SPECIAL SPECIFICATION 6759 Communication Building

Transcription

1 2004 Specifications CSJ SPECIAL SPECIFICATION 6759 Communication Building 1. Description. This Item will govern for the furnishing and installation of the Fiber Communications Hub as shown on the plans, as detailed in this Special Specification and as directed. These buildings will house the various surveillance and control equipment required for the system. Upon completion of the work, each building will be properly installed and tested. (1) General. Overall floor dimensions of the structure will be a minimum 6 ft. by 8 ft., or as required by the plans. All materials furnished, assembled, fabricated or installed under this Item will be in full compliance with Bellcore Technical requirements. Determine the suitability of the building for the equipment complement shown at each field location on the plans. If required, a larger size building will be furnished and installed by the Contractor at no additional cost. Other than size, the selected building will fully meet the requirements of this Specification and will be mounted to a foundation. All Communication Buildings, of the sizes specified, will be identical in size, shape and quality throughout the entire project. Each building will be provided complete with all internal components, back and side panels, terminal strips, harnesses, and connectors as well as mounting hardware necessary to provide for installation of equipment as described herein and on the plans. All electronic components will comply with Special Specification, "Electronic Components, in the project proposal. The building will be constructed using unpainted sheet aluminum with a minimum thickness of in. The building will be designed to withstand a 100 mph wind load. The exterior of the building will be unpainted and the interior will be painted white. All external screws, nuts and locking washers will be stainless steel. No self tapping screws will be used unless specifically approved. All parts will be made of corrosion resistant material, such as plastic, stainless steel, aluminum or brass. All materials used in construction will be resistant to fungus growth and moisture deterioration. Dissimilar metals will be separated by an inert dielectric material. Buildings will conform to the requirements of ASTM designation: B209 for 5052-H32 aluminum sheet. Welding on aluminum buildings will be done by the gas metal arc (MIG) or gas tungsten arc (TIG) process using bare aluminum welding electrodes. Electrodes will

2 conform to the requirements of the American Welding Society (AWS) A5.10 for ER5356 aluminum alloy bare welding electrodes. Procedures, welding machines and welding machine operators for welding on aluminum will be qualified in accordance with the requirements of AWS B3.0, "Welding Procedures and Performance Qualification" and to the practices recommended in AWS C5.6. The surfaces on each aluminum building will be finished to conform to the requirements of Military Specification MIL-A8625C ("Anodic Coatings for Aluminum and Aluminum Alloys") for a Type II, Class I coating, except that the anodic coating will have a minimum thickness of in. and a minimum coating weight of 27 milligrams per square inch. Prior to applying the anodic coating, the buildings will be cleaned and etched. The anodic coating will be sealed in a 5% aqueous solution of nickel acetate (ph of 5.0 to 6.5) for 15 minutes at 208º to 212ºF. The building will be completely weatherproofed to prevent the entry of water, dust and dirt. All conduits will be caulked around the top of the cable ducts with B caulking compound or approved equal, to seal clearance between the cables and ducts. Conduit plugs will be placed in the vacant conduit ducts. No wood, wood fiber product or flammable products will be allowed in the cabinet. All unwelded seams will be sealed with a clear or aluminum-colored weather-seal compound. The building will be equipped with shelves for supporting all shelf-mounted equipment and 19 in. racks to support rack-mounted equipment. The complete rack assembly details and layouts will be submitted approval prior to fabrication. Rack assembly will be designed for the cabinet equipment. The shelves will be mounted on unistrut or keyhole channels or equal. The shelves will be at least 10-1/2 in. deep and be located in the building to provide a 1/2 in. clearance between the back of the shelf and wall. The front of the shelves will have a 1/2 in. lip to prevent equipment from sliding off the shelves. The building will be tamper resistant and have a full size main door to allow entry while standing up. The building will also be equipped with a second door, if called for on the plans, to allow access to the rear panels of the rack-mounted electronic equipment and to allow cross ventilation when the equipment is being serviced. Each door will be equipped with filtered vent openings. The doors and hinges will be braced to withstand a 50 lb. per vertical foot of door height load applied vertically to the outer edge of the door when standing open. There will be no permanent deformation or impairment of any part of the door or building body when the load is removed. Provisions will be designed to hold the doors open at approximately the 90 degree and 180 degree positions. The door handles will be provided with the means to securely padlock the handle in the closed position. The padlock will be a Number 2 Corbin lock. A gasket will be provided to act as a permanent dust and weather resistant seal at the building door facings. The gasket material will be of a non-absorbent material and will maintain its resiliency after long term exposure to the outdoor environment. The gasket

