Lithium-Ion Cell Balancing Using Auxiliary Battery and DC/DC Unidirectional Converter

2021 IEEE Conference on Energy Conversion (CENCON) Pub Date : 2021-10-25 DOI:10.1109/CENCON51869.2021.9627298

Muhammad Hazwan Hashim, Mohd Saiful Jamaluddin, Mohd Hafidzuddin Sam Hun, M. J. Aziz, N. M. Nordin

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Abstract

The lithium-ion battery became commercially popular and used due to its salient characteristics such as high terminal voltage, energy density and power density of a single cell. However, if there is no proper power regulation during the process of both charging and discharging. In that case, the life span of the batteries will significantly decrease and leads to undesirable results such as fire or explosion at times. Proper power regulation is essentials, and battery management systems (BMS) are employed to circumvent these problems. SOC estimation, cell balancing, and thermal management are the common subsystems of the battery management system (BMS). This paper focuses on the cell balancing subsystem, where it is a crucial subsystem of the BMS that will efficiently prolong the battery life span. The active balancing topology used in this paper is a Single Switch Capacitor to performed module balancing and cell balancing within internal modules. The BMS is based on the pack modularization architecture, where a single capacitor is being installed for module-to-module balancing. As for internal module balancing, cells are balanced using a single capacitor with applications of Auxiliary Battery and DC/DC Unidirectional Converter for boost charging purposes. Finally, the simulation of the BMS is being modelled with MATLAB Simulink to validate the results of the implementation system.

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用辅助电池和DC/DC单向变换器平衡锂离子电池

锂离子电池因其高终端电压、能量密度和单电池功率密度等显著特性而在商业上流行和使用。但是，如果在充电和放电过程中没有适当的功率调节。在这种情况下，电池的寿命将大大减少，并导致诸如火灾或爆炸等不良后果。适当的功率调节是必不可少的，而电池管理系统(BMS)的使用可以规避这些问题。SOC评估、电池平衡和热管理是电池管理系统(BMS)的常见子系统。电池平衡子系统是电池管理系统中有效延长电池寿命的关键子系统。本文采用的有源平衡拓扑是单个开关电容，在内部模块内进行模块平衡和单元平衡。BMS基于封装模块化架构，其中单个电容器被安装用于模块到模块的平衡。至于内部模块平衡，电池使用单个电容器进行平衡，并应用辅助电池和DC/DC单向转换器进行升压充电。最后，利用MATLAB Simulink对BMS进行了仿真，验证了实现系统的结果。

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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2021 IEEE Conference on Energy Conversion (CENCON)

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