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Home My WebLink AboutF_GHC Longacres Signal and lighting Special Provisions 2017_170322_Approved SP 1 9-29 ILLUMINATION, SIGNALS, ELECTRICAL 9-29.1 Conduit, Innerduct, and Outerduct Section 9-29.1 is supplemented by adding the following: (******) The conduit PVC - non-metallic shall be of the two types indicated below: 1. Schedule 80 Extra heavy wall PVC conforming to ASTM, Standards, to be used in all installations under roadways. 2. Schedule 40 heavy wall PVC conforming to ASTM Standards. 9-29.2(1)A Standard Duty Junction Boxes Section 9-29.2(1)A is supplemented with: (******) Junction boxes shall be reinforced concrete with galvanized steel frame anchored in place and galvanized steel cover plate (Diamond pattern). Grounding lugs shall be stainless steel and shall be mechanically and electrically bonded. Junction boxes for copper wire shall incorporate a locking lid per City of Renton Standard Plan. Junction boxes placed in the sidewalks shall have non-skid lids. 9-29.3 Fiber Optic Cable, Electrical Conductors and Cable 9 29.3(1)(A)Fiber Optic Cable Section 9-29.3f 1) is supplemented as follows: Fiber optic cable conduit shall be supplied as a system from a single manufacturer providing all the conduit, all required fittings, termination and other installation accessories, all in accordance with the Contract Documents. The fiber optic cable network shall be singlemode, non-zero dispersion shifted, loose tube fiber capable of supporting both SONET transmission speeds and protocols up to 2.4 GE/s, and NTSC quality color video applications. Trace wire will need to be in cable or pulled in conduit with fiber cable. Install signal controller mounted patch panels for all fiber terminating applications. Patch panels shall accept LC style connectors. The Contractor shall provide all necessary tools, consumables, cleaner, mounting hardware and other materials required for the complete installation of each patch panel. A wiring diagram shall be supplied with each patch panel. The wiring diagram shall identify the destination of each fiber terminated in the patch panel. The destination information shall include at a minimum, an intersection name, cabinet number, patch panel number and patch panel port. The wiring diagram shall be placed in a plastic sheet protector next to the patch panel and a copy submitted to the Project Representative with As-Built drawings. Each row of ports in the patch panels shall be labeled with the associated port numbers with the assumption that the numbers increase from top to bottom or left to right. The Contractor is responsible for demonstrating the functionality of the installed system SP 2 through testing. These tests shall be conducted in accordance with an approved test plan that shall cover the key functional requirements of the Work. The Contractor shall, at its cost, provide suitable test equipment, instruments and labor for the purpose of tests. The Contractor shall provide sufficient notice of not less than three (3) working days prior to the commencement of the first test. The Contractor shall submit with this notice a schedule of all tests covered by this notice. 9 29.3(1)(B) OTDR Testing of Spliced Fiber Links This describes the testing to be completed on all sections of the fiber network after splicing is completed. For this section, a fiber link shall be defined as a continuous section of fiber from connector to connector that may pass through a number of intermediate splices. OTDR testing shall be completed as follows: • Test each fiber link in the cable at 1310 nm and 1550 nm, in each direction. • Verify that each completed fusion is less than 0.20 dB, measured as the average of splice loss measured in each direction through the link. • Re-make any fusions in excess of 0.20 dB, unless the Engineer specifically approves such high loss fusions, and re-test any fiber links that have been re-fused. 9-29.3(2) Electrical Conductors and Cable Section 9-29.3(2) is revised and supplemented as follows: (******) Supplement: Each wire shall be numbered at each terminal end with a wrap-around type numbering strip bearing the circuit number shown on the Plans. The Contractor shall provide and install all the necessary wiring, fuses and fittings so as to complete the installation of the signal and lighting equipment as shown on the Plans. All materials and installation methods, except as noted otherwise herein, shall comply with applicable sections of the National Electrical Code. Revisions: 8. 11. Communications cable shall meet REA specification PE-39 and shall have No. 19 AWG wires with 0.008 inch FPA/MPR coated aluminum shielding. The cable shall have a petroleum compound completely filling the inside of the cable. 9-29.3(2)J Cable for Vehicle Video Detection Cameras The permanent video detection system shall consist of the following: • Video cameras, including camera enclosure, filter, sunshield and connector kit. • Camera mount assemblies, including extensions as specified in the Plans. • Video image processors • Remote communications module • 9-inch Video Monitor, including cable • Programming devices and/or software • Remote management software • Camera lenses and lens adjustment modules • Surge Suppressor • Coaxial and power cables • All other equipment necessary for a fully operational video detection system. SP 3 Naches Avenue SW and SW 27th Street (Existing traffic signal controller cabinet): Contractor shall prioritize order placement and installation of video detection at this intersection. • Video cameras, including camera enclosure, filter, sunshield and connector kit. • Camera mount assemblies, including extensions as specified in the Plans. • Video image processors • Remote communications module 9-29.6(1)A Decorative Signal Poles Type II and III Section 9-29.6(1)A is a new section: (******) The decorative steel traffic signal poles shall be capable of supporting one (1) mast arm up to sixty-five (65) feet in length and up to two (2) luminaire arms, and shall be complete in all respects. No welding will be allowed at the site at the time of erection. The vertical pole shaft shall be round tapered steel, multi-sided poles are not acceptable. The pole shaft shall consist of a maximum 17” round smooth steel tapered pole, with adequate wall thickness to meet all design requirements. The vertical section shall be continuous taper (0.14/ft.) for the entire length without a reducing cone. The pole shaft and mast arm shall meet ASTM A595 Grade A or Grade 572 specifications, minimum yield 55 KSI. The pole shall have a base plate (bolt circle per the Plans) meeting ASTM Grade A-36 specifications welded to the pole shaft per the manufacturer’s recommendations and have four (4) holes at 90 degrees to accept the properly sized anchor bolts. The pole shall have a 4” x 6” oval handhole located 18” up from the base plate to the top of the centerline of the handhole and oriented as per detail in the Signal Pole Specifications sheet. A pressure type grounding nut shall be welded 180 degrees from the handhole opening. Four (4) galvanized steel anchor bolts (design to be supplied by pole manufacturer) conforming to ASTM F1554 GR105 specifications shall be provided for each pole complete with two (2) nuts and washers for each bolt. Pole top tenon shall be 4 ¼” OD X 11” tall with removable pole top cap. Decorative Arm (Steel) Arm Assembly shall be as dimensioned in the Plans, 3/16” minimum wall, ASTM A500 Grades B & C with ¼” upper gusset (fin) and 4” OD decorative hole per plan sheets. Two piece clamp assembly shall be 3/16” tubing welded on each end, sized to fit luminaire and pole, clamp assemblies are secured with ½”-13NC stainless steel hex head bolts. Fixture clamp shall have 1” NPT X 1” long threaded pipe nipple with bushings to provide additional means of securing luminaire to clamp assembly and provide a raceway for the conductors. Arm assembly shall be hot dipped galvanized per ASTM A123. Poles and arms shall be factory galvanized, primed and finish coated as referenced in Section 6- 07 of these Special Provisions. 9-29.6(1)B Decorative Light Poles Section 9-29.6(1)B is a new section: (******) SP 4 Decorative Arms (Aluminum): Arm assembly shall be extruded tubing, as dimensioned in the Plans, minimum .125 wall, 6061- T6 alloy with upper gusset (fin) and decorative hole per plan sheets. Two piece clamp assembly shall be .188 wall tubing welded on each end, sized to fit luminaire and pole at the proper mounting height, clamp assemblies are secured with ½”-13NC stainless steel hex head bolts. Fixture clamp shall have a 1½” wireway going from pole shaft to fixture extending into pole shaft and fixture by 1”. Prove ½” through hole at 45 degrees on pole clamp assembly for 3/8”-16NC self-tapping screw to prevent rotation of arm assembly after installation. Poles and arms shall be factory primed and finish coated as referenced in Section 6-07 of these Special Provisions. 9-29.10(2) Decorative Luminaires Section 9-29.10(2) is replaced with the following: (*****) Roadway and pedestrian luminaires shall be LED type, wattages similar to the wattages shown in the luminaire schedules on the Plans. The Contractor shall be responsible for verifying that the performance of the LED luminaires is adequate to comply with the City illumination standards (roadways: 1.3 ft-candles average and 4:1 uniformity; intersections: 1.5 ft-candles average and 4:1 uniformity, and a minimum of 0.8 ft-candles at any location within the crosswalks) without modifying illumination and signal pole locations shown on the Plans. AGI32 files shall be provided, by the Contractor upon the request, by the Engineer. The roadway and pedestrian luminaire housing shall be dome shaped and similar to dimensions as shown on the Plans, made of cast or spun aluminum with tempered flat glass lens attached to a round cast aluminum lens frame with one or more latches to provide tool less access to the internal components, upper section shall be round aluminum tubing with shallow dome shaped top cap. Luminaire shall be IP66 certified and conform to UL 1598 standards or CSA certified. Optical assembly/reflector shall be made of pre-anodized aluminum, segmented in multiple facets, ventilated perforations and heat sinks to maximize heat dissipation. Reflector shall produce full cut-off Type III optics to meet the design/performance criteria, 4000K CCT. LED driver module rated for 120V-277V operation, high power factor (90%), with a minimum starting temperature of -40 Degrees Fahrenheit, secured on a tool less access tray with quick disconnects. Individual LED chips or modules shall be removable by means of tool less access in the event they need to be replaced. LED driver not to exceed 750 MA. All decorative fixtures shall be of the same manufacturer and external appearance. Color shall be per these Special provisions, Section 6-07 Painting. 9-29.11(2) Photoelectric Controls Section 9-29.11(2) is replaced with: (******) Photoelectric controls shall be a plug-in device, rated to operate on 120 volts, 60 Hz. The unit shall consist of a light sensitive element connected to necessary control relays. The unit shall be so designed that a failure of any electronic component will energize the lighting circuit. The photo cell shall be a solid state device with stable turn-on values in the temperature range of -55 degrees C to +70 degrees C. In a contactor controlled system, the photo cell to control the SP 5 system shall be mounted on the luminaire nearest to the service/contactor cabinet. The photo cell shall be rated as a 10-year (or higher) life expectancy. 