OPERATION AND MAINTENANCE INSTRUCTIONS...MONOPULSE SECONDARY SURVEILLANCE RADAR (MSSR) SYSTEM 808390/000 EFFECTIVITY: ASR-11 Configurations 1 thru 5. * * XX/XX/XXXX SDR-ASR11-057 TI

XX/XX/XXXX SDR-ASR11-057 TI 6310.47

WP 005 00

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WORK PACKAGE

OPERATION AND MAINTENANCE INSTRUCTIONS

PRIMARY SURVEILLANCE RADAR (PSR) GROUP G584000-501

EFFECTIVITY: ASR-11 Configurations 1 thru 5.

TABLE OF CONTENTS

Paragraph Page

1. GENERAL INFORMATION ........................................................................... 3 1-1 PURPOSE ..................................................................................................... 3 1-2 SCOPE .......................................................................................................... 3 1-3 DESCRIPTION .............................................................................................. 3 1-3.1 Transmitter ..................................................................................................... 3 1-3.2 Receiver/Exciter ............................................................................................. 4 1-3.3 Signal Data Processor ................................................................................... 5 1-3.4 System Control and Data Interface ................................................................ 5 1-4 CONFIGURATIONS ...................................................................................... 5 1-5 LEADING PARTICULARS ............................................................................. 5 1-6 PRINCIPLES OF OPERATIONS ................................................................... 5

2. INSPECTIONS .............................................................................................. 6

3. TESTING ....................................................................................................... 6 3-1 ROUTINE TESTING ...................................................................................... 6 3-2 FAULT ISOLATION ....................................................................................... 6

4. MAINTENANCE ............................................................................................. 6 4-1 PREVENTIVE MAINTENANCE TASKS ........................................................ 6 4-2 REPAIR PROCEDURES ............................................................................... 6

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WP 005 00

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LIST OF ILLUSTRATIONS

Figure Page

1 PSR Functional Block .......................................................................... 4

LIST OF TABLES

Table Page

None

REFERENCE MATERIAL REQUIRED

Publication Number Publication Title

TI 6310.57A Digital Airport Surveillance Radar, ASR-11, ASR-11 S-Band, Solid State Primary Surveillance Radar

TI 6310.59 Digital Airport Surveillance Radar, ASR-11 Antenna and Drivetrain Manual, Book 1, Operation and Maintenance Manual ASR-11 Antenna Pedestal, Models 7547686 and 174670

JO 6310.30B Maintenance Handbook for Airport Surveillance Radar, ASR-11 Facilities

APPLICABLE TCTOS

None

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TI 6310.47 1 DECEMBER 2003 WP 005 00

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1. GENERAL INFORMATION. 1-1 PURPOSE. The purpose of this Work Package (WP) is to provide operation and maintenance information for the Digital Airport Surveillance Radar (ASR-11) Primary Surveillance Radar (PSR) Group. 1-2 SCOPE. This WP provides system-level information for the PSR. For a detailed description of the PSR, refer to Reference Material Required section. 1-3 DESCRIPTION. The PSR group consists of a solid-state transmitter with dual drivers, dual-channel Receiver/Exciters (REXs), dual Signal Data Processors (SDPs), System Control and Data Interface (SCDI) and a microwave assembly. PSR Functional Block Diagram Figure 1 depicts the PSR Functional Block Diagram. Monitoring and control capabilities are contained internal to the PSR Group (to ensure high availability) and interface to site control and monitoring external to the PSR Group. The PSR Group, in combination with the PSR Antenna/Pedestal Group (WP 005 01), provides aircraft target and weather detection for Air Traffic Control (ATC) Services. The PSR with antenna system operates on two assigned frequencies at S-band. Transmissions are in five pulse pairs per Coherent Processing Interval (CPI). The frequencies are changed on successive CPIs for single channel diversity. Within each assigned frequency, ± 0.5 MHz offset is introduced to decorrelate precipitation returns. Coverage degradation due to weather clutter is minimized by utilizing switchable circular polarization in both high and low beams. The PSR includes automatic Built-In Test (BIT) and control circuitry. This circuitry automatically detects failures and informs the Radar Monitoring Subsystem (RMS). Redundant equipment is automatically reconfigured in order to maintain the flow of data to the end user under single failure conditions. The PSR Group has two roles of operation: on-line and maintenance. The on-line role is the normal role of operation of the PSR. The maintenance role is used to perform maintenance activities on the PSR equipment, i.e., maintenance testing and diagnostic testing. Operational and maintenance commands are actioned by PSR channels functioning in the maintenance role. The PSR channels accept commands from the Operators Maintenance Terminal (OMT) within the selected SCDI and provide status reports to both SCDIs. 1-3.1 Transmitter. The Transmitter is a coherent, completely solid-state, modular unit containing eight output amplifier modules. Switches are provided to permit each one of the eight output modules to be either independently or simultaneously switched from on-line to off-line. The transmitter design contains eight power amplifier modules, two driver modules, and associated power supplies. The amplifier power outputs are RF combined to provide the specified power output for the eight-module unit. The transmitter interfaces to the microwave assembly, REX and SDP, interlock circuits, and prime power.

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Figure 1. PSR Functional Block Diagram

1-3.2 Receiver/Exciter. The REX is dual-redundant. Each REX is composed of six LRUs:

a. RF Assembly

b. Stability Monitor

c. Local Oscillator Module

d. Waveform Generator/upconverter and Target

e. Weather and TargetDownconverters

The RF Assembly provides the target path with separate high and low beam front ends. The high/low beam switch is part of the RF Assembly. The RF Assembly also provides a separate weather path. The weather high/low beam switch is located at the antenna.

The Stability Monitor decorrelates signal samples from either the upconverter, the transmitter pre-driver or the transmitter before injection into the RF Assembly or the downconverter for the purpose of fault isolation and stability monitoring.

XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 005 00

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The Local Oscillator (LO) Module generates all LO signals for the upconverter and downconverters and generates all clocks for the SDP and REX.

The upconverter generates all transmission and test waveforms. It is composed of a Digital Waveform Generator (DWG) and frequency upconversion circuitry. The target and weather downconverters use identical components mounted on a single Circuit Card Assembly (CCA). In addition, the REX accepts control information from, and provides status information to, the SDP. The REX and SDP equipment share a cabinet. The REX interfaces with the SDP, microwave assembly, transmitter, and AC power units. 1-3.3 Signal Data Processor. The PSR incorporates dual-redundant SDPs, one in each PSR channel. The SDP provides PSR control and monitoring as well as system synchronization, digital-pulse compression, target processing, and weather processing for the receiver channel in which it resides. Digital-pulse compression is supplied for both the target and weather input signals. Target Processing consists of Doppler filtering, Constant False Alarm Rate (CFAR) detection thresholding, dwell-to-dwell binary integration, plot extraction, and scan-to-scan tracking. Weather processing consists of clutter rejection, map generation, and contour thresholding. 1-3.4 System Control and Data Interface. The PSR provides for redundant site Control and Monitoring System (CMS) located in the SCDI workstations. The role of the CMS is to provide the maintenance personnel with system status and control information of the PSR, MSSR, and site peripherals. The site CMS provides comprehensive monitoring, control, and diagnostic testing of the radar site subsystems. The PSR, MSSR, and site peripherals perform extensive internal performance monitoring and error checking. Each subsystem performs automatic reconfiguration (changes channels) when a failure occurs and allows internal control of the off-line channel. Additional circuits are provided to monitor site peripheral equipment such as smoke, heat, fire, and intrusion alarms, pneumatic systems, antenna equipment, power systems, and UPS systems. 1-4 CONFIGURATIONS. The ASR-11 PSR supports the configurations listed in WP 002 00.

1-5 LEADING PARTICULARS.

Refer to Section 1, Table 1-1 of TI 6310.57A for information on the PSR Operational and Physical parameters. 1-6 PRINCIPLES OF OPERATIONS. Refer to Section 2 of TI 6310.57A for the ASR11 theory of operation.

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2. INSPECTIONS. Refer to WP 004 05 for inspection requirements. 3. TESTING. 3-1 ROUTINE TESTING. Refer to Section 4 and Appendix 4A of TI 6310.57A for information on routine measurements, monitoring and control adjustments, and other adjustments that can be performed remotely. 3-2 FAULT ISOLATION. Refer to Section 6 of TI 6310.57A for information on fault isolating the PSR. 4. MAINTENANCE. 4-1 PREVENTIVE MAINTENANCE TASKS. Refer to Section 5 of TI 6310.57A for a list of preventive maintenance tasks and their associated procedures. 4-2 REPAIR PROCEDURES. Refer to Section 6 of 6310.57A for on-site PSR repair procedures.

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TI 6310.47 WP 005 01

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WORK PACKAGE


PSR ANTENNA PEDESTAL GROUP EFFECTIVITY: ASR-11 Configurations 1 thru 5.

LIST OF EFFECTIVE WP PAGES

Total number of Pages in this WP is 74

Page No. Change Page Change Page Change

No. No. No. No. No. No.

1 thru 74 0

TABLE OF CONTENTS

Paragraph Page 1. PURPOSE ..................................................................................................... 2 2. SCOPE .......................................................................................................... 2 3. CONFIGURATIONS ...................................................................................... 2


Publication Number

Publication Title

TI 6310.57A ASR11 S-Band Solid State Primary Surveillance Radar Technical Manual

TI 6310.47 WP004 02, System Operation

TI 6310.47 WP004 05, System Maintenance TI 6310.47 WP 004 07, System Interconnections


None

LIST OF TABLES

TI 6310.47 WP 005 01

2

None

AVAILABLE TCTOS

None *

TI 6310.47 WP 005 01

3

1. PURPOSE.

The purpose of this Work Package (WP) is to provide operation and maintenance information for the Digital Airport Surveillance Radar (ASR-11) Primary Surveillance Radar (PSR) Antenna Group.

Note: All required maintenance on ASR-11 facilities is directed by Order 6310.30B. TI 6310.59 (Book3) is the Technical Instruction Book for the antenna.

2. SCOPE.

This WP provides system-level information for the PSR Antenna Group. For a detailed description of the PSR Antenna, refer to the Reference Material Required section.

3. CONFIGURATIONS.

The ASR-11 PSR Antenna Group supports all configurations listed in WP 02 00.

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WORK PACKAGE

TABLE OF CONTENTS

Paragraph Page

1. GENERAL INFORMATION ................................................................... 3 1-1 PURPOSE ............................................................................................. 3 1-2 SCOPE .................................................................................................. 3 1-3 DESCRIPTION ...................................................................................... 3 1-4 CONFIGURATIONS .............................................................................. 3 1-5 LEADING PARTICULARS ..................................................................... 3 1-6 PRINCIPLES OF OPERATIONS ........................................................... 3

2. INSPECTIONS ...................................................................................... 4

3. TESTING ............................................................................................... 4 3-1 FAULT ISOLATION ................................................................................ 4 3-1.1 System .................................................................................................... 4 3-1.2 Interrogator ............................................................................................. 4

4. MAINTENANCE ..................................................................................... 4 4-1 PREVENTIVE MAINTENANCE TASKS ................................................ 4 4-1.1 System ................................................................................................... 4 4-1.2 Interrogator ............................................................................................ 4 4-2 REPAIR PROCEDURES ....................................................................... 4 4-2.1 System ................................................................................................... 4 4-2.2 Interrogator ............................................................................................ 4

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MONOPULSE SECONDARY SURVEILLANCE RADAR (MSSR) SYSTEM 808390/000


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Figure Page

1 MSSR System - Family Tree ............................................................... 4

LIST OF TABLES Table Page

None



TI 6310.56 Digital Airport Surveillance Radar ASR-11 System Manual for MSSR System TI 6310.53 Digital Airport Surveillance Radar ASR-11 Equipment Manual for Condor MSSR Interrogator JO 6310.30B Maintenance Handbook for Airport Surveillance Radar, ASR-11

Facilities

APPLICABLE TCTOS

None

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1. GENERAL INFORMATION.

1-1 PURPOSE.

The purpose of this Work Package (WP) is to provide operation and maintenance information for the Digital Airport Surveillance Radar (ASR-11) Monopulse Secondary Surveillance Radar (MSSR).

1-2 SCOPE.

This WP provides system-level information for the MSSR. For a detailed description of the MSSR, refer to the appropriate publications identified in WP 002 00.

1-3 DESCRIPTION.

The MSSR is a dual-redundant channel Mode-S upgradable system. It incorporates full transmission, reception, processing, and control capabilities in a single cabinet. The system is comprised of the following equipment:

a. Dual CONDOR MSSR Interrogators, each containing a transmitter, receivers and plot extraction, processing and formatting capability.

b. RF Changeover (RFCO) assembly.

c. Control and Monitoring System (CMS).

d. Large Vertical Aperture (LVA) antenna.

The system is centered around the Condor Mk IID plot processor, operating in conjunction with a Mk II LVA antenna and a transmitter and receiver. System control functions are included within the plot processor, providing for local and remote control and monitoring facilities.

A local CMS terminal (PC based) is provided, which when combined with the Condor Mk IID interface to the local Radar Monitoring Subsystem (RMS)/Operator Maintenance Terminal (OMT) provides control, monitoring, and maintenance capabilities. Figure 1 depicts the MSSR family tree.

1-4 CONFIGURATIONS.

The ASR-11 MSSR supports all four of the configurations listed in WP 002 00.


Refer to Section 1 of TI 6310.56 Digital Airport Surveillance Radar ASR-11 System Manual for MSSR System, brief specifications (operational and physical specification).

1-6 PRINCIPLES OF OPERATIONS.

Refer to Section 2 of TI 6310.56 Digital Airport Surveillance Radar ASR-11 System Manual for MSSR System, for functional description of the MSSR.

Refer to Section 3 of TI 6310.56 Digital Airport Surveillance Radar ASR-11 System Manual for MSSR System, for operating instructions of the MSSR.

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Figure 1. MSSR System - Family Tree 2. INSPECTIONS.

There is no routine system level inspection of the MSSR.

3. TESTING.

3-1 FAULT ISOLATION.

3-1.1 System. Refer to Section 4 of TI 6310.56, System Manual for MSSR System for DASR, for general diagnostics of the MSSR.

3-1.2 Interrogator. Refer to Section 4 of TI 6310.53, Equipment Manual for Condor MSSR Interrogator, for diagnostics of the Interrogator.

4. MAINTENANCE.

4-1 PREVENTIVE MAINTENANCE TASKS.

4-1.1 System. Refer to Section 4 of TI 6310.56 and Order 6310.30B, Chapter 4, Sections 3 and 4.

4-1.2 Interrogator. Refer to Section 4 of TI 6310.53, Equipment Manual for Condor MSSR Interrogator, for routine maintenance of the Interrogator.

4-2 REPAIR PROCEDURES.

4-2.1 System. Refer to Section 4 of TI 6310.56, System Manual for MSSR System for DASR, for general maintenance of the MSSR.

4-2.2 Interrogator. Refer to Section 4 of TI 6310.53, Equipment Manual for Condor MSSR Interrogator, for maintenance procedures of the Interrogator.

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WP 006 01

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WORK PACKAGE


MSSR LVA ANTENNA


TABLE OF CONTENTS

Paragraph Page 1. PURPOSE ........................................................................................................ 3 2. SCOPE ............................................................................................................. 3 3. DESCRIPTION ................................................................................................. 3 3-1 CONSTRUCTION ............................................................................................ 3 3-2 MOUNTING ...................................................................................................... 4 4. CONFIGURATIONS ......................................................................................... 5 5. LEADING PARTICULARS ............................................................................... 5 6. PRINCIPLES OF OPERATIONS ..................................................................... 5 7. INSPECTIONS ................................................................................................. 5 8. TESTING .......................................................................................................... 5 9. MAINTENANCE ............................................................................................... 5

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WP 006 01

2


Figure Page 1 MSSR LVA Antenna ............................................................................................... 4

LIST OF TABLES

Table Page

None



TI 6310.55 Digital Airport Surveillance Radar ASR-11 Equipment Manual for Condor LVA Antenna


APPLICABLE TCTOS

None

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WP 006 01

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1. PURPOSE.

The purpose of this Work Package (WP) is to provide operation and maintenance information for the Digital Airport Surveillance Radar (ASR-11) Condor Mk II Large Vertical Aperture (LVA) Antenna system.

2. SCOPE.

This WP provides system-level information for the Monopulse Secondary Surveillance Radar (MSSR) LVA Antenna. This includes system descriptions, system interfaces, and other pertinent information for the maintenance of the Condor Antenna. For a more detailed description of the Condor Antenna, refer to TI 6310.55, Digital Airport Surveillance Radar ASR-11 Equipment Manual for Condor LVA Antenna.

3. DESCRIPTION.

The MSSR LVA Antenna (Figure 1) is an LVA array that generates radiation patterns suitable for MSSR operation.

The antenna is made up of 35 vertical radiating columns mounted on an aluminum spine. This provides the rigidity required to withstand the loads and forces imposed by high winds and ice coatings, while protecting cables and distribution networks against extreme environmental conditions.

The radiating aperture of the antenna comprises a planar array of 420 dipoles. The dipoles are arranged in 35 columns of 12 and the array comprises 17 columns on either side of a central column (control front). An additional rear-facing radiator (control rear) is mounted on the back of the antenna.

A vertical stripline distribution network is integral with each column of dipoles so there is only one input per column fed from an azimuth stripline power divider network via low-loss coaxial cables. The azimuth stripline power-divider network comprises four interconnected assemblies.

3-1 CONSTRUCTION.

The MSSR LVA Antenna comprises 35 identical vertical columns, each containing 12 radiating elements, supported on a central spine that carries all loads and forces imposed by wind, ice, and the weight of the assembly.

Each column consists of a bonded glass/Polytetraflouroethylene (PTFE) stripline printed circuit board enclosed in a streamlined housing. This comprises a strong aluminum backbone and a glass reinforced polycarbonate radome, giving excellent microwave performance, great mechanical strength and stiffness, together with minimum wind drag. Each column is provided with three drain holes in the base to allow the housing to breathe. Each column may be removed from the support structure without disturbing adjacent columns.

Between each of the columns is an assembly of four aluminum tubes, attached to the front of the spine. Like the columns, they are fixed at top and bottom to the outer metal framework. The tube assemblies function to eliminate most rear radiation.

A rear radiator is attached to the rear spine on the centerline. This unit consists of a backplate and a printed circuit board with four dipoles mounted on it.

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TI 6310.47 1 DECEMBER 2003 WP 006 01

4

Condor MK II LVA (MSSR) Antenna shown in actual

Configuration mounted on top of PSR Antenna.

Figure 1. MSSR LVA Antenna

The central spine is a closed box containing the stripline assemblies and RF cables that feed the radiating elements. Covers are provided on the rear face of the box for access to the distribution network, but this box is not sealed. Drain holes, designed to prevent access by insects, are included.

A clinometer plane is marked on the top face of the spine and can be used for setup. A telescope mount (optional) can also be fitted.

3-2 MOUNTING.

The combined antenna and beam assembly is intended for mounting onto the primary antenna, which has a suitable hardback structure. The antenna has standard mounting attachments.


WP 006 01

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For antenna mounting information, refer to Section 2 of TI 6310.55, Digital Airport Surveillance Radar ASR-11 Equipment Manual for Condor LVA Antenna

4. CONFIGURATIONS.

The ASR-11 LVA Antenna supports all five configurations listed in WP 002 00.

5. LEADING PARTICULARS.

Refer to Section 1 of TI 6310.55, Airport Surveillance Radar ASR-11 Equipment Manual for Condor LVA Antenna, for operational and physical specifications of the MSSR LVA Antenna.

6. PRINCIPLES OF OPERATIONS.

There are no operating instructions required for the MSSR LVA Antenna.

7. INSPECTIONS.

All antenna inspections are directed by Order 6310.30B, chapter 4 section 7.

8. TESTING.

There is no testing required for the MSSR LVA Antenna.

9. MAINTENANCE.

Refer to Section 4 of TI 6310.55, Digital Airport Surveillance Radar ASR-11 Equipment Manual for Condor LVA Antenna, for maintenance procedures of the MSSR LVA Antenna. Periodic maintenance on the LVA antenna is directed by Order 6310.30B

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TI 6310.47 1 DECEMBER 2003 WP 006 01

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This page intentionally left blank.


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WORK PACKAGE


REMOTE MONITORING SUBSYSTEM (RMS)


TABLE OF CONTENTS

Paragraph Page

1. GENERAL INFORMATION ............................................................................... 3 1-1 PURPOSE ........................................................................................................ 3 1-2 SCOPE ............................................................................................................. 3 1-3 DESCRIPTION ................................................................................................. 3 1-4 CONFIGURATIONS ......................................................................................... 3 1-5 PRINCIPLES OF OPERATIONS ...................................................................... 3 1-5.1 Local Site RMS Operation ................................................................................ 5 1-5.2 Remote RMS Operation .................................................................................... 6 1-5.3 Performance and Functional Requirements ..................................................... 7 1-5.4 Local and Remote Control and Local Site Parameter Adjustments .................. 7 1-5.5 Monitoring ......................................................................................................... 8 1-5.6 RMS Alarms and Alerts ..................................................................................... 8 1-5.7 Fault Isolation ................................................................................................... 9 1-5.8 RMS Data Security ........................................................................................... 9 1-5.9 SCDI State Change Processing ...................................................................... 10 1-5.10 Data Storage ................................................................................................... 10 1-5.11 Data Retrieval ................................................................................................. 11 1-5.12 RMS Communication Mode ............................................................................ 11 1-5.13 Operator Maintenance Terminal Menu ........................................................... 11 1-5.14 Remote Site Functional Interface .................................................................... 11 1-5.15 Operator Maintenance Terminal Common Functionality ................................ 11 1-5.16 SCDI Functionality Differences ....................................................................... 11 1-5.17 RMS Architecture ............................................................................................ 11 1-5.18 Adjustable Parameters .................................................................................... 12

2. INSPECTIONS ................................................................................................ 12

3. TESTING ......................................................................................................... 12

4. MAINTENANCE .............................................................................................. 12 4-1 PREVENTIVE MAINTENANCE TASKS ......................................................... 12 4-2 REPAIR PROCEDURES ................................................................................ 12

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WP 007 00

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Figure Page

1 Typical ASR-11 RMS ............................................................................................. 4

LIST OF TABLES

Table Page

None



TI 6310.54 Digital Airport Surveillance Radar ASR-11 Equipment Manual for Dual Channel Site Monitor

TI 6310.56 Digital Airport Surveillance Radar ASR-11 System Manual for MSSR System

TI 6310.57A Digital Airport Surveillance Radar ASR-11, ASR11 S-Band Solid State Primary Surveillance Radar


APPLICABLE TCTOS

None

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WP 007 00

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1-1 PURPOSE.

The purpose of this Work Package (WP) is to provide operation and maintenance information for the Digital Airport Surveillance Radar (ASR-11) Remote Monitoring Subsystem (RMS).

1-2 SCOPE.

This WP provides system-level information for the RMS. For a detailed description of the various equipment contained in the RMS, refer to Reference Material Required section.

1-3 DESCRIPTION.

The RMS provides the interface between the ASR-11 and the end user, by providing the functions needed to perform local and remote monitoring, fault isolation, and control of the ASR-11 system.

The ASR-11 RMS function is performed through a distributed hardware/software architecture and presentation of information is in graphical form on System Control and Data Interface (SCDI) workstations and through indicators and controls on Radar Control Panels (RCPs) at local and remote sites. The same status available on the local radar site SCDIs is available to remote OMTs. Status and Control screens available on the local radar SCDIs are the same at remote sites that have remote OMTs.

Interfacing to various remote sites is via various equipment consisting of Modems, 4-Channel MUX, cable adapters, fiber optic transceivers, thin-wire transceivers, and a converter.

1-4 CONFIGURATIONS.

The ASR-11 RMS supports all ASR-11 configurations listed in WP 002 00.


The RMS allows the same control and monitoring capability of the ASR-11 from any OMT or SCDI. A typical ASR-11 RMS concept block diagram is shown in Figure 1 and illustrates the distributed architecture of the ASR-11 RMS. The dotted lines denote functional and typical location boundaries. Also shown is an Ethernet interface between the local radar site and a Surveillance Data Translator (SDT) at the indicator site. The design accommodates a remote SDT location. The indication that Standard Terminal Automation Replacement System (STARS) exist at remote sites (Sites 3, 4, and 5, respectively in Figure 1) is meant to be representative only. The interface design accommodates local indicator site STARS installations.

