................................. 10-3
10.3 Menu System ..........................................................................................................................................10-4
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Contents
10.3.1 Main Menu Overview ..................................................................................................................... 10-4
10.3.2 Using the Menus ............................................. ... ............................................................................. 10-5
10.4 Basic Operation ...................................................................................................................................... 10-5
10.4.1 Setting Time and Date ....................................................................................................................10-5
10.4.2 Disable / Enable a Point ............................................. ..................................................................... 10-5
10.4.3 Disable / Enable NACs by Group ................................................................................................... 10-5
10.4.4 View Event History ...................................................... .................................................................. 10-6
10.4.4.1 To clear the event history ..................................................................................................... 10-6
10.4.5 Conduct a Fire Drill ........................................................................................................................ 10-6
10.4.6 Conduct an Indicator Test ............................................................................................................... 10-6
10.4.7 Conduct a Walk Test ....................................................................................................................... 10-7
10.4.8 Conduct a Dialer Test ..................................................................................................................... 10-7
10.4.9 Silence Alarms or Troubles ............................................................................................................10-8
10.4.10 Reset alarms ................................................................ ... ...............................................................10-8
10.4.11 Check Detector Sensitivity Through Point Status ........................................................................ 10-8
10.4.12 View Status of a Point .................................................................................................................. 10-9
10.4.13 View Alarms or Troubles ............................................................................................................. 10-9
10.4.14 View System Information ............................................................................................................. 10-9
10.4.15 Communicating with a Remote Computer ................................................................................. 10-10
10.5 Operation Mode Behavior .................................................................................................................... 10-11
10.6 Multi-Site Annunciator and Multi-Site user Access 10-14
10.7 Releasing Operations ................................................... ........................................................................ 10-15
10.7.1 Single Interlock Zone Releasing ...................................... ............................................................. 10-16
10.7.2 Double Interlock Zone Releasing .................................................................................................10-17
10.8 Smoke Alarm Verification ................................................................................................................... 10-18
10.9 Function Keys ..................................................................................................................................... 10-18
10.9.1 Recording an F-Key macro: .................................. ........................................................................ 10-18
10.9.2 Aborting an F-Key macro recording session: ............................................................................... 10-19
10.9.3 Erasing an F-Key macro: ................................................. .............................................................10-19
10.9.4 Using a recorded F-Key macro: ....................................................................................................10-19
Section 11
Reporting ................................................................................................................................................... 11-1
11.1 Receivers Compatible with the Control Panel .......................................................................................11-1
11.2 Reporting Formats Table .......................................................................................................................11-1
11.3 SIA - Intelliknight / IFP-2000 Panels PI Modifier Reporting: ........................................................ ....... 11-6
11.4 SIA – IFP-2000 Panel Dialer: ................................................................................................................11-7
Section 12
Testing and Troubleshooting ......................................................................................... 12-1
12.1 Troubleshooting .....................................................................................................................................12-1
12.2 Common Problems ................................................................................................................................. 12-1
12.2.1 Periodic Testing And Maintenance .................................................................................................12-2
12.2.2 Event History .................................................................................................................................. 12-3
12.3 Built-in Troubleshooting and Testing Tools ..........................................................................................12-3
12.3.1 SLC Device Locator .......................................................................................................................12-3
12.3.2 SLC Multi Device Locator ............................................................................................................. 12-4
12.3.3 I/O Point Control ............................................................................................................................ 12-5
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12.3.4 Earth Fault Resistance .................................................................................................................... 12-6
Section 13
Installation Records ....................................................................................................................13-1
13.1 Detector and Module Point Record ........................................................................................................13-1
13.2 Conventional Output Point Record ........................................................................................................13-6
Appendix A
Compatible Devices ....................................................................................................................14-1
Appendix B
Special Characters Lists .........................................................................................................B-1
Silent Knight Fire Product Warranty and Return Policy
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IFP-2000 Installation Manual
viii
Introduction
Section 1 Introduction
The IFP-2000 Fire Alarm Control/Communicator is an analog addressable fire control system
that meets the requirements of UL 864. The RPS-2000 is used in a networked system where
there is at least one IFP-2000 in the system. The RPS-2000 is the same as the IFP-2000
without the display. When using the RPS-2000 as a stand alone local unit, one RA-2000 must
be connected, and the RA-2000 must be wired in conduit within 20’ of the RPS-2000.
1.1 Overview of Basic System
The IFP-2000 base system is packaged as an assembled stack of 3 circuit boards mounted to
an aluminum housing.
1.1.1 Hardware Features
• The basic IFP-2000 panel contains one built in signaling line circuit (SLC), which can
support up to 159 IDP sensors and 159 IDP modules. Additional SLC loops can be added
using the model 5815XL SLC expander to increase overall point capacity to a maximum
of 636 points. The SLC(s) supports Intelligent Device Protocol (IDP) analog addressable
sensors and modules.
• Each SLC supports 159 IDP sensors and 159 IDP modules to a maximum of 636 points
per IFP-2000 Control panel.
• 9.0A of output power is available through 8 sets of terminals for notification and auxiliary
applications. Each circuit is power limited per UL 864 and can source up to 3.0A (total
output power must not exceed 9.0A). When used as a constant auxiliary power, must not
exceed 6.0A.
• Built-in dual phone line, digital alarm communicator/transmitter (DACT).
• Reports events to central station by point or by zone.
• UL Listed for pre-action and deluge releasing systems.
• Dedicated Form C trouble relay and two general purpose Form C programmable relays.
• Can be used with Model RA-2000 Remote Annunciators (sold separately).
• Supports the 5865-3, 5865-4, and 5880 LED annunciator. See sections 4.9 and 4.10 for
additional information on these models.
• Printing of event log available through the Model 5824 Serial/Parallel Printer Interface
Module (sold separately).
151430 1-1
IFP-2000 Installation Manual
• Supports conventional 2-wire & 4-wire detectors using the 8 Flexput™ circuits or SLC
zone modules.
• 999 software zones, 999 output groups.
• Add 4 notification/auxiliary power circuits with each 5496 Intelligent Power Module.
• Add 6 Flexput™ circuits with each RPS-1000 Remote Power Supply.
• Interconnection capability for up to 8 panels.
1.1.2 Network System Hardware Features
• Up to 8 IFP-2000 panels can be connected within a networked system providing a
maximum addressable point capacity of 5,088.
• The networked system can be configured to emulate a large virtual system or can be
segmented into separate sites for multiple building applications.
• Each building is referred to as a “site”. All panels in a site operate as a single panel.
• Panels can be interconnected using a BUS or CLASS A (style 7) topology.
• Panels can be connected cost effectively via shielded twisted pair copper wire within
conduit when the panels are located no more than 20 feet apart and within the same room.
• Panels separated by more than 20 feet or located in multiple buildings use IFP-RPT
network repeater hardware to provide up to 3000 ft. of separation with twisted pair copper
wire or up to 8dB loss of signal separation for fiber optic cable. All 3 methods of panel
connectivity can be used within the same networked system.
• The network architecture provides true peer to peer capability allowing network
survivability for all hardware that remains operational in the event of partial system
failure.
1.1.3 Software Features
• Advanced analog smoke detector features:
Three sensitivity settings (high, medium, low)
Automatic drift compensation
Maintenance alert region
Point status eliminates calibrated smoke test requirements for NFPA 72
Automatic day/night sensitivity adjustment
• “JumpStart AutoProgramming” feature for easy programming
• Non-volatile event history stores 1000 events per panel
• A choice of output patterns available for notification outputs, including ANSI 3.41
temporal signal
®
• Built-in synchronization appliance support for AMSECO, Gentex
Wheelock®.
1-2 151430
, System Sensor®, and
Introduction
1.2 About this Manual
This manual is intended to be a complete reference for all installation and operation tasks for
the IFP-2000 and RPS-2000. Please let us know if the manual does not meet your needs in any
way. We value your feedback!
1.2.1 Terms Used in this Manual
The following terminology is used with the above mentioned control panels:
Table 1-1 Manual Terminology
Term Description
SLC Signaling line circuit
Module The term module is used for all hardware devices except for SLC
addressable devices and notification appliances. This includes the IFP2000/RPS-2000 panels itself and the built-in power supply. It also refers to
any (optional) 5815XL SLC expansion modules.
Input Point An addressable sensing device, such as a smoke or heat detector or a contact
monitor device.
Input Zone A protected area made up of input points.
Output Point
(or Output Circuit)
Group (or “Output Group”) A group of output points. Operating characteristics are common to all
Mapping Mapping is the process of specifying which outputs are activated when
Networking Up to 8 panels can be networked to sites that act like one panel.
A notification point or circuit for notification appliances. Relay circuits and
auxiliary power circuits are also considered output points.
output points in the group.
certain events occur in the system. Section 8.2 explains mapping in detail.
151430 1-3
IFP-2000 Installation Manual
1.3 Compatible Products
Table 1-1 lists the products available from Silent Knight for use with the IFP-2000.
Table 1-2: IFP-2000 Compatible Products
Ty pe of
Device
IDP
Addressable
SLC Devices
Other
Modules
Misc. 7860 Telephone Cord RJ31X cord for connecting phone line to the IFP-2000.
See Section 7.1 for a list of compatible devices.
5815XL SLC Expander Each 5815XL allows up to 159 IPD sensors and 159 IDP modules to be added to the system.
5824 Serial/Parallel Printer
Interface Module
RPS-1000 Intelligent Power
Module
5496 Intelligent Power
Module
RA-2000 Remote Fire Alarm
Annunciator
5865-3 and 5865-4 LED
Annunciator
5880 LED I/O Module Driver for up to 40 LEDs. Interfaces with customized annunciator boards. In addition the
5883 General Purpose Relay
Module
VIP-VCM Voice Control Module used with the IFP-2000VIP. Refer to the VIP-Series
VIP-SW16 16 switch expander with the IFP-2000VIP.
VIP-50 50 watt audio amplifier
VIP-CE4 Provides four additional audio circuits for the VIP-50
VIP-RM2000 Remote Microphone used with the IFP-2000VIP.
Silent Knight Software Suite
(SKSS-2)
RBB Remote Battery Box for mounting backup batteries up to 35AH that are too large to fit into
AB-55 Remote Battery Box for mounting backup batteries up to 55AH that are too large to fit into
Model Description
The number of 5815XLs that can be added to the system is limited only by the maximum
number of SBUS devices. However the maximum point count is limited to 636 per panel.
This allows the installer to distribute the 636 points on more than two SLC loops and also
allows all 636 points to be all sensors or all modules or any combination of sensors and
modules.
Allows a printer to be attached for the on-site event logging.
Maximum of two 5824s per control panel
Provides additional power, six Flexput™ circuits, and two Form C relays. See Model RPS-
1000 Installation Instructions P/N 151024.
Provides four additional Notification Appliance Circuits/Auxiliary power.
Same operation, similar appearance as on-board annunciator.
LED annunciator can display up to 30 LEDs (15 red and 15 yellow). 5865-4 has key
switches for silence and reset, and a system trouble LED.
5880 has eight generic switch input points.
Provides 10 Form C relays. Designed to be driven by the 5880. Up to four, 5883s can be
used with each 5880 module.
For communication and panel programming with a Windows-based computer and *modem
(not sold by Silent Knight, see Table 1-3 for compatible modems). Enables remote viewing
of detector status and event history.
the main control panel cabinet.
Dimensions: 16" W x 10" H x 6" D (40.64 cm W x 25.4 cm H x 15.24 cm D)
the main control panel cabinet.
Dimensions: 20" W x 12" H x 7.5" D (50.8 cm W x 30.48 cm H x 19.05 cm D)
Installation Manual P/N
151286 for more
information on these
accessories. VIP series is
not FM approved for use
with IFP-2000
1-4 151430
Introduction
The following modems have been tested by Silent Knight for compatibility with the Silent
Knight Software Suite software packages:
Table 1-3: Compatible Modems
Manufacturer Model
US Robotics 28.8
LifeStyle
Motorola
MultiTech MT19321ZDX
28.8, 3400 series
Premier 33.6
1.4 How to Contact Silent Knight
If you have a question or encounter a problem not covered in this manual, contact Silent
Knight Technical Support at 800-328-0103 or 763-493-6455. To order parts, contact Silent
Knight Sales at 800-446-6444 or 763-493-6435 in Minnesota.
Flexput™ is a trademark of Silent Knight.
