含锂矿物机械化学强化提锂工艺

doi:10.12034/j.issn.1009-606X.218169

过程工程学报 ›› 2019, Vol. 19 ›› Issue (1): 126-135.DOI: 10.12034/j.issn.1009-606X.218169

含锂矿物机械化学强化提锂工艺

何明明^1,2，尤海侠¹，赵春龙^1,3，郑晓洪¹，曹宏斌¹，孙峙^1,2*

1. 中国科学院过程工程研究所环境技术与工程研究部，绿色过程与工程重点实验室，北京市过程污染控制工程技术研究中心，北京 100190 2. 中国科学院大学化学工程学院，北京 101407 3. 北京科技大学钢铁冶金新技术国家重点实验室，北京 100083

收稿日期:2018-04-08 修回日期:2018-07-13 出版日期:2019-02-22 发布日期:2019-02-12
通讯作者: 孙峙 sunzhi@ipe.ac.cn
基金资助:
北京市科委项目;自然科学基金项目;中科院重点部署项目

Technology of lithium extraction from lepidolite through mechanochemistry activation

Mingming HE^1,2, Haixia YOU¹, Chunlong ZHAO^1,3, Xiaohong ZHENG¹, Hongbin CAO¹, Zhi SUN^1,2*

1. Beijing Engineering Research Center of Process Pollution Control, Key Laboratory of Green Process and Engineering, Division of Environment Technology and Engineering, Institute of Process Engineering, Chinese Academy of Sciences, Beijing 100190, China 2. School of Chemical Engineering, University of Chinese Academy of Sciences, Beijing 101407, China 3. State Key Laboratory of Advanced Metallurgy, University of Science and Technology Beijing, Beijing 100083, China

Received:2018-04-08 Revised:2018-07-13 Online:2019-02-22 Published:2019-02-12

摘要/Abstract

摘要： 采用机械化学活化方法，在机械活化过程中用K2SO4为活化添加剂，强化锂云母中惰性Li?O配位结构活化转型，通过温和稀酸浸出高效分离锂，考察了活化过程添加剂用量、球磨时间和球料比及浸出条件如酸浓度、液固比、搅拌速度、温度和时间等对锂回收率的影响，确定了最佳工艺条件，讨论了反应过程机理。结果表明，机械化学活化强化破坏云母片层结构中的Si?O?K结构，降低了Si?O配位结构对Li?O配位结构的牵制力，导致Li?O键强减弱，反应活性增加。在最优条件下(精矿与K2SO4质量比5:1，球磨机转速500 r/min，球料质量比20:1，球磨时间3 h，硫酸浓度15vol%、液固比4 L/g、反应温度80℃、浸出搅拌速率200 r/min)，锂浸出率可达99.1%。

关键词: 锂, 浸出, 锂云母, 机械化学活化

Abstract: The demand for lithium resources has increased significantly in recent years due to the rapid development of hybrid electric vehicles, plug-in-vehicles and so on. To alleviate the shortage of lithium resources in China, the lithium extraction from lithium-containing minerals has received widely attention. As an important lithium-containing minerals, lepidolite has a stable mineral structure. Therefore, it is difficult to extract valuable metals from lepidolite efficiently. Based on the understanding of the stable mineral structure of lepidolite, direct leaching lithium from minerals with dilute sulfuric acid and limestone calcination-sulfuric acid leaching method are adopted to realize the activation and separation of lithium from minerals. However, the extraction of lithium by these methods are complicated, besides, the comsumption of medium is great, and a large amount of residues and waste water are produced during these processes. In this paper, the mechanochemical activation was introduced to activate the transformation of inert Li?O coordination structure in lepidolite under the condition of K2SO4 as an additive, then dilute acid was used to achieve efficient separation of lithium. Various parameters including type and amount of additive, milling time and ball-to-concentrate mass ratio in the mechanochemical activation process as well as the acid concentration, liquid-to-solid ratio, stirring speed, temperature and time in the leaching process were optimized and the mechanism was further discussed. The results showed that the mechanochemical process destroyed the structure of Si?O?K and reduced the effect of the Si?O coordination on the Li?O coordination structure, resulted in a decrease in the Li?O bond strength and an increase in its reactivity. Under the optimum conditions (lepidolit-to-additive mass ratio 5:1, ball mill speed 500 r/min, ball-to-concentrate mass ratio 20:1, ball milling time 3 h, sulfuric concentration 15vol%, liquid-to-solid ratio 4 L/g, temperature 80℃ and stirring speed 200 r/min), the leaching rate of Li was 99.1%. With this research, it is expected to provide a new approach for short range extraction and efficient utilization of lepidolite.

Key words: lithium, leaching, lepidolite, mechanochemistry activation

何明明尤海侠赵春龙郑晓洪曹宏斌孙峙. 含锂矿物机械化学强化提锂工艺[J]. 过程工程学报, 2019, 19(1): 126-135.

Mingming HE Haixia YOU Chunlong ZHAO Xiaohong ZHENG Hongbin CAO Zhi SUN. Technology of lithium extraction from lepidolite through mechanochemistry activation[J]. Chin. J. Process Eng., 2019, 19(1): 126-135.

