模块电压对电池集成变流器系统效率的影响

R. Khanaki, Geoffrey R Walker, M. Broadmeadow, G. Ledwich
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摘要

与单个电池组和转换器相比,模块化电池与多个专用DC-DC或DC-AC转换器的概念带来了几个好处。其中包括电荷平衡控制、增强的可靠性、改进的安全性和降低的投资风险。降低电力电子转换器元件的电压和额定功率也可能是有益的,但需要优化。系统设计可能倾向于较少的电池电源模块(bpm),具有大量的电池单元和较高电压的电力电子开关,或者许多bpm具有较少的电池单元和低电压开关。本文从效率的角度研究了电池集成变换器系统中电池功率模块(bpm)额定电压选择的优化和其他实际权衡。以标称3.8 kW的LiFePO4电池系统为例,采用集成降压转换器模块化380 Vdc稳压母线。基于MOSFET和模块额定电压(30,40,60,80,100和150v),推导出不同的配置。测试了不同配置的MOSFET和电感在高、低工作频率下的损耗。在高、低工作频率下,系统总损耗不超过52w。然而,具有大量低电压模块的配置具有较低MOSFET损耗的优点,这应该简化冷却。
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IMPACT OF MODULE VOLTAGE ON EFFICIENCY OF BATTERY-INTEGRATED-CONVERTER SYSTEMS
The concept of modularizing batteries with multiple dedicated DC-DC or DC-AC converters brings several benefits as compared to a single battery pack and converter. These include charge balancing control, enhanced reliability, improved safety, and lower investment risk. Lower voltage and power ratings of power electronic converter elements may also be beneficial, but require optimization. The system design might favour fewer battery power modules (BPMs) with a high number of battery cells and higher voltage power electronic switches, or many BPMs with fewer cells with low voltage switches. This paper examines the optimization and other practical trade-offs associated with the selection of the voltage rating of battery power modules (BPMs) in a battery-integrated-converter system from an efficiency perspective. A nominal 3.8 kW battery system with LiFePO4 battery cells is taken as an example, and modularized with integrated buck converters for a regulated 380 Vdc bus. Based on MOSFET and thus module voltage rating (30, 40, 60, 80, 100 and 150 V), different configurations are derived. The MOSFET and inductor losses of different configurations are examined for high and low working frequencies. The total system losses of all scenarios does not exceed 52 W, for both high and low working frequencies. However, configurations with a high number of lower voltage modules have the advantage of lower MOSFET loss, which should simplify cooling.
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