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et BaD igs CHEMETRON 4601 Southwick Drive " ™ Matteson, IL Fire Systems or я SR ME N -- E INTERLICEMT FINE [A TENE E | i Fire Systems” MICRO 200-I ANALOG FIRE PANEL INSTRUCTION MANUAL RELEASE 2 PN 70100714 50604:F N Installation Precautions - Adherence to the following will aid In problem-free installation with tong-tem reliabllity: 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 whiie the unit is energized. Do not attempt to install, service, or operate this unit until this manual is read and understood. CAUTION - System Reacceplance Test after Software Changes: To ensure proper eysiem operation, this product must be tested in accordance with NFPA 72- 1993 Chapter 7 after any programming operation or change in site-specific software. Reacceptance 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 lo 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 NFPA requirements for operation at 0-48° C/32-120° F and at a relative humidity of 85% RH (non-condensing) at 30°C/86° F, 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 sysiem and its peripherals be installed in an environment with a nominal room temperature of 15-27" С160-80° Е. Verify that wire sizes are adequate for all initiating and indicaling device loops. Most devices cannot tolerate more than a 10% LR. drop from the specified device vollage. Fire Alarm System Limitations An automatic fire alarm system - typically made up of smoke detectors, heat detectors, manual pull stations, audible waming devices, and a fire alarm control with remote notification capability can provide early waming of a developing fire. Such a sysiem, however, does not assure protection against property damage or loss of file resulting from & fire. Any fire alarm system may fall for a variety of reasons: Smoke detectors may not sense fire where smoke cannot reach the delectors such #5 In chimneys, in walls, or roofs, or on the other side of dosed doors. Smoke deteclors also may not sense a firs on another level or floor of a building. A second floor detector, for example, may not sense a first floor or basement fire. Further- more, all types of smoke detectors - both ionization and photoelectric types, have sensing imitations. 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 clreuits, children playing with matches, or arson. IMPORTANT! Smoke detectors must be installed in the sams room as the contro! panel and in rooms used by the system for the connection of alarm transmission wiring, communications, signaling, and/or power. 1f deteclors sre not so located, a developing fire may damage the alarm syslem, crippling is ability to report a fire. Like all solld state electronic devices, this system may operate ematically or can be damaged when subjected to lightning induced transients. Although no system is completely immune from lightning transients and interferences, proper grounding will reduce susceptibility. Overhead or outside serial wiring Is not recommended, due lo an increased susceplibiiity fo 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 circult boards, Fallure to do so can damage circuits. Remove all electronic assemblies prior to any drilling, filing, reaming, or punching of the enclosure. When possible, make ail cable entries from the sides or rear. Before making modifications, verify that they will not interfere with battery, transformer, and printed circuit board location. Do not tighten screw terminals more than 9 in-bs. Over tightening may damage threads, resulting in reduced terminal contact pressure and difficulty wilh screw terminal removal. This system contains static-sensitive components. Always ground yourself with a proper wrist strap before handiing any circuits so that static charges are removed from the body. Use static suppressive packaging to protect electronic assemblies removed from the unit. Foliow 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! Audible waming 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 falls, 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 defector 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 alam elgnals from # premise to a central monitoring station may be out of service or temporarily disabled. The most common cause of fire alam malfunctions, howsver, is inadequate maintenance. All devices and system wiring should be tested and maintained by professional fire alarm installers following writlen procedures supplied with each device, System inspection and testing should be scheduled monthly or as required by National and/or local fire codes. Adequate writlen records of ell inspections should be kept. FCC Warning WARNING: This equipment generates, uses, and can radiate radio frequency energy and H not installed and used in accordance with the instruction manual, may cause interference to radio communications. It has been tesied and found lo comply with the limits for class À computing device pursuant to Subpar 8 of Part 15 of FCC Rules, which is designed lo provide reasonable protection agalnst such interference when operated in a commercial environment. Operation of this equipment in a residential area is likely to cause interference, in which case the user will be required to correct the interference at his own expense. Canadian Requirements This digital apparatus does not exceed the Class A fimlts for radlafion nofse emissions from digital apparatus set out in the Radio Interference Reguiations of the ‘Canadian Department of Communications. Le present apparel numerique n'emet pas de bruits radioslectriques depassant ies miles applicables aux apparels numeriques de la classe À prescrites dans le Raglament sur le brouillage radioslectrique edicts par le ministers des Communica. tions du Canada. CONTENTS 1. SYSTEM OVERVIEW -..navnnannvennaounnnnanaranannannane na nunano nena nanco nacen 6 1.1 Agency Standards and Compliance ... 6 1.2 General Description vee e...>.. 7 1.3 MICRO-200- Features ... 8 1.4 Controls and Indicators .. нынче. . 9 1.4.1 Membrane PANEl ….….……urrasseacerrensranmeces reneacareneasreccanrenserencansenee 9 1.4.2 Local SOUNder ……..…..….…………cccerceracesreserenenren renrarmenrernenaaencecceraven cac s 9 1.4.3 Output Circuits ..................=ee=mereerereanrererececerreeareeereeoo reee. 9 1.4.4 Relays ..................re0ecerrecricoeonannecacco rene ner ene onereeecarerenenena cecenennonanas 9 1.5 Components .. an. .. eoranzananano 17 1.6 Optional Devices .................===.e==e. enano eo. .. ..... 13 1.6.1 Option Slot .............e..=ee.een eee rre are ee rn reee 13 1.6.2 Optional Devices — Intelligent Detectors (Notifier) ...................... 14 1.6.3 Optional Devices: Addressable Modules (Notifier) ..................... 14 1.6.4 Other Optional Devices ...............c.......ce000re e De DD. 15 1.6.5 Optional Devices — Alphanumeric Display ..................e.eeeecerenes 16 1.6.7 Optional Devices — ElA-232 Port ....................ececrcervesmee eee 16 1.7 Specifications a 17 1.8 Cabinet Dimensions ..........e.n=aseesenaannenanas .. ... 18 A N 19 2.1 Installation Overview . sv... 19 2.2 Backbox Mounting FT ... I . 19 2.3 POWET ..........eenuanonanornnaanenooe osuna enen ra anae nene neranan anta rn eene dana nareneo nene neranas 20 2.4 Output Circuits .. IN — 21 2.5 Standard Relays .... .. ‚ 21 2.6 Remote Printers/CRT (Notifier) ........... .. „. 22 2.7 Wiring the Signaling Line Circuit . „... 24 2.7.1 The Isolator Module .............e....e.eemereermerie ee e e ee ee eee 30 2.7.2 The Monitor Module..................................eeereecie enana recnereecone. 30 2.7.3 The Control Module (Notifier) ..................e..e-...— cera een. 36 2.7.4 The Addressable Manual Pull Station (Notifier) ........................ 40 2.7.5 The Intelligent Detector (Notifier) ee 41 Lexan® 15 a registered trademark of GE Plastics, Inc. 3. Programming and Status Change ............me==es2annneeencornm. 43 3.1 Program/Status Change Entry .. 43 3.2 Program Change Operation . peenenonana SS 43 3.2.1 Clear (0) ..................oe...oeea0ecercarocacoconaosarcone cenar e nr aren noo cenerro ro necocces 44 3.2.2 Autoprogram (1) ....................eee.=. eses ee eran ener ecerrene. 44 3.2.3 Point Programming (2) ....................ermimeienreneno encore nene Renee. 47 3.2.4 Password Change (3) .................e2essereseerecororirecoe rene nereearenceereeccas 48 3.2.5 Message Change (4) ......................reserrerecenerioe anno ee rece 48 3.2.6 Zone Change (5) ..................ewecermesasiorarconene cero ranaenancaraanacenres 48 3.2.7 Special Zone Change (6) .....................e=eeso0c00rimicer e e 49 3.2.8 System Function Programming (7) ................e.........esrececenzeccencea 50 3.2.9 Upload/Download ....................e....e.esericarenencar ener nanencoeo recen 50 | 3.2.10 CHECK (B) nece en eneenen een eaerenanceraareacee 50 — 3.3 Status Change Operation 51 3.3.1 Disable/Enable (1) ...............—.—.ec.encazariaaa neon orar eeerecacacare. 51 3.3.2 Detector Sensitivity (2) .............e.e.esrerieereren cer ere ener 51 3.3.3 Clear Verification Counters (3) .................e.e...r2ceeencne ee 51 3.3.4 Clear History (4) ........…………erereresarsonconnessmerarensaesennvansavaneccrananvavane 52 3.3.5 Set Time/Date (5) .…..….…......…ercreeosssenenessersastenvencenverranseccancan nes 52 A 52 4. Operating Instructions ..........e==...====eneserres aereas 53 4.1 Switch Functions 53 Acknowledge/Step ..................... sees nene enero e seem e renee snes saes 53 AJRITN SHIBNCE weenie caer ee ees meressesessssesmmmenensassesessasens 53 Drill ..........e.e. reconocen en snanececranceaocacenan esa nanD ere ereen a ereareoceeaeanenenananorcecarrames 53 System Reset....................errecevcrcecnccaroncero rencor ene era oo nereeno near reeeenee. 53 4.2 LED Indicators ....... 54 AC Power ...................cen..eeiaraaaoneo enero nenene eo sasss tenes en sees sass snsnessnnsnsesan 54 Pre-Alarm Warning ....................-eserreriee en e eee one nen rene eareneee b4 SUPEIVISOTY ere een nero erereenarcanereresercencace 54 Alarm Silence ....................—......eseee eee ener eee neon reoeneaneareenereecacae 54 System Trouble ..............................eerrescereneriner o eeneenenerenrcenre recen. 54 4.3 Normal Operation ...................essermesconon.. . 54 4.4 Trouble Operation. u. 55 4.5 Alarm Operation . 55 4.6 Supervisory Operation ... ; 56 4.7 Non-Alarm Point Operation . 56 4.8 Trouble Monitor Point Operation 56 4.9 Notification Appliance Circuit Operation ......... . 57 4.10 Control-By-Event Operation .............=...ee=ee=acarracrreene 57 4.11 Releasing Functions . . 57 4.12 Intelligent Detector Functions 57 50604:F = ey 4.13Time Functions u. 59 4.14 Coding Operation (NAC only) nEMREMURARUUEO ... 59 4.15 Pre-signal/PAS Operation .. SS : ... 59 4.16 Special System Timers I вече... 60 4.17 Style 6 Operation ............e........ aneurennenmane neue . 60 4.18 Read Status ......... . un 61 4.19 History Operation 64 Appendix À — Power Supply CalculationS as 65 Appendix B — NFPA StandardS essen 71 Appendix C — ANNUNCIAÎOIS …....….………rssassessensenenançentennnss 72 Appendix D — Releasing Applications ………….…………………cccoe 76 Appendix E — Wire Requirements ..............——— meseros 80 Appendix F — Pre-Alarm (AWACS™) Applications .......... 81 Appendix G — Pre-signal/Positive Alarm Sequence (PAS), Coding, and Time Control. ..................... 84 Appendix H —Terminal Interface Protocol ...................... 85 Appendix | —~ AVPS-24 Power Expansion ...........-..e.e=..=... 92 Appendix J — UL Power-limited Wiring Requirements .............«<==e.e-eornieean ener nearar.ennanaacanoneoenramene 94 Appendix K — U.S. Coast Guard ........ e... 95 1. System Overview 1.1 Agency Standards and Compliance This Fire Alarm Contro! Panel complies with the following NFPA standards NFPA’ Marine Approvals (Require CAB-AM) The installer should be also familiar with the following documents and standards Underwriters (Up) Laboratories Underwriters Laboratories of Canada (ULC) Other NFPA 12 CO2 Extinguishing Systems (High Pressure Only) NFPA 12A Halon 130] Extinguishing Systems NFPA 12B Halon 1211 Extinguishing Systems NFPA 13 Sprinkler Systems NFPA 15 Water Spray Systems NFPA 16 Foam/Water Deluge and Foam/Water Spray Systems NFPA 17 Dry Chemical Extinguishing Systems NFPA 17A Wet Chemical Extinguishing Systems NFPA 72-1993 Central Station Fire Alarm Systems Protected Premises Unit (re- quires Notifier DACT). NFPA 72-1993 Local Fire Alarm Systems. NFPA 72-1993 Auxiliary Fire Alarm Systems (requires 4XTM or RTM-8). NFPA 72-1993 Remote Station Fire Alarm Systems (requires 4XTM or Notifier 911AC DACT). NFPA 72-1993 Proprietary Fire Alarm Systems (Protected Premises Unit). NFPA 2001 Clean Agent Fire Extinguishing Systems United States Coast Guard — Fire Protection System* Lloyd's Register — Marine, Offshore and Industrial Category ENV] and ENV2* NFPA 72-1993 Initiating Devices for Fire Alarm Systems NFPA 72-1993 Inspection, Testing and Maintenance for Fire Alarm Systems NFPA 72-1993 Notification Appliances for Fire Alarm Systems UL 38 Manually Actuated Signaling Boxes UL 217 Smoke Detectors, Single and Multiple Station UL 228 Door Closers — Holders for Fire Protective Signaling Systems UL 268 Smoke Detectors for Fire Protective Signaling Systems UL 268A Smoke Detectors for Duct Applications UL 346 Waterflow Indicators for Fire Protective Signaling Systems UL 464 Audible Signaling Appliances UL 521 Heat Detectors for Fire Protective Signaling Systems UL 864 Standard for Control Units for Fire Protective Signaling Systems UL 1481 Power Supplies for Fire Protective Signaling Systems UL 1971 Visual Signaling Appliances UL 1076 Proprietary Burglar Alarm Systems Standard CAN/ULC-8527-M87 EIA-485 and ELA-232 Serial Interface Standards NEC Article 300 Wiring Methods NEC Article 760 Fire Protective Signaling Systems Applicable Local and State Building Codes Requirements of the Local Authority Having Jurisdiction *Approval does not apply to optional 911AC Digital Alarm Communicator/Transmitter or optional UDACT Universal Digital Alarm Communicator/Transmitter, 50604:F 1.2 General Description The MICRO 200-1 is a compact, cost-effective, intelligent fire alarm control panel with an extensive list of powerful features. The power supply and all electronics are contained on a single circuit board, providing a complete fire control system for most applications. Optional modules which plug into the main circuit board are available for special functions. Nate: Unless otherwise notated, general terms are used throughout this manual to reference the specific part numbers shown in the table below: Genera! Term Specific Part Number(s) CMX (Notifier) CMX-1 or CMX-2 CRT (Notifier) CRT-2 MMX (Notifier) MMX-101, MMX-1, or MMX-2 РАМ {Мы ег) PRN-4 50604:F 1.3 MICRO-200-I Features Single standard communication (SLC) loop, meets NFPA Style 4, 6, or 7 requirements 198% intelligent device capacity Overall 301 point capability Four Notification Appliance Circuits standard Optional eight-zone relay module with transmit- ter Optional 911AC Digital Alarm Communicator/ Transmitter Optional UDACT Universal Digital Alarm Com- municator/ Transmitter LCD-80 liquid crystal display, mounts up to 6,000 feet from panel ACS annunciators, including LDM custom graphic annunciators ACM-8R remote relay module, increases point capacity Printer interface Real time clock, with European format option History file with 650 event capacity Intelligent features « Sensitivity display in percent * Manual sensitivity adjustment » Day/Night automatic sensitivity adjustment - Drift compensation (U.S. patent pending) * Auto detector test (meets NFPA 72E) « Maintenance Alert « Pre-Alarm (AWACS — 2 levels) + LED blink control Releasing features * Four independent hazards * Cross zone (three methods) * Delay timer + Soak timer Abort — four options Manual release Waterflow (non-silenceable) selection per module point Supervisory selection per point with separate LED Alarm Verification Walk Test Positive alarm sequence (PAS) pre-signal per NFPA 72-1993 Silence Inhibit timer option Auto silence timer option March time/temporal code Two-stage option for Canada California code Tomado waming code Remote Ack/Silence/Reset/Drill via MMX Monitor Modules Automatic time control functions, with holi- day exceptions Autoprogram (learn mode) reduces installation time Password- and key-protected nonvolatile mem- ory. Programmable from a PC using the PK-200 programming utility Rapid poll algorithm for manual stations (U.S. patent pending) Operates up to 1,000 ft. with untwisted, unshielded wire (U.S. Patent 5,210,523) Operates sounder base on Action Pre-Alarm level with general evacuation on alarm level. Burglar alarm point option. Critical process monitoring Read status on program via modem using dial- up phone lines. Marine cabinet option (CAB-AM) 50604: F 1.4 1.4.1 1.4.2 1.4.3 1.4.4 50604:F Controls and Indicators Membrane Panel The MICRO-200-1 membrane panel includes windows for the Liquid Crystal Display (LCD) and six LEDs. The control panel has 21 keys, including a 12-key alphanumeric pad, similar to a telephone keypad. Slide-in labels for the six LEDs and the four main operator switches are included. Refer to Figure 1 for the location of switches and LEDs. | LED Indicators AC Power (green) » System Alarm (red) * Pre-Alarm Warning (yellow) « Supervisory/Security (yellow) * Alarm Silence (yellow) « System Trouble (yellow) Operational switches = Acknowledge/Step * Alam Silence ° Drill * System Reset (lamp test) Service/program switches + Twelve-key pad with 0-9, *, # * Four cursor keys (Up, Down, Right, Left) + ENTER key Local Sounder The piezo sounder provides unique sounds for alarm, trouble and supervisory/security conditions. Output Circuits The MICRO-200-I output circuits consist of four Class B (Style Y) Notification Appliance Circuits (NACs) or releasing circuits (fully programmable). Relays The control panel includes three dry contact relays for system alarm, system trouble, and supervisory. Con- tacts are rated 2 A at 30 VDC and 0.5 A at 30 VAC (resistive). ТВ? JP2 Extamal ТВ! ification Ci TB3 Charar DC Power Notification Circults Relays TEA TBE TBE a Battery Fault LED High Rate Charge LED by IY «ij — NE Tut, Alpha-numaric programming keypad M fn ue AY LCD JP1 Cut for Ammeter function Cursor and Enter Kays AC Power and Circult Breaker 6 LED Indicalors Earth Ground 4XMM Fautt LED Meter Moduia Option Figure 1: Connections and Controls (shown with dress panel removed) 10 SW3 AC Delay Reporting ElA-485 Salect Laft=Tarminal Right=ACS Four Control Swilches 50604:F 1.5 Components Circuit Board At the heart of the MICRO-200-I control panel, the ay circuit board contains the system's central processing BREN unit (CPU), power supply, and other primary compo- ments, It is delivered pre-mounted in the cabinet (see “na elo | te FAL AT a O | © [ee] Eo ево | | > o Ex J---)O The circuit board mounts in a compact (16.125" x 14.5" x 5.5") CE W cabinet with a Lexan® front dress plate. The cabinet provides space SEE ET ) MP Put et A i= de] ye A for two batteries (up to 12 AH). LCD Display - re ra Ar pa a TETE The control panel uses an 80-character LCD I Ts display (4 X 20 characters). The display includes a long-life LED backlight that remains illuminated unless AC power is lost while the system is not in alarm. 11 50604:F Membrane Switch Panel > j The membrane switch panel provides LED indicators and operational o 0 (3) E CE switches (ACKNOWLEDGE, SILENCE, DRILL, RESET). The © O (5) E. я operational switches and LEDs are visible with the cabinet door (7) (8) © pe ma closed. The programming switches are visible only with the door COLO EEE bis I open. Slide-in labels are provided for switch and LED description. OFT ' я LL YA LEA | MARE 1? Pr 1 EEN ALO wen |: Ear 1 a O | В Iz | JAN a TEM NETA bad E | o ACH HESET | { Transformer Assembly Two 100 VA transformers and connector. Batteries , q 0 The cabinet provides space for 7 AH or 12 AH batteries (for 17 AH batteries use the BB-17 battery box). Batteries must be ordered separately. 12 SO604F 1.6 1.6.1 Optional Devices Option Slot The circuit board includes an option module slot located on the right side of the board. When an option module 1s installed, jumper JP5 located to the right of the membrane switch pane! must be cut. The option slot supports one of the modules described below. Meter Module The 4XMM Meter Module provides a voltmeter to measure voltage across the batteries and an ammeter to measure charging current to the batteries. A single assembiy containing both meters mounts in the lower left- hand corner of the MICRO-200-I cabinet. Trim Ring ° The TR-4XG gray trim ning 1s available for semi-flush mounting of the control panel cabinet. Battery Box The BB-17 battery box may be used to mount two 17 AH batteries. The box mounts directly ^ below the control panel cabinet. Г с к > Dress Panel A dead front dress panel (DP-AFP200) is available as an option (required for Canadian installations). Expansion Power Supply Power supply model AVPS-24/AVPS-24E provides an additional 3 A of notification appliance power. Refer to the Device Compatibility Document for compatible notification appliances. Marine Cabinet Cabinet CAB-AM 1s required for applications requiring United States Coast Guard or Lloyd's Register approvals. 