9-29.13 Traffic Signal Controllers Section 9-29.13 is supplemented with the following: (*****) The Contractor shall give fourteen (14) calendar days written notice to the Engineer prior to delivering the signal control equipment to the COR Field Maintenance Shop. The equipment shall be delivered far enough in advance of actual need to allow for testing by the COR Field Maintenance Shop. This may involve retesting because of failures or rejections. The COR Field Maintenance Shop may require thirty-five (35) calendar days for testing the signal control equipment. This time will increase if the equipment does not meet the contract requirements or is incomplete. If more than thirty-five (35) calendar days are required for any individual testing or retesting by the COR Field Maintenance Shop, an extension of time will be considered in accordance with Section 1-08.8. Tests in environment chamber will only be run as needed for type changes. Upon successful completion of testing by the COR Field Maintenance Department, the signal controller equipment shall be available for pickup. A certificate verifying environmental testing, if required, shall be supplied in the cabinet to the COR Field Maintenance Shop for each respective control cabinet. The Contractor shall notify the COR Field Maintenance Shop in writing a minimum of fourteen (14) calendar days before the Contractor is ready to pick up the signal controller cabinet. The Contractor shall not pick up the controller cabinet from COR Field Maintenance Shop until the electrical service is energized and all site preparation required to install the controller cabinet is complete. Documentation A complete documentation set shall be furnished with the control equipment prior to the start of testing. It shall include the following: · Serial numbers when applicable. · Written certification that equipment of the same make and model has been tested according to NEMA Environmental Standards and Test Procedures, and has met or exceeded these standards. The certificate shall include equipment model number and where, when, and by whom the tests were conducted. This certificate shall accompany each shipment of controllers. · The Contractor shall provide wiring diagrams, including a duplicate set of 3-1/2” high density diskettes containing the diagrams for all controllers in AUTOCAD Release 2000 or later and two blue-tone prints for each controller and cabinet supplied. The sheet size shall be 22 inches by 34 inches. · Wiring diagrams for all auxiliary equipment furnished. One set per cabinet. · Complete operations and maintenance manuals including complete and correct software listing and flow charts, five sets of operations and maintenance manuals per cabinet, and five sets of software listings and flow charts. SP 6 · Complete operations and maintenance manuals for all auxiliary equipment. One set per cabinet. · The operational and maintenance manuals for each traffic signal controller supplied including as a minimum, but not to be limited to the following: Detailed instructions for maintaining all hardware components, controller, and auxiliary equipment; a complete parts list detailing all manufacturer's identification codes; detailed wiring diagrams and schematics indicating voltage levels and pictorial description, part name, and location for all hardware components, controller, and auxiliary equipment. · Traffic signal cabinet shall be a Western Systems NEMA TS-2 Type 1 P+ cabinet or as noted on approved plans. The supplier has 5 working days to repair or replace any components that fail during the testing process at no cost to the Contracting Agency. All failed or rejected equipment shall be removed from the COR Field Maintenance Shop within seven (7) calendar days following notification; otherwise, the failed or rejected equipment will be returned, freight collect, to the Contractor. 9-29.13(2) Flashing Operations The following items in Section 9-29.13(2) are revised as follows: (******) 2. Police Panel Switch. When the flash-automatic switch located behind the police panel door is turned to the flash position, the signals shall immediately revert to flash and remove power from the controller. When the switch is placed on automatic, power shall be applied to the controller to initiate start-up sequence. 3. Cabinet Switches. When the flash-automatic switch located inside the controller cabinet is placed in the flash position, the signals shall immediately revert to flash; however, the controller shall continue to function. When the flash-automatic switch is placed in the automatic position, the controller shall immediately resume normal cyclic operation. Adjacent to the flash-automatic switch shall be a controller on-off switch. If the flash-automatic switch is in the automatic position and the controller on-off switch is placed in the OFF position, the signals shall immediately revert to flash. 5. Conflict Monitor. Upon sensing conflicting signals or unsatisfactory operation voltages, the conflict monitor shall immediately cause the signal to revert to flash; however, the controller shall stop time at the point of conflict. After the conflict monitor has been reset, the controller shall immediately take command of the signal displays. The following is a supplement: 6. Flash unit shall be a two-circuit type, capable of switching loads up to 1000 watts per circuit alternately at a rate of 60 flashes per minute per circuit, plus or minus two flashes per minute. 9-29.13(6) Emergency Pre-emption Section 9-29.13(6) is replaced with: (******) Immediately after a valid call has been received, the preemption controls shall cause the signals to display the required clearance intervals and subsequent preemption intervals. Preemption shall sequence as noted in the contract. Preemption equipment shall be installed so that internal wiring of the controller, as normally furnished by the manufacturer, is not altered. Termination of the pre-emption sequence shall NOT place a call on all vehicle and pedestrian phases. SP 7 Pre-emption indicators, if required, shall turn on when the controller reaches the pre-empted phase. Emergency vehicle pre-emption shall be furnished as modules that plug directly into a rack wired to accept GTT Opticom discriminator type units. The pre-emption system operation shall be compatible with the 764 GTT company "opticom" system which the City of Renton is currently using and shall be capable of being activated by the same transmitters. The optical signal discriminator system shall enable an authorized vehicle to remotely control traffic control signals from a distance of up to 1800 feet (0.54 kilometers) along an unobstructed "line of sight" path. The system shall cause the traffic signals controller to move into an appropriate fire pre-emption program. this optical discriminator shall interface to the 562 software, for field programmability. It shall consist of the following components: 1. Optical energy detectors which shall be mounted on the traffic signal mast arms and shall receive the optical energy emitter's signal. 2. Discriminators which shall cause the signal controller to go into internal pre-emption which will give the authorized vehicle the right of way in the manner shown on the phase sequence diagram. 3. Pre-emption Indicator Lights. Optical Detector 1. Shall be of solid state construction. 2. Fittings shall meet the specifications of the system manufacturer to facilitate ease of installation. 3. Shall operate over an ambient temperature range of -40°F to +180°F (-40°C to +85°C). 4. Shall have internal circuitry encapsulated in a semi-flexible compound and shall be impervious to moisture. 5. Shall respond to the optical energy impulses generated by a pulsed Xenon source with a pulse energy density of 0.8 micro joule per square meter at the detector, a rise time less than one microsecond and half power point pulse width on not less than thirty microseconds. Discriminator When a pre-emption detector detects an emergency vehicle, the phase selector shall hold the controller in the required phase or advance directly to that phase after observing all vehicle clearances. The phase selector shall hold the controller in the phase selected until the detector no longer detects the emergency vehicle. When the phase selector is responding to one detector, it shall not respond to any other detector until calls from the first detector are satisfied. Indicator lights shall indicate power on, signal being received, channel called. Switches shall control system power and simulate detector calls for each phase. 9-29.13(4) Wiring Diagrams Section 9-29.13(4) is modified and supplemented by retaining the first three sentences and replacing the remainder with: (******) The controller cabinet shall have a waterproof envelope with a side access attached to the inside of the cabinet door. There shall be four (4) complete sets of controller cabinet schematics as well as manuals for all assemblies and sub-assemblies. The controller cabinet schematics shall include the intersection name, and an intersection diagram that shall include intersection phasing and loop assignments. There shall be a digital compact disk (CD) containing the controller cabinet schematics in AutoCad digital file format. 9-29.13(6) Radio Interference Suppressors Section 9-29.13(6) is supplemented by adding the following: (******) SP 8 A Cornell-Dubiler radio interference filter NF 10801-1 30 amps or equivalent shall be used to filter the A.C. power. Additionally, all power supplies shall have noise immunity from other devices within the cabinet. 9-29.13(7) Traffic-Actuated Controllers Section 9-29.13(7) is revised with the following: (*****) The NEMA controller shall be a Siemens Eagle Model EPAC300-M62 with a USB Data module with a hand-held Display Unit. Two Input / Output configurations shall be provided: a. NEMA TS-2 Type 1 for serial connection to cabinet Bus Interface Unit b. NEMA TS-2 Type 2 for direct parallel connection to load switches and detectors. In addition to NEMA requirements, the controller shall provide the following: a. Built-in 10 Base-T Ethernet with RJ-45 connector on controller front panel b. Built-in Internet Protocol (IP) address assigned by Institute of Electrical and Electronic Engineers (IEEE), one unique IP address for each controller. c. Built-in Infrared (IR) wireless port compatible with Microsoft Windows for Pocket PC Infrared RAW mode. d. Built-in 1200 bps Frequency Shift Keying (FSK) modem. Modem is optional per Agency specification. Choice of 2 or 4 wire operation per Agency specification. e. Built-in EIA-232 port for uploading and downloading applications software, as well as to update the operating system. f. Built-in C60 connector for use with removable Keyboard and Display, Personal Computer COM1 or Personal Digital Assistant (PDA). C60 protocol per Joint NEMA/AASHTO/ITE ATC standard. NEMA Traffic Signal Controller Firmware: (Addendum No. 2) The controller shall have Siemens Eagle SE-PAC firmware Version 3.51 (or higher). 9-29.13(7)A Environmental, Performance and Test Standards for Solid-State Traffic Controller Section 9-29.13(7)A is supplemented by adding the following: (******) The traffic signal controller assemblies, including the traffic signal controller, auxiliary control equipment and cabinet shall be shop tested to the satisfaction of the Engineer. Testing and check-out of all timing circuits, phasing and signal operation shall be at the City of Renton Signal Shop, Renton, Washington. The contractor shall give the city of Renton Signal Shop at least one week lead time to delivery. The contractor shall deliver the controller and cabinet to the shop and shall pick up the units at the end of the test period, deliver to the job site, and install. Allow for three weeks for testing. The Signal Shop will make space available to the Contractor for the required test demonstrations. The Contractor shall assemble the cabinet and related signal control equipment ready for testing. A complete demonstration by the Contractor of all integrated components satisfactorily functioning shall start the test period. Any malfunction shall stop the test period until all parts are satisfactorily operating. The test shall be extended until a minimum of 72 hours continuous satisfactory performance of the entire integrated system has been demonstrated. The demonstration by the Contractor to the Engineer of all components functioning properly shall not relieve the Contractor of any responsibility relative to the proper functioning of all aforestated control gear when field installed. SP 9 9-29.13(7)B Auxiliary Equipment for NEMA Controllers Section 9-29.13.(7)B is revised as follows: (*****) The following auxiliary equipment shall be furnished and installed in each cabinet for NEMA traffic-actuated controllers: 1. A solid-state Type 3 NEMA flasher with flash-transfer relay which will cut in the flasher and isolate the controller from light circuits. See Section 9-29.13(2) for operational requirements. The flasher shall be two circuit with indicator lights. The unit shall be rated for fifteen (15) amps per circuit through the entire NEMA temperature range. 2. Modular solid state relay load switches of sufficient number to provide for each vehicle phase (including future phases if shown in the Plans), each pedestrian phase and preemption sequence indicated in the contract. Type P & R cabinets shall include a fully wired 16-position back panel. Solid-state load switches shall conform to NEMA standards except only optically isolated load switches will be allowed. Load switches shall include indicator lights on the input and output circuits. 3. A power panel with: a. A control-display breaker sized to provide 125 percent overload protection for all control equipment and signal displays, 30 ampere minimum. b. A 20 ampere accessory breaker wired parallel to the control display breaker. The breaker will carry accessory loads, including vent fan, cabinet light, plug receptacle, etc. c. A busbar isolated from ground and unfused for the neutral side of power supply. d. A radio interference suppresser to the output side of the control display breaker. See Section 9-29.13(6) for other requirements. e. A transient voltage protection device connected to the controller power circuit for protection against voltage abnormalities of 1 cycle or less duration. The protector shall be a solid state high energy circuit containing no spark gap, gas tube, or crow bar component. The current rating of the device shall be 15 amps minimum. The device shall provide transient protection between neutral and ground, line and ground, as well as line and neutral. If the protection circuits fail, they shall fail to an open circuit condition. The device shall meet all requirements of UL standard 1449. The suppressed voltage rating shall be 600 volts or less when subjected to an impulse of 6,000 volts, 3,000 amp source impedance, 8.0/20 microsecond waveform as described in UL 1449. In addition, the device shall withstand, without failure or permanent damage, one full cycle at 264 volts RMS. The device shall contain circuitry to prevent self-induced regenerative ringing. There shall be a failure warning indictor light which shall illuminate when the device has failed and is no longer operable. f. Cabinet ground busbar independent (150K ohms minimum) of neutral. Sections 4 - 13 are replaced with the following: GENERAL All mounting hardware used in the cabinet, whether it is used to secure equipment or some portion of the cabinet itself, shall be stainless steel or nickel plated brass. SP 10 FAIL SAFE UNIT 1. INTRODUCTION This specification sets forth the minimum requirements for a shelf-mountable, sixteen channel, solid-state Malfunction Management Unit (MMU). The MMU shall meet, as a minimum, all applicable sections of the NEMA Standards Publication No. TS2-1998. Where differences occur, this specification shall govern. 