On Lagrangian mechanics and the material point method for large deformation elasto-plasticity [dataset]

  • William M. Coombs (Creator)
  • Charles E. Augarde (Creator)
  • Andrew Brennan (Creator)
  • M.J. Brown (Creator)
  • T. J. Charlton (Creator)
  • Jonathan Knappett (Creator)
  • Y. Ghaffari Motlagh (University of Sheffield) (Creator)
  • L. Wang (Durham University) (Creator)
  • Durham University (Contributor)
  • Durham University (Contributor)
  • Engineering And Physical Sciences Research Council (Contributor)

Dataset

Description

The material point method is ideally suited to modelling problems involving large deformations where conventional mesh-based methods would struggle. However, total and updated Lagrangian approaches are unsuitable and non-ideal, respectively, in terms formulating equilibrium for the method. This is due to the basis functions, and particularly the derivatives of the basis functions, of material point methods normally being defined based on an unformed, and sometimes regular, background mesh. It is possible to map the basis function spatial derivatives using the deformation at a material point but this introduces additional algorithm complexity and computational expense. This paper presents a new Lagrangian statement of equilibrium which is ideal for material point methods as it satisfies equilibrium on the undeformed background mesh at the start of a load step. The formulation is implemented using a quasi-static implicit algorithm which includes the derivation of the consistent tangent to achieve optimum convergence of the global equilibrium iterations. The method is applied to a number of large deformation elasto-plastic problems, with a specific focus of the convergence of the method towards analytical solutions with the standard, generalised interpolation and CPDI2 material point methods. For the generalised interpolation method, different domain updating methods are investigated and it is shown that all of the current methods are degenerative under certain simple deformation fields. A new domain updating approach is proposed that overcomes these issues. The proposed material point method framework can be applied to all existing material point methods and adopted for implicit and explicit analysis, however its advantages are mainly associated with the former.
Date made available2019
PublisherDurham University

Data Monitor categories

  • elasto-plasticity
  • finite deformation mechanics
  • Lagrangian mechanics
  • material point method

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