FIREQUEST ANALOGUE ADDRESSABLE FIRE CONTROL PANEL. Section 1 Installation Manual. Issue 1.3

FIREQUEST ANALOGUE ADDRESSABLE FIRE CONTROL PANEL FIREQUEST Section 1 Installation Manual Issue 1.3

CONTENTS iii CONTENTS SECTION 1 INSTALLATION... 1 Using the Manual... 1 GETTING STARTED... 2 What does a typical system consist of?... 2 Detection... 2 Display... 2 Sounder Control... 2 SOME THINGS YOU NEED TO KNOW... 3 Operating Voltage... 3 Environmental Constraints... 3 Quiescent current... 3 Battery Size... 3 Battery Charging capacity... 3 Current Limits... 3 Fire Brigade signal... 3 Connections... 4 Operating Instructions... 4 Earth Connections... 4 Internal Earth Connections... 4 Loop Earth Connections... 4 Repeater Communications Cable Installation... 4 Installing the Enclosure...5 Fixing to wall... 5 Connecting Cables... 5 Mains Supply...5 Field Device Installation...7 Detector Bases... 7 Manual Callpoints... 7 Zone Monitoring,Input,Output and other Loop-powered Units... 7 Cable Installation... 7 Loop Cable Testing... 7 Megger Tests... 8 Resistance Checks... 8 Sounder Circuit Installation... 8 Megger Tests... 8 Resistance Checks... 8 Cable Test Sheet (Sample)... 9 Standby Battery Calculations... 9 For 24-hour standby... 9 For 72 hour standby... 9 Calculating the Available Alarm Current... 10 Installing the Control Unit... 10 Baseboard Installation... 10 Cable Routing (must be through the top of the enclosure)... 10 Powering Up the Control Unit... 11 Battery power up... 11 Detector Loop Cables... 11 Sounder Circuit Cables... 11 Fitting the Front Door Assembly... 11 Fitting the Programme EPROM... 12 Setting the Battery Charger Voltage... 12 Connecting the Backfire Lead... 12

iv CONTENTS Hardware Installation Details... 12 Baseboard... 12 Baseboard Components Function Table... 12 Baseboard Additional Information... 14 Sounder Circuit/Volt Free Output Selection... 14 Network Module... 15 Door mounted CPU Board... 15 CPU Board Function Table... 15 CPU Board Additional Information... 16 Internal Wiring... 16 Printer... 17 Paper Feed... 17 Loading Paper... 17 Backfire Connection... 17 Backfire Cable details... 17 REPEATER CONNECTIONS... 18 Repeater Self test...18 REPEATER INTERNAL WIRING... 19 FIELD DEVICE SPECIFICATIONS... 20 Apollo Apollo XP95/Series 90... 20 XP95 Ancillary Specification... 21 Hochiki... 22 ESP Device Types... 22 Additional Features of ESP Detectors... 22 Power Up Sequence... 22 Device Test... 23 Optical Detectors... 23 Heat Detectors... 23 Ionisation Detectors... 23 Dual Zone Monitor... 24 Manual Callpoint... 24 Mini Zone Monitor... 24 Addressable Base... 24 Master Addressable Base... 24 Dual Relay Controller... 25 Dual Sounder Controller... 25 Dual Switch Monitor... 25 Output Bit Control... 25 Nittan... 26 Device Types... 26 AS Device Details... 26 Cable Test Sheet (Sample)... 27

SECTION 1 1 SECTION 1 INSTALLATION Using the Manual The manual is divided into sections, each of which will guide you through a particular aspect of the system. In the left hand margin icons are used to draw your attention to important Notes [!] or Warnings [ " ]. If you need to install and commission the system, then go to Section 1. This also contains drawings and connection details of all the hardware modules. If the system has already been installed and you need to know how to operate FireQuest Control Panel, then Sections 2 & 3 will detail the controls and indicators and take you through the normal operation of the system. Once installed Sections 4 & 5 will guide you through the configuration. When configuring a system with Apollo, Nittan or Hochiki ESP devices there are some additional features that are relevant to the configuration, these are covered in Appendix A If a fault or problem occurs refer to Section 3 - Normal Operation Dealing with Faults, which details the normal system faults that may occur. If further assistance is required, refer to the Troubleshooting Guide in Section 2.

2 SECTION 1 Getting Started This manual describes how the system is used for normal day-to-day operation and how to install and configure the system. What does a typical system consist of? The system may be divided into three main sections: Detection, Display, and Sounder Operation. Detection This is configured as a number of detection devices connected to a cable, in the form of a ring. This is referred to as a Loop. There may be up to 126 devices on a Loop. Each Loop can be subdivided into smaller groups of detectors, or Zones. The FireQuest panel is fitted with one loop interface. It may also be fitted with one additional loop. Display There are several independent display systems on the Control Unit. The main display is the 2-line Liquid Crystal Display, (LCD) which shows all the information with text messages to aid clarity, as well as a Zone indication. These independent indications ensure that a Fire can be detected and located. In addition, there are various LED s for immediate status indication for Fire, Faults, and so on. An optional printer records all the information for later analysis. Note: The LED s are supplied with chopped DC to reduce loading and therefore flicker. Sounder Control When an Alarm occurs, the sounders will operate in a pre-programmed arrangement. The sounders are connected to the Control Unit, in groups, or Sectors. Each Sector output may have a large number of sounders connected to it, all of which will operate in the same way.

