Impact of battery cell imbalance on electric vehicle range

Green Energy and Intelligent Transportation Pub Date : 2022-12-01 DOI:10.1016/j.geits.2022.100025

Jun Chen , Zhaodong Zhou , Ziwei Zhou , Xia Wang , Boryann Liaw

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引用次数: 9

Abstract

Due to manufacturing variation, battery cells often possess heterogeneous characteristics, leading to battery state-of-charge variation in real-time. Since the lowest cell state-of-charge determines the useful life of battery pack, such variation can negatively impact the battery performance and electric vehicles range. Existing research has been focused on control design to mitigate cell imbalance. However, it is yet unclear how much impacts the cell imbalance can have on electric vehicle range. This paper closes this knowledge gap by using a simulation environment consisting of real-world driving speed data, vehicle longitudinal control, propulsion and vehicle dynamics, and cell level battery modeling. In particular, each battery cell is modeled as an equivalent circuit model, and variations among cell parameters are introduced to assess their impact on electric vehicles range and to identify the most influential parameter variations. Simulation results and analysis can be used to assist balancing control design and to benchmark control performance.

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电池单体不平衡对电动汽车续航里程的影响

由于制造工艺的变化，电池通常具有非均匀特性，导致电池的充电状态实时变化。由于电池的最低充电状态决定了电池组的使用寿命，因此这种变化会对电池的性能和电动汽车的行驶里程产生负面影响。现有的研究主要集中在控制设计以减轻细胞失衡。然而，目前尚不清楚电池不平衡对电动汽车续航里程有多大影响。本文通过使用一个仿真环境来弥补这一知识差距，该环境包括真实世界的驾驶速度数据、车辆纵向控制、推进和车辆动力学以及电池级电池建模。特别是，将每个电池单元建模为等效电路模型，并引入电池参数之间的变化，以评估它们对电动汽车续航里程的影响，并确定最具影响力的参数变化。仿真结果和分析可用于辅助平衡控制设计和基准控制性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Green Energy and Intelligent Transportation

CiteScore

6.40

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0.00%

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