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Volume 25 Issue 4
Apr.  2018
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Xiao-ping Wang, Ti-chang Sun, Chao Chen, and Jue Kou, Effects of Na2SO4 on iron and nickel reduction in a high-iron and low-nickel laterite ore, Int. J. Miner. Metall. Mater., 25(2018), No. 4, pp. 383-390. https://doi.org/10.1007/s12613-018-1582-y
Cite this article as:
Xiao-ping Wang, Ti-chang Sun, Chao Chen, and Jue Kou, Effects of Na2SO4 on iron and nickel reduction in a high-iron and low-nickel laterite ore, Int. J. Miner. Metall. Mater., 25(2018), No. 4, pp. 383-390. https://doi.org/10.1007/s12613-018-1582-y
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研究论文

Effects of Na2SO4 on iron and nickel reduction in a high-iron and low-nickel laterite ore

  • 通讯作者:

    Ti-chang Sun    E-mail: suntc@ces.ustb.edu.cn

  • This study investigates the reactions of Na2SO4 and its effects on iron and nickel reduction in the roasting of a high-iron and low-nickel laterite ore through gas composition, X-ray diffraction, and scanning electron microscope analyses. Results showed that a reduction reaction of Na2SO4 to SO2 was performed with roasting up to 600℃. However, no clear influence on iron and nickel reductions appeared, because only a small amount of Na2SO4 reacted to produce SO2. Na2SO4 reacted completely at 1000℃, mainly producing troilite and nepheline, which remarkably improves selective reduction of nickel. Furthermore, the production of low-melting-point minerals, including troilite and nepheline, accelerated nickel reduction and delayed iron reduction, which is attributed to the concurrent production of magnesium magnetite, whose structure is more stable than the structure of magnetite. Reduction reactions of Na2SO4 resulted in weakening of the reduction atmosphere, and the main product of Na2SO4 changed and delayed the reduction of iron. Eventually, iron metallization was effectively controlled during laterite ore reduction roasting, leading to iron mainly being found in wustite and high iron-containing olivine.
  • Research Article

    Effects of Na2SO4 on iron and nickel reduction in a high-iron and low-nickel laterite ore

