• ♦Manual Notice 2018-1
• ►1. Introduction
  • ►1. Overview
    • ♦Purpose of Manual
    • ♦Users of Manual
    • ♦Training
    • ♦Experience
    • ♦References
  • ►2. Responsibilities
    • ♦Introduction
    • ♦Traffic Operations Division
    • ♦Bridge Division
    • ♦Districts
• ►2. Lighting Systems, Eligibility, and Warrants
  • ►1. Overview
    • ♦Introduction
    • ♦Types of Lighting Systems
    • ♦Eligibility and Warrants
  • ►2. Continuous Lighting
    • ♦Description
    • ♦Eligibility
    • ♦Warrants
    • ♦Specially Funded Projects
  • ►3. Safety Lighting
    • ♦Description
    • ♦Eligibility
    • ♦Warrants
    • ♦Continuous Lighting Classified as Safety Lighting
  • ►4. Bikeway and Pedestrian Way Lighting
    • ♦Eligibility
    • ♦Adjacent Roadway Lighting
  • ►5. Systems Financed, Installed, and Operated by Other Agencies
    • ♦TxDOT Policy
    • ♦Guidelines
• ►3. Master Lighting Plans
  • ►1. Overview
    • ♦Introduction
    • ♦Definition
    • ♦Benefits
    • ♦Plan Development
• ►4. Lighting Agreements
  • ►1. Overview
    • ♦Introduction
    • ♦Authority
    • ♦When an Agreement is Required
    • ♦When an Agreement is Not Required
    • ♦Ordinance or Resolution
    • ♦Lighting Agreements
    • ♦Initiation of Agreement
    • ♦Traffic Engineering Agreement (TEA) Templates
    • ♦Modifying Standard Templates
    • ♦More Information
  • ►2. Lighting Agreements
    • ♦Background
    • ♦Written Agreement Not Required
    • ♦Default
    • ♦Lighting Systems Financed, Installed, and Operated by Other Agencies
    • ♦Quotation on Plan Title Sheet
    • ♦Safety Lighting Agreements
    • ♦Safety Lighting Incidental to Other Agreements
    • ♦Safety Lighting Incorporated Into a Continuous Lighting System
    • ♦Agreement No. 19: Safety Lighting (Blanket) (SM, CP)
    • ♦Agreement No. 20: Safety Lighting (Blanket) (City M&P)
    • ♦Agreements for Continuous Lighting Systems
    • ♦Agreement No. 21: Continuous Lighting SC (100)-CMO (100)(B)
    • ♦Agreement No. 22: Continuous Lighting SC (100)-CMO (100) (SL)
    • ♦Agreement No. 23: Continuous Lighting SC (50)-CMO (50) (SL)
    • ♦More Information
  • ►3. Lighting Agreement Processing and Execution
    • ♦Background
    • ♦Standard Templates
    • ♦Excess Cost
    • ♦Private Agreements
    • ♦Preparing an Agreement
    • ♦Contract Services Review
    • ♦Executing an Agreement
    • ♦Digital Signature
    • ♦Agreement Requirements for Cities
    • ♦Agreement Requirements for Counties
    • ♦Document Retention
    • ♦More Information
• ►5. Lighting Equipment
  • ►1. Overview
    • ♦Overview
    • ♦TxDOT Standard Specifications Book
    • ♦Departmental Material Specifications
    • ♦Material Producer List
    • ♦Standard Sheets
    • ♦Special Specifications and Special Provisions
  • ►2. Roadway Illumination Assemblies
    • ♦Item 610 - Roadway Illumination Assemblies
    • ♦Configurations
    • ♦DMS 11010
    • ♦RID Standards
    • ♦LED Luminaires
    • ♦HPS Luminaires
    • ♦Prequalification
    • ♦Light Loss Factor (LLF)
    • ♦Light Distribution Patterns
    • ♦Luminaire Poles
    • ♦RIP Standards
    • ♦Shoe Base Poles
    • ♦Transformer Base Poles
    • ♦Light Pole Foundations
    • ♦Poles on Traffic Barriers
    • ♦Poles on Bridges
    • ♦Poles on Retaining Walls
    • ♦Breakaway Connectors
    • ♦Underpass Lighting
    • ♦Item 616 - Performance Testing of Lighting Systems
  • ►3. High Mast Lighting Assemblies
    • ♦Introduction
    • ♦Configurations
    • ♦Item 613 - High Mast Illumination Poles
    • ♦HMIP Standards
    • ♦Item 614 - High Mast Illumination Assemblies
    • ♦DMS-11020 High Mast Light Fixtures
    • ♦SS 6156 LED High Mast Light Fixtures
    • ♦DMS-11021 High Mast Illumination Assembly Kits
    • ♦HMID Standards
