Thermodynamics and phase transformations in the recovery of zinc from willemite

Feng Chen; Wei Chen; Yu-feng Guo; Shuai Wang; Fu-qiang Zheng; Tao Jiang; Ze-qiang Xie; Ling-zhi Yang

doi:10.1007/s12613-018-1691-7

International Journal of Minerals, Metallurgy, and Materials ›› 2018, Vol. 25 ›› Issue (12) : 1373 -1379. DOI: 10.1007/s12613-018-1691-7

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Thermodynamics and phase transformations in the recovery of zinc from willemite

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Abstract

Willemite is a common component of zinc and lead metallurgical slags that, in the absence of effective utilization methods, cause serious environmental problems. To solve this problem and increase zinc recovery, we proposed a novel extraction method of zinc from willemite by calcified roasting followed by leaching in NH₄Cl–NH₃·H₂O solution. The thermodynamics and phase conversion of Zn₂SiO₄ to zinc oxide (ZnO) during calcified roasting with CaO were investigated. The mechanism of mineralogical phase conversion and the effects of the CaO-to-Zn₂SiO₄ mole ratio (n(CaO)/n(Zn₂SiO₄)), roasting temperature, and the roasting time on zinc-bearing phase conversion were experimentally investigated. The results show that Zn₂SiO₄ was first converted to Ca₂ZnSi₂O₇ and then to ZnO. The critical step in extracting zinc from willemite is the conversion of Zn₂SiO₄ to ZnO. The zinc percent leached in the ammonia leaching system rapidly increased because of the gradual complete phase conversion from willemite to ZnO via the calcified roasting process.

Keywords

willemite / zinc residues / calcified-roasting / thermodynamics / mineralogical phase conversion

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Feng Chen, Wei Chen, Yu-feng Guo, Shuai Wang, Fu-qiang Zheng, Tao Jiang, Ze-qiang Xie, Ling-zhi Yang. Thermodynamics and phase transformations in the recovery of zinc from willemite. International Journal of Minerals, Metallurgy, and Materials, 2018, 25(12): 1373-1379 DOI:10.1007/s12613-018-1691-7

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References

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[1]	Wang J., Huang Q., Li T., Xin B., Chen S., Guo X., Liu C., Li Y. Bioleaching mechanism of Zn, Pb, In, Ag, Cd and As from Pb/Zn smelting slag by autotrophic bacteria. J. Environ. Manage., 2015, 159, 11.

[2]	Abkhoshk E., Jorjani E., Al–Harahsheh M.S., Rashchi F., Naazeri M. Review of the hydrometallurgical processing of non–sulfide zinc ores. Hydrometallurgy, 2014, 149, 153.

[3]	Sethurajan M., Huguenot D., Jain R., Lens P.N.L., Horn H.A., Figueiredo L.H.A., van Hullebusch E.D. Leaching and selective zinc recovery from acidic leachates of zinc metallurgical leach residues. J. Hazard. Mater., 2017, 324, 71.

[4]	Yin N.H., Sivry Y., Guyot F., Lens P.N.L., van Hullebusch E.D. Evaluation on chemical stability of lead blast furnace (LBF) and imperial smelting furnace (ISF) slags. J. Environ. Manage., 2016, 180, 310.

[5]	Hu H.P., Deng Q.F., Li C., Xie Y., Dong Z.Q., Zhang W. The recovery of Zn and Pb and the manufacture of lightweight bricks from zinc smelting slag and clay. J. Hazard. Mater., 2014, 271, 220.

[6]	Lima L.R.P.D., Bernardez L.A. Characterization of the lead smelter slag in Santo Amaro, Bahia, Brazil. J. Hazard. Mater., 2011, 189(3): 692.

[7]	S. Onisei, Y. Pontikes, T. van Gerven, G.N. Angelopoulos, T. Velea, V. Predica, and P. Moldovan, Synthesis of inorganic polymers using fly ash and primary lead slag, J. Hazard. Mater., 205–206 (2012), p. 101.

[8]	Altundogan H.S., Erdem M., Orhan R., Ozer A., Tumen F. Heavy metal pollution potential of zinc leach residues discarded in cinkur plant. Turk. J. Eng. Environ. Sci., 1998, 22, 167.

[9]	Zhao Y.C., Stanforth R. Integrated hydrometallurgical process for production of zinc from electric arc furnace dust in alkaline medium. J. Hazard. Mater., 2000, 80(1–3): 223.

[10]	M. Li, B. Peng, L.Y. Chai, N. Peng, H. Yan, and D.K. Hou, Recovery of iron from zinc leaching residue by selective reduction roasting with carbon, J. Hazard. Mater., 237 (2012), p. 323.

[11]	Xiong L. Study of the Preparation of High Pure Zinc from Zinc Oxides by Vacuum Carbothermic Reduction [Dissertation], 2011

[12]	Miki T., Chairaksa–Fujimoto R., Maruyama K., Nagasaka T. Hydrometallurgical extraction of zinc from CaO treated EAF dust in ammonium chloride solution. J. Hazard. Mater., 2016, 302, 90.

[13]	Xiong L.Z., Chen Q.Y., Yin Z.L., Zhang P.M., Ding Z.Y., Liu Z.X. Preparation of metal zinc from hemimorphite by vacuum carbothermic reduction with CaF2 as catalyst. Trans. Nonferrous Met. Soc. China, 2012, 22(3): 694.

[14]	Sueoka Y., Sakakibara M. Primary phases and natural weathering of smelting slag at an abandoned mine site in southwest Japan. Minerals, 2013, 3(4): 412.

[15]	Chairaksa–Fujimoto R., Maruyama K., Miki T., Nagasaka T. The selective alkaline leaching of zinc oxide from electric arc furnace dust pre–treated with calcium oxide. Hydrometallurgy, 2016, 159, 120.

[16]	He S.M., Wang J.K., Yan J.F. Pressure leaching of synthetic zinc silicate in sulfuric acid medium. Hydrometallurgy, 2011, 108(3–4): 171.

[17]	Santos F.M.F., Pina P.S., Porcaro R., Oliveira V.A., Silva C.A., Leão V.A. The kinetics of zinc silicate leaching in sodium hydroxide. Hydrometallurgy, 2010, 102(1–4): 43.

[18]	Liu Z.Y., Liu Z.H., Li Q.H., Cao Z.Y., Yang T.Z. Dissolution behavior of willemite in the (NH4)2SO4−NH3−H2O system. Hydrometallurgy, 2012, 125, 50.

[19]	Liu Z.Y., Liu Z.H., Li Q.H., Yang T.Z., Zhang X. Leaching of hemimorphite in NH3−(NH4)2SO4−H2O system and its mechanism. Hydrometallurgy, 2012, 125, 137.

[20]	Chen W., Guo Y.F., Chen F., Jiang T., Liu X.D. The extraction of zinc from willemite by calcified–roasting and ammonia–leaching process based on phase reconstruction. the 7th International Symposium on High–Temperature Metallurgical Processing, 2016 109.

[21]	Bale C.W., Bélisle E., Chartrand P., Decterov S.A., Eriksson G., Hack K., Jung I.H., Kang Y.B., Melançon J., Pelton A.D., Robelin C., Petersen S. FactSage thermochemical software and databases–recent developments. Calphad, 2009, 33(2): 295.