Roadway Design Manual: Determining Length of Need of Barrier

♦Manual Notice 2022-2
►Preface
►1. Design General
►2. Basic Design Criteria
- ►1. Overview
  - ♦Introduction
- ►2. Functional Classifications
  - ♦Overview
- ►3. Traffic Characteristics
  - ♦Overview
  - ♦Traffic Volume
  - ♦Speed
  - ♦Terrain
  - ♦Safety
  - ♦Additional Considerations
- ►4. Sight Distance
  - ♦Overview
  - ♦Stopping Sight Distance
  - ♦Decision Sight Distance
  - ♦Passing Sight Distance
  - ♦Intersection Sight Distance
  - ♦Sight Distance at Under-Crossings
- ►5. Horizontal Alignment
  - ♦Overview
  - ♦General Considerations for Horizontal Alignment
  - ♦Curve Radius
  - ►Superelevation Rate
  - ♦Sight Distance on Horizontal Curves
- ►6. Vertical Alignment
  - ♦Overview
  - ♦Grades
  - ♦Vertical Curves
  - ♦Grade Change without Vertical Curves
  - ♦Vertical Alignment at Railroad Crossings
  - ♦Vertical Alignment at Intersections
  - ♦Vertical Clearance
  - ♦Combination of Vertical and Horizontal Alignment
- ►7. Cross-Sectional Elements
  - ♦Overview
  - ♦Pavement Cross Slope
  - ♦Median Design
  - ♦Lane Widths
  - ♦Shoulder Widths
  - ♦Pavement Taper Lengths
  - ♦Curb and Curb with Gutters
  - ♦Roadside Design
  - ♦Slopes and Ditches
  - ♦Lateral Offset to Obstructions
  - ♦Clear Zone
- ►8. Drainage Facility Placement
  - ♦Overview
  - ♦Introduction
  - ♦Design Treatment of Cross Drainage Culvert Ends
  - ♦Parallel Drainage Culverts
  - ♦Side Ditches
- ♦9. Roadways Intersecting Department Projects
►3. New Location and Reconstruction (4R) Design Criteria
- ►1. Overview
  - ♦Introduction
- ►2. Urban Streets
  - ♦Overview
  - ♦Level of Service
  - ♦Basic Design Features
  - ♦Medians
  - ♦Median Openings
  - ♦Clear Zones
  - ♦Borders
  - ♦Berms
  - ♦Grade Separations and Interchanges
  - ♦Right-of-Way Width
  - ♦Intersections
  - ♦Speed Change Lanes
  - ♦Drainage Horizontal Offsets
  - ►Bus Facilities
  - ♦Bus Streets
- ►3. Suburban Roadways
  - ♦Overview
  - ♦Basic Design Features
  - ♦Access Control
  - ♦Medians
  - ♦Median Openings
  - ♦Clear Zones
  - ♦Borders
  - ♦Grade Separations and Interchanges
  - ♦Right-of-Way Width
  - ♦Intersections
  - ♦Speed Change Lanes
  - ♦Parking
- ►4. Two-Lane Rural Highways
  - ♦Overview
  - ♦Basic Design Features
  - ♦Access Control
  - ♦Transitions to Four-Lane Divided Highways
  - ♦Passing Sight Distances
  - ♦Speed Change Lanes
  - ♦Grade Separations and Interchanges
  - ♦Intersections
- ►5. Multi-Lane Rural Highways
  - ♦Overview
  - ♦Basic Design Features
  - ♦Level of Service
  - ♦Basic Design Features
  - ♦Access Control
  - ♦Medians
  - ♦Turn Lanes
  - ♦Travel Lanes and Shoulders
  - ♦Intersections
  - ♦Transitions to Four-Lane Divided Highways
  - ♦Converting Existing Two-Lane Roadways to Four-Lane Divided Facilities
  - ♦Grade Separations and Interchanges
- ►6. Freeways
  - ♦Overview
  - ♦Basic Design Criteria
  - ♦Access Control
  - ♦General
  - ♦Mainlane Access
  - ♦Frontage Road Access
  - ♦Control of Access Methods
  - ♦Control of Access by Design
  - ♦Mainlanes
  - ♦Design Speed
  - ♦Level of Service
  - ♦Lane Width and Number
  - ♦Shoulders
  - ♦Medians
  - ♦Outer Separation
  - ♦Crossing Facilities
  - ♦Vertical and Clear Zones at Structures
  - ♦Frontage Roads
  - ♦Function and Uses
  - ♦Planning
  - ♦Design Speed on Frontage Roads
  - ♦Capacity and Level of Service
  - ♦Frontage Road Design Criteria
  - ♦Conversion of Frontage Roads from Two-Way to One-Way Operation
  - ♦Grade Separations and Interchanges
  - ♦Three-Leg Interchanges
  - ♦Four-Leg Interchanges
  - ♦Diamond Interchanges
  - ♦Cloverleaf Interchanges
  - ♦Directional Interchanges.
  - ♦Interchange Spacing
  - ♦Auxiliary Lanes
  - ♦Ramps and Direct Connectors
  - ♦General Information
  - ♦Design Speed
  - ♦Ramp Geometrics
  - ♦Gores
  - ♦Cross Section and Cross Slopes
  - ♦Sight Distance
  - ♦Ramp Terminal Design
  - ♦Exit Ramps to Frontage Roads
  - ♦Ramp Spacing
  - ♦Metered Ramps
  - ♦Collector-Distributor Roads
  - ♦Frontage Road Turnarounds and Intersection Approaches
- ►7. Freeway Corridor Enhancements
  - ♦Overview
  - ♦Freeways with High Occupancy Vehicle Treatments
  - ♦Light Rail Transit
  - ♦Peak Hour Lanes
  - ♦Tolled Express Lanes
- ►8. Texas Highway Freight Network (THFN)
►4. Non-Freeway Rehabilitation (3R) Design Criteria
- ►1. Purpose
  - ♦Overview
  - ♦Design Guidelines
- ►2. Design Characteristics
  - ♦Pavement Design
  - ♦Geometric Design
  - ♦Design Values
  - ♦Alignment
  - ♦Design Speed
  - ♦Side and Backslopes
  - ♦Lane Widths
- ►3. Designing for Safety
  - ♦Overview
  - ♦Safety Design
  - ♦Basic Safety Improvements
  - ♦Other Safety Improvements
- ►4. Frontage Roads
  - ♦Overview