2. MONITORING FUNCTIONS The following monitoring functions shall be provided in addition to those required by the NEMA Standard Section 4. 2.1 DUAL INDICATION MONITOR Dual Indication monitoring shall detect simultaneous input combinations of active Green (Walk), Yellow, or Red (Don’t Walk) field signal inputs on the same channel. In Type 12 mode this monitoring function detects simultaneous input combinations of active Green and Yellow, Green and Red, Yellow and Red, Walk and Yellow, or Walk and Red field signal inputs on the same channel. 2.1.1 DUAL INDICATION MONITORING Sixteen switches labeled FIELD CHECK/DUAL ENABLES shall be provided on the MMU front panel to enable Dual Indication Monitoring on a per channel basis. The Dual Indication Monitor function shall provide two modes of operation, Dual Indication Fault and GY-Dual Indication Fault. When voltages on two inputs of a vehicle channel are sensed as active for more than 450 msec, the MMU shall enter the fault mode, transfer the OUTPUT relay contacts to the Fault position, and illuminate the DUAL INDICATION indicator. The MMU shall remain in the fault mode until the unit is reset by the RESET button or the EXTERNAL RESET input. When voltages on two inputs of a vehicle channel are sensed as active for less than 200 msec, the MMU shall not transfer the OUTPUT relay contacts to the Fault position. When operating in the Type 16 mode with Port 1 communications enabled, Bit #68 (Spare Bit #2) of the Type #129 response frame shall be set to indicate a Dual Indication fault has been detected. Dual Indication Monitoring shall be disabled when the RED ENABLE input is not active. 2.1.2 GY-DUAL INDICATION MONITOR GY-Dual Indication monitoring shall detect simultaneous inputs of active Green and Yellow field signal inputs on the same channel. It will be used to monitor channels which have an unused Red field signal input tied to AC LINE such as a five section signal head. GY-Dual Indication Monitoring shall be enabled by a front panel option switch. When the GY-Dual Indication Monitoring option is enabled, all channels which have the front panel FIELD CHECK/DUAL ENABLE switches OFF shall be individually monitored for simultaneous active Green and Yellow field signal inputs. All channels which have the front panel FIELD SP 11 CHECK/DUAL ENABLE switches ON (i.e. enabled for Dual Indication Monitoring) shall function as described above in Dual Indication Monitoring. 2.2 FIELD CHECK MONITORING Sixteen switches labeled FIELD CHECK/DUAL ENABLES shall be provided on the MMU front panel to enable Field Check Monitoring on a per channel basis. The Field Check Monitor function shall provide two modes of operation, Field Check Fault and Field Check Status. Field Check Monitoring shall be disabled when the RED ENABLE input is not active. The Field Check Monitoring function shall be disabled in the Type 12 mode. 2.2.1 FIELD CHECK MONITOR In the Field Check Fault mode, when the field signal input states sensed as active or inactive by the MMU do not correspond with the data provided by the Controller Unit in the Type #0 message for 10 consecutive messages, the MMU shall enter the fault mode, transfer the OUTPUT relay contacts to the Fault position, and illuminate the FIELD CHECK FAIL indicator. The Channel Status Display shall indicate the channels on which the Field Check fault was detected. Bit #67 (Spare Bit #1) of the Type #129 response frame shall be set to indicate a Field Check fault has been detected. The MMU shall remain in the fault mode until the unit is reset by the RESET button or the EXTERNAL RESET input. 2.2.2 FIELD CHECK STATUS The Field Check Status mode shall work in combination with the other fault monitoring functions of the MMU. When a Conflict, Red Fail, Clearance Fail, or Dual Indication Fail triggers the MMU, the Channel Status Display and Fault Status Display shall correspond to that detected fault. If Field Check errors were detected while the fault was being timed, the inputs on which the Field Check errors were detected shall double pulse at the same time as the FIELD CHECK STATUS indicator. Bit #67 (Spare Bit #1) of the Type #129 response frame shall also be set to indicate Field Check errors have been detected. 2.3 RECURRENT PULSE MONITORING The Signal Monitor shall detect Conflict, Red Fail, and Dual Indication faults that result from intermittent or flickering field signal inputs. These recurring pulses shall result in a latching fault with the RECURRENT PULSE STATUS indicator illuminated along with the resulting Conflict, Red Fail, or Dual Indication indicator. An option switch shall be provided to disable the RP detect function for testing purposes. When operating in the Type 16 mode with Port 1 communications enabled, Bit #69 (Spare Bit #3) of the Type #129 response frame shall be set to indicate a Recurrent Pulse status has been detected. 2.4 EXTERNAL WATCHDOG MONITOR The MMU shall provide the capability to monitor an optional external logic level output from a Controller Unit or other external cabinet circuitry. If the MMU does not receive a change in state on the EXTERNAL WATCHDOG input for 1500 SP 12 msec (_+100 msec), the MMU shall enter the fault mode, transfer the OUTPUT relay contacts to the Fault position, and illuminate the CVM/WATCHDOG indicator. The MMU shall remain in the fault mode until the unit is reset by the RESET button or the EXTERNAL RESET input. An MMU Power Failure shall reset the CVM/WATCHDOG fault state of the monitor. The EXTERNAL WATCHDOG input shall be wired to connector MSB-S. When operating in the Type 16 mode with Port 1 communications enabled, Bit #70 (Spare Bit #4) of the Type #129 response frame shall be set to indicate an External Watchdog fault has been detected. 2.5 WALK DISABLE OPTION The MMU shall provide the capability to exclude the Walk inputs from the Red Fail fault detection algorithm when operating in the Type 12 mode. When the option is selected, the absence of signals on the Green, Yellow, and Red field outputs of a channel will place the MMU-16 unit into the fault mode, transfer the OUTPUT relay contacts to the Fault position, and illuminate the RED FAIL indicator. 2.6 TYPE FAULT MONITOR The MMU shall verify at power-up that the Type 12 or Type 16 operating mode as determined by the TYPE SELECT input is consistent with the mode set by the last external reset. Detection of a Type Fault shall place the MMU into the fault mode, transfer the OUTPUT relay contacts to the Fault position, illuminate the DIAGNOSTIC indicator, and flash the TYPE 12 indicator at a 2Hz rate. The MMU shall remain in the fault mode until the unit is reset by the RESET button or the EXTERNAL RESET input. An MMU Power Failure shall reset the Type Fault state of the monitor. 2.7 CONFIGURATION CHANGE MONITOR On power-up, reset, and periodically during operation, the Signal Monitor shall compare the current configuration settings with the previously stored value. If the settings have changed, the Signal Monitor shall automatically log the new setting. These settings shall include the Program Card jumpers and all switches. A programming option shall be provided such that any change in the configuration parameters shall cause the Signal Monitor to enter the fault mode causing the Output relay contacts to close and enabling the Stop-Time output to the controller. To indicate this fault mode the PGM CARD / CF indicator shall flash at a 4 Hz rate. Depressing the Reset button for 3 seconds shall be required to clear this fault and log the new configuration parameters. If the programming option is not selected, the unit shall not set the fault mode but will still log the configuration change. 2.8 CVM LOG DISABLE The MMU shall provide a means to disable the logging of CVM fault events. 3. DISPLAY FUNCTIONS The following display functions shall be provided in addition to those required by the NEMA Standard Section 4. SP 13 3.1 FULL INTERSECTION CHANNEL STATUS DISPLAY A separate Red, Yellow, and Green indicator shall be provided for each channel to show full intersection status simultaneously. For Type 12 mode operation the Walk input status shall be shown on channel indicators 13 through 16. 3.2 FAULT CHANNEL STATUS DISPLAY During normal operation the 48 Channel Status indicators shall display all active signals. In the fault mode the Channel Status indicators shall display all signals active at the time of the fault for six seconds and then indicate the channels involved in the fault for 2 seconds. 3.3 FIELD CHECK STATUS DISPLAY The FIELD CHECK FAIL indicator shall illuminate when a Field Check Fault is detected. The Channel Status display shall show the channels on which the Field Check fault occurred. If Field Check errors occurred during a Conflict Fault, Red Fail, Clearance Fail, or Dual Indication Fail the FIELD CHECK STATUS indicator shall illuminate. The channels on which the Field Check Status was detected during the fault shall double pulse on the Channel Status Display at the same time as the FIELD CHECK STATUS indicator. 3.4 RECURRENT PULSE STATUS DISPLAY If Recurrent Pulse inputs were detected during a Conflict Fault, Red Fail, or Dual Indication Fail the RECURRENT PULSE STATUS indicator shall illuminate. The channels on which the Recurrent Pulse Status was detected during the fault shall double pulse on the Channel Status Display at the same time as the RECURRENT PULSE STATUS indicator. 3.5 DISPLAY INDICATORS The following display indicators shall be provided in addition to those required by the NEMA Standard Section 4. 3.5.1 TYPE 12 MODE INDICATOR The TYPE 12 indicator shall illuminate when the MMU is programmed for Type 12 operation. If a Type Fault is detected the DIAGNOSTIC indicator shall illuminate and the TYPE 12 indicator shall flash at a rate of 2Hz. 3.5.2 DUAL INDICATION The DUAL INDICATION indicator shall illuminate when a DUAL INDICATION Fault is detected. The Channel Status display shall show the channels which were detected as DUAL INDICATION. 3.5.3 POWER INDICATOR The POWER indicator shall flash at a rate of 2Hz when the AC LINE voltage is below the drop-out level. It shall illuminate steadily when the AC LINE voltage returns above the restore level. 3.5.4 PORT 1 RECEIVE INDICATOR The RECEIVE indicator shall illuminate for a 33 msec pulse each time a Port 1 message is correctly received from the Controller Unit. SP 14 3.5.5 PORT 1 TRANSMIT INDICATOR The TRANSMIT indicator shall illuminate for a 33 msec pulse each time a Port 1 message is transmitted from the MMU. 3.5.6 RS232 RECEIVE INDICATOR The COMM indicator shall illuminate for a 33 msec pulse each time a message is correctly received on the RS-232 port. 3.5.7 PROGRAM CARD / CF INDICATOR The PGM CARD indicator shall illuminate if the Programming Card is absent or not seated properly in the edge connector. The PGM CARD indicator shall flash at a 4 Hz rate if the MMU has been triggered by a Configuration Change fault. 3.5.8 Y+R CLEARANCE INDICATOR The Y+R CLEARANCE indicator shall illuminate when the MMU has been triggered by a Yellow Change plus Red Clearance fault. 3.5.9 FIELD CHECK FAIL INDICATOR The FIELD CHECK FAIL indicator shall illuminate when the MMU has been triggered by a Field Check fault. 3.6 OPERATING MODES The MMU shall operate in both the Type 12 mode and Type 16 mode as required by the NEMA Standard. 4. HARDWARE 4.1 ENCLOSURE 4.1.1 The MMU shall be compact so as to fit in limited cabinet space. It shall be possible to install on a shelf that is at least 7" deep. Overall dimensions, including mating connectors and harness, shall not exceed 10.5" x 4.5" x 11" (H x W x D). 4.1.2 The enclosure shall be constructed of sheet aluminum with a minimum thickness of 0.062", and shall be finished with an attractive and durable protective coating. Model, serial number, and program information shall be permanently displayed on the top surface. 4.2 ELECTRONICS 4.2.1 A microprocessor shall be used for all timing and control functions. Continuing operation of the microprocessor shall be verified by an independent monitor circuit, which shall force the OUTPUT RELAY to the de- energized "fault" state and indicate an error message if a pulse is not received from the microprocessor within a defined period not to exceed 500 ms. 4.2.2 High speed sampling techniques shall be used to determine the true RMS value of the AC field inputs. Each AC input shall be sampled at least 32 SP 15 times per line cycle. The RMS voltage measurement shall be insensitive to phase, frequency, and waveform distortion. 4.2.3 In the interest of reliability, only the PROM memory device for the microprocessor firmware shall be socket mounted. The PROM Memory socket shall be a precision screw machine type socket with a gold contact finish providing a reliable gas tight seal. Low insertion force sockets or sockets with "wiper" type contacts shall not be acceptable. 4.2.4 All user programmed configuration settings shall be stored in an electrically erasable programmable read-only memory (EEPROM) or front panel DIP switches. Designs using a battery to maintain configuration data shall not be acceptable. 