A method to quantitatively upscale the damage initiation of dual-phase steels under various stress states from microscale to macroscale

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A method to quantitatively upscale the damage initiation of dual-phase steels under various stress states from microscale to macroscale. / Lian, Junhe; Yang, Hanqi; Vajragupta, Napat; Münstermann, Sebastian; Bleck, Wolfgang.

In: Computational Materials Science, Vol. 94, No. C, 01.11.2014, p. 245-257.

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Lian, Junhe ; Yang, Hanqi ; Vajragupta, Napat ; Münstermann, Sebastian ; Bleck, Wolfgang. / A method to quantitatively upscale the damage initiation of dual-phase steels under various stress states from microscale to macroscale. In: Computational Materials Science. 2014 ; Vol. 94, No. C. pp. 245-257.

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@article{6107bc1f884941c887017824f76cda8a,
title = "A method to quantitatively upscale the damage initiation of dual-phase steels under various stress states from microscale to macroscale",
abstract = "The aim of this paper is to develop a micromechanical model to quantitatively upscale the damage initiation of dual-phase steels under various stress states from micro to macro and reveal the underlying mechanisms of the damage initiation dependency on stress states from a microstructural level. Finite element (FE) model based on the real microstructure of a DP600 steel sheet is employed by representative volume element (RVE) method. Several numerical aspects are also discussed, such as mesh size and discretisation feature of the phase boundary. The plastic strain localisation theory is applied to the RVE modelling without any other damage models or imperfections. Three typical stress states, uniaxial tension, plane-strain tension and equibiaxial tension, are considered to investigate the influence of the stress state on damage initiation. The quantitative evaluation of the damage initiation for three stress states obtained from the RVE simulation shows the dependency on both stress triaxiality and Lode angle. The results are further compared to the experimentally calibrated damage initiation locus (DIL) and a fairly good agreement is achieved. From this study, the general physical understanding of the effect of stress states on damage initiation is explored and the method for quantitative analysis of the damage initiation in a microstructural level is also established. The microstructure heterogeneity is considered as the key factor that contributes to the damage initiation behaviour of the dual-phase steel.",
keywords = "Damage initiation, Dual-phase steels, Lode angle, Plastic strain localisation, Representative volume elements, Stress triaxiality",
author = "Junhe Lian and Hanqi Yang and Napat Vajragupta and Sebastian M{\"u}nstermann and Wolfgang Bleck",
year = "2014",
month = "11",
day = "1",
doi = "10.1016/j.commatsci.2014.05.051",
language = "English",
volume = "94",
pages = "245--257",
journal = "Computational Materials Science",
issn = "0927-0256",
publisher = "Elsevier",
number = "C",

}

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TY - JOUR

T1 - A method to quantitatively upscale the damage initiation of dual-phase steels under various stress states from microscale to macroscale

AU - Lian, Junhe

AU - Yang, Hanqi

AU - Vajragupta, Napat

AU - Münstermann, Sebastian

AU - Bleck, Wolfgang

PY - 2014/11/1

Y1 - 2014/11/1

N2 - The aim of this paper is to develop a micromechanical model to quantitatively upscale the damage initiation of dual-phase steels under various stress states from micro to macro and reveal the underlying mechanisms of the damage initiation dependency on stress states from a microstructural level. Finite element (FE) model based on the real microstructure of a DP600 steel sheet is employed by representative volume element (RVE) method. Several numerical aspects are also discussed, such as mesh size and discretisation feature of the phase boundary. The plastic strain localisation theory is applied to the RVE modelling without any other damage models or imperfections. Three typical stress states, uniaxial tension, plane-strain tension and equibiaxial tension, are considered to investigate the influence of the stress state on damage initiation. The quantitative evaluation of the damage initiation for three stress states obtained from the RVE simulation shows the dependency on both stress triaxiality and Lode angle. The results are further compared to the experimentally calibrated damage initiation locus (DIL) and a fairly good agreement is achieved. From this study, the general physical understanding of the effect of stress states on damage initiation is explored and the method for quantitative analysis of the damage initiation in a microstructural level is also established. The microstructure heterogeneity is considered as the key factor that contributes to the damage initiation behaviour of the dual-phase steel.

AB - The aim of this paper is to develop a micromechanical model to quantitatively upscale the damage initiation of dual-phase steels under various stress states from micro to macro and reveal the underlying mechanisms of the damage initiation dependency on stress states from a microstructural level. Finite element (FE) model based on the real microstructure of a DP600 steel sheet is employed by representative volume element (RVE) method. Several numerical aspects are also discussed, such as mesh size and discretisation feature of the phase boundary. The plastic strain localisation theory is applied to the RVE modelling without any other damage models or imperfections. Three typical stress states, uniaxial tension, plane-strain tension and equibiaxial tension, are considered to investigate the influence of the stress state on damage initiation. The quantitative evaluation of the damage initiation for three stress states obtained from the RVE simulation shows the dependency on both stress triaxiality and Lode angle. The results are further compared to the experimentally calibrated damage initiation locus (DIL) and a fairly good agreement is achieved. From this study, the general physical understanding of the effect of stress states on damage initiation is explored and the method for quantitative analysis of the damage initiation in a microstructural level is also established. The microstructure heterogeneity is considered as the key factor that contributes to the damage initiation behaviour of the dual-phase steel.

KW - Damage initiation

KW - Dual-phase steels

KW - Lode angle

KW - Plastic strain localisation

KW - Representative volume elements

KW - Stress triaxiality

UR - http://www.scopus.com/inward/record.url?scp=84926278887&partnerID=8YFLogxK

U2 - 10.1016/j.commatsci.2014.05.051

DO - 10.1016/j.commatsci.2014.05.051

M3 - Article

VL - 94

SP - 245

EP - 257

JO - Computational Materials Science

JF - Computational Materials Science

SN - 0927-0256

IS - C

ER -

ID: 29166591