- ►5. Bridges, Including Bridge-Classification Culverts
  - ♦Overview
- ►6. Super 2 Highways
  - ♦Overview
  - ♦Basic Design Criteria
- ►7. 3R Project Documentation
  - ♦Project-Specific Design Information
  - ♦Plan Set Requirements
►5. Non-Freeway Resurfacing or Restoration Projects (2R)
- ►1. Criteria
  - ♦Overview
  - ♦Definition
  - ♦Upgrading
  - ♦Crash Analysis
►6. Special Facilities
►7. Miscellaneous Design Elements
- ►1. Longitudinal Barriers and Roadside Safety Hardware Criteria
  - ♦Overview
  - ♦Concrete Barriers (Median and Roadside)
  - ♦Guardrail
  - ♦Attenuators (Crash Cushions)
  - ♦Roadside Safety Hardware Crash Criteria
- ►2. Fencing
  - ♦Overview
  - ♦Right-of-way
  - ♦Control of Access Fencing on Freeways
- ►3. Pedestrian Facilities
- ►4. Parking
  - ♦Overview
  - ♦Fringe Parking Lots
  - ♦Parking Along Highways and Arterial Streets
- ►5. Rumble Strips
- ►6. Emergency Crossovers
  - ♦Overview
  - ♦Location
  - ♦Construction
- ►7. Minimum Designs for Truck and Bus Turns
  - ♦Overview
  - ♦Application
  - ♦Channelization
  - ♦Alternatives to Simple Curvature
  - ♦Urban Intersections
  - ♦Rural Intersections
  - ♦Median U-Turn Movements
►8. Mobility Corridor (5 R) Design Criteria
- ►1. Overview
  - ♦Introduction
- ►2. Roadway Design Criteria
  - ♦Overview
  - ♦Lane Width and Number
  - ♦Shoulders
  - ♦Pavement Cross Slope
  - ♦Vertical Clearances at Structures
  - ♦Stopping Sight Distance
  - ♦Grades
  - ♦Horizontal Alignment
  - ♦Superelevation
  - ♦Superelevation Transition
  - ♦Vertical Curves
- ►3. Roadside Design Criteria
  - ♦Clear Zone
  - ♦Slopes
  - ♦Medians
- ►4. Ramps and Direct Connectors
  - ♦Overview
  - ♦Design Speed
  - ♦Lane and Shoulder Widths
  - ♦Acceleration and Deceleration Lengths
  - ♦Distance Between Successive Ramps
  - ♦Grades and Profiles
  - ♦Cross Section and Cross Slopes
▼A. Longitudinal Barriers
- ►1. Overview
  - ♦Introduction
- ►2. Barrier Need
  - ♦Overview
  - ♦Types of Barrier
  - ♦Applications
  - ♦Working Width
- ►3. Structural Considerations of Guard Fence
  - ♦Overview
  - ♦Post Spacing, Embedment, and Lateral Support
  - ♦Rail Element
  - ♦Blockouts
- ►4. Placement of Guard Fence
- ►5. End Treatment of Guard Fence
  - ♦Overview
- ▼6. Determining Length of Need of Barrier
  - ♦Overview
  - ♦Variables
  - ♦Design Equations
  - ♦Using Design Equations to Determine Length of Guard Fence
- ►7. Example Problems
  - ♦Example Problem 1
  - ♦Example Problem 2
  - ♦Example Problem 3
- ►8. Median Barrier
  - ♦Overview
  - ♦Application
  - ♦Placement
  - ♦Additional Cable Median Barrier Guidance
- ►9. Emergency Crossovers
  - ♦Overview
  - ♦Location
  - ♦Construction
►B. Treatment of Pavement Drop-offs in Work Zones
- ►1. Overview
  - ♦Scope
  - ♦Types of Treatment
  - ♦Factors Affecting Treatment Choice
  - ♦Edge Condition
  - ♦Guidelines for Treatment
►C. Driveway Design Guidelines
- ♦1. Overview
- ►2. Introduction
  - ♦General Guidelines
  - ♦Definitions
- ►3. Driveway Design Principles
  - ♦General Guidelines
  - ♦Geometrics for Two-Way Driveways
  - ♦Divided Driveways
- ►4. Profiles
- ►5. Driveway Angle
  - ♦Two-Way Driveways
  - ♦One-Way Driveways
- ►6. Bicycle and Pedestrian Considerations
  - ♦General Guidelines
- ♦7. Visibility
- ♦8. References
►D. Right-Turn Slip Lane Design Guidelines
- ♦1. Introduction
- ►2. New Construction
  - ♦Urban Design
  - ♦Suburban Design
  - ♦Rural Design
- ►3. Retrofitting Treatments
- ♦4. References
►E. Alternative Intersections and Interchanges
- ►1. Overview
  - ♦Introduction: Alternative Intersections and Interchanges
  - ♦Pedestrian Considerations for Alternative Intersections
- ►2. Roundabouts
  - ♦Overview
  - ♦Planning
  - ♦Geometric Design
  - ♦Entry Width
  - ♦Circulatory Roadway Width
  - ♦Entry Curve
  - ♦Exit Curve
  - ♦Roundabout Speeds
  - ♦Vertical Geometry
  - ♦Cross-Slope
  - ♦Splitter Islands
  - ♦Pedestrian Considerations
  - ♦Bicyclist Considerations
  - ♦Access Management
- ►3. Diverging Diamond Interchange (DDI)
  - ♦Overview
  - ♦Design Considerations
  - ♦Sight Distance
  - ♦Horizontal Alignment Alternatives
  - ♦Auxiliary Lanes
  - ♦Pedestrian and Bicyclist Considerations
  - ♦Access Management
- ►4. Median U-Turn Intersection (MUT)
  - ♦Overview
  - ♦Design Considerations
  - ♦Location Considerations
  - ♦Pedestrian and Bicyclist Considerations
  - ♦Access Management
- ►5. Restricted Crossing U-Turn Intersection (RCUT)
  - ♦Overview
  - ♦Design Considerations
  - ♦Intersection Angle
  - ♦Pedestrian and Bicyclist Considerations
  - ♦Access Management
- ►6. Displaced Left Turn Intersection (DLT)
  - ♦Overview
  - ♦Design Considerations
  - ♦Sight Distance
  - ♦Pedestrian and Bicyclist Considerations
  - ♦Access Management
- ♦7. References

