Estimation method of SOC for power lithium battery based on improved EKF algorithm adaptive to various temperature

doi:10.19799/j.cnki.2095-4239.2019.0209

Abstract

Abstract:

Accurate estimation of the state-of-charge （SOC） with respect to the power in a lithium battery is the key to its safe and reliable use. Temperature significantly influences the usage of the lithium power battery. The advantages and disadvantages are compared by comprehensively analyzing the impact of various factors on the SOC for lithium batteries combined with various existing SOC estimation methods. Considering a temperature change from -10 ℃ to 40 ℃, a hybrid pulse power characteristic was obtained with respect to an AVIC 50 A·h lithium battery at intervals of 10 ℃. Based on the experimental data, the battery’s parameters were identified according to the least squares principle. The characteristics of the battery were explored with different temperature parameters, and the Thévenin equivalent circuit model （adapted for temperature changes） was established. The error variance matrix may gradually lose its positive definiteness or symmetry, resulting in filter divergence, because all the computer algorithm programs may be affected by word limitations or calculation errors. To solve this problem, the extended Kalman filter （EKF） algorithm is improved by square root decomposition of the EKF algorithm to accurately estimate the SOC. Through the simulation of the vehicle operating conditions of the China National Aviation’s ternary lithium battery, the simulation verification algorithm is used to estimate the effect under variable temperature conditions. The results reveal that the maximum error of SOC estimation based on the Thévenin equivalent circuit model at the considered variable temperature is less than 1.5% with an average error of 0.37%, which is better than that of the EKF algorithm. The improved EKF algorithm based on square root decomposition can rectify the error of the initial value of SOC and realize SOC estimation at different temperatures without depending on the accuracy of the initial value.

Key words: power Lithium-ion battery, SOC estimation, temperature, parameter identification, Thévenin model, improved extended Kalman filter

CLC Number:

TK 421

JIANG Cong, WANG Shunli, LI Xiaoxia, XIONG Xin. Estimation method of SOC for power lithium battery based on improved EKF algorithm adaptive to various temperature[J]. Energy Storage Science and Technology, 2020, 9(1): 145-151.

Figures/Tables 7

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References 8

1	梁奇, 于春梅, 王顺利, 等. 基于PNGV电路模型的航空钴酸锂电池内阻研究[J]. 电源学报, 2017, 15(2): 153-158.
	LIANG Qi, YU Chunmei, WANG Shunli, et al. Research on internal resistance of aviation battery based on PNGV circuit model[J]. Journal of Power Supply, 2017, 15(2): 153-158.
2	WANG Shunli, FERNANDEZ C, ZOU Chuanyun. Open circuit voltage and state of charge relationship functional optimization for the working state monitoring of the aerial lithium-ion battery pack[J]. Journal of Cleaner Production, 2018. 198: 1090-1104.
3	蒋超宇, 王伟超, 杨学平. 混合动力汽车磷酸铁锂动力电池建模与SOC计算[J]. 储能科学与技术, 2018, 7(5): 897-901.
	JIANG Chaoyu, WANG Weichao, YANG Xueping. Modeling and SOC calculations of hybrid electrical vehicles (HEV) powered by lithium iron phosphate[J]. Energy Storage Science and Technology, 2018, 7(5): 897-901.
4	李争, 张丽平. 基于无迹卡尔曼滤波的锂离子电池SOC估计[J]. 电池, 2018, 48(5): 313-317.
	LI Zheng, ZHANG Liping. SOC estimation of Li-ion battery based on unscented Kalman filter[J]. Battery Bimonthly, 2018, 48(5): 313-317.
5	凡旭国, 周金治. 基于PNGV模型和高斯-厄米特滤波的SOC估算研究[J]. 自动化仪表, 2017, 38(12): 21-26.
	FAN Xuguo, ZHOU Jinzhi. Research on SOC estimation based on PNGV Model and Gauss-Hermite filter[J]. Process Automation Instrumentation, 2017, 38(12): 21-26.
6	HE Jiangtao, FENG Daiwei, HU Chuan. Two-layer online state-of-charge estimation of lithium-ion battery with current sensor bias correction[J]. International Journal of Energy Research, 2019, 43(8): 3837-3852.
7	ZENG Zhibing, TIAN Jindong, LI Dong. An online state of charge estimation algorithm for lithium-ion batteries using an improved adaptive cubature Kalman filter[J]. Energies, 2018, 11(1): 59.
8	LAI Xin, ZHENG Yuejiu, SUN Tao. A comparative study of different equivalent circuit models for estimating state-of-charge of lithium-ion batteries[J]. Electrochimica Acta, 2018, 259: 566-577.

参数	数值
芯标称容量/A·h	50
标称电压/V	3.65
充电电压/V	4.2±0.05
放电终止电压/V	2.65±0.05
尺寸	148 mm×27 mm×93 mm
标准充电电流/C	1
标准放电电流/C	3
最大放电电流/C	5
内阻/mΩ	0.8
推荐温度	充电0～45 ℃放电-20～60 ℃

温度T/℃	40	30	20	10	0	-10
R_O/mΩ	0.9251	0.9304	1.2391	1.7918	2.9133	5.4038
温度系数ξ	0.747	0.751	1	1.446	2.351	4.361

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