A pseudo-static approach to the seismic bearing capacity of eccentrically loaded footing lying on rock obeying a generalized Hoek–Brown strength criterion

The ultimate seismic bearing capacity problem of strip foundations under eccentric loading is investigated within the framework of limit analysis theory. Referring to the kinematic approach formulated in the context of pseudo-static method, the analysis aims to assess the reduction in bearing capaci...

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Veröffentlicht in:	Arabian journal of geosciences 2023-02, Vol.16 (2), Article 117
Hauptverfasser:	Saada, Zied, Chihi, Oussama, Maghous, Samir, Garnier, Denis
Format:	Artikel
Sprache:	eng
Schlagworte:	Analysis Bearing capacity Criteria Earth and Environmental Science Earth science Earth Sciences Earthquake loads Eccentric loads Eccentricity Failure mechanisms Kinematics Limit analysis Nonlinear systems Nonlinearity Original Paper Reduction Seismic stability Series (mathematics) Stability analysis Upper bounds
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creator	Saada, Zied Chihi, Oussama Maghous, Samir Garnier, Denis
description	The ultimate seismic bearing capacity problem of strip foundations under eccentric loading is investigated within the framework of limit analysis theory. Referring to the kinematic approach formulated in the context of pseudo-static method, the analysis aims to assess the reduction in bearing capacity induced by the combined effects of load eccentricity and seismic loading. At the material level, the generalized Hoek–Brown failure criterion is adopted for modeling the nonlinearity of the strength properties. At that respect, derivation of closed-form expressions for the support functions associated by duality with such a failure condition is a fundamental component for the implementation of the kinematic approach. At the structure level, elaboration of two specific failure mechanisms allows deriving rigorous upper bound estimates for the ultimate bearing capacity. The approach is then applied to assess the effects of relevant geometry, strength, and loading parameters controlling the stability conditions. The accuracy of the analysis is evaluated by comparison with a series of lower and upper finite element solutions, thus emphasizing effectiveness of the approach to predict the reduction in ultimate bearing capacity associated with the particular loading conditions.
doi_str_mv	10.1007/s12517-022-11169-0
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subjects	Analysis Bearing capacity Criteria Earth and Environmental Science Earth science Earth Sciences Earthquake loads Eccentric loads Eccentricity Failure mechanisms Kinematics Limit analysis Nonlinear systems Nonlinearity Original Paper Reduction Seismic stability Series (mathematics) Stability analysis Upper bounds
title	A pseudo-static approach to the seismic bearing capacity of eccentrically loaded footing lying on rock obeying a generalized Hoek–Brown strength criterion
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