SECTION 1 3 Some things you need to know OPERATING VOLTAGE The operating voltage is 230v.a.c.(+10% to 15%), ENVIRONMENTAL CONSTRAINTS Operating Temperature 5 to +40, RH 93% non-condensing. QUIESCENT CURRENT Normal condition quiescent current for the Control panel with a standard loop card is:- 1 Loop No Printer 250mA 1 Loop With printer 280mA 2 Loops No Printer 275mA 2 Loops With printer 305mA With a Mains Fault present, the current is reduced in both cases by 20mA. BATTERY SIZE Max battery size which will fit into the Control Panel is 12Ah. See the battery manufacturer s data on battery replacement for both the standby batteries and the memory battery, which should be typically 4 years and 8 years respectively. BATTERY CHARGING CAPACITY The total supply to the battery is 1.1 amps. See the battery manufacturer s data on battery replacement for both the standby batteries and the memory battery, which should be typically 4 years and 8 years respectively. Excluding the charger supply to the battery (as this has its own charging circuit); the system 24v has the capacity to supply an alarm load of up to 1.8 amps. CURRENT LIMITS The total any single circuit can take is 700mA. The Auxiliary supply output is rated at a maximum of 500mA. The total loading must not exceed 1.8 Amps. FIRE BRIGADE SIGNAL There is no facility to delay the Fire Brigade signal on LPC-approved systems.

4 SECTION 1 CONNECTIONS The terminals will accept from 0.5mm 2 to 2.5mm 2 cables, with a cable length of 2Km, subject to using the detector manufacturers calculations for voltage and capacitance. Mineral Insulated Copper Clad (MICC) cable is recommended; however most of established brands of fire-rated screened cable can generally be used. See connection details later in this Section for information on how to connect the system components. Please take the time to read the detector manufacturers information on field devices. OPERATING INSTRUCTIONS To operate the system read this Manual in full before use. Please see the section on Routine Testing in this manual in accordance with relevant sections of BS 5839 part 1 1988 and EN54. Earth Connections Special attention should be paid to Earth Connection. The system backbox should be connected to earth using a 4mm Earth cable. This should be connected to the backbox using the earth stud provided, and connected via a 5mm ring crimp, not wrapped around the stud. All field cable screens should also be terminated on this stud or the terminal provided. INTERNAL EARTH CONNECTIONS Internal earth cables are there to protect the system from static damage and the user from harm. DO NOT REMOVE THEM and ensure they are secure at all times. LOOP EARTH CONNECTIONS The Detector manufacturer provides a connection in the base of the detector for the termination of the Earth cable, which should be made use of. This must provide a continuous path around each loop. Loop earths must not cross, and therefore multi-core cable must not be used. This should be connected to the box using the stud provided, and connected via a 5mm ring crimp, not wrapped around the stud. REPEATER COMMUNICATIONS CABLE INSTALLATION The screen from the communications cable between the Repeater and the Fire Control panel should not be connected to the earth stud; it should be connected to the terminal provided. The Repeater enclosure should have both an isolated screen on the data cable, and a 4mm earth cable. If the Repeater is powered from the Fire Panel the 24v supply should be in a 2-core cable with an earth screen, as well as the data cable. If the Repeater is the main display for the building it must have all the standard elements of the EN54 Standard included, e.g. dual supply, dual data path etc.

SECTION 1 5! Installing the Enclosure The FireQuest Control Unit is normally supplied with the printed circuit cards fitted. These will not be required until commissioning, and may be removed and temporarily stored in a cool dry place. Where the panel is fitted with a printer, this is susceptible to dust and grit, and must be looked after accordingly. Fixing to wall Remove the front door assembly by disconnecting the ribbon cables leading from the CPU, removing the cable on TB1, and lifting off at the hinges. Remove the baseboard chassis by removing the fixing nuts and washers, and store temporarily in a safe place. There must be 5mm clearance at top and bottom of the box, 5mm clearance at the right, and 40mm clearance at the left, to allow for hinging. Drill three holes in the positions indicated. Fit the wall plugs and a panhead fixing screw in the upper mounting hole. Screw this almost home. Hang the enclosure on this screw, and fix to the wall with the two lower screws, taking care that the box does not twist, which would prevent the front door from closing correctly. Tighten the top screws until the unit is securely fixed to the wall. Remove the 20mm knockouts located on the top and bottom of the enclosure where necessary for cable entry, and make off incoming cable conduit or glands. The enclosure is now ready for cable installation.! Connecting Cables All cables should be specified and installed to meet the requirements of BS5839 Part 1 Subsection 17 or local equivalent standard. For the Loop circuit wiring, any type of unscreened or screened cable may be used with an MX fire C.I.E.. Thus MICC, FP200, SWA, Belden shielded twisted pair, shielded untwisted pair, unshielded untwisted pair cables, may all be used, providing that the conductor size is not less than 1.0mm 2, and not greater than 2.5mm 2 and that the cable parameters given below are not exceeded. When used, the Loop circuit cable screens must be joined within each device on the loop to form a continuous cable screen. All other cables must be of a sufficient size not to cause an excessive voltage drop. Note: It is an I.E.E. Regulation that fire alarm cables be segregated from all other (non-fire alarm) cables. All cables should have been meggered without any detection devices fitted. (See Field Device Installation later in this section for details of cable testing). The terminal blocks will accept cables with a cross-section of 2.5mm 2 in all cases. Cables should be stripped back, leaving 600mm within the enclosure for termination, if the cables are brought in through the bottom of the box, or 300mm if brought in through the top. Mains Supply The mains supply to the Control unit should be 220-250v.d.c. 50Hz, taken from an unswitched fused spur on a maintained power circuit. Connection to the mains supply must be via an isolating switch reserved solely for the purpose, its cover coloured red and labelled FIRE ALARM: DO NOT SWITCH OFF.

