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Mineral Processing and Extractive Metallurgy Review
An International Journal
Volume 37, 2016 - Issue 4
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Articles

Phosphorus Removal and Iron Recovery from High-Phosphorus Hematite Using Direct Reduction Followed by Melting Separation

Huiqing TangState Key Laboratory of Advanced Metallurgy, University of Science and Technology Beijing, Beijing, ChinaCorrespondence[email protected]
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,
Yanqi QinState Key Laboratory of Advanced Metallurgy, University of Science and Technology Beijing, Beijing, ChinaView further author information
&
Tengfei QiState Key Laboratory of Advanced Metallurgy, University of Science and Technology Beijing, Beijing, ChinaView further author information
Pages 236-245 | Published online: 08 Jun 2016

References

  • Bai, S., Wen, S., Liu, D., Zhang, W. and Cao, Q., 2012, “Beneficiation of high phosphorus limonite ore by sodium carbonate-added carbothermic reduction.” ISIJ International, 52(10), pp. 1757–1763
  • Cheng, C. Y., Misra, V. N., Clough, J. and Mun, R., 1999, “Dephosphorization of western Australian iron ore by hydrometallurgical process.” Minerals Engineering, 12(9),pp.1083–1092.
  • Elias, M. and Mitsutaka, H., 2011, “Dephosphorization treatment of high phosphorus iron ore by pre-reduction, air jet milling and screening methods.” ISIJ International, 51(4), pp. 544–551.
  • Fisher-white, M. J., Lovel, R. R. and Sparrow, G. J., 2012, “Phosphorus removal from goethitic iron ore with a low temperature heat treatment and a caustic leach.” ISIJ International, 52(5), pp. 797–803.
  • Halt, J. A. and Kawatra, S. K., 2014. “Review of organic binders for iron ore concentrate agglomeration.” Minerals & Metallurgical Processing, 31(2), pp. 72–94.
  • Halt, J. A., Roache, S. C. and Kawatra, S. K., 2015. “Cold bonding of iron ore concentrate pellets.” Minerals Processing and Extractive Metallurgy Review, 36(3), pp. 192–197.
  • Ionkov, K., Gaydardzhiev, S., Araujo, A., Bastin, D. and Lacoste, M., 2013, “Amenability for processing of oolitic iron ore concentrate for phosphorus removal.” Minerals Engineering, 46(6),pp.119–127.
  • Li, S., Zhang, Y., Gao, J., Li, J., Chen, P., Liu, R. and Wang, Y., 2011, “Experimental study on gas-based reduction of ultra-fine oolitic high-phosphorus hematite powder.” Chinese Journal of Process Engineering (in Chinese), 20(4), pp. 599–605.
  • Li, Y., Sun, T., T., Kou, J., Guo, Q. and Xu, C., 2014, “Study on phosphorus removal of high-phosphorus oolitic hematite by coal-based direct reduction and magnetic separation.” Mineral Processing & Extractive Metallurgy Review, 35(1), pp. 66–73.
  • Liu, S., Wang, W., Zhang, M. and Wen, S., 2014, “Beneficiation of a low grade hematite-magnetite ore in China.” Minerals & Metallurgical Processing, 31(2), pp. 136–142.
  • Manning, C. P. and Fruehan, R. J., 2001, “Emerging technologies for iron and steelmaking.” JOM, 63(10), pp. 36–43.
  • McClelland, J. M. and Metius, G. E., 2003, “Recycling ferrous and nonferrous waste streams with FASTMET.” JOM, 65(8), pp. 30–34.
  • Nunes, A., Pinto, C., Vala, G. and Viana, P., 2012, “Floatability studies of wavellite and preliminary results on phosphorus removal from a Brazilian iron ore by froth flotation.” Minerals Engineering, 39(12), pp. 206–212.
  • Omran, M., Fabritius, T., Abdel-Khalek, N. and Elmahdy, A., 2014, “Effect of microwave pretreatment on the magnetic properties of iron ore and its implication on magnetic separation.” Separation and Purification Technology, 136(5), pp. 223–232.
  • Omran, M., Fabritius, T. and Mattila, R., 2015, “Thermally assisted liberation of high phosphorus oolitic iron ore: comparison between microwave and conventional furnace.” Powder Technology, 269(1), pp. 7–14.
  • Song, S., Campos-Toro, E. F., Zhang, Y. and Lopez-Valdivieso, A., 2013, “Morphological and mineralogical characterizations of oolitic ore in the Exi region, China.” International Journal of Minerals, Metallurgy and Materials, 20(2), pp. 113–118.
