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Journal of Iron and Steel Research International

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02-12-2021 | Original Paper

Effect of vertical electromagnetic stirring on solute distribution in billet continuous casting process

Authors: Tao Wang, En-gang Wang, Yves Delannoy, Yves Fautrelle, Olga Budenkova

Published in: Journal of Iron and Steel Research International | Issue 1/2022

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Abstract

A volume averaged columnar solidification model, which couples the flow, temperature and solute concentration fields, is applied to simulate experimental continuous casting cases with and without vertical electromagnetic stirring (V-EMS). The calculated distribution of magnetic induction intensity and final macrosegregation maps are consistent with the experimental results. Calculation results reveal that the V-EMS promotes longitudinal melt flow, accelerates heat dissipation and solidification and finally reduces the central segregation of carbon. However, when V-EMS is applied, the solute distribution becomes asymmetric because the melt flow shows opposite directions between the near and far sides from stirrer. An obvious positive segregation band is observed at about 1/4 width of the billet near the stirrer in both calculated and experimental results. The position and degree of such positive segregation could be affected by installation height of stirrer, as demonstrated by additional simulation cases.

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[1]

K.S. Oh, Y.W. Chang, ISIJ Int. 35 (1995) 866–875.CrossRef

[2]

S.M. Cho, B.G. Thomas, Metals 9 (2019) 471.CrossRef

[3]

F. Wang, E. Wang, L.T. Zhang, P. Jia, T. Wang, J. Manuf. Process. 26 (2017) 364–371.CrossRef

[4]

D.B. Spencer, R. Mehrabian, M.C. Flemings, Metall. Mater. Trans. B 3 (1972) 1925–1932.CrossRef

[5]

Y. Xu, X.J. Xu, Z. Li, T. Wang, A.Y. Deng, E.G. Wang, High Temp. Mater. Process. 36 (2017) 339–346.CrossRef

[6]

D.B. Jiang, M.Y. Zhu, L.F. Zhang, Metals 9 (2019) 452.CrossRef

[7]

Y. Xu, E.G. Wang, Z. Li, A.Y. Deng, J. Iron Steel Res. Int. 24 (2017) 483–489.CrossRef

[8]

Y. Xu, T. Wang, F. Wang, E.G. Wang, J. Cryst. Growth 468 (2017) 506–509.CrossRef

[9]

L. Hachani, K. Zaidat, Y. Fautrelle, Int. J. Heat Mass Transfer 85 (2015) 438–454.CrossRef

[10]

W.Z. Yang, X.D. Wang, B. Wang, F. Baltaretu, J. Etay, Y. Fautrelle, Metall. Mater. Trans. B 47 (2016) 2771–2784.CrossRef

[11]

X. Zhang, Q. Zhao, J. Guo, Q. Xing, L. Deng, X. Hou, C. Fang, Acta Metall. Sin. Engl. 26 (2013) 345–351.CrossRef

[12]

H.B. Sun, J.Q. Zhang, Metall. Mater. Trans. B 45 (2014) 1133–1149.CrossRef

[13]

O. Budenkova, A. Noeppel, J. Kovács, A. Rónaföldi, A. Roósz, A.M. Bianchi, F. Baltaretu, M. Medina, Y. Fautrelle, Mater. Sci. Forum 649 (2010) 269–274.CrossRef

[14]

L.B. Trindade, J.E.A. Nadalon, A.C. Contini, R.C. Barroso, Steel Res. Int. 88 (2017) 1–8.CrossRef

[15]

N. Barman, P. Kumar, P. Dutta, J. Mater. Process. Technol. 209 (2009) 5912–5923.CrossRef

[16]

N. Genma, T. Soejima, T. Saito, M. Kimura, Y. Kaihara, H. Fukumoto, K. Ayata, ISIJ Int. 29 (1989) 1056–1062.CrossRef

[17]

M. Dubke, K.H. Tacke, K.H. Spitzer, K. Schwerdtfeger, Metall. Trans. B 19 (1988) 595–602.CrossRef

[18]

M. Rappaz, P.H. Thévoz, Acta Metall. 35 (1987) 1487–1497.CrossRef

[19]

J. Ni, C. Beckermann, J. Mater. Process. Manuf. Sci. 2 (1993) 217–231.

[20]

M.H. Wu, A. Ludwig, A. Kharicha, Metals 9 (2019) 229.CrossRef

[21]

T. Carozzani, C.A. Gandin, H. Digonnet, M. Bellet, K. Zaidat, Y. Fautrelle, Metall. Mater. Trans. A 44 (2013) 873–887.CrossRef

[22]

A. Karma, W.J. Rappel, Phys. Rev. Lett. 77 (1996) 4050–4053.CrossRef

[23]

D. Tourret, A. Karma, Acta Mater. 120 (2016) 240–254.CrossRef

[24]

T. Wang, E.G. Wang, Y. Delannoy, Y. Fautrelle, O. Budenkova, Metals 11 (2021) 262.CrossRef

[25]

W.T. Tu, H.F. Shen, B.C. Liu, ISIJ Int. 54 (2014) 351–355.CrossRef

[26]

T. Wang, L. Hachani, Y. Fautrelle, Y. Delannoy, E.G. Wang, X.D. Wang, O. Budenkova, Int. J. Heat Mass Transfer 151 (2020) 119414.CrossRef

[27]

D.B. Jiang, M. Zhu, Metall. Mater. Trans. B 48 (2017) 444–455.CrossRef

[28]

A. Pakanati, K.O. Tveito, M. M’Hamdi, H. Combeau, M. Založnik, Metall. Mater. Trans. A 50 (2019) 1773–1786.CrossRef

[29]

Y. Zheng, M. Wu, A. Kharicha, A. Ludwig, IOP Conf. Ser. Mater. Sci. Eng. 143 (2016) 012032.

[30]

B. Wang, X.D. Wang, Y. Fautrelle, J. Etay, X.Z. Na, F. Baltaretu, Metall. Mater. Trans. B 47 (2016) 3476–3488.CrossRef

[31]

S.K. Choudhary, S. Ganguly, ISIJ Int. 47 (2007) 1759–1766.CrossRef

[32]

M. Založnik, A. Kumar, H. Combeau, Comput. Mater. Sci. 48 (2010) 11–21.CrossRef

[33]

J. Li, M. Wu, J. Hao, A. Ludwig, Comput. Mater. Sci. 55 (2012) 407–418.CrossRef

[34]

T.H. Shih, W.W. Liou, A. Shabbir, Z.G. Yang, J. Zhu, Comput. Fluids 24 (1995) 227–238.CrossRef

[35]

M. Dubke, K.H. Tacke, K.H. Spitzer, K. Schwerdtfeger, Metall. Trans. B 19 (1988) 581–593.CrossRef

[36]

M. Yamazaki, Y. Natsume, H. Harada, K. Ohsasa, ISIJ Int. 46 (2006) 903–908.CrossRef

[37]

T. Nozaki, J. Matsuno, K. Murata, H. Ooi, M. Kodama, Tetsu-to-Hagané 62 (1976) 1503–1512.CrossRef

Title: Effect of vertical electromagnetic stirring on solute distribution in billet continuous casting process
Authors: Tao Wang
En-gang Wang
Yves Delannoy
Yves Fautrelle
Olga Budenkova
Publication date: 02-12-2021
Publisher: Springer Singapore
Published in: Journal of Iron and Steel Research International / Issue 1/2022
Print ISSN: 1006-706X
Electronic ISSN: 2210-3988
DOI: https://doi.org/10.1007/s42243-021-00685-0

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Effect of vertical electromagnetic stirring on solute distribution in billet continuous casting process

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