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Metallurgical and Materials Transactions B

Erschienen in:

02.12.2019

CFD Investigation of Effect of Multi-hole Ceramic Filter on Inclusion Removal in a Two-Strand Tundish

verfasst von: Qiang Wang, Yu Liu, Ao Huang, Wen Yan, Huazhi Gu, Guangqiang Li

Erschienen in: Metallurgical and Materials Transactions B | Ausgabe 1/2020

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Abstract

Multi-hole ceramic filter is regarded as an effective and cheap method of additional flow control device in tundish. In order to evaluate the performance of the ceramic filter, a transient three-dimensional (3D) comprehensive numerical model has been developed to study the flow pattern, temperature distribution and residence time of the molten steel, as well as the elimination of inclusion in a full size two-strand tundish. One-way coupled Euler–Lagrange approach with random walk model was adopted to track the inclusion motion trajectory. The gravity, buoyancy, drag, virtual mass, lift, pressure gradient, and rebound forces were included. The inclusion Reynolds number was utilized for the judgment of the inclusion separation at the slag-steel interface and the internal surface of the filter hole. Besides, the residence time distribution curve has been analyzed for figuring out the macroscopic mixing of the molten steel. The results indicate that the ceramic filter increases the flow resistance of the molten steel in the tundish, resulting in a longer residence time and a higher temperature drop. Except removed by the covering molten slag, the inclusion could also be trapped by the filter hole when the molten steel travels through the ceramic filter. The elimination of the smaller inclusion is significantly improved. The removal ratio of the 1 μm inclusion in the tundish without ceramic filter is only 59.3 pct, while the value is improved to 65.3 pct if we apply the ceramic filter with slenderness ratio of 3 to the tundish. And with the slenderness ratio changing from 3 to 5, the removal ratio of the 1 μm inclusion increases from 65.3 to 72.0 pct. Additionally, the ceramic filter could counteract certain side effects of the increasing inclusion density on the removal, especially for the smaller inclusion. With the inclusion density increasing from 3990 to 5000 kg/m³, the removal ratio of the 1 μm inclusion decreases by 14.5 pct in the tundish without ceramic filter, and after using the ceramic filter, the removal ratio decreases by 13.0, 7.4, and 5.0 pct with the slenderness ratio varies from 3 to 5.

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K. Chattopadhyay, M. Isac, and R.I.L. Guthrie: ISIJ Int., 2010, vol. 50 (3), pp. 331-348.CrossRef

Q. Wang, F.S. Qi, B.K. Li, and F. Tsukihashi: ISIJ Int., 2014, vol. 54 (12), pp. 2796-2805.CrossRef

S. López-Ramirez, J. de Barreto, J. Palafox-Ramos, R.D. Morales, and D. Zacharias: Metall. Mater. Trans. B, 2001, vol. 32B (4), pp. 615-627.CrossRef

P.K. Jha, P.S. Rao, and A. Dewan: ISIJ Int., 2008, vol. 48 (2), pp. 154-160.CrossRef

J.P. Rogler, L.J. Heaslip, and M. Mehrvar: Can. Metall. Quart., 2004, vol. 43 (3), pp. 407-415.CrossRef

S. Neumann, A. Asad, T. Kasper, and R. Schwarze: Metall. Mater. Trans. B, 2019, vol. 50B (5), pp. 2334-2342.CrossRef

M.R.M. Yazdi, A.R.F. Khorasani, and S. Talebi: Can. Metall. Quart., 2019, vol. 58 (4), pp. 379-388.CrossRef

P Ni, LTI Jonsson, M Ersson, PG Jönsson (2017) Steel Res. Int., 83(3): 1600155.CrossRef

R. Mishra and D. Mazumdar: Trans. Indian Inst. Met., 2019, vol. 72 (4), pp. 889-898.CrossRef

10.

L.H. Wang, H.-G. Lee, and P. Hayes: ISIJ Int., 1996, vol. 36 (1), pp. 17-24.CrossRef

11.

S. Ali, R. Mutharasan, and D. Apelian: Metall. Trans. B, 1985, vol. 16B (6), pp. 725-742.CrossRef

12.

K. Yamada, T. Watanabe, K. Fukuda, T. Kawaragi, and T. Tashiro: Trans. ISIJ, 1987, vol. 27, pp. 873-877.CrossRef

13.

K. Janiszewski: Arch. Metall. Mater., 2013, vol. 58 (2), pp. 513-521.CrossRef

14.

L. Bulkowski, U. Galisz, H. Kania, Z. Kudliński, J. Pieprzyca, and J. Barański: Arch. Metall. Mater., 2012, vol. 57 (1), pp. 363-369.CrossRef

15.

K. Janiszewski: Steel Res. Int., 2013, vol. 84 (3), pp. 288-296.CrossRef

16.

M. Warzecha, T. Merder, P. Warzecha, and G. Stradomski: ISIJ Int., 2013, vol. 53 (11), pp. 1983-1992.CrossRef

17.

H.-J. Odenthal, M. Javurek, and M. Kirschen: Steel Res. Int., 2009, vol. 80 (4), pp. 264-274.

18.

H.-J. Odenthal, M. Javurek, M. Kirschen, and N. Vogl: Steel Res. Int., 2010, vol. 81 (7), pp. 529-541.CrossRef

19.

