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不同表面改性强化处理对TC4钛合金表面完整性及疲劳性能的影响
发布人:上海艾荔艾合金股份有限公司www.shailiai.cn
更新时间:2016-06-01
对 TC4 钛合金进行了喷丸强化、激光冲击强化和低塑性抛光 3 种表面强化改性处理, 测定了不同表面改性处理下的表面粗糙度、显微硬度、残余应力及微观组织, 研究了不同表面改性处理下的旋转弯曲疲劳性能, 利用 SEM 观察分析了疲劳断口特征, 提出了表面强化改性机理和效果评价方法.
不同表面改性强化处理对TC4钛合金表面完整性及疲劳性能的影响INFLUENCE OF DIFFERENT SURFACE MODIFICATION TREATMENTS ON SURFACE INTEGRITY AND FATIGUE PERFORMANCE OF TC4 TITANIUM ALLOY
对 TC4 钛合金进行了喷丸强化、激光冲击强化和低塑性抛光 3 种表面强化改性处理, 测定了不同表面改性处理下的表面粗糙度、显微硬度、残余应力及微观组织, 研究了不同表面改性处理下的旋转弯曲疲劳性能, 利用 SEM 观察分析了疲劳断口特征, 提出了表面强化改性机理和效果评价方法. 结果表明, 喷丸强化、激光冲击强化和低塑性抛光 3 种表面强化改性处理后, TC4 钛合金的旋转弯曲疲劳寿命提高, 疲劳强度也大幅度提升, 而且疲劳裂纹位于表面强化层下的次表层; 对于未表面强化改性处理的 TC4 钛合金, 疲劳裂纹位于表面. 基于位错理论, 对次表层裂纹萌生抗力和疲劳强度进行了分析并给出了定量分析模型.
TC4 titanium alloy is usually used to manufacture engine blades, blings or blisks and fatigue is the main failure of these components due to its high strength, good corrosion resistance and light weight. In engineering applications, three typical surface modification processes as shot peening (SP), laser shock peening (LSP) and low plasticity burnishing (LPB) were employed to improve fatigue performance. In this work, SP, LSP and LSB were taken to enhance surface layer of TC4 titanium alloy. The surface integrity of specimens including surface roughness, microhardness, residual stresses and microstructure was investigated to obtain the effects of modification on surface layer by different methods. The rotation bending fatigue performance was tested at room temperature and fatigue fracture surfaces were analyzed by SEM. Fatigue life was compared at the same stress 760 MPa with the referece machinced specimen. Fatigue strength was determined by stair method for 1×107 cyc. The results show that both the rotation bending fatigue life and fatigue strength of TC4 titanium alloy are increased by these surface modification processes. The fatigue life prolonging factor (FLPF) for SPed specimens is 20.4, and FLPF for LSPed specimens and LPBed specimens is 89.6 and 99, respectively. Meanwhile, fatigue strength improvement percentage (FSIP) for SPed, LSPed and LPBed specimens is 36.3%, 37.8% and 38.8%, respectively. Moreover, the fatigue cracks initiate beneath surface enhanced layer for surface-modified specimens, while they are located at surfaces for un-surface-enhanced ones. Based on dislocation theory, the subsurface cracks initiation resistance and fatigue strength for surface-enhanced specimens were analysied. Finally, surface modification mechanism was discussedand some quantitative analysis method on surface modification effects was proposed. For surface-enhanced smooth specimens, the FSIP limit is 40% based on proposed analysis model and it is verified in this work by different surface layer enhancement processes (36.3% for SPed specimens, 37.8% for LSPed and 38.8% for LPBed specimens are near to 40%). Fatigue total life including initiation and propagation is a complex problem, and therefore it is difficult to give accurate life prediction and analysis, especially for small crack growth, although some invesitigations on total fatigue life can be roughly estimated based on Basquin relation for stress fatigue life or Coffin and Marson equtionfor strain fatigue life which have not any physical meaning or any mechanism.
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