3 will have a minimum thickness of 3/8 in., and will be located in a channel provided for this purpose either on the building or on the doors. A channel formed by an "L" bracket and the door lip is acceptable. In any case, the gasket will show no sign of rolling or sagging and will insure a uniform dust and weather resistant seal around the entire door facing. Any other method is subject to approval during inspection of an order. The building will be vented and cooled by a thermostatically controlled fan. The thermostat will be an adjustable type with an adjustment range of 90º to 135ºF. A pressto-test switch will be provided to test the operation of the fan. The fan will be a 12 in. commercially available model and will be designed to operate reliably over the temperature range of -30º to +165ºF. The intake for the vent system will be filtered with a 16 in. wide by 25 in. high by 1 in. thick air conditioning filter. The filter will be securely mounted so that any air entering the building must pass through the filter. The building opening for intake of air will be screened to prevent entry of insects and will be large enough to use the entire filter. The screen will have openings no larger than sq. in. The total free air opening of the vent will be large enough to prevent excessive back pressure on the fan. Two 20 watt fluorescent lights will be mounted in the building. These lights will be provided with an on-off switch. The lights will be positioned to provide illumination to all maintenance areas of the building. Two momentary, pin-type door switches will be installed in the building or on the door. One switch will be used to turn on the building lights when the door is open. The remaining switch will be wired in parallel to a terminal block for the purpose of detecting a building intrusion condition by Satellite Control Center equipment. The building will be provided with a unique 5 digit serial number which will be stamped directly on the building or engraved on a metal or metalized mylar plate epoxied or riveted with aluminum rivets to the building. The digits will be at least 0.2 in. in height and located on the upper right side wall near the front of the building. Details of the building design will be submitted for review and approval prior to fabrication. Submit a building layout for each building location for approval. Only buildings with an approved layout will be accepted under this project. The equipment, design and construction will utilize the latest available techniques with a minimum number of different parts, subassemblies, circuits, cards and modules to maximize standardization and commonality. The equipment will be designed for ease of maintenance. All component parts will be readily accessible for inspection and maintenance. 2. Electrical Requirements. (1) Distribution Panel. The buildings will be furnished with a U.L. listed single phase, three wire, 120/240, 100 ampere main circuit breaker, six circuit indoor surface

4 mounted power distribution panel mounted on the inside wall of the building. The Contractor will provide a detailed layout of the distribution panel for approval. The panel will be Square D QO series, GE Power Mark Plus series, or equal. All power wiring will be installed as per National Electric Code. (a) Duplex Outlet. A 120 volt AC duplex outlet will be provided and will be protected by a circuit breaker. The receptacle will be a NEMA Type 5-15R duplex receptacle. (b) Circuit Breakers. Unless otherwise called for on the plans, six circuit breakers will be installed. One 15 ampere, U.L. Class A 15 ampere G.F.I. circuit breaker will protect the building lights, duplex receptacle and fan. Two properly rated circuit breakers will be so wired to protect the controller circuits and electronic equipment circuits. The breakers will be the Square D QO series, GE THQ series, or equivalent. The 2 breakers designated for electronic equipment will be wired so that one breaker protects FTM equipment and a second breaker protects SCS equipment. Circuit breakers will be unaffected by ambient temperature range, relative humidity, applied power, shock and vibration range specified in Section 2, "Environmental Standards and Test Procedures," of NEMA TS1-1989, latest revision. Circuit breakers will have an interrupt capacity of 10,000 amperes and insulation resistance of 100 Megs at 500 volts DC. The circuit breakers will be equipped with solderless connectors and installed in such a manner that their rating markings will be visible and the breaker will be easily accessible. (c) Radio Interference Suppressor. All buildings will be equipped with a radio interference suppressor installed on the load side of each electronic equipment circuit breaker. The suppressors will be provided in series with the incoming AC power line before it is distributed to any equipment in the building. The suppressor will provide a minimum attenuation of 50 decibels over a frequency range of 200 kilohertz to 75 megahertz. The suppressor will be hermetically sealed in a substantial metal case, and then filled with a suitable insulation compound. The suppressor terminals will be nickel plated brass studs of sufficient external length to provide space for connection of two appropriately sized conductors and will be mounted so that the terminals cannot be turned in the case. The suppressors will be designed for operation at the proper current rating as determined by the Contractor, per the plans. The suppressors will be designed for 120 volts, 60 Hertz, operation and will be approved by UL and EIA. (d) Power Line Surge Protection. Power line surge protectors will be installed in each building between the line conductors and ground. Power line surge protectors will be provided and installed as described herein. (i) One surge protector will be a three electrode gas tube type and will have the following ratings: 1. Impulse Breakdown: Less than 1,000 volts in less than 0.1 microseconds at 10 kilovolts/microsecond

