Separation and recovery of chromium and vanadium from reduced vanadium-chromium precipitate by calcinations-alkaline leaching

doi:10.3969/j.issn.0438-1157.2014.03.026

CIESC Journal ›› 2014, Vol. 65 ›› Issue (3): 948-953.DOI: 10.3969/j.issn.0438-1157.2014.03.026

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Separation and recovery of chromium and vanadium from reduced vanadium-chromium precipitate by calcinations-alkaline leaching

YANG He, MAO Linqiang, XUE Xiangxin

School of Materials and Metallurgy, Northeastern University, Shenyang 110004, Liaoning, China

Received:2013-06-13 Revised:2013-10-13 Online:2014-03-05 Published:2014-03-05
Supported by:
supported by the National Natural Science Foundation of China (51090384) and the High Technology Research and Development Program of China (2012AA062304).

煅烧-碱浸法从钒铬还原渣中分离回收钒铬

杨合, 毛林强, 薛向欣

东北大学材料与冶金学院, 辽宁沈阳 110004

通讯作者: 杨合
作者简介:杨合（1970—），男，博士，副教授。
基金资助:
国家自然科学基金项目（51090384）；国家高技术研究发展计划项目（2012AA062304）。

Abstract

Abstract: Separation and recovery of chromium and vanadium from reduced vanadium-chromium precipitate were implemented by calcination followed by alkaline leaching. The reaction process during calcination and the factors, such as temperature, time and alkaline medium, affecting leaching vanadium were investigated. Cr(Ⅲ) and V(Ⅳ) could form CrVO₄, and then CrVO₄ was decomposed into Cr₂O₃ and V₂O₅ during calcinations. The appropriate conditions for calcination were temperature of 950℃ and time of 1.0—3.0 h. Under the same molarity conditions, NaOH was better than Na₂CO₃ for leaching V₂O₅. Increasing NaOH concentration and time was favorable for leaching of V₂O₅while temperature had little effect on leaching of V₂O₅. When reduced vanadium-chromium precipitate was calcined for 1.5 h at 850℃ and was treated for 1.5 h using 3 mol·L^-1 NaOH, the content of Cr₂O₃ in the residue was more than 96%, and leaching rates of vanadium and chromium were 87.3% and less than 1%, respectively. Additionally, 97% of vanadium in the filtrate could be precipitated by acidic ammonium salt.

Key words: reduced vanadium-chromium precipitate, calcination, leaching, recovery

摘要： 通过煅烧-碱浸法从钒铬还原渣中分离回收钒铬，考察了煅烧反应过程并探讨了煅烧-碱浸条件对浸出钒的影响。结果表明：煅烧过程中Cr（Ⅲ）和V（Ⅳ）反应生成中间产物CrVO₄，随后CrVO₄分解为Cr₂O₃和V₂O₅；相同浓度条件下，在V₂O₅浸出效果方面NaOH要优于Na₂CO₃，提高浸出介质浓度和延长浸出时间有利于V₂O₅的浸出，而浸出温度对V₂O₅浸出无明显影响，钒铬还原渣在850℃煅烧1.5 h后经3 mol·L^-1 NaOH在90℃浸出1.5 h，滤渣中的Cr₂O₃质量分数高于96%，钒、铬的浸出率分别为87.3%和小于1%，另外，利用酸性铵盐法能够沉淀滤液中97%的钒。

关键词: 钒铬还原渣, 煅烧, 浸取, 回收

CLC Number:

TF803.21

YANG He, MAO Linqiang, XUE Xiangxin. Separation and recovery of chromium and vanadium from reduced vanadium-chromium precipitate by calcinations-alkaline leaching[J]. CIESC Journal, 2014, 65(3): 948-953.

杨合, 毛林强, 薛向欣. 煅烧-碱浸法从钒铬还原渣中分离回收钒铬[J]. 化工学报, 2014, 65(3): 948-953.