6 SECTION 1 " The isolating device: Must be as close to the incoming supply as is practicably possible. Should be secure from unauthorised operation. WARNING: FOR A SITE WHERE THE NEUTRAL OF THE MAINS SUPPLY CANNOT BE IDENTIFIED A TWO-POLE ISOLATING DEVICE MUST BE USED WHICH DISCONNECTS BOTH POLES SIMULTANEOUSLY. WHERE THE NEUTRAL OF THE MAINS CAN BE IDENTIFIED, A SINGLE POLE ISOLATING DEVICE MAY BE USED WHICH DISCONNECTS THE PHASE CONDUCTOR. Note: If a two-pole device is used, a label must be affixed inside the unit warning of a fuse in the neutral line. Earthing should be in accordance with the current IEEE regulations. All exposed metalwork and cabling conduits must be returned to earth via a suitable copper conductor. All cable screens are to be terminated on cable entry via suitable glands. System 0V MUST NOT be connected to earth It is important to ensure the correct routing of cables in order to minimise coupling effects. In particular, power and Loop signal cables should NOT be grouped together in the same conduit or trunking. Where it is unavoidable to run power and signal cables together, it is recommended that the separation between them is kept to the maximum distance.

SECTION 1 7! Field Device Installation The installation of the Detectors Bases, Manual Callpoints, Zone Monitoring Units and Isolators should be carried out as per the relevant Detector Installation Guide. The following notes are intended to point out possible pitfalls, which may affect the operation of the panel. Always remember to observe the polarity of connections, and where possible, avoid wiring detectors on a spur. We strongly advise against the use of multicore cables for loop wiring, and for the use of spare cores for other services, including DC supplies, unless suitable de-coupling is fitted at the panel to prevent crosstalk being induced from cable-to-cable via the common 'carrier'. We suggest the with FP200-type cable, earthing is at the panel end only, with the screen continuous. With MICC, site-earths should be minimised, but the screening should be continuous. DETECTOR BASES Most manufacturers Detector Bases are interchangeable, regardless of the type of detector being fitted in the base. However, with some types, the Short-Circuit Isolator is fitted into an Isolator Base, and the Zone Monitoring Units and other field units are wired into via terminals. The Loop cabling is connected to the bases such that continuity is maintained without the detector being present. The Isolators do not maintain cable continuity. For this reason, in order to megger the Loop cables, and conduct the resistance checks, the bases which contain Isolators must be temporarily fitted with Link Heads, while cable tests take place. MANUAL CALLPOINTS These units contain sensitive electronic circuitry, and must not, therefore, be fitted during cable proving tests. The incoming and outgoing Loop cables should be temporarily joined (observing polarity) using terminal blocks while cable tests are carried out. ZONE MONITORING,INPUT,OUTPUT AND OTHER LOOP-POWERED UNITS These units contain sensitive electronic circuitry, and must not, therefore, be fitted during cable proving tests. The incoming and outgoing Loop cables should be temporarily joined (observing polarity) using terminal blocks while cable tests are carried out. CABLE INSTALLATION Cables can be 1.5mm 2 or 2.5mm 2 in conduit, FP200 or MICC, with a maximum Loop length of 2km (1km for 1.5mm), subject to the normal load calculations. Other cables may be suitable, but they should have a core-to-core capacitance of not more than 300nF for the loop, nor a resistance of more than 20ohms when tested as described below. Reasonable care should be taken where possible, to avoid routing the detection loops close to any highvoltage or high-current cables or sources. Loop Cable Testing The Loop cables should all be tested for continuity and isolation before being connected to the terminals on the motherboard. They should be clearly marked with the Loop Number, the polarity (+ or -) and the 'direction' (Out or In). The following tests must be carried out with no devices (including callpoints, Isolators or boxed I/O modules) fitted to the system:

8 SECTION 1 MEGGER TESTS With the Link heads fitted in the Isolator bases (if installed), and the wiring at the Manual Callpoints and Zone Monitoring Units (if fitted) linked out with terminal blocks, the Loop cables should be meggered at 500v. Check that the resistance from core-to-core, and from each core to screen or earth is not less than 200Mohms. Record the actual values for each cable on the Pre-commissioning Test sheets. RESISTANCE CHECKS Link the Zone In +ve and the Zone In -ve cables together with a terminal block. Using a digital multimeter set to ohms, measure the resistance value across the Zone Out +ve and the Zone Out -ve cables. This must not exceed 20ohms. Remove the terminal block, and measure the resistance across the Zone Out+ve and the Zone In +ve cables. Measure the resistance across the Zone Out -ve and the Zone In -ve cables. These should be approximately the same figure. Record all these values on the Pre-commissioning Test sheets. If the Loop resistance exceeds the maximum acceptable figure, or if the Zone +ve and Zone - ve resistance figures differ by more than 2ohms, then there is probably a wiring error or a high-resistance (loose) terminal on that Loop. This should be located and remedied.! On very lightly loaded loops, there may be a need to fit a loading resistance across the loop to prevent incorrect operation of the system 1K8 ½ watt.. Sounder Circuit Installation The Sounder Circuits are all monitored for open- and short-circuit faults by use of a terminating end-of-line resistor, and sounder operation is by a 24v line-reversal principle. For these reasons, sounder circuit cabling must be checked thoroughly for faults. The cables should run as radial circuits from the control unit and be checked as follows: MEGGER TESTS With no devices connected, the Sounder Circuit cables should be meggered at 500v. Check that the resistance from core-to-core, and from each core to screen or earth is not less than 200Mohms. Record the actual values for each cable on the Pre-commissioning Test sheets. RESISTANCE CHECKS Link the Sounder +ve and the Sounder -ve cables together with a terminal block. Using a digital multimeter set to ohms, measure the resistance value across the Sounder +ve and the Sounder -ve cables. This must not exceed 20ohms. Record all these values on the Precommissioning Test sheets. When the tests are completed, fit the 4K7 end-of line resistor either within the panel, or at the end of line or in the last device. Note that on the 5 baseboard sounder circuits, the voltage across the EOL in normal state will be 5V (+/-0.2).

