A p-adaptive scheme for overcoming volumetric locking during plastic flow

A p-adaptive scheme for overcoming volumetric locking during plastic flow

A feature of many classical plasticity yield functions is that they impose a volumetric constraint on plastic deformation. For low-order finite elements, this results in kinematic restraints on possible deformation modes of an element leading to an overly stiff response. The most robust procedure fo...

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Bibliographic Details
Published in:Computer methods in applied mechanics and engineering Vol. 191; no. 29; pp. 3153 - 3164
Main Authors: Wells, G.N., Sluys, L.J., de Borst, R.
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 10-05-2002
Elsevier
Subjects:
Computational techniques
Exact sciences and technology
Finite elements
Finite-element and galerkin methods
Fundamental areas of phenomenology (including applications)
Inelasticity (thermoplasticity, viscoplasticity...)
Mathematical methods in physics
p-adaptivity
Partition of unity
Physics
Plasticity
Solid mechanics
Structural and continuum mechanics
Viscoelasticity, plasticity, viscoplasticity
Volumetric locking
Finite elements
02
Volumetric locking
28
Plasticity
Partition of unity
p-adaptivity
40
65
Polynomial function
Finite element method
Inelasticity
Plastic flow
Numerical method
Non linear effect
Indentation
Adaptive method
Locking
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Summary:A feature of many classical plasticity yield functions is that they impose a volumetric constraint on plastic deformation. For low-order finite elements, this results in kinematic restraints on possible deformation modes of an element leading to an overly stiff response. The most robust procedure for overcoming volumetric locking is to use higher-order finite elements. However, low-order elements are popular for their efficiency and simplicity. To remedy volumetric locking in low-order elements, a p-adaptive scheme is proposed where through the partition of unity property of finite element shape functions, the underlying basis of low-order finite elements undergoing plastic flow is enhanced with higher-order polynomial functions. The computational result is extra degrees of freedom at existing nodes of elements undergoing plastic flow, while the rest of the nodes remain unaltered. The performance of the scheme is illustrated through two- and three-dimensional numerical examples.
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ISSN:0045-7825
1879-2138
DOI:10.1016/S0045-7825(02)00252-9