4.2.5 All 120 VAC field terminal inputs shall provide an input impedance of at least 150K ohms and be terminated with a resistor having a power dissipation rating of 0.5 Watts or greater. 4.2.6 All electrical components used in the MMU shall be rated by the component manufacturer to operate over the full NEMA temperature range of -34oC to +74oC. 4.2.7 All printed circuit boards shall meet the requirements of the NEMA Standard plus the following requirements to enhance reliability: a. All plated-through holes and exposed circuit traces shall be plated with solder. b. Both sides of the printed circuit board shall be covered with a solder mask material. c. The circuit reference designation for all components and the polarity of all capacitors and diodes shall be clearly marked adjacent to the component. Pin #1 for all integrated circuit packages shall be designated on both sides of all printed circuit boards. d. All electrical mating surfaces shall be gold plated. e. All printed circuit board assemblies shall be coated on both sides with a clear moisture-proof and fungus-proof sealant. 4.3 FRONT PANEL & CONNECTORS 4.3.1 All displays, configuration switches, and connectors shall be mounted on the front panel of the MMU. All MMU configuration inputs beyond those required by the NEMA Standard shall be provided by front panel mounted DIP switches and shall be clearly labeled. Configuration DIP switches shall be provided for the following functions: a. Field Check / Dual Enables 1-16 b. GY-Dual Indication Enable (GY ENABLE) c. Recurrent Pulse Test Disable (RP DISABLE) d. External Watchdog Enable (WD ENABLE) e. Walk Disable (Type 12) f. Configuration Change Fault Enable (CF ENABLE) g. CVM Log Disable SP 16 4.3.2 MS CONNECTORS The MS connectors on the MMU shall have a metallic shell and be attached to the chassis internally. The connectors shall be mounted on the front of the unit in accordance with the following: Connector A shall intermate with a MS 3116 22-55 SZ, and Connector B shall intermate with a MS 3116 16-26 S. In the interest of reliability and repair ability, printed circuit board mounted MS connectors shall not be acceptable. Internal MS harness wire shall be a minimum of AWG #22, 19 strands. 4.3.3 EIA-232 PORT The EIA-232 port shall be electrically isolated from the MMU electronics using optical couplers. The connector shall be an AMP 9721A or equivalent 9 pin metal shell D subminiature type with female contacts. Pin assignments shall be as shown in the following table: PIN FUNCTION 1 DCD* 2 TX DATA 3 RX DATA 4 DTR (Data Terminal Ready) 5 SIGNAL GROUND 6 DSR* 7 DSR* 8 CTS* 9 NC *Jumper options shall be provided to allow the connection of Pin #4 to be made with Pin #7, and the connection of Pin #8 to be made with Pin #1 and or Pin #6. 5 EVENT LOGGING FUNCTIONS The Signal Monitor shall be capable of storing in non-volatile memory a minimum of 100 events. Each event shall be marked with the time and date of the event. These events shall consist of fault events, AC Line events, reset events, and configuration change events. The capability to assign a four digit identification number and 30 character description to the unit shall be provided. The event logs shall be uploaded to a PC using the serial port of the Signal Monitor and Windows 9x based software provided by the manufacturer. Each event log report shall contain the following information: a) Monitor ID#: a four digit (0000-9999) ID number and 30 character description assigned to the monitor. b) Time and Date: time and date of occurrence. c) Event Number: identifies the record number in the log. Event #1 is the most recent event. 5.1 MONITOR STATUS REPORT (CS) The Current Status report shall contain the following information: a) Fault Type: the fault type description. SP 17 b) Field Status: the current GYR(W) field status and field RMS voltages if the monitor is not in the fault state, or the latched field status and field RMS voltages and fault channel status at the time of the fault. c) Cabinet Temperature: the current temperature if the monitor is not in the fault state, or the latched temperature at the time of the fault. d) AC Line Voltage: the current AC Line voltage and frequency if the monitor is not in the fault state, or the AC Line voltage and frequency at the time of the fault. e) Control Input Status: the current state and RMS voltages of the Red Enable input & Load Switch Flash bit input if the monitor is not in the fault state, or the status latched at the time of the fault. 5.2 PREVIOUS FAULT LOG (PF) The Previous Fault log shall contain the following information: a) Fault Type: the fault type description. b) Field Status: the latched field status with RMS voltages, fault channel status, RP Detect status and Field Check status at the time of the fault. c) Cabinet Temperature: the latched temperature at the time of the fault. d) AC Line Voltage: the AC Line voltage & frequency at the time of the fault. e) Control Input Status: the latched state of the Red Enable input at the time of the fault. 5.3 AC LINE EVENT LOG (AC) The AC Line log shall contain the following information: a) Event Type: describes the type of AC Line event that occurred. Power-up - AC on, monitor performed a cold start Interrupt - AC Line < Brownout level Restore - AC restored from AC brown-out or AC interruption (AC Off), no cold start · AC Line Voltage: the AC Line voltage & frequency at the time of the event. 5.4 MONITOR RESET LOG (MR) The Monitor Reset log shall contain the following information: a) The monitor was reset from a fault by the front panel Reset button, or External Reset input, or a non-latched event clear. 5.5 CONFIGURATION CHANGE LOG (CF) The Configuration Change log shall contain the following information: a. The status of all configuration programming including the contents of the Program Card, all configuration dip switches and option switches. b. Any configuration programming inputs such as 24V Inhibit, Port 1 Disable, Type select. c. Configuration CRC: A unique CRC value which is based on the configuration of items #a and #b above. The log shall also indicate which items have been changed since the last log entry. SP 18 5.6 SIGNAL SEQUENCE LOG (SSQ) A log shall be provided that graphically displays all field signal states for up to 30 seconds prior to the current fault trigger event. The resolution of the display shall be at least 50 milliseconds. SURGE PROTECTOR (LIGHTING ARRESTER) The controller shall have an input voltage surge protector that shall protect the controller input from any voltage surges that could damage the controller or any of its components. FIELD WIRING TERMINAL There shall be a terminal strip for field wiring in the controller cabinet. The terminals shall be numbered in accordance with the schematic wiring diagram on the Plans. If a different numbering system is used for the cabinet wiring, then both numbers shall label each terminal and the cabinet wiring schematic drawing shall include the field wiring numbers where the terminal strip is illustrated. A common bus bar with a minimum of 15 terminals and a ground bar with a minimum of 6 terminals shall be provided. COMPUTER INTERFACE UNIT Interface communication devices shall be designed as separate units or as modules that plug directly into the controller case. The communication devices shall be used for on-line computer control of the intersection and shall be capable of transmitting all detector and signal status information and receiving and decoding command information from the computer all in conformance and within the capability of the multisonic master computer unit or other central system as specified in the Plans and specifications and the interconnect cables. DOOR SWITCH A second door switch shall be provided to operate the cabinet light. WIRE COLOR SCHEME All 120VAC circuits shall use black wire. All other circuits shall not use black wires. ons. Red with white tracer wire is to be used for all 24VDC circuits, and white with red tracer for logic ground circuits. PREEMPTION INDICATOR LIGHT The preemption indicator light shall be energized when the emergency vehicle preemption system is in operation. Said light shall turn on when a phase is preempted and the priority green is displayed. There shall be one indicator light for each of the four emergency vehicle preempt channels. Opticom inputs/outputs need to be wired to green sense panel located on left side wall of the cabinet. POWER REQUIREMENTS The controller cabinet and all associated equipment shall be designed for use on 120 volts, 60 Hz., single phase alternating current. Main Panel Configuration (Load-Bay) The design of the panel shall conform to NEMA TS2 Section 5, Terminals and Facilities, unless modified herein. This panel shall be the termination point for the controller unit (CU) MSA,(MMU) MSA & B cables, bus interface units I & 2 (BIU) and field terminal facilities. The SP 19 terminal and facilities layout shall be arranged in a manner that allows all equipment in the cabinet and all screw terminals to be readily accessible by maintenance personnel. The load-bay shall be fully wired and meet the following requirements: • The load-bay shall have the following dimensions; constructed from aluminum with a nominal thickness of 0.125”, a maximum height of 24” and maximum width of 28.5”. The field tenninals width shall be 31.5” including attached wiring bundles. • The entire assembly shall roll down and provide access to all of the back of panel wiring. All solder terminals shall be accessible when the load-bay is rolled down. The assembly shall be able to roll down without requiring other components, cables or switches to be removed. • The load-bay shall be designed so that all other cabinet screw terminals are accessible without removing cabinet electronics. • All the controller (CU) and malfunction management (MMU) cables shall be routed through the back of the load-bay so that they will not be subject to damage during loadbay roll down. • The top of the load-bay panel shall attach directly to UnistmtTM spring nuts without the use of standoffs and spacers. • The load-bay shall be balanced such that it will not roll down when the UnistrutTM spring nuts are removed, even when fully loaded with BIUs load switches, flasher and flash transfer relays. • The load-bay facility shall be wired for 16 channels. Load switch(s) 1-8 shall be vehicle phases 1-8; load switch(s) 9-12 shall be pedestrian phases 2, 4. 6 & 8; load switches 13- 16 shall be overlaps A, B, C & D. Load switches 1-8 & 13-16 shall be routed through a flash transfer relay. • (16) Load switch sockets in two rows of(8) spaced on 2” center per NEMA TS2 section 5.3.1.2, figure 5-2. • (6) Flash transfer relay sockets. • (1) Flasher socket. • All load switches and flasher shall be supported by a bracket extending at least V the length of the load switch. • (2) Bus interface unit rack slots for BIU’s I and 2. The main panel BIU racks shall be left of the load switches, placed vertically with BIU 1 on top and BIU 2 on bottom. • BIU wires connection to the PCB shall be two (2) 34 pin connectors. These connectors shall have locking latches. • All BIU wiring shall be soldered to backside of a screw terminal. The screw terminals provide access to all functions of BIUs. • Wiring for one Type-16 MMU. All MMU wiring shall be soldered to backside of a screw terminal. The screw terminals provide access to all functions of the MMU. • All 24 VDC relays shall have the same base socket, but it shall be different from the 1 15VAC relays • Alt 11 5VAC relays shall have the same base socket, but it shall be different from the 24VDC relays. (not applicable to flash transfer relays) Shall have a relay that drops +24VDC to load switches when the cabinet is in flash. The load bay shall have terminals to access the flash circuits I and 2. There shall be a wire between the pedestrian yellow field terminals and another terminal on the load bay. The MMU channel 9-12 yellows shall terminate next to said pedestrian yellows terminal. • The load-bay shall be silkscreened on both sides. Silkscreen shall be numbers and functions on the front side, and numbers only on the back side. • Field wiring terminations shall be per channel across the bottom of the load-bay. Each SP 20 channel shall have 3 terminations corresponding to the appropriate vehicle phase Red, Yellow and Green. Default wiring shall be left to right vehicle phases 1-8, pedestrian phases 2, 4, 6 & 8 and overlap channels A, B, C & D following the order of the load switches. Field terminals shall be #10 screw terminal and be rated for 600V. • All cable wires shall be terminated. No tie-off of unused terminals will be allowed. • Shall be 100°/b manufactured in the United States of America All wiring shall conform to NEMA TS2 Section 5.2.5 and table 5-1. Conductors shall conform to military specification MIL-W-l6878D, Electrical insulated high heat wire, type B. Conductors #14 or larger shall be permitted to be UL type THHN. Main panel wiring shall conform to the following colors and minimum wire sizes: Vehicle green load switch output 14 gauge brown Vehicle yellow load switch output 14 gauge yellow Vehicle red load switch output 14 gauge red Pedestrian Don’t Walk switch 14 gauge orange Pedestrian Walk switch 14 gauge blue Pedestrian Clearance load switch 14 gauge yellow Vehicle green load switch input 22 gauge brown Vehicle yellow load switch input 22 gauge yellow Vehicle red load switch input 22 gauge red Pedestrian Don’t Walk input 22 gauge orange Pedestrian Walk input 22 gauge blue