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8For citation: ZHOU Cong. Analysis of solid boronizing and high frequency induction heating surface heat treatment technology //
URL: http://rectors.altstu.rU/ru/periodical/archiv/2021/1/articles/3_15.pdf DOI: 10.25712/ASTU.2410-485X.2021.01.030
UDK 669.017.3
Analysis of solid boronizing and high frequency induction
heating surface heat treatment technology
ZHOU Cong1
1 Hubei Digital Textile Equipment Key Laboratory, Wuhan Textile University, Wuhan 430073, China
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(References)
[1] Chen Shuwang, Chen Weidong. Research and application of solid boronizing technology [J]. Heat Treatment, 2011, 26(03):1-8.
[2] Zhou Yang. Study on the boronizing kinetics of Cr structural steel [J]. Mechanical Design and Manufacturing Engineering, 2013, 42(11): 79-83.
[3] Xu Bin, Feng Chengming, Nie Chengfang. 45~# The effect of the brittleness of the boronized steel layer on its wear resistance [J]. Journal of Tribology, 1999(04): 354-357.
[4] Zhou Peifu. Characteristics, problems, countermeasures and prospects of powder solid boronizing [J]. Heat Treatment of Metals, 1980(10): 1-7.
[5] Wu Luzhou, Yang Di. Low voltage and high current short-time heating direct boronizing eutectic process [J]. Journal of Inner Mongolia Institute of Technology, 1986(02): 45-52.
[6] Chen Shuwang, Chen Weidong, Wang Quansheng. Research on the technology and organization of high frequency induction heating boronizing and eutecticization [J]. Heat Treatment, 2014, 29(02): 34-40.
[7] Liu Chao, Chen Zhen, Mei Shunqi, Butukhanov Viacheslav, Tsydypov Bulat, Lygdenov Burial. Research on High Frequency Electromagnetic Induction Boronizing Process of 55 Steel[J]. Thermal Processing Technology, 2020, 49(10): 117-120.
