integrated building management systems - iti …intra.itiltd-india.com/bgp/tenders/tech...

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Date : 09/05/2017 Version : 00

TECHNICAL BID FOR

INTEGRATED BUILDING MANAGEMENT SYSTEMS FOR

PROPOSED

ITI DATA CENTRE AT: ITI, BENGALURU.

CLIENT

INDIAN TELEPHONE INDUSTRY (ITI) AT: BENAGALURU.

DATE CENTRE CONSULTANT

TRIMAX IT INFRASTRUCTURE & SERVICES LTD

AT: MUMBAI

VENDOR’S SING @ STAMP

ITI DATA CENTER @ BANAGLORE

Vendor’s Sign & Stamp

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TABLE OF CONTENTS

ADDRESSABLE FIRE DETECTION & ALARM SYSTEM

PUBLIC ADDRESS SYSTEM

BUILDING MANAGEMENT SYSTEM

DIGITAL RODENT REPELLANT SYSTEM

NOVEC1230 BASED FIRE SUPPRESSION SYSTEM

HIGH SENSITIVITY SMOKE DETECTION SYSTEM

ACCESS CONTROL SYTEM

CCTV SYSTEM

WATER LEAK DETECTION SYSTEM

ADDRESSABLE LEDBASE EMERGENCY LIGHTING SYSTEM



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ELIGIBILITY CRITERIA - ELV / IBMS / GAS SUPPRESSION SYSTEM Sr No

Criteria List Documents required Compliance by vendor

1 The Bidder (prime) should be a Company registered under the Companies Act, 1956 since last 5 years ending 31st March 2017

Certificate of incorporation and Self Certification of being in the business for the last 5 years should be attached.

2 Company should have AN ISO 9001 : 2008 CERTIFIED COMPANY

Certification to be submitted

3 Bidder should have Service support office at Bangalore from Last three year

Proof of document submitted.

4 No joint venture (JV) is allowed for this project

Proof to be submitted with Self declaration.

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The bidder should have successfully completed as a contractor at least Two Data Centre project of value not less than Rs. 200 lacs each, PO should be with complete IBMS ( Fire , Securty , BMS & Gas suppression System).

PO Copies / Completion Certification to be attached with self attestation

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The bidder should have successfully completed commulative Total IBMS of complete Project Value ending 31st March 2017 not less than Rs. 800 Lacs

Details List of projects to be attached with Self Attestation with IBMS offering.

7 The bidder should have successfully completed at least THREE Tier-3 Data center till ending 31st March 2017 .

Details List of Data Centre projects to be attached with Self Attestation , if required PO can be asked .

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The bidder should have successfully completed Total Single Max Size of Data center executed at one location , Rack Qty to be mentioned by Bidder.

Details List of Data Centre projects to be attached with Self Attestation

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The bidder should have an average annual turnover of at least Rs. 1000 lacs in the last 3 consecutive financial years. The attested copies of original Audited Profit & Loss account and original Balance Sheet statement for the last three consecutive financial years should be certified by chartered Accountant:

CA Certificates to be attached .

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The bidder should have a solvency of not less than Rs.100 lacs from a Nationalized/ Scheduled bank valid on date of opening, as specified in the certificate failing which it shall be reckoned as valid for a period of one year from the date of issue of Solvency Certificate.

11 The bidder should have 50 No's or more no's of Gas cylinders in a single project

PO document to be submitted with Site execution details.

12 Proposed Gas suppression refilling station should have mandatory in india, preferably southern part of India

Proof of document to be submitted.

all points compliance are necessary, also if required other documents can be asked for proof. NOTE:

1. Each and every page of this RFP should be stamped & signed by the bidder as a token of acceptance of this RFP conditions. Deviation if any, shall be clearly mentioned in a separate sheet of paper. However, accepting the bid with deviation is the sole discretion of Tenderer.

2. Any enquiry in this Bid should reach the Tenderer on or before ________________________. Thereafter No query will be entertained.



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TENDER SPECIFICATION FOR FIRE DETECTION AND ALARM SYSTEM

1) DESCRIPTION IN GENERAL The Fire Alarm System supplier shall furnish and install a fully integrated Fire Detection& alarm system for the area. Wherein all the sensors, modules, devices are too installed in all areas and voids to cover the entire premises. This section of the specification includes the furnishing, installation, and connection of a microprocessor controlled, analog addressable, intelligent fire alarm equipment required to form a complete coordinated system ready for operation. It shall include, but not be limited to, alarm initiating devices, alarm notification appliances, control panels, auxiliary control devices, annunciators, power supplies, and wiring as shown on the drawings and specified herein. The Panel shall be interface with a Public Address System to relay evacuation messages in case of a fire emergency. Each designated zone shall transmit separate and different alarm, supervisory and trouble signals to the Central Monitoring Stations and designated personnel in other buildings at the site via a multiplex communication network. The system shall also support independent gas release circuits for activation of Fire Suppression system. The system shall include hardware, modules to facilitate cross zoning of specific sensors, abort release functions, time delay and inputs for pressure switch and 24V output for solenoid operation. The panel shall be capable to further extend fire and fault output to the BMS for critical alarm monitoring, and it shall be possible to connect an interface card for open Protocol based (Commonly BACnet, Modbus or eqv.) output to enable a software level integration with the BMS System. The system and its components shall be Underwriters Laboratories, Inc. listed under the appropriate UL testing standard as listed herein for fire alarm applications and the installation shall be in compliance with the UL listing. PART 1 – GENERAL Scope: The control panel, to be intelligent device addressable, analog detecting, low voltage and modular, with digital communication techniques, in full compliance with all applicable codes and standards. The features and capacities described in this specification are required as a minimum for this project and shall be furnished by the successful contractor. The system shall be in full compliance with National and Local Codes. The system shall include all required hardware, interconnecting wiring and software to accomplish the requirements of this specification and the contract drawings, whether or not specifically itemized herein. All equipment furnished shall be new and the latest state of the art products of a single manufacturer, engaged in the manufacturing and sale of intelligent fire detection devices for over ten years.



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The system as specified shall be supplied, installed, tested and approved by the local Authority Having Jurisdiction, and turned over to the owner in an operational condition. Standards & Codes: The publications listed below form a part of this publication to the extent referenced. The publications are referenced in the text by the basic designation only. The latest version of each listed publication shall be used as a guide unless the authority having jurisdiction has adopted an earlier version. Factory Mutual (FM) FM AG Approval Guide. Underwriters' Laboratories, Inc. (UL) Appropriate “UL” equipment standards. “UL” 864 Control Panels. “UL” 268 Smoke Detectors. “UL” 268A Smoke Detectors (HVAC). “UL”1076 Security. “UL” 1971, Standard for Visual Signaling Appliances. Building Codes BOCA National Building Code and the BOCA Fire Code. Standard Building Code and the Standard Fire Code. Uniform Building Code and the Uniform Fire Code. International Building Code and the International Fire Code. State and Local Building Codes as adopted and/or amended by The Authority Having Jurisdiction. ADA, and/or State and local equivalency standards as adopted by The Authority Having Jurisdiction. Qualifications of Installers: Before commencing work, submit data showing that the manufacturer / contractor / vendor has successfully installed fire alarm systems of the same scope, type and design as specified. Manufacturer's Representative: Provide the services of a factory trained and certified representative or technician, experienced in the installation and operation, maintenance and service of the type of system provided. The technician shall supervise installation, software documentation, adjustment, preliminary testing, final testing and certification of the system. The technician shall provide the required instruction to the owner's personnel in the system operation, maintenance and programming. Submittal: The contractor shall include the following information in the equipment submittal: Power calculations. Battery capacity calculations. NAC circuit design shall incorporate a 15% spare capacity for future expansion. Complete manufacturers catalog data including supervisory power usage, alarm power usage, physical dimensions, and finish and mounting requirements. Incomplete submittals shall be returned without review, unless with prior approval of the Engineer. System Requirements:



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The system shall be a complete, electrically supervised fire detection and notification system, microprocessor based operating system having the following; capabilities, features and capacities: Communication between network nodes, each supporting an interactive, self-standing, intelligent local control panel, with system wide displays. Any network node shall be capable of supporting a local system in excess of 4000 input/output points. The local system shall provide status indicators and control switches for all of the following functions: Audible and visual notification alarm circuit zone control. Status indicators for sprinkling system water-flow and valve supervisory devices. Any additional status or control functions as indicated on the drawings, including but not limited to; emergency generator functions, fire pump functions, door unlocking and security with bypass capabilities. Each intelligent addressable device or conventional zone on the system shall be displayed at the Central Alarm Receiving Terminal and the local fire alarm control panel by a unique alphanumeric label identifying its location. System Operation: Activation of any system fire, security, supervisory, trouble, or status initiating device shall cause the following actions and indication to display in the panel. Fire Alarm Condition: Sound an audible alarm and display a custom screen/message defining the building in alarm and the specific alarm point initiating the alarm in a graphic display. The display shall provide standard NFPA graphical symbols indicating hazardous materials and personnel situations critical to situation management. Hazmat ICONs must conform to NFPA standard 170 format. The system shall supply a simple building floor plan and icons representing alarm devices in off normal or alarm condition. Log to the system history archives all activity pertaining to the alarm condition. Print to system printer (where required) alarm condition information. Sound the ANSI 117-1 signal with synchronized audibles and synchronized strobes throughout the facility. Audible signals shall be silenced from the fire alarm control panel by an alarm silence switch. Visual signals shall be programmable to flash until system reset or alarm silencing, as required. A signal dedicated to sprinkler system water flow alarm shall not be silenced while the sprinkler system is flowing at a rate of flow equal to a single head. Where indicated on drawings heat detectors in elevator shaft and machine rooms shall activated an elevator power shunt trip breaker. The heat detectors shall be rated at a temperature below the ratings of the sprinkler heads in respective locations to insure that the power shall be shut off before activation of sprinkler system. HVAC shut down shall, be accomplished by system operated duct detectors as per local requirements. Door closure devices shall operate by floor or by local requirements. Supervisory Condition: Display the origin of the supervisory condition report at the local fire alarm control panel graphic LCD display.



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Activate supervisory audible and dedicated visual signal. Audible signals shall be silenced from the control panel by the supervisory acknowledge switch. Record within system history the initiating device and time of occurrence of the event. Print to the system printer (where required) the supervisory condition. Trouble Condition: Display at the local fire alarm control panel graphic LCD display, the origin of the trouble condition report. Activate trouble audible and visual signals at the control panel and as indicated on the drawings. Audible signals shall be silenced from the fire alarm control panel by a trouble acknowledge switch. Trouble reports for primary system power failure to the master control shall be optionally delayed for a period of time not greater than 200 seconds. Trouble conditions that have been restored to normal shall be automatically removed from the trouble display queue and nor require operator intervention. This feature shall be software selectable and shall not preclude the logging of trouble events to the historical file. Record within system history, the occurrence of the event, the time of occurrence and the device initiating the event. Print to the system printer (where required) the trouble condition. Security Condition: Display at the local fire alarm control panel graphic LCD display, the origin of the security condition report. A dedicated security LED shall flash until the alarm has been acknowledged, then revert to a steady "ON" state. The control system shall be capable of bypassing the alarms from an individual security system installed within selected areas. The pass code allowing this function shall be assignable to individual security personnel and each bypass action shall be logged to system history. Intrusion alarms occurring during a bypass period shall be logged to history and displayed but no audible alarm shall occur at the control panel. Print to the system printer (where required) the security condition. The Local Fire Control Panel shall be “UL” 1076 listed for security purposes. PART 2 – PRODUCT Control Panel: The fire alarm control panel shall be microprocessor based using the multiple microprocessors throughout the system providing rapid processing of smoke detector and other initiation device information to control system output functions. There shall be a watchdog circuit, which shall verify the system processors and the software program. Problems with either the processors or the system program shall activate a trouble signal, and reset the panel. The system modules shall communicate with an RS 485 network communications protocol. All module wiring shall be to terminal blocks, which will plug into the system card cage. The blocks shall be color coded to prevent accidental crossing of wiring. The basic system shall have capabilities for 252 intelligent initiation devices and can be expanded up to 2500 intelligent initiation devices. The system shall employ a flexible number of detection input loops to reach



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maximum system capacity. Systems which, have a fixed number of device addresses per node based on a fixed number of device circuits (loops) shall provide 20% of loop maximum spare capacity on all loops to meet this requirement. The Device Loop Card shall be capable of minimum 252 intelligent devices distributed between two SLC circuits. Any trouble on one circuit shall not affect the other circuit. This module controls the signaling from the initiation devices reporting alarms and troubles to the control panel. This module shall also provide the signaling to the field devices for controlling the output of specific initiation devices. The circuit shall be capable of being connected with polarity insensitive intelligent initiation devices. The circuits shall have the ability to be wired, Style 4, Style 6. Any of all of the 252 devices on the loop card shall be capable of activating up to two devices (relay base, audible base or remote lamps). These accessories shall not take away from the 252 addresses available per loop. Systems which, require unique addresses for SLC circuit accessories (remote relays, relay bases, audible bases and remote lamps) shall provide 50% spare capacity for each loop to provide for system expansion. The on board microprocessor provides the loop card with the ability to function even if the main microprocessor fails. LED’s on the board shall provide annunciation for the following; Power, Card Failure, Network Failure, Ground. Fault, Alarm, Trouble, Short Zone 1, Short Zone 2, Style 6 Open Zone 1, Style 6 Open Zone 2. This card shall plug into the system card cage. The Signal Line Circuits shall be tested for opens, shorts, ground faults, device status and multiple device response (2 devices at same address) and communications with all addressable devices installed before connection to the control panel. Systems without this capability shall have a test panel installed for initial testing to eliminate any possible damage short term or long term to the control panel. After initial testing replace the test panel and proceed with complete testing. The Person Machine Interface (Display) or the Remote Person Machine Interface (Repeater) shall provide the system information on six inch ¼ VGA monochrome LCD, with Touch Screen and LED display. The DISPLAY shall provide floor plans with alarm type and “you are here” indication. The DISPLAY shall be navigable by device/module custom message in the system architecture with no need for device address knowledge. The DISPLAY shall provide a physical as well as a system geographic view. Graphic user interface shall be menu driven with 4 tabs showing the level and the total events for each tab. The tabs shall be; Alarm, Supervisory, Trouble and Security. Each level shall show 5 events simultaneously. The LED displays shall indicate Power, Audibles On or Silenced, and Partial system disabled. Systems not having the above LED’s shall provide separate LED’s within the control panel enclosure with appropriate labels. Selection buttons shall be backlit to aid the operator in the selection process. There shall be controls for scrolling throughout the event list. A button shall provide zoom in zoom out for the amount of information desired for a specific entry. The DISPLAY shall be capable of monitoring the power supply loading and show available capacity for future expansion planning. The DISPLAY LCD shall provide standard NFPA symbols showing Fire Service Equipment, Hazards, compliant with NFPA 170 and People in the area of alarm. Systems without this type of display shall supply a “UL” listed Graphics package with their system. The LCD shall have a keyboard screen to allow the technician ability to enter test and numbers for passwords or text changes. The Zone Indicating Card shall contain 4 NAC circuits rated at 4 amps each with power-limited outputs. All zone inputs for the card shall be isolated and independently supervised. There shall be at least 3 unique codes/signals for each circuit based on system logic. These signals shall be Temporal Code 3 (Evacuation), Steady (Such as “Recall”), and Alert (such as “Tornado Alert”). The card shall be listed for notification appliances, horns, bells, strobes, and speakers. The card shall also be listed for NFPA 13 Pre-Action Release, Halon 1301 NFPA 12A, NOVEC1230 NFPA 2001, Lease Line, and Municipal Tie. The card shall have the ability to wire the circuits Style Y or Style Z with outputs synchronized. The card shall have the following LED’s to provide trouble shooting and annunciation; Reset, Power, Card Failure, Network Failure, Ground. Fault, Zone Activation or Trouble. This card shall plug into the system card cage. The Network Interface Card shall provide communication between enclosures. The network card supervises the network to insure proper operation. Any faults that are detected shall be reported to the DISPLAY for annunciation. The network card shall isolate short circuits to each individual segment of the network. If a short occurs only the segment between the network card will be affected. The card shall have the ability to



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provide Style 4 or 7 network wiring configurations. The card shall have as the minimum the following diagnostic LED; Reset, Power, Card Fail, CAN Fail, HNET Fail, ZNET Fail, GND Fault, Loop A Fail, Loop B fail, Networks - Style 7, Style 4, Gnd Fault Enabled, GND Fault Disabled. The Controllable Relay Card shall provide 6 programmable relays. Each relay shall have SPDT contacts rated at 4 amps at 30VDC/120VAC resistive and 3.5 amps, 120VAC inductive. The card shall have as a minimum the following diagnostic LED’s; Reset, Power, Card Fail, 24V Fail, Relay 1, Relay2, Relay3, Relay 4, Relay5, Relay6. Where required to monitor a large amount of relays, such as monitoring subsystems or normally open contact devices, provide a Supervised Input Module, which will monitor up to 16 inputs. Each input shall be individually programmed for supervised or non-supervised circuits. This module shall be connected to a system network. The module shall contain 2 programmable form “C” relays for control of the monitored subsystem. Where required for control of relays or LED’s the Output control Module shall provide 16 open collector outputs to operate LED’s, incandescent lamps or relays as needed. The module shall contain a local audible output, Lamp Test and local audible silence. All circuits shall be power limited. The system card cage shall provide the mounting of all system cards, field wiring, and panel’s inter-card wiring. The terminal strips for the cards shall be color-coded to eliminate the possibility of making the wrong connection. The terminal blocks maybe disconnected and reconnected while the system is powered up without causing any difficulties. All power limited field wiring shall connect to the top of the card cage. All non-power limited internal wiring shall be connected to the bottom of the card cage. The card cage shall hold the systems cards and have capability of connecting multiple card cages to meet system demands. System response time from alarm to output shall not exceed four (4) seconds. To expedite system troubleshooting, the system cards shall have ground fault detection, and diagnostic LED’s by card. All system cards and modules shall have Flash memory for downloading the latest module firmware. Power Supply: The system Power Supply/Charger shall be a 12-amp supply with battery charger. The power supply shall be filtered and regulated. The power supply shall have a minimum of 1 power limited output rated at 4 amps, and a minimum of 1 output rated at 12 amps. The system power supply can be expanded up to 48 amps. The auxiliary power supply module shall share common batteries with the primary power supply. The system power supply shall have 4 relays, one for common alarm, one for common trouble and two programmable relays. The power supply shall be rated for 120/240 VAC 50/60 Hz. The battery charger shall be able to charge the system Lead Acid batteries up to 100 AH batteries. Battery charging shall be microprocessor controlled and programmed with a special software package to select charging rates and battery sizes. An optional Thermistor for monitoring battery temperature to control charging rate shall be available. The power supply shall have a plug for an AC adapter cable, which allows a technician to plug in a laptop computer for up or down loading program information or test equipment. System Enclosures: Provide the enclosure needed to hold all the cards and modules as specified with at least spare capacity for two cards. The enclosures shall be either black or red. The outer doors shall be capable of being a left hand open or a right hand open. The inner door shall have a left hand opening. System enclosure doors shall provide where required ventilation for the modules or cards in the enclosure.



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Intelligent Initiation Devices: All initiation devices shall be insensitive to initiating loop polarity. Specifically, the devices shall be insensitive to plus/minus voltage connections on either Style 4 or Style 6 circuits. The smoke detector shall be an intelligent digital photoelectric detector with a programmable heat detector. Detectors shall be listed for use as open area protective coverage, in duct installation and duct sampling assembly installation and shall be insensitive to air velocity changes. The detector communications shall allow the detector to provide alarm input to the system and alarm output from the system within four (4) seconds. Detectors shall be programmable as application specific, selected in software for a minimum of eleven environmental fire profiles unique to the installed location. These fire profiles shall eliminate the possibility of false indications caused by dust, moisture, RFI/EMI, chemical fumes and air movement while factoring in conditions of ambient temperature rise, obscuration rate changes and hot/cold smoke phenomenon into the alarm decision to give the earliest possible real alarm condition report. The intelligent smoke detector shall be capable of providing three distinct outputs from the control panel. The system controlled output functions shall be from an individual or unique input of smoke obscuration, a thermal condition or a combination of obscuration and thermal conditions. The detector shall be designed to eliminate calibration errors associated with field cleaning of the chamber. The detector shall support the use of a relay and LED remote indicator at the same time. Low profile, white case shall not exceed 2.5 inches of extension below the finish ceiling. Detector wiring shall not require any special shielded cable. Thermal Detectors shall be rated at 135 degrees fixed temperature and 15 degrees per minute rate of rise. Detectors shall be constructed to compensate for the thermal lag inherent in conventional type detectors due to the thermal mass, and alarm at the set point of 135 degrees Fahrenheit. The choice of alarm reporting as a fixed temperature detector or a combination of fixed and rate of rise shall be made in system software and be changeable at any time without the necessity of hardware replacement. The detectors furnished shall have a listed spacing for coverage up to 2,500 square feet and shall be installed according to the requirements of NFPA 72 for open area coverage. The smoke detector shall be an intelligent digital photoelectric detector with a programmable heat detector. Detectors shall be listed for use as open area protective coverage, in duct installation and sampling assembly installation and shall be insensitive to air velocity changes. The detector communications shall allow the detector to provide alarm input to the system and alarm output from the system within four (4) seconds. The detector shall be mounted in a duct detector housing listed for that purpose. The duct detector shall support the use of a remote test switch, relay or LED remote indicator. The duct detector shall be supplied with the appropriate sampling tubes to fit the installation. Where duct detectors are exposed to the weather provide a weatherproof enclosure. Detector bases shall be low profile twist lock type with screw clamp terminals and self-wiping contacts. Bases shall be installed on an industry standard, 4" square or octagonal electrical outlet box. Where selective localized control of electrical devices is required for system operation, furnish and install detector base with software programmed addressable relay integral to the base. The relay shall switch electrical loads within relay ratings, as indicated on the drawings. Operation of the addressable control circuit shall be independent of the number of detectors and relays on the circuit or the number in an alarm state. Relay bases shall be rated for resistive or inductive load (120VAC or 30VDC) 3 amps. Where indicated on the drawings, furnish detector base with integral approved audible evacuation alarm signal having an output of 85db. The audible signal shall be individually addressable and software programmed for operation. Provide single action addressable manual stations where shown on the drawings, to be flush or surface mounted as required. Manual stations shall contain the intelligence for reporting address, identity, alarm and trouble to the fire alarm control panel. The manual station communications shall allow the station to provide



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alarm input to the system and alarm output from the system within less than four (4) seconds. The manual station shall be equipped with terminal strip and pressure style screw terminals for the connection of field wiring. Surface mounted stations where indicated on the drawings shall be mounted using a manufacturer's prescribed matching red enamel outlet box. Addressable Interface Devices shall be provided to monitor contacts for such items as water-flow, tamper, and PIV switches connected to the fire alarm system. These interface devices shall be able to monitor a single or dual contacts. An address will be provided for each device and all physical devices shall require only one address on a signaling line circuit regardless of the number of circuits on an individual module. Where remote supervised relay is required the interface shall be equipped with a SPDT relay rated for 4 amps resistive and 3.5 amps inductive. Notification Appliances: The Horn or horn/strobe appliance as indicated on the drawings shall be a synchronized temporal horn with a synchronized strobe light with multiple candela taps to meet the intended application. The appliance shall be red or white as indicated on the drawings. The strobe light taps shall be adjustable for 15/75, 30/75, 75, and 110 candela. The appliance shall be red for wall mounted and white for ceiling mounted. Ceiling mounted appliances shall be rated for that application. The electronic chime or chime/strobe as indicated on the drawings shall be a speaker with a tone card and have and adjustable range of 700 to 1300 Hz. The chime or chime/strobe shall be adjustable for either single stroke or continuous operation. The chime/strobe shall be available with adjustable strobe intensities of 15, 30, 75, and 110 candela. The appliance shall be red for wall mounted and white for ceiling mounted. Ceiling mounted appliances shall be rated for that application. The strobe only appliance as indicated on the drawings shall be a synchronized strobe light with multiple candela taps to meet the intended application. The strobe light taps shall be adjustable for 15, 30, 75, and 110 candela. The appliance shall be red for wall mounting and white for ceiling mounted. Ceiling mounted appliances shall be rated for that application. Where required provide a 10” bell where indicated on drawings to be connected to a non-silenceable circuit for activation of the sprinkler system. An alarm extender panel shall be provided where needed. The power supply shall be a minimum of 6 amps. The power supply shall contain four supervised notification circuits maximum of 3 amps each circuit. The power supply shall contain built-in synchronizing modules for strobes and audibles. There shall be a 3 amp filtered auxiliary power limited output. There shall be a minimum of 8 options as to the operations of the inputs and outputs. PART 3 – EXECUTION Installation: Perform work in accordance with the requirements of NFPA 70 and NFPA 72. Fasten equipment to structural members of building or metal supports attached to structure, or to concrete surfaces. Limited energy cable installation is allowed under Div. 16, all cable runs shall be run at right angles to building walls, supported from structure at intervals not exceeding 3 feet and where installed in environmental air



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plenums, be rated for such use and tied/supported by components listed for environmental air plenums installation. Boxes, Enclosures And Wiring Devices: Boxes shall be installed plumb and firmly in position. Extension rings with blank covers shall be installed on junction boxes where required. Junction boxes served by concealed conduit shall be flush mounted. Upon initial installation, all wiring outlets, junction, pull and outlet boxes shall have dust covers installed. Dust covers shall not be removed until wiring installation when permanent dust covers or devices are installed. "Fire Alarm System" decal or silk-screened label shall be applied to all junction box covers. Conductors: Each conductor shall be identified as shown on the drawings at each with wire markers at terminal points. Attach permanent wire markers within 2 inches of the wire termination. Marker legends shall be visible. All wiring shall be supplied and installed in compliance with the requirements of the National Electric Code, NFPA 70, Article 760, and that of the manufacturer. Wiring for strobe and audible circuits shall be a minimum 14 AWG, signal line circuits shall be minimum 18 AWG. All splices shall be made using solderless connectors. All connectors shall be installed in conformance with the manufacturer recommendations. Crimp-on type spade lugs shall be used for terminations of stranded conductors to binder screw or stud type terminals. Spade lugs shall have upset legs and insulation sleeves sized for the conductors. Permanently label or mark each conductor at both ends with permanent alphanumeric wire markers. A consistent color code for fire alarm system conductors throughout the installation. The installation contractor shall submit for approval prior to installation of wire, a proposed color code for system conductors to allow rapid identification of circuit types. Wiring within sub panels shall be arranged and routed to allow accessibility to equipment for adjustment and maintenance. Devices: Relays and other devices to be mounted in auxiliary panels are to be securely fastened to avoid false indications and failures due to shock or vibration. Wiring within sub-panels shall be arranged and routed to allow accessibility to equipment for adjustment and maintenance. All devices and appliances shall be mounted to or in an approved electrical box. Certificate of Compliance: Complete and submit to the Project Engineer in accordance with NFPA 72, 1999 edition section 1-6.2.



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FIELD QUALITY CONTROL: Testing, general All Alarm Initiating Devices shall be observed and logged for correct zone and sensitivity. These devices and their bases shall be tagged with adhesive tags located in an area not visible when installed, showing the initials of the installing technician and date. Wiring runs shall be tested for continuity, short circuits and grounds before system is energized. Resistance, current and voltage readings shall be made as work progresses. A systematic record shall be maintained of all readings using schedules or charts of tests and measurements. Areas shall be provided on the logging form for readings, dates and witnesses. The acceptance inspector shall be notified before the start of the required tests. All items found at variance with the drawings or this specification during testing or inspection by the acceptance inspector shall be corrected. Test reports shall be delivered to the acceptance inspector as completed. The installing contractor shall make instruments, tools and labor required to conduct the system tests available. The following equipment shall be a minimum for conducting the tests: Ladders and scaffolds as required to access all installed equipment. Multimeter for reading voltage, current and resistance. Two way radios and flashlights. A manufacturer recommended device for measuring airflow through air duct smoke detector sampling assemblies. Decibel meter. In addition to the testing specified to be performed by the installing contractor, the installation shall be subject to test by the Engineer of Record and the AHJ. Acceptance Testing: A written acceptance test procedure (ATP) for testing the fire alarm system components and installation will be prepared by the engineer in accordance with NFPA 72 and this specification. The contractor shall be responsible for the performance of the ATP, demonstrating the function of the system and verifying the correct operation of all system components, circuits, and programming. A program matrix shall be prepared by the installing contractor referencing each alarm input to every output function affected as a result of an alarm condition on that input. The installing contractor prior to the ATP shall prepare a complete listing of all device labels for alphanumeric annunciator displays. The acceptance inspector shall use the system record drawings in combination with the documents during the testing procedure to verify operation as programmed. In conducting the ATP, the acceptance inspector shall request demonstration of any or all input and output functions. The items tested shall include but not be limited to the following: System wiring shall be tested to show the following results and the system subsequence operation: Open, Shorted or Grounded Circuits.