    • ♦High Mast Illumination Pole Foundations
    • ♦HMIF Standards
  • ►4. Conduit, Conductors and Ground Boxes
    • ♦Item 618 - Conduit
    • ♦DMS-11030
    • ♦Item 620 - Electrical Conductors
    • ♦DMS-11040
    • ♦Item 621 - Tray Cable
    • ♦DMS 11050
    • ♦Item 622 - Duct Cable
    • ♦DMS 11060
    • ♦Item 624 - Ground Boxes
    • ♦DMS 11070
  • ►5. Electrical Services
    • ♦Item 628-Electrical Services
    • ♦Configurations
    • ♦Standard Sheets
    • ♦DMS 11080
    • ♦Type A Electrical Services
    • ♦Type C Electrical Services
    • ♦Type D Electrical Services
    • ♦Type T Electrical Services
    • ♦Pedestal Services
• ►6. Lighting Design and Layout
  • ►1. Overview
    • ♦Project Design Procedures
    • ♦Project Lead Time
    • ♦Joint Usage
    • ♦Luminaires on Traffic Signal Poles
    • ♦Railroad Crossings
    • ♦Underpasses
    • ♦Tunnels
    • ♦Sidewalks and Bikeways
    • ♦Aesthetic Lighting
    • ♦Other Types of Lighting
  • ►2. Illumination Levels
    • ♦Introduction
    • ♦Illuminance and Luminance
    • ♦Continuous Lighting
    • ♦Illuminance and Luminance Design Values for Continuous Lighting
    • ♦Definitions for Illuminance and Luminance Design Values Table
    • ♦Illumination for Intersections
    • ♦Safety Lighting
    • ♦Lighting of Isolated Intersections and Interchanges
    • ♦Pedestrian Areas
  • ►3. Plan Standards
    • ♦Introduction
    • ♦Scale of Plans
    • ♦Boring Logs
    • ♦Standard Plan Symbols
  • ►4. Conventional vs. High Mast Lighting
    • ♦Introduction
    • ♦Installation Costs
    • ♦Maintenance Costs
    • ♦Some Deciding Considerations
    • ♦High Mast Systems Recommended
    • ♦FAA Obstruction Evaluation
    • ♦High Mast Systems and Light Trespass
    • ♦High Mast Design and Layout
  • ►5. Glare and Sky Glow Issues
    • ♦Introduction
    • ♦Cutoff and BUG Rating
    • ♦Choice of Luminaires
    • ♦Luminaire Modification
  • ►6. Spacing of Light Poles
    • ♦Standard Spacing for Freeways and Complete Interchange Lighting
    • ♦Standard Spacing for Roadways Other than Freeways
    • ♦Merge and Diverge Lanes
    • ♦Lighting Near Overpasses
    • ♦Determining Mounting Height
  • ►7. Pole Placement Guidelines
    • ♦Introduction
    • ♦Clear Zone
    • ♦House Side vs. Median Mounting
    • ♦Two Types of Poles
    • ♦Breakaway Poles Preferred
    • ♦When Not To Use Breakaway Poles
    • ♦Protection of Non-Breakaway Poles
    • ♦Placement of Non-Breakaway Poles
    • ♦Falling Area for Breakaway Poles
    • ♦Use and Placement of Breakaway Poles
    • ♦House Side Lighting
    • ♦Median Lighting
    • ♦Median Lighting Design Examples
    • ♦Avoid Channelizing Islands
    • ♦Breakaway Pole Placement Examples
    • ♦Minimum Values
    • ♦Poles in Sidewalks
    • ♦Foundation Height
    • ♦Striking Height
    • ♦Breakaway Pole Frangibility
• ▼7. Electrical Systems
  • ►1. Overview
    • ♦Introduction
    • ♦National Electrical Code
    • ♦National Electrical Safety Code
    • ♦NEC, NESC, and Roadway Lighting on TxDOT ROW
    • ♦Electrical Details
  • ►2. Electrical Service
    • ♦Introduction
    • ♦Electrical Service Data
    • ♦Electrical Service ID
    • ♦Electrical Service Description
    • ♦Service Conduit Size
    • ♦Service Conductors
    • ♦Safety Switch
    • ♦Main Circuit Breaker
    • ♦Two-Pole Contactor
    • ♦Panelboard/Load Center
    • ♦Branch Circuit ID
    • ♦Branch Circuit Breakers
    • ♦Branch Circuit Amps
    • ♦KVA Load
    • ♦Separate Electrical Service for Signs
    • ♦Electrical Service Calculator
    • ♦Where Service Does Not Exist
    • ♦Coordination with Electric Utilities
  • ▼3. Circuit Design
    • ♦Introduction
    • ♦Voltage Drop
    • ♦Circuit Length Limits
    • ♦Conductors and Conduit Size
    • ♦Conduit Run Length
    • ♦Overcurrent Protection
