Investigation on the Very High Cycle Fatigue Life of Titanium Alloys by Near-β Forging and Shot Peening

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Qiangang Xu, Yonghui Chen, Kai Pan, Xingwei Xu, Fei Zhao, Kai Guo, Xiaotao Liu, Zhen Zhang
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Abstract

In order to enhance the fatigue properties of metallic materials, a feasible rationale is to delay or prevent the interior and surface fatigue crack initiation. Based on this rationale, the study investigates the approach of improving the very high cycle fatigue properties of TC6 titanium alloys through near-β forging coupled with shot peening, conducted at 930 ℃ and ambient temperature, respectively. To unveil the associated mechanisms, microstructure, microhardness, residual stress, and fatigue properties are thoroughly analyzed after each process. Results indicate a considerable refinement in microstructure and significant mitigation of the initially existed strong texture post near-β forging and annealing, efficiently delaying crack initiation and propagation. As a result, the very high cycle fatigue property of TC6 achieves remarkable enhancement after forging. Compared to near-β forging, shot peening might not necessarily improve the very high cycle fatigue performance, particularly beyond 106 cycles.

Abstract Image

通过近β锻造和喷丸强化研究钛合金的超高循环疲劳寿命
为了提高金属材料的疲劳性能,一种可行的方法是延迟或防止内部和表面疲劳裂纹的产生。基于这一原理,本研究分别在 930 ℃ 和常温下,通过近 β 锻造和喷丸强化,研究了改善 TC6 钛合金超高循环疲劳性能的方法。为了揭示相关的机理,对每个过程后的显微结构、显微硬度、残余应力和疲劳特性进行了全面分析。结果表明,在近β锻造和退火后,微观结构得到了显著改善,最初存在的强纹理也得到了明显缓解,从而有效地延缓了裂纹的产生和扩展。因此,TC6 的高循环疲劳性能在锻造后得到显著提高。与近β锻造相比,喷丸强化不一定能改善超高循环疲劳性能,尤其是超过 106 个循环后。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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