Comparative Study of the State of Charge (SoC) Balancing Techniques for Battery Power Module Configurations

2023 IEEE Conference on Power Electronics and Renewable Energy (CPERE) Pub Date : 2023-02-19 DOI:10.1109/CPERE56564.2023.10119591

Abdulrahman Mostafa, M. Gaafar, O. Abdel-Rahim, M. Orabi

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Abstract

The concept of the battery power module (BPM) has recently gained increased interest where the battery cells are decoupled from each other by connecting each cell with a lowpower DC-DC power converter. Accordingly, the output of BPMs can be connected in series and parallel to meet the required load voltage and power. In such systems, State-of-Charge (SoC) equalization is achieved by changing the rate of charge/discharge of each cell by controlling the duty cycle of the corresponding converter in BPM. Different types of DC-DC converters and control algorithms have been adopted in BPM architecture. The SoC estimation is generally acknowledged as one of the most important functions in the battery management system for lithium-ion batteries. Therefore, this paper comprehensively reviews the different control techniques presented in the literature to deal with BPM. The comparison includes the required number of sensors, the number of controlled variables, and its capability to achieve SoC balancing during both charging and discharging.

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电池电源模块配置中荷电状态平衡技术的比较研究

电池电源模块(BPM)的概念最近获得了越来越多的关注，其中通过将每个电池单元与低功率DC-DC电源转换器连接起来，将电池单元相互解耦。因此，bpm的输出可以串联和并联，以满足所需的负载电压和功率。在这样的系统中，充电状态(SoC)均衡是通过控制BPM中相应转换器的占空比来改变每个电池的充放电速率来实现的。BPM架构采用了不同类型的DC-DC转换器和控制算法。电池荷电状态估计是锂离子电池管理系统中最重要的功能之一。因此，本文全面回顾了文献中提出的处理BPM的不同控制技术。比较包括所需的传感器数量，控制变量的数量，以及在充电和放电期间实现SoC平衡的能力。

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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2023 IEEE Conference on Power Electronics and Renewable Energy (CPERE)

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