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Mielke, Alexander [Verfasser:in]; Roubíc̆ek, Tomáš [Verfasser:in]

Rate-independent elastoplasticity at finite strains and its numerical approximation - [published Version]

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  • Medientyp: Sonstige Veröffentlichung; Bericht; E-Book
  • Titel: Rate-independent elastoplasticity at finite strains and its numerical approximation
  • Beteiligte: Mielke, Alexander [Verfasser:in]; Roubíc̆ek, Tomáš [Verfasser:in]
  • Erschienen: Berlin : Weierstraß-Institut für Angewandte Analysis und Stochastik, 2016
  • Ausgabe: published Version
  • Sprache: Englisch
  • DOI: https://doi.org/10.34657/3076
  • ISSN: 0946-8633; 2198-5855
  • Schlagwörter: 2nd-grade nonsimple materials ; Lavrentiev phenomenon ; quasistatic evolution ; finite-element approximation ; Gamma-convergence ; dissipation distance ; Plasticity ; hardening ; Signorini contact ; Ciarlet-Neˇcas condition ; energetic solutions ; polyconvexity
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  • Beschreibung: Gradient plasticity at large strains with kinematic hardening is analyzed as quasistatic rate-independent evolution. The energy functional with a frame-indifferent polyconvex energy density and the dissipation are approximated numerically by finite elements and implicit time discretization, such that a computationally implementable scheme is obtained. The non-selfpenetration as well as a possible frictionless unilateral contact is considered and approximated numerically by a suitable penalization method which keeps polyconvexity and simultaneously by-passes the Lavrentiev phenomenon. The main result concerns the convergence of the numerical scheme towards energetic solutions. In the case of incompressible plasticity and of nonsimple materials, where the energy depends on the second derivative of the deformation, we derive an explicit stability criterion for convergence relating the spatial discretization and the penalizations.
  • Zugangsstatus: Freier Zugang