Multifield finite strain plasticity: theory and numerics

Karol Lewandowski; Daniele Barbera; Paul Blackwell; Amir H. Roohi; Ignatios Athanasiadis; Andrew McBride; Paul Steinmann; Chris Pearce; Łukasz Kaczmarczyk

doi:10.1016/j.cma.2023.116101

Multifield finite strain plasticity: theory and numerics

Karol Lewandowski, Daniele Barbera, Paul Blackwell, Amir H. Roohi, Ignatios Athanasiadis, Andrew McBride^*, Paul Steinmann, Chris Pearce, Łukasz Kaczmarczyk

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

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Abstract

Motivated by the inability of classical computational plasticity to fully exploit modern scientific computing, a multifield formulation for finite strain plasticity is presented. This avoids a local integration of the elastoplastic model. In the multifield approach, the balance of linear momentum, the flow relation and the Karush–Kuhn–Tucker constraints are collectively cast in a variational format. In addition to the deformation, both the plastic strain and the consistency parameter are global degrees of freedom in the resulting spatially discrete problem. The ensuing proliferation of global degrees of freedom in the multifield approach is addressed by exploiting the block sparse structure of the algebraic system together with a tailored block matrix solver which can utilise emerging hardware architectures. A series of numerical problems demonstrate the validity, capability and efficiency of the proposed approach.

Original language	English
Article number	116101
Journal	Computer Methods in Applied Mechanics and Engineering
Volume	414
Early online date	12 Jun 2023
DOIs	https://doi.org/10.1016/j.cma.2023.116101
Publication status	Published - 1 Sept 2023

Keywords

plasticity
finite element methods
FEM
finite deformation
solid mechanics

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10.1016/j.cma.2023.116101Licence: CC BY 4.0

Lewandowski-etal-CMAME-2023-Multifield-finite-strain-plasticity-theory-and-numericsFinal published version, 1.86 MBLicence: CC BY 4.0

Predictive modelling for incremental cold flow forming: An integrated framework for fundamental understanding and process optimisation
Blackwell, P. (Principal Investigator)
EPSRC (Engineering and Physical Sciences Research Council)
1/04/20 → 31/03/23
Project: Research

Cite this

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title = "Multifield finite strain plasticity: theory and numerics",

abstract = "Motivated by the inability of classical computational plasticity to fully exploit modern scientific computing, a multifield formulation for finite strain plasticity is presented. This avoids a local integration of the elastoplastic model. In the multifield approach, the balance of linear momentum, the flow relation and the Karush–Kuhn–Tucker constraints are collectively cast in a variational format. In addition to the deformation, both the plastic strain and the consistency parameter are global degrees of freedom in the resulting spatially discrete problem. The ensuing proliferation of global degrees of freedom in the multifield approach is addressed by exploiting the block sparse structure of the algebraic system together with a tailored block matrix solver which can utilise emerging hardware architectures. A series of numerical problems demonstrate the validity, capability and efficiency of the proposed approach.",

keywords = "plasticity, finite element methods, FEM, finite deformation, solid mechanics",

author = "Karol Lewandowski and Daniele Barbera and Paul Blackwell and Roohi, {Amir H.} and Ignatios Athanasiadis and Andrew McBride and Paul Steinmann and Chris Pearce and {\L}ukasz Kaczmarczyk",

year = "2023",

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doi = "10.1016/j.cma.2023.116101",

language = "English",

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TY - JOUR

T1 - Multifield finite strain plasticity

T2 - theory and numerics

AU - Lewandowski, Karol

AU - Barbera, Daniele

AU - Blackwell, Paul

AU - Roohi, Amir H.

AU - Athanasiadis, Ignatios

AU - McBride, Andrew

AU - Steinmann, Paul

AU - Pearce, Chris

AU - Kaczmarczyk, Łukasz

PY - 2023/9/1

Y1 - 2023/9/1

N2 - Motivated by the inability of classical computational plasticity to fully exploit modern scientific computing, a multifield formulation for finite strain plasticity is presented. This avoids a local integration of the elastoplastic model. In the multifield approach, the balance of linear momentum, the flow relation and the Karush–Kuhn–Tucker constraints are collectively cast in a variational format. In addition to the deformation, both the plastic strain and the consistency parameter are global degrees of freedom in the resulting spatially discrete problem. The ensuing proliferation of global degrees of freedom in the multifield approach is addressed by exploiting the block sparse structure of the algebraic system together with a tailored block matrix solver which can utilise emerging hardware architectures. A series of numerical problems demonstrate the validity, capability and efficiency of the proposed approach.

AB - Motivated by the inability of classical computational plasticity to fully exploit modern scientific computing, a multifield formulation for finite strain plasticity is presented. This avoids a local integration of the elastoplastic model. In the multifield approach, the balance of linear momentum, the flow relation and the Karush–Kuhn–Tucker constraints are collectively cast in a variational format. In addition to the deformation, both the plastic strain and the consistency parameter are global degrees of freedom in the resulting spatially discrete problem. The ensuing proliferation of global degrees of freedom in the multifield approach is addressed by exploiting the block sparse structure of the algebraic system together with a tailored block matrix solver which can utilise emerging hardware architectures. A series of numerical problems demonstrate the validity, capability and efficiency of the proposed approach.

KW - plasticity

KW - finite element methods

KW - FEM

KW - finite deformation

KW - solid mechanics

U2 - 10.1016/j.cma.2023.116101

DO - 10.1016/j.cma.2023.116101

M3 - Article

SN - 0045-7825

VL - 414

JO - Computer Methods in Applied Mechanics and Engineering

JF - Computer Methods in Applied Mechanics and Engineering

M1 - 116101

ER -

Multifield finite strain plasticity: theory and numerics

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Keywords

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Predictive modelling for incremental cold flow forming: An integrated framework for fundamental understanding and process optimisation

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