Evaluation of elastic-viscoplastic self-consistent models for a rolled AZ31B magnesium alloy under monotonic loading along five different material orientations and free-end torsion

Comprehensive experiments including monotonic tension and monotonic compression of specimens taken from a rolled AZ31B Mg thick plate along five different material orientations with respect to the rolled direction (RD), and free-end torsion of a tubular specimen machined along the thickness direction (ND) were conducted. The experimental results were used to evaluate an elastic-viscoplastic self-consistent model with the consideration of twinning and detwinning (EVPSC-TDT) on magnesium (Mg) alloys. The EVPSC-TDT model provides stress-strain curves and the hardening rates in close agreement with the experimental results of all the 11 loading cases. The model adequately predicts the textures after fracture of all the 11 loading cases and the evolutions of tension twins with increasing strains for tension in the ND, compression in the RD, and torsion along the ND. The Swift effect was observed in the experiment and was properly simulated by the model.

Automated summary

Comprehensive experiments were conducted on a rolled AZ31B Mg thick plate and a tubular specimen to evaluate the elastic-viscoplastic self-consistent model with twinning and detwinning (EVPSC-TDT) on magnesium alloys. The model accurately predicted stress-strain curves, hardening rates, textures after fracture, and tension twin evolutions for different loading conditions. The experiment also observed the Swift effect, which was properly simulated by the model.