1 State Key Laboratory of Advanced Special Steel, Shanghai Key Laboratory of Advanced Ferrous Metallurgy, School of Materials Science and Engineering, Shanghai University, Shanghai 200444, China 2 Institute of Material Science and Engineering, National Taiwan University, Taipei 10617, Taiwan, China
1 State Key Laboratory of Advanced Special Steel, Shanghai Key Laboratory of Advanced Ferrous Metallurgy, School of Materials Science and Engineering, Shanghai University, Shanghai 200444, China 2 Institute of Material Science and Engineering, National Taiwan University, Taipei 10617, Taiwan, China
摘要 Te is widely used in iron and steel industry. After adding a certain amount of Te in the steel, many physical and chemical properties can be improved. As a free-cutting element, a small amount of Te can significantly improve the machinability of steel. The existing form of Te in the steel, the modification law of MnS inclusion by Te and the influence rule and mechanism of Te on the machinability of steel are summarized and expounded in detail, providing a reference for further study and development of Te-containing free-cutting steels.
Abstract:Te is widely used in iron and steel industry. After adding a certain amount of Te in the steel, many physical and chemical properties can be improved. As a free-cutting element, a small amount of Te can significantly improve the machinability of steel. The existing form of Te in the steel, the modification law of MnS inclusion by Te and the influence rule and mechanism of Te on the machinability of steel are summarized and expounded in detail, providing a reference for further study and development of Te-containing free-cutting steels.
CHEN Beng,YANG Qian-Kun,ZHANG Dong, et al. Application of tellurium in free-cutting steels[J]. Journal of Iron and Steel Research International, 2018, 25(8): 787-795.
[1]
Y. Dai, New type of Te-Ni-Cr alloy of the high-temperature oxidation resistance, Lanzhou University of Technology, 2011 (in Chinese).
[2]
Y. Hao, P. Zhu, Z. Li, J. Gansu U. Techno. 17 (1991) 53-57 (in Chinese).
[3]
I. V. Popova, A. G. Nasibov, G. G. Gulei, G. A. Sveshnikova, Met. Sci. Heat Treat. 28 (1986) 52-55.
[4]
S. Yao, D. Wang, Hebei Metall. (1992) 38-41 (in Chinese).
[5]
S. Liu, China Nonferrous Metall. (1983) 65-66 (in Chinese).
[6]
S. Liu, Non-ferrous Met. Rareearth, (1995) 16-21 (in Chinese).
[7]
P. Zhu, G. Zhang, H. Ren, Y. Hao, J. Gansu U. Techno. 12 (1986) 51-57 (in Chinese).
[8]
H. Yaguchi, N. Onodera, Trans. Inst. Iron Steel Inst. Jpn. 28 (1988) 1051-1059.
[9]
N. E. Luiz, á. R. Machado, Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 222 (2008) 347-360.
[10]
P. Reynolds, V. Block, I. Essel, F. Klocke, Steel Res. Int. 78 (2007) 908-914.
[11]
W. D. Cobb, W. W. Foster, T. S. Harrison, Analyst, 101 (1976) 39-43.
[12]
J. Ding, Heat Treat. Techno. Equip. (1986) 8-12 (in Chinese).
[13]
T. Katoh, S. Abeyama, A. Kimura, S. Nakamura, Denki Seiko(Electr. Furn. Steel), 53 (1982) 195-202 (in Japanese).
[14]
S. Abeyama, S. Nakamura, Jpn. Inst. Met. 21 (2011) 363-365.
[15]
A. Kimura, K. Nishikiori, Denki Seiko (Electr. Furn. Steel), 59 (1989) 59-64 (in Japanese).
[16]
J. Xu, X. Zhang, Y. Yin, China Writ. Instrum. (2014) 27-44 (in Chinese).
[17]
D. Bhattacharya, D. T. Quinto, Metall. Trans. A, 11 (1980) 919-934.
[18]
Y. Liu, J. Dong, Auto. Technol. Mater. (2009) 50-54 (in Chinese).
[19]
T. B. Smith, D. B. Clayton, Nature, 198 (1963) 380-381.
[20]
D. Li, S. Gao, L. Zhang, Z. Wang, X. Dong, Iron Steel, 22 (1987) 38-44 (in Chinese).
[21]
G. Gupta, D. G. C. Robertson, M. E. Schlesinger, Can. Metall. Q. 44 (2013) 351-356.
[22]
J. A. Dean, Lange's handbook of chemistry, 13th ed. Science press, Beijing, 2003.
[23]
I. Barin, F. Sauert, E. Schultze-rhonhof, S. S. Wang, Thermochemical data of pure substances, Science Press, Beijing, 2003 (in Chinese).
[24]
J. D. Watson, Microscopy and the development of free-machining steels, Springer US, New York, United States, 1986.
[25]
M. E. Schlesinger, J. Phase Equilib. 19 (1998) 591-596.
[26]
H. Yaguchi, Metall. Trans. A, 24 (1993) 504-508.
[27]
T. Y. Tien, L. H. Van Vlack, R. J. Martin, Umr, (1967) 1-6.
[28]
G. Yan, Study of technology theory and quality control for free-cutting machinability of medium-carbon-steel, University of Science and Technology Beijing, 2006 (in Chinese).
[29]
X. Zhou, Study on the morphology control of sulfide inclusion in free-cutting steel 30MnVS, Southeast University, 2009 (in Chinese).
[30]
F. Duan, R. Zhu, T. Lin, J. Iron. Steel Res. 24 (2012) 36-39 (in Chinese).
[31]
E. Costa, N. Luiz, M. D. Silva, A. Machado, E. Ezugwu, Ind. Lubr. Tribol. 63 (2011) 420-426.
[32]
G. Luo, H. Wang, Shanghai Met. 37 (2015) 10-14 (in Chinese).
[33]
Y. Wang, F. Wang, Numerical study on cutting performance of free cutting stainless steel used in ball pen, Xian University of Architecture and Technology, 2016 (in Chinese).
[34]
P. Gao, K. Chen, Q. Dai, A. Meng, T. Dai, Mater. Mech. Eng. 34 (2010) 41-45 (in Chinese).
[35]
A. Mahmutoviü, M. Rimac, J. Trands Dev. Mach. Assoc. Technol. 19 (2015) 53-56.
[36]
Z. Sun, Study on recovery and purification of tellurium from copper anode slime and relative fundamental theory, Central South University, 2012 (in Chinese).
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