电池管理系统的硬件设计

Fathir Endrawan, Reza Fauzi Iskandar, Indra Wahyudin Fathonah
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引用次数: 0

摘要

在依赖可再生能源发电的微电网系统中,电池储能系统是最重要的组成系统之一,因为它在维持微电网稳定向负荷供电方面起着至关重要的作用。然而,为了保证电池的正常运行,需要一个电池管理系统来保证电池在预期的工作范围内运行,从而保证电池的可靠性。为了确定微电网的行为和设计的BMS符合期望的规范,使用Simulink设计了一个硬件在环(HIL)仿真来模拟直流微电网,该微电网由几个子系统组成,例如:一个理想设计的发电机和负载作为测试仪,一个带有PI控制器的双向降压和升压转换器,以及一个配备开关分流电阻单元平衡类型的电池系统,所有这些都使用在Arduino上实现的BMS算法进行控制。从测试结果中可以发现,只要满足Arduino采样时间,HIL就可以在各种输入上进行良好的QoS通信。采用HIL的PI控制器不仅提高了变换器的性能,还成功地控制了电池的平衡,充电和空闲模式的效率分别达到99%和99.4%。最后,在对集成系统的测试中,BMS在各种SoC条件下,即使存在高电压瞬变,也能在母线电压和电池电流参数以及发电机电压波动的情况下保持微电网的性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Perancangan Simulasi Hardware-in-The-Loop Untuk Sistem Manajemen Baterai
In a Microgrid system that relies on renewable energy generation, one of the most important constituent systems is the Battery Energy Storage System because of its vital role in maintaining the stability of the Microgrid in providing power to the load. However, to operate the battery, a Battery Management System is needed to ensure the battery operates at the desired working range, so that battery reliability can be maintained. To determine the behavior of the Microgrid and the designed BMS in accordance with the desired specifications, a Hardware-inthe-Loop (HIL) Simulation has been designed using Simulink to model a DC Microgrid which consists of several sub-systems such as: An ideally designed generator and load as a tester, a bidirectional buck and boost converter with a PI controller, and a battery system equipped with a Switched Shunt Resistor Cell Balancing type, all controlled using the BMS algorithm implemented on Arduino. From the test results, it is found that HIL can communicate with good QoS on various inputs as long as the Arduino sample time meets. Then the PI controller with HIL was able to improve converter performance and also succeeded in controlling cell balancing with the efficiency of charging and idle modes of 99% and 99.4% respectively. Finally, in testing the integrated system, the BMS can maintain the performance of the Microgrid with bus voltage and battery current parameters in various SoC conditions and generator voltage fluctuations, even though there are high voltage transients.
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