Separation of Lithium and Cobalt Ions and Regeneration of Nitric Acid by Electrodialysis Using Bipolar Membranes for Water Splitting and Monovalent Cation Selective Bipolar Membranes

Hiroshi Takahashi, Satomi Takao, Etsuko Kashiuchi
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Abstract

The demand for lithium-ion batteries has been rapidly increasing in the modern electronics and electric vehicle industries. Tremendous lithium-ion battery consumption leads to an increase in battery scrap, which has to be recycled to relieve the shortage of rare resources. We examined a new process for separation of lithium and cobalt ions, and the regeneration of nitric acid from their mixture solution by use of electrodialysis with water splitting and monovalent cation selective bipolar membranes. In the experiment with an electrodialysis cell divided between an anode and cathode with a water splitting, an anion exchange, a monovalent cation selective, and a water-splitting bipolar membrane, lithium ion selectively permeates to strip compartment through monovalent cation selective bipolar membrane. The nitrate ion also permeates through the anion-exchange membrane and regenerated to nitric acid solution by water splitting bipolar membrane. These results revealed that electrodialysis using water splitting and monovalent cation selective bipolar membrane is applicable to the selective separation of lithium and cobalt ions, and regeneration of nitric acid solution.
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双极水分离膜和单价阳离子选择性双极膜的锂钴离子分离和硝酸的电渗析再生
在现代电子和电动汽车工业中,对锂离子电池的需求迅速增加。巨大的锂离子电池消耗导致电池报废增加,必须对其进行回收,以缓解稀有资源的短缺。我们研究了一种分离锂和钴离子的新工艺,并利用电渗析与水分裂和单价阳离子选择性双极膜从它们的混合溶液中再生硝酸。实验中,电渗析电池分为正极和负极,分别具有水分裂、阴离子交换、一价阳离子选择性和水分裂双极膜,锂离子通过一价阳离子选择性双极膜选择性渗透到条带室。硝酸离子也通过阴离子交换膜渗透,通过水裂解双极膜再生为硝酸溶液。结果表明,采用水裂解和一价阳离子选择性双极膜的电渗析技术可用于锂、钴离子的选择性分离和硝酸溶液的再生。
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