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Primary and Battery power disconnected. System notification circuits and appliances operate as programmed. Audibility and Visual levels meet required standards. System shall demonstrate the correct messages at the FACP and Remote Annunciator. System off site reporting shall be verified for alarm, supervisory and trouble. System shall be tested for stand-by battery back up as outline in this specification. Documentation: System documentation shall be supplied to the owner and shall include but not belimited to the following: System record drawings and wiring details including one set of reproducible drawings, and a CD ROM with copies of the record drawings in DXF format for use in a CAD drafting program. System Operating, Installation and Maintenance Manuals. System matrix showing input signals to output commands. Provide a Soft copy of the system program. Warranty and Services: The contractor shall warranty the entire system for electrical and mechanical failures for a period one year. The warranty shall begin with the completion of the acceptance testing or when beneficial use to the owner is determined. The fire alarm system subcontractor or manufacturer shall offer for the owner’s consideration at the time of system submittal a priced inspection, maintenance, testing and repair contract in full compliance with the requirements of NFPA 72. The contractor performing the contract services shall be qualified, factory trained and certified in the service and the maintenance of the system provided and listed to maintain ongoing certification of the completed system to the “UL” installed system listing. The installation contractor shall furnish training as follows: Training in the receipt, handling and acknowledgment of alarms. Training in the system operation including manual control of output functions from the system control panel. The total training requirement shall be a minimum of 2 hours, but shall be sufficient to cover all items specified. The contractor shall provide two such training sessions.



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General description The contractor shall supply, install, test, connect and commission a high quality fast-acting Public Address and Voice Alarm System. The Public Address and Voice Evacuation System shall comprise of Audio Matrix Units, High quality speakers, Audio rack all mounted on a 19” Rack and fully connected and integrated on the fire alarm loop. The system shall be used for Professional Sound Reproduction for all the areas where possible special events take place. To ensure whole site integration capability, the fire and voice alarm system will be awarded to a single specialist local supplier who will be responsible for the design, global operation, management and interfacing of the system. The contractor shall make sure that all power tapping of the speakers must be carried out as specified, even if the acoustic calculations indicates less power tapings. The contactor must endure minimum of 10dB above the ambient noise levels are achieved. The system shall be fully programmed to accommodate fire alarm and voice communication zones as indicated on the drawings and schematics Scope of Work The scope of work under this head shall include designing supplying and installing of Public Address System. The work under this system shall consist of furnishing all materials, equipment’s and appliances and labor necessary to install the said system, complete with Speakers, Amplifiers, Microphone, Zone Selection Panel for interfacing with other systems. The PA system is designed to serve the dual purpose of making general announcement and Voice Evacuation at the time of Fire alarm activation. System Design The PAVA system shall be connected on the same Fire Alarm loop. The system shall be de-centralized in nature, each distributed rack DAU (Distributed Amplifier Unit) shall have all the DSP (Digital Signal Processing), messages, amplifiers in such a way that can work in a stand-alone mode or Centralized mode. The Man Machine Interface (MMI) shall be connected back to the control room, to monitor and control the entire PAVA system. The DAU shall play background / Foreground music and in case of Fire Alarm / Paging announcement, the system shall go to full power as programmed to provide the enough SPL (Sound Pressure Level) levels to comply with BS5839 part8, with minimum of 10dB above the noise levels. The PAVA system shall be properly integrated with the fire alarm system. The integrated PAVA system shall cover all normally accessible areas including the car parks. In addition, a FIRE DRILL, BOMB ALERT, EARTHQUAKE ALERT and an ALL CLEAR message shall be incorporated into the operation. A fire alarm broadcast signal shall cancel any public-address operation and shall override it. When a fireman’s microphone is operated, this shall override any automatic voice alarm signal being transmitted to the zone selected. The PAVA Rack shall be in the Control/Security Room enabling the operator to select music from the CD player, FM tuner or the double cassette deck to transmit music to selected zones or all the zones in the building from the Keypad paging microphone. A public-address announcement shall override the music transmission to selected zones or all zones. The Speakers shall be distributed in the entire floor and shall be configured in different zones. The announcement can have made in zone wise or to all the speakers simultaneously in ALL

INTELLIGENTPUBLIC ADDRESS AND VOICE EVACUATION SYSTEM



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CALL mode. Fire Alarm shall be announced immediately on receipt of Fire signal from the panel to all zones or group of Zones. System shall have following functions: Voice Evacuation and Public Address system integration includes paging system and background music system. Monitoring of microphone, controller, amplifier, fireman microphone, and source modular, AC&DC power Supply, and Volume Control. Amplifiers All amplifiers shall be power amplifier with High quality speech and Music broadcast. The power amplifiers shall have adequate continuous (RMS) power output to meet the requirement of the configuration. The unit shall can deliver the rated output power with less than 0.1% harmonic distortion in the design bandwidth. The amplifier shall have a broad band frequency response of 60 Hz to 15 KHz. The output voltage and impedance shall meet with the system requirements. Amplifiers shall be protected against over loads and output shorts and a special thermal overload on the heat sink. The Amplifier shall be one channel or Two Channel and each channel have rated power 120/240or 480W. Amplifier shall have AC 110V or 230V power supply, having separate fuse for each channel. The Amplifier shall be connected through balanced audio input and shall work on 100V Speaker Line. Technical Specifications Rated Output Voltage(RMS) 120W/240W/480W/2x120W/2x240W/2x480W Frequency Response 60Hz to 15KHz S/N Ratio >70 dB Total Harmonic Distortion <0.1% @ 1kHz Power Efficiency >70% Power Consumption < 670W for 480W Amplifier Input 10k Ohm < 1V Output 10k Ohm 0.775V (0dB) Speakers Speakers shall be especially designed for broadcasting high quality, integrated emergency fire alarm signals and voice communications and approved by an appropriate authority for use in such situations. Speakers shall be ceiling, wall mounted or Horn Speaker as shown in the schedule of work and shall be completed with mounting brackets accessories etc. Speakers shall be in metal enclosures only. Speakers shall be interconnected in the zone configuration. 6W Ceiling/wall Mounted Speaker The ceiling mounted 6 W speakers shall be installed as depicted in the drawing. The speakers support EASE, CATT or ULYSSES models for acoustic studies. This mean the acoustic model can be designed to simulate the sound quality and distortion prior to installation. The Speaker should be in compliance BS/EN 60065, 2003 and EMC (BS EN 61000-6-Part 1/2/3/4). The Ceiling speaker shall work on 100V line so that it can reduce line losses over long distance and allow easy parallel connection of multiple loudspeakers. The Speaker shall have multiple tapping for different application according to room size and ambient noise environment. The Speaker shall have aluminum grille and metal baffle and shall have spring clip clamp for easy installation. Technical Specifications Rated power 6 W Tapings 100V line 6/3/1.5W Operation Voltage 100V or 70V Effective frequency range 110 ~ 15kHz SPL @ 1W/m >91 dB S.P.L., @Full power/ 1m, dB >97 dB Speaker Drive 6” Color White Ceiling Cut-out 170mm Dimensions 200 mm x 65 mm



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10W Ceiling/wall Mounted Speaker Rated power 10 W Effective frequency range 150 ~ 15kHz Sensitivity 98dB Power Handling 10W Line Input 100V Component 6.5” Material ABS Grille Power coated Iron mesh Color White Dimensions 200 mm x 105mm x 275mm 15W Horn Speaker The Horn speakers with 15W Output shall be installed as depicted in the drawing. The speakers support EASE, CATT or ULYSSES models for acoustic studies. This mean the acoustic model can be designed to simulate the sound quality and distortion prior to installation. The Speaker should be complying BS/EN 60065, 2003 and EMC (BS EN 61000-6-Part 1/2/3/4). The Horn speaker shall work on 100V line so that it can reduce line losses over long distance and allow easy parallel connection of multiple loudspeakers. The Speaker shall have multiple tapping for different application per room size and ambient noise environment. Technical Specifications Rated power 15 W Tapings 100V line 15W/7.5W Operation Voltage 100V or 70V Effective frequency range 250 ~ 8kHz SPL @ 1W/m >103 dB S.P.L., @Full power/ 1m, dB >113 dB Color White IP Rate IP 66 Dimensions 282 x 210 x 290mm Remote Paging Microphone The Remote Paging Microphone should be fully digital connected via CAT6 Cable with Controller. The Microphone should have capability to make announcement in 12 Zones and have all call facility. The Microphone shall have ability to control music and should be able to route the music in zones. The Microphone should have LED indication for the different Status, the unit shall have 12 Selection buttons with colored indicators. The Microphone have reset/channel, All call & Call buttons. The Unit shall have RJ45 ports for connection. The Microphone shall have following features: 12 Zone Control button and indicators LED for Zones indication Connect up to 5 Microphone. Compress function through microphone input to avoid distortion. Auxiliary input for supply background Music Auxiliary input -22dBV, 47K Communication up to 400 meter Voice Alarm Controller (VCA) The Controller shall be a 19” Rack Node, which shall operate on 230V mains, it can be installed next to the Fire Alarm Control Panel The System shall comprise of Master Control Modules, Amplifiers, Link Audio Processor, Power Supply and all the connectors, wires to complete a standalone PAVA Rack with in-built messages.



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The use of these units shall be primarily for broadcast fire messages and other optional auxiliary messages as well the back-ground music which is site and application specific, as well live evacuation messages and instructions from the operator or the fire brigade to direct the people to the safety points of the building. The all components installed for small and medium scale installations. It comprises the latest technology in Voice Evacuation, Voice messages can be customized. It shall be possible to define Siren Tone for each message and define the length of it without depending on the message recording. Controller shall have one audio input (0dB symmetric) Each controller unit can support up to 12 or 8 speaker circuits of up to 480W per circuit speaker. All communication must be digital between the entire system components, except the output to the 100V line of the speaker circuit and the 100V output of the amplifier units. When amplifier, manual switching over of amplifier is option available. Inbuilt fire evacuation messages, it can be customized based on project/client requirement. Individual digital control for each input and output level from the Microphone. Controller having individual volume controller for music, announcement and fire message All messages shall be of WAV files directly can be downloaded to the system through a PC. 0dB input / outputs Audio input impedance: 10K Ohms Input sensitivity: 0dB Audio output impedance: 50Ohms Output levels 0dB Max input/output level +14 dBv Pass-band 10 Hz to 22KHz Sampling 48 kHz 24bit Distortion 0.02% to 1 KHz Output noise<84 dBu Lin, <88 dBu A-weighted Output dynamic >98dBu Lin, >102dBu A-weighted 100V Inputs/Outputs Max power per Channel 500W, and 12 channel per VOICER-G2 Amplifier gain measurement 1 kHz, 18 kHz Line impedance measurement 100V 1kHz, 18kHz Ground fault measurement Digital AM/FM Tuner The digital AM/FM tabletop and rack mount design with aluminum alloy panel. It shall have clearly visible LDC display, microcomputer control and touch-button operation. FM/AM two band receive option, FM receiving frequency 76MHz – 108MHz, AM receiving frequency 520Hz – 1708 KHz. Radio frequency automatic search and memory function, memory up to 99 bands and a power off memory functions. Using vehicle dedicated digital radio module, integrated radio tuner module, with a small size good performance and strong anti – interference etc. Built in High fidelity wideband monitor Speaker, Sound full and clear, and a monitor with adjustable volume knob Technical Specifications: Power Supply 220V/50Hz Power Consumption 8W 1 Channel audio signal left and right channel output CD/DVD Player The CD/DVD player shall be capable playing MP3 audio tracks from USD or DVD or CD. Technical Specifications: D/A converter24 bit, 192 kHz



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Frequency response30-20000 Hz Signal to noise ratio > 90 Distortion and Noise (1kHz)> 65 dB Crosstalk (1kHz)> 70 dB Dynamic Range (1kHz)> 80 dB Sound System Dolby Digital Playback Media CD MP3-CD MP3-DVD WMA-CD CD-R/RW Audio CD Compression format MP3 Dolby Digital PCM WMA MP3 bit rates 32 - 320 kbps 19” Rack The equipment shall be housed in a standard rack of suitable height, with Plexiglas door or metal mesh and lock. Ventilation panels of 1U height shall be provided between each item of equipment. Details of the proposed equipment shall be forwarded to the Consultant with performance specifications, dimensions, construction and finish for approval. Rack should comply with ANSI/EIA RS-310-D; DIN41491; DIN41494; IEC297-2; and GB/T3047.2-92. The Rack should have DIN Rail Mounted Terminal Blocks for termination of Speaker Zone cables on the rear. All cables coming from Speaker zones, Call Stations, Power supply should enter from Bottom. Rack should be installed at location which has minimum 600mm space from front & back for accessing it easily. Rack should be installed in well ventilated room preferable Air conditioned. The unit should have Fans from top. The unit should have Lockable Glass door at front Dimensions Height as per the Quantity of PA Processor & Amplifiers Depth 600mm Deep Width 19” Speaker Cables All cables associated with PA System shall be of following specifications: The 2-core speaker cable will be connected to the speakers by screw terminals before which it shall be crimped using 1.5 sq. mm. bootlace lugs. Care must be taken for avoiding any single strand of wire shall not come out of Lug & screw terminals to avoid noise & leakage. Speaker cables used should be Multi-Conductor Stranded type Flexible Copper Conductor of cross section 1.5 Sq. mm / 2.5 Sq. mm insulated, PVCFRLS sheathed control Cable as per IS 694. These Cables shall be laid in G.I. Conduits concealed/surface. Call Station Cables Call station cables should be 4pair CAT6 STP (Shielded Twisted Pair) type, It should be crimped by RJ45 Shielded Male Connectors.



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Testing PAVA System

Sr. No. Description Visual Test Readings Documentation

1 All cables are tested for continuity, insulation, resistance etc.

√

2 System installation proper as per drawing √

3

Carry out visual checks on all speakers & Processors are free from any mechanical damage, cables, inter phase modules etc.to ensure they are properly installed.

√

4 Check for proper termination of bootlace lugs & feruling

√

5 Check Input A/C Supply Voltage √

6 Check location / spacing of loudspeakers as in drawing.

√ √

7 Check Distribution of Zones as per Drawing. √ √

8 Check full load speaker sound quality & measure Sound pressure level (SPL) in dB.

√ √

9 Check if local loudspeakers overrides by voice messages in case of emergency evacuation.

√ √

10 If power fails, whether Voice evacuation system is working on battery supply if yes for what time

√

11

Check if recorder messages are CLEAR, free from any noise distortion & easy to understand with Room acoustic speech transmission Index (RaSTI) value >0.5.

√ √

12 Processor LED’s and all keys are working properly

√

13 Check for Microphone locations & the sensitivity by paging

√ √

14 Play a soft music & check sound quality √



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BUILDING MANAGEMENT SYSTEM

1) GENERAL The Building Automation System (BAS) supplier shall furnish and install a fully integrated building automation system,wherein all the services to be monitored and integrated are distributed. The BMS incorporating direct digital control (DDC) for energy management, equipment monitoring and HVAC control, suitable for the building usage. The control strategies shall be developed to ensure that specified environmental conditions are maintained, whilst giving due regard to minimizing of energy consumption. The system design shall utilize the latest technology in “open” network architecture, either LONWORKS or BACNET with distributive intelligence and processing, and direct digital control. The BMS system offered should be from the latest offerings and should be freely programmable management and automation stations for the full spectrum of today’s building application services. 2) SCOPE General The BAS supplier shall provide new, latest technology, high speed, network able, interoperable, user friendly fully operational, Lon works/ BACnet protocol Building Management System In the building operates the following utilities & services to be integrated to achieve Monitoring, control, scheduling, operational control, maintenance, ease of operation, energy conservation, & remote interface. The integrated system network architecture shall offer the maximum operational systems redundancy. The System shall mainly comprise of Direct Digital Controllers, Middleware, Web Server LAN Routers, and relevant field level instrumentation. The BAS shall provide design the system with DDC Controls distributed at all floors to minimize Cabling and to achieve maximum operational system redundancy & high speed communication. The DDC`s offered shall be intelligent type with self storage of data & expanded memory. The BAS shall ensure that all critical / medium alarm generation points of any one service not to be linked to one DDC/PI. This shall avoid failure of entire data of particular services in case of failure of the corresponding DDC/PI. Integration of open standards Integrate via OPC Integrate third-party devices via OPC The system must be OPC Foundation tested and certified and must be able to integrate and process, but also to provide real-time data as OPC data points. The System processing must include Alarming, Trending, Scheduling, Reporting and allow cross communication with other integrated devices.



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The System must be support the OPC specification: OPC Data Access Energy efficiency and references to applicable standards. Energy efficiency class "A" as per EN 15232. Standard EN15232 serves as the basis for energy efficiency functions. The system supplier must prove that the functions are as described by the standard. This tender was established based on Class A criteria. Energy efficiency monitoring and evaluation. Management level Visualize the quality state in the plant graphics. A violation of energy efficiency limit values for measured values of primary plants (e.g. centralized air handling, energy generation) must also be displayed in the plant graphic directly on the application components or function. The parameters for monitoring, evaluating and forming the quality state can be set directly in the plant graphic based on read and write access rights. As an alternative: Make possible the simple navigation to an appropriate user program.

FUNCTION OF BUILDING AUTOMATION SYSTEM The various functions that this system shall perform are as follows:

The system shall ensure sequential and automatic start/stop of the various air-conditioning equipment based on time schedule and ambient temperature.

It shall maintain design inside conditions, within the specified limits, throughout the year.

It shall monitor the start/stop and faults of units.

It shall duty cycle to provide equal run time for all equipment and start the standby unit on a similar unit failure.

It shall provide automatic startup of standby equipment in case of failure of operating unit and indicate fault status of the biped unit. The Employer requires that all goods and materials to be used in the works are new, unused, of the most recent or current models and incorporate all recent improvements in design and materials. All the equipment and ancillary materials shall confirm in all respects to highest standard of engineering, design and workmanship. SCOPE The scope of this section comprises the supply, installation, testing and commissioning of BMS. BMS PCs including hardware and software conforming to these specifications and in accordance with the schedule of quantities. The BMS integration shall be done for the following items:



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HARDWARE The BMS PC shall comprise of windows based function units necessary for full data acquisition directly or through a gateway / router, storing, visualizing and communication with other providing high-level operator interface with the system. The BMS PC shall be provided with an operator interface with the facility for remote system Operation, control, and retrieval/storage of logged data, annunciation of alarms and reports. The BMS PC shall support consistent archiving of alarms, offline trend data, and data backup. The BMS Server will be well equipped with:

Minimum hardware requirement (Plants from +/- 2'000 up to +/- 20'000 data points)

A client / server system for large sites is required. The hardware and software environment must fulfill the the folowoing definition:

Type: Server 19” Rack Processor: 1x Xeon E5-2690 or 2x Xeon E5-2690 HDD: 4x Seagate Constellation 2 SAS 2000GB 7.2k Hot Plug SED Graphic Card: On-board video graphics or AMD Radeon 7750 1GB or Nvidia GeForce GT 610 1GB RAM: 32GB DDR3-1333 4x 8GB

Recommendet software environment

Windows Server 2008 R2, 64bit Edition MS SQL 2008 R2 Standard or MS SQL 2008 R2 Enterprise

Network requirements

Local Network 1000 Mbps up/down Latency <lt/>10ms

Additional: System must be to extent with a dedicated SQL server if a high data throughput is required.

.

K Third Party Integrations

1.1 Chiller System (assumed 25 points per chiller) 4

1.2 ACB , MCCB Breakers (20 Soft Points considered for each Unit ) 26

1.3 Variable Frequency Drives (assumed 5 points per VFD) 4

1.4 Diesel Generator (DG) System (assumed 25 points per DG) 5

1.5 Un-Interupted Power Supply (UPS) System (assumed 10 points per UPS) 18

1.6 Precision Air-Conditioning (PAC) System (assumed 20 points per PAC) 70

1.7 Transformer (10 Soft Points considered for each Unit ) 4

1.8 PDU Load manager for BLOCK 21-S ( 3 Soft Points considered for each Energy Meter ) on MODBUS RTU PROTOCOL.175

1.9 PDU Load manager for BLOCK 65-F ( 3 Soft Points considered for each Energy Meter ) on MODBUS RTU PROTOCOL.610

1.10 Fire Alarm System (assumed total number of detectors & modules) 1

1.12 Water Leak detection Panel Integretion 12



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SOFTWARE

GENERAL SPECIFICATIONS The system offered shall be completely modular in structure and freely expandable at any stage. Each level of the system shall operate independently of the next level up. The system shall fully be consistent with the latest industry standards, operating on Windows 2000 or Window NT on a network environment, allowing the user to make full use of the features provided with these operating systems. THE MANAGEMENT LEVEL The head-end of management shall be BMS PC stations and operation of the BMS PC shall include process visualization, data analysis. The system shall be open for vertical and horizontal integration. The management platform presents a single point of entry for users to operate, monitor and optimize building automation, fire safety and security systems or a combination thereof. It shall be flexible, full client-server architecture allowing scalability from small and medium to large and complex systems. The platform provides customizable- and market-specific distributions. It shall be installed on one single computer, with full server and client functionality. Furthermore, Installed, Web, and Windows App Clients can also be added on separate hardware. Additional system connections shall be made through systems installed with Front End Processors (FEP) configurations. Web interfaces provide the customer an increased flexibility for operation and future extensions, e.g. mobile applications for tablets and smart phones.

User shall be

Graphically monitor and control the system

Visualize and treat events

Directly navigate (with just one click) to the triggering element of an event

Quickly navigate to custom operator instructions and graphical display of event locations

Ensure that the facilities remain productive and easy to use

Achieve optimal energy and equipment performance

Store and retrieve alarm system activity data

Distribute monitoring and control capabilities across a network of BMS management platform

Provide Operating Procedure checklists to guide the operator under stress conditions and during the treatment of life safety events

Extend the system by adding additional disciplines

Access the system via web at any time and from anywhere

Send out automatic remote notifications (RENO) through e-mail

Deliver reliable, effective and targeted emergency messages at the push of a button

NETWORK The system configuration shall facilitate the current network to be expanded in future at locations designated by the user. Central management of user-specific information such as passwords and protected access to data and programs shall thus be made easily possible. The management system shall also support software updates and changes in the project data. PRINTING



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It shall be possible to connect printers directly to the BMS PC. REMOTE MANAGEMENT The BAS software shall support Remote Access management i.e. Remote management station shall be connected via

Modems

ISDN facilitées

Internet/Intranet

RAS

FTP etc.,

THE AUTOMATION LEVEL

The level at which, the actual processing takes place is based on the logic written on the DDC. The processes are carried out at the DDC controllers for autonomous control (all controls functions are independent of the network/other DDC’s). All DDC’s are with 32 bit technology & BTL Approved. DDC PROGRAMMING SOFTWARE The software shall be a graphically programming tool. It enables user to make the function diagrams, to parameter, commission all the automation stations and to change the parameters while the system is in operation. The programming tool shall be a windows based for convenience. PROCESS VISUALISATION SOFTWARE FEATURES Building automation and control system requirements Integration of open standards Integrate via OPC Integrate third-party devices via OPC The system shall be OPC Foundation tested and certified and shall be able to integrate and process, but also to provide real-time data as OPC data points. The System processing shall include Alarming, Trending, Scheduling, Reporting and allow cross communication with other integrated devices. The System shall be support the OPC specification: OPC Data Access Energy efficiency and references to applicable standards. Energy efficiency class "A" as per EN 15232. Standard EN15232 serves as the basis for energy efficiency functions. The system supplier shall prove that the functions are as described by the standard. This tender was established based on Class A criteria. Energy efficiency monitoring and evaluation. Management level Visualize the quality state in the plant graphics. A violation of energy efficiency limit values for measured values of primary plants (e.g. centralized air handling, energy generation) shall also be displayed in the plant graphic directly on the application components or function. The parameters for monitoring, evaluating and forming the quality state can be set



26

directly in the plant graphic based on read and write access rights. As an alternative: Make possible the simple navigation to an appropriate user program. Management level Management level requirements General All information comes together at the management level. The management level is the graphical, interactive interface for the operator to the automation station and the integrated plants and plant parts. The operator can display, query, process, save, or print any plant information via the peripheral units at the management level. System operation shall be simple, i.e. dialog-driven. The plants are displayed in synoptic images and the values and states are presented and displayed dynamically. Special programs are used for higher control, optimization functions, maintenance and energy management. Operating system for building automation and control system All data servers, operator workspaces etc. for the building automation and control system shall be compatible with the current, common 64-bit Windows operating system. As a result, the current Windows version (at least 6 months after release by Microsoft) shall be supported as well as the previous version as a minimum. Adjustment to the customer network is targeted. The building automation and control system shall thus be able to be installed on any commonly available PC environment. Data exchange via various subsystems If several subsystems are used, various data shall be exchanged between the automation stations (outside temperature, demand and coordination signals, etc.). Automate recurring tasks The building automation and control system shall take care of recurring tasks to lower the operator's workload. This includes, for example, cyclical report generation triggering, plant release at various conditions, or automatic adjustment of setpoints or alarm limits. Designed for use with fire life safety systems (UL certified) The management station shall have passed performance and environmental tests by the Underwriters Laboratories (UL). To combine the comfort and fire life syfe system, the management station shall provide all the relevant functions: Visualize and treat events Graphically monitor and control the life safety system Know where to start as highest priority events are highlighted. Directly navigate to the triggering element of an event. Quickly navigate to custom operator instructions and graphical display of event locations. Store and retrieve fire alarm system activity data. Distribute fire monitoring and control capabilities across the network of the management stations. Provide Operating Procedure checklists to guide the operator, under stress conditions, during the treatment of life safety events. Send out automatic remote notification of responders through email. View and schedule automatic history reports. SCADA plattform The management station shall be based on a SCADA plattform, which shall be fully compliant with the BACnet B-AWS profile. It shall enable the integration of any type of building equipment, such as HVAC and lighting. Operating system for building automation and control system



27

All data servers, operator workspaces etc. for the building automation and control system shall be compatible with the current, common 64-bit Windows operating system. As a result, the current Windows version (at least 6 months after release by Microsoft) shall be supported as well as the previous version as a minimum. Adjustment to the customer network is targeted. The building automation and control system shall be able to be installed on any commonly available PC and shall provide a multi-tasking type environment that allows the user to run several applications simultaneously Help functions The software shall provide an online, context-sensitive help, including an index, glossary of terms, and the capability to search help via keyword or phrase User profiles Plant overview Individual views Individual, specific, or own views shall be able to be set up to broaden plant overview. These views shall cover various electrical and mechanical installations or follow geographic or organizational criteria and shall allow personalized hierarchical “tree” views that represent the workstation, control systems, geographical facility layouts, and mechanical equipment relationships. User privileges The building automation and control system shall allow users to define, change, or delete predefined reactions as per their user privileges. Multi language possibility The user interface shall be able to support minimal three languages simultaniously in one system. Graphics General Operator interface to CAD system The operator interface shall allow users to access the various system schematics and floor plans via a graphical penetration scheme, menu selection, point alarm association. Graphics software shall permit the importing of CAD symbol, or scanned pictures for use in the system. Operating messages Operating messages shall be able to be displayed and evaluated at the management level. Graphics shall be capable of displaying the status of points that have been overridden by a local priority switch, for points that have been designed to provide a field local priority override capability. Full graphics mode A fully graphic management level featuring ergonomic images shall be available. The system shall be designed for operation, monitoring, optimization, and logging of all connected automation stations in real-time. Graphics creation User shall be able to add/delete/modify system graphics and state text for digital points, from standard user interface without the need of any external or specialized tools. Navigation



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The navigation through various graphic screens shall be optionally achieved through a hierarchical “tree” structure. Graphics viewing shall also include dynamic pan zoom capabilities and include the ability to switch between multiple layers with different information on each layer. Pictures Graphic symbols and standard The plant pictures shall satisfy ergonomic needs of operators. The displayed graphic symbols shall correspond to the generally valid standard for HVAC symbols (DIN 19227) and ASHRAE guidelines. Symbols shall be supported as two or three dimensional graphics. Capability to create color graphic floor plan displays and system schematics for each piece of mechanical equipment, including, but not limited to, air handling units, chilled water systems, hot water boiler systems, and room level terminal units. Associated prints of standard plant pictures shall thus be added to the bid. Object-oriented graphics The building automation and control system shall offer dynamic, high-resolution graphics. The graphics shall be object-oriented. Each symbol shall be able to display several states in the same, consistent format. At the same time, several views shall be able to be open concurrently, and all views shall be updated dynamically. Continuous update and display. Measured values, setpoints, user settings, and alarms shall be displayed immediately and continuously. State changes shall be indicated via symbol, e.g. using animation or changing the color, in general, however, graphic presentation, or text. Graphic symbols and standard The plant pictures shall satisfy ergonomic needs of operators. The displayed graphic symbols shall correspond to the generally valid standard for HVAC symbols (DIN 19227) and ASHRAE guidelines. Sysmbols shall be supported as two or three dimensional graphics.Capability to create color graphic floor plan displays and system schematics for each piece of mechanical equipment, including, but not limited to, air handling units, chilled water systems, hot water boiler systems, and room level terminal units. Associated prints of standard plant pictures shall thus be added to the bid. Scheduler programs General Management via central scheduler programs Operate all scheduler programs online from the management level to achieve consistent, transparent operation of all integrated systems and subsystems. Scheduler program The system shall offer the possibility to operate scheduler programs running on the automation stations and also support management station based scheduling capabilities. Every currently used plant picture shall offer user-friendly scheduler program operation. Scheduling and override Providing a calendar type format for simplification of time and date scheduling and overrides of building operations is requested. Schedule definitions shall reside in the PC workstation and in the Building Controller to ensure time equipment scheduling when PC is off-line. Provide override access through menu selection, graphical mouse action or function key. Provide the following capabilities as a minimum: Fully support all BACnet Schedule, Calendar, and Command objects. Daily and Weekly schedules Ability to combine multiple points into a logical Command Groups for ease of scheduling (e.g., Building 1 lights) Schedule predefined reports. Ability to schedule for a minimum of up to ten (10) years in advance.