151430 1-5
IFP-2000 Installation Manual
Limitations of Fire Alarm Systems
Manufacturer recommends that smoke and/or heat detectors be located throughout a protected
premise following the recommendations of the current edition of the National Fire Protection
Association Standard 72 (NFPA 72), manufacturer’s recommendations, State and local codes,
and the recommendations contained in Guide for the Proper Use of System Smoke Detectors,
which is made available at no charge to all installing dealers. A study by the Federal
Emergency Management Agency (an agency of the United States government) indicated that
smoke detectors may not go off or give early warning in as many as 35% of all fires. While
fire alarm systems are designed to provide warning against fire, they do not guarantee warning
or protection against fire. A fire alarm system may not provide timely or adequate warning, or
simply may not function, for a variety of reasons. For example:
• Particles of combustion or smoke from a developing fire may not reach the sensing
chambers of smoke detectors because:
Barriers such as closed or partially closed doors, walls, or chimneys may inhibit particle or
smoke flow.
Smoke particles may become cold, stratify , and not reach the ceiling or upper walls where
detectors are located.
Smoke particles may be blown away from detectors by air outlets
Smoke particles may be drawn into air returns before reaching the detector.
In general, smoke detectors on one level of a structure cannot be expected to sense fires
developing on another level.
• The amount of smoke present may be insufficient to alarm smoke detectors. Smoke
detectors are designed to alarm at various levels of smoke density. If such density levels
are not created by a developing fire at the location of detectors, the detectors will not go
into alarm.
• Smoke detectors, even when working properly, have sensing limitations. Detectors that
have photoelectronic sensing chambers tend to detect smoldering fires better than flaming
fires, which have little visible smoke. Detectors that have ionizing-type sensing chambers
tend to detect fast flaming fires better than smoldering fires. Because fires develop in
different ways and are often unpredictable in their growth, neither type of detector is
necessarily best and a given type of detector may not provide adequate warning of a fire.
• Smoke detectors are subject to false alarms and nuisance alarms and may have been
disconnected by users. For example, a smoke detector located in or near a kitchen may go
into nuisance alarm during normal operation of kitchen appliances. In addition, dusty or
steamy environments may cause a smoke detector to falsely alarm. If the location of a
smoke detector causes an abundance of false alarms or nuisance alarms, do not disconnect
the smoke detector; call a professional to analyze the situation and recommend a solution.
• Smoke detectors cannot be expected to provide adequate warning of fires caused by arson,
children playing with matches (especially within bedrooms), smoking in bed, violent
explosions (caused by escaping gas, improper storage of flammable materials, etc.).
• Heat detectors do not sense particles of combustion and are designed to alarm only when
1-6 151430
Introduction
heat on their sensors increases at a predetermined rate or reaches a predetermined level.
Heat detectors are designed to protect property, not life.
• Warning devices (including horns, sirens, and bells) may not alert people or wake up
sleepers who are located on the other side of closed or partially open doors. A warning
device that activates on a different floor or level of a dwelling or structure is less likely to
awaken or alert people. Even persons who are awake may not notice the warning if the
alarm is muffled by noise from a stereo, radio, air conditioner or other appliance, or by
passing traffic. Audible warning devices may not alert the hearing-impaired (strobes or
other devices should be provided to warn these people). Any warning device may fail to
alert people with a disability, deep sleepers, people who have recently used alcohol or
drugs, or people on medication or sleeping pills.
Please note that:
i) Strobes can, under certain circumstances, cause seizures in people with conditions
such as epilepsy.
ii) Studies have shown that certain people, even when they hear a fire alarm signal, do not
respond or comprehend the meaning of the signal. It is the property owner’s responsibility to conduct fire drills and other training exercises to make people aware of fire
alarm signals and instruct on the proper reaction to alarm signals.
iii) In rare instances, the sounding of a warning device can cause temporary or permanent
hearing loss.
• Telephone lines needed to transmit alarm signals from a premises to a central station may
be out of service or temporarily out of service. For added protection against telephone line
failure, backup radio transmission systems are recommended.
• System components, though designed to last many years, can fail at any time. As a
precautionary measure, it is recommended that smoke detectors be checked, maintained,
and replaced per manufacturer’s recommendations.
• System components will not work without electrical power. If system batteries are not
serviced or replaced regularly , they may not provide battery backup when AC power fails.
• Environments with high air velocity or that are dusty or dirty require more frequent
maintenance.
In general, fire alarm systems and devices will not work without power and will not function
properly unless they are maintained and tested regularly.
While installing a fire alarm system may make the owner eligible for a lower insurance rate,
an alarm system is not a substitute for insurance.
Property owners should continue to act
prudently in protecting the premises and the people in their premises and should properly
insure life and property and buy sufficient amounts of liability insurance to meet their needs.
151430 1-7
IFP-2000 Installation Manual
Requirements and recommendations for proper use of fire alarm systems including smoke detectors and other fire alarm devices:
Early fire detection is best achieved by the installation and maintenance of fire detection
equipment in all rooms and areas of the house or building in accordance with the requirements
and recommendations of the current edition of the National Fire Protection Association
Standard 72, National Fire Alarm Code (NFPA 72), the manufacturer’s recommendations,
State and local codes and the recommendations contained in Guide for the Proper Use of
System Smoke Detectors, which is made available at no charge to all installing dealers. For
specific requirements, check with the local Authority Having Jurisdiction (ex. Fire Chief) for
fire protection systems.
Requirements and Recommendations include:
• Smoke Detectors shall be installed in sleeping rooms in new construction and it is
recommended that they shall also be installed in sleeping rooms in existing construction.
• It is recommended that more than one smoke detector shall be installed in a hallway if it is
more than 30 feet long.
• It is recommended that there shall never be less then two smoke detectors per apartment or
residence.
• It is recommended that smoke detectors be located in any room where an alarm control is
located, or in any room where alarm control connections to an AC source or phone lines
are made. If detectors are not so located, a fire within the room could prevent the control
from reporting a fire.
• All fire alarm systems require notification devices, including sirens, bells, horns, and/or
strobes. In residential applications, each automatic alarm initiating device when activated
shall cause the operation of an alarm notification device that shall be clearly audible in all
bedrooms over ambient or background noise levels (at least 15dB above noise) with all
intervening doors closed.
• It is recommended that a smoke detector with an integral sounder (smoke alarm) be
located in every bedroom and an additional notification device be located on each level of
a residence.
• To keep your fire alarm system in excellent working order, ongoing maintenance is
required per the manufacturer’s recommendations and UL and NFPA standards. At a
minimum the requirements of Chapter 7 of NFPA 72 shall be followed. A maintenance
agreement should be arranged through the local manufacturer’s representative.
Maintenance should be performed annually by authorized personnel only.
• The most common cause of an alarm system not functioning when a fire occurs is
inadequate maintenance. As such, the alarm system should be tested weekly to make sure
all sensors and transmitters are working properly.
1-8 151430
Introduction
SURVIVABILITY:
Per the National Fire Alarm Code, NFPA 72, all circuits necessary for the operation of the
notification appliances shall be protected until they enter the evacuation signaling zone that
they serve. Any of the following methods shall be considered acceptable as meeting these
requirements:
1) A 2-hour rated cable or cable system
2) A 2-hour rated enclosure
3) Performance alternatives approved by Authority Having Jurisdiction
151430 1-9
IFP-2000 Installation Manual
1-10 151430
Agency Listings, Approvals, and Requirements
Section 2 Agency Listings, Approvals, and Requirements
2.1 Federal Communications Commission (FCC)
1. The following information must be provided to the telephone company before the IFP-
2000 can be connected to the phone lines:
A Manufacturer: Silent Knight
B Model Number: IFP-2000 and IFP-2000HV
C FCC registration number: AC6AL11B6820
Ringer equivalence: 0.8B
D Type of jack: RJ31X
E Facility Interface Codes: Loop Start: 02LS2
F Service Order Code: 9.0F
This equipment complies with Part 68 of the FCC rules and the requirements adopted by
ACTA. On the inside cover of this equipment is a label that contains, among other
information, a product identifier. If requested, this information must be provided to the
telephone company.
A plug and jack used to connect this equipment to the premises wiring and telephone network
must comply with the applicable FCC Part 68 rules and requirements adopted by the ACTA.
A compliant telephone cord (not provided) and modular jack must be utilized with this
product. It is designed to be used with a modular jack that is also compliant.
The REN (ringer equivalence number) provided on this installation sheet is used to determine
the number of devices that may be connected to the public switched telephone network. This
number must not exceed 5.0. Since this product has an REN of 1.0, the number of devices is
limited. The REN number is imbedded in the FCC registration number as 10B.
If the IFP-2000/IFP-2000HV causes harm to the telephone network, the telephone company
will notify you in advance that the temporarily discontinuance of service may be required. But
if advance notice is not practical, the telephone company will notify the customer as soon as
possible. Also, you will be advised of your right to file a complaint with the FCC if you
believe it is necessary.
The telephone company may make changes in its facilities, equipment, operations or
procedures that could affect the operation of the equipment. If this happens the telephone
company will provide advance notice in order for you to make necessary modifications to
maintain uninterrupted service.
If trouble is experienced with the IFP-2000/IFP-2000HV, for repair or warranty information,
please contact Silent Knight at 1-800-328-0103 or www.silentknight.com. If the equipment is
causing harm to the telephone network, the telephone company may request that you
disconnect the IFP-2000/IFP-2000HV until the problem has been resolved.
151430 2-1
IFP-2000 Installation Manual
This product cannot be adjusted or repaired in the field. It must be returned to the factory for
service.
This equipment is not designed for use with party line service. Connection to party line
service is subject to state tariffs. You may contact the state public utility commission, public
service commission or corporation commission for information.
Since the IFP-2000/IFP-2000HV is a commercial fire alarm panel, it must be connected
upstream of all other equipment utilizing the phone lines. If you have questions about the
installation, contact your telephone company or a qualified installer.
Warning
This device has been verified to comply with FCC Rules Part 15. Operation is subject to the following conditions:
(1) This device may not cause radio interference, and (2) This device must accept any interference received,
including interference that may cause undesired operation.
2.2 Underwriters Laboratories (UL)
2.2.1 Requirements for All Installations
General requirements are described in this section. When installing an individual device, refer
to the specific section of the manual for additional requirements. The following subsections
list specific requirements for each type of installation (for example, Central Station Fire
Alarm systems, Local Protected Fire Alarm systems, and so on). See Section 10.7 for
information on releasing operation.
1. All field wiring must be installed in accordance with NFPA 70 National Electric Code.
2. Use the addressable smoke detectors specified in Section 7.1 (IDP devices) of this manual
and or conventional detectors listed in the compatibility chart
3. Use UL listed notification appliances compatible with the IFP-2000 from those specified
in the Appendix at the back of this manual.
4. A full system checkout must be performed any time the panel is programmed.
2-2 151430
Agency Listings, Approvals, and Requirements
Restricted Options:
• The loss of AC signal is defaulted to 3 hours however the system allows settings from 0 30 hours. For UL certified installations this number must be set from 1 to 3 hours.
• The system allows the use of non-latching spot type smoke detectors. This feature may not
be used in commercial applications whereby a general alarm is sounded. It is intended for
elevator recall, door holding applications, and hotel/motel room applications.
• The system allows the Alarm Verification confirmation time to be set from 1 to 255 seconds. For UL certified installations the setting must be a minimum of 60 seconds.
• Call forwarding shall not be used.
• When two count is used detector spacing shall be cut in half, you shall not use the alarm
verification feature, and no delay shall be used.
• P.A.S feature shall be used only with automatic detectors.
2.2.2 Requirements for Central Station Fire Alarm
Systems
1. Use both phone lines. Enable phone line monitors for both lines.
2. You must program a phone number and a test time so that the IFP-2000 sends an automatic daily test to the central station.
3. The AC Loss Hours option must be set from 1-3 hours.
2.2.3 Requirements for Local Protected Fire Alarm
Systems
At least one UL listed supervised notification appliance must be used.
2.2.4 Requirements for Remote Station Protected Fire
Alarm Systems - Digital Alarm Communicator
Transmitter (DACT)
1. Do not exceed the current load restrictions shown in Section 3.6.
2. The AC Loss Hours option must be set from 1-3 hours for UL installations.
151430 2-3
IFP-2000 Installation Manual
2-4 151430
Before You Begin Installing
Section 3 Before You Begin Installing
This section of the manual is intended to help you plan your tasks to facilitate a smooth
installation. Please read this section thoroughly, especially if you are installing a IFP-2000 or
RPS-2000 panel for the first time.