Pedestrian Clearance input 22 gauge yellow Logic Ground 18 gauge white with red tracer +24V DC 18 gauge red with white tracer +12VDC 18 gauge pink AC+ Line 14 gauge black AC- Line 14 gauge white Earth Ground 16 gauge green AC line (load bay) 12/14 gauge black AC neutral (load bay) 12-14 gauge white Controller A cables 22 gauge blue with the exception of power wires (AC+ Black, AC- White & Earth Ground Green) These wires shall be 18A WG MMU A & B cables 22 gauge orange with the exception of power wires (AC+ Black, AC- White & Earth Ground Green Start Delay Relay Common Black, Normally open Black & Normally Closed Black) These wires shall be I8AWG Four conductors will supply alternating current (AC) power to the load switch sockets. The load switch sockets shall be supplied 1-4, 5-8, 9-12 & 13-16 by each conductor. SP 21 The field terminal blocks shall have a screw Type No. 10 post capable of accepting no less than 3 No. 12 AWG wires fitted with spade connectors. four (4) 12-position terminal blocks shall be provided in a single row across the bottom of the main panel. Spade lugs from internal cabinet wiring are not allowed on field terminal screws. There shall be a second row of four (4) 12- position terminal blocks with screw type #10 above the field terminal blocks. These blocks shall operate the flash program. It shall be changeable from the front of the load bay. The terminal block above the Pedestrian field blocks shall be tied to the Don’t Walks and Walks with orange and blue I4AWG wire. This shall provide termination for pushbutton control wires without utilizing field terminals. The power terminal blocks shall have a screw Type No. 10 post capable of accepting no tess than 3 No. 12 AWG wires fitted with spade connectors. One (1) 12-position terminal block and one (1) 6-position terminal block shall be provided vertically on the right side of the load bay. The placement of the power terminal block on any other panel shall not be allowed. All load switches, flasher, and flash transfer relay sockets shall be marked and mounted with screws. Rivets and clip-mounting is unacceptable. Wire size 16 AWG or smaller at solder joints shall be hooked or looped around the eyelet or terminal block post prior to soldering to ensure circuit integrity. All wires shall have lugs or terminal fittings when not soldered. Lap joint/tack on soldering is not acceptable. All soldered connections shall be made with 60’40 solder and non-corrosive, non-conductive flux. All wiring shall be run neatly and shall use mechanical clamps and conductors shall not be spliced between terminations. Cable shall be sleeved in braded nylon mesh and wires shall not be exposed. Auxiliary Panel The cabinet shall include an auxiliary switch panel mounted to the interior side of the police panel compartment on the cabinet door. The panel shall be secured to the police panel compartment by (2) screws and shall be hinged at the bottom to allow access to the soldered side of the switches with the use of only a Phillips screwdriver. Both sides of the panel shall be silkscreened. Silk-screening on the backside of the switch panel shall be upside down so that when the panel is opened for maintenance the silk-screening will be right side up. All of the switches shall be protected by a hinged see-through Plexiglas cover. At a minimum the following switches shall be included; Controller ON/Off Switch: There shall be a switch that renders the controller and load-switching devices electrically dead while maintaining flashing operations for purpose of changing the controller or load-switching devices. The switch shall be a general-purpose bat style toggle switch with .688-inch long bat. Stop Time Switch: There shall be a 3-position switch labeled “Normal” (up), “Off’ (center), and “On” (down). With the switch in the “Normal” position, a stop timing command shall be applied to the controller by the police flash switch or the MMU (Malfunction Management Unit). When the switch is in its “Of?’ position, stop timing commands shall be removed from the controller. The “On” position shall cause the controller to stop time. The switch shall be a general-purpose bat style toggle switch with .688-inch long bat. SP 22 Technician flash Switch: There shall be a switch that places the field signal displays in flashing operation while the controller continues to operate. This flash shalt have no effect on the operation of the controller or MMU. The switch shall be a general-purpose bat style toggle switch with .688-inch long bat. Signals ON/OFF Switch: There shall be a switch that renders the field signal displays electrically dead while maintaining controller operation for purpose of monitoring controller operations. The switch shall be a general-purpose bat style toggle switch with .688-inch long bat. Vehicle Test Switches: All eight vehicle phase inputs shall have a 2 position switches labeled “Off’ (up), “On” (down). With the switch in the “On” position a constant input shall be applied to the controller. The switches shall directly input a call to the related controller vehicle phase without Touting the call through the detector rack(s). These switches shall be labeled 1, 2, 3, 4, 5, 6, 7 and 8. Pedestrian Test Switches: All eight pedestrian phase inputs shall have a 2 position switches labeled “Off’ (up), “On” (down). With the switch in the “On” position a constant input shall be applied to the controlter. The switches shall directly input a call to the related controller pedestrian phase. These switches shall be labeled 1, 2, 3, 4, 5, 6, 7 and 8. Ventilating Fans The cabinet shalt be provided with two (2) finger safe fan mounted on the right and left sides of the cabinet plenum, and shall be thermostatically controlled (adjustable between 4-176° Fahrenheit). The safe touch thermostat fuse holder and power terminal block(s) shall be din rail mounted on right side of cabinet plenum. Detector Racks At a minimum, the cabinet shall be wired to accommodate (32) channels of detection. One detector rack shall support (16) channels of loop detection, (1) Buss Interface Unit (BIU) and (4) channel of OpticomTM. One detector rack shall support (16) channels of loop detection and one (1) Buss Interface Unit (BIU). Racks shall be capable of using both two channel or four channel detection devices or OpticomTM cards. The loop cabling shall be connected via a 37 pin DB connector using spring clips. The Opticom cable shall be connected via a 24 pin connector using locking latches. The power cable shall be a 6 pin connector. All power wires shall be 1 8AWG. The addressing of detector racks shall be accomplished via dipswitches mounted to the PCB. There shall be the capability to turn off the TS2 status to the BIU for the uses of TSI detector equipment via dipswitches mounted to the PCB. There shall be a 34 pin connector using locking latches that breaks the output from the detector to the input of the BIU, there shall also be +24VDC and logic ground on this connector. All racks shall have space at the bottom front for labeling. All racks shall be designed for horizontal stacking. Separate racks for detection and preemption are not allowed. FLASH TRANSFER RELAY Flash transfer relays shall be provided with each cabinet. Six (6) each shall be supplied with the Type ‘P’ cabinet. A thin copper disc called a non-freeze pin shall be included in the relay SP 23 design to combat the residual magnetism phenomena. The uses of tape, plastic or dimples are not acceptable solutions. LOADSWITCHES The load switches shall be a three-(3) function NEMA and shall have LED indicator lights that show the input side of the relay. The unit shall be rated for a minimum of ten (10) amps per circuit through the entire NEMA temperature range. DETECTOR CARD CAGE The detector card cage shall be a completely enclosed assembly. It shall have 12 positions and wired for two channel detector amps as specified in section 9-29.18. The last two card cage slots shall be wired for the emergency pre-emption modules described in section 9- 29.13(3). The detector power supply(s) shall occupy the first two slots of the card cage. UNIVERSAL PROGRAM PANEL The controller cabinet shall be provided with a raised universal Program Panel, with connectors attached in lieu of a “D” cable. A cable shall be provided to work with the controller specified. The attached connectors and pin assignments shall be consistent with existing standards. The panel shall contain 2 dual surge suppressors, SRA64. These are to be wired for protection of the telemetry lines. The panel shall contain ten 20 position feed through terminal blocks, and one 6 position terminal block. The function and layout of these terminal blocks shall be consistent with existing standards. The first block shall be used to input to the controllers normal 8 phase inputs on the A, B and C cables. Pull up resistors shall be provided on this block to insure compatibility with both TS1 and TS2 detectors. The second and third blocks shall be the detector out puts from the card cage(s). The fourth block shall be the detector inputs to the “D” cable. The fifth and seventh blocks shall be the green inputs into the card cages. The sixth block shall have the controller greens and reds. The remaining blocks shall have miscellaneous “D” functions laid out consistent with existing standards. The panel shall be a Cascade Signal Corporation assembly # 564 or a pre- approved equal. The “D” cable provided must work with an Eagle M-50 controller. The table below indicates the standard field detector numbers and the standard controller detector numbers. CABINET QUALITY The cabinet shall be compliant to both mechanical and function specification prior to being shipped to owner. 1. Cabinet and hardware will comply with project specification. 2. Function compliance will be tested with power applied. 3. All cabinet and loadbay functions will pass point-to-point tests including expansion requirements. 4. All field detector inputs must be checked from field connection point to controller. Cabinet issues and clarifications need to be documented and addressed prior to Delivery. This agency will NOT provide QA or testing service for the delivered cabinet. Testing done by this agency is not in lieu of manufacturer test requirements. Cabinet Enclosure SP 24 At a minimum the cabinets shall meet the following criteria: 1. It shall have nominal dimensions of 56” high x 44” width x 25.5” depth and meet the footprint dimensions as specified in Section 7.3, table 7-1 ofNEMA TS2 standards for a Type P cabinet. The cabinet base shall have continuously welded interior mounting reinforcement plates with the same anchor bolt hole pattern as the fbotprint dimensions. 2. Shall be fabricated from 5052-H32 0.1 25-inch thick aluminmn. 3. The cabinet shall be double-flanged where it meets the cabinet door. 4. The top of the cabinet shall be sloped 1” towards the rear to facilitate water runoff And shall bend at a 90° angle at the front of the cabinet. Lesser slope angles are not allowed. 5. The inside of the cabinet shall have (2) separate compartments. The main compartment shall be accessible from the front door and shall house the cabinet load facilities and electronics. The BBS compartment shall be accessible from the side door and shall contain the UPS system batteries. The UPS system inverter and ATS assembly shall be mounted in the BBS compartment but shall be accessible when the front door is open. 6. The inside of the cabinet shall utilize C channel rails. (2) Welded on the back wall on 25” center and (4) welded on each side wall on 08” center with 2” between sets. The C channel rails on the back wall shall be 48” in length and start 5” from the bottom of the cabinet interior. The C channel rails on the side walls shall be 48” in length and start 5” from the bottom of the cabinet interior. Adjustable rails are not allowed. 7. The Cabinet shall be supplied with the following finishes; the interior natural mill finish. The exterior natural mill finish. 8. All external fasteners shall be stainless steel. Pop rivets shall not be allowed on any external surface. 9. The front door handle shall be “round stock stainless steel bar. The side door shall use a recessed hexagonal socket in lieu of a door handle. All door handle mechanisms shall be interchangeable and field replaceable. 10. The front door shall contain (2) flush mount locking recessed compartments. The upper compartment that houses a police door and a lower compartment that houses a generator bypass receptacle. A stiffener plate shall be welded to the inside of the front door to prevent flexing. It shalt have a two-position, three-point door stop that accommodates open-angles at 900, 125°, and 1500. A louvered air entrance located at the bottom of the main door shall satisfy NEMA rod entry test requirements for 3R ventilated enclosures. Bearing rollers shall be applied to ends of door latches to discourage metal-on-metal surfaces from rubbing. The main front door lock assembly shall be positioned so the door handle does not cause interference with the key when opening the door. 11. The police door compartment shall come with a conventional police lock. 12. The generator bypass receptacle compartment shall be equipped with a universal lock bracket capable of accepting a BestTM style lock and a Corbin #2 tumbler series lock. The lock shall be a tapered lock using a Best style lock or Corbin #2 series core. The door shall have an integrated door slide mechanism that allows the door to be closed and locked after a generator has been connected to the internal receptacle. This compartment is used by maintenance personnel for emergency generator operation in the absence of service power or BBS control. 