5 2. Standby Current: Less than one milliampere. 3. Striking Voltage: Limit any voltage greater than 212 volts dc. 4. Capable of withstanding 15 pulses of peak current, each of which will rise in eight microseconds and fall in 20 microseconds to one half the peak voltage, at three minute intervals. Peak current rating will be 20,000 amperes. Additional surge protectors will be provided that utilize both metal oxide varistors and silicon avalanche diodes to protect against transients having a single surge energy level up to 70 joules, voltage transients up to 6 kv and current transients up to 6 ka. Protection will be provided for line to neutral, line to ground and neutral to ground terminals. (ii) The protectors will have the following ratings: 1. Recurrent peak voltage volts. 2. Energy rating minimum joules. 3. Power dissipation - average 0.85 watts. 4. Peak current for pulses of less than 6 microseconds - 20,000 amperes. 5. Standby current - less than one milliampere. (e) Power Cable Input Junction Terminals. A barrier terminal block with a minimum of two terminals and one compression fitting designed to accept up to a No. 2 AWG stranded wire will be provided for the power supply lines. The block will be rated at 100 amperes and will have double binder head screw terminals. The AC neutral and equipment ground wiring will be electrically isolated from the line wiring by an insulation resistance of at least 10 megohms when measured at the AC neutral. The AC neutral and equipment grounding wiring will be color coded white and green, respectively. (2) Back Panel. Each building will include fully wired equipment panels to be mounted on the inside wall of the building. The Contractor will provide a detailed layout for approval. The back panels will be utilized to distribute and properly interconnect all building wiring related to the specific complement of equipment. Each item of equipment including any furnished by the Department will have its cable harness properly terminated at terminal boards on the back panel. All functions available at the equipment connector will be carried in the connector cable harness to the terminal blocks from the power distribution panel. (3) Wiring. (a) The building will be fully wired and all wiring within the building will be neatly wrapped and routed such that opening and closing the door or raising or lowering

6 the back panel will not twist or crimp the wiring. No cable pressure points will be present. All wires will be cut to the proper length before assembly. No wires will be doubled back to take up slack. Harnesses to connectors will be covered with PVC sheathing, woven braid or braided. Cables will be secured with nylon cable clamps. Cable slack will be provided to facilitate removal and replacement of assemblies, panels and modules. (b) All harnesses and wiring will be color coded. In addition, each wire in every harness will be hot-stamped every four inches with a number indicating the pin number of the connector that the wire is connected to. Harnesses with connectors with pins identified by letters will be stamped with numbers that correspond to the alphabetic sequence of the pins. Each harness will be cross-referenced to a chart on the building print that lists the connector pin letter or number, the wire number, the terminal number that the wire is connected to and the function of the wire. Each harness will be enclosed in PVC sheathing, woven braid or braided. Individual conductors in detector harnesses will be exempt from the requirements for hotstamping. Tie wraps, tape or other cable ties are not acceptable. All electrical connections in the building, including relays, flashers, terminal strips, etc., will have sufficient clearance between each terminal, and the building, to provide an adequate distance to prevent a leakage path or physical contact under stress. All equipment grounds will run directly and independently to the ground bus. The lay of the interconnect cable between the components must be such that when the door is closed, it does not press against the cables or force the cables against the various components inside the buildings. Sufficient length of cable will be provided to easily reach the electronic equipment placed anywhere on the shelves. All wiring containing line voltage AC will be routed and bundled separately and shielded from all low voltage, i.e., control circuits. All conductors and live terminals or parts, which could be hazardous to maintenance personnel, will be covered with suitable insulating material. All conductors used on the building wiring will be stranded No. 22 AWG or larger. Conductors will conform to MIL SPEC MIL-W , Type B or D. The insulation will have a minimum thickness of 10 millimeters. All wiring containing line voltage will be a minimum size of No. 14 AWG. All conductors between the main power circuit breakers and the signal power bus will be a minimum size 10 AWG stranded copper. All AC service lines will be of sufficient size to carry the maximum current of the circuit or circuits for which they are provided. Conductors for AC common will be white. Conductors for equipment ground will be green. All other conductors will be a color, different from the previously mentioned colors