3.1 What’s in the Box?
The IFP-2000 or RPS-2000 ships with the following hardware:
• A cabinet with all hardware assembled
• Two keys for the front door
• Ten 4.7K ohm end-of-line resistors
• A battery cable for batteries wired in series
3.2 Environmental Specifications
It is important to protect the IFP-2000 control panel from water. To prevent water damage, the
following conditions should be AVOIDED when installing the units:
• Intended for indoor use in dry locations only
• Do not mount directly on exterior walls, especially masonry walls (condensation)
• Do not mount directly on exterior walls below grade (condensation)
• Protect from plumbing leaks
• Protect from splash caused by sprinkler system inspection ports
• Do not mount in areas with humidity-generating equipment (such as dryers, production
machinery)
When selecting a location to mount the IFP-2000 control panel, the unit should be mounted
where it will NOT be exposed to temperatures outside the range of 0°C-49°C (32°F-120°F) or
humidity not exceeding 93% noncondensing.
151430 3-1
IFP-2000 Installation Manual
3.3 Electrical Specifications
Terminal Label Description Rating
Voltage Current
B AC input (hot)
G Earth ground N/A N/A N/A
W AC input (neutral)
X
*I/O 1 Flexput™ Circuits 24 VDC
O
X
*I/O 2 Flexput™ Circuits 24 VDC
O
X
*I/O 3 Flexput™ Circuits 24 VDC
O
X
*I/O 4 Flexput™ Circuits 24 VDC
O
X
*I/O 5 Flexput™ Circuits 24 VDC
O
X
*I/O 6 Flexput™ Circuits 24 VDC
O
X
*I/O 5 Flexput™ Circuits 24 VDC
O
X
*I/O 8 Flexput™ Circuits 24 VDC
O
B
A
+
-
SBUS1 OUT
SBUS communication 5 VDC 100 mA
SBUS power 24 VDC 1.0 A
120/240 VAC,
50/60 Hz
120/240 VAC,
50/60 Hz
5A for the IFP-2000,
2.5A for the IFP-2000HV
5A for the IFP-2000,
2.5A for the IFP-2000HV
3.0 Amp Notification and
Aux power Circuits
100 mA for initiation
circuits
3.0 Amp Notification and
Aux power Circuits
100 mA for initiation
circuits
3.0 Amp Notification and
Aux power Circuits
100 mA for initiation
circuits
3.0 Amp Notification and
Aux power Circuits
100 mA for initiation
circuits
3.0 Amp Notification and
Aux power Circuits
100 mA for initiation
circuits
3.0 Amp Notification and
Aux power Circuits
100 mA for initiation
circuits
3.0 Amp Notification and
Aux power Circuits
100 mA for initiation
circuits
3.0 Amp Notification and
Aux power Circuits
100 mA for initiation
circuits
Earth Ground
Faults
N/A
N/A
0Ω
0Ω
0Ω
0Ω
0Ω
0Ω
0Ω
0Ω
0Ω
* Regulated for NAC circuits
* Special application when used for releasing or auxiliary power circuits.
3-2 151430
Before You Begin Installing
Terminal Label Description Rating
Voltage Current
B
+
B
A
+
B
A
+
A
GND
N.C.
N.O.
N.C.
N.O.
N.C.
N.O.
SS+
SCSC+
Ring Phone Line 1 Telco Ring
Tip Phone Line 1 Telco Tip
Ring Phone Line 1 Premises Ring
Tip Phone Line 1 Premises Tip
Ring Phone Line 2 Telco Ring
Tip Phone Line 2 Telco Tip
Ring Phone Line 2 Premises Ring
Tip Phone Line 2 Premises Tip
+
–
SBUS1 IN
SBUS2 OUT
SBUS2 IN Used for Class A installations 0Ω
NETWORK
RELAY 2 General Purpose Relay 2 24 VDC 2.5 A, resistive N/AC
RELAY 1 General Purpose Relay 1 24 VDC 2.5 A, resistive N/AC
TROUBLE Trouble Relay 24 VDC 2.5 A, resistive N/AC
SLC OUT SLC terminals 32 VDC 150 mA 0Ω
SLC IN Used for Class A installations 0Ω
Battery Battery Connection 24 VDC 1.12 A N/A
Used for Class A installations 0ΩA
SBUS communication 5 VDC 100 mA
SBUS power 24 VDC 1.0 A
NETWORKING
CONNECTION
5V 100mA N/AB
N/A 0Ω
N/A 0Ω
Earth Ground
Faults
0Ω
151430 3-3
IFP-2000 Installation Manual
3.4 Wiring Specifications
Induced noise (transfer of electrical energy from one wire to another) can interfere with
telephone communication or cause false alarms. To avoid induced noise, follow these
guidelines:
• Isolate input wiring from high current output and power wiring. Do not pull one multiconductor cable for the entire panel. Instead, separate the wiring as follows:
High voltage AC power terminal
SLC loops SLC In/Out Terminals
Audio input/output Phone line circuits, Ring Tip Telco,
Phone Terminals
Notification circuits I/01-I/08 Terminals
SBUS SBUS1 In/Out Terminals, SBUS 2
In/Out Terminals
Relay circuits Trouble, Relay 1, Relay 2
Terminals
• Do not pull wires from different groups through the same conduit. If you must run them
together, do so for as short a distance as possible or use shielded cable. Connect the shield
to earth ground at the panel. You must route high and low voltages separately.
• Route the wiring around the inside perimeter of the cabinet. It should not cross the circuit
board where it could induce noise into the sensitive microelectronics or pick up unwanted
RF noise from the high speed circuits. See Figure 3-1 for an example.
• High frequency noise, such as that produced by the inductive reactance of a speaker or
bell, can also be reduced by running the wire through ferrite shield beads or by wrapping it
around a ferrite toroid.
3-4 151430
Before You Begin Installing
Figure 3-1 Wire Routing Example
151430 3-5
IFP-2000 Installation Manual
Chassis
Mounting
Nuts
On-board Annunciator
To AC
Trouble
Relay
Phone lines
SLC
In/Out
Battery
Connections
Network
Repeater
USB
Ethernet
Port
Programming
Port
(non-power
limited)
3.5 Board Assembly Diagram
Figure 3-2 Model IFP-2000 Assembly
Figure 3-2 shows the circuit boards, metal housing and annunciator that attach the IFP-2000
assembly to the cabinet. If you should need to remove the board assembly for repair, remove
the four mounting nuts which hold the assembly in the cabinet. Then lift the entire assembly
out of the cabinet. Do not attempt to remove the circuit boards from the metal bracket.
3-6 151430
Before You Begin Installing
3.6 Calculating Current Draw and Standby Battery
This section is for helping you determine the current draw and standby battery needs for your
installation.
3.6.1 Current Draw Worksheet Requirements
The following steps must be taken when determining IFP-2000 current draw and standby
battery requirements.
1. You will use the Current Draw Worksheet to determine current draw and standby battery
requirements. Use Table 3-1 if installing IDP SLC Devices. For the IFP-2000, the worst
case current draw is listed for the panel, addressable devices, and all SBUS expanders. Fill
in the number of addressable devices and expanders that will be used in the system and
compute the current draw requirements for alarm and standby. Record this information in
the current draw worksheet on Line A.
2. Add up the current draw for all auxiliary devices and record in the table at Line B.
3. Add up all notification appliance loads and record in the table at Line C.
4. For notification appliances and auxiliary devices not mentioned in the manual, refer to the
device manual for the current ratings.
5. Make sure that the total alarm current you calculated, including current for the panel itself,
does not exceed 9.0 A. This is the maximum alarm current for the IFP-2000 control panel.
If the current is above 9.0 A you will need to use a notification power expander(s) such as
the Silent Knight 5495 or the RPS-1000 intelligent power expander, to distribute the
power loads so that the IFP-2000 or the power expanders do not exceed their power rating.
Refer to the current draw worksheets provided with the 5495 or the RPS-1000 manuals so
you do not exceed their power requirements.
6. Alternatively, you may network additional IFP-2000s or RPS-2000s to get additional
power
7. Complete the remaining instructions in the appropriate current draw worksheet for determining battery size requirements.
3.6.2 Current Draw Worksheet for IDP SLC Devices
Use T able 3-1 to determine current requirements during alarm/battery standby operation when
IDP SLC devices are installed. You can install up to 159 IDP sensors per loop (636 max points
per panel) and 159 IDP modules per loop (636 points max per panel). Copy this section if
additional space is required.
151430 3-7
IFP-2000 Installation Manual
Table 3-1: Current Draw Worksheet for IDP SLC Devices
2
2
Standby
Current
mA mA
mA mA
mA
mA mA
mA mA
mA mA
mA mA
Device # of Devices Current per Device
For each device use this formula: This column X This column = Current per number of devices.
Fire Panel (Current draw from
battery)
1
Standby: 290 mA 290 mA
Alarm: 530 mA 530 mA
Addressable SLC Detectors
IDP-Photo
IDP-Photo-T mA mA
IDP-Ion mA mA
Standby/Alarm: 0.27 mA
IDP-Heat mA mA
IDP-Heat-HT mA mA
SLC
IDP-Beam (without integral test)
Aux. Pwr
IDP-Beam-T (with integral test)
(159 max/loop
& 636 max/
panel)
1
SLC
Aux. Pwr
IDP-Pduct (non-relay) SLC
Aux. Pwr
IDP-Pduct-R (with relay)
SLC
IDP-Acclimate
IDP-Heat-ROR mA mA
Standby/Alarm: 0.3 mA
Standby/
Alarm: 2 mA
Standby: 2 mA mA
Alarm: 8.5 mA mA
Standby/
Alarm: 2 mA
Standby: 2 mA mA
Alarm: 8.5 mA mA
Standby/
Alarm: 0.27 mA
Standby: 26 mA
Alarm: 87 mA
Standby/
Alarm: 0.27 mA
Addressable SLC Modules
IDP-Monitor
IDP-Control mA mA
IDP-Minimon mA mA
Standby/Alarm: 0.3 mA
IDP-Pull-SA/IDP-Pull-DA mA mA
IDP-Monitor-2 Standby/Alarm: 0.75 mA mA mA
IDP-Monitor-10 Standby/Alarm: 3.5 mA mA mA
IDP-Relay-6 Standby/Alarm: 1.45 mA mA mA
(159 max/loop
& 636 max/
panel)
1
IDP-Control-6 Standby/Alarm: 2.25 mA mA mA
IDP-Relay
IDP-Zone mA mA
Standby/Alarm: 0.2 mA
IDP-Zone-6 mA mA
SLC Accessories
SSB501BHT Sounder Base
(159 max/loop
& 636 max/
SSB224RB Relay Base Standby/Alarm: 0.5 mA mA mA
panel)
Aux Pwr
SLC Alarm: 0.7 mA
Standby: 1 mA mA
Alarm: 15 mA mA
RTS451/451 KEY Alarm: 7.5 mA
RA400Z Alarm: 10 mA
SLC Isolator Devices
IDP-Iso (Isolator Module) (318 max/loop
SSB224BI Isolator Base Standby/Alarm: 0.5 mA mA mA
& 636 max/
panel)
Standby/Alarm: 0.45 mA mA mA
Alarm
Current
mA
mA
mA
mA
3-8 151430
Before You Begin Installing
Device # of Devices Current per Device
Standby
Current
Alarm
Current
Accessories Modules
5
5815XL SLC Expander
RA-2000 Remote Fire Alarm
Annunciator
(63 max)
(63 max)
Standby/Alarm: 55 mA mA mA
Standby: 25 mA mA
5
Alarm: 50 mA mA
5824 Serial/Parallel Module (2 max.) Standby/Alarm: 45 mA mA mA
5
5496 Intelligent Power Module
RPS-1000 IntelliKnight Power
Module
5865-4 LED Annunciator
(with reset and silence switches)
5865-3 LED Annunciator
5880 I/O Module
(63 max)
(63 max)
(63 max)
(63 max)
(63 max)
5883 Relay Interface
VIP-VCM Voice Control Module (1 max.)
VIP-SW16 Switch Expander (3 max.)
VIP-50 50 watt with/without
VIP-CE4
(8 max.)
VIP-RM2000 Remote Microphone (2 max.)
IFP-RPT-FO
IFP-RPT-UTP
(1 max)
Standby/Alarm: 10 mA mA mA
Standby/Alarm: 10 mA mA mA
5
Standby: 35 mA mA
5
Alarm: 145 mA mA
Standby: 35 mA mA
5
Alarm: 145 mA mA
Standby: 35 mA mA
5
Alarm: 200 mA mA
Standby: 0 mA mA
Alarm: (22 mA/relay) 220 mA mA
Standby: 50 mA mA
Alarm: 125 mA mA
Standby: 10 mA mA
Alarm: 75 mA mA
Standby: 10 mA mA
Alarm: 10 mA mA
Standby: 50 mA mA
Alarm: 125 mA mA
Standby: 13mA mA
Alarm: 13mA mA
A Total System Current
Auxiliary Devices
3
Refer to devices manual for current rating.