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Provide filtering capabilities of schedules, based on name, time, frequency, and schedule. Provide sorting capabilities of schedules, based on name, time and type of schedule. Scheduler program types Customized scheduler program The user can customize the schedule defining the operating mode for each plant. Switching times are defined via weekly schedule. Overriding recurring weekly schedules via local or global exceptions as well as operation via any operator unit shall be possible Customized calendar Local or global calendar exceptions shall be able to override the plant-specific weekly scheduler program. Equal calendars shall be assigned priority over each other. Calendar operation shall be possible via all operator units. Building automation and control system operation Multiuser-System with online services Create calendar online Calendar programs shall be able to be remotely created online to provide service personnel a high level of flexibility. Create scheduler online Scheduler programs shall be able to be remotely created online to provide service personnel a high level of flexibility. Online creation of offline trends Trends, that also trend offline, shall be able to be remotely created online to provide service personnel a high level of flexibility. Multiple, concurrent users Multiple users shall be able to work concurrently on various workspaces on the building automation and control system for efficient and comprehensive work. Plants shall simultaneously be analyzed and e.g. monitored or operated via a remote station. Security Access protection Different persons maintain and operate the plant. For this reason, passwords shall be assigned to authorized persons to guarantee transparency for tracking or authorization purposes. A minimum of four different rights shall be assignable. Administrator. Program and graphics creation. Operation to change or adjust setpoints. Guest. Windows authentication The building automation and control system's password administration shall be consistent with the customer's IT guidelines. In other words, corporate customer guidelines shall also apply to the building automation and control system. As a result, password administration and related properties shall be equal to standard Windows login and shall "follow" the operator to any workstation logged onto. Alarm handling Alarm generation Message handling Both types of alarm management (Intrinsic Reporting/Algorithmic Reporting) are supported as recipients. Alarms from automation stations are received at the management level, but not generated based on a



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change to Present_Value or Status_Flags in the automation station. All alarms are displayed when the management level is started. Intrinsic: Each BACnet object is alarmable. Algorithmic: Limit value supervision. Alarm routing Media, independence, formats Current alarms may need to be routed independent of media at certain times to a central service (Printer, email). To do this, various formats shall be available (CSV, XLS, PDF). There shall be no limit to the number of points that can be configured for remote notification of alarm conditions and no limit on the number of remote devices which can receive messages from the system Alarm message escalation list System shall be configurable to send messages to an individual person or group of people and shall be configurable to send different messages to different remote devices based on alarm message priority level.It shall be able to send also to an escalation list so that if the first device does not respond, the message is sent on to a second device after a configurable time has elapsed. Acknowledgment Operator units for acknowledgement After user rights are assigned, all alarms (alarms and faults, errors) shall be acknowledgeable from all operator units. This helps to trace alarms. A time stamp and assignment (based on user account) is required. This includes: Local acknowledgement (control panel, automation station). Management level. Remote operating equipment. Alarm management strategy The software shall allow the user to configure the alarm management strategy for each point. The editor shall provide the ability for editing the point database directly online with the Building Controllers. The operator interface software shall also provide the capability to perform bulk modification of point definition attributes to a single or multiple user-selected points. Alarm display Color display Incoming alarms shall be colored for quick and easy interpretation. Both order and state as well as alarm priority shall be recognizable. The alarm window shall be displayed as per operator needs. Alarm window displays shall be added to the bid Alarm message content The message texts shall contain all information necessary to allocate and resolve the error. This includes at least the following attributes: Clear text. Control panel name Plant name Priority (min. 16 different priorities). Time. Status (acknowledged, unacknowledged). Instructions on how to resolve the problem shall be available in the background. Filter alarms The building automation and control system shall offer alarm filtering. Filtering shall be possible by alarm lists or priorities. Alarms are displayed in popup windows. Step-by-step instructions on handling each alarm help the building automation and control system operator to find a solution.



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Event management Event Routing and sorting Event Routing shall allow the user to send event notification to selected printers or workstation location(s) based on event severity, or point type. The List shall have the ability to list and sort the events based on event status, point name, ascending or descending activation time. Event Notification Event Notification shall be presented to each workstation in a tabular format application, and shall include the following information for each event: name, value, event time and date, event status, priority, acknowledgement information, and alarm count. Each event shall have the ability to sound an audible notification based on the category of the event. Event acknowledge Directly from the Event List, the user shall have the ability to acknowledge, silence the event sound, print, or erase each event. The interface shall also have the option to inhibit the erasing of active acknowledged events, until they have returned to normal status. The user shall also have the ability to navigate to all information related to a selected point in order to command, launch an associated graphic or trended graphical plot, or run a report on a selected point directly from the Event List. Report generation Reports Report generation The system shall spontaneously (snapshot) generate predefined reports (real-time and historical data) to provide vital plant data at any time. These reports shall be printable or exported to third-party spreadsheet software and as PDF file. The data shall be editable in other programs (Microsoft Excel, or Microsoft Access) for further analysis. Standard report templates Templates help generate comprehensive reports without much effort. At least three different report templates shall be available. Reports to record alarm and fault states. Reports to record logbook entries. Reports to record plant and building panels states List of all points currently in override status List of all disabled points List of alarm strategy definitions Point totalization report Point Trend data listings Initial Values report User activity report Event history reports Customized report templates The system shall allow for creating specific report templates to meet individual report generation requirements, which also may include plant and trend graphics. Remote operation Operating options General requirement for operating The Web based interface shall provide the same functionalities as those available at any other workstation, including operation and configuration capabilities. All operator interface functions shall be available in clients running in a browser, installed client console, or Windows desktop app. Via web browser



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Users shall be able to remotely operate and engineer plants regardless of location with the same user interface. This openness, of course, may in no way impact plant safety. The client shall run in a browser as a Full Trust client application Dedicated Desktop Installed client Users shall be able to remotely operate and engineer plants regardless of location. This openness, of course, may in now way impact plant safety. The client shall run as a fully installed software installation that can lockdown desktop space and prevent the ability for the software to be minimized or covered by other applications. Windows Desktop APP Users shall be able to remotely operate and engineer plants regardless of location with the same user interface. This openness, of course, may in no way impact plant safety. An app shall be downloaded to the client from the server PC, that runs like an installed application, and shall be automatically updated whenever new apps are available at the server. Trend data Analyses Simultaneous, multiple trends Multiple trend views shall be possible simultaneously to provide a comprehensive plant overview. Standard plants from medium to higher complexity (as in this project) require a simultaneous display of up to 10 trend curves on the current page view to assess the plants. Multiple trend curves shall thus be recorded at the same time. Freely assign trend data For greatest possible flexibility, operators shall be able to assign and thus record max. 4 additional data points individually for each plant. The assignment shall be carried out from the management station. Decentralized data storage None of the trend data may be lost during communications failure to achieve gap-free trend documentation. For this reason, all trend data shall be created and saved to the automation station. After communications are restored, all values saved on the management station shall be updated automatically. Record history data, trend Vital data points and setpoints shall be saved for each building services plant. The polling time is oriented to the signal type, i.e. analog values are recorded cyclically while digital or multistate values are recorded by event. Intermediate storage of history data Trend data are collected in the automation station and transferred to the management level after a specific time has expired or specific number of data has been recorded. Trend data may not be lost if the management station is unavailable temporarily. Trend comparison To make analysis of changed conditions in different times, the system shall provide a time shifted trend view. EXCHANGE OF DATA THROUGH STANDARD INTERFACES.



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The system shall be an open system using an OPC, which is a standard communication protocol to exchange data. The system shall support the use of standard interfaces and drivers that make it easy to integrate to third party software directly at the management station level, or to make common use of data from the system, e.g. via ODBC (Open Database Connectivity. Further the system shall also be capable of integrating with third party system using Modbus RTU, BACNET or LonWorks protocols. ACCESS PROTECTION The management station shall grant access to the system only to authorized users. The system administrator shall adapt to an environment to match the individual requirements of each user. The access protection facility shall define sites and equipment to which a given user has access, the software functions available to that user within the site. The system shall support the following features

Access to control and develop functions is protected with User name/ password.

Individual access privileges covering access to sites, subsystems, and program functions down to individual objects in Plant Viewer.

Encrypted Passwords.

Association of users to groups.

Association of objects to groups.

Up to 500 users shall be grouped in a single group

New users can be defined at runtime. Every single group shall have the rights to

Lock a station

Shut down a station

Log off

Change the password SYSTEM DESIGN As a decentralized module with autonomous intelligence, the system controller shall be able to process, store and handle a large volume of data. In this way all the demands placed on an advanced control and management system shall be met in full. THE COMMUNICATION LEVEL The controller of the BAS shall be an intelligent module that can be operated autonomously and should not need to be supported/located centrally. The DDC controller shall co-ordinate the flow of data in both directions; it shall be responsible for the communication upwards to the management station, on the same level with other system controllers and downwards via the interface to the locally operating DDC modules. THE DATA EXCHANGE The interface transmits and receives data both via the DDC bus and via the trunk bus of the System controller. The tasks of the interface shall include:

Processing the installed DDC data points.

Converting local system controller addresses into physical DDC module addresses.

Monitoring topology and DDC bus communication.



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Optimizing communication between the interface and the system controller.

Synchronizing date, time and daylight savings time adjustments in the interface and the DDC modules. Standard BACnet / AMEV DIN EN ISO 16484-5 / AMEV

AMEV MOU-B (management station) AMEV MBE-B (management and operation facility)

Management stations shall meet the AMEV profile MBE-A and MBE-B as per AMEV guidelines "Bacnet 2011" B-AWS (management station)

Management stations shall match the BACnet Profile B-AWS (Advanced workstation) as per the BTL Listing and also specified in ANSI / ASHRE 135 guidline. It shall also support the BACnet Life Safety Points and BACnet Life Safety Zones functionality ONVIF video standard

The system shall be able to implement Video streams of IP cameras. The presentation in “video wall” modus shall be supported. DDC CONTROLLERS The Distributed direct digital control (DDC) system shall be designed with functions distributed both physically and functionally over the field controllers. All DDC’s are with 32 bit technology & BTL Approved. The DDC’s shall be true autonomous with peer-to-peer communication and shall have minimum the following features. In case of systems using master / slave communications, the master shall be redundant. Inbuilt memory for viewing any historic data base at least for 1MB of data in each controller. Parameters like various temperatures, RH, pressure and any other stipulated parameters should be possible for storing within each controller and shall be available for viewing/uploading in the event central system is switched off or the communication network is under maintenance. (Storing of buffer database at other locations other than individual DDC is not acceptable).

Provision shall be available for connecting laptops or PC or portable operator terminal directly to DDC for any detailed evaluation locally in the AHU room for any exigency. The autonomous controller for each unit shall be with EPROM chip of required capacity with function blocks for performing required closed loop and open loop (interlocks) functions at the various locations shall be a part of the controller. The controller shall be housed in proper enclosure, providing all required data acquisition, processing capability as required. The controllers shall be completely wired and all interface relays required for interfacing to external system like MCC etc. should be provided. Autonomous DDC Controllers shall be able to access any data directly to any other DDC Controllers or combination of controllers on the network without dependence upon a central processing device. Autonomous DDC Controllers shall work without dependence upon a Process Data Manager. The DDC controllers shall be chosen with minimum amount of I/O points (including spares as mentioned in the I/O list) as required in the I/O schedule, expansion of I/Os shall be possible either by modular expansion with low I/O density expansion modules, or in rack execution with plug-in cards. The selection of DDC controller shall be as per I/O schedule and the quantity of DDC controller shall be as in the BOQ given hear in the specification no deviation shall be expectable. FUNCTIONS



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It shall be possible to set the parameters and structure the application programs by using a graphic and element oriented programming language. For generation of the application programs, the following function elements are required

Arithmetic operations

Addition/subtraction

Exponentiation

Multiplication /Division

Sign

Root functions Logic Operations

Logic AND

Logic ANDb

Logic OR

Logic ORb

Logic EXOR

Logic EXORb

Logic NOT

Logic NOTb Comparison Operations Four levels of comparison functions available

Limit 2

Limit 4

Limit 6

Limit 8

Controllers

PID controllers

2 point PID controllers

3 point PID controllers

Selection Operations

Maximum value

Minimum value

Special Functions

Power failure

Watch dog

Pulse counters Above blocks shall be resident in the DDC controllers and independent of any high level interfaces/controllers. Further, the DDC unit software shall have the following additional functions:

Free selection of range and unit (dimensions) of all signals (measured values, accumulated values, calculated values, etc.).

Free allocation of access protection in accordance with operating priorities.

FIELD SENSORS AND DEVICES



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Room Temperature Sensor: Sensing Element : Pt1000 Range of Use : 0...50 °C Degree of protection : IP 30 to IEC 529 Output Signal : Resistive Output Environmental conditions Temperature : 0...50 °C Humidity : <85 % r. h. Room Temperature & RH Sensor: Sensing Element : NTC 10k(Temperature), capacitive sensing element(Humidity) Range of Use : 0...50 °C/ − 35...+ 35 °C / − 40…+70 °C (Temperature), 0…100 % r.h Degree of protection : IP 30 as per IEC 60529 Output Signal : DC 0...10 V for both(Temperature and Humidity) Power supply : AC 24 V ± 20 %, 50/60 Hz Accuracy : ± 0.8 K(15...35 °C), ± 3 % r.h (30...70 % r.h) Approval : CE, UL 873,C-Tick Environmental conditions Temperature : -15...50 °C Humidity : <95 % r. h. Duct Temperature Sensor: Sensing Element : Pt1000 Range of Use : − 50...+ 80 °C Degree of protection : IP 42 to IEC 529 Output Signal : Resistive Output Probe Length : 400mm Environmental conditions Temperature : – 40...+ 70 °C Humidity : 5...95 % r. h. Duct Temperature & RH Sensor: Sensing Element : NTC 10k(Temperature), capacitive sensing element(Humidity) Range of Use : 0...50 °C/ − 35...+ 35 °C / − 40…+70 °C (Temperature), 0…100 % r.h Degree of protection : IP 54 as per IEC 60 529 Output Signal : DC 0...10 V for both(Temperature and Humidity) Power supply : AC 24 V ± 20 %, 50/60 Hz Accuracy : ± 0.8 K(15...35 °C), ± 3 % r.h (30...70 % r.h) Approval : CE, UL 873,C-Tick Environmental conditions Temperature : -25...70 °C Humidity : <95 % r. h. Water Temperature Sensor: Sensing Element : Pt1000/LG-Ni1000 Range of Use : -30...+130 °C Degree of protection : IP 42 Output Signal : Resistive Output Thermo well : 100/150mm Length Time constant : approx. 30 s(With Protection Pocket)



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Immersion rod : Stainless steel Environmental conditions Temperature : -40...70 °C Humidity : <5...95 % r.h. Duct Differential Pressure Sensor(Air) Sensing Element : Piezo-resistive Range of Use : 0...200 Pa/ 0...250 Pa/ 0…500 Pa Degree of protection : IP 42 as per IEC 60 529 Power supply : AC 24 V ± 15 %, 50/60 Hz Output Signal : DC 0...10 V Accuracy : < ± 0.1 % FS / °C( at 20°Ambient, TC zero point) Overload Pressure : 5,000 Pa Medium temperature : 0...70 °C

Pressure connection : PVC nipples ∅ 6.2 mm Approval : CE, C-Tick,ROHS Accessories : consisting of 2 m plastic tubes, 2 air duct probes Environmental conditions Temperature : -25...70 °C Humidity : <90 % r. h. (without condensation) Room Differential Pressure Sensor(Air) Sensing Element : Piezo-resistive Range of Use : ±50 Pa/ ±100 Pa Degree of protection : IP 42 as per IEC 60 529 Output Signal : DC 0...10 V Power supply : AC 24 V ± 15 %, 50/60 Hz Accuracy : < ± 0.1 % FS / °C( at 20°Ambient, TC zero point) Overload Pressure : 5,000 Pa Medium temperature : 0...70 °C

Pressure connection : PVC nipples ∅ 6.2 mm Approval : CE, C-Tick,ROHS Accessories : consisting of 2 m plastic tubes, 2 air duct probes Environmental conditions Temperature : -25...70 °C Humidity : <90 % r. h. (without condensation) Air Differential Pressure Switch(Air): Sensing Element : spring-loaded diaphragm Range of Use : 50...500 Pa Degree of protection : IP 54 as per IEC 60 529 Output Signal : Single-pole change-over, multi-layer contact(AC 250 V, max. 5 A res.) Overload Pressure : 7500 Pa Cycle Time : >1 mio switching cycles Approval : CE, UL94,C-Tick, DVGW approval Accessories : consisting of 2 m plastic tubes, 2 air duct probes Environmental conditions Temperature : -30...85 °C Humidity : <90 % r. h. (without condensation) Water Pressure Sensor:



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Sensing Element : Piezo-resistive Range of Use : 0...10 bar Degree of protection : IP 65 to EN 60 529 Output Signal : DC 0 ...10 V Power supply : AC 24 V ± 15 %, 50/60 Hz Rupture Pressure : 3 x scale end value of measuring range (FS) Medium Temperature : − 40...+ 80 °C Accuracy : < ± 0.6 % FS Approval : CE, C-Tick Accessories : Mounting kit 1 m copper capillary line, both ends prefabricated ready for connection Thread adapters and terminal nuts Pressure connection : G1/8“ or G1/2“ outer threading. Environmental conditions Temperature : -40...80 °C Humidity : insensitive to condensation Water Differential Pressure Sensor: Sensing Element : ceramic sensor Range of Use : 0...10 bar Degree of protection : IP 65 to IEC 60 529 Output Signal : DC 0 ...10 V Power supply : AC 24 V ± 15 %, 50/60 Hz Overload Pressure : 8 bar Medium Temperature : – 15...+ 85 °C Accuracy : < ± 0.4 % FS Approval : CE, C-Tick Accessories : Mounting kit 1 m copper capillary line, both ends prefabricated ready for connection Thread adapters and terminal nuts Pressure connection : G1/8“ or G1/2“ outer threading. Environmental conditions Temperature : -15...85 °C Humidity : <90 % r. h. (non-condensing) Water Flow Switch: Suitable media : All liquids (not suitable for ammonia) Pipe Diameter : DN 20…200 Switching capacity : max. AC 230 V, 1 A, 26 VA Degree of protection : IP 65 per EN 60 529 Output Signal : Reed contact Nominal pressure : 25 bar Medium Temperature : -20…110 °C Approval : CE Environmental conditions Temperature : -20...80 °C Humidity : <95 % r. h Air Velocity Sensor: The sensor measures a point, i.e., it measures the values at a specific location in the flow profile.



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Priniciple : Anemometric measurement Range of Use : 0...5 m/s, 0...10 m/s, and 0...15 m/s Output Signal : DC 0...10 V or 4…20 mA Operating Voltage : AC/DC 24 V ± 20 %, 50/60 Hz Degree of protection : IP 42 Medium Temperature : -20…110 °C Approval : CE Environmental conditions Temperature : –10…+45 °C Humidity : <95 % r.h Combined Room air quality sensor CO2+temperature+rel. air humidity maintenance-free CO2 sensing element (depending on type) based on optical infrared absorption measurement (NDIR1))or with VOC 2) sensing element based on a heated tin dioxide semiconductorCO2 temperature (active or passive) and CO2 humidity-temperature multisensor No recalibrations required Operating voltage AC 24 V or DC 15…35 V Signal outputs DC 0...10 V or DC 0...5 V adjustable Selectable passive temperature sensing element Power consumption 2 VA Time constant CO2: <5 min, Humidity: <20 s, Temperature: <8.5 min Operating voltage AC 24 V, DC 15...35 V Analog output, signal DC 0...5 V, DC 0...10 V Measuring range, temperature 0...50 °C, -35...35 °C Measurement range humidity 0...95 % r.H. Measuring range CO2: 0...2000 ppm Ambient temperature, operation 0...50 °C Connection, electrical Screw terminals Degree of protection IP30 Dimensions (W x H x D) 90 x 100 x 36 mm Modulating Valves: Threaded : Up to 40mm Flanged : > or Equal 50mm PN Rating : PN16 Valve Body : bronze up to 40mm, Grey cast iron for 50mm and above Δp max across the valve : Minimum 175Kpa Two Way/3-Way : As per BOQ Stem : Stainless steel Medium temperature : +1…95 °C Environmental conditions Temperature : -10…55 °C Humidity : 5…95% r.h. Valve Actuator: Type : Electro-Motoric up to 65mm, Electrohydraulic for 80mm and above Operating voltage : AC 24 V ± 20 % 50 or 60 Hz IP Rating : IP54 Type of Signal : Modulating DC 0..10V Nominal stroke : 5.5mm up to 40mm dia Valves, 20mm for 50,65,80mm Dia valves 40mm for 100,125,150mm Dia Valves



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Manual Override : YES Approval : CE Environmental conditions Temperature : -5…50 °C Humidity : 5…95% r.h. Damper Actuator (Fire Damper Actuator On/Off) Type : Rotary version with spring return Operating voltage : AC 24 V ± 20 % 50 or 60 Hz IP Rating : IP54 Type of Signal : Two-position control Torque : 7NM (1.5SQM damper Area) or 18NM,(3SQM Damper Area) Runtime for rotary angle 90° : 90 s Closing time with return spring : 15 s Manual Override : YES Round / square shaft: 6.4...20.5 / 6.4...13 mm (7NM) Round / square shaft: 8...25.6 / 6...18 mm (18NM) Approval : CE,C-Tick Environmental conditions Temperature : –32…+70 °C Humidity : <95 % r.h Damper Actuator (Modulating) Type : Rotary version without spring return Operating voltage : AC 24 V ± 20 % 50 or 60 Hz IP Rating : IP54 Type of Signal : DC 0…10V Torque : 5NM (0.8SQM damper Area) /10NM,(1.5SQM Damper Area) 15 NM(3SQM Damper Area) Runtime for rotary angle 90° : 150 s Manual Override : YES Round / square shaft: 6.4...20.5 mm / 6.4...13 mm (15NM) Approval : CE,C-Tick Temperature : –32…+70 °C Humidity : <95 % r.h Butterfly Valves: Valve Body : Grey cast iron PN Rating : PN 16 to EN1333 Permissible operating pressure : 1600 kPa (16 bar) Angle of rotation : 90° (to end stop) Medium temperature : -10…120 °C Permissible media : chilled water, low temperature hot water, high temperature hot water, Brine Approval : CE Butterfly Valve Actuator: Type : Electromotoric rotary actuators Type of Signal : 3-position Operating voltage : AC 230 V ±15%( 3-position) Operating voltage : AC 24 V ± 20% (DC 0..10V, Modulating) if included in BOQ Type of Signal : DC 0…10V if included in BOQ



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IP Rating : IP54 as per EN 60529 Positioning times : 120s Manual Override : YES Approval : CE,UL Environmental conditions Temperature : –15…+55 °C Humidity : 5..95 % r.h Further to the above technical specification laid down in the Tender, the BMS Vendor shall also satisfy following technical requirements and scope of works :- Design, supply, installation, testing and commissioning of all hardware, software, controls wiring, containment, conduiting, truncking and power to the equipment from Isolators provided under the Electrical Contract. Supply and Install wall/duct temperature and humidity sensors, tank level sensors. Supply liquid differential pressure switches and actuators for installation by the BMS Contractor. Transportation, off-loading, craneage and moving into position of all of the above. Include for travel and accommodation for three people for factory witness testing. Commission the complete system on site to an agreed programme. Handover to include IST testing following completed commissioning of all works. Include for services visits at 3 months after commissioning. Warranty the Works for 24 months from date of issue of the Certificate of Practical Completion. 2 Set of details and drawings to be provided as defined in the Construction Instruction section of this Specification. 2 Set of Operating & Maintenance (O & M) documentation to be provided as defined in the Construction Instruction section. Include for closely liaising with the Fire Protection system Contractor, Mechanical and Electrical Works Contractors and all other associated Trade Contractors. A training section should be conducted to Instruct Employer’s Staff on operating and maintenance procedures. Should Provide critical spare parts list which shall be available till 10 years from date of successful handover.. Prior to Practical Completion of the Project the Trade Contractor shall carry out a full clean of the works. The Tenderer is to allow for enclosures to be painted in RAL or BS colours other than this standard. This is to allow for identification of systems. Up to 4 different colours may be required. Colours shall be advised at the time of ordering. The above works are described in more detail in subsequent Clauses and Schedules and as the accompanying Drawings. 3. QUALITY ASSURANCE



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The Building Automation and Control System shall be furnished, engineered, and installed by Trained Engineers of the Contractor. The contractor shall have extensive knowledge and shall be factory certified. The contractor shall employ technicians who have completed the factory authorized training. The contractor shall employ technicians to provide instruction, routine maintenance, and emergency service within 24 hours upon receipt of request. System Integrator Qualifications The system integrator must be an authorized representative in good standing of the manufacturer of the proposed hardware and software components. The system integrator shall have an office that is staffed with designers trained in integrating interoperable systems and technicians fully capable of providing instructions and routine emergency maintenance service on all system components. The system integrator shall have in house capabilities to provide control strategies for whole building control. This includes HVAC, lighting, Access, Fire Detection, Fire Suppression and Protection, and security applications. The system integrator shall have a service facility, staffed with qualified service personnel, capable of providing instructions and routine emergency maintenance service for networked control systems. Hardware and Software Component Manufacturer Qualifications The manufacturer of the hardware and software components must be primarily engaged in the manufacture of Building Automation systems as specified herein, and must have been so for a minimum of ten (10) years. The manufacturer of the hardware and software components shall have an authorized representative capable of providing service and support as referenced in section B above, and must have done so for a minimum of Two (2) years. The manufacturer of the hardware and software components shall have a technical support group accessible via a toll free Or any alternative number that is staffed with qualified personnel, capable of providing instruction and technical support service for networked control systems.. The manufacturer of the hardware and software components must have Minimum ten (10) year similar projects, which have building systems as specified herein. These projects must be on-line and functional such that the Owners/Users representative can observe the system in full operation. 4). APPROVALS The system shall have proper listing and/or approval from the following nationally recognized agencies: UL Underwriters Laboratories Inc FM Factory Mutual IDENTIFICATION OF HARDWARE AND WIRING A. All wiring and cabling, including that within factory-fabricated panels shall be labeled at each end within 2" of termination with a cable identifier and other descriptive information. B. Permanently label or code each point of field terminal strips to show the instrument or item served. C. Identify control panels with minimum 1 inch letters on nameplates.



