基于fpga的电池管理系统,用于实时监测和瞬时SOC预测

Abdulkadir Saday, I. Ozkan, I. Saritas
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引用次数: 2

摘要

对于使用电池组的所有类型的电动汽车来说,电池管理系统(BMS)正变得至关重要。电池的温度和平衡等各种因素直接影响到车载电池的使用寿命、安全性和效率。为了安全性和鲁棒性,应该立即监控和调整这些因素。如今,电池管理系统正在使用不同的生产方法和算法不断开发。在本研究中,通过测量电池单体的温度、电流、电流平衡、负载状态、健康状态等参数进行计算,并通过这些计算提供对电池组的控制。通过使用强大的处理器,可以对所有这些数据进行即时和连续的测量和处理,并根据计算结果创建控制算法。FPGA是一种能够提供BMS所需的速度和功能的处理器。在电池管理系统中,FPGA负责接收和处理来自电池单元的所有信号并产生结果。它立即处理来自温度,电流和电压传感器的数据,并应用平衡所需的控制阶段。此外,通过即时测量充电状态(SOC)来计算电池的充放电容量。在电池管理系统中,SOC是保证电池组安全运行的重要组成部分。因此,需要准确、实时地估计SOC。由于其并行处理能力,FPGA可以同时从传感器读取数据并执行相关计算。本研究在FPGA上实现了一种实时、高计算速度的多功能BMS系统设计。在仿真环境下,对基于嵌入式系统的实验电池的电压和电流进行了实时监测。实验结果表明,瞬时SOC估计是成功的,系统将即时结果返回到输入的传感器数据。使用FPGA作为管理单元将为BMS提供显著的优势,具有高运行速度、实时监控、低功耗和可重编程性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
FPGA-Based battery management system for real-time monitoring and instantaneous SOC prediction
Battery management systems (BMS) are becoming essential for all types of electric vehicles using battery packs. Various factors, such as battery temperature and balance, directly affect the life, safety, and efficiency of batteries used in vehicles. For security and robustness, these factors should be monitored and adjusted instantly. Today, battery management systems are constantly being developed using different production methods and algorithms. In the studies, calculations are made by measuring parameters such as temperature, current, current balance, load status, and health status of the battery cells, and the control of the battery group is provided with these calculations. Instant and continuous measurement and processing of all these data and the creation of a control algorithm according to the calculation result are possible with the use of powerful processors. FPGA is a processor that can provide the speed and functionality required for BMS. In the battery management system, the FPGA is responsible for receiving and processing all signals from the battery cells and producing results. It instantly processes the data from temperature, current, and voltage sensors and applies the control stage required for balancing. In addition, the charge and discharge capacity of the battery is calculated by instantly measuring the state of charge (SOC). SOC is of great importance in the battery management system to ensure the safety of the battery pack. Therefore, the SOC needs to be estimated accurately and in real-time. Thanks to its parallel processing capability, the FPGA can simultaneously read data from the sensors and perform related calculations. In this study, a versatile system design with real-time, high computational speed for BMS was carried out on FPGA. The voltage and current of an experimental battery based on the embedded system were monitored in real time in a simulation environment. Experimental results show that the instantaneous SOC estimation is successful, and the system returns instant results to the incoming sensor data. The use of FPGA as a management unit will provide significant advantages in BMS with its high operating speed, real-time monitoring, low power consumption, and re-programmability.
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