网络拓扑
推进
逆变器
模块化设计
碳化硅
电压
转换器
汽车工程
电流隔离
电气工程
计算机科学
拓扑(电路)
可靠性(半导体)
工程类
电力航天器推进
功率(物理)
航空航天工程
材料科学
物理
变压器
操作系统
冶金
量子力学
作者
Janine Ebersberger,Maximilian Hagedorn,Malte Lorenz,Axel Mertens
标识
DOI:10.1109/jestpe.2022.3164804
摘要
Decarbonization of the air transport sector is a major challenge for the upcoming years. To achieve this goal, electrification of the propulsion for small to medium civil aircraft is a key enabler for various concepts, ranging from hybrid over fuel cell to full battery powered aircraft. While small electric aircraft for lower altitudes already exist, it is necessary to extend the power range to several megawatts for passenger aircraft flying at medium to high altitudes. Here, the question of the most promising inverter topology and dc supply voltage level is yet to be answered. Challenges include lightweight, high efficiency, and reliability due to cosmic-ray-induced failures. To address this, a broad range of topologies, covering conventional two-level, three-level inverters, and modular multilevel converters (MMCs), are compared in this article. For this purpose, an inverter design methodology is introduced, including chip area optimization, inverter loss, and weight calculation. As a prerequisite, a loss model for high-voltage silicon carbide (SiC) MOSFETs is derived and used to estimate the characteristics for voltage levels not readily available today. Uncertainty is addressed by covering several scenarios.
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