Development of High-Power High Switching Frequency Cryogenically Cooled Inverter for Aircraft Applications

To better support the superconducting propulsion system in the future aircraft applications, the technologies of high-power high switching frequency power electronics systems at cryogenic temperatures should be investigated. This article presents the development of a 40-kW cryogenically cooled three...

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Veröffentlicht in:IEEE transactions on power electronics 2020-06, Vol.35 (6), p.5670-5682
Hauptverfasser: Gui, Handong, Zhang, Zheyu, Chen, Ruirui, Ren, Ren, Niu, Jiahao, Li, Haiguo, Dong, Zhou, Timms, Craig, Wang, Fei, Tolbert, Leon M., Blalock, Benjamin J., Costinett, Daniel, Choi, Benjamin B.
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Sprache:eng
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Zusammenfassung:To better support the superconducting propulsion system in the future aircraft applications, the technologies of high-power high switching frequency power electronics systems at cryogenic temperatures should be investigated. This article presents the development of a 40-kW cryogenically cooled three-level active neutral point clamped inverter with 3 kHz output line frequency and 140 kHz switching frequency. Si mosfets are characterized at cryogenic temperatures, and the results show that they have promising performance such as lower on-resistance and switching loss. The design of the inverter is presented in detail with the special consideration of the cryogenic temperature operation. Moreover, a packaging and integration architecture is designed and fabricated to demonstrate the feasibility and performance of the inverter in the lab. It is able to achieve no leakage with good thermal and air insulation. With the inverter and packaging, the experimental results show that the inverter operates properly at cryogenic temperatures. The loss is measured at different load conditions, and the loss analysis is given, which shows that the cryogenically cooled inverter has 30% less loss than operating at room temperature.
ISSN:0885-8993
1941-0107
DOI:10.1109/TPEL.2019.2949711