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14-08-2024

Pyrometallurgical processing of red mud

Authors: N. V. Vasyunina, I. V. Dubova, K. E. Druzhinin, T. R. Gilmanshina

Published in: Metallurgist | Issue 4/2024

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Abstract

High-iron Bayer red mud, containing over 30% of iron, is considered low-grade iron ore. Due to the global iron deficiency in recent decades, the effective utilization of the iron contained in high-iron red mud has received increasing attention. In this work, a technological scheme was developed for the extraction of iron into cast iron from red mud by smelting reduction, followed by rapid cooling to separate the metal from the slag. The influence of various experimental parameters, including temperature, basicity, and reduction time, on the recovery of iron from red mud was studied in detail. The results demonstrated that the separation of metal from slag was complete. The maximum extraction of iron into cast iron was obtained at a temperature of 1450 °C, with approximately 88.5% achieved in the absence of sodium carbonate and 91.5% with sodium carbonate. The optimal experimental result is of great importance for the large-scale and highly efficient recycling of red mud.

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Literature
1.
go back to reference Archambo M, Kawatra SK (2021) Red mud: fundamentals and new avenues for utilization. Miner Process Extr Met Rev 42:427–450CrossRef Archambo M, Kawatra SK (2021) Red mud: fundamentals and new avenues for utilization. Miner Process Extr Met Rev 42:427–450CrossRef
2.
go back to reference Liu X, Han Y, He F, Gao P, Yuan S (2021) Characteristic, hazard and iron recovery technology of red mud—a critical review. J Hazard Mater 420:126542CrossRefPubMed Liu X, Han Y, He F, Gao P, Yuan S (2021) Characteristic, hazard and iron recovery technology of red mud—a critical review. J Hazard Mater 420:126542CrossRefPubMed
3.
go back to reference Yu J, Li Y, Lv Y, Han Y, Gao P (2022) Recovery of iron from high-iron red mud using suspension magnetization roasting and magnetic separation. Miner Eng 178:107394CrossRef Yu J, Li Y, Lv Y, Han Y, Gao P (2022) Recovery of iron from high-iron red mud using suspension magnetization roasting and magnetic separation. Miner Eng 178:107394CrossRef
4.
go back to reference Liu X, Gao P, Yuan S, Lv Y, Han Y (2020) Clean utilization of high-iron red mud by suspension magnetization roasting. Miner Eng 157:106553CrossRef Liu X, Gao P, Yuan S, Lv Y, Han Y (2020) Clean utilization of high-iron red mud by suspension magnetization roasting. Miner Eng 157:106553CrossRef
5.
go back to reference Zinoveev DV, Grudinsky PI, Dubanov VG, Kovalenko LV, Leontiev LI (2018) Review of world practice of red mud processing. Part 1. Pyrometallurgical methods. Izv Vyssh Uchebn Zaved Chern Met 61(11):843–858 Zinoveev DV, Grudinsky PI, Dubanov VG, Kovalenko LV, Leontiev LI (2018) Review of world practice of red mud processing. Part 1. Pyrometallurgical methods. Izv Vyssh Uchebn Zaved Chern Met 61(11):843–858
6.
go back to reference Alam S, Das SK, Rao BH (2017) Characterization of coarse fraction of red mud as a civil engineering construction material. J Clean Prod 168:679–691CrossRef Alam S, Das SK, Rao BH (2017) Characterization of coarse fraction of red mud as a civil engineering construction material. J Clean Prod 168:679–691CrossRef
7.
