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Journal of Iron and Steel Research International

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24-05-2022 | Original Paper

Developing laterite nickel ore leaching residue as sustainable blast furnace charge

Authors: Qing-yu Tang, Kai-jia Wu, Min Gan, Xiao-hui Fan, Zeng-qing Sun, Hao Lv, Guo-jing Wong

Published in: Journal of Iron and Steel Research International | Issue 11/2022

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Abstract

A kind of leaching residue generated during high pressure acid leaching of laterite nickel ore is creatively prepared as blast furnace charge for ironmaking. Results show that the briquettes with uniform shape, compressive strength higher than 72.3 N/pellet, and cracking temperature over 400 °C can be obtained by the non-binder briquetting with water content of 12.2 wt.% and pressure of 30 MPa. After preheating at 975 °C for 12 min and roasting at 1225 °C for 15 min, the strength of the roasted briquettes can reach 2815 N/pellet, and the iron grade is 59.27 wt.%. And the sulfur content can be simultaneously reduced to 0.067 wt.%. The obtained briquettes achieve adequate reducibility index, reduction degradation index, reduction swelling index, softening and melting temperatures, which are suitable for blast furnace ironmaking. The results show that this method cannot only effectively treat the leaching residue to reduce the risk of environmental pollution, but also realize the utilization of leaching residue.

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[1]

P. Zhang, Q. Guo, G. Wei, L. Meng, L. Han, J. Qu, T. Qi, Hydrometallurgy 157 (2015) 149–158.CrossRef

[2]

A.E.M. Warner, C.M. Díaz, A.D. Dalvi, P.J. Mackey, A.V. Tarasov, JOM 58 (2006) 11–20.CrossRef

[3]

G. Senanayake, J. Childs, B.D. Akerstrom, D. Pugaev, Hydrometallurgy 110 (2011) 13–32.CrossRef

[4]

Nornickel, Annual report 2019 (2020-05-15)[2021-04-05] https://ar2019.nornickel.com/shareholders/share-capital.

[5]

Q. Guo, J. Qu, T. Qi, G. Wei, B. Han, Miner. Eng. 24 (2011) 825–832.CrossRef

[6]

X. Lv, L. Wang, Z. You, W. Yu, X. Lv, JOM 71 (2019) 4191–4197.CrossRef

[7]

C.A. Ang, F. Zhang, G. Azimi, ACS Sustainable Chem. Eng. 5 (2017) 8416–8423.CrossRef

[8]

K. Liu, Q. Chen, H. Hu, Z. Yin, B. Wu, Hydrometallurgy 104 (2010) 32–38.CrossRef

[9]

S. Çetintaş, U. Yildiz, D. Bingöl, J. Clean. Prod. 199 (2018) 616–632.CrossRef

[10]

D. Zhu, L. Pan, Z. Guo, J. Pan, F. Zhang, Adv. Powder Technol. 30 (2019) 451–460.CrossRef

[11]

V. Davidson, World 20 (2006) 25.

[12]

F. Ma, Z. Yu, Y. Wu, X. Zhang, C. Lv, J. Qu, Hydrometallurgy 195 (2020) 105370.CrossRef

[13]

M.A.R. Önal, Y.A. Topkaya, Hydrometallurgy 142 (2014) 98–107.CrossRef

[14]

T. Gultom, A. Sianipar, IOP Conf. Ser.: Earth Environ. Sci. 413 (2020) 012015.

[15]

C.W. Luo, T.J. Zhu, S.Q. Luo, J. Li, J.F. Zhang, X.Y. Zhang, Yunnan Metallurgy 43 (2014) No. 5, 43–46.

[16]

M. Lei, B. Ma, Y. Chen, W. Liu, B. Liu, D. Lv, W. Zhang, C. Wang, ACS Sustainable Chem. Eng. 8 (2020) 3959–3968.CrossRef

[17]

E. Stamboliadis, G. Alevizos, J. Zafiratos, Miner. Eng. 17 (2004) 245–252.CrossRef

[18]

B.I. Whittington, D. Muir, Miner. Process. Extr. Metall. Rev. 21 (2000) 527–599.CrossRef

[19]

W.Y. Huang, R.H. Zhu, F. He, D. Li, Y. Zhu, Y.M. Zhang, Chem. Eng. J. 228 (2013) 679–687.CrossRef

[20]

S.P.E. Forsmo, A.J. Apelqvist, B.M.T. Björkman, P.O. Samskog, Powder Technol. 169 (2006) 147–158.CrossRef

[21]

J.J. Carlson, S.K. Kawatra, Miner. Process. Extr. Metall. Rev. 34 (2013) 269–303.CrossRef

[22]

M. Gan, X.H. Fan, Z.H. Zhang, X.J. Zhou, Y.Q. Wang, H.J. Yu, J. Iron Steel Res. Int. 16 (2009) No. S2-1, 327–331.

[23]

S.P.E. Forsmo, S.E. Forsmo, P.O. Samskog, B.M.T. Björkman, Powder Technol. 183 (2008) 247–259.CrossRef

[24]

I.U. Bhuiyan, J. Mouzon, B. Schröppel, A. Kaech, I. Dobryden, S.P.E. Forsmo, J. Hedlund, Microsc. Microanal. 20 (2014) 33–41.CrossRef

[25]

Y.G. Zhou, Modern Mining 36 (2020) No. 6, 224–226+230.

[26]

S. Dwarapudi, T.K. Ghosh, A. Shankar, V. Tathavadkar, D. Bhattacharjee, R. Venugopal, Int. J. Miner. Process. 96 (2010) 45–53.CrossRef

[27]

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

[28]

D.J. Wang, S.L. Wu, ISIJ Int. 54 (2014) 715–720.CrossRef

[29]

O.A. Mohamed, M.E.H. Shalabi, N.A. El-Hussiny, M.H. Khedr, F. Mostafa, Powder Technol. 130 (2003) 277–282.CrossRef

[30]

D.Q. Zhu, Z.Y. Ruan, T.J. Chun, J. Pan, J. Iron Steel Res. Int. 20 (2013) No. 10, 32–38.CrossRef

Title: Developing laterite nickel ore leaching residue as sustainable blast furnace charge
Authors: Qing-yu Tang
Kai-jia Wu
Min Gan
Xiao-hui Fan
Zeng-qing Sun
Hao Lv
Guo-jing Wong
Publication date: 24-05-2022
Publisher: Springer Nature Singapore
Published in: Journal of Iron and Steel Research International / Issue 11/2022
Print ISSN: 1006-706X
Electronic ISSN: 2210-3988
DOI: https://doi.org/10.1007/s42243-022-00783-7

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Developing laterite nickel ore leaching residue as sustainable blast furnace charge

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