Effects of elemental Sn on the properties and inclusions of the free-cutting steel

Shao-chun Chen; Rong Zhu; Li-qiu Xue; Teng-chang Lin; Jing-she Li; Yang Lin

doi:10.1007/s12613-015-1054-6

International Journal of Minerals, Metallurgy, and Materials ›› 2015, Vol. 22 ›› Issue (2) : 141 -148. DOI: 10.1007/s12613-015-1054-6

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Effects of elemental Sn on the properties and inclusions of the free-cutting steel

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Abstract

A new environment-friendly free-cutting steel alloyed with elemental Sn (Y20Sn) was developed to meet the requirements of machinability and mechanical properties according to GB/T8731—1988. The machinability of the steel is enhanced by the segregation of elemental Sn at grain boundaries. The effect of Sn segregation on intergranular brittle fracture at normal cutting temperature from 250°C to 400°C is confirmed. The formation mechanism of main inclusions MnS is influenced by the presence of Sn and the attachment of Sn around MnS itself as a surfactant, and this mechanism also explains the improvement in machinability and mechanical properties of the steel. In the steel, the relevant inclusions are mainly spherical or axiolitic, and are uniformly distributed in small volume. Such inclusions improve the machinability of the steel and do not impair the mechanical properties as well. Experimental results demonstrate that the appropriate content of Sn in the steel is 0.03wt% to 0.08wt%, and the remaining composition is close to that of standard Y20 steel.

Keywords

free-cutting steel / machinability / mechanical properties / inclusions / surfactant

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Shao-chun Chen, Rong Zhu, Li-qiu Xue, Teng-chang Lin, Jing-she Li, Yang Lin. Effects of elemental Sn on the properties and inclusions of the free-cutting steel. International Journal of Minerals, Metallurgy, and Materials, 2015, 22(2): 141-148 DOI:10.1007/s12613-015-1054-6

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References

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[1]	Jin HL. Recent progress on toxicity of lead. Trace Elem. Sci., 2004, 11(10): 9.

[2]	Yu YF, Ye ML, Zheng ZJ. Environmental Chemistry, 1997, Shanghai, Fudan University Press, 329.

[3]	Yamamoto S. Development of free cutting steel without lead. J. Jpn. Soc. Heat Treat., 2000, 40(3): 104.

[4]	Ryabov AV, Pobolotskii DYa, Ryabov VV. Bismuth distribution in free-cutting steel. Steel Trans., 2002, 32(9): 49.

[5]	Garcia CI, Hua M, Deardo AJ. Green manufacturing: eliminating lead from vehicles by using tin-enhanced free machining steels. SAE 2002 World Congress and Exhibition, 2002

[6]	Pennington JN. “Green” steel eliminates lead. Mod. Met., 1999, 55(11): 38.

[7]	Hao CS, Yu SP, Tian CF, Qi HS. Effect of cutting temperature on the film covering tool surface. J. Northeast. Univ., 1994, 15(1): 67.

[8]	Rhee K, Ahn SB, Lee DL. Development of non-leaded free cutting steel at POSCO. SEAISI Q., 2010, 39(4): 37.

[9]	Reynolds P, Block V, Essel I, Klocke F. Alternatives to lead as a machinability enhancer in free cutting steels. Steel Res. Int., 2007, 78(12): 908.

[10]	Jia YQ. Common Metal Materials Handbook, 2000, Beijing, China Standard Press, 85.

[11]	Murakami T, Shiraga T. Free cutting steel containing BN inclusions without lead addition. NKK Tech. Rep., 2002, 178(1): 21.

[12]	Hashimura M, Mizuno A, Miyanishi K. Effect of MnS distribution on machinability in low-carbon free-cutting steel. Iron Steel Technol., 2009, 6(9): 45.

[13]	Matsui N, Hasegawa T, Fujiwara J. Effect of sulfide inclusion morphology on machinability and tool wear mechanism in low carbon free cutting steel. J. Jpn. Soc. Precis. Eng., 2011, 77(3): 322.

[14]	Hu HQ. The Principle of Metal Solidification, 1988, Beijing, China Machinery Press, 31.

[15]	Sun DR, An J, Liu YB, Zhao XC, Cao XW, Zhang JB. Microstructure and properties of cast Al-Pb bearing alloy. Spec. Cast. Nonferrous Alloys, 2000 23.