Microstructure evolution and wear behavior of titanium alloy under cryogenic dry sliding wear condition

Microstructure evolution and wear behavior of Ti6Al4V alloy under cryogenic dry sliding wear condition was investigated. An external cryogenic device was designed to produce a steady cryogenic environment (−172 °C) during the wear process. We found that the near surface microstructure of Ti6Al4V all...

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Bibliographic Details
Published in:Materials characterization 2020-07, Vol.165, p.110385, Article 110385
Main Authors: Weng, Zeju, Gu, Kaixuan, Cui, Chen, Cai, Huikun, Liu, Xuanzhi, Wang, Junjie
Format: Article
Language:English
Subjects:
Cryogenic temperature
Dislocation
Microstructure
Plastic deformation
Ti6Al4V titanium alloy
Wear behavior
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Summary:Microstructure evolution and wear behavior of Ti6Al4V alloy under cryogenic dry sliding wear condition was investigated. An external cryogenic device was designed to produce a steady cryogenic environment (−172 °C) during the wear process. We found that the near surface microstructure of Ti6Al4V alloy exhibited obvious accumulation of dislocations in the grain boundaries of α phase, as well as the refinement of α and β phase grains during cryogenic temperature wear. On the contrary, the plastic deformation was predominated by twins during room temperature wear. Under cryogenic temperature wear, little plastic deformation of microstructure was observed in the near surface and subsurface of specimens, while severe deformation was found to be prevalent under room temperature wear. Worn surfaces of specimens after cryogenic wear tests were smoother with lower block spalling and friction coefficient. The cryogenic wear behavior was considered to be fracture spalling of surface induced by the initiation and extension of fatigue cracks, unlike the severe oxidative and delamination wear under room temperature. Meanwhile, as compared to room temperature wear, wear rate of Ti6Al4V alloy was reduced by 49.7%, 57.2% and 36.6% under the loading force of 100 N, 150 N and 200 N respectively after cryogenic temperature wear. •Cryogenic and room temperature wear (CT/RT) of Ti6Al4V alloy were studied comparatively.•Dislocation dominated after CT wear while twins prevailed after RT wear.•Main mechanism of CT wear was fracture spalling instead of oxidative and delamination.•Wear resistance of Ti6Al4V alloy was improved by 57.2% under cryogenic environment.
ISSN:1044-5803
1873-4189
DOI:10.1016/j.matchar.2020.110385