  • Sun, Y., Han, Y., Gao, P., Wang, Z. and Ren, D., 2013, “Recovery of iron from high phosphorus oolitic iron ore using coal-based reduction followed by magnetic separation.” International Journal of Minerals,Metallurgy and Materials, 20(5), pp. 411–419.
  • Sun, Y., Han, Y., Gao, P. and Yu.J., 2015, “Size distribution behavior of metallic iron particles in coal-based reduction products of an oolitic iron ore.” Mineral Processing & Extractive Metallurgy Review, 36(4), pp. 249–257.
  • Tang, H. Fan, L., Ma, L. and Guo, Z., 2014a, “Study on phosphorus removal of oolitic high phosphorus iron ore using biomass char.” Journal of University of Science and Technology Beijing (in Chinese), 13(7), pp. 673–682.
  • Tang, H., Liu, W., Zhang, H. and Guo, Z., 2014b, “Effect of microwave treatment upon processing oolitic high phosphorus iron ore for phosphorus removal.” Metallurgical and Materials Transactions B, 45(10), pp. 1683–1693.
  • Tang, H., Ma, L., Wang, J. and Guo, Z., 2014c, “Slag-metal separation process of gas-reduced high phosphorus iron ore fines.” Journal of Iron Steel Research International, 21(12), pp. 1009–1015.
  • Wang, D., 1983, Dephosphorization in Iron and Steel Making, 1st Ed., Beijing(China):Metallurgical Industry Press, pp.75–78.
  • Wu, J., Wen, Z. and Cen, M., 2011, “Development of technologies for high phosphorus oolitic hematite utilization.” Steel Research International, 82(5), pp. 494–500.
  • Xu, C., Sun, T., Kou, J., Li, Y., Mo, X. and Tang, L., 2012, “Mechanism of phosphorus removal in beneficiation of high phosphorous oolitic hematite by direct reduction roasting with dephosphorization agent.” Transactions of Nonferrous Metal Society China, 22(11), pp. 2806–2812.
  • Yang, X., Duan, J., Shi, C., Zhang, M., Zhang, Y. and Wang, J., 2011a, “A thermodynamic model of phosphorus distribution ratio between CaO-SiO2-MgO-FeO-Fe2O3-MnO-Al2O3-P2O5 slags and molten steel during a top–bottom combined blown converter steelmaking process based on the ion and molecule coexistence theory.” Metallurgical and Materials Transactions B, 42(4), pp. 738–770.
  • Yang, X., Shi, C., Zhang, M., Duan, J. and Zhang, J., 2011b, “A thermodynamic model of phosphate capacity for CaO-SiO2-MgO-FeO-Fe2O3-MnO-Al2O3-P2O5 slags equilibrated with molten steel during a top–bottom combined blown converter steelmaking process based on the ion and molecule coexistence theory.” Metallurgical and Materials Transactions B, 42(5), pp. 951–977.
  • Ye, D. and Hu, J., 2002, Thermodynamic Data of Inorganic Substances, 2nd Ed., Beijing(China):Metallurgy Industry Press, pp.32–44.
  • Yin, J., Lv, X., Bai, C., Qiu, G., Ma, S. and Xie, B., 2012, “Dephosphorization of iron ore bearing high phosphorous by carbothermic reduction assisted with microwave and magnetic Separation.” ISIJ International, 52(9), pp. 1579–1584.
  • Yu, J., Guo, Z. and Tang, H., 2013a, “Dephosphorization treatment of high phosphorus oolitic iron ore by hydrometallurgical process and leaching kinetics.” ISIJ International, 53(12), pp. 2056–2064.
  • Yu, W., Sun, T., Kou, J., Wei, Y., Xu, C. and Liu, Z., 2013b, “The function of Ca(OH)2 and Na2CO3 as additive on the reduction of high-phosphorus oolitic hematite-coal mixed pellets.” ISIJ International, 53(3), pp. 427–433.
  • Zhang, M., Li, H., Andrade, M., Xuan, W. and Correa, A., 2015. “Feasible bioprocessing technologies for low-grade iron ore.” Minerals & Metallurgical Processing, 31(2), pp. 78–87.
  • Zhang, X., Xie, B., Li, H., Diao, J. and Ji, C., 2013, “Coupled reaction kinetics of duplex steelmaking process for high phosphorus hot metal.” Ironmaking and Steelmaking, 40(4), pp. 282–289.
  • Zhou, J., Xue, Z., Li, Z. and Zhang, H., 2007, “Characteristics of grain growth of metallic phase in direct reduction of high phosphorus oolitic hematite.” Journal of Wuhan University of Science and Technology (in Chinese), 30(5), pp. 458–460.
  • Zhu, D., Chun, T., Pan, J., Lu, L. and He, Z., 2013, “Upgrading and dephosphorization of western Australian iron ore using reduction roasting by adding sodium carbonate.” International Journal of Minerals, Metallurgy and Materials, 20(6), pp. 505–513.

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