go back to reference Li XF, Zhang TA, Lv GZ, Wang K, Wang S (2023) Summary of research progress on metallurgical utilization technology of red mud. Minerals 13:737CrossRef Li XF, Zhang TA, Lv GZ, Wang K, Wang S (2023) Summary of research progress on metallurgical utilization technology of red mud. Minerals 13:737CrossRef
8.
go back to reference Vasyunina NV, Dubova IV, Druzhinin KE, Alekseev AV, Gilmanshina TR, Rudnitsky EA (2020) Methods for extracting valuable elements (Fe, Al, Na, and Ti) from red mud. Ekol Prom Ross 24(9):32–38CrossRef Vasyunina NV, Dubova IV, Druzhinin KE, Alekseev AV, Gilmanshina TR, Rudnitsky EA (2020) Methods for extracting valuable elements (Fe, Al, Na, and Ti) from red mud. Ekol Prom Ross 24(9):32–38CrossRef
9.
go back to reference Agrawal S, Dhawan N (2021) Evaluation of red mud as a polymetallic source—a review. Miner Eng 171:107084CrossRef Agrawal S, Dhawan N (2021) Evaluation of red mud as a polymetallic source—a review. Miner Eng 171:107084CrossRef
10.
go back to reference Chesnokov YA, Leontiev LI, Sheshukov OY, Dmitriev AN, Vitkina GY, Marshuk LA (2013) Pyrometallurgical recycling of aluminum production waste. Vestn Magnitogorsk Gos Tekhn Univ Gi Nosov 3(43):19–22 Chesnokov YA, Leontiev LI, Sheshukov OY, Dmitriev AN, Vitkina GY, Marshuk LA (2013) Pyrometallurgical recycling of aluminum production waste. Vestn Magnitogorsk Gos Tekhn Univ Gi Nosov 3(43):19–22
11.
go back to reference Zinoveev D, Pasechnik L, Grudinsky P, Yurtaeva A, Dyubanov V (2023) Kinetics and mechanism of red mud carbothermic reduction and reduced iron grain growth: an influence of sodium sulfate. Crystals 13(1):1CrossRef Zinoveev D, Pasechnik L, Grudinsky P, Yurtaeva A, Dyubanov V (2023) Kinetics and mechanism of red mud carbothermic reduction and reduced iron grain growth: an influence of sodium sulfate. Crystals 13(1):1CrossRef
12.
go back to reference Wang S, Jin H, Deng Y, Xiao Y (2021) Comprehensive utilization status of red mud in China: a critical review. J Clean Prod 289:125136CrossRef Wang S, Jin H, Deng Y, Xiao Y (2021) Comprehensive utilization status of red mud in China: a critical review. J Clean Prod 289:125136CrossRef
13.
go back to reference Zinoveev D, Grudinsky P, Zakunov A, Semenov A, Panova M, Valeev D, Kondratiev A, Dyubanov V, Petelin A (2019) Influence of Na2CO3 and K2CO3 addition on iron grain growth during carbothermic reduction of red mud. Metals 9:1313CrossRef Zinoveev D, Grudinsky P, Zakunov A, Semenov A, Panova M, Valeev D, Kondratiev A, Dyubanov V, Petelin A (2019) Influence of Na2CO3 and K2CO3 addition on iron grain growth during carbothermic reduction of red mud. Metals 9:1313CrossRef
14.
go back to reference Zhang J, Yao Z, Wang K, Wang F, Jiang H, Liang M, Wei J, Airey G (2021) Sustainable utilization of bauxite residue (red mud) as a road material in pavements: a critical review. Constr Build Mater 270:121419CrossRef Zhang J, Yao Z, Wang K, Wang F, Jiang H, Liang M, Wei J, Airey G (2021) Sustainable utilization of bauxite residue (red mud) as a road material in pavements: a critical review. Constr Build Mater 270:121419CrossRef
15.
go back to reference Gomes HI, Mayes WM, Rogerson M, Stewart DI, Burke IT (2016) Alkaline residues and the environment: a review of impacts, management practices and opportunities. J Clean Prod 112:3571–3582CrossRef Gomes HI, Mayes WM, Rogerson M, Stewart DI, Burke IT (2016) Alkaline residues and the environment: a review of impacts, management practices and opportunities. J Clean Prod 112:3571–3582CrossRef
16.
