| METALS AND METAL MATRIX COMPOSITES |
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| Research Progress on the Tribological Properties of Textured Surfaces |
| ZHONG Bing1,2, XING Zhiguo2, WANG Haidou2, LYU Xiaoren1, HUANG Yanfei2, GUO Weiling2, ZHANG Zhong1,2
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1 School of Mechanical Engineering, Shenyang University of Technology, Shenyang 110870, China
2 National Key Laboratory for Remanufacturing, Army Academy of Armored Forces, Beijing 100072, China |
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Abstract As a method to improve the surface properties, surface texture has become a hot topic in the field of surface engineering at home and abroad. With the rapid development of fine processing technology, one can control the size and shape of the surface texture to improve the surface properties of the sample. Biomimetic technology provides a source of surface texture design, and the surface properties of the surface of the organism can be processed to the surface of the material to enhance its surface properties. The research on precise fabrication of surface texture and the modeling of factors affecting processing has made great progress, but the research on effectiveness of surface texturing under certain contact conditions is still in research stage. Current research indicates that no texture design can be applied to any solution, as most surface texture techniques can only be applied to specific dimensions and geometries, and different techniques are required for different problems.
The textured surface has better tribological properties than the untextured surface. In this paper, the tribological properties of textured surfaces are discussed. Firstly, the method of preparing microstructures on the surface of materials by laser etching, chemical etching, photoetching technology, electrochemical processing technology, laser shot peening technology and ultrasonic vibration assisted processing technology are introduced. By changing the geometry of the surface texture of the processed surface. Different friction and anti-wear textures can be obtained under the conditions of size, processing precision and area density. Then the friction reduction mechanism under different friction states is analyzed. Finally, the advantages and disadvantages of various surface texture preparation techniques are summarized.
At present, the research on the optimal texture parameters is still in progress, and the effectiveness of anti-friction anti-wear surface texture depends mainly on the actual contact situation and application. The number of parameters of surface texture design is large, mainly including texture shape, area density, feature size and so on. The texturing technique must be optimized to allow the surface texture to have regular geometric shapes and feature sizes. Therefore, the prediction of the optimal texture parameters will be necessary. Simulating the friction and wear of the surface texture under different friction conditions can replace the “repetitive test” which is time-consuming and expensive, and provides convenience for the rapid development of the mechanical field and the medical field. Finally, outlook the textured surface.
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Published: 24 December 2020
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| Fund:This work was financially supported by the National Natural Science Foundation of China (NSFC) (51775554, 51535011). |
About author:: Bing Zhong graduated from Qiqihar University in July 2018 with a bachelor’s degree in engineering. She is currently a master student at the School of Mechanical Engineering of Shenyang University of Technology. The research was conducted under the guidance of professor Xiaoren Lyu, assistant researcher Zhiguo Xing, and researcher Haidou Wang. At present, the main research direction is surface texture of materials.
Zhiguo Xing is an assistant researcher of National Key Laboratory for Remanufacturing. He mainly engages in teaching and researching in the field of tribology and remanufacturing life assessment. He is currently the deputy director of the Youth Friction Working Committee of the Tribology Branch of the Chinese Society of Mechanical Engineering; writer of the entry for the green manufacturing chapter of the third edition of the mechanical engineering volume; a member of the Ministry of Education’s 10 000 scientific problem manufacturing volume writing group;a reviewer of three international and domestic SCI and EI indexed journals. He won 1 second prize of Beijing Natural Science, ranking 5th. Authorized 30 kinds of patents, including 2 US invention patents, 11 national invention patents, 17 national utility model patents and software copyrights. A total of 49 academic papers were published, of which 22 were the first author and corresponding authors, 8 were retrieved by SCI, and 13 were retrieved by EI. |
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2020, Vol. 34 
