Vacuum Levels Needed to Simulate Internal Fatigue Crack Growth in Titanium Alloys and Nickel-Base Superalloys: Thermodynamic Considerations

V. Sinha; J. M. Larsen

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Vacuum Levels Needed to Simulate Internal Fatigue Crack Growth in Titanium Alloys and Nickel-Base Superalloys: Thermodynamic Considerations

机译：模拟钛合金和镍基高温合金内部疲劳裂纹扩展所需的真空水平：热力学考虑

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Prior studies have examined fatigue growth of surface cracks in vacuum to simulate subsurface growth in Ti alloys and Ni-base superalloys. Even with the highest vacuum level attained using “state-of-the-art” pumps, it is unclear if conditions of internal crack growth are truly simulated. We consider thermodynamics of the oxidation process to help answer this question. This consideration helps explain a previously reported anomalous behavior of longer life in air than in vacuum under certain material/test conditions.

机译：先前的研究已经检查了真空中表面裂纹的疲劳增长，以模拟Ti合金和Ni基高温合金的地下生长。即使使用“最先进”的泵达到了最高真空水平，也不清楚内部裂纹扩展的条件是否是真实模拟的。我们认为氧化过程的热力学可以帮助回答这个问题。这种考虑有助于解释先前报道的在某些材料/测试条件下在空气中的寿命比在真空中更长的异常行为。

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《Metallurgical and Materials Transactions A》 |2012年第10期|p.3433-3441|共9页
作者
V. Sinha; J. M. Larsen;
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UES, Inc, Dayton, OH, 45432, USA;

Air Force Research Laboratory, Materials and Manufacturing Directorate, AFRL/RXLM, Wright-Patterson Air Force Base, OH, 45433, USA;

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1. Vacuum Levels Needed to Simulate Internal Fatigue Crack Growth in Titanium Alloys and Nickel-Base Superalloys: Thermodynamic Considerations [J] . V. SINHA, J.M. LARSEN Metallurgical and Materials Transactions, A. Physical Metallurgy and Materials Science . 2012,第10期

机译：模拟钛合金和镍基高温合金内部疲劳裂纹扩展所需的真空水平：热力学考虑
2. Effect of nitrogen content on microstructure and fatigue crack growth rate of high titanium-alloyed superalloy [J] . Gao Xiaoyong, Zhang Lin, Chen Xiaowei, Materials Characterization . 2020,第1期

机译：氮含量对高钛合金超合金微观结构和疲劳裂纹生长速率的影响
3. The mechanism of internal fatigue-crack initiation and early growth in a titanium alloy with lamellar and equiaxed microstructure [J] . Xiangnan Pan, Shouwen Xu, Guian Qian, Materials Science and Engineering . 2020,第Nova4期

机译：钛合金内疲劳裂纹引发和早期生长的机理，具有层状合金和等式的微观结构
4. FATIGUE CRACK GROWTH OF TITANIUM ROTOR ALLOYS IN VACUUM AND AIR [C] . R. S. Piascik, Y. Gill, C. Date, International symposium on fatigue behavior of titanium alloys . 1999

机译：真空和空气中钛转子合金的疲劳裂纹生长
5. APPLICATION OF FRACTURE MECHANICS PRINCIPLES TO FATIGUE CRACK GROWTH IN A POWDER METALLURGY NICKEL-BASE SUPERALLOY (STRAIN ENERGY DENSITY, SHORT CRACK, ELEVATED TEMPERATURE, ASTROLOGY). [D] . VECCHIO, ROBERT SCOTT. 1985

机译：断裂力学原理在粉末冶金镍基高温合金中疲劳裂纹扩展的应用（主能密度，短裂纹，升高的温度，占星学）。
6. Effect of Heat Treatment Process on Microstructure and Fatigue Behavior of a Nickel-Base Superalloy [O] . Peng Zhang, Qiang Zhu, Gang Chen, 2015

机译：热处理工艺对镍基高温合金组织和疲劳行为的影响
7. The mechanism of internal fatigue-crack initiation and early growth in a titanium alloy with lamellar and equiaxed microstructure [O] . Xiangnan Pan, Shouwen Xu, Guian Qian, 2020

机译：钛合金内疲劳裂纹引发和早期生长的机理，具有层状合金和等式的微观结构
8. Vacuum Levels Needed to Simulate Internal Fatigue Crack Growth in Titanium Alloys and Nickel-base Superalloys: Thermodynamic Considerations. [R] . Sinha, V., Larsen, J. M. 2012

机译：模拟钛合金和镍基高温合金内部疲劳裂纹扩展所需的真空水平：热力学考虑因素。

Vacuum Levels Needed to Simulate Internal Fatigue Crack Growth in Titanium Alloys and Nickel-Base Superalloys: Thermodynamic Considerations

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