go back to reference Wei D, Xu J‑H, Yang P, Shen S‑Y, Chen T, Zhou K (2022) Extraction of scandium and iron from red mud. Miner Process Extr Met Rev 43:61–68CrossRef Wei D, Xu J‑H, Yang P, Shen S‑Y, Chen T, Zhou K (2022) Extraction of scandium and iron from red mud. Miner Process Extr Met Rev 43:61–68CrossRef
17.
go back to reference Wang Y, Zhang T, Lyu G, Guo F, Zhang W, Zhang Y (2018) Recovery of alkali and alumina from bauxite residue (red mud) and complete reuse of the treated residue. J Clean Prod 188:456–465CrossRef Wang Y, Zhang T, Lyu G, Guo F, Zhang W, Zhang Y (2018) Recovery of alkali and alumina from bauxite residue (red mud) and complete reuse of the treated residue. J Clean Prod 188:456–465CrossRef
18.
go back to reference Borra CR, Pontikes Y, Binnemans K, Van Gerven T (2015) Leaching of rare earths from bauxite residue (red mud). Miner Eng 76:20–27CrossRef Borra CR, Pontikes Y, Binnemans K, Van Gerven T (2015) Leaching of rare earths from bauxite residue (red mud). Miner Eng 76:20–27CrossRef
19.
go back to reference Khanna R, Konyukhov Y, Zinoveev D, Jayasankar K, Burmistrov I, Kravchenko M, Mukherjee PS (2022) Red mud as a secondary resource of low-grade iron: a global perspective. Sustainability 14:1258CrossRef Khanna R, Konyukhov Y, Zinoveev D, Jayasankar K, Burmistrov I, Kravchenko M, Mukherjee PS (2022) Red mud as a secondary resource of low-grade iron: a global perspective. Sustainability 14:1258CrossRef
20.
go back to reference Pasechnik LA, Skachkov VM, Bibanaeva SA, Medyankina IS, Bamburov VG (2022) Composition and properties of iron oxides in the products of hydrothermal treatment of red mud and bauxites. Russ J Inorg Chem 67(7):1101–1107CrossRef Pasechnik LA, Skachkov VM, Bibanaeva SA, Medyankina IS, Bamburov VG (2022) Composition and properties of iron oxides in the products of hydrothermal treatment of red mud and bauxites. Russ J Inorg Chem 67(7):1101–1107CrossRef
21.
go back to reference Ding W, Xiao J, Peng Y, Shen S, Chen T, Zou K, Wang Z (2020) A novel process for extraction of iron from a refractory red mud. Physicochem Probl Miner Process 56:125–136CrossRef Ding W, Xiao J, Peng Y, Shen S, Chen T, Zou K, Wang Z (2020) A novel process for extraction of iron from a refractory red mud. Physicochem Probl Miner Process 56:125–136CrossRef
24.
go back to reference Wei ZB, Liu QS, Sun ZQ, Huang XX, Gan M, Ji ZY, Chen XL, Fan XH (2022) Co-disposal of semi-dry Desulfurization residue and red mud into high performance alkali activated. Constr Build Mater 350:128776CrossRef Wei ZB, Liu QS, Sun ZQ, Huang XX, Gan M, Ji ZY, Chen XL, Fan XH (2022) Co-disposal of semi-dry Desulfurization residue and red mud into high performance alkali activated. Constr Build Mater 350:128776CrossRef
25.
go back to reference Balomenos E, Gianopoulou I, Panias D, Paspaliaris I, Perry K, Boufounos D (2011) A novel red mud treatment process: process design and preliminary results. Miner Process Extr Met 32:1–21 Balomenos E, Gianopoulou I, Panias D, Paspaliaris I, Perry K, Boufounos D (2011) A novel red mud treatment process: process design and preliminary results. Miner Process Extr Met 32:1–21
Metadata
Title
Pyrometallurgical processing of red mud
Authors
N. V. Vasyunina
I. V. Dubova
K. E. Druzhinin
T. R. Gilmanshina
Publication date
14-08-2024
Publisher
Springer US
Published in
Metallurgist / Issue 4/2024
Print ISSN: 0026-0894
Electronic ISSN: 1573-8892
DOI
https://doi.org/10.1007/s11015-024-01767-6

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