Evaluation of carbothermic processing for mixed discarded lithium-ion batteries

Revue De Metallurgie-cahiers D Informations Techniques Pub Date : 2020-04-01 DOI:10.1051/metal/2020025

Sanjay Pindar, N. Dhawan

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引用次数: 3

Abstract

The limited life span and huge demand for lithium-ion batteries, environment concerns, and the consumption of rare metals such as lithium and cobalt are the key facts for the worldwide recycling efforts. In this study, the cathode material of discarded lithium-ion batteries was carbothermally reduced using recovered graphite. A comparative evaluation of reduction behavior of single-phase (LiCoO2 ) and mixed-phase (LiCoO2 .LiNi0.5 Mn1.5 O4 .LiMn2 O4 ) cathode materials was investigated under an ambient and inert atmosphere. Processing of single-phase cathode material in inert atmosphere yielded pure metallic cobalt, whereas, higher metallic recoveries and metal purity were obtained by processing of mixed cathode material in ambient conditions. The excellent product obtained under ambient conditions comprises 68% Co, 21% Mn, 2.5% Ni with saturation magnetization: 106 emu/g, and a precursor for the synthesis of cathode material. The process yield is 46.2% and lithium extraction 83%. In terms of metal purity and recovery, graphite was found to be better for reduction than activated charcoal. The process followed is simple, adaptable, and cost-effective for metals recovery from discarded lithium-ion batteries.

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混合废弃锂离子电池碳热处理评价

锂离子电池有限的寿命和巨大的需求、环境问题以及锂和钴等稀有金属的消耗是全球回收努力的关键因素。本研究采用回收石墨对废旧锂离子电池正极材料进行碳热还原。对比评价了单相(LiCoO2)和混合相(LiCoO2 . lini0.5 Mn1.5 O4 . limn2 O4)正极材料在环境气氛和惰性气氛下的还原行为。在惰性气氛中处理单相正极材料可获得纯金属钴，而在环境条件下处理混合正极材料可获得更高的金属回收率和金属纯度。在常温条件下获得的优异产品含有68% Co, 21% Mn, 2.5% Ni，饱和磁化强度为106 emu/g，是合成正极材料的前驱体。该工艺收率为46.2%，锂提取率为83%。在金属纯度和回收率方面，石墨被发现比活性炭更好的还原。接下来的过程简单，适应性强，从废弃的锂离子电池中回收金属具有成本效益。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Revue De Metallurgie-cahiers D Informations Techniques 工程技术-冶金工程

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审稿时长

24 months