Section 6: Determining Length of Need of Barrier

Overview

The shape of the obstacle, its location with respect to travel lanes, the volume of traffic and its corresponding clear zone width are the primary variables influencing length of barrier need. Barrier can be rigid such as a concrete barrier, or semi-rigid, such as metal beam guard fence.

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Variables

After all practical means to free the roadside of obstacles have been exhausted, certain areas may remain which constitute an obstacle to errant vehicles. These areas, as illustrated in Figure A-7, will be referred to as an “area of concern.”

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Figure A-7. Areas of Concern

Figure A-8 illustrates the variables of interest in the layout of approach barrier to shield an area of concern. The total length of need is equal to the sum of the following variables:

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Equation A-1.

Where:

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L_total = Length of guard fence needed, ft

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L_u = Guard fence Length Upstream of area of concern, ft

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L_p = Guard fence Length Parallel to area of concern, ft

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L_d = Guard fence Length Downstream from area of concern, ft

When discussing length of need as it pertains to metal beam guard fence, L_u is the length of guard fence needed to shield the area of concern for adjacent traffic. Upstream refers to the guard fence upstream of traffic adjacent to proposed guard fence. L_d is the length of guard fence needed to protect the opposing traffic. For roadways serving one-way traffic operations, L_d = 0. L_d is greater than zero for two-way operations when the area of concern lies within the clear zone of opposing (northbound in Figure A-8) traffic as measured from the centerline pavement markings.

