Mechanically stabilized earth

Mechanically stabilized earth (MSE or reinforced soil) is soil constructed with artificial reinforcing. It can be used for retaining walls, bridge abutments, seawalls, and dikes.^[1]^[2] Although the basic principles of MSE have been used throughout history, MSE was developed in its current form in the 1960s. The reinforcing elements used can vary but include steel and geosynthetics.

MSE is the term usually used in the US to distinguish it from the trade name "Reinforced Earth". Elsewhere "reinforced soil" is the generally accepted term.

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Description

MSE walls stabilize unstable slopes and retain the soil on steep slopes and under crest loads. The wall face is often of precast, segmental blocks, panels or geocells that can tolerate some differential movement. The walls are infilled with granular soil, with or without reinforcement, while retaining the backfill soil. Reinforced walls utilize horizontal layers typically of geogrids. The reinforced soil mass, along with the facing, forms the wall. In many types of MSE’s, each vertical fascia row is inset, thereby providing individual cells that can be infilled with topsoil and planted with vegetation to create a green wall.

The main advantages of MSE walls compared to conventional reinforced concrete walls are their ease of installation and quick construction. They do not require formwork or curing and each layer is structurally sound as it is laid, reducing the need for support, scaffolding or cranes. They also do not require additional work on the facing.

In addition to the flexibility of MSE walls in design and construction, seismic testing conducted on a large scale shaking table laboratory at the Japan National Institute of Agricultural Engineering (Tsukuba City), showed that modular block reinforced walls,^[3] and even more so geocell retention walls,^[4] retain sufficient flexibility to withstand large deformations without loss of structural integrity, and have high seismic load resistance. Highway overpasses along interstates often employ the INTER-LOK System.

History

Using straw, sticks, and branches to reinforce adobe bricks and mud dwellings has happened since the earliest part of human history, Parts of the Great Wall of China are formed as reinforced soil as are the ziggurats of the Middle East.

In the 1960s French engineer Henri Vidal invented the modern form of MSE, termed Terre Armee (reinforced earth) using steel strip reinforcements. The first geosynthetic-reinforced soil walls were built in France in 1970 and 1971.^[5] Geosynthetic-reinforced walls have been in use in the United States since 1974. Bell and Steward (1977) describe some of these early applications, which were primarily geotextile wrapped-face walls supporting logging roads in the northwestern United States.^[6]

Since the 1980s the development of reinforced soil has been dramatic using a range of construction forms and reinforcements including metallic and polymeric anchors, strips and grids. The first modern forms of reinforced soil were constructed in Europe in the late 1960s. The first MSE wall in the United States was built in 1971 on State Route 39 near Los Angeles.

Reinforcement

Reinforcement placed in horizontal layers throughout the height of the wall provides the tensile strength to hold the soil together. The reinforcement materials of MSE can vary. Originally, long steel strips 50 to 120 mm (2 to 5 in) wide were used as reinforcement. These strips are sometimes ripped, although not always, to provide added friction. There are also prefabricated pile sleeve options to reduce negative skin friction on piles embedded behind MSE bridge abutments.^[7] Sometimes steel grids or meshes are also used as reinforcement. Several types of geosynthetics can be used including geogrids and geotextiles. The reinforcing geosynthetics can be made of high-density polyethylene, polyester, and polypropylene. These materials may be ribbed and are available in various sizes and strengths.^[8]

For erosion control and load support the upper layer can be reinforced by geocell materials.^[9]

References

^ "Mechanically Stabilized Earth Structures". Archived from the original on December 16, 2005. Retrieved 2007-01-27.
^ "Mechanically Stabilized Earth Wall Inspector's Handbook" (PDF). Florida Department of Transportation. Retrieved 2007-01-27.
^ Ling, Hoe I.; Mohri, Yoshiyuki; Leshchinsky, Dov; Burke, Christopher; Matsushima, Kenichi; Liu, Huabei (2005). "Large-Scale Shaking Table Tests on Modular-Block Reinforced Soil Retaining Walls" (PDF). Journal of Geotechnical and Geoenvironmental Engineering. 131 (4): 465–476. doi:10.1061/(ASCE)1090-0241(2005)131:4(465). ISSN 1090-0241.
^ Leshchinsky, D. (2009). "Research and Innovation: Seismic Performance of Various Geocell Earth-retention Systems" (PDF). Geosysnthetics. 27 (4): 46–52. ISSN 0882-4983.
^ Allen, Tony & Bathurst, Richard & Berg, R.. (2002). Global Level of Safety and Performance of Geosynthetic Walls: An Historical Perspective. Geosynthetics International. 9. 395-450. 10.1680/gein.9.0224.
^ Bathurst, Richard. (2014). Challenges and recent progress in the analysis, design and modelling of geosynthetic reinforced soil walls. 10th International Conference on Geosynthetics, ICG 2014.
^ "Yellow Jacket Brochure", Foundation Technologies, Inc., retrieved 2017-04-28
^ "Mechanically Stabilized Earth Walls And Reinforced Soil Slopes: Design & Construction Guidelines" (PDF). FHWA. March 2001. Retrieved 2007-08-27.
^ Jones, Colin J F P (2013). Earth Reinforcement and Soil Structures. Elsevier. p. 379. ISBN 978-1-4831-0446-1.

External links

Sand Castle Holds Up A Car! - Mechanically Stabilized Earth Practical Engineering

Geotechnical engineering

Offshore geotechnical engineering

Investigation
and
instrumentation

Field (in situ)

Core drill

Cone penetration test

Geo-electrical sounding

Permeability test

Load test
- Static
- Dynamic
- Statnamic

Pore pressure measurement
- Piezometer
- Well

Ram sounding

Rock control drilling

Rotary-pressure sounding

Rotary weight sounding

Sample series

Screw plate test

Deformation monitoring
- Inclinometer
- Settlement recordings

Shear vane test

Simple sounding

Standard penetration test

Total sounding

Trial pit

Visible bedrock

Nuclear densometer test

Exploration geophysics

Crosshole sonic logging

Pile integrity test

Wave equation analysis

Laboratory
testing

Soil classification

Atterberg limits

California bearing ratio

Direct shear test

Hydrometer

Proctor compaction test

Hydraulic conductivity tests

Water content tests

Soil

Types	Clay Silt Sand Gravel Peat Loam Loess
Properties	Hydraulic conductivity Water content Void ratio Bulk density Thixotropy Reynolds' dilatancy Angle of repose Friction angle Cohesion Porosity Permeability Specific storage Shear strength Sensitivity

Structures
(Interaction)

Natural features	Topography Vegetation Terrain Topsoil Water table Bedrock Subgrade Subsoil
Earthworks	Shoring structures Retaining walls Gabion Ground freezing Mechanically stabilized earth Pressure grouting Slurry wall Soil nailing Tieback Land development Landfill Excavation Trench Embankment Cut Causeway Terracing Cut-and-cover Cut and fill Fill dirt Grading Land reclamation Track bed Erosion control Earth structure Expanded clay aggregate Crushed stone Geosynthetics Geotextile Geomembrane Geosynthetic clay liner Cellular confinement Infiltration
Foundations	Shallow Deep

Mechanics

Forces	Effective stress Pore water pressure Lateral earth pressure Overburden pressure Preconsolidation pressure
Phenomena/ problems	Permafrost Frost heaving Consolidation Compaction Earthquake Response spectrum Seismic hazard Shear wave Landslide analysis Stability analysis Mitigation Classification Sliding criterion Slab stabilisation Bearing capacity * Stress distribution in soil