13. The side door shall be one piece construction without any recessed compartments. It shall have a three-position, two-point door stop that accommodates open-angles at roughly 80°, 100°, and 120°. A louvered air entrance located at the bottom of the side door shalt satisfy NEMA rod entry test requirements for 3R ventilated enclosures. Bearing rollers shall be applied to ends of door latches to discourage metal-on-metal surfaces from SP 25 rubbing. Lock assembly shall be positioned so handle does not cause interference with key when opening the door. 14. Closed-cell, neoprene gaskets shall be bonded to the inside of the cabinet doors. The gaskets shall cover all areas where the doors contact the double flanged cabinet housing exterior and be thick enough to provide a watertight seal. 15. A complete set of keys shall be supplied providing access to the cabinet front door, cabinet side door, the police door and the generator receptacle door. 16. The cabinet shall be equipped with a universal lock brackets capable of accepting a BestTM style lock and a Corbin #2 tumbler series lock. The cabinet shall come equipped with a BestTM style lock. 17. The cabinet shall be supplied with three (3) door switches which control the door and police door open status and the cabinet interior lighting circuits. 18. All exterior seams shall be manufactured with a neatly formed continuously weld construction. The weld for the police and generator bypass box door shall be done on the inside of the cabinet door. All welds shall be free from burrs, cracks, blowlioles or other irregularities. 19. The fan baffle panel seams shall be sealed with RTV sealant or equivalent material on the interior of the cabinet. 20. The cabinet shall be UL listed. 21. The cabinet shall come with lifting ears affixed to the upper exterior of the cabinet. These ears shall utilize only one bolt for easy reorientation. (The cabinet flfling ears shall not be used when the batteries are installed,. 22. The cabinet shall come with two (2) three-stage, multi-ply progressive density polyester, disposable air filter; and the filter performance shall conform to listed UL 900 Class 2 and conform to ASKRAE Standard 52.1. The filter element shall be secured to louvered entrance on main door and side door with Velcro type mounting on alt four edges. 23. All cabinet doors shall be mounted with a single continuous stainless steel piano hinge that runs the length of the door. The hinge shall be attaching via stainless steel tamper resistant bolts. 24. All steel incorporated in the cabinet shell shall be manufactured in the United States of America, and shall meet the requirements of Section 1605 of the American Recovery and 25. The cabinet enclosure shall be a P+ style Western Systems Part #3012500000. Cabinet mounting and installation The foundation for a cabinet shall be a concrete pedestal of the same size as the base of the cabinet with one foot of the foundation above the adjacent grade. The pedestal shall be poured in place and shall be 12 inches below grade and 12 inches above grade. A sidewalk shall be provided on all sides of a cabinet and poured in place with the cabinet foundation. Refer to Cabinet Foundation details on project Plans for concrete pedestals where multiple cabinets are to be installed on one pad. 9-29.16(2) Conventional Traffic Signal Heads Section 9-29.16(2) is supplemented by adding the following: (******) Vehicular signal heads shall have 12 inch lens sizes unless shown otherwise on the signal Plans. Signal heads shall be manufactured by McCain. Each signal head shall have a 1/4 inch drain hole in its base. SP 26 Signal heads shall be mounted on the mast arm such that the red indicators lie in the same plane and such that the bottom of the housing of a signal head shall not be less than 16 feet 6 inches nor more than 18 feet 6 inches above the grade at the center of the roadway. 9-29.16(2)A Optical Units Section 9-29.16(2)A has been revised as follows: (******) Light Emitting Diode (LED) light sources are required for all displays. 9-29.16(2)B Signal Housing The fifth paragraph of Section 9-29.16(2)B has been revised as follows: (******) Each lens shall be protected with a removable visor. The visor shall be tunnel type unless noted otherwise in the contract. Tunnel, cap, and cut away type visors shall be made of aluminum throughout. Visors shall be flat black in color inside and shall be yellow baked enamel on the outside. Visors shall have attaching ears for installation to the housing door. The signal display shall have square doors. End caps shall be made from aluminum and shall be installed with fittings to provide a watertight seal. A bead of silicone sealant shall be applied around the perimeter of all top end cap openings prior to installation of the end cap assembly. Plastic end caps shall utilize a threaded stud with seal and wing nut. End caps shall have the same color as the signal housing. 9-29.16(2)C Louvered Visors Section 9-29.16(2)C has been revised as follows: (******) Where noted in the Contract, louvered tunnel visors shall be furnished and installed. Directional louvers shall be constructed to have a snug fit in the signal visor. The outside cylinder shall be constructed of aluminum, and the louvers shall be constructed of anodized aluminum painted flat black. Dimensions and arrangement of louvers shall be as shown in the contract. 9-29.16(2)D Back Plates Section 9-29.16(2)d has been deleted and replaced with: (******) Back plates shall be furnished and attached to the signal heads. Back plates shall be 3-S half-hard aluminum sheet, 0.058-inch minimum thickness, with 5-inch square cut border and painted black in front and yellow in back. Back plates shall have 1” reflective yellow tape boarder. 9-29.16(2)E Painting Signal Heads Section 9-29.16(2)E has been revised as follows: (******) Traffic signal heads (vehicle and pedestrian) shall be finished with two coats of factory applied traffic signal federal yellow baked enamel or shall be finished with a traffic signal federal yellow oven baked powder coating comprised of resins and pigments. Aluminum end caps and the back of back plates shall be painted to match the color of the signal housing. The inside of visors, front of back plates, and louvers shall be finished with two coats of factory applied flat black enamel. 9-29.17 Signal Head Mounting Brackets and Fittings Section 9-29.17 is replaced as follows: (******) Mounting hardware will provide for a rigid connection between the signal head and mast arm. All mounting hardware will be of the top-mount plumbizer type as shown on the standard Plans, unless specified otherwise on the Plans. Vehicle and pedestrian signal head mountings shall be as detailed in the Standard Plans. Material requirements for signal head mounts are as follows: Aluminum SP 27 1. Arms and slotted tube fittings for Type N mount (temporary signals only). 2. Tube clamp and female clamp assembly for Type N mount. Bronze 1. Terminal compartments for Type A, B, C, F, H, and K mounts. 2. Collars for Type C, D, and F mounts. 3. Ell fittings for Type L and LE mounts. 4. Messenger hanger and wire entrance fittings for Type P, Q, R, and S mounts. 5. Balance adjuster for Type Q, R, and S mounts. Galvanized Steel 1. Washers for Type A, B, C, D, F, H, and K mounts. 2. Fasteners for Type A, B, E, H, and K mounts. Stainless Steel 1. All set screws and cotter Keys. 2. Bands for Type N mount. 3. Bolt, nut and washers for Type L mount. 4. Bolts, nuts, washers, and screw buckle swivels. Steel 1. Center pipes, nipples, elbow and tee fittings for Type A, B, C, F, H, and K mounts. 2. Nipples for Type L, LE, and P mounts. All other miscellaneous hardware shall be stainless steel. All hardware for mounts shall be painted with two coats of factory applied traffic signal federal yellow baked enamel. Pins for messenger hanger fittings shall be a minimum of 1 /2 inch in diameter. Terminal compartments for Type A, B, C, F, H, and K mounts shall contain a 12 section terminal block. All hardware for mounts shall be painted with two coats of factory applied traffic signal Federal yellow baked enamel. 9-29.18(1) Induction Loop Detectors Section 9-29.18(1) is replaced with: (******) 4 Channel Rack Mount Detector Specifications: The detector shall be a Reno A&E model C or a pre-approved equal meeting the following specifications: PHYSICAL Weight: 6 oz. (170 gm.). Size: 4.500 inches (11.43 cm.) high x 1.12 inches (2.84 cm.) wide x 6.875 inches (17.46 cm.) long including connector (not including front handle). Operating Temperature: -40°F to +180°F (-40°C to +82°C) Circuit Board: Printed circuit boards are 0.062in. FR4 material with 2 oz. copper on both sides and plated through holes. Circuit board and components are conformal coated with polyurethane. Connector: 2 x 22 pin edge card connector with 0.156-inch (0.396 cm.) contact centers. Key slots located between B & C and M & N. Loop Feeder Length: Up to 5000 feet (1500m.) maximum with proper feeder cable and appropriate loops. ELECTRICAL Power: 10.8 to 30 VDC, 120 mA max. Loop Inductance Range: 20 to 2500 microHenries with a Q factor of 5 or greater. Loop Inputs: Transformer isolated. The minimum capacitance added by the detector is 0.068 microFarad. SP 28 Lightning Protection: The detector shall be able to tolerate, without damage, a 10 microFarad capacitor charged to 2,000 volts being discharged directly into the loop input terminals, or a 10 microFarad capacitor charged to 2,000 volts being discharged between either loop terminal and earth ground. Reset: Shall meet and/or exceed NEMA TS 1 and TS 2 detector specifications. Application of a 30-millisecond low state (0 to 8 VDC) to pin C shall reset both channels. Each detector channel shall be manually reset by pressing the CHAN button until the desired channel is selected, then holding the CHAN button for 3 seconds, or by changing the sensitivity or loop frequency of the channel. Phase Green Inputs: Also known as Call Delay Overrides. Shall meet and/or exceed all NEMA TS 1 and TS 2 requirements. Application of a Low state voltage (0 to 8 VDC) to pin 1(Ch. 1) and/or pin 2 (Ch. 2) shall cause the delay timer for the channel to abort the delay timing function and also provide control for Phase Green Loop Compensation, Max Presence Timing (End-of-Green), Extension timing, and Detector Disconnect, if the features are programmed. Fail-Safe Outputs: Per NEMA TS 2 - conducting state indicates detection output. Each detector channel output shall default to a CALL state for any loop failure condition or loss of power. Channel Status Outputs: Per NEMA TS 2 - Each channel shall have an output to communicate the status states of the channel as follows: Normal operation Continuous Low or On State Detector failure Continuous High or Off State Open loop 50 millisecond On time, 50 millisecond Off time Shorted loop 50 millisecond On time, 100 millisecond Off time Excessive inductance change (±25%) 50 millisecond On time, 150 millisecond Off time Solid State Output Ratings: Shall be optically coupled field effect transistors. 30 VDC max. drain to source. 50 mA. max. current. The output transistor shall be protected with a 33-volt zener diode connected between the drain and source. OPERATIONAL Display: Shall be LCD and back lighted whenever any push button is pressed. The back lighting shall extinguish 15 minutes after the last actuation of any push button. Detect Indicators: Each channel shall have an super high intensity red light emitting diode (LED) to indicate a CALL output, Delay Timing, Extension Timing, Pending state, or failed loop. Response Time: Shall Meet or exceed NEMA TS 1 and TS 2 response time specifications. Self-Tuning: The detector shall automatically tune and be operational within 2 seconds after application of power or after being reset. Environmental & Tracking: The detector shall be fully self-compensating for environmental changes and loop drift over the full temperature range and the entire loop inductance range. Grounded Loop Operation: The loop isolation transformer shall allow operation with poor quality loops (which may include one short to ground at a single point). Loop (Fail) Monitor: If the total inductance of the channel’s loop input network goes out of the range specified for the detector, or rapidly changes by more than ±25%, the channel shall immediately enter the Fail-Safe mode and display “LOOP FAIL” on the LCD. The type of loop failure shall also be displayed as “L lo” (for -25% change or shorted loop conditions) or “L hi” (for +25% change or open loop conditions). This will continue as long as the loop fault exists. The Fail-Safe mode shall generate a continuous call in Presence Mode or in Pulse Mode. At the time of a loop failure, the channel’s LED shall begin repeating a burst of three flashes each one second. The LED shall continue these bursts until the channel is manually reset or power is removed. If the loop “self heals”, the LOOP FAIL message on the LCD shall extinguish and the channel will resume operation in a normal manner; except the LED shall continue the bursts thus providing an alert that a Loop Fail condition occurred. Each loop failure for the channel shall be counted and accumulated into the Loop Fail Memory. The total number of loop failures written into the Loop Fail Memory (since the last power interruption or manual reset) can