Approach for modelling the Taylor-Quinney coefficient of high strength steels

Publikation: Beitrag in FachzeitschriftKonferenzaufsatz in FachzeitschriftForschungPeer-Review

Autoren

  • Bernd Arno Behrens
  • Alexander Chugreev
  • Florian Bohne
  • Ralf Lorenz

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Details

OriginalspracheEnglisch
Seiten (von - bis)464-471
Seitenumfang8
FachzeitschriftProcedia Manufacturing
Jahrgang29
Frühes Online-Datum4 Apr. 2019
PublikationsstatusVeröffentlicht - 2019
Veranstaltung18th International Conference on Sheet Metal, SHEMET 2019 - Leuven, Belgien
Dauer: 15 Apr. 201917 Apr. 2019

Abstract

Precise knowledge of the temperature that arises in the material during plastic forming is of crucial importance, as it has a significant influence on material behaviour and therefore on the forming process. In order to describe the amount of heat that is generated during plastic forming accurately, the Taylor-Quinney coefficient β was introduced as the ratio of dissipated heat to plastic work and generally assumed to be a constant value. However, recent studies have shown that there is a dependency on material and process-specific parameters. In this study, the Taylor-Quinney coefficient β is shown as a function of strain and being influenced by the test specific strain rate and stress state. The tested material is a dual-phase steel HCT980X. The uniaxial tensile test and the Marciniak test with different tallied specimen at forming-relevant global strain rates were investigated. By means of thermographic and optical measuring systems the temperature and local strains were recorded during the tests. Based on an approach similar to the finite volume method, both experimental setups were modelled taking heat transfer effects into account. As a result, the Taylor-Quinney coefficient is calculated by means of experimental data. It is shown that the Taylor-Quinney coefficient is a variable value depending on the flow behaviour of the steel. The local strain rate and the specimen geometries of Marciniak test have a significant influence on the arising heat conduction. The stress state, however, has minor influence on β.

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Approach for modelling the Taylor-Quinney coefficient of high strength steels. / Behrens, Bernd Arno; Chugreev, Alexander; Bohne, Florian et al.
in: Procedia Manufacturing, Jahrgang 29, 2019, S. 464-471.

Publikation: Beitrag in FachzeitschriftKonferenzaufsatz in FachzeitschriftForschungPeer-Review

Behrens, BA, Chugreev, A, Bohne, F & Lorenz, R 2019, 'Approach for modelling the Taylor-Quinney coefficient of high strength steels', Procedia Manufacturing, Jg. 29, S. 464-471. https://doi.org/10.1016/j.promfg.2019.02.163
Behrens, B. A., Chugreev, A., Bohne, F., & Lorenz, R. (2019). Approach for modelling the Taylor-Quinney coefficient of high strength steels. Procedia Manufacturing, 29, 464-471. https://doi.org/10.1016/j.promfg.2019.02.163
Behrens BA, Chugreev A, Bohne F, Lorenz R. Approach for modelling the Taylor-Quinney coefficient of high strength steels. Procedia Manufacturing. 2019;29:464-471. Epub 2019 Apr 4. doi: 10.1016/j.promfg.2019.02.163
Behrens, Bernd Arno ; Chugreev, Alexander ; Bohne, Florian et al. / Approach for modelling the Taylor-Quinney coefficient of high strength steels. in: Procedia Manufacturing. 2019 ; Jahrgang 29. S. 464-471.
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abstract = "Precise knowledge of the temperature that arises in the material during plastic forming is of crucial importance, as it has a significant influence on material behaviour and therefore on the forming process. In order to describe the amount of heat that is generated during plastic forming accurately, the Taylor-Quinney coefficient β was introduced as the ratio of dissipated heat to plastic work and generally assumed to be a constant value. However, recent studies have shown that there is a dependency on material and process-specific parameters. In this study, the Taylor-Quinney coefficient β is shown as a function of strain and being influenced by the test specific strain rate and stress state. The tested material is a dual-phase steel HCT980X. The uniaxial tensile test and the Marciniak test with different tallied specimen at forming-relevant global strain rates were investigated. By means of thermographic and optical measuring systems the temperature and local strains were recorded during the tests. Based on an approach similar to the finite volume method, both experimental setups were modelled taking heat transfer effects into account. As a result, the Taylor-Quinney coefficient is calculated by means of experimental data. It is shown that the Taylor-Quinney coefficient is a variable value depending on the flow behaviour of the steel. The local strain rate and the specimen geometries of Marciniak test have a significant influence on the arising heat conduction. The stress state, however, has minor influence on β.",
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note = "Funding Information: The IGF-Project “Extension of heat release rate modeling for steels“of the European Research Association for Sheet Metal Working (EFB e.V.) was funded by the Federal Ministry of Economics and Energy (BMWi) under the funding number 19245N of the German Federation of Industrial Research Associations (AiF) on the basis of a decision by the German Bundestag. The authors would like to thank for this financial support.; 18th International Conference on Sheet Metal, SHEMET 2019 ; Conference date: 15-04-2019 Through 17-04-2019",
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T1 - Approach for modelling the Taylor-Quinney coefficient of high strength steels