    + Author Affiliations
    • This study investigates the reactions of Na2SO4 and its effects on iron and nickel reduction in the roasting of a high-iron and low-nickel laterite ore through gas composition, X-ray diffraction, and scanning electron microscope analyses. Results showed that a reduction reaction of Na2SO4 to SO2 was performed with roasting up to 600℃. However, no clear influence on iron and nickel reductions appeared, because only a small amount of Na2SO4 reacted to produce SO2. Na2SO4 reacted completely at 1000℃, mainly producing troilite and nepheline, which remarkably improves selective reduction of nickel. Furthermore, the production of low-melting-point minerals, including troilite and nepheline, accelerated nickel reduction and delayed iron reduction, which is attributed to the concurrent production of magnesium magnetite, whose structure is more stable than the structure of magnetite. Reduction reactions of Na2SO4 resulted in weakening of the reduction atmosphere, and the main product of Na2SO4 changed and delayed the reduction of iron. Eventually, iron metallization was effectively controlled during laterite ore reduction roasting, leading to iron mainly being found in wustite and high iron-containing olivine.
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    • [1]
      B.Z. Ma, W.J. Yang, B. Yang, C.Y. Wang, Y.Q. Chen, and Y.L. Zhang, Pilot-scale plant study on the innovative nitric acid pressure leaching technology for laterite ores, Hydrometallurgy., 155(2015), p. 88.
      [2]
      B. Li, H. Wang, and Y.G. Wei, The reduction of nickel from low-grade nickel laterite ore using a solid-state deoxidisation method, Miner. Eng., 24(2011), No. 14, p. 1556.
      [3]
      R. Elliott, C.A. Pickles, and J. Peacey, Ferronickel particle formation during the carbothermic reduction of a limonitic laterite ore, Miner. Eng., 100(2017), p. 166.
      [4]
      S.W, Zhou, J.C. Dong, C. Lu, B. Li, F. Li, B. Zhang, H. Wang, and Y.G. Wei, Effect of sodium carbonate on phase transformation of high-magnesium laterite ore, Mater. Trans., 58(2017), No. 5, p. 790.
      [5]
      X.M. Lv, X.W. Lv, L.W. Wang, and J. Qiu, Thermal analysis kinetics of the solid-state reduction of nickel laterite ores by carbon,[in] 8th International Symposium on High-Temperature Metallurgical Processing, Ontario, 2017, p. 147.
      [6]
      A.P. He and J.M. Zeng, Direct preparation of low Ni-Cr alloy cast iron from red mud and laterite nickel ore, Mater. Des., 115(2017), p. 433.
      [7]
      M. Jiang, T.C. Sun, Z.G. Liu, J. Kou, N. Liu, and S.Y. Zhang, Mechanism of sodium sulfate in promoting selective reduction of nickel laterite ore during reduction roasting process, Int. J. Miner. Process., 123(2013), p. 32.
      [8]
      X.H. Tang, R.Z. Liu, L. Yao, Z.J. Ji, Y.T. Zhang, and S.Q. Li, Ferronickel enrichment by fine particle reduction and magnetic separation from nickel laterite ore, Int. J. Miner. Metall. Mater., 21(2014), No. 10, p. 955.
      [9]
      M. Liu, X.W. Lv, E.G. Guo, P. Chen, and Q.G. Yuan, Novel process of ferronickel nugget production from nickel laterite by semi-molten state reduction, ISIJ Int., 54(2014), No. 8, p. 1749.
      [10]
      G.H. Li, T.M. Shi, M.J. Rao, T. Jiang, and Y.B. Zhang, Beneficiation of nickeliferous laterite by reduction roasting in the presence of sodium sulfate, Miner. Eng., 32(2012), p. 19.
      [11]
      R. Elliott, A Study on the Role of Sulphur in the Thermal Upgrading of Nickeliferous Laterite Ores[Dissertation], Queen's University, Kingston, 2015.
      [12]
      M.J. Rao, G.H. Li, X. Zhang, J. Luo, Z.W. Peng, and T. Jiang, Reductive roasting of nickel laterite ore with sodium sulphate for Fe-Ni production. Part Ⅱ:Phase transformation and grain growth, Sep. Sci. Technol., 51(2016), No. 10, p. 1727.
      [13]
      D.Q. Zhu, Y. Cui, K. Vining, S. Hapugoda, J. Douglas, J. Pan, and G.L. Zheng, Upgrading low nickel content laterite ores using selective reduction followed by magnetic separation, Int. J. Miner. Process., 106(2012), p. 1.
      [14]
      M.J. Rao, G.H. Li, X. Zhang, J. Luo, Z.W. Peng, and T. Jiang, Reductive roasting of nickel laterite ore with sodium sulfate for Fe-Ni production. Part I:Reduction/sulfidation characteristics, Sep. Sci. Technol., 51(2016), No. 8, p. 1408.
      [15]
      R. Elliott, F. Rodrigues, C.A. Pickles, and J. Peacey, A two-stage thermal upgrading process for nickeliferous limonitic laterite ores, Can. Metall. Q., 54(2016), No. 4, p. 395.
      [16]
      J. Lu, S.J. Liu, J. Shangguan, W.G. Du, F. Pan, and S. Yang, The effect of sodium sulphate on the hydrogen reduction process of nickel laterite ore, Miner. Eng., 49(2013), p. 154.
      [17]
      E.X. Gao, Z.G. Liu, T.C. Sun, and X.P. Wang, Inhibition mechanism of iron mineral reduction in high iron type laterite nickel ore with the addition of sodium sulfate, Chin. J. Eng., 38(2016), No. 6, p. 754.
      [18]
      Z.G. Liu, T.C. Sun, X.P. Wang, and E.X. Gao, Generation process of FeS and its inhibition mechanism on iron mineral reduction in selective direct reduction of laterite nickel ore, Int. J. Miner. Metall. Mater., 22(2015), No. 9, p. 901.
      [19]
      S.W. Zhou, B. Li, Y.G. Wei, H. Wang, C.Y. Wang, and B.Z. Ma, Effect of additives on phase transformation of nickel laterite ore during low-temperature reduction roasting process using carbon monoxide,[in] Drying, Roasting, and Calcining of Minerals, Florida, 2015, p. 177.
      [20]
      Y.F. Ren, L.Y. Jiang, S.T. Wang, and L. Feng, Studies of the occurrence state and the mineral composition of MgO in dolomite sintered ore as well as its effect on the metallurgical performance, Sintering Pelletizing, 1984, No. 3, p. 1.
      [21]
      Y.F. Ren, L.Y. Jiang, and S.T. Wang, The occurrence state and function of magnesia on the artificial enriched ore, J. Beijing Univ. Iron. Steel. Technol., 1983, No. 4, p. 1.
      [22]
      G.H. Li, M.J. Rao, T. Jiang, T.M. Shi, and Q.Q. Huang, Reduction roasting-magnetic separation mechanisms of nickelferous laterite ore in presence of sodium salts, Chin. J. Nonferrous Met., 22(2012), No. 1, p. 274.

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