be viewed by stepping through the channel’s functions in Program Mode to the “LOOP FAIL” message. SP 29 LOOP FREQUENCY There shall be eight (8) selectable loop frequency settings per channel (normally in the range of 20 to 100 kilohertz). The actual loop operating frequency shall be digitally displayed on the LCD. SENSITIVITY There shall be nine (9) selectable sensitivity levels per channel, plus Continuous-Call and Channel-Off. The sensitivity levels are to be designed so that a one level increase actually doubles the sensitivity and a one level decrease halves the sensitivity. A bar graph shall be displayed on the LCD to make it easy to quickly set the sensitivity to the ideal level for any loop/lead-in network situation. Continuous-Call: When set to the Continuous-Call state, the channel output shall be in the continuously call state regardless of the presence or absence of vehicles over the loop. The loop oscillator shall be disabled when in the “Continuous-Call State”. This state shall be indicated by CALL flashing on the LCD. This option shall be selected from the Sensitivity menu in Program Mode. Channel-Off: When set to the Channel-Off state, the channel output shall be continuously in the No-Call state regardless of the presence or absence of vehicles over the loop. The loop oscillator shall be disabled when in the “Channel-Off State”. This state shall be indicated by OFF flashing on the LCD. This option shall be selected from the Sensitivity menu in Program Mode. CALL DELAY Each channel’s Call Delay shall be adjustable from 0 to 255 seconds in 1-second steps. Call Delay time shall start counting down when a vehicle enters the loop detection zone. The remaining Call Delay time shall be continuously displayed on the LCD. Whenever a Phase Green Input (call delay override) signal (pins 1 or 2) is active (low state), the Call Delay function for that channel shall be aborted and the Call Delay time forced to zero. CALL EXTENSION Each channel’s Call Extension shall be adjustable from 0 to 25.5 seconds in 0.1-second steps. Extension time shall start counting down when the last vehicle clears the loop detection zone. The remaining Extension time shall be continuously displayed on the LCD. Any vehicle entering the loop detection zone during the Extension time period shall cause the channel to return to the Detect state, and later, when the last vehicle clears the loop detection zone, the full Extension time shall start counting down again. PRESENCE/PULSE One of two mutually exclusive modes of operation for each channel shall be available. Presence or Pulse mode shall be toggled by momentarily pressing either the up or down button. Presence Mode: Will provide a Call hold time of at least 4 minutes (regardless of vehicle size) and typically 1 to 3 hours for an automobile or truck. Pulse Mode: An output Pulse of 125±10 milliseconds duration shall be generated for each vehicle entering the loop detection zone. Each detected vehicle shall be instantly tuned out if it remains in the loop detection zone longer than 2 seconds. After each vehicle leaves the loop detection zone, the channel shall resume full sensitivity within 0.5 seconds. MAX PRESENCE TIMER Each channel’s Max Presence timer shall be adjustable from 1 to 999 seconds in 1-second steps, plus OFF. The Max Presence function is used to limit presence time, by automatically resetting a channel. If this function is enabled (on), the Max Presence timer begins counting down when a Call is initiated and the remaining time is continuously displayed on the LCD. If the loop becomes vacant before the Max Presence timer reaches zero, the Call is dropped and no automatic reset occurs. If the End-Of-Green (EOG) function is not enabled (off) and the Call is still present when the Max Presence timer reaches zero, the channel then is automatically reset. If the EOG function is enabled (on) and the Call is still present when the Max Presence timer reaches zero, the channel enters a “Wait” state. The Wait state continues until either the loop becomes vacant or the Phase Green Input signal for the channel (pin 1 or 2) transitions from green to not green with the Call still present. If the loop SP 30 becomes vacant first, the Call is dropped and no automatic reset occurs. If the Phase Green Input for the channel transitions from green to not green while the channel is in a Wait state, the channel is automatically reset. The signals on pins 1 and 2 are also called Call Delay Overrides. END-OF-GREEN (EOG) Each channel’s EOG setting can be toggled ON or OFF by momentarily pressing either the up or down button. The EOG function is used to synchronize resetting of a channel with the termination of the associated phase green. The EOG function is only available when the Max Presence function is set between 1 and 999 seconds. It is not available when the Max Presence function is OFF. When the EOG function is enabled (ON), the channel will automatically be reset at the time the phase green input signal (pin 1 or 2) transitions from the ON state to the OFF state, if the Max Presence Time has counted down to zero and is resting in the wait state. The signals on pins 1 and 2 are also called Call Delay Overrides. OPTION 1, LOOP INDUCTANCE DISPLAY The detector’s Loop Inductance Display setting shall be toggled ON or OFF by momentarily pressing either the up or down button. When this option is enabled (on), the LCD will display the total loop inductance (actual loop inductance plus actual lead-in inductance) in microHenries with an accuracy of ±3% for loop inductance values in the range of 20 to 2500 microHenries. NOTE: Enabling this option activates it for all channels. This option shall be automatically disabled 15 minutes after activation or on loss of power. OPTION 2, LOOP INDUCTANCE -DL/L DISPLAY The detector’s Loop Inductance -DL/L Display setting shall be toggled ON or OFF by momentarily pressing either the up or down button. When this option is enabled (on), the LCD displays the percentage of inductance change (-DL/L value) during the Call state. To facilitate the viewing of the maximum amount of change in the -DL/L value while traffic is in motion over the detection zone, the detector shall hold the peak -DL/L value for a period of 2 seconds. NOTE: Enabling this option activates it for both channels. This option shall be automatically disabled 15 minutes after activation or on loss of power. OPTION 3, CALL EXTENSION CONTROL Each channel’s Call Extension Control setting shall be toggled ON or OFF by momentarily pressing either the up or down button. When this option is enabled (on), the channel will extend calls for the programmed extension time only when the Phase Green Input signal (pin 1 or 2) is active for the channel. When this option is off, the channel shall extend ALL calls for the programmed extension time. The signals on pins 1 and 2 are also called Call Delay Overrides. OPTION 4, NORMAL/FAST RESPONSE MODE The detector’s Normal/Fast Response Mode setting shall be toggled ON or OFF by momentarily pressing either the up or down button. When this option is enabled (on), internal call filtering is disabled thus providing a faster response time. When this option is off, normal call filtering is used. NOTE: Turning this option ON will make it active for both channels. OPTION 5, PHASE GREEN LOOP COMPENSATION The detector’s Phase Green Loop Compensation setting shall be toggled ON or OFF by momentarily pressing either the up or down button. When Option 5 is enabled (on), normal loop compensation is used until the Phase Green Input signal (pin 1 or 2) becomes active. Once the Phase Green Input signal is active, the detector shall desensitizes the loop. Maximum desensitization shall not exceed 0.05% (-DL/L). This desensitization will “tune out” small changes, such as adjacent lane pick up therefore minimizing the chance for max timing an empty lane. When Option 5 is not enabled (off), normal loop compensation shall be used. OPTION 6, VEHICLE COUNTING DISPLAY (OPTIONAL OPTION) When Option 6.0 is enabled (on) for a channel, the normal operating display for that channel shall be replaced with the accumulated vehicle count. The unit shall be capable of accumulating 65,535 vehicle counts before rolling over to 0. The display will show just the SP 31 hundreds, tens, and ones digits until the accumulated count exceeds 999. At this point the display will alternate between the ten thousands and thousands digits and the remaining three digits for hundreds, tens, and ones. The accumulated vehicle count is cleared by loss of power or can be manually cleared using Option 6.1. Option 6.1 shall be used to reset the accumulated vehicle count for the selected channel. When Option 6.1 is changed from the off state to the on state, the accumulated vehicle count for the selected channel shall be reset to zero. Option 6.1 shall always be in the off state when first viewed. OPTION 7, VEHICLE COUNTING LOOP CONFIGURATION (OPTIONAL OPTION) The detector's Vehicle Counting Loop Configuration setting shall be set from 01 to 04 for each channel. This setting should indicate the number of loops installed in a single lane. 01 would indicate a single loop. This could be a single 6' x 6' or a long loop such as a 6' x 50' QuadrapoleTM. The remaining three settings indicate the number of 6' x 6' loops installed in a single lane of traffic. OPTION 8, COMMON FAIL OUTPUT (OPTIONAL OPTION) The Common Fail Output setting shall be toggled ON or OFF by momentarily pressing either the up or down button. The Common Fail Output setting shall be a "detector wide" option. This means that setting it to ON for any channel turns it ON for all channels, and setting it to OFF for any channel turns it OFF for all channels. When Option 8 is enabled (on), a failure on any channel in the detector will cause all of the fail outputs for the detector to activate. OPTION 9, THIRD CAR PASSAGE Each channel’s Third Car Passage setting can be toggled ON or OFF by momentarily pressing either the up or down button. Option 9 is a “paired channel” option. This means that it takes two channels to implement the feature. Therefore, when this option is toggled ON or OFF in one channel, its paired channel is also set to the same state. Option 9 shall be mutually exclusive with Option 10. Turning ON one option shall automatically turn OFF the other option. When Option 9 is enabled (on), the output of the paired channels shall be logically ANDed together. This means that while the loops for both of the paired channels are occupied, a call will output on both channels. While only one channel is occupied, or neither channel is occupied, a call will not output for either channel. The first channel with detection shall enter a “pending” state while waiting for detection in the other paired channel. While in the pending state, the LCD shall show “Pnd” on the display. OPTION 10, DIRECTIONAL LOGIC Each channel’s Directional Logic setting shall be toggled ON or OFF by momentarily pressing either the up or down button. Option 10 is a “paired channel” option. This means that it takes two channels to implement the feature. Therefore, when this option is toggled ON or OFF in one channel, its paired channel is also set to the same state. Option 9 shall be mutually exclusive with Option 10. Turning ON one option shall automatically turn OFF the other option. When Option 10 is enabled (on), directional logic shall be enabled. Direction logic starts with a detection on one channel. This channel shall go into the “pending” state, display “Pnd” on the LCD display, and NOT output a call. When both of the paired channels have detection, the last channel to have detection will output a Call until the detection for the last channel ends, even if the detection ends for the first channel. None of the timing functions of the first channel with a detection shall time (Delay, Extension, Max Presence, and Detector Disconnect) and the first channel shall always operate in the Presence Mode regardless of programming for the channel. The second channel with a detection shall time all timing functions as programmed. OPTION 11, AUDIBLE DETECT SIGNAL Each channel's, Audible Detect Signal setting shall be toggled ON or OFF by momentarily pressing either the up or down button. Only one channel can be turned on at a time. Turning this option on for one channel automatically turns it off for the other channel. When this option is enabled (on), an audible signal will be activated whenever the detection zone for the selected channel is occupied. The audible signal indicates actual occupancy of the SP 32 loop detection zone. Timing and disconnect functions shall have no effect on the audible signal. This option shall be automatically disabled 15 minutes after activation or on loss of power. OPTION 12, DETECTOR DISCONNECT Each channel's Detector Disconnect settings shall be toggled ON or OFF and the Extension timer toggled between ON and OFF by momentarily pressing either the up or down button. The Detector Disconnect feature requires that the Phase Green Inputs for each channel be connected to the proper controller phase. When the Phase Green Input is not active (high), the detector shall operate normally. When the Phase Green Input is active (low), at the end of each detection the extension timer will start to count down. If this timer reaches zero before the next detection, this channel will no longer output a call until the phase green input is not active. Because the extension timer is used as a disconnect timer while in this mode, two different disconnect types shall be available: Option 12.1 OFF - Extension timing occurs and the extension timer also serves as the disconnect timer during phase green. This will cause the Call output to remain in the Call state until disconnect occurs. Option 12.1 ON - Extension timing is disabled and the extension timer is used as the disconnect timer. This will cause the Call output to follow the occupancy of the loop detection zone until disconnect occurs. 