    • ♦Grounding Conductor Size
    • ♦Copper Theft
  • ►4. Calculating Voltage Drop
    • ♦Introduction
    • ♦Maximum Allowable Voltage Drop
    • ♦Formula
    • ♦Current in the Run
    • ♦Conductor Resistance
    • ♦Length of Run
    • ♦Calculation Example
    • ♦Total Voltage Drop
    • ♦Split Branch Circuit
• ►8. Temporary Lighting
  • ►1. Design and Layout
    • ♦Purpose
    • ♦Difference Between Temporary and Work Zone Lighting
    • ♦Special Considerations
    • ♦Types of Temporary Lighting
    • ♦Illumination Levels
    • ♦Electrical System Integrity
    • ♦Placement of Light Poles
    • ♦Installation
    • ♦Plans and Specifications
  • ►2. Financing
    • ♦General
    • ♦Method of Payment
    • ♦Reusable Equipment
• ►9. Construction and Maintenance Guidelines
  • ►1. Overview
    • ♦Introduction
    • ♦Consistency
    • ♦Assistance
  • ►2. Breakaway Light Poles
    • ♦Frangibility Requirement
    • ♦Structural Requirement
    • ♦Replacement Guidelines
    • ♦New Installation Guidelines
    • ♦Relocated Poles
    • ♦Poles Placed by Maintenance Forces
    • ♦Guidelines Apply to Cities
    • ♦Identifying Transformer Bases
    • ♦Striking Height
    • ♦Anchor Bolts
  • ►3. Group Relamping
    • ♦Background
    • ♦Advantages
    • ♦Strategy
    • ♦Cleaning Luminaires
  • ►4. High Mast Lighting Inspection and Servicing
    • ♦Introduction
    • ♦Documentation (Inspection Form)
    • ♦Items to Inspect
    • ♦Replacing Fixtures
    • ♦Responsibility of Cities
    • ♦Assistance
  • ►5. Other Maintenance Considerations
    • ♦Duct Cable
    • ♦Grout
    • ♦Rehabilitation of Old Circuits
    • ♦Maintenance Level of Service
    • ♦Maintenance Responsibilities of Cities
    • ♦Problems
• ►10. Resources
  • ►1. Forms
    • ♦High Mast Lighting Pole Assembly Inspection Record
  • ►2. Texas Administrative Code
    • ♦Purpose
  • ►3. Texas Health and Safety Code
    • ♦Purpose
  • ►4. Electrical Code Policies
    • ♦Memorandums
  • ►5. Clear Zones
    • ♦Clear Zone Specifications
  • ►6. Glossary of Terms and Formulas
    • ♦Introduction
    • ♦AASHTO
    • ♦Alternating Current (AC)
    • ♦Ampere (A)
    • ♦Ballast
    • ♦Blanket Agreement
    • ♦Breakaway Support
    • ♦Candela or Candlepower (cd)
    • ♦Capacitance (C)
    • ♦Clear Zone
    • ♦Complete Interchange Lighting
    • ♦Conductor
    • ♦Continuous Lighting
    • ♦Conventional Lighting
    • ♦Cutoff
    • ♦Direct Current (DC)
    • ♦Electrical Details (ED)
    • ♦Electrical Service
    • ♦FHWA
    • ♦Floodlight
    • ♦Footcandle (FC)
    • ♦Frangible
    • ♦High Mast Illumination Details (HMID)
    • ♦High Mast Illumination Pole Foundations (HMIF)
    • ♦High Mast Illumination Poles (HMIP)
    • ♦Illuminating Engineering Society of North America (IESNA, also IES)
    • ♦High Mast Lighting
    • ♦Inductance (L)
    • ♦Kilowatt (KW)
    • ♦Kilovolt-amp (KVA)
    • ♦Lamp
    • ♦Light Source
    • ♦Lumen (lm)
    • ♦Luminaire
    • ♦Lux (lx)
    • ♦Mast Arm
    • ♦Mounting Height
    • ♦National Electric Safety Code (NESC)
    • ♦National Electrical Manufacturer's Association (NEMA)
    • ♦National Fire Protection Association (NFPA)
    • ♦NFPA 70: National Electric Code (NEC)
    • ♦NFPA 70E: Standard for Electrical Safety in the Workplace
    • ♦Ohm (O)
    • ♦Partial Interchange Lighting
    • ♦Pole
    • ♦Power (P)
    • ♦Power Factor (pf)
    • ♦PVC
    • ♦Reflector
    • ♦Refractor
    • ♦Regulated Output Ballast
    • ♦RMC
    • ♦Roadway Illumination Assembly
    • ♦Roadway Illumination Details (RID)
    • ♦Roadway Illumination Poles (RIP)
    • ♦Safety Lighting
    • ♦Starter or Starting Aid (also called igniter)
    • ♦Transformer
    • ♦Transformer Base
    • ♦Uniformity
    • ♦Volt (V or E)
    • ♦Voltage Drop
    • ♦Warrant

