Table Of Contents

Best Practices for Segmental Retaining Wall Design
The intent of this document is to communicate the best practices for design of Segmental Retaining Walls (SRW) as determined by Allan Block Corporation based on 30 plus years of research, design and field experience.
Navigate by using the arrows at the top, or jump directly to specific sections with the Table of Contents
   
Part 2 - Best Practice Considerations

Chapter 1.0 Design Guidelines and Pre-Construction Considerations
  • 1.1 Meeting with Owner
  • 1.2 Determining when Engineering is Required
  • 1.3 Existing and Proposed Utilities
  • 1.4 Wall Layout, height and geometry
  • 1.5 Geotechnical Report Considerations
  • 1.6 Understanding sites soils
  • 1.7 Site Visit
  • 1.8 Temporary Load Considerations
  • 1.9 Scope of Responsibility and Design Methodologies
  • 1.10 Minimum Design Safety Factors
  • 1.11 Coherent Gravity Mass and Connection Strength Considerations
  • 1.12 Contractor Requirements
  • 1.13 Manufactured Product Specifications
  • 1.14 Freeze Thaw Durability
  • 1.15 Pre-Construction Meeting
  • 1.16 Visiting the Site During Construction
  • 1.17 Construction Drawings
  • 1.18 For the Bidding Process
  • 1.19 Quality Control, Quality Assurance
   

Chapter 2.0 Typical Wall Construction
  • 2.1 Inspection of Materials
  • 2.2 Allowable Foundation Soils
  • 2.3 Allowable Infill Soils
  • 2.4 Wall Rock Guidelines
  • 2.5 Soil Parameter Verification
  • 2.6 Typical Wall Embedment
  • 2.7 Base Trench Requirements
  • 2.8 Base Trench Considerations
  • 2.9 Minimum Grid Lengths
  • 2.10 Initial Grid Location
  • 2.11 Maximum Grid Spacing
  • 2.12 Minimum Wall Facing Depth
  • 2.13 Capping the Wall
   

Chapter 3.0 Water Management - Typical
  • 3.1 Identifying Potential Water Sources
  • 3.2 Blanket and Chimney Drains
  • 3.3 Venting of Drain Pipes
  • 3.4 Above Grade Water Management
   

Chapter 4.0 Water Management - Alternate Drain
  • 4.1 Alternate Drain Locations
  • 4.2 Heel Drain Recommendations
   

Chapter 5.0 Water Application
  • 5.1 Below Grade Water Management
  • 5.2 Water Application Construction
   

Chapter 6.0 Soil and Compaction
  • 6.1 Understanding sites soils
  • 6.2 Allowable Foundation Soils
  • 6.3 Allowable Infill Soils
  • 6.4 Wall Rock Guidelines
  • 6.5 Soil Parameter Verification
  • 6.6 Inspection and Testing Recommendations
  • 6.7 Compaction Requirements at the Face of Wall
  • 6.8 Maximum Compaction Lift Spacing
  • 6.9 Compaction Requirements for Backfill Soil
  • 6.10 Testing Location and Frequencies
  • 6.11 Water Management During Construction
  • 6.12 Wall Step Ups in Base Course
  • 6.13 Stair Considerations
   

Chapter 7.0 Geogrid Reinforcement Requirements, Corner and Radius Design Practices
  • 7.1 Geogrid Reinforcement Requirements and Certification
  • 7.2 Proper Grid Orientation
  • 7.3 Wall Rock Design for Corners and Curved Walls
   

Chapter 8.0 Tall Walls Considerations
  • 8.1 Tall Wall Definition
  • 8.2 Variable Rock Thickness at Face
  • 8.3 Compaction and Soil Considerations
  • 8.4 Increased Forces in Lower Portion of Walls
  • 8.5 Global Stability of Tall Walls
  • 8.6 Internal Compound Stability Calculations
  • 8.7 Minimum Wall Facing Depth
   

Chapter 9.0 Global Stability - General
  • 9.1 Wall Embedment with Toe Slope
  • 9.2 When to Analyze for Global Stability
  • 9.3 Increasing Global Stability Options
  • 9.4 Effect of Groundwater on Global Stability
   

Chapter 10.0 Global Stability - Terraced
  • 10.1 Terraced Wall Considerations
  • 10.2 Upper Wall Influence - Surcharge
  • 10.3 Height and Grading
  • 10.4 Grid Considerations
  • 10.5 Compaction and Testing
  • 10.6 Toe and Heel Drain
  • 10.7 Global Stability
  • 10.8 Tall Wall Terraces
   

Chapter 11.0 Seismic Considerations
  • 11.1 Recommendations Associated with Seismic Loading
  • 11.2 Slope Above Seismically Loaded Walls
  • 11.3 Mononobe-Okabe Slope Above Limitations
  • 11.4 Alternate Design Approach – Trial Wedge Method
   

Chapter 12.0 Above Wall Considerations
  • 12.1 Minimum Grid Lengths at the Top of the Wall
  • 12.2 Fences and Railings
  • 12.3 Slopes Above the Wall
  • 12.4 Stability of Slopes Above
  • 12.5 Compaction Requirements for Slopes Above
  • 12.6 Reinforcing Slopes Above Walls
  • 12.7 Plantings
   

Allan Block Resources
Allan Block Spec Book
AB Engineering Manual
AB Commercial Manual
Seismic Testing Book
   
Search
 

Chapter 4: Water Managment - Alternate Drain

Click on the topics below to view more information on the best practices for Allan Block segmental retaining wall design for residental and commercial applications.



Allan Block Best Practices Alternate Drainage Detail for Reinforced Retaining Walls

Cad Details
Download (.dwg)
Typical Wall Detail



4.1   Location, type, and venting of drain pipes.

  1. When the drain pipe must be raised to accommodate outlets through the wall face.
    1. Low permeable granular soils should be used to create a shelf inside the mass, level to the height of the finished grade outside the wall to prevent water from ponding below grade. See Allan Block Design Detail – Alternate Drain, in the Allan Block Spec Book.
  2. Drain pipes existing to daylight through the wall should be installed with rodent screen to prevent nesting within the pipe. Cut adjoining block to allow for installation of a manufactured drain cover. Alternatively, Wall Drain Pro could be used without the requirement of cutting block. See more information here on Wall Drain Pro.
Retaining Wall Alternate Drain location detail

Figure 4-1: Alternate Drain


4.2   A heel drain should be specified for sites whenever grid is used or where migrating water from behind the mass is possible.

  1. The purpose of the heel drain is to pick up any water that migrates from behind the retaining wall structure at the cut, and route the water away from the reinforced mass during construction and for incidental water for the life of the structure.
  2. The piping used at the back of the reinforced mass shall have a 1% minimum gradient over the length, but it is not critical for it to be positioned at the very bottom of the cut
  3. The heel drain should be vented at 100 ft (30 m) intervals along the entire length of the wall and should not be tied into the toe drain system.
  4. The pipe may be a rigid pipe with holes at the bottom or a corrugated perforated flexible pipe.
  5. For infill soils with a high percentage of sand and/or gravel the heel drain pipe does not need to be surrounded by wall rock. When working with soils containing fine grained cohesive soils having a PI of greater than 6 and LL of 30 or greater, 1 ft³ (.03 m³) of wall rock is required around the pipe for each 1 ft (30 cm) of pipe length.

Typical Drain for a retaining wall application

Figure 4-2: Typical Drain with Heel Drain