基于等效电路模型融合电化学原理的锂离子电池荷电状态估计

doi:10.19799/j.cnki.2095-4239.2024.0594

摘要/Abstract

摘要：

准确高效地评估锂离子电池荷电状态(SOC)是确保电动汽车和储能设备性能和安全的关键。等效电路模型被认为是描述锂离子电池内部复杂反应过程的一种有效方法。针对基于等效电路模型的SOC估计准确性与复杂性难以权衡的问题，本研究采用一阶RC模型作为基础，为了提高整个SOC区间的模型性能表现，通过电化学原理对模型进行优化，通过在一阶RC模型的OCV模块上添加反映电池内部固相扩散过程的改进误差项，在保证较低的计算复杂性的前提下，减小了等效电路模型与更准确的机理模型之间存在的误差。然后基于倍率测试以及脉冲测试数据对电池进行参数辨识，以粒子群算法为基础通过参数解耦的方式降低了参数辨识的复杂度、提升了辨识准确度；同时基于小倍率测试的开路电压(OCV)数据采用多项式方法进行OCV-SOC曲线拟合。随后基于模型参数辨识结果开展SOC估计研究，针对常规卡尔曼滤波准确度不足的问题，在无迹卡尔曼滤波基础上结合加权滑动窗口的思想以提升SOC估计的精确性和鲁棒性，并基于UDDS和DST动态工况测试数据进行算法验证，最终估计效果相对于传统方法呈现出优异的精度与鲁棒性，并且可以在初始SOC有较大偏差时快速收敛至准确值。

关键词: 锂离子电池, 融合模型, 荷电状态估计, 无迹卡尔曼滤波

Abstract:

The accurate and efficient assessment of the state of charge (SOC) of lithium-ion batteries is critical to ensuring the satisfactory performance and safety of electric vehicles and energy storage devices. The equivalent circuit model is considered to be effective for describing complex reaction processes inside Li-ion batteries. To use the equivalent circuit model to address the difficult trade-off between accuracy and complexity in SOC estimation, we use the first-order RC model as the foundation of this study. In order to improve the performance of the model over the SOC interval, the RC model is optimized according to electrochemical principles. By adding an improved error term for the solid-phase diffusion process inside the reactive battery to the open-circuit voltage (OCV) module of the first-order RC model, we reduce the computational complexity. By adding a modified error term that reflects the solid-phase diffusion process inside the cell to the first-order RC model of the OCV module, we also reduce the error between the equivalent circuit model and the more accurate mechanism model while ensuring that the computational complexity remains low. Then, based on the multiplicity test and pulse test data, a particle swarm algorithm is used to reduce the complexity and improve the accuracy of parameter identification through parameter decoupling. At the same time, a polynomial method is used to fit the OCV-SOC curve based on the OCV data from a small-multiplication test. Subsequently, based on the model parameter identification results, SOC estimation research is carried out. To address the insufficient accuracy of conventional Kalman filtering, a weighted sliding window is used with traceless Kalman filtering to improve the accuracy and robustness of the SOC estimation, and the Kalman filtering algorithm is verified based on the UDDS and DST dynamic test data. The final estimation results show excellent accuracy and robustness, unlike the traditional method. The results quickly converge to the accurate value when the initial SOC has a large deviation.

Key words: lithium-ion battery, fusion model, state of charge estimation, untracked Kalman filtering

中图分类号:

TM 912

李清波, 张懋慧, 罗英, 吕桃林, 解晶莹. 基于等效电路模型融合电化学原理的锂离子电池荷电状态估计[J]. 储能科学与技术, 2024, 13(9): 3072-3083.

Qingbo LI, Maohui ZHANG, Ying LUO, Taolin LYU, Jingying XIE. Lithium-ion battery state of charge estimation based on equivalent circuit model[J]. Energy Storage Science and Technology, 2024, 13(9): 3072-3083.

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参考文献 19

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参数	磷酸铁锂
标称容量/Ah	20
标称电压/V	3.2
内阻/mΩ	≤6
充电上限电压/V	3.65±0.05
放电下限电压/V	2
连续充电最大电流/C	2
连续放电最大电流/C	2
充放电温度	25
标准充电制度	CCCV
循环次数/次	1500

算法	工况	RMSE	MaE	MAE
粒子群算法	DST	0.0615	0.0487	0.1340
粒子群算法	UDDS	0.0478	0.0348	0.1260

解耦算法	DST	0.0391	0.0088	0.0750
解耦算法	UDDS	0.0135	0.0348	0.0597

模型	工况	RMSE	MaE	MAE
一阶RC模型	DST	0.0413	0.0124	0.1402
一阶RC模型	UDDS	0.0186	0.0427	0.0735

改进模型	DST	0.0391	0.0088	0.0850
改进模型	UDDS	0.0135	0.0348	0.0597

工况	算法	RMSE	MaE	MAE
DST	UKF	0.86%	0.52%	0.75%
DST	加权UKF	0.45%	0.29%	0.39%

UDDS	UKF	1.26%	0.98%	1.53 %
UDDS	加权UKF	0.33%	0.27%	0.45%

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