13 1.6.2 Optional Devices — Intelligent Detectors (Notifier) These intelligent, addressable detectors provide analog information to the MICRO-200-I contro] panel, which continually processes this information to determine the alarm, mainte- eu nance, or normal status of each device. Each detector head mounts to a B501 Flangeless wl Base, BX-501BH Base (illustrated at left) or BHX-501 Sounder Base for ease of installa- mE tion and replacement. The sensitivity of each detector can be set by the programmer at the contral panel to one of three levels (low, medium, or high). Each detector responds to an address that 15 set in the head by adjusting built-in rotary decimal switches. BX-501BH Base - — SDX-5511H/SDX-551TH*/SDX-751* (Notifier) These Intelligent Photoelectric Smoke Detectors provide analog measurements of the optical smoke level in the detector chamber to the control panel. The detectors are available as the SDX-551TH* with 135° thermostat and as the SDX-751 low profile photoelectric detector. CPX-551/CPX-751* (Notifier) These Intelligent Ionization Smoke Detector measure the level of combustion products in the detector chamber using the ionization principle and report this measurement to the control panel. Also available as CPX-751* low profile detector. FDX-551 (Notifier) An Intelligent Thermal Sensor (140° F fixed temperature), which is also available as an FDX-351R* which is a combination 135° F fixed and 15° F per minute rate of rise. DHX-501, DHX-502 (Notifier) These are duct housings for the SDX-551 and CPX-551. When used in duct applications, the CPX-551 must be set to high sensitivity. *The SDX-551TH, SDX-751, FDX-551R, and CPX-751 are not approved by U.S. Coast Guard or Lloyd's Register. 1.6.3 Optional Devices: Addressable Modules (Notifier) The CMX Series Control Modules and the MMX Series Monitor Modules provide an interface between the control panel and conventional initiating and notification devices. All module types respond to an address that is set by the installer with built-in rotary decimal switches. A flashing LED indicates power is applied. A thermo- plastic cover is provided with each module for mounting to a four-inch square mounting box. MMX-1/MMX-2 (Notifier) These are Addressable Monitor Modules that can be used to monitor conventional initiating devices. The MMX-1 is used for normally open contact alarm initiating devices, such as manual pull stations, four-wire smoke detectors, heat detectors, waterflow, security contacts, and supervisory devices. The MMX-2 may be used for two-wire smoke detectors in addition to normally open contacts. Supervised circuit can be wired NFPA Style B or Style D. CMX-1/CMX-2 (Notifier) These are Addressable Control Modules that can be used as Notification Appliance Circuits for powering and supervising compatible, UL-listed notification appliances. Supervised circuits can be wired NFPA Style Y or Style Z. By breaking the two built-in tabs, the CMX can be used as a Form-C control relay. The CMX-2 is rated for higher voltage applications (70,7 У). 50604:F 1.64 50604:F The MMX-101 Addressable Module is functionally similar to an MMX-1 Monitor ISO-X (Notifier) “© o| [o The ISO-X Loop Isolator Module is an automatic switch which opens the circuit - . voltage to a communications loop branch whenever a fault is detected on that circuit. The remainder of the communications loop leading up to the ISO-X will a continue to operate, unaffected by the fault. MMX-i01 (Notifier) Module (Style B circuits only), but offered in a smaller package for mounting directly in the electrical box of the device being monitored. It does not include a blinking LED or a magnetic test switch. BGX-101L (Notifier) An Addressable Manual Pull Station featuring a key-lock reset. The pull station responds to an address set by the installer with built-in rotary decimal switches and includes a key. Other Optional Devices System Sensor (SSD) A2143-00 The 47K End-Of-Line Resistor Assembly 1s used in the supervision of MMX-1 or MMX-101 Monitor and CMX Control Module circuits and is included with each [aa module, Note: MMX-2 Monitor Module requires a UL-listed 3.9K ELR. N-ELR The N-ELR Resistor Assortment is required for use in Canada. Resistors can be _ used for the supervision of an MMX Monitor Module or CMX Control Module 9 circuit, 15 1.6.5 1.6.7 16 Optional Devices ~ Alphanumeric Display LCD-80 (Notifier) This alphanumenc display module is an ancillary device used by the contro! panel. It has two modes of operation. In Terminal mode, it acts as a display repeater and in ACS mode it acts as an alphanumeric annunciator. The display module features an 80-character LCD display that is backlit under normal and alarm conditions. It contains control switches for Acknowledge, Signal Silence and System Reset, a Time/Date display field, and a local piezo sounder with alarm/troubie resound. The LCD-80 can be mounted up to 6,000 feet from the contro] panel in an ABF-1 package. Up to four of these annuncia- tors can be installed on a system (observe power limitations). ACS Mode provides a remote or local digital display and a printer interface for the control panel. In addition, this mode offers the following features: * General status banner. * 40 character custom label. « ‘Alarm/trouble count. Custom “normal” message. « First alarm/last alarm/alarm count (European option). » Field-programmable messages (foreign language versions). « STEP DISPLAY and TIME/DATE SET switches. + Field programmable, nonvolatile memory in two options (128 points, 40-char- acter labels or 256 points, 20-character labels). * Internal nonvolatile clock. Terminal Mode offers the following features: » Device type identifiers from control panel. * Device and zone custom alphanumeric labels from contro} panel. * Time/date and device address from control panel. This mode 1s usually preferred over ACS mode because no programming is necessary. Optional Devices ~ EIA-232 Port PRN Remote Printer (Notifier) This printer provides a printout of all status changes within the system and time-stamps the printout with the current time and date. The PRN provides columns of data on standard 9" x 11" tractor-feed paper. CRT Terminal (Notifier) The CRT terminal provides a video display of status and a full keyboard for access to status information, 50604:F 1.7 S0604:F Specifications Primary AC Power * For the MICRO-200-1: 120 VAC, 50/60 Hz, 3.0 A. * For the MICRO-200-1E: 220/240 VAC, 50/60 Hz, 1.5 A. * Wire size; minimum 14 AWG with 600 VAC insulation. Battery (lead-acid only) * Maximum Charging Circuit — Dual Rate High Charge is 29.1 V @ 0.7 A; Normal Flat Charge is 27.6 V @ 0.5 A. * Maximum Battery Capacity — 17 AH. (Batteries larger than 12 AH require a BB-17 or other UL-listed battery cabinet.) Communication (SLC) Loop * 24 VDCnominal, 27.6 VDC max. « Maximum length is 10,000 ft. per channel (NFPA Style 4) or 10,000 ft. total twisted-pair length (NFPA Style 6 and 7). ° Maximum loop current is 250 mA (max short circuit) or 100 mA (normal). ° Maximum loop resistance is 40 ohms. + Supervised and power-limited. Notification Appliance and Releasing Circuits * Power-limited circuitry. = Max. wiring voltage drop: 2 VDC. * Normal Operating Voltage: 24 VDC. * NAC circuit 1=2,5 A ° NAC circuits 2-4 = 2.5 A shared total * Current for all external devices: 5.0 A. * Optional AVPS-24/AVPS-24E: additional 3.0 A of notification appliance power (see Appendix I). ® Max. signaling current/circuit: 2.5 A. ° End-of-line resistor: 4.7K, 1/2-Watt (PN 71252 UL-listed) for Notification Appliance Circuits. * REL-4.7K for releasing circuits (REL47K for use with CMX). Alarm, Trouble, and Supervisory Relays Power-limited circuits only. Contact ratings: » 2.0 A@ 30 VDC (resistive), 0.5 A @ 30 VAC (resistive). * Alarm and Trouble: Form-C. * Supervisory: Form-A., Four-wire Smoke Detector Power (24 VDC + 5%) — TB1 terminals 5 and 6 ° Max. ripple voltage: 10 mVmms. » Up to 500 mA is available for powering four-wire smoke detectors'* Non-resettable Regulated 24 V Power (24 VDC + 5%) — TB1 terminals 3 and 4 * Max, Tipple voltage: 10 mVrms. * Total DC current available from this output is up to 500 mA (subtracted from four-wire smoke power)”, High Ripple Regulated 24 V Power (24 VDC :=10%) — TB1 terminals 1 and 2 + Max. ripple voltage: 2 М выс | * Total DC current available for powering external devices is 1.0 A standby and 1.5 A alarm’. * This power is not recommended for LCD-80 or ACS annunciators except for ACM-8R ‘For power supply calculations, refer to Appendix A. ‘Total current for regulated power, non-resettable power, four-wire smoke power, and four Notification Appliance Circuits must not exceed 5 A or 8 A if using an AVPS-24 (refer to Appendix I). Total external system current in excess of 2.5 A requires 12 AH or 17 AH batteries—not 7 AH, 17 1.8 Cabinet Dimensions 1.8.1 Surface Mount with BB-17 Battery Box Door = 14,825" 1 Backbor = 14.5" "| Door = 16.125" Backbox = 16.0" TE 1 4 4 Battary Sox = 14.5" Щ (Optiona! BB-17) I 1.8.2 Semi-flush Mount FF —— W— Trim Ring = 17.52" -yY TR4XG Trim Ring Follow — instructions supplied with > ring for mounting. Trim Ring = 19.17" 18 | Depth=5.5° | | w 4,75 | je — 1.5" typical lor 4" wal S0604:F Installation 2.1 Installation Overview Carefully unpack the system and check for shipping damage. Mount the cabinet in a clean, dry, vibration-free area where extreme temperatures are not encountered. The area should be readily accessible with sufficient room to easily install and maintain the control panel. Locate the top of the MICRO-200-I cabinet approximately 60 inches above the floor with the hinge mounting on the left. Determine the number of conductors required for the devices to be installed. Pull the required conductors into the box through the knockouts provided. an wiring should be in accordance with the national and/or local codes for fire alarm systems. 2.2 Backbox Mounting 1. Remove the main circuit board assembly by unscrewing the four screws in the corners of the board, Set the board aside in a safe, clean place. Avoid static discharge which may damage the board. 2. Mark and predrill the four mounting bolts using dimensions shown in Figure 2. 3. Install two upper fasteners in wall with screw heads protruding. 4. Using upper “keyholes,” mount the backbox over the two screws. Tighten the screws. 5. Install the lower two screws. 6. When location is dry and free of construction dust, reinstall the main circuit board. 14.5 > te 1-00). 12.5 > + | o o 0.5 : X--- a Aa o 9.5 - 16.0 © ee eee eee ни O. О —/ N— o D Ÿ Figure 2-1 Cabinet Dimensions 50604:F 19 2.3 Power CAUTION: Several different sources of power can be connected to the MICR(Q-200-1. Disconnect all sources of power before servicing. The control panel and associated equipment may be damaged by removing and/or inserting cards, modules, or connecting cables while this control panel is energized. High Ripple Regulated Power 24 VDC power for notification appliances. Four-wire Smoke Detector Power 24 VDC filtered, - regulated, resettable power for TB1 terminal 1 (+) and 2 (-). Note: This Non-resettable Power EA be | 24 VDC filtered, regulated, non- our-wire smoke detectors can power is unsuitable for all E{A-485 abi bed obtained from TB1 terminals 5 annunciation devices, except the ACM-BR. — > 45€ power can be drawn from TB1 terminals 3 (+) and 4 (-). (+) and 6 (-). O O” > O. o o Figure 2-2 DC Power Output Connections (All DC power outputs are power-limited) AC Power connections Primary power required for the MICRO-200-1 is 120 VAC, 50/60 Hz, 3 A and primary power required for the MICRO-200-1E is 220/240 VAC, 50/60 Hz, 1.5 A. Overcurrent protection for this circuit must comply with Article 760 of the National Electrical Code (NEC) and/or local codes. Use 14 AWG or larger wire with a 600 VAC rating. Battery Power Observe polarity when connecting battery. Connect the battery cable to J3 on the main circuit board using the plug-in connector provided. Refer to Appendix A for instructions on calculating the correct battery rating. CAUTION: Battery contains sulfuric acid which can cause severe burns to the skin and eyes, and can destroy Jabrics. If contact is made with sulfuric acid, immediately flush skin or eyes with water for 15 minutes and seek immediate medical attention. AVPS-24/AVPS-24E (Notifier) Optional Power Expansion A <-> > cr Y mele B= Y OW (Refer to Appendix I) o AC Power Battery Power | Figure 2-3 AC and Battery Power Connections 20 50604:F 2.4 Output Circuits Notification Appliance Circuits The MICRO-200-I control panel provides four Notification Appliance Circuits (Style Y). Each circuit can supply up to 2.5 A of current. Total current drawn from these as well as DC power outputs cannot exceed 5.0 A. An additional 3.0 A are available when using an AVPS-24/AVPS-24E (see Appendix I). Use UL-listed 24 VDC notification appliances only. Circuits are supervised and power-limited. Refer to the Device Compat- ibility Document for a list of compatible notification appliances. Releasing Circuits Any or all of these circuits may be used as a releasing circuit by programming it for RELEASE CKT. Refer to the Device Compatibility Document for a list of compatible releasing devices. 4.7K, 1/2-Watt (PN 71252 UL-listed) {I ——— Polarized Bsl| fe Note: Notification circuit polarity shown in alarm state, Releasing Circuit (supervised and power-limited) Polarized Strobe = + - Dummy Load all od REL4.7K unused Circuits Polarized Horn 4.7K, 1/2-Watt Style Y Notification Appliance Circuit (supervised and power-limited) | 2 3 4 5 6 7 8 "| 9O9O0090100000000|"00000000 U 2 ТГ F 3 1} 1—= "+ - 4+ - + 8+8-8+B-B+B-B+B- NO C NO NC C NO NC C Figure 2-4 Circuit Connections 2.5 Standard Relays The MICRO-200-I control panel provides a set of Form-C alarm and a set of Form-C trouble contacts rated for 2.0 A @ 30 VDC (resistive). The control panel also provides a Form-A supervisory contact rated for 2.0 A @ 30 VDC (resistive). SUPV ALARM TROUBLE 00000000 NO с NO NC с NO NC C Wo IA VDDO TX REF TX REF > À Figure 2.-5 Relay Connections S0604:F 21 =“. 2.6 22 Remote Printers/CRT (Notifier) The PRN-4 remote printer provides a hard-copy printout of all status changes within the system and time-stamps the printout with the current time and date. The PRN-4 provides 80 columns of data on standard nine-inch by eleven-inch tractor-feed paper. Installation Remote printers require 120 VAC, 50/60 Hz primary power. A secondary power source (battery backup) is not provided. The use of a separate uninterruptable power supply (UPS), UL-listed for Fire Protective Signaling is recommended. Connection between the control panel and the PRN-4 is via an EIA-232 interface. A custom cable must be assembled for connection to the printer's ELA-232 port. Printer Configuration Refer to the documentation supplied with the PRN-4 for instructions on the printer’s menu controls. Set the printer's options as listed in Figure 2-6. OFTION SETTING L/R ADJUST о FONT HS DRAFT LPI 6 CPI ESC — CHARACTER — |FSC BIDIRECTIONAL | COPY CG-TAB GRAPHIC COUNTRY E-USE ASCH AUTO CR 15 COLOR OPTION ÍNOT INSTALLED FORMLEN: LINES 6 LIP-50 STANDARD “— |EXECUTIVE 10.5" CPI 10 CPI SKIP 0.5" EMULATE EPSON VO: 36k BAUD 2400 FORMAT 7 BIT, EVEN, 1 STOP PROTOCAL | XON/XOFF ‘CHARACTER CHA STANDARD S1. ZERO ON AUTO LF OFF MENLOCK ALL PAPER: BIN 1 12/72" BIN 2 1272" SINGLE 1272 PUSHTRA |1272° PULL TRA 12772" PAP ROLL 12/72" PAPORT NO Figure 2-6 PRN-4 Remote Printer Options 1 . A AN ® Plug the DB-9 or DB-25 connector into the ElA-232 port of the printer. HOT > 38 Note: The ETA-232 printer interface may [= Ae DB-25 Connections: Connect TX (Pin 3) to TB4 terminal 1 Connect REF (Pin 7) to TB4 terminal 2 Connect RX (Pin 2) to TB4 terminal 3 DB-9 Connections: Connect TX (Pin 2) to TB4 terminal 1 Connect REF (Pin 5) to TB4 terminal 2 | Connect RX (Pin 3) to TB4 terminal 3 __ Note: If also using a DB-S connector for | upload/download connect a jumper between pin 4 and pin 6. @| 2000| [000606 —+—— REF OUT OUT MIN also be used with EDP-listed equipment, such as personal computers, to monitor the control panel for supplementary purposes. Figure 2-7 Remote Printer Connections A B Br Ar EB A ТВБ 506504:F = FET 4 . 2.6 Remote Printers/CRT, continued Plug this DB-25 connector into the ElA-232 port of the CRT. | Figure 2-8 CRT Connections Twisted Pair / Ц I e co0000d0008d0 e 0000906000000 To AUX Port of CRT Appendix H.) 9000600000660 © po000e0/ @ 0000002000000 To EIA Роя о? пех СЕТ ог РЕМ | E + ool loo oo x REF RX REF 006006 x DUT OUT IM IM AL A B Be AY Dé TBS TB6 Connect TX (Pin 3) to TB4 terminal 1 Connect REF (Pin 7) to TB4 terminal 2 Connect RX (Pin 2) to TB4 terminal 3 Ta TB4-2 To TB4-1 1 сосособассё Во e ? 7/0 0900090600000 To EIA Port of CRT with keyboard Note: This configuration requires that the copy parameter of the CRT setup be changed to BCOPY (Refer to CRT configuration in To TB4-3 Figure 2-9 Connections For Multiple CRT units or CRT/PRN Combination Note: For terminal interface and protocol information, refer to Appendix H. S0604:F 23 2.7 24 Wiring the Signaling Line Circuit Communication with intelligent and addressable initiating monitor and control devices occurs through a signaling line circuit (SLC) loop, often referred to as the communications loop. This SLC loop can be wired to meet the requirements of NFPA Style 4 (see Figure 2-12), Style 6 (see Figure 2-13) or Style 7 (see Figure 2-14). Isolator Modules Isolator Modules (ISO-X) permit a zone of detectors and modules to be electrically isolated from the remainder of the communications loop, allowing critical loop components to function in the event of a circuit fault (see the figures on the following three pages). Isolator modules are required to meet the requirements of NFPA Style 7. Monitor Modules Addressable Monitor Modules (MMX Seres) allow the control panel to monitor entire circuits of conven- tional, alarm initiating devices, such as manual pull stations, smoke detectors, heat detectors, waterflow and supervisory devices. A type of Monitor Module, the addressable MMX-101 provides point annunciation of manual] pull stations. Control Modules Through addressable control modules (CMX Series), the control panel can selectively activate Notification Appliance Circuits or Form-C output relays. Intelligent Detectors Through the communications loop, the control panel communicates with intelligent ionization, photoelectric, and thermal detectors. Device Capacity MICRO-200-I capacity includes up to 99 intelligent detectors and an additional combination of up to 99 addressable pull stations, control modules, and Monitor Modules. In addition, the control panel also supports four Notification Appliance Circuits and up to 99 programmable relays. Note: Refer to Appendix A and installation drawings supplied with each loop device for rating and specification information. Single Open Single d on Shorted Loo Loop Shorted {Loop Shorted (Loop Opened |Communicatl- on Loop Loop P land Opened {and Grounded | and Grounded | опа Сока Style 4 (2 wire) Loop Alarm Operation Trouble! Troubi Troubl Troubi Trout! (Meets NFPA 72 Style 4 a Capabilly rouble Trouble rouble rouble rouble Requirements) rou Oration wire) Loop Alarm Alarm Alarm (Meets NFPA 72 Style 6 Capabliity re Trouble Trouble Trouble Capablliy Trouble Trouble Trouble rouble Raquirements) or 9) - {Alarm Alarm Alarm Alarm Alarm {Meets NFPA 72 Style 7 Capabliity Capability Capability Trouble Capability Capability Trouble Requirements) Trouble Trouble Trouble Trouble Trouble Figure 2-10 Communications Loop Performance I Trouble indicates a trouble signal will be generated at the control panel during the abnormal condition. “Alarm Capability indicates an alarm signal can be transmitted to the control panel during the abnormal condition. ‘Loop operation meeting Style 7 requirements isolates entire physical zones on the communications loop from Jaults that occur within other areas of the loop. 50504:F 2.7 Branch B Wiring the Signaling Line Circuit, continued no connection | Branch E Branch | D — Branch C Loop Branch Out A 006000] у y A "EEE TBE For each loop, add the lengths of all the branches on one loop. This sum cannot exceed 10,000 feet (12 AWG). (Branch A) + (Branch B) + (Branch C) + (Branch D) + (Branch El = 10,000 feet or less Communications Loop Out Branch Resistance Short the termination point of one branch at a time and measure DC resistance from the beginning of the loop to the end of that particular branch. The total DC resistance from panel to branch end cannot exceed 40 ohms. Repeat this procedure for all remaining branches. For detailed wiring requirements, refer to Appendix E. Figure 2-11 Wire Requirements — Two Wire SLC Circuit Loop Out « Loop Retum DC Resistance of the Communications Loop pair cannot exceed 40 ohms, Measure by disconnecting loop out and return at the contro! panel, shorting the two leads of communications loop return, and metering loop out. For detailed wiring requirements, refer to Appendix E. No T-Tapping Allowed no connection 366666) B=Output Loop AE Bi A 8 Al A=Return Loop | TB6 Total length of the communications loop pair cannot exceed 10,000 feet (12 AWG). Figure 2-12 Wire Requirements — Four Wire SLC Circuit 50604. F 25 2.7 Wiring the Signaling Line Circuit, continued BGX-101L ( \ = + 129] BX-501 Base ` / For use with SDX, CPX and FDX series Intelligent Detectors 9 — 19 IL, 8 1|— + (8 Le + 7 e |+ +17 3 сом 6 — | 41NO NC |5 = | oT CMX MMX Separate T-Tap to other loop devices mr Led | 11— j|— A+ 214 3 |— Э|— 4|+ “|+ So ISO-X ISO-X no connection | 1 2 4 4 5 A 2000| 0000| [0060000] IX REF RX REF rows AE B+ A+ BA) TB5 TB6 Connect (+) to TB 6-3 Connect (-) to TB 6-5 Figure 2-13 Two Wire SIC Communications Loop (Supervised and power-limited -- meets NFPA 72-1993 Style 4 requirements) Note: The maximum number of devices between isolator modules is 25. 1SO-X devices are not required to meet NFPA Style d. 26 S0604:F Tr 2.7 Wiring the Signaling Line Circuit, continued BGX-101L BX-501 Base For use with SDX, CPX and FDX series Intelligent Detectors no connection OO OO| JOO OO TX REF RX REF| |OUT OUT IN IN A В B+ A+ B- A B4 TBS .. Connect Loop Qut to TB 6-3 (+) and TB 6-5 (--). Connect Loop Return to TB 6-4 (+) and 6-6 (-). Figure 2-14 Four-Wire SLC Communications Loop (Supervised and power-limited — meets NFPA 72-1993 Style 6 requirements) Note: The maximum number of devices between isolator modules is 25. ISO-X devices are not required to meet NFPA Style 4. 