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Volume 24 Issue 11
Nov.  2017
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Peng Xing, Bao-zhong Ma, Peng Zeng, Cheng-yan Wang, Ling Wang, Yong-lu Zhang, Yong-qiang Chen, Shuo Wang,  and Qiu-yin Wang, Deep cleaning of a metallurgical zinc leaching residue and recovery of valuable metals, Int. J. Miner. Metall. Mater., 24(2017), No. 11, pp. 1217-1227. https://doi.org/10.1007/s12613-017-1514-2
Cite this article as:
Peng Xing, Bao-zhong Ma, Peng Zeng, Cheng-yan Wang, Ling Wang, Yong-lu Zhang, Yong-qiang Chen, Shuo Wang,  and Qiu-yin Wang, Deep cleaning of a metallurgical zinc leaching residue and recovery of valuable metals, Int. J. Miner. Metall. Mater., 24(2017), No. 11, pp. 1217-1227. https://doi.org/10.1007/s12613-017-1514-2
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研究论文

Deep cleaning of a metallurgical zinc leaching residue and recovery of valuable metals

  • 通讯作者:

    Cheng-yan Wang    E-mail: chywang@yeah.net

  • Huge quantities of zinc leaching residues (ZLRs) generated from zinc production are dumped continuously around the world and pose a potential environmental threat because of their considerable amounts of entrained heavy metals (mainly lead). Most ZLRs have not been properly treated and the valuable metals in them have not yet been effectively recovered. Herein, the deep cleaning of a ZLR and recovery of valuable metals via a hydrometallurgical route were investigated. The cleaning process consists of two essential stages:acid leaching followed by calcium chloride leaching. The optimum conditions for extracting zinc, copper, and indium by acid leaching were a sulfuric acid concentration of 200 g·L-1, a liquid/solid ratio of 4:1 (mL/g), a leaching time of 2 h, and a temperature of 90℃. For lead and silver extractions, the optimum conditions were a calcium chloride concentration of 400 g·L-1, a pH value of 1.0, a leaching time of 1 h, and a temperature of 30℃. After calcium chloride leaching, silver and lead were extracted out and the lead was finally recovered as electrolytic lead by electrowinning. The anglesite phase, which poses the greatest potential environmental hazard, was removed from the ZLR after deep cleaning, thus reducing the cost of environmental management of ZLRs. The treatment of chlorine and spent electrolyte generated in the process was discussed.
  • Research Article

    Deep cleaning of a metallurgical zinc leaching residue and recovery of valuable metals