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D. Identify all other control components with permanent labels. Identifiers shall match record documents. E. Identify room sensors relating to terminal box or valves with nameplates. PROGRAMMING A. Provide sufficient internal memory for the specified control sequences and trend logging. B Point Naming: System point names shall be modular in design, allowing easy operator interface without the use of a written point index. C. Software Programming 1. Provide programming for the system as per specifications and adhere to the strategy algorithms provided. The HVAC Control System Contractor shall also provide all other system programming necessary for the operation of the system but not specified in this document. Imbed into the control program sufficient comment statements to clearly describe each section of the program. The comment statements reflect the language used in the sequence of operations. Switchboard, PDU Breaker Monitoring The BMS shall monitor and display a ON/OFF and Tripped Status via volt free contacts for all breakers Spare Capacity The Contractor shall provide 10% spare control points of each type in the form of universal input/output contacts and supporting software capacity at each outstation. Each Floor network shall have the capacity of a 10% increase in the number of nodes on that floor without introduction of further networks. The Contractor shall also provide 2 spare Port at each TCP/IP Hub or Switch if applicable to allow future BMS network expansion. Alarm Monitoring Alarms shall be initially separated into 3 priority levels as follows: Critical Alarms (High) –Critical Alarms including: Critical Switchboard Breaker Tripped Statuses, Out of Limits Temperature/Humidity in building critical areas. Medium Alarms– Plant Alarms including: Ventilation system failures, Sensor Failures, Common Faullts on all non-critical circuits. Maintenance Alarms (Low) – Maintenance Alarms including: Out of Limits Temperature/Humidity in non critical areas. However, definition of all these alarm shall further be classified in co-ordination with individual service providers and any specific requirements from Client. The BMS vendor shall ensure all alarm definitions as per priority given by Client The system shall have all necessary interface modules to allow connection on the Clients IT CLEANING



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A. This contractor shall clean up all debris resulting from his or her activities daily. The contractor shall remove all cartons, containers, crates, etc. under his control as soon as their contents have been removed. Waste shall be collected and placed in a location designated by the Construction Manager or General Contractor. B. At the completion of work in any area, the Contractor shall clean all of his/her work, equipment, etc., making it free from dirt and debris, etc. C. At the completion of work, all equipment furnished under this Section shall be checked for paint damage, and any factory-finished paint that has been damaged shall be repaired to match the adjacent areas. Any metal cabinet or enclosure that has been deformed shall be replaced with new material and repainted to match the adjacent areas. PROTECTION A. The Contractor shall protect all work and material from damage by his/her work or workers, and shall be liable for all damage thus caused. B. The Contractor shall be responsible for his/her work and equipment until finally inspected, tested, and accepted. The Contractor shall protect his/her work against theft or damage, and shall carefully store material and equipment received on-site that is not immediately installed. The Contractor shall close all open ends of work with temporary covers or plugs during storage and construction to prevent entry of foreign objects. FIELD QUALITY CONTROL A. All work, materials and equipment shall comply with the rules and regulations of applicable local, state, and federal codes and ordinances as identified in Part 1 of this Section. Contractor shall continually monitor the field installation for code compliance and quality of workmanship. All visible piping and/or wiring runs shall be installed parallel to building lines and properly supported. Contractor shall arrange for field inspections by local and/or state authorities having jurisdiction over the work. INSTALLATION Do not install electronic hardware in the project until non-condensing environmental conditions have been established. Products installed in violation of this request maybe requested to be replaced at no additional cost to the project. Coordinate storage requirements for factory mounted terminal control units on air terminal devices, air handling units or other packaged control equipment. Do not store control units on site in non-conditioned areas for more than two weeks. Factory-Mounted Components: Where control devices specified in this section are indicated to be factory mounted on equipment, arrange for shipping control devices to unit manufacturer. GENERAL INSTALLATION REQUIREMENTS A.Install all control components in accordance with manufacturer's instructions and recommendations.



45

B.If the controls contractor is responsible for providing the damper then provide mixing dampers of parallel blade construction arranged to mix streams. Provide separate minimum outside air damper section adjacent to variable outside air damper. C.Mount control panels adjacent to associated equipment on vibration-free walls or freestanding angle iron supports. One cabinet may accommodate more than one system in same equipment room. Provide nameplates for instruments and controls inside cabinet and nameplates on cabinet face. D.After completion of installation, test and adjust control equipment. Submit data showing setpoints and final adjustments of controls. E.Install equipment, piping, wiring/conduit parallel to building lines (i.e., horizontal, vertical, and parallel to walls) wherever possible. F.Provide sufficient slack and flexible connections to allow for vibration of piping and equipment. G.Verify integrity of all wiring to ensure continuity and freedom from shorts and grounds. H.All equipment, installation, and wiring shall comply with acceptable industry specifications and standards for performance, reliability, and compatibility and be executed in strict adherence to local codes and standard practices. TESTING Upon completion of the installation, Contractor shall start-up the system and perform all necessary calibration and testing to ensure proper operation of the project control systems. Schedule a hardware demonstration and system acceptance test in the presence of the Contracting Officer and/or the Engineer. The acceptance testing is defined as demonstrating the sequence of operation as indicated in the drawings. The hardware demonstration is specified in this Section. The Contractor shall perform all tests prior to scheduling the acceptance test and hardware demonstration to insure the overall system is ready for inspection and observations. When the system performance is deemed satisfactory in whole or in part by these observers, the system parts shall be accepted for beneficial use and be deemed substantially complete as defined in Division 1. COMMISSIONING The BMS specialist shall be responsible for the full commissioning of his system and any other controls equipment supplied by him. All safety interlocks, overrides and fail-safe conditions are to be operational prior to starting the plant. Demonstrate as agreed with the engineer prior to starting plant in BMS auto mode. Fault conditions for all critical alarms, safety devices and control interlocks shall be simulated and proved effective as soon as practical once BMS control mode is selected. Sensors shall be checked to ascertain accuracy within limits, pressure switches checked for switch points and hysteresis. Humidity sensors shall be checked for accuracy using a wet/dry bulb thermometer. All the necessary test equipment and materials used in commissioning shall be supplied by the BMS specialist. All test equipment shall have valid test certificates. Graphs shall be provided to demonstrate the stable control of the plant. Simulated inputs shall be employed to check stability over the design environmental range. The BMS specialist shall allow one additional full day by his commissioning engineer to revisit the system at a later date (after hand-over). He shall check and adjust operational parameters, and re-tune any control as maybe required by change in the control system load conditions or bedding-in of the plant. Commissioning documentation and schedules shall be submitted for approval during the design phase showing each plant, point, interlock and control algorithms, and the stages of checks and commissioning required. Each cleared item to have date and engineer reference. Completed copies shall be available to the engineer



46

prior to acceptance testing. A complete set of the commissioning documentation is to form part of the system documentation. Once any item of plant is commissioned and left running to the dictates of the BMS, documentation showing the overrides, control and software configuration shall be available on site at all times. All system documentation shall be in accordance with standard templates. Acceptance Demonstrations The BMS specialist shall give seven days notice to the engineer of his intention to provide the acceptance demonstrations once the commissioning is complete. The operation of all safety interlocks shall be tested and ten per cent of all points shall be selected by the engineer and demonstrated for operation/accuracy. Should more than 1% fail performance test, a further ten per cent may be selected. If above 1% fail he may at his discretion demand 100% demonstration. The BMS specialist shall supply sufficient man-power/test equipment, consumable items and portable telephones to conduct the demonstration efficiently. Testing shall also incorporate an audit of the wiring and hardware installation, demonstration of safety interlocks, start of system from power-down and review of time schedules and alarm levels, grouping and selected control parameters. DOCUMENTATION Submit the following according to conditions of Contract and Specification sections. In addition, provide the following: 1.Product data on all components used to meet the requirements of the specifications such as enclosures, network transceivers, XIF documentation, configuration parameter options, mounting details, power supplies, etc. 2.Software documentation regarding the proposed PC operating system, third party utilities and application programs, and the proposed application program for the Control Units. 3.Logical and physical diagrams for each channel indicating each node (control devices and ID’s), node address (domain, subnet and group), channel type and router specifications. Submit functional temperature control diagrams for each Mechanical syste 4. served by the HVAC Control System. Indicate and Tag each input/output served by each Control Unit or Intelligent Device. 5 Submit 2 sets of submittals for review within 2 weeks of contract award. Shop Drawings 1.The controls contractor shall submit AutoCAD or Visio generated schematic drawings for the entire control system for review and approval before work shall begin. Included in the submittal drawings shall be a one-page diagram depicting the complete system architecture complete with a communications riser. Drawings shall include point-to-point wiring diagrams and must show all temperature controls, start-stop arrangement for each piece of equipment, equipment interlocks, wiring terminal numbers and any special connection information required for properly controlling the mechanical equipment. The submittal shall include a bill of material reference list as well as equipment sequences of operation. 2.The submittals shall include manufacturer's catalog data describing each item of control equipment or component provided and installed for the project. 3.System Color Graphics using the AutoCAD or Visio generated schematic drawings. Dynamic points, menus icons, commandable points, etc. should be clearly identified. 4.Color conventions proposed for all graphics. Close-Out Documents 1.Submit final copies of the shop drawings outlined in paragraph B above. These final submittals shall reflect all field modifications and change orders required to complete the installation. Submit the following quantities of record submittal drawings immediately following receipt of notification of substantial completion. Auto CAD drawing or VISIO files of all shop drawings on or CD ROM disks.



47

2.Three complete sets of documents located in a Spiral Bound notebook and organized by subject with divider tabs. HANDOVER Submit 3 sets of operation and maintenance manual in accordance with requirements of the Specifications. Include the following documentation: Network Management Software User Manual specific to each tool package provided. Maintenance Instructions: Document all maintenance and repair/ replacement procedures. Provide ordering number for each system component, and source of supply. Provide a list of recommended spare parts needed to minimize downtime. Documentation of network variables, network node configurations, priority interrupts, node binding, addressing structure, etc. TRAINING A. All training shall be by the Building Controls Contractor and shall utilize specified manuals, as-built documentation, and the on-line help utility. B. Operator training shall include four initial eight-hour sessions. The initial operator training program shall be to establish a basic understanding of Windows based software, functions, commands, mouse, etc. The training shall encompass as a minimum: Troubleshooting of input devices, i.e., bad sensors. Sequence of operation review. Sign on - sign off. Selection of all displays and reports. Commanding of points, keyboard and mouse mode. Modifying English text Use of all dialogue boxes and menus. System initialization. GUI Software. Network Management Software. MAINTENANCE General According to the standard recommendations systems should be regularly maintained under a maintenance agreement. The customer shall be responsible for ensuring that daily, weekly and monthly routine maintenance is carried out in accordance with the recommendations set out in and the service and maintenance instructions provided by the manufacturer



48

Sr. No. Description QTY

Anal

og In

puts

(AI)

Dig

ital I

nput

s (D

I)

Anal

og O

utpu

ts (A

O)

Dig

ital O

utpu

ts (D

O)

Soft

war

e Po

ints

From To Remarks

A Plant Room

1 Chillers 4

1.1 Chiller Enable / Disable Command 4 DDC Controller Chiller MCC PanelPotential Free Contact to be provided by

HVAC Vendor

1.2 Chiller Run Status Monitoring 4 Differential Pressure Switch (Liquid) DDC Controller1/2" socket to be provided by HVAC

Vendor

1.3 Chiller Trip Status Monitoring 4 Chiller MCC Panel DDC ControllerPotential Free Contact to be provided by

HVAC Vendor

1.4 Chiller Auto / Manual Switch Status Monitoring 4 Chiller MCC Panel DDC ControllerPotential Free Contact to be provided by

HVAC Vendor

1.5 Chiller Isolation Valve Control 4 DDC Controller Valve ActuatorPotential Free Contact to be provided by

Valve Vendor

1.6 Chiller Isolation Valve feedback monitoring 4 Valve Actuator DDC ControllerPotential Free Contact to be provided by

Valve Vendor

1.7 Chiller Common Header Supply Temperature monitoring 1 Immersion type Temperature Sensor DDC Controller1/2" socket to be provided by HVAC

Vendor

1.8 Chiller Common Header Return Temperature monitoring 1 Immersion type Temperature Sensor DDC Controller1/2" socket to be provided by HVAC

Vendor

1.9 Chiller Supply Temperature monitoring 4 Immersion type Temperature Sensor DDC Controller1/2" socket to be provided by HVAC

Vendor

1.10 Chiller Return Temperature monitoring 4 Immersion type Temperature Sensor DDC Controller1/2" socket to be provided by HVAC

Vendor

1.11 Condensor Water Isolation Valve Control 0 DDC Controller Valve ActuatorPotential Free Contact to be provided by

Valve Vendor

1.12 Condensor Water Isolation Valve feedback monitoring 0 Valve Actuator DDC ControllerPotential Free Contact to be provided by

Valve Vendor

1.13 Condensor Water Supply & Return Temperature monitoring 0 Immersion type Temperature Sensor DDC Controller1/2" socket to be provided by HVAC

Vendor

1.14 Chilled Water Temperature Reset Command 0 DDC Controller Chiller MCC Panel 0 to 10 VDC Signal

2 Primary Chilled Water Pumps 4

2.1 Pump Start / Stop Command 4 DDC Controller Pump Starter PanelPotential Free Contact to be provided by

HVAC Vendor

2.2 Pump Run Status Monitoring 4 Differential Pressure Switch (Liquid) DDC Controller Signal from Switch to DDC Controller

2.3 Pump Trip Status Monitoring 4 Pump Starter Panel DDC ControllerPotential Free Contact to be provided by

HVAC Vendor

2.4 Pump Auto / Manual Status Monitoring 4 Pump Starter Panel DDC ControllerPotential Free Contact to be provided by

HVAC Vendor

3 Secondary Chilled Water Pumps 4

3.1 Pump Start / Stop Command 4 DDC Controller Pump Starter PanelPotential Free Contact to be provided by

HVAC Vendor

3.2 Pump Run Status Monitoring 4 Differential Pressure Switch (Liquid) DDC Controller Signal from Switch to DDC Controller

3.3 Pump Trip Status Monitoring 4 Pump Starter Panel DDC ControllerPotential Free Contact to be provided by

HVAC Vendor

3.4 Pump Auto / Manual Status Monitoring 4 Pump Starter Panel DDC ControllerPotential Free Contact to be provided by

HVAC Vendor

3.5 Pump Bypass Status Monitoring 4 Pump Starter Panel DDC ControllerPotential Free Contact to be provided by

HVAC Vendor

3.6 Chilled Water Pressure monitoring 2 Differential Pressure Transmitter DDC Controller Signal from Sensor to DDC Controller

3.7 Secondary Pump Speed Control 4 DDC Controller VFD starter Panel 0 to 10 VDC Signal

3.8 Secondary Pump Speed Feedback 4 VFD starter Panel DDC Controller 0 to 10 VDC Signal

Total for Plant Room 16 44 4 16 80

I Electrical System

1 HT Panel On / Off Status monitoring 2 2 HT Panel DDC ControllerPotential Free Contact to be provided by

Electrical Vendor

2 HT Panel Trip Status monitoring 2 2 HT Panel DDC ControllerPotential Free Contact to be provided by

Electrical Vendor

3 Transformer Alarm Status monitoring 4 Transformer DDC ControllerPotential Free Contact to be provided by

Transformer Vendor

4 Transformer Trip Status monitoring 4 Transformer DDC ControllerPotential Free Contact to be provided by

Transformer Vendor

5 Transformer Winding Temperature Alarm Status monitoring 4 Transformer DDC ControllerPotential Free Contact to be provided by

Transformer Vendor

6 Transformer Oil Temperature Alarm Status monitoring 4 Transformer DDC ControllerPotential Free Contact to be provided by

Transformer Vendor

7 LT Breaker On / Off Status monitoring 2 LT Panel DDC ControllerPotential Free Contact to be provided by

Electrical Vendor

8 LT Breaker Trip Status monitoring 2 LT Panel DDC ControllerPotential Free Contact to be provided by

Electrical Vendor

9 Bus Coupler Status monitoring 2 LT Panel DDC ControllerPotential Free Contact to be provided by

Electrical Vendor

10 Auto Changeover Switch status monitoring 2 LT Panel DDC ControllerPotential Free Contact to be provided by

Electrical Vendor

11 ACB , MCCB Breakers 134

11.1 Breakers On / Off /TRIP Status monitoring 134 DDC Controller DDC ControllerPotential Free Contact to be provided by

Electrical Vendor

12 Diesel Generator (DG) System 5

12.1 DG Run Status monitoring 5 DG Panel DDC ControllerPotential Free Contact to be provided by

DG Vendor

12.2 DG Breaker Status monitoring 5 DG Panel DDC ControllerPotential Free Contact to be provided by

DG Vendor

12.3 Day Oil Tank Level (Hi / Lo) Level monitoring 10 Flameproof Level Switch DDC Controller

Flameproof Level Switch to be provided by

DG Vendor/Sendor provided by BMS

vendor.

13 Filed Devices

13.1 Outside Air Temperature & RH monitoring 1 2 Temperature & RH Sensor DDC Controller

Signal from Sensor to DDC

Controller.Sendor provided by BMS

vendor.

13.2 Hydroge Sensor 2 2 Hydrogen sensor DDC Controller Potential Free Contact to DDC Controller

13.3 Air quality sensors 5 5 Air Quality Senors DDC ControllerSignal from Senor to DDC Controller.

Sendor provided by BMS vendor.

13.4 Gas release Status 23 46 PFC from GSS panel DDC ControllerPotential Free Contact from GSS panel to

DDC Controller

13.5 VESDA/Aspiration System -Status 28 28 PFC from VESDA panel DDC ControllerPotential Free Contact from VESDA panel

to DDC Controller

13.6 Temerature and RH sensor FOR ALL ROOMS 73 146 Temp & Rh sensor DDC ControllerSignal from Senor to DDC Controller.

Sendor provided by BMS vendor.

Total for Electrical System 153 256 0 0 409

K Third Party Integrations

1.1 Chiller System (assumed 25 points per chiller) 4 100Chiller Microprocessor Panel interface with BMS

on BACnet on TCP/IPBMS Integrator

1.2 ACB , MCCB Breakers (20 Soft Points considered for each Unit ) 26 520 Breakers of all Panel integrate on modbus BMS Integrator

1.3 Variable Frequency Drives (assumed 5 points per VFD) 4 80 Variable Frequency Drive (VFD) panel BMS Integrator

1.4 Diesel Generator (DG) System (assumed 25 points per DG) 5 100 DG Microprocessor panel BMS Integrator

1.5 Un-Interupted Power Supply (UPS) System (assumed 10 points per UPS) 18 180 UPS Microprocessor panel BMS Integrator

1.6 Precision Air-Conditioning (PAC) System (assumed 20 points per PAC) 70 1400 PAC Microprocessor panel BMS Integrator

1.7 Transformer (10 Soft Points considered for each Unit ) 4 40 Transformer Panel BMS Integrator

1.8 PDU Load manager for BLOCK 21-S ( 3 Soft Points considered for each Energy Meter ) on MODBUS RTU PROTOCOL.175 525 All Load Manger integrate with BMS on Modbus BMS Integrator

1.9 PDU Load manager for BLOCK 65-F ( 3 Soft Points considered for each Energy Meter ) on MODBUS RTU PROTOCOL.610 1830 All Load Manger integrate with BMS on Modbus BMS Integrator

1.10 Fire Alarm System (assumed total number of detectors & modules) 1 850 Seamlessly Integration with FAS & BMS ( IBMS) on same software platform.

1.12 Water Leak detection Panel Integretion 12 12 60 WLD panel Integration BMS Integrator

Total for Plumbing System 0 12 0 0 5685

SubTotal of Input & Output Points 169 312 4 16 6174

Spare 10% 17 14 1 4 1152

Grand Total of Input & Output Points Soft & Hardpoint 186 326 5 20 7326

TOTAL POINTS SOFTWARE AND HARDWARE

Modbus Data to be demonstrated on

Modscan software & Bacnet data to be

demonstrated on Bacnet explorer by the

respective vendors to the BMS vendor. The

details of data & number of points

required shall be finalised by the client /

client representative.

7326

TENDER IO SUMMARY



49

RODENT REPELLANT SYSTEM

1.0 SPECIFICATIONS FOR RODENT REPELLENT SYSTEM 1.1 GENERAL Rodent Repellent System shall be designed by using Electronic transmitters of high frequency sound waves, which will emit sound at very high decibel levels painful to pests, as described in the specification given hereunder. 1.2 SYSTEM The system shall consist of a Master Console, satellites and its cable circuits. 1.3 MASTER CONSOLE These will be Electronic transmitters of high frequency sound waves (well above the 20 KHZ frequency which is the upper limit of the hearing range of the human ear.) emitting sound at high decibel levels (sound pressure) that is audible and painful to pests, but inaudible and harmless to humans. The system will consist of one Master Console and twelve Satellites / Transducers. The Console will be installed in the control room, or as directed and the satellites in the problem areas as required. The powerful sound waves generated by the satellites shall be within the hearing range of many pests, and cause them pain and discomfort. Satellites should be quiet and inaudible to humans. 1.4 SATELLITE Each satellite will cover an open floor area of approximately 400 sq. ft for an average height of the ceiling is 10 ft. As regards area of false ceilings or false floorings, it should cover an approximate area of 400 sq. ft. The satellites should 1. Be able to mount in any angle to match the décor. 2. Possible to install in sensitive areas. 3. Should withstand high temperatures in false ceilings, and low temperatures in cold storages and air locks. 4. Should not require a power connection. 5. Should be able to test on an audible range with the help of a self-testing facility or any other suitable means. TECHNICAL INFORMATION 1. SATELLITES 1.1 Crystal DM 44T 24V MAS Germany 1.2 Frequency Peak frequency responses of the satellites are



50

i) 21.6 KHz + / -3 KHz ii) 31.6 KHz + / -3 KHz iii) 50.4 KHz + / -3 KHz iv) 60 KHz + / - 3 KHz 1.3 Nature of sound waves The sound waves propagated should be linear sine waves with constantly varying frequencies. 1.4 Operating environment Range of –4 deg C to 60 deg C, 100 % humid environment and also under water. 2 CIRCUIT 2.1 Signal generator should have full wave rectification, regulated 12V DC power supply to withstand power fluctuations ranging from 170V AC to 270V AC. 2.2 Amplifier should have a preamplifier stage coupled with signal generator for dual transistor amplification having a push-pull configuration. Pressure 2.3 Uniform pressure output of 80 dB to 110 dB with 360transmission angle. 2.4 Linear propagation of mixed / variable frequencies detectable at, or about 40 ft distance from the source (Transducer/ Satellite). 2.5 Spatial average intensity – 83mW per cm² 3 POWER SUPPLY 3.1 5A Power Socket (230 V AC) will be provided for each VHFO as may be required. Alternatively, 3.2 Bidder to specify the required power and the no. of Power Sockets required for each unit for both Rodent. 4 SPECIFICATIONS 5.1 Operating frequency : Above 20 KHz (Variable) 5.2 Sound Output : 80 dB to 110 dB at 1.00 Mts. 5.3 Power Output : 800 MW per Satellite 5.4 Power Consumption : 15 Watt Approx. 5.5 Power Supply : 230 V AC, 50 Hz Mounting : Wall / Table Dimension: 16” x 8 “ x 4” Weight : 5.5 Kgs approximately



51

GAS SUPPRESSION SYSTEM -NOVEC1230

General The bidder shall supply, install, test and put in operation NOVEC1230 based fire suppression system. The fire suppression system shall include and not be limited to gas release control panel, PESCO/CCOE approved seamless cylinders, discharge valve (with solenoid or pneumatic actuator) as the case may be, discharge pipe, non-return valve and all other accessories required to provide a complete operation system meeting applicable requirements of NFPA 2001 or ISO standards and installed in compliance with all applicable requirements of the local codes and standards. The system design should be based on the specifications contained herein, NFPA 2001 & in accordance with the requirements specified in the design manual of the agent. The bidder, shall confirm compliance to the above along with their bid. The system shall be properly filled and supplied by an approved OEM (Original Equipment Manufacturer) Generally the key components* of the system shall be VdS or LPCB or FM/UL listed. The NOVEC 1230 gas shall: Comply with NFPA 2001 or ISO 14520 standard have the approval from US EPA (Environmental Protection Agency) for use as a total flooding fire extinguishant for the protection of occupied space: Be given Underwriters' Laboratories Inc. (ULI, USA) component listing for the NOVEC 1230 gaseous agent. Must have zero ozone depletion potential (ODP); Have a short life span in the atmosphere, with atmospheric life time of less than 5 days Be efficient, effective and does not require excessive space and high pressure for storage; Vommercially available *Key components are valves and its accessories, actuators, flexible discharge and connection hoses, check valves, pressure switch, and nozzles Design Condition The hazard space volumes shall be protected from a common central or individual supply, the cylinder bank or individual cylinder system, with corresponding pipes and nozzle system. The individual zone/ system shall be dimensioned to give a complete discharge of the agent in less than 10 seconds into the affected zone. The software calculation shall be approved VdS or FM / UL. The discharge time shall not exceed 10 seconds. After end of discharge (10s) a homogeneous NOVEC 1230 concentration shall be built-up in the room. The design concentration shall follow ISO 14520 or at minimum NFPA 2001 for under floor, room and ceiling

space. Unless otherwise approved, room temperature for air-conditioned space shall be taken around 20C. For non-air conditioned space, the temperature shall be taken around ambient temperature. The system shall be designed with minimum design concentration of 4.7 % as applicable to Class-A & C fire. All voids within each hazard shall be discharged simultaneously. Each hazard shall have an independent system, unless otherwise specifically stated.



52

The system engineering company should carry out the piping Isometric design and validate the same with a hydraulic flow calculation generated by using the agent's design software. Appropriate fill density to be arrived at based on the same. The system shall be so designed that a fire condition in any one protected area shall actuate automatically the total flooding of clean agent in that area independently. The entire system shall incorporate inter-alia detection, audible and visual alarms, actuation and extinguishing . Clean Agent Supply System The extinguishing agent shall be NOVEC 1230 with physical properties conforming to NFPA Standard 2001 or ISO 14520 standard. Each zone to be protected by the Total Flooding System shall be capable of being flooded independently of the other. Re-Filling and Maintenance In case of any leakage or accidental discharge of the agent, it should be possible to re-fill the cylinders in India itself. The contractor should indicate the source of re-filling and the time that will be taken for re-filling and replacement. Storage of Extinguishing Agent The agent shall be stored in liquid form at ambient temperature in high-pressure seamless cylinder containers designed for the purpose. The cylinder shall be high pressure, seamless, flat type and concave bottom. As per the regulations of the Chief Controller of Explosive (CCE) Nagpur, any system which has a working pressure above 19 bar will require the use of seamless cylinders that have been duly approved by the CCE, Nagpur. Each cylinder shall have its own built-in pressure safety relief valves and shall also be equipped with pressure gauge to indicate the pressure of its content. The cylinders shall be super-pressurized with dry Nitrogen to 42 Bar. The cylinder shall be capable of withstanding any temperature between -30 Deg C and 70 Deg C. All cylinders shall be distinctly and permanently marked with the quantity of agent contained, the empty cylinder weight, the pressurization pressure and the zones they are protecting. All cylinders shall be adequately mounted and supported in a manner to facilitate individual servicing or content weighing. Cylinders installed shall be of the same size where possible and the manifold shall be provided with non-return or check valves to prevent back flow when any cylinder is being removed for maintenance. Piping and Fittings All piping shall be Schedule 40 seamless pipes complying with grade B and all fitting shall be of ASTM A-105. Discharge Nozzles Discharge nozzles shall be manufactured in corrosion resistant material and shall be positioned in a manner to effect a uniform concentration at the shortest time after discharge. Each nozzle shall be able to cover a height of 5m effectively.



