iEnergy (Mar 2022)

Design of a 10 kV SiC MOSFET-based high-density, high-efficiency, modular medium-voltage power converter

  • Slavko Mocevic,
  • Jianghui Yu,
  • Boran Fan,
  • Keyao Sun,
  • Yue Xu,
  • Joshua Stewart,
  • Yu Rong,
  • He Song,
  • Vladimir Mitrovic,
  • Ning Yan,
  • Jun Wang,
  • Igor Cvetkovic,
  • Rolando Burgos,
  • Dushan Boroyevich,
  • Christina DiMarino,
  • Dong Dong,
  • Jayesh Kumar Motwani,
  • Richard Zhang

DOI
https://doi.org/10.23919/IEN.2022.0001
Journal volume & issue
Vol. 1, no. 1
pp. 100 – 113

Abstract

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Simultaneously imposed challenges of high-voltage insulation, high dv/dt, high-switching frequency, fast protection, and thermal management associated with the adoption of 10 kV SiC MOSFET, often pose nearly insurmountable barriers to potential users, undoubtedly hindering their penetration in medium-voltage (MV) power conversion. Key novel technologies such as enhanced gate-driver, auxiliary power supply network, PCB planar dc-bus, and high-density inductor are presented, enabling the SiC-based designs in modular MV converters, overcoming aforementioned challenges. However, purely substituting SiC design instead of Si-based ones in modular MV converters, would expectedly yield only limited gains. Therefore, to further elevate SiC-based designs, novel high-bandwidth control strategies such as switching-cycle control (SCC) and integrated capacitor-blocked transistor (ICBT), as well as high-performance/high-bandwidth communication network are developed. All these technologies combined, overcome barriers posed by state-of-the-art Si designs and unlock system level benefits such as very high power density, high-efficiency, fast dynamic response, unrestricted line frequency operation, and improved power quality, all demonstrated throughout this paper.

Keywords