锂离子电池加速循环测试研究

doi:10.19799/j.cnki.2095-4239.2022.0448

摘要/Abstract

摘要：

以圆型21700 4.8 Ah电池为测试样本，采用零和脉冲法进行加速循环测试研究。以所筛选的10%SOC作为最优的荷电态测试区间，对3种不同正负极材料组成的实验电池进行7天的加速循环测试，以基准电池参数为对比，综合多种参数对电池循环性能优劣进行分析评价。通过对电池加速循环前后的容量保持率分析，即可获得与常规循环测试一致的测评结果：负极二元化电池的放电容量保持率最高，为99.75%，其次是基准方案电池，为99.43%，而正极二元化电池的放电容量保持率最低，为96.33%。此外，通过对电池在加速循环过程中的直流内阻和极化电压增长率的分析，正极二元化电池的增长率远高于其他两种电池。进一步通过对电池瞬时及弛豫阻抗的拆解分析，可知导致正极二元化电池循环较差的原因主要是其正极及负极上均发生了大量的副反应，由于界面膜增厚及沉积物增多导致固相扩散阻抗增大，因此弛豫阻抗增长率达40%。通过对循环后电池进行EIS测试及正负极的物性分析发现，正极二元化电池的扩散阻抗显著较高，且其正极二次颗粒碎裂程度较高，此结果可初步解释正极二元化电池在加速循环中因正极碎裂引发副反应导致固相扩散阻抗增长率较高的现象。该加速循环测试方法以实际循环制式为依据，不引入额外的温度及倍率等应力影响因素，通过对各种测试参数的综合分析，达到定性判断实验电池循环性能优劣的目的，不仅可以大大缩短电池循环测评周期，同时可以为电池循环衰减原因分析提供依据。

关键词: 锂离子电池, 零和脉冲, 加速循环, 弛豫阻抗, 直流内阻, 极化电压

Abstract:

The zero-sum pulse method was used to perform the accelerated cycle tests on the cylindrical 21700 battery with a nominal capacity of 4.8 Ah. The experimental batteries, composed of three positive and negative materials, were evaluated in an accelerated cycle for 7 days, with 10%SOC chosen as the best test interval. In comparison with the test findings of the reference battery, the cycle performance of the battery was investigated and evaluated by incorporating different characteristics. The assessment result was similar with the traditional cycle test when the capacity retention rate of the battery was compared before and after the accelerated cycle. The negative binary battery had the greatest discharge capacity retention rate of 99.75%, followed by the reference battery with 99.43%, while the positive binary battery had the lowest discharge capacity retention rate of 96.33%. Additionally, according to the examination of the DC internal resistance and polarization voltage growth rate of the battery during the accelerated cycle, the growth rate of the positive binary battery was significantly larger than that of the other two types of batteries. Further examination of the battery's instantaneous and relaxation impedance revealed that a considerable number of side reactions had happened on both the positive and negative electrodes, which was the main reason for the positive binary battery's poor cycle. The solid phase diffusion impedance increased due to the interface film's thickening and the growth of the deposits. Consequently, the relaxation impedance growth rate reached 40%. Through the EIS test and physical property analysis of the positive and negative electrodes of the battery after cycling, it was revealed that the diffusion impedance of the positive binary battery was noticeably higher, and the cracking degree of the secondary particles of the positive electrode was higher. This finding offers a basic explanation for the phenomenon whereby the positive electrode cracking side reaction causes the positive binary battery's solid diffusion impedance to increase quickly during accelerated cycling. The accelerated cycle test method is based on the real cycle operating parameters without adding extraneous variables like temperature and rate. Through comprehensive analysis of numerous test parameters, the objective of qualitatively evaluating the cycle performance of experimental batteries can be accomplished, which can not only considerably minimize the cycle test length but also offer reference data for the investigation of battery cycle failure.

Key words: Li-ion batteries, zero-sum pulse, accelerated cycle, relaxation impedance, DC internal resistance, polarization voltage

中图分类号:

TM 911

韩江浩, 王晓丹, 李奇松, 李慧芳, 王睿, 许刚. 锂离子电池加速循环测试研究[J]. 储能科学与技术, 2023, 12(1): 255-262.

Jianghao HAN, Xiaodan WANG, Qisong LI, Huifang LI, Rui WANG, Gang XU. Research on accelerated cycle test of lithium-ion batteries[J]. Energy Storage Science and Technology, 2023, 12(1): 255-262.

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序号	实验方案	正极材料	负极材料
1	基准方案	A0	B0
2	正极二元化	A1	B0
3	负极二元化	A0	B1

实验电池	初始充电容量/Ah	初始放电容量/Ah	加速循环后充电容量/Ah	加速循环后放电容量/Ah	充电容量保持率	放电容量保持率
基准方案电池	4.812	4.757	4.744	4.730	98.58%	99.43%
正极二元化电池	4.845	4.820	4.630	4.643	95.55%	96.33%
负极二元化电池	4.889	4.877	4.869	4.864	99.61%	99.75%

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