Superplasticity of Nb-Si-Fe and TiAl Intermetallics Synthesized by Powder Metallurgy

Kai Feng Zhang; Shao Song Jiang; Zhen Lu; Guo Feng Wang; Chun Ping Zhang; Ji Liang Yu

doi:10.4028/www.scientific.net/MSF.735.113

Paper Titles

Enhanced Plastic Deformation of Magnesium Alloy Produced through Accumulative Diffusion Bonding
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High-Temperature Deformation of Magnesium Elektron^TM 43
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Precise Calibration of Displacement Vector Map during Superplastic Deformation in Tetragonal Zirconia Polycrystal
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Superplastically Foaming Method for Reliable Porous Ceramics
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Superplasticity of Nb-Si-Fe and TiAl Intermetallics Synthesized by Powder Metallurgy
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Recent Insights on the Superplastic Behaviour of Ceramics
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Improving Thickness Uniformity of Ti₃Al Sheet Metal SPF by Preforming
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Superplastic Bulging of Nanocrystalline Ni-Co Alloy with Different Heating Methods
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Superplasticity in the Aerospace Titanium Alloy Ti-5553
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HomeMaterials Science ForumMaterials Science Forum Vol. 735Superplasticity of Nb-Si-Fe and TiAl...

Superplasticity of Nb-Si-Fe and TiAl Intermetallics Synthesized by Powder Metallurgy

Abstract:

Nb-16Si-2Fe alloy were processed by mechanical alloying (MA) and hot pressing sintering (HPS). Microstructure analysis revealed the presence of four phases: Nb solid solution (Nbss), three kinds of intermetallics Nb3Si, Nb5Si3 and Nb4Fe3Si5. The maximum elongation over 500% was obtained at 1450°C and strain rate of 2.31×10-4s-1. TiAl powder pre-alloyed was carried out on pulse current sintering equipment (PCS) with high heating rate. The effect of heating rate on microstructures and high temperature ductility was investigated. The results show that relatively high heating rate is beneficial for obtaining fine grained microstructures. And the resultant intermetallic alloy with equiaxed near gamma structures exhibits superplasticity at relatively low temperature.