Tin recovery from a low-grade tin middling with high Si content and low Fe content by reduction—sulfurization roasting with anthracite coal

Jing-cheng Wang; Lei Li; Yong Yu

doi:10.1007/s12613-020-2038-8

International Journal of Minerals, Metallurgy, and Materials ›› 2021, Vol. 28 ›› Issue (2) : 210 -220. DOI: 10.1007/s12613-020-2038-8

Article

Tin recovery from a low-grade tin middling with high Si content and low Fe content by reduction—sulfurization roasting with anthracite coal

Jing-cheng Wang ¹^,²^,³
, Lei Li ¹^,²^,³^,^b
, Yong Yu ¹^,²^,³

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Abstract

A new method for separating and recovering tin from a low-grade tin middling with high Si content and low Fe content by roasting with anthracite coal was researched by studying the reaction mechanism and performing an industrial test, in which the Sn was sulfurized into SnS(g) and then collected using a dust collector. The Fe-Sn alloy may be formed at roasting temperatures above 950°C, and like the roasting temperature increases, the Sn content and Sn activity in this Fe-Sn alloy decrease. Also, more FeS can be formed at higher temperatures and then the formation of FeO-FeS with a low melting point is promoted, which results in more serious sintering of this low-grade tin middling. And from the thermodynamics and kinetics points of view, the volatilization of the Sn decreases at extremely high roasting temperatures. The results of the industrial test carried out in a coal-fired rotary kiln show that the Sn volatilization rate reaches 89.7% and the Sn is concentrated in the collected dust at a high level, indicating that the Sn can be effectively extracted and recovered from the low-grade tin middling with a high Si content and low Fe content through a reduction—sulfurization roasting process.

Keywords

low-grade tin middling / tin recovery / roasting process / Fe-Sn alloy / resource recycling

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Jing-cheng Wang, Lei Li, Yong Yu. Tin recovery from a low-grade tin middling with high Si content and low Fe content by reduction—sulfurization roasting with anthracite coal. International Journal of Minerals, Metallurgy, and Materials, 2021, 28(2): 210-220 DOI:10.1007/s12613-020-2038-8

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References

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[1]	Angadi SI, Sreenivas T, Jeon HS, Baek SH, Mishra BK. A review of cassiterite beneficiation fundamentals and plant practices. Miner. Eng., 2015, 70, 178.

[2]	Meng L, Wang Z, Zhong YW, Chen KY, Guo ZC. Supergravity separation of Pb and Sn from waste printed circuit boards at different temperatures. Int. J. Miner. Metal. Mater., 2018, 25(2): 173.

[3]	Xu YB, Qin WQ, Liu H. Mineralogical characterization of tin-polymetallic ore occurred in Mengzi, Yunnan province, China. Trans. Nonferrous Met. Soc. China, 2012, 22(3): 725.

[4]	Brocchi EA, Moura FJ. Chlorination methods applied to recover refractory metals from tin slags. Miner. Eng., 2008, 21(2): 150.

[5]	Leistner T, Embrechts M, Leißner T, Chehreh Chelgani S, Osbahr I, Möckel R, Peuker UA, Rudolph M. A study of the reprocessing of fine and ultrafine cassiterite from gravity tailing residues by using various flotation techniques. Miner. Eng., 2016, 96–97, 94.

[6]	Bulatovic SM. Handbook of Flotation Reagents: Chemistry. Theory and Practice: Volume 2. 21-Flotation of Tin Minerals, 2010, Amsterdam, Elsevier, 87.

[7]	Richards RG, Mhunter DM, Gates PJ, Palmer MK. Gravity separation of ultra-fine (−0.1mm) minerals using spiral separators. Miner. Eng., 2000, 13(1): 65.

[8]	Xu XY, Hayes PC, Jak E. Phase equilibria in the “SnO-SiO₂-FeO” system in equilibrium with tin-iron alloy and the potential application for electronic scrap recycling. Int. J. Mater. Res., 2012, 103(5): 529.

[9]	Zhang YB, Jiang T, Li GH, Huang ZC, Guo YF. Tin and zinc separation from tin. zinc bearing complex iron ores by selective reduction process. Ironmaking Steelmaking, 2011, 38(8): 613.