参考文献

[1] Taberna P L, Mitra S, Poizot P, et al. High rate capabilities Fe3O4-based Cu nano-architectured electrodes for lithium-ion battery applications [J]. Nature Materials. 2006, 5(7): 567-573.
[2] Wu Z, Ren W, Wen L, et al. Graphene Anchored with Co3O4 Nanoparticles as Anode of Lithium Ion Batteries with Enhanced Reversible Capacity and Cyclic Performance [J]. ACS Nano. 2010, 4(6): 3187-3194.
[3] Gao W, Zhang X, Zheng X, et al. Lithium Carbonate Recovery from Cathode Scrap of Spent Lithium-Ion Battery: A Closed-Loop Process [J]. Environmental Science & Technology. 2017, 51(3): 1662-1669.
[4] Swain B. Recovery and recycling of lithium: A review [J]. Separation and Purification Technology. 2017, 172: 388-403.
[5] Zheng X H, Gao W F, Zhang X H, et al. Spent lithium-ion battery recycling-Reductive ammonia leaching of metals from cathode scrap by sodium sulphite [J]. Waste Management. 2017, 60: 680-688.
[6] Xu W, Wang J L, Ding F, et al. Lithium metal anodes for rechargeable batteries [J]. Energy & Environmental Science. 2014, 7(2): 513-537.
[7] Ge X Y, Xia Y Q, Shu Z Y. Conductive and Tribological Properties of Lithium-Based Ionic Liquids as Grease Base Oil [J]. Tribology Transactions. 2015, 58(4): 686-690.
[8] 吴荣学. 锂资源及Li2CO3产业的开发与利用 [J]. 材料导报. 2012, 26(17): 36-39.
Wu R X. The Exploitation and Utilization of Lithium Resources and Li2CO3 Industry [J]. Materials Review 2012, 26(17): 36-39.
[9] 成岳，李燕孙，陈策和. 锂云母精矿制备碳酸锂的研究 [J]. 无机盐工业. 2012(04): 16-18.
[10] 赵春龙，孙峙,郑晓洪，等. 碳酸锂的制备及其纯化过程的研究进展. 过程工程学报，2018, 18(1): 20-28.
Zhao C L, Sun Z, Zheng X H, et al. Research Progress of Lithium Carbonate Preparation and Purification Process. Chin. J. Process Eng., 2018, 18(1): 20-28.
[11] 孙传尧，,选矿工程师手册[M] .冶金工业出版社,2015.03:85-88.
[12] 李良彬，刘明，彭爱平，等. 锂云母提锂工艺及工业化应注意的问题 [J]. 世界有色金属. 2014(08): 37-39.
[13] Yan Q, Li X, Yin Z, et al. A novel process for extracting lithium from lepidolite [J]. Hydrometallurgy. 2012, 121-124: 54-59.
[14] Kuang G, Li H, Hu S, et al. Recovery of aluminium and lithium from gypsum residue obtained in the process of lithium extraction from lepidolite [J]. Hydrometallurgy. 2015, 157: 214-218.
[15] Barbosa L I, Valente G, Orosco R P, et al. Lithium extraction from β-spodumene through chlorination with chlorine gas [J]. Minerals Engineering. 2014, 56: 29-34.
[16] Schneider A, Schmidt H, Meven M, et al. Lithium extraction from the mineral zinnwaldite: Part I: Effect of thermal treatment on properties and structure of zinnwaldite [J]. Minerals Engineering. 2017, 111: 55-67.
[17] Barbosa L I, González J A, Ruiz M D C. Extraction of lithium from β-spodumene using chlorination roasting with calcium chloride [J]. Thermochimica Acta. 2015, 605: 63-67.
[18] 郭春平，周健，文小强，等. 锂云母硫酸盐法提锂研究 J]. 无机盐工业. 2014(03): 41-44.
[19] 郭春平，周健，文小强，等. 锂云母硫酸盐法提取锂铷铯的研究 [J]. 有色金属(冶炼部分). 2015(12): 31-33.
[20] Luong V T, Kang D J, An J W, et al. Iron sulphate roasting for extraction of lithium from lepidolite [J]. Hydrometallurgy. 2014, 141: 8-16.
[21] Yan Q, Li X, Wang Z, et al. Extraction of valuable metals from lepidolite [J]. Hydrometallurgy. 2012, 117-118: 116-118.
[22] 孙友润. 锂云母-石灰石法烧成工艺最佳条件的选择 [J]. 稀有金属. 1984(5): 13-17.
[23] Luong V T, Kang D J, An J W, et al. Factors affecting the extraction of lithium from lepidolite [J]. Hydrometallurgy. 2013, 134-135: 54-61.
[24] 冯文平，谢晶磊，汤建良，等. 硫酸浸取锂云母提锂方法的研究 [J]. 精细化工中间体. 2016(03): 66-69.
[25] Choubey P K, Kim M, Srivastava R R, et al. Advance review on the exploitation of the prominent energy-storage element: Lithium. Part I: From mineral and brine resources [J]. Minerals Engineering. 2016, 89: 119-137.
[26] 陈鼎，陈振华. 机械力化学 [M]. 北京：化学工业出版社 2008.4: 206-272.

含锂矿物机械化学强化提锂工艺

Technology of lithium extraction from lepidolite through mechanochemistry activation

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