先进的锂离子电池回收技术

Muammer Kaya
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引用次数: 17

摘要

锂(Li)主要存在于矿产资源、盐水和海水中。从矿床中提取锂是昂贵且耗能的。锂离子电池(LIBs)无疑是减少对化石燃料资源依赖的重要替代品之一。全球便携式电子电气设备(EEE)和电动汽车对锂离子电池的需求大幅增加,使用的锂离子电池(s - lib)的数量正呈对数增长。s - lib含有有害重金属和有毒有机化学物质,对人类健康和生态系统构成严重威胁。当前的形势要求从经济角度出发,对s - lib的回收利用是保护环境不可或缺的,也是稀缺原材料的回收利用。在这篇文章中,最近的发展和最先进的技术的LIB回收是集中和全面审查。介绍了s - lib的预处理方法(如放电、拆除、阴极活性物质(CAM)去除、粘合剂消除方法、分类和分离),并对不同物理和化学回收过程中使用的所有现有和新颖技术进行了总结和比较。LIB回收中的预处理工艺既能提高有价组分的回收率,又能显著降低后续的能耗。值得注意的是,预处理、金属提取和产品制备阶段在基于火法冶金、湿法冶金、生物冶金、直接回收、机械处理和水浸出的所有锂回收工艺中起着至关重要的作用。本文综述了新型S-LIB材料的回收研究现状,以及在综合、环保、经济、低碳和清洁能源技术方面的创新。最后,对不同的工业回收工艺进行了比较,指出了存在的挑战,并对未来锂离子电池的回收应用提出了建议和展望。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
State-of-the-art lithium-ion battery recycling technologies

Lithium (Li) is primarily found in mineral resources, brines, and seawater. Extraction of Li from mineral ore deposits is expensive and energy-intensive. Li-ion batteries (LIBs) are certainly one of the important alternatives to lessen the dependence on fossil fuel resources. The global demand for LIBs for portable electrical and electronic equipment (EEE) and EVs have increased significantly, and the amount of spent LIBs (S-LIBs) is rising logarithmically. S-LIBs contain both hazardous heavy metals and toxic organic chemicals that create a serious threat to human health and the ecosystem. The current position requires the recycling of S-LIBs indispensable for the protection of the environment and the recycling of scarce raw materials from economic aspects. In this manuscript, recent developments and state-of-the-art technologies for LIB recycling were focused on and reviewed comprehensively. Pretreatment methods (such as discharging, dismantling, cathode active material (CAM) removal, binder elimination methods, classification, and separation) for S-LIBs are introduced, and all available and novel technologies that are used in different physical and chemical recovery processes are summarized and compared. The pretreatment process in LIB recycling can both improve the recovery rate of the valuable components and significantly lessen the subsequent energy consumption. Notably, pretreatment, metal extraction, and product preparation stages play vital roles in all LIB recovery processes, based on pyrometallurgy, hydrometallurgy, biometallurgy, direct recycling, and mechanical treatment and water leaching. The main goal of this review is to address the novel S-LIB materials’ current recycling research status and innovations for integrated, eco-friendly, economic, low carbon, and clean energy technologies. In the end, different industrial recycling processes are compared, existing challenges are identified and suggestions and perspectives for future LIBs recycling applications are highlighted.

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