Effect of.superheat on.quality of.central equiaxed grain zone of.continuously cast bearing steel billet based on.two-dimensional segregation ratio

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ժҪ The quality of central equiaxed grain zone (CEGZ) of GCr15 bearing steel billets was investigated at di. erent superheats (20, 25 and 35.��C) by experimental observations and a . nite element model in order.to optimize superheat in continuous casting process. Several GCr15 billets were collected from the continuous casting shop, and the same CEGZ was chosen for comparison of internal quality of GCr15 billets. Considering the limitation of segregation index at some points, two-dimensional segregation ratio in CEGZ was introduced. Firstly, the segregation ratio and the area of center large dark points in CEGZ obtain the minimum at 25.��C superheat, which indicates that the quality of CEGZ at 25.��C superheat is improved compared with those at 20 and 35.��C superheats for corresponding continuously cast billets. The highest superheat and the lowest superheat are not bene. cial for improving the central zone quality in the billets. Secondly, the quality of CEGZ of GCr15 billets increases with a decrease in the secondary dendrite arm spacing of CEGZ. Finally, according to the established .nite element model, it is deduced that the secondary dendrite arm spacing of CEGZ is closely related to its later solidi. ca-tion time at solid fraction of 0.5�C1.0, and the former will be decreased when decreasing the latter.

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	Wei Wang
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	Jianghai CAO

�ؼ�� �� superheat, continuous casting billet, equiaxed zone, segregation, solidification time

Abstract��The quality of central equiaxed grain zone (CEGZ) of GCr15 bearing steel billets was investigated at di. erent superheats (20, 25 and 35.��C) by experimental observations and a . nite element model in order.to optimize superheat in continuous casting process. Several GCr15 billets were collected from the continuous casting shop, and the same CEGZ was chosen for comparison of internal quality of GCr15 billets. Considering the limitation of segregation index at some points, two-dimensional segregation ratio in CEGZ was introduced. Firstly, the segregation ratio and the area of center large dark points in CEGZ obtain the minimum at 25.��C superheat, which indicates that the quality of CEGZ at 25.��C superheat is improved compared with those at 20 and 35.��C superheats for corresponding continuously cast billets. The highest superheat and the lowest superheat are not bene. cial for improving the central zone quality in the billets. Secondly, the quality of CEGZ of GCr15 billets increases with a decrease in the secondary dendrite arm spacing of CEGZ. Finally, according to the established .nite element model, it is deduced that the secondary dendrite arm spacing of CEGZ is closely related to its later solidi. ca-tion time at solid fraction of 0.5�C1.0, and the former will be decreased when decreasing the latter.

Key words�� superheat continuous casting billet equiaxed zone segregation solidification time

�ո��: 2016-12-02 ��: 2018-05-15

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Wei . Wang �� Zi-bing Hou �� Yi Chang �� Jiang-hai Cao . Effect of.superheat on.quality of.central equiaxed grain zone of.continuously cast bearing steel billet based on.two-dimensional segregation ratio[J].Journal of Iron and Steel Research International, 2018, 25(1): 9-18. Wei . Wang �� Zi-bing Hou �� Yi Chang �� Jiang-hai Cao . Effect of.superheat on.quality of.central equiaxed grain zone of.continuously cast bearing steel billet based on.two-dimensional segregation ratio. , 2018, 25(1): 9-18.

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http://gt.chinamet.cn/Jweb_gtyjxb_en/CN/ �� http://gt.chinamet.cn/Jweb_gtyjxb_en/CN/Y2018/V25/I1/9

[1]	F Liu, J Wang, Y Liu, R Misra, C Liu: Journal of Iron and Steel Research International, 23(2016), 559.
[2]	U. Toshikazu: Trans. Trans. Iron Steel Inst. Jpn., 26(1986), 614.
[3]	M .C. Flemings: ISIJ Int., 40(2000), 833.
[4]	H. Mori, N. Tanaka, N. Sato, M. Hirai: Trans. Iron Steel Inst. Jpn., 12(1972), 102.
[5]	S. K. Choudhary, S. Ganguly: ISIJ Int., 47(2007), 1759.
[6]	M. Nakatani, T. Adachi, Y. Sugitani, S. Kobayashi, M. Yoshihara, S. Ishimura: Tetsu-to-Hagan��, 67(1981), 1287.
[7]	H. Esaka, T. Wakabayashi, K. Shinozuka, M. Tamura: ISIJ Int., 43(2003), 1415.
[8]	Z. Hou, F. Jiang, G. Cheng: ISIJ Int., 52(2012), 1301.
[9]	Y. Tsuchida, I. Sugawara, T. Ishida : Trans. Iron Steel Inst. Jpn., 22(1982), 265.
[10]	M. Bobadilla, J. M. Jolivet, J. Y. Lamant: Mater. Sci. Eng. A, 173(1993), 275.
[11]	Z. Hou, G. Cheng, F. Jiang, G. Qian: ISIJ Int., 53(2013), 655.
[12]	M. C. Flemings: Solidification Processing, McGraw-Hill, New York, (1974)
[13]	K. P. Young, D. H. Kirkwood: Metall. Trans.A, 6(1975), 197.
[14]	S. P. Marsh, M. E. Glicksman: Metall. and Mater. Trans A., 27 (1996), 557.
[15]	S. K. Choudhary, D. Mazumdar: Steel Res. Int., 66(1995), 199.
[16]	K. Cai, J. Yang: J. Univ. Sci. Technol. Beijing, 6(1989), 510.
[17]	K. J. Schwerdtfeger: The Casting Volume of the 11th ed. of the Making, Shaping and Treating of Steel, The AISE Steel Foundation, Pittsburgh, PA(2003), 18.
[18]	Z. Hou, G. Cheng, C. Wu, C. Chen. Metall. and Mater. Trans B., 43 (2012), 1517.
[19]	O. Volkova, H. P. Heller and D. Janke: ISIJ Int., 43(2003), 1724.
[20]	S. Chakraborty, P. Dutta: Materials Science and Technology, 17(2001), 1531.
[21]	W. Kurz, D. J. Fisher: Fundamentals of Solidification, 4th revised ed., Trans Tech Publisher, Aedermannsdorf, Switzerland, (1998), 77.
[22]	W. Li, G. Zhu, X. Wang: J. Univ. Sci. Technol. Beijing, 25(2003), 315.
[23]	J. Cui, W. Li: J. Tsinghua Univ., 41(2001), 5.