Supercritical Carbon Dioxide (sCO₂)-Cooled Current Source Inverter-Based Integrated Motor Drive for MW-Scale Electric Aviation Applications

Authors

Hang Dai, Utah State UniversityFollow
John Yagielski, GE Aerospace ResearchFollow
Thomas Jahns, University of Wisconsin-MadisonFollow
Kum-Kang Huh, GE Aerospace ResearchFollow
Vandana Rallabandi, Oak Ridge National LaboratoryFollow
Libing Wang, GE Aerospace ResearchFollow
Tarak Saha, GE Aerospace ResearchFollow
Wenda Feng, University of Wisconsin-MadisonFollow
Bulent Sarlioglu, University of Wisconsin-MadisonFollow

Document Type

Conference Paper

Journal/Book Title/Conference

2025 IEEE Applied Power Electronics Conference and Exposition (APEC)

Publisher

Institute of Electrical and Electronics Engineers

Publication Date

5-1-2025

First Page

3174

Last Page

3180

Abstract

Wide-bandgap enabled current-source inverter (CSI) is a promising power converter topology that has cleaner output voltage waveform, higher fault tolerance, and higher temperature operation capability than conventional voltage-source inverters (VSI). This paper presents a WBG-enabled CSI for a 2-MW integrated motor drive (IMD) for electric aviation application. The CSI system consists of two series-connected CSI that forms as a unit, and three such units are connected in parallel to drive a specially designed surface permanent magnet synchronous motor (PMSM) that has six individual groups of three-phase windings. Furthermore, the CSI’s dc-link inductor and power modules are cooled with supercritical carbon dioxide (sCO₂), and also cools the integrated PMSM’s stator windings. The proposed CSI-based MW-scale IMD achieves an estimated 97.3% efficiency and 18.1 kW/kg power density. Its high-power density and promising fault-tolerance characteristics make it a competitive solution for MW-scale electric aviation applications.

Recommended Citation

H. Dai et al., "Supercritical Carbon Dioxide (sCO2)-Cooled Current Source Inverter-based Integrated Motor Drive for MW-scale Electric Aviation Applications," 2025 IEEE Applied Power Electronics Conference (APEC), Atlanta, GA, USA, 2025, pp. 3174-3180, doi: 10.1109/APEC48143.2025.10977553.