Experimental and Numerical Investigations of Reinforced Soil Wall Subjected to Impact Loading

Reinforced soil wall has proved to have excellent impact resistance in engineering, but less attention has paid to their failure process and dynamic response subjected to impact loading. The authors performed model tests and numerical simulations of reinforced soil walls with and without cushion und...

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Bibliographic Details
Published inRock mechanics and rock engineering Vol. 54; no. 11; pp. 5651 - 5666
Main Authors Lu, Liang, Lin, Haoxin, Wang, Zongjian, Xiao, Liang, Ma, Shuwen, Arai, Katsuhiko
Format Journal Article
LanguageEnglish
Published Vienna Springer Vienna 01.11.2021
Springer Nature B.V
Subjects
Absorption
Civil Engineering
Cushions
Deformation
Dynamic response
Earth and Environmental Science
Earth Sciences
Energy
Failure analysis
Geophysics/Geodesy
Geosynthetics
Impact loads
Impact resistance
Laboratories
Mathematical models
Mechanical properties
Original Paper
Reinforced soils
Retaining walls
Sliding
Slumping
Soil
Soil compaction
Soil investigations
Soils
Strain gauges
Surface chemistry
Geosynthetic
Deformation
Stress distribution
Cushion
Impact loading
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Summary:Reinforced soil wall has proved to have excellent impact resistance in engineering, but less attention has paid to their failure process and dynamic response subjected to impact loading. The authors performed model tests and numerical simulations of reinforced soil walls with and without cushion under differential impact loading. The deformation, failure process and impact stress of three retaining walls were mainly analyzed, and the influence mechanism of geosynthetic and cushion on the impact performance of retaining wall were discussed qualitatively. The results showed that the impact deformation of reinforced soil wall with cushion was mainly concentrated on the cushion. The failure process of retaining wall could be divided into two stages: the soil around the impact point of retaining wall was compacted (stage I), a sliding surface formed in retaining wall gradually and retaining wall would failure (stage II). Geosynthetics benefited the sliding surface move back and cushion improved the impact resistance of retaining wall. Furthermore, stress absorption of geosynthetic and cushion was confirmed. The absorption rate of geosynthetic was related to the impact energy positively. The absorption rate of cushion was related to the impact energy positively and related to the thickness of cushion negatively. Engineers can consider the impact energy and the absorption rate of geosynthetic and cushion to design reinforced soil wall with cushion under impact loading.
ISSN:0723-2632
1434-453X
DOI:10.1007/s00603-021-02579-9