7 (c) Terminal Blocks. Terminal blocks located on the panels will be accessible to the extent that it will not be necessary to remove the electronic equipment from the cabinet to make an inspection or connection. Terminal blocks will be a 2 position, multiple pole barrier type. Shorting bars will be provided in each of the positions provided along with an integral marking strip. Terminal blocks will be so arranged that they will not upset the entrance, training and connection of incoming field conductors. All terminals will be suitably identified by legends permanently affixed and attached to the terminal blocks. Not more than three conductors will be brought to any one terminal screw. No electrically energized components or connectors will extend beyond the protection afforded by the barriers. All terminal blocks will be located below the shelves. Terminals used for field connections will secure conductors by means of a No nickel or cadmium plated brass binder head screw. Terminals used for interwiring connections, but not for field connections, will secure conductors by means of a No nickel plated brass binder head screw. As a minimum, all connections to and from the electronic equipment will terminate to an interwiring type block. These blocks will act as intermediate connection points for all electronic input and output connections. All terminals will be permanently identified in accordance with the building wiring diagram. Where through-panel solder lugs or other suitable connectors are used, both sides of the panel will be permanently attached and as close to the terminal strip as possible and will not be affixed to any part which is easily removable from the terminal block panel. (4) Solid-State Load Switches. The load switches will be solid state and will have no moving parts. The load switches will meet the requirements set forth in Section 5 of NEMA Standard TS1-1989, latest revision, and will be "Triple Signals Load Switch" type. An indicator light for each circuit will be provided on each load switch. The indicator light will be on when a true input to the load switch is present. The load switches will be capable of operation at ten amperes of tungsten lamp load over the specified temperature range. (5) Building Internal Grounding. The building internal ground will consist of one or more ground bus-bars permanently affixed to the building and connected to the grounding electrode. Bare stranded No. 6 AWG copper wire will be used between the bus- bars and between bus-bar and grounding electrode. Each copper ground bus-bar will have a minimum of 20 connector points, each capable of securing at least one No. 10 AWG conductor. AC neutral and equipment ground wiring will return to these busbars. (6) Transient Suppression. Transient suppression devices will be placed on the coil side of all relays in the building. DC relay coils will have, as a minimum, a reverse biased diode across the coil. AC relays will have MOV's or equivalent suppression across their coils. External Twisted Wire Pair (Twp) Terminators -Transient Protection Chassis. Each cabinet will be equipped with a rack mounted chassis to contain transient

8 protection barrier devices. Four-wire operations will be connected to one side of the transient protection devices, while the TWP field cable, connecting to LCU devices, CMS controllers, or CCTV controllers, will be connected to the other side of the transient protection devices. The chassis will provide for 96 transient protection TWP termination. The transient protection devices will be firmly attached to the chassis and the chassis will be attached to slides for moving the chassis to enable the transient protection devices to be serviced. The chassis will have screw type hold down fixtures in the closed position. Harnesses for field cables will be firmly attached to the chassis and will not bind while servicing the chassis contents. Install a total chassis cover lid. Submit a chassis component layout for approval before installation. (7) Surge Protection, Protector And Building Configuration. All ungrounded conductor wires entering or leaving the building will be provided with surge protectors. The conductor leads and the surge protector leads will be kept as short as possible with all conductor bends formed to the maximum possible radius. The protector units will be located as near as possible, 6 in., to the entry or exit point, and as far as possible from any electrical equipment. The protector ground lead will be connected directly to the ground bus. The surge protector utilized for AC power will not dissipate any energy and will not provide any series impedance during standby operation. The unit will return to its nonshunting mode after the passage of any surge, and will not allow the shunting of AC power. The equipment being protected by the surge protectors will be consistent from one fiber communications hub to another, and will be submitted for approval. (8) Environmental Design Requirements. The buildings will meet all of its functional requirements during and after subjection to any combination of the following requirements: 1. Ambient temperature range of 0ºF to 158ºF. 2. Temperature shock not to exceed 30ºF per hour, during which the relative humidity will not exceed 95%. 3. Relative humidity range not to exceed 95% over the temperature range of 40ºF to 110ºF. 4. Moisture condensation on all surfaces caused by temperature changes. (9) Documentation. Each Communications Hub Building will be provided with the following documentation: 1. Three complete and accurate building wiring diagrams. 2. The wiring diagrams will document every harness wire termination in the building. It will be the Contractor's responsibility to provide updated drawings if any discrepancies are discovered. Prior to final acceptance of a building, provide a reproducible tracing of the building wiring diagrams

