Crystal plasticity finite element modelling of the extrusion texture of a magnesium alloy.
- Resource Type
- Article
- Authors
- Yichuan Shao; Tao Tang; Dayong Li; Weiqin Tang; Yinghong Peng
- Source
- Modelling & Simulation in Materials Science & Engineering. Jul2015, Vol. 23 Issue 5, p1-1. 1p.
- Subject
- *CRYSTALS
*FINITE element method
*COHESION
*ELASTICITY
*MAGNESIUM
- Language
- ISSN
- 0965-0393
In this paper, a crystal plasticity finite-element model (CPFEM) is developed to simulate the hot extrusion texture of the magnesium alloy AZ31. The crystal plasticity model is implemented in ABAQUS™ via user interface VUMAT subroutine. The elasto-plastic self-consistent (EPSC) model is used as the basic polycrystal framework to simulate the slip and twinning during the extrusion. Furthermore, this framework is extended to account for the effects of the dynamically recrystallized (DRX) grains on the extrusion textures. Good agreement is found between the experimentally measured and simulated textures. The simulation results show that the presence of a secondary texture component around || extrusion direction (ED) can be attributed to the lattice rotation around the c-axis during the formation of the DRX grains. In addition, the shear strain imposed on the extruded material affects the resulting texture by enhancing the basal slip mode as the material passes through the extrusion opening. [ABSTRACT FROM AUTHOR]