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Study of anisotropic plastic behavior in high pressure torsion of aluminum single crystal by crystal plasticity finite element method

Journal Article


Abstract


  • In this study, a crystal plasticity finite element method (CPFEM) model has been developed to investigate the anisotropic plastic behavior of (001) aluminum single crystal during high-pressure torsion (HPT). The distributions of equivalent plastic strain and Mises stress recorded on the sample surface are presented. The directional variations of plastic strain and Mises stress with the development of four-fold symmetry pattern are observed along the sample circumference. The crystallographic orientation evolution along the tangential direction is studied, and the corresponding lattice rotation and slip trace are predicted, respectively. The plastic anisotropy mechanism is discussed in detail based on the theory of crystal plasticity. The simulation results reveal that the differences in slip systems activation (dominant slip and multiple slips) are responsible for the anisotropic plastic deformation in HPT.

Publication Date


  • 2017

Citation


  • Wei, P., Lu, C., Liu, H., Su, L., Deng, G. & Tieu, K. (2017). Study of anisotropic plastic behavior in high pressure torsion of aluminum single crystal by crystal plasticity finite element method. Crystals, 7 (12), 362-1-362-11.

Scopus Eid


  • 2-s2.0-85037740927

Start Page


  • 362-1

End Page


  • 362-11

Volume


  • 7

Issue


  • 12

Place Of Publication


  • Switzerland

Abstract


  • In this study, a crystal plasticity finite element method (CPFEM) model has been developed to investigate the anisotropic plastic behavior of (001) aluminum single crystal during high-pressure torsion (HPT). The distributions of equivalent plastic strain and Mises stress recorded on the sample surface are presented. The directional variations of plastic strain and Mises stress with the development of four-fold symmetry pattern are observed along the sample circumference. The crystallographic orientation evolution along the tangential direction is studied, and the corresponding lattice rotation and slip trace are predicted, respectively. The plastic anisotropy mechanism is discussed in detail based on the theory of crystal plasticity. The simulation results reveal that the differences in slip systems activation (dominant slip and multiple slips) are responsible for the anisotropic plastic deformation in HPT.

Publication Date


  • 2017

Citation


  • Wei, P., Lu, C., Liu, H., Su, L., Deng, G. & Tieu, K. (2017). Study of anisotropic plastic behavior in high pressure torsion of aluminum single crystal by crystal plasticity finite element method. Crystals, 7 (12), 362-1-362-11.

Scopus Eid


  • 2-s2.0-85037740927

Start Page


  • 362-1

End Page


  • 362-11

Volume


  • 7

Issue


  • 12

Place Of Publication


  • Switzerland