二次谐波分量下锂离子电池安全运行区间研究

夏向阳; 陈贵全; 夏天; 周冠东; 欧名勇; 王灿

doi:10.19912/j.0254-0096.tynxb.2022-0827

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太阳能学报 ›› 2023, Vol. 44 ›› Issue (10) : 496-503. DOI: 10.19912/j.0254-0096.tynxb.2022-0827

二次谐波分量下锂离子电池安全运行区间研究

夏向阳¹, 陈贵全¹, 夏天¹, 周冠东², 欧名勇³, 王灿⁴

作者信息 +

STUDY ON SAFE OPERATION RANGE OF LITHIUM-ION BATTERY UNDER SECOND HARMONIC COMPONENT

Xia Xiangyang¹, Chen Guiquan¹, Xia Tian¹, Zhou Guandong², Ou Mingyong³, Wang Can⁴

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文章历史 +

摘要

针对光储系统直流侧主要二次谐波分量对储能电池影响的问题,该文通过电化学模型分析直流侧不同大小的二次谐波分量对锂离子电池内外特性影响的机理和规律,发现影响电池寿命的主要因素是电池充放电状态期间的电流平均值而不是电流有效值。根据该因素对电池寿命的影响程度提出可将电流中二次谐波分量大小分为3个区间,相对应分为不显著影响电池寿命、减缓电池寿命衰减及加速电池寿命衰减,最后通过仿真以及实验验证了这3个区间,基于这3个区间可为工程应用中优化光储系统与电网交互影响下锂离子电池安全运行区间提供参考,降低储能直流侧滤波器成本。

Abstract

For the main second harmonic component of the DC side of the photovoltaic storage system on the impact of energy storage batteries, the paper analyzes the mechanism and law of the influence of different sizes of second harmonic components on the internal and external characteristics of the Li-ion battery through electrochemical modeling, and finds that the main factor affecting the battery life is the average value of the current during the charging and discharging state rather than the effective value of the current. Based on the influence of this factor on the battery life, it is proposed that the second harmonic component of current can be divided into three intervals, which are not significantly affecting the battery life, slowing down the battery life decay and accelerating the battery life decay, and finally these three intervals are verified by simulation and experiment. These three intervals provide a reference for optimizing the safe operation interval of lithium-ion batteries under the influence of interaction between photovoltaic storage system and power grid in engineering applications and reducing the cost of DC-side filters for energy storage.

导出引用

夏向阳, 陈贵全, 夏天, 周冠东, 欧名勇, 王灿. 二次谐波分量下锂离子电池安全运行区间研究[J]. 太阳能学报. 2023, 44(10): 496-503 https://doi.org/10.19912/j.0254-0096.tynxb.2022-0827

Xia Xiangyang, Chen Guiquan, Xia Tian, Zhou Guandong, Ou Mingyong, Wang Can. STUDY ON SAFE OPERATION RANGE OF LITHIUM-ION BATTERY UNDER SECOND HARMONIC COMPONENT[J]. Acta Energiae Solaris Sinica. 2023, 44(10): 496-503 https://doi.org/10.19912/j.0254-0096.tynxb.2022-0827

