Parameter identification for anisotropic plasticity model using digital image correlation: Comparison between uni-axial and bi-axial tensile testing

David Lecompte; Steven Cooreman; Sam Coppieters; John Vantomme; Hugo Sol; Dimitri Debruyne

doi:10.3166/ejcm.18.393-418

Parameter identification for anisotropic plasticity model using digital image correlation: Comparison between uni-axial and bi-axial tensile testing

David Lecompte
, Steven Cooreman
, Sam Coppieters
, John Vantomme
, Hugo Sol
, Dimitri Debruyne

Structures & Effects of Explosions

Technical University KaHo Sint-Lieven
Vrije Universiteit Brussel

Publikation: Beitrag in Fachzeitschrift › Artikel › Begutachtung

40 Zitate (Scopus)

Abstract

The basic principle of the described procedure for plastic material identification is the generation of a complex and heterogeneous deformation field, which is measured by digital image correlation (DIC) and compared to Finite Element (FE) simulations. In this paper two tests for the identification of the hardening behaviour and the yield locus of DC06 steel are compared: a uni-axial test on a perforated rectangular specimen and a bi-axial tensile test on a cruciform specimen. The work hardening of the material is assumed to be isotropic and the yield locus is modelled by the anisotropic Hill48 criterion. The identification results for the different material parameters, based on both the uni- and the bi-axial test, are discussed and show a significant agreement.

Originalsprache	Englisch
Seiten (von - bis)	393-418
Seitenumfang	26
Fachzeitschrift	European Journal of Computational Mechanics
Jahrgang	18
Ausgabenummer	3-4
DOIs	https://doi.org/10.3166/ejcm.18.393-418
Publikationsstatus	Veröffentlicht - 2009

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abstract = "The basic principle of the described procedure for plastic material identification is the generation of a complex and heterogeneous deformation field, which is measured by digital image correlation (DIC) and compared to Finite Element (FE) simulations. In this paper two tests for the identification of the hardening behaviour and the yield locus of DC06 steel are compared: a uni-axial test on a perforated rectangular specimen and a bi-axial tensile test on a cruciform specimen. The work hardening of the material is assumed to be isotropic and the yield locus is modelled by the anisotropic Hill48 criterion. The identification results for the different material parameters, based on both the uni- and the bi-axial test, are discussed and show a significant agreement.",

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author = "David Lecompte and Steven Cooreman and Sam Coppieters and John Vantomme and Hugo Sol and Dimitri Debruyne",

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AU - Lecompte, David

AU - Cooreman, Steven

AU - Coppieters, Sam

AU - Vantomme, John

AU - Sol, Hugo

AU - Debruyne, Dimitri

PY - 2009

Y1 - 2009

N2 - The basic principle of the described procedure for plastic material identification is the generation of a complex and heterogeneous deformation field, which is measured by digital image correlation (DIC) and compared to Finite Element (FE) simulations. In this paper two tests for the identification of the hardening behaviour and the yield locus of DC06 steel are compared: a uni-axial test on a perforated rectangular specimen and a bi-axial tensile test on a cruciform specimen. The work hardening of the material is assumed to be isotropic and the yield locus is modelled by the anisotropic Hill48 criterion. The identification results for the different material parameters, based on both the uni- and the bi-axial test, are discussed and show a significant agreement.

AB - The basic principle of the described procedure for plastic material identification is the generation of a complex and heterogeneous deformation field, which is measured by digital image correlation (DIC) and compared to Finite Element (FE) simulations. In this paper two tests for the identification of the hardening behaviour and the yield locus of DC06 steel are compared: a uni-axial test on a perforated rectangular specimen and a bi-axial tensile test on a cruciform specimen. The work hardening of the material is assumed to be isotropic and the yield locus is modelled by the anisotropic Hill48 criterion. The identification results for the different material parameters, based on both the uni- and the bi-axial test, are discussed and show a significant agreement.

KW - Digital image correlation

KW - Inverse modelling

KW - Material identification

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JO - European Journal of Computational Mechanics

JF - European Journal of Computational Mechanics

IS - 3-4

ER -

Parameter identification for anisotropic plasticity model using digital image correlation: Comparison between uni-axial and bi-axial tensile testing

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