9 3. One set of the documentation will be placed in the building in an approved heavy duty plastic envelope. The other documentation will be delivered to the Engineer. 3. Guaranty. If it is normal trade practice for the manufacturer to furnish a guaranty for the work provided herein, the Contractor will turn this guaranty over to the Engineer for potential dealing with the guarantor. The extent of such guaranty will not be a factor in selecting the successful bidder. 4. Testing Requirements. (1) General. It is the policy of the Department to require performance testing of all materials and equipment not previously tested and approved. If technical data are not considered adequate for approval, samples may be requested for testing. The contract period will not be extended for time lost or delays caused by testing prior to final Department approval of any items. The equipment referenced to this Specification will be subjected to Design Approval Tests and Factory Demonstration Tests at the equipment manufacturer's facility to determine conformance with all the specification requirements except that the Engineer may accept certification by an independent testing lab in lieu of the design approval tests, to verify that the design approval tests have previously been satisfactorily completed. The Contractor will arrange for and conduct the tests in accordance with the testing requirements stated herein. Unless otherwise specified on the plans, the Contractor will satisfy all inspection requirements prior to submission for inspection and acceptance. The Engineer reserves the right to have his representative witness all Design Approval Tests and Factory Demonstration Tests. The results of each test will be compared with the requirements specified herein. Failure to conform to the requirements of any test will be counted as a defect, and the equipment will be subject to rejection. Rejected equipment may be offered again for retest, provided all non-compliances have been corrected and retested by the Contractor, and evidence thereof submitted to the Engineer. The tests on all of one type of equipment will be completed within five days and any delays in performing all these tests will result in the Contractor paying the additional costs of providing the Engineer and his representatives for the additional testing. Final inspection and acceptance of equipment will be made after installation at the destination specified unless otherwise specified herein. (2) Design Approval Tests. Design Approval Tests will be conducted by the Contractor on 1 or more sample equipments of each type, as approved, to determine if the design of the equipment meets the requirements of this Specification. The tests will be conducted in accordance with the approved test procedure as described in Subarticle 4.(17). The Engineer will be notified a minimum of 25 working days in advance of the time when these tests are to be conducted

10 (3) Temperature, Condensation And Relative Humidity. The equipment Operational Test in Subsection 4.(11), specified for the Factory Demonstration Tests (FDT), will be successfully performed under the following conditions in the order specified below: 1. The equipment will be stabilized at 0ºF. After stabilization at this temperature, the equipment will be operated for two hours without degradation. 2. Moisture will be caused to condense on the equipment by allowing it to warm up to room temperature in an atmosphere having relative humidity of at least 40 percent and the equipment will be satisfactorily operated for two hours while wet. 3. The equipment will be stabilized at 140ºF. After stabilization, the equipment will be satisfactorily operated for two hours without degradation or failure. 4. The equipment will be stabilized at a temperature and relative humidity of 140ºF and 40%, respectively. The equipment will be maintained at the above condition for 48 hours. At the conclusion of the 48-hour soak, the equipment will meet the 13 requirements of the Operational Test of the FDT within 30 minutes. (4) Primary Power Variation. The equipment will meet the specified performance requirements when the input voltage is plus or minus 20 volts from the nominal value of 115 volts for 15 minutes, during which the Operational Test of the FDT will be successfully performed. (5) High-Frequency. The equipment will meet the requirements of the Operational Test of the FDT when subjected to the high- frequency and voltage transient interference specified in Section 2.1.6, "Transient, Power Service," of the NEMA Standard TS , or latest revision to this publication. (6) Vibration. The equipment will show no degradation of mechanical structure, soldered components, plug-in components, or satisfactory operation in accordance with the manufacturer's equipment specifications after being subjected to the vibration tests as described in Section 2.2.5, "Vibration Test," of the NEMA Standard TS , or latest revision to this publication. (7) Consequences of Design Approval Test Failure. Design Approval Tests will be performed on units randomly selected from the prototype design manufacturing run, or if only one design prototype is manufactured, they will be performed on that unit. If the unit fails the Design Approval Test, the design fault will be corrected and the entire Design Approval Test will be repeated. All deliverable units will be modified, without additional costs to the Department, to include design changes required to pass the Design Approval Tests. (8) Factory Demonstration Tests. The Contractor will conduct Factory Demonstration Tests on all units at the manufacturer's facility. These tests will be performed on each unit supplied. The Department will be notified a minimum of 25 working days before the start of the tests. All tests will be conducted in accordance with the approved test procedure of Subsection 4.(17). Each equipment accepted will have passed the following individual tests

