Superplasticity of Inconel 718 after processing by high-pressure sliding (HPS)

Abstract

This study reports a production of a superplastic Ni-based superalloy (Inconel 718) using a process of severe plastic deformation through high-pressure sliding (HPS). The grain size of the alloy was reduced to ~120nm by operating the HPS process under 4GPa at room temperature with a recently upscaled facility. The ultrafined-grained structure was well retained even after annealing at 1173K for 1h. Tensile tests were conducted in air at a testing temperature in the range of 973–1173K with an initial strain rate of 5.0×10−4–2.0×10−2s−1. Superplastic elongation more than 400% were attained at all testing conditions except at 973K. High-strain rate superplasticity (defined with strain rates higher than 1×10−2s−1) was achieved at temperatures higher than 1073K. Electron back scatter diffraction analyses revealed that a preferential orientation of the grains was developed by the HPS processing but it was randomized with tensile deformation. Evaluation of the strain rate sensitivity and the activation energy for the superplastic deformation confirmed that the superplasticity of Inconel 718 was controlled by grain boundary sliding through lattice diffusion.