50604:F ВЕ 27 2.7 28 Wiring the Signaling Line Circuit, continued ISO-X ISO-X isolator Module P roteclod Promises Isolator Module mo"; Protected Premises Protected Premises Zone "1" Zone “3 1650-Х ISO-X Isolator Module ISolator Module . LOY VOD TX REF RX REF OUT OUT IN WN A В Bt At B A B4 TBS Connect Loop Out to TB 6-3 (+) and TB 6-5 (-). Connect Loop Return to TB 6-4 (+) and TB 6-6 (-). Figure 2-15 Four Wire SLC Communications Loop (meets NFPA 72-1993 Style 7 requirements) Operation By “flanking” each communications loop device with a pair of ISO-X isolator modules, each device is pro- tected from short circuit faults that may occur on other devices. For example, a fault on Zone 2 will not affect Zones 1 and 3. The isolator modules on either side of Zone 2 will open the communications loop. Zone 1 will still operate from power on loop out and Zone 3 will operate from loop return. Because the control panel will no longer be able to communicate with Zone 2, a trouble signal(s) will be generated for that device. No T-tapping or branching is allowed on this circuit. The ratings and characteristics are the same as for a four-wire circuit meeting NFPA Style 6 requirements. 50604:F 2.7 Wiring the Signaling Line Circuit, continued Shield Drain Wire Cabinet FM Loop + Do not allow the shield drain wire to enter the system cabinet. Connect the drain wire to the outside of the cabinet via a BX-type connectar. Note: scrape paint away from cabinet to make good electrical connection. Loop - . Figure 2-16 Shield Termination in No Conduit - Cabinet The shield drain wire must be Ta Loop + connected to the negative (-) side of т the loop. Do not allow the shield . drain wire or the shield foil to touch the system cabinet. Note: For Style 6 or Style 7 field wiring of the Communi- Loop - cations Loop, connect each end of the shield to the negative side of the respective channel. Shield Drain Wire The shield must not be connected to earth ground at any point. Figure 2-17 Shield Termination in Full Conduit Shield Drain Wire Do not allow the shield drain wire to enter the system cabinet or the conduit Connect the drain wire to the termination point of the conduit run. Note: The conduit = НЕЕ Must employ metal conduit cannot be longer than 20 feet. and a metal box. Figure 2-18 Shield Termination in Partial Conduit S0604F ^--` 29 2.7.1 Communications Loop | 2.7.2 30 The Isolator Module The loop isolator module (ISO-X) is used to protect critical elements of the communications loop from faults on other branches or sections of the loop. The ISO-X continuously monitors the circuit connected to terminals 3 (=) and 4 (+). Upon power-up, an integral relay is latched on. The ISO-X periodically pulses the coil of this relay. A oo г о short circuit on the loop resets the relay. The ISO-X sees this short Loon out à and disconnects the faulted branch by opening the positive side of the Loop Out (+' loop (terminal 4). This effectively isolates the faulted branch from | the remainder of the loop. Once the fault is removed, the ISO-X automatically reapplies power to the communications loop branch. Figure 2-19 illustrates the use of an 1SO-X on a two wire communi- cations loop meeting NFPA Style 4 requirements; Figure 2-15 shows a four wire loop meeting NFPA Style 7 requirements, Note: The maximum number of devices that can be connected to an isolator module is 25. During a fault condition, the control panel will register a trouble condition for each zone mapped to the isolated loop branch. —— EPT EE PP T— — T—— EE EE LL EE + В Shorts on this branch of an isolated — o 7 communications loop meeting NFPA Style 4 1SO-X requirements, will be isolated from all a 6 devices installed both upstream of the ISO-X and on the continuation of the loop 4 5 (shown as dotted line). RIT T-Tapped Branch off the Communications Loop Figure 2-19 Isolating Two Wire SLC Communications Loops The Monitor Module The MMX-1/MMX-2 Monitor Module is an addressable module that monitors conventional, alarm initiating devices. It includes a magnetic test switch located near the center front of the module. The supervised MMX circuit can be wired as an NFPA Style B or Style D Initiating Device Circuit. Refer to Figures 2-21 and 2-23 for MMX-1 wiring diagrams. The MMX-2 addressable module monitors conventional, two-wire smoke detectors. Refer to Figures 2-22 and 2-24. Communications Loop Connections Connect the communications loop to MMX terminals 1 (—) and 2 (+). The MMX occupies one module address on the loop. Use the rotary switches on the MMX to set the module to the required loop address. NFPA Style B Initiating Device Circuit Connect as shown in Figure 2-21 and 2-22. NFPA Style D Initiating Device Circuit Connect as shown in Figure 2-23 and 2-24. Power The MMX-2 requires the additional connection of 24 VDC filtered, regulated and resettable power on MMX- 2 terminals 3 (—) and 4 (+). 50604:F 2.7.2 The Monitor Module, continued The MMX-101 Monitor Module The MMX-101 Monitor Module is an addressable module that is functionally and electrically identical to an MMX-1 Monitor Module (Style B circuits only), but offered in a smaller package for mounting directly in the electrical box of the contact-type device being monitored. Sat the module address with these switches IDC +) IDC (+) Yellow] Violet) Loop (+) Loop (-) (Red) (Black) Figure 2-20 NFPA Style B Initiating Device Circuit Terminate with a 55D A2143-00 ELR (N-ELR in Canada). Notes on the MMX-1 and MMX-101 Monitor Modules 1. The Initiating Device Circuit is supervised and current limited to 210 pA @ 24 VDC (nominal). 2. The Initiating Device Circuit provides the following services {do not mix): * Fire Alarm Service. * Automatic/Manual Waterflow Alarm Service with normally open contact devices. * Sprinkler Supervision with normally open contact devices. * Security Service, 3. Due to wiring, the maximum loop resistance 15 20 ohms. The MMX-2 Monitor Module The MMX-2 Monitor Module is an addressable module used to monitor a single Initiating Device Circuit of two-wire smoke detectors. The monitored circuit may be wired an NFPA Style B (Class B) or Style D (Class A). MMX-2 Compatible Smoke Detectors Reference the Device Compatibility Document for compatible two-wire smoke detectors. 50604:F 31 bat] 1 2.7.2 The Monitor Module, continued UL-listed Power Supervision Relay End-of-Line Resistor Shown 47K, 1/2-watt Energized PN 55D A2143-00 (N-ELR in Canada) 24 VDC Four-Wire Smoke Detector jo — Manual To Next © Pull Station Device on Loop + E Heat Detector Four-wire © detector power Note: Maximum initiating device circuit Loop Out resistance is 20 ohms. MMX-1 200006) |p0000000| |p00000 00) 20 00) 0000| 0000| 54 + т) A. MO E NONE E MO ACC TE REF RX REF| [OUT OUT MM career TB1 TB2 TB3 B4 TB5 TB6 24 Y (+) TB1-5 SLC (+) TE 6-3 24 \ (-) ТВ 1-6 SLC (-) TB 6-5 Figure 2-21 NFPA Style B Initiating Device Circuit with an MMX-1 Module (supervised and power-limited) 32 50604.F 2.7.2 The Monitor Module, continued 3.9K UL-listed ELR To Next Device on - Loop + о Compatible В Two-wire Smoke A A Detectors — 1 2 3 4 Note: Maximum initiating device circuit resistance is 25 ohms. Maximum alarm current is 90 mA. Maximum detector standby current is 2.4 mA. 24 VDC filtered, regulated and resettable power | 200000] kbooo00000| kboo00000 oooo| 0000| 66 066 tt Des 6 RENE [mc mmc me TE RE RE MEF] (OUT out mM A RRE TB1 TB? TB3 TB4 TBS TBE 24 V (+) TB1-5 SLC (+) TB 6-3 24 Y (-) TB 1-6 SLC (-) TB 6-5 Figure 2-22 NFPA Style B Initiating Device Circuit with an MMX-2 Module Supervised and Power-limited Note: For more information, refer to the MMX-2 Installation Instructions, Document M500-03-00. list of compatible devices, reference the Device Compatibility Document. S50604:F Fora 33 pag ee ps mary UL-listed Power Supervision Relay SZ shown cn Energized 24 VDC Four-Wire Smoke Detector - Manual Pull To next Station device on Loop +. Heat Detector 24 VDC Note: Maximum initiating device drcuit filtered, resistance is 20 ohms. regulated and LOOP resettable OUT power 200000| P0000000| Povvvvreal 2000| JVC. [00000d| + = + = + - "0 a. MO E NO NC OC MO NC OC TE REF RX MEF] (OUT OUT MON AR Bw le TB1 | TB2 TBA TB5 TB6 | 24 Y (+) TB1-5 SLC {+) TB 6-3 24 У (-} TB 1-6 SLC (-) TB 6-5 Figure 2-23 NFPA Style D Initiating Device Circuit with an MMX-1 Module {supervised and power-limited) 34 _ | S0604:F а > 2.7.2 The Monitor Module, continued To next device on т Loop + - Compatible Two-wire Smoke A A LL Detectors 3.9K Ul-listed ELR © H © 1 2 3 4||* Note: Maximum initiating device circuit resistance is 25 ohms. Maximum alarm current M M X 2 is 90 mA. Maximum detector standby current is = 2.4 mA. 24 VDC filtered, regulated and resettable power 200000 Pero] Poor o)| 0000| 0000| 006000] + = + | x |» € юж с южс 1х REF RX REF ост ол M лв мм "| Tai TB2 ; TB3 B4 TBS TB6 24 Y (+) TB1-5 SLC (+) TB 6-3 24 Y (-) TB 1-6 SLC (-) TB 6-5 20604:F Figure 2-24 NFPA Style D Initiating Device Circuit (supervised and power-limited) Note: For more information, refer to the MMX-2 Installation Instructions, Document M500-03-00. For compatible devices, reference the Device Compatibility Document. 35 F4 2.7.3 The Control Module (Notifier) The CMX control module is an addressable module that supervises and switches power to a Notification Appliance Circuit. The CMX-1 and CMX-2 are identical except that the CMX-2 has a higher voltage rating (70.7 Y) at full current. The CMX circuit can be wired as an NFPA Style Y or Style Z Notification Appliance Circuit, Alternately, the CMX can be used as a Form-C control relay. + o Style D NAC (+) Loop (-) U - co Style D NAC (-) Loop (+) U2|+ CMX - 77 styleB NAC ( 24 VDC Power (—) (113| - +163 Style B МАС (+) s 24 VDC Power (+) 4| + 5 Figure 2-25 The CMX Control Module (Alarm polarity shown) Communications (SLC) Loop Connections Connect the communications loop to CMX terminals 1 (-) and 2 (+). The CMX occupies one module address on the loop. Set the rotary switches on the CMX to the particular loop address required. NFPA Style Y Notification Appliance Circuit Connect polarized alarm notification appliances to a single two-wire circuit. This circuit cannot be T-tapped or branched in any fashion, and must be terminated across the last device by a 47K, 1/2-watt ELR (PN A2143-00). Connect the circuit to CMX terminals 6 (+) and 7 (-). See Figure 2-27. NFPA Style Z Notification Appliance Circuit Connect polarized alarm notification appliances to a single two-wire circuit. This circuit cannot be T-tapped or branched in any fashion. No external ELR is required for Style Z wiring. Connect the four-wire circuit to CMX terminals 6 (+) and 9 (+), then 7 (=) and 8 (-). See Figure 2-28. Notification Appliance Power Connect notification appliance power to CMX terminal 3 (common) and terminal 4 (+ 24 VDC). This power must be supervised by a UL-listed power supervision relay, wired as shown in Figure 2-27 and 2-28. Test switch The CMX includes a magnetic test switch located near the center front of the module. Activation of this switch will cause a short circuit indication for the Style B/D loop. 36 0604: F 2.7.3 The Control Module, continued _ To next dovica on oop +19 - 18 - 7 CMX + 6 Common Contact 5 Normalty Ctosad Contact Normally Open Contact Break off tabs to enable Form-C operation 060066) TB6 A8 B+ Ae к SLC (+) ТВ 6-3 SLC(-) ТВ 6-5 Figure 2-26 The CMX Control Module (Form-C Relay) Break Tabs To configure a CMX as a Form-C relay, the two tabs must be broken off of the module. Use a pair of needle- nose pliers to break off each tab. Communications (SLC) Loop Connections Connect the communications loop to CMX terminals 1 (~) and 2 (+). The CMX occupies one module address -on the loop. Set the rotary switches on the CMX to the particular loop address required. Contact Connections Wire the common and the normally-open or normally-closed contacts to the CMX as required, Contact Ratings Note: Contacts are not rated for motor loads. CMX-1 CMX-2 Resistive: 2 À @ 30 VDC 2 À @ 30 VDC Inductive: 1 À @ 30 VDC (0.6 pf) 1 À @ 30 VDC (0.6 pf) 0.3 À @ 120 VDC (0.35 pf) Pilot Duty: 0.6 A @ 30 VDC (0.35 pf) 50604F 37 r=" 2.7.3 The Control Module, continued UL-listed Power Supervision Relay Note: If more than one CMX PN SSD A2143-00 Notification Appliance Circuit is (N-ELR in Canada) provided, install the power End-of-Line Resistor 47K, 1/2-watt supervision relay after the last CMX. Note: Maximum initiating device circuit resistance is 20 ohms. 24 VDC Notification Appliances To next device 1 on Loop LOOP OUT 3 CMX Note: Do not loop wiring under any terminals. Break wire run to maintain supervision. Fr 290000! Im6000000) P20200000| [22 29| 0000| j6ddd6d6] ros ее твое вы в ue на мс с но ж с TX REF RX REF| [OUT OUT WR EEE TB1 TB2 TB3 Ва TBS ТВб 24 V (+) TB1-1 SLC (+) TB 6-3 24 V (4) TB 1-2 SIC (-) TB 6-5 Figure 2-27 NFPA Style Y Notification Appliance Circuit (All circuits are supervised and power-limited.) 38 50604: F 2.7.5 The intelligent Detector (Notifier) The BX-501 base provides the connection between the communications loop and SDX-551, SDX-551TH, CPX-551, FDX-551R and FDX-551 intelligent detectors. INSTALLATION 1. Connect the communications loop to terminal ! (=) and terminal 2 (+) on the BX-501. 2. If using an RA400Z remote LED annunciator, connect the RA400Z positive terminal to BX-501 terminal 3 and the negative terminal to BX-501 terminal 1. 3. Before installing the appropriate intelligent detector head, set the detector’s address on the detector head with a small slotted screwdriver. Mark this address on the detector base and on the detector head. © Communications Loop Channel (+) то next device Channal {-) Channel {-) en loop 2(+) D y mal ADDR TYPE Co Bi + [@] - @ BX-501 Detector Base RA400Z Remote LED Annunciator Figure 2-30 Wiring the BX-501 Detector Base 41 pr ry 42 Notes 50604:F FA = 2.7.3 The Control Module, continued For a list of compatible notification appliances, reference the Device Compatibility Document. To next device on Loop 24 VDC + Notification A Appliances LOOP OUT С ez UL-listed Power Pacino | Supervision Relay Si np HAAN AR ee! eri Lan Note: Do not loop wiring under any terminals. Break wire run to maintain supervision. 200000] RPocoroee| PuvvvoCEel ое 28] [2200] [666650] + = + - + - BBE BEB Es EX NO NC с NO NC E TR REF Rx REF OUT TAIT WN |^' BA di 181 ТВ? TB3 B4 ТВ5 TB6 24 V (+) TB1-1 SLC (+) TB 6-3 24V() TB1-2 SLC (-) TB 6-5 Figure 2-28 NFPA Style Z Notification Appliance Circuit {All circuits are supervised and power-limited.) 50604:F 39 Tee 1 a wm à 2.7.4 The Addressable Manual Pull Station (Notifier) The BGX-101L is an addressable manual pull station with a key-lock reset feature. Installation I. Connect the communications loop to terminal screws (+) and (>). 2. The BGX-101L 1s factory preset with address 00. Set the address for the BGX-1010L by using a screw- driver to turn the rotary address switches on the MMX-101 to the desired address settings. oa a +) Black (+) Red ,(-) Yellow : « (+) Violet (+) Red (-) Black OOOO D 1 2 3 4 5 6 SLC (+) TB 6-3 BGX-101L (back view) SLC (-) ТВ 6-5 Figure 2-29 Wiring Addressable Manual Pull Stations 40 50604: F — 3. Programming and Status Change The MICRO-200-I control panel is completely field-programmable and requires no special software skills. Programming may be done in one of two ways: 1. Using the Autoprogram feature and the control panel keypad is a convenient way to quickly bring the ~ system on-line and to make changes to an existing system program. This chapter provides detailed instruc- tions for programming the control panel using the keypad. 2. Using the Off-Line Programming Utility lets you create site-specific programming information using a DOS-based computer and is the preferred method for programs requiring a large amount of data entry. This chapter only provides instructions for uploading and downloading programs created off-line. For detailed instructions, refer to the Off-Line Programming Utility manual. 3.1 Program/Status Change Entry Press the Enter key to enter programming mode and the display shows the Programming Entry screen: ! me ENTER PROG OR STR nea dE ETA Ee bee à ; SE ET Se EE CEE EL side ur UE EL e 11 Edie tr EE a ré A Tar FL A TT НаИЕ mm - . Li = 3 > du. - J я . "о Mera Prada EAT e Y pr A a pre F A : Y ml Pe NE SPACE Passwords There are two passwords, Program Change and Status Change. The Program Change password is factory set at 00000, and Status Change is factory set at 11111. Passwords are user-definable and a method exists for the identification of a forgotten password. If an invalid password is entered, the display shows, INVALID PASS- WORD and an error code number. By contacting the manufacturer, the error code can be deciphered to identify the true password that exists in the machine. To exit from Program Change or Status Change operations at any time, press the Backspace key repeatedly, or press System Reset. 3.2 Program Change Operation if the correct programming password is entered, the control panel will enter Program Change mode. In Program Change mode, the trouble relay is activated, the piezo is off, and the System Trouble LED flashes (and cannot be made steady). The LCD displays the following screen: At this point, a numeric key (0-8) must be pressed. Pressing the Backspace key will abort the operation. 50604:F 43 pá NE 3.2.1 3.2.2 Clear (0) Pressing 0 will clear all programming information from the nonvolatile memory of the contro! panel. Before executing the Clear command, the display will prompt the user for verification of the command before the system actually clears all programming data. The Clear command is typically used to clear data from the control before autoprogramming the control panel for the first time. Autoprogram (1) The autoprogram feature (1=AUTO) identifies all installed devices, determines if new (unprogrammed) devices are installed, and displays any new devices to the user for editing and acceptance. Autoprogramming also loads default program information for new devices. When autoprogramming is first used, it sets up defauit values for all system parameters. While this is happening the display shows the screen to the right. Autoprogram only displays devices to the LCD that do not match the program (not same address and type). Devices matching the existing program in memory do not change and do not display on the LCD. New Detectors | EDITE For each new detector, the autoprogram feature selects “PROGRM SM default program values and displays the information on A tris the LCD. A typical example is shown on the sample LCD display to the right, with descriptions of each item below: 7 : Ee eR EA a 4 a E A Rt JAE at, : Ai + == ем ле snake cr ; si : Ah FEE ь СНЕ e SMOKE(PHOTO) is the actual type code of the de- tector found at address 01. DETECTOR ADDRESS 01 1s the default custom label. Z03 15 the default zone selection. Zone 01 15 the default for heat detectors, Zone 02 for ionization detectors, and Zone 03 for photo detectors. In addition to changing this selection, the user may add four more zones for cach detector’s program. 2.0% obscuration per foot is the sensitivity setting (ion detectors show HIGH, MED, or LOW). Note: If this is a CPX-551 Ionization detector used in a duct application, the sensitivity must be set to HIGH. P indicates that the AWACS Pre-Alarm function is operational (the default setting is Alert level at 70% of alarm level). To deselect, press the * key. See Appendix F for more information). "+" Indicates drift compensation and Alarm Verification options set, respectively. Make sure to record detectors programmed for verification on the Protected Premises Label located inside the unit door. To select the drift compensation option, position the cursor over the first * and press the D (3) key. To select Alam Verification, position the cursor over the second * and press the V (8) key, After a new detector displays, press Enter to accept the default program or do the following: press the left cursor (the triangle to the left of Enter) to reject the autoprogram information and not enter it into memory. In most cases, edit the point program using the procedure described in the next paragraphs. The control panel leads you through the program editing process. A blinking cursor moves through the fields as you press the right cursor key (the triangle to the right of Enter). After moving into other fields, you may return to a previous field by pressing the left cursor or move directly down to the next lower line by pressing the down cursor. Change the blinking fields by pressing the up cursor key or by pressing the appropriate numeric key. Alphanumeric Operation of the Keypad “The alphanumeric operation of the keypad changes a blinking letter in the custom label field. For example, to enter the letter R, press the 7 key to step through 7, P, R and S. Stop on R and then press the right cursor key (not Enter). The custom labels are 19 characters long (the last character is forced to blank). 