METALS AND METAL MATRIX COMPOSITES |
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Research Progress on Very High Cycle Fatigue Performance and Damage Mechanism of High Strength Steel Under Corrosion Condition |
WU Xingjun1,2, CHEN Yueliang2,*, ZHANG Yong2, BIAN Guixue2, ZHANG Yangguang2, WANG Andong2, ZHANG Zhuzhu1
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1 92728 Troops, Shanghai 200040, China 2 Naval Aeronautical University Qingdao Branch, Qingdao 266041, Shandong, China |
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Abstract The process of crack initiation, propagation and fracture with more than 107 cycles under fatigue load is called very high cycle fatigue. Parts of machines made of high strength steel need to be used in corrosive environment, and they need to bear up to 108—1011 fatigue loads during the service life. The problem of very high cycle fatigue of high strength steel in corrosive environment has become a key problem affecting the reliability and safety of structures, and it has become an urgent difficulty to be solved in aerospace, automobile, high-speed railway and other fields. Thanks to the summary and accumulation of metal materials on traditional fatigue problems and the help of advanced test methods, many scholars have developed a variety of new test methods to study the very high cycle fatigue of high strength steel under corrosive conditions. At present, the core problems such as the degradation law and damage mechanism of very high cycle fatigue properties of high strength steel under corrosive conditions, the competition mechanism of crack initiation and initial crack propagation behavior under corrosive conditions, and the effect of hydrogen on very high cycle fatigue properties of high strength steel and the formation mechanism of granular bright facet are becoming more and more clear. Moreover, some research results have been gradually applied in engineering practice. In this review, the very high cycle fatigue damage characteristics of high strength steel without corrosion are briefly described from the perspective of S-N curve. Then the effects of typical corrosive media on very high cycle fatigue properties of high strength steel are summarized, also it is pointed out that hydrogen embrittlement fracture is one of the fracture mechanisms of high strength steel in corrosive environment. Then, the research progress of hydrogen on very high cycle fatigue properties of high strength steel and the formation mechanism of granular bright facet are described in detail. Finally, several key issues are prospected.
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Published: 25 June 2023
Online: 2023-06-20
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Fund:National Natural Science Foundation of China (51375490) and ‘Green Innovation Science and Technology Plan’ of Colleges and Universities in Shandong Province (2020KJA014). |
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