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WP 007 00

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Figure 1. Typical ASR-11 RMS

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TI 6310.47 1 DECEMBER 2003 WP 007 00

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1-5.1 Local Site RMS Operation. The dual redundant SCDIs at the local site perform overall local site control and serve as the central local site RMS. They control themselves, the dual redundant Facilities Monitoring and Control (FMAC) units, the Monopulse Secondary Surveillance Radar (MSSR), the Primary Surveillance Radar (PSR), and monitor and collect status information from all site equipment. A Radar Control Panel (RCP) connects to both local SCDIs through an A/B switch that is provided. In normal operations, one of the SCDIs at the local radar site is On-line Selected and the other is in On-line Standby. In the event of a failure in the On-line Selected SCDI, the SCDI transfers control to the On-line Standby and is itself placed in maintenance.

The local site MSSR and PSR are in control of their own startup and contain their own local RMS functions, which monitor and control their own start up diagnostics, channel switchover (unless overruled by the SCDIs) and fault detection and isolation.

The PSR interfaces to the OMTs via dual redundant Ethernets and the MSSR interfaces to the OMTs via dual redundant serial lines.

Change in Variable Site Parameters (VSPs) via a text edit function is only done at the local radar site via the local SCDIs. The local SCDIs permit two levels of VSP changes. These are changes by the maintenance operator and second level engineering changes. Operator adjustable parameters are made available on the SCDI screens for local and remote operator control. There are typically 500+ maintenance operator VSPs and 1000+ second level engineering VSPs.

1-5.1.1 Typical Maintenance Operator VSPs. Typical maintenance operator VSPs that are currently available in the baseline system include:

a. Permanent echo and MSSR Remote Site Monitor (MRSM) location data.

b. Antenna alignment settings.

c. General tracker (e.g., coast count, velocity threshold).

d. Track initiation inhibit zones (25).

e. Primitive target reporting zones (25).

f. general weather (e.g., map vector limit, map compaction levels).

g. Sector blanking (no reporting) zones (10).

h. Initial start up control settings.

i. Initial start up selections (e.g., In use beam STC maps).

j. UNIX environment limits (e.g., maximum number of open windows).

k. Local site data (e.g., name, ASTERIX SIC/SAC).

l. Transmitter blanking (No RF output) zones (8).

m. Weather calibration thresholds.

n. Constant false alarm thresholds (per Doppler filter).

o. Velocity threshold over-ride zones.


WP 007 00

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1-5.1.2 Second Level Engineering VSPs. Typical second level engineering VSPs that are currently available in the baseline system include:

a. Communication port definition tables.

b. Site equipment configuration tables.

c. General facilities monitoring logic tables.

d. Plot processing (cluster validation VSPs and complex cluster VSPs).

e. Detection/plot/track overload thresholds.

f. Detection overload protection response VSPs.

g. Doppler filter editing function table.

h. Plot amplitude thresholding function responses.

i. Plot overload protection responses.

j. Track overload protection responses.

k. General radar combiner parameters.

l. Weather processing adaptive filter clutter thresholds.

m. General Signal Data Processor (SDP) data (e.g., recorded data default file names).

n. Alarm and event filtering tables.

1-5.2 Remote RMS Operation. The local SCDIs, in addition to controlling the site and collecting site status, also collect status of links to remote sites, as well as status of the SDTs and whether the System Interface Unit (SIU) communication status is operational or unknown. Single point of control is maintained through the local SCDIs, which communicate with the remote OMTs.

The local SCDIs interface to various remote sites via Commercial Off-The-Shelf (COTS) equipment. In the case of a nearby indicator site, the interface is through dual redundant Local Area Network (LANs), with fiber optic transfer of data to another dual redundant LAN at the indicator site. In the case of a remote indicator site, communications media other than fiber optics, including Line Sharing Units (LSUs), modems and telephone lines may be used to provide the data transfer to the indicator site. The SDT, remote OMTs, their control panel(s), and modems are used for data remoting from a nearby indicator site to other automation sites. The SIU shown in Figure 1 is used to provide a formatting function, as required for remoting to other automation sites (e.g., STARS).

Due to the flexibility of the LAN-LAN interface structure, the remoting of information to distant sites can be performed from either the indicator site (e.g., Radar Approach Control Center (RAPCON)/Terminal Radar Approach Control Center (TRACON) or tower) or from the local radar site without impact to the integrity of the data remoting interfaces, but within the availability of telephone lines (when needed) at the local site. The SIU can also be located at the indicator site, at the local site (if the data remoting is done from the local site), or at a distant remote site.

The local SCDIs and remote OMTs have the same Status and Control screens, and remote control of the local radar site is requested through the remote OMTs via control panel(s) or the remote OMTs themselves.

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WP 007 00

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The following applies to all subsequent paragraphs of this WP:

a. Operator requested data (e.g., detailed status) is only sent to the originator (local SCDI or remote OMT).

b. Periodic (i.e., once per second) summary status messages (i.e., information on the top level OMT screen) are sent to all connected users. This is done automatically without need for user request/action.

c. System alarms and alerts are sent to all connected users (SCDIs and OMTs). This is done automatically without need for user request/action.

1-5.3 Performance and Functional Requirements. The RMS performs the following control, monitoring, and troubleshooting functions (either locally or remotely).

a. Control of ASR-11 operational functions and adjustable operator parameters. VSPs are changed only at the local radar site SCDIs.

b. Monitor, collect, and process performance and status data to determine if the ASR-11 is operating within specified limits.

c. Provide alarms, alerts, and status of system elements needed for operation (e.g., PSR and SSR electronics; Heating, Ventilation, and Air Conditioning (HVAC); back-up power systems; system security and safety control systems).

d. Perform fault isolation and diagnostic tests on the ASR-11 system to isolate failures.

e. Loss of remote maintenance monitoring connectivity (i.e., failure of the NIMS interface) does not cause loss of radar data to automation systems.

f. No remote monitoring subsystem function in the maintenance mode causes loss of radar data to automation systems.

Note: It is a task of the RMS to maintain the ASR-11 in an operational state. In the event of a failure, the RMS has the ability to reconfigure subsystems and units to ensure this is maintained. During such reconfigurations, it is normal to experience minor interruptions in radar data (typically one frame of High-Level Data Link Control (HDLC) data). These minor interruptions do not constitute a loss of radar data to automation systems as specified in steps e and f. In the On-line mode, there are instances when the RMS can interrupt system operation.

1-5.4 Local and Remote Control and Local Site Parameter Adjustments. The RMS executes control functions and operator parameter adjustment commands upon receipt of commands from an OMT, SCDI, or an RCP within an average time of two seconds and a maximum time of five seconds, from the time the RMS receives a control command. The local SCDI and remote OMTs are able to control ASR-11 functions and operator parameters. The remote monitoring subsystem through the local SCDI and remote OMTs at the originating site inherently validates all commands and restricts operator actions automatically if a command is disallowed. At a minimum, the following functions can be included upon receipt of the appropriate command:

a. Change, including initialization and reset, operator adjustable parameters, including mode of operation and system configuration.

b. Change, from local site only, parameter threshold values that are adjustable.

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*

*

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WP 007 00

8

c. Local SCDI or remote agent initiate diagnostics routines to isolate faults (performed from local or remote OMTs or automatically when automatic fault detection occurs. Channels are automatically placed in Maintenance mode for diagnostics and fault isolation. Otherwise, manual placement of channels is performed from either the remote OMT or local SCDIs).

d. Where applicable, reset an ASR-11 subsystem or part of a subsystem. This is done from the local SCDI and remote OMTs. Limited control is provided by the RCP to ensure integrity of operation of the ASR-11 system.

e. Disable/Enable alarm or alert indications (SCDIs or OMTs only). This function is unique to each SCDI and OMT.

1-5.5 Monitoring.

1-5.5.1 Performance Monitoring. At periodic intervals (typically 1 second), the RMS monitors, executes measurements, and collects hardware and software critical performance data of the ASR-11 to determine whether each subsystem (e.g., PSR, MSSR, HVAC, back-up power system, and facility) is operating within specified limits.

1-5.5.2 Status Data. The RMS monitors and collects operating status and Built-In Test (BIT) results, including those of system configuration, mode of operation, and facilities equipment.

1-5.5.3 RMS Data Acquisition.

a. The collection of performance and status data is performed every status cycle without the need for an external command.

b. Collected status data is used by the local site radar monitoring subsystem to determine and remotely distribute the equipment status for each element of the ASR-11. Remote terminal data is distributed once per cycle.

c. The performance status data collected is used by the remote monitoring subsystem to determine system operability.

1-5.6 RMS Alarms and Alerts. The RMS determines and reports alarm and alert status of the ASR-11 equipment for parameters that are required to maintain continuous ASR-11 operation:

a. An alert condition is defined as an occurrence or performance parameter outside the normal operational configuration or operating range of the system, but which does not affect continued operation of the system (e.g., engine generator door open, operator induced system reconfiguration). The second level VSPs permit the change in classification for most events from Alarms-to-Alerts and vice-versa.

b. An Alarm condition is defined as an occurrence or performance parameter that affects or will affect system performance if not fixed (e.g., any system faults as displayed on the top level screen of the SCDIs, OMT, low transmitter power, motor B failure, stability out-of-specification).

c. The alarm and alert thresholds that are available for these conditions or parameters (e.g., probability of detection alarm threshold), with the exception of those which are on/off only, are programmable so that they can be changed at the local OMTs by a maintenance operator or by second level engineering via a text edit function.

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WP 007 00

9

d. The RMS reports alarms and alerts based on the set thresholds for conditions which affect critical system performance or data integrity.

1-5.6.1 Alarm and Alert Processing. The RMS performs a discriminating function to minimize the declaration of alarms and alerts caused by transient conditions.

a. The RMS checks every performance parameter value for an alarm or an alert condition at least once during a general status cycle and automatically report any and all alarm or alerts discovered.

b. The RMS monitors and checks numeric performance parameter values, detects out-of-tolerance values, and reports out-of-tolerance events (alarm or alert).

c. All out-of-tolerance and status conditions identified as alarms and alerts will be reported immediately and time tagged and stored in order of occurrence.

1-5.6.2 Return to Normal Processing. The RMS automatically generates a system notification message with a return to normal indication for each applicable parameter previously reported as an alarm or alert when it is no longer in either the alarm or alert state (normal operating range).

1-5.7 Fault Isolation. The RMS initiates fault isolation and diagnostic routines of the ASR-11 to isolate system failures to the Lowest Replaceable Unit (LRU) level, under control of an operator maintenance terminal, SCDIs or OMTs.

a. The RMS initiates the appropriate diagnostic routine automatically on fault detection and executes the command by directing the diagnostic test, collects and analyzes data, and formats and sends a response to the SCDIs or OMTs.

b. The RMS permits the termination of fault isolation and maintenance tests at any time by maintainer action from a SCDIs or OMTs.

c. The RMS is able to initiate manual fault isolation on a channel placed in maintenance by the RMS or placed in maintenance by an operator at a SCDIs or OMTs. Results of manual fault isolation are only sent out to the originator.

1-5.8 RMS Data Security. The RMS provides security measures to protect the integrity of the ASR-11:

a. Control access to the RMS through a SCDIs or OMTs is permitted only in response to a valid log-on procedure, based on a valid user ID in conjunction with a unique code word.

b. The RMS logs off an attached SCDIs or OMTs and returns to a no controller mode when the operator maintenance terminal in control has been inactive after a VSP timeout period.

c. Each SCDI or OMT provides for the disabling of automatic log off.

Note: The default power-up state for the local SCDIs is Automatic Log Off - Disabled, for all remote OMTs, it is Automatic Log Off - Enabled.

d. Protocol for RMS control access among the ASR-11 points of control is as follows:

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*

*


WP 007 00

10

1. Only one control point is designated as the primary point of control (locking out all others) for the radar site equipment.

2. The capability for transfer of control between designated control points is provided.

3. The transfer of control between two control points requires deliberate and coordinated action at each of those control points.

4. Visual signals are provided at both control points during control transfers.

5. The system status does not change due to a control point transfer.

6. Each control point provides a visual indication of its status.

7. If an ASR-11 radar control panel is in control, system status will be provided to the SCDIs or OMTs. The ASR-11 RCPs are permitted to attain system control without the logon or user ID requirements of step 1-5.8a or any other security restrictions.

1-5.9 SCDI State Change Processing. The RMS notifies (within 1 + 0.5 second from detection) all connected SCDIs or OMTs when an operating mode or system configuration changes for the ASR-11. Changes to the operator adjustable parameters are registered at the originating SCDI or OMT.

1-5.10 Data Storage. The local site RMS maintains initialization tables, threshold values, parameter state values, adjustable parameter values, and equipment status and performance data.

a. Equipment status and performance data includes all critical performance parameter data, including certification data, the past history of alarms and alerts with a time and date tag for each entry. Archiving of this data takes place automatically when the log size reaches 100%. If the archived data is not copied or moved to another location it will be overwritten when the next automatic (or manual) archive action occurs. For manual archives, follow the instructions displayed on the "Dump Log" pop up screen to copy the archive file to removable media. The OMTs provide the functionality to enable the user to review the event log.

Note: Each SCDI or OMT compiles its own log of alarms and alerts. Each SCDI or OMT has the capability to review this log at any time (e.g., does not have to be in control of the system to perform this review).

b. The stored data is configured in such a way that an individual group or category of data can be recalled separately when requested by a SCDI or OMT.

1-5.11 Data Retrieval. Applicable ASR-11 equipment parameter values collected and stored by the RMS (e.g., alarms, alerts, and certification parameter values) is retrievable through commands issued to the RMS via SCDIs or OMTs.

1-5.12 RMS Communication Mode. The RMS is able to operate in the following modes. The switch from one mode to another occurs within an average time of one second and a maximum time of three seconds. The modes are Remote, Local, and No Controller.

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WP 007 00

11

a. Remote Mode - A single remote OMT or radar control panel is in control of RMS functions. However, status and performance data is available to all other OMTs, SCDIs, and RCPs.

b. Local Mode - The radar site local SCDI is in control of RMS functions. In this mode, the local site RMS will continue to supply status data to all other OMTs and RCPs.

c. No Controller Mode - In this mode, all RCPs, SCDIs, and OMTs have relinquished control. System control will be given to the first RCP that requests it or to the first remote OMT, or SCDI that provides a valid user/password combination. The first RCP or local SCDI to request control gets it.

Note: ASR-11 equipment detailed status is available on request to all OMTs, and NIMS proxy agent at all times and does not require the originator to be in control of the system.

1-5.13 Operator Maintenance Terminal Menu. The RMS software provides menus containing all information necessary for maintenance personnel to control the RMS or obtain data from the RMS using an OMT or SCDI. An on-line Help feature is also provided.

1-5.14 Remote Site Functional Interface. The RMS has the capability to use a commercial telephone network via EIA-530 to interface to remote terminals.

1-5.15 Operator Maintenance Terminal Common Functionality. All local SCDIs, remote OMT and NIMS proxy agents have the following common functionality:

a. ASR-11 control and monitoring.

b. ASR-11 diagnostics and fault isolation (BIT/FI).

1-5.16 SCDI Functionality Differences. The following functions are limited to radar site local SCDIs only.

a. VSP data file adjustment.

b. Radar Data Display (RDD).

c. Local Workstation actions (e.g., Map administration).

1-5.17 RMS Architecture. ASR-11 provides a flexible RMS architecture. In addition to the two local radar site SCDIs and one radar control panel, it is possible to have from one to four remote OMTs and from one to four RCPs (maximum of two per OMT).

1-5.18 Adjustable Parameters. The RMS supports and permits adjustment to the following parameter groups under the conditions specified.

1-5.18.1 Operator Adjustable Parameters. These parameters (e.g., Beam/STC map number selection) are those that are currently available on any OMT (local or remote), SCDI and appear as controls on the SCDI screens. Adjustment of this group is permitted in on-line maintenance by any OMT or SCDI proxy agent that has been granted control of the ASR-11 system.

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TI 6310.47 1 DECEMBER 2003 WP 007 00

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1-5.18.2 Variable Site Parameters. These VSPs are only available on the radar site local SCDIs and reside on the hard disk in text form. In general, these parameters modify the operation of the radar. The radar site local SCDI RMS application provides a facility where by these files may be called up and the contents edited.

Changes to VSPs are only permitted when the PSR system is in maintenance mode. Since the VSPs affect the detailed processing of the radar as well as determining the PSR system operating configuration, it is not envisioned that these parameters would require adjustment following site commissioning.

The SCDI RMS application provides password protection to restrict access to these parameters by maintenance personnel. Further password protection is provided to allow a qualified maintenance technician to gain access and change these parameters.

2. INSPECTIONS.

Refer to WP 004 05 for all inspections.

3. TESTING.

Refer to the equipment manual G584380 ASR11 S-Band Primary Surveillance Radar Equipment Manual Section 2.

4. MAINTENANCE.


Refer to WP 004 05 for preventative maintenance tasks for each item listed in the Reference Material Required section.


There is no authorized repair of the RMS.

TI 6310.47 1 DECEMBER 2003 WP 007 01

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WORK PACKAGE


DATA TRANSLATOR EQUIPMENT (DTE)




Page Change Page Change Page Change No. No. No. No. No. No.

1 thru 10 0

TABLE OF CONTENTS

Paragraph Page

1. PURPOSE ........................................................................................................ 4

2. SCOPE ............................................................................................................. 4

3. DESCRIPTION ................................................................................................. 4 3-1 SDT COMPONENTS ....................................................................................... 4 3-2 DVG COMPONENTS ....................................................................................... 4 3-3 SIU COMPONENTS ......................................................................................... 6

4. EXTERNAL INTERFACES ............................................................................... 6

5. CONFIGURATIONS ......................................................................................... 6

6. LEADING PARTICULARS ............................................................................... 7 6-1 DTE CONSOLE ................................................................................................ 7 6-2 SYSTEM INTERFACE UNIT ............................................................................ 7 6-3 DIGITAL VIDEO GENERATOR ....................................................................... 7 6-4 SURVEILLANCE DATA TRANSLATOR .......................................................... 7

7. PRINCIPLES OF OPERATIONS ..................................................................... 7 7-1 DTE CONSOLE ................................................................................................ 7 7-2 SYSTEM INTERFACE UNIT ............................................................................ 7 7-3 DIGITAL VIDEO GENERATOR ....................................................................... 8 7-4 SURVEILLANCE DATA TRANSLATOR .......................................................... 8

8. INSPECTIONS ................................................................................................. 8

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Paragraph Page

9. TESTING .......................................................................................................... 8 9-1 ROUTINE TESTING ......................................................................................... 8 9-1.1 DTE Console .................................................................................................... 8 9-1.2 System Interface Unit ........................................................................................ 8 9-1.3 Digital Video Generator ..................................................................................... 8 9-1.4 Surveillance Data Translator ............................................................................. 8 9-2 FAULT ISOLATION .......................................................................................... 8 9-2.1 DTE Console .................................................................................................... 8 9-2.2 System Interface Unit ........................................................................................ 8 9-2.3 Digital Video Generator ..................................................................................... 8 9-2.4 Surveillance Data Translator ............................................................................. 8

10. MAINTENANCE ............................................................................................... 8 10-1 PREVENTIVE MAINTENANCE TASKS ........................................................... 8 10-1.1 DTE Console .................................................................................................... 8 10-1.2 System Interface Unit ........................................................................................ 8 10-1.3 Digital Video Generator ..................................................................................... 9 10-1.4 Surveillance Data Translator ............................................................................. 9 10-2 REPAIR PROCEDURES .................................................................................. 9 10-2.1 DTE Console .................................................................................................... 9 10-2.2 System Interface Unit ........................................................................................ 9 10-2.3 Digital Video Generator ..................................................................................... 9 10-2.4 Surveillance Data Translator ............................................................................. 9


Figure Page

1 SDT Functional Block Diagram ............................................................................... 5

LIST OF TABLES

Table Page

None

TI 6310.47 1 DECEMBER 2003 WP 007 01

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REFERENCE MATERIAL

REQUIRED Publication Number Publication Title

730-009116 Installation, Operation and Maintenance Manual for the Digital Airport Surveillance Radar (DASR) Data Translator Equipment System (Sensis)

TI 6310.47 1 DECEMBER 2003 WP 007 01

4

1. PURPOSE.

The purpose of this Work Package (WP) is to provide operation and maintenance information for the Digital Airport Surveillance Radar (ASR-11) Data Translator Equipment (DTE).

2. SCOPE.

This WP provides system-level information for the DTE. This includes system description, system interfaces, system operation, and other pertinent information to allow the user to be familiar with the DTE. For a detailed description of the ASR-11 DTE, refer to Reference Material Required section.

3. DESCRIPTION.

The DTE is a subsystem within the ASR-11 system that provides the interfacing between the ASR-11 radar equipment and the government Air Traffic Control (ATC) automation systems. A DTE system consists of two System Interface Units (SIUs). An overview of the relationship of the DTE equipment to other parts of ASR-11 and the external interfaces is illustrated in Figure 1.

3-1 SIU COMPONENTS. The SIU consists of the following components:

a. SIU Enclosure with power module

b. SIU Module

c. Ethernet 10baseT Hub 4. EXTERNAL INTERFACES. This section describes the external interfaces of the DTE subsystem. The external interfaces are unidirectional. For more detailed information, refer to the 730-009116 manual.

a. SCDI-to-SIU - An SIU accepts target data and weather reports from the on-line SCDI via one of the two Ethernet LANs. Two SIUs, one connected to each LAN, are used for redundancy.

b. SIU-to-STARS - The SIU provides data to STARS installations via multiple synchronous serial RS-530 interfaces. 5. CONFIGURATIONS. The DTE supports the configuration listed in WP 002 00, as required by the specific site.

a. SIU - To provide digital surveillance and weather feeds to Standard Terminal Automation Replacement System (STARS).

6. LEADING PARTICULARS.

6-1 SYSTEM INTERFACE UNIT.

Refer to Chapter 5 of 780-004232, Installation, Operation, and Maintenance Manual for the

TI 6310.47 1 DECEMBER 2003 WP 007 01

5

System Interface Unit of the Airport Surveillance Radar (ASR-11) Data Translator Equipment, for leading particulars on the SIU.

7. PRINCIPLES OF OPERATIONS.

7-1 SYSTEM INTERFACE UNIT.

Refer to Chapter 8 of 780-004232, Installation, Operation, and Maintenance Manual for the System Interface Unit of the Airport Surveillance Radar (ASR-11) Data Translator Equipment, for operations information on the SIU.

8. INSPECTIONS. Not Applicable.

9. TESTING.

9-1 ROUTINE TESTING.

9-1.1 System Interface Unit. No routine testing required.


9-2.1 System Interface Unit. No fault isolation.

10. MAINTENANCE.


10-1.1 System Interface Unit. There are no preventative maintenance tasks for the SIU.

10-2 REPAIR PROCEDURES. 10-2.1 System Interface Unit. Refer to WP004 07, paragraph 4-6.2, for replacement procedures for the SIU. The SIU is a LRU and is not repairable at the organizational level.

TI 6310.47 1 DECEMBER 2003 WP 007 01

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This page intentionally left blank.


WP 008 00

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WORK PACKAGE


MSSR REMOTE SITE MONITOR (MRSM)


TABLE OF CONTENTS

Paragraph Page

1. GENERAL INFORMATION .............................................................................. 3 1-1 PURPOSE ....................................................................................................... 3 1-2 SCOPE ............................................................................................................ 3 1-3 DESCRIPTION ................................................................................................ 3 1-4 CONFIGURATIONS ........................................................................................ 3 1-5 LEADING PARTICULARS ............................................................................... 3 1-6 PRINCIPLES OF OPERATIONS ..................................................................... 3

2. INSPECTIONS ................................................................................................. 3

3. TESTING .......................................................................................................... 3 3-1 ROUTINE TESTING ........................................................................................ 3 3-2 FAULT ISOLATION ......................................................................................... 4

4. MAINTENANCE ............................................................................................... 4 4-1 PREVENTIVE MAINTENANCE TASKS .......................................................... 4 4-2 REPAIR PROCEDURES ................................................................................. 4

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WP 008 00

2


Figure Page

None

LIST OF TABLES

Table Page

None


Publication Number Publication Title TI 6310.54 Digital Airport Surveillance Radar ASR-11 Equipment Manual for

Dual Channel Site Monitor


APPLICABLE TCTOS

None

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*


WP 008 00

3


1-1 PURPOSE.

The purpose of this Work Package (WP) is to provide operation and maintenance information for the Digital Airport Surveillance Radar (ASR-11) Monopulse Secondary Surveillance Radar (MSSR) Remote Site Monitor (MRSM).

1-2 SCOPE.

This WP provides system-level information for the MRSM. For a detailed description of the MRSM, refer to Reference Material Required section.

1-3 DESCRIPTION.

