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Metals 2021, 11, 1301 16 of 17 59. Xiao, W.D. Mineralogy of black shale from Shanglin of Guangxi and vanadium extraction with hydrometallurgical process. Nonferr. Met. 2007, 59, 85–90. 60. He, D.; Feng, Q.; Zhang, G.; Ou, L.; Lu, Y. An environmentally-friendly technology of vanadium extraction from stone coal. Miner. Eng. 2007, 20, 1184–1186. [CrossRef] 61. Hu, K.L.; Liu, X.H. Review of roasting processing of vanadium-bearing carbonaceous shale. Rare Met. Cem. Carbides 2015, 43, 1–7. 62. Lin, H.L.; Fan, B.W. Study on mechanism of phase transformation during roasting and extracting vanadium from Fangshankou bone coal. Chin. J. Rare Met. 2001, 25, 273–277. (In Chinese) 63. Zhang, Y.M.; Bao, S.X.; Liu, T.; Chen, T.J.; Huang, J. The technology of extracting vanadium from stone coal in China: History, current statues and future prospects. Hydrometallurgy 2011, 109, 116–124. [CrossRef] 64. Wang, M.; Huang, S.; Chen, B.; Wang, X. A review of processing technologies for vanadium extraction from stone coal. Miner. Process. Extr. Met. 2020, 129, 290–298. [CrossRef] 65. Bie, S.; Wang, Z.J.; Li, Q.H.; Zhang, Y.G. Review of vanadium extraction from stone coal by roasting technique with sodium chloride and calcium oxide. Chin. J. Rare Met. 2010, 34, 291–297. (In Chinese) 66. Wang, H.S. Extraction of vanadtum from stone coal by roasting in the presence of sodium salts. Min. Metall. Eng. 1994, 14, 49–52. 67. Wan, J.Y.; Chen, T.J.; Han, J.; Feng, Y. Thermodynamics analysis of chlorination volatilization enrichment process of black shale. Nonferr. Met. (Extr. Metall.) 2018, 5, 50–55. (In Chinese) 68. Zhang, Y.; Hu, Y.; Bao, S. Vanadium emission during roasting of vanadium-bearing stone coal in chlorine. Miner. Eng. 2012, 30, 95–98. [CrossRef] 69. Li, C.-X.; Wei, C.; Deng, Z.-G.; Li, M.-T.; Li, X.-B.; Fan, G. Recovery of vanadium from black shale. Trans. Nonferr. Met. Soc. China 2010, 20, s127–s131. [CrossRef] 70. Erust, C.; Akcil, A.; Bedelova, Z.; Anarbekov, K.; Baikonurova, A.; Tuncuk, A. Recovery of vanadium from spent catalysts of sulfuric acid plant by using inorganic and organic acids: Laboratory and semi-pilot tests. Waste Manag. 2016, 49, 455–461. [CrossRef] 71. Li, Z.; Chen, M.; Zhang, Q.; Liu, X.; Saito, F. Mechanochemical processing of molybdenum and vanadium sulfides for metal recovery from spent catalysts wastes. Waste Manag. 2017, 60, 734–738. [CrossRef] [PubMed] 72. Beolchini, F.; Fonti, V.; Dell’Anno, A.; Rocchetti, L.; Vegliò, F. Assessment of biotechnological strategies for the valorization of metal bearing wastes. Waste Manag. 2012, 32, 949–956. [CrossRef] 73. Akcil, A.; Vegliò, F.; Ferella, F.; Okudan, M.D.; Tuncuk, A. A review of metal recovery from spent petroleum catalysts and ash. Waste Manag. 2015, 45, 420–433. [CrossRef] 74. Biswas, R.; Wakihara, M.; Taniguchi, M. Recovery of vanadium and molybdenum from heavy oil desulphurization waste catalyst. Hydrometallurgy 1985, 14, 219–230. [CrossRef] 75. Gaballah, I.; Djona, M. Recovery of Co, Ni, Mo and V from unroasted spent hydrorefining catalysts by selective chlorination. Metall. Mater. Trans. B 1995, 26, 41–50. [CrossRef] 76. Gaballah, I.; Djona, M.; Mugica, J.; Solozobal, R. Valuable metals recovery from spent catalysts by selective chlorination. Resour. Conserv. Recycl. 1994, 10, 87–96. [CrossRef] 77. Zhang, J.Y. Metallurgical Physical Chemistry; Metallurgical Industry Press: Beijing, China, 2004. (In Chinese) 78. Mink, G.; Bertóti, I.; Székely, T. Chlorination of V2O5 by CCl4. Adsorption and steady state reaction. React. Kinet. Catal. Lett. 1985, 27, 33–38. [CrossRef] 79. Mink, G.; Bertóti, I.; Székely, T. Chlorination of V2O5 by CCl4, the proposed reaction mechanism. React. Kinet. Catal. Lett. 1985, 27, 39–45. [CrossRef] 80. Jena, P.; Brocchi, E.; González, J. Kinetics of Low-Temperature Chlorination of Vanadium Pentoxide by Carbon Tetrachloride Vapor. Metall. Mater. Trans. B 2005, 36, 195–199. [CrossRef] 81. Gaballah, I.; Djona, M.; Allain, E. Kinetics of chlorination and carbochlorination of vanadium pentoxide. Met. Mater. Trans. A 1995, 26, 711–718. [CrossRef] 82. McCarley, R.E.; Roddy, J.W. The preparation of high purity vanadium pentoxide by a chlorination procedure. J. Less Common Met. 1960, 2, 29–35. [CrossRef] 83. Pap, I.S.; Mink, G.; Bertóti, I.; Székely, T.; Babievskaya, I.Z.; Karmazsin, E. Comparative kinetic and thermodynamic study on the chlorination of V2O5 with CCl4, COCl2 and Cl2. J. Therm. Anal. Calorim. 1989, 35, 163–173. [CrossRef] 84. Jiang, D.-D.; Zhang, H.-L.; Xu, H.-B.; Zhang, Y. A novel method to prepare high-purity vanadium pentoxide by chlorination with anhydrous aluminum chloride. Chem. Lett. 2017, 46, 669–671. [CrossRef] 85. Jiang, D.D.; Zhang, H.L.; Xu, H.B.; Zhang, Y. Chlorination and purification of vanadium pentoxide with anhydrous aluminum chloride. J. Alloy. Compd. 2017, 709, 505–510. [CrossRef] 86. Shlewit, H.; Alibrahim, M. Extraction of sulfur and vanadium from petroleum coke by means of salt-roasting treatment. Fuel 2006, 85, 878–880. [CrossRef] 87. Vitolo, S.; Seggiani, M.; Filippi, S.; Brocchini, C. Recovery of vanadium from heavy oil and Orimulsion fly ashes. Hydrometallurgy 2000, 57, 141–149. [CrossRef] 88. Murase, K.; Nishikawa, K.I.; Ozaki, T.; Machida, K.I.; Adachi, G.Y.; Suda, T. Recovery of vanadium, nickel and magnesium from a fly ash of bitumen-in-water emulsion by chlorination and chemical transport. J. Alloy. Compd. 1998, 264, 151–156. [CrossRef]PDF Image | Extraction of the Rare Element Vanadium
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