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Figure A-8. Variables Involved in Barrier Layout.

In certain instances, judgment should be exercised to supplement design chart solutions and provide for additional safety. For example, high severity fixed objects (e.g., bridge columns) may justify minimum guard fence treatment where located outside the clear zone if geometric conditions (i.e., steep fill slope, outside of horizontal curvature, etc.) increase the likelihood of roadside encroachments. Also, bridge class culverts require protection inside and outside the clear zone. If a bridge class culvert is outside the clear zone, consider increasing the offset of the metal beam guard fence to decrease the length of need. Maintain a 4-ft 0-in minimum distance away from the obstacle and provide a maximum slope of 1V:10H or flatter for the placement of the metal beam guard fence. If the bridge class culvert is outside the clear zone, D_u equals the clear zone distance. If the bridge class culvert is inside the clear zone distance, D_u equals the distance to the outside edge of the bridge class culvert.

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Design Equations

To determine the needed length of guard fence or barrier required for a given obstacle, design equations have been formulated for low volume (ADT 750 or less) and higher volume (ADT more than 750) conditions. A clear zone width of 16-ft and length of roadside travel of 200-ft are incorporated in the low volume design equation (for use on roadways when the present ADT volume is 750 or less). Also, if the clear zone required is less than 16-ft and the present ADT is 750 or less, use Equation A-1 for calculating the guard fence length of need.

Anchor: #i1036763Table A-2: Equations for Upstream and Downstream Length of Need
ADT < 750	Anchor: #JKPYUPJE Equation A-2.
	Anchor: #MEHMSHHX Equation A-3.
ADT > 750	Anchor: #KENUMWFR Equation A-4.
	Anchor: #XOHFNKCR Equation A-5.

Where:

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L_u = Length of guard fence needed (upstream of area of concern), ft

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L_d = Length of guard fence needed (downstream of area of concern), ft

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D_u = Distance from edge of travel lane to far side of area of concern or to outside edge of clear zone, whichever is least, ft (for upstream direction of traffic)

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D_d = Distance from edge of travel lane to far side of area of concern or to outside edge of clear zone, whichever is least, ft (for opposing direction of traffic)

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G_u = Guard fence offset from edge of travel lane adjacent to proposed guard fence, ft

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G_d = Guard fence offset from edge of opposing direction of travel lane (centerline), ft

For low volume conditions, if the clear zone width of 16-ft is met or exceeded, L=0.

For higher volumes, a clear zone width of 30-ft and length of roadside travel of 250-ft are incorporated into the design equation (for use on roadways when the present ADT volume is more than 750 or the recommended clear zone is greater than 16-ft).

For high volume conditions, if the clear zone width (30-ft) is met or exceeded, L=0.

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Using Design Equations to Determine Length of Guard Fence

Before determining length of guard fence, the designer should assemble the following pertinent data:

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Present ADT volume;

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Clear zone (horizontal clearance);

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Traffic operations (one-way or two-way);

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Lateral and longitudinal dimension of the area of concern;

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Shoulder width;

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Offset distance of the area of concern from the edge of travel lane (including from the centerline markings for two-way traffic operations);

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Design slope conditions, (i.e. will slopes be 1V:10H or flatter);

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Placement location (alongside shoulder vs. near object, flared, etc.); and

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Presence of other nearby areas of concern which should be considered simultaneously.

Once this design data has been assembled, the equation for length of guard fence can be used.

Where the prescribed length of the guard fence cannot be installed at a bridge end due to an intervening access point such as an intersecting roadway or driveway, the length of guard fence may be interrupted or reduced. This change in length is acceptable only in locations where the Department must meet the obligation to provide access and this access cannot be reasonably relocated. Alternative treatments in these situations include installing an appropriate radius rail, terminating the guard fence prior to the access location with an appropriate end treatment and continuing the guard fence beyond the access location if necessary, or using an alternate bridge end treatment. The selected treatment should consider potential sight line obstructions, crash history at the site, cost, and maintenance associated with the selected treatment. Reduced guard fence length to accommodate access points will not require a design exception or a design waiver.

Section 7, Example Problems provides example problems and solutions using the design equations. The guard fence lengths produced by the equations should be rounded up to an even length of guard fence. In circumstances where site conditions permit, the rounded-up length of need should terminate at the end of guard fence; any additional length of need component available from an end attenuator should be considered an additional buffer.