Stress update algorithm for elastoplastic models with nonconvex yield surfaces

Pedroso, Dorival M.; Sheng, Daichao; Sloan, Scott W.

Title: Stress update algorithm for elastoplastic models with nonconvex yield surfaces
Creator: Pedroso, Dorival M.; Sheng, Daichao; Sloan, Scott W.
Relation: International Journal for Numerical Methods in Engineering Vol. 76, Issue 13, p. 2029-2062
Publisher Link: http://dx.doi.org/10.1002/nme.2407
Publisher: John Wiley & Sons
Resource Type: journal article
Date: 2008
Description: A stress update algorithm for elastoplastic models with nonconvex yield surfaces is presented. An explicit algorithm based on the Runge–Kutta embedded method of second-order accuracy is developed. The crossing of the yield surface is properly taken into account by means of a robust intersection-finding algorithm. This algorithm is based on a simple multiple-root-finding technique, which requires the yield function, evaluated along a given secant stress path, to be continuously differentiable to the second order. The accuracy of the intersection-finding algorithm is illustrated through examples using simple yield functions similar to the ones adopted in models for unsaturated soils and the modified Cam clay model yield surface with a nonconvex Argyris et al. failure criterion. Isoerror surfaces and finite element simulations are used to investigate the accuracy and efficiency of the stress update algorithm. It is observed that although the algorithm for nonconvex surfaces is slower than its equivalent for convex surfaces, the accuracy can be controlled locally by means of specified tolerances.
Subject: stress integration; nonconvex yield surface; unsaturated soils; Runge–Kutta method; differential algebraic system; explicit schemes; multiple roots
Identifier: http://hdl.handle.net/1959.13/43519
Identifier: uon:5619
Identifier: ISSN:0029-5981
Language: eng
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