Materials Reports  2021, Vol. 35 Issue (Z1): 347-351 |
| METALS AND METAL MATRIX COMPOSITES |
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| Research Progress of Selective Laser Melting Additive Manufacturing Technology of Titanium Matrix Composites |
| ZHU Dong1,2, ZHANG Liang2,3, WU Wenheng2,3, LU Lin2,3, NI Xiaoqing2,3, SONG Jia2,3, ZHAO Jinmeng1,2, ZHU Wenhua1, GU Sunwang4, SHAN Xiaolong5
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1 Faculty of Engineering, Shanghai Polytechnic University, Shanghai 201209, China
2 Shanghai Research Institute of Materials, Shanghai 200437, China
3 Shanghai Engineering Research Center of 3D Printing Materials, Shanghai 200437, China
4 ZTT SRIM Additive Manufacturing Co., Ltd,Nantong 226000,China
5 Shanghai Zhongtian Aluminum Wire Co., Ltd,Shanghai 201100,China |
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Abstract Compared with titanium alloys, titanium-based matrix composites have higher hardness, strength and wear resistance, which can further expand the application scope of titanium alloys in aerospace, marine, medical and other fields. At the present, the preparation methods of titanium matrix composites can be divided into two categories: first, traditional methods, such as smelting and casting, have the problems of high energy consumption and high cost; secondly, the laser selective melting technology has the advantages of short processing time, high forming precision and no need to prepare the mold, but it also has some disadvantages such as easy spheroidization, cracking and reducing the plasticity of the forming part. This article reviews the current research progress of titanium-based matrix composites at home and abroad, including the inf-luence of reinforcement and process parameters on microstructure, forming quality and performance, and combines the current research situations to discuss and prospect the future development direction.
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Published: 16 July 2021
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| Fund:Project to Shanghai Rising-star Program (18QB1400600), Shanghai Polytechnic University Graduate Project Fund (EGD19YJ0086). |
| About author:: Dong Zhu, as a postgraduate student of Shanghai Polytechnic University, conducts research under the gui-dance of senior engineer Liang Zhang. At present, his main research direction is titanium and titanium-based composite materials for additive manufacturing.Liang Zhang, graduated from Delft University of Technology in the Netherlands in 2013. He is currently wor-king at the Shanghai Institute of Materials Research as the R&D director of the Shanghai 3D Printing Materials Engineering Technology Research Center. He is mainly engaged in the research of cutting-edge technologies such as metal 3D printing and material genomes, selec-ted into the Shanghai Youth Science and Technology Venus Program, Shanghai Academy of Sciences/Shanghai Institute of Industrial Technology "Innovation Pioneer" Program, and Hongkou Youth Top Talent Program. He is now serving as a member of the 11th Technical Committee of the Shanghai Institute of Materials Science and Technology, as a member of the Technical Committee of the Shanghai 3D Printing Materials Engineering Technology Research Center. He conducted over a number of scientific research projects of Shanghai Science and Technology Commission, Shanghai Academy of Sciences and Shanghai Institute of Materials, and successfully developed a high-quality metal powder consumable for 3D printing, such as titanium alloys for aviation, aerospace, molds, high-temperature alloys, and mold steels. |
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