11 (9) Examination of Product. Each piece of equipment will be examined carefully to verify that the materials, design, construction, markings, and workmanship comply with the requirements of this specification. (10) Continuity Test. The wiring will be checked to determine conformance with the requirements of the appropriate paragraph in the "Electrical Requirements" sections. (11) Operational Test. Each equipment will be operated long enough to permit equipment temperature stabilization, and to check and record an adequate number of performance characteristics to ensure compliance with the requirements of this specification. (12) Consequence of Factory Demonstration Test Failure. If a unit fails to pass its Factory Demonstration Test, the unit will be corrected or another unit substituted in its place, and the test successfully repeated. If a unit has been modified as a result of a demonstration test failure, a report will be prepared and delivered to the Engineer prior to shipment of the unit. The report will describe the nature of the failure and the corrective action taken. If a failure pattern develops, the Engineer may direct that design and construction modifications be made to all units, without additional cost to the Department, or extension of the contract period. (13) Stand-Alone Tests. The Contractor will conduct an approved Stand-Alone Test of the equipment installation at the field site. The test will, as a minimum, exercise all standalone, non-network, functional operations with all of the equipment installed per the plans, or as directed. Approved data forms will be completed and turned over to the Engineer, as the basis for review and rejection or acceptance. At least, 25 working days notice will be given prior to all tests, to permit the Engineer, or his representative to observe each test. (14) Consequences of Stand-Alone Test Failure. If a unit fails to pass its Stand-Alone Test, the unit will be corrected or another unit substituted in its place and the test successfully repeated. If a unit has been modified as a result of a Stand-Alone Test failure, a report will be prepared and delivered to the Engineer prior to retesting of the unit. The report will describe the nature of the failure and the corrective action taken. If a failure pattern develops, then the Engineer may direct that design and construction modifications be made to all units, without additional cost to the Department, or extension of the contract period. (15) System Integration Tests. The Contractor will conduct System Integration Tests with both the field and satellite control center equipment interconnected. The tests will demonstrate all control and monitor functions of the field equipment by the central control equipment. Approved data forms will be completed and turned over to the Engineer, for review, and as the basis for rejection or acceptance. (16) Consequence of System Integration Test Failure. If the equipment fails to pass its System Integration Tests, the equipment will be corrected and the complete System Integration Tests will be repeated

12 (17) Test Procedures. The Contractor will provide all Design Approval, Factory Demonstration, Stand-Alone and System Integration Test procedures and data forms for the Engineer's approval. The test procedures will include the sequence of conducting the tests. The test procedures will have the Engineer's approval prior to submission of equipment for tests. The Contractor will furnish data forms containing all of the data taken, as well as quantitative results for all tests. The data forms will be signed by an authorized representative, company official, of the equipment manufacturer. At least one copy of the data forms will be sent to the Engineer. 5. Measurement. This Item will be measured as each unit furnished, installed and tested in accordance with this Special Specification. 6. Payment. The work performed and materials furnished in accordance with this Item and measured as provided under "Measurement" will be paid for at the unit price bid for "Communication Building" of the sizes specified. This price will be full compensation for all equipment described under this item with all cables and connectors, building foundation, documentation and testing, and for furnishing all labor, materials, training, equipment and incidentals