The MRSM is a dual-redundant channel Mode-S upgradable system and provides continuous on-line performance monitoring of the MSSR system. It replies with preset codes to MSSR interrogations on Modes 3/A, B, and C. It is possible to select either channel/transponder as the operational transponder with the nonselected channel always remaining in a standby mode for immediate operation. If a failure is detected in the selected transponder, changeover to the standby transponder is automatic. The MRSM will be locatable with its antenna mounted on a mast in line-of-sight and between 0.5 and 10 nmi of the Interrogator antenna head. It may be located in either an existing building if available, if appropriate housing is not available, a pre-fabricated NEMA 4 enclosure will be used. The MRSM consists of the following equipment:

a. Site monitor (with two power supplies, two transponders, and two controllers)

b. Antenna

1-4 CONFIGURATIONS.

The MRSM supports configurations 1, 3, 4, and variations as depicted in WP 002 00.


Refer to Section 1 of TI 6310.54, Digital Airport Surveillance Radar (ASR-11) Equipment Manual for Dual Channel Site Monitor for leading particulars.


Refer to Section 2 of TI 6310.54, Digital Airport Surveillance Radar (ASR-11) Equipment Manual for Dual Channel Site Monitor for principles of operation.

2. INSPECTIONS.

Refer to Section 4 of TI 6310.54, Digital Airport Surveillance Radar (ASR-11) Equipment Manual for Dual Channel Site Monitor for inspection information.

3. TESTING.


No routine testing is required for the Dual Channel Site Monitor. All testing is automatic and requires no operator initiation or intervention.

**

**

**


WP 008 00

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Refer to Section 4 of TI 6310.54, Digital Airport Surveillance Radar (ASR-11) Equipment Manual for Dual Channel Site Monitor for fault isolation information.

4. MAINTENANCE.


Refer to Order 6310.30, Maintenance Handbook for Airport Surveillance Radar (ASR-11) Facilities for preventative maintenance instructions.


Refer to Section 4 of TI 6310.54, Digital Airport Surveillance Radar (ASR-11) Equipment Manual for Dual Channel Site Monitor for repair procedures.

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WP 009 00

1

WORK PACKAGE


MTI/REFLECTORS


TABLE OF CONTENTS

Paragraph Page

1. GENERAL INFORMATION ............................................................................... 3 1-1 PURPOSE ........................................................................................................ 3 1-2 SCOPE ............................................................................................................. 3 1-3 DESCRIPTION ................................................................................................. 3 1-4 CONFIGURATIONS ......................................................................................... 3 1-5 LEADING PARTICULARS ................................................................................ 3 1-6 PRINCIPLES OF OPERATIONS ...................................................................... 4

2. INSPECTIONS .................................................................................................. 4

3. TESTING ........................................................................................................... 4 3-1 ROUTINE TESTING ......................................................................................... 4 3-2 FAULT ISOLATION .......................................................................................... 4

4. MAINTENANCE ................................................................................................ 4 4-1 PREVENTIVE MAINTENANCE TASKS ........................................................... 4 4-2 REPAIR PROCEDURES .................................................................................. 4

**


WP 009 00

2


Figure Page

None

LIST OF TABLES

Table Page

None


Publication Number Publication Title MA150A Technical Manual for Moving Target Indicator (MTI) Reflector, S Band PSI Model A-150a JO 6310.30 Maintenance Handbook for Airport Surveillance Radar, ASR-11

Facilities.

APPLICABLE TCTOS

None

* *

TI 6310.47 1 DECEMBER 2003 WP 009 00

3


1-1 PURPOSE.

The purpose of this Work Package (WP) is to provide operation and maintenance instructions for the Digital Airport Surveillance Radar (ASR-11) Moving Target Indicator (MTI)/Reflectors.

1-2 SCOPE.

This WP provides system-level information for the MTI/Reflectors. For a detailed description of the MTI/Reflectors, refer to Reference Material Required section.

1-3 DESCRIPTION.

The MTI will be used to align the Primary Surveillance Radar (PSR), monitor its performance, and provide geographical reference points (including runway centerline) required for radar surveillance approaches. The MTI will employ a parabolic reflector and includes a feed system that is responsive to frequencies in the range 2700 to 2900 MHz. The MTI phase-switching rate, phase variations and effective radar cross section in the frequency band allows the PSR to detect and process the reflected signal from selected MTI/Reflector positions within 6 nmi of the PSR position.

The MTI/Reflector is comprised of a parabolic dish antenna and electronics located at a known geographic reference point on the radar displays. It provides the user with an indication of the centerline of a runway and/or a fixed mileage reference point.

a. MTI/Reflector electronics are mounted in close proximity to the antenna and housed in a weatherproof case.

b. MTI/Reflectors take advantage of mounts of opportunity (e.g., buildings, towers, and poles) where feasible and available. If these are not feasible or desirable, a mounting, such as a pole or tower with appropriate foundation and structural support is provided.

c. Power for the MTI/Reflectors is mounted in conjunction with the MTI/Reflector and is integral to the system.

d. Power for the MTI/Reflector is self-contained with preference given to rechargeable batteries, and is housed in a weatherproof case.

e. Where environmental conditions permit, batteries are provided with solar cell panels to automatically provide recharging power. Solar cells are installed to maximize sunlight collection are not be susceptible to movement by winds.

f. Batteries and solar panels have been installed in a manner to permit ease of maintenance service, while preventing access by unauthorized personnel.

1-4 CONFIGURATIONS.

The ASR-11 MTI/Reflectors supports all configurations listed in WP 002 00.


Refer to Chapter 1 of A-150a_manual.doc, Technical Manual for Moving Target Indicator (MTI) Reflector, S Band PSI Model A-150a.


WP 009 00

4


Refer to Chapter 3-1 of A-150a_manual.doc, Technical Manual for Moving Target Indicator (MTI) Reflector, S Band PSI Model A-150a.

2. INSPECTIONS.


3. TESTING.


There is no routine testing required.



4. MAINTENANCE.


Refer to Order 6310.30, Maintenance Handbook for Airport Surveillance Radar, ASR-11 Facilities, chapter 4, paragraph 4-16.



**

TI 6310.47 1 DECEMBER 2003 WP 010 00

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WORK PACKAGE

OVERVIEW

FACILITY EQUIPMENT




Page Change Page Change Page Change No. No. No. No. No. No.

1 thru 14 0

FP-1 thru FP-16 0

TABLE OF CONTENTS

Paragraph Page

1. GENERAL INFORMATION ......................................................................................... 4 1-1 PURPOSE .................................................................................................................. 4 1-2 SCOPE ....................................................................................................................... 4 1-3 DESCRIPTION ........................................................................................................... 4 1-3.1 Tower and Antenna Equipment Housing .................................................................... 7 1-3.2 MSSR Remote Site Monitor Housing ......................................................................... 8 1-3.3 Radar Electronics Housing ......................................................................................... 8

2. SITE HOUSING .......................................................................................................... 9 2-1 PRE-FABRICATED SHELTER(S) .............................................................................. 9 2-2 PRE-ENGINEERED HOUSING ................................................................................. 9 2-3 BUILT-ON-SITE HOUSING ........................................................................................ 9 2-4 MODIFICATIONS OR ALTERATIONS TO EXISTING BUILDINGS ......................... 10

3. EQUIPMENT ............................................................................................................. 10 3-1 HEATING, VENTILATION, AND AIR CONDITIONING SYSTEM ............................ 10 3-1.1 Air Filters .................................................................................................................. 10 3-1.2 HVAC Design ........................................................................................................... 11 3-1.3 HVAC Equipment ..................................................................................................... 11 3-1.4 Compressor Dehydrator ........................................................................................... 11 3-2 POWER AND SUPPLIES ......................................................................................... 11 3-2.1 Uninterruptible Power Supply ................................................................................... 11 3-2.2 Electrical Configuration ...................................................................................................... 11 3-2.3 Critical Power Distribution ........................................................................................ 11

TI 6310.47 1 DECEMBER 2003 WP 010 00

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Paragraph Page

3-2.4 Non-Critical Power Distribution 12 3-2.5 Exterior Lighting 12

4. INSPECTIONS 12

5. MAINTENANCE 13 5-1 PREVENTIVE MAINTENANCE TASKS 13 5-1.1 Facility 13 5-1.2 Compressor Dehydrator Access 13 5-2 REPAIR PROCEDURES 14


Figure Page

1 Top Level Facilities Block Diagram 5 2 Typical Engine-Generator Housing Plan 6 FO-1. Config 1 Electrical One-Line Diagram FP-1 FO-2. Config 1 Facility Power Layout FP-2 FO-3. Config 1 Control and Signal Plan FP-3 FO-4. Config 1 Facility Grounding Plan FP-4 FO-5. Config 1 Facility Waveguide and Conduit Details FP-5 FO-6. Config 1 Pedestal Equipment Room Detail FP-6 FO-7. Config 1 Exhaust Fan Detail FP-7 FO-8. Config 1 Waveguide Support Details FP-8 FO-9. Config 4 CMU Building HVAC Plan, Sections and Details FP-9 FO-10. Config 4 Electrical One Line Diagram FP-11 FO-11. Config 4 Facility Power Layout FP-12 FO-12. Config 4 Facility Grounding Plan FP-13 FO-13. Config 4 Waveguide and Conduit Details FP-14 FO-14. Config 4 Pedestal Equipment Room Details FP-15 FO-15. Config 4 Controls and Signals Diagram FP-16

LIST OF TABLES Table Page 1 Electronic Equipment Housing Environment 10 2 Engine-Generator Set and MRSM Housing Environment 10


3



TI 6310.47 Digital Airport Surveillance Radar ASR-11 System Operation Maintenance Instructions Organizational Maintenance Level

TI 6310.54 Digital Airport Surveillance Radar ASR-11 Equipment for Dual Channel Site Monitor

TI 6310.56 Digital Airport Surveillance Radar ASR-11 System Manual for MSSR System

TI 6310.57A Digital Airport Surveillance Radar ASR-11, ASR-11 S-Band, Solid State Primary Surveillance Radar Technical Manual

JO 6310.30 Maintenance Handbook for Airport Surveillance Radar, ASR-11 Facilities

BAT-1189 HVAC Controller Manual

164201014 Installation Manual for International Power Machines Balanced Power 30-80 KVA Uninterruptible Power System

164201016 Operation Manual for International Power Machines Balanced Power 30-160 KVA Uninterruptible Power System

164201017 Installation Manual for International Power Machines Balanced Power Model 27 and Model 43 Auxiliary Battery Cabinets

None Equipment Building Technical Manual

None Engine Generator Building Technical Manual

IB-S 268 Rev. - Models 600/850/1200 Series A-D Compressor Dehydrator Installation

Part No. 48248 and Operation Manual

IB-S 268 Addendum

APPLICABLE TCTOS

None

*

*

* *

TI 6310.47 1 DECEMBER 2003 WP 010 00

4


1-1 PURPOSE.

The purpose of this Work Package (WP) is to provide an overview of the ASR-11 system level facility.

1-2 SCOPE.

This WP provides an overall description of the various facilities used with the ASR-11 system and necessary information allowing the user to become familiar with these facilities. Site specific information can be obtained in the Facilities/Antenna Tower Design (FATD) package.

1-3 DESCRIPTION.

The ASR-11 facility consists of the following:

a. Engine-Generator (E-G) housing

b. Tower and antenna equipment housing.

c. Monopulse Secondary Surveillance Radar (MSSR) Remote Site Monitor (MRSM) housing.

d. Radar electronics housing

Figure 1 shows these components. The E-G housing provides for a backup E-G set, an automatic transfer switch, and a load bank. The E-G set is capable of carrying the total power load and has a 20 percent reserve. The automatic transfer switch senses voltage increases or decreases of 10 percent or more on any phase, and automatically starts the E-G set, and assumes the facility load within 10 seconds. The load bank is rated at 100 percent of the E-G output power capacity. The fuel tank is capable of providing 72 hours of engine operation at full load.

The E-G housing (typical E-G housing plan is shown in Figure 2) contains the following:

a. Double doors.

b. Drip pan and mounting system for the E-G.

c. Power distribution system for control of the housing power and the powering of test equipment.

d. Work bench, integrated with the working design of the housing and suitable for mechanical maintenance activities typical of this type of facility, is provided inside the E-G housing and includes a minimum of two 120 volt/20 amp polarized duplex electrical receptacles.

e. Fire and smoke detection system is integrated into the E-G Room Housing and interfaced into the ASR-11 Radar Monitoring Subsystem (RMS).


5

Figure 1. Top Level Facilities Block Diagram

*

*


6

Figure 2. Typical Engine-Generator Housing Plan

*

*

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1-3.1 Tower and Antenna Equipment Housing. The ASR-11 facility includes a tower and antenna equipment on site.

The antenna tower meets the azimuth accuracy requirements for both the primary and secondary radar, based on anticipated static and dynamic loading, and on the combined wind and ice loading conditions. The tower is constructed so that the focal point of the radar is a minimum of 25 feet above the ground. The tower is expandable with standard tower sections to achieve a maximum focal point height of 95 feet.

The ASR-11 tower features the following:

a. Access doors, stairs, work platforms, and hoists to provide access for maintenance and replacement of tower and antenna elements.

b. A stairway is provided from the ground level to the top deck of the tower with landings at appropriate increments.

c. The antenna deck provides safe working access for the antenna system and associated components.

d. A perimeter guardrail and toe board is provided around each working level of the tower and access stairway.

e. The section of antenna deck immediately above the maintenance platform under the antenna/pedestal, or mezzanine, is solid to shield the work area from precipitation.

f. Access to the antenna deck is through a lockable door or hatch.

The antenna deck access is equipped with an interlock switch with manual override that disables both the antenna drive motor and the radar transmitter.

A permanently mounted, electrically powered weatherproof hoist capable of lifting the heaviest/largest item that might be replaced (excluding the antenna/pedestal and reflector assembly), is provided to transport equipment and tools from the ground onto the tower mezzanine.

Refer to System Interconnections WP 004 07, for site specific information on electrical signal and power cabling between the tower and the electronic equipment housing.

Two 120-volt, 20 amp, Ground Fault Interrupter (GFI) protected duplex convenience outlets housed in a UL-approved enclosure for outdoor electrical use is provided on opposite sides of the antenna/pedestal, on opposite sides of the mezzanine, and one additional duplex outlet at the foot of the tower stairway.

Aircraft obstruction lights are located on the tower. Lighting is provided for the antenna tower and related work areas as follows:

a. Stairway lights controlled by a switch at the ground level access to the stairs.

b. Lights for the mezzanine and platform level work areas controlled from switches at the mezzanine level and at the ground level.

c. Two portable floodlights that provide at least 100 foot-candles of light, with electrical cords to permit their use at any location on the antenna deck, for temporary illumination of the antenna and pedestal.

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1-3.2 MSSR Remote Site Monitor Housing. The MRSM electronics are housed in an existing building, if available. If an appropriate building is not available, NEMA housing is used.

Power distribution and protection equipment, and back-up power equipment for the MRSM are installed inside the MRSM enclosure. This power equipment is an integral part of the MRSM system.

1-3.3 Radar Electronics Housing. The radar electronics housing (Equipment Building) provides support for the Primary Surveillance Radar (PSR) and MSSR radar electronics, the Facilities Monitoring and Control (FMAC), the communications electronics and miscellaneous items, such as lights, smoke, fire, and intrusion alarms. The housing also contains a Heating, Ventilation and Air Conditioning (HVAC) system that maintains the interior environment between 11 and 31 ° C and 80 percent maximum relative humidity.

The radar electronics housing provides critical and non-critical power distribution. The critical power distribution contains an Uninterruptible Power Supply (UPS), which is capable of providing power continuity to the critical electronics for a minimum of 5 minutes. The UPS has a minimum of 20 percent reserve. The radar electronics housing power distribution system provides for isolation/step-down transformers from 480-volt delta primary to 208Y/120 or 380Y/220-volt electrical power. In addition, step-up transformers from 208-volt delta primary to 480Y/277-volt connected 4-wire secondary are provided at each branch panel board for loads requiring 480Y/277-volt electrical power. An alternative is also provided for ASR-11 system electrical configurations that utilize 3-phase, 60 Hz, 208Y/120 volts power at the service entrance.

The HVAC system, UPS, and facility items, including fire, smoke and intrusion alarm, provide for remote fault indication, status, and control.

Electronic equipment housing is designed as follows:

a. The housing provides adequate floor space to house the PSR, MSSR, a monitor and control workstation, an UPS, any ancillary equipment required for the maintenance and operation of the ASR-11 system, and adequate storage for required maintenance equipment, spare parts, and maintenance and operation manuals.

b. UPS equipment is also installed in the same area that houses electronic equipment.

c. A workbench, with a work surface made of a material that prevents static discharges, is integrated into the working design of the housing and is provided in the electronic equipment area. The workbench is suitable for electronic maintenance activities typical of this type of facility and includes a minimum of two 120-volt/20 amp polarized duplex electrical receptacles.

d. The housing has two entry doors designed to permit personnel and equipment access to the interior of the housing, generally located on opposite sides of the housing.

e. If the ASR-11 electronics and E-G equipment share housing, the E-G equipment is physically partitioned by a continuous fire-rated wall (for a minimum of one hour or higher, according to applicable building codes), and separate exterior doorways are provided.

f. A fire and smoke detection system is provided in each unit.

TI 6310.47 1 DECEMBER 2003 WP 010 00

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2. SITE HOUSING.

An ASR-11 installation can be housed in any of the following (as determined by the customer):

a. Pre-fabricated shelter.

b. Pre-engineered housing.

c. Built-on-site housing.

d. Modifications or alterations to existing housing.

2-1 PRE-FABRICATED SHELTER(S).

Shelters are constructed so that they can be transported to the site, installed on a prepared foundation, and in their final assembled state form an integral unit. Characteristics for this type of housing depend on its intended use:

a. Electronic equipment

b. Back-up power equipment

c. MRSM

Fabricated housings are provided for each of these as determined appropriate during the site survey. The electronic equipment housing(s) layout(s) accommodates the ASR-11 primary radar configured with secondary surveillance radar (MSSR). The HVAC system appropriate for pre-fabricated shelter use is integral to pre-fabricated shelter(s). Refer to the pre-fabricated shelter manual for more details.

2-2 PRE-ENGINEERED HOUSING.

Pre-engineered housing will typically be provided in modules and assembled at the construction site. Characteristics for this type of housing depend on its intended use:

a. Electronic equipment

b. Back-up power equipment

c. MRSM

Pre-engineered housing will be provided for each of these, as determined appropriate during the site survey. The housing will be anchored to a cast in-place concrete foundation at the installation site. Design details will be provided once the first pre-engineered housing is ordered.

2-3 BUILT-ON-SITE HOUSING.

A built-on-site structure for the ASR-11 electronics equipment is provided when needed. Construction drawings for a typical built-on-site structure are provided for reference and are included as Foldouts (FOs) to this WP. For a floor plan of a typical built-on-site structure, see Figure FO-1. The following FOs are provided with this WP:

a. FO-1 CMU Building HVAC Plan, Sections and Details

b. FO-2 Electrical One Line Diagram

c. FO-3 Facility Power Layout

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d. FO-4 Facility Grounding Plan

e. FO-5 Waveguide and Exterior Lighting Details

f. FO- 6 Pedestal Equipment Room Detail

g. FO-7 CMU Lighting and Receptacle Layout Plan

h. FO-8 Controls and Signals Diagram

2-4 MODIFICATIONS OR ALTERATIONS TO EXISTING BUILDINGS. At some ASR-11 locations, use of an existing building(s) may be used.

3. EQUIPMENT.

Each ASR-11 facility contains HVAC systems, power supply systems, tower features, alarms, and security. 3-1 HEATING, VENTILATION, AND AIR CONDITIONING SYSTEM. The ASR-11 facility includes HVAC systems appropriate for the geographic location of the structure, the type of housing, and the use of the housing. The HVAC system has one redundant unit and the HVAC controller sequences the turn-on of units and stages the operation of multiple units. The HVAC maintains the electronic equipment housing environment within the temperature and humidity range specified in Table 1, under all operating and environmental conditions anticipated to exist for each site, without exceeding 80% of the system's operational capacity. The HVAC systems supplied for the electronic equipment housing is provided with remote monitoring. The E-G and MRSM housings are provided with adequate heating systems to maintain the temperature specified in Table 2.

Table 1. Electronic Equipment Housing Environment

Characteristics Values

Temperature (range)

Relative Humidity (maximum)

52 - 88 ° F (11 - 31 ° C)

80%

Table 2. Engine-Generator Set and MRSM Housing Environment

Characteristics Values

Temperature (minimum) 50 ° F (10 ° C)

3-1.1 Air Filters. Filters are incorporated and mounted so that they can be readily examined and replaced in order to prevent the intrusion of dust or other environmental contaminants into the equipment housing and into equipment cabinets with independent ventilation systems. Special filter systems may be required for sites that have a high concentration of environmental pollution, or unusual climatic conditions.

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3-1.2 HVAC Design. Multiple HVAC system designs are fielded based on the environmental conditions prevalent at a particular site, and to accommodate the type and use of the housing. For site specific data, refer to the FATD and Commercial Off-The-Shelf (COTS) manuals provided. 3-1.3 HVAC Equipment. The HVAC equipment permits flexibility in configuration and operation, and provides energy-efficient operation.

a. For pre-engineered housing, built-on-site housing, and existing buildings that have been modified or altered, the basic HVAC system of equipment for the electronic equipment housing is comprised of three individual units, incorporated into a multiple-unit configuration. The individual units are small enough to provide efficient operation on days that require little or moderate cooling or heating. The system is designed so that individual or additional units can come on-line as needed to meet heating/cooling requirements. In addition to the basic system, an auxiliary unit is provided that can come on-line in the event of failure of an operating unit. This auxiliary unit has the same heating/cooling capability as one of the basic units. The system allows for control of units so that operating time on all units can be balanced.

b. For pre-fabricated shelters, the basic system is comprised of a primary individual unit, and a completely redundant auxiliary unit that can come on-line in the event of primary system failure.

c. The HVAC system controls provide for lead unit operation, with the equipment designated as lead to be remotely controlled and monitored.

The HVAC system incorporates controls to delay restarting and to sequentially restart individual units after a power failure to minimize surge currents. 3-1.4 Compressor Dehydrator. The Compressor Dehydrator provides pressurized dry air to the waveguide. This prevents condensation within the waveguide. 3-2 POWER AND SUPPLIES. Commercial power is provided to the ASR-11 site by a single-user pad-mounted transformer located adjacent to the electronic equipment housing. 3-2.1 Uninterruptible Power Supply. The UPS equipment, in conjunction with the facility surge arrestor, accepts commercial power variations without damage, stabilizes both frequency and voltage of commercial and E-G power during normal operation, and suppresses transient voltage conditions that may damage the ASR-11 equipment supplied by the critical power distribution system. Refer to the COTS manuals provided with equipment for site-specific data. 3-2.2 Electrical Configuration. Refer to the FATD Package and Installation Manual for site specific electrical configuration data. 3-2.3 Critical Power Distribution. The distribution system provides independent panelboards for dual channel equipment. Minimum system requirements are:

a. PSR, MSSR, CEC, Radar Monitoring System, and Communications Network breakers.

b. Antenna drive motor breakers.

TI 6310.47 1 DECEMBER 2003 WP 010 00

12

Cabinet ventilation blower breakers (if applicable), with power wiring separate from the electronics wiring for blowers external to the cabinets.

c. Breakers for receptacles.

d. Obstruction Lights and Azimuth Data Generator (ADG) breakers.

3-2.4 Non-Critical Power Distribution. The non-critical power distribution system has, as a minimum:

a. Lighting circuit breakers.

b. Receptacle circuit breakers.

c. EGEN Monitor system breakers.

d. HVAC circuit breakers.

e. Fire Alarm circuit breakers (has independent UPS).

f. Tower auxiliary circuit breakers.

g. Compressor/Dehydrator circuit breakers.

h. Cabinet utility receptacle circuit breakers (if required).

WARNING ON LOSS OF COMMERCIAL POWER, ALARMS AND ALERTS FOR MONITORED ITEMS ON NON-CRITICAL POWER DISTRIBUTION WILL BE REPORTED TO THE SCDI. THIS IS NORMAL AND WILL ONLY OCCUR WHILST TRANSITIONING BETWEEN POWER SOURCES. ALARMS AND ALERTS WILL CLEAR WHEN TRANSITION IS COMPLETE.

3-2.5 Exterior Lighting. Exterior site security lighting is provided throughout the site for employee safety. On a site-optional basis, security lighting can be controlled by a key-operated switch beside the access road at the site perimeter (outside of the security fence, if applicable), or by a photocell-controlled switch, based on the requirements of the specific site. 4. INSPECTIONS. Refer to site specific facility manuals provided for buildings listed in the Reference Materials Required section.


WP 010 00

13

5. MAINTENANCE.

All maintenance is scheduled per Order JO 6310.30.


Warning: Personnel performing maintenance should read and become familiar with the safety summary located in the front of this manual.

5-1.1 Facility. Refer to the Preventative Maintenance Table in WP 004 05 for the facility preventative maintenance schedule.

5-1.2 Compressor Dehydrator Access.

