溶剂萃取法分离废锂离子电池盐酸浸出液中金属的工艺研究

Masakazu Niinae, Tasuma Suzuki, Tomonori Nakamura, Y. Inoue, J. Shibata
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引用次数: 2

摘要

锂离子二次电池(LIBs)含有有价值的金属成分,虽然废旧的LIBs通常不被归类为危险废物,但从经济角度来看,回收这些金属是必要的。本文研究了以溶剂萃取为基础的湿法冶金处理对废lib中主要金属铝、铜、钴和锂的分离。结果表明:铝和铜的析出曲线较为接近,由于铝和铜与氢氧化铝或氢氧化铜共沉淀法析出了钴,因此铝和铜不能以氢氧化铜的形式选择性分离铝和钴。同时,在pH 1.0 ~ 2.0用Acorga M5640选择性萃取铜后,在pH 2.0 ~ 2.5用PC-88A溶剂萃取可将铝与钴、锂选择性分离,钴、锂留在萃余液中。Acorga M5640在pH约为6.0时,对钴的萃取效率高,选择性好,同时将锂留在萃取液中。然而,从有机相(Acorga M5640)中剥离Co的效率很低。因此,与Acorga M5640相比,PC-88A/TOA组合在pH约为5.0时更有利于Co和Li的分离。提出了一种溶剂萃取湿法冶金从废lib中分离铝、铜、钴和锂的工艺。
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Separation Process of Metals from Hydrochloric Acid Leach Liquor of Spent Lithium Ion Batteries by Solvent Extraction
The lithium ion secondary batteries (LIBs) contain valuable metallic components and although spent LIBs are not generally classified as dangerous waste, recovery of these metals is necessary from an economic point of view. In this work, separation of main metals such as aluminum, copper, cobalt and lithium contained in spent LIBs has been inves-tigated using a hydrometallurgical treatment based on solvent extraction. The results obtained this study are summa- rized as follows: Aluminum could not be selectively separated from copper and cobalt by the precipitation method as hydroxide because the precipitation curves of aluminum and copper were close and cobalt was precipitated due to the coprecip- itation with aluminum hydroxide or copper hydroxide. Meanwhile, aluminum could be selectively separated from cobalt and lithium with solvent extraction using PC-88A at pH 2.0–2.5 after the selective extraction of copper with Acorga M5640 at pH 1.0–2.0 while leaving cobalt and lithium in the raffinate. Acorga M5640 was efficient and selec- tive for the extraction of cobalt at pH of approximately 6.0 while leaving lithium in the raffinate. However, the stripping efficiency of Co from organic phase (Acorga M5640) was very low. Therefore, the extractant combination, PC-88A/TOA, was favorable to the separation of Co and Li at pH of approximately 5.0 compared with Acorga M5640. A separation process of aluminum, copper, cobalt and lithium from the spent LIBs using hydrometallurgical treatment based on solvent extraction was proposed.
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