53

Detection The detection part shall consist of the installation of an adequate number of smoke detectors strategically positioned for the early detection of smoke, and/or products of combustion. All detectors shall be ULI, FMRC and/or LPC or Vds approved. The detection of smoke by such detectors shall immediately set of an audible alarm at the control unit and visual indication of the zone where smoke has been detected. The detectors in each zone protected by Total Flooding System shall be wired on a DUAL RISK CIRCUIT basis. The actuation of one detector in a zone shall not be sufficient to cause the discharge of the agent. The agent shall only be actuated to discharge on activation of another adjacent detector in that zone. The signal from the second activated detector within the particular zone protected by the Total Flooding System shall after a time delay activate the agent release device of the Total Flooding System. The time-delay circuit shall have a delay period adjustable from zero second to 180 seconds. Documentation: The system engineering company should prepare & submit along with the bid documents, the piping Isometric drawing and support the same with a hydraulic flow calculation generated by using the agent's design software. The calculations shall validate the fill density assumed by the bidder. The bidder shall submit copies of the datasheets of the hardware used in the system. The bidder shall also submit copy of CCE approval letter for the cylinder proposed to be used. The bidder shall also submit calculations to evidence the qty of agent considered for the system. The successful vendor must submit, along with the supply invoice, a certificate of authenticity, for the agent from the system engineering company duly checked and verified by distributor. The system engineering company should provide, as part of the handing over, the As-built drawings and operation & maintenance manual. System: Novec 1230 (3M OEM for gas) gaseous based Fire Suppression system

1. Design & execution need to be complied with NFPA & local safety standards. Company to mention the

listing or approval for overall system & equipment’s. 2. Company to submit all type of certificates for design, equipment’s & accessories. 3. Company to submit the OEM cylinder ref & gas filling certificates. 4. Company to submit the necessary certificates for Cylinders, accessories. 5. Company to deploy trained & skilled personnel for the execution of job. 6. Company to highlight any system limitations, Pre requirements from ITI . Company to submit solution

write up etc., along with quote. 7. Company to submit system schematic with operation philosophy considering future build. 8. Company to confirm the pressure at nozzle while release of gas. 9. Pressure gauges & pressure switches at individual cylinders 10. Low Pressure alarm of cylinder bank / cylinders to be integrated in FAS / BMS 11. The Manual operation (Release / Abort), alert indications with signage’s on the door of protected

rooms will be provided & controlled by Company's control panel. 12. In FSS Control Panel- Complete with Gas Release Module, Timer 0-120 sec delay config, Gas Release

Indication, Abort Switch, Manual Release Switch, Auto - Manual Selector Switch with Stand-by Battery & Battery Charger, additional I/O’s for integration & controls of warning sign, hooters etc.

13. The Manual release & Abort switches to install in red color powder coated MS make enclosure, front with glass, hammer, key lock etc

14. Company to clean the internal piping through pressurized nitrogen gas before final testing of system. Also need to carried out Pipe & Manifold test leak & strengthening test.

15. Room Integrity Test for all the protected rooms, same need to be considered in quote



54

16. The Fire suppression solution/ system life requires min 10 years. Company to provide support/maintenance for entire system min 10 years post commissioning.

17. In warranty & AMC period Company to follow Tata Communications SLA for response & resolution time.

18. Refilling of fire suppression gas shall be cover under contract for Top ups. a. If the gas is released because of manual error by Company the refilling will be done by

Company (total cost), any gas release due to fire/incident the refilling will be done at extra cost on PO confirmation. Cylinder refilling include transportation (if needed) & Company to make system operational within max 10 days working

19. Before handover the system to Operations, OEM visit is must to verify the execution quality of overall system.

20. Training to Operations team preferred from OEM or his representative



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HIGH SENSITIVITY SMOKE DETECTION SYSTEM

1) DESCRIPTION IN GENERAL A high performance aspirating smoke detection system shall be supplied, installed and commissioned by the specialist contractor in accordance with the requirements detailed in the NFPA – 72, Aspirating Detection Systems. The system has been designed to sense incepient smoke at a very early stage in all critical rooms, namely: Server Room. Electrical Room UPS & battery Room Telecom Room The panels shall be mounted inside the risk protected and there shall be a network of air sampling pipe work. The High Sensitivity Smoke detection consist of highly sensitive Laser-based Smoke Detectors with aspirators connected to networks of sampling pipes. The alarms are generated once the laser sensor receives smoke at a pre determined obscuration level to activate and alert, Fire 1, Fire 2 and alert signal. The signal is extended to the Fire Aarm monitor Modules / BMS through Volt free contacts for further investigation. When Required, it shall be possible to connect a interface card for open Protocol output to BMS system for online Monitoring with Software level integration. When required, an optional remote Display unit shall be provided to monitor each detector, and a Programmer shall be supplied to configure the system. SCOPE OF WORK 1.1.0 This specifications covers the requirements of design, supply of materials, installation, testing and commissioning of Aspirating Smoke Detection System. The system shall include all equipment’s, appliances and labour necessary to install the system, complete with high sensitive LASER-based Smoke Detectors with aspirators connected to network of sampling pipes. 1.2.0 The Bidder shall also make provision in the Aspirating Smoke Detectors to trip AHU and to shut fire dampers in the event of fire through the relay contacts. CODES AND STANDARDS The entire installation shall be installed to comply one or more of the following codes andstandards : NFPA Standards, US British Standards, BS 5839 part :1 APPROVALS All the equipments shall be tested, approved, and/or listed by : LPCB (LossPrevention Certification Board), UK



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FM Approved for hazardous locations Class 1,Div 2 UL (Underwriters Laboratories Inc.), US ULC (Underwriters Laboratories Canada), Canada Vds (Verband der Sachversicherer e.V), Germany DESIGN REQUIREMENTS 1.0 The System shall consist of a high sensitive LASER-based smoke detector, aspirator, and filter. 2.0 It shall have a display featuring LEDs and Reset/Isolate button. The system shall be configured by a programmer that is either integral to the system, portable or PC based. 3.0 The system shall allow programming of: Multiple Smoke Threshold Alarm Levels. Time Delays. Faults including airflow, detector, power, filter block and network as well as an indication of the urgency of the fault. Configurable relay outputs for remote indication of alarm and fault Conditions. 4.0 It shall consist of an air sampling pipe network to transport air to the detection system, supported by calculations from a computer-based design modeling tool. 5.0 Optional equipment may include intelligent remote displays and/or a high level interface with the building fire alarm system, or a dedicated System Management graphics package. 6.0 Performance Requirements Shall provide very early smoke detection and provide multiple output levels corresponding to Alert, Action, Fire 1 & 2. These levels shall be programmable and shall be able to set sensitivities ranging from 0.025 – 20% obscuration / meter. Shall report any fault on the unit by using configurable fault output relays or via the graphics Software. Shall monitor for filter contamination. Shall incorporate a flow sensor in each pipe and provide staged airflow faults. MATERIALS AND EQUIPMENT’S 1.0 Both Light Scattering and Particle Counting shall be utilized in the device as follows: The Laser detection Chamber shall be of the mass Light Scattering type and capable of detecting a wide range of smoke particle types of varying size. A particle counting method shall be employed for the purposes of Preventing large particles from affecting the true smoke reading. Monitoring contamination of the filter (dust & dirt etc.) to notify automatically when maintenance is required.



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2.0 The Laser Detection Chamber shall incorporate a separate secondary clean air feed from the filter; providing clean air barriers across critical detector optics to eliminate internal detector contamination. 3.0 The detector shall not use adaptive algorithms to adjust the sensitivity from the set during commissioning. A learning tool shall be provided to ensure the best selection of appropriate alarm thresholds during the commissioning process. DETECTOR ASSEMBLY 1.0 The Detector, Filter, Aspirator and Relay Outputs shall be housed in a mounting box and shall be arranged in such a way that air is drawn continuously from the fire risk area by the Aspirator and a sample passed through the Dual Stage Filter and then to the detector. 2.0 The detector shall be LASER-based and shall have an obscuration sensitivity range of 0.025 – 20% obs/m. 3.0 The detector shall have four programmable smoke alarm thresholds across its sensitivity range with adjustable time delays for each threshold between 0 - 60 seconds. 4.0 The detector shall also incorporate the facility to transmit a fault through a relay. 5.0 The detector shall have a single pipe inlet that must contain an ultrasonic flow sensor. High flow fault (urgent and non-urgent) and low flow fault ( urgent and non-urgent) can be reported. 6.0 The filter must be a two-stage disposable filter cartridge. The first stage shall be capable of filtering particles in excess of 20 microns from the air sample. The second stage shall be ultra-fine, removing more than 99% of contaminant particles of 0.3 microns or larger, to provide a clean air barrier around the detector’s optics to prevent contamination and increase service life. The aspirator shall be a purpose-designed rotary vane air pump. It shall be capable of allowing/ supporting for a single pipe run / multiple sampling pipe runs with a transport time of less than 90 seconds. Detectors shall be capable of supporting a single pipe run of 25m with a maximum transport time of 120 seconds or as appropriate standards dictate. The Assembly must contain relays for fire 1, Action and fault conditions. The relays shall be software programmable (latching or non-latching). The relays must be rated at 2 A at 30V DC. Remote relays shall be offered as an option and either configured to replicate those on the detector or programmed differently. The Assembly shall have built-in event and smoke logging. It shall store smoke levels, alarm conditions, operator actions and faults. The date and time of each event shall be recorded. Each detector (Zone) shall be capable of storing up to 18000 events. As per BOQ consider single zone pipe panel and 4 zone panel for this project. DISPLAYS ON THE DETECTOR ASSEMBLY The detector will be provided with LED indicators. Each Detector shall provide the following features at a minimum. Alert, Alarm, Fire 1 and Fire 2 corresponding to the alarm thresholds of the detector. Smoke Dial display represents the level of smoke present. Fault Indicator.



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Disabled indicator. Buttons supporting the following features shall be accessible to authorized personnel. Reset – Unlatches all latched alarm and faults. Disable – Disables the fire relay outputs from actuating and indicates a fault. SAMPLING PIPE The sampling pipe shall be smooth bore with an outside diameter of 25mm and internal diameter of 21mm should be used. The pipe material should be suitable for the environment in which it is installed, or should be the material as required by the specifying body. All joints in the sampling pipe must be air tight and made by using solvent cement, except at entry to the detector. The pipe shall be identified as Aspirating Smoke Detector Pipe along its entire length at regular intervals not exceeding the manufacturer’s recommendation or that of local codes and standards. All pipes should be supported at not less than 1.5m centres, or that of the local codes or standards. The far end of each trunk or branch pipe shall be fitted an end cap and drilled with a hole appropriately sized to achieve the performance as specified and as calculated by the system design. SAMPLING HOLES Sampling Holes of 2mm, or otherwise appropriately sized holes, shall not be separated by more than the maximum distance allowable for conventional detectors as specified in the local codes & standards. Intervals may vary according to calculations. Each sampling point shall be identified in accordance with Codes or Standards. Consideration shall be given to the manufacturer’s recommendations and standards in relation to the number of Sampling Points and the distance of the Sampling Points from the ceiling and roof structure and forced ventilation systems. INSTALLATION The Contractor shall install the system in accordance with the manufacturer’s recommendation. Where false ceilings are available, the sampling pipe shall be installed above the ceiling, and Capillary Sampling Points shall be installed on the ceiling and connected by means of a capillary tube. The minimum internal diameter of the Capillary tube shall be 5mm, the maximum length of the capillary tube shall be 2m unless the manufacturer in consultation with the engineer have specified otherwise. The Capillary tube shall terminate at a ceiling Sampling Point specifically approved by the Client. The performance characteristics of the sampling points shall be taken into account during the system design. Air Sampling Piping network shall be laid as per the approved pipe layout. Pipe work calculations shall be submitted with the proposed pipe layout design for approval.



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TESTING COMMISSIONING TEST Commissioning of the entire installation shall be done in the presence of the owner and/or its representative. All necessary instrumentation, equipment, materials and labour shall be provided by the Contractor. The Contractor shall record all tests and system calibrations and a copy of these results shall be retained on site in the system Log Book. FUNCTIONAL TEST Introduce Smoke into the Detector Assembly to provide a basic functional test. Introduce smoke to the least favourable Sampling Point in each Sampling Pipe. Transport time is not to exceed 120 Sec’s. DOCUMENTATION The bidder shall be authorized and trained by the manufacturer to design, install, test and maintain the Aspiration Smoke Detection system and shall be able to produce a certificate issued by the manufacturer along with the offer. The bidder shall submit computer generated software calculations for design of aspirating pipe network, on award of the contract. Product data and performance criteria shall be submitted by the bidder. The bidder should provide, as part of handing over, the as-built drawing, operation manual and maintenance manual. The as-built drawing shall exactly match the Sampling pipe layout with the aspire pipe software calculation.



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ACCESS CONTROL SYSTEM

SYSTEM DESCRIPTION The Integrated Access Control System’s (ACS) primary function shall be to regulate access through specific doors, gates or barriers to secured areas of the facility. It shall also have the provision of capturing cardholder images and producing access cards used to provide this access. The system shall use a single seamlessly integrated database for both its access control and badging functionality. This integration shall be provided under one operating environment. The system shall provide a multi-tasking environment that allows the user to run several applications simultaneously. The ACS software shall run on a Windows Vista 32 bit operating system and be licensed by Microsoft under the Windows Vista Logo program. Such licensing shall ensure that the application was specifically designed for the Windows Vista platform and follow Microsoft’s development guidelines for this operating system. The ACS shall be able to run in conjunction with other Windows Vista applications such as MS Word and Excel while concurrently annunciating on-line access and security alarms and monitoring information. The system shall operate on a Windows Vista multi-tasking, multi-threading 32-bit operating system. The System software shall be a true native 32-bit application built `from the ground up' for Windows XP. The System shall NOT be ported over from another operating system (i.e. UNIX, DOS, or OS/2) and shall not be a Win-16, UNIX, QNX or OS/2 program using a Windows NT Server. In addition, the system shall not be a UNIX or QNX Server using a Windows client. All system application modules, features, and functions shall be generated from a single source code set. In addition, the source code must be designed using object-oriented software development techniques and compiled into native 32-bit applications. There shall not be separate source code bases for access control and ID badging. All system features and functionality listed in the proceeding pages shall ship with each system. Features and functionality available to the “Owner” shall be determined through licensing and shall be controlled by a software license key. The “Security Contractor” shall work with the Owner to develop and configure the system. GLOSSARY OF TERMS & ABBREVIATIONS ACS Access Control System, incorporates the entire access control and security network, including the Server, Workstations and Intelligent field or system controllers. ISC (Intelligent System Controller). The hardware components of the system to which the physical components (input devices, entry devices, and output devices) of the access control system connect. The ISC communicates with the ASC Server. MMI Man Machine Interface. Also known as the Graphical User Interface (GUI). NIC Network Interface Card. DRIM Dual Reader Interface Module SRIM Single Reader Interface Module



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GEM Graphics Editing Module (GEM)Compliance & Standards a.The “Tenderer” shall be regularly engaged in the manufacturing, installation and maintenance of ACS systems and shall have a minimum of ten (10) years of demonstrated technical expertise and experience in the manufacture, installation and maintenance of ACS systems similar in size and complexity to this project. The tenderer shall also be a maintained service organisation consisting of at least ten (10) competent service people for a period of not less than ten years and be able provide a list of five projects, similar in size and scope to this project, completed within the last five years. b.The Intelligent System Controllers (ISC's) shall comply with at least two standards from the following compliance regulations:

CE

C-Tick

UL The purpose of these regulations is to maximise the operational useability of the product and to ensure minimum standards within the access control system development have been maintained. These standards will also ensure electromagnetic interference between electronic products are minimized as these may diminish the performance of electrical products or disrupt essential communications. INSTALLATION c.The ACS shall be designed, installed, commissioned and serviced by manufacturer employed, factory trained personnel. d.All materials supplied by the Security Contractor shall be new and shall comply with the latest published specifications and recommendations of the manufacturer in all respects unless otherwise indicated. The Security Contractor shall supply the latest model available for all equipment items. Unless otherwise indicated in the specification, all electronic equipment shall be a standard, unmodified production model. e.Equivalent products may not be substituted for previously approved products unless the Architect has approved a written request from the Security Contractor. All requests for substitute equipment must reflect a complete description of the proposed substitute equipment, including manufacturer's technical descriptions, drawings and technical performance. f.The Security Contractor shall be responsible for providing complete and operational subsystems, including but not limited to all hardware, software, wire, cable, conduit and boxes, power circuit connections, terminal blocks, labour, management, engineering, training, testing, relocation adjusting and connection to NIC work and devices. System Requirements System Architecture i.The system shall be of a Server / Client architecture with the option to configure the Server and client ACS software on different PCs residing on the same computer network. Full network functionality shall be available over remote links between the Server and any workstation, using the following protocols:

NetBEUI, IPX/SPX, TCP/IP ii.Dial-in capability from remote workstation to the Server using a remote access service shall also be available. iii.Encryption between the Server and each Client is configurable and safeguarded using IPSec, to ensure the integrity and security of the data transferred. Server The ACS Server shall be capable of operating on an IBM compatible computer with the following minimum system requirements: Operating System Windows XP SP3 / Windows Server 2003 SP2 / Windows Vista SP2 / Windows 7 SP1

/ Windows Server 2008 SP1 ODBC Microsoft SQL Server 2005 SP4 Standard Edition / Microsoft SQL Server 2005 Express Edition / SQL Server 2008 SP2 / SQL Server 2008 Express Edition Processor 2 GB RAM 2048 MB (SQL Express Edition), 4096 MB (SQL Server Editions) Hard Drive 80 GB ( SQL Express Editions), 160 GB ( SQL Server Editions) Ports At least one network connection (as outlined above) Standard mouse, keyboard, and colour monitor Workstation Workstations shall be capable of operating on an IBM compatible computer with the following minimum system requirements:



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Operating System Windows 7 SP1 / Windows Server 2008 SP1 Processor 4 GB RAM 4 GB Hard Drive 120 GB Minimum Monitor VGA or better Ports At least one network connection port to the Server PC. Standard mouse, keyboard, video card and colour monitor Intelligent System Controllers The system shall be configured with the ACS software connected via an Ethernet link to any configurable number of Intelligent System Controllers. Distributed intelligence The system shall employ a distributed architecture so that all access decisions are made locally at the Intelligent System Controller (ISC). All decisions to grant access shall be made by the local ISC. An Intelligent System Controller (ISC) shall link the ACS software to all other field hardware. It shall provide full distributed processing for access control and alarm monitoring operations. Access levels, hardware configurations and programmed alarm outputs assigned at the administrative workstation shall be downloaded immediately to the ACS software. All access granted/denied decisions shall be made at the ISC to provide fast responses to card reader transactions. The ISC shall be required to operate in a stand-alone and peer-to-peer mode in the event it loses communication with system software. It shall continue to make access granted/denied decisions and maintain a log of events. Events shall be stored in local memory, and then uploaded automatically to the system when communications are restored. Furthermore, an individual ISC shall be able to communicate with another ISC to distribute cardholder locations and to perform scheduled and alarm events. Ethernet Communications The ISC shall communicate with the ACS via any standard WAN / LAN communications link. The ISC shall provide integrated onboard port for direct Ethernet connection. This connection shall not be an RS-485 communications channel that has simply been converted into an Ethernet connection using a “Terminal Server” or similar conversion device. The ISC shall be IP addressable and support standard TCP/IP transmission. Dial-up capabilities The system shall be capable of communicating with remotely located ISCs using dial-up modem connectivity. The system shall provide the capability to download database changes to such a controller incrementally. The ISCs shall also provide the additional functionality of dialling into the ACS Server to communicate alarm events, and other events deemed severe enough for this activity. All other transactions that occur at the remote ISC shall be stored in its internal buffer until that buffer reaches 80% capacity or the server requests the buffer contents, at which point the ISC will upload the entire contents of its transaction buffer. Internal Memory The ISCs will be supplied complete with internal non-volatile memory. This memory will allow all program, access permissions, time schedules and the current date and time data stored in the ISC memory to be retained during periods of power failure. The purpose is to ensure the ISC returns to full operation after the event of absolute power failure. In addition, the ISC memory will not require the connection of a battery to permanently store system information. Expandable Memory The ISCs will support the installation of an expandable memory card. This memory card will be used to increase the overall capacity of the ISC and allow the backup of programmed and transaction data locally for recovery immediately following a power failure. Local Alarm Input and Output The ISC shall support the onboard direct connection of a tamper input. This input connection shall be reserved for connecting a tamper switch of the equipment cabinet in which the ISC has been installed. Upon the Tamper input being triggered the ISC shall also provide a local output that is capable of connecting an output device that can be triggered as a result of cabinet tempering. LED diagnostics



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As a minimum the ISC shall provide at least 6 separate LEDs that can be easily viewed for diagnostic purposes. These LEDs shall indicate the state of power and communications at any given time. Auto Discovery It shall be possible for the ICS to automatically discover all ISCs connected to the same Ethernet network. As a minimum the auto discovery will provide the following: Automatically discover installed ISCs Pre-programme ISCs in the ACS database Allow basic configuration of ISCs Dual Reader Interface Module A Dual Reader Interface Module (DRIM) shall be available for each controlled door and provide the ability to connect up to two card readers or entry devices. This DRIM shall: Monitor the door position (door contact) Allow the connection of a Request-to-Exit (REX) switch for exit Control an electric door lock or strike Provide the facility for up to 3 auxiliary input devices to be connected Allow the connection of an alarm buzzer that can be triggered in the case of an alarm event, or more specifically locally trigger a buzzer for a door held event before this alarm is registered at the host. All events that occur at the door must be reported from the DRIM to the ISC. To allow for situations where an entry and exit reader may be required at the one door a DRIM will allow two readers to be connected. However, in circumstances where a door shall only require one reader the DRIM can be configured to operate in a two door mode, whereby a reader, door lock and door monitoring device can be connected for each door. In addition, the DRIM shall also provide connection for single advanced reader that connects via an RS-485 or Wiegand / Clock/Data connections. Finally, the DRIM shall also provide the ability to work offline in cases where communications with ISC has have been lost and still continue to accept a set of specified cards as being valid to the door(s) which it controls. Eight Reader Interface Module An Eight Reader Interface Module (ERIM) shall be available for each controlled door and provide the ability to connect up to eight separate card readers or entry devices. This ERIM shall: Monitor the door position (door contact) for each door Allow the connection of a Request-to-Exit (REX) switch for each exit Control an electric door lock or strike for each door Provide the facility for up to 16 auxiliary input devices to be connected Allow the connection of an alarm buzzer that can be triggered in the case of an alarm event, or more specifically locally trigger a buzzer for a door held event before this alarm is registered at the host. All events that occur at any door must be reported from the ERIM to the ISC. To allow for situations where an entry and exit readers may be required at a door the ERIM will allow two readers to be used for single door control and provide the possibility to uses the following combinations of door control: Eight single reader doors Six single reader doors and one dual reader door Four single reader doors and two dual reader doors Two single reader doors and three dual reader doors Four dual reader doors The ERIM shall also provide connection for up to eight advanced readers that connect via an RS-485 or Wiegand / clock/data connection. The ERIM shall also provide emergency override that supports wire supervision, to ensure that false fire override conditions are not triggered. Input Control Module A hardware module shall be available to independently monitor up to 32 alarm input devices and report line fault conditions, alarm conditions, power failure and wire supervision. When an alarm input is activated, the condition shall be reported to the ISC and subsequently to the ACS host. The same module shall also provide the ability to connect up to four control devices and support emergency override capabilities. The emergency override shall additionally support wire supervision, to ensure that false fire override conditions are not triggered.



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Elevator control module (Additional module for Future Expansion) A hardware module shall be available to monitor up to 16 independent input devices and reports line fault conditions, alarm conditions, and power failure. When an alarm input is activated, the condition shall be reported to the ISC and subsequently to the ACS workstation. The same module shall also allow the control of up to 16 output devices that can be controlled via the change in state of an input (monitor point) or a command received from the ACS Server. These outputs shall support fire override operation. The emergency override shall additionally support wire supervision, to ensure that false fire override conditions are not triggered. Input / Output control module A hardware module shall be available to monitor up to 8 independent input devices and reports line fault conditions, alarm conditions, power failure, and wire supervision. When an alarm input is activated, the condition shall be reported to the ISC and subsequently to the ACS workstation. The same module shall also allow the control of up to 8 output devices that can be controlled via the change in state of an input (monitor point) or a command received from the ACS Server. These outputs shall support fire override operation. Remote Arming Terminal A hardware module shall be available to provide a facility for system users to turn on and off the alarm system manually. This device shall provide a keypad and LCD screen for the easy navigation of alarm areas and for feedback to the user of the status of any actions they take. The Remote arming terminal shall also be capable of producing an audible sound when the alarm is first turned on or entry to an alarmed area is made to warn the users that an alarm is about to be raised. Diagnostics Each ISC and hardware module shall provide a series of visible Light Emitting Diodes (LEDs) that display the status of the controller or module, and can be used as visual diagnostic indicators. As a minimum, the following diagnostic LEDs should be available:

Communications

Monitor point (input) status

Control point (output) status

Power Housings & equipment tamper switches All access control hardware components shall be housed in a lockable metal cabinet that is fitted with equipment tamper switches and meets the appropriate environmental requirements. The ISC shall allow the connection of equipment tamper switches to detect access to security equipment and shall consist of a spring loaded switch assembly. Any movement of the cabinet door shall cause the switch contacts to transfer. Tamper switches shall incorporate SPDT contacts and be mounted within each cabinet containing security equipment such that the switch cannot be disconnected or disabled from the cabinet exterior. Firmware Download All access control hardware components shall be supported by a built in firmware download and configuration utility from the ACS. This utility shall be included within the MMI and not via an external dedicated tool only. COMMUNICATIONS The system shall use TCP/IP communications techniques over Ethernet, whilst employing proprietary communications protocols. The encryption between the ACS host and each ISC shall use implementation of the Advanced Encryption Standard (AES) to encrypt all messages and ensure data security. ACS communications iv. The connection between the ACS Server and each MMI workstation shall use standard Ethernet communications. v. The communications protocol to transfer messages to or from the ACS Server to any MMI workstation in the system shall be of a proprietary nature to the manufacturer providing the highest level of security. vi. In addition, the communications protocol shall allow an encryption mechanism to be configured, that ensures the transfer of data cannot be interpreted. ACS / ISC communications vii. The connection between the ACS Host and the ISCs shall use standard Ethernet communications. All communications between the ISCs and sub-devices shall be based upon the standard RS485 transmission techniques using a proprietary protocol.



