Achieving fine-grained equiaxed alpha via thermo-mechanical loading under off-equilibrium state in two-phase Ti-alloys

Abstract

An off-equilibrium hot deformation scheme was proposed to achieve fine-grained equiaxed alpha (αs) for two-phase titanium alloys. Controlled cooling and deformation was carried out at the soaking temperatures of 950–990 ℃,cooling rates of 50–140 ℃/min and strain rates of 0.01–0.1 s−1 in TA15 alloy. The results showed that fully fine-grained equiaxed αs (∼500 nm) was obtained after heating to near β-transus temperature, fast cooling (i.e., >140 ℃/min) and subsequent hot deformation at strain rates above 0.1 s-1. The transformation of nucleation mode from complete wetting to incomplete wetting promoted by hot deformation mainly resulted in the formation of fine equiaxed αs at the β/β grain boundaries. For intragranular αs phase, selective heterogeneous nucleation at dislocations with reduced nucleation barrier and weak variant selection mainly led to the formation of equiaxed α precipitates. A comparison among different off-equilibrium cases revealed that flow stress was decreased greatly by increasing the soaking temperature due to more αp → β transformation. This would provide a novel path to achieve grain refinement of equiaxed structure with decreased forming load and low cost.