9-29.18(3) Video Detection System Section 9-29.18(3) is a new section: (*****) The video detection camera housing and mounting hardware shall be painted per Section 6-07 of these Special Provisions. The fully functional video detection systems shall be provided and installed by the Contractor. The Contractor shall submit complete equipment list to the City Engineer for approval prior to the systems purchase. The video detection system shall be capable of providing presence vehicle detection and shall be expandable without removing or replacing existing units. All materials furnished during construction for temporary and permanent detection shall be new, unused, current production models and shall be items currently in distribution. The video detection system shall have a minimum 18-month warranty (from the time of permanent installation) against manufacturing defects in materials and workmanship from the date of shipment. The Contractor shall supply the warranty and all documentation necessary to maintain and operate the system to the Electrical Inspector prior to approval of the video detection system by the Electrical Inspector. The Video Detection System shall consist of ITERIS video detection equipment, auxiliary equipment, cameras, housings, and mounts, and all required mounting hardware, cables, connectors, and wiring. The video detection equipment shall be of the quantities shown in the Plans, and shall meet the following specifications (The contractor shall submit to the COR Field Maintenance Shop Representative a detailed summary of video detection equipment prior to placing an order): Camera: Vantage RZ-4 Advanced WDR color camera with integrated weatherproof housing or Vantage Vector with video and radar sensor fusion. Mounting: Pelco Astro-Brac Extended Tilt & Pan mount with cable mount and 72 inch tube. The cable mount shall be suitable for the mast arm diameter at each camera installation location. SP 33 Video Detection Board: Vantage Edge 2 – Dual Camera Processor Remote Monitoring: Vantage View (include 9” LCD color monitor at each signal and non rack mounted design. Modem: Edge Connect Network Modem Surge Suppression: Each camera assembly shall have a surge suppressor which shall be installed inside the traffic signal controller cabinet. The surge suppressor shall be an EDCO CX06-BNCY or equivalent meeting these specifications: Peak Surge Current 5Ka Technology Hybrid, Solid State Attenuation 0.1dB @ 10 Mhz Response Time <1 nanosecond Protection Line to Ground Clamp Voltage 6 V Connectors BNC Impedance 75 ohms Environmental -40°F to 185°F Mechanical 4½" x 1½" x 1¼" 9-29.19 Pedestrian Push Buttons Section 9-29.19 is replaced by the following: (*****) APS is a fully integrated pedestrian station that provides the pedestrian with visual, tactile and audible information about the intersection crossing at the pedestrian station. It is designed to monitor the CMU output signal to the walk display while utilizing the existing wires from the traffic control cabinet. APS push buttons shall be Polara I Navigator. 9-29.20(1) LED Pedestrian Displays Section 9-29.20(1) is supplemented with the following: (*****) SP 34 The pedestrian signal shall be hand/man with a countdown feature. The hand and man and countdown symbols shall have a uniform appearance; individual LEDs shall not be visible. The hand and man symbols shall be on the left side superimposed and the countdown symbol on the right side and shall comply with the latest MUTCD requirements. The countdown feature shall allow countdown time to remain stored internally, even when power is removed for extended periods of time, shall automatically adjust to traffic controller interval changes and the symbol shall be minimum 9 inches high. The housing shall be 18 inches and the face shall have z-crates. Except as noted in the following pre-approved list of this section, samples of each item shall be submitted to the Engineer for approval. 9-29.24 Service Cabinets Section 9-29.24 is replaced by the following: (******) The signal/street lighting service cabinet shall be Skyline or as indicated on the contract Plans and detail sheets. All electrical conductors, buss bars and conductor terminals shall be copper or brass. The cabinet shall be fabricated from galvanized cold rolled sheet steel, with 12 gauge used for exterior surfaces and 14 gauge for interior panels. Door hinges shall be the continuous concealed piano type and no screws, rivets or bolts shall be visible outside the enclosure. The cabinet door shall be fitted for a Best internal type lock. The cabinet shall have ventilation louvers on the lower and upper sides complete with screens, filters and have rain tight gaskets. The cabinet door shall have a one piece weather proof neoprene gasket. 9-29.24(1) Painting Section 9-29.24(1) is replaced with the following: (******) The finish coat shall be a factory baked on enamel light grey in color. The galvanized surface shall be etched before the baked on enamel is applied. The interior shall be given a finish coat of exterior grade of white metal enamel. Painting shall be done in conformance with the provisions of Section 8-20.3(12). 9-29.24(2) Electrical Circuit Breakers and Contactors Section 9-29.24(2) is deleted and replaced with the following: (******) The electrical circuit breakers and contactors shall be as indicated on the contract Plans and detail sheets. The following equipment shall be featured within the cabinet. 1. Main circuit breaker 2. Branch circuit breakers 3. Utility plug (120 volt-20 Amp rated) G.F.I. Type 4. Light control test switch (120 volt-15 Amp) 5. Contactor relay for each circuit 6. Double pole branch breaker(s) for lighting circuits (240 volt) 7. One 120 volt, 20 Amp single pole branch breaker (for utility plugs) 8. Type 3-single phase 120/240 volt grounded neutral service 9. One 120 volt 40 Amp single pole branch breaker (signal service) 10. Complete provisions for 16 breaker poles 11. Name plates phenolic black with white engraving except the main breaker which shall be red with white lettering. All name plates shall be attached by S.S. screws. 12. Meter base sections are unnecessary SP 35 9-29.25 Amplifier, Transformer, and Terminal Cabinets Section 9-29.25 is supplemented as follows: (******) The terminal box shall be weather tight, have a single door with continuous hinge on one side and screw hold-downs on the door locking side. All hardware will be stainless steel. All mounting hardware shall be stainless steel and shall be incidental to the unit price of terminal box. Terminal blocks shall be 600V heavy duty, barrier type. Each terminal shall be separated by a marker strip. The marker strip shall be permanently marked with the circuit number indicated in the Plans. Each connector shall be a screw type with No. 10 post capable of accepting no less than 3 #12 AWG wires fitted with spade tips. Interconnect splice tower cabinets shall be Type F, with nominal dimensions of 22" high x 13" wide x 11" deep and constructed of cast aluminum and fitted with a Best internal lock. 9 30 PAVEMENT MARKING Contractor shall notify the Engineer and request approval of the pre-mark channelization at least 48 hours prior to placement of pavement markings. All Pavement markings at intersection shall be 3M Stamark all weather Tape 380AW and Contrast Tape 380AWE-5. 9 30.1 Removing Pavement Markings Section 8-22.3(6) is supplemented with the following: Existing pavement markings within the construction limits, including stop bars, traffic arrows, lane markers, and raised pavement markers shall be removed prior to overlaying the roadway surface. All conflicting channelization shall be removed as necessary to install temporary pavement markings or after the final channelization has been installed. Removal of existing pavement markings shall be conducted using such methods to prevent damage to the remaining pavement. The use of chemicals that may be harmful to the pavement will not be allowed. Damaged pavement shall be replaced at the Contractor's 9 30.2 PERMANENT SIGNING 8-21.1 Description Section 8-21.1 is supplemented with the following: This work shall also consist of fabricating, assembling and installing Street Name Signs on signal mast arms in accordance with details shown in Plans and as specified herein. 9 30.3 Materials Section 8-21.2 is supplemented with the following: Materials shall meet the requirements of the following sections as applicable unless noted: Painting 6-07 Permanent Signing 8-21 Signing Materials and Fabrication 9-28 Lettering and border graphics shall be white, non-reflective, in an opaque, white 2-mil cast SP 36 vinyl adhesive graphic film with matte finish, clear, removable, pressure-sensitive adhesive (solvent acrylic) for exterior signage application and have a life performance of (7) years durability, UV resistant, chemical and moisture resistant. Sign Name Signs shall have 2-mil cast vinyl adhesive graphic film with matte finish, clear, removable, pressure-sensitive adhesive (solvent acrylic) for exterior signage application and have a life performance of (7) years durability, UV resistant, chemical and moisture resistant, applicable for color printing application. Aluminum sheet shall conform to ASTM B209M – 07 Standard Specification for Aluminum and Aluminum Alloy Sheet and Plate. Fasteners to secure sign plates into places shall be Type 316 stainless steel. Zinc-plated fasteners with coating complying with ASTM B 633, Class FE/ZN 5. Custom colored digitally printed logo shall have coefficient of retroreflection varying between that of the base sheeting as given in Table B, and zero (opaque) depending on the hue and saturation (or chromaticity and lightness) of the custom color. Conformance to standard chromaticity and luminance factor requirements shall be in accordance with ASTM E1164. Conformance to coefficient of retroreflection requirements shall be in accordance with ASTM E810 “Test Method for Coefficient of Retroreflection of Retroreflective Sheeting”. Minimum percentage of retroflection retained after 8 years shall be minimum of 70%. Adhesive and film properties shall be applied to test panels and conditioned in accordance with ASTM D4956 and test methods and conditions shall conform to ASTM D4956. The following properties shall conform to the requirements in ASTM D4956: 1. Adhesion 2. Outdoor weathering - retained coefficient of retroreflection- colorfastness 3. Shrinkage 2. Flexibility 3. Liner removal 4. Impact resistance Gloss test method shall be in accordance with ASTM D523. Rating shall not be less than 50. Optical stability of the sheeting shall retain a minimum of 85% and a maximum of 115% of the original coefficient of retroreflection. Street Name Signs on signal mast arms shall be provided with a warranty for signs made with custom colors. The areas of the signs featuring custom colors shall be warrantied against excessive fading, discoloring, cracking, crazing, peeling, blistering and loss of reflectivity such that signs become visually unsuitable for their intended purpose for a period of eight years. 9 30.4 Construction Requirements Section 8-21.3 is supplemented with the following: SP 37 Surface of street name sign plate shall be prepared by sheeting manufacturer’s recommendations. damage to the remaining pavement. The use of chemicals that may be harmful to the pavement will not be allowed. Damaged pavement shall be replaced at the Contractor's expense. Vinyl adhesive graphic film shall be positioned at zero degree application angle at +4°C minimum (air and substrate) per manufacturer’s recommendation. Sign Code Numbers indicated on the Plans are in reference to the Washington State Department of Transportation Sign Fabrication Manual and the Manual on Uniform Traffic Control Devices (MUTCD). Upon completion of the project, the Contractor shall reset all signs that have been disturbed or removed during the construction in their permanent location to the satisfaction of the City. Existing concrete at the base of signpost shall be removed prior to installation in new concrete. Relocated signs shall be installed on new painted schedule 40 galvanized steel poles per the detail shown in the Plans or attached to light poles where noted on the Plans. Steel sign poles shall be powder coated and color per Section 6-07.2, Painting. All costs associated with resetting, relocation and removal & replacement of existing signs shall be included in the lump sum “Permanent Signing”. Any damage due to the Contractor’s negligence before the end of the project shall be replaced by the Contractor with no additional compensation allowed. The Contractor shall request from the Engineer electronic graphic files prior to street name sign samples approval. The Contractor shall provide graphic artwork, catalog cut sheet and a full scale sample of all street name signs mounted on signal mast arms for Engineer’s approval, prior to manufacturing. The Contractor shall provide 3 copies of shop drawings for fabrication, fastening locations, and installation of all street name sign types prior to fabrication, for Engineer’s approval.