The relationship between the stress state and the deep-drawn deformation structure of Mg-1.5Zr alloy was studied. The alloy blanks, made from cast material, were deep-drawn at 300°C with a drawing ratio of 1.7. A series of circular laser-etched marks, made on the blank surface from the center to the rim of the blank, were used to measure strains in various directions caused during deep-drawing. The results indicated that since no shear stress is generated at the bottom of the cup due to equal biaxial tension, slip deformation is unlikely to occur and hence no development of basal texture is observed, however a large number of twins were formed. The R part of the cup is also biaxially tensioned, but the shear stress is |σr-σθ| and conjugated shear stress is generated due to bending, which promotes the formation of new crystals and twin deformation. Along the side wall from the R toward the rim areas of the cup, there is a transition area where σθ changes from tension to compression and as compression strain increases, basal texture develops significantly. The main deformation mechanism is by twin when σθ is “tensile” and by slip when σθ is “compression”. © 2022 The Japan Institute of Light Metals