Alarm/Standby: mA mA mA
Alarm/Standby: mA mA mA
Alarm/Standby: mA mA mA
B Auxiliary Devices Current
Notification Appliance Circuits Refer to device manual for current rating.
Alarm: mA
Alarm: mA
mA
mA
Alarm: mA mA
Alarm: mA
C Notification Appliances Current
mA
mA
D Total current ratings of all devices in system (line A + line B + C) mA mA
E Total current ratings converted to amperes (line D x .001): A A
F Number of standby hours H
G Multiply lines E and F. Total standby AH AH
H Alarm sounding period in hours. (For example, 5 minutes = .0833 hours) H
I Multiply lines E and H. Total alarm AH
J
Add lines G and I.
4
Total ampere hours
required
AH
AH
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IFP-2000 Installation Manual
1. Total does not include isolator devices or accessory bases.
2. If using 24 VDC aux power only. No standby or alarm current for battery calculation if using 24 VAC, 120 VAC or
240 VAC.
3. If using door holders, you do not need to consider door holder current for alarm/battery standby, because power is
removed during that time. However, during normal operation, door holders draw current and must be included in the
9.0A total current that can be drawn from the panel.
4. Use next size battery with capacity greater than required.
5. Maximum SBUS address capacity is 63 SBUS modules. The practical limit is determined by the amount of SBUS
bandwidth consumed by each SBUS module. See section 4.5.2
3.6.3 Maximum Battery Standby Load
Table 3-2 and Table 3-3 show the standby load calculations for the IFP-2000 based on 24 and
90 hours of standby. The standby load calculations of line D in the Current Draw Calculation
Worksheet (Table 3- 1) mus t be less than the number shown in Table 3-2 and Table 3-3 for the
selected battery size, standby hour and alarm time. The numbers below have a built in 20%
derating factor for the battery amp hour capacity.
Table 3-2: Maximum Battery Standby Loads for 24 Hour Standby
Rechargeable
Battery Size
17AH 535 mA 473mA 442mA
18AH 569mA 506mA 475mA
24AH 769 mA 706mA 675mA
33AH 1.07A 1.01A 975mA
35AH 1.14A 1.07A 1.04A
40AH 1.30A 1.24A 1.21A
55AH 1.80A 1.74A 1.71A
24 hr Standby,
5 mins. Alarm
24 hr Standby,
15 min alarm
24 hr Standby,
20 min alarm
Table 3-3: Maximum Battery Standby Loads for 90 Hour Standby*
Note: *For FM installations only
Rechargeable
Battery Size
33 AH N/A N/A N/A
40 AH 347mA 331mA 322mA
55 AH 480mA 464mA 456mA
90 hr Standby,
5 min alarm
90 hr Standby,
15 min alarm
90 hr Standby,
20 min alarm
Warning!
Silent Knight does not support the use of batteries smaller than those listed in Table 3-2 and Table 3-3. If you
use a battery too small for the installation, the system could overload the battery resulting in the installation
having less than the required 24 hours standby power. Use Table 3-2 and Table 3-3 to calculate the correct
battery amperes/hour rating needed for your installation. It is recommended that you replace batteries every
five years.
3.7 Installation Tasks Overview
This section provides a chart listing tasks that need to be performed when installing the IFP2000 system. The chart is intended to be a handy way for you to make sure you have
completed all necessary tasks. Unless noted, these tasks do not have to be performed in the
3-10 151430
Before You Begin Installing
order they are listed here.
Important: Connect and address SLC devices before running JumpStart AutoProgramming.
Task
Main Panel Hardware Installation
U Mount the control panel cabinet. 4.1
U Connect AC. 4.2
U Connect phone lines. 4.12
U Install 5815XL SLC expander modules (if needed). 4.7
U Install RA-2000 Remote Fire Alarm Annunciator modules if used. 4.5
U Install 5865 or LED Annunciator modules if used. 4.10
U Install 5880 LED I/O module if customized LED annunciation will be used. 4.9
U Install notification appliances. 4.13
U Install auxiliary power devices (if used). 4.13.5
U If using a printer, install the 5824 Serial/Parallel Printer Interface Module. 4.8
U Connect batteries (typically last step). 4.3
SLC Device Hardware Installation
Perform these steps before running JumpStart AutoProgramming.
U Connect device bases to the loop. IDP 7.4
U Set device addresses. IDP 7.5
U Physically connect detectors to their bases. Connect relay and contact
monitor modules.
JumpStart AutoProgramming
JumpStart AutoProgramming searches for expanders and SLC devices connected
to the panel but not programmed into the system. JumpStart AutoProgramming
automatically selects some options for SLC devices. See “Input Point
Configuration” section of this chart for other options.
JumpStart AutoProgramming makes selections for the following options. You
can customize options, if necessary.
Device type (detector or switch) configured by JumpStart
AutoProgramming.
Program type of detector (heat, photoelectric, or ionization) selected by
JumpStart AutoProgramming.
System Software Configuration
U Select low AC hours report time (3 hours by default). 9.6.5.2
U Enable/disable automatic DST adjustment feature (enabled by default). 9.6.5.3
U Change clock display format (12-hour with AM/PM by default). 9.6.5.4
U Enable/disable day/night sensitivity (disabled by default). 9.6.3
U Select holiday schedule (up to 18 days) if installation is using day/night
sensitivity.
U Set up reporting accounts. 9.6.1
U Select options for phone lines. 9.6.2
U Customize banner message (message that displays on LCD in normal
mode) if desired.
Input Point (SLC Device) Configuration
See Sec.
(for more info.)
7.3 & see device
install instructions
8.1 & 9.7
To change, see 9.6
To change, see 9.5
9.6.4
9.6.8
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IFP-2000 Installation Manual
Task
JumpStart AutoProgramming automatically selects some options for SLC devices (see “JumpStart
AutoProgramming” section of this chart). You can change options selected by JumpStart
AutoProgramming, if necessary and further customize input point options.
U Program type of switch (manual pull, fire drill, and so on), if necessary.
(JumpStart AutoProgramming assigns all switches as Manual Pull type.)
U If the installation includes duct detectors, program detector type.
(JumpStart AutoProgramming does not distinguish duct detectors from
ordinary smoke detectors.)
U Assign a name (or description) to the point. 9.5.3.1
U Assign input points to zones, if necessary. (JumpStart AutoProgramming
assigns all input points to Zone 1.)
Zone Configuration
U Add the zone to the system if it does not already exist. 9.3.2
U Program a name (or description) for the zone. 9.3.1.1
U Select alarm delay options (detection characteristics) for zone. 9.3.1.2
U Select heat detector trip temperature and/or smoke sensitivity level for
photoelectric smoke detectors. (JumpStart AutoProgramming selects 150°F
for heat detectors and Low sensitivity for smoke detectors.)
Output Point Configuration
Conventional notification circuits (circuits 1-8):
U Enable circuits used for notification appliances through programming, if
necessary.
Conventional relay circuits (circuits 9-10):
U Select options for relay circuits, if desired. Note: Relay circuits will always
output continuously (constant pattern), even if assigned to an Output Group
that uses a different output pattern.
Auxiliary power circuits (circuits 1-8):
U Enable any circuit used for auxiliary power devices through programming. 9.5
U Select type of power (door holder, co nstant, or resettable) 9.5
Addressable relay modules
U Assign addressable relay modules to output groups through programming.
(JumpStart AutoProgramming assigns all relay modules to Group 1.)
LED output points (from the 5880 LED I/O module or 5865/66 LED Annunciator)
U Assign LED modules to output groups through programming. 9.5.3
All output circuits (1-8):
U Disable (set to UNUSED) any unused circuits. If you do not disable unused
output circuits, they will cause a trouble condition (unless an EOL resistor
is used).
U Select a name for the point, if desired. 9.6
Output Group Configuration
U Add the group to the system if it does not already exist. 9.4.2
U Assign output points to the group. 9.5
U Program a name (or description) for the group, if desired. 9.4.1.1
Select “group properties” (see below).
U Select options for activation with system switches. 9.4.1
See Sec.
(for more info.)
9.5
9.5
9.5
9.3.1.2
9.4.1
9.4.1
9.5
9.5
3-12 151430
Control Panel Installation
Section 4 Control Panel Installation
Caution!
To avoid the risk of electrical shock and damage to the unit, power should be OFF at the control panel while
installing or servicing.
4.1 Mounting the Control Panel Cabinet
Read the environmental specifications in Section 3.2 before mounting the control panel
cabinet. This will ensure that you select a suitable location.
The panel should be accessible to main drop wiring runs. It should be mounted as close to the
center of the building as possible and located within a secured area, but should be accessible
for testing and service.
Mount the control panel cabinet so it is firmly secured to the wall surface. When mounting on
concrete, especially when moisture is expected, attach a piece of 3/4-inch plywood to the
concrete surface and then attach the cabinet to the plywood. Also mount any other modules to
the plywood.
The cabinet can be surface- or flush-mounted. If you will be flush-mounting the cabinet, the
hole for the enclosure should be 14.75" W x 25" H x 4" D. Do NOT flush-mount in a wall
designated as a fire break.
4.1.1 Preventing Water Damage
Water damage to the fire system can be caused by moisture entering the cabinet through the
conduits. Conduits that are installed to enter the top of the cabinet are most likely to cause
water problems. Installers should take reasonable precautions to prevent water from entering
the cabinet. Water damage is not covered under warranty.
4.1.2 Removing the IFP-2000 Assembly from the Housing
If it should ever be necessary to remove the control panel assembly from the cabinet for
repair, do so by unscrewing the nuts that connect the control panel assembly to the cabinet. Do
not attempt to disassemble the circuit boards. See Section 3.5 for location of the nuts.
4.1.3 Ethernet Connection
Ethernet connection is not used at this time. For port location see Figure 3-2.
151430 4-1
IFP-2000 Installation Manual
240 VAC Models
are Labeled Here
4.2 AC Connection
At installation, connect the AC terminals to the power source as shown in Figure 4-1 or Figure
4-2. It may be necessary for a professional electrician to make this connection.
The AC terminals are rated at 120 VAC, 50 or 60 Hz, 5A (for the IFP-2000) or 240 VAC 50 or
60 Hz, 2.5A (for the IFP-2000HV).
Figure 4-1 120 VAC Power Connection for the IFP-2000
Figure 4-2 240 VAC Power Connection for the IFP-2000HV
4-2 151430
Control Panel Installation
To Control Panel
Red
Black
Battery Jumper
(P/N 140694)
Shipped With Panel
UL Recognized 12V Battery
UL Recognized 12V Battery
4.3 Battery Connection
The control panel battery charge capacity is 17 to 55 AH. Use 12V batteries of the same AH
rating. Determine the correct AH rating as per your standby load calculation (see Section 3.6).
Wire batteries in series to produce a 24-volt equivalent. Do not parallel batteries to increase
the AH rating. It is recommended that you replace batteries every five years.
Figure 4-3 Battery Connection
151430 4-3
IFP-2000 Installation Manual
Cabinet
Mounting Holes
4.3.1 Battery Accessory Cabinets
The Model RBB or AB-55 Accessory cabinets can be used when your required to use backup
batteries that are too large to fit into the main control panel cabinet.
The RBB cabinet holds batteries up to the 35 AH size. The RBB dimensions are 16" W x 10"
H x 6" D (40.64 cm W x 25.4 cm H x 15.24 cm D).
The AB-55 Accessory cabinet holds batteries up to the 55AH size. The AB-55 dimensions are
20" W x 11.5" H x 7.5" D (50.8 cm W x 30.48 cm H x 19.05 cm D).
4.3.1.1 Installing the RBB or AB-55 Accessory Cabinet and Batteries
To properly install the accessory cabinet and backup batteries, follow these steps:
1. Mount the accessory cabinet. See figure Figure 4-4 for the four cabinet mounting holes.
• If mounting onto drywall the accessory cabinet must be mounted onto 3/4-inch plywood. This is necessary because the weight of the batteries inside the accessory cabinet could cause the cabinet to pull away from the drywall.
• When mounting on concrete, especially when moisture is expected, attach a piece of
3/4-inch plywood to the concrete surface and then attach the RBB or AB-55 cabinet to
the plywood.
• If using the battery cable extenders provided (P/N 140643), mount the RBB or AB-55
cabinet no more than 18" away from the main control panel cabinet. This will ensure
that the battery cables reach the battery terminals.
Figure 4-4 RBB or AB-55 Cabinet Mounting Holes
4-4 151430
Control Panel Installation
Conduit
Conduit
Coupler
+
+
-
-
RBB/AB-55 Cabinet
Cover Screws
RBB/AB-55 Cabinet
Cover Screws
2. Connect the main control panel battery cables to the battery cable extenders as shown in
Figure 4-5.
