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Journal of Iron and Steel Research International

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04-10-2019 | Review

Review on improving gas permeability of blast furnace

Authors: Yu-zhu Pan, Hai-bin Zuo, Jing-song Wang, Qing-guo Xue, Guang Wang, Xue-feng She

Published in: Journal of Iron and Steel Research International | Issue 2/2020

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Abstract

Blast furnace ironmaking process is the most mature and highly effective process for producing liquid iron. Blast furnace is a gas–solid and gas–solid–liquid countercurrent reactor, and maintaining gas permeability is the precondition of smooth production. Therefore, improving the gas permeability throughout the blast furnace remains a hot issue which is concerned by many metallurgical scholars. According to the research results of many scholars, the dominant factors influencing the gas permeability of different locations in the blast furnace (locations are distinguished according to the morphology change of the burdens) were reviewed. And the strategies for improving the gas permeability of different locations in the blast furnace were summarized based on these dominant influencing factors, such as suppressing the low-temperature reduction degradation of sinter in the lump zone, improving the indirect reduction degree and suppressing the interaction between different burdens. It is hoped to provide both theoretical and practical values for guiding the blast furnace so as to improve smooth operation and smelting efficiency.

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[1]

Y. Kashiwaya, ISIJ Int. 52 (2012) 1383.CrossRef

[2]

L.L. Cao, Y.N. Wang, Q. Liu, X.M. Feng, ISIJ Int. 58 (2018) 573–584.CrossRef

[3]

W.Q. Chen, X.G. Zhu, H.G. Zheng, J.L. Sun, P. Yu, Iron and Steel 36 (2001) No. 7, 17–19.

[4]

S.X. Zhu, Steelmaking 32 (2016) No. 6, 27–33.

[5]

R. Zhu, X.J. Wang, C.J. Niu, F. Gao, Z.B. Hu, Special Steel 29 (2008) No. 1, 40–42.

[6]

D.M. Zhao, Ferro-Alloys 201 (2008) 11–13.

[7]

S. Ergun, Chem. Eng. Prog. 48 (1952) 89–94.

[8]

J.S. Wu, B.M. Yu, Int. J. Heat Mass Transfer 50 (2007) 3925–3932.CrossRef

[9]

G. Wang, J.S. Wang, Q.G. Xue, ISIJ Int. 57 (2017) 590–592.CrossRef

[10]

S.L. Wu, X.Q. Liu, Q. Zhou, J. Xu, C.S. Liu, J. Iron Steel Res. Int. 18 (2011) No. 8, 20–24.CrossRef

[11]

R. Jaffarullah, A. Arumugam, V.K. Jha, V. Narayanan, ISIJ Int. 48 (2008) 918–924.CrossRef

[12]

I. Shigaki, M. Sawada, N. Gennai, Trans. ISIJ 26 (1986) 503–511.CrossRef

[13]

R. Liu, L.H. Wang, Z.Z. Yan, X.J. Wang, Y.C. Zhao, Q. Lv, Sintering and Pelletizing 43 (2018) No. 1, 1–5.

[14]

X. Zhang, J.L. Zhang, Z.W. Hu, H.B. Zuo, H.W. Guo, J. Iron Steel Res. Int. 17 (2010) No. 11, 7–12.CrossRef

[15]

Y.F. Guo, X.M. Guo, ISIJ Int. 57 (2017) 228–235.CrossRef

[16]

Y.F. Guo, X.M. Guo, J Iron Steel Res. 29 (2017) 697–703.

[17]

S.C. Panigrahy, P. Verstraeten, J. Dilewijns, Metall. Trans. B 15 (1984) 23–32.CrossRef

[18]

U.S. Yadav, B.D. Pandey, B.K. Das, D.N. Jena, Ironmak. Steelmak. 29 (2002) 91–95.CrossRef

[19]

P. Pourghahramani, E. Forssberg, Int. J. Miner. Process. 82 (2007) 96–105.CrossRef

[20]

M. Matsumura, M. Hoshi, T. Kawaguchi, ISIJ Int. 45 (2005) 594–602.CrossRef

[21]

H. Kimura, T. Ogawa, M. Kakiki, A. Matsumoto, F. Tsukihashi, ISIJ Int. 45 (2005) 506–512.CrossRef

[22]

F.M. Shen, X. Jiang, G.S. Wu, G. Wei, X.G. Li, Y.S. Shen, ISIJ Int. 46 (2006) 65–69.CrossRef

[23]

D.C. Goldring, T.A.T. Fray, Ironmak. Steelmak. 16 (1989) 83–89.

