推动废旧锂离子电池 (LIB) 循环利用的电化学技术:最新进展与前景

Ming Li, Ruzi Mo, Anting Ding, Kai Zhang, Fan Guo, Chengliang Xiao
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摘要

近年来,锂离子电池(LIB)的广泛使用导致废旧电池的数量显著增加,从而在资源稀缺和环境影响方面带来了严峻的全球性技术挑战。因此,我们需要高效、环保的电池回收方法。废锂电池的回收方法包括湿法冶金、火法冶金、固相再生和电化学方法。与其他回收方法相比,电化学方法具有高离子选择性和环保性。汇集有关废锂离子电池回收和再利用的研究成果,重点关注可增强这些工艺的各种电化学技术,是至关重要的。透彻分析这些方法的特点和演变,对于推动电池回收电化学技术领域的发展至关重要。本综述首先从多个角度讨论了回收废锂电池的必要性,并简要介绍了主要的火法冶金和湿法冶金回收技术,分析了它们的优缺点。此外,我们还全面总结了目前电化学技术在废锂离子电池回收中的应用,包括预处理、浸出、元素分离和再生等。然后,我们分析了不同电化学技术在 LIB 回收过程中的特点和优势,并讨论了电化学技术应用过程中遇到的障碍及其解决方案。最后,比较了电化学技术和传统回收工艺,强调了电化学技术在降低回收成本和减少废物排放方面的潜在优势。
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Electrochemical technology to drive spent lithium-ion batteries (LIBs) recycling: recent progress, and prospects
The widespread use of lithium-ion batteries (LIBs) in recent years has led to a marked increase in the quantity of spent batteries, resulting in critical global technical challenges in terms of resource scarcity and environmental impact. Therefore, efficient and eco-friendly recycling methods for these batteries are needed. The recycling methods for spent LIBs include hydrometallurgy, pyrometallurgy, solid-phase regeneration, and electrochemical methods. Compared to other recycling methods, electrochemical methods offer high ion selectivity and environmental friendliness. Assembling research on the recycling and reutilization of spent LIBs, with a focus on the various electrochemical techniques that can enhance these processes, is essential. A thorough analysis of the characteristics and evolution of these methods remains crucial to advancing the field of electrochemical technology in battery recycling. This review first discussed the necessity of recycling spent LIBs from multiple perspectives and briefly introduced the main pyrometallurgical and hydrometallurgical recycling technologies, analyzing their advantages and disadvantages. Moreover, we comprehensively summarized the current applications of electrochemical technology in the recycling of spent LIBs, including pretreatment, leaching, element separation, and regeneration. Then, we analyzed the characteristics and advantages of different electrochemical techniques in the LIB recycling process and discussed the obstacles encountered in the application of electrochemical technology and their solutions. Finally, a comparison between electrochemical technology and traditional recycling processes was provided, highlighting the potential advantages of electrochemical technology in reducing recycling costs and minimizing waste emissions.
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