Figure 4-5 Splicing Control panel Battery Cable to RBB or AB-55 Battery Cable Extenders
3. Run extended battery cable from control panel cabinet through conduit to RBB or AB-55
cabinet.
See Figure 4-6.
Figure 4-6 Battery Connections in the RBB or AB-55 Cabinet
Note: Figure 4-6 is an example of how the wire connections can be routed. However, any other cabinet knock-
outs (on either the main control panel or the RBB/AB-55 cabinet), that are not previously being used may
be utilized to connect conduit between the two cabinets.
4. Connect battery leads to the backup battery terminals. See Figure 4-6.
Observe the proper polarity to prevent damage to the batteries or the control panel.
5. Insert the RBB or AB-55 cover screws into the cover mounting holes (see Figure 4-6).
Screw the cover screw 3/4 of the way into the cover mounting hole.
151430 4-5
IFP-2000 Installation Manual
Cover Plate
Mounting Keyholes
6. Align the cover plate mounting keyhole over the cover mounting screws. See Figure 4-7.
Figure 4-7 Cover Plate Mounting Keyholes and Cover Mounting Screws Alignment
7. Slide the cover into place and tighten the cover mounting screws. See Figure 4-7
4-6 151430
Control Panel Installation
4.4 SBUS Wiring
This section contains information on calculating SBUS wire distances and the types of wiring
configurations (Class A and B).
4.4.1 Calculating Wiring distance for SBUS modules
The IFP-2000 panel has two SBUS circuits which can support up to 1.0A of module load per
SBUS circuit. When determining the type of wire and the maximum wiring distance that can
be used, you will need to calculate loads for each SBUS to ensure that each SBUS does not
exceed 1.0A
To calculate the wire gauge that must be used to connect SBUS modules to the control panel,
it is necessary to calculate the total worst case current draw for all modules on a single SBUS
Circuit. The total worst case current draw is calculated by adding the individual worst case
currents for each module. The individual worst case values are shown in the table below.
Note: Total worst case current draw on a single SBUS cannot exceed 1 amp. If a large number of accessory mod-
ules are required, and the worst case current draw will exceed the 2 amps total, then the current draw must
be distributed using RPS-1000 Power Expanders. Each RPS-1000 Power Expander provides an additional
SBUS, with an additional 1 amp of SBUS current. Wiring distance calculations are done separately for
each RPS-1000, and separately for each control panel SBUS.
Model Number Worst Case Current Draw
RA-2000 Fire Annunciator .120 amps
5815XL .150 amps
5824 Serial/Parallel Printer Interface Module .040 amps
5880 LED I/O Module .250 amps
5865 LED Fire Annunciator .200 amps
RPS-1000 Intelligent Power Supply .010 amps
5496 Intelligent Power Supply .010 amps
VIP-50 .010 amps
VIP-VCM/VIP-VCM with VIP-SW16 .125 amps/.200 amps
VIP-RM2000/VIP-RM2000 with VIP-SW16 .125 amps/.200 amps
After calculating the total worst case current draw, Table 4-1 specifies the maximum distance
the modules can be located from the panel on a single wire run. The table insures 6.0 volts of
line drop maximum. In general, the wire length is limited by resistance, but for heavier wire
gauges, capacitance is the limiting factor.
151430 4-7
IFP-2000 Installation Manual
These cases are marked in the chart with an asterisk (*). Maximum length can never be more
than 6,000 feet, regardless of gauge used. (The formula used to generate this chart is shown in
the note below).
Table 4-1: Wire Distances Per Wire Gauge Using Copper Wire
Wiring Distance: SBUS Modules to Panel
Total Worst Case
Current Draw (amps)
0.100 1852 ft. 4688 ft. * 6000 ft. * 6000 ft.
0.200 926 ft. 2344 ft. 3731 ft. 5906 ft.
0.300 617 ft. 1563 ft. 2488 ft. 3937 ft.
0.400 463 ft. 1172 ft. 1866 ft. 2953 ft.
0.500 370 ft. 938 ft. 1493 ft. 2362 ft.
0.600 309 ft. 781 ft. 1244 ft. 1969 ft.
0.700 265 ft. 670 ft. 1066 ft. 1687 ft.
0.800 231 ft. 586 ft. 933 ft. 1476 ft.
0.900 206 ft. 521 ft. 829 ft. 1312 ft.
1.000 (Max) 185 ft. 469 ft. 746 ft. 1181 ft.
22 Gauge 18 Gauge 16 Gauge 14 Gauge
Note: The following formulas were used to generate the wire distance chart:
Maximum Resistance (Ohms) =
Maximum Wire Length (Feet) =
(6000 feet maximum)
where: Rpu = Ohms per 1000 feet for various wire gauges (see table below)
Total Worst Case Current Draw (amps)
Maximum Resistance (Ohms)
6.0 Volts
Rpu
* 500
Table 4-2: Typical Wire Resistance Per 1000 ft. Using Copper Wire
Wire Gauge Ohms per 1000 feet (Rpu)
22 16.2
18 6.4
16 4.02
14 2.54
4-8 151430
Wiring Distance calculation example:
Suppose a system is configured with the following SBUS modules:
2 - Module RA-2000 Fire Annunciator
1 - RPS-1000 Intelligent Power Expander
1 - 5865 LED Fire Annunciator
1 - 5824 Serial/Parallel Interface Module
The total worst case current is calculated as follows:
RA-2000 Current Draw = 2 x .120 amps = .240 amps
RPS-1000 Current Draw = 1 x .010 amps = .010 amps
5865 Current Draw = 1 x .200 amps = .200 amps
5824 Current Draw = 1 x .040 amps = .040 amps
Total Worst Case Current Draw = .490 amps
Control Panel Installation
Using this value, and referring to the Wiring Distance table, it can be found that the available
options are:
370 feet maximum using 22 Gauge wire
938 feet maximum using 18 Gauge wire
1493 feet maximum using 16 Gauge wire
2362 feet maximum using 14 Gauge wire
4.4.2 Wiring Configurations
Figure 4-8 illustrates SBUS 1, Class A wiring configuration and Figure 4-9 illustrates SBUS1
151430 4-9
IFP-2000 Installation Manual
Caution
For proper system supervision do not use looped
wire under terminals marked A, B, +, and - of the
SBUS device connectors. Break wire runs to
provide supervision of connections.
Class B configuration. SBUS 2 wiring configurations are the same as SBUS1.
Figure 4-8 SBUS Class A Wiring
Figure 4-9 SBUS Class B Wiring
4-10 151430
Control Panel Installation
Do Not Use
4.5 Configuring SBUS Modules
This section describes how to configure any system hardware modules that have been added
to the system.
4.5.1 Assigning SBUS Module IDs
SBUS devices on a panel are addressed from 1 to 63 and are connected to either SBUS 1 or
SBUS 2. Although the addressing scheme allows 63 SBUS devices to be connected to a panel
the actual number is limited by current draw and SBUS bandwidth usage as discussed below.
When installing a hardware module (such as, 5815XL, 5824, RA-2000, 5496, RPS-1000,
5865-3 or 5865-4), you must use the DIP switches on the module to assign an ID# to the
module. Address zero is an invalid address and is not allowed.
Figure 4-10 shows all possible DIP switch positions and their correlation to a numerical ID.
For example, to select ID 2, place DIP switch 2 in the up position.
Figure 4-10 Possible SBUS module addresses
Refer to Section 9.2 to edit, add, delete, and view module list
151430 4-11
IFP-2000 Installation Manual
4.5.2 SBUS Bandwidth Considerations
Each SBUS device generates a certain amount of traffic on the SBUS. Generally, the amount
of traffic generated depends on the type of SBUS device. To help you figure out the SBUS
bandwidth usage of a given collection of devices, we have created a tool available on the
Farenhyt website (www.farenhyt.com). The tool will serve as a guide to help determine how
heavily loaded an SBUS is with respect to bandwidth. We recommend you use this tool if you
plan to have more than eight SBUS devices per SBUS. Remember to include devices that are
on RPS-1000 SBUS repeaters in your list of devices for SBUS bandwidth calculators.
4-12 151430
Control Panel Installation
4.6 RA-2000 Remote Annunciator Installation
The optional Model RA-2000 Remote Annunciator, shown in Figure 4-11, performs the same
functions as the on-board annunciator. Operation is identical. The RA-2000 can be surface or
flush mounted.
Figure 4-11 Model RA-2000 Remote Annunciator, Front View
RA-2000 installation involves the following steps:
1. Make sure power is off at the panel.
2. Mount the RA-2000 in the desired location (see Section 4.6.1).
3. Connect the RA-2000 to the panel (see Section 4.4).
4. Use the DIP switches on the back of the RA-2000 to assign an SBUS ID# to the RA-2000
(see Section 4.5.1).
5. The RA-2000 module must be added to the system through programming. JumpStart
AutoProgramming will add the module automatically (see Section 8.1.3). You can also
add it manually (see Section 9.2.2). Select a name, if desired (see Section 9.2.1.1).
151430 4-13
IFP-2000 Installation Manual
Mounting Holes
Mounting Holes
4.6.1 Mounting the RA-2000
This section of the manual describes mounting the remote annunciator. The annunciator can
be flush- or surface-mounted.
4.6.1.1 Flush Mounting
This section of the manual describes flush mounting.
Follow these steps to flush mount the RA-2000
1. The back box dimensions are 9-9/32” w x 8-3/8” h. The minimum depth 2". The back box
can be mounted prior to the complete installation of the RA-2000 using any of the mounting holes shown in Figure 4-12.
Figure 4-12 Back Box Mounting Holes
4-14 151430
Control Panel Installation
Wire Knockouts
Wire Knockouts
Wire Knockouts
2. Remove knockout holes as needed for wires. See Figure 4-13 for backbox knockout locations
Figure 4-13 Back Box Knockout Locations
3. Wire the Annunciator board to the main control panel. See Figure 4-9.
4. Attach the annunciator and door assembly to back box as shown in Figure 4-14 using the
supplied screws.
151430 4-15
Figure 4-14 Attaching Annunciator/Door Assembly to Backbox
IFP-2000 Installation Manual
Key Shaped
Mounting Hole
Back Box
Mounting Holes
4.6.1.2 Surface Mounting
The Model RA-100TR trim ring kit is available for use when surface mounting the RA-2000.
1. Remove the desired knock out. See Figure 4-13.
2. To properly mount the back box, insert a single screw into the key shaped mounting hole.
Do not tighten all the way. See Figure 4-15.
Place a level on top of the back box, with the back box level insert the rest of the mounting
screws.
3. Run wires to the control panel.
4. Place the trim ring over the back box as shown in Figure 4-16.
5. Attach the Door assembly to the back box using screws provided.
Figure 4-15 Back Box Surface Mount Holes
Figure 4-16 Installing Trim Ring
4-16 151430
Control Panel Installation
6. After the annunciator wiring to the panel has been completed (described in Section 4.6.2),
replace the electronic assembly in the back box. Place the bezel over the back box and
tighten the set screws on the bezel.
4.6.2 Model RA-2000 Connection to the Panel
Connect the RA-2000 to the panel as shown in Figure 4-17
Figure 4-17 Model RA-2000 Connection to the Panel
151430 4-17
IFP-2000 Installation Manual
DIP switches for
setting IDs
Model 5815XL
To panel via SBUS To SLC loop
4.7 5815XL Installation
The 5815XL SLC expander lets you add additional addressable devices. The maximum
number of SLC devices per panel is 636. The number of 5815XL’s is limited by the maximum
number of SBUS devices.)
To install the 5815XL:
1. Make sure power is off at the panel.
2. Mount the 5815XL in the IFP-2000, the RPS-1000 cabinet, or the 5815RMK remote
mounting kit. Use the standoffs located under the control panel board assembly and secure
with screws provided with the 5815XL. See also Model RPS-1000 Installation Instruc-
tions (P/N 151153) or 5815RMK Remote Mounting Kit Installation Instructions (P/N
151391).
3. Connect the 5815XL to the control panel. (See Section 4.7.1.)
4. Use on-board DIPswitches to select an ID#. (See Section 4.5.1.)
5. The new 5815XL module must be added to the system through programming. JumpStart
will add the module automatically (see Section 8.1). You can also add it manually (see
Section 9.2.2). Select a name, if desired (see Section 9.2.1.1).
6. You are now ready to connect SLC devices to the 5815XL (see Section 7.3).
Figure 4-18 is a drawing of the 5815XL board, showing the location of terminals and DIP
switches.