SECTION 1 9 Cable Test Sheet (Sample) See sample in Appendix Standby Battery Calculations The Battery load without the loop connected,(with the panel in a quiescent state) is between 230mA and 240mA without a printer connected and 270mA to 280mA with. The examples below are for a requirement of 24 hours or 72 hours cover; with an assumed Alarm load of 1.5A and no printer fitted. For 24-hour standby Multiply the quiescent current in amperes by 24, add 0.75 (assuming the normal practice of allowing for the panel to run a full alarm load for 30 minutes following a 24hr power failure) and multiply that by 1.25 (to allow for battery ageing); the answer is in Ampere Hours. FOR 72 HOUR STANDBY Multiply the quiescent current by 72 then add 0.75 (assuming the normal practice of allowing for the panel to run a full alarm load for 30 minutes following a 72hr power failure) before multiplying that by 1.25. e.g. 0.230A x 24=5.52 + 0.75=6.27 x 1.25=7.84AH. The battery would need to be 9 AH Once the loop requirements have been established reference must be made to the MX Digital loop loading calculation document (Document 17A-02-LOOP) where TYCO MX devices are being used and the apollo loading calculation PC programme LOOPCALC when the devices are of the Apollo type.

10 SECTION 1 Calculating the Available Alarm Current It is necessary to calculate the total available current for the detection loop devices and sounder circuits. The total available current is a dependent on the hardware modules fitted. The current can be calculated by adding up the quiescent currents from the table below and applying that to the Y-axis of the chart. The X-axis gives the total current available where the line intersects that current. For example, if the total quiescent current of the panel and optional fitted hardware is 330mA, then the total loop and sounder current available would be 1.25A. QUIESCENT CURRENT v ALARM LOAD ma (Quiescent) 450 400 350 300 250 200 150 100 50 0 1 1.1 1.2 1.3 1.4 1.5 1.6 1.7 Alarm Load (Amps) Installing the Control Unit It is essential that the cable tests described in the previous sections have been carried out before any attempt is made to install the control unit. The assumption has been made that the procedures described can be followed, and that no major problems are encountered. Where a problem means that a procedure cannot be followed, and where the remedy is not immediately apparent, then Section 2 - Trouble Shooting should be consulted. Ensure that the cables are all marked with polarity and function. Check that all cables are brought into the panel through suitably protected apertures, to avoid chafing. Check that the enclosure is securely fitted, and that the screw fixings are secure. Baseboard Installation Check the baseboard for any obvious damage, and fit into enclosure on studs provided. Fit washers and nuts, and tighten securely. Pay attention to the earth bonding and the alignment of the heatsink/transformer. Fit the Front Door Data Connectors, noting the orientation of the cable colours for later use. At this time it is also wise to check that the correct fuses are fitted as shown in Section 2 - Trouble Shooting. Cable Routing (must be through the top of the enclosure) It will be easier if the cables are routed to their approximate positions and cut to length at this stage, although they should not be made off into the terminals until instructed. Loop

SECTION 1 11 wiring is on the left hand end of the terminal block, with Outputs/Sounders in the centre section of the terminal block, and Repeaters and supplies on the right hand section. The incoming mains should be brought in through the top right hand side of the enclosure. The terminal block schematic in the end of this Section should be referred to for the final destinations of the cables.! Powering Up the Control Unit PCB's in this system are fitted with some STATIC-SENSITIVE components, and so anti-static handling procedures should be followed at all times. Failure to do so may damage the cards, and will invalidate the warranty. Disconnect the front panel p.c.b., and then switch on the mains. Check that the incoming supply is 220-240v.a.c. Check that the PSU supply is 27.5v.d.c. (+/- 0.2v) by measuring the voltage across the battery terminals. Remove the mains fuse and disconnect the battery before proceeding further. Connect the front panel p.c.b., and re-check the voltages. " Battery power up The unit can be powered up on batteries only, by connecting the batteries to the battery terminals at the bottom of the terminal field PCB and pushing and holding SW1 (located near the battery terminals) for 5 seconds. If the batteries are suitably charged, the system will start. The system will automatically turn off if the battery voltage falls below 22 volts. REMOVE THE MAINS SUPPLY AND BATTERY BEFORE THE NEXT STEP. Detector Loop Cables Make off the Detector Loop cables into the relevant terminal blocks, ensuring that polarity and direction are observed. This may be done by making off one end of the loop, and the Isolators (if fitted) removed from their bases. Connect a 24v supply to the loop cables, noting the polarity. Check at each Isolator in turn, starting with the one nearest the panel, that the voltage on the incoming terminals is +24v (typical) and 0v respectively, and that there are no volts on the outgoing terminals, with the Isolator removed. Replace the Isolator, and move to the next Isolator and repeat the above checks. When the final Isolator has been checked, return to the panel, and check the voltage on the incoming (un-terminated) loop cable. Ensure that the +ve leg is connected to the +ve terminal, to complete the loop. Sounder Circuit Cables Make off the Sounder Circuit cables into the relevant terminal blocks, ensuring that polarity is correct and ensure that any relays or other inductive devices are fitted with diodes reversebiased across the coils. Fitting the Front Door Assembly The front door assembly contains the controls and the operator keypad, which will be needed to set the system up for testing. The door should be fitted to the enclosure using the knurled screws provided, and the wiring and ribbon cables connected. Check that the front door closes and locks securely. If not, adjust the fixings as required.