AU - Behrens, Bernd Arno

AU - Chugreev, Alexander

AU - Bohne, Florian

AU - Lorenz, Ralf

N1 - Funding Information: The IGF-Project “Extension of heat release rate modeling for steels“of the European Research Association for Sheet Metal Working (EFB e.V.) was funded by the Federal Ministry of Economics and Energy (BMWi) under the funding number 19245N of the German Federation of Industrial Research Associations (AiF) on the basis of a decision by the German Bundestag. The authors would like to thank for this financial support.

PY - 2019

Y1 - 2019

N2 - Precise knowledge of the temperature that arises in the material during plastic forming is of crucial importance, as it has a significant influence on material behaviour and therefore on the forming process. In order to describe the amount of heat that is generated during plastic forming accurately, the Taylor-Quinney coefficient β was introduced as the ratio of dissipated heat to plastic work and generally assumed to be a constant value. However, recent studies have shown that there is a dependency on material and process-specific parameters. In this study, the Taylor-Quinney coefficient β is shown as a function of strain and being influenced by the test specific strain rate and stress state. The tested material is a dual-phase steel HCT980X. The uniaxial tensile test and the Marciniak test with different tallied specimen at forming-relevant global strain rates were investigated. By means of thermographic and optical measuring systems the temperature and local strains were recorded during the tests. Based on an approach similar to the finite volume method, both experimental setups were modelled taking heat transfer effects into account. As a result, the Taylor-Quinney coefficient is calculated by means of experimental data. It is shown that the Taylor-Quinney coefficient is a variable value depending on the flow behaviour of the steel. The local strain rate and the specimen geometries of Marciniak test have a significant influence on the arising heat conduction. The stress state, however, has minor influence on β.

AB - Precise knowledge of the temperature that arises in the material during plastic forming is of crucial importance, as it has a significant influence on material behaviour and therefore on the forming process. In order to describe the amount of heat that is generated during plastic forming accurately, the Taylor-Quinney coefficient β was introduced as the ratio of dissipated heat to plastic work and generally assumed to be a constant value. However, recent studies have shown that there is a dependency on material and process-specific parameters. In this study, the Taylor-Quinney coefficient β is shown as a function of strain and being influenced by the test specific strain rate and stress state. The tested material is a dual-phase steel HCT980X. The uniaxial tensile test and the Marciniak test with different tallied specimen at forming-relevant global strain rates were investigated. By means of thermographic and optical measuring systems the temperature and local strains were recorded during the tests. Based on an approach similar to the finite volume method, both experimental setups were modelled taking heat transfer effects into account. As a result, the Taylor-Quinney coefficient is calculated by means of experimental data. It is shown that the Taylor-Quinney coefficient is a variable value depending on the flow behaviour of the steel. The local strain rate and the specimen geometries of Marciniak test have a significant influence on the arising heat conduction. The stress state, however, has minor influence on β.

KW - Heat dissipation

KW - Heat transfer process

KW - Taylor-Quinney coefficient

KW - Temperature

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