Design charts for yield acceleration and seismic displacement of retaining walls with surcharge through limit analysis

Design of retaining walls under seismic conditions is based on the calculation of seismic earth pressurebehind the wall. To calculate the seismic active earth pressure behind the vertical retaining wall, many researchers reportanalytical solutions using the pseudo-static approach for both cohesionless and cohesive soil backfill. Design charts havebeen presented for the calculation of seismic active earth pressure behind vertical retaining walls in the non-dimensionalform. For inclined retaining walls, the analytical solutions for the calculation of seismic active earth pressure as well as thedesign charts (in non-dimensional form) have been reported in few studies for c-ϕ soil backfill. One analytical solution forthe calculation of seismic active earth pressure behind inclined retaining walls by Shukla (2015) is used in the present studyto obtain the design charts in non-dimensional form. Different field parameters related with wall geometry, seismic loadings,tension cracks, soil backfill properties, surcharge and wall friction are used in the present analysis. The present study hasquantified the effect of negative and positive wall inclination as well as the effect of soil cohesion (c), angle of shearingresistance (ϕ), surcharge loading (q) and the horizontal and vertical seismic coefficient (kh and kv) on seismic active earthpressure with the help of design charts for c-ϕ soil backfill. The design charts presented here in non-dimensional form aresimple to use and can be implemented by field engineers for design of inclined retaining walls under seismic conditions. Theactive earth pressure coefficients for cohesionless soil backfill achieved from the present study are validated with studiesreported in the literature.

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Seismic internal stability assessment of geosynthetic reinforced earth retaining wall in cohesive soil using limit analysis

MATEC Web of Conferences ◽

10.1051/matecconf/201928102008 ◽

2019 ◽

Vol 281 ◽

pp. 02008

Author(s):

Hicham Alhajj Chehade ◽

Daniel Dias ◽

Marwan Sadek ◽

Fadi Hage Chehade ◽

Orianne Jenck

Keyword(s):

Limit Analysis ◽

Limit Equilibrium ◽

Retaining Wall ◽

Cohesive Soil ◽

Retaining Walls ◽

Reinforced Soil ◽

Seismic Stability ◽

Collapse Mechanism ◽

Kinematic Theorem ◽

Soil Retaining Walls

Assessment of internal seismic stability of geosynthetic reinforced cohesive soil retaining walls with likelihood for developing cracks in the failure mechanism is typically done with the limit equilibrium method. However, in this paper, the kinematic theorem of limit analysis combined with the discretization method are used to implement the crack formation in the collapse mechanism in the internal seismic assessment of geosynthetic reinforced soil retaining walls within the framework of the pseudo-static approach. The presence of the crack leads to an increase of the required reinforcement strength that prevent the failure of the structure.

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Effects of subsoil and backfill conditions on seismic displacement ofgravity type retaining walls

Cyclic Behaviour of Soils and Liquefaction Phenomena ◽

10.1201/9781439833452.ch78 ◽

2004 ◽

pp. 665-671 ◽

Cited By ~ 1

Author(s):

J Koseki ◽

N Kato ◽

K Watanabe ◽

M Tateyama

Keyword(s):

Retaining Walls ◽

Seismic Displacement

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Upper-Bound Multi-Rigid-Block Solutions for Seismic Performance of Slopes with a Weak Thin Layer

Mathematical Problems in Engineering ◽

10.1155/2017/1985458 ◽

2017 ◽

Vol 2017 ◽

pp. 1-11

Author(s):

Gang Zheng ◽

Xinyu Yang ◽

Haizuo Zhou ◽

Da Ha ◽

Tianqi Zhang

Keyword(s):

Thin Layer ◽

Failure Mechanism ◽

Seismic Performance ◽

Upper Bound ◽

Limit Analysis ◽

Slope Angle ◽

Rigid Block ◽

Acceleration Coefficient ◽

Critical Yield ◽

Yield Acceleration

The presence of a weak layer has an adverse influence on the seismic performance of slopes. The upper-bound solution serves as a rigorous method in the stability analysis of geotechnical problems. In this study, a multi-rigid-block solution based on the category of the upper-bound theorem of limit analysis is presented to examine the seismic performance of nonhomogeneous slopes with a weak thin layer. Comparison of the static factors of safety is conducted with various solutions (i.e., limit analysis with a different failure mechanism, limit equilibrium solution, and numerical method), and the results exhibit reasonable consistency. An analytical solution in estimating the critical yield acceleration coefficient is derived, and the influence of slope angle, slope height, and soil strength on the critical yield acceleration coefficient and failure mechanism is analyzed. Subsequently, Newmark’s analytical procedure is employed to evaluate cumulative displacement with various real earthquake acceleration records as input motion. Results show that the strength and geometric parameters have a remarkable influence on the critical yield acceleration coefficient, and the cumulative displacement increases with the increasing slope angle.

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