硝酸钠为助浸剂时石煤提钒的酸浸工艺研究

doi:10.12677/MEng.2020.71007

期刊菜单

硝酸钠为助浸剂时石煤提钒的酸浸工艺研究
Study on Extracting Vanadium from Stone Coal by Acid Leaching with Aid of Sodium Nitrate

DOI: 10.12677/MEng.2020.71007, PDF,
作者: 龙飞^*：吉首大学化学化工学院，湖南吉首；湖南省矿产清洁生产和绿色功能材料开发重点实验室，湖南吉首；李飞, 华俊, 高峰, 颜文斌：吉首大学化学化工学院，湖南吉首；湖南省矿产清洁生产和绿色功能材料开发重点实验室，湖南吉首；锰–锌–钒协同创新中心，湖南吉首
关键词: 石煤；硝酸钠；五氧化二钒；强化酸浸；Stone Coal； Sodium Nitrate； Vanadium Pentoxide； Enhanced Acid Leaching

摘要: 石煤提钒很困难。本文研究了以硝酸钠为助浸剂时，用硫酸从石煤中提钒的新工艺。探讨了助浸剂、固液比、浸出时间、浸出温度及硫酸浓度对钒浸出率的影响。实验结果表明，添加1.5 wt%硝酸钠比不添加时钒的浸出率提高30%左右。在硫酸用量3.0 mol/L、硝酸钠用量1.5 wt%、固液比1:1 g/ml、浸出温度95℃，浸出时间9 h的条件下，钒的浸出率达到98.16%。

Abstract: It is very difficult to extract vanadium from stone coal. A new process for extracting vanadium from stone coal with sulfuric acid using sodium nitrate as leaching aid is proposed and studied. The effects of sulfuric acid concentration, leaching temperature, leaching time and leaching aids on vanadium leaching rate were discussed. The results show that the leaching rate of vanadium with 1.5% sodium nitrate is about 30% higher than that without additives. Under the conditions of 3.0 mol/L sulfuric acid, 1.5% sodium nitrate, 1:1 g/ml solid-liquid ratio, 95˚C leaching tem-perature and leaching time 9 h, the leaching rate of vanadium reached 98.16%.

文章引用：龙飞, 李飞, 华俊, 高峰, 颜文斌. 硝酸钠为助浸剂时石煤提钒的酸浸工艺研究[J]. 冶金工程, 2020, 7(1): 41-48. https://doi.org/10.12677/MEng.2020.71007

