Design of a Multi-Chemistry Battery Pack System for Behind-the-meter Storage Applications

Anik Chowdhury, Ashraf Siddiquee, Partha P. Mishra, M. Haque, Mithat J. Kisacikoglu, Alastair P. Thurlbeck, Edward Watt, Mohammad Arifur Rahman, Y. Sozer, Jeff Holt
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Abstract

Battery management systems (BMS) are essential for a battery pack's safe operation and longevity. This paper presents an active balancing method-based BMS for different cell chemistry structures to be used in behind-the-meter storage (BTMS) applications. The proposed system utilizes modular isolated dual active bridge (DAB) DC/DC converters to actively balance the battery pack through a low voltage (LV) bus. A supervisory controller monitors all the cell voltage, current, and state of charge (SOC) values. Based on the estimation of the SOCs, reference currents for the DAB converters are generated by the supervisory controller. Detailed modeling and the control approach of the modular DAB converters are presented in the paper. Moreover, the control strategy of the supervisory control is also analyzed. The proposed method and structure can be extended to any combination of the number of cells to design the battery pack. Simulation results are provided for a system consisting of three cells in parallel to form a cell block and three cell blocks in series to form the battery module. Experimental results are provided for three modular DAB converters operating with a LiFeMnPO4 prismatic cell with 3.2V, 20Ah rated values.
用于表后存储应用的多化学电池组系统的设计
电池管理系统(BMS)对于电池组的安全运行和使用寿命至关重要。本文提出了一种基于主动平衡方法的基于不同电池化学结构的BTMS,用于表后存储(BTMS)应用。该系统采用模块化隔离双有源桥(DAB) DC/DC转换器,通过低电压(LV)总线主动平衡电池组。监控控制器监控所有电池电压、电流和荷电状态(SOC)值。在对soc进行估计的基础上,由监控控制器生成DAB变换器的参考电流。文中给出了模块化DAB变换器的详细建模和控制方法。并对监控的控制策略进行了分析。所提出的方法和结构可以扩展到电池数量的任意组合来设计电池组。提供了由三个并联的电池组成电池块和三个串联的电池块组成电池模块的系统的仿真结果。实验结果提供了三个模块化的DAB转换器,使用额定电压为3.2V, 20Ah的LiFeMnPO4棱镜电池。
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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