Tools, Equipment and Consumables Required:

Torque Wrench

Torque screwdriver

Compressor Dehydrator Maintenance Kit (P/N 46789-501) Sockets, at least 3/4 inch high (qty 2)

a. Turn off the compressor dehydrator power switch.

Note: Refer to TAGOUT/LOCKOUT section of Safety Summary for circuit breaker locations and tagout/lockout procedures. Lockout/Tagout procedures will be performed in accordance with locally-approved procedures.

b. Turn off and lockout circuit breaker 16 on distribution panel DP6.

c. Bleed tank pressure.

d. Remove compressor dehydrator cover.

e. Remove compressor pressure lines at compressor and compressor power.

f. Loosen, but DO NOT remove the two housing-mounting bolts on the left side of the compressor dehydrator unit (left when facing the front panel). Remove only the two housing-mounting bolts from the right side of the unit.

g. Lift right side of the unit and insert two sockets (at least 3/4 inch high) under the rubber feet of the compressor dehydrator.

h. Remove four compressor-mounting bolts.

**

TI 6310.47 1 DECEMBER 2003 WP 010 00

14

NOTE

Note orientation of compressor before removing.

i. Remove compressor from frame and rest on suitable working surface.

j. Service compressor according to IB-S 268 Rev. - (Models 600/850/1200 Series A-D Compressor Dehydrator Installation and Operation Manual). Use the Compressor/Dehydrator Maintenance Kit (P/N 46789-501) in accordance with the instructions in Section 8.0. DO NOT perform the torquing operation after 10 minutes of warm-up in Maintenance Kit Instructions (wait for step p below).

k. Remount compressor in compressor dehydrator housing in original orientation using four compressor mounting bolts.

l. Remove sockets from below rubber feet, lower housing, and reinstall two mounting bolts. Tighten all four mounting bolts.

m. Reattach pressure lines and compressor power.

n. Unlock and turn on circuit breaker 16 on power distribution panel DP6.

o. Turn on compressor dehydrator power switch. Ensure that the unit runs for ten minutes by bleeding the pressure from the tank valve, if necessary.

p. Torque cylinder head bolts to 150-160 in-lbs according to the Compressor Dehydrator Maintenance Kit Instructions.

q. Install cover.

5-2 REPAIR PROCEDURES. There are no repair procedures for the facility.

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2. BRKR2 SHALL BE SQ UARE D TYPE EHB IN NEWA 3R ENC LO SURE.

3. USE W6 AND W12 O UTSIDE O F EQ UIPM ENT SHELTER.

4. TVSS’S ARE LO C ATED IN THE EQ UIPM ENT SHELTER, TRANSIENT PRO TEC TIO N PANEL U31A12A1.

5. TVSS HAS AN INTERNAL M ANUAL DISC O NNEC T SWITC H.

6. C ABLE NUM BERS O N THIS DRAWING ARE FO R SYSTEM S INFO RM ATIO N . THEY DO NO T DELINEATE WHO SUPPLIES O R INSTALLS THE C ABLES.

7. C O NTRAC TO R TO RE-IDENTIFY C FE C ABLES W0041B, W0042B, W0041C , AND W0042C IN THE SURG E PRO TEC TIO N PANEL. THE SAFETY SWITC H AND AT THE PEDESTAL M O TO RS WITH PVC TAPE. C O LO RS TO BE AS FO LLO WS:

RED TO BLAC K/BRO WN BLAC K TO BLAC K/O RANG E BLUE TO BLAC K/YELLO W

8. M BP = M AINTENANC E BYPASS PANEL UPS = UNINTERUPTABLE PO WER SUPPLY

9. NEUTRAL TO BE C O NTINUO US BETWEEN THE SERVIC E ENTRANC E SWITC H AND THE G ENERATO R . DO NO T C O NNEC T TO THE AUTO M ATIC TRANSFER SWITC H.

10. C O NTRAC TO R TO C O NNEC T TVSS WIRES TO FEEDERS USING ILSC O IPC -350-410 O R EQ UAL.

TI 6310 .47WP 010 001 DEC EM BER 2003

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# 6 AWG WIRE INSULATED GREEN.

INSTALL 2" GRSC W/33/0 - THWN AND 1 # 6 GND

INSTALL 2" GRSC W/33/0 THWN AND 1 # 6 GND

INSTALL 1 1/4" GRSC W/3# 3 - THWN AND 1 # 8 GND

FOR EXACT LOCATION OFLIGHT SEE DWG

DASR-GEN1-C01(TYP 2 PLACES) INSTALL 2-3/4"

GRSC W/2 # 12 - THWN AND 1 # 12 GND

AIR

IN

AIR

OU

T

S3

1" GRSC W/4 # 6 - THWN AND1 # 10 GND TO PNL DP2

3/4" GRSC W/4 # 10 - THWN AND1 # 10 GND TO PNL DP3

SEE “PEDESTAL EQUIPMENT ROOMDETAIL” DRAWING FOR MEZZANINE WIRING

4" GRSC WITH 4 POWER CABLES(CABLES FURNISHED, CONTRACTORINSTALLED)

TRANSFORMER T5

CKT BRKR2

CKT BRKR1

SURGE S. PANELECU1

ECU2

ECU3

ECU4

PANEL DP4 PANEL DP5 PANEL DP1 PANEL DP6S1

S2

PANEL DP7

ELECTRICMETER

INSTALL 2" GRSC W/33/0 - THWN AND 1 # 6 GND

INSTALL 1" GRSC W/4 # 6 THWN AND 1 # 10 GND

INSTALL 3" GRSC W/43/0 THWN

TRANSFORMERT1

FACILITY POWER LAYOUT PLANSCALE: ¼" + 1" -0"

GEN. REV. # 1, ECO’S RTSC-02-01...48 PLC EFWCHK’D APP’DDESCRIPTIONDATEREV.LTR.

A 05/20/02

DEPARTMENT OF DEFENSEUNITED STATES AIR FORCE

DIGITAL AIRPORT SURVEILLANCE RADAR (DASR)CONFIGURATION 1 GENERIC DESIGN

FACILITY POWER LAYOUT

REVIEWED BY SUBMITTED BY APPROVED BY

ISSUED BY DATE 10/31/01 REV.LTR.

ADRAWING NO.DASR-GEN1- E3

DEVELOPED BYPLC

DRAWN BYAO

CHECKED BYPLC

RaytheonTECHNICAL SERVICES COMPANY

BURLINGTON, MA 01803

F:\0

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Figure FO-2. Config 1 Facility Power Layout

FP-2

DECASHIELD 1000 LUMINAIRE W/1000 WATT,TYPE BT56 METAL HALIDE LAMP - TYPE HPF DR CWIBALLAST- 30FT ROUND ALUMINUM LIGHT POLEPROVIDE 1000W, BT56 METAL HALIDE LAMP,ROUND POLE ADAPTER

GENERAL ELECTRIC FIXT#DSAD1M2A4GMCIDB4POLE #ARTA30SD80BDBROUND POLE ADAPTER#RPADB-DS

A

AREA LIGHTING DETAILSSCALE: Not To Sc a le

A

TYPE DESCRIPTION

LIGHTING FIXTURE SCHEDULE

MANUFACTURER

FOUNDATION AND ANCHORBOLTS SEE DWG C6

3/4“ GRSC WITH2-# 12-THWN AND1-# 12 TO E/G SHELTERPANEL DP7

3/4“ GRSC WITH2-# 12-THWN AND 1-# 12

TOAREA LIGHT

# 6 BARE COPPERTO COUNTERPOISE

24" MIN

GND LUG

GRADE

30' - 2"

30' ALUMINUM POLE

TYPE A LIGHT FIXTURE

NOTES:1. ALL UNDERGROUND CONDUITS MUST BE BONDED TO THE COUNTERPOISE WITH 4/0 AWG BARE COPPER WIRE. INSTALL GROUND CLAMP OR EXOTHERMIC WELD ABOVE GRADE AND EXOTHERMIC WELD TO COUNTERPOISE.

2. THIS DRAWING IS DIAGRAMATIC ONLY. CONDUITS MUST BE INSTALLED SO THERE ARE NOT MORE THAN THE EQUIVALENT OF FOUR QUARTER BENDS (360 DEGREES TOTAL) BETWEEN PULL POINTS, SUCH AS CONDUIT BODIES OR BOXES. INSTALL SUITABLE PULLBAXES WHERE REQUIRED. COORDINATE ALL CONDUIT RUNS WITH SCE.

3. INSTALL CONDUITS AT THE MINIMUM DEPTHS AS REQUIRED BY THE NEC, TABLE 300-5 FOR UNDER STREETS, HIGHWAY, ROADS, ALLEYS, DRIVEWAYS, AND PARKING LOTS.

TI 6310.47WP 010 001 DECEMBER 2003

LOADBANK

A

~

~

UPS BATE/G

FUELTANK

A

A

1 DECEM BER 2003TI 6310.47W P 010 00

WXXXX ALL PLUG INC O NNEC TO RS FO R DETAIL SEE

PEDESTAL ASSEM BLYINSTRUC TIO N M ANUAL

INSTALL G RO UND BUSHING.BO ND TO M EZZANINE WALL WITH

# 6 WIRE INSULATED G REEN

TO PLATFO RM G ATE SWITC H

C FE C ABLE

3/4" C .,

PRO VIDE AND INSTALL A TELEPHO NEBO X WITH A TELEPHO NE SET. INSTALL G RO UND BUSHING O N 2 " C O NDUIT - BO ND TO

M EZZANINE STEEL WITH # 2 AWG WIRE INSULATED G REEN

INSTALL 1" G RSC WITHFIRE ALARM , DO O R SEC URITY& TELEPHO NE WIRES 18-# 14& 1-# 12 PAIR TELC O C ABLE

PEDESTAL LO C AL C O NTRO L PANEL

C FE C ABLE

WIND M O NITO R

C FE C ABLES

3/4" C ., 2# 14 TO C B5

3/4" C ., 2# 14 TO C B5

PEDESTAL SAFETY SWITC H

3/4" C ., 2# 14 TO C B5

3/4" C ., 2# 14TO C B53/4" C ., 2# 14 TO C B5

SC

H

W1501 W0201A

W1

301

W7

01B

W1

601

B

W1

802

B

W9

602

B

W9

601

B

W0

701

B

W07

01C

W96

01C

W96

02C

W04

04

W03

05

W00

49

W00

46

PANEL U35A7

PANEL U34A1

4" G RSC

C B5

DP3

PLC P

PEDESTAL

DP2

C B4

C FE C ABLE

4" G RSC

EC UEC U

M BP

EC U

A

EC U

BATUPS

TRANSIENT PRO TEC TIO NPANEL U31A12

PANEL DP5 PANEL DP4

EQ UIPM ENT SHELTER

PANELDP1

2" G RSC

C B2

3/4" G RSC , 2 # 14

TO FENC E G ATESWITC H

FM AC JUNC TIO N BO X

E/GSHELTER

FUEL LEVELM O NITO R

FUELTANK

SENSO REQ UIPM ENTBO X

FUELALARM

LO AD BANKC O NTRO L PANEL

W7230B

INSTALL WIRES FRO MFUEL LEVEL SENSO R TOFUEL LEVEL M O NITO R IN 1" G RSC

C B1

2" G RSC WITH43 # 14 & 1 2PRTELC O C ABLE

E/G C O NTRO L & SENSO R WIRES

LOA

D B

AN

K C

ON

TRO

L W

72

28

B

LO ADBANK

PUNC H HO LE IN LO ADBANK AC C ESS PLATEINSTALL G RO UND BUSHING O N C O NDUIT

BO ND TO EQ UIPM ENT G RO UND BUSWITH THE SAM E # 6 AWG USED TO

G RO UND THE PO WER C O NDUIT - SEE DWG E1.

AIR IN

AIR O

UT

1 " G RSC WITH 3# 12 & 19 # 14

DASR FAC ILITY C O NTRO L AND SIG NALS PLANNO T TO SC ALE

TRANSFO RM ERT1


A 05/20/02

DEPAR TM ENT O F D EFENSEUNITED STATES A IR FO RCE

D IG ITAL A IRPO RT SU RVEILLANCE RADAR (DASR)CONFIG URATIO N 1 G ENERIC DESIG N

CO NTRO L AND S IG NAL PLAN

REVIEWED BY SUBMITTED BY APPRO VED BY


ADRAWING NO .

DASR-G EN1- E4

DEVELO PED BYPLC

DRAWN BYAO

C HEC KED BYPLC



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Figure FO -3. Config 1 Contro l and S ignalP lan

FP-3

NO TES:

1. ALL UNDERG RO UND C O NDUITS M UST BE BO NDED TO THE C O UNTERPO ISE WITH 4/0 AWG BARE C O PPER WIRE. INSTALL G RO UND C LAM P O R EXO THERM IC WELD ABO VEG RADE AND EXO THERM IC WELD TO THE C O UNTERPO ISE.

2 . THIS DRAWING IS DIAG RAM M ATIC O NLY. C O NDUITS M UST BE INSTALLED SO THEREARE NO T M O RE THAN THE EQ UIVALENT O F FO UR Q UARTER BENDS (360 DEG REESTO TAL) BETWEEN PULL PO INTS, SUC H AS C O NDUIT BO DIES O R BO XES. INSTALLSUITABLE PULLBO XES WHERE REQ UIRED. C O O RDINATE ALL C O NDUIT RUNS WITHSC E.

3 . INSTALL C O NDUITS AT THE M INIM UM DEPTHS AS REQ UIRED BY THE NEC, TABLE 300-5 FO R UNDER STREETS, HIG HWAY, RO ADS, ALLEYS, DRIVEWAYS, AND PARKING LO TS.

4 . PLC P = PEDESTAL LO C AL C O NTRO L PANEL

5. C FE = C O NTRAC TO R FURNISHED EQ UIPM ENT.

FIRE ALARMC O NTRO L PANEL

1/2” - 13 STA INLE SS S TEE LB OLT AND W AS HE R

C RIM PE D CO NNE CTO R

4/0 AW G B ARE COP P ERW IRE TO CO UNTE RPO IS E

DETAIL O F REBAR G RO UNDC O NNEC TIO N TO E/G SHELTER

SC ALE: No t To Sc a le

4/0 A W G B ARE CO P PE R W IRE FRO MP AD RE BA R CO NNE CTIO N

4/0 A W G B ARE CO P PE R E X OTHE RM ICA LLYW ELD TO E /G E X HAUS T P IP E

- S EE NO TE 3

4/0 AW G BA RE CO PP ER W IRE FRO MG ENE RA TO R HO USING TO C OUN TE RPO ISE .

INS TA LL 1" PV C CO NDUIT FRO M THEG ENE RA TO R TO 1" BE LO W FIN IS H G RA DE

4/0 AW G B ARE C OP PE R W IRE FRO MP AD RE BA R CO NNE CTIO N

FO R CO NTINUA TIO NS E E DW G E13

4/0 AW G BA RE CO PP ER EX OTHE RM ICA LLY W ELDTO DA Y TA NK V ENT P IPE-

SE E NO TE 3

4/0 AW G BA RE CO PP ER W IRETO CO UNTE RPO ISE

PIPE S UPP O RT

#2 AW G INS ULATE D G RE ENCO P PE R W IRE TO G RO UNDE ACH TRANS FOR M E R

#6 AW G B AR ECO PP E R W IRE FO RG RO UNDINGE LECTRO DECO NDUCTO R

#6 AW G BA RECO P PE R W IRE FRO MCB 1 B A SE TOCO UNTE RPO ISE

FO R CO NTINUA TIO NS EE DW G E6

500 M CMCO PP ER INS ULA TE D G REE NTO CO UNTERP O IS E

4/0 A W G BA RE CO PP E R W IRETO CO UNTE RPO IS E FRO MLO AD B ANK

4/0 A W G B ARE CO P PE R W IR EFRO M M A NUA L TRA NSFE RS W ITCH

4/0 AW G W IRE INSULATED G REE N ANDTA PE D W ITH A RE D STRIP E. INS TALL IN

1" P VC CO NDUIT A BO VE GRO UND .LEA VE 3" O F W IRE IN BO X -BO ND TO CITE L B AS E AN D

G RO UND BUS HINGS IN TH ETE LEP HO NE BO X ES

4/0 AW G BA RE CO PP ER W IRE TOCO UNTERP O IS E FROM THE

P O LYP HA SE R S ANDW ICHBA R GR OUN D

#2 A W G B ARE CO P PE R W IRETO G ROU ND TRA NSFO RM ER

4/0 AW G INS ULATE D G RE ENW ITH RED S TR IP E TOCO UNTE RP OISE FO R

EX TERIO R G RO UND BA R

4/0 AW G COP P ER W IRE INSULA TED G REE N

TO C OUN TE RPO ISE FRO MINTE RIO R GR OUN D B AR

4/0 AW G COP P ER W IRETO CO UNTE RPO ISE

FRO M TRA NSIENT PRO TE CTIO N

P ANE L A ND G RO UNDBUS HING IN P ANE L

500 M CMCO P PE R W IRE

INS ULATE D G RE ENTO CO UNTERP O IS E

FO R CO NTINUATIONS EE DW G E13

#6 AW G BA RE CO PP ERW IRE FRO M CB 2 B AS E

TO CO UNTERP O IS E

4/0 A W G B ARE CO P PE R W IRE FRO M

P AD RE BA R CO NNE CTIO N

4/0 A W G BA RE CO PP ERW IRE TO FUE L V AU LT

#6 A W G BA RE CO P PE RW IRE FRO M PA NE L DP7

TO CO UNTE RPO ISE

500 M CMCO P PE R INS ULATED

G RE ENTO CO UNTERP O IS E

4/0 AW G BA RE CO PP ERW IRE FRO M SHE LTER

M O DULE S TO CO UNTERP O IS E

(TY P. 4)

4 /0 AW G B AR E CO PP ER W IRE FRO M PA D R EB ARC ONN ECTIO N

#6 AW G B ARE COP P ERW IRE FRO M P ANE L D P1

TO COUN TE RP OISE

E XO THERM IC W ELDTO CO UNTE RPO ISE

(TY P) NO TE 4

4/0 AW G B ARE COP P ERW IRE TO TRANS FOR M E R

GRO UND

4/0 AW G B A RE CO PP ERW IRE FRO M FO UNDA TIO N REB ARTO CO UNTERP O IS E (SE E NO TE 5)

4 /0 AW G B AR E CO PP ER W IRE FRO M PA D R EB AR C ONN ECTIO N

G RO UND RO D(TYP)

2' TO 4 ' O UTSIDE O F DRIP LINEO F S HELTE R (TY P)-CO UNTE RPO ISEIS SHO W N FA RTHER FRO MS HELTE R FO R C LARITY

4/0 A W G BA RE CO PP ERW IRE FRO M S HELTE RM O DULES TO CO UNTERP O IS E(TYP. 6)

G RO UND W IRE -FURNISH ED & INSTA LLEDB Y CO NTRACTO R

3" SC H 80 PV CFURNISHE D & IN STALLEDBY CON TRA CTO R

TO CO UNTERP O IS E

E /G SHELTER W ALL D ETAILFO R G R O UN D W IR ES

S CALE:: NO T TO SCA LE

FIN ISHG RAD E

S EA L CO NDUIT W ITHDUCT SE AL3" S CH 80 P VC

INSTA LLEDBY O THE RS

4/0 AW G BA RE CO PP ER W IRE FROM FO UNDA TIO N REB ARTO CO UNTERP O IS E (SE E NO TE 5)

CO NCRETE W A LL

NO TE 5)

500 M CM CO P PE RW IRE INSULATED G REE NTO CO UNTERP O IS E

FO R CO NTINU ATIO NS EE DW G E6

TO DEV ICE TO BEGR OUN DED

FO R CO NTINUATIONS EE D W G E6

4/0 AW G BA RE CO PP ER W IRE FRO M P AD REB AR CO NNECTIO N

1 DECEM BER 2003TIB6310.47W P 010 00

NO TES:1. THE 4/0 A W G G RO UND W IRE EN CIRCLING THE FA CILITY AND ANY O TH ER UN DERG RO U ND G RO U ND W IRE SHA LL BE BU RIED A M IN IM UM O F 30 INCHES BE LO W G R ADE. ALL BEND S IN G RO UND CO NDUCTO R TO BE M ADE W ITH 12" IN RADIUS O R LA RG ER.

2. A LL ELECTRICA L A ND LIG HTNING PRO TECTIO N CO N NECTIO NS SHA LL BE FR EE O F A LL P A INT AN D G ALVA NIZATIO N. S CRAP E ALL S TEE L CO NNEC TIO NS FREE O F A NY PAINT O R P RO TE CTIV E CO ATING B EFO R E M AK ING ANY G RO UNDING CO NNE CTIO NS.

3. V ERTICALLY M O UNTED 1" PVC CO NDUIT U SED AS A G U IDE FO R G RO UND CO NDUCTO R .

4. A LL CO NNE CTIO NS TO G RO U ND RO DS AND CO UNTERP O ISE SY STEM SH ALL B E B Y E XO THERM IC W E LD.

5. CO N NECT THE RE BAR O F THE EQ UIPM ENT HO US ING A ND THE E/G SH ELTER W ITH 4/0 A W G BARE CO P PER W IRES TO THE G RO UND CO UNTERP O ISE USING EX O THE RM IC W ELDS A S S HO W N.

6. IN STA LL #2 AW G BA RE CO PPE R G RO U ND W IRE S A ND CO NN ECT BY EX O THE RM IC W ELD TO TH E RE BA RS O F THE B UILDING FO UNDA TIO N IN TW O O PP O SITE PLA CES AS SH O W N. CO N NECT EA CH CA BLE TO TH E G RO U ND CO UN TERP O IS E S YSTEM.

7. A LL EQ UIPM ENT CO NN ECTED TO M ULTI-PO INT P LATES SHA LL B E CO N NECTED U SING A #2 AW G CO NDU CTO R INSU LATED G REE N W ITH AN O RANG E STRIP.

8. THE G R O UND G RID W ILL C O NSIS T O F A PPRO XIM ATELY E IG HT 3/4" D IA . X 10' LO NG , G RO U ND RO DS . THE AC TUAL CO N FIG UR ATIO N W ILL B E S ITE S PECIFIC. THE CO N NECTING CO U NTER PO IS E W ILL CO NSIST O F 4 /0 AW G B ARE CO PP ER W IR E.

9. A LL UNDE RG RO UND CO NDUITS M U ST BE BO NDE D TO THE CO UN TERP O IS E W ITH 4/0 A W G BARE CO P PER W IRE. INSTALL G RO UND C LAM P O R E XO THERM IC W E LD ABO V E G RADE A ND E XO TH ERM IC W E LD TO THE C O UNTE RPO ISE.

IP LINETE RPO ISE

ECU

LO A DB A NK

E/G

FU ELTAN K

ECU

EQ UIPM ENT SHELTER

M BPT4

UPS BA T

M G PT2,T3

A

PANEL DP 4 PANEL DP 5 PANEL DP 1

GG

G G

SHELTER

FO UNDATION

G RO UND

A

W G P

CB1

SVC ENTR SW

3AE8

W G PPNL DP 7

3CE8

E /GSH ELTER

3CE8

T5

W G PEC U

E CU

38E8 12" M IN .

~

G EN. REV. # 1 , EC O ’S RTSC-02-01...48 PLC EFWC HK’D APP’DDESC RIPTIO NDATEREV.LTR.

A 05/20/02

DEPARTM ENT O F DEFENSEUNITED STATES AIR FO RCE

DIG ITAL A IRPO RT SURVEILLANCE RADAR (DASR)CO NFIG URATION 1 G ENERIC DESIG N

FACILITY G RO UNDING PLAN



ADRAWING NO .

