EFFECTS OF OXYGEN AND HEAT TREATMENT ON THE MECHANICAL PROPERTIES OF ALPHA AND BETA TITANIUM ALLOYS.

Two alloys, Ti-6Al-2V and Ti-2Al-16V, simulating the alpha and beta phases of Ti-6Al-4V, respectively, were prepared with oxygen concentrations from 0. 07 to 0. 65 wt pct (0. 20 to 1. 83 at. pct). Their microstructure, deformation behavior, and strength were investigated with X-ray diffraction, microscopy, and mechanical tests. The hardness increases in identical fashion with the square root of oxygen concentration. The strength also depends on heat treatment, but in different ways. Whereas the alpha alloy is non-age-hardenable, the beta alloy's strength can be doubled by aging. The hardening effect of oxygen is generally unaffected by heat treatment, except for alloys with the highest oxygen concentrations. During aging of the alpha a small amount of Ti//3Al can form and slight age hardening occurs. The ductility is little affected by aging. On the other hand, oxygen causes a change from good ductility at low oxygen concentration (0. 07 wt pct) to total brittleness at 0. 65 wt pct oxygen, independent of heat treatment. In the beta alloy there are complex phase transformations depending on heat treatment. Its deformation behavior varies from very ductile in solution-treated and quenched (STQ) condition to totally brittle in aged conditions. The aging embrittlement appears to be caused by alpha and some omega precipitation.