The influence of non-dissipative quantities in kinematic hardening plasticity
(2003) 6th Asia-Pacific Symposium on Engineering Plasticity and its Applications (AEPA 2002) 233-236. p.773-778- Abstract
- A kinematic hardening plasticity model valid for finite strains is presented. The model is based on the well-known multiplicative split of the deformation gradient into an elastic and a plastic part. The basic ingredient in the formulation is the introduction of locally defined configurations center configurations- which are associated with deformation gradients that are used to characterize the kinematic hardening behavior. One of the aspects of the model investigated here is found when the plastic and kinematic hardening evolution laws are split into two parts: a dissipative part, which is restricted by the dissipation inequality, and a non-dissipative part, which can be chosen without any thermodynamical considerations. To investigate... (More)
- A kinematic hardening plasticity model valid for finite strains is presented. The model is based on the well-known multiplicative split of the deformation gradient into an elastic and a plastic part. The basic ingredient in the formulation is the introduction of locally defined configurations center configurations- which are associated with deformation gradients that are used to characterize the kinematic hardening behavior. One of the aspects of the model investigated here is found when the plastic and kinematic hardening evolution laws are split into two parts: a dissipative part, which is restricted by the dissipation inequality, and a non-dissipative part, which can be chosen without any thermodynamical considerations. To investigate the predictive capabilities of the proposed formulation, the simple shear problem and torsion of a thin-walled cylinder are considered. In the numerical examples it turns out that the non-dissipative quantities affect the response to a large extent and are consequently valuable ingredients in the formulation when representing real material behavior (Less)
Please use this url to cite or link to this publication:
https://lup.lub.lu.se/record/612968
- author
- Wallin, Mathias LU ; Ristinmaa, Matti LU and Ottosen, Niels Saabye LU
- organization
- publishing date
- 2003
- type
- Chapter in Book/Report/Conference proceeding
- publication status
- published
- subject
- keywords
- dissipation inequality, dissipative part, kinematic hardening evolution laws, plastic evolution laws, kinematic hardening behavior, center configurations, locally defined configurations, plastic part, elastic part, deformation gradient, kinematic hardening plasticity model, finite strains, thermodynamical considerations, nondissipative part, simple shear problem, torsion, thin-walled cylinder, real material behavior
- host publication
- Key Engineering Materials
- volume
- 233-236
- pages
- 773 - 778
- publisher
- Trans Tech Publications
- conference name
- 6th Asia-Pacific Symposium on Engineering Plasticity and its Applications (AEPA 2002)
- conference location
- Sydney, NSW, Australia
- conference dates
- 2002-12-02 - 2002-12-06
- external identifiers
-
- wos:000180723900121
- other:CODEN: KEMAEY
- ISSN
- 1013-9826
- language
- English
- LU publication?
- yes
- id
- 6843b3cb-e55c-41d9-aab2-fdae7c745155 (old id 612968)
- date added to LUP
- 2016-04-01 17:00:37
- date last changed
- 2021-02-22 09:56:12
@inproceedings{6843b3cb-e55c-41d9-aab2-fdae7c745155, abstract = {{A kinematic hardening plasticity model valid for finite strains is presented. The model is based on the well-known multiplicative split of the deformation gradient into an elastic and a plastic part. The basic ingredient in the formulation is the introduction of locally defined configurations center configurations- which are associated with deformation gradients that are used to characterize the kinematic hardening behavior. One of the aspects of the model investigated here is found when the plastic and kinematic hardening evolution laws are split into two parts: a dissipative part, which is restricted by the dissipation inequality, and a non-dissipative part, which can be chosen without any thermodynamical considerations. To investigate the predictive capabilities of the proposed formulation, the simple shear problem and torsion of a thin-walled cylinder are considered. In the numerical examples it turns out that the non-dissipative quantities affect the response to a large extent and are consequently valuable ingredients in the formulation when representing real material behavior}}, author = {{Wallin, Mathias and Ristinmaa, Matti and Ottosen, Niels Saabye}}, booktitle = {{Key Engineering Materials}}, issn = {{1013-9826}}, keywords = {{dissipation inequality; dissipative part; kinematic hardening evolution laws; plastic evolution laws; kinematic hardening behavior; center configurations; locally defined configurations; plastic part; elastic part; deformation gradient; kinematic hardening plasticity model; finite strains; thermodynamical considerations; nondissipative part; simple shear problem; torsion; thin-walled cylinder; real material behavior}}, language = {{eng}}, pages = {{773--778}}, publisher = {{Trans Tech Publications}}, title = {{The influence of non-dissipative quantities in kinematic hardening plasticity}}, volume = {{233-236}}, year = {{2003}}, }