DASR-G EN1- E7

DEVELO PED BYPLC

DRAWN BYAO

C HEC KED BYPLC

RaytheonTECHNICAL SERVICES COM PANY


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3CE8

A

F igure FO -4. Config 1 Facility G roundingP lan

FP-4

T5

CADW ELD TO COUNTERPOISE

B

B

INSTALL2 - 4" GRSC

1" PVC CONDUITW ITH 4/0 AW GBARE.ATTACH TO DIAGONALTOW ER BRACE

GRADE

STAIRW AY NOT SHOW N

30" CABLE TRAY90` BEND

(CONTRACTORFURNISHED)

GROUNDCLAMPS ON4 GRSC CONDUITSSEE DETAIL 3/E14

30" GALV. CABLE TRAYCONTRACTOR FURNISHEDMOUNT UPSIDE DOW N

INSTALL W AVEGUIDES & COAX CABLES (FURNISHED)

2 - 4" GRSC2 - 1" GRSC1 3/4" GRSC

INSTALL 30" CABLE TRAYAND SUPPORTS (FURNISHED)

TOW ER COLUMN

EQUIPMENT SHELTERCKTBRKR2

TRANSIENT PROTECTION PANEL U31A12A1AND CONDUIT NOT SHOW N

T5CKTBRKR2

GROUND CABLE TRAY TOW AVEGUIDE GROUNDING PLATE(SEE NOTE 1)

INSTALL W AVEGUIDES

EQUIPMENT SHELTER

1" GRSC W ITH FIREALARM, DOOR SECURITY

& TELEPHONE W IRES &1 - 2 PAIR TELCO CABLE

4" GRSC W ITH 4POW ERCABLES (CABLESFURNISHED)

30" NON-VENTILATEDCABLE TRAY,CONTRACTOR FURNIHED ,MOUNT UPSIDE DOW N

SEE VIEW A

W AVEGUIDE CONDUIT DETAIL - ELEVATIONSCALE: 3/8" = 1' -0"

TOW ER BRACINGTYPICAL

HORIZONTALTOW ER MEMBER

4" GRSC W ITH PEDESTALCONTROL SIGNAL CABLES(CABLES FURNISHED)SEE DW G E4

1" GRSC

TRANSIENT PROTECTIONPANEL U31A12A1

TOW ER &CFE BRACKET UNISTRUT BY CONTRACTOR

INSTALLW AVEGUIDE

(FURNISHED)

INSTALLCOAX

(FURNISHED)

NON-VENTILATED CABLE TRAY& RADIUSED TRANSITION FROMVERTICAL TO HORIZONTAL -MOUNTED UPSIDE DOW N

1" GRSC

3/4" GRSC4" GRSC

1" GRSCVIEW A

SCALE: Not To Scale

1" GRSC CONDUIT TOTRANSFORMER T5

3/4" PVC FORGROUND W IRE

NOTE:1. ALL PENETRATIONS IN TRANSIENT PROTECTION PANEL U31A12A1 BY CONTRACTOR

VIEW B - BSCALE: 3/4" = 1' -0"

5' 0"

A.F

.F.

TRANSIENTPROTECTIONPANELU31A12A1(CFE)

1" UNISTRUT SUPPORT (TYP)

4" GRSC CONDUIT TOGASKETED JCT BOX ON TOW ER

1" GRSC CONDUIT TOPANEL DP2

NOTES:1. EACH CABLE TRAY SECTION SHALL BE BONDED TO THE ADJACENT SECTION W ITH #2 AW G W IRE INSULATED GREEN. GROUND TO THE BULKHEAD GROUND PLATE W ITH #2 AW G BARE W IRE.

2. SEE DW G E14 FOR W AVEGUIDE BULKHEAD GROUND DETAILS.

3. CONTRACTOR TO LAYOUT CONDUIT RUNS SO THERE SHALL NOT BE MORE THAN THE EQUIVALENT OF FOUR QUARTER BENDS (360 DEGREES TOTAL) BETW EEN PULLPOINTS. INSTALL CONDUIT BODIES AND BOXES AS REQUIRED.

TI 6310.47W P 010 001 DECEMBER 2003

TYPE C-A CONDUIT FITTING-SEE NECF 346-11

4" GRSC CONDUIT FORSIGNAL CABLES

1" UNISTRUTSUPPORT

PENETRATION FOR1 1/4" GRSC NIPPLE

SEE DRAW INGS S4 & S5 AND TOW ERDRAW INGS H311018, SHT 2, 3 & 4.

W AVEGUIDE CONDUIT DETAIL - PLANSCALE: 3/8" = 1' -0"

FP-5

Figure FO-5. Config 1 Facility W aveguide andConduit Details

3/4" GRSC

1" UNISTRUTSUPPORT

1" -0"

G ENERAL REVISIO N # 1: UPREV ONLY PLC EFWC HK’D APP’DDESC RIPTIO NDATEREV.LTR.

A 05/20/02



W AVEGUIDE AND CONDUITDETAILS



ADRAWING NO .DASR-GEN1- E10

DEVELOPED BYPLC

DRAWN BYAO

C HEC KED BYPLC



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FIRE ALARM AUDIBLE/VISIBLE ALARM

DOOR INTRUSIONALARM SENSORS (2)

3/4" GRSC

SAFETY SW ITCH(CFE)

FINISHFLOOR

3/4" GRSC W /SESORCABLE TO PLATFORM

GATE SW ITCH

7' -5

1/2"

7 ' -4"

SECTION A-ASCALE: 1/2" = 1' -0"

8' -0"

INSTALL CFESAFETY SW ITCH

CFE CABLES - INSTALLED TOCFE BOX ON PEDESTAL

EXHAUST FAN EF - 1THERMOSTAT

3/4" GRSC TOW IND MONITOR

3/4" GRSC TOHOIST RECEPT.

50A DISTRIBUTION PANEL(SEE DW G E2), DP2

A

A

3" GRSC1" GRSC W ITH

4 - #6 THW N1 - #10 GND

FIRE ALARMPULL STATIONLIGHT

SW ITCH

4" SQ BOX W /20A GFC120V RECEPTACLEAND W EATHERPROOFCOVER (TYP)

TVSS

3" GRSC TO END 18" BELOW SAFETYSW ITCH, INSTALL GROUND BUSHING ONCONDUIT. BOND GROUND BUSHING TO

SHELTER W ALL W ITH #2 AW G W IREINSULATED GREEN. SEAL CONDUIT

W ITH DUCT SEAL.

5' -0

"

4"

5"

8'

#2 AW G INSULATEDGREEN TO MAINGROUND PLATE

PEDESTAL LOCALCONTROL PANEL(CFE)

4" GRSC W ITH GROUNDINGBUSHING ON END

3/4" GRSC W ITH 3 -#12 THW N

VIEW DSCALE: 1/2" = 1' -0"

4"X4" JUNCTION BOX FOR FEED

DOW N TO LIGHT SW ITCH

4

4 3

1

2

3

4

3

2

1

PEDESTAL EQUIPM ENT ROOMLIGHTING PLAN

SCALE: 1/2" = 1' -0"PEDESTAL EQUIPM ENT ROOM FLOOR PLAN

SCALE: 1/2" = 1' -0"

3/4" GSRCW ITH 3 -#12

SEE NOTE 11.

FIRE ALARMPULL STATION1" GSRC TO

W IND MONITOR

B

1" GSRC3/4" GRSC

1" GSRC4" GSRC

4" AW G INSULATED GREEN FROM U35A7PCBOARD TO M EZZANINE CEILING

VIEW ESCALE: 1/2" = 1 ' -0"

EXHAUST FAN HOODSEE NOTE 12

W EATHERPROOFTELEPHONE

24"X24"X6" (M INIMUMSIZE) NEMA 4

10 1/2”

FROM W EB OF BEAM

6 1/

2”

FROM

WEB

OF

BEAM

SURGE SUPPRESSIONPANEL U35A7 (CFE)

4" GSRC W ITHCONTROL CABLES

AND SIGNAL CABLES(CABLES FURNISHED)

CADW ELDTYP.

BOLTED

3/4" GRSC AND SENSOR CABLEBETW EEN THE PEDESTAL LOCAL CONTROL

PANEL & THE PLATFORM GATE SW ITCH

3/4" GRSC W /4-#10THW N & 1-#10 GRD

30" W AVEGUIDECABLE TRAY

W AVEGUIDE

COAX

A 30 A DISTRIBUTIONPANEL (SEE DW G E2), DP3

C A

C

E

AA

#2 AW G INSULATED GREEN

3/4" GRSC TO FLUORESCENT LIGHT

3/4" LIQUID TIGHT

TVSS

3/4" GRSC W ITH3-#12 THW N

MAIN GROUND PLATE (SEE DW G E15)

FINIFH FLOOR

1" PVC W / 4/0 AW G GRDATTACH TO TOW ER STEEL

4" GRSC 2" GRSC 3" GRSC4/0 W ELDING W IRE

TYP 4 CORNERSTOW ER COLUMNS

ATTACH UNISTRUTS TO TOW ERSTRUCTURAL MEM BERS - HANG BOXFROM UNISTRUT BY THREADED RODS -CAULK AROUND RODS AT BOX

SECTION B-BSCALE: 1/2" = 1' -0"

GATE TO PLATFORM

DOW N CONDUCTOR EXOTHERMICALLYW ELD TO NEAREST #4 AW G W IREW ITH GREEN INSULATION

DOW N

3/4" GRSC, LB & SENSOR CABLETERMINATE IN THE LOCAL

PEDESTAL CONTROL PANELAND AT THE GATE SW ITCH

TO AUDIBLE/VISIBLE ALARMM OUNT HOIST ONMONORAIL BEAM

(FURNISHED BYOTHERS)

INSTALL SOHOOK IS ONTHIS END

4" SQ WP BO X WITH 120V20A NEMA L5-20RTWISTLO C K REC EPTAC LEFO R HO IST. (SEE NO TE 1)

3/4" GRSC FROM DP2INTRUSION SENSOR CONTACTS

2" GRSC

3" GRSCD

#2 GROUND TO MGP B

A

W P, BOX W ITH120V GFCI RECEPTACLE PLATFORM

GATESW ITCH

RAILINGS

1" GSRC W /SENSOR CABLEAND GROUND W IRE FOR

W IND MONITORPERFORATED ANGLE“B-LINE” SA276 (TYP)

INSTALL PEDESTAL LOCALCONTROL PANEL (CFE) 4"

SURGE SUPPRESSION PANELU34A1 - SEE NOTE 13

1 5/8" X 1 5/8" UNISTRUT CHANNELAND HARDW ARE BOTH S IDES OF W ALL (TYP)

2" G RSC TO END 18" BELO W LO C ALPEDESTAL C O NTRO L PANEL. INSTALL

G RO UND BUSHING O N C O NDUIT.BO ND G RO UND BUSHING TO SHELTERWALL WITH # 2 AWG WIRE INSULATED

G REEN. SEAL C O NDUIT WITH DUC T SEAL.

4" G RSC TO BELO W SURG ESUPPRESSIO N PANEL. INSTALL G RO UND

BUSHING AND BO ND TO WALL WITH# 2 AWG WIRE INSULATED G REEN.

# 1 G RSC TO C B5. INSTALL G RO UNDBUSHING IN C B5. BO ND G RO UNDBUSHING TO THE MEZZANINE WALL

WITH # 6 AWG WIRE INSULATED G REEN.

3/4" G RSC TO PNL DP3

2"

2 ' -1"

7' -5

1/2"

7 ' -4"

4' -9

"

4"

3 ' -2"

4"

2" G RSC

TO EQUIPMENT SHELTER

4" G RSC TO G ASKETED BO X

1" G RSC TO PNL DP2

3/4" G RSC W/SENSO R C ABLETO THE PLATFO RM G ATE SWITC H

TVSSC B5

FINISHFLO O R

# 2 AWG WIRE INSULATED G REEN FRO MU34A1 ENC LO SURE G RO UND TO MG P

#4 AW G INSULATED GREEN FROM U34A1 PCBOARD TO HARGER GROUND BAR (TYP 3X)

WEATHERPRO O F TELEPHO NE

HARG ER G RO UND BAR G B1 141.524 EO R APPRO VED EQ UAL

3/4" G RSC AND SENSO R C ABLETO FIRE ALARM AUDIBLE/VISIBLE ALARM

C O NTRAC TO R TO MO UNT C FE SURG EPRO TEC TIO N ENC LO SURE O N C EILING

BUSHING

H S

SECTION C-CSCALE: 1/2" = 1' -0"

NO TES;1. MO UNT REC EPTAC LE TO UNDERSIDE O F RADAR PLATFO RM. EXAC T LO C ATIO N SHALL BE DETERMINED IN THE FIELD WITH THE SC E. C O NTRAC TO R TO INSTALL C FE HO IST O N TO WER MO NO RAIL BEAM.

2. ALL EQ UIPMENT NO T INDIC ATED AS “FURNISHED” SHALL BE FURNISHED AND INSTALLED BY THE C O NTRAC TO R.

3. SEE DWG E02 FO R ELEC TRIC AL PANEL SC HEDULES.

4. ALL C O NDUITS IN MEZZANINE SHAL BE G RSC WITH C AST BO XES.

5. INSTALL A # 6 AWG G RO UND WIRE FRO M THE G RO UND BUS O F PANELS DP2 AND DP3 TO THE STRUC TURAL STEEL O F THE TO WER. C O NNEC T WIRES TO THE STRUC TURAL STEEL WITH AN EXO THERMIC WELD.

6. INSTALL C O NDUIT HUBS FO R C O NDUITS AT 24"X24"X6" BO X.

7. C O NTRAC TO R SHALL BE RESPO NSIBLE FO R MAKING ALL PENETRATIO NS THRO UG H THE WALL AND FLO O R O F MEZZANINE RO O M. AFTER C O NDUIT IS INSTALLED, SEAL HO LE WITH C LEAR SILIC O NE C AULK.

8. TELEPHO NE TO BE ALLEN TEL C AT. NO . G 890D-14 O R APPRO VED EQ UAL.

9. BO ND G RO UND IN C B5 BASE TO MEZZANINE WALL WITH 4/0 AWG WIRE INSULATED G REEN

10. C O NTRAC TO R TO INSTALL # 2 AWG C O PPER WIRE INSULATED G REEN FRO M PEDESTAL DRIVE MO TO R A AND PEDESTAL DRIVE M O TO R B TO THE MAIN G RO UND PLATE.

11. INSTALL C ANE TYPE, STAINLESS STEEL O R BRASS DO O R HO LDER O N DO O R. DRILL MEZZANINE FLO O R PLATE SO THE DO O R IS HELD O PEN AT 90` AND APPRO XIMATELY 180` .C O LD G ALVANIZE THE FLO O R PLATE AFTER DRILLING.

12. FO R EXHAUST FAN DETAILS SEE DWG M3.

13. C O NTRAC TO R TO PURC HASE SURG E SUPPRESSIO N PANEL U34A1 FRO M BAT ELEC TRIC INC. BAT ELEC TRIC, INC . 20200 C HARLANNE DR. REDDING,C A 96002 (530) 221-1336

14. INSTALL # 2 G RO UND WIRE INSULATED G REEN FRO M THE RO TARY JO INT TO THE M G P.

15. INSTALL 4/0 AWG WIRE INSULATTED G REEN FRO M THE PEDESTAL G RO UND STUD TO THE NEAREST STRUC TURAL STEEL C O NNEC T WIRE TO THE STRUC TURAL STEEL WITH AN EXO THERMIC WELD.

A

A

INSTALL PEDESTAL LO C ALC O NTRO L PANEL

INSTALL SAFETY SWITC H

PO WER PANELS

SIDE WALL SURFAC EM O UNT 4" FLUO RESC ENTLIG HT FIXTURE - TYPE E

A

PLATFORMGATE SW ITCH(FURNISHED )

UP

LEGEND

# 4 WITH G REEN INSULATIO N, EXO THERMIC ALLYWELD TO NEAREST DO W C O NDUC TO R

G EN. REV. # 1, EC O ’S RTSC-02-01...48 PLC EFWC HK’D APP’DDESC RIPTIO NDATEREV.LTR.

A 05/20/02

DEPARTM ENT OF DEFENSEUNITED STATES AIR FORCE


PEDESTAL EQUIPMENT ROOM DETAIL



ADRAWING NO .DASR-GEN1- E11

DEVELOPED BYPLC

DRAWN BYAO

C HEC KED BYPLC


BURLINGTON, M A 01803

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D

TYPE DESCRIPTION MANUFACTURER

LITHONIA LIGHTING#DMSW 2320GEBRIF

LIGHTING FIXTURE SCHEDULE

2 LAM P RAPID START FLUORESCENT FIXTUREFOR SURFACE MOUNTING W ITH PREMIUM W RAP AROUNDACRYLIC LENS. PROVIDE TW O 32 W T8 LAMPSBALLAST SUITABLE 0F.

#2 AW G W IREINSULATED GREEN

FROM U35A7ENCLOSURE

GROUND TO MGP

S

H

FP-6

Figure FO-6. Config 1 Pedestal EquipmentRoom Detail

TI 6310.47W P 010 001 DECEMBER 2003

A

A

SECTIO N A-AD RILL A N D TA P W ELDM EN TFO R #10-24 S CR EW S (TY P 12X)

DRILL A ND TA P W E LDM E NTFO R 1/4-20SC RE W S (TY P 4X )

DRILL W ELD M EN TTO S UIT M O U NTIN G O F FA N

STA INLE S S S TEE L M A CHINE S CR EW,W AS H ER , LO CK W A SH ER A ND NU TTO S UIT (TYP AS RE Q ’D BY FAN)

RA IN HO O D

E XH AU S T FA N EF-1(NO T CUT FO R CLA RITY )

FAN E X TE NS IO N W E LD M E NTFURN IS HE D B Y CO N TRA CTO R

W E LD M EN TFURN IS HE D W ITH TO W ER

P ED ES TA L RO O MW A LL (R EF)

M O UNTING HO LE S1/4" D IA .

3"

22"

21"

15"

17"

2 " TYP 17"

S TIFFE NE RSA S R EQ U IR ED

INS E CT S CRE E N

G ENEREL REVISIO N # 1 UPREV O NLY PLC EFWC HK’D APP’DDESC RIPTIO NDATEREV.LTR.

A 05/20/02

DEPARTM ENT OF DEFENSEUNITED STATES A IR FO RCE

DIG ITAL A IRPO RT SURVEILLANCE RADAR (DASR)CO NFIG URATIO N 1 G ENERIC DESIG N

M EZZANINE EXHAUST FAN DETAIL



ADRAWING NO .DASR-G EN1- M 3

DEVELO PED BYPLC

DRAWN BYAO

C HEC KED BYPLC

RaytheonTECHNICAL SER VIC ES CO M PANY

BURLIN GTO N , M A 01803

EF - 1 RAIN HO O D DETAIL - ELEVATIO N V IEW

FP-7

Figure FO -7. Config 1 Exhaust Fan Detail

1 DECEM BER 2003TI 6310.47W P 010 00

EXHAUST FAN SCHEDULEEQ UIPM EN T

NUM BER M ANUFACTURER M O DEL AND TYPE LO CATIO N D ISC HARG E TYPE CFMFAN DATA M OTOR D ATA

REM ARKS

W ITH TOTALLY ENCLOSED M OTOR120V

160Hz

15501/12DIRECT0.125610PRO PELLERHO R IZO NTALW ALLM O UNTED

P10RO R

EQ UAL

PENNO R EQ UAL

EF-1

NOTES:1. THE RM O S TAT FO R E F-1 TO B E IN A NE M A E NC LO S URE. THE RM O S TA T TO BE G RA NG E R CA T. NO . 4E636 O R A PP RO V E D E Q UA L.

2 . FA BR ICA TE FAN E X TEN SIO N W E LDM E NT FRO M 10 G A UG E (.125") S TEE L M ATE RIA L. H O T DIP G A LV A NIZE A FTE R FA BR IC ATIO N.

3. FA BR ICA TE RA IN HO O D FR O M G A LV A NIZED S HE E T S TE EL P E R S M A CN A S TA NDA RD S.

4. S ET THE RM O S TA T TO TURN O N A T 95`F .

02.F

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EXT.S .P .(IN H2O) DR IVE M IN . H .P. RPM ELECT.

TOWER

SELF-LOCKING NUT ANDFLAT WASHER (TYP)

TOWERSTEEL (TYP)BY OTHERS

7/16" THREADROD (TYP)

CABLETRAY

7/16" THREADED ROD(TYP) SEE NOTE 3.

DETAIL GTHIS DWG

10"

B-LINECABLE TRAY 30"

7/16" THREADEDROD (TYP)SEE NOTE 3.

SELF-LOCKING NUT ANDFLAT WASHERS (TYP)

1 5/8" UNISTRUT 2" X 3/16". 30" LONGGALV. STEEL PLATE

3/8" GALV.BOLTAND LOCK NUT(TYP)

FP-8

Figure FO-8. Config 1 Waveguide SupportDetails

SECTION C-CWAVEGUIDE AND COAX CABLES NOT SHOWN

SCALE: 1" = 1' -0"

:\02.

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A

ANGLE HARDWARE(2 REQ’D)

SCALE: 3" = 1' -0"

6X3½"X3/8"X4" LONG ANGLEHARDWARE (TYP)

2"

1/2"THRU HOLE

3"1 1/2"

HOLES

1/2"THRU HOLE

6"

3 1/4"

7/16" THREADED RODWELDED TO SLEEVE

1/2" THRU HOLE2"

1"

1 1/2"

1 LOCK NUT AND FLAT WAASHERS REQ’D W/EACH ASSEMBLY A

HARDWARE(2 REQ’D FOR TOWERS 27' THRU 87')

SCALE: HALF SIZE

7/16" THREADED ROD

7/16" LOCK NUT

FL6X3½"X3/8"

X3" LONG(2 REQ’D)

L3½"X3 TOWER STEEL(BY OTHERS)

7/16" BOLT, LOCK NUTAND FLAT WASHER

3 1/2"

DETAIL GSCALE: 2" = 1' -0"

L 3½"X3TOWER

(BY OTHERS)1/2"HOLEFOR 7/16"BOLT

L6X3½"X3/8"X 3" LONG

1/2" HOLE

1/2"6"

3"

HARDWARESEE THIS DWGVIEW F

SCALE: 2" = 1' -0"

CABLETRAY

VIEW ESCALE: 2" = 1' -0"

CADWELD 4/0 BARE COPPERGROUND STRAPTO CABLE TRAY TO WAVEGUIDEGROUNDING PLATE

WAVEGUIDE GROUNDING PLATE( FOR DETAILSSEE DWG E14 )

USE 1/2"X3 1/2"HILTI KWIK BOLTOR APPROVEDEQUAL

3 1/2"

3 1/2"

15" 15"4"

3/8"X6"X4"X4" LONGANGLE BRACKET (TYP)

CONCRETE SHELTERBY OTHERS EQUIPMENT SHELTER

EXTERIOR WALL SURFACE(FLAT IN ATTACHMENT

AREA)

NOTE:COAX CABLES, WAVEGUIDES AND GROUNDINGARE NOT SHOWN FOR CLARITY

SECTION D-DSCALE: 1 1/2" = 1' -0"

3 1/2"

4 1/2"

3"

ED

D

DETAIL BCABLE TRAY SUPPORT DETAIL AT SHELTER

SCALE: 1 1/2" = 1' -0"

WAVEGUIDE

A

A

CADWELD 4/0 BARE COPPERGROUND STRAP TO CABLE

TRAY TO WAVEGUIDEGROUND PLATE.

WAVEGUIDE

DETAIL ACABLE TRAY SUPPORT DETAIL AT TOWER

SCALE: 1 1/2" = 1' -0"

REMOVE CABLE TRAY RUNGSIF THEY INTERFERE WITH THE

COAX CABLE INSTALLATIONCOLD GALV. DAMAGE AREAS

A

A

24" RAD/90` BEND

B-LINE#574-G-ST-30BY CONTRACTOR,NO SUBSTITUTIONS ALLOWED

B-LINE#574-30-90-V0-24BY CONTRACTOR,NO SUBSTITUTIONS ALLOWED

NOTE: CONTRACTOR RESPONSIBLE TO CUT CFE B-LINE CABLE TRAY TO SUIT, AND COLD GALV. DAMAGED AREAS

SUPPLIEDWITH THE

TOWERCABLE TRAY

CONTRACTORFURNISHED

BY OTHERS

B LINE574-G-12-30 (CFE)

ANGLE BRACKET(2 REQ’D)

SCALE: 3" = 1' -0"

A


HOLES

9/16" DIA THRU HOLE

9/16"


USE 1/2"X3 1/2"HILTI KWIK BOLT OR

APPROVED EQUAL(2 3/8"=EMB.)

CONCRETE SHELTERBY OTHERS

NOTE:ONE SIDE SHOWNFOR CLARITY

6"

6"

2 3/8"

1"4 1/2"

2 1/2"

4"2"

9/16" X 1" SLOTTED THRU HOLEFOR 1/2" DIA SHOULDER BOLT

A

A

C

C

7' -9

3/16

"AB

OVE

FINI

SHED

FLO

OR

EQUIPMENT SHELTER

TOP OF CABLE TRAY

DETAIL BTHIS DWG

B-LINE#574-G-ST-30BY CONTRACTOR

TOWER COLUMN

B-LINE#574-G-12-30 (BY OTHERS)

DETAIL ATHIS DWG

TOWERSTAIRWAY

FINISHGRADE

CABLE TRAY INSTALLATIONSCALE: 3/16" = 1' -0"

GENERAL NOTES:1. ALL SUPPORT HARDWARE TO BE HOT-DIP GALV. AFTER FABRICATION.

2. COORDINATE WITH ADDITIONAL DETAILS ON DWG E10.

3. ADJUST SELF-LOCKING NUTS TO REMOVE ANY SIDE TO SIDE MOVEMENT. DO NOT PRELOAD 7/16"f RODS.

1 DECEMBER 2003TI 6310.47WP 010 00

GEN. REV. # 1, ECO’S RTSC-02-01...48 PLC EFWCHK’D APP’DDESCRIPTIONDATEREV.LTR.

