Microstructure and mechanical properties of Ti–V–Al–Cu shape memory alloy by tailoring Cu content

The microstructure, martensitic transformation behavior, mechanical and shape memory properties of the Ti–V–Al–Cu light weight shape memory alloys were investigated systematically. The results showed that the phase constitution gradually evolved from single α″ martensite phase to the complete β phas...

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Published inMaterials science & engineering. A, Structural materials : properties, microstructure and processing Vol. 771; p. 138641
Main Authors Sun, Kuishan, Yi, Xiaoyang, Sun, Bin, Yin, Xinghe, Meng, Xianglong, Cai, Wei, Zhao, Liancheng
Format Journal Article
LanguageEnglish
Published Elsevier B.V 13.01.2020
Subjects
Light weight shape memory alloy
Martensitic transformation
Mechanical properties
Microstructure
Ti–V–Al alloy
Mechanical properties
Martensitic transformation
Light weight shape memory alloy
Microstructure
Ti–V–Al alloy
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Abstract The microstructure, martensitic transformation behavior, mechanical and shape memory properties of the Ti–V–Al–Cu light weight shape memory alloys were investigated systematically. The results showed that the phase constitution gradually evolved from single α″ martensite phase to the complete β phase with the Cu content increasing in the solution treated Ti–13V–3Al-xCu alloys at room temperature. The spear-like martensite variant constituted the typical self-accommodation configuration, and {111} type I twins and type II twins coexisted in the Ti–V–Al–Cu alloys. Moreover, Ti2Cu precipitate can be observed in the Ti–V–Al–Cu alloys with the higher Cu contents. The martensitic transformation temperature of Ti–V–Al–Cu alloys decreased continuously with the increased Cu content. The Ti–V–Al–Cu alloys with the higher transformation temperature and higher strength as well as the superior shape recovery characteristics can be obtained by tailoring Cu content. It was the perfect combination of solid solution strengthening, grain refinement and precipitation strengthening to promote the enhancement of matrix strength. The maximum recoverable strain was 4.4%, for 6% pre-strain and the reverse martensite transformation temperature was 334 °C in the optimal Ti–13V–3Al-0.5Cu alloy.
AbstractList The microstructure, martensitic transformation behavior, mechanical and shape memory properties of the Ti–V–Al–Cu light weight shape memory alloys were investigated systematically. The results showed that the phase constitution gradually evolved from single α″ martensite phase to the complete β phase with the Cu content increasing in the solution treated Ti–13V–3Al-xCu alloys at room temperature. The spear-like martensite variant constituted the typical self-accommodation configuration, and {111} type I twins and type II twins coexisted in the Ti–V–Al–Cu alloys. Moreover, Ti2Cu precipitate can be observed in the Ti–V–Al–Cu alloys with the higher Cu contents. The martensitic transformation temperature of Ti–V–Al–Cu alloys decreased continuously with the increased Cu content. The Ti–V–Al–Cu alloys with the higher transformation temperature and higher strength as well as the superior shape recovery characteristics can be obtained by tailoring Cu content. It was the perfect combination of solid solution strengthening, grain refinement and precipitation strengthening to promote the enhancement of matrix strength. The maximum recoverable strain was 4.4%, for 6% pre-strain and the reverse martensite transformation temperature was 334 °C in the optimal Ti–13V–3Al-0.5Cu alloy.
ArticleNumber 138641
Author Yin, Xinghe
Meng, Xianglong
Zhao, Liancheng
Yi, Xiaoyang
Sun, Kuishan
Sun, Bin
Cai, Wei
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Keywords Mechanical properties
Martensitic transformation
Light weight shape memory alloy
Microstructure
Ti–V–Al alloy
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Snippet The microstructure, martensitic transformation behavior, mechanical and shape memory properties of the Ti–V–Al–Cu light weight shape memory alloys were...
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StartPage 138641
SubjectTerms Light weight shape memory alloy
Martensitic transformation
Mechanical properties
Microstructure
Ti–V–Al alloy
Title Microstructure and mechanical properties of Ti–V–Al–Cu shape memory alloy by tailoring Cu content
URI https://dx.doi.org/10.1016/j.msea.2019.138641
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