Effect of Al2O3 particles on mechanical properties of directionally solidified intermetallic Ti–46Al–2W–0.5Si alloy

Abstract

The effect of Al2O3 particles on microhardness and room-temperature compression properties of directionally solidified (DS) intermetallic Ti–46Al–2W–0.5Si (at.%) alloy was studied. The ingots with various volume fractions of Al2O3 particles and mean α2–α2 interlamellar spacings were prepared by directional solidification at constant growth rates ranging from 2.78×10−6 to 1.18×10−4 ms−1 in alumina moulds. The ingots with constant volume fraction of Al2O3 particles and various mean interlamellar spacings were prepared by directional solidification at a growth rate of 1.18×10−4 ms−1 and subsequent solution annealing followed by cooling at constant rates v̇ varying between 0.078 and 1.889 K s−1. The mean α2–α2 interlamellar spacing λ for both DS and heat-treated (HT) ingots decreased with increasing cooling rate according to the relationship λ∝ν̇−0.46. In DS ingots, microhardness, ultimate compression strength, yield strength and plastic deformation to fracture increased with increasing cooling rate. In HT ingots, microhardness and yield strength increased and ultimate compression strength and plastic deformation to fracture decreased with increasing cooling rate. The yield stress increased with decreasing interlamellar spacing and increasing volume fraction of Al2O3 particles. A linear relationship between the Vickers microhardness and yield stress was found for both DS and HT ingots. A simple model including the effect of interlamellar spacing and increasing volume fraction of Al2O3 particles was proposed for the prediction of the yield stress.