A 05/20/02



WAVEGUIDE SUPPORT DETAILS(27' ...87' TOWERS)



ADRAWING NO.

DASR-GEN1- S4

DEVELOPED BYPLC

DRAWN BYAO

CHECKED BYPLC



A

A

A

GEN. REV. # 2, ECO’S RTSC-02-49...125

PLC EFWCHK’D APP’DDESCRIPTIONDATEREV.LTR.

A 05/20/02



CMU BUILDINGHVAC PLAN, SECTIONS AND DETAILS



BDRAWING NO.DASR-GEN4- M1

DEVELOPED BYOC

DRAWN BYSW/AO

CHECKED BYPLC



12/09/02BGENERAL REVISION #1, UPREV ONLY

PLC EFW

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1 DECEMBER 2003TI 6310.47WP 010 00

Figure FO-9. Config 4 CMU BuildingHVAC Plan, Sections and Details(Sheet 1 of 2)

FP-9

1

2

RAIN HOODSEE DETAIL“C”

DETAIL ATHIS DRAWING

16" X 6" REGISTER(SEE NOTE 9)

18"X20" 18"X24" 18"X40"

36" X 8" REGISTER,(TYP) SEE NOTE 9

PRESSURE RELIEFDAMPER

SECURE DUCTS TO WALLFITTINGS 4' -0" MIN O.C.

SECTION 1 - 11/4“=1' -0”

TRANSITIONHVAC DUCTSUPPORTFLEXCONNECTION

ECU2

4 4 DUCT SUPPORT

CMU WALL

WHERE SPLIT FACE BLOCK ISINSTALLED, GRIND OR FILLTHE BLOCK TO CREAT A FLATSURFACE PRIOR TO INSTALLATIONOF SUPPORT (TYP)

CMU WALL

ECU

DUCTSUPPORT

10"

10" -0"

DETAIL A1/2“=1' -0”

3/8" BOLT (TYP)

44"X 22"HVACDUCT

3/8" BOLT (TYP)7/16" HOLE FOR

1 3/4“ X3/16”BENT PLATE

2 1/2" 10"

5

5

L3" X 3" X 3/16" WELDED FRAME(SEE NOTE 12)

SECTION 4 - 41“=1' -0”

MECHANICAL GENERAL NOTES

1. CONSTRUCT ALL DUCTS WITH GALVANIZED STEEL IN ACCORDANCE WITH THE “SMACNA DUCT CONSTRUCTION STANDARDS”. ALL DUCTWORK SHALL BE INSTALLED AND SUPPORTED TO THESE STANDARDS ALSO.

2. DUCT DIMENSIONS ARE SHOWN TO THE OUTSIDE SHEETMETAL. SUBTRACT DUCT LINER THICKNESS FORNET INSIDE DUCT DIMENSIONS.

3. REINFORCE DUCT AND SEAL PER SMACNA FOR 2" WATER GAGE PRESSURE CLASSIFICATION AND SEALCLASSIFICATION C.

4. DUCT ELBOWS HAVE DOUBLE WALL TURNING VANES.

5. FOR DUCT PENETRATIONS OF EXTERIOR WALL, SEE DETAIL ON DWG. M2.

6. PROVIDE BALANCING DAMPERS AT ALL SUPPLY REGISTERS.

7. EXTERIOR DUCTWORK AND APPURTNEANCES SHALL BE CONSTRUCTED TO WITHSTAND WIND FORCES OF144 MPH AND SEISMIC ZONE IV CHARACTERISTICS. SEE CIVIL DWGS. FOR DETAILS.

8. FOR SCHEDULES AND DETAILS REFER TO DRAWING M2.

9. 36"X42" RETURN AIR GRILLE, HART & COOLEY MODEL RH45. REGISTERS, 821 SERIES, DEFLECTION G,HART & COOLEY CAT. FEB. ’99. APPROVED EQUALS WILL BE ALLOWED.

10. CONDENSATE DRAIN PIPING TO BE ALL COPPER TUBING.

11. CONDENSATE DRAIN SHOULD MEET DRAINAGE REQUIREMENTS WITH ALL LOCAL AUTHORITIES AND CODES.

12. ALL HARDWARE SHALL BE HOT DIPPED GALVANIZED OR STAINLESS STEEL. ALL STEEL SHALL BE HOTDIPPED GALVANIZED AFTER FABRICATION.

13. RAIN HOOD TO BE FABRICATED FROM GALVANIZED STEEL SHEET, 16 GAUGE. INSECTS SCREEN TO BE6X6 MESH. 18GA 316 S.S. WIRE WITH APPROX. 51.8% OF OPEN AREA.

SEQUENCE OF OPERATIONS

1. ENVIRONMENTAL CONTROL UNITS ECU-1 AND ECU-2 OPERATE ON DEMAND FROM THE ECU CONTROLPANEL. THE CONTROLLER WILL PROVIDE THE FOLLOWING:

2. THE INDOOR FAN ON THE LEAD ECU WILL OPERATE CONTINUOUSLY. THE LEAD ECU WILL PROVIDEAUTOMATIC SEQUENCE OF TWO COMPRESSORS TO MAINTAIN INDOOR TEMP.

3. WHEN OUTDOOR ENTHALPY CONDITIONS ARE OPTIMUM THE ECONOMIZER CYCLE WILL PROVIDE COOLING BYINTRODUCING OUTSIDE AIR.

4. THE LEAD ECU WILL RUN AS REQUIRED TO KEEP THE RELATIVE HUMIDITY BELOW 80%.

5. WHEN THE LEAD UNIT FAILS, IT WILL BE AUTOMATICALLY DE-ENERGIZED AND THE LAG UNIT WILL BEENERGIZED.

6. BOTH ECU’S WILL BE TIME DELAYED ON START-UP AFTER A POWER FAILURE.

ECU INTERLOCKS

1. THE CONTROL WILL INTERLOCK ECU1 AND ECU2 SO THAT ONLY ONE OF THE UNITS CAN OPERATE AT A TIME.

2. THE CONTROL PANEL WILL ALTERNATE THE LEAD UNIT AUTOMATICALLY. IT WILL CHANGE BETWEEN ECU-1AND ECU-2 EVERY 168 HOURS.

ECU FAILURE

1. WHEN THE LEAD ECU UNIT FAILS, THE CONTROL PANEL WILL SEND A SIGNAL TO THE FMAC INDICATINGTHE UNIT HAS FAILED.

4"X4'X1/4” PLT.3/16"

ANTISYPHON VENTGOOSENECK W/S/S INSECT SCREEN

18"MIN 7/16"DIA. HOLE FOR

3/8" DIA. BOLT1 1/2“ MIN.1 1/2“1 “

CONCRETESLAB

ECU

S/S DRAINSCREEN

DETAIL BNot To Scale

1 CUBIC FT 3/4“ GRAVEL(SEE MECHANICAL NOTE 11)

ADAPTER WITH THREADED CAP

SECTION 5 - 5Not To Scale

ECU2

10"

DETAIL “C”1“=1' -0”

2' -6"

2' -6"

MOUNTING HOLES6" O.C.

INSECT SCREENSEE NOTE 13

26 1/2“ X 42 1/2“ CONNECT TO ECU24 9/16" X 42 1/2“ CONNECT TO ECU

2' -10"

1' -1"

42 1/2“ X 36”RETURN AT

THE WALL

44“ X 22” SUPPLY ATTHE WALL

44“ X 22 SUPPLY ATTHE WALL

HVAC DUCTWALL SUPPORT(TYP 4 PLACES)

42 1/2“ X 36”RETURN ATTHE WALL

1' -3"GRADE

SECTION 3-3SCALE: 1/4“ = 1' -0”

EXHAUST FAN (EF-2)SEE SCHEDULE ON DWG. M2

32

1ECU

2

44“ X 22”SUPPLY

42 ½"X 36”

RETURN

30 CFM OUTSIDE AIR

1' -1

ECU1

10" -0"7" -0"

10' -0"

12" -0"

8" -2"(TYP)

3' -0" 4' -0"

40" X18"

44" X22"SUPPLY

42 ½"X 36”

RETURN

FLOOR PLAN1/4“ = 1' -0”

2' -10"

10' -6"

1" CONDENSATIONDRAIN (TYP)

42"X36"RETURN AIR GRILLE

BAROMETRICBACKDRAFT DAMPER

(TYP)

ACCESS DOOR ONBOTTOM OF DUCT

40“ X 18”

24' - 6”

18'-6"

ECU CONTROL PANEL

ACCESSTO ATTIC

40" X 18”20“ X 18” 24“ X 18”

1' -0"

TYP.4 PLCS.

ACCESS DOOR ONBOTTOM OF DUCT

HVAC DUCT SUPPORT (TYP)SEE DRAWING M2 FOR SUPPORTDETAILS

HVAC PAD

RAIN HOODSEE NOTE 13

STIFFENERSREQUIRED

ECONOMIZER

GRADE

CONDENSATION DRAIN(SEE DETAIL 8)

9" CONCRETE PAD (TYP)

ACCESS DOOR

HVAC DUCTSUPPORTFLEXCONNECTION

NOTE:SUPPLY DUCT NOT SHOWN FOR CLARITY

TRANSITION

42½ "X36"RETURN

42" X 36" RETURNAIR GRILLE

T

D

3

3' -6"

2' -0"

10"

3' -1 3/4“ X 3/16" BENT PLATESEE DETAIL ON PLAN 4-4 AND NOTE 12.

7/16" HOLE FOR 3/8" BOLTSEE DETAIL ON PLAN A-A AND NOTE 12.

SECTION 2 - 21/4” =1' -0”

EQ UIPM ENTNUM BER SERVICE M ANUFACTURER M ODEL AND TYPE LOCATIO N DISCHARG E EER

RATING

UNIT CAPACITYBTUH

TO TAL SENSIBLE TO TAL SENSIBLE TYPE CFM E.S.P .(IN . H 2O ) M IN HP RPM ELECT PO W ER TYPE NUM BER SIZE (IN )

NOM INALINPUT

FILTER DATAINDO O R FAN M O TO R DATAINDO OR FAN DATA

AIR C O NDITIO NING UNIT SC HEDULE

DESIGN LOADBTUH

ELECTRICAL DATA

CO M PRESSO R O UTDO O R FAN INDOO R FAN ELEC HEAT

CO NTROLS

UNIT HEADPRESSURE CO M PRESSOR

INTERNAL PRO TECTIO NFO R CO NDENSER FANINTERLO CK ANDM O DULATING O UTDOO RAIR PACKAGE

FOR LOW AM BIENTO PERATIONDO W N TO 0 F

UNITS ECU 1& ECU 2 TO BECOM PATIBLE W ITHECU CO NTRO LPANEL

1814.8

kWINPUTSTAGEFLAHP

3.011.600.50270101

1 10 70

Q TYFLAHPQ TYLRARLAQ TY

460V3 PHASE

60Hz

20 X 20 X 220 X 25 X 2

24

DISPO SABLEPLEATED M EDIAASHRAE 52-92.1

CO M PLIANT

30.8884,500CENTRIFUG ALCLASS -1

XXX,XXXXXX,XXXXXX,XXXXXX,XXXHO RIZONTALSUPPLY ANDRETURN

SLABM OUNTED

TCH151C40AAAAM ERICANSTANDARD

(TRANE )11.3

ELECTRONICEQUIPM ENTSHELTER

ECU 1ECU 2 1740

460V3 PHASE

60 Hz

EXHAUST FAN SCHEDULESEQUIPM ENT

NUM BER M ANUFA CTURE R M O DEL AND TYPE, LO CATIO N DISC HARG ETYPE

FAN DATA

C FM EXT.S.P.(IN H2O ) DRIVE M IN.H.P.

M O TO R DATA

RPM ELEC T. INSEC T SC REEN REM ARKS

WITH TO TALLY ENC LO SED M O TO R

WITH M O TO R G UARD M O UNTINGPANEL.START FANS W/T-STAT SET TOO PERATE @ 95 F, SHUTO FF @ 80 FM INIM UM LO UVER NET FREE AREA1.64 SQ . FT

NO . 12 M ESH,21 G A S.S. WIRE

120V1

60Hz

NO . 12 M ESH,21 G A S.S. WIRE

120V1

60Hz

1550

13001/4

1/12DIREC T

DIREC T0.375

0.125

1670

610PRO PELLER

PRO PELLER

HO RIZO NTAL

HO RIZO NTAL

TO WERM EZZANINE

C M UBUILDING

ATTIC

P16SAO R

EQ UAL

P10RO R

EQ UALPENN

O R EQ UAL

PENNO R EQ UAL

EF-1

EF-2

LO UVER SCHEDULEEQ UIPM ENT

NUM BERW ALL O PENING

W IDTH HEIG HT

L-1

L-2

24" 24"

24" 24"

VENTILATIONFAN EF-2

SERVES BLADETYPE

BLADEANGLE

BLADEW IDTH

J

J 45o

45o 6"

6"

6063, .125"extruded alum

6063, .125"extruded alum

KYNAR 500

KYNAR 500

45%

45%

NO . 12 M ESH,21 G A S.S. W IRE

NO . 12 M ESH,21 G A S.S. W IRE

DESIG N FO R 45PSF WINDLO AD

M INIM UM LO UVER NETFREE AREA 1.64 SQ . FT

DESIG N FO R 45PSF WINDLO AD

M INIM UM LO UVER NETFREE AREA 1.64 SQ . FT

DAM PER SCHEDULE

REM ARKS

HI EFFIC IENCY ULTRA , V INYL BLADE EDG E,LO W LEAKAG E, 2 REQ ’D, TIE BAR, G REENHECK W D400

G REENHECK W D400, REFER TO BARO M ETRIC DAM PERFO R CHARACTERISTICS, 1 REQ ’D6 X 6 M ESH, 18 G A 316 S .S. W IRE

FRAM EM ATERIA L

18 G A.G ALV. STEEL

G ALV. STEELG ALV. STEEL

0.050ALUM .

BLADE M ATERIALTYPE

PRESSUREDIFFERENTIAL

PRESSUREDIFFERENTIAL

SERVES

AIR SUPPLYDUCT

B LDG .(2600 CFM )

W ALL O PENING

W IDTH HEIG HT

40" 18"

30" 30"

BARO M ETRICDAM PER

PRESSRELIEF

DAM PER

EQUIPM ENTNUM BER

NO TE:REFER TO DRAW ING S A1 & A2 FO R LO CATIO N AND DETAILS

NOTES:

1. CAPACITY BASED ON XXX’F D .B . ENTERING CONDENSER , 90oF D .B. 61oF W .B. ENTERING EVAPORATOR

2. SET PRESSURE RELIEF DAMPER IN THE W ALL TO THE M INIM UM SETTING .

GE NENERAL REVIS ION #1, UP RE V O NLY PLC EFWC HK’D APP’DDESC RIPTIO NDATEREV.LTR.

A 05/20/02

DEPARTM ENT O F DEFENSEUNITED STATES A IR FO RCE

DIG ITAL A IRPO RT SURVEILLANCE RADAR (DASR)CO NFIG URATIO N 4 G ENERIC DESIG N

CM U BUILDINGHVAC SCHEDULES AND DETAILS



BDRAWING NO .DASR-G EN4- M 2

DEVELO PED BYO C

DRAWN BYSW/AOC HEC KED BY

PLC



GE N. REV. #2, ECO’S RTSC-02-49...125B 12/09/02 PLC EFW

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:46

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. 1:2

SE AL PE RIM ETERW /SILICO N CAULK (TYP)

M ASO NRY W ALL


2X8 BLO CK ING (TYP)

1" FIB ERGLAS SDUCTBO ARD W ITHALUM INUM FA CING

P ERIM E TERINSULATION (TYP)

HVAC DUCT

EXTERIO RSPA CE

INTERIO RSP ACE

2" DUCTLINER (TY P)

L 3 1/2“ X 5” X 1/4“(TYP)

STAINLE SS STE ELSCREW S TO DUCTW O RK

AND BLO CKING (TYP)

1" X 2" TRIM P IECEO N SUPP LY DUCTS

SUPPLY HVAC M ASO NRY PENETR ATIO N SECTIO NSSCA LE: 1 1/2“ = 1 ' -0”

RETURN

L 3 1/2“ X 5” X 1/4“(TYP)

STA INLESS STEELSCRE W S TO DUCTW ORK

AND B LOCKING (TYP)

EXTERIO RSPACE

S EAL P ERIM E TERW /SILICON CAULK (TYP)

M ASO NRY W ALL


2X8 BLO CK ING (TYP)

P ERIM E TERINSULATION (TYP)

INTE RIORSPACE2" DUCT

LINER (TYP)

RETURN A IR G RILL

HVAC DUCT

7/16" HOLE (TYP)FO R 3/8" ANCHOR BO LTSW / 2 1/2“ M INEM BE DM ENT. A LL ANCHO RBOLT HARDW A RE TO BEHO T DIPP ED G ALVANIZED.

1/4

SECTION A-ANot To Scale

HVAC DUCT SUPPO RTFRAM E (4 REQ ’D)

SCALE: 1 1/2“=1 ' -0”

L2X2X3/16

3 3/4"

A A

42 5 /8"

* 26 5 /8"

* 24 3 /4"

L3X3X3/16(TYP UNLES S NO TEDO THERW ISE)

1/4

1 5/8" UNISTRUT1" CLR .(TYP)

TYP

HVAC INTERIOR DUCT SUPPORT DETAILS CALE: 1 1/2“=1 ' -0 ”

DUCT A ND INSULATION W IDTH (VARIE S)

1" DUCT BO ARD3/8" THREAD RO D

HVAC DUCT

1 5/8" UNIS TRUT

5/8" CEILINGPLYW OO D

3/8" LO CK NUT W ITHFLAT W ASHER (TYP)

TO P O F DUCT BO ARD

10' - 0" AFF

TRUSSE S(TYP) 2X4 (TYP)

1 DECEM BER 2003TI 6310.47W P 010 00

Figure FO-9. Config 4 CM U Build ingHVAC Plan, Sections and Details(Sheet 2of 2)

FP-10

NOTE:ALL S TEEL TO BE HO T D IPPEDG A LVANIZED AFTER FAB RICATIO N* 2 FRAM ES REQ UIRED @ 26 5/8" &2 FRAM ES REQ UIRED @ 24 3 /4"

VENTILATIO NFAN EF-2

EG INE/GENERATO R SHELTER

NORM AL = RAYTHEO N FURNISHED/PRINT CO NTRACTO R INSTALLED

BO LD = CO NTRACTO R FURNISHED /PRINT CO NTRACTO R INSTALLED

480 /277V, 200A,M ETER SO C KET

AC C EPTABLE TO UTILITY

SEE NO TE 1

200A FUSEDDISC O NNEC T SWITC H

w/200A FUSES

TVSSW 5

W17

S1

W2

260 AUTOTRANSFERSWITC H

AUTO M ANUAL

DIESELENG IN/G ENERATO R

STARTER

G ENERATO R135kW

480Y/277V

S

E/GSTARTINGBATTERY

200A

S2

W2

W2

SEE NO TE 1

W20

TVSS

SEE NO TE 1

SEE NO TE 8

SEE NO TE 1

100kW LO AD BANK480 VO LTS WITH5 UNEQ UAL STEPS

200AM ANUAL

TRANSFERSWITC H

W2

W22

UPSE/G

OFF

S3

W23

12" X12"JUNC TIO N

BO X

PANELDP6

W25

W20

W9

W8

TVSS

FUEL M O NITO R & ALARM

E/G BLO C K HTR

E/G DAY TANK

EXHAUST FAN

LO AD BANK C O NTRO L

UNIT HEATER 3

BATTERY C HARG ER

M O TO RIZED DAM PER

120V REC EPTAC LES

LIG HT C KT 1W9

20A

20A

20A

20A

20A

20A

20A

20A

20A

20A

30A

50A

100ARATED

DP7

112.5 Kvatra nsfo rm e r

PRO VIDED BYUTILITY

xx.x Kv -480y/277v

W3 W1T1

TO WER PEDESTAL EQ UIPM ENT RO O M

TVSSW22

W22

TO PEDESTAL

W0

04

1C

W0

04

2C

W10 W10

W0

04

1B

W0

04

2B

W0

04

3B

W0

04

4B

AN

TEN

NA

REC

EPT

AN

TEN

NA

REC

EPT

EXT

GFI

REC

PT

INTE

RIO

R R

ECPT

INTE

RIO

R L

IGH

TS

STA

IRW

AY

LIG

HTS

AN

TEN

NA

LIG

HTS

ENC

OD

ER X

ENC

OD

ER Y

MO

TOR

CO

NTR

OLL

ER A

MO

TOR

CO

NTR

OLL

ER B

TO SURG E SUPPRESSIO NPANEL U31A12A1

SAFETYSWITC H

(C FE)

PEDESTALLO C ALC O NTRO LPANEL(PLC P)(C FE)

DP2

W15

W9 W14 W9

HO

IST

MEZ

Z EX

H F

AN

TVSS

50A100ARATED

20A 20A 20A 20A 20A 20A 30A 20A 20A 30A

TVSS

TVSSSEE NO TE 4

W20W20

DP3

W6

SEE NO TE 1

BRKR2 30A

T5 15kVA480V -

380Y/220V

W21

W21

SEE NO TE 4TVSS

30A125ARATED

W15W19

TVSS

PED

ESTA

L JC

T BO

X

PLC

P H

EATE

R

PLC

P H

EATE

RPL

CP

HEA

TER

W0

07

2

W0

07

2

30A 20A 20A

W4

W5W5

W16

T4 30kVA480V -

208Y/120VDP6

100A100ARATED

20A 20A 20A 20A20A 20A 20A 30A

PAN

EL D

P7

SITE

LIG

HTS

2

ATT

IC F

AN

EF-

2

FIR

E A

LAR

M C

NTR

L PN

L

LIG

HTI

NG

CKT

1

12

0V

REC

EPTA

CLE

1

12

0V

REC

EPTA

CLE

2

CO

MP/

DYH

R

TVSS

50A 50A

W9

20A

W5 W9 W20

W4

W2

W2

0

W22

W13

T2 45kVA480V -

380Y/220V

W13

N.C

W18W13W22

BRKR1

250ARATED

250AM O LDEDC ASESWITC H

40A 50A 45A100A

125A

480V-480VUPS (C FE)

FURNISHED)50kVA/40kVW

TVSS

200ANON-FUSED

SW

DP1

UPS M AINTENANC EBYPASS PANEL (M BP)

C 1 C 2 C 3

S6

TVSS

UPS BYPASS UPS INPUT

W2

SEENO TE 3

40A40A125A

W24

45kVA480V -

380Y/220V

T3

W11

DP5W11

W9W19 W9W12 W20W19 W9 W9

20A 20A15A 15A 15A 15A 15A 15A 15A 15A 15A 15A 15A30A 30A

W0042A

W15

DP4

125ARATED

125ARATED

90A90A

SURG E SUPPRESSIO N PANEL U31A12A1 (C FE

PED

MO

TOR

CO

NTR

OLL

ER B

CFE

FU

RN

ISH

ED

ENC

OD

ER Y

REX

/SD

P U

NIT

1

B

REX

/SD

P U

NIT

2

B

REX

/SD

P U

NIT

1

A

REX

/SD

P UN

IT

2A

PSR

A

PSR

B

MSS

R A

MSS

R B

CEC

A

CEC

B

W0

05

4

W0

05

5

PED

MO

TOR

CO

NTR

OLL

ER A

CFE

FU

RN

ISH

ED

W0041A

RA

DA

R C

NTR

L. P

NL

W15

ENC

OD

ER X

SEE NO TE 9TO TO WER PEDESTAL EQ UIPM ENT RO O M

50ANO N-FUSED

SW

SEE NO TE 1

50ANO N-FUSED

SW

S4 S4 W18

EC U1 EC U2

ECU

CO

NTR

OL

PAN

EL

C M U EQ UIPM ENT BUILDING

NO TES:1. CONDUIT SHALL BE TREATED W ITH A GROUNDING BUSHING ON EACH END . CONNECT THE G ROUND BUSHING TO THE EQUIPM ENT GROUND BUS W ITH A #6 AW G BARE CO PPER W IRE.

2. BRKR1 SHALL BE SQUARE D TYPE KA IN NEW A 1 ENCLOSURE . BRKR2 SHALL BE SQUARE D TYPE FA 480V IN NEW A 1 ENCLOSURE .

3. TVSS HAS AN INTERNAL M ANUAL DISCONNECT SW ITCH .

4. TVSS’S ARE LOCATED IN THE SURGE SUPPRESSION PANEL U 31A12A1.

5. CABLE NUM BERS ON THIS DRAW ING ARE FO R SYSTEM S INFORM ATION. THEY DO NO T DELINEATE W HO SUPPLIES O R INSTALLS THE CABLES.

