Wear mechanism transforming of ultrafine-grained pure titanium by multi-axial forging and low-temperature annealing

• Published in: Journal of materials research and technology Vol. 28; pp. 2980 - 2989
• Main Authors: Chen, Rongyou, Guo, Shubo, Zhao, Xiaolian, Yin, Yutang, Du, Sijie, Song, Yang, Liang, Wei, Jiang, Aoke, He, Yiting, Wei, Chunhua
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.01.2024; Elsevier
• Subjects: Microstructure; Multi-axial forging; Pure titanium; Ultrafine grain; Wear mechanism; Pure titanium; Multi-axial forging; Wear mechanism; Microstructure; Ultrafine grain
• ISSN: 2238-7854
• DOI: 10.1016/j.jmrt.2023.12.229

The effect of microstructure and mechanical properties of submicro grained commercial pure titanium (CP–Ti) on the wear mechanism is still unclear. In the present work, CP-Ti samples were subjected to multi-axial forging (MAF) and low-temperature annealing treatment to prepare ultrafine-grained (UFG) material. The mechanical properties, microstructure, and tribological characterization between coarse-grained (CG) sample and UFG samples were comparatively studied. The results showed that the MAF sample could reach a grain size of 165 nm, while its grains coarsened slightly after low-temperature annealing. The MAF sample had the highest strength and hardness and the lowest coefficient of friction, but only a 7.3 % decrease in wear rate compared to the CG sample. The 400 °C annealed MAF sample possessed a good combination of tensile strength (814 MPa) and elongation (18.6 %), resulting in the lowest wear rate of 16.8 × 10−5mm3/(N∙m). The dominated wear mechanisms of the CG sample, MAF sample and 500 °C annealed MAF sample were abrasive wear, adhesive wear and delamination wear, while the primary mechanism of the 400 °C annealed MAF sample was abrasive wear and adhesive wear. It was found that the wear mechanism transforming, higher hardness and sufficient work hardening could be responsible for lower wear rate of the 400 °C annealed MAF sample. The 400 °C annealed MAF sample showed a thinner and more homogeneous deformation layer near the worn surface, and its thickness of deformation layer was about 8 μm. [Display omitted] •Commercial pure titanium samples were processed by multi-axial forging and low-temperature annealing.•Multi-axial forging and low-temperature annealing caused wear mechanism transforming.•The deformation layers near the worn surface were compared.