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viii. The communications protocol to transfer messages to or from the ACS Host to any ISC in the system shall be of a proprietary nature to the manufacturer providing the highest level of security. ix. In addition, the communications protocol shall incorporate an error checking routine that checks the integrity of the messages that are transferred on this line. ISC communications x. The connection between an ISC and a series of entry devices using Reader Interface Modules (RIMs), or system extension boards shall use standard RS485 communications techniques. The communications protocol to transfer messages to or from the ISC to any connected device shall be of a proprietary nature to the manufacturer providing the highest level of security possible. xi. In addition, the communications protocol shall incorporate an error checking routine that checks the integrity of the messages that are transferred on this line. xii. Each ISC shall be capable of communicating with at least 96 of these devices at any one time, using four separate channels to co-ordinate the communications process and share the load across different channels. MAN MACHINE INTERFACE (MMI) As a minimum the ACS shall provide the ability to connect up to 140 workstations to the server. Each workstation shall have the capability of displaying an easy to use MMI, from which all system operation, including programming, control and operation can be accomplished. The MMI shall employ a standard Windows look and feel and provide both an intuitive menu and button driven navigation system. On-line help The MMI shall provide a comprehensive on-line help system, which shall be available at anytime and from any screen. The help system shall describe the use of all system functions and provide a comprehensive glossary of terms. In addition, the help system shall provide the standard windows help contents listing, index listing and key word or phrase search functionality. Navigation The MMI shall use standard Windows controls, including:

Mouse control

Menu functionality

Button navigation

Keyboard equivalent mouse shortcuts Toolbar Customization The MMI shall use allow for the customisation of an operator specific toolbar. This shall provide the ability to create a custom toolbar that only includes those buttons (links to parts of the ACS) that are most commonly used or required for the operation of the system. In addition, the operator shall be able to display the look and feel of the toolbar buttons that allow them to perform tasks quickly and efficiently including the text size and placement and size and position of icons displayed. In addition, the MMI shall also provide the ability for custom toolbar buttons to be programmed. This customisation will permit the selection of a personalized icon and the ability to include a command to be performed when the button is clicked by an operator. Windows look and feel xiii. The MMI shall support a user friendly, Windows Graphical User Interface (GUI) that shall be intuitive. All messages and interface text shall be in English prose unless another language has been specified and installed. All functions shall be either keyboard or mouse driven to allow the System Operators to choose the method of navigating through the screens. In the alarm-monitoring module of the system software, all major functions (opening a door, acknowledging alarms, etc.) shall be accomplished using a minimum number of mouse clicks. xiv. The operator workstation interface software shall minimise operator training through the use of language prompting, on-line help, and industry standard PC application software. Languages xv. The system shall support the installation of multiple language versions. xvi. In addition, the manufacturer shall be able to provide the tools to translate the ACS into other languages as may be required. Installation



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xvii. The MMI and ACS shall use standard Windows installation processes and employ a software installation that is similar in look and feel to other Windows Vista applications. The installation licensing shall allow for the selection of software installations that cater for the size and functionality of the facility at which the system is being installed. As a minimum the following package types should be available as default: Basic IntermediateAdvancedSystem Operators The system will only permit authorised operators, who have been given permissions to log on to the ACS at a workstation, to administer aspects of the system. The functionality available to these operators shall be fully configurable via the comprehensive partitioning architecture. Authentication The system shall request an operator’s user name and password before entry to the MMI is granted. The password must be fully encrypted on-screen to prevent it from being easily copied. The MMI will not be displayed until the identification of the operator has been verified and access to the ACS is granted. Authentication may be based on a pre-defined time schedule for certain groups of operators. Authentication Rules It shall be possible for the following configurable logon rules to apply to each account: Password age Password Length Logon retries Complexity Finally, it may be possible for the operator to change their own password or for authentication to be performed using the standard Windows logon identification. Therefore the currently logged in Windows User’s details can be used to verify their permission to log into the ACS. Partitioning Operator specific password access protection shall be provided to allow the user/manager to limit workstation control, display and database manipulation capabilities as deemed appropriate for each user, based upon an assigned password. Operator privileges shall "follow" the operator to any workstation logged onto (an unlimited number of operator accounts shall be supported). The System shall employ an application partitioning design so that applications are broken into separate distinct programs capable of running independently to other System applications. Applications shall include, but not be limited to, alarm monitoring, system administration & configuration, cardholder management, graphics, ID card printing, and cardholder forms designing modules. Each client workstation shall have the ability to be installed with any combination of the above listed modular applications. The system shall allow partitioning to be assigned on the basis of the following conditions (as a minimum):

Cardholders

System Functions (minimum of 60 feature levels)

Holidays

ISCs

Field Devices

Custom Pages

Time Schedules

Site Plans

Reports The system shall prevent the currently logged in operator from viewing the details, regarding any alarms triggered by a system component to which they have not been assigned privileges, including:

Audit trail alarm entries

Audit trail reports, which include alarm details

Audible and visual alarm annunciation The alarm information associated with any system component to which an operator has been assigned privileges will be displayed.



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The system shall allow partitioning to be assigned on the basis of audit trail reports. The currently logged on operator shall only be able to create or run those reports to which they have been assigned privileges. The system shall also prevent the currently logged in operator from printing reports that include those system components to which they have not been provided privileges. Privilege levels When assigning a function to an operator, the system shall allow the level of assignment to be specified. These levels include:

Read only. This type of privilege level does not allow the operator to create or modify components in the specified area of the system. However, they are allowed to view those records.

Modify. This type of privilege level does not allow the operator to create components in the specified area of the system. However, they are allowed to view and make modifications to existing records.

Full. This type of privilege level allows the operator to create, modify and view components in the specified area of the system. Operator profiles The ACS shall support multiple operator profiles such that preferences are retained for individual operators, irrespective of the workstation that they log onto. The display colours and data layout shall be configurable (and be saved) per operator. Operator journal A system operator journal shall be available to log important daily events. The operator is required to select a journal subject from a pre-defined list. The ACS shall allow an administrator to set the names to comprise this list of subjects. The system shall also allow all journal entries relating to a particular subject to be recalled and viewed on-screen, printed or both. Workstation auto-lock All ACS workstations shall automatically lock if left idle for a configurable period of time - requiring the operator to identify him or herself by re-entering their password. The operator shall also have the capability of manually locking a workstation at any time. Any system initiated or manual workstation locks shall be logged in the ACS audit trail. Default Accounts At installation the ISC shall be automatically configured with default operator accounts. These accounts shall be defined in such away that they reflect the standard duties of different operators that can be expected to use the system. CARDHOLDERS The system shall include a cardholder management component that is integrated with the access control system. The system must support at least 500,000 cards – all of which are downloaded and retained in the memory of each ISC. This cardholder management functionality must allow the enrolment of cardholders into the database, capturing of images and import/export of employee data. This functionality shall also allow a system operator to assign or modify the access rights of any cardholder. Cardholder data As a minimum, the ACS shall allow up to 196 configurable fields to be customised by the system administrator to suit the needs of the facility owner. The system shall provide a Graphics Editing Module (GEM) that gives operators the ability to modify any standard field to customise the cardholder screens as desired. Once these fields have been defined, the ACS shall not permit these (database) fields to be changed. In addition it shall be possible to add cardholders to the database without assigning a card to that cardholder. Searching The system shall allow the search of all programmed cardholders, based on the criteria supplied by an operator. Operators shall only be able to search and retrieve cardholder records to which they have assigned privileges. The search criteria shall include any information that can be recorded against the cardholder and as a minimum include:

Card number

Name (first and / or last)



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Work Group

Title

Address

Contact Numbers (phone, mobile, and pager)

Payroll Number

Vehicle Details (registration, colour, model)

Custom Cardholder Data Searching shall not only be limited to entire word matches. An operator may also search for cardholders by entering data that appears in the beginning of a word or string. If more than one cardholder in the system meets the specified criteria, the operator shall be displayed a list of all matching records, from which they can select a particular record. When search results are returned, the operator shall be able to dynamically re-sort the information displayed so that appears in a useful order (for example, by last name). When selecting an individual record to expand, it shall be possible to keep the search dialog active so that other cardholder records can be opened at a later time if required. Cardholder images The ACS shall support the capturing of a high quality image of a cardholder from any workstation. The system operator shall have the option of capturing images in real-time or alternatively by importing an existing image. If capturing images in real-time, the operator shall be able to use an appropriate capture card or use a USB digital video camera. If cardholder images already exist, the operator shall be able to import images of all standard formats including jpg, bmp, gif, and tif The cardholder image shall be able to be recalled at any time from any workstation to verify the identity of any cardholder on the facility. Cardholder Fingerprints The ACS shall support the capturing of high quality finger prints and encoding the finger print into the card during enrolment process that is native of ACS. Also the ACS shall allow operators to capture and store the fingerprint to the ACS database. The fingerprints shall be captured using a biometric reader and an enrolment reader shall be used for fingerprint encoding. Cardholder Signatures The ACS shall support the capturing of cardholder signatures from any workstation. The system operator shall have the option of capturing signatures in real-time or alternatively by importing an existing signature. If capturing signature in real-time, the operator shall be able to use a USB signature capture pad. If cardholder signature already exists, the operator shall be able to import images of all standard formats including jpg, bmp, gif, and tif. Card Trace The ACS shall record the last visited access point (with date and time) for every cardholder. A special trace function shall be available for operators to track activity of specific cardholders. When the trace has been applied, all card activity relating to that cardholder will be highlighted in the audit trail. A report may also be generated that details the locations visited by the traced cardholder. Grouping cardholders The ACS shall allow the grouping of cardholders into specific configurable entities. This shall facilitate voiding of a large number of cards with a single action and also assist with operator partitioning. Cardholder violations The system shall monitor every card presented at each reader in the system and prevent access at the reader (door) if any of the following access violation conditions exist:

The card has not been assigned access permission at the current time.

The card has not been assigned permission at the reader.

The cardholder has been voided in the system.

The cardholder belongs to a group of cardholders that has been voided.

Entry to or exit from an area governed by anti-passback control has been violated.

A card belongs to a group of cards that has been disabled.

A card was presented at a reader that has been disabled or taken out of service.

The card has been presented before its allocated start date, or after the card’s designated end date.



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The card presented does not belong to the site, which includes an invalid card number, an invalid site number or a card containing an invalid facility code. In addition, a message will be logged in the audit trail indicating the card use violation, and if configured, a visual and audible alarm will also be displayed. Cardholder Data Import / Export The system shall provide an external software tool that can be used to import or export cardholder data from another application via text file. This manipulation of data shall be governed by the same login rules applied to a standard operator of the system and shall also be capable of synchronising data over a period of time. The system shall also provide an automatic synchronization tool that allows changes to be automatically bought in the ACS. . Cardholder Record Changes It shall be possible to display all changes made to a cardholder record within a specified date range so that record can be reversed to a previous status from any point in time. Multiple Cards per Cardholder It shall be possible to define up to 5 cards for each cardholder in the system and have an independent void or active status for each card and the overall cardholder. In addition, it shall be possible for each card assigned to the same cardholder to be of a different card technology and for each card to have separate access permissions. Inactive Cardholders It shall be possible to effectively park cardholders by removing a card from their current identity profile. Whilst this data will still remain in the ACS the cardholder will still be considered inactive and not count toward any overall licensing structure or otherwise. Custom Cardholder Information xviii. The ACS shall provide an integrated tool for creating custom cardholder information. This shall provide the ability to add the following information types to a cardholder custom page:

Textbox

Dropdown List Box

Date Calendar

Group Box

Dialog Labels

Custom Button

Attachments Box xix. In addition, design of custom pages shall be simple drag and drop functionality with automatic page guides for aligning already placed components and the ability to individually change the parameters of each component selected. xx. Finally, it shall be possible to import or export custom pages using an xml format. Cardholder Watchlists xxi. The ACS shall provide the ability to import information regarding any cardholder on a watchlist from a government agency or otherwise xxii. When an operator attempts to enrol a cardholder into the ACS that matches the information already contained in a watchlist, the ACS shall generate an alarm that alerts the operator that a match has been recognised and further action may be required. This match shall include general cardholder information or may even include custom cardholder information. ASSIGNMENT OF ACCESS g. The system shall allow an infinite number of combinations of access permissions to be assigned to any cardholder programmed in the system. The system shall allow access permissions to be assigned to access points, areas, elevator floors and groups of any of these. h. In addition, the system shall provide the ability to schedule the times during which cardholder access to each separately allocated resource is permitted. i. Access shall also be extended to output points, whereby a cardholder presenting their access badge not only unlocks a door, but can also easily change the state of any output in the system. j. Upon changing or assigning access to any cardholder, the details shall be immediately propagated to all on-line ISCs. Access privileges shall be assignable on the following basis: Access based upon group privileges



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Access based upon individual privileges Access based upon a temporary privilege Access based upon offline doors Any combination of the above Time Schedules & Holidays k. The ACS shall allow up to 65,000 configurable time schedules to be defined. Each time schedule can consist of up to 20 independent time periods including up to 2 holidays. For ease of configuration, the operator shall be able to select from week days, weekends, or specify a particular day or time. The ACS shall have the intelligence to check whether the time periods are valid and not conflicting with existing credentials. l. A time schedule can be configured to include or exclude holidays. Upon changing a time schedule record, the ACS shall immediately propagate the appropriate changes to all affected ISCs. CARD READERS AND CARDS Card Readers shall read encoded data from the access card and transmit that data back to the ISC. The card reader or entry device should give an audible and visual indication of each read. Supported cards and technologies i. The system shall be compatible with all major card and access entry technologies, including (but not limited to):

Proximity cards and readers

Biometric readers

Bar code cards and readers

Magstripe cards and readers

Wiegand cards and readers

Smart cards and readers

iClass cards and readers (HADP range)

Optical cards and readers

Transmitter and infra-red cards and readers

Keypads and PIN pads ii. In addition, the ACS manufacturer shall be able to provide a number of different encoded card technologies, which use sophisticated algorithms. These algorithms shall be proprietary in nature to the manufacturer, and should be sophisticated enough that they increase the security of the installation. The support for these formats will be in addition to any format perceived to be an industry standard. These shall include at least one proprietary format in each of the following:

Bar code

Magstripe

Wiegand (output protocol)

Smart Card

RS-485

Clock & Data Ability to produce cards with bar codes, magnetic stripes, smart cards The system shall be able to create and print either magstripe, bar code, or smart cards using an integrated printing function. When creating bar code cards the user must have the option to choose the type of barcode that suits their facility. The user should be able to specify the bar code ratios, character length and position on the card. Ability to support multiple cards The ACS system shall support the use of 60 different card technologies. As such, each tenant within an allotted environment may bring their own card technologies with them. Ability to support MIFARE smart cards The ACS system shall support the use of MIFARE smart card technology. As such the system shall provide the ability to encode smart cards including the ability to program the following: Specify a custom format including length, facility, company, card number and parity. Program each sector / block on a MIFARE (1K and 4K byte) smart card for access control and non-access control applications Specify sector keys and the way in which these keys interact with the sector for the reading and writing of information



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Specify the output type and data type of the information stored on the card Program database information for each block / sector The ACS system shall also support the ability to read an entire smart (1Kb and 4Kb) card based upon a pre-configured profile. This card reading shall provide a dedicated viewing screen from which the currents contents of all blocks and sectors can be viewed on-screen. Ability to support DESFire smart cards The ACS system shall support the use of DESFire smart card encoding technology. This option shall support a wide range of smart cards. The ACS shall provide the ability to encode DESFire smart cards including the ability to program the following: Specify a custom format including length, facility, company, card number and parity. Program each Application / File on a DESFire (2K, 4K and 8K) smart card for access control and non-access control applications Encryption Key for the smart card Length of data written on the card, Output format, Access Control, and the Data Type to be encoded on to the smart card. Ability to support Custom Wiegand cards The ACS system shall support the use of proximity card technology with a custom wiegand format including the ability to program the following: Specify a custom format including; Length Facility Code Company Code Card number Revision Parity Provide a graphical means of specifying the format details Enrollment It shall be possible to connect standard card readers to the ISC workstation directly using a free USB port for the purpose of automatically capturing the card details during the cardholder enrollment process. Ability to support iClass cards and readers The ACS system shall support the use of iClass technology natively (e.g.; not just via a wiegand connection) including the ability to perform the following: Support for HADP iCLass readers Support for access control via CSN or iClass ID Ability to display appropriate status messages on those readers with an LCD screen Host Event Processing The ACS shall be capable of processing events in the system as they occur, and distributing this information throughout the entire access control and security network. Immediate propagation iii.Changes made using the ACS software shall be automatically recorded to the ODBC compliant database and downloaded to the correct ISC(s) using the appropriate communications channel. In addition, the ACS software shall also provide the tools to manually download all appropriate database information, allowing the full initialisation of each ISC. All database changes shall be performed while the workstation is on-line without disrupting other system operations. iv.Changes made at the ISC equipment shall be automatically uploaded to the ACS server, to ensure system continuity. Each ISC shall be capable of reporting all changes in status, system events, and actions performed, to the ACS in real-time. These messages shall be displayed immediately in the ACS audit trail. The affect of each message must be reflected throughout the system as they occur, such as, the immediate changing of the colour of a symbol located on a site plan to indicate a change in point status. Local event buffer The ISCs shall maintain a buffer of all events that occur locally. This buffer shall store all messages until they are uploaded to the ACS server. If the communications between the ISC and the ACS server are lost, the buffer will be retained until communications is restored, at which point all logged events shall be uploaded to the ACS server.



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Database accessibility All System data must reside on a single database on the network and must be accessible in real-time to every / any system workstation. This shall allow for automatic change propagation to all workstations on the system as well as a common database to consolidate all information and allow for better disaster recovery. Real time Audit Trail The system shall log all events that occur to both an on-screen audit trail window and a retrievable database record. These events must be logged on-screen as they occur (in real-time). All system changes, alarm events, entry / exit conditions, point state changes, exception messages, miscellaneous system messages, or any information relating to the access control system in general shall be logged to this audit trail. Partitioned display data The system shall be capable of filtering all displayed audit trail messages based upon the currently ‘logged in’ operator’s assigned privileges. Only those events to which the operator has been assigned privileges will appear on-screen or any audit trail report printed whilst that operator is logged on. Operator audit trail profile v.The system shall allow the operator to select which information columns are displayed and which information columns are not displayed on-screen in the audit trail window. The system shall also allow the operator to change the width of any displayed audit trail column by simply using the mouse to drag the column wider. vi.The system shall allow the operator to select the colours in which certain events are displayed in the on-screen audit trail window. The operator shall also be able to select the background colours displayed behind these entries. As a minimum, the system shall allow the following audit trail component colours to be configured:

Alarm message text color

Normal message text color

Alarm message background colour

Normal message background colour In addition, it shall be possible to display each alarm with an individual alarm color, this will allow alarms of a similar to type to be instantly recognised. History View The system shall provide the ability to switch to an audit trail history mode that allows history events to be easily searched. This view shall allow events to be searched based upon any text contained in the audit trail messages that have been recorded. Event short-cuts The system shall facilitate a quick link (short-cut) from any event appearing in the audit trail. As a minimum, there shall be a link to the cardholders and the point location relating to the audit trail event. This will enable easy access to the respective record, allowing the operator to change the details of that record, if necessary. Dual window vii. The ACS shall allow any operator to scroll through past events without losing the ability to monitor new events. This shall be easily achieved via a split-pane audit trail window. Both viewers shall display all events as they occur. The upper viewer shall allow the operator to scroll-back and view previous events that have occurred at the facility, but have scrolled off screen as other events are logged. The lower viewer shall display the latest logged events at all times. viii. The two viewers shall be separated by a movable partition that allows the operator to change the viewable area by simply using the PC mouse. In addition, the system shall allow the operator to select the number of entries that are retained in each on-screen viewer at any time. ix. Any older events that cause the viewer to exceed the configured entry limit, will be removed and must be logged to a permanently stored log-file that can be recovered by creating an audit trail report. x. The currently logged in operator shall also be allowed to determine the order in which events are displayed (i.e.: latest event appearing at the top or the bottom of the audit trail). Real-time audit trail printing



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The ACS shall allow the system administrator to configure the type of events to print to a dedicated printer in real-time. The administrator shall have the option of selecting to print all events or only alarm events. This can be in addition to displaying the events on-screen. Filtering and Search The MMI workstation shall allow the audit trail messages displayed on-screen (in history mode) to be searched using a full text search field. In addition, should be possible to filter the displayed records.. The filter options will include, but will not be limited to: Date and Time Type and Category of event Point Information Group Name Employee ID Change Tracking The Audit Trail shall detail each database change made within the system, including the data that was changed and a record of the operator who made that change. Custom Audit Trails Views The ACS shall provide the ability for an operator to create a custom Audit Trail view that includes the following features: The customised view should update in real time as transactions occur in the system Multiple custom views shall be permitted at any point in time Ability to filter information displayed (for example may only display messages from a select group of doors) An operator shall be permitted to share views (configuration of) with other ACS operators Ability to configure a view with special trace conditions such that any important event in the system is displayed with identifying colors. For example, whenever a specific door is unlocked a message should appear in green Any view shall support the configuration of multiple trace conditions at any time It shall be possible to print the custom view at any system printer Advanced Alarm Management The ACS shall provide an advanced alarm management system. This system shall allow the visual and audible annunciation of alarm events as they occur, in real-time. The annunciation of an alarm shall take priority over all other system functionality to ensure the alarm is registered immediately upon occurring. Alarm annunciation xi.The system shall provide an audible and visual annunciation of all appropriate alarm situations as they occur. Each alarm annunciation shall be configurable, so that it requires positive action to be taken by the System Operator when acknowledging it, and always appears in the foreground of the MMI. Immediately following the visual and audible annunciation of an alarm, a field shall become available where the system operator can enter comments regarding the alarm situation, and shall prevent the alarm from being cleared until an entry in this field has been made. Once entered the System Operator shall be allowed to acknowledge the alarm. In addition, pre-defined alarm responses shall be available. These responses are specific to the facility and can be selected from a drop-down list to ensure quick and efficient acknowledgement of an alarm situation, in lieu of typing a message. xii.After an alarm has been announced, the system shall allow the operator to silence the alarm for a selected period of time. After this time period has elapsed the alarm annunciation will be regenerated. xiii.Upon an alarm being announced, the System Operator shall be provided with the facility to view an alarm queue before taking further action. Alarms with the highest priority shall be placed at the head of the queue. As a minimum the alarm queue will display the following alarm attributes:

Priority of the alarm

Date and Time at which the alarm occurred

Name of the system component that caused or initiated the alarm

Current status of the system component that caused or initiated the alarm xiv. The system shall provide the ability to outline unique emergency instructions to be specified for each type of alarm. These instructions should be displayed on request before the alarm is actioned, in order to help the Operator understand the requirements and necessary routines for clearing the alarm. These alarm



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instructions should be able to contain any combination text or graphics and if appropriate contain a windows video (*.avi) that can be played on request of the system operator. In addition, these instructions should appear in a dialog that allows the system operator to enter a log in relation to the alarm and acknowledge the alarm, whilst simultaneously viewing the instructions. Visual alarm graphics The system shall be configured so that the activation of any alarm provides text and audio instructions outlining the procedures to follow in responding to the alarm, at the Alarm Monitoring Workstation and automatically calls up associated maps upon grabbing the alarm. The alarm-handling portion of the system shall provide dynamic colour alarm graphic maps. These maps shall allow the operator to respond to and clear alarms from the alarms graphics screen. The system shall allow the creation of colour graphic floor plan displays and system schematics for each piece of equipment, including card readers, inputs (monitor points), and outputs (control points) to optimise system performance, analysis and speed alarm recognition. The MMI shall allow users to access the various system schematics and floor plans via a graphical penetration scheme, menu selection or text-based commands. The system shall allow the equipment state to be changed by clicking on the point block or graphic symbol and selecting the new state. In addition symbol colours shall be used to indicate status and change as the status of the equipment changes. Real-time, dynamic graphical maps will mean that the map screen will not have to re-paint or refresh each time a new alarm or event condition occurs. Multimedia alarming The system shall extensively integrate and use multimedia throughout the ACS. The system shall provide owner customisable voice alarm annunciation and a flashing coloured system icon for each alarm in the System. In addition, the System shall provide customisable voice instructions so that each alarm or event in the System can have both sets of text instructions and/or pre-recorded audio voice instructions. Alarm re-activation The ACS shall allow each alarm to be configured with an internal timer that re-activates the alarm annunciation if the change in status that initially caused the alarm to be announced has not been rectified. This timer shall only accompany those alarms where the status of the system component can be restored to a normal state. Alarm Queue The ACS shall place each outstanding alarm in a queue with the highest priority alarm at the top of the queue. The alarm queue shall be able display different alarms with unique colours to allow for easy and quick identification of any outstanding alarm. In addition, each entry in the queue as a minimum, will display the alarm location, its current status, and the date and time at which the alarm first occurred. The alarm queue will also provide the ability to clear alarms when necessary. Alarm configuration xv.The ACS shall allow each alarm to be fully configurable. As a minimum the System Operator shall be able to configure alarms in response to changes in state or messages received from the following system components:

Access Points

Areas or zones

Communications

Elevator floors

Input points

Output points

Intelligent System Controller (ISC)

Interlocked Door Groups

External System Points xvi.As a minimum, each alarm created shall allow the operator to define the following attributes:

Whether or not the alarm is required to be acknowledged when announced

Alarm priority, with up to 1,000 priority alarm levels

The colour of each alarm priority level

Instructions to be associated with the alarm

Sound to be played when the alarm is visually announced



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Alarm re-activation time

State change or event that will trigger the alarm or return the system component to normal

Description of each status

Symbols to represent the alarm and normal status of the component on a graphical map xvii.The system shall also allow alarms to be forwarded to an alternative alarm handling solution. The methods in which alarms can be forwarded include:

To a mobile phone using SMS

To a pager

Via email

From one ACS server to another (in the same security network and communications structure) via OPC

To an OPC (Alarm and Events) compliant system Printers All printers can reside on the same network as the access control and security system. Dedicate printers by function The system shall be capable of configuring dedicated printers for each specific task that requires the use of printed results. As a minimum the system shall allow the following printer types to be specified:

Audit Trail printing

Card printing

Plan printing

Report printing Reports The system shall be capable of configuring a dedicated printer specifically for the task of printing audit trail, database, or operator journal reports. This facility shall provide the selection of a default printer for this task and the ability to change the printer characteristics to suit the printing requirements. Real time printing The system shall be capable of printing all audit trail entries as they occur, using a dedicated printer specifically for this task. This facility shall allow the filtering of audit trail messages that are printed, including alarm messages only or all messages. In addition, the system shall allow the printer type used to be selected, be it 132 column, 80 column, or other printer types. ID card printing The system shall support any card printer with industry standard Windows drivers. It shall support double-sided full colour printing, edge to edge printing with the additional ability to encode magnetic stripes or bar codes on cards. Plan printing xviii. The system shall be capable of configuring a dedicated printer specifically for the task of printing graphical site plans. This facility shall provide the selection of a default printer for this task including the ability to select the following type of printers:

pen plotters

inkjet printers

bubblejet printers

laser printers

electrostatic printers xix. The ability to change the printer characteristics to suit the operator’s requirements shall also be available. ARCHIVING SYSTEM The system shall be capable of archiving the programmed database information, the logged audit trail data, operator journal entries, graphics, alarm sound files, alarm instructions and custom designed reports. Once archived, the system shall provide the tools required to restore this data at a later time if necessary. Archiving medium The system shall provide the ability to select the location of the archived data, be it using a local hard drive, another hard drive located on a machine in the same computer network, a floppy drive or any other mass storage device as deemed acceptable. User-definable archiving parameters



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xx.The archiving facility shall allow the operator to select what information is to be stored. When archiving database information, the operator should be able to independently or collectively select the following information for storage:

All programmed database records

All system graphics, including site plans, symbols, alarm instructions and drawings

System parameters

Operator profiles

Cardholder images

Reports xxi.Upon restoring the archived data, the system operator shall have the same flexibility in choosing which components are to be restored if more than one component was part of the archived file. xxii. When archiving audit trail information, the operator should be able to independently or collectively select specific dates for storage. Upon restoring the archived data, the system operator shall have the same flexibility in choosing the dates for which audit trail entries are to be restored. In addition, the operator shall be able to choose whether to encrypt the backed audit trail data. Automatic Archive The system shall provide the mechanisms to create an automated backup. This will allow a backup schedule to be implemented for the ACS data and will include scheduling for one off date and time, day f the week, or monthly. In addition it shall be possible to specify the type of data to be automatically archived. REPORTING The system shall be capable of providing detailed reports regarding the information contained in the database, audit trail, or operator journals, without the need for programming skills. The system shall provide the capability for the configuration and set-up of a specific system printer for printing reports, and allow the use of network printers. The system shall also exclude those records from any report to which the currently logged in System Operator has not been assigned privileges to view. Available Reports The list of reports shall be available in a tree view sorted by functional area of the system, whereby individual report views can be easily selected and displayed within the MMI. As a minimum the system shall supply at least 50 pre-defined reports in the following functional areas: Alarm Information Hardware Components Time Schedules Groups (hardware / cardholders) Access Definitions Site Plans Cardholders Audit Trail Messages Event Routines External Devices (e.g.: CCTV) Holidays Elevators Operators Mustering Credential Profiles Advanced Security Programming Synchronization The report view MMI shall be displayed within an independent window to the ACS main operation window so that the reporting function never takes away focus from the audit trail view or other important access control information being displayed on screen, In addition, it shall be possible to hide the tree view navigation pane to maximise the area on screen in which to view the data associated with the report selected. Report sort and filtering Once displayed, each report can be filtered and information ordered as required. The main functions that shall be available to customise the current view of a displayed report shall include as a minimum:

Customised column view (order columns, add new columns, remove columns)



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Column order (alphabetical sort order – ascending / descending)

Information Grouping (Group information based upon data in a column, including hierarchical grouping)

Key word filter (filter any information in a column based on a key word including wild card characters etc.)

