Lower bound limit analysis with adaptive remeshing

Lyamin, Andrei Vadimovich; Sloan, Scott William; Krabbenhoft, Kristian; Hjiaj, Mohammed

Title: Lower bound limit analysis with adaptive remeshing
Creator: Lyamin, Andrei Vadimovich; Sloan, Scott William; Krabbenhoft, Kristian; Hjiaj, Mohammed
Relation: International Journal for Numerical Methods in Engineering Vol. 63, no. 14, p. 1961-1974
Publisher: John Wiley & Sons
Resource Type: journal article
Date: 2005
Description: The objective of this work is to present an adaptive remeshing procedure for lower bound limit analysis with application to soil mechanics. Unlike conventional finite element meshes, a lower bound grid incorporates statically admissible stress discontinuities between adjacent elements. These discontinuities pen-nit large stress jumps over an infinitesimal distance and reduce the number of elements needed to predict the collapse load accurately. In general, the role of the discontinuities is crucial as their arrangement and distribution has a dramatic influence on the accuracy of the lower bound solution (Limit Analysis and Soil Plasticity, 1975). To ensure that the discontinuities are positioned in an optimal manner requires an error estimator and mesh adaptation strategy which accounts for the presence of stress singularities in the computed stress field. Recently, Borges et al. presented an anisotropic mesh adaptation strategy for a mixed limit analysis formulation which used a directional error estimator. In the present work, this strategy has been tailored to suit a discontinuous lower bound formulation which employs the stresses and body forces as primary unknowns. The adapted mesh has a maximum density of discontinuities in the direction of the maximum rate of change in the stress field. For problems involving strong stress singularities in the boundary conditions (e.g. a strip footing), the automatic generation of discontinuity fans, centred on the singular points, has been implemented. The efficiency of the proposed technique is demonstrated by analysis of two classical soil mechanics problems; namely the bearing capacity of a rigid strip footing and the collapse of a vertical cut.
Subject: lower bound; limit analysis; finite elements; error estimation; adaptivity; crack problems; refinement
Identifier: uon:353
Identifier: http://hdl.handle.net/1959.13/25334
Identifier: ISSN:1097-0207
Language: eng
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