50604: F r= Programming Hint The control panel includes a special recall function to display the last 19-character label used, which can save many keystrokes. When the blinking cursor is over the first letter of the label field, press the zero key twice to display the label entered for the previous point. If the last character of the label is a number, pressing the zero key a third time will increment this number. Once the label is recalled, you can edit the each character of the label. To load the point's program into memory at any time, press Enter. After pressing Enter, the autoprogram routine displays the next new detector. If a detector exists in the control panel program, but is missing (no answer), the display shows the screen to the right. If you press Enter, the control panel deletes the device from memory and autoprogram displays the next new device. If you press the left cursor, the program remains unchanged, and the next new device displays. pee Et se When autoprogram finishes displaying all new detectors, autoprogram displays the first new module with the lowest address. Monitor Module Autoprogram Monitor module autoprogram is similar to detector autoprogram. A sample LCD display of a typical “Monitor Module autoprogram screen appears to the right EE - The major program editing for Monitor Modules is the “ selection of the type code on the first line. To change this selection, use the up and down cursor keys as the entire field blinks. The default selection is “Monitor,” as shown in the screen to the right. Note: Selection of a type code may change the functional operation of that point. Figure 3-1 contains a list of Monitor Module type codes. TYPE CODE LABEL SPECIAL FUNCTION MONITOR None (default) PULL STATION None SMOKE DETECT None HEAT DETECT Nona Blank None, saiect whan no othar type code applias WATERFLOW Causes a Non-Silancaabde Alarm Becomas a Supervisory Point (Ses Operation SUPERVISORY Chapter) Becomes a Supervisory Point (Sas Operation TAMPER Chapter) Special non-Alarm Polnt (ses Operation NON FIRE Chaptar) Special nor-Alatm Point {see Oparation HAZARD ALERT Chapter) Epeacial non-Alam Point {see Operation FIRE CONTROL Chapter) ABORT SWITCH Aboris Raleasa Zone (sas Appendix D} MAN RELEASE Overrides Abort {ses Appendix D) BILENCE Functions lika Silenca Switch SYSTEM RESET Functions Eke Reset Switch +. | EVACUATE Functions Kia Drill Switch PAS INHIBIT Overrides Presignal (ses Appendix H) TROUBLE MON Short = Trouble (sse Operation Chapter) Causes Security Alarm on Open Short (see BURGLAR ALA Appendix E) Figure 3-1 Monitor Module Type Codes 45 mE Figure 3-2 contains the default zone selection for Monitor Modules. Monitor Module Address Zone Default 01 through 19 704 20 through 39 Z05 40 through 59 206 60 through 79 207 80 through 89 Z08 Figure 3-2 Monitor Module Default Zone Selection This first default zone as well as the other three zones may be changed for each Monitor Module in the same manner as detectors. When autoprogram displays a new Monitor Module, press Enter to accept the default program. To reject the default autoprogrammed information, press the left cursor. To edit the fields, press the right cursor key (the triangle to the right of Enter) and a blinking cursor moves through the fields. Change the blinking fields by pressing the up cursor key, or by pressing a numeric key. Control Module Autoprogramming A sample LCD display of a typical control module autoprogram screen appears to the right. Control modules are similar to Monitor Modules, except that the default zone is always Zone 00 (general alarm). A silenceable selection is required {default is S) and the Walk Test selection is required (default is NO; change * to W if desired). Selection of control module type codes may change their function. Figure 3-3 contains descriptions of the control module type codes type codes. Type Code Label Special Function CONTROL None (default) RELAY ignore Open Clrcult STROBE CKT None BELL None HORN CIRCUIT None AUDIBLE CKT None blank Nong, salact whan no other type code applies. RELEASE CKT Short = Normal (Nonpower-limited, see Appandix D) REL CKT ULC arn {Supervised and power-fimited, see RELEA FROM_C Contacts operated upon release Figure 3-3 Control Module Type Codes Note: A release circuit is always non-silenceable. Notification Appliance Circuit (NAC) Programming NAC program functions and type codes are similar to control modules. Because the four NACs are always installed, autoprogram does not need to display NACs. A sample edit screen for NAC point programming appears to the right. To edit an NAC point, access this screen in Program Change mode (refer to Section 3.2.3), so you can select zoning, silencing, type code, and Walk Test features. 50604:F ‚= NACs are similar to control modules, except for the default type code, and the default label. Note the "B" instead of "M" in the address. The default zone selection is ZOO (general alarm). Walk Test is selected by default. Figure 3-4 contains type code selections for the four Notification Appliance Circuits: Type Code Label Special Function BELL CIRCUIT None (default) STROBE CKT None HORN CIRCUIT None AUDIBLE CKT None None (blank label) RELEASE CKT Short = Normal (Nonpower-limited, see Appendix D} HEL CKT ULC roar DO) (Supervised and power-limited, see Figure 3-4 Notification Appliance Circuit Type Codes System Function Autoprogramming The autoprogram feature automatically selects default system functions during initial programming of the control panel. Subsequent autoprogramming will not change previous editing of these functions. Figure 3. 3-5 contains default system functions and parameters, System Functlon Default Parameter Zone 00 Labal = "GENERAL ALARM ZONE" Zones 01 through 89 Label is blank Zone 90 Labal = “PRESIGNAL/FAS DELAY", DELAY=180,PAS=N Zones 91-94 Label = "RELEASE ZONE 91", DELAY=00, ABORT=ULI, CROSS=N, SOAK=00 Label = "TIME CONTROL ZONE 95," ON=00:00, OFF=00:00, DAYS=SMTWTFSH Zone 97 Label = "HOLIDAY ZONE 97°, all days are 00/00 Zona 98 Label = ail blanks, CODE TYPE=MARCH TIME Label = *FRE-ALARM ZONE 99°, ALERT=70% OF ALARM, ACTION=00% OF ALARM SILINH=000, AUTO=000, VERIFY=00, USA TIME, ANNUN=NON SUPV, ram T BLINK=Y, §T=4, AVPS=N Zones 95 and 96 Zone 99 System Parameters . Passwords PROGRAM CHANGE 00000, STATUS CHANGE 11111 All Systams Normal Custom _ Message Label = 40 Blanks Figure 3-5 Default Parameters for System Functions 3.2.3 Point Programming (2) Selecting 2=POINT from the Program Change menu, lets you edit the program for any detector, module, or Notification Appliance Circuit. The display to the right shows a sample Point Edit screen. From the Point Edit screen, you can select a detector address for program editing by a) pressing the * key, b) pressing the numeric keys that represent the detector address (1-99), then c) pressing Enter. To | i select a module address for program editing, a) press the # key, b) p press the numeric keys that represent the module address (1-99), then c) press Enter. To select a Notification Appliance Circuit address for program editing, a) press the * key, b) press the # key, c) press the numeric key which represents the circuit address (1-4), then d) press Enter. If the selected point number is not installed, the control panel displays the next higher installed point. After making point changes and pressing Enter, the LCD display returns to the Point Edit screen. Note: Rather than reentering the next point number, you can press the up or down key to display the next lower or higher existing point. The point display format and the method of editing are described in Section 3.2.2, Autoprogramming. 50604:F - | 47 para Er y 3.2.4 3.2.5 3.2.6 48 Password Change (3) From the Program Change screen, you can display the Password Change screen by selecting 3=PASS- WORD. Select the password to change by typing * or #, then enter the new password. As the new Program or Status password is entered it displays on the fourth line. To save the new password and return to the Program Change screen, press Enter. To retum to the Program Change screen without changing the password, press Backspace, Message Change (4) From the Program Change screen, you can display the Message Change screen by selecting 4=MES- SAGE. The Message Change screen lets you change the 40-character “All Systems Normal” message. The screen to the right shows a sample Message Change screen display. The first character on the third line blinks and may be changed to any alphabetic character by using the keypad, then pressing the right cursor. When all characters are entered (up to 40), press Enter. Type a blank space in character position 20 or 21 so the words do not run together on an 80-character printer. Zone Change (5) From the Program Change screen, you can display the Change Zone Label screen by selecting 5=ZONES. The Change Zone Label screen lets the user change the custom label assigned to Zones 1-89. The screen to the right shows a sample Change Zone Label screen. Select a zone to change by entering the zone number Gr Silty em ER (01-99) in character positions 19 and 20 on the second line. For single digit numbers, enter a leading zero before the digit (for example, enter 07 for zone 7). The existing (if any) zone label displays on line 4 of the LCD display, characters 2 through 20. Character 1 on line 4 is blank to force a space between the device and zone labels when they are linked on the printer. Enter or change the zone label, then press Enter to change the zone label in memory and return to the Change Zone Label screen. If the zone is out of range, the software ignores the Enter key. Pressing the left cursor key returns to the Program Change screen. 50604:F aÑo 3.2.7 Special Zone Change (6) The selection 6=SPL ZONES lets you change the program for special Zones 90 through 99. From the Program Change screen, select 6=SPL ZONES to display the Special Zone Change screen. The display to the right shows a sample Special Zone _ Change screen. From the Special Zone Change screen, enter a number in the range of 90 through 99. If selecting Software Zone 90 (pre-signal), the typical display is shown to the right. You can change the delay time or the PAS selection. Refer to Appendix G for a detailed explanation of pre-signal and PAS. If selecting Software Zone 91, 92, 93, or 94 (releas- ing), you can change delay times (0-60 seconds), abort type (ULI, IRI, NYC or AHJ), cross zoning (NO, YES, HEAT, or ZONE) or soak time (00, 10-15 _ minutes). Refer to Appendix D for a detailed ‘explanation of releasing functions. If selecting Software Zone 95 or 96 (time control), you can change the start time, stop time, or days of week (Refer to Appendix G). If selecting Software Zone 97 (holiday), you can select up to nine holiday dates. Any device programmed to Software Zone 97 will be active on the holiday dates listed. A typical display screen might be like the one to the right. If selecting Software Zone 98 (code type), you can select one of four code types: March Time, Temporal, California, or Two Stage. Selection of coding only has an effect if one or more Notification .... Appliance Circuits call out Zone 98. SOGOS-F 7 =". If selecting Software Zone 99, you can program the Alert and Action Pre-Alarm. Refer to Appendix F for a detailed explanation of the Pre-Alarm function. ENE PA e a SPECIAL 20 3 : rs A Ro E ARANA A NA emir po al y DA As TA a 2 e im : e vA re A Ве: Зевс fp lei ATA mE Te E. ue E ee te vais ter ai aie, pr A SABER LE partant BE A а: E ce Tee LT LE 0 = 7 ann lo ra ALL: 4 Ë 3 и mo mA ui С FE : E - Rp TE 4 se Set TS e a TE if mp we are! E НЫ font rai Hira pi CUITE ami Pete paie FE te a ELA, ET, ALETA Mi pk Tir A E A НЫ ART A 2 L mi Em pet o i Te | A E; LE RA tre EE AL a pr vu AE E BES: feel, ee + VIT ES AR E 49 3.2.8 3.2.9 System Function Programming (7) From the Program Change screen, selecting 7=SYS- TEM (General System Functions) displays the System Function screen. The sample screen to the right shows a typical System Function screen. The following details each item on the System Function screen: SIL INH (Silence Inhibit) may be set from 0 to 300 seconds. AUTO (Auto Silence) may be set from 600 to 900 seconds, or to zero (none). VERIFY (Alarm Verification time) may be set from 0 to 30 seconds (for systems with Software Release 1.2). Verification times of 0 to 60 seconds were permitted in systems with Software Releases 1.0 and 1.1 only). USA TIME may be changed to EUR TIME with the up/down cursor keys. The default is USA TIME, Selecting EUR Time does the following: changes to 24-hour time, places day before month, provides FAULT instead of TROUBL, and ISOLAT instead of DISABL in the display status field. ANNUN=ACS(1+2) indicates two ACS type annunciators. ANNUN may be changed to ANNUN=ACS ADDR 1 for a single ACS annunciator, to ANNUN=LCD-80(T) for use with an LCD-80 in terminal mode, to ANNUN= UDACT for use with a UDACT Digital Communicator, or to ANNUN=NON SUPYV for no annun- ciator. LocT may be selected meaning that there is a local CRT terminal in the same room as the control panel that is allowed to Acknowledge, Silence, Drill and Reset the control panel. It may also be set to LocM (loca! monitor only) or RemM (remote terminal status monitor only). The default setting is RemM (refer to Appendix H). BLINK=Y (device LED blink) may be changed to BLINK=N (no blink) using the up/down cursor keys. Note: When BLINK=N, a detector only blinks when the detector is tested (every three to four hours) but does not blink each time it is polled. ST=4 (Style four communications loop wiring) may be changed to ST=6 (Style 6 loop wiring). AVPS=N (AVPS-24/AVPS-24E not installed) may be changed to AVPS=Y (AVPS-24/AVPS-24E is installed). Refer to Appendix I for detailed information. Upload/Download An upload/download of the control panel may be done at any time by connecting a personal computer to the Е1А-232 port and running the off-line programming routine. Refer to the PK-200 Off Line Programming Utility manual for more information. 3.2.10 Check (8) 50 From the Program Change screen, selecting 8=CHECK directs the control panel to check the control program as follows: * Search for output points that are mapped to a zone with no inputs mapped to it, « Search for input points that are mapped to a zone with no output points mapped to it (including Z00 outputs). » Search to see if releasing zones (91, 92, 93, and 94) have an input device but no RELEASE CKT; or have a RELEASE CKT but no input device mapped to them. Note: If multiple devices fail the check, use the up/down keys to step through the devices. To correct any errors detected by the Check-routing, return to point programming and correct the program errors. 0604. F 3.3 3.3.1 — the type of point to be disabled/enabled (* for Status Change Operation Status Change is used to change operating param- eters of the control panel—but not its basic configu- ration or control program. Because Status Change wild ALU Ix Sen - allows change of functions that are less critical than q >TCADI E = SENS? OMP those controlled by the programming password, the PEREA am Auca : Status Change password can be provided to an individual with a less training than that required for application programming. From the Program Entry screen, enter the correct Status Change password and the LCD displays the Status Change screen (sample to the right). Status Change operations (except for Walk Test) have a two-minute timer. If no keys are pressed for this period, the control panel exits to normal operation. The Walk Test feature has a one-hour timer. Disable/Enable (1) From the Status Change screen, pressing 1 displays the Disable/Enable screen (sample to the right). Enter detectors, # for modules or *# for Notification Appliance Circuits) followed by the two-digit address; then, press Enter. The point displays on the screen similar to a read status display, but with the status banner blinking (The status banner could show - NORMAL, TROUBL, DISABL, etc.). The status banner can be changed to DISABL or back to its present status 3.3.2 3.3.3 506504:F Clear Verification Counters (3) by pressing the up or down cursor keys. The disable status is changed in memory by pressing Enter, and the display returns to the above screen. The operator can then enter a new point number, press the up cursor to go to the next address point, or press the down cursor to go to the previous address point. The software will not disable initiating devices that are in alarm or control points that are on. Detector Sensitivity (2) From the Status Change screen, pressing 2 displays the Detector Sensitivity screen (sample to the right). Enter a valid detector address and the control panel displays information for the detector on a screen similar to a detector Read Status display, but with the sensitivity setting blinking. If an FDX detector or other invalid address is entered, the display returns to the above menu. The sensitivity can be changed and drift compensation enabled, by using the cursor keys, followed by Enter. Photoelectric detectors may be set for 2.0, 1.5, or 1.0 percent obscuration per foot. loniza- tion detectors may be set for HIGH, MED, or LOW sensitivity. Ionization detectors used in duct applications must be set to HIGH sensitivity. Note: The operator may then press the up/down cursor to bring up the next lower or higher existing address smoke detector for sensitivity change, From the Status Change screen, pressing 3 displays eH HERS EE ERE HE : the screen to the right. MC CARES 2 2 = - E о | par e a WER pi A "am Press Enter to clear all verification tally counters. Eo En Backspace returns to the Status Change screen, 51 3.3.4 3.3.5 3.3.6 52 file. Clear History (4) From the Status Change screen, pressing 4 displays the screen to the right, Press Enter to clear the entire history file. Set Time/Date (5) From the Status Change screen, pressing 5 displays the screen to the night. The first digit of the hours flashes and can be changed with the numeric pad. Pressing the right cursor moves to the next digit, and so on. Pressing Enter changes the time and date in the clock chip and returns to the Status Change screen. Td meda Eme ED ies AT Walk Test (6) From the Status Change screen, pressing 6 displays the Walk Test screen (shown to the right). To enter Walk Test mode, press Enter—the second line goes blank, and the control panel goes into Walk Test mode. To stop Walk Test mode at any time, press Backspace and the control panel returns to the Status Change screen. A one-hour timer automati- cally returns the control panel to normal operation. Walk Test allows a single person to test the entire system without returning to the control panel to press system reset. When in Walk Test mode, the control panel accepts each new alarm and activates its programmed control pomts—if those control points are programmed for Walk Test activation. The control panel also stores each alarm in the history file and sends each alarm to the printer with a “TEST XX” status banner (XX is a count of the number of times a device with this address is tested). All outputs automatically shut off after a few seconds. Normal Walk Test procedure is to activate all devices in a planned sequence using a magnet tool. Upon completion of the test, the history file can be checked against this expected test sequence, If a new trouble occurs, all control modules programmed for Walk Test are activated for a longer period (about 8 seconds) and the control panel sends a trouble banner (“TEST T™) to the history file and optional printer. While in Walk Test, the trouble relay is on, and the System Trouble LED flashes (as in all of program and Status Change operations). The alarm relay is not activated. CAUTION: Fire protection is not active while in the Walk Test mode. Ensure that the building is secure before entering Walk Test mode and be sure to exit Walk Test immediately upon completion of testing. If you want to do a “silent” Walk Test, do not select any of the output modules to participate in Walk Test when programmed (refer to Control Module Programming). Note: The "TEST XX" message may be used to find installation errors. After walk testing the entire system and setting each device into alarm once, if two devices are set to the same address, a "TEST 02" will be reported for that address. The installer should verify that no "TEST 02" or higher entries exist in the history 50604:F 4.1 4. Operating Instructions ra EE a : STEP . ERE Un | ALARM}! e ALAR ai Ue e ¡SUPRVISORY |: o UAM Е и QE TT ES ad (SILENCED_ TT e CORA TROUBLE Figure 4-1 The Membrane Switch Panel Switch Functions Acknowledge/Step The Acknowledge/Step switch silences the piezo sounder and changes all flashing conditions to steady. Only - one key press is necessary regardless of the number of new alarms, troubles or supervisory signals, If the piezo ~ sounder is silenced, the control panel sends an acknowledge message to the printer and history file. Acknowl- S0604:F edge also automatically sends a special command to the LCD-80 and ACS annunciators to silence their piezo sounders. If more than one event exists, the control panel advances the LCD display to the next item and holds there for 20 seconds, or until the Acknowledge/Step switch is pressed again (Step function). Alarm Silence Pressing the Alarm Silence switch performs all functions of the Acknowledge/Step switch. In addition, if an alarm exists, the control panel turns off all silenceable circuits and lights the Alarm Silence LED. The control panel sends an alarm silenced message to the printer and the history file. Note: A subsequent new alarm will resound the system. Drill The control panel waits for the Drill switch to be held for two seconds (to prevent accidental activations), then turns on all silenceable circuits (all CMX modules and Notification Appliance Circuits that are pro- grammed as silenceable) and turns off the Alarm Silence LED. The control panel sends a “Manual Evacuate” message to the LCD display, LCD-80, printer, and history file. System Reset Pressing the System Reset switch turns off all CMX modules and Notification Appliance Circuits, breaks resettable power to four-wire detectors, and sends an “All Systems Normal” message to LCD display, LCD-80, printer, and history file. it also tums on all LEDs, piezo, and LCD display segments for as long as the System Reset is held (lamp test). Any alarm or trouble that exists after System Reset will resound the system. 53 4.2 4.3 sa LED Indicators AC Power The AC Power green LED lights if AC power 15 applied to the contro! panel. The AC Power LED flashes when one or more alarms occur. The Fire Alarm LED lights steadily when you press the Acknowledge/Step switch and turns off when you press the System Reset switch. Pre-Alarm Warning The Pre-Alarm Warning yellow LED flashes when a Pre-Alarm threshold is reached. The LCD display indicates if it is an Alert or Action Pre-Alarm. Supervisory The Supervisory yellow LED flashes when one or more supervisory conditions occur, such as a sprinkler valve tamper condition. The Supervisory LED also lights steadily when you press the Acknowledge/Step switch and turns off when you press the System Reset switch, The Supervisory LED is used for security functions in a combination fire/security protective signaling application. For details, refer to Appendix E. Alarm Silence The Alarm Silence yellow LED lights after an alarm condition occurs, and the Alarm Silence switch is pressed. The Alarm Silence LED turns off when you press the Drill switch or the System Reset switch. System Trouble The System Trouble yellow LED flashes when one or more troubles occur and goes steady-on when you press the Acknowledge/Step switch. The System Trouble LED turns off when all trouble conditions are cleared. This LED will also light if the microprocessor watchdog timer fails (CPU FAIL). Normal Operation When no alarms or troubles are in the system, the LCD display shows the “All Systems Normal” message. A typical example is shown to the night. The control panel does the following functions at regular intervals when 1n normal mode: « Polis all loop devices and the four Notification Appliance Circuits, checking for valid replies, alarms, troubles, etc. * Checks for power supply troubles and batteries ev- ery 10 seconds. « Sends a supervisory query on the LCD-80 interface and verifying proper response. « Refreshes the LCD and LCD-80 display and updating time. » Scans the keypad for System Reset or Enter. » Auto tests detectors. « Tests system memory. 