References 21

[1]	Du Hegui(杜鹤桂). The Principle of Smelting Vanadium-Titanium Magnetite by Blast Furnace(高炉冶炼钒钛磁铁矿原理)[M]. Beijing: Science Press, 1996:2-5
[2]	Yu Shuqiu(于淑秋), Meng Xiangsheng(孟祥胜), Chen Jiayong(陈家镛). Separation and recovery of chromiun and vanadium by primary amine with extraction[J]. Chemical and Metallurgical(化工冶金), 1980, 2: 4-7
[3]	Wang X, Wang M, Shi L, Hu J, Qiao P. Recovery of vanadium during ammonium molybdate production using ion exchange[J]. Hydrometallurgy, 2010, 104(2): 317-321
[4]	Ning P, Cao H, Zhang Y. Stability of the interfacial crud produced during the extraction of vanadium and chromium[J]. Hydrometallurgy, 2013, 133: 156-160
[5]	Fan Y Y, Wang X W, Wang M Y. Separation and recovery of chromium and vanadium from vanadium-containing chromate solution by ion exchange[J]. Hydrometallurgy, 2013, 136: 31-35
[6]	Yang Kang(杨康), Tian Xueda(田学达), Yang Yonglong(杨用龙), Zhong Renhua(钟仁华), Chen Yanbo(陈燕波), Liu Hong(刘洪). Leaching of vanadium from vanadium-bearing chromium residues by alkaline process[J]. Mining and Metallurgical Engineering(矿冶工程), 2010, 30(3): 70-73
[7]	Yang Qiuliang(杨秋良), Chen Xibao(陈锡宝). The method of separation and recovery of vanadium and chromium from vanadium containing chromium waste water[P]: CN,200910061579.1. 2009-09-23
[8]	Zhang Yang(张洋), Xu Hongbin(徐红彬), Zhang Yi(张懿). The method of separation and recovery of vanadium and chromium from vanadium and chromium reduction precipitate[P]: CN,201110265111. 1. 2012-01-25
[9]	Guo Zhuang(郭壮). Study and application of chromium wastewater treatment by reduction and sedimentation[D]. Harbin: Harbin Industrial University, 2007: 21-24
[10]	Zhang B, Feng C, Ni J, Zhang J, Huang W. Simultaneous reduction of vanadium (Ⅴ) and chromium (Ⅵ) with enhanced energy recovery based on microbial fuel cell technology[J]. Journal of Power Sources, 2012, 204: 34-39
[11]	Ouyang Yuzhu(欧阳玉祝), Wang Jihui(王继徽). Treatment of vanadium-containing wastewater by iron filings microelectrolysis-coprecipitation process[J]. Chemical Environmental Protection(化工环保), 2002, 22(3): 165-168
[12]	Guan Hongliang(关洪亮), Cao Yanlan(操艳兰), Gu Yiya(顾逸雅), Li Caixia(李彩霞), Wang Xinglin(王杏林), He Dongsheng(何东升), Yu Xunmin(于训民). Precipitating treatment of vanadium contained waste water by using ferrous sulfate[J]. J. Wuhan Inst. Tech.(武汉工程大学学报), 2012, 34(12): 25-27
[13]	Zeng Xiaoming(曾小明), Li lingpu(李凌璞), Shu Hui(舒晖). Chemical treatment of highly concentrated vanadium-containing industrial wastewater[J]. Industrial Water Treatment(工业水处理), 2009, 27(7): 51-53
[14]	Yan Jiangfeng(阎江峰), Chen Jiaxi(陈加希), Hu Liang(胡亮). Chrome Metallurgy(铬冶金)[M]. Beijing: Metallurgical Industry Press, 2007: 121-126
[15]	Yang Shouzhi(杨守志). Vanadium Metallurgy(钒冶金)[M]. Beijing: Metallurgical Industry Press, 2010:69-72
[16]	Avena M J, Giacomelli C E, De Pauli C P. Formation of Cr(Ⅲ) hydroxides from chrome alum solutions: precipitation of active chromium hydroxide[J]. Journal of Colloid and Interface Science, 1996, 180(2): 428-435
[17]	Lei Xuefei(雷雪飞), Xue Xiangxin(薛向欣). Effect of acidity and acidic medium on photocatalytic reduction of Cr(Ⅵ) by sulfate modified titanium-bearing blast furnace slag[J]. Journal of Chemical Industry and Engineering (China)(化工学报), 2008, 59(9): 2247-2254
[18]	Palmer C D, Wittbrodt P R. Processes affecting the remediation of chromium-contaminated sites[J]. Environmental Health Perspectives, 1991, 92: 25-31
[19]	Yang K, Zhang X, Tian X. Leaching of vanadium from chromium residue[J]. Hydrometallurgy, 2010, 103(1): 7-11
[20]	Moskalyk R R, Alfantazi A M. Processing of vanadium: a review[J]. Minerals Engineering, 2003, 16(9): 793-805.
[21]	Chen Liang(陈亮). Effects of pH and temperature on acidic ammonium salt precipitation of vanadate leaching solution[J].Chinese Journal of Rarementals (稀有金属), 2010, 34(6):924-929

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Separation and recovery of chromium and vanadium from reduced vanadium-chromium precipitate by calcinations-alkaline leaching

煅烧-碱浸法从钒铬还原渣中分离回收钒铬

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