Effect of laser shock peening on the surface integrity and fretting fatigue properties of high-strength titanium alloy TC21

材料科学 微动 喷丸 激光喷丸 喷丸 钛合金 休克(循环) 合金 冶金 疲劳极限 激光器 表面完整性 复合材料 残余应力 光学 医学 物理 内科学
作者
Bowen Song,Xibin Wang,Lijing Xie,Junfeng Xiang,Xiangping Zou,Shikun Zou
出处
期刊:Journal of materials research and technology [Elsevier BV]
卷期号:33: 4533-4547 被引量:6
标识
DOI:10.1016/j.jmrt.2024.10.130
摘要

High-strength titanium alloy TC21 is often used to make aircraft load-bearing components in the aviation field. However, due to vibration, load-bearing components often suffer from fretting fatigue (FF), which greatly reduces their actual service life. Nowadays, laser shock peening (LSP) is being recognized as an effective strengthening process for many materials. Therefore, in this study, the effectiveness of LSP on the strengthening of high-strength titanium alloy TC21 is studied, in terms of surface integrity and FF properties. TC21 fretting specimens and tests are designed. Before fretting tests, the specimens are processed by LSP with varying laser pulse energies, number of shocks and overlap rate, and their surface integrity and FF properties are analyzed. It is found that the greater the laser pulse energy and number of shocks, the higher the surface hardness and compressive residual stress, the more the grain refinement, the greater the improvement in FF life. Under 32J-50%-T1, the FF life is improved by 191.3% compared with BM. But the overlap rate has little effect on surface integrity and FF life. Meanwhile, there forms amorphous structures, which tended to be transformed into nanograins during fretting process. This transformation is helpful for prolonging FF life due to its action of energy absorption. This study reveals the strengthening mechanism of LSP on TC21 and its effect on the FF properties of TC21 specimens.
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