50604: F 4.4 50604:F Trouble Operation When no alarm conditions exist, the detection of a = TETE vr trouble in the system will cause the piezo to sound, Te ROUGE | SL CESTO ELO O i ; 7 van с ir Sis the System Trouble LED to flash, and the trouble Shee ae relay to activate. The display to the right shows a SES typical message that could occur on the LCD display during a trouble condition, The same message is sent to the LCD-80, printer, and history file. The first line lists the type of event (trouble) and the type of device (pull station). The second line is a 19-character custom descriptor for this device location. The third line is the software zone to which it is assigned (zone 5), and the type of trouble that exists (open circuit). The last line is the time and date, plus the point address. For example, in the sample display above, the M37 address represents module number 37. If the device in trouble was a detector, the "M" of address M37 is replaced with a “D”, Pressing the Acknowledge/Step switch causes the piezo sounder to silence and the System Trouble LED to go steady. This occurs regardless of the number of troubles, alarms, and supervisory signals in the system (block acknowledge). When pressing the Acknowledge/Step switch and at least one new alarm or trouble exists in the system, an acknowledge message is sent to the printer and history file, If the trouble clears before or after an acknowledge, the clear trouble message is sent to the printer. The following is an example of a clear trouble message sent to the printer: CLR.TB PULL STATION WEST HALLWAY FLR.5.Z05.DPEN CIRCUIT 11:13R.12/25/97 M37 If all troubles clear and no supervisory or fire conditions exist in the system, the control panel returns to a normal operation status, and sends an “All Systems Normal” message to the LCD display, LCD-80, history file, and pninter. This trouble restore occurs even if the troubles were never acknowledged (auto restore). Pressing the Alarm Silence switch when only troubles exist, produces the same effect as pressing the Acknowl- edge/Step switch. The Alarm Silenced LED does not light unless an alarm also exists in the system. Note: CMX modules report both open and short circuit messages. If multiple trouble conditions exist in the system, the LCD and LCD-80 display steps through each trouble automatically at a two-second rate, If you press the Acknowledge/Step switch, the display stops on the current trouble for 1 minute, or until you press the Acknowledge/Step switch again. As you press the Acknowledge/Step switch, events display in the following order: 1. Alarms, in order of address. 2. Supervisory, in order of address, or security alarms. 3. Troubles, in order of address. Alarm Operation Alarm operation is similar to trouble operation, but with the following differences: « The piezo is a steady sound, not pulsed. « The System Alarm LED flashes. The Display Status banner is “ALARM:”, * The LCD display third line 15 the label of the first zone. * Alamsiatch andare not allowed to clear. » Alarms cause recalculation of all Control-by-Event. * Timers (Silence Inhibit, Auto Silence) start. + Alarms activate the general alarm relay and zone 2.00, A typical alarm display is shown in the screen to the right. 4.6 4.7 4.8 56 Supervisory Operation Supervisory operation is similar to alarm operation, but with the following differences: * The piezo sounds a warbling tone. » The Supervisory LED flashes. * The LCD display status banner is ACTIVE. » Silenced alarms do not resound. Timers do not start * The Supervisory relay activates. + The Alarm relay does not activate, A typical supervisory event display is shown in the screen to the right. Note that, like alarms, supervisory signals latch and may have their own Control-by-Event. They do not cause resound of alarms or reactivation of silenced alarm CBE, Supervisory circuits may also open circuit troubles, which operate like any other trouble. If the event is a security point activation, this LED will operate the same as a supervisory, but the LCD display will show the security type code. Refer to Appendix E for further information on security alarms. y À “REF: - a ca ba A TH en a kg pe RT ee à pa E LETS a I a Sa Cr RITE Soi pa Non-Alarm Point Operation Non-alarm points are MMX modules that activate CBE but do not activate the System Alarm LED or the piezo sounder. These points are tracking and have three type codes: » Non fire codes send a message to the LCD, history file, printer, or LCD-80, except when the system is in alarm. They are generally used for energy management or other non-fire situations. » Hazard Alert codes send a message to the LCD, history file, printer, and LCD-80 (status 15 ACTIVE), and activate the four Notification Appliance Circuits steadily, regardless of the coding selection in Zone 98. These points may be used for monitoring critical processes or other hazardous situations, such as a tornado. * Fire Control codes send messages to the LCD, history file, printer and LCD-808, regardless of the state of the control panel. These codes are generally used for air handler shutdown and are intended to override automatic fire functions. Trouble Monitor Point Operation Trouble monitor-type MMX modules monitor remote power supplies or other external equipment. Operation is similar to trouble operation but with the following differences: « The display status banner is ACTIVE. » The type code is TROUBLE MON. * The modules latch. « The modules may have control-by-event. 50604:F 4.9 4.10 4.11 4.12 Notification Appliance Circuit Operation The four Notification Appliance Circuits have Control-by-Event and trouble functions similar to CMX modules on the communications loop. The circuits differ from CMX modules in the following ways: * Addresses (last three digits in LCD field ) are B01, B02, B03 or B04. » The default type code field is “BELL CIRCUIT.” * Circuits may be used for March Time, California Code, Temporal, and Two Stage coded functions. (CMX modules may not be used for these functions.) Control-By-Event Operation Control-by-event (CBE) is done through 99 software zones, Each system point (detector, MMX, CMX or Notification Appliance Circuit) may list up to five zones in its program information. A general alarm zone (Z00) may be listed for output (control) points, but is not necessary to list for input points. Z00 is not activated by non-alarm or supervisory points. If any input device (detector or MMX) becomes active and it is not disabled, it activates all software zones in its list. An output device (CMX module or Notification Appliance Circuit) that is not disabled is turned on if any of the software zones in its list are active. This is basically an “OR” functionality. Zones 90 through 99 are reserved for special functions such as cross-zoning (Refer to the Programming section). Releasing Functions Zones 91, 92, 93, and 94 are reserved for special releasing functions. This allows for up to four simultaneous release operations (quad hazard). Each zone includes the following: * Cross Zone will activate only if two or more fire type input points are activated that list this zone. In addition, there are two other types of cross-zones One cross zone requires that the two devices reside in different zones; and the other requires that the two devices are a smoke detector plus a heat detector, * Delay timer allows the selection of a 0 to 60 second delay before the zone can activate. * Abort switch-type code in a given zone is used to abort activation of the zone. « Manual Release overrides the abort function, cross-zone function, and delay timer, and activates the zone immediately. » Soak Timer automatically shuts off the releasing device. Select 10 through 20 minutes (or zero for no timer). À hazard is protected by assigning one of the four zones to each initiating device, Abort Switch, Manual Release Switch, and Release Solencid. Refer to Appendix D for detailed information about releasing applications. Intelligent Detector Functions Analog Display The control panel reads and displays analog information from the 99 analog detectors. The display is in percent ‘obscuration per foot for photoelectric detectors and percent of the alarm threshold for ionization detectors. Sensitivity Adjust Alarm levels for the intelligent detectors may be manually set within the UL range. There are three selections: E = ‘High, medium, or low for ionization detectors; and 2.0%, 1.5% or 1.0% obscuration per foot for photoelectric detectors. Ionization detectors used in duct applications must be set to high sensitivity. Day/Night Sensitivity Operation The system can be programmed to automatically force the smoke detectors to their minimum sensitivity (2.0%) during the “day.” For more information, refer to Section 4.13, Time Functions. 57 4.12 58 + typical message displayed to the right is sent to the LCD, LCD-80, printer and history file. Intelligent Detector Functions, continued Drift Compensation Intelligent detector drift compensation provides accurate and stable readings of smoke, counteracting long-term drift caused by dust contamination and other long term environmental factors. Drift compensation permits a detector to remain within performance specifications throughout its life span, quickly detecting true fires, yet rejecting false signals. The drift compensation algorithm uses three measurements from each ionization or photoelectric detector. Drift compensation can be selected on a per-detector basis (refer to Programming). « Long-term measurement of location’s clear air. This is an average reading which moves slowly. It ‘adjusts to gradual buildup of dust contamination, unaffected by true smoke, even from smoldering fires. » Alarm test level measurement. This uses special electronics in the detector and panel software to pen- odically command each detector to simulate an alarm level reading from the sensing chamber. + Present chamber reading. Under normal conditions, this will be close to the stored air clear value. If smoke occurs, it will begin to move toward the alarm test level. | The control panel's software converts the present reading to percent per foot obscuration or percent of alarm, based on its position between the known clean air and test values. The accuracy of this measurement method is sufficient to meet the NFPA 72E requirements as a calibrated smoke test instrument. Maintenance Alert When the compensation reaches the limit of the amount of drift compensation that may safely be applied, a special trouble condition is reported. This condition will also be activated 1f the detector remains at very high or very low levels for extended periods of time. Automatic Test Operation The control panel performs an automatic test of each detector every 2 hours. Failure to meet the test limits causes an AUTO TEST FAIL trouble type. Pressing the System Reset switch clears this trouble. Type Code Supervision The control panel monitors hardware device type codes (CPX, SDX, FDX, MMX and CMX) at slow intervals. Mismatch of type compared to the program will cause a point trouble, The trouble label is INVALID TYPE. LED Control Operation The control panel includes a global program selection to prevent blinking of detector LEDs during normal conditions. This is often desired in sleeping areas where a flashing light may be objectionable. As a standard function, the control panel allows up to 99 LEDs to turn on in alarm. Alarm Verification and Counter Operation The control panel performs Alarm Verification on CPX and SDX intelligent smoke detectors. Selection of detectors for Alarm Verification is described in the Programming section. Alarm Verification time is a global programming selection of 0 to 30 seconds. Each detector includes a verification counter which displays the number of times a detector enters verification but does not time-out to alarm. The counter counts to 99 and holds. Pre-Alarm Operation/Advanced Warning Addressable Combustion Sensing (AWACS) If an SDX or CPX detector exceeds the programmed Alert level, it causes an Alert Pre-Alarm situation. When this occurs, the piezo is activated, Zone 99 is activated, and the Pre-Alarm LED is illuminated. The In the example to the right, the detector is pro- | grammed for alarm at 1.00% per foot of obscuration (High level), and has now reached the Alert level programmed for 50% of that, or 0.50% per foot. The 50% is a real-time display and may change. Alert Pre- Alarms automatically restore. 50604:F - * +4 4.12 Intelligent Detector Functions, continued An Action Pre-Alarm is indicated if a detector exceeds the Action level threshold. When this occurs, all re br ep in rech functions of the Alert level occur, plus a special ul SEAL] Hs OST sat Dl: Action software zone (5th zone) may be activated if PON: SAA: ac programmed. Action Pre-Alarms latch until reset. À typical Action Pre-Alarm display is shown to the right. drt AC 2 4.13 Time Functions Real Time Clock Operation The control panel includes a crystal time base clock that provides time, date, and day of week. The clock includes its own lithium battery backup. Time is normally displayed as 12 hour time with month/day/year, but may be programmed for European time format, displayed as 24-hour time with day/month/year. Time Control Command Operation Zones 95 and 96 are reserved for control-by-time functions. These special zones may be programmed to activate at a specific time and deactivate at another time and may do so for only certain days of the week. Any control point may be tumed on and off (lighting control, setback thermostat, etc.) by using one of these zones. These functions are intended for ancillary (non-fire) applications. Day/Night Sensitivity Adjust Operation If a CPX or SDX detector calls Zone 95 or 96, it will set the detector sensitivity to the minimum 3.0% (low) setting when activated. When the zone deactivates, the sensitivity returns to its programmed setting. For day/ night sensitivity use, 95 and 96 may be thought of as “DAY” zones. Holiday Operation Zone 97 is reserved for setting holidays (up to 9 dates) and can be used for special day-of-year control. You can also use Zone 97 as the “8th day” in the programming of Zones 95 and 96. When the current date matches any of the 9 dates, the zone activates. 4.14 Coding Operation (NAC only) Zone 98 is reserved for coding functions which are only used by NACs B01-B04 including Zone 98 in their CBE list. If Zone 98 is called out for CMX modules, it has no effect. Only one of the following types of code may be selected: * MARCH TIME Pulses at 120 ppm. о TEMPORAL CODE 0.5 sec. on, 0.5 sec. off, 0.5 sec. on, 0.5 sec. off, 0.5 sec. on, 1.5 sec. off. ~o CALIFORNIA CODE 10 sec. on, 5 sec. off. « TWO STAGE Pulses at 20 ppm for 5 min., then changes to steady on. Note: If an alarm occurs, and an NAC is programmed for two stage, and it is not activated by any other zone, it pulses 20 PPM. After five minutes, the Notification Appliance Circuit changes to steady on unless Acknowl- edge is pressed. The Drill function will change the NAC fo steady. 4.15 Pre-signal/PAS Operation Zone 90 is reserved for pre-signal functions and is used to delay control points for human verification. If zone 90 is included in a CMX or Notification Appliance Circuit CBE list, it inhibits all other CBE. Detectors and Monitor Modules must call out Zone 90 in their program to be included in the pre-signal/PAS operation. When any alarm occurs and no PAS inhibit type MMX is activated, Zone 90 activates. If a second alarm activates, or the Drill switch is pressed, Zone 90 goes false. If PAS is selected, and the Acknowledge switch is not pressed within 15 seconds, Zone 90 goes false. At the first alarm, a programmable 000 to 180 second timer is started. If signal silence occurs, the timer is frozen. If the timer expires, Zone 90 goes false. The alarm relay and transmitter are delayed if PAS is selected, but are not delayed for pre-signal operations. 50604:F 59 4.16 4.17 60 Special System Timers Silence Inhibit Timer (0-300 seconds) The Silence Inhibit timer starts at the first alarm and restarts with each new alarm. It prevents the Alarm Silence switch from functioning. Auto Silence Timer (0=no timer, 600-900 seconds) If the Auto Silence Timer is selected and times out, it performs the same function as pressing the Alarm Silence switch. Pressing the Drill switch starts the timer. Alarm Verification Timer (0-30 seconds) If a smoke detector (CPX or SDX) is selected for Alarm Verification, its alarm is ignored for the Alarm Verification time. If an alarm from another point occurs while timing, it dumps the timer and activates the alarm. If time-out and alarm still exists, it performs all standard functions. If time-out and alarm no longer exists, the control panel increments the verification counter for this device (stops at 99) and returns to normal. Waterflow Circuits Operation If an alarm exists from a MMX point that has a waterflow type code, the Alarm Silence switch will not function. Disable/Enable Operation Input points which are disabled do not cause an alarm or any CBE activity. Disabled output points are held in the off state. All disabled points are treated as if they were in trouble except the status banner is DISABL.. Style 6 Operation Tf the communication loop is wired and programmed for Style 6 or Style 7, and a single fault occurs, the control panel will detect the fault and drive both ends of the line, fully recovering from the fault. The control panel latches the trouble and displays it until System Reset. The LCD display shows STYLE 6 trouble type. Style 7 requires use of the ISO-X isolator modules (refer to Chapter 2). 50604:F 4.18 Read Status The Read Status function lets you read the current status of all points and zones. Read Status functions do not require a password. In read status mode, the control panel continues to provide fire protection. You can enter Read status with the control panel in alarm or trouble. If a new alarm or trouble occurs during a Read Status function, the Read Status is aborted to prevent confusion. 4.18.1 Read Status Entry When you press the Enter key, the LCD display shows the screen to the right. Press 2 for Read Status, the LCD display shows the screen to the right. To perform the Read Point function, identify the first detector or module number you wish to read; then, press Detector (* key) or Module (# key) followed by + the address (two numeric digits), followed by Enter. = il To Print Points, press the 1 key, then press Enter. . To Read History, press the 2 key, then press Enter. To Print History, press the 3 key, then press Enter. Note: Refer to Section 4.19 for explanation of history operation. When you enter Read History, the LCD displays the most recent event. To display earlier or later events, press the up cursor or down cursor keys. The time displayed is the time that the event happened. During all Read Status operations—except print operations—a two-minute timer starts. If no key is pressed during the two-minute timer, the LCD returns to the previous display. Each key press restarts the two-minute timer. Pressing the left cursor (backspace) deletes the previous entry. If there is no entry, the control panel aborts the Read Status operation and returns to the previous display. You can also abort Read Status by pressing the System Reset switch. 4.18.2 Read Point Read Point operations display point status on the LCD display, but the status is not sent to the serial ports or the history file. After a point is read, you can press the down key to read the next point in sequence, or press the up key read the prior point in sequence. The sequence of points is detector points 01-99, module points 01-99, Notification Appliance Circuits 01-04, system parameters, and then software zones 01-99, Refer to the follow- ing pages for examples of the Read Status display. 