中图分类号： TM912

参考文献

[1] 葛乐, 袁晓冬, 陆宣统, 等. 柔性并网光储系统的设计与实现[J]. 太阳能学报, 2017, 38(10): 2871-2878.
GE L, YUAN X D, LU X T, et al.Design and implementation of flexible grid connected PV and energy storage system[J]. Acta energiae solaris sinica, 2017, 38(10): 2871-2878.
[2] GHAFFARI A, ASKARZADEH A,FADAEINEDJAD R.Optimal allocation of energy storage systems, wind turbines and photovoltaic systems in distribution network considering flicker mitigation[J]. Applied energy, 2022, 319: 119253.
[3] 夏向阳, 易浩民, 邱欣, 等. 双重功率优化控制的规模化光伏并网电压越限研究[J]. 中国电机工程学报, 2016, 36(19): 5164-5171, 5397.
XIA X Y, YI H M, QIU X, et al.Research on dual power optimal control of limit of large-scale photovoltaic grid-connected voltoge[J]. Proceedings of the CSEE, 2016, 36(19): 5164-5171, 5397.
[4] 许阔, 王婉君, 贾利虎, 等. 混合微电网交流不对称故障对直流系统的影响[J]. 中国电机工程学报, 2018, 38(15): 4429-4437, 4643.
XU K, WANG W J, JIA L H, et al.Influence of AC unbalanced faults on DC system of AC/DC microgrid[J]. Proceedings of the CSEE, 2018,38(15): 4429-4437, 4643.
[5] 朱永强, 刘康, 张泉, 等. 混合微电网交流侧故障传播机理及抑制方法[J]. 电机与控制学报, 2020, 24(4):1-11.
ZHU Y Q, LIU K, ZHANG Q, et al.Fault propagation mechanism and suppression method on AC siole of hybrid microgrid[J]. Electric machines and control, 2020,24(4): 1-11.
[6] JUANG L W, KOLLMEYER P J, ANDERS A E, et al.Investigation of the influence of superimposed AC current on lithium-ion battery aging using statistical design of experiments[J]. Journal of energy storage,2017, 11: 93-103.
[7] UDDIN K, SOMERVILLE L, BARAI A, et al.The impact of high-frequency-high-current perturbations on film formation at the negative electrode electrolyte interface[J]. Electrochimica acta,2017, 233: 1-12.
[8] UDDIN K, MOORE A D, BARAI A, et al.The effects of high frequency current ripple on electric vehicle battery performance[J]. Applied energy,2016, 178: 142-154.
[9] UNO M, TANAKA K.Influence of high-frequency charge-discharge cycling induced by cell voltage equalizers on the life performance of lithium-ion cells[J]. IEEE transactions on vehicular technology, 2011, 60(4): 1505-1515.
[10] BEH H Z Z, COVIC G A, BOYS J T. Effects of pulse and DC charging on lithium iron phosphate (LiFePO4) batteries[C]//2013 IEEE Energy Conversion Congress and Exposition. Denver, CO, USA, 2013, 315-320.
[11] BALA S, TENGNER T, ROSENFELD P, et al.The effect of low frequency current ripple on the performance of a Lithium Iron Phosphate (LFP) battery energy storage system[C]//2012 IEEE Energy Conversion Congress and Exposition (ECCE), Raleigh, NC, USA, 2012.
[12] BREUCKER S, ENGELEN K, DHULST R,et al.Impact of current ripple on Li-ion battery ageing[J]. World electric vehicle journal, 2013, 6(3): 532-540.
[13] BRAND M J, HOFMANN M H, SCHUSTER S S, et al.Jossen, The influence of current ripples on the lifetime of Lithium-Ion batteries[J]. IEEE transactions on vehicular technology, 2018,67(11):10438-10445.
[14] GHASSEMI A, BANERJEE P C, ZHANG Z, et al.Aging effects of twice line frequency ripple on Lithium Iron phosphate (LiFePO₄) batteries[C]//2019 21st European Conference on Power Electronics and Applications (EPE’19 ECCE Europe). Genova, Italy, 2019.
[15] BESSMAN A, SOARES R, WALLMARK O, et al.Aging effects of AC harmonics on lithium-ion cells[J]. Journal of energy storage, 2019, 21: 741-749.
[16] GHASSEMI A, BANERJEE P, HOLLENKAMP A F, et al.Effects of alternating current on Li-ion battery performance: monitoring degradative processes with in-situ characterization techniques[J]. Applied energy, 2021, 284: 116192.
[17] TREMBLAY O, DESSAINT L A.Experimental validation of a battery dynamic model for EV applications[J]. World electric vehicle journal. 2009, 3(2):289-298.
[18] OMAR N, MONEM M, FIROUZ Y, et al.Lithium iron phosphate based battery-Assessment of the aging parameters and development of cycle life model[J]. Applied energy, 2014, 113: 1575-1585.
[19] ZHU J G, SUN Z C, WEI X Z, et al.An alternating current heating method for lithium-ion batteries from subzero temperatures[J]. International journal of energy research, 2016, 40(13): 1869-1883.
[20] 丁黎, 李帆, 蔡文嘉, 等. 锂离子电池的老化特性分析[J]. 电源技术, 2019, 43(1): 77-80.
DING L, LI F, CAI W J, et al.Analysis on aging characteristics of lithium ion batteries[J]. Chinese journal of power sources, 2019, 43(1): 77-80.
[21] 闫啸宇, 周思达, 卢宇, 等. 锂离子电池容量衰退机理与影响因素[J]. 北京航空航天大学学报, 2023, 49(6): 1402-1413.
YAN X Y, ZHOU S D, LU Y, et al.Degradation mechanism and influencing factors on lithium-ion batteryies[J]. Journal of Beijing University of Aeronautics and Astronautics, 2023, 49(6): 1402-1413.