4-18 151430
Figure 4-18 5815XL Board
Control Panel Installation
Supervised
Power Limited
4.7.1 5815XL Connection to the Panel
Connect the 5815XL to the control panel as shown in Figure 4-19. After the 5815XL is
connected to the panel, it must be added to the system. This programming step is described in
Section 9.2.2.
151430 4-19
Figure 4-19 5815XL Connection to Main Panel Assembly
IFP-2000 Installation Manual
Supervised
Power Limited
Model 5824 Board
Parallel
Serial
Cable
Connectors
for Connection
to Printer
4.8 5824 Serial/Parallel Interface Module
Installation
The 5824 serial/parallel interface module allows you to connect a printer to the panel, so you
can print a real-time log of system events. Instructions for installing the 5824 appear below.
The 5824 is for ancillary use only.
5824 installation involves the following steps:
1. Make sure power is off at the panel.
2. Connect the 5824 to the panel as shown in Figure 4-20.
Note: Two 5824s per panel maximum.
3. Use the DIP switches on the 5824 board to assign an ID# to the 5824 (see Section 4.5.1).
4. Configure the 5824 device through programming. See Section 4.8.1.
5. Connect a printer to the 5824 as shown in Figure 4-21.
Figure 4-20 5824 Connection to the Panel
4-20 151430
Figure 4-21 Printer Connection
Model 5824 (with housing)
To Parallel Printer
T o Se r ial Prin te r
4.8.1 Selecting 5824 Options
Control Panel Installation
Configuring the 5824 includes the following steps:
• Add the module to the system. JumpStart will add the module automatically (see Section
8.1). You can also add it manually (see Section 9.2.2).
• Select a name, if desired (see Section 9.2.1.1).
• Select options for the printer and the output port. See below.
151430 4-21
IFP-2000 Installation Manual
711
Printer and Output Port Options
1. From the Main Menu, select for Panel Programming.
2. Select for Module.
3. Select for Edit Module.
4. From the list that displays, select the 5824 module you want to configure.
5. Press to bypass the next two screens. A screen similar to the one shown in
Figure 4-22 will display.
Figure 4-22 Selecting Printer and Output Port Options
6. Select options for the printer as needed for your installation. Most printers are parallel.
7. If you are using a serial printer, use the next screen to select serial port options as required
for your printer. Refer to your printer manual if you need more information.
Option Choices
Baud Rate: 75 - 19200
Data Bits: 5 - 8
Stop Bits: .5, 1, 2
Parity: None, Even, Odd
4-22 151430
Control Panel Installation
SBUS Connection
Dry Contact Inputs
SBUS Address
DIP Switch
4.9 5880 LED I/O Module
The 5880 is an LED driver board that can be used in a wide variety of applications, including
as an interface with most customized floor plan annunciator boards. The 5880 can drive up to
40 LEDs and has one PZT controller. The 5880 also has eight inputs for dry contact
monitoring. The following sub-sections describe hardware installation. Refer to Section 6 for
programming information.
4.9.1 5880 Board Layout
Figure 4-23 is a picture of the 5880 board showing locations of screw terminals for connection
to the panel and contact monitor wiring; pin connectors for connecting LEDs; and the DIP
switch for selecting an SBUS ID number.
Figure 4-23 5880 Board Layout
151430 4-23
IFP-2000 Installation Manual
4.9.2 FACP Connection
The 5880 connects to the panel via the SBUS. Make connections as shown in Figure 4-24.
After the 5880 is connected to the panel, it must be added to the system. This programming
step is described in Section 9.2.2.
4-24 151430
Figure 4-24 5880 Connection to Main Control Panel Assembly
Control Panel Installation
4.9.3 LED Wiring
There are four 12-pin connectors on the 5880 board for connecting LEDs. Each LED gets its
power from Pin 11. Internal resistors are sized so that there is approximately 10 mA of current
for each LED, no series resistors are required. LED outputs can be mapped to output circuits.
See Section 9.5.3 for programming details.
Wire the LEDs as shown in Figure 4-25.
On connector P1, Pin 12 is an open collector output for controlling a PZT. If used, the 5880
PZT will match the PZT pattern of the on-board (or RA-2000) annunciator.
Note: The circuit connected to “Open Collector Output” (last pin on P1) must be current limited so that no more
than 100 mA of current is allowed to flow into the open collector transistor.
Figure 4-25 5880 Board Layout
151430 4-25
IFP-2000 Installation Manual
Model 7628
Supervised
4.9.4 Dry Contact Wiring
The 8 input circuits on the 5880 board are for monitoring switch inputs-any type of switch
supported by the control panel can be used with the 5880. For example, you can use a 5880 to
monitor pull stations, water flow, tamper, reset, or silence switches.
Wire dry contacts as shown in Figure 4-26. Notice grouping of terminals; power terminals are
shared by two inputs.
Figure 4-26 Dry Contact Wiring
4-26 151430
Control Panel Installation
4.10 5865-3 / 5865-4 LED Annunciator Installation
The 5865-3 and 5865-4 are LED annunciators. The 5865-4 has 30 mappable LEDs, remote
silence and reset key switches, and a general system trouble LED. The 5865-3 has 30
mappable LEDs only. These are arranged as 15 pairs of red (typically used for alarm) and
yellow (typically used for trouble) LEDs.
Installation of the 5865-3 and 5865-4 is identical. The key switches and the trouble LED
follow the behavior of other system annunciators and do not require any installation steps. The
following sub-sections describe how to install the 5865-3 and 5865-4 hardware. Refer to
Section 9 for programming information.
Note: This manual uses “5865” when referring to aspects of the 5865-3 and 5865-4 that are common to both
models.
Figure 4-27 5865-3 and 5865-4 Assembly (front view)
151430 4-27
IFP-2000 Installation Manual
4.10.1 FACP Connection
The 5865 connects to the panel via the SBUS. Make connections as shown in Figure 4-28.
After the 5865 is connected to the panel, it must be added to the system. This programming
step is described in Section 9.2.2.
Figure 4-28 5865 Connection to the FACP
4-28 151430
Control Panel Installation
4.10.2 5865 Mounting
Mount the 5865-4 to a standard 4-gang electrical box. Mount the 5865-3 to a standard 3-gang
electrical box. In Figure 4-29, the 5865-4 attached to a 4-gang box is used as an example.
Figure 4-29 5865 Mounting Example
The 5865 ships with a set of zone description labels that can be inserted into the 5865 board
assembly. These labels can be used in a typewriter or can be written on by hand. Slide the
labels under the plexiglass as shown in Figure 4-30. The LEDs will show through the label
when illuminated.
Figure 4-30 Inserting Zone Description Labels
151430 4-29
IFP-2000 Installation Manual
4.11 Vip Module Installation
For Installation of the VIP-50, VIP-VCM and VIP-RM2000 modules refer to the VIP-Series
Installation manual P/N 151286.
Note: When using these modules on a network of panels, the VBUS must not span panels. A VBUS can only be
connected between modules on the same panel.
4.12 Telephone Connection
Connect the telephone lines as shown in Figure 4-31. The Model 7860 phone cord is available
from Silent Knight for this purpose.
If you do not use the model 7860 to connect to the phone lines, the wire used for the
connection must be 26 AWG or larger diameter wire.
A number of programmable options are available for customizing telephone lines. These
options are described in Section 9.6.2.
Figure 4-31 Connection of Telephone Lines
4-30 151430
Control Panel Installation
4.13 Flexputs
The eight Flexput™ circuits are an innovative and versatile feature of the control panel. They
can be used as: Class A or B notification circuits, Class A or B initiation circuits (either 2 or 4
wire detectors), or as auxiliary power (resettable, continuous, or door holder).
The polarity of the Flexput terminals differs depending on whether the circuit is programmed
as an input or an output circuit. If the circuit is programmed as an input circuit (for a detector
or normally open contact) the X terminal is negative and O terminal is positive. If the circuit is
programmed as an output circuit (Aux power or NAC) then the X terminal is positive and the
O terminal is negative.
This section of the manual explains how to install conventional notification appliances and
initiating devices to be used with the system.
™
I/O Circuits
4.13.1 Conventional Notification Appliance
This sub-section of the manual explains how to install conventional notification appliances for
Class A (Style Z) and Class B (Style Y) configurations.
4.13.1.1 Regulated Class B Notification Wiring
You must use an appliance from the list of compatible appliances in the at the back of this
manual.
To install a circuit:
1. Wire Class B Notification appliances as shown in Figure 4-32.
151430 4-31
IFP-2000 Installation Manual
Alarm Polarity
Shown.
Supervised
Power Limited
Notification Wiring
Regulated 24 VDC
3A per Circuit, 9A max Combined
UL Listed EOL
Model 7628
4.7 kΩ
2. Configure the circuit through programming (see Section 9.5))
Figure 4-32 Class B Notification Appliance Circuit Wiring
Maximum voltage drop per Class B notification circuit is 3V. See Table 4-3
Table 4-3 Maximum Impedance Class B
Current Maximum Impedance
1.0A 3Ω
1.5A 2Ω
2.0A 1.5Ω
2.5A 1.2Ω
3.0A 1.0Ω
4-32 151430
Control Panel Installation
Supervised
Power Limited
Regulated 24 VDC
3A per Circuit, 9A max Combined
4.13.1.2 Class A Notification Wiring
You must use an appliance from the list of compatible appliances in the Appendix at the back
of this manual.
To install a Class A notification appliance circuit:
1. Wire the Class A notification appliances as shown in Figure 4-33.
2. Configure the circuit for Class A in programming (see Section 9.5).
Figure 4-33 Class A Notification Appliance Circuit Configuration
Note: In program ming any p oint t hat uses multip le Flexput circuits, the lowest Flexput circuit number is used to
refer to the circuit pair. For example, Figure 4-33 uses both Flexput circuit 1 and 2, so in programming it
would be referred to as point 1.
Maximum voltage drop is 3V per Class A circuit. See Table 4-4
Table 4-4 Maximum Impedance Class A
Current Maximum Impedance
1.0A 3Ω
1.5A 2Ω
151430 4-33
2.0A 1.5Ω
2.5A 1.2Ω
3.0A 1.0Ω
IFP-2000 Installation Manual
Supervised
Power Limited
Maximum Impedance per
Circuit is 50Ω
UL Listed
EOL
Model
4.13.2 Conventional Input Switch Circuits
This section of the manual explains how to install conventional initiating devices for Class A
(Style D) or Class B (Style B) configurations.
4.13.2.1 Class B Inputs
You can connect conventional Class B switches, such as waterflow switches and pull stations,
directly to the Flexput circuits of the control panel.
To install a Class B switch:
1. Wire the Class B switch as shown in Figure 4-34.
2. Configure the circuit through programming (see Section 9.5).
Figure 4-34 Class B Input Switches
4-34 151430
Control Panel Installation
Note:
Flexput circuit 1 and 2
used as an example.
Any Flexput point pairing
could be used.
Supervised
Power Limited
Maximum Impedance per
Circuit is 50Ω
4.13.2.2 Class A Inputs
You can connect conventional Class A switches, such as waterflow switches and pull stations,
directly to the Flexput circuits of the control panel.
To install a Class A switch:
1. Wire the Class A switch as shown in Figure 4-35.
2. Configure the circuit through programming (see Section 9.5).
Figure 4-35 Class A initiating Switches
Note: In program ming any p oint t hat uses multip le Flexput circuits, the lowest Flexput circuit number is used to
refer to the circuit pair. For example, Figure 4-35 uses both Flexput circuit 1 and 2, so in programming it
would be referred to as point 1.
151430 4-35
IFP-2000 Installation Manual
Note:
Flexput circuit 5
used as an example.
Any Flexput circuit
could be used.
UL Listed
EOL Model
7628
4.7 k Ω
Maximum Impedance per
Circuit is 50Ω
Supervised
Power Limited
4.13.3 Installing 2-Wire Smoke Detectors
Any compatible U.L. listed two-wire smoke detector can be used with the control panel (see
for list of compatible smoke detectors). Figure 4-36 and Figure 4-37 illustrate how to connect
a UL listed 2-wire detector to the control panel.
4.13.3.1 Installing 2-Wire Class B Smoke Detectors
To install a Class B two-wire smoke detector, wire as shown in Figure 4-36.
Figure 4-36 Two-Wire Class B Smoke Detector
4-36 151430
Control Panel Installation
Note:
Flexput circuit 5 and 6
used as an example.
Any Flexput point pairing
could be used.
Supervised
Power Limited
Maximum Impedance per
Circuit is 50Ω
4.13.3.2 Installing 2-Wire Class A Smoke Detector
To install a Class A two-wire smoke detector, wire as shown in Figure 4-37.
