A direct regeneration of cathode materials from spent LiFePO4 batteries using a solid phase sintering method has been proposed in this article. The spent battery is firstly dismantled to separate the cathode and anode plate, and then the cathode plate is soaked in DMAC organic solvent to separate the cathode materials and Al foil at optimal conditions of 30 min at 30 °C and solid liquid ratio of 1[thin space (1/6-em)]:[thin space (1/6-em)]20 g ml−1. XRD and SEM results of the spent LiFePO4 after separation show that there are some impurity phase components and irregular morphologies with many agglomerations. The spent materials are regenerated at appropriate temperatures with doping of new LiFePO4 at different ratios. Battery capacities from regenerated LiFePO4 can reach over 120 mA h g−1 at 0.1C discharge conditions, especially with the highest value of 144 mA h g−1 with a doping ratio of 3[thin space (1/6-em)]:[thin space (1/6-em)]7 at 700 °C. The rate capabilities and cycling performance of batteries made from regenerated LiFePO4 with doping at 600 °C and 700 °C are generally better than those at 800 °C. All the performances of batteries made from regenerated LiFePO4 with pure phase and uniform morphology can meet the basic requirements for reuse.
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机译:本文提出了使用固相烧结法从废LiFePO4电池中直接再生正极材料的方法。首先将废电池拆解以分离阴极和阳极板,然后将阴极板浸入DMAC有机溶剂中,以在30°C的最佳条件30分钟和固液比为1 [的条件下分离阴极材料和铝箔。薄空间(1 / 6-em)]:[薄空间(1 / 6-em)] 20克ml-1。分离后的废LiFePO4的XRD和SEM结果表明,存在一些杂质相成分和不规则形貌,且有许多团聚。废料在适当的温度下进行再生,并以不同的比例掺杂新的LiFePO4。在0.1C放电条件下,再生的LiFePO4的电池容量可以达到120 mA hg-1以上,特别是在掺杂比为3 [薄空间(1 / 6-em)]时,最高值为144 mA hg-1。空间(1 / 6-em)] 7在700°C。由掺有600°C和700°C掺杂的LiFePO4制成的电池的倍率性能和循环性能通常优于800°C。由纯相和均匀形态的再生LiFePO4制成的电池的所有性能都可以满足重复使用的基本要求。
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