Plastic Flow and Microstructure Evolution During Low Temperature Superplasticity of Ultrafine Ti-6AL-4V Sheet Material (Preprint)
Abstract
The low-temperature superplastic flow behavior of two lots of Ti-6Al-4V sheet, each with an ultrafine microstructure, was established by performing tension tests at temperatures of 775 and 815 degrees C and true strain rates of 10-4 and 10-3 s-1. The as-received microstructures of the two materials comprised either equiaxed or slightly-elongated alpha particles in a beta matrix. The material with equiaxed-alpha particles exhibited flow hardening which was correlated with concurrent (dynamic) coarsening. The rate of dynamic coarsening was rationalized in terms of static coarsening measurements and the enhancement of kinetics due to pipe diffusion. By contrast, the material with initially elongated alpha particles exhibited comparable flow hardening at the lower strain rate but a complex, near-steady state behavior at the higher strain rate. These latter observations were explained on the basis of evolution of alpha-particle shape and size during straining; dynamic coarsening or dynamic spheroidization was concluded to be most important at the lower and higher strain rates, respectively. The plastic-flow behavior was interpreted in the context of a long-wavelength flow-localization analysis.
Document Details
- Document Type
- Technical Report
- Publication Date
- Apr 01, 2009
- Accession Number
- ADA502898
Entities
People
- A. Zane
- Ashish Ghosh
- G. A. Sargent
- J. F. Betten
- P. N. Fagin
- Sheldon Lee Semiatin
Organizations
- Air Force Research Laboratory