Micromechanical finite element analysis of strain partitioning in multiphase medium manganese TWIP+TRIP steel

In the present contribution, a phenomenological constitutive model of medium manganese steels, in which both twinning-induced (TWIP) and transformation-induced (TRIP) plasticity enhancing mechanisms are activated, is implemented in the finite element framework. The implementation is utilized for the...

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Published inActa materialia Vol. 108; pp. 219 - 228
Main Authors Latypov, Marat I., Shin, Sunmi, De Cooman, Bruno C., Kim, Hyoung Seop
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.04.2016
Subjects
Austenite
Finite element method
Finite element methods
Manganese
Mathematical analysis
Medium Mn steel
Partitioning
Strain
Strain localization
Strain partitioning
TRIP steels
TWIP steels
TWIP+TRIP
Strain partitioning
TWIP+TRIP
Finite element methods
Medium Mn steel
Online AccessGet full text
ISSN1359-6454
1873-2453
DOI10.1016/j.actamat.2016.02.001

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Abstract In the present contribution, a phenomenological constitutive model of medium manganese steels, in which both twinning-induced (TWIP) and transformation-induced (TRIP) plasticity enhancing mechanisms are activated, is implemented in the finite element framework. The implementation is utilized for the analysis of the full-field strain partitioning in dual-phase microstructure maps obtained from electron backscattering diffraction. The results of the finite element analysis suggest that the strain localization in the studied steel has an alternating character. Specifically, in the low strain region, most of the externally imposed deformation is accommodated by the initially softer austenite. The higher strain hardening rate of austenite due to deformation twinning (TWIP effect) and the mechanically-induced transformation to martensite (TRIP effect) results in a shift of the strain localization to ferrite. This alternating strain localization is a key feature that distinguishes the medium manganese TWIP+TRIP steel. It is shown that this alternating strain localization contributes to the superior mechanical behavior of medium manganese TWIP+TRIP steel reported in the literature. [Display omitted]
AbstractList In the present contribution, a phenomenological constitutive model of medium manganese steels, in which both twinning-induced (TWIP) and transformation-induced (TRIP) plasticity enhancing mechanisms are activated, is implemented in the finite element framework. The implementation is utilized for the analysis of the full-field strain partitioning in dual-phase microstructure maps obtained from electron backscattering diffraction. The results of the finite element analysis suggest that the strain localization in the studied steel has an alternating character. Specifically, in the low strain region, most of the externally imposed deformation is accommodated by the initially softer austenite. The higher strain hardening rate of austenite due to deformation twinning (TWIP effect) and the mechanically-induced transformation to martensite (TRIP effect) results in a shift of the strain localization to ferrite. This alternating strain localization is a key feature that distinguishes the medium manganese TWIP+TRIP steel. It is shown that this alternating strain localization contributes to the superior mechanical behavior of medium manganese TWIP+TRIP steel reported in the literature.
In the present contribution, a phenomenological constitutive model of medium manganese steels, in which both twinning-induced (TWIP) and transformation-induced (TRIP) plasticity enhancing mechanisms are activated, is implemented in the finite element framework. The implementation is utilized for the analysis of the full-field strain partitioning in dual-phase microstructure maps obtained from electron backscattering diffraction. The results of the finite element analysis suggest that the strain localization in the studied steel has an alternating character. Specifically, in the low strain region, most of the externally imposed deformation is accommodated by the initially softer austenite. The higher strain hardening rate of austenite due to deformation twinning (TWIP effect) and the mechanically-induced transformation to martensite (TRIP effect) results in a shift of the strain localization to ferrite. This alternating strain localization is a key feature that distinguishes the medium manganese TWIP+TRIP steel. It is shown that this alternating strain localization contributes to the superior mechanical behavior of medium manganese TWIP+TRIP steel reported in the literature. [Display omitted]
Author De Cooman, Bruno C.
Kim, Hyoung Seop
Latypov, Marat I.
Shin, Sunmi
Author_xml – sequence: 1
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  surname: Latypov
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  givenname: Sunmi
  surname: Shin
  fullname: Shin, Sunmi
  organization: Graduate Institute of Ferrous Technology, POSTECH, Pohang, 790-784, Republic of Korea
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  givenname: Bruno C.
  surname: De Cooman
  fullname: De Cooman, Bruno C.
  email: decooman@postech.ac.kr
  organization: Graduate Institute of Ferrous Technology, POSTECH, Pohang, 790-784, Republic of Korea
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  givenname: Hyoung Seop
  orcidid: 0000-0002-3155-583X
  surname: Kim
  fullname: Kim, Hyoung Seop
  email: hskim@postech.ac.kr
  organization: Center for Advanced Aerospace Materials, POSTECH, Pohang, 790-784, Republic of Korea
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Finite element methods
Medium Mn steel
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Snippet In the present contribution, a phenomenological constitutive model of medium manganese steels, in which both twinning-induced (TWIP) and transformation-induced...
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SubjectTerms Austenite
Finite element method
Finite element methods
Manganese
Mathematical analysis
Medium Mn steel
Partitioning
Strain
Strain localization
Strain partitioning
TRIP steels
TWIP steels
TWIP+TRIP
Title Micromechanical finite element analysis of strain partitioning in multiphase medium manganese TWIP+TRIP steel
URI https://dx.doi.org/10.1016/j.actamat.2016.02.001
https://www.proquest.com/docview/1808110117
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