A strategy for scaling the hardening behavior in finite element modelling of geometrically exact beams

T. Gärtner*, S. J. van den Boom, J. Weerheijm, L. J. Sluys

*Corresponding author for this work

Research output: Contribution to journalArticleScientificpeer-review

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Abstract

A yield function in the stress resultant space of geometrically exact beams based on the elastoplastic cross-sectional warping problem has been proposed by Herrnböck et al. (Comput Mech, 67(3):723–742, 2021). This plasticity framework has been extended with a hardening tensor to model the kinematic hardening effects in Herrnböck et al. (Comput Mech, 71(1):1–24, 2022). While this framework provides scaling for the yield surface in ideal plasticity, scaling in hardening plasticity has not yet been explored. This paper focuses on the numeric modelling of hardening beams and beam assemblies at different geometric scales. Discretization effects from the introduction of plasticity into the geometrically exact beam model are demonstrated. Furthermore, the effects of scaling are explored, and a method to mitigate undesirable effects in order to achieve a size-agnostic formulation is proposed. Consistent geometric scaling is demonstrated for two alternative scaling approaches of the yield function.

Original languageEnglish
Number of pages12
JournalComputational Mechanics
DOIs
Publication statusPublished - 2024

Keywords

  • Elastoplasticity
  • Geometric scaling
  • Geometrically exact beams
  • Hardening plasticity

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