Faceted crack induced failure behavior and micro-crack growth based strength evaluation of titanium alloys under very high cycle fatigue

Wei Li; Meng Li; Rui Sun; Xinxin Xing; Ping Wang; Tatsuo Sakai

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Faceted crack induced failure behavior and micro-crack growth based strength evaluation of titanium alloys under very high cycle fatigue

机译：极高循环疲劳下钛合金的多面裂纹诱导失效行为和基于微裂纹增长的强度评估

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摘要

Very high cycle fatigue properties of titanium alloys under symmetrical and asymmetrical loads were experimentally examined to clarify the failure behavior. An inhomogeneous microstructure zone (IMZ) containing facets is observable. By focused ion beam testing, the interior micro-crack extends along the maximum shear stress plane and the facet plane is about 45°. By the modeling of growth rate and the definition of controlling line, a strength evaluation approach with the failure behavior was well proposed. This reflects that the micro-crack growth rate in IMZ stage is below one Burger's vector.

机译：通过实验研究了钛合金在对称和不对称载荷下的极高循环疲劳性能，以阐明破坏行为。可以观察到包含刻面的不均匀微结构区（IMZ）。通过聚焦离子束测试，内部微裂纹沿着最大剪切应力平面延伸，并且小平面大约为45°。通过对增长率的建模和控制线的定义，很好地提出了一种具有破坏行为的强度评估方法。这反映出IMZ阶段的微裂纹增长率低于一个Burgers向量。

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来源
《International Journal of Fatigue》 |2020年第2期|105369.1-105369.11|共11页
作者
Wei Li; Meng Li; Rui Sun; Xinxin Xing; Ping Wang; Tatsuo Sakai;
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作者单位

School of Mechanical Engineering Beijing Institute of Technology Beijing 100081 China;

Institute of Oceanographic Instrumentation Shandong Academy of Sciences Qingdao 266001 China;

College of Science and Engineering Ritsumeikan University Kusatsu 5258577 Japan;

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收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);
原文格式 PDF
正文语种 eng
中图分类
关键词
Titanium alloys; Very high cycle fatigue; Inhomogeneous microstructure zone; Micro-crack growth modeling; Strength evaluation;

机译：钛合金;极高的循环疲劳;微结构区不均匀;微裂纹增长建模;强度评估;

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1. Subsurface facets-induced crack nucleation behavior and microstructure- based strength evaluation of titanium alloys in ultra-long life regime [J] . Li Wei, Xing Xinxin, Gao Ning, Materials Science and Engineering . 2019,第JULa22期

机译：钛合金在超长寿命条件下的亚表面刻面诱导的裂纹成核行为和基于显微组织的强度评估
2. Subsurface facets-induced crack nucleation behavior and microstructure- based strength evaluation of titanium alloys in ultra-long life regime [J] . Li Wei, Xing Xinxin, Gao Ning, Materials Science and Engineering . 2019,第Jul22期

机译：地下刻面诱导的超长寿命制度钛合金基于裂纹成核行为和基于微观结构的强度评价
3. Crack initiation and early growth behavior of TC4 titanium alloy under high cycle fatigue and very high cycle fatigue [J] . Li Wei, Gao Ning, Zhao Hongqiao, Journal of Materials Research . 2018,第8期

机译：TC4钛合金在高周疲劳和极高周疲劳下的裂纹萌生和早期生长行为
4. Threshold fatigue crack growth behavior of the gamma titanium aluminide alloy Ti-46.5Al-3Nb-2Cr-0.2W under high cycle fatigue conditions [C] . Brian D.Worth, James M.Larsen, Andrew H.Rosenberger Structural intermetallics 1997 . 1997

机译：高循环疲劳条件下γ-铝化钛合金Ti-46.5Al-3Nb-2Cr-0.2W的阈值疲劳裂纹扩展行为
5. Fatigue and Crack-Growth Behavior in a Titanium Alloy Under Constant-Amplitude and Spectrum Loading [D] . Kota, Kalyan Raj. 2018

机译：恒定振幅和频谱载荷下钛合金的疲劳和裂纹扩展行为
6. Very High Cycle Fatigue Failure Analysis and Life Prediction of Cr-Ni-W Gear Steel Based on Crack Initiation and Growth Behaviors [O] . Hailong Deng, Wei Li, Tatsuo Sakai, 2015

机译：基于裂纹萌生和生长行为的Cr-Ni-W齿轮钢超高周疲劳失效分析和寿命预测
7. Very High Cycle Fatigue Failure Analysis and Life Prediction of Cr-Ni-W Gear Steel Based on Crack Initiation and Growth Behaviors [O] . Hailong Deng, Wei Li, Tatsuo Sakai, 2015

机译：基于裂纹萌生和生长行为的Cr-Ni-W齿轮钢超高周疲劳失效分析及寿命预测
8. Fatigue Crack Growth Behavior of Small and Large Cracks in Titanium Alloys andIntermetallics [R] . Ravichandran, K. S. 1993

机译：钛合金和金属间件中小裂纹和大裂纹的疲劳裂纹扩展行为

Faceted crack induced failure behavior and micro-crack growth based strength evaluation of titanium alloys under very high cycle fatigue

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