12 SECTION 1 Fitting the Programme EPROM The socket for this EPROM is in the rear of the front panel p.c.b., and is sized to take a 2Mb device. The notch should be at the top. Setting the Battery Charger Voltage This is factory set to 27.3V at 25 C. To adjust this, use VR1, which is on the right-hand side of the Baseboard. The voltage will very dependent on temperature so any adjustments should be made with the Test Link fitted and a 1K resistor in the place of the Battery. Connecting the Backfire Lead Use the 5-pin DIN socket on the door mounted CPU board. Hardware Installation Details Baseboard Figure 1 FireQuest Baseboard BASEBOARD COMPONENTS FUNCTION TABLE Description Terminal Block 1 Terminal Block 2 Terminal Block 3 Function Earth Connection Loop 1 +VE Out Loop 1 +VE In

SECTION 1 13 Description Terminal Block 4 Terminal Block 5 Terminal Block 6 Terminal Block 7 Terminal Block 8 Terminal Block 9 Terminal Block 10 Terminal Block 11 Terminal Block 12 Terminal Block 13 Terminal Block 14 Terminal Block 15 Terminal Block 16 Terminal Block 17 Terminal Block 18 Terminal Block 19 Terminal Block 20 Terminal Block 21 Terminal Block 22 Terminal Block 23 Terminal Block 24 Terminal Block 25 Terminal Block 26 Terminal Block 27 Terminal Block 28 Fuse 1 Fuse 2 Fuse 3 Fuse 4 Fuse 5 Fuse 6 Fuse 7 Fuse 8 Fuse 9 Fuse 10 Fuse 11 LK 1 LK 2 LK 3 LK 4 Function Loop 1 -VE Out Loop 1 -VE In Loop 2 +VE Out Loop 2 +VE In Loop 2 -VE Out Loop 2 -VE In Output 1 +VE Output 1 -VE Output 2 +VE Output 2 -VE Output 3 +VE Output 3 -VE Output 4 +VE Output 4 -VE Output 5 +VE Output 5 -VE Repeater A (out) Repeater B (out) Repeater A (return) Repeater B (return) Repeater Cable Screen (all) 24VB 24VB 0VB 0VB Sounder Circuit 1 Resettable Fuse (800 ma Trip 400 ma Hold) Sounder Circuit 2 Resettable Fuse (800 ma Trip 400 ma Hold) Printer Fuse (2A) Sounder Circuit 3 Resettable Fuse (800 ma Trip 400 ma Hold) 5V Fuse (1A) Sounder Circuit 4 Resettable Fuse (800 ma Trip 400 ma Hold) Sounder Circuit 5 Resettable Fuse (800 ma Trip 400 ma Hold) 24V AUX Fuse (500 ma) Battery Fuse (3A) 24V Fuse (1A) 24V IN Fuse (3A) Sounder 1 Setup Reset Link - Link For Reset Sounder 2 Setup Engineer Test Link

14 SECTION 1 Description Function LK 5 Sounder 3 Setup LK 6 Sounder 4 Setup LK 7 Sounder 5 Setup LK 8 Buzzer Link LK 9 Earth Link LK 10 Fault Output Control TB1 Printer / CPU 5V TB2 Field Wiring TB3 Mains Terminal Block PL1 Edge Connector To CPU PL2 Loop Card Socket (Loop 1) PL3 Loop Card Socket (Loop 2) PL4 Network Connector PL5 Temperature Probe Socket PL6 Expansion Port PL7 VREF Control - Not Used ST1 Field Wiring Earth Tag Baseboard Additional Information SOUNDER CIRCUIT/VOLT FREE OUTPUT SELECTION The output relays can be field-configured for Sounder (24v line-reversal) or Volt-free operation as follows: For Sounder Operation Fit Relay in its base biased towards the top of the base Fit Link 1 and 2 on configuration link For Volt-free Operation Fit Relay in its base biased towards the bottom of the base For a Normally Closed contact, fit Link 2 and 3 on configuration link For a Normally Open contact, fit Link 1 and 2 on configuration link " ALL FIELD EARTH CONNECTIONS SHOULD BE TERMINATED ON ST1 ON NO ACCOUNT SHOULD THE TRANSFORMER STUD BE USED. 5V SHOULD ONLY BE USED FOR THE CPU AND PRINTER (IF FITTED) AND NOT FOR ANY OTHER PURPOSE. THE MAINS COVER SHOULD NOT BE REMOVED LK 10 Changes the function of the Common Fault relay to operate as a programmable output - the default is as Common Fault relay. Link 1 and 2 for programmable relay, 2 and 3 for Common Fault

SECTION 1 15 NETWORK MODULE The Network Module will be required for connecting a number of panels using a 2-wire Network Loop. The Network Interface fits as a daughter board onto the Baseboard and connects to PL4. PL4 may still be used for External Node Connection. Pin Outs For PL4: Pin 1 0V Pin 2 0V Pin 3 24V Pin 4 24V Pin 5 Network Interface TX Pin 6 Network Interface RX Pin 7 0V Pin 8 Network Enable Door mounted CPU Board Figure 2 Door-mounted CPU card (seen from inside of door) CPU BOARD FUNCTION TABLE Description PL3 SK1 TB1 LK1 LK2 Function Printer Interface Connector Backfire / Keyboard Connector CPU/Printer 5V Terminal Battery Link Reset Link - Short to reset

