Broad stress triaxiality ratio band fracture experiments in DP900 metal sheets and corresponding predictive capability of advanced phenomenological and micromechanical fully coupled damage models

Zhenming Yue; Xinrui Min; Zhiyu Tuo; Celal Soyarslan; Xincun Zhuang; Houssem Badreddine; Khemais Saanouni; Jun Gao

doi:10.1016/j.msea.2021.140978

Broad stress triaxiality ratio band fracture experiments in DP900 metal sheets and corresponding predictive capability of advanced phenomenological and micromechanical fully coupled damage models

Zhenming Yue, Xinrui Min, Zhiyu Tuo, Celal Soyarslan, Xincun Zhuang^*, Houssem Badreddine, Khemais Saanouni, Jun Gao^*

^*Corresponding author for this work

Nonlinear Solid Mechanics

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4 Citations (Scopus)

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Abstract

Correct prediction of the fracture time and location and their evolution in metallic materials has always been a research hotspot in the field of metal forming. To this end, and in the context of metal forming process simulation, an advanced mathematical material model is crucial. In this paper, we investigate the accuracy of two fully-coupled damage models, one of which is phenomenologically-based and the other one micromechanically-based, in predicting the failure in DP900 steel plates subject to various loading paths. These are applied throughout tests, including tensile tests on unnotched and notched specimens with different notch radii as well as butterfly wing shear tests. Through the comparisons of the numerical and experimental results, in terms of force-displacement curves and fracture strains (or ductility) under wide range of strain paths, the accuracy of the proposed two coupled damage models are discussed.

Original language	English
Article number	140978
Number of pages	14
Journal	Materials Science & Engineering A
Volume	811
Early online date	11 Mar 2021
DOIs	https://doi.org/10.1016/j.msea.2021.140978
Publication status	Published - 15 Apr 2021

Keywords

Damage model
Failure prediction
Full coupling
Loading paths
Plastic deformation
22/2 OA procedure

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10.1016/j.msea.2021.140978

Broad stressFinal published version, 93.2 KBLicence: Taverne

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Yue, Z., Min, X., Tuo, Z., Soyarslan, C., Zhuang, X., Badreddine, H., Saanouni, K., & Gao, J. (2021). Broad stress triaxiality ratio band fracture experiments in DP900 metal sheets and corresponding predictive capability of advanced phenomenological and micromechanical fully coupled damage models. Materials Science & Engineering A, 811, Article 140978. Advance online publication. https://doi.org/10.1016/j.msea.2021.140978

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title = "Broad stress triaxiality ratio band fracture experiments in DP900 metal sheets and corresponding predictive capability of advanced phenomenological and micromechanical fully coupled damage models",

abstract = "Correct prediction of the fracture time and location and their evolution in metallic materials has always been a research hotspot in the field of metal forming. To this end, and in the context of metal forming process simulation, an advanced mathematical material model is crucial. In this paper, we investigate the accuracy of two fully-coupled damage models, one of which is phenomenologically-based and the other one micromechanically-based, in predicting the failure in DP900 steel plates subject to various loading paths. These are applied throughout tests, including tensile tests on unnotched and notched specimens with different notch radii as well as butterfly wing shear tests. Through the comparisons of the numerical and experimental results, in terms of force-displacement curves and fracture strains (or ductility) under wide range of strain paths, the accuracy of the proposed two coupled damage models are discussed.",

keywords = "Damage model, Failure prediction, Full coupling, Loading paths, Plastic deformation, 22/2 OA procedure",

author = "Zhenming Yue and Xinrui Min and Zhiyu Tuo and Celal Soyarslan and Xincun Zhuang and Houssem Badreddine and Khemais Saanouni and Jun Gao",

note = "Funding Information: The authors acknowledge the support from the National Natural Science Foundation of China (No. 51975327 and 51605257 ) and the Future Plan Project for Young Scholars of Shandong University ( 2017WHWLJH06 ). Publisher Copyright: {\textcopyright} 2021 Elsevier B.V.",

year = "2021",

month = apr,

day = "15",

doi = "10.1016/j.msea.2021.140978",

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Yue, Z, Min, X, Tuo, Z, Soyarslan, C, Zhuang, X, Badreddine, H, Saanouni, K & Gao, J 2021, 'Broad stress triaxiality ratio band fracture experiments in DP900 metal sheets and corresponding predictive capability of advanced phenomenological and micromechanical fully coupled damage models', Materials Science & Engineering A, vol. 811, 140978. https://doi.org/10.1016/j.msea.2021.140978

Broad stress triaxiality ratio band fracture experiments in DP900 metal sheets and corresponding predictive capability of advanced phenomenological and micromechanical fully coupled damage models. / Yue, Zhenming; Min, Xinrui; Tuo, Zhiyu et al.
In: Materials Science & Engineering A, Vol. 811, 140978, 15.04.2021.

Research output: Contribution to journal › Article › Academic › peer-review

TY - JOUR

T1 - Broad stress triaxiality ratio band fracture experiments in DP900 metal sheets and corresponding predictive capability of advanced phenomenological and micromechanical fully coupled damage models

AU - Yue, Zhenming

AU - Min, Xinrui

AU - Tuo, Zhiyu

AU - Soyarslan, Celal

AU - Zhuang, Xincun

AU - Badreddine, Houssem

AU - Saanouni, Khemais

AU - Gao, Jun

N1 - Funding Information: The authors acknowledge the support from the National Natural Science Foundation of China (No. 51975327 and 51605257 ) and the Future Plan Project for Young Scholars of Shandong University ( 2017WHWLJH06 ). Publisher Copyright: © 2021 Elsevier B.V.

PY - 2021/4/15

Y1 - 2021/4/15

N2 - Correct prediction of the fracture time and location and their evolution in metallic materials has always been a research hotspot in the field of metal forming. To this end, and in the context of metal forming process simulation, an advanced mathematical material model is crucial. In this paper, we investigate the accuracy of two fully-coupled damage models, one of which is phenomenologically-based and the other one micromechanically-based, in predicting the failure in DP900 steel plates subject to various loading paths. These are applied throughout tests, including tensile tests on unnotched and notched specimens with different notch radii as well as butterfly wing shear tests. Through the comparisons of the numerical and experimental results, in terms of force-displacement curves and fracture strains (or ductility) under wide range of strain paths, the accuracy of the proposed two coupled damage models are discussed.

AB - Correct prediction of the fracture time and location and their evolution in metallic materials has always been a research hotspot in the field of metal forming. To this end, and in the context of metal forming process simulation, an advanced mathematical material model is crucial. In this paper, we investigate the accuracy of two fully-coupled damage models, one of which is phenomenologically-based and the other one micromechanically-based, in predicting the failure in DP900 steel plates subject to various loading paths. These are applied throughout tests, including tensile tests on unnotched and notched specimens with different notch radii as well as butterfly wing shear tests. Through the comparisons of the numerical and experimental results, in terms of force-displacement curves and fracture strains (or ductility) under wide range of strain paths, the accuracy of the proposed two coupled damage models are discussed.

KW - Damage model

KW - Failure prediction

KW - Full coupling

KW - Loading paths

KW - Plastic deformation

KW - 22/2 OA procedure

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SN - 0921-5093

VL - 811

JO - Materials Science & Engineering A

JF - Materials Science & Engineering A

M1 - 140978

ER -

Broad stress triaxiality ratio band fracture experiments in DP900 metal sheets and corresponding predictive capability of advanced phenomenological and micromechanical fully coupled damage models

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