50604:F 61 4.18.2 Read Point, continued 62 Point Status A typical Read Status display example for a point read is shown to the right. me * NORMAL the present status. Status can be ALARM, TROUBL, DISABL, etc. « SMOKE(PHOTO) is the device type. Device types include SMOKE [ION], PULL STATION, HORN CIRCUIT, etc. « WEST HALLWAY FLR 51s the custom label programmed for this device. + Z05Z01 Z157Z87 Z90 is a list of assigned software zones (if less than five are programmed, some are blank). e 15% is the current reading of percent of alarm, 15% of 1.0% would be 0.15% obscuration per foot (does not exist for modules). A * 1.0% is the alarm threshold selection (does not exist for modules). « D indicates drift compensation is enabled, e P indicates Pre-Alarm is enabled. « V indicates that the detector is programmed for Alarm Verification. The 08 is a verification tally and indicates that this device entered the verification cycie eight times since the counter last cleared. Note: The verification field does not exist if this device is a module. If the device is a control module or Notification Appliance Circuit, an “S” or “W” may appear in this area, indicating that the module is programmed for Silenceable or ` Walk Test activation. « D indicates that this device is a detector and the detector address is 13. Note: M is for a module, B is for a Notification Appliance Circuit, and Z is for a software Zone. If the point is not installed, a Read Status command to that point will result in a NOT INSTALLED message on the display. Software Zones 01-89 The typical display shown to the right is used to show de eg the the status of Zones 01-89. De AS у + =X MT 1 a ля a ea | Ear La ATT a + + HH + « OFF is the zone status (status can be ON or OFF) + FLRSMAIN BUILDING is the custom label pro- grammed for this zone. о 7Z201is the zone number. Note: To read the status of a zone directly, press *, press * again, then enter the zone two digit number and Enter. To read the sysiem parameters, press *, * , Enter. Software Zone 90 The typical display shown to the right shows the status of software zone 90 (Pre-signal Delay control). + DELAY=180 indicates the programmed pre-sig- nal delay in seconds. « PAS=YES (could be NO) indicates that Positive Alarm Sequence operation is selected in the pro- gram. 50604:F 4.18.2 Read Point, continued 50604:F ‘The typical display to the right shows the status of Software Zone 97 (Holiday zone). The day/month Software Zones 91, 92, 93, and 94 The typical display shown to the right shows the status of Software Zones 91, 92, 93, or 94 (Releasing control zones). о DELAY=30 indicates programmed delay time in seconds. » ABORT=ULI indicates the abort function, if an abort switch is mapped to this zone (ULL, IR], NYC, or AHI). « CROQSS=Y indicates that cross zoning is used (must have two or more detectors programmed to this zone in alarm to activate the zone). La жа! ait ел Sted] ny A it Ta E Seni régies ei a ie; о SOAK indicates the soak timer (automatic shut off) value in minutes (00 = no soak timer). Software Zones 95 or 96 The typical display to the right shows the status of Zones 95 or 96 (time control zones). In addition to automatic activation of non-fire control points, this zone may be used for detector day/night sensitivity select. If day/night sensitivity is desired for a smoke detector, it must call out Zone 95 or 96 in its program. When the fire control is active, it forces the detector sensitivity to the low setting (2.0 % per foot obscura- tion for photoelectric detector). се ON=7:00 OFF=18:00 indicates the programmed times that this zone will automatically turn on and off each day. The times are in 24-hour (military) format. « DAYS=MTWTF H indicates the programmed days of week that the on/off times are effective. His a holiday, which is defined by Zone 97. Software Zone 97 numbers are user-programmed holidays of the year. Software Zone 98 The typical display to the right is used to show the status of Software Zone 96 (coders). MARCH TIME indicates the type of coding that will be applied to each of the four panel Notification Appliance Circuits if mapped to Zone 98. Zone 98 does not affect addressable control modules. Other possible program selections are Temporal, California, and Two-stage. Refer to Coding Operation in this chapter for more information. Software Zone 99 The typical display shows the status of Software Zone 99 (Pre-Alarm). This zone turns on if any detector reaches it's Pre-Alarm threshold to indicate an incipient alarm, or the need for detector maintenance. Zone 99 can be mapped to any control point. 4.18.2 Read Point, continued System Parameters The typical display to the right shows System Parameters. Note: To read the System Parameters directly, press * twice, then press Enter. » SIL INH=060 is the Silence Inhibit time in sec- onds, required in Canada and some areas of the Unites States (SIL INH=000 indicates the timer is not selected), * AUTO=60015 the automatic silence timer in seconds (000=not selected). * VERIFY=3015 the Alarm Verification timer in seconds (00=not selected). * USA TIME may be EUR TIME if European time/date display format is selected. * ANNUN=ACS(1+2) indicates that the EIA-485 port (TBS) is programmed to use point annunciation (ACS family) and that both Addresses 1 and 2 are used. Other selections include ANNUN=ACS(ADDR 1), ANNUN=LCD380 (T), ANNUN=NON SUPY and ANNUN=UDACT. NON SUPV is terminal mode and is selected if no annunciation of any type is used. + LocT indicates that a local terminal (CRF-1, CRT-2) is connected and can be used for Acknowledge, Signal Silence, Drill, and Reset functions. Note: For LocT, the terminal must be in the same room as the control panel. —* BLINK=Y refers to the LEDs on intelligent devices. The blink may be suppressed for certain applications. ~ + ST=4refers to the NFPA wiring style desired for the communications loop. It can be set to Style 4 or Style 6. Li . The 6 setting is used for both Style 6 and Style 7 operation. * AVPS=N indicates that there is no AVPS-24/AVPS-24E expansion power supply installed (refer to Appendix J). 4.19 History Operation The control panel maintains a history file of the last 650 events. These events include all alarms, troubles, and operator actions such as Acknowledge, Reset, Signal Silence, Manual Evacuate (Drill), and Walk Test. Pro- gramming entry is also stored, along with a number indicating the programming submenu that was entered (0-9). All events are time and date stamped. To clear the history file refer to Section 3.3.4. For information on reading or printing the history file, refer to Section 4.18. The control panel also has a non-erasable "shadow history" file that always contains the last 650 events in time. To read this file: press 8; then, press Enter. To print this file: press 9; then, press Enter. A.1 А.2 50604:F Appendix A — Power Supply Calculations Overview This appendix contains instructions and tables for calculating power supply currents in alarm and standby conditions. This is a four-step process, consisting of the following: 1) Calculating the total amount of AC branch circuit current required to operate the system, 2) Calculating the power supply load current for non-fire and fire alarm conditions and calculating the secondary (battery) load. 3) Calculating the size of batteries required to support the system if an AC power lass occurs. 4) Selecting the proper batteries for your system. Calculating the AC Branch Circuit The control panel requires connection to a separate, dedicated AC branch circuit (120 VAC for MICRO-200-1 and 220/240 VAC for MICRO-200-IE), which must be labeled FIRE ALARM. This branch circuit must connect to the line side of the main power feed of the protected premises. No other equipment may be powered from the fire alarm branch circuit. The branch circuit wire must run continuously, without any disconnect devices, from the power source to the fire alarm control panel. Overcurrent protection for this circuit must comply with Article 760 of the National Electrical Codes as well as local codes. Use 14 AWG wire with 600-volt insulation for this branch circuit. Use Table A-1 and Table A-2 to determine the total amount of current, in AC amperes (A), that must be supplied to the system. Device Type of mer surrent Total Current Devices (amps) per Device MICRO 200-1 X 30 = 3.0 AVPS-24 [ ] X 1.0 = Sum Column for AC Branch Current Required | = A Table A-1 120 VAC Branch Circuit Requirements Device Type mer current Total Current Devices (amps) per Device MICRO 200-IE 1 X 1.5 = 1.5 AVPS-24E [ 3 X 0.5 = Sum Column for AC Branch Current Required | = A Table A-2 220/240 VAC Branch Circuit Requirements 65 A.3 A.3.1 A.3.2 66 The Main Power Supply The control panel's main power supply can supply a total of 5.0 A in alarm and 1.0 A in standby (non-alarm condition), The current available for powering extemal devices, however, is subject to lower limits as shown in Figure A-1 and Figure A-2. Current Limitations in Standby Current for operating an external device in standby (non-alarm) is subject to the following limitations: 1. Non-resettable power (TB1, terminals 3 and 4) and resettable power (TB1, terminals 5 and 6) are limited to a combined total of 0.5 A. Using Table A-3, Calculation Column 1, verify that the combined subtotal of rows 4 and 5 is less that 0.5 A, 2. The total power supply load is limited to 1.0 A. Using Table A-3, verify that the total of Calculation Column 1 is less than 1.0 A. 1.0 À Total System | | 0.5 А | combined + - + - +4 - TB1 Figure A-1 TB1 Standby Current Limitations oT Current Limitations in Alarm — System operation on primary power Current for operating external devices in alarm is subject to the following limitations: 1. High ripple power (TBI, terminals 1 and 2) is limited to 1.5 A. Using Table A-3 Calculation Column 2, verify that the subtotal of row 3 is less than 1.5 A. 2. Non-resettable power (TB1, terminals 3 and 4) and resettable power (TB!, terminails 5 and 6) are limited to a combined total of 0.5 A. Using Table A-3 Calculation Column 2, verify that the subtotal of rows 4 and 5 combined is less than 0.5 A. 3. The maximum load on NAC #1 (TB1, terminals 1 and 2) cannot exceed 2.5 A. Using Table A-3 Calcula- tion Column 2, verify that the subtotal of row 6 is less than 2.5 A. 4. The maximum combined load on NAC #2, NAC #3, and NAC #4 (TB2, terminals 3-8) cannot exceed 2.5 A. Using Table A-3 Calculation Column 2, verify that the subtotal of row 7, 8, or 9 is less than 2.5 A. 5. The total power supply load is limited to 5.0 A. Using Table A-3, verify that the subtotal for Calculation Column 2 15 less than 5.0 A. 5.0 A Total System | | 0.5A | 25A combined combined TB1 TB2 Figure A-2 TB1 and TB2 Alarm Current Limitations 50604:F A.4 Calculating the System Current Draw Overview The control panel must be able to power all internal and external devices continuously during the non-fire alarm condition. To calculate the non-fire alarm load on the system power supply when primary power is applied, use Calculation Column 1 in Table A-3. The control panel must support a larger load current during a fire alarm condition. To calculate the fire alarm load on the power supply, use Calculation Column 2 in Table A-3. The secondary power source (batteries) must be able to power the system during a primary power loss. To calculate the non-fire alarm load on the secondary power source, use Calculation Column 3 in Table A-3. When calculating current draw and the battery size, note the following: » “Primary” refers to the main power source for the control panel. o “Secondary” refers to the control panel's backup batteries. * All currents are given in amperes (A). Figure A-3 shows how to convert milliamperes and microamperes to full amperes. To convert... Multiply Example Milliamperes (mA) to mA x .001 3 mA x 001= ,003 À amperes {A) Micmamperes (HA) to HA x 000001 300 pA x .000001=.0003 A amperes (A) Figure A-3 Converting to Full Amperes How to Use Table A-3 to calculate system current draws - Use Table A-3 to calculate current draws as follows. o 1) Enter the quantity of devices in ali three columns. 2) Enter the current draw where required. Refer to the Device Compatibility Document for compatible +". devices and their current draw. 3) Calculate the current draws for each in all columns. 4) Sum the total current for each column. 5) Copy the totals from column 2 and column 3 to Table A-4. . Figure A-4 shows the types of current that you enter into Table À-3: — Calculation Column 1 — The primary supply current load that the control panel must support during a non-fire alarm condition, with AC power applied. This current draw cannot exceed 1.0 À. Calculation Column 2 — The primary supply current load that the control panel must support during a fire alarm condition, with AC power applied. This current draw cannot exceed 5 A. Calculation Column 3 — the standby current drawn from the batteries in a non-fire alarm condition: during a loss of AC power. чи BUS CHE | ove ui a | | i +1 = — i ic Li = 1 Li wy = = En | a 11 | we == :} + + тот -= *| — te ji * me ul > ANO Y EN Fr ТЕ Li Figure A-4 Calculating the System Current Draws 50604:F 67 Calculating the System Current Draw, continued Table A-3 contains three columns for calculating current draws, For each column, calculate the current and enter the total (in amps) in the bottom row. When finished, copy the totals from Calculation Column 2 and Calculation Column 3 to Table A-4. Notes referenced in Table A-3 are listed on the next page. Calculation Column ! Calculation Column 2 Calculation Column 3 Primary, Non-Fire Alarm Primary, Fire Alarm Current Secondary, Non-Fire Alarm Row |Category Current (amps) (amps) Current (amps) Qty ent total Qry X [current total Qty Y e total 1 Basic System N/A N/A N/A N/A N/A N/A ] x [0.10] 0.10 2 AVPS-24 { ] x[0.009]= 3 High ripple power TE terminals + and? Notification appliances via CMX | N/A N/A, N/A { 1] x | } = N/A N/A N/A Notification appliances via CMX | N/A N/A N/A [ ) х [ ] = N/A N/A N/A Releasing devices via CMX N/A N/A N/A { ] x [ |= N/A N/A N/A Other compatible devices [3 x | ]= [ ] x [ } = [ 1 x] j= (Note 1) Non-resettable power 4 TB) terminals 3 and 4 LCD-80, LED-B0TM (Note 2) I 1 x [0.100]= [ 1 х [0.100] { ] x [0.050}- 5 Resetrable Power Four-wire smoke Four-wire Fo] x [ js [ T x [ |= [ 1 x] Ju Two-wire smoke detector { ] x [ ]= [ ] x [ I= [ ] x] |= connected to MMX-2 A77-7168 Relay [ ] x[0.020)= Г x[0.020)= { | x][0.020}= Other compatible devices [ ] x [ ]= [ 1 x E ]= [ ji x{ j= (Note 1} 6 NAC #1 (Note 1) TB2 terminals 1 and 2 Notification Appliance [ ]) XI = Releasing Solenoid [ 1] x[ J= 7 NAC #2 (Note 1) TEZ terminals 3 and 4 Notification Appliance [ |] x{i je Releasing Solenoid [ 1 x{ Je B NAC #3 (Notes 1 and 3) TEZ terminals 5 and 6 Notification Appliance [ ] x] Im Releasing Solenold { 1] X] 1» 9 NAC #4 (Notes | and 3) TB2 terminals 7 and 8 Notification Appllance [ ] x{ I= Releasing Solenold { ] x[ = 10 SLC Communication Loop TB6 terminals 3-6 SDX-551, CPX -551, CPX-751 [ } —x(0.00020)= Lo] x [0.00020)= [ 1 х[0.00020]= & FDX-551, SDX-551TH SDX-751 { 1 х [0.00029 [ 1] х [0.00029] = [) x (0.00029)» MMX-1, MMX-101, BOX-TOFL { } x [D.00030]= [o] x (0.00043}= [ 1 x][0.00030]= CMX 1 1 x[0.00030]= [ 1] x (0.00030)= [ 1 x[0.00030)= MMX-2 {see Doc. M500-03-00) { ] x | Ju [ ] x | ]= EJ x] ]= B6O1BH { 1 x[0.00100)= E] x {0.00100]= FJ x[0.00100)» #501 ВН (Horn in base) [ } — х[0.00100]- E ] x {0.01500]= [ ] x [0.00100j- DHX-501, DHX-502 (see data sheet) |[ | x[ ]= Е] x { - EJ xt = 150-X [1 x [0.00045]= Lol x [0.00045]= [ 1 x[0,00045)= 11 Optional modules RTM-8 (Note 4) { ] x[0.0010)= i ] x[0.160j= [ ) x10.0010]= 4XTM { ] x[0.0110)= { ) x[0.020]w 1 } x{0.0110]= Municipal Box (Note 5) N/A { 1] x[ ]= N/A Reverse Polarity Qutputs used [ ] x[0.0050]= 1 ] x[0.0050) | J x{0.0050]= Primary non-alarm: Primary alarm Secondary alarm: (1.0 A max.): (5.0 A max): Copy to Table A-4 12 Sum each column for totals Copy to Table A-4 "Secondary “Secondary Alarm Standby load” Load” 68 Table A-3 System Current Draw Calculations 50604:F EE = Calculating the System Current Draw, continued Notes for Table A-3: A.5 50604:F 1) 2) 3) 4) 5) 6) Refer to the Device Compatibility Document for compatible devices and their current draws. For non-English language systems, the LCD-80TM (Terminal Mode) standby current is 0.100 A. Do not enter current for NAC #3 and NAC #4 in Table A-3 if powering, these Circuits from an AVPS-24. For more information on the AVPS-24, refer to Appendix 1. The RTM-8 alarm current is based on all eight alarm relays being activated. The alarm current can be reduced by 0.019 A for each zone (between zone | and zone 8) that is not used by the system. Enter the current from the Municipal Box data sheet into Calculation Column 2. The Reverse Polarity Output values apply to the RTM-8, 4XTM, and Municipal Box. Calculating the Battery Size Use Table A-4 to calculate the total Standby and Alarm load in ampere hours (AH). This total load determines the battery size (in AH), required to support the control panel under the loss of AC power. Complete Table A-4 as follows: 1) 2) 3) 4) 5) Enter the totals from Table A-3 Calculation Columns 2 and 3 where shown. Enter the NFPA Standby and Alarm times (refer to “NFPA Battery Requirements” below.) Calculate the ampere hours for Standby and Alarm; then, sum the Standby and Alarm ampere hours. Multiply the sum by the derating factor of 1.2 to get the proper battery size (in AH). Write the ampere-hour requirements on the Protected Premises label located inside the cabinet door. Secondary Standby Load Required Standby Time (toa! from Table A-3 Calculation (24 or 60 hours) Column 3) [ ] x | ] = АН Primary Alarm Load Required Alarm Time (total fram Table A-3 Calculation (For 5 min., enter 0,084, Colurm?) for 10 min., enter 0.168) [ ] х | ] = AH AVPS-24 Alarm Load Required Alarm Time {if using AVPS-24, enter 3.0 A) (For 5 min., enter 0,084, for 10 min, enter 0.168) { ] x [ ] = АН Sum of Standby and Alarm Ampere Hours = AH Multiply by the Derating Factor х 1.2 Battery Size, Total Ampere Hours Required = AH Table A-4 Total Secondary Power Requirements at 24 VDC NFPA Battery Requirements NFPA 72-1993 Local and NFPA 72-1993 Remote Station Fire Alarm Systems require 24 hours of standby power followed by 5 minutes in alarm. NFPA 72-1993 Central Station, NFPA 72-1993 Auxiliary, and 72-1993 Remote Station require 60 hours of standby power followed by 5 minutes in alarm. Batteries installed in a system powered by a generator need to provide at least 4 hours of standby power. NFPA 12, 12A, 12B require 24 hours plus 5 minutes activation. The total ampere hours required cannot exceed 17 AH with an internal charger. A.6 70 Selecting and locating Batteries Select batteries that meet or exceed the total ampere hours calculated (from Table A-4). The control panel can charge batteries in the 7 AH to 17 AH range. Table A-5 contains information, such as the battery size and location, for the batteries required to power the control panel if an AC power loss occurs. Note: 15 AH to 17 AH batteries require the BB-17 or other UL-listed external battery cabinet. Battery Voltage Number Part " 1 {Skze Rating Required Number Location 7 AH 12voits two PS-1270 12AH — 12volts two ps-12120 !” Panel 17 AH lZvolts wo PS-12170 BB-17 Battery Box Table A-5 Battery Size and Location 50604F "= Appendix B — NFPA Standards Specific Requirements 50604:F The control panel is designed for use in commercial, industrial, and institutional applications and meets the requirements for service under the National Fire Protection Association (NFPA) Standards outlined in this Appendix. The minimum system components required for compliance with the appropriate NFPA standard are listed below. o MICRO-200-I Control Panel containing the main circuit board, cabinet (backbox and door), main supply transformer and power supply. > Batteries (refer to Appendix À for standby power requirements). Initiating Devices connected to one of the control panel's initiating device circuits, = Notification Appliances connected to the control panel's Notification Appliance Circuit or via a CMX module. 71 Appendix C — Annunciators Terminal Mode (LCD-80) Annunciation Interface (TB5 on CPU) In terminal mode, the control panel annunciates all point information to remote LCD-80 displays. Each LCD-80 mirrors the front panel display and includes Acknowiedge, Silence, and Reset switches. An LCD-80 will display all 198 intelligent points without being programmed. Switch SW2 on the circuit board must be set for TERM and the control panel must be programmed for terminal mode. ACS Annunciation Interface (TB5 on CPU) In ACS mode, the control panel annunciates its 99 software zones. The use of software zones allows the user to freely map any number of modules or detectors to a single LED. The ACS connection uses a standard ELA-485 interface, capable of two-way, high speed communications with multiple annunciators located up to 6,000 ft. from the control panel. Annunciator Capacity 72 ACS annunciation displays the 99 software zones of the control panel plus 8 system points, for a total of 107. Information is transmitted using annunciator addresses 1 and 2. The ELA-485 interface will allow up to 32 annunciators (all but two must be in receive-only mode), over distances of up to 6,000 fi. (check power limitations). SO604:F Terminal Mode ElA-485 Connections Note: The LCD-80s require connection of operating power! Connect 24 V power to the MICRO-200-1 TB] terminal 3 (+) and TB1 terminal 4 (-). Power connections are supervised and power-limited, Power-limited and supervised. Maximum of four LCD-80s may be connected to this circuit when pow- ered by the control panel. If LCD-80s are powered by a sepa- rate UL-listed power supply, up to 32 may be connected. 6,000 feet maximum distance (16 AWG) between the control panel and the first or last LCD-80 and between each LCD-80. Use overall foil/braided-shield twisted pair cable suitable for ELA- 485 applications. EIA-485 circuit rated 5.5 VDC max., 60 mA max. See the LCD-80 Manual for addi- tional information. Set SW2 on the control panel to the TERM position. (Set the Switch in the left position.) Set SW 4 and 5 on the LCD-80 to the TERM position: SW1-7 ON. For non-English language systems, LCD-80 standby current is the same as the alarm current (100 mA). Each LCD-80 must have R-120 re- sistors installed across the in and out terminals as shown below. 1 PT PE PEE Ean Es mr mak mm de PVE SR TER EE Sam Em EE Em Ee Er dar mr dvr = ek SA am Em Em am о вто = ER First LCD-80 {must set DIP Switch SW3-1 AND SW3-2 "OFF" on all — LCD-80's except the last one) (-) ElA-485 IN | | 4 |] Das (-) ElA-485 our || 3 || Dee (+) Ela-485 IN || 2 10M 1 | EIA485 LastLCD-80 Out (SW3.4 and SW3-2 mustbe set ON on the last LCD-80) P2 (-) E1A-485 IN (-) ElA-485 OUT (+) ElA-485 IN (+) EIA-485 OUT =. M CG) Pw Shielded Twisted Pairs Out (+) P= 2000! |0000 (+) ElA-485 OUT on = = mmm ws > Cl Cr Cl CU A Sm guy aay a mb AE бай EE AE COCA O CU CU O Em abl Er Em Em CA ve dl ya EE EE ER EE. 000000 > TX REF RX RER OUT OUT IN IN А В В+ А+В-А- TB5-1 (+) TB5-2 {-) Figure C-1 Termina! Mode ElA-485 Connection 73 LCD-80 ACS Mode ElA-485 Connections 74 P2 (-) ElA-485 IN (-) ElA-485 OUT (+) ElA-485 IN (+) ELA-485 OUT install 120 ohm . terminating resistor on last LCD-80 nv © da Du nd Du On Power-limited and supervised. Maximum of four LCD-80s may be con- nected to this circuit when powered by the control panel. If LCD-80s are powered by a separate UL- listed power supply, up to 32 may be con- nected. 