16 SECTION 1 IC23 B1 Eprom Socket Battery CPU Board Additional Information Upload / Download is achieved through the Keyboard Connector on the CPU Board. CPU Reset Link Short out to Reset CPU. CPU Battery Link - Should be left connected. Disconnection will empty the configuration memory when power is lost. CPU Terminal Block - As labelled on drawing CPU Edge Connector - To Baseboard PL3 - Printer Interface connector EPROM - Mounted on socket. Terminal Block 5V should not be used to power anything other than CPU or printer. Internal Wiring 1 2 3 4 5 6 7 8 D D PRINTER PORT AND SUPPLY OUTPUT RELAYS 1 TO 5 500 ma 24V OUTPUT MAINS SUPPLY IN EPROM MEMORY BATTERY LINK LOOP 1 WIRING LOOP 2 WIRING FIELD CABLE EARTH REPEATER WIRING C C 34 WAY RIBBON CPU & DISPLAY LCD CONTRAST ADJUST B B DIN CONNECTOR FOR KEYBOARD AND PC LINK TO "BACKFIRE" 5V ORANGE OP ( PRINTER 0V) BLUE ALL 16/0.2 BASE BOARD 5P ( PRINTER 5V) VIOLET 0V BLACK PRINTER FUSE5 VOLT FUSE LOOP 2 PLUG IN CARD BATTERY - BATTERY + LOOP 1 PLUG IN CARD A A Title FireQuest Internal Wiring Size Number Revision 2535v1 1 A3 Date: 1 Drawn 1 ACD 3-Aug-1999 Sheet of File: H:\PROTEL\PROJ\FQ98\2535V1.SCH By: 7 1 2 3 4 5 6 8 Figure 3 FireQuest Internal Wiring

SECTION 1 17 Printer Paper Feed Use the push-button mounted on the printer panel to feed the paper. Loading Paper To change the Paper Roll, move Lever to release the paper. Remove the old Paper Roll. Locate the new Paper Roll on the Spindle and feed through the Paper Roller. Excess paper needs to be fed through the Printer Cover to allow for correct spooling. EPSON PRINTER COVER LEVER PAPER ROLL PAPER ROLLER SPINDLE REPLACEMENT ROLL - PART NO. PRT/TP2 Backfire Connection Refer to Backfire Configuration Manual BACKFIRE CABLE DETAILS 9 Pin D type 5 Pin 180 DIN 2 3 3 1 5 4 Link pins 1, 6, 4 together Link pins 7 & 8 " PINS 2 & 4 ARE TTL ON THE DIN PLUG AND DAMAGE WILL OCCUR IF USED INCORRECTLY. THE PC WILL EARTH THE FIRE PANEL WHEN CONNECTED; ENSURE SYSTEM IS FREE OF EARTH BEFORE PLUGGING IN.

18 SECTION 1 Repeater Connections There are a number of versions of repeater available with the FireQuest panel. The simplest type can be just an LCD repeater, or it can be an LCD Repeater with Zone Lamps and Local controls. If the Repeater is of that type, then the following details are applicable. If the Repeater is a Full-function FireQuest Repeater, then please see the FireQuest Repeater Manual. If a Repeater is being connected to the Fire Panel, it must have the following connections: Connect from the Baseboard Terminals (marked REPT A, REPT SCR, REPT B) to the corresponding terminals on the Repeater. If there is more than one repeater, connect on from the first to the second and so on.. Set the Repeater Addresses: The first repeater MUST be set to address 02, the next to address 03 and so on. Connect the Power (if not integral). This may be in the range 10-35V d.c. Ensure that there is a link fitted on PL8 if there is not an Enable key. Fuse 1 is the 5V fuse and Fuse 2 is the Vin fuse; both should be 500mA. LK1 is the Buzzer enable link. Remove this to disable the buzzer. LED1 is the Power On LED. LED3 (yellow) is the Watchdog LED. If this is lit, the CPU has failed. LED s 2,4, and 5 show the communications status, and under normal operation, these should be pulsing intermittently. Repeater Self test The Repeater has a range of built-in test routines. Set the address switches to read 77, and re-apply power. Follow the on-screen prompts to check: That the Display is operating fully That the Switches all operate That the communications operates That the Address Switches are being correctly read And so on.

SECTION 1 19 Repeater Internal Wiring Figure 4 - Repeater Internal Wiring

20 SECTION 1 Field Device Specifications This Appendix gives more details for the following detector ranges: Apollo, Hochiki, Nittan Apollo Apollo XP95/Series 90 No Usage Abbreviation 0 Heat (Rate of Rise) ROR HEAT 1 Sounder SOUNDER 2 Digital (I/O Units) DIGITAL 3 Ionisation Smoke Detector ION 4 Shop Interface Unit SHOP UNIT 5 Optical Smoke Detector PHOTOELEC 6 Fixed Heat Detector HEAT 7 Manual Callpoint (inc. CPM) MAN CP 8 Control Unit Monitor CUM 9 Device Monitor Unit DMU 10 XP95 Loop Sounder XP SOUNDR 11 XP95 I/O Unit XP I/O 12 XP95 O/P Unit XP O/P 13 XP95 ZMU XP ZMU 14 XP95 Switch Monitor XP SWITCH 15 XP95 Switch Monitor Plus XP SWTCH+ 16 XP95 Priority Switch Monitor XP PRI SW 17 XP95 Sounder Group XP GROUP 18 XP95 High Sensor Optical 19 XP95 High Temp Fixed 20 Discovery Optical Multi-Crit 21 Discovery Dual Sensor 22 XP95 Beam Detector 23 XP95 Flame Detector! As some of the Apollo XP95 devices send back the same type code, then in the SELF LEARN sequence, the panel cannot distinguish one from the other. These are types 14, 15, and 16. In these cases, the device type will have to be entered manually after the self learn process, to ensure correct operation.