[24]

H.P. Pimenta, V. Seshadri, Ironmak. Steelmak. 29 (2002) 175–179.CrossRef

[25]

J.Z. Liu, Q.G. Xue, X.F. She, J.S. Wang, Powder Technol. 246 (2013) 73–81.CrossRef

[26]

G.J. Ba, Research on Iron and Steel 101 (1998) 3–6.

[27]

S.L. Wu, H.L. Han, H.F. Xu, H.W. Wang, X.Q. Liu, ISIJ Int. 50 (2010) 686–694.CrossRef

[28]

S.L. Wu, H.L. Han, X.Q. Liu, ISIJ Int. 50 (2010) 987–993.CrossRef

[29]

S.L. Wu, H.L. Han, H.F. Xu, L.J. Yan, Chin. J. Process Eng. 10 (2010) No. S1, 37–42.

[30]

S.L. Wu, G.J. Wang, W.Z. Jiang, J.D. Sun, H.F. Xu, Iron and Steel 42 (2007) No. 3,10–13.

[31]

S.L. Wu, L.X. Wang, Y.J. Wang, J.C. Zhang, Chinese Journal of Engineering 38 (2016) 1546–1552.

[32]

W.T. Guo, Q.G. Xue, Y.L. Liu, X.F. She, J.S. Wang, Ironmak. Steelmak. 43 (2016) 22–30.CrossRef

[33]

W.T. Guo, Q.G. Xue, Y.L. Liu, X.F. She, J.S. Wang, High Temperature Materials and Processes 35 (2016) 805–812.

[34]

Y.L. Liu, J.S. Wang, W.T. Guo, Z.S. Dong, Q.G. Xue, High Temperature Materials and Processes 35 (2016) 507–514.

[35]

Y.L. Liu, W.T. Guo, Q.G. Xue, J.S. Wang, Sci. Sin. Tech. 44 (2014) 933–940.

[36]

L. Chen, Q.G. Xue, W.T. Guo, X.F. She, J.S. Wang, Ironmak. Steelmak. 43 (2016) 458–464.CrossRef

[37]

L.J. Yan, S.L. Wu, H.L. Han, Chin. J. Process Eng. 10 (2010) No. S1, 93–97.

[38]

L. Chen, Q.G. Xue, W.T. Guo, X.F. She, J.S. Wang, Iron and Steel 51 (2016) No. 2, 15–21.

[39]

M.S. Zhou, F.P. Tang, D.M. Zhao, X.P. Yang, J.S. Wang, J.J. Li, Iron and Steel 53 (2018) No. 4, 15–19.

[40]

M.A. Tseitlin, S.E. Lazutkin, G.M. Styopin, ISIJ Int. 34 (1994) 570–573.CrossRef

[41]

Y.H. Qi, D.L. Yan, J.J. Gao, J.C. Zhang, M.K. Li, Iron and Steel 46 (2011) No. 3, 6–8.

[42]

P. Kaushik, R.J. Fruehan, Ironmak. Steelmak. 33 (2006) 507–519.CrossRef

[43]

P. Kaushik, R.J. Fruehan, Ironmak. Steelmak. 33 (2006) 520–528.CrossRef

[44]

S.H. Chung, K.H. Kim, I. Sohn, ISIJ Int. 55 (2015) 1157–1164.CrossRef

[45]

X.F. She, J.S. Wang, J.Z. Liu, X.X. Zhang, Q.G. Xue, ISIJ Int. 54 (2014) 2728–2736.CrossRef

[46]

J. Ishii, R. Murai, I. Sumi, Y. Yongxiang, R. Boom, ISIJ Int. 57 (2017) 1531–1536.CrossRef

[47]

J.Y. Mu, G.F. Zhou, K.T. Liu, W.S. Zheng, S.G. Miao, Journal of Wuhan Iron and Steel University 13 (1990) 117–124.