6,000 feet maximum distance (16 AWG) between the control panel and the first or last LCD-80 and between each LCD-80. po Use twisted pair cable with a characteris- tic impedance of approximately 120 ohms. (-) ElA-485 IN EIA-485 circuit rated 5.5 VDC max., (-) ElA-485 OUT 60 mA max. (+) ElA-485 IN See the LCD-80 Manual for additional in- | (*) ElA-485 OUT formation. Set SW2 on the contro! panel to the "ACS" position. (Set the switch to the right position.) — — № — n JE I | > Nm © A Femme minime 2000|] 1000011000000 ô Hi ui IX REF EX REF OUT OUT IN À B B+A+B-At Ps Y TB5-1 (+) TB5-2 {+) Figure C-2 LCD-80 ACS Mode ElA-485 Connection Notes: 1) LCD-80s require connection of operating power! Connect 24 VDC power to TB1 terminal 3 (+) and TB1 terminal 4 (—). Power connections are supervised and power-limited. 2) The LCD-80 start address must be set to address 01. Switch SW2 must be set to "1", and SW3-1 and SW3- 2 must be set to "OFF". Set the LCD-80 to a size of 128 points. To use a 40-character display; set SW5 OFF and SW6 ON. To use a 20-character display; set SW5 ON and SW6 OFF. 7 50604:F Power Connections for LCD, ACS type Annunciators » Connections are power-limited. ° The power run to the LCD-80 or ACS Annunciator does not require a Power Supervision Relay because the loss of power is mherently supervised through communication loss. е The maximum LCD-80 current draw from power supply is 500 mA. C Providing power to 0000000 “NU BRU AU N.C. Trouble Inputs Common in (>) Common Out (-) Power In (+24VDC) Power Out (+24VDC) C ACS and LDM-type Annunciators terminals 6 and 7 do not exist on the ACM-8R 0000000 — PS Lo be UN Os 4 Earth Ground E 1222922290 DODODBOO||po60600200|; Pa 8 +B-8+8-8+5-B+81 КО © но нЕ CONO MOE TB1-3 (+) TB1-4 (-) Figure C-3 S0604:F HA-242 Tronsmil ELA-237 Referenca ~ Iyrivrn Common OUT - System Common IN +24 VDC OUT +24 VDC IN ELA-232 Eecetve + VDC or +24 VLC IN ELA -247 Escoive a P ВА-232 Tronemit | De FLA-714 Reference =) - System Common CUT [a - System Common IN (e [im] [=] Der 11002200}; 5.4 4.0 Providing power to the LCD-80 220000 0002000 В«Й- Я. В.К. й- В. й- 3 aD € ka нс с ко ис о TBT-3 (+) TB1-4 (-) Power Connections for LCD, ACS type Annunciators 75 Appendix D - Releasing Applications Standards The control panel can be used as a control panel for agent release or pre-action/deluge control applications. When used with compatible, UL-listed actuating and initiating devices, the system meets the requirements of the following standards: NFPA 12 CO2 Extinguishing Systems (high pressure only) NFPA 12A Halon 1301 Extinguishing Systems NFPA 12B Halon 1211 Extinguishing Systems NFPA 13 Sprinkler Systems NFPA 15 Water Spray Systems NFPA 16 Foam-water Deluge and Foam-water Spray Systems NFPA 17 Dry Chemical Extinguishing systems NFPA 17A Wet Chemical Extinguishing systems NFPA 2001 Clean Agent Extinguishing systems Programming The contro! panel includes four software zones (zones 91, 92, 93 and 94) that are used to control releasing functions. Each zone operates independently, and is fully programmable. The LCD display called up during READ STATUS or SPL ZONE programming for zones 91-94 is shown to the right. кА Валы Е fins > = 433 TEL PA Tue, STR TAE TL NT TE TE Delay is the programmed time from alarm activation of an initiating device mapped to this zone, until activation of all output devices mapped to this zone. If cross-zoning is selected, the delay timer starts when two or more devices are in alarm (see below for details). The timer “XX” values may be set from 0 seconds to 60 seconds, If abort or manual release type MMX modules are mapped to this zone they affect the timer operation as defined below. Abort is the type of abort algorithm used by the zone. It may be one of four types, ULL IRI, NYC or AHJ, defined in the table below. ULI Standard Ul-typs delay timar which continues to count down upon ABORT, and stops and hotds at 10 seconds until release of the ABORT switch. Upon release of tha ABORT switch, the timer rasu- IRI IRLtypa deizy timer which func- tions the same es the UL-type timer with the excaption that the ABORT will function only if pressed and heldbafore 2nd zone goes into alarm. NYC NYC-type delaytimer. Pressing ABDRT, once an alarm exists, changes timer value lo tha time seleciod plus BO seconds. The timer will not start as long as the ABORT ewilch is haid. AHJ Local Jurisdiction dalay timer. Onca the timer has slarted, pressing ABORT restores timer 10 tt5 full lime. The timer will not start as long as ABORT is held. Halanse of the ABORT swilch mes lhe countdown al 10 seconds. continues the countdown, whereas pressing ABORT again will restore the timer lo its full valua. These modes are the only ones that comply with UL Standard 864. Note: ABORT timer will not operate when timer is set for "NO DELAY". - Cross N= No Cross zoning of any type. ve Y = Cross zone activation will occur after two or more devices mapped to the same zone activate, Z = Requires the activation of two initiating devices mapped to two different zones. H = Requires the activation of at least one smoke detector and at least one heat detector. Soak 1s used to automatically shut off the releasing solenoids for a user-defined time after the zone turns them on. It may be programmed for zero (no soak timer), or 10 to 15 minutes. Use in NFPA 16 applications . only. 76 > 50604 Special Module Types 50604:F The following module type codes, which have special releasing functions, can be programmed into the control panel. Special releasing device type codes are listed below. "ABORT SWITCH" — A type code assigned to an MMX Monitor Module which performs the abort functions described above. The MMX is connected to a UL-listed abort station such as the Notifier ARA-10. All wiring is fully supervised, following the wiring instructions for the MMX modules described earlier in this document. Multiple Abort Switch modules may be installed and they will provide a logical “OR” function, similar to multiple conventional abort switches on a single conventional zone. "MAN. RELEASE" — A type code assigned to an MMX Monitor Module which performs a manual release function. The MMX is connected to a UL-listed manual station such as the Notifier ARA-10 or NBG-10. It will override all Abort Switch modules that are active and programmed to the same releasing zone. All wiring is fully supervised, following the wiring instructions for the MMX modules described earlier in this document. Multiple MAN. RELEASE modules may be installed, and they will provide a logical “OR” function, similar to multiple conventional release switches on a single conventional zone. "REL CKT ULC" — A type code assigned to a CMX contrel module, or one of the four Notification Appliance Circuits on the control panel, which activates a releasing solenoid ar other releasing device. All wiring to the release device, and the release device itself, is fully supervised and suitable for use with limited energy cable. The release device activates when an initiating device programmed to the same zone activates (two devices if cross-zoning selected); and the delay timer (if used) expires; and no Abort Switch (if used) is active. You can program multiple Release CKT types to the same releasing zone, and they all activate when the : zone becomes active. RELEASE CKT" — This type code operates similar to "REL CKT ULC" but the release device circuit is supervised for open circuits and ground faults only (not short circuits). You cannot use this type code for | applications requiring ULC Listing or with limited energy cable. Do not use REL-4.7K (panel output) or REL-47K (CMX module) with this type code. 77 Initiating Devices Initiating devices may be FDX intelligent heat detectors, SDX or CPX intelligent smoke detectors, or may be conventional detection devices which are UL-listed for the purpose and connected to MMX modules. Several of these initiating devices may be used for the same releasing hazard by mapping them to the same releasing zone. Factory Mutual and certain local authorities having jurisdiction (LAHJ) require that redundant wiring (NFPA 72 Style 6 or Style D) be used for the initiating devices in releasing applications. Warning Sounders Warning sounders are connected to any of the four Notification Appliance Circuits or to CMX module circuits as described earlier in this document. Multiple Notification Appliance Circuits may be activated by the same releasing hazard. To activate when the delay timer is started, and/or the releasing device is activated, the CMX module should be mapped to the releasing hazard zone (91, 92, 93 or 94). Note that if cross zoning is selected, this sounder will only activate when two zones are in alarm. Also note that, unlike the release solenoids, the sounders do not wait for the delay timer. To activate immediately when any one of the initiating devices are activated, the CMX should be mapped to a separate zone (not 91, 92, 93 or 94) that is also mapped to all initiating devices of the hazard. Note: If coded sounds are required for warning sounders, they must use one of the four panel Notification Appliance Circuits, not a CMX circuit. Auxiliary Control Functions If control relays are required for release application, CMX modules set for dry contact operation may be used. They may be programmed for different functions the same as warning sounders described above. Control functions may also be provided by use of the RTM-8 module or the ACM-8R remote relay module mapped to the software zones of the control panel. ACS Annunciation ACS point annunciation of releasing functions can be done by annunciating any of the software zones described above, including zones 91, 92, 93 and 94. ACS annunciation of individual detectors may be achieved by assigning each detector to a separate software zone and annunciating the zone. Deluge/Pre-Action Release 78 When using this configuration for Deluge and/or Pre- Action Services, wiring must be configured to maintain a minimum voltage on releasing circuits. Calculation of maximum allowable resistance: Where R, = maximum allowable resistance of wiring, I = solenoid current, and V, = allowable voltage drop. Notes: » Factory Mutual requires 90 hours of standby power, Style D (Class A) wiring on all Initiating Device Circuits and V, = 0.2 volts. « For NFPA 13 and 15 applications, the soak timer must be disabled. « For NFPA 16 applications, the soak timer may be set to 10 or 15 minutes. « For UL-listed and FM approved Solenoid Release Valves, refer to the Device Compatibility Document. 50604:F = — Compatible Solenoid Valves Terminate ай unused circuits with a 4.7K ELR For a list of compatible solenoid valves, refer to the Device Compatibility Document. 200000 22000000| 120000000 + = + - + B+ B- B+ B- B+ B- B+ B- NO C NO NCC NO NCC 181 TB2 TB3 Figure D-1 Notification/Releasing Connections 24 VDC power from MICRO-200-I 2 Red 7) TB2-2 (--) Releasing Device (UL-listed) 24 VDC Figure D-2 Typical Connection of Releasing Device to Panel SLC Loop to MICRO-200-1 С) TB6-5 (-) L TB6-3 (+) 24 VDC power = Alarm polarity shown rom MICRO-200- —2 СМУ 7 |= | GE -2 (-) la nano _ Releasing Device - (UL-listed) 24 VDC 2 e —— [WT t TB1-i (+) N.C. Supervised ! a EE EE wT Relay Contact Power Supervision Relay A77-716-02 Figure D-3 Typical Connection of Releasing Device to CMX 50604:F 79 80 Appendix E — Wire Requirements Each type of circuit within the fire alarm control system has a specific type of wire that must be used to ensure proper operation. In addition, the wire gauge of a particular circuit depends on the length of that circuit. Use the table below to determine the specific wiring requirements for each circuit. Note: If the communications loop is to be run in conduit with Notification Appliance Circuits, the risk of encountering problems can be greatly reduced by exclusively employing electronic sounders (such as the MA/SS-241) instead of more electronically noisy notification appliances (such as electromechanical bells or homs). Circult Type Circult Function Wire Requirements Distance (feet) Typical Wire Type SLC Loop Connects to intelligent Twisied-shielded pair, 1210 | 10,000 12 AWG Belden 8583 WPW 999 (power-limited) and addressable modules | 18 AWG. 40 ohms maximum | 8,000 14 AWG Belden 8581 WPW 935 per length of Style 6 and 7 4,875 16 AWG Belden 9575 WPW 991 loops. 40 ohms per branch 3,225 18 AWG Balden 8574 WPW 975 maximum for Style 4 loops Untwisted, unshielded wire, {1,000 18-12 AWG in conduit or outside of | conduit _ _ ElA-485 Connects lo LCD-80 orto | Twisted-shielded palr witha {6,000 (max) Belden 9860 (16 AWG) {power limited) Annunciator Control Characteristic impedance of System Modules 120 ohms * 18 AWG minimum ElA-232 Connects to PAN or P40 | Twisted-shielded pair * 18 50 (without Belden 9860 (16 AWG) (power-imitec) Remote Printers andto a | AWG minimum. modam DOS-based personal | computer _ _ MMX-1, Initiating Device Circuit 12-18 AWG » Maximum loop | To meet 20 ohms | 12-18 AWG MMX-101 (IDC) wire resistance is 20 ohms {powerdimited) CMX Notification Appliance 12-18 AWG. MP5-24A: Al To meet 1.2 V 12-18 AWG (power-limited) Circuit (NAC) alarm current level, no more {drop than a 1.2 V drop at the end of the circuit 24 VDC To annunciators and CMX | 12-18 AWG, Size wire so that | To meet 1.2 V 12-18 AWG Power Runs no more than 1.2 V drop drop {power-limited) across wire run from supply source to end of any branch NR45-24 Remote secondary power 112 AWG in conduit 20 (max) 12 AWG source 50604:F Appendix F — Pre-Alarm (AWACS™) Applications General ~The control panel includes a facility to give early warning of incipient or potential fire conditions (U.S. Patent — Pending). This is a two level Pre-Alarm function called AWACSTM (Advance Warning Addressable Combustion Sensing). The two levels are Alert and Action. ME o Alert Level Pre-Alarm Operation The contro! panel software, in addition to checking | for alarm levels, will check for Pre-Alarm thresh- or SM НЕМ. olds for each ionization or photo smoke detector 5 : (not analog thermal detectors). If a level is reached Г that exceeds the programmed Alert threshold, the Alert condition is indicated. As an example, a . typical display is shown to the right. —. PREALM is the Pre-Alarm status banner. ALERT indicates that the Alert level is reached. up EN E E Te A ая nr - + Nu ll E wp bet | 2] in Sin tet 4 Les + у a mn e. EL + 50% is the reading of smoke in approximate percent of alarm. This is a real-time display which is updated every few seconds to show the current reading of this detector. In this case, assume that zone 99 is programmed ‘to ALERT= 40% OF ALARM. This means Alert will occur at measured smoke levels that exceed .40 x 2.0% per foot obscuration (low) = 0.80% per foot obscuration. In the example above, the reading is at 50% of alarm, therefore the control panel is in Alert condition. 2.0% is the programmed alarm threshold (2.0% per foot obscuration is the low sensitivity setting). _ The following functions are performed at Alert level: « Theabove message 15 sent to the history file and (ifthey are installed) to the LCD-80 and printer, The message is sent (and time stamped) only at the time that it first occurred. This historical data could provide valuable information about the progress of a fire. . The Pre-Alarm LED flashes and the piezo sounder pulses until acknowledged. Zone 99 is activated. Not activated are Zone 00 (general alarm) or any other zone, or trouble relay or alarm relay. * The Pre-Alarm indication for this detector will restore automatically to normal if its sensitivity drops below Alert level. Zone 99 clears automatically when no Pre-Alarm conditions exist. - A subsequent alarm, or an Action level condition for this detector will clear the Alert indication. 50604:F 81 Action Level Pre-Alarm Function If a detector reaches a level that exceeds the pro- grammed Action threshold, an Action condition is indicated. The display shown to the right appears if a detector is in Action level. ACTION indicates that the Action level is reached. 70% 1s the real-time approximate obscuration reading. Suppose Zone 99 was programmed for ACTION = 60% OF ALARM. Any measurement over .60 X 2.00% = 1.20% would cause an Action Pre-Alarm. The following functions are performed at Action level: « The message is sent to the LCD-80, printer, and history file. * The Pre-Alarm LED and piezo sounder pulse until acknowledged. » Zone 99 1s activated. Zone Z00 (general alarm) is not activated, nor are trouble and alarm relays. * The fifth zone programmed (not the first four) for this detector is activated. The fifth zone is the right-most entry on line three of the point programming screen. This zone may be used to control functions of a detector or group of detectors on Action level. The fifth zone activations will also allow ACS annunciation by a detector or group of detectors in Action Pre-Alarm state. * The Pre-Alarm condition and the zone programmed will latch until System Reset, even 1f the sensitivity drops below the Action or Alert level. * A subsequent alarm condition for this detector will clear the Action indication from the LCD display and keypad LED, but will not reset the fifth zone (the fifth zone is also on the alarm list). Pre-Alarm Programming You can adjust the setting of the two Action and Alert levels as desired. The Special Zone 99 display is shown to the right. ALERT=70% OF ALARM means that every photo and ion detector will give an Alert indication when its present sensitivity reaches 70% of its alarm level. The “ACTION=00% OF ALARM" means that there will be no Pre-Alarm Action level in the system. The numbers 70% and 00% are default values, and may be adjusted in the range from 00% to 99%. ACTION=00% means no Pre-Alarm, therefore the default 1s no Action level. The control panel's software ensures that the Action level is higher than the Alert level (or the Action level is zero) and that both are below 100%. The Alert and Action program levels are global settings, meaning they apply to all SDX or CPX detectors. However, different Pre-Alarm Action can be selected for each detector by using different alarm levels. For example, if the Alert level is set at 50% of alarm, and detector D13 is set to alarm at 2.00%, D13 will Pre-Alarm at 1.00%, while if detector D14 is set to alarm at 1.00%, it will Pre-Alarm at 0.50% per foot obscuration. There are applications where only one level of Pre-Alarm function is necessary, but the Pre-Alarm must be latching. This can be done by programming ALERT=00% and only using the Action level. Also, if non-latching operation is desired, ACTION=00% can be selected to allow use of Alert level only. Nete: Only the Action level will provide ACS point annunciation. 82 S0604:F — 1 3% — ALERT ACTION ALARM Woming ai panel Shut off power Evacudie building of possible fire to equipment monitored and call fire deportment by this detector PREALM SKOKE FLOOR 3 EQUI ALERT! 8,72% 2% — 11:725P 17775 SCHE ) <> CBSCURATION % pet foot . 1% —— . TIME ——— > Figure F-1 Typical AWACS Application Threshold Levels Self-Optimizing Pre-Alarm Function ‘The control panel software (PN 73609 or higher) includes a Self-Optimizing Pre-Alarm selection, where the control panel determines the highest practical Pre-Alarm sensitivity for each detector. Statistical methods and special software filters are used to automatically set the optimal Pre-Alarm sensitivity. The software compen- sates for electrical noise transients, dust buildup, and other environmental factors. When a detector senses smoke above the calculated optimal Pre-Alarm level, the control panel will latch into an Action Level Pre-Alarm. The Action Level Pre-Alarm Function was described earlier in this appendix. Applications include computer rooms, electrical equipment rooms, and telecommunication facilities where environments are clean and stable and early warning is very important. It is not recommended for applications where false smoke indications could exist, such as cigarette smoking. . Self-Optimizing Pre-Alarm mode will only operate with SDX-551 or SDX-751 photoelectric detector. Ioniza- tion detectors will not Pre-Alarm when Self-Optimizing is selected. Self-Optimizing is selected by programming Special Zone 99 for ALERT=00 and ACTION=01. Select “P” on the point programming screen for all photoelectric detectors for which Pre-Alarm is desired. The control panel will determine the optimal Pre-Alarm Action Level sensitivity after approximately 10 minutes of data sampling. Sounder Base Applications for AWACS The B501BH sounder base may be used with AWACS to give a local audible warning before general evacua- tion. This may be used to reduce the impact of false alarms from cooking, smoking, etc. in a multiple unit housing application. An individual in the apartment would receive advanced audible warning and could elimi- nate the source of the pending false alarm. Note: The control panel will activate the LEDs on the SDX or CPX detectors on a Pre-Alarm condition (Alert level or Action level). The detectors LEDs are used to drive the sounder base. When the LEDs on the detector light steadily for 10 seconds the sounder base will activate. If latching operation of the sounder base is desired, program the control panel for Action Pre-Alarm. If non-latching (self-restoring) operation is desired, program the system for Alert Pre-Alarm operation. If all sounder-bases are to activate on alarm, wire the power for these bases through two CMX relay contacts that will reverse the polarity to the B501BH bases on alarm. 