Numerical Evaluation of Surface Roughness Influences on Cold Formability of Dual-Phase Steel

Peerapon Wechsuwanmanee; Junhe Lian; Wenqi Liu; Sebastian Münstermann

doi:10.1002/srin.202000141

Numerical Evaluation of Surface Roughness Influences on Cold Formability of Dual-Phase Steel

Peerapon Wechsuwanmanee^*, Junhe Lian, Wenqi Liu, Sebastian Münstermann

^*Corresponding author for this work

Department of Energy and Mechanical Engineering

RWTH Aachen University

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

5 Citations (Scopus)

78 Downloads (Pure)

Abstract

DP1000 steel sheets with different surface treatments are taken to three-point bending tests to evaluate their damage and fracture behavior. It is found that different surface treatments yield different fracture behaviors. Conventional finite-element (FE) simulation with an uncoupled material model is able to capture the material's response only for the sheets with the perfectly smooth surface condition. A multiscale strategy is introduced to quantitatively include the surface information into the material model. The localization at the microlevel simulation allows adjusting the fracture criterion of the surface elements in the macrolevel simulation. Therefore, a good agreement between FE simulation and experiment is yielded.

Original language	English
Article number	2000141
Number of pages	8
Journal	Steel Research International
Volume	91
Issue number	11
Early online date	3 Jul 2020
DOIs	https://doi.org/10.1002/srin.202000141
Publication status	Published - 1 Nov 2020
MoE publication type	A1 Journal article-refereed

Keywords

DP1000
dual-phase steel
ductile damage
modified Bai-Wierzbicki model
surface roughness

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ENG_Wechsuwanmanee_et_al_Numerical_Evaluation_of_Surface_Steel_ResearchFinal published version, 2.28 MBLicence: Unspecified

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title = "Numerical Evaluation of Surface Roughness Influences on Cold Formability of Dual-Phase Steel",

abstract = "DP1000 steel sheets with different surface treatments are taken to three-point bending tests to evaluate their damage and fracture behavior. It is found that different surface treatments yield different fracture behaviors. Conventional finite-element (FE) simulation with an uncoupled material model is able to capture the material's response only for the sheets with the perfectly smooth surface condition. A multiscale strategy is introduced to quantitatively include the surface information into the material model. The localization at the microlevel simulation allows adjusting the fracture criterion of the surface elements in the macrolevel simulation. Therefore, a good agreement between FE simulation and experiment is yielded.",

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AU - Liu, Wenqi

AU - Münstermann, Sebastian

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N2 - DP1000 steel sheets with different surface treatments are taken to three-point bending tests to evaluate their damage and fracture behavior. It is found that different surface treatments yield different fracture behaviors. Conventional finite-element (FE) simulation with an uncoupled material model is able to capture the material's response only for the sheets with the perfectly smooth surface condition. A multiscale strategy is introduced to quantitatively include the surface information into the material model. The localization at the microlevel simulation allows adjusting the fracture criterion of the surface elements in the macrolevel simulation. Therefore, a good agreement between FE simulation and experiment is yielded.

AB - DP1000 steel sheets with different surface treatments are taken to three-point bending tests to evaluate their damage and fracture behavior. It is found that different surface treatments yield different fracture behaviors. Conventional finite-element (FE) simulation with an uncoupled material model is able to capture the material's response only for the sheets with the perfectly smooth surface condition. A multiscale strategy is introduced to quantitatively include the surface information into the material model. The localization at the microlevel simulation allows adjusting the fracture criterion of the surface elements in the macrolevel simulation. Therefore, a good agreement between FE simulation and experiment is yielded.

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KW - modified Bai-Wierzbicki model

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Numerical Evaluation of Surface Roughness Influences on Cold Formability of Dual-Phase Steel

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