[10]	Wang ZW, Wang CY, Lu HM. Investigation on removal of tin from Sn-bearing iron concentrates by reduction roasting. Min. Metall., 2005, 14(2): 63.

[11]	Tong X, Zhou YC, Lü JF, Xie X, Li GD. Recovering tin and iron from vein tin tailings in Yunnan tin group by roasting-cohesion-magnetic separation technology. Chin. J. Nonferrous Met., 2011, 21(7): 1696.

[12]	Zhou LJ. Industrial practice of direct treatment of high silicon Tin slag by cigarette furnace. China Nonferrous Metall., 1992, 2, 30.

[13]	Y.N. Dai, Development of tin metallurgy technology in China, Nonferrous Met.(Extr. Metall.), 1979, No. 5, p. 8.

[14]	Omran M, Fabritius T, Elmahdy AM, Abdel-Khalek NA, Gornostayev S. Improvement of phosphorus removal from iron ore using combined microwave pretreatment and ultrasonic treatment. Sep. Purif. Technol., 2015, 156, 724.

[15]	Zhang YB, Chen LY, Li GH, Jiang T, Huang ZC. Mineralogical features and comprehensive utilization technology of tin, zinc-bearing iron concentrates. J. Cent. South Univ., 2011, 42(6): 1501.

[16]	Li PL, Cai J, Zhang XZ, Xie YL. How to utilize the foreign iron ore resources effectively. Met. Mine Des. Constr., 2002, 34(6): 18.

[17]	Yu Y, Li L, Wang JY, Li KZ, Wang H. Phase transformation of Sn in tin-bearing iron concentrates by roasting with FeS₂ in CO-CO₂ mixed gases and its effects on Sn separation. J. Alloys Compd., 2018, 750, 8.

[18]	Zhang RJ, Li L, Yu Y. Reduction roasting of tin-bearing iron concentrates using pyrite. ISIJ Int., 2016, 56(6): 953.

[19]	Yu Y, Li L, Sang XL. Removing tin from tin-bearing iron concentrates with sulfidation roasting using high sulfur coal. ISIJ Int., 2016, 56(1): 57.

[20]	Yu Y, Li L, Wang JY, Wang JC, Li KZ. Sn separation from Sn-bearing iron concentrates by roasting with waste tire rubber in N₂ + CO + CO₂ mixed gases. J. Hazard. Mater., 2019, 371, 440.

[21]	Wang S, Guo YF, Fan JJ, He Y, Jiang T, Chen F, Zheng FQ, Yang LZ. Initial stage of deposit formation process in a coal fired grate-rotary kiln for iron ore pellet production. Fuel Process. Technol., 2018, 175, 54.

[22]	Lv WZ, Yu DX, Wu JQ, Zhang L, Xu MH. The chemical role of CO₂ in pyrite thermal decomposition. Proc. Combust. Inst., 2015, 35(3): 3637.

[23]	Su ZJ, Zhang YB, Liu BB, Zhou YL, Jiang T, Li GH. Reduction behavior of SnO₂ in the tin-bearing iron concentrates under CO-CO₂ atmosphere. Powder Technol., 2016, 292, 251.

[24]	Huang F, Zhang LQ, Yi BJ, Xia ZJ, Zheng CG. Transformation pathway of excluded mineral pyrite decomposition in CO₂ atmosphere. Fuel Process. Technol., 2015, 138, 814.

[25]	Li Y, Gao XP, Wu HW. Ash cenosphere from solid fuels combustion. Part 2: Significant role of ash cenosphere fragmentation in ash and particulate matter formation. Energy Fuels, 2013, 27(2): 822.

[26]	Li Y, Wu HW. Ash cenosphere from solid fuels combustion. Part 1: An investigation into its formation mechanism using pyrite as a model fuel. Energy Fuels, 2012, 26(1): 130.

[27]	Urban NR, Ernst K, Bernasconi S. Addition of sulfur to organic matter during early diagenesis of lake sediments. Geochim. Cosmochim. Acta, 1999, 63(6): 837.

[28]	Li PS, Hu Y, Yu W, Yue YN, Xu Q, Hu S, Hu NS, Yang J. Investigation of sulfur forms and transformation during the co-combustion of sewage sludge and coal using X-ray photoelectron spectroscopy. J. Hazard. Mater., 2009, 167(1–3): 1126.