48V软包锰酸锂电动车动力电池的梯次利用
Echelon use of 48 V flexible packing power Li-ion manganite battery in electric vehicles
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摘要: 针对我国面临的体量巨大的电动踏板车的动力锂离子电池退役后处理处置问题,研究了动力电池回收再梯次利用的具体方法。以市场上大量退役的48V软包锰酸锂动力电池为研究对象,对退役电池的容量、内阻、放电性能以及电池组的损耗分布进行了研究,从而提出了修复后梯次利用作为电动踏板车动力电池的策略。研究结果表明:不同损耗程度的电池组的损耗各有差异,剩余电量为70%的损耗组以个别单体损耗为主但其余未损耗单体一致性较好,可进行更换修复后重新服役;40%损耗组损耗单体数增加同时一致性尚可,更换受损单体后无法直接服役,需定制并联组形式重新使用;20%单体与一致性均较差,可直接拆解回收再利用。Abstract: Aiming at the problems of disposing the large amounts of the retired Li-ion batteries in electric vehicles of our country, the methods for the recovery and echelon use of these power batteries were studied. Then, the retired 48 V flexible packing power Li-ion manganite batteries were taken as a model to study its electricity capacity, resistance, and discharging performance of single battery cell, and the loss distribution of battery pack, and a strategy for reclamation and echelon use of the used Li-ion batteries in scooters was suggested. The results show that there are some discrepancies among the battery packs with different loss. In the retired battery pack with 70% remained power, some specific cells presented much loss while other cells without loss presented good consistency, the former could be replaced, then the retired battery pack could be rebuilt and reused. For the retired battery pack with 40% remained power, the amounts of the retried cells increased and the consistency of other cells without loss was well, but this retired battery pack could not be directly reused even the retried cells were replaced, and a specific mode of parallel discharging could be suitable for its reuse. As for the retired battery pack with 40% remained power, the increased amount of the retired cells and the inconsistency of other cells could result in directly disassemble this pack for the further recovery and reuse.
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Key words:
- lithium manganite /
- Li-ion battery /
- scooter /
- echelon use
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[1] 张文亮, 武斌, 李武峰,等. 我国纯电动汽车的发展方向及能源供给模式的探讨[J]. 电网技术,2009,33(4):1-5 [2] JI S, CHERRY C R, BECHLE J M, et al.Electric vehicles in China: Emissions and health impacts[J].Environmental Science & Technology,2012,46(4):2018-2024 10.1021/es202347q. [3] 杨钫, 王庆年, 刘明辉,等. 混合动力客车的排放污染物测量及分析[J]. 吉林大学学报(工学版),2007,37(2):291-295 [4] 柴海波, 鄢治国, 况明伟,等. 电动车驱动电机发展现状[J]. 微特电机,2013,41(4):52-57 [5] ELMAS C, USTUN O.A hybrid controller for the speed control of a permanent magnet synchronous motor drive[J].Control Engineering Practice,2008,16(3):260-270 10.1016/j.conengprac.2007.04.016. [6] 国务院发布《节能与新能源汽车产业发展规划(2012—2020年)》[J].煤气与热力,2012(9):13 [7] MAJEAUBETTEZ G, HAWKINS T R, STROMMAN A H.Life cycle environmental assessment of lithium-ion and nickel metal hydride batteries for plug-in hybrid and battery electric vehicles[J].Environmental Science & Technology,2011,45(10):4548-4554 10.1021/es103607c. [8] 王人洁. 电动车和天然气车能源环境影响的燃料生命周期评价研究[D]. 北京:清华大学,2015 [9] MA H, BALTHASAR F, TAIT N, et al.A new comparison between the life cycle greenhouse gas emissions of battery electric vehicles and internal combustion vehicles[J].Energy Policy,2012,44(5):160-173 10.1016/j.enpol.2012.01.034. [10] OU X, YAN X, ZHANG X, et al.Life-cycle analysis on energy consumption and GHG emission intensities of alternative vehicle fuels in China[J].Applied Energy,2012,90(1):218-224 10.1016/j.apenergy.2011.03.032 [11] 丁亮. 论电动自行车在我国城市交通工具中的地位[J]. 科技经济市场,2012(11):75-77 [12] 王永亮. 论促进我国纯电动汽车行业发展的措施[J]. 科协论坛(下半月),2013(4):35-36 [13] 贺理珀, 孙淑英, 于建国. 退役锂离子电池中有价金属回收研究进展[J]. 化工学报,2018,69(1):327-340 [14] 戈志华, 胡学伟, 杨志平. 能量梯级利用在热电联产中的应用[J]. 华北电力大学学报(自然科学版),2010,37(1):66-68 [15] 丁修乘. 电动汽车锂离子动力电池快速充电技术研究[D]. 柳州:广西科技大学,2015 [16] 王丰伟. 退役动力电池剩余容量梯次利用的关键技术研究[D]. 沈阳:沈阳工程学院,2017 [17] 中华人民共和国国家发展和改革委员会.电动汽车用锂离子蓄电池:QC/T 743-2006 [S].北京:中国计划出版社,2006 [18] 王雪非. 基于工况仿真的锂动力电池寿命研究[D].哈尔滨:哈尔滨理工大学,2011 [19] 李欣然,户龙辉,吕超贤,等.锂离子电池容量的预测建模及其仿真研究[J].系统仿真学报,2014,26(8):1733-1740 [20] 陈杰. 锂离子电池组健康状况评估方法研究[D].武汉:武汉理工大学,2014 -
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