磷酸锂渣制备电池级碳酸锂工艺研究
收稿日期: 2021-06-20
网络出版日期: 2022-03-18
基金资助
江西省科技项目(20192BBE50022);赣州市科技项目(赣市科发[2018]50号)
Study on preparation process of battery-grade lithium carbonate from slag containing lithium phosphate
Received date: 2021-06-20
Online published: 2022-03-18
磷酸锂渣作为低浓度含锂废液的回收产物,因杂质含量高难以直接作为锂电池的生产原料。为充分利用该类磷酸锂渣,以缓解新能源汽车产业的快速发展对锂资源的需求压力,依据锂盐与钙盐在弱酸性条件下具有较大的溶解性差异,向磷酸锂中添加一定量酸和易溶性钙盐,在酸性条件下直接实现磷酸锂渣中锂与磷的分离。实验研究了酸加入量、钙加入量、转化终点pH、转化液固比及转化时间对锂转化效率的影响,发现在酸加入量与固体原料的体积质量比为1.04 mL/g、钙加入量为磷酸锂中磷物质的量的0.9倍、回调pH终点为4.0条件下,锂的转化率可达96.8%。转化液经调节pH除杂、离子交换深度除杂,控制完成液的锂浓度、碳酸钠过滤精度、反应体系温度等,可制备出电池级碳酸锂。碳酸锂产品主成分质量分数约为99.65%,产品质量符合YS/T 582—2013《电池级碳酸锂》的要求,锂的综合回收率达到93.4%。
郭春平 , 周有池 , 文小强 , 刘雯雯 , 洪侃 , 黄叶钿 . 磷酸锂渣制备电池级碳酸锂工艺研究[J]. 无机盐工业, 2022 , 54(3) : 82 -86 . DOI: 10.19964/j.issn.1006-4990.2021-0292
The slag containing lithium phosphate as the recovery product of low concentration lithium containing waste liquid is hardly used as the production raw material of lithium battery due to its high impurity content.In order to make full use of this kind of lithium phosphate slag to alleviate the demand pressure of lithium resources for the rapid development of new energy vehicle industry,according to the large solubility difference between lithium salt and calcium salt under weak acid conditions,acid and soluble calcium salt were added to lithium phosphate to directly realize separation of lithium and phosphorus from lithium phosphate slag under acidic conditions.The effect of acid addition amount,calcium addition amount,pH of conversion end point,conversion liquid-solid ratio and conversion time on lithium conversion efficiency was studied.It was found that the conversion rate of lithium could reach 96.8% when the volume mass ratio of acid addition amount to solid raw material was 1.04 mL/g,calcium addition amount was 0.9 times of the amount of phosphorus in lithium phosphate and the pH end point was 4.0.After pH adjustment,chemical impurity removal and ion exchange depth removal of the converted liq-uid,battery grade lithium carbonate could be prepared by strictly controlling the lithium concentration in the purified liquid,the filtration accuracy of sodium carbonate,the temperature of the reaction system.The product contained the main component of about 99.65%,with the impurity content up to the requirements of YS/T 582—2013.The comprehensive recovery of lithium was 93.4%.
Key words: lithium phosphate; conversion rate; recycling; battery-grade; lithium carbonate
| [1] | 王冬斌, 梁精龙, 邓孝纯, 等. 锂资源提取与回收及锂制备工艺研究现状[J]. 无机盐工业, 2020, 52(6):8-12. |
| [2] | 谭博, 刘香环, 刘旭东, 等. 锂辉石浸出液提锂除杂规律研究[J]. 无机盐工业, 2021, 53(4):56-60. |
| [3] | ZHOU Z, FAN L, WEI Q, et al. Coupled reaction and solvent extrac-tion process to form Li2CO3:Mechanism and product characteriza-tion[J]. American Institute of Chemical Engineers Journal, 2014, 60(1):282-288. |
| [4] | YAN Q, LI X, WANG Z, et al. Extraction of lithium from lepidolite by sulfation roasting and water leaching[J]. International Journal of Mineral Processing, 2012, 110-111:1-5. |
| [5] | 熊攀, 赖先熔, 钟辉. 磷酸盐沉淀法用于高镁锂比盐湖卤水锂镁分离研究[J]. 化工矿物与加工, 2019, 48(3):58-60,64. |
| [6] | 戴江洪, 王宏岩, 李平. 高纯碳酸锂制备研究进展[J]. 中国有色冶金, 2020(1):49-53. |
| [7] | 杜国山, 唐建文, 羡鹏飞. 锂辉石制备碳酸锂工艺节能分析[J]. 有色冶金节能, 2020, 36(3):8-11. |
| [8] | 南东东, 曾小毛, 刘剑叶, 等. 基于一步法对以锂云母为原料制备电池级碳酸锂的方法研究[J]. 冶金与材料, 2020, 40(5):41-42. |
| [9] | 徐陈栋, 方舒杰, 潘超杰, 等. 新能源汽车产量的影响因素分析[J]. 汽车工程师, 2021(2):11-14. |
| [10] | 柴文帅. 新冠疫情影响下的全球锂资源供需情况分析[J]. 新材料产业, 2020(4):46-50. |
| [11] | 张亮, 杨卉芃, 柳林, 等. 全球提锂技术进展[J]. 矿产保护与利用, 2020, 40(5):24-31. |
| [12] | 邢佳韵, 彭浩, 张艳飞, 等. 世界锂资源供需形势展望[J]. 资源科学, 2015, 37(5):988-997. |
| [13] | 乔延超, 陈若葵, 王榆彬, 等. 一种以粗制磷酸锂制备碳酸锂的方法:中国, 109264748A[P]. 2019-01-25. |
| [14] | 陈亚, 甘辉, 曹利涛, 等. 一种从含磷酸锂废渣中提取高纯碳酸锂或氢氧化锂的方法:中国,108285156A[P]. 2018-07-17. |
| [15] | 魏述彬, 李振华, 员江平, 等. 一种由磷酸锂直接制备电池级碳酸锂的方法:中国,110127731A[P]. 2019-08-16. |
| [16] | 郭春平, 文小强, 周有池, 等. 一种低品位磷酸锂酸性转化法制备电池用碳酸锂的方法:中国,108675323A[P]. 2018-10-19. |
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