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Section 3: Circuit Design

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Introduction

Once the service type is determined, the circuits can be designed. This section covers the major considerations in the design of roadway lighting circuits. Designers should refer to the National Electrical Code (NEC) Handbook for additional information.

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Voltage Drop

The primary limitation on the length of circuits is the voltage drop. “Calculating Voltage Drop,” Section 4 of this chapter, explains how to calculate voltage drop.

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Circuit Length Limits

At 480 volts, a 4,000 foot circuit of twin-arm poles can be served without unduly large conductors. At 240 volts, the circuit is limited to about 2,000 feet. (Conductor size and voltage drop are discussed in "Circuit Design" and "Calculating Voltage Drop" of this chapter.).

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Conductors and Conduit Size

Another consideration is the number of conductors that can be installed in the various sizes of conduits. Annex C of the National Electrical Code shows the maximum number of conductors allowed in each conduit based on the capability of the wire to dissipate heat. However, with conduit runs of any substantial length, it is usually not practical to install the maximum number of conductors allowed in the conduit. A good rule of thumb is to limit the number of conductors to approximately one-half of the number shown in Annex C.

For underground lighting conduit, TxDOT's standard practice is to use 2 inch PVC. Although this is usually larger than required by the NEC for typical TxDOT lighting circuits, the larger size conduit is easier to clean and to pull conductors through. Since the largest cost of trenched conduit is the trench, 2-inch trenched conduit has a similar cost to smaller sizes of trenched conduit.

