Advances in direct repair of cathode materials from retired lithium iron phosphate battery and ternary lithium battery

被引:0
|
作者
Wang H. [1 ,2 ,3 ,4 ]
Li D. [1 ,3 ,4 ]
Dong N. [2 ]
Yang J. [1 ,3 ,4 ]
Ni X. [1 ,3 ,4 ]
Ye J. [1 ,3 ,4 ]
Yuan H. [1 ,3 ,4 ]
Chen Y. [1 ,3 ,4 ]
机构
[1] Guangzhou Institute of Energy Research, Chinese Academy of Science, Guangdong, Guangzhou
[2] School of Energy and Power Engineering, Northeast Electric Power University, Jilin, Jilin
[3] Guangdong Provincial Key Laboratory of New Energy and Renewable Energy Research, Development and Application, Guangdong, Guangzhou
[4] Key Laboratory of Renewable Energy, Chinese Academy of Science, Guangdong, Guangzhou
来源
Huagong Jinzhan/Chemical Industry and Engineering Progress | 2024年 / 43卷 / 06期
关键词
cathode material; lithium battery; regeneration; repair;
D O I
10.16085/j.issn.1000-6613.2023-0845
中图分类号
学科分类号
摘要
The rapid development of the lithium battery industry and the new energy storage demand for lithium-ion batteries have drawn much attention in the resource and environmental field. Therefore, the recycling of retired lithium-ion batteries is necessary in the current industrial system. The cathode materials are the most valuable part of lithium-ion batteries, while the direct repair of waste cathode electrode materials is still in its early stages compared to the hydrometallurgy and pyrometallurgy methods. The prospect of a direct repair method is better than traditional methods due to its low cost and green environmental protection. This review introduced two major batteries, including lithium iron phosphate battery and ternary lithium battery, as well as the reason for the cathode materials failure of these two batteries. Meanwhile, several direct repair methods for the cathode materials of these two retired batteries and the problems existing in different direct repair methods were reviewed. Some relevant suggestions were also proposed to promote development of direct repair in the lithium battery industry. © 2024 Chemical Industry Press Co., Ltd.. All rights reserved.
引用
收藏
页码:3336 / 3346
页数:10
相关论文
共 98 条
  • [1] DENG Yuanfu, WAN Lina, XIE Ye, Et al., Recent advances in Mn-based oxides as anode materials for lithium ion batteries, RSC Advances, 4, 45, pp. 23914-23935, (2014)
  • [2] TOBIAS Placke, Richard Kloepsch, Simon Duhnen, Et al., Lithium ion, lithium metal, and alternative rechargeable battery technologies: The odyssey for high energy density, Journal of Solid State Electrochemistry, 21, 7, pp. 1939-1964, (2017)
  • [3] WANG Yu, ZHANG Yu, TONG Weiwen, Et al., Engineering hierarchical pore network for Li-ion battery electrodes, CIESC Journal, 72, 12, pp. 6340-6350, (2021)
  • [4] ZHANG Xiang, WANG Chunlei, KONG Jizhou, Et al., A preliminary analysis on the synthesis of layered Li-Ni-Co-Mn-O cathode material by co-precipitation method, Chemical Industry and Engineering Progress, 33, 11, pp. 2991-2999, (2014)
  • [5] LI Jiebin, MENG Haijun, PI Zhengjie, Et al., Application status and development trends of the lithium primary batteries, Chinese Journal of Power Sources, 42, 5, pp. 725-727, (2018)
  • [6] AN Xiaoyu, TAN Lingsheng, Development of lithium-ion batteries as new power sources for space application, Chinese Journal of Power Sources, 30, 1, pp. 70-73, (2006)
  • [7] ZHOU Dexi, Review on lithium batteries for underwater weapons, Chinese Journal of Power Sources, 39, 4, pp. 846-848, (2015)
  • [8] LI Yantao, ZHANG Hui, LI Yanjie, Application of lithium batteries in communication base station, Chinese Journal of Power Sources, 41, 2, pp. 202-204, (2017)
  • [9] ZENG Xiaoqiao, LI Matthew, ABD EL-HADY Deia, Et al., Commercialization of lithium battery technologies for electric vehicles, Advanced Energy Materials, 9, 27, (2019)
  • [10] TURCHENIUK K, BONDAREV D, SINGHAL V, Et al., Ten years left to redesign lithium-ion batteries reserves of rare metals used in electric-vehicle cells are dwindling, so boost research on iron and silicon alternatives, urge Kostiantyn Turcheniuk and colleagues, Nature, 559, 7715, pp. 467-470, (2018)
12345678910