Stepped superplasticity deformation-induced plastic enhancement of Ti–6Al–1.5Cr–2.5Mo–0.5Fe–0.3Si alloy

Abstract

A novel superplasticity deformation (SPD) approach called stepped superplasticity deformation (Stepped-SPD) is proposed for the SPD of Ti–6Al–1.5Cr–2.5Mo–0.5Fe–0.3Si alloy. The effect of Stepped-SPD process on the microstructural evolution and mechanical properties of Ti–6Al–1.5Cr–2.5Mo–0.5Fe–0.3Si alloy was explored by the Stepped-SPD tensile experiment which was divided into two forming steps to carry out. The former step adopted the constant speed deformation and the latter one chose the maximum m superplasticity deformation (MaxmSPD). The plastic strain in the former step and clearance time between the two steps in Stepped-SPD were controlled in order to facilitate the grain refinement and microstructure property improvement which induced plastic enhancement. Furthermore, the single-step constant velocity SPD (ConstvSPD) and the single-step MaxmSPD tensile tests were also conducted. The experimental results of Ti–6Al–1.5Cr–2.5Mo–0.5Fe–0.3Si alloy showed that the Stepped-SPD tensile method obtained the best SPD capability, with an elongation of 2053%, whereas the MaxmSPD and constant speed tensile method produced the biggest elongations of 1347% and 753.9%, respectively. Thus, it is indicated that the Stepped-SPD induces the plastic enhancement in comparison with the single-step deformation method.