For underground lighting conductors, TxDOT's standard practice has previously been to use a minimum size of 8 AWG copper. However, it is now recommended to use the smallest size conductor that the NEC and voltage drop will allow, with a minimum size of 12 AWG. Using the minimum size conductor gives three advantages:

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• Lower cost of installation
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• Reduced consequences of copper theft. Smaller conductors reduce the scrap value of the copper and can help to reduce the incentive to steal it. If the conductors are stolen, the smaller conductors are less expensive to replace.
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• Increased safety due to the possibility of reduced arc flash. Smaller conductors have higher resistance, which can reduce arcing if they are accidentally shorted or grounded during maintenance.

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Conduit Run Length

As conduit run length and number of bends increases, the effort required to pull conductors also increases. Generally continuous conduit runs in excess of 700 feet are not recommended. Continuous conduit runs in excess 500 feet are not recommended when bends total 180 degrees. The NEC limits total conduit bends between pulling points to 360 degrees (no matter what the length of the run).

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Overcurrent Protection

The ampacity of conductors is shown in Table 310.15(B)(16) and accompanying notes of the National Electrical Code. This ampacity should be observed in sizing overload protection for the circuit.

Lighting is considered a continuous load. NEC 210.20 requires that for continuous loads, the rating of the overcurrent device shall be at least 125% of the actual lighting load. For example, if the actual lighting load is 18 amps, then the minimum breaker size would need to be at least 1.25 x 18 amps = 22.5 amps. Since that is not a standard size, the next higher breaker size of 30 amps would be used.

When sizing overcurrent protection, the device closest to the load should be the smallest size. Devices should increase in size toward the service disconnect. For example, a 10 amp fuse might be used in the pole base where the branch circuit breaker is 20 amps, and the main breaker is a 60 amp circuit breaker.

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Grounding Conductor Size

An equipment grounding conductor (EGC) should be installed in every conduit. The EGC may be sized according to NEC table 250.122, or it may be the same size as the largest current-carrying conductor in the conduit. For traffic signal installations, the minimum size of the EGC in every conduit is 8 AWG.

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Copper Theft

Theft of copper conductors from roadway electrical installations is an ongoing problem for TxDOT and many other public entities. Replacing stolen conductors can have a high cost in materials and manpower. Copper theft also leaves the installation inoperable, which decreases safety for drivers.

Although there is no universal solution to prevent all copper theft, three strategies can be used to help deter it. Law enforcement can reduce theft by taking thieves off the street and punishing those involved. Engineering methods can be used to make it more difficult for thieves to access the wiring. Reducing the value of conductors by using smaller sizes or alternate materials can help reduce the incentive for theft. Details on the three strategies follow.

Law Enforcement:

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• Texas Penal Code, Section 31.03, makes it a state jail felony to steal aluminum, bronze, copper, and brass up to a value of $20,000. This includes aluminum and copper conductors.
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• Texas Occupations Code, Chapter 1956, requires scrap and recycling yards to collect information on sellers of scrap wire, including driver's license or official ID, contractor license, thumbprints, vehicle information, and photos or videos of the person selling the scrap.

Engineering Methods:

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• Locking ground box covers, handhole covers, and T-base covers are available from several manufacturers.
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• Eliminate junction boxes during design to reduce the number of access points to conductors.
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• Ground boxes can be hidden a few inches underground. If this is done, then a method to locate them for maintenance is needed.
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• Tack weld bolts to metal junction box covers. The tack weld needs to be removed for maintenance inside the box.

Reduce Value of Conductors:

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• Use the smallest size conductor that will work according to the design and the NEC. The smaller wire is less expensive to replace and has less scrap value.
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• Aluminum conductors have lower scrap value than copper, but the NEC has restrictions on the use of aluminum conductors that makes it mostly unsuitable for underground wiring. NEC 250.120(B) does not allow bare aluminum equipment grounding conductors to come in contact with the earth or to be used in corrosive conditions. Also NEC 250.120(B) does not allow aluminum equipment grounding conductors to be terminated within 18 inches of the earth. For these reasons, aluminum conductors are usually not recommended for underground wiring of illumination.