6. CONTRACTOR TO RE-IDENTIFY CFE CABLES W 0041A, W 0042A, W 0041B, W 0042B, W 0041C, W0042C, W 0043B AND W 0044B IN M OTOR CONTROLLERS. THE SURGE SUPPRESSION PANEL, THE SAFETY SW ITCH AND AT THE PLCP. ALSO RE-IDENTIFY TVSS LEADS AT THE PLCP AND PANEL DP3. USE PVC TAPE FOR RE -IDENTIF ICATION. RED TO BLACK/YELLOW BLACK TO BLACK/BROW N BLUE TO BLACK/ORANGE

7. SEE SPECIFICATION SECTION 16120 FOR W IRE COLOR CODING.

8. CONTRACTOR TO CONNECT TVSS W IRES TO FEEDERS USING ILSCO IPC–4/0-6 OR EQUAL.

9. CONTRACTOR TO FURNISH AND INSTALL A CONDUIT FO R THE CABLES.

3 # 8-THWN + 1 # 8 G ND3 3/0-THWN + 1 # 6 G RD

TVSS LEADS, # 10 AWG4 # 10-THWN + 1 # 10 G RD

3 # 1-THWN + 1 # 6 G RD

4 # 12-THWN + 1 # 12 G RD

4 3/0 - THWN4 # 2 - THWN + 1 # 8 G RD

C FE FURNISHED C ABLE

3 # 8 - THWN + 1 # 10 G RD

2 # 10 - THWN + 1 # 10 G ND3 # 2 - THWN + 1 # 6 G ND

3 # 10 - THWN + 1 # 10 G RD4 # 3 - THWN + 1 # 8 G ND

C FE FURNISHED C ABLE2 # 12 - THWN + 1 # 12 G ND3 # 12 - THWN + 1 # 12 G ND

3 # 3 - THWN + 1 # 8 G ND4 # 6 - THWN + 1 # 10 G ND4 # 8 - THWN + 1 # 8 G RD3 # 6 - THWN + 1 # 10 G ND

4 3/0 - THWN3 3/0 - THWN + 1 # 6 G RD

3 # 2, 15KV AL. W/C O NC , NEUT. & O A. JKTW1W2W3W4W5W6W7W8W9W10W11W12W13W14W15W16W17W18W19W20W21W22W23W24 3/4"

2" C FE

NO NE

3/4"

3/4"

3/4"

3" C FE1 1/4"

1 1/4"

NO NE3/4"

1 1 /4"

3/4"

3/4"1 1/4"

4"

3/4"1 1/4"

1"1"1"4"2"4"

C O NDUITC ABLE DESC RIPTIO NLABEL

PO WER C ABLES AND C O NDUIT SC HEDULE


A 05/20/02

DE PARTM ENT OF TRANS PORTATIONFEDERAL A VIATION ADM INISTRATIO N

W ASHINGTO N , D .C . 20591

DIGITAL A IRPO RT SURVEILLANCE RADAR (DASR)CO NFIG URATIO N 4 G ENERIC DESIG N

ELECTRICAL O NE LINE DIAG RAM

REVIEWED BY SUBM ITTED BY APPROVED BY


BDRAWING NO .

DASR-GEN1- E4

DEVELO PED BYPLC

DRAWN BYSW/AOC HEC KED BY

PLC


BURLING TON, M A 01803

GEN. REV. #2, ECO’S RTSC-02-49...125B 12/09/02 PLC EFW

02.F

AT

D\0

2.FA

TD

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A S

ites

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XX

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XX

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/200

3 01

:13:

47 P

M. 1

:2

W25 4 # 6-THWN + 1 # 10 G ND 1 1/4"

1 DECEM BER 2003TI 6310.47W P 010 00

Figure FO -10.Config 4 E lectrical O neLine D iagram

FP-11

FU E LTA N K

S 1

S2

P A N E L DP7

E /G

E LE C TRICM E TE R

INSTALL 1 1 /4" G RSC W/4# 6 - THWN AND 1 # 10 G ND

INSTALL 2 " G RSC W/3 3 /0 - THWN

AND 1 # 6 G ND

1" G RS C W /4 #6 - THW N A ND 1 #10 G N D TO P N L DP 2

3/4" G R S C W /4 #10 - TH W N A N D 1 #10 G ND TO P NL D P 3

SEE “PEDESTAL EQ UIPM ENT RO O MDETAIL” DRAWING FO R M EZZANINE WIRING

4" G RSC WITH 4 PO WER C ABLES(C ABLES FURNISHED, C O NTRAC TO RINSTALLED)

~

~

PUNC H HO LE IN LO ADBANK AC C ESS PLATEINSTALL G RO UND BUSHING O N C O NDUIT.

BO ND TO EQ UIPM ENT G RO UND BUSWITH # 6 AWG WIRE INSULATED G REEN.

INSTALL 2 " G RSCWITH 3 3/0 - THWN AND

1 # 6 G ND

INSTALL 2 " G RSC WITH 3 3 /0 - THWN

AND 1 # 6 G ND

INSTALL 1 1 /4" G RSC WITH 3# 1 - THWN AND 1 # 6 G ND

FO R EXAC T LO C ATIO N O FLIG HT SEE DWG C3 (TYP 2 PLAC ES) INSTALL 3 /4 " G RSC

WITH 2 # 12 - THWN AND 1 # 12 G ND

S3

LO ADB A NK

SEE NO TE 1

SEE NO TE 1

INSTALL 4" G RSC W/43/0 THWN

FAC ILITY PO WER LAYO UT PLANSC ALE: ¼ " + 1" -0"

SEE NO TE 1

SEE NO TE 1

SEE NO TE 4

E C U2

E C U1

3/4" G RSC W/3-# 8 THWNAND 1 # 10 G ND

12" LO NG LIQ UIDTIG HT FLEXIBLEM ETAL C O NDUIT FO RBO TH EC U’S

S4

S5

FO UNDATIO N AND ANC HO RBO LTS SEE C IVIL DWG

STANDARD DETAILS

3/4 “ G RSC WITH2-# 12 -THWN AND1-# 12TO C M U BUILDINGPANEL DP6

3 /4 “ G RSC WITH2-# 12-THWN AND 1 -# 12

TO AREA LIG HT

4 //0 BARE C O PPERTO C O UNTERPO ISE

24" M IN

G ND LUG

G RADE

30' - 2 "

30 ' ALUM INUM PO LE

TYPE D LIG HT FIXTURE

G RO UND C LAM P(TYP)

NO TES:1. BO ND THE C O NDUIT TO THE C O UNTERPO ISE WITH 4 /0 AWG BARE C O PPER WIRE. EXO THERM IC ALLY THE 4/0 WIRE TO THE C O NDUIT ABO VE FINISH G RADE AND TO THE C O UNTERPO ISE BELO W G RADE.

2 . THIS DRAWING IS DIAG RAM M ATIC O NLY. C O NDUITS M UST BE INSTALLED SO THERE ARE NO T M O RE THAN THE EQ UIVALENT O F FO UR Q UARTER BENDS (360 DEG REES TO TAL) BETWEEN PULL PO INTS, SUC H AS C O NDUIT BO DIES O R BO XES. INSTALL SUITABLE PULLBO XES WHERE REQ UIRED.

3 . INSTALL C O NDUITS AT THE M INIM UM DEPTHS AS REQ UIRED BY THE NEC, TABLE 300-5 FO R UNDER STREETS, HIG HWAY, RO ADS, ALLEYS, DRIVEWAYS, AND PARKING LO TS.

4 . ATTAC H UNISTRUT TO WALL M O UNT SWITC HES S4 AND S5 O N UNISTRUT.

5 . ALL LIQ UID TIG HT FLEXIBLE M ETAL C O NDUITS SHALL HAVE A # 5 AWG EXTERNAL BO NDING JUM PER INSULATED G REEN.

4 ' 2 ' 0 ' 4 ' 8 ' 16 '

G RAPHIC SC ALE: 1 /4 " = 1 " -0"

G EN . R E V . #1, E C O ’S R TS C-02-01...48 PLC EFWC HK’D APP’DDESC RIPTIO NDATEREV.LTR.

A 05/20/02

D EPAR TM EN T O F TR AN SPO RTATIO NFEDER AL AV IATIO N AD M IN ISTR ATIO N

W ASH IN G TO N , D .C . 25091

D IG ITAL A IRPO R T SU R VEILLANC E R AD AR (DASR )CO NFIG URATIO N 4 G ENERIC DESIG N

FACILITY PO W ER LAYO UT


ISSUED BY DATE 02/04 /02 REV.LTR.

BDRAWING NO .

DASR-G EN4- E3

DEVELO PED BYJTR

DRAWN BYAO

C HEC KED BYPLC

RaytheonTEC HN IC AL SERVICES CO M PANY

BU RLIN G TO N , M A 01803

G EN . RE V . #2, E CO ’S RTS C -02-49...125B 12/09/02 PLC EFW

AREA LIG HTING DETAILSSC ALE: No t To Sc a le

T I 6310.47W P 010 001 DECEM BER 2003

FP-12

Figure FO -11. C onfig 4 Facility Pow er Layout

02.F

AT

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Xxx

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01/

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01:1

4:22

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. 1:2

C ABLE TRAY

SURG E S. PANELWW

DP6

BRKR2

T4T5

T3T2

DP5

DP4

DP1

G R O U N D W IR E-FU R NISHED & INSTALLEDB Y C O N TR AC TO R

3" SCH 8 0 PVCFU R NISHED & INSTALLEDB Y C O N TR AC TO R

TO CO U NTERP O ISE

E/G SHELTER W ALL DETAILFOR GROUND W IRES

SCALE:: NOT TO SCALE

FINISHG R A D E

SEAL CO ND U IT W ITHD U C T SEAL

3 " SCH 8 0 P VC

INSTALLEDB Y O TH ER S

C O N C R ETE W ALL

TO D EVICE TO B EG R O U N D ED

12" M IN.

~

E/G

FUELTANK

W GP

CB1

SVC ENTR SWS1

3AE8

W GP PNL DP7

E/GSHELTER

1/2” - 13 STAINLESS STEELBO LT AND W ASHER

C R IM PED C O N NECTO R

4/0 AW G B AR E CO P PERW IR E TO CO U NTERP O IS E

DETAIL OF REBAR GROUNDC ONNEC TION TO E/G SHELTER

SC ALE: No t To Sc a le

SHELTER

FOUNDATION

GROUND

LOADBANK

NOTES:1. THE 4/0 AW G GROUND W IRE ENCIRCLING THE FACILITY AND ANY OTHER UNDERGROUND GROUND W IRE SHALL BE BURIED A M INIM UM OF 30 INCHES BELOW GRADE. ALL BENDS IN GROUND CONDUCTOR TO BE MADE WITH 12" IN RADIUS OR LARGER.2. ALL ELECTRICAL AND LIGHTNING PROTECTION CONNECTIONS SHALL BE FREE OF ALL PAINT AND GALVANIZATION. SCRAPE ALL STEEL CONNECTIONS FREE OF ANY PAINT OR PROTECTIVE COATING BEFORE M AKING ANY GROUNDING CONNECTIONS.3. VERTICALLY MOUNTED 1" PVC CONDUIT USED AS A GUIDE FOR GROUND CONDUCTOR .4. ALL CONNECTIONS TO GROUND RODS AND COUNTERPOISE SYSTEM SHALL BE BY EXOTHERM IC W ELD.5. CONNECT THE REBAR OF THE EQUIPM ENT BUILDING AND THE E/G SHELTER W ITH 4/0 AW G BARE COPPER W IRES TO THE GROUND COUNTERPOISE USING EXOTHERM IC W ELDS AS SHOWN.6. CONNECT EACH XFM R SECONDARY NEUTRAL TO THE COUNTERPOISE USING A 4/0 THWN CONDUCTOR (EXOTHERM IC W ELD)7. ALL EQUIPM ENT CONNECTED TO M ULTI-POINT PLATES SHALL BE CONNECTED USING A #2 AW G CONDUCTOR INSULATED GREEN W ITH AN ORANGE STRIP.8. THE GROUND GRID W ILL CONSIST OF APPROXIM ATELY EIGHT 3/4" DIA. X 10' LONG, GROUND RODS . THE ACTUAL CONFIGURATION W ILL BE SITE SPECIFIC. THE CONNECTING COUNTERPOISE W ILL CONSIST OF 4/0 AW G BARE COPPER W IRE.9. ALL UNDERGROUND CONDUITS M UST BE BONDED TO THE COUNTERPOISE W ITH 4/0 AW G BARE COPPER W IRE. INSTALL GROUND CLAM P OR EXOTHERMIC WELD ABOVE GRADE AND EXOTHERMIC W ELD TO THE COUNTERPOISE.10. SRP LAYOUT AND DETAIL SHOWN ON DWG E28.11. CONTRACTOR TO INSTALL 4/0 W IRE INSULATED BLACK FROM COUNTERPOISE TO COPPER GROUND BAR IN GENERATOR HOUSING. INSTALL W IRE IN 1" PVC INSIDE THE E/G SHELTER AND PVC SLEEVE TO 1" BELOW FINISH GRADE OUTSIDE THE SHELTER. USE EXISTING PENETRATION IN E/G SHELTER.12. CONNECT A 4/0 AW G W IRE INSULATED GREEN W ITH ORANGE STRIPES TO THE CABLE TRAY W ITHIN 2 FT. FROM THE END OF THE CABLE TRAY. ATTACH THE OTHER END OF THE WIRE TO THE NEAREST M ULTI-POINT GROUND PLATE. TYPICAL OF 4 PLACES. 13. BOND ALL JOINTS OF THE CABLE TRAY W ITH #2 WIRE INSULATED GREEN W ITH ORANGE STRIPES.14. GROUND BAR FOR W PG E5 LONG SHALL BE HARGER CAT. NO. GBIP14484.15. CONNECTIONS TO EXTERIOR HVAC DUCT TO BE TYPICAL CONNCTION OF GROUND CONNECTORS (SEE THIS DWG)

4/0 AW G C OPPER W IREINSU LATED GREEN W ITHRED STRIPE TO C OU NTERPOISE FROMSURGE SUPPRESSION PANEL

4/0 AW G COPPER W IRE IN SULATEDGREEN W ITH RED ST RIPE (INSIDEBU ILD ING) TO C OUN TERPO ISE FRO MIN TERIOR G ROUN D BAR

4/0 AW G C O P P ER W IRE TOC O UNTERPOISE FROM T HEPOLYPHASER SANDW IC HBAR GRO UND

INSTALL 4/0 AW G BARE COPPERW IRE FROM FOU NDATION REBAR TO C OUNT ERPOISE (SEE NO TE 5)

CO NNECTO R TO O THEDLO CK W ASHER

ECU2

ECU1

M ETALM EM B ER

TO O THEDLO CKW ASHER

TYPICAL MECHANICAL CONNECTIONOF GROUND CONNECTORS

SCALE: Not To Scale

4/0 AW G B AR ECO P PER W IIR E TOC O U NTER PO IS EFR O M LO AD B ANK

4/0 AW G B AR EC O P PER W IIR E

4/0 AW G CO P PER W IIR EINSU LATED G R EEN W ITH R ED STR IPE

FR O M CB 4 TO CO U NTERP O ISE

INSTALL 4/0 AW G CO P PER W IIR E INSU LATED

G R EEN W ITH R ED S TR IP EFRO M W AVEG U ID E B U LK HEAD

P LATE TO CO U NTER P O ISEINS TALL 5 0 0 M CMCO PP ER G R EEN INSU LATEDTO CO U NTER PO ISE

FO R CO NTINU ATIO NSEE D W G E6

4 /0 AW G W IIRE INSU LATED G R EEN.INS TA LL IN 1" P VC C O N D U IT A B O VE G R O U N D.LEAV E 3'IN B O X.

4/0 AW G B AR E CO P PER W IIR E


INSTALL 5 00 M CM CO PP ER G R EEN INSU LATED TO C O U NTER P O IS E


4 /0 AW G CO PPER W IIREINSU LATED G R EEN W ITH R EDS TRIP E FR O M C B3 TOC O U NTER PO IS E

4/0 AW G CO P PER W IIR EFR O M PAD R EB ARTO CO U NTER PO ISE (TYP 2)

2 ' TO 4' O U TSID E O F D R IP LINE O FB U ILD IN G (TYP ) - CO U N TER PO ISE IS S H O W NFARTHER FR O M B U ILD ING FO R CLAR ITY

4/0 AW G B AR E CO PP ERW IIR E FR O M ECU TOCO U NTERP O ISE (TYP 2)

4 /0 AW G B AR E CO PPER W IIR E FR O MSU PP LY D U CT TO CO U NTER PO ISE (TYP 2)SEE NO TE 15

4 /0 AW G B AR E C O PPER W IIREFR O M R ETU RN D U CTTO CO U NTER P O ISE (TYP 2)SEE NO TE 15

4/0 AW G B AR ECO PP ER W IIR E

4 /0 AW G BAREC OPPER W IIRE TOTRAN SFORM ER GROUN D

4/0 AW G B AR E CO P PER W IIR E

4/0 AW G INSU LATED G R EEN CO PP ER W IIR E FR O M U PS G R O U NDTO CO U NTER PO ISE

INST ALL EXOTHERM ICW ELD TO C OUNT ER PO ISE (TYP)

SEE NOTE 4FO R CO NTINU ATIO N

SEE D W G E13

4/0 AW G CO P PER W IIR E INSU LATEDG R EEN W ITH RED STR IPE FR O MC B 1 TO C O U NTER PO ISE.

4 /0 AW G CO PPER W IIRE INSU LATEDG R EEN W ITH R ED STR IP E FR O M

CB 2 TO CO U NTER PO ISE.

INSTALL 4/0 AW G B ARE C OPPERW IIRE FROM FOUN DATIO N REBAR TO

C O UNTERPOISE. (SEE NO TE 5 )

5 0 0 M CM CO PPERG R EEN INS U LATED

TO CO U NTER PO ISEFR O M M G P E1

G R O U N DRO D (TYP )

USE BRAID ED D S TRAP FO RDO OR FRAM E (TYP)

3CE8

3AE8

3AE8

FGE28

3CE8

3BE8

4 /0 AW G B AR EC O P PER W IIR E

4/0 AW G B AR E CO P PER W IIR EFR O M G EN ER ATO R V EN T

TO CO U NTER P O ISE

4 /0 AW G B AR E C O PPER W IIRE EXO TH ERM ICALLYW ELD TO E/G EXHAU ST P IP E

-SEE NO TE 3

4/0 AW G B AR E CO PP ER W IIREFR O M PAD R EB AR C O NNECTIO N

SEE NO TE 11

M PGE3

M PGE7

4/0 AW G C OPPER W IREINSULATED GREEN W ITH

ORANGE STRIPS (TYP)

4/0 AW G C OPPER W IREINSULATED GREEN W ITH

ORANGE STRIPS (TYP)

M P G

MPGE1

M PG

M P G

M PG M P G M P G M PG M P GM P G

M P GE8

M P GE5

M PGE6

M PGE4

M P G M PGE2

M PGC O M P/D YH R

FLOO RGR OUND

4/0 AW G B AR E CO PP ERW IIR E FR O M HO O DTO CO U NTERP O ISE

4/0 AW G B AR E C O PPER W IIR EFO R G R O U N D ING ELECTR O D ECO NDU CTO R

4/0 AW G B AR E CO P PER W IIR E TOTR ANS FO R M ER N EU TR AL (TYP 4)

4 /0 AW G B AR E C O PPER W IIRE FR O M HO O D P ANEL D P1 TO CO U NTER PO ISE

4 /0 AW G B AR E CO P PER W IIR EFR O M P AD R EB AR TOCO NNECTIO N

4/0 AW G B ARE CO PP ER W IIR EFR O M S H ELTER M O D U LES TO C O U NTER PO ISE (TYP 4)

4/0 AW G B AR E CO PP ERW IIR E FR O M P ANEL D P7

TO CO U NTER PO ISE

4/0 AW G B ARE CO PP ERW IIR E TO FU EL V AU LT

AND LAD D ER

4/0 AW G B ARE CO PP ERW IIR E FR O M HO O DTO CO U NTER PO ISE

INSTALL 5 0 0 M CMCO P PER INSU LATED G R EEN

TO CO U NTER PO ISE

V ENTPIPE

4 /0 AW G B AR EC O PP ER W IR E

4/0 AW G B ARECO PP ER W IIR E

FR O M E/G B U LK HEADP LATE TO CO U NTER P O ISE

PIPE SU PPO R T

FLO ORG ROUN D

FLOOR GR OUND

FLOO RG ROUN D

M P G


4/0 AW G B AR E CO P PERW IIR E EXO THER M ICALLY

W ELD TO D AY TANK VENTP IP E – SEE N O TE 3

4 /0 AW G B AR E CO PPER W IR E TO CO U NTER PO ISE

S UR GE S. PN L

CB 4

C B 3

4' - 10 "

C BT

W W

BRKR 2DP6

T5T4

T3T2

DP5

DP4

DP1

CB2UPSBAT

UPS

CMU EQUIPMENT BUILDING

G G

GG

FP-13

Figure FO-12.Config 4 FacilityGrounding Plan

GEN. REV. #1, ECO’S RTSC-02-01...48 PLC EFWC HK’D APP’DDESC RIPTIO NDATEREV.LTR.

A 05/20/02

DEPARTMENT OF TRANSPORTATIONFEDERAL AVIATION ADMINISTRATION

W ASHINGTON, D.C. 25091


FACILITY GROUNDING PLAN



BDRAWING NO .

DASR-GEN4- E7

DEVELOPED BYJTR

DRAWN BYAO

C HEC KED BYPLC




1 DECEMBER 2003TI 6310.47W P 010 00

8'

4'

4'2'

2'

2' 1'

1' 6" 0'

0'

1'

GRAPHIC SCALE: 3/8" = 1' -0"

GRAPHIC SCALE: 3/4" = 1' -0"


GROUND CABLR TRAY TOWAVEGUIDE GROUNDING PLATE(SEE NOTE 1)

INSTALLWAVEGUIDES

3/4” GRSC

SURGESUPPRESSIONPANEL

4" GRSC W/4 POWERCABLES (CABLESFURNISHED)

1" GRSC WITH FIREALARM, DOOR SECURITY& TELEPHONE WIRES &1-2 PAIR TELCO CABLE

SEE VIEW A30" NON-VENTILATED CABLETRAY, CONTRACTOR FURNISHED,MOUNT UPSIDE DOWN

4" GRSC WITH PEDESTALCONTROL SIGNAL CABLES (CABLES FURNISHED)SEE DWG E4

HORIZONTAL TOWERMEMBER

TOWER BRACING (TYP)

1" GRSC

WAVEGUIDE CONDUIT DETAIL – PLANSCALE: 3/8" = 1' -0"

1" GRSC

NON-VENTILATED CABLE TRAY& RADIUSED TRANSITION FROMVERTICAL TO HORIZONTAL -MOUNT UPSIDE DOWN

INSTALLWAVEGUIDE

(FURNISHED)

INSTALLCOAX

(FURNISHED)

TOWER &CFE BRACKET UNISTRUT BY CONTRACTOR

WAVEGUIDE CONDUIT DETAIL – ELEVATIONSCALE: 3/8" = 1' -0"

CADWELD TO COUNTERPOISE

1" PVC CONDUIT WITH4/0 AWG BARE.ATTACH TO DIAGONALTOWER BRACE

GRADE B

BSURGE SUPPRESSION PANELAND CONDUIT NOT SHOWN

INSTALL 1-1" GRSCCONDUIT THRU SHELTERWALL – INSTALL GROUNDBUSHING ON 1"CONDUIT ENDS

INSTALL2-4" GRSC


2-4" GRSC2-1" GRSC1-3/4” GRSC

INSTALL WAVEGUIDE & COAX CABLES (FURNISHED)

30" GALV. CABLE TRAYB-LINE #574-G-ST-30CONTRACTOR FURNISHEDMOUNT UPSIDE DOWN

TOWER COLUMN

30" GALV. CABLE TRAYB-LINE #574-G-12-30

AND SUPPORTS (FURNISHED)

GROUNDCLAMPS ON5 GRSC CONDUITSSEE DETAIL 3/E14

30" CABLE TRAYB-LINE #7G-30-90V024

90O BEND(CONTRACTOR

FURNISHED)

STAIRWAY NOT SHOWN

VIEW ASCALE: NOT TO SCALE

3/4" GRSC

4" GRSC

1" GRSC

1" GRSC CONDUITTO PANEL DP2

4" GRSC CONDUIT TOGASKETED JCT BOX ON TOWER

3/4” GRSC CONDUITTO PANEL DP3

1" UNISTRUT SUPPORT(TYP)

5' -

0" A

.F.F

.