[48]

Z.J. Teng, S.S. Cheng, G.L. Zhao, J. Iron Steel Res. 26 (2014) No. 12, 9–14.

[49]

G.L. Zhao, S.S. Cheng, W.X. Xu, C. Li, Iron and Steel 51 (2016) No. 6, 10–18.

[50]

P.D. Chen, Q.D. Sun, Y.Q. Xue, J.C. Liu, T. Wang, China Metallurgy 29 (2019) No. 1, 48–51.

[51]

Y. Sheng, D.Q. Chen, M.M. Zhang, Research on Iron and Steel 43 (2015) No. 2, 10–13.

[52]

X.H. Zhu, L.S. Yang, T. Peng, G.Z. Li, X.G. Yang, Metal Materials and Metallurgy Engineering 42 (2014) No. 4, 36–38.

[53]

X.W. An, J.S. Wang, R.Z. Lan, Y.H. Han, Q.G. Xue, J. Iron Steel Res. Int. 20 (2013) No. 5, 11–16.CrossRef

[54]

S. Ueda, T. Kon, T. Miki, S.J. Kim, H. Nogami, ISIJ Int. 55 (2015) 2098–2104.CrossRef

[55]

S.P. Yang, C. Wang, J. Dong, C. Wang, Z.Z. Ji, J.K. Pang, J. Iron Steel Res. 31 (2019) 24–30.

[56]

T. Hilding, S. Gupta, V. Sahajwalla, B. Björkman, J.O. Wikström, ISIJ Int. 45 (2005) 1041–1050.CrossRef

[57]

J. Haapakangas, J. Uusitalo, O. Mattila, T. Kokkonen, D. Porter, T. Fabritius, Steel Res. Int. 84 (2013) 65–71.CrossRef

[58]

X. Xing, H. Rogers, G. Zhang, K. Hockings, P. Zulli, O. Ostrovski, ISIJ Int. 56 (2016) 786–793.CrossRef

[59]

P. Wang, Y.Q. Zhang, J.X. Li, H.M. Long, Q.M. Meng, S.C. Yu, Chin. J. Process Eng. 16 (2016) 138–143.

[60]

M. Zamalloa, D. Ma, T.A. Utigard, ISIJ Int. 35 (1995) 458–463.CrossRef

[61]

Q.Q. Zhao, Q.G. Xue, X.F. She, H. Wang, J.S. Wang, Chin. J. Process Eng. 12 (2012) 789–795.

[62]

R. Guo, Q. Wang, S. Zhang, Coal Conversion 35 (2012) No. 2, 12–16.

[63]

Y.L. Liu, Q.G. Xue, G. Wang, J.S. Wang, Ironmak. Steelmak. 45 (2018) 821–827.CrossRef

[64]

N.S. Hur, B.R. Cho, J.S. Choi, K.W. Hanand, K.Y. Seo, Rev. Met. Paris 93 (1996) 367–377.CrossRef

[65]

W. Xiong, X.G. Bi, G.F. Zhou, Chin. J. Process Eng. 6 (2006) 347–351.

[66]

S.J. Chew, P. Zulli, A. Yu, ISIJ Int. 41 (2001) 1122–1130.CrossRef

[67]

Y. Ohno, T. Furukawa, M. Matsu-Ura, ISIJ Int. 34 (1994) 641–648.CrossRef

[68]

K. Kimura, S. Kishimoto, A. Sakai, T. Ariyama, M. Sato, Rev. Met. Paris 93 (1996) 575–580.CrossRef

[69]

X. Liu, X.Q. Chen, J. Northeast. Univ. (Nat. Sci.) 21 (2000) 177–180.

Title: Review on improving gas permeability of blast furnace
Authors: Yu-zhu Pan
Hai-bin Zuo
Jing-song Wang
Qing-guo Xue
Guang Wang
Xue-feng She
Publication date: 04-10-2019
Publisher: Springer Singapore
Published in: Journal of Iron and Steel Research International / Issue 2/2020
Print ISSN: 1006-706X
Electronic ISSN: 2210-3988
DOI: https://doi.org/10.1007/s42243-019-00321-y

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Review on improving gas permeability of blast furnace

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