Tensile, Creep, and Low-Cycle Fatigue Behavior of a Cast gamma-TiAl-Based Alloy for Gas Turbine Applications

摘要

The influence of chemical composition on the microstructure of the gamma-titanium aluminide alloy Ti-48A1-2W-0.5Si (at. pct) and the accompanying tensile, low-cycle fatigue, and creep properties has been evaluated. The study showed that small variations in chemical composition and casting procedures resulted in considerable variations in the microstructure, yielding vastly different mechanical properties. Low contents of aluminum and tungsten led to a coarse-grained lamellar (gamma/alpha_2) microstructure with high creep resistance. A composition close to the nominal one produced a duplex (gamma + gamma/alpha_2) structure with favorable strength, ductility, and low-cycle fatigue properties. By controlling the solidification and cooling rates at casting, a pseudoduplex (PS-DP) microstructure with a unique combination of high strength and high fatigue and creep resistance can be obtained. These unique properties can be explained by the diffuse boundaries between the relatively small gamma grains and the neighboring lamellar colonies, combined with semicoherent interfaces between the gamma and alpha_2 phases. At tensile and low-cycle fatigue loading, these boundaries act like high-angle boundaries, producing a virtually fine-grained material promoting strength, whereas at creep loading, grain-boundary sliding is hindered in the semicoherent interfaces leading to high creep resistance.