Automatically size columns for the information displayed Design custom report views The system shall provide the tools necessary for the operator to create custom reports regarding information in either the audit trail or database. This customization shall allow the following selection criteria as a minimum:

Customised report creation wizard

Custom report name

Report type selection (for example: cardholders)

Selection of column information to be displayed (for example: first name, last name)

Filtered criteria (for example: first name = John) with more than 15 different filter types (equal to, greater than, etc)

Ability to add additional filtered criteria including logical operators (and / or / and not / or not)

Addition of the new custom report to the tree view for easy and permanent selection Print to reports printer The system shall provide the functionality to configure and setup individual printers for each different system task that may require printed results. This includes the ability to configure a printer specifically for the purpose of creating printed reports. In addition, the printer configuration shall allow for the setup of local or network printers for these tasks. Print reports automatically The system shall provide the tools to automatically generate reports, based upon a defined schedule without operator intervention. These automatically generated reports shall be saved to disk and can be viewed at any later time while still saved. Print Preview It shall be possible to provide a print preview on screen with the option to change the printer settings so that the view can be customised by the operator before printing. Report Export It shall be possible to export the data contained within a report to the following data formats:

Microsoft Excel (.xls)

XML (.xml)

Tab delimited (.txt)

Comma delimited (.csv) Report Layout Where applicable it shall be possible to dynamically change the report layout on screen by selecting an appropriate current view. For example, when creating a report based upon cardholders it shall be possible to view layouts based upon a list, by card status, alphabetical order, grouping, or with photograph. Once selected the screen will reflect the layout chosen. Interactive Reporting The ACS shall provide a report with an interactive functionality. As a minimum, interactive reports shall permit the following:

Ability to create a complex report based on any information contained within the ACS

Alternatively, it will be possible to import reports from an external source

Each interactive report will provide the facility for a set of conditions to configured for the report information (e.g.: date > mm/dd/yyyy)

Perform functions on any information that meets the criteria selected. These functions shall include voiding a cardholder.

Functions shall be activated manually by right clicking or automatically upon report analysis by the ACS. Unused Cards The ACS shall provide a mechanism to remove unused cards from an active state in the system. The length of time which defines an unused card shall be configurable. xxiii. The ACS shall allow a report to be generated that lists all cards that at the time the report was generated the cards listed were considered unused.



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It shall be possible to directly from right clicking on entries in the report to void any or all unused cards as seen applicable by the operator who produced the report. xxiv. The ACS shall also provide the ability for unused cards to be automatically voided in the system at a regular interval (for example, on a weekly basis), without the need for operator intervention. Scheduling The system must provide the capability for an operator to define specific times, during which certain events and system control will occur. The system must be capable of handling at least 65,000 distinct time schedules. These schedules must be operator customisable, so that, they can schedule events across an entire week, with up to twenty distinct time periods during that week. Primarily, the time schedules must be able to handle holidays, provide access at certain times, and schedule or permit events during the specified times. Holidays The system must be capable of defining over 100 holiday dates in advance of them occurring. A defined holiday will override the normal timed schedules where configured and allow other system functions to behave as normal. Public floor access The system must be capable of scheduling specific times when access to floors in an elevator system are taken ‘off’ security and are accessible to the general public. At all other times the system shall secure those floors and provide access only to valid cardholders. Access per door The system must be capable of scheduling specific times when a cardholder is permitted to access a specified door, barrier or gate. At all other times the cardholder will be prevented from gaining access at that door. By specific date & time The system shall be capable of scheduling certain programmable events to occur on specific dates or during specific times of the day. By certain event The system shall be capable of scheduling certain programmable events to occur in response to the activation of another event or system status change. The event or status changes that trigger this response shall be configurable. ANTI-PASSBACK The system shall be capable of providing anti-passback control, whereby, a cardholder that uses their card at an entry reader must not be able to re-enter until they have first exited using the specified exit reader. The system must also be capable of operating in either a soft or hard anti-passback mode The anti-passback control should also be flexible so that cardholder’s that have violated anti-passback rules or have lost their access card can be forgiven by a system operator. Soft Anti-passback The system shall provide the selection of a soft anti-passback mode, which permits entry at a door or barrier (to a valid cardholder) when the anti-passback rules have breached. However, the system will still generate an alarm in response to this anti-passback violation. Hard Anti-passback The system shall provide the selection of a hard anti-passback mode, which does not permit entry at a door or barrier (to a valid cardholder) when anti-passback rules have been breached. In addition this type of breach will also generate an alarm. Peer-to-Peer Anti-passback The system shall provide full anti-passback capabilities across multiple ISCs without the need to consult the ACS host. This will allow full anti-passback capability even when communications with the host has been lost. In addition, peer-to-peer anti-passback operation shall provide a fail-safe mode, whereby entry or exit to a secure area will be permitted when communications between controllers has been lost. Mustering Area



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The system shall provide the facility via the anti-passback functionality to designate specific mustering areas. These areas shall allow reports to be generated that display all those cardholders currently logged into that area. Area Limits The system shall allow each area to be defined with a maximum cardholder count. Once this limit has been reached the area will be considered as being “Full”. Once the full capacity has been reached, the system shall allow:

The prevention of further cardholders from entering the area

The triggering of an output device, for example a “Max entry ” sign Cascading Anti-passback The system shall allow single reader doors to be created within an area. These doors will not fall under normal anti-passback control, however, entry will not permitted unless the anti-passback conditions assigned to the surrounding area have been previously observed. Four Eyes Access The system shall allow an area to be nominated as a “Four Eyes” location. An alarm in a four eyes location shall be raised when a single cardholder has entered that location and resided within the location for a specified amount of time with out a second or subsequent cardholder entering. A four eyes area will also allow an alarm to be raised when no cardholders reside within the location. Timed Re-entry The system shall allow an entry point(s) to be nominated as a timed re-entry point. Once a cardholder has used their card at a timed re-entry access point, that cardholder will not be permitted to re-use their card again to gain access to that location within a specified time period. Door Interlocking The system shall allow the configuration of a set of interlocked doors, such that opening any single door within the defined set prevents any other door from being opened at the same time, even if a valid cardholder attempts to gain entry at that door. In addition, it shall be possible define a time period once the first door has been closed, before another door in the set can be opened. Dual Custody The system shall allow the configuration of a door such that it can only be opened if two valid cardholders present their access badge at the door within a defined time period. This mode shall also allow for supervisory access (e.g.: visitor escort) and an override function based upon cardholder so that cardholders of an authorised level do not require a subsequent cardholder before entry is permitted. Clustering Finally, the system shall allow the configuration of a set of controllers in a single group for the purpose of antipassback configuration. Whilst both local anti-passback and global anti-passback operation shall be available, this subset allows a group of controllers to monitor anti-passback within their own cluster. This type of clustering shall also allow cardholders to maintain a current count in separate anti-passback locations. For example, when a cardholder leaves their car in the carpark the increased count because of that card remains raised, even if the cardholder enters another anti-passback area that is managed across multiple controllers. xxv.The system shall allow cardholders to indicate whether they are requesting access under a forced or duress situation and thus communicate a potential emergency to the ACS. When such a duress action has been



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registered, the cardholder will be permitted access and a duress alarm will be announced on the system, without arousing suspicion. xxvi. In addition, the system shall allow the configuration of a duress button, which, when triggered shall raise a visual and audible alarm at each ACS workstation. SECURITY PROGRAMMING The ISC or the system controller shall have a Programmable logic engine allowing security programming and control. The security control shall be presented to the operator through a user-friendly graphical designer. The programmable security control shall operate like a programming logic engine running in a controller. This feature shall give the ACS operators an ability to construct logical activities using the graphical designer. The logical activities shall then be executed by the controller The programmable security control shall allow the operator to visually design activity programs in the system and download them to the controller. The operators shall be able to customize activities for multiple triggers, and resulting effects via the graphical designers. As a minimum, the ACS’s security programming shall make the following features available: Enabling users to create and design customized, site-specific activity programs for their site, without having to contact vendors for related firmware modifications A Single ISC or controller shall execute multiple programmable activities simultaneously. A single programmed activity shall be executed from multiple ISC’s. The programmable activities shall be controlled and executed by Time Schedules A variety of entities like Access, Input and Output point, Access Events, Intrusion Areas, Anti-Passback areas, Workgroups, and Floors shall be supported. Virtual Components like flags, timers, counters shall be incorporated as triggers and effects. Time and Attendance Recording The system shall be capable of recording the entry and exit of cardholders at designated card readers or groups of card readers. m.Once recorded the system shall allow for the export of the time and attendance information to a third party T&A or HR application. This export shall be available in a “.CSV” or “tab delimited” format to a pre-defined file location and file name. n.In addition, the exact information contained within the export file shall be selectable and extend to at least the following required information:

First Name

Last Name

Date of record

Time of record

Location that the record was logged o.The system shall provide the ability for a report to be generated that counts the hours a cardholder is estimated to have been on-site. i.The hour counting function shall allow a count of hours from a specified date at specified readers within the ACS ii.The hour counting function shall allow a count of hours from within a given time frame (for example, within the last week) iii.It shall be possible to automate such a report and send this via email to a specified recipient. iv.It shall be possible to export the report so that the information contained can be used in another third party system. Graphical Maps v.The system shall allow the design, import, and construction of site plans, which can be used to visually handle alarms, control access, and generally monitor the facility. Each site plan shall be updated dynamically as the status of system components change. The symbol representing each component will automatically update in colour, alerting the operator of its change in status.



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vi.The system shall provide a pre-defined library of symbols that represent the most common access control and security components. In addition, the system shall allow the operator to create their own library of symbols that represent the devices installed at the facility. vii.The system shall provide a built-in suite of graphics tools that can be used to create or modify a site plan. As a minimum, these tools shall include:

Import of existing site plans, including AutoCAD, bmp, jpg, wmf, tif, and most other raster type images.

Common Windows text tools, such as alignment, font, and style.

Colour tools to change the fill and border colour of components in a plan.

Drawing tools, so that lines, boxes, circles, arcs, and free-hand lines can be drawn.

Alignment tools, to align separate components in a site plan.

Shortcuts that add a button to a site plan that, when clicked automatically open a new site plan or trigger a system action, such as opening a door.

Grid or crosshairs that aid in the alignment and scale when creating a site plan. viii.Each site plan shall have the ability to unlock a door to allow entry, control points at the click of a button, retrieve point information at the click of a button, and create shortcut buttons to other plans in the system or frequently used system commands. ix.In addition, the ACS shall allow partitioning for each graphical map. This partitioning shall allow only those System Operators that have been assigned the appropriate privileges to the graphical map, to view it and control points located on that map.



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IP CCTV SYSTEM

GENERAL: The work under this system shall consist of design, supply, installation, testing, training & handing over of all materials, equipment’s and appliances and labor necessary to commission the said system. The True IP Based CCTV System shall comprise of fixed dome indoor cameras, PTZ cameras power supply units, monitoring stations, Network video recorders, Hard disk storage devices, Software and other associated accessories. It shall also include cabling, necessary for installation of the system as indicated in the specification and Bill of Quantities. Any openings/chasing in the wall/ceiling required for the installation shall be made good in appropriate manner. SYSTEM DESIGN AND ARCHITECTURE: CCTV system should be designed such as to cover the strategic locations and sensitive areas of High end cameras with Night sense feature to be installed for this outdoor application. All outdoor speed domes and Fixed camerasshall be rugged and shall be weather proof as per specifications. Also the systems should utilize only industry standard protocol. General positioning of the cameras are in the Entrance of Buildings,all entry doors ,security area, receptions, all the lift lobbies, corridors, all exits, lobbies, electrical rooms, server rooms& Racks Rows, and external areas, DG area, Transformer area, Chiller area & Out perimeter can be monitored. Interactive cameras can be used in certain areas, pan, tilt and zoom cameras are provided in critical areas that need to be observed in the event of some disturbance. A digital IP-Surveillance system, images from a network camera are digitized once and they stay digital with no unnecessary conversions and no image degradation due to distance traveled over a network. In addition, digital images can be more easily stored and retrieved than in cases where analog video tapes are used. By using a data connection and computer networking, IP cameras can provide much better performance with no real limitations for future growth in resolution or other capabilities. System should be programmed such that operator’s intervention if required shall be minimal and the system should provide features like guard tours, preset positions and the preset positions will be linked to perimeter protection system/intrusion system in future. The NVRs should allow for recording of events both continuous and motion triggered as per requirement and recordings should be able to create evidences and support post event analysis.



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SPECIFICATIONS OF CAMERAS 2MP RESOLUTION INDOOR DOME CAMERA: 2.01 GENERAL A. All equipment and materials used shall be standard components that are regularly manufactured and used in the manufacturer’s system. B. All systems and components shall have been thoroughly tested and proven in actual use. Camera Feature:-

Image Sensor 1/2.8" Progressive CMOS

Maximum Resolution 1920 x 1080 (2MP)

Lens Type Fixed-focal

Focal Length f = 2.8 mm

Aperture F1.8

Field of View

113° (Horizontal)

63° (Vertical)

136° (Diagonal)

Shutter Time 1/5 sec. to 1/32,000 sec.

WDR Technology WDR Enhanced

Day/Night Yes

Minimum Illumination

0.05 Lux @ F1.8 (Color)

< 0.001 Lux @ F1.8 (B/W), 0 Lux with IR illumination on

Pan Range 45°

Tilt Range 33° ~ 90°

Pan/Tilt/Zoom Functionalities

ePTZ:

48x digital zoom

(4x on IE plug-in, 12x built-in)

IR Illuminators Built-in 940nm IR illuminators, effective up to 6 meters with Smart IR

On-board Storage

Slot type: MicroSD/SDHC/SDXC card slot

Seamless Recording

Video Compression H.264 & MJPEG

Maximum Frame Rate

30 fps @ 1920x1080

In both compression modes

Maximum Streams 4 simultaneous streams

S/N Ratio 47 dB

Dynamic Range 70 dB

Video Streaming

Adjustable resolution, quality and constant bitrate control

Smart Stream II



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Image Settings

Time stamp, text overlay, flip & mirror; Configurable brightness, contrast, saturation, sharpness, white balance, exposure control, gain, backlight compensation, privacy masks; Scheduled profile settings, 3D noise reduction, video rotation, defog

Audio Audio Capability One-way audio

Compression G.711, G.726

Interface Built-in microphone

Effective Range 5 meters

Network Users Live viewing for up to 10 clients

Protocols

IPv4, IPv6, TCP/IP, HTTP, HTTPS, UPnP, RTSP/RTP/RTCP, IGMP, SMTP, FTP, DHCP, NTP, DNS, DDNS, PPPoE, CoS, QoS, SNMP, 802.1X, UDP, ICMP, ARP, SSL, TLS

Interface

10 Base-T/100 Base-TX Ethernet (RJ-45)

*It is highly recommended to use standard CAT5e & CAT6 cables which are compliant with the 3P/ETL standard.

ONVIF Supported, specification available at www.onvif.org

Intelligent Video Video Motion Detection Five-window video motion detection

VCA

Line crossing detection, field detection, loitering detection

*Available per project request.

Alarm and Event

Alarm Triggers

Motion detection, manual trigger, periodical trigger, system boot, recording notification, camera tampering detection, audio detection

Alarm Events

Event notification using HTTP, SMTP, FTP, NAS server and SD Card

File upload via HTTP, SMTP, FTP, NAS server and SD card

General

Connectors RJ-45 cable connector for 10/100Mpbs Network/PoE connection

LED Indicator System power and status indicator

Power Input IEEE 802.3af PoE Class 2

http://www.onvif.org/



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Power Consumption Max. 4.75 W

Dimensions Ø 90 x 50 mm

Weight 145.8 g

Safety Certifications CE, LVD, FCC Class B, VCCI, C-Tick, UL

Operating Temperature

Starting Temperature: 0°C ~ 50°C (32°F ~ 122°F )

Working Temperature: -10°C ~ 50°C (14°F ~ 122°F )

Humidity 90%

System Requirements Operating System Microsoft Windows 7/Vista/XP/2000

Web Browser

Mozilla Firefox 7~43 (Streaming only)

Internet Explorer 7/8/9/10/11

Other Players

VLC: 1.1.11 or above

Quicktime: 7 or above Included Accessories

Others Quick installation guide, warranty card, screws pack, focus kit

2.02 2 MP verifocal Indoor Camera

Image Sensor 1/2.7" Progressive CMOS

Maximum Resolution 1920x1080 (2MP)

Lens Type Vari-focal

Focal Length f = 2.8 ~ 12 mm

Aperture F1.8 ~ F2.85

Auto-iris P-iris

Field of View

34° ~ 107° (Horizontal)

19° ~ 56° (Vertical)

39° ~ 133° (Diagonal)

Shutter Time 1/5 sec. to 1/32,000 sec.

WDR Technology WDR

Day/Night Removable IR-cut filter for day & night function

Minimum Illumination

0.1 Lux @ F1.8 (Color)

0.01 Lux @ F1.8 (B/W)

Pan/tilt/zoom Functionalities

ePTZ:

48x digital zoom (4x on IE plug-in, 12x built in)

IR Illuminators

Built-in IR illuminators, effective up to 30 meters with Smart IR

IR LED*8

On-board Storage

Slot type: MicroSD/SDHC/SDXC card slot

Seamless Recording

Video

Compression H.264 & MJPEG



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Maximum Frame Rate

30 fps @ 1920x1080

In both compression modes

Maximum Streams 4 simultaneous streams

S/N Ratio 66dB

Dynamic Range 100dB

Video Streaming Adjustable resolution, quality and bitrate, Smart Stream

Image Settings

Adjustable image size, quality and bit rate; Time stamp, text overlay, flip & mirror; Configurable brightness, contrast, saturation, sharpness, white balance, exposure control, gain, backlight compensation, privacy masks; Scheduled profile settings, 3D noise reduction, video rotation, defog

Audio

Audio Capability Two-way Audio (full duplex)

Compression G.711, G.726

Interface

Built-in Microphone

External line input

External line output

Network

Users Live viewing for up to 10 clients

Protocols

IPv4, IPv6, TCP/IP, HTTP, HTTPS, UPnP, RTSP/RTP/RTCP, IGMP, SMTP, FTP, DHCP, NTP, DNS, DDNS, PPPoE, CoS, QoS, SNMP, 802.1X, UDP, ICMP, ARP, SSL, TLS

Interface

10 Base-T/100 BaseTX Ethernet (RJ-45)

*It is highly recommended to use standard CAT5e & CAT6 cables which are compliant with the 3P/ETL standard.

ONVIF Supported, specification available at www.onvif.org

Intelligent Video

Video Motion Detection Five-window video motion detection

VCA

Line crossing detection, field detection, loitering detection

*Available per project request.

Alarm and Event

Alarm Triggers

Motion detection, manual trigger, digital input, periodical trigger, system boot, recording notification, camera tampering detection, audio detection

Alarm Events

Event notification using digital output, HTTP, SMTP, FTP, NAS server and SD Card

File upload via HTTP, SMTP, FTP, NAS server and SD card



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General

Smart Focus System Remote Focus

Connectors

RJ-45 cable connector for Network/PoE connection

Audio input

Audio output

DC 12V power input

Digital input*1

Digital output*1

LED Indicator System power and status indicator

Power Input

DC 12V

IEEE 802.3af/at PoE Class 0

Power Consumption Max. 13 W

Dimensions Ø 138 x 103 mm

Weight 541 g

Safety Certifications CE, LVD, FCC Class B, VCCI, C-Tick, UL

Operating Temperature

Starting Temperature: 0°C ~ 50°C (32°F~ 122°F)

Working Temperature: -10°C ~ 50°C (14°F~ 122°F) 2.07 NETWORK PROTOCOL A. Ethernet RJ-45 (10/100Base-T) B. Video Compression Format H.264(MPEG-4 part 10/AVC), MJPEG C. Resolution 1280x1024 /1280x720 / 1024x768 / 800x600 / 640x480 320x240 D. Max. Framerate 1. H264 Max 60fps at all resolutions 2. Motion JPEG 1280x1024/ 1280x720 / 1024x768 : Max. 15 fps 800x600 / 640x480 / 320x240 : Max. 30fps E. Video Quality Adjustment 1. H.264 Compression level, Target bit rate level control 2. MJPEG Quality level control F. Bitrate Control Method 1, H.264 CBR or VBR 2. MJPEG VBR G. Streaming Capability Multiple Streaming (Up to 10 Profiles) H. Audio I/O Mic(Line) in / Line out (1Vrms), Built-in Mic. I. Audio Compression Format G.711 u-law /G.726 Selectable G.726 (ADPCM) 8KHz, G.711 8KHz G.726 : 16Kbps, 24Kbps, 32Kbps, 40Kbps J. Audio Communication Bi-directional audio K. IP IPv4, IPv6 L. Protocol TCP/IP, UDP/IP, RTP(UDP), RTP(TCP), RTCP,RTSP, NTP, HTTP, HTTPS, SSL, DHCP, PPPoE, FTP, SMTP, ICMP, IGMP, SNMPv1/v2c/v3(MIB-2), ARP, DNS, DDNS, QoS, PIM-SM, UPnP, Bonjour M. Security HTTPS(SSL) Login Authentication Digest Login Authentication IP Address Filtering



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User access Log802.1x Authentication N. Streaming Method Unicast, Multicast O. Max. User Access 15 users at Unicast mode P. Memory Slot SD/SDHC/SDXC

- motion Images recorded in the SDX/SDHC/SD memory card can be downloaded.

Q. ONVIF Conformance : Yes, Profile S R. Webpage Language : English, French, German, Spanish, Italian, Chinese, Korean,Russian,

Japanese, Swedish, Denish,Portuguese, Turkish, Polish, Czech, Rumanian, Serbian, Dutch, Croatia, Hungary, Greek, Norwegian

S. Web Viewer 1. Supported OS Windows XP / VISTA / 7 / 8, MAC OS X 10.7 2. Supported Browser Microsoft Internet Explorer (Ver. 7~10),

Mozilla Firefox (Ver. 9~19), Google Chrome (Ver. 15~25), Apple Safari (Ver. 6.0.2(Mac OS X 10.8, 10.7 Only),* Mac OS X Only.

3. Central Management Software SmartViewer 4.0 2.08 ELECTRICAL A. Voltage DC12V, PoE(IEEE802.3af,Class3) B. Consumption Max. 9.0W (DC 12V) Max. 11.0W(PoE, Class3) 2.09 ENVIRONMENTAL SPECIFICATIONS A. Operating Temperature - 10°C ~ +55°C (14°F ~ 131°F) B. Operating Humidity Less than 90% RH 2.10 PHYSCIAL SPECIFICATIONS A. Dimension D132.1 ,H107.6 B. Weight 525g C. Color IVORY(Polycarbonate) 2.11 CERTIFICATIONS A. CE mark B. FCC mark NETWORK VIDEO RECORDER NVR is a full-featured high-performance H.265 NVR. Equipped with a 2U 64-CH 8 Bay Rackmount network appliance, standard RAID capability and H.265 video codec, the total storage capacity of the NVR also endows with scalability and flexibility. NVR equipped with 8 hard-drive bay design provides for a storage capacity of up to 48TBs, offering greater than 30% ~ 50% more recording capacity than systems employing H.264 compression. This advance affords users larger storage space for longer durations of video recording. The RAID 0/1/5/6/10 configuration provides further data security in the rare event of a hard drive failure. Further, equipping with a DOM system has resulted inreliability and stability. Feature of fisheye network camera “FisheyeDewarp” function, which provides multiple de-warping modes in live view and playback, ensuring the correct angle of video view anddetailed information for flexible usage. This ingenious NVR is also equipped to carry out remote management with a full range of theserver/client structures and thus constitutes a robust system for diverse applications.Moreover, NVR features well-built ONVIF compliance andscalable configuration, with Central Monitoring Software empowering users to setup and manage advanced IP surveillance systems with ease. NVR also supports both remote and mobile access via iViewerapp, for both iOS and Android handheld devices.



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Key Features H.265/H.264 Compression Technology 64-CH Recording, 64 Display Support HDMI, Display Port, VGA and DVI SimultaneousOutput 8 Hot-Swappable HDD Bays Support RAID 0/1/5/6/10 Storage Max Support up to 48TB HDD Redundant Power USB Interface - USB 2.0 x4 & USB 3.0 x2 Inside (LiveClient/Playback) Dual Lan Giga Network Ports Graphics Decoder Software decoding Decoding Capacity H.265/H.264: 1920x1080 @ 270 fps (4Mbps) ONVIF Open Platform IP Camera Configuration and CMS Integrated Multiple Fisheye Dewarp Support Multiple Video Search Modes Safety Certifications CE, LVD, FCC, VCCI, C-Tick, UL

CABLES: Power cable: The Power Cable shall be Multicore 2 core 1.5 sq mm PVC insulated and Shielded cables. Unshielded Twisted pair cable: The unshielded twisted pair cable shall be CAT5E/CAT6 for connection for Camera to Switch/NVR, Server and LAN Technical Specification of Twisted pair cable: Unshielded Twisted Pair, Category 5E/6 Type cable. 24-26 AWG stranded copper conductor. 1 meter and 2 meter Length Matching colored snag-less, boot to maintain bend radius Plug - Clear polycarbonate Housing, Phosphor Bronze with gold plating, 50 micron'' gold over nickel Terminals. PBT polyester Load bar. PVC Jacket. Flame Retardant Polyethylene Insulation. Factory standard connector End point connector. Approval like UL, ETL and 3P certificates.



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ADDRESSABLE WATERLEAK DETECTION SYSTEM Overview This section of the specification covers the design, supply, installation, testing, commissioning and thereafter maintaining of the Liquid Leak Detection System (LLDS) during the twelve (12) months defect liability period. Installation of a liquid leak detection system (LLDS) is recommended for continuous protection from the risk of water leaking within critical areas of the building. This complete LLDS shall include electronic leakage detection panel, addressable zonal modules, conductive sensing cable, monitoring leakage at any point along the run and all required auxiliary accessories(such as jumper cables, connectors, hold down clips and tag/labels).This system shall detect and locate multiple leaks simultaneously as well as cable break faults for different zones. The LLDS shall be installed at the various rooms as per specified in the tender drawing This specification shall be the guideline for Supply, installation, testing and commissioning of Water Leak Detection System installed in the designated Sub-floor / Floor Areas as per the following: 1. Installation Data Center 2. UPS & battery Room 3. Electrical Room The layout of the liquid leak detection equipment and circuits as shown on the Drawings is given for guidance to the Contractor for preparing his estimation during tendering and indication of the design intent only. The Contractor shall be responsible to determine the most effective arrangement of the detection system and circuits basing on the manufacturer’s recommendations, quantity of liquid leak detection panels required, the additional of the accessories, individual features and operating coverage characteristics of the selected products. CODES AND STANDARDS: Original Equipment Manufacturer Standard System performance General The liquid leak detection system (LLDS) shall identify any abnormal presence of liquid on any point of its connected sensing cables, to the nearest meter. In the event of leak detected, an audible alarm is triggered and dry contact is activated. The panel’s touch screen display shows the time and date of the alarm, the type of fault and the location of the leak to the nearest metre. Dynamic zone maps highlighting faults on the panel’s screen are available as an optional feature.