4" GRSC CONDUITFOR SIGNAL CABLES

1" UNISTRUTSUPPORT

1" UNISTRUTSUPPORT

TYPE LL-A CONDUITFITTING – SEENEC 346-11

PENETRATION FOR1 1/4” GRSCNIPPLE

PENETRATIONS FORTEC 90 CABLECONNECTORS

TYPE LB-A CONDUITFITTING – SEENEC 346-11

3/4" PVC FORGROUND WIRE

VIEW B-BSCALE: 3/4” = 1 ' -0"

NOTE:1. ALL PENETRATIONS IN SURGE SUPPRESSION PANEL U31A12A1 BY CONTRACTOR.

NOTES:1. EACH CABLE TRAY SECTION SHALL BE BONDED TO THE ADJACENT SECTION W ITH #2 AW G W IRE INSULATED GREEN. GROUND TO THE BULKHEAD GROUND PLATE W ITH #2 AW G BARE W IRE.

2. SEE DW G E14 FOR W AVEGUIDE BULKHEAD GROUND DETAILS.

3. CONTRACTOR TO LAYOUT CONDUIT RUNS SO THERE SHALL NOT BE MORE THAN THE EQUIVALENT OF FOUR QUARTER BENDS (360 DEGREES TOTAL) BETW EEN PULLPOINTS. INSTALL CONDUIT BODIES AND BOXES AS REQUIRED.

SURGESUPPRESSIONPANELUS1A12A1(CFE)

SEE DRAWING S5 AND WAVEGUIDEDRAWINGS H311018, SHT 2, 3 & 4.

GEN. REV. #1, ECO’S RTSC-02-01...48 PLC EFWC HK’D APP’DDESC RIPTIO NDATEREV.LTR.

A 05/20/02

DEPARTMENT OF TRANSPORTATIONFEDERAL AVIATION ADMINISTRATION

W ASHINGTON, D.C. 25091


W AVEGUIDE AND CONDUIT DETAILS



BDRAWING NO .DASR-GEN4-

E10

DEVELOPED BYJTR

DRAWN BYAO

C HEC KED BYPLC




02.F

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01/

09/2

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01:1

7:33

PM

. 1:2

1 DECEMBER 2003TI 6310.47W P 010 00

Figure FO-13.Config 4 W aveguide andConduit Details

FP-14

1 DECEM BER 2003TI 6310.47W P 010 00

CONTRACTOR TO MOUNT CFE U35A7SURGE PROTECTION PANEL ON CEILING

BUSHING

3/4“ GRSC AND SENSOR CABLESTO FIRE ALARM AUDIBLE/VISIBLE ALARM

HARGER GROUND BAR GBI 141.524 EOR APPROVED EQUAL

#4 AWG INSULATED GREEN FROM U34A1 PCBOARD TO HARGER GROUND BAR (TYP 3X)

WEATHERPROOF TELEPHONE

#4 AWG WIRE INSULATED GREEN FROMU34A1 ENCLOSURE GROUND TO MGP

3/4“ GRSC W/CABLE W0072TO DP3CB5 (SEE DW G E25)

3/4“ GRSC W/ SENSOR CABLE, W1501.TO THE PLATFORM GATE SWITCH & PLCPJ15 TERMINATE CONDUIT ADJACENT TOPLCP WITH GND BUSHING

#4 AWG WITH GREEN INSULATION, EXOTHERMICALLYWELD TO NEAREST DOW CONDUCTOR

TVSS

1" GRSC TO PNL DP2

4" GRSC TO GASKETED BOX

SECTION C-CSCALE: 1/2“ = 1' -0”

TO EQUIPMENT SHELTER

FINISHFLOOR

3' -2"

3/4“ GRSC TO PNL DP3

1" GRSC TO CB5. INSTALL GROUNDBUSHING IN CB5. BOND GROUND

BUSHING TO THE MEZZANINE WALLWITH #6 AWG WIRE INSULATED GREEN.

4" GSRC TO BELOW SURGESUPPRESSION PANEL, INSTALL GROUND

BUSHING AND BOND TO WALL WITH#2 AWG WIRE INSULATED GREEN.

2" GRSC

2" GRSC TO END 18" BELOW LOCALPEDESTAL CONTROL PANEL. INSTALL

GROUND BUSHING ON CONDUIT.BOND GROUND BUSHING TO SHELTERWALL WITH #2 AWG WIRE INSULATED

GREEN. SEAL CONDUIT WITH DUCT SEAL.

1 5/8" X 1 5/8" UNISTRUT CHANNEL

22" GRSC

SURGE SUPPRESSION PANELU34A1 – SEE NOTE 13

#4 AWG INSULATEDGREEN TO MGP

INSTALL PEDESTAL LOCALCONTROL PANEL (CFE) 4"

PERFORATED ANGLE“8-LINE” SA276 (TYP)

1" GRSC W/SENSOR CABLEAND GROUND WIRE FOR

WIND MONITOR7' - 4"

7' –5

1/2

"

4' -9

"

4"J15

H S

NOTES:1. M O UNT RECEPTACLE TO UNDERSIDE O F RADAR PLATFO RM . EXACT LO CATIO N SHALL BE DETERM INED IN THE FIELD W ITH THE SCE. CONTRACTOR TO INSTALL CFE HO IST O N TOW ER M O NO RAIL BEAM.2. ALL EQUIPM ENT NO T INDICATED AS “FURNISHED” SHALL BE FURNISHED AND INSTALLED BY THE CONTRACTOR .3, SEE DW G E2 FOR ELECTRICAL PANEL SCHEDULES .4. ALL CO NDUITS IN M EZZANINE SHALL BE G RSC W ITH CAST BO XES.5. INSTALL A #6 AW G G ROUND W IRE FRO M THE G ROUND BUS O F PANELS DP2 AND DP 3 TO THE STRUCTURAL STEEL O F THE TOW ER. CO NNECT W IRES TO THE STRUCTURAL STEEL W ITH AN EXO THERM IC W ELD .6. INSTALL RIG ID CO NDUIT HUBS AT 24"X 24"X6" BO X. INSTALL #2 AW G BARE BETW EEN ALL G RSC ENTERING BO X TO STRUCTURAL STEEL, USING APPRO VED CLAM PS O N CO NDUIT. EXO THERM IC W ELD TO STRUCTURAL STEEL.7. CO NTRACTO R SHALL BE RESPONSIBLE FO R M AKING ALL PENETRATIO NS THRO UG H THE W ALL AND FLO OR O F M EZZANINE RO OM . AFTER CO NDUIT IS INSTALLED , SEAL HO LE W ITH CLEAR SILICO N CAULK.8. TELEPHONE TO BE ALLEN TEL CAT. NO . G890D-14 OR APPRO VED EQUAL.9. BOND GRO UND IN CB5 BASE TO M EZZANINE W ALL W ITH 4/0 AW G W IRE INSULATED GREEN.10. CO NTRACTO R TO INSTALL #2 AW G COPPER W IRE INSULATED G REEN FRO M PEDESTAL DRIVE M O TO R A AND PEDESTAL DRIVE M O TO R B TO THE M AIN G RO UND PLATE.11. INSTALL CANE TYPE, STAINLESS STEEL O R BRASS DO O R O LDER O N DOO R . DRILL M EZZANINE FLO O R PLATE SO THE DO O R IS HELD O PEN AT 90O AND APPRO XIM ATELY 180O .CO LD G ALVANIZE THE FLO OR PLATE AFTER DRILLING.12. FOR EXHAUST FAN DETAILS SEE DW G M 6.13. CO NTRACTO R TO PURCHASE SURG E SUPPRESSIO N PANEL U 34A1 FRO M BAT ELECTRIC INC. BAT ELECTRIC, INC . 20200 CHARLANNE DR . REDDING , CA 96002 (530) 221-133614. INSTALL #2 G RO UND W IRE INSULATED GREEN FRO M THE RO TARY JO INT TO THE M G P.15. INSTALL 4/0 AW G W IRE INSULATED GREEN FRO M THE PEDESTAL G ROUND STUD TO THE STRUCTURAL STEEL. CO NNECT W IRE TO THE STRUCTURAL STEEL W ITH AN EXO THERM IC W ELD .16. INSTALL PANEL DP2 SO THE DO OR O PENS A M INIM UM O F 90O W ITH THE PEDESTAL M OTOR INSTALLED.

G EN. REV. #1, E CO ’S RTS C-02-01...48 PLC EFWC HK’D APP’DDESC RIPTIO NDATEREV.LTR.

A 05/20/02

DEPARTM ENT O F TRANSPO RTATIO NFEDERAL AVIATIO N ADM INISTRATIO N

W ASHING TO N, D .C . 25091

DIG ITAL A IRPO RT SURVEILLANCE RADAR (DASR)CO NFIGURATION 4 G ENERIC DESIG N

PEDESTAL EQ UIPM ENT ROO M



BDRAWING NO .DASR-GEN4- E11

DEVELO PED BYJTR

DRAWN BYAO

C HEC KED BYPLC


BURLINGTON , M A 01803

GE N. RE V. #2, ECO ’S RTSC-02-49...125B 12/09/02 PLC EFW

02.F

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01:1

7:50

PM

. 1:2

1

2

3

4

INSTALL PEDESTAL LOCALCONTROL PANEL

INSTALL SAFETY SW ITCH

POWER PANELS

SIDE WALL SURFACEMOUNT 4' FLOURESCENTLIGHT FIXTURE – TYPE E

B

TYPE F LIGHTFIXTURE (SEEDWG E9)

TIE-OFF O-RING(SEE DWG E9)

INSTALL SOHOOK IS ONTHIS END

4" SQ WP BOX WITH 120V20A. NEMA L5-20RTWISTLOCK RECEPTACLEFOR HOIST. (SEE NOTE 1)

3/4“ GRSC FROM DP2INTRUSION SENSOR CONTACTS

1

2

3

3

D

O

B

MOUNT HOIST ONMONORAIL BEAM

(FURNISHED BYOTHERS)

TO AUDIBLE/VISUAL ALARM

3/4“ GRS C, LB, & S ENSO R CAB LETE RM INA TE IN THE LO CAL

PEDE STAL CO NTRO L P ANELA ND AT THE GA TE S W ITCH

FIRE ALARMPULL S TA TIO N1" G RSC TO

W IND M O NITO R

1" G RSC3/4" GRS C

1" GRS C4" GRS C

EX HAUST FAN HO O DSEE NO TE 12

W EA THE RP ROO FTELE PHO NE

24"X24"X6" (M IN IM UMSIZE) NEM A 4

PED ESTAL EQ UIPM ENT RO O M FLO O R PLANSCA LE: 1/2” =1' -0"

#2 G RO UND TO M G P2" G RSC

3" G RSC

SE E NO TE 6

V IEW ESCALE: 1/2” =1 ' -0"

GA TE TO PLA TFORM

PLA TFO RMG ATE S W ITCH(FURNISHED )

#4 A W G W IRE W ITH G REENINS ULA TIO N, E XO THE RM ICA LLY W LEDTO NEARE ST DOW N CO NDUCTO R

ATTA CH UNIS TRUTS TO TO W E RSTRUCTURAL M EM BERS – HANG B OXFRO M UNISTRUT BY THREADE D RODS -CAULK ARO UND RODS AT B OX

TOW ER CO LUM NS

AC

E

A

2" G RS C4" G RSC 3" G RSC

SECTIO N B-BSCALE: 1/2” =1 ' -0"

1" PVC W/ 4/0 AWG GRDATTACH TO TOWER STEEL

FIN ISH FLO OR

W P , BO X W ITH120V G FCI RECE PTACLE P LATFO RM

G ATES W ITCH

RA ILINGS

3/4“ GRSC W ITH3-#12 THW N

S URGE SUP PRES SIO NPA NEL U35A7 (CFE )

#4 AW G W IREINS ULA TE D G REEN

FROM U35A7ENCLO SURE

GRO UND TO M G P

10 1/2”

FROM W EB OF B EA M “

#4 AW G INS ULATED G REE N FRO M U35A7PC BO ARD TO M E ZZANINE CE ILING

6 1/2“

FROM

WEB

OF

BEAM

3 /4" GRS CW ITH 3-#12

SE E NO TE 11.

PEDESTAL EQ U IPM EN T R O O M LIG HTING PLAN

SCALE: 1/2” =1' -0"

4"X4" JUNCTIO N BO X FO R FEE DDO W N TO LIG HT SW ITCH

4

4

VIEW DSCALE: 1/2” =1 ' -0" 3/4" G RSC W ITH 3 - #12 THW N

4" GRSC W ITH G RO UNDINGBUS HING O N END

PE DESTAL LOCALCONTRO L PA NE L(CFE)

4" SQ B OX W /20A G FC120V RE CEPTACLEAND W E ATHE RPRO OFCO VER (TY P)

5"

8"

6' -0

"

4 "

F IRE A LA RMP ULL STATIO NLIGHT S W ITCHTV SS

3/4" G RSC TOW IND M ONITO R

EX HUA ST FAN EF-1THE RM O STAT

CFE CABLE S – INSTALLED TOCFE ON PE DE STAL

SECTIO N A-ASCA LE: 1/2” =1 ' -0"

8 ' -0"

INSTALL CFES AFETY S W ITCH

4" G RSC W ITHCONTROL CABLE S

A ND SIGNA L CAB LE S(CAB LES FURNISHED)

3/4“ G RSC AND S ENSO R CAB LEB ETW E EN THE PE DE STAL LO CAL CONTROL

P ANEL & THE PLATFORM G ATE S W ITCH

3/4“ G RSC W /4 - #10THW N & 1 - #10 G RD

30" W A VEG UIDECA BLE TRA Y

W AVE GUIDE

COA X

30A D ISTRIB UTIONP ANEL (SE E DW G E2), DP3

3/4“ G RSC TO FLO URE SCENT LIGHT.

MAIN GROUND PLATE (SEE DWG E15)

TV SS 3/4“ LIQ UID T IG HT

FIRE ALA RM A UDIBLE/V IS IBLE ALARM

DO OR INTRUS IO NALA RM S ENSO RS (2)

3/4“ G RSC

SA FE TY S W ITCH(CFE)

INS TA LL BRISTLESW EE P ON DOO RBO TTO M

FINISHFLOO R

3/4“ GRS C W /S ENSO RCAB LE TO THE P LATFO RM

G ATE SW ITCH

2' - 1"

2'

11"

7' - 4"

7' –5

1/2

"

3/4" G RSC TOHOIST RECP T.

50A D ISTRIB UTION PANE L(SE E DW G E2), DP2

S EE NOTE 16

3/4" G RSC TO END B ELO W SA FE TYS W ITCH, INS TA LL G RO UND B USHING O NCONDUIT . BO ND G ROUND BUSHING TO

SHE LTE R W ALL W ITH #2 AW G W IREINS ULA TE D G REEN. S EAL CONDUIT

W ITH DUCT SEA L.

C

~

UP

DO W N

S

H

FP-15

Figure FO -14. Config 4 Pedestal Equipm entRoom Details

LO A DB AN K

1" G R S C W ITH3 #12 A N D 23 #14

LOA

D B

AN

K C

ON

TRO

L W

72

28

B

2 - 4" G R S C (FO RFIB E R O P TIC S IG N A L

C A B LE)2 - 4" G R S C FO R

TE LE P H O N E S E R V IC E

H A N D H O LES E E N O TE 1

LO A D B A N KC O N TR O L P A N E L

FU EL LE V E LM O N ITO R

FU E L A LA R MS E N S O RE Q U IP M E N TB O X

W 7230B

E /GS H ELTER

1000 G LD IE SE L

FU EL TA N K

2 " G R S C W ITH43 #14 A N D1 2 P A IR TE LC OC A B LE

S E E N O TE 1

IN S T A LL W IR E S FR O MFU E L LE V E L S E N S O R A N D FU E LLE V E L LE A K D E TE C TO R S TOFU E L LE V E L C O N TR O L P A N E LIN 1" G R S C

C B 1

3/4" C ., 3 #14

3/4" C ., 6 #14

3/4" C .,17 #14

TO FM A CC B 2

2" R G S C

E/G C O NTRO L & SENSO R WIRES

3/4" G R S C , 2 #14

S E E N O TE 1TO FEN C E G A TES W ITC H

IN S TA LL G R O U N D B U S H IN G S IN E N C LO S U R E -W ITH #6 A W G IN S U LA TE D G R E E N .

D P 1

D P 4

F C

D P5

J

S

SH

T2T3

T4T5

3 /4 " C ., 22 #14

3/4" C ., 14 #14TO FM A C JB

IN A TTIC

FM A C JU N C TIO N B O X-S E E D W G E 21

C B T

D P6B R K R 2

W WU 31A 12

J

CF

C C

3/4" C ., 2 #14

C B 3

C M U E Q U IPM EN T BU ILD IN G

D A SR FA C ILITY C O N TR O L AN D S IG N ALS PLA NS C A LE: N O T T O S C A LE

3/4" C ., 5 #14 TO FM A C

3/4" C ., 2 #14 TO C B 2

3/4" C ., 2 #14 TO FM A C

3/4" C ., 22 #14 TO FM A C

3/4" C ., 4 #14 TO FA C P3/4" C ., 4 #14

3 /4" C ., 2 #14 S E E N O TE 8

C B 44" G R S C

3/4" C ., 4 #14TO FM A C

3/4" C ., 2 #143/4" C ., 2 #14 TO C B 4

3/4" C ., 2 #14

W17

01B

W15

01B

W16

02B

W96

02B

W96

01B

W07

01B

C FE C A B LE S

S E EN O TE 1

C B 3

E C U1

E C U2

3/4" C ., 7 #14

IN S TA LL G R O U N D B U S H IN G – B O N DW ITH #6 A W G W IR E IN S U LA TE D G R E E N.TO E Q U IP M E N T G R O U N D B A R

IN S TA LL 1" G R S C W ITHF IR E A LA R M , D O O R S E C U R ITY &TE LE P H O N E W IR E S 20-#14 &1 – 2 P A IR TE LC O C A B LE

IN S TA LL G R O U N D B U S H IN G O N 2" C O N D U IT –B O N D TO M E ZZA N IN E S TE E L W ITH#2 A W G W IR E IN S U LA TE D G R E E N .

4" G R S CP A N E L U 34A1P A N E L U35A 7

P E D E S TA L LO C A L C O N TR O L P A N E L

C FE C A B LE

W IN D M O N ITO R

C FE C A B LE

P LC PW 0201

W07

01C

W98

01C

W98

02C

W04

04W

0505

W00

49W

0046

W 1501

H

SC

C B 5

W13

01

DP3

P E D E S TA L

DP2

F

3 /4" C ., 2 #14 TO C B 5

3/4" C ., 2 #14 TO C B 5

C FE C A B LE

3/4" C ., 2 #14 TO C B 5

3/4" C ., 2 #14 TO C B 5

3/4" C ., 24 #14 TO C B5

P E D E S T A L S A FE T Y S W ITC H

C FEC A B LE

C FE C A B LE3/4" C ., 2 P A IR

TE L C A B LE TO C B5P R O V ID E A N D IN S T A LL A TE LE P H O N E

B O X W ITH A TE LE P H O N E S E T

IN S TA LL G R O U N D B U S H IN G .B O N D TO M E ZZA N IN E W A LL

W ITH #6 W IR E IN S U LA TE DG R E E N

W X X X XA LL P LU G IN C O N N E C TO R S

F O R D E T A ILS S E E P E D E S TA LA S S E M B LY IN S TR U C TIO N

M A N U A L

TO P LA TFO R M G A TE S W ITC H

P U N C H H O LE IN LO A D B A N K A C C E S S P LA TE.IN S TA LL G R O U N D B U S H IN G O N C O N D U IT .

B O N D TO E Q U IP M E N T G R O U N D B U SW ITH T H E S A M E #6 A W G U S E D T O

G R O U N D TH E P O W E R C O N D U IT -S E E D W G E 1.

C B2SC A LE: N O T TO S C ALE

C B2

P U LLSTAT IO N

TE LC OB O X

FM A C FAC P H /S C B 1 G A TE SC B2

TOFAC P

H O R N /S TR O B EP U LL S T A TIO N

C B 1FM A C

TELC O B O XG A TE

C O N D U IT & W IR E S3/4”C ., 10 #14 A W G & G N D3/4”C ., 4 #14 A W G & G N D3/4”C ., 2 #14 A W G & G N D

3/4”C ., 18 #14 A W G & G N D3/4”C ., 17 #14 A W G & G N D3/4”C ., 2 P A IR TE L. W IR E S3/4”C ., 2 #14 A W G & G N D

C B3S C ALE: N O T TO S C ALE

E C U 2

E C U C O N TR O L P A N E L

E C U 1

CB3

C B3TO

E C U 1E C U 2

E C U C O N TR O LP A N E L

C O N D U IT & W IR E S3/4”C ., 7 #14 A W G & G N D3/4”C ., 7 #14 A W G & G N D

3/4”C ., 14 #14 A W G & G N D

TOFA C P

H O R N /S TR O B EP U LL S TA T IO N

C B 5FM A C

TE LC O BO X

C O N D U IT & W IR E S3/4”C ., 4 #14 A W G & G N D3/4”C ., 4 #14 A W G & G N D3/4”C ., 2 #14 A W G & G N D

3/4”C ., 10 #14 A W G & G N D3/4”C ., 4 #14 A W G & G N D3/4”C ., 2 P A IR TE L. W IR E S

C B 4S C ALE: N O T TO S C ALE

C B4C B 4

P U LLSTAT IO N

TE LC OB O X

FM AC FA C P H /S C B 5

N O TES:1. B O N D TH E C O N D U IT TO TH E C O U N TE R P O IS E W ITH 4 /0 A W G B A R E C O P P E R W IR E. E X O TH E R M IC A LLY W E LD TH E 4 /0 W IR E TO TH E C O N D U IT A B O V E F IN IS H G R A D E A N D TO TH E C O U N TE R P O IS E B E LO W G R A D E

2. TH IS D R A W IN G IS D IA G R A M M ITIC O N LY . C O N D U ITS M U S T B E IN S TA LLE D S O TH E R E A R E N O T M O R E TH A N TH E E Q U IV A LE N T O F FO U R Q U A R TE R B E N D S (360 D E G R E E S TO TA L) B E TW E E N P U LL P O IN TS, S U C H A S C O N D U IT B O D IE S O R B O X E S. IN S TA LL S U ITA B LE P U LLB O X E S W H E R E R E Q U IR E D. C O O R D IN A TE A LL C O N D U IT R U N S W ITH S C E . 3 . IN S TA LL C O N D U ITS A T TH E M IN IM U M D E P TH S A S R E Q U IR E D B Y TH E N E C , TA B LE 300-5 FO R U N D E R S TR E E TS , H IG H W A Y, R O A D S, A LLE Y S , D R IV E W A Y S, A N D P A R K IN G LO TS .

4. P LC P = P E D E S TA L LO C A L C O N TR O L P A N E L.

5 . C FE = C O M P A N Y FU R N IS H E D E Q U IP M E N T.6. N O T A LL C FE C A B LE S A R E S H O W N. S E E S D G584625 .

7 . E Q U IP M E N T R M D O O R C O N TA C TS TO B E W IR E D S E R IE S P R IO R C O N N E C TIO N TO FJB 1 A N D 2 . S P LIC E TO G E TH E R IN FM A C JB.

8 . IN S TA LL S M O K E D E TE C TO R S O IT IS N O T IN H V A C A IR S TR E A M.

9. A LL C O N D U ITS TO H A V E #14 A W G G R E E N IN S U LA TE D G R O U N D C O N D U C TO R .

G E N . R E V. #1, E C O ’S R TS C -02-01...48 PLC EFWC HK’D APP’DDESC RIPTIO NDATEREV.LTR.

A 05/20/02

D EPA R TM E N T O F TR A N SP O R TA TIO NFE D ER AL A V IAT IO N AD M IN ISTR ATIO N

W ASH IN G TO N , D .C . 25091

D IG ITAL A IR PO R T SU R VEILLAN C E R AD A R (D ASR)C O N FIG U RA TIO N 4 G EN E R IC D ES IG N

C O N TRO LS A ND S IG N AL PLA N



BDRAWING NO .

DASR-G EN4- E4

DEVELO PED BYJTR

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C HEC KED BYPLC

RaytheonTEC H N IC AL SER VIC ES C O M PANY

BU RLING TO N , M A 01803

G E N . R E V. #2, E C O ’S R TS C -02-49...125B 12/09/02 PLC EFW

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FP-16

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Documents

OPERATION AND MAINTENANCE INSTRUCTIONS...MONOPULSE SECONDARY SURVEILLANCE RADAR (MSSR) SYSTEM 808390/000 EFFECTIVITY: ASR-11 Configurations 1 thru 5. * * XX/XX/XXXX SDR-ASR11-057 TI