Multi-scale modelling of AISI H11 martensitic tool steel surface anisotropic mechanical behaviour

Multi-scale modelling of AISI H11 martensitic tool steel surface anisotropic mechanical behaviour

In this work, a numerical investigation is carried out on the anisotropic and heterogeneous behaviour of the AISI H11 martensitic tool steel surface using finite element method and a multi-scale approach. An elasto-viscoplastic model that considers nonlinear isotropic and kinematic hardenings is im...

Full description

Bibliographic Details
Main Authors: Zouaghi Ahmed, Velay Vincent, Soveja Adriana, Rézaï-Aria Farhad
Format: Article
Language:English
Published: EDP Sciences 2014-06-01
Series:MATEC Web of Conferences
Online Access:http://dx.doi.org/10.1051/matecconf/20141204018
id doaj-df7783bd88184b9ab744e0a0c90fcb00
record_format Article
spelling doaj-df7783bd88184b9ab744e0a0c90fcb002021-02-02T02:54:49ZengEDP SciencesMATEC Web of Conferences2261-236X2014-06-01120401810.1051/matecconf/20141204018matecconf_fdmd2014_04018Multi-scale modelling of AISI H11 martensitic tool steel surface anisotropic mechanical behaviourZouaghi AhmedVelay Vincent0Soveja Adriana1Rézaï-Aria Farhad2Université de Toulouse; INSA, UPS, Mines Albi, ISAE; ICA (Institut Clément Ader), Campus JarlardUniversité de Toulouse; INSA, UPS, Mines Albi, ISAE; ICA (Institut Clément Ader)Université de Toulouse; INSA, UPS, Mines Albi, ISAE; ICA (Institut Clément Ader), Campus Jarlard In this work, a numerical investigation is carried out on the anisotropic and heterogeneous behaviour of the AISI H11 martensitic tool steel surface using finite element method and a multi-scale approach. An elasto-viscoplastic model that considers nonlinear isotropic and kinematic hardenings is implemented in the finite elements code ABAQUS using small strain assumption. The parameters of the constitutive equations are identified using macroscopic quasi-static and cyclic material responses by the mean of a localization rule. Virtual realistic microstructures, consisting of laths and grains, are generated using particular Voronoï tessellations. These microstructures consider the specific crystallographic orientations α’/γ. Finite element investigation is then performed. The local heterogeneous and anisotropic behaviour of the surface as well as the subsurface is shown under quasi-static and cyclic mechanical loadings. The laths morphology and crystallographic orientation have an important impact on the local mechanical fields. http://dx.doi.org/10.1051/matecconf/20141204018
collection DOAJ
language English
format Article
sources DOAJ
author Zouaghi Ahmed
Velay Vincent
Soveja Adriana
Rézaï-Aria Farhad
spellingShingle Zouaghi Ahmed
Velay Vincent
Soveja Adriana
Rézaï-Aria Farhad
Multi-scale modelling of AISI H11 martensitic tool steel surface anisotropic mechanical behaviour
MATEC Web of Conferences
author_facet Zouaghi Ahmed
Velay Vincent
Soveja Adriana
Rézaï-Aria Farhad
author_sort Zouaghi Ahmed
title Multi-scale modelling of AISI H11 martensitic tool steel surface anisotropic mechanical behaviour
title_short Multi-scale modelling of AISI H11 martensitic tool steel surface anisotropic mechanical behaviour
title_full Multi-scale modelling of AISI H11 martensitic tool steel surface anisotropic mechanical behaviour
title_fullStr Multi-scale modelling of AISI H11 martensitic tool steel surface anisotropic mechanical behaviour
title_full_unstemmed Multi-scale modelling of AISI H11 martensitic tool steel surface anisotropic mechanical behaviour
title_sort multi-scale modelling of aisi h11 martensitic tool steel surface anisotropic mechanical behaviour
publisher EDP Sciences
series MATEC Web of Conferences
issn 2261-236X
publishDate 2014-06-01
description In this work, a numerical investigation is carried out on the anisotropic and heterogeneous behaviour of the AISI H11 martensitic tool steel surface using finite element method and a multi-scale approach. An elasto-viscoplastic model that considers nonlinear isotropic and kinematic hardenings is implemented in the finite elements code ABAQUS using small strain assumption. The parameters of the constitutive equations are identified using macroscopic quasi-static and cyclic material responses by the mean of a localization rule. Virtual realistic microstructures, consisting of laths and grains, are generated using particular Voronoï tessellations. These microstructures consider the specific crystallographic orientations α’/γ. Finite element investigation is then performed. The local heterogeneous and anisotropic behaviour of the surface as well as the subsurface is shown under quasi-static and cyclic mechanical loadings. The laths morphology and crystallographic orientation have an important impact on the local mechanical fields.
url http://dx.doi.org/10.1051/matecconf/20141204018
work_keys_str_mv AT zouaghiahmed multiscalemodellingofaisih11martensitictoolsteelsurfaceanisotropicmechanicalbehaviour
AT velayvincent multiscalemodellingofaisih11martensitictoolsteelsurfaceanisotropicmechanicalbehaviour
AT sovejaadriana multiscalemodellingofaisih11martensitictoolsteelsurfaceanisotropicmechanicalbehaviour
AT rezaiariafarhad multiscalemodellingofaisih11martensitictoolsteelsurfaceanisotropicmechanicalbehaviour
_version_ 1724308944056221696

Similar Items