Note: In program ming any p oint t hat uses multip le Flexput circuits, the lowest Flexput circuit number is used to
151430 4-37
Figure 4-37 Two-Wire Class A Smoke Detector Connections
refer to the circuit pair. For example, Figure 4-37 uses both Flexput circuit 5 and 6, so in programming it
would be referred to as point 5.
IFP-2000 Installation Manual
Air Products
PAM-2
Model 160150
Supervision
Module
UL Listed
EOL Resistor
Model 7628
ESL 449CT
Note:
Flexput circuit 5 and 6
used as an example.
Any Flexput point pairing
could be used.
Supervised
Power Limited
Maximum
Impedance per
Circuit is 50Ω
4.13.4 Installing 4-Wire Smoke Detectors
Any compatible U.L. listed four-wire smoke detector can be used with the control panel (see
for list of compatible smoke detectors). Figure 4-38 and Figure 4-39 illustrate how to connect
a UL listed four-wire detector to the control panel.
4.13.4.1 Installing a Class B 4-Wire Smoke Detector
Figure 4-38 illustrates how to install a 4-wire Class B smoke detector.
Conventions used for wiring 4-wire Class B loops:
1. Up to four Class B 4-wire smoke detector loops can be connected to the control panel at
once.
2. Each Class B loop input is paired with a unique power source as shown in Figure 4-38.
3. Each loop gets smoke power from the even numbered Flexput circuit and the contact input
is connected to the odd numbered Flexput circuit.
Note: In program ming any p oint t hat uses multip le Flexput circuits, the lowest Flexput circuit number is used to
4-38 151430
Figure 4-38 Class B 4-Wire Smoke Detector Connections
refer to the circuit pair. For example, Figure 4-38 uses both Flexput circuit 5 and 6, so in programming it
would be referred to as point 5.
Control Panel Installation
Air Products
PAM-2
Model 160150
Supervision
Module
Air Products
PAM-2
Model 160150
Supervision
Module
Supervised
Power Limited
Maximum
Impedance per
circuit is
50Ω
4.13.4.2 Installing 4-Wire Class A Smoke Detectors
Figure 4-39 illustrates how to install 4-wire Class A detectors.
Conventions used for wiring 4-wire Class A loops:
1. Up to two Class A 4-wire loops can be connected to the control panel at once.
2. Smoke power is supplied to each Class A loop as shown in Figure 4-39.
Figure 4-39 Class A 4-Wire Smoke Detector Connections
Note: In programming any point that uses multiple Flexput circuits are always referred to as the lowest Flexput
circuit number used. For example, Figure 4-39 uses Flexput circuits 1, 2, 3 together and 4, 5, 6 together.
In programming (1, 2, 3) would be referred to as point 1, and (4, 5, 6) would be referred to as point 4.
151430 4-39
IFP-2000 Installation Manual
When used as auxiliary power, terminals labeled “O” are
negative, terminals labeled “X” are positive
4.13.5 Auxiliary Power Installation
Flexput Circuits 1-8 on the control panel can be used as auxiliary power circuits. The three
types of auxiliary power available are:
• Door Holder (see Section 4.13.5.1)
• Constant (see Section 4.13.5.2)
• Resettable Power (see Section 4.13.5.3)
Auxiliary power circuits are power limited. Each circuit can source up to 3A (total current for
all Flexput circuits must not exceed 9.0 A), and 6A when used as constant auxiliary power.
To install an auxiliary power circuit:
1. Wire the Flexput circuit(s) that will be used for auxiliary power. See Figure 4-40 for location of Flexput circuits.
2. Configure the auxiliary power output through programming (see Section 9.5).
Figure 4-40 Flexput Circuit Location
4.13.5.1 Door Holder Power
Door holder power is intended for fire door applications. When there are no alarms in the
system and the panel has AC power, door holder circuits have 24-volt power present at their
terminals. Any alarm will cause power to disconnect. Power will be re-applied when the
system is reset. If AC power is off for more than 15 seconds, the auxiliary door holder power
will be disconnected to conserve the battery backup. When AC power is restored, power is
immediately restored to the door holder circuits.
Use a UL listed door holder such as ESL DHX-1224, for this application. See Table A-5 for
compatible door holder list.
4-40 151430
Control Panel Installation
4.13.5.2 Constant Power
Use constant power for applications that require a constant auxiliary power source. Power is
always present at constant circuits. You must have backup generator to supply standby power.
See Appendix A.
4.13.5.3 Resettable Power
Resettable power is typically used to power beam detectors, flame detectors and conventional
4-wire smoke detectors. For circuits selected as Resettable, 24-volt power is always present at
the terminals unless a system reset occurs. If a system reset occurs, power is disconnected
from the terminals for 30 seconds, then re-applied. See Table A-4 for compatible four wire
smoke detectors.
4.14 On-Board Relays (Conventional)
The control panel has two built-in programmable relays and a built-in trouble relay. All relays
are Form C rated at 2.5 A @ 24VDC.
Figure 4-41 Location of Conventional Relay Circuits
4.14.1 Trouble Relay
The control panel has a dedicated Form C trouble relay built in. The relay provides a normally
open and a normally closed contact. The trouble relay will deactivate under any trouble
condition.
Note: The NC contact is the relay contact that is closed when the panel has power and there are no trouble con-
ditions.
4.14.2 Programmable Relays
The control panel has two Form C programmable relays built in. Each relay provides a
normally open and a normally closed contact.
To install one or two programmable relays, follow these steps.
151430 4-41
IFP-2000 Installation Manual
1. Wire Relay 1 and/or Relay 2 as needed for your application. See Figure 4-41 for the location of the relay terminals.
2. Configure the relay through programming (see Section 9.5).
4.15 Remote Station Applications
4.15.1 Keltron Model 3158 Installation
The control panel is compatible with Keltron Model 3158, used for direct connection to a
Keltron receiver. The 3158 reports alarms, supervisories, and troubles.
The steps for connecting the 3158 to the control panel. Refer to the 3158 installation
instructions for complete information.
1. Wire the 3158 to the control panel as shown in the connection list and Figure 4-42.
2. Wire the 3158 within 20 feet of the control panel. Wiring must be enclosed in conduit.
3. Program control panel Relay 1 for alarm.
4. Program Flexput circuit 5 for alarm.
5. Program Flexput circuit 6 for supervisory non latching.
Table 4-5: Keltron 3158 to Control Panel Connections
Terminal # Connects To Terminal # Connects To
3158 Term. 1 To Keltron receiving equipment 3158 Term. 8 Control panel Relay 1 COM
3158 Ter m. 2 To Keltron receiving equipment 3158 Term. 9 Control panel I/O6 O
3158 Term. 3 Earth ground 3158 Term. 10 Control panel I/O6 X
3158 Term. 4 Not used; no connection. Control panel I/O5 X Control panel Relay 1 NO
3158 Term. 5 Control panel SBUS OUT + Control panel Relay 1 COM Control panel Trouble COM
3158 Term. 6 Control panel SBUS OUT – Control panel Relay 1 NO Control panel Trouble NC
3158 Term. 7 Control panel I/O5 O
4-42 151430
Control Panel Installation
Not suitable for remote station
where separate transmission
supervisory (if applicable), an d
protected premise service
circuits are required for fire
trouble signals.
Intended for connection to a
polarity reversal circuit of a
remote station receiving unit
having compatible ratings.
Example
Figure 4-42 Keltron 3158 Connection to Control Panel
151430 4-43
IFP-2000 Installation Manual
Not suitable for remote
station protected
premise service where
separate transmission
circuits are required for
fire supervisory (if
applicable), and trouble
signals.
Note: Flexput circuit 1
used as an example.
Any flexput circuit
could be used
All circuit off the 5220 are
non- power limited and
all wiring is non-supervised
*The wiring off the main control
is still power limited and supervised
4.15.2 City Box Connection Using the 5220 Module
This section describes how to connect the control panel to a local energy municipal fire alarm
box or “city box” as required by NFPA 72 Auxiliary Protected Fire Alarm systems for fire
alarm service. The city (master) box is an enclosure that contains a manually operated
transmitter used to send an alarm to the municipal communication center which houses the
central operating part of the fire alarm system.
City Box Standby Current: 0 (Notification supervision current
accounted for in control panel draw.)
Alarm Current: 1 Amp for 1 second
27.2 VDC max
The maximum coil and wire resistance (combined) must not exceed 30 ohms.
To install the 5220 for city box connection:
1. Use one of the knockouts on the right side of the control panel to connect the 5220 using a
short piece of conduit (must not exceed 20 feet in length).
2. Wire the 5220 to the control panel as shown in Figure 4-43. This drawing also shows how
to connect the city box coil to terminals 3 and 4 on the 5220. Do not install an EOL resistor in the terminals of the Flexput circuit used for this application.
3. Connect earth ground wire to the 5220 chassis with mounting screw.
4. Program the Flexput circuit as a notification circuit, Refer to Section 9.5.2. Assign this
Flexput to an output group that is mapped to activate with non silenceable constant output
in response to a system general alarm condition.
It is not possible to reset the remote indication until you clear the condition and reset the
control panel.
4-44 151430
Figure 4-43 City Box Connection
Control Panel Installation
UL listed Model
7642 Must be
Installed in City
Box Enclosure
4.15.3 Using the IDP-Relay Addressable Relay Module for
City box Connection
Wire the IDP-Relay as shown in Figure 4-44
Figure 4-44 IDP-Relay Module for City box Connection
151430 4-45
IFP-2000 Installation Manual
Note:
Flexput circuit 1 and Relay 2
used as examples. Any
Flexput circuit and either
relay 1 or relay 2 could
be used.
Jumper these terminals
when City Box is not used.
Intended for connection to a Polarity Reversal
circuit of a Remote Station receiving unit having
compatible ratings.
4.15.4 NFPA 72 Polarity Reversal
Note: Intended for connection to a polarity reversal circuit of a control unit at the protected premises having
compatible rating.
4.15.4.1 Using the 5220 Module
When the 5220 is wired and programmed for polarity reversal, it reports alarm and trouble
events to a remote site. Alarms will override trouble conditions and it will not be possible to
reset the remote indicator until the condition is cleared and the control panel is reset.
If an alarm condition occurs, the alarm relay will close, overriding the trouble condition.
Standby Current: 100 mA, 24 VDC
Alarm: 100 mA, 24 VDC
To install the 5220 for polarity reversal, follow the steps below:
1. Locate the knockout on the right side of the control panel cabinet to connect the 5220
using a short piece of conduit (must not exceed 20 feet in length).
2. Wire the 5220 to the control panel using the four-wire pigtail provided as shown in Figure
4-45. This diagram also shows how to connect the 5220 to the remote indicator. Do not
install an EOL resistor in the terminals of the flexput circuit used for this application.
3. Connect earth ground wire to the 5220 chassis with mounting screw.
4. Program the flexput circuit as a notification circuit, Refer to Section 9.5.2. Assign this
flexput to an output group that is mapped to activate with non silenceable constant output
in response to a system general alarm condition.
5. If necessary, adjust loop current using the potentiometer (R10) on the 5220 board . Normal
loop current is 2-to-8 mA with a 1k ohm remote station receiving unit. Maximum loop
resistance is 3k ohm.
Figure 4-45 Polarity Reversal Connection Using the 5220 Module
4-46 151430
Control Panel Installation
4.15.4.2 Using the 7644 Module
When the 7644 is used for polarity reversal, it allows alarm and trouble events to be reported
to a remote site. Alarms will override trouble conditions and it will not be possible to reset the
remote indicator until the condition is cleared and the control panel is reset.
To install the 7644 for polarity reversal:
1. Wire the 7644 to the control panel as shown in Figure 4-46. Do not install an EOL resistor
on the terminals of the flexput circuit used.
Note: Use only Flexput circuits on the control panel for reverse polarity.
2. Program the Flexput circuit as a notification circuit. See Section 9.5.2.
3. Map the group to activate non silenceable constant on in response to a system general
alarm, and to disconnect in response to a system trouble.
4. Intended for connection to a polarity reversal circuit of a remote station receiving unit
having compatible rating.
Figure 4-46 Polarity Reversal Connection Using the 7644
151430 4-47
IFP-2000 Installation Manual
4.15.5 Transmitter Activated by Dry Contacts
This section describes the connection of a UL 864 listed remote station transmitter to the
IFP-2000 FACP dry contacts. The FACP contacts must be supervised by the remote station
transmitter module using end-of-line resistors (ELRs) with a value determined by the transmitter manufacturer. Power is also provided by the remote station transmitter manufacturer.
Refer to the remote station transmitter manufacturer’s manual for details.
