Roadway Design Manual: Example Problems

♦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 7: Example Problems

Example Problem 1

Given: A rural two-lane collector highway containing 6-ft wide shoulders and a current ADT of 500 is illustrated in Figure A-9. The area of concern is a 16-ft design clear zone that includes 1V:2H side slopes on a 10-ft high embankment section that is 125-ft in length alongside the highway.

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Figure A-9. Example 1 Problem Layout Rural Low Volume.

Solution: From the information above and referring to Figure A-1 it is determined that a “rail is needed.” As shown in Equation A-1, the length of need is L_total = L_u+L_p+L_d. From the given information, L_p = 125-ft. Because the ADT is less than 750, Equations A-2 and A-3 are used to solve for L_u and L_d, respectively (if necessary).

For the upstream direction, the area of concern is the full (16-ft) clear zone width and the guard fence offset (G_u) is 6-ft. Substituting in Equation A-2.

A placement of guard fence alongside the 6-ft wide shoulder results in L_u = 125-ft.

Referring to Figure A-9, the length of guard fence needed in the downstream is zero because the offset distance from the edge of the travel lane (centerline marking) to the area of concern is greater than the design clear zone (17-ft greater than 16-ft). Therefore, L_d is zero.

The design placement is shown in Figure A-10 including 125-ft of guard fence adjacent to the obstacle plus 125-ft shielding traffic adjacent to proposed guard fence upstream of the obstacle. These lengths of need do not include end treatments.

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Figure A-10. Example 1 Problem Solution Guard Fence Layout

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Example Problem 2

Given: A rural two-lane arterial highway containing a shoulder width of 8-ft and a current ADT of 3500 is illustrated in Figure A-11. The areas of concern are bridge bents located 5-ft from the edge of shoulder. The side slopes are 1V:6H.

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Figure A-11. Example 2 Problem Layout Rural High Volume.

Solution: Referring to Table A-1: General Applications of Conditions for Roadside Barriers bridge piers within the clear zone (30-ft in this case) indicates guard fence placement for the north side of the roadway displayed in Figure A-11. As shown in Equation A-1 the length of need is L_total = L_u+L_p+L_d. Therefore, L_p is 34-ft from the given (see Figure A-11) information. Because the ADT is greater than 750, Equations A-4 and A-5 are used to find L_u and L_d (if necessary), respectively:

Substituting in the equation, the upstream length (L_u) is 116.5-ft if placement is at the shoulder edge.

The downstream (westbound traffic) length of guard fence is also determined by substituting into Equation A-5:

L_d is 65-ft as shown above, based on the shoulder edge placement. For westbound traffic, the centerline is the edge of the travel lane and thus guard fence offset (G) is 20-ft (12-ft lane plus 8-ft shoulder) from the edge of the travel lane.

Total length of guard fence, L_u+L_p+L_d, thus is 116.5-ft + 34-ft + 65-ft or 215.5-ft; or, rounded to an even length of guard fence, 225-ft.

The solution for the south side of the roadway yields the same results; hence placement should be as shown in Figure A-12.

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Figure A-12. Example 2 Problem Solution Guard Fence Layout.

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Example Problem 3

Given: A divided (76-ft median) highway with 4-ft left and 10-ft right shoulder widths is illustrated in Figure A-13. The median slopes are 1V:10H, and the outside side slopes are 1V:6H. The cross-sectional design allows for the addition of a future lane on the median side of the present lanes. The areas of concern are overhead sign bridge supports offset 25-ft left and 18-ft right from edge of the travel lanes as shown below. The ADT is 10,000.

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Figure A-13. Example 3 Problem Layout Divided Highway.

Solution: Crash cushions in lieu of guard fence should be considered, particularly for facilities with higher than 10,000 ADT. For this example problem assume crash cushions are not cost effective.

Because the median is sloped at 1V:10H, as shown in Figure A-13, guard fence may be placed thereon (see Figure A-5). Therefore, place the guard fence such that the back of the posts are 5-ft in front of the median overhead sign bridge support to allow for deflection, i.e., 20-ft from the edge of the travel lanes (including the 1.5-ft from the back of the post to the face of the rail).

Referring to Equation A-1, L_total = L_u+L_p+L_d. For one-way traffic operations, L_d=0; furthermore, for the overhead sign bridge support L_p=0. Equation A-4 is used to find L_u because ADT is greater than 750:

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Equation A-6.

For the median side, L_u = 65-ft (rounded to 75-ft to conform to even lengths of guard fence) based on parallel placement for the full length of need, and placement on the 1V:10H slope 5-ft in front of the fixed object. In contrast, parallel placement at the shoulder edge would have required over 200-ft of guard fence.

For the right side of traffic, guard fence must be placed at the shoulder edge (Reference Figure A-5). Substituting in Equation A-2 to determine L_u:

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Equation A-7.

Using parallel placement for the entire length, L_u = 111-ft (which should be rounded to 125-ft to conform to even lengths of guard fence).

Using parallel placement for the entire length of guard fence for both the median and left side, placement is as shown in Figure A-14.

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Figure A-14. Example 3 Problem Solution Guard Fence Layout.