    + Author Affiliations
    • Huge quantities of zinc leaching residues (ZLRs) generated from zinc production are dumped continuously around the world and pose a potential environmental threat because of their considerable amounts of entrained heavy metals (mainly lead). Most ZLRs have not been properly treated and the valuable metals in them have not yet been effectively recovered. Herein, the deep cleaning of a ZLR and recovery of valuable metals via a hydrometallurgical route were investigated. The cleaning process consists of two essential stages:acid leaching followed by calcium chloride leaching. The optimum conditions for extracting zinc, copper, and indium by acid leaching were a sulfuric acid concentration of 200 g·L-1, a liquid/solid ratio of 4:1 (mL/g), a leaching time of 2 h, and a temperature of 90℃. For lead and silver extractions, the optimum conditions were a calcium chloride concentration of 400 g·L-1, a pH value of 1.0, a leaching time of 1 h, and a temperature of 30℃. After calcium chloride leaching, silver and lead were extracted out and the lead was finally recovered as electrolytic lead by electrowinning. The anglesite phase, which poses the greatest potential environmental hazard, was removed from the ZLR after deep cleaning, thus reducing the cost of environmental management of ZLRs. The treatment of chlorine and spent electrolyte generated in the process was discussed.
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    • [1]
      E. Abkhoshk, E. Jorjani, M.S. Al-Harahsheh, F. Rashchi, and M. Naazeri, Review of the hydrometallurgical processing of non-sulfide zinc ores, Hydrometallurgy, 149(2014), p. 153.
      [2]
      M. Deniz Turan, H. Soner Altundoğan, and F. Tümen, Recovery of zinc and lead from zinc plant residue, Hydrometallurgy, 75(2004), No. 1-4, p. 169.
      [3]
      Y.L. Zhang, X.J. Yu, and X.B. Li, Kinetics of simultaneous leaching of Ag and Pb from hydrometallurgical zinc residues by chloride, Rare Met., 31(2012), No. 4, p. 402.
      [4]
      A. Özverdİ and M. Erdem, Environmental risk assessment and stabilization/solidification of zinc extraction residue:I. Environmental risk assessment, Hydrometallurgy, 100(2010), No. 3-4, p. 103.
      [5]
      X.B. Min, X.D. Xie, L.Y. Chai, Y.J. Liang, M. Li, and Y. Ke, Environmental availability and ecological risk assessment of heavy metals in zinc leaching residue, Trans. Nonferrous Met. Soc. China, 23(2013), No. 1, p. 208.
      [6]
      M. Erdem and A. Özverdi, Environmental risk assessment and stabilization/solidification of zinc extraction residue:Ⅱ. Stabilization/solidification, Hydrometallurgy, 105(2011), No. 3-4, p. 270.
      [7]
      D. Qiu and L. Chai, Nonferrous Metallurgy and Environmental Protection, Central South University Press, Changsha, 2015, p. 292.
      [8]
      J.K. Rastas, K.M.J. Saari, V.V.H. Hintikka, J.O. Leppinen, and A.E. Jarvinen, Flotation Recovery of Lead, Silver and Gold as Sulfides from Electrolytic Zinc Process Residues, United States Patent, Patent No. 4385038, 1983.
      [9]
      F. Rashchi, A. Dashti, M. Arabpour-Yazdi, and H. Abdizadeh, Anglesite flotation:a study for lead recovery from zinc leach residue, Miner. Eng., 18(2005), No. 2, p. 205.
      [10]
      R. Raghavan, P.K. Mohanan, and S.C. Patnaik, Innovative processing technique to produce zinc concentrate from zinc leach residue with simultaneous recovery of lead and silver, Hydrometallurgy, 48(1998), No. 2, p. 225.
      [11]
      X.S. Yan and C.L. Chen, Discussion on the pyrometallurgical process for zinc leaching residues, China Nonferrous Metall., 2012, No. 5, p. 58.
      [12]
      Y. Ma and F. Wang, Study on comprehensive utilization of lead-silver residue, China Nonferrous Metall., 2008, No. 5, p. 44.
      [13]
      P. Ashtari and P. Pourghahramani, Selective mechanochemical alkaline leaching of zinc from zinc plant residue, Hydrometallurgy, 156(2015), p. 165.
      [14]
      M. Sethurajan, D. Huguenot, R. Jain, P.N.L. Lens, H.A. Horn, L.H.A. Figueiredo, and Eric D. van Hullebusch, Leaching and selective zinc recovery from acidic leachates of zinc metallurgical leach residues, J. Hazard. Mater., 324(2017), p. 71.
      [15]
      A. Ruşen, A.S. Sunkar, and Y.A. Topkaya, Zinc and lead extraction from Çinkur leach residues by using hydrometallurgical method, Hydrometallurgy, 93(2008), No. 1-2, p. 45.
      [16]
      F. Farahmand, D. Moradkhani, M.S. Safarzadeh, and F. Rashchi, Brine leaching of lead-bearing zinc plant residues:Process optimization using orthogonal array design methodology, Hydrometallurgy, 95(2009), No. 3-4, p. 316.
      [17]
      Z.H. Guo, F.K. Pan, X.Y. Xiao, L. Zhang, and K.Q. Jiang, Optimization of brine leaching of metals from hydrometallurgical residue, Trans. Nonferrous Met. Soc. China, 20(2010), No. 10, p. 2000.
      [18]
      B. Behnajady and J. Moghaddam, Chloride leaching of lead and silver from refractory zinc plant residue, Res. J. Chem. Environ., 15(2011), No. 2, p. 473.
      [19]
      M. Şahin and M. Erdem, Cleaning of high lead-bearing zinc leaching residue by recovery of lead with alkaline leaching, Hydrometallurgy, 153(2015), p. 170.
      [20]
      Y.J. Zhang, X.H. Li, L.P. Pan, X.Y. Liang, and X.P. Li, Studies on the kinetics of zinc and indium extraction from indium-bearing zinc ferrite, Hydrometallurgy, 100(2010), No. 3-4, p. 172.
      [21]
      S.M.J. Koleini, H. Mehrpouya, K. Saberyan, and M. Abdolahi, Extraction of indium from zinc plant residues, Miner. Eng., 23(2010), No. 1, p. 51.
      [22]
      X.B. Li, C. Wei, Z.G. Deng, C.X. Li, G. Fan, H. Rong, and F. Zhang, Extraction and separation of indium and copper from zinc residue leach liquor by solvent extraction, Sep. Purif. Technol., 156(2015), p. 348.
      [23]
      H. Sawai, I.M.M. Rahman, Y. Tsukagoshi, T. Wakabayashi, T. Maki, S. Mizutani, and H. Hasegawa, Selective recovery of indium from lead-smelting dust, Chem. Eng. J., 277(2015), p. 219.
      [24]
      F. Carranza, R. Romero, A. Mazuelos, and N. Iglesias, Recovery of Zn from acid mine water and electric arc furnace dust in an integrated process, J. Environ. Manage., 165(2016), p. 175.
      [25]
      M. Volpe, D. Oliveri, G. Ferrara, M. Salvaggio, S. Piazza, S. Italiano, and C. Sunseri, Metallic lead recovery from lead-acid battery paste by urea acetate dissolution and cementation on iron, Hydrometallurgy, 96(2009), No. 1-2, p. 123.
      [26]
      Y. Xing and S.X. Wu, Study on electrowinning extraction of lead from zinc oxide leach residue of ironmaking dust, Min. Metall., 22(2013), No. 2, p. 75.
      [27]
      E. Expósito, J. Iniesta, J. González-García, V. Montiel, and A. Aldaz, Lead electrowinning in an acid chloride medium, J. Power Sources, 92(2001), No. 1-2, p. 260.
      [28]
      D. Sinadinović, Ž. Kamberović, and A. Šutić, Leaching kinetics of lead from lead (Ⅱ) sulphate in aqueous calcium chloride and magnesium chloride solutions, Hydrometallurgy, 47(1997), No. 1, p. 137.
      [29]
      C.I. Cerceau, C.F. Carvalho, A.C.S. Rabelo, C.G. Santos, S.M.D. Gonçalves, and E.V.V. Varejão, Recovering lead from cupel waste generated in gold analysis by Pb-fire assay, J. Environ. Manage., 183(2016), No. 3, p. 771.

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