50604:F 83 Appendix G — Pre-signal/Positive Alarm Sequence (PAS), Coding, and Time Control Pre-signal and PAS Activation of outputs that contain Z90 in their Control-by-Event (CBE) equation will be delayed for all alarm initiating devices that also contain Z90 in their CBE equation. A subsequent alarm will abort the delay and control-By-event equations will be executed. Do not include Z90 in the CBE equation for a releasing device. Pressing the Alarm Silence switch before the delay has expired will abort circuit activation. Pre-signal The Pre-signal delay time can be set between 60 and 180 seconds. The Pre-signal delay will not apply to the system alarm relay, 4X TM polarity reversal alarm output, 4XTM municipal box, and any RTM-§ output. Positive Alarm Sequence (PAS) Selected outputs are delayed for 15 seconds. Pressing Acknowledge within the 15-second delay will increase the delay to the full value programmed (60 to 180 seconds). The system alarm relay, 4XTM Polanty Reversal Alarm output, 4XTM Municipal Box output and the RTM-8 Transmitter output will delay when the alarm is from an initiating device that contains Z90 in its CBE equation. Do not include Z90 in the CBE equation for any Monitor Module that connects to a device other then an automatic fire detector. PAS will not delay the RTM-8 relay outputs. NFPA-72 requires the installation of a PAS inhibit switch. This can be done by using a Monitor Module programmed to type code “PAS INHIBIT.” Time Control All outputs that contain Z95 (or Z96) in their CBE equation will activate between the times specified for the days of the week listed in Z95 (or Z96). All smoke detectors that contain Z95 (or Z96) in their CBE equation will switch to their lowest sensitivity (3.0%) between the times specified for the day-of-week listed in Z95 (or Z96). Time control is active for all day-of-week selections listed in Z95 (or Z96). Holidays listed in 297, however, are excluded unless “H” is listed in the day-of-week selection. Enter time in 24-hour format with the Off time greater than On time. When using time control, always press the System Reset switch when making programming changes. Note: Active time control outputs turn off momentarily when programming or resetting the control panel. Coding 84 Control panel NACs that contain Z98 in their CBE equation are coded when activated by a fire alarm. However, the NACs are steady if activated by a Hazard Alert only. Do not include Z98 in the CBE equation if using these NAC: for releasing applications. Select coded type on a system base, via zone 98. Coding selections are: MARCH TIME (DEFAULT): 120 PPM (Pulses Per Minute) TWO STAGE: Alert signal—20 PPM; Genera! alarm signal: Steady on* - CALIFORNIA: 10 sec. on, 5 sec. off, repeats Ш TEMPORAL: 0.5 on, 0.5 off, 0.5 on, 0.5 off, 0.5 on, 1.5 off, repeats Note: An Alert signal is automatically sent to any of the four NACs that are not mapped to the alarm signal but are mapped to Z00 and Z98. After 5 minutes without an Acknowledge or Alarm Silence, the Alert signal becomes steady. 50604:F Appendix H — Terminal Interface Protocol General Description The control panel can communicate with a remote terminal or computer connected to its ELA-232 port (TB4), as described in Section 2.6 of this manual. Refer to the EIA-232D Protocol And Data Formats Manual for a complete description of the remote terminal or computer. The EIA-232 port can be configured for interactive operation or for monitoring only. Interactive operation requires that all equipment be listed under UL Standard for Safety UL864 and be installed/configured as directed under Local Terminal Mode (LocT) or Local Monitor Mode (LocM). EDP-listed equipment 15 permitted for ancillary system monitoring when the system is installed/configured as directed under Remote Monitor Mode (RemM), Use of EDP-listed equipment is also permitted for system servicing or programming. The EIA-232 ports on some terminals/computers, including the CRT, are not isolated from earth ground. These devices should be connected to the control panel via isolation modems, since their direct connection ‘would introduce a ground fault. There are three different operating modes for the EIA-232 port; Local Terminal, Local Monitor, and Remote Monitor. The operating mode is selected during panel programming, under the system parameters section (7=SYSTEM). The operation of each mode 15 described below. Modes of Operation Local Terminal Mode (LocT) Local Terminal Mode operation lets you perform Read Status and Alter Status operations from the terminal. In addition you can also do Acknowledge, Signal Silence, System Reset, and perform a Drill functions from the CRT. A user-definable password is required to perform the Alter Status function. The functions described below are available when operating in Local Terminal Mode. The Terminal must be mounted in a UL-864 listed enclosure, a Notifier Rack-51, Rack-67 or arranged to provide equivalent protection against unauthorized use. * Read Status Display the status of an individual point (detector, module, panel circuit, or zone) Display a list of all the points in alarm or trouble Display a list of all programmed points in the system Step through the history buffer event by event — Display the entire history buffer * Alter Status Disable/Enable an individual point Change the sensitivity of a detector Clear the verification counter of all detectors Clear the entire history buffer | Set the AWACS Alert and Action levels » (Control Functions Acknowledge Signal Silence System Reset Drill Local Monitor Mode (LocM) Local Monitor mode operation allows the same functions as Local Terminal mode with the exception that a password is required to perform Acknowledge, Alarm Silence, System Reset, and Drill. Because of this password security feature, the terminal does not need to be enclosed in a rack to prevent unauthorized use. S0604.F 85 Remote Monitor (RemM) Remote Monitor mode operation only permits the user to perform the Read Status function. This mode can be used with UL EDP listed terminals, including personal computers using Notifier PK-200 release 2.0 software or terminal emulation software. It is also intended for terminals that are connected through modems connected through a public switched telephone network, such as the Notifier TP1-232 modem. r CRT-2 Operation Read Status To perform the Read Status function from the CRT, the operator simply presses the Read Status function key (F1). The control panel responds with a menu which displays a number of options. = User presses Control panel displays on CRT: | READ : Read Point=0 Alm/Tbl Status=1 Read All Points=2 History Step=1/All=4 | STATUS TT т — Pilon ged Jot A ES NS SE TL PESO rete Мм TROT TT SW eE PATERNA e re Td UTA TÉR CPE AT фо — Read Point enables the operator to read the status of any point in the system (detectors, modules, panel circuits, software zones, and system parameters). [o] ENTER + Enter D(Det.) / M(Mod.) / B(Bell) / Z(Zone),AR or S{system params.) 3 NORMAL SMOKE (PHOTO) DETECTOR ADDRESS 29 2912 г 0.00/2.00% *р* Pressing the PRIOR (F5) or NEXT (F6) function keys allows the user to step forward or backward through a list of devices, DETECTOR ADDRESS 30 291 2 2 2 Z 0,00/1,50% *P* D30 mm — My Basi came mT бери E au ee ar 8 - ee : т. Колм „т Эта и cri "Pr tale Alm/Tbl Status display a list of all the devices in the system that are either in alarm or trouble. Sr ENTER - : В ETROUBL HEAT (ANALOG) DETECTOR ADDRESS 06 291 INVALID REPLY 08:10A 08/20/97 DOA { TROUBL SMOKE (PHOTO) DETECTOR ADDRESS 29 212 DEVICE DISABLED 08:10A 08/20/97 p29f i TROUBL CONTROL MODULE ADDRESS 21 200 OPEN CIRCUIT 08:10A 08/20/97 M2 E H Brae ELE TD TE o a nu iaa rie o ALA de ph Tio ly я 86 20604:F Read All Points displays a list of all points programmed in the system. This list will display the status of all addressable detectors, modules, panel circuits, system parameters and software zones. | a | [ENTER NORMAL HEAT (ANALOG) DETECTOR ADDRESS 32 232 2 Z Z 2 08:10A 08/20/97 DOGli : MODULE ADDRESS 02 . - 201 Z 08:10A 08/20/97 M02[: 200 0B:10A 08/20/97 MD2} Pa LEED Sh = Er ss History-Step allows the user to step through the history buffer using the PRIOR and NEXT keys. The first event displayed is the most recent event. SYSTEM RESET 3:17A Fri 08/20/97 |i PITT ee NE ic: alar ica ENEE" EEN TE NU NT 1 > Erle : = mia, LG ER n A À ad SENTE 1 Lidl Ar Sdn ar lei Ee TP a SE ar ACKNOWLEDGE | 3:16A Fri 08/20/97 |; PRIOR ALARM: SMOKE (PHOTO) DETECTOR ADDRESS 29 ZONE 01 3:15A 08/20/57 D29 - | PRIOR History-All sends the entire history buffer to be the CRT, from oldest event to newest. | ¡ENTER i AAA EA wv hk dd EVENT HISTORY STUART Od dl led EEE Ri 4 ALARM: HEAT (ANALOG) DETECTOR ADDRESS 55 ZONE 55 3:10A 04/20/97 055 | ii ALARM: SMOKE {PHOTO} DETECTOR ADDRESS 23 ZONE Di 3:15A 04/20/97 029 | | ACKNOWLEDGE 3:16A Fri 04/20/97 É SYSTEM RESET 3:17A Fri 04/20/97 $ H 1 El = de de de le de de de de ae de de e dr de hdd de AIN ER EVENT HISTORY END OT te ETA EA Re EEE Ep EE TT EE RE Cap RÉ UT EE 50604:F 87 Alter Status The Alter Status function allows the operator to enable or disable points, change detector sensitivity, globally clear the detector verification counters, clear the history buffer, and set AWACS Alert and Action levels. After pressing the Alter Status key, the following menu will appear: ALTER STATUS] [ff Enter Status Change Password or Escape to Abort TE Te ELE Da E ELA TALA E Вы бое TC SEE EE METE . + EE . - I] a ALA DELLA ANDAN AAA AAA NEAL hy To aC Te FEE ed TA LEA Dalmata nai os e The Status Change Password must now be entered. The factory default Status Change Password is 11111. The password does not display on the CRT, five asterisks will display in place of the password. OC DOC PAPE aa Te EN и Пеле 7 La - ETT dial: EAT TNA TAR ALL EE A E. TT NA UT E E La No em Toe EAT a TAJO A Rae ai DOE Del La AA E AA E NE EA ETE ie 5 4 i=Disable 2=Sensitivity 3=Clear Verification 4=Clr History 5=Set Action/Alert : a A AA RE Set Le Ll re Le Ts er A EE Pa LE er CAE EE EE pe EE em BE mE ar eee -тка Disable allows the operator to enable or disable detectors, modules, or panel circuits. De Enter the number of the detector, module, or bell circuit you wish to disable or enable. Example Notification Appliance Circuit (NAC) number 1. BLE) Disable/Enable D(Det.) / M(Mod.) / B(Bell ckt.}, AA RAE AT ea Ten TEE NIC Ear TT EAT ARE La A A TE E И A A RENTA ные ПО. рен e AA Ts AA TAI MIRAS ZT. LV Smads Lar, ae Iber ae La] 5 BOl Now Enabled, Enter E(Enable) / D(Disable) or Esc. to Abort È и" a Ц pinta i FA Map , — pal ri ddl ¿E ha a peli eS be TAN AAA A dae ae ri ea ld TA A e cr Th re Le e 88 50604:F Sensitivity allows the operator to change the sensitivity of any addressable detector in the system. ENTER! В Ce #5 Det. Sensitivity Enter point: AA, E Now enter the address of the detector you wish to change. Example Detector 57. (9) (5) a D57 now Low sens. Enter H, M, or L to change, Esc. to Abort fe a as Tao A pa ERA PEA A Er A A meh ET a D EE A EEE ra LEE Clear Verification enables the operator to clear the verification counter for all the addressable detectors in the system. | 3 | [ENTER] 4 Press Enter to Clear Verification Counts or Esc. to fink TITAN ET Bp Te pe AA TEE ETE MEN NN Le EY JER ae ay Clear History allows the operator to clear the entire history buffer, 8 [4] ENTER ÿ Press Enter to Clear History or Esc. to Abort TACA A ELA AAA NAL ZALLA ALELLA ES ES AS E AAA AENA RSE TA ASAS LLANA E Thr DnB Par wl Sedans dn ais Set Action/Alert enables the operator to set the AWACS Alert and Action levels. | 5 | [ENTER] i set % of Alarm: Alert (T) and Action (N) Format: TxxNxx then ; в Enter LM, a ; Ad ora ie 4 = fe a me met tp - ee : : Enter the Alert and Action AWACS levels. Example: Alert level=50% and the Action level=70% ENTER ENE y A TN EEE eN DANCE NET ra RE PE En 50604:F 89 CRT-2 Configuration The CRT-2 must be set up to communicate with the control panel using the proper protocol. To enter the setup menu on the CRT-2, hold down the CTRL button while pressing the SCROLL LOCK key. There are thirteen groups of parameters that must be set. Each of these thirteen groups is reached by pressing the 90 corresponding function key (F1 — F13). Use the arrow key to move through each setup group and use the space bar to view the options for each parameter. F1 Emulation=Wyse-50+ Aux Baud Rate=2400 Aux Data Format=7/1/E Host/Printer=EIA/Aux F2 Emulation=Wyse-50+ Auto Font Load=0n Monitor Mode=Off Warning Bell=On F3 Page Length=24 Display Cursor=0n Columns=80 Scroll=Jump F4 Language=U.S. Keyclick=0ff Key Lock=Caps FS Enter Key=<CR> Alt Key=Meta F6 ELA Baud Rate=2400 Aux Baud Rate=2400 EIA Xmt=Xon-Xoff Aux Xmt=Xon-Xoff ELA Break=Off Aux Break=Off F7 Comm Mode=Full Recv <DEL >=lgnore Send Block Term=<CR> Comm Mode=Full Duplex Enhanced=0n Language=U.S. Enhanced=On Auto Page=0ff Screen Saver=0ff Host/Printer=EIA/Aux Screen Length=26 Lines Cursor=Blink Block Width Change Clear=0ff Refresh Rate=60 Hz Char Set Mode=PC Key Repeat=Off Return Key=<CR> Desk Acc=Disabled ELA Data Format=7/1/E Aux Data Format=7/1/E EIA Recv=Xon-Xoff{XPC) Aux Recv=Xon-Xoff(XPC) ELA Modem Control=Off Aux Modem Contro!=Off Duplex Local=Off send ACK=On Null Suppress=0ff EIA Baud Rate=2400 ELA Data Format=7/1/E Sessions=One — Auto Wrap=01f Auto Scroli=On Bell Volume=09 Sessions=One Screen Video=Normal Auto Adjust Cursor=0n Speed=Normal Overscan Borders=Off Key Mode=ASCI Margin Bell=Off Backspace=<BS>/<DEL> ”. Pound Key=U.S. ELA Panty Check=On Aux Panty Check=0n EIA Xmt Pace=Baud Aux Xmt Pace=Baud EIA Disconnect=2 sec Aux Disconnect=2 sec Recv <CR>=<CR> Send Line Term=<US> 50604:F FE Pmt Line Term=<CR><LF> Prnt Block Term=<CR> Secondary Recv=0n F9 Page Edit=Off WPRT Intensity=Dim WPRT Reverse=0ff WPRT Underline=Off WPRT Blink=Off Display NV Label=Off Save Labels=On Status Line=Off #19 and Fil Note: No functions in setup groups F10 and F11 will affect communications with the control panel. F12 The function keys on the CRT-2 should be programmed as follows: F1 —-А F2—B F3 —C F4 ~D F5~E F6 ~F F7~G F8 ~H FO ~] F10 ~J F11 -K F12 ~L F13-M F14 —N F15-0 F16 —P Shift F13 ~Q Upon the completion of programming of all the setup groups, press the Pause key, then press Y (yes) to save all changes. Upload/Download 50604:F The EIA-232 port of the control panel may also be used to upload and download the operating program of the control panel. The operation of the upload/download software (PK-200) is described in the PK-200 Off Line Programming Utility manual. Download operations which change the basic program of the control panel must be done with responsible service personnel in attendance at the control panel. After a program is downloaded, the control panel must be tested is accordance with NFPA 72-1993. 91 Appendix | — AVPS-24 Power Expansion General Description The notification appliance power available from the control panel can be increased by three amperes when adding an AVPS-24/AVPS-24E to the system. The AVPS-24/AVPS-24E must be mounted in the battery compartment of the cabinet and the batteries must be relocated to the BB-17 Battery Box. The AVPS-24/ AVPS-24E supplies a maximum of 3.0 A to the notification appliances connected to circuits three and four combined, however the maximum current from any one circuit is limited to 2.5 A. Since the AVPS-24/ AVPS-24E supplies special purpose (unfiltered, unregulated) power, only compatible notification appliances listed in the Device Compatibility Document can be connected to circuits three and four, AC Power AC power required for the AVPS-24 15 120 VAC, 50/60 Hz, 1.0 A and AC power required for the AVPS-24E is 220/240 VAC, 50/60 Hz, 0.5 A. Programming The control panel must be programmed to supervise the AVPS-24/AVPS-24E. To program supervision for an AVPS-24/AVPS-24E, enter a "Y" in the SYSTEM screen after "AVPS=". A control panel programmed for an AVPS-24/AVPS-24E cannot be used in a combination Fire/Burglary application, since the AVPS-24/AVPS-24E trouble input is the same input used to monitor the door tamper switch (STS-200). Programming menu selection #7 SYSTEM SIL INH=000 AUTO=000 VERIFY=00 - USA TIME ANNUN=NONE SUPV LocM BLINK=Y 5ST=4 AVPS=Y Supply Calculations Supply calculations for systems with an AVPS-24/AVPS-24E are as follows. « Add 1.0 À for the AVPS-24 and 0.5 A for the AVPS-24E to the AC branch circuit current in Table A-1 « Do not include the load current on bell circuits 3 and 4 in the 5.0 A limitation in Table A-4 notes. » Include the load current on bell circuits 3 and 4 in the 5.0 A limitation in Table A-6 notes. System alarm current limitations with an AVPS-24/AVPS-24E installed follow: » TBl, terminals land2=15A « TBI, terminals 3and4=05A « TBl,terminais 5 and 6 = 0.5 À + TBI, terminals 3 and 4 combined with terminals Sand 6=0.5 A « All cireuits on TB! combined with TB2 terminals 1, 2, 3, and 4 = 5.0 A « TB2, terminals 5, 6, 7 and 8 combined (bell circuits (NACs) 3 and 4)=3.0 A + TB2, any one circuit = 2.5 À Installation I. Mount the AVPS-24/AVPS-24E as shown in Figure I-1. 2. Connect the AVPS-24/AVPS-24E and the control panel as follows: Earth Ground (green): AVPS-24/AVPS-24E, TB1 terminal 6 connects to control panel TB7 terminal 3. AC Hot (black): AVPS-24/AVPS-24E , TB] terminal 5 connects to control panel TB7 terminal 1. AC Neutral (white): AVPS-24/AVPS-24E, TB1 terminal 4 connects to control panel TB7 terminal 2. Battery (—): Black wire from the battery cable connects to AVPS-24/AVPS-24E TBI terminal 3. Battery (+): Red wire from the battery cable connects to AVPS-24/AVPS-24E TB] terminal 2. 97 50604:F S0604:F Connect AVPS-24/AVPS-24E output to control panel Notification Appliance Circuits 3 and 4 as follows: Cut jumpers JP6 and 7, located in the top center of the control panel circuit board. Plug the bell power cable, PN 71093 into plug J10. Plug J10 is located in the top center of the control panel circuit board. Connect J10 (—) to TB2 terminal 2 on the AVPS-24/AVPS-24E. Connect 310 (+) to TB2 terminal ! on the AVPS-24/AVPS-24E. Connect the AVPS-24/AVPS-24E trouble output to the control panel as follows: Cut jumper JP3, located in the bottom right center of the control panel circuit board. Plug the gray trouble cable, PN 71033 into Plug J11 with the wires exiting the connector on top. Plug J11 is located in the bottom right center of the control panel circuit board. Plug the other end of the cable into P1 with the wires exiting from the bottom. Primary power 1s connected to the AVPS-24/AVPS-24E as follows: Connect earth ground to TB! terminal 6, connect AC hot to TB] terminal 5, and connect AC neutral to TB1 terminal 4. Battery Connections: Connect the battery (-) to AVPS-24/AVPS-24E TB1 terminal 3. Connect the battery (+) to AVPS-24/ _ AVPS-24E TBI terminal 2. PN71093 E EJ O o) = EI JO © PN 71033 Figure 1-1 MICRO-200-1/AVPS-24 Power Expansion 93 Appendix J — UL Power-limited Wiring Requirements General Description r Power-limited and nonpower-limited circuit wiring must remain separated in the cabinet. All power-limited circuit wiring must remain at least % inch away from any nonpower-limited circuit wiring. Furthermore, all power-limited and nonpower-limited circuit wiring must enter and exit the cabinet through different knock- outs and/or conduits. A typical wiring diagram for the MICRO-200-1 is shown in Figure J-1. Power-limited Circuits Power-limited Circuits — — 0.75" gap a Nonpower-limited Circuits 0.25" gap | = == AC Power Figure J-1 — Typical Wiring Diagram for UL Power-limited Requirements 94 S0604:F Fire Systems’ WARRANTY All equipment described herein is warranted to be free from defects in all material and workmanship and this express warranty is in lieu of and excludes all other warranties, whether expressed or implied by operation of law or oth- erwise, including any warranty of merchantability and fitness for a particu- lar purpose. Warranty is for a period of one (1) year from the date equipment is placed in service or date equipment is ready for test, whichever date occurs first. The Purchaser agrees that he will inspect the goods upon delivery. Any claim on Account of Damages - either as received or during subsequent unloading, any storage handling, or where items of equipment may not agree in quantity, identi- fication number or description with the shipping documents - shall be deemed waived by the Purchaser unless made in writing within fifteen (15) days of the date of shipment. "Defective equipment for which a valid claim has been made shall be returned to the Seller in accordance with the return material policy; defective equipment goods so returned will be replaced without charge. The Seller will credit only standard freight charges prepaid by Purchaser (not air freight or any other express delivery charge). The Seller shall not be liable for any other loss, damage, or expense, including any consequential damages directly or indirectly arising from the condition or use of the equipment, or from any other cause; the exclusive remedy against the Seller being to require the replacement or repair of defective goods. Seller makes no warranty with respect to equipment manufactured by others and sold to Purchaser. However, Seller shall extend to Purchaser any warranties which it receives from such vendors. chemwar,p6S 04/16/98 Appendix K- U.S. Coast Guard Following is a list of equipment suitable for use in marine and shipyard applications as compatible with the MICRO-200-I, AVPS-24 Audio/Visual Power Supply B401B Detector Base B402B Four-Wire Detector Base B501 Flangeless Base for Intelligent Detectors B501BH Sounder Base BGX-101L Addressable Manual Pull Station BX-501 Base for all Intelligent Detectors/Sensors CAB-AM Cabinet for Marine Applications CMX-1 Addressable Control Module CMX-2 Addressable Control Module CPX-551 Intelligent lonization Smoke Detector CRT-2 Video Display Monitor with Keyboard DHX-501 Duct Housing DHX-502 Duct Housing Drip Shield Kit Alternate to CAB-AM FDX-551 Intelligent Thermal Sensor 1SO-X Loop Fault Isolator Module LCD-80 Liquid Crystal Display Module LP-610 Smoke Detector Base MMX-1 Addressable Monitor Module MMX-2 Addressable Monitor Module MMX-101 Addressable Mini Monitor Module PRN-4 80-Column Printer 50604:F 58-10 Surface Backbox SMB-500 Surface Mount Box SDX-551 Intelligent Photoelectric Detector System Sensor N-ELR Assortment Pack with Mounting Plate R-120 120 ohm End-of-Line Resistor R-2.2K 2.2K End-of-Line Resistor R-27K 27K End-of-Line Resistor R-47K 47K End-of-Line Resistor R-470K 470K End-of-Line Resistor 95
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