M. Javurek, B. Kaufmann, G. Zuba, and P. Gittler: Steel Res., 2002, vol. 73 (5), pp. 186-193.CrossRef

20.

E. Gutiérrez, S. Garcia-Hernandez, and J.J. Barreto: Steel Res. Int., 2019, p. 1900328.

21.

F. Xing, S. Zheng, Z. Liu, and M. Zhu (2019) J. Metals, 9(5):561.CrossRef

22.

C. Chen: Doctoral thesis, KTH Royal Institute of Technology, Stockholm, Sweden, 2001, pp. 1–4.

23.

Q.F. Hou and Z.S. Zou: ISIJ Int., 2005, vol. 45 (3), pp. 325-330.CrossRef

24.

Y. Miki and B.G. Thomas: Metall. Mater. Trans. B, 1999, vol. 30B (4), pp. 639-654.CrossRef

25.

L.F. Zhang, S. Taniguchi, and K.K. Cai: Metall. Mater. Trans. B, 2000, vol. 31B (2), pp. 253-266.CrossRef

26.

K. Raghavendra, S. Sarkar, S.K. Ajmani, M.B. Denys, and M.K. Singh: Appl. Math. Model., 2013, vol. 37, pp. 6284-6300.CrossRef

27.

J. Strandh, K. Nakajima, R. Eriksson, and P. Jönsson: ISIJ Int., 2005, vol. 45 (11), pp. 1597-1606.CrossRef

28.

C. Liu, S.F. Yang, J.S. Li, L.B. Zhu, and X.G. Li: Metall. Mater. Trans. B, 2016, vol. 47B (3), pp. 1882-1892.CrossRef

29.

M.J. Assael, K. Kakosimos, R.M. Banish, J. Brillo, I. Egry, R. Brooks, P.N. Quested, K.C. Mills, A. Nagashima, Y. Sato, and W.A. Wakeham (2006) J. Phys. Chem. Ref. Data, 35(1): 285-300.CrossRef

30.

T. Nishi, H. Shibata, H. Ohta, and Y. Waseda: Metall. Mater. Trans. A, 2003, vol. 34A (12), pp. 2801-2807.CrossRef

31.

S.F. Yang, J.S. Li, C. Liu, L.Y. Sun, and H.B. Yang: Metall. Mater. Trans. B, 2014, vol. 45B (6), pp. 2453-2463.CrossRef

32.

Q. Wang, B.K. Li, and F. Tsukihashi: ISIJ Int., 2014, vol. 54 (2), pp. 311-320.CrossRef

33.

K. Chattopadhyay, M. Isac, and R.I.L. Guthrie: ISIJ Int., 2012, vol. 52 (11), pp. 2026-2035.CrossRef

34.

Q. Wang, R.T. Wang, Z. He, G.Q. Li, B.K. Li, and H.B. Li: Int. J. Heat Mass Trans., 2018, vol. 125, pp. 1333-1344.CrossRef

35.

B.G. Thomas, Q. Yuan, S. Mahmood, R. Liu, and R. Chaudhary: Metall. Mater. Trans. B, 2014, vol. 45B (1), pp. 22-35CrossRef

36.

D. Bouris and G. Bergeles: Metall. Mater. Trans. B, 1998, vol. 29B (3), pp. 641-649.CrossRef

37.

J.K. Kim and P.K. Rohatgi: Metall. Mater. Trans. A, 1998, vol. 29A (1), pp. 351-358.CrossRef

38.

K. Takahashi, M. Ando, and T. Ishii: ISIJ Int., 2014, vol. 54 (2), pp. 304-310.CrossRef

39.

U.D. Salgado, C. Weiβ, S.K. Michelic, and C. Bernhard: Metall. Mater. Trans. B, 2018, vol. 49B (4), pp. 1632-1643.CrossRef

40.

C. Chen, L.T.I. Jonsson, A. Tilliander, G.G. Cheng, and P.G. Jönsson: Metall. Mater. Trans. B, 2015, vol. 46B (1), pp. 169-190.CrossRef

41.

C. Chen, L.T.I. Jonsson, A. Tilliander, G.G. Cheng, and P.G. Jönsson: Chem. Eng. Sci., 2015, vol. 137, pp. 914-937.CrossRef

42.

Y. Ono and S. Matsumoto: Trans. JIM, 1975, vol. 17 (7), pp. 415-422.CrossRef

43.

C. Chen, G.G. Cheng, H.B. Sun, Z.B. Hou, X.C. Wang, and J.Q. Zhang: Steel Res. Int., 2012, vol. 83 (12), pp. 1141-1151.CrossRef

44.

Y. Sahai and T. Emi: ISIJ Int., 1996, vol. 36 (6), pp. 667-672.CrossRef

45.

J.H. Shin, Y. Ghung, and J.H. Park: Metall. Mater. Trans. B, 2017, vol. 48B (1), pp. 46-59.CrossRef

Titel: CFD Investigation of Effect of Multi-hole Ceramic Filter on Inclusion Removal in a Two-Strand Tundish
verfasst von: Qiang Wang
Yu Liu
Ao Huang
Wen Yan
Huazhi Gu
Guangqiang Li
Publikationsdatum: 02.12.2019
Verlag: Springer US
Erschienen in: Metallurgical and Materials Transactions B / Ausgabe 1/2020
Print ISSN: 1073-5615
Elektronische ISSN: 1543-1916
DOI: https://doi.org/10.1007/s11663-019-01736-4

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