SECTION 1 21 XP95 Ancillary Specification Protocol Usage Mini Switch Monitor Mini Switch Monitor with Interrupt Switch Monitor Switch Monitor Plus Zone Monitor Command Bits O/P Bit 2 LED/Rem LED/Rem LED LED Detector LED Sounder Control Unit Ind or Grp Control O/P Bit 1 Self Test Self Test Self Test Self Test Self Test Pulsed Mode O/P Bit 0 Fault Test Not Used Not Used Opto Reset Reset Zone Continuou s Mode Input/ Output Unit Not Used Not Used Relay Operation Output Unit Not Used Not Used Relay Operation Interrupt No Yes No No No No No No Analogue Value Quiescent 16 16 16 16 16 16 16 16 Fault 4 4 4 4 4 4 4 n/a Pre-alarm 48+/-3 n/a 48+/-3 48+/-3 n/a n/a n/a n/a Alarm 64 64 64 64 64 n/a n/a n/a Input Bits I/P Bit 2 I/P Bit 1 I/P Bit 0 Type Bits LED/Rem confirmed Self Test confirmed Fault Test confirmed LED/Rem confirmed High=Qui Low=Alm High=Alm Low=Qui LED confirmed Self Test confirmed Confirms O/P bit 0 LED confirmed Self Test confirmed Opto-reset confirmed Det. LED confirmed Self Test confirmed Reset confirmed Ind/Grp addr conf Pulsed mode conf Continuou s mode conf Not Used Unmon. I/P status Monitored I/P status Not Used Not Used Not Used Bit 2, 1, 0 1 0 0 1 1 1 1 0 0 1 0 0 1 0 0 0 0 1 0 1 0 0 1 0 Bit 4, 3 0 1 1 1 0 1 0 1 0 0 0 0 0 0 0 0 XP95 Flag Yes Yes Yes Yes Yes Yes Yes Yes Alarm Flag Yes No Yes Yes Yes No No No Interrupt/Alarm Address Yes Yes Yes Yes Yes No No No Loop Current (total) Quiescent 1mA 730µA 1mA 2mA 1.2mA 720µA Alarm 3.5mA 3.4mA 3.5mA n/a 4.5mA n/a S/C 2mA 3.5mA 3.5mA 4mA 6mA n/a Max 3.5mA 5.6mA 5.6mA 4mA 6mA 3.3mA Surge 3mA for 60mS 2.5mA for 65mS 2.4mA for 94mS 3.5mA for 150mS 3.5mA for 150mS 3mA for 100mS Rly/Sndr operated n/a n/a n/a 3mA 4.5mA 3.3mA Max per loop 30 30 30 30 20 30 External Supply required No No No No No Yes No No Resistance req for: EOL 20KΩ 20KΩ 20KΩ 20KΩ 10KΩ 20KΩ n/a Alarm 1KΩ 1KΩ 1KΩ 1KΩ n/a 4K7 n/a Pre-alarm 10KΩ n/a 10KΩ 10KΩ n/a n/a n/a Special Functions Pre-alarm Pre-alarm Beam Detector Reset. Time delay on input Sychro in pulse mode. Group Addressing Additional unmonitor ed optoisolated input

22 SECTION 1 Hochiki ESP Device Types No Usage Abbreviation 0 Manual Callpoint MAN CP 18 Addressable Base ADD BASE 20 Master Base MAST BASE 21 Mini Zone Monitor MINI ZONE 25 Dual Zone Monitor DUAL ZONE 57 Dual Switch Monitor DUAL SWCH 94 Addressable Sounder 120 Dual Sounder Controller DUAL SNDR 124 Dual Relay Controller DUAL RLY 136 Optical Detector PHOTOELEC 152 Fixed Heat Detector HEAT 168 Ionisation Detector ION 216 Multisensor 255 Unused (Not scanned) UNUSED Additional Features of ESP Detectors Under normal circumstances, the Apollo XP95 and the Hochiki ESP ranges are treated in the same way. However, there are some aspects where users of Apollo XP95 systems may notice that the ESP range differs in operation. In particular, the Device Types (which are set as numbers from 1 to 10 for Apollo) are more diverse, and can have 3-digit values. This is dealt with in the manual by showing the two types in their own charts. Power Up Sequence The Hochiki ESP detector range has a somewhat more complex power-up sequence, which takes a few minutes to initialise the devices. The panel will display the message 01/JAN/97 12:34 LOOP INITIALISATION IN PROGRESS You may note that the LED s on the detectors and callpoints flash at irregular intervals while initialising (and in particular, if there are any Ionisation detectors, the LED on the lowest address device on each loop will flash almost continuously for one minute - this is normal). While initialising, the panel will be checking the detectors, and the Device Fault indicator may light, even though the initialising is not finished. This does mean that there is a device fault, which can be investigated (by pressing the MENU key with the CONTROLS keyswitch set to OFF for example) and rectified once the initialisation is completed. Once the panel has finished initialising, the detector LED s will flash once every 13 seconds approximately (irrespective of the number of devices). The alarm response time is not a function of the 13 seconds, as the devices use an interrupt to generate an alarm within the relevant timescales as set by the British Standards.

