Porous-ductile fracture in thermo-elasto-plastic solids with contact applications

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • M. Krüger
  • M. Dittmann
  • F. Aldakheel
  • A. Härtel
  • P. Wriggers
  • C. Hesch

Organisationseinheiten

Externe Organisationen

  • Universität Siegen
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Details

OriginalspracheEnglisch
Seiten (von - bis)941-966
Seitenumfang26
FachzeitschriftComputational mechanics
Jahrgang65
Ausgabenummer4
Frühes Online-Datum11 Dez. 2019
PublikationsstatusVeröffentlicht - Apr. 2020

Abstract

Industrial forming processes depend on several physical effects, including large deformation thermomechanical damage, localized near the contact zone of the forming tools. The main challenge in this process relies on the detailed knowledge of the desired thermoplastic effects at finite strains and the undesired initiation of macro-cracks. For the numerical solution of this problem, a regularized sharp crack surface in the framework of a phase-field approach is combined here with a modified, thermomechanical Gurson–Tvergaard–Needelman GTN-type plasticity model, such that we obtain a thermodynamically consistent framework. This allows to adapt this highly complex multi-field model using variationally consistent Mortar contact formulations in a straightforward manner. Eventually, the proposed approach is tested on complex three-dimensional geometries, emanating from industrial relevant forming processes.

ASJC Scopus Sachgebiete

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Porous-ductile fracture in thermo-elasto-plastic solids with contact applications. / Krüger, M.; Dittmann, M.; Aldakheel, F. et al.
in: Computational mechanics, Jahrgang 65, Nr. 4, 04.2020, S. 941-966.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Krüger M, Dittmann M, Aldakheel F, Härtel A, Wriggers P, Hesch C. Porous-ductile fracture in thermo-elasto-plastic solids with contact applications. Computational mechanics. 2020 Apr;65(4):941-966. Epub 2019 Dez 11. doi: 10.1007/s00466-019-01802-3
Krüger, M. ; Dittmann, M. ; Aldakheel, F. et al. / Porous-ductile fracture in thermo-elasto-plastic solids with contact applications. in: Computational mechanics. 2020 ; Jahrgang 65, Nr. 4. S. 941-966.
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title = "Porous-ductile fracture in thermo-elasto-plastic solids with contact applications",
abstract = "Industrial forming processes depend on several physical effects, including large deformation thermomechanical damage, localized near the contact zone of the forming tools. The main challenge in this process relies on the detailed knowledge of the desired thermoplastic effects at finite strains and the undesired initiation of macro-cracks. For the numerical solution of this problem, a regularized sharp crack surface in the framework of a phase-field approach is combined here with a modified, thermomechanical Gurson–Tvergaard–Needelman GTN-type plasticity model, such that we obtain a thermodynamically consistent framework. This allows to adapt this highly complex multi-field model using variationally consistent Mortar contact formulations in a straightforward manner. Eventually, the proposed approach is tested on complex three-dimensional geometries, emanating from industrial relevant forming processes.",
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AU - Krüger, M.

AU - Dittmann, M.

AU - Aldakheel, F.

AU - Härtel, A.

AU - Wriggers, P.

AU - Hesch, C.

N1 - Funding Information: Support for this research was provided by the Deutsche Forschungsgemeinschaft (DFG) under Grants HE5943/8-1 and DI2306/1-1. This support is gratefully acknowledged.

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Y1 - 2020/4

N2 - Industrial forming processes depend on several physical effects, including large deformation thermomechanical damage, localized near the contact zone of the forming tools. The main challenge in this process relies on the detailed knowledge of the desired thermoplastic effects at finite strains and the undesired initiation of macro-cracks. For the numerical solution of this problem, a regularized sharp crack surface in the framework of a phase-field approach is combined here with a modified, thermomechanical Gurson–Tvergaard–Needelman GTN-type plasticity model, such that we obtain a thermodynamically consistent framework. This allows to adapt this highly complex multi-field model using variationally consistent Mortar contact formulations in a straightforward manner. Eventually, the proposed approach is tested on complex three-dimensional geometries, emanating from industrial relevant forming processes.

AB - Industrial forming processes depend on several physical effects, including large deformation thermomechanical damage, localized near the contact zone of the forming tools. The main challenge in this process relies on the detailed knowledge of the desired thermoplastic effects at finite strains and the undesired initiation of macro-cracks. For the numerical solution of this problem, a regularized sharp crack surface in the framework of a phase-field approach is combined here with a modified, thermomechanical Gurson–Tvergaard–Needelman GTN-type plasticity model, such that we obtain a thermodynamically consistent framework. This allows to adapt this highly complex multi-field model using variationally consistent Mortar contact formulations in a straightforward manner. Eventually, the proposed approach is tested on complex three-dimensional geometries, emanating from industrial relevant forming processes.

KW - Ductile fracture modeling

KW - Finite deformations

KW - GTN model

KW - Mortar contact method

KW - Phase-field approach

KW - Thermomechanics

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VL - 65

SP - 941

EP - 966

JO - Computational mechanics

JF - Computational mechanics

SN - 0178-7675

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