Seismic stability analysis of piled embankments: A multiphase approach

Quang Thai Son; Ghazi Hassen; Patrick de Buhan

doi:10.1002/nag.816

Seismic stability analysis of piled embankments: A multiphase approach

Quang Thai Son
, Ghazi Hassen
, Patrick de Buhan

Université Paris-Est

Research output: Contribution to journal › Article › peer-review

Abstract

The seismic stability analysis of an embankment lying over a soft foundation soil reinforced by a group of vertical piles is performed within the framework of the upper bound kinematic approach of yield design. The analysis is based on a previously developed 'multiphase' model of the reinforced ground, which explicitly accounts for the shear and bending resistances of the piles. Making use of appropriate failure mechanisms involving shear zones across which the reinforcements are continuously deforming, along with 'plastic hinge' surfaces, upper bound estimates to the critical seismic coefficient of the structure are derived. The results, which are confirmed by the simulations obtained from a finite element elastoplastic code, give clear evidence of the key role played by the bending strength capacities of the piles in ensuring the stability of the pile reinforced embankment.

Original language	English
Pages (from-to)	91-110
Number of pages	20
Journal	International Journal for Numerical and Analytical Methods in Geomechanics
Volume	34
Issue number	1
DOIs	https://doi.org/10.1002/nag.816
Publication status	Published - 1 Jan 2010
Externally published	Yes

Keywords

Multiphase model
Piled embankment
Reinforcement
Seismic analysis
Yield design

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10.1002/nag.816

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title = "Seismic stability analysis of piled embankments: A multiphase approach",

abstract = "The seismic stability analysis of an embankment lying over a soft foundation soil reinforced by a group of vertical piles is performed within the framework of the upper bound kinematic approach of yield design. The analysis is based on a previously developed 'multiphase' model of the reinforced ground, which explicitly accounts for the shear and bending resistances of the piles. Making use of appropriate failure mechanisms involving shear zones across which the reinforcements are continuously deforming, along with 'plastic hinge' surfaces, upper bound estimates to the critical seismic coefficient of the structure are derived. The results, which are confirmed by the simulations obtained from a finite element elastoplastic code, give clear evidence of the key role played by the bending strength capacities of the piles in ensuring the stability of the pile reinforced embankment.",

keywords = "Multiphase model, Piled embankment, Reinforcement, Seismic analysis, Yield design",

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T1 - Seismic stability analysis of piled embankments

T2 - A multiphase approach

AU - Son, Quang Thai

AU - Hassen, Ghazi

AU - de Buhan, Patrick

PY - 2010/1/1

Y1 - 2010/1/1

N2 - The seismic stability analysis of an embankment lying over a soft foundation soil reinforced by a group of vertical piles is performed within the framework of the upper bound kinematic approach of yield design. The analysis is based on a previously developed 'multiphase' model of the reinforced ground, which explicitly accounts for the shear and bending resistances of the piles. Making use of appropriate failure mechanisms involving shear zones across which the reinforcements are continuously deforming, along with 'plastic hinge' surfaces, upper bound estimates to the critical seismic coefficient of the structure are derived. The results, which are confirmed by the simulations obtained from a finite element elastoplastic code, give clear evidence of the key role played by the bending strength capacities of the piles in ensuring the stability of the pile reinforced embankment.

AB - The seismic stability analysis of an embankment lying over a soft foundation soil reinforced by a group of vertical piles is performed within the framework of the upper bound kinematic approach of yield design. The analysis is based on a previously developed 'multiphase' model of the reinforced ground, which explicitly accounts for the shear and bending resistances of the piles. Making use of appropriate failure mechanisms involving shear zones across which the reinforcements are continuously deforming, along with 'plastic hinge' surfaces, upper bound estimates to the critical seismic coefficient of the structure are derived. The results, which are confirmed by the simulations obtained from a finite element elastoplastic code, give clear evidence of the key role played by the bending strength capacities of the piles in ensuring the stability of the pile reinforced embankment.

KW - Multiphase model

KW - Piled embankment

KW - Reinforcement

KW - Seismic analysis

KW - Yield design

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DO - 10.1002/nag.816

M3 - Article

AN - SCOPUS:74549202627

SN - 0363-9061

VL - 34

SP - 91

EP - 110

JO - International Journal for Numerical and Analytical Methods in Geomechanics

JF - International Journal for Numerical and Analytical Methods in Geomechanics

IS - 1

ER -

Seismic stability analysis of piled embankments: A multiphase approach

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