SECTION 1 23 Device Test The Device test function for the Hochiki ESP range is different depending upon the type of device in question. Having entered the relevant passcode and selected the menu item, the screen will show (typically): ADDRESS DEVICE TEST 1001 HEAT DEVICE TYPE VALUE=N C SET=X C However, should the device under test not be of the same type as is stored in the panel memory (i.e. differs from the system configuration), then the screen might show: DEVICE TEST 1001 CON=ION LP=HEAT VALUE=N C THIS IS THE TYPE WHICH IS CONFIGURED IN THE MEMORY SET=X C THIS IS THE TYPE WHICH HAS BEEN FOUND ON THE LOOP AT THAT ADDRESS! The value data shown is always that of the device type actually found on the loop (if different from the configured type) The display will show (on the second line) slightly different data for each type of device as follows: OPTICAL DETECTORS VALUE=0.01%/M SET=3.00%/M THIS IS THE ALARM VALUE: IT IS MULTIPLIED BY 10 IN BACKFIRE TO ALLOW EASIER SCALING (I.E. A VALUE OF 35 IN BACKFIRE WILL SHOW AS A VALUE OF 3.5 IN THIS TEST) HEAT DETECTORS VALUE=X C THIS ACTUALLY REPRESENTS THE TEMPERATURE IN C SET=Y C IONISATION DETECTORS VALUE=0.X SET=0.35

24 SECTION 1 DUAL ZONE MONITOR ZN1=NORM ZN2=NORM THIS CAN SAY NORM(AL) FLT FIRE AS REQUIRED If there is a failure of the PSU it will say: PSU FAIL MANUAL CALLPOINT This can have the following states: STATE=NORM STATE=FIRE or. FAULTY MINI ZONE MONITOR STATE=NORM THIS CAN SAY OPEN (CCT), SHORT (CCT), FIRE AS REQUIRED ADDRESSABLE BASE STATE=NORM THIS CAN SAY FAULTY (=ZONE O/C OR HEAD MISSING) SHORT (ZONE IS SHORT CCT) FIRE AS REQUIRED MASTER ADDRESSABLE BASE STATE=NORM THIS CAN SAY MISSING (NO HEAD FITTED) FIRE AS REQUIRED

SECTION 1 25 DUAL RELAY CONTROLLER INPUT=OFF THIS CAN SAY ON OPEN (CCT) SHORT (CCT) AS REQUIRED DUAL SOUNDER CONTROLLER INPUT=OFF O/P1=OPEN O/P2=OPEN THIS CAN SAY ON OPEN (CCT) SHORT (CCT) IF THIS AREA IS BLANK, THEN O/P1 AND O/P 2 ARE NORMAL OPEN=OPEN CCT SHORT=SHORT CCT or PSU FAIL DUAL SWITCH MONITOR I/P1=OFF IP2=OFF or FAULTY Output Bit Control There is no facility for Output bit manual control with the Hochiki ESP detector range.

26 SECTION 1 Nittan Device Types No Usage Abbreviation 0 Manual Callpoint MAN CP 1 Ionisation Smoke ION 2 Fixed Heat FIXED 3 Optical Smoke PHOTOELEC 4 Output Module OCM 5 Monitor/Control MCM 6 Sounder Module SCM 7 Addressable Base 3RB 8 Monitor Module NAM 9 Rate of Rise Heat ROR HEAT AS Device Details NITTAN AS Devices: Communication Code Summary Mode Command Ionisation Optical Heat Call point COLLECT DATA COMMANDS 1 01 Collect Analogue Data Address - able Base Monitor -ing Module Analogue Data G1 G2 G3 G1 Sensitivity High Norm Low High Norm Low 58C 66C 74C 82C Fire 20 26 31 18 22 26 42 48 53 58 28 28 28 30 Pre Alarm 17 22 25 15 19 21 - - - - - - - Normal 2-16 2-21 2-24 2-14 2-17 2-20 1-43 1-47 1-52 1-57 2-27 2-27 2-27 2-29 Fault 1 1 1 1 1 1 0 0 0 0 1 1 1 1 DI Meaning Always 0 Always 0 0=Low Always 0 0=No PSU Flt 1=High 1=PSU Flt Type Data 01 11 10 00 00 00 00 CONTROL COMMANDS 0 1110 LED on LED on LED on - - - - + Fire Test on + Fire Test on + Fire Test on Sounder Control Module 0 1101 Fire Test on Fire Test on Fire Test on Fire Test on Sounders Pulsing 0 1011 LED on LED on LED on - - Relay On Sounders Conts 0 1000 Reset Reset Reset Reset Reset Reset Reset

SECTION 1 27

28 SECTION 1 REPEATER POWER REPEATER DATA SOUNDER 5 SOUNDER 4 SOUNDER 3 CABLE TEST SHEET ENGINEER PROJECT NAME DATE SOUNDER 2 SOUNDER 1 LOOP 8 LOOP 7 LOOP 6 LOOP 5 LOOP 4 LOOP 3 LOOP 2 LOOP 1 TARGET PANEL SERIAL NO DESCRIPTION CORE-TO-CORE CORE 1 TO SCREEN CORE 2 TO SCREEN 500Mohm MIN 500Mohm MIN 500Mohm MIN 2 ohm MAX 2 ohm MAX 0.1µF MAX 500Mohm MIN 500Mohm MIN 500Mohm MIN LOOP OUT+VE TO LOOP BACK +VE LOOP OUT VE TO LOOP BACK -VE CAPACITANCE CORE-TO-CORE SCREEN TO EARTH CORE 1 TO EARTH CORE 2 TO EARTH Cable Test Sheet (Sample)