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Figure 2.1.1: Example of the Leak alarm message on the panel screen with date/time and Zone name

Figure 2.1.2 Example of the zone map highlighting the leak location precisely with a RED DOT detected at 20m

Sensing cable length The monitoring Touch screen panel shall have the ability to supervise and control up to 10 Zonal Modules and capable of monitoring up to an accumulated length of 2,000m (6,560 feet) of sensing cable and accumulated length of 1,000m (3,280 feet) for communication cable. These cables lengths shall not include the jumper cable connecting between sensing cables which can be accumulated up to 300m (984 feet). The panel shall be able to show the total sensing cable length connected for each zone and the status of each zone under monitoring.



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Figure 2.2.1 Example of the front screen showing all the Zones names (max. 10 zones) connected to the panels with the total sensing cable Length and Status of each zone under monitoring.

Multiple faults Every sense cable of each zone shall be able to detect and locate leaks and cable-break independently and capable of displaying simultaneously.



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Figure 2.3.1 Example of front screen showing multiple faults with different colour codes for leaks(red) and cable break(yellow) displayed simultaneously.

Cable break fault Besides leak, the system shall be capable to detect any damaged sensing cables (cable break). In the event of a cable break, an audible alarm is triggered and the dry contact is activated. The dynamic zone maps showing a cable break logo on the panel’s screen is available as an optional feature.



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Figure 2.4.1 Example of the alarm message and cable break logo on the panel screen in case of cable break..

Figure 2.4.2 Example of the Event Log message with Timestamp, Event and Zone information . It can store up to 5,000 events and can be downloaded to thunbdrive. Products Touch screen display Supervising Panel The entire system shall has the ability to be supervised by a Touch screen panel with at least 12 Inch display. This touch panel is able to pin-point leak location (i.e. highlight as a single point of leak location) exactly with the precision of +/-1m and display the zone map/floor plan accordingly. LCD display Supervising Panel Such Panel shall have a LCD display (4 lines X 20 characters) with backlight and a 90dB max. buzzer with silencing button. It shall also have LEDs indicating “POWER” (green), “LEAK” (red) and “TROUBLE” (red). (ie: “TROUBLE” means either cable break or power failure). The System shall sound an audible alarm upon detecting a “LEAK” and/or “TROUBLE”. If there is a cable break at any point along the sensing cable, the sensing cable length still in connection to the control units shall continue to function and detect leak (if any). This Fail-Safe Loop Back feature (Class A wiring) shall be incorporated as necessity to enhance the system capability. Once the alarm condition has been cleared, the System shall be capable to reset itself automatically. Zone type leak sensing cable A continuous leak detection cable shall be installed to cover small areas or zone within the building. The cable should be multi-wired design and manufactured from rugged, corrosion resistant material which resist abrasion to ensure long cable life. The Cable shall be capable of water detection over it’s entire length and shall provide the following: a. Water detection cable shall consist of 4 conductors, 2 water sensitive and 2 for data b. The cable shall be restorable and corrosion resistant and shall not require replacement after being wet c. Maximum length of linear WLD cable not to exceed 200m per Sensor interface module d. Minimum spacing from exterior walls shall be 1 foot e. Sensing cable shall be installed in the path of a potential water Leak After leakage, the cable should shed liquids quickly and easily return to normal operating condition. The cable shall be capable of detecting liquids such as water & slightly corrosive & conductive liquids. The cable shall be available in different custom length with factory installed male/female connectors to facilitate the setting up of leak detection circuit without the need for special tools as well as for future expansion of the system and replacement.



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Zonal Modules Each Module shall be able to handle up to 200m of accumulated sensing cable and shall actuate an output relay during a fault that can be connected to any voltage free enabled system. The Modules used at each site/zone shall be capable of adjusting the leak sensitivity level at site. For a liquid puddle size of about 20mm to 200mm shall be adjustable. Centralized and Distributed Monitoring System- Optional The System shall be capable of configuring into a Centralized and/or Distributed Monitoring system. 3.5.1 Centralized Monitoring System means: the System Monitoring panel together with the Modules are housed in a custom enclosure panel at one location. This configuration shall provide ease of monitoring and installation of the battery back-up units and power supply source. Distributed Monitoring System means: the System Monitoring Panel is housed separately with the Modules. The Modules are mounted on each individual zone area (localized) as defined by client. This configuration shall provide a more reliable management of the system remotely and its independence power supply source. Security The System Monitoring Panel shall provide security to the user or administrator via password access. Power The System shall be powered by 230 +/- 15% VAC, 50/60 Hz single phase. It shall be provided with the option to be powered by 12 to 24Vdc or Vac source. Interface The LCD Supervising Panel output shall have two separate dry contacts which is for liquid leakage and for cable break. The dry contact relays output shall have a voltage free contact (N.O./N.C.) for external interfacing. In addition, the Panel shall be provided as an option for 4-20mA analogue signal or high level RS-485 (MODBUS) or TCP/IP (MODBUS) serial communication interface with the Building Management System (BMS) Failed-Safe Loop Back The entire system shall be able to connect as a Failed Safe Loop Back configuration. Thus, during any cable break point (especially at start point of sensor), the system is still able to perform and activate an alarm for liquid leakage. Jumper cable connection and auxiliary equipment 3.10.1 Where leak detection is required, a four-core jumper cable shall be used to connect sensing cables in between zones, floors or rooms. Warning labels shall be placed on the sensing cable approximately every Three (3) meters. Hold-down clips shall be used to fix the sensing cables every one (1) meter or where deem necessary. Enclosure The liquid leak detection panel enclosure shall be constructed of metal / PVC and dust-tight NEMA 4X rating and capable of surface mounting. Installation The system shall be installed by well trained staffs, with the procedure recommended by the manufacturer. 4.0 TESTING : Testing the cable by placing a wet cloth or wire gauge over the cable to simulate an water leak , distance is displayed and the alarm relay operates. Extension of alarm to the BMS system to be verified. 5.0 COMMISSIONING :

S No. Description Visual Test Reading

Documentation



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1 All cables are tested for continuity & insulation √

2 System installation proper as per drawing √

3 Carry out visual checks on sensor cables, interface modules etc. to ensure they are clean and free from any mechanical damage

√

4 Check for proper termination & ferruling √

5 Check input A/C supply voltage √

6 Check for proper Sensor cable installation for the floor with non-conductive supports & Tagging

√

7 Check for fault indications √

8 Apply wet cloth or metallic wire gauge to sensing cable and check for Leak indication on the panel with leak distance in meters

√

9 Check for extension of alarms in the BMS √

6.0 DOCUMENTATION : The Contractor, upon completion of the commissioning activity, shall hand over the system to the customer. At the time of hand over, the contractor shall provide the customer with the following documentation: 1. Copy of detailed report 2. Component and equipment list 3. Product description sheets 4. System design drawing(s) 5. System schematic diagram(s) 6. System operating manuals 7.0 HANDOVER : Prior to final acceptance, the installing contractor shall provide complete operation and maintenance instruction manuals to the owner. All aspects of system operation and maintenance shall be detailed, including wiring diagrams of all circuits, a written description of the system design, sequence of operation and drawing(s), illustrating control logic and equipment used in the system. Checklists and procedures for emergency situations, maintenance operations and procedures shall be included in the manual. 8.0 TRAINING : General The contractor shall provide the customer with details of the training required by personnel to operate and maintain the Water leak detection system. The Contractor and the customer shall jointly agree the number of staff to attend the training courses. 9.0 MAINTANANCE : Routine maintenance should be carried out in accordance with relevant IS and TAC requirements. All performance checks undertaken should be recorded in the system log book. As a minimum, the following performance checks must be undertaken on each maintenance visit. The standard handling procedures must be adhered to and extreme caution must be exercised when working under the floor or with Sensor Interface Modules due to the presence of main voltage 240 V AC. Carry out verification checks as detailed in the commissioning instructions. Remove dust and dirt from the panel exterior using a soft brush or a lint cloth. A solvent which is harmless to the finishes of metal and plastic may be applied to more stubborn stains. Examine the exterior of the enclosure for any signs of damage or loose cable glands and rectify any faults found. Remove any dust or dirt form the interior of the control panel using a soft brush or a vacuum cleaner. Examine the printed circuit boards for signs of over-heating, dry joints and/or damaged tracks. Sensing cable to be cleaned with a damp cloth preferably every six-months.



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ADDRESSABLE INTELLIGENT EMERGENCY LIGHTING SYSTEM

1.1General The emergency lighting system will be afully addressable,self-testsystem usingself-contained luminaires and comply with the requirements of BS5266 and all otherrelated standards. All luminaires and exit signs shall incorporate an LED light source and Lithium Polymer battery technology to improve operational efficiency, reduce costs and protect the environment. Luminaires incorporating fluorescent lamp technology, nickel cadmium or nickel metal hydride batterieswill not be accepted. The system shall be designed to meet the requirementsof BS5266 pt1 and a certificate of complianceshall be issued on completion. 2 System Requirements Each lighting final sub-circuit shall be individually monitored by use of a DIN railmounted phase monitor. The phase monitor shall be microprocessor controlled anddetect the presence or absence of the mainssupply in accordancewith the parameters laid down in BS EN 60598-2-22. The emergency lighting control panel shall be capable ofsupporting up to two circuits of emergency lighting luminaires. Each of thesecircuitsshallbe capable of supporting up to 127 devices. Where more than 254 luminaires are required it shallbe possible to install a second ELCP and interface them via a graphics package and an IEEE802.3 Ethernet network. It shall be possible toconnect up to 15 panels onto a single network. The user interfaceshallconsist of a keypad with a2line by 40character LCD display. It shall be possibleto connect up to eight user interfaces onto each ELCP. 3 Luminaires Each luminaire shall be self-contained and consist of a single LED light source -with a specially designed lens to provide optimum light distribution, electronics and battery, all contained within a single plug-inhousing. Each luminaire shall be of the self-contained type andbeconnectedvia a 2 coredata communicationcable to a control panel. The power tocharge the batteries in each self-contained luminaireshall also bedelivered through this cable. Luminaires requiring a local 230V ac mains supply to charge the batteries shall not be permitted. Each luminaire shall be microprocessor controlled andallocated an individual address within the system. This address will be programmed into the microprocessor ofthe luminaire using a hand-held programming tool. Setting address by use of switches shall not bepermitted. Each luminaire and exit sign shall be capable of a minimum of 3hrs continuousoperation in an active mode. Each luminaire shall be fitted with a bi-colourRed/GreenLED to indicate itsstatus. This LEDshall providethe following information. Green Steady – battery fully charged. Green Flashing – battery charging. Alternate Green/Red – LED fault.



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Red Flashing, - battery fault. Red Steady –LED and battery faults. Each luminaire shall be siteprogrammable for operationin a maintained or non-maintained mode andshallprovide a minimum of3 hours continuous operation in the event of a mainspower supplyfailure. When a luminaire is operating in the maintained mode, itshall be possible to set the light output to seven different levels of brightness. Should the main supply fail, the luminaire shall automaticallyswitch to maximum brightness. To assist in servicing andmaintenance, each luminaire shall plug-in to a common base. Thisbase shall befree of any electronic components, addressingdevices or batteries. To avoid unauthorisedremoval it shall be possible to lockthe luminaire into the basewith removal only possible by use of a special tool. 3.1Battery Technology The standby batteries incorporated intoeach luminaire shall be Polymer LithiumIon technologyand incorporate over voltage, over current and deep discharge protection circuitry. Additional protection shall also be provided in case of a short circuit across the batteryterminals. 3.2End of Life Disposal LuminairesshallbeWEEEandRoHScompliantandsuitableforrecycling.Luminairesshallnotcontainany heavy metals which require special handling for disposal, such asmercury, leador cadmium. 3.3Range of Luminaires A range of products shall be availablecovering all types ofemergency lighting application. All of the luminaires shall use LED technology. The range shall include the following: LED Down-light with specially designed lens forcorridor area applications.Both surface and semi-flush mounting modelsshall be available. LED Down-light with specially designed lens for openarea applications. Both surface and semi-flush mounting modelsshall be available. A weatherproof housing shall be available for 3.10.1.1and 3.10.1.2. LED “step light” designed for flush mounting applications. LED “swing frame” exit signs which allows thesamesign to be either ceiling orwall mounted.Thesesigns shall utilise the same“plug-in” base as the luminaires. Two blade sizes shall be available for 20M and 40M viewing distances. LED recessed mounting exit signs. All of the above luminaires and exit signs shall be soft addressable via a handheld programming tool. 4 Emergency Lighting Control Panel (ELCP)



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The ELCPshall consist of a sheet steelenclosurewitha white powder coat finish and containan internal termination board for all incoming and outgoingcables. The housing shall measure 295w x 475h x 100d (mm) and incorporate asecure hinged front door. The panel shall be designed for surfacemounting All external cablingconnections are viaplug-inscrew terminals.Terminals areof the rising-clampstyle suitable for cablessizedup to 2.5mm2 Cable entry is through the top or rear of the panel. The panel shall derive its power from anexternally mounted 220V/35V a.c. transformer. The transformer shall have a protection rating of IP44. The panel shall have space for one 12V7.2 Ah Sealed Lead Acid batteries. The ELCPshall not incorporate any user controls. User controls shall be provided via a separate combinedkeypad and display unit. The panel shall support upto two circuits of addressable luminaires, exit signs and Input/output modules. Each circuit shall be able to support 127 addresses. The ELCPshall have a transactions logof the last 512 events. Subsequent events should overwrite the logon a FIFO principle. The data shall be held in non-volatilememory. The ELCPshall have a reports log of at least the last 12months activity.Subsequent activity should overwrite the log on a FIFOprinciple. The data shall be held in non-volatile memory. 4.1 Serial Outputs The ELCPshall include aminimum of two RS232 serialdata ports, with an expansion card for an additional two RS232/485 ports. The ELCPshall include anRS485 port for communicationwith upto eight combined keypadand display units. One serial port shall be dedicated for uploading and downloading the programmed data to and from a PC, or to provide data to a network interface module. 4.2 Panel Networking The ELCPshall include a serial output whichwill allow upto 15 panels to be connected via an existing or dedicated TCPIP Ethernet network to a graphical interface. 4.3PowerSupply Each ELCP shall be supplied via an external 220V/35Va.c. transformer. Each ELCP shall contain 1x 7Ah Sealed Lead Acid batteries tosupport panel and keypad operation duringa mains failurecondition. 5 UserInterface The user interfaceshallconsist of an illuminated alpha-numeric membrane keypad, witha group of “soft keys” to be used in conjunction witha graphic based 128x64 pixelbacklit LCD display in a surface mounting enclosure measuring 147W x 144H x 29D. It shall be possible to connect up to eight user interfaces on an RS485 bus to the ELCP. The LCD shall be menu driven and incorporate the following capabilities:



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5.1 Initiation of light test with selectable duration settings It shall be possible to initiate a manual test of the emergency lighting luminaires. The duration of which shall be selectable from 10 minutesin increments of 10 minutes upto a maximum of 180minutes. Oralternatively, a “No Limit” test can be initiated,the durationof which will last until the battery voltage reaches its lower cut off limit. It shall be possible to initiate a battery status check toallow the operator to view the capacity of the battery within each luminaire. To extend battery life it shall be possible to initiate a battery refresh (discharge/recharge)cycle. 5.2 Initiation of service mode, by line To prevent emergency mode operationof luminairesduring routinemaintenanceoperations. 5.3 Auto Learn Devices Allows thesystem to identify and include in configuration all addressable line devicesconnected to the ELCP. 5.4 Auto Learn New Devices Allows new devices to be added into the ELCP configuration. 5.5 Manual Learn New Devices Allows new devices to be added into the system. 5.6 ServiceState It shall be possible to set a line into a “servicestate”.Inthis state, the powerwill be removed from the line (to allow maintenance work on the line wiring to be carried out). When switched into thismode, the luminairesshallremain off so as to prevent discharge ofthe luminairestandby batteries. 6 Wiring The cable thatinterconnects the luminaires, I/O units and the panelshall be ascreened and twisted singlepair 1.5mm²cablewith a maximum length of up to 1000M. 7 Output Relay Card It shall be possible to connect up to four8way relay cards on a single RS485 Port. These relays shall be used for interfacing to other systems within the building. 8 Panel Programming Software The ControlPanel shall be fully site configurable and programmable using a PC-based programme and allow the data to be backed-up to a disc for archiving purposes. This programme shall alsoinclude thefacility to produce reports of all the systemprogramming in a printable format. 9 Monitoring of General Lighting MainsSupplies



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Each lighting final sub-circuit shall be monitored at the lighting distribution boardby a DIN railmounting phase monitor. Thephase monitor shall be microprocessor controlled anddetect the presence or absence of the mains supply in accordance withthe parameters laid downin BS EN 60598-2-22. andincorporate avoltage free change of state relay. Each phase monitorshallbe connectedvia an addressable input module to theELCP to signal the presence or absence of its monitoredsupply.

______________________End___________________________

LIST OF APPROVED MAKES

SR DESCRIPTION PREFFERED MAKES



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A FIRE ALARM SYSTEM (All Components shall be UL Listed)

1 Fire Alarm Panel(s) Siemens-Fire Finder / Notifier 3030/ Simplex 4100U

2 Network Repeater with Fire Fighters Telephone System

Siemens / Notifier/ Simplex

3 Graphic User Interface Software Siemens / Notifier/ Simplex

4 Smoke Detectors (Photo/PhotoThermal) Siemens / Notifier/ Simplex

5 Heat Detectors Siemens / Notifier/ Simplex

6 Beam detectors Siemens / Notifier/ Simplex/Fireray

7 UV/IR Flame Detectors Notifier / Detronics/ Hochiki

8 Rate Compensated Heat Detectors Fenwal Detect-A-Fire

9 Interface Modules : Monitor / Relay / Control / Zone Monitor etc.


10 Sounders / Sounder cum Flashers / Strobes / Annunciation devices


11 Manual Pull Stations Siemens / Notifier/ Simplex

12 Fire warden station, FF Telephone Jack, FFT Module Siemens / Notifier/ Simplex

13 Fault Isolator Modules Siemens / Notifier/ Simplex

14 Addressable Power Supplies Siemens / Notifier/ Simplex

15 Autodialler ADT / GE /Securico

16 Fire Extinguisher Minimax/Safex/CeaseFire

17 LED emergency Lighting system Technoware/Hochiki/Prolite

B DIGITAL PUBLIC ADDRESS SYSTEMS

1 Digital Controller HEINRICH/BOSCH / ATIES

2 Digital Power Amplifier HEINRICH/BOSCH / ATIES

3 Volume Control HEINRICH/BOSCH / ATIES

4 Background music source HEINRICH/BOSCH / ATIES

5 Call Station HEINRICH/BOSCH / ATIES

6 Speakers HEINRICH/BOSCH / ATIES

H HIGH SENSITIVITY SMOKE DETECTION SYSTEM

1 High Sensitivity Smoke detection unit Xtralis/Airsense/Hochiki

2 Hydrogen Detection Assembly Xtralis/Airsense/Hochiki

3 Air Sampling Piping Sch. 40 Fusion Pipe/ Airsal//BEC/Suprema

4 Capillary Tubes & Sampling Points Xtralis/Airsense/Hochiki

5 Listed Power Supply Xtralis/System sensor/Micropower / Sanstar


I NOVEC 1230 BASED FIRE SUPPRESSION SYSTEM



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1 NOVEC 1230 Gas 3M Corp., USA

2 Cylinder with valve ( OEM Factory Filled) CCOE Approved

Siemens /Ansul/SEVO

3 Electrical Actuator Siemens /Ansul/SEVO

4 Manual Actuator Siemens /Ansul/SEVO

5 Pneumatic Actuator Siemens /Ansul/SEVO

6 Discharge Hoses Siemens /Ansul/SEVO

7 Actuation Hoses Siemens /Ansul/SEVO

8 Manifold Check Valves Siemens /Ansul/SEVO

9 Nozzles Siemens /Ansul/SEVO

10 Low Pressure Switch Siemens /Ansul/SEVO

12 Discharge Pressure Switch Siemens /Ansul/SEVO

13 Piping ASTM A106 Gr. B Sch 40 & Sch.80 Indian Seamless / Maharashtra Seamless

14 "UL Listed" Gas Relerase Panel, with programmable Relay Modules& Builtin Listed Power Supply

PCD/Ravel/Notifier

15 "UL Listed" Dual Action Manual Release Station PCD/Ravel/Notifier

16 "UL Listed" Deadman type Abort Switch PCD/Ravel/Notifier

17 Integrety Test Siemens /Ansul/SEVO

J DIGITAL RODENT REPELLENT SYSTEM

1 Satellite Stations / Transducers R Scat /MASER/STAR

2 Rodent Repellant Controllers R Scat /MASER/STAR

DIGITAL WATER LEAK DETECTION SYSTEM

1 WLD Panel with LCD Display TTK/Tracetech/Elsa

2 Distance Measuring type WLD Cable TTK/Tracetech/Elsa

3 Digital Diversion Boxes, End Connectors TTK/Tracetech/Elsa

4 Leader Cable BELDEN/Kabletec/molex/Schnieider

A IP BASED CCTV SYSTEM

1 IP BASED CCTV CAMERA Axis/Vivotek/Honeywell/Dvtel/Samsung

2 Indoor PTZ CCTV CAMERA Axis/Vivotek/Honeywell/Dvtel/Samsung

3 Network Video Recorder Axis/Vivotek/Honeywell/Dvtel/Samsung

4 Server / PC / Monitors FUJITSU/HP/DELL

5 SAM/NAS Netapp/EMC2/Fujitsu/HP/QSAN

5 Professional CCTV Monitors SAMSUNG/LG/NEC/PANAONIC

6 Managed LAN Network Switches HP/CISCO/BROCADE/DIGISOLE


7 Power Supplies Transtech / Micropower / Sanstar

8 Copper Conductor Control Cable FINOLEX / SKYTONE / PLYCAB /CLIPLAST/VARSHA



104

9 Communication Cables/Signal Cable FINOLEX / SKYTONE / PLYCAB /CLIPLAST/VARSHA

10 LAN cable and Accessories BELDEN / COMMSCOPE/SYSTIMAX/SCHNEIDER/MOLEX

11 RACK VALRACK/APW/RITTAL/WD

B ACCESS CONTROL SYSTEMS

1 Contact less Access Readers HID/Rosellar

2 PIN type Readers HID/Rosellar

3 Biometric Fingerprint Scanners Smarti/HID/eSSL/Verdi/Rosellar

4 Hand Geometry Readers Ingersoll Rand

5 Access Controllers Siemens/Honeywell-Prowatch/GE Lenel/Genetec

6 Access Control Software Siemens/Honeywell-Prowatch/GE Lenel/Genetec

7 Cards HID

8 Electro Magnetic Lock Algatec/BELL/Trimac/Ebelco

9 Magnetic Contact Algatec/BELL/Trimac/Ebelco

10 Emergency Door Release KAC/Rosellar/Dafikas

11 Exit Push Button Algatec/Rosellar/Trimac/Ebelco

12 Panic Bar Dafikas/Boonadam/C-system

13 Cables Varsha/ Finolex/Polycab/Caliplast

14 Server/Workstation HP/DELL/Fujitsu/IBM

G BUILDING MANAGMENT SYSTEM

1 NETWORKABLE DDCS HONEYWELL-TREND/SIEMENS/UTC - ALC / TRANE

2 WEB BASED BMS SOFTWARE WITH UNLIM HONEYWELL-TREND/SIEMENS/UTC - ALC / TRANE

3 WEB BASED ROUTER / NETWORK AREA C HONEYWELL-TREND/SIEMENS/UTC - ALC / TRANE

4 IMMERSION TEMPERATURE SENSOR HONEYWELL/SIEMENS / TRANE / SONTAY

5 DUCT TEMPERATURE SENSOR HONEYWELL/SIEMENS / TRANE / SONTAY

6 OUTSIDE AIR TEMPERATURE & HUMIIDTY SENSOR HONEYWELL/SIEMENS / TRANE / SONTAY

7 ROOM TEMPERATURE SENSOR HONEYWELL/SIEMENS / TRANE / SONTAY

8 AIR QUALITY SENSOR/CO2 SENSOR HONEYWELL/SIEMENS / TRANE / SONTAY / SENSAIR

9 TEMPERATURE AND HUMIDITY SENSOR HONEYWELL/SIEMENS / TRANE / SONTAY

10 WATER LEVEL SWITCH MINILEC/TECHTROL/ VEKSLERL/FILPRO

11 DP SWITCH – WATER HONEYWELL/SIEMENS/TRANE/SONTAY/KELE

12 DP SWITCH – AIR HONEYWELL/SIEMENS / TRANE / SONTAY

13 HYDROGEN SENSOR HONEYWELL/SIEMENS/MSR / AMBETRONICS

14 WATER FLOW SWITCH MINILEC/TECHTROL/ VEKSLERL/FILPRO

15 PRESSURE TRANSMITTER – WATER HONEYWELL/SIEMENS / TRANE / SONTAY

16 CURRENT RELAY/TRNSDUCER SITU/VERIS/ABB/SIEMENS

17 VOLTAGE / CURRENT / POWER FACTOR TR SITU/VERIS/ABB/SIEMENS

18 FLAME PROOF LEVEL SWITCH / LEVEL TRA MINILEC/TECHTROL/ VEKSLERL/FILPRO

19 SRVER /WORKSTATION HP / DELL/FUJITSU

20 COLOUR MONITOR SAMSUNG/LG/NEC/PANASONIC

21 PRINTER HP / EPSON / CANON


22 SWITCHES HP/CISCO/BROCADE/DIGISOLE

23 COPPER CONDUCTOR CONTROL CABLE FINOLEX / SKYTONE / POLYCAB /CALIPLAST/VARSHA

24 COMMUNICATION CABLES / SIGNAL CABL FINOLEX / SKYTONE / POLYCAB /CALIPLAST/VARSHA

25 LAN CABLES FOR BMS NETWORK BELDEN / COMMSCOPE/SYSTIMAX/DIGILINK/MOLEX



105

26 PVC Conduits BEC / VIP / UNIVERSAL / PRECISION

J CABLES AND CONTAINMENT

1 2 core x 1.5 mm2, Multistrand Copper, Fire survival, Armoured cable, RED in Colour.

Finolex/Polycab/Century/RRKable/Varsha/Caliplast

2 FRLS 8c x 0.75 mm

2 multistranded copper, Shielded,

PVC sheathed Armoured Cable


3 FRLS 4c x 0.75 mm

2 multistranded copper, PVC

sheathed Armoured Cable


4 FRLS 2c x 0.75 mm

2 multistranded copper ,shielded,

PVC sheathed Armoured Cable


6 Armoured FRLS 2c x 1.0 mm2 Cu, Multistranded, PVC sheathed Cables.


7 ISI Marked FRLS 2 core x 1.5 mm2, Multistrand Copper, Armoured cable


9

Signal cabling : Armoured FRLS Copper Flexible Conductor Shielded ( Aluminium Mylar tape with ATC Drain wire of 0.75 Sq. mm),PVC insulated,PVCS heathed Cable as per IS : 694

2Cx 1 sq. Mm


3Cx 1 sq mm Finolex/Polycab/Century/RRKable/Varsha/Caliplast



10 FiberOptic Cable Systimax/Panduit/Kabletec

11 Specially Armoured CAT6 / CAT 6E Cable Systimax/Panduit/Kabletec

12 20 mm / 25 mm GI Conduit and Fiitings BEC /AKG/Precision

13 Perforated GI Cable tray, Medium Duty Profab/ ASIAN /RM CON

14 GI Trunking Profab/ ASIAN /RM CON