4-48 151430
Networking
Section 5 Networking
5.1 Network System Hardware Features
IFP-2000 panels can be networked to create a virtual system that is larger than 636
addressable points. It is possible to have up to eight IFP-2000/RPS-2000 panels networked
providing a maximum addressable point capacity of 5,088 points (636 x 8 = 5,088).
5.1.1 Networked Sites
A networked site is a logical group of IFP-2000 and/or RPS-2000 panels that behave as
though the logical group is one large control panel. Each building is referred to as a “site”. All
panels in a site operate as a single panel. The control functions like reset, silence or alarm
activation operate across the entire site. There can be one or more logical sites within a
networked system. Taken to the extreme, the maximum number of sites within a network
system is limited to 8 with each site comprised of only one panel. Alternatively , the maximum
number of panels within a site is limited to 8 panels which is also the maximum panel capacity
of a networked system.
5.1.2 Wiring Options to Connect Networked Panels
1. Direct Connect - Panels can be connected cost effectively via shielded twisted pair copper
wire within conduit when the panels are located no more than 20 feet apart and in the same
room.
2. Repeater Connection - Panels separated by more than 20 feet or are located in multiple
buildings, must use the P/N IFP-RPT network repeater hardware to provide up to 3000
feet of separation with twisted pair copper wire or up to 8dB loss of signal separation for
fiber optic cable.
All methods of panel connectivity can be used within the same networked system. The
network architecture provides true peer to peer capability allowing network survivability for
all hardware that remains operational in the event of partial system failure.
5.2 Model RPS-2000
The model RPS-2000 provides the same power and point capacity of an IFP-2000 panel, but
does not include any user interface. It is used in networked systems where added power and/or
point capacity is required but where additional user interface is not needed.
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5.3 Direct Connect Wiring Option
When networking a group of IFP-2000s and/or RPS-2000s within a 20 foot radius of each
other, you may use the direct connect method to link the panels together in the site.The cable
used must be shielded twisted pair communication grade cable. See Figure 5-1, direct connect
wiring option. The direct connect wiring option uses a BUS configuration. There are no T-taps
or class A wiring options.
Figure 5-1 Direct Connect wiring option
5.3.1 Installing using Direct Connection within a Site:
1. Mount the IFP-2000 and /or RPS-2000 panels within 20 feet of conduit run distance from
each other. Place the conduit for routing the direct connect networking cable between
panels in a bus configuration as shown above in Figure 5-1
2. Make the network wiring connections. The cable used must be shielded twisted pair 18
gauge or larger wire. See Figure 5-2 for the DIP switch termination settings for Direct
Connect wire option. Run one of the twisted pair wires from the NETWORK A terminal
on one panel to the NETWORK A terminal on the next panel. Use the other wire of the
twisted pair to connect the NETWORK B terminals together. Run the network ground
connection using the twisted pair shield between the NETWORK GND terminal on both
panels. Repeat this for each additional panel until all A, B and GND terminals are wired
together as a BUS.
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Networking
3. Configure the network terminators. The panels at both ends of the network bus must have
DIP switches 8, 9, and 10 set to the “ON” position. All panels that are not at the BUS ends
must have the terminators set to the OFF position. See Figure 5-2
4. T-Tapping is not allowed, wire must be run in a BUS configuration.
Figure 5-2 DIP Switch terminations settings for Direct Connect Wiring option
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Class A
Wiring
5.4 Repeater Wiring Options
Networking a group of IFP-2000s and/or RPS-2000s at a distance greater then 20 feet requires
the use of a network repeater with each panel. Repeaters are used to travel long distances and/
or between buildings. Figure 5-3 shows the repeater wiring connection for style 4, class B as a
solid line. For style 7, class A the dotted line would be used in addition to the solid lines.
Figure 5-3 Repeater Networking Connection
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Networking
5.4.1 Network Repeater Types
Network repeaters are available in two configurations. See Figure 5-4
1. P/N IFP-RPT-UTP is used for twisted pair copper wiring up to 3000 ft. between panels.
2. P/N IFP-RPT-FO is used for fiber optic cable or twisted pair wiring between panels.
Figure 5-4 Types of Network Repeaters
The IFP-RPT-UTP repeater is used for connecting panels via unshielded twisted pair wiring
up to a maximum wiring distance of 3000 feet. The IFP-RPT-FO repeater is used for
connecting panels via fiber optic cable up to a maximum signal loss of 8dB. The IFP-RPT-FO
repeater also has connections for unshielded twisted pair wiring so that either fiber optic cable
or unshielded twisted pair wiring can be used for connecting panels.
Due to the physical size of the repeaters it is difficult to mount them directly in the IFP-2000
cabinet. Accessory kits for the repeaters are available that include a small cabinet with door,
key, mounting hardware, 5 foot ribbon cable to connect the repeater to the control panel and
the repeater printed circuit board. The accessory kit part numbers are:
1. IFP-RPT-UTP-KIT - Wired twisted pair network repeater card and cabinet kit.
2. IFP-RPT-FO-KIT- Fiber optic network repeater card and cabinet kit.
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5.4.2 Network Repeater Installation
The network repeater mounts in its own cabinet. The cabinet must be placed within 2 feet of
the main control panel cabinet in order for the 5 foot ribbon cable to reach between the
repeater and the control panel.
Figure 5-5 Network Repeater mounted in cabinet
Use the following steps to properly mount the network repeater to the IFP-2000.
1. Place the network repeater cabinet within 2’ of the IFP-2000 panel. Use 3/4”or larger
conduit between the IFP-2000 and the repeater cabinet. Install the repeater PCB in the
repeater cabinet using the mounting hardware provided.
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Networking
2. Use the 5’ ribbon cable to connect the IFP-2000 to the repeater board. Run an insulated
wire from the screw terminal labeled TB2 on the repeater to an earth screw terminal on the
control panel.
Figure 5-6 Panel to Networked repeater connection
3. Place jumper J1 (also labeled TERM) for ALL repeater installations.
4. Place Jumpers J2 and J3 when there is a twisted pair cable connected to positions 1 and 2
of terminal black TB1. Each repeater has the ability to monitor for earth ground faults on
the twisted pairs connected to terminals 1 and 2 of its terminal block TB1. Earth fault
detection for any wiring at terminals 3 and 4 of TB1 is done at the next/previous repeater
due to these wiring connections being connected to terminals 1 and 2 of TB1 at the next/
previous repeater. When no twisted pair wiring is made to terminals 1 and 2 of TB1
jumpers J2 and J3 must be left OPEN at the repeater. This would be the case when using
fiber optic cable or when terminals 3 and 4 of TB1 are only being used.
5. On fiber optic repeaters, jumpers J4 through J9 are normally left OPEN. See IFP-RPT
installation instruction (p/n 9001-0061) for determining when to use J4 through J9. Fiber
optic ports that are not used must have their dust caps placed on the port.
6. Based on the type of network repeater board chosen, run the twisted pair wiring /fiber
optic cable to the next network repeater using a BUS or style 7 (class A) wiring method. A
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IFP-2000 Installation Manual
Class A
Wiring
combination of both repeater types can be used. See Figure 5-7, Figure 5-8, Figure 5-9,
and Figure 5-10 for repeater wiring examples.
5.4.2.1 Network Repeater Cable Requirements
Cable requirements for wire runs between repeaters.
1. All fiber cable must be multimode 62.5/125 micron cable with ST type connectors. It is
important that the cable be verified to contain no more then 8dB of loss including the
connectors.
2. Twisted pair wiring must be UNSHIELDED twisted pair conductor cable. The wire gauge
must be 18 AWG or larger. The maximum wire length is 3000 ft. between repeaters.
5.4.2.2 Unshielded Twisted Pair Wiring between Multiple Panels
Unshielded twisted pair wiring between multiple panels is shown in Figure 5-7. Class A
wiring is shown with a dotted line.
Figure 5-7 Twisted Pair Wiring Configuration
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Networking
Class A
Wiring
5.4.2.3 Fiber Optic Repeater Wiring
Fiber optic cable between multiple panels is shown in Figure 5-8. Class A is shown with a
dotted line.
Figure 5-8 Fiber Optic Wiring Example
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Class A
Wiring
Fiber optic ports
that are not used
must have their
dust caps placed
on the port
5.4.2.4 Fiber Optic and Twisted Pair Repeater Wiring between
Multiple Panels
A mixture of fiber optic cable and twisted pair wiring between multiple panels is shown in
Figure 5-9. Class A cabling is shown with dotted line.
Figure 5-9 Twisted Pair and Fiber Optic Combination Wiring Example
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Networking
Class A
Wiring
5.5 Using Both Repeaters and Direct Connect Wiring on a Networked System
Figure 5-10 below shows a network wiring example using both repeaters and direct connect
wiring. All repeaters in the system must be placed only on panels that are at the ends of a
direct connect BUS or connected to panels with no direct connect network wiring.
Figure 5-10 Network Wiring Example using both Repeaters and Direct Connect Wiring
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IFP-2000 Installation Manual
5.5.1 Setting the Network Terminators at Panel DIP
Switches and Repeater Jumpers
Use the following steps for determining DIP switch and jumper settings.
1. DIP switch positions 8 through 10 on the control panel are used for direct connect network
BUS termination. When a panel is located at the end of a direct connect BUS and it does
NOT have a repeater connected, DIP switches 8, 9 and 10 must be ON. When a panel is
not direct connected to other panels, but a repeater is used to network the panel, its DIP
switches 8, 9, and 10 must be ON. Otherwise, DIP switches 8, 9 and 10 are always OFF.
2. Jumper J1 on the network repeater is used for termination between the panel and the
repeater. Jumper J1 must always be present (jumper is ON).
3. Jumpers J2 and J3 for the network repeater should be present (jumper is ON) only when a
twisted pair is connected to terminals 1 and 2 of terminal block TB1. Jumpers J2 and J3
are used to enable earth ground fault monitoring at terminals 1 and 2 of terminal block
TB1.
4. It is a requirement that an insulated wire be run between the network repeater terminal
TB2 and an earth grounding screw at the control panel for all network repeater installations.
The following text details how the panel and repeater terminators must be set
for the network example in Figure 5-10.
Panel 1 is at the end of a direct connect BUS and it does not have a repeater, so its DIP
switches 8, 9 and 10 must be ON to provide direct connect BUS termination.
Panel 2 is NOT at the end of a direct connect BUS so its DIP switches 8, 9 and 10 must be
OFF.
Note: A repeater would not be allowed to be connected to panel 2 in this example because it is not at the end of
a direct connect BUS.
Panel 3 looks like it is at the end of a direct connect BUS, but because it has a repeater
connected to it, DIP switches 8, 9 and 10 at panel 3 must be OFF. The direct connect BUS
termination is provided by the repeater through jumper J1. Recall that jumper J1 must placed
(ON) as this is the rule for ALL repeaters. Jumpers J2 and J3 on the repeater of panel 3 must
be OFF because no wires are connected to the repeater twisted pair terminals 1 and 2 of TB1.
Panel 4 is not directly connected to other panels but it is effectively direct connected to its
repeater which electrically behaves the same as a direct connected BUS between panels.
Because panel 4 is connected only to its repeater its DIP switches 8, 9 and 10 at panel 2 must
be ON to provide direct connect BUS termination. Jumper J1 of the repeater must also be
placed (ON) to provide the other direct connect BUS termination and because the rule for
repeaters is that Jumper J1 must always be placed (ON). Repeater jumpers J2 and J3 must be
placed (ON) because a wired twisted pair is connected to terminals 1 and 2 of TB1.
Connecting these jumpers enables earth ground fault monitoring of the twisted pair wire
between the repeater of panel 4 and panel 3.
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Networking
Panel 5 is at the end of a direct connect BUS so its DIP switches 8, 9 and 10 must be ON to
provide the direct connect BUS termination.
Panel 6 looks like it is at the end of a direct connect BUS, but because it is also using a
repeater its DIP switches 8, 9 and 10 must be OFF. In this example, panel 6 is actually in the
middle of a direct connect BUS between panel 5 and the repeater of panel 6. Jumper J1 of the
repeater is placed (ON) and provides the termination. Jumpers J2 and J3 for the repeater must
be OFF because no wires are connected to the twisted pair terminals 1 and 2 of TB1.
5.6 Setting the Network ID for each Panel
Note: It is important that much thought is given when choosing the network IDs for each panel. It is difficult to
change the IDs once panel programming has begun.
The network ID for each panel is set using DIP switch positions 1 through 7. The valid range
of network IDs is 1-8 for a maximum of 8 panels per networked system. See Figure 5-11
below for possible DIP switch settings.
Figure 5-11 Network ID Settings
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