Experimental and numerical analysis of the flow behaviour of magnesium wrought alloy AZ31 for deep drawing processes at elevated temperatures

Research output: Chapter in book/report/conference proceedingConference contributionResearchpeer review

Authors

  • B. A. Behrens
  • A. Bouguecha
  • T. Huinink
  • I. Peshekhodov
  • T. Matthias
  • J. Moritz
  • J. Schrödter
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Details

Original languageEnglish
Title of host publicationComputational Plasticity XII
Subtitle of host publicationFundamentals and Applications - Proceedings of the 12th International Conference on Computational Plasticity - Fundamentals and Applications, COMPLAS 2013
Pages1198-1209
Number of pages12
Publication statusPublished - 1 Dec 2013
Event12th International Conference on Computational Plasticity: Fundamentals and Applications, COMPLAS 2013 - Barcelona, Spain
Duration: 3 Sept 20135 Sept 2013

Publication series

NameComputational Plasticity XII: Fundamentals and Applications - Proceedings of the 12th International Conference on Computational Plasticity - Fundamentals and Applications, COMPLAS 2013

Abstract

In the present paper, the flow behaviour of the magnesium wrought alloy AZ31 is analysed experimentally and numerically. Especial in deep drawing processes is the knowledge of the flow behaviour important. Depending on the type and size of the hardening and softening of a material, the process parameters such as temperature and sheet thickness must be adjusted to produce a flawless part. The material behaviour of magnesium is different compared to conventional steels, because the hardening and softening effects are changing highly with increasing temperature. For this purpose, yield curves were recorded experimentally at different temperatures by means of layer compression tests. Following the yield curves were converted based on the principle of the plastic work equivalence for finite element simulations (FEA). For validation, numerical simulations of the layer compression test at elevated temperature using the converted yield curve were carried out.

Keywords

    Deep drawing, FEA, Magnesium, Material characterisation

ASJC Scopus subject areas

Cite this

Experimental and numerical analysis of the flow behaviour of magnesium wrought alloy AZ31 for deep drawing processes at elevated temperatures. / Behrens, B. A.; Bouguecha, A.; Huinink, T. et al.
Computational Plasticity XII: Fundamentals and Applications - Proceedings of the 12th International Conference on Computational Plasticity - Fundamentals and Applications, COMPLAS 2013. 2013. p. 1198-1209 (Computational Plasticity XII: Fundamentals and Applications - Proceedings of the 12th International Conference on Computational Plasticity - Fundamentals and Applications, COMPLAS 2013).

Research output: Chapter in book/report/conference proceedingConference contributionResearchpeer review

Behrens, BA, Bouguecha, A, Huinink, T, Peshekhodov, I, Matthias, T, Moritz, J & Schrödter, J 2013, Experimental and numerical analysis of the flow behaviour of magnesium wrought alloy AZ31 for deep drawing processes at elevated temperatures. in Computational Plasticity XII: Fundamentals and Applications - Proceedings of the 12th International Conference on Computational Plasticity - Fundamentals and Applications, COMPLAS 2013. Computational Plasticity XII: Fundamentals and Applications - Proceedings of the 12th International Conference on Computational Plasticity - Fundamentals and Applications, COMPLAS 2013, pp. 1198-1209, 12th International Conference on Computational Plasticity: Fundamentals and Applications, COMPLAS 2013, Barcelona, Spain, 3 Sept 2013.
Behrens, B. A., Bouguecha, A., Huinink, T., Peshekhodov, I., Matthias, T., Moritz, J., & Schrödter, J. (2013). Experimental and numerical analysis of the flow behaviour of magnesium wrought alloy AZ31 for deep drawing processes at elevated temperatures. In Computational Plasticity XII: Fundamentals and Applications - Proceedings of the 12th International Conference on Computational Plasticity - Fundamentals and Applications, COMPLAS 2013 (pp. 1198-1209). (Computational Plasticity XII: Fundamentals and Applications - Proceedings of the 12th International Conference on Computational Plasticity - Fundamentals and Applications, COMPLAS 2013).
Behrens BA, Bouguecha A, Huinink T, Peshekhodov I, Matthias T, Moritz J et al. Experimental and numerical analysis of the flow behaviour of magnesium wrought alloy AZ31 for deep drawing processes at elevated temperatures. In Computational Plasticity XII: Fundamentals and Applications - Proceedings of the 12th International Conference on Computational Plasticity - Fundamentals and Applications, COMPLAS 2013. 2013. p. 1198-1209. (Computational Plasticity XII: Fundamentals and Applications - Proceedings of the 12th International Conference on Computational Plasticity - Fundamentals and Applications, COMPLAS 2013).
Behrens, B. A. ; Bouguecha, A. ; Huinink, T. et al. / Experimental and numerical analysis of the flow behaviour of magnesium wrought alloy AZ31 for deep drawing processes at elevated temperatures. Computational Plasticity XII: Fundamentals and Applications - Proceedings of the 12th International Conference on Computational Plasticity - Fundamentals and Applications, COMPLAS 2013. 2013. pp. 1198-1209 (Computational Plasticity XII: Fundamentals and Applications - Proceedings of the 12th International Conference on Computational Plasticity - Fundamentals and Applications, COMPLAS 2013).
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abstract = "In the present paper, the flow behaviour of the magnesium wrought alloy AZ31 is analysed experimentally and numerically. Especial in deep drawing processes is the knowledge of the flow behaviour important. Depending on the type and size of the hardening and softening of a material, the process parameters such as temperature and sheet thickness must be adjusted to produce a flawless part. The material behaviour of magnesium is different compared to conventional steels, because the hardening and softening effects are changing highly with increasing temperature. For this purpose, yield curves were recorded experimentally at different temperatures by means of layer compression tests. Following the yield curves were converted based on the principle of the plastic work equivalence for finite element simulations (FEA). For validation, numerical simulations of the layer compression test at elevated temperature using the converted yield curve were carried out.",
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AU - Behrens, B. A.

AU - Bouguecha, A.

AU - Huinink, T.

AU - Peshekhodov, I.

AU - Matthias, T.

AU - Moritz, J.

AU - Schrödter, J.

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