参考文献

[1]	Hu, P.C., Zhang, Y.M., Liu, T., Huang, J., Yuan, Y.Z. and Xue, N.N. (2018) Source Separation of Vanadium over Iron from Roasted Vanadium Bearing Shale during Acid Leaching via Ferric Fluoride Surface Coating. Journal of Cleaner Production, 181, 399. [Google Scholar] [CrossRef]
[2]	胡凯龙, 刘旭恒. 含钒石煤焙烧工艺综述[J]. 稀有金属与硬质合金, 2015, 43(1): 1-6+14.
[3]	Wang, F., Zhang, Y.M., Liu, T., Huang, J., Zhao, J., Zhang, G.B. and Liu, J. (2014) Comparison of Direct Acid Leaching Process and Blank Roasting Acid Leaching Process in Extracting Vanadium from Stone Coal. International Journal of Mineral Processing, 128, 40. [Google Scholar] [CrossRef]
[4]	史玲, 谢建宏. 含钒石煤提钒工艺研究[J]. 有色金属工程, 2009, 61(2): 77-79.
[5]	徐永新, 杨欢. 石煤提钒的最佳焙烧酸浸条件[J]. 有色金属工程, 2008, 60(3): 74-76.
[6]	Zeng, X., Wang, F., Zhang, H.F., Cui, L.J., Yu, J. and Xu, G.W. (2015) Extraction of Vanadium from Stone Coal by Roasting in a Fluidized Bed Reactor. Fuel, 142, 180. [Google Scholar] [CrossRef]
[7]	Zhu, Y.G., Zhang, G.F. and Feng, Q.M. (2010) Acid Leaching of Vanadium from Roasted Residue of Stone Coal. Transactions of Nonferrous Metals Society of China, 20, s107. [Google Scholar] [CrossRef]
[8]	储少军, 章俊. 石煤资源利用技术的现状与展望[J]. 铁合金, 2014(3): 60.
[9]	Zhang, Y.M., Bao, S.X., Liu, T., Chen, T.J. and Huang, J. (2011) The Technology of Extracting Vanadium from Stone Coal in China: History, Current Status and Future Prospects. Hydrometallurgy, 109, 116. [Google Scholar] [CrossRef]
[10]	Chen, X.Y., Lan, X.Z. and Zhang, Q.L. (2010) Leaching Vanadium by High Concentration Sulfuric Acid from Stone Coal. Transactions of Nonferrous Metals Society of China, 20, s123. [Google Scholar] [CrossRef]
[11]	Xue, N.N., Zhang, Y.M., Liu, T. and Huang, J. (2015) Study of the Dissolution Behavior of Muscovite in Stone Coal by Oxygen Pressure Acid Leaching. Metallurgical & Materials Transactions B, 47, 1. [Google Scholar] [CrossRef]
[12]	Neelameggham, N.R., Alam, S., Oosterhof, H., Jha, A. and Wang, S. (2014) Ultrasonic Assisted Alkaline Leaching of Vanadium from Stone Coal. John Wiley & Sons, Inc., New York.
[13]	杨德芹, 梁晓峰, 郭学, 李海建, 等. 含钒石煤硫酸化焙烧-超声浸出实验[J]. 金属矿山, 2014(7): 101.
[14]	许金泉, 张济祥, 周京明. 石煤提钒直接酸浸法工艺研究[J]. 云南冶金, 2015, 44(2): 39.
[15]	Wang, F., Zhang, Y.M., Huang, J. and Liu, T. (2013) Mechanisms of Aid Leaching Reagent Calcium Fluoride in the Extracting Vanadium Processes from Stone Coal. Rare Metals, 32, 57. [Google Scholar] [CrossRef]
[16]	Wang, F., Zhang, Y.M., Tao, L., Jing, H., Jie, Z., Zhang, G.B. and Liu, J. (2015) A Mechanism of Calcium Fluoride Enhanced Vanadium Leaching from Stone Coal. International Journal of Mineral Processing, 145, 87. [Google Scholar] [CrossRef]
[17]	Zhang, X.Y., Yang, K. and Tian, X.D. (2011) Vanadium Leaching from Carbonaceous Shale Using Fluosilicic Acid. International Journal of Mineral Processing, 100, 184-187. [Google Scholar] [CrossRef]
[18]	C.F. (1978) Treatment of Metal Bearing Mineral Material. US Patent No. 4084961.
[19]	Anderson, C.G. (2003) Treatment of Copper Ores and Concentrates with Industrial Nitrogen Species Catalyzed Pressure Leaching and Non Cyanide Precious Metals Recovery. Journal of Management, 55, 32. [Google Scholar] [CrossRef]
[20]	Gok, O., Anderson, C.G., Çiçekli, G. and Cöcen, E.İ. (2014) Leaching Kinetics of Copper from Chalcopyrite Concentrate in Nitrous Sulfuric Acid. Physicochemical Problems of Mineral Processing, 50, 399.
[21]	Alvarado Macías, G., Fuentes Aceituno, J.C., Nava Alonso, F. and Lee, J.C. (2016) Silver Leaching with the Nitrite Copper Novel System: A Kinetic Study. Hydrometallurgy, 160, 98. [Google Scholar] [CrossRef]
[22]	Peters, E. (1992) Hydrometallurgical Process Innovation. Hydrometallurgy, 29, 431. [Google Scholar] [CrossRef]
[23]	Ye, P.H., Wang, X.W., Wang, M.Y., Fan, Y.Y. and Xiang, X.Y. (2012) Recovery of Vanadium from Stone Coal Acid Leaching Solution by Coprecipitation, Alkaline Roasting and Water Leaching. Hydrometallurgy, 117, 108. [Google Scholar] [CrossRef]
[24]	Tavakoli, M.R., Dornian, S. and Dreisinger, D.B. (2014) The Leaching of Vanadium Pentoxide Using Sulfuric Acid and Sulfite as a Reducing Agent. Hydrometallurgy, 141, 59. [Google Scholar] [CrossRef]

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