Rapid Electric Vehicle Charging Based on Silicon Carbide Enabled Medium Voltage DC Tranmission Systems

Arkadeep Deb; Jose Ortiz Gonzalez; Ruizhu Wu; Walid Issa; Saeed Jahdi; Olayiwola Alatise

doi:10.1049/gtd2.70092

Rapid Electric Vehicle Charging Based on Silicon Carbide Enabled Medium Voltage DC Tranmission Systems

Arkadeep Deb, Jose Ortiz Gonzalez, Ruizhu Wu, Walid Issa, Saeed Jahdi, Olayiwola Alatise

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Abstract

Rapid electric vehicle (EV) chargers with power ratings above 100 kW will become more common in the future. Reinforcing UK distribution networks with additional power handling capacity can be costly and disruptive. This is due to the limited headroom in 11 kV distribution networks and the high population densities where 11 kV/400 V transformers are located. This paper proposes a medium voltage DC (MVDC) system that bypasses the 33 kV/11 and 11 kV/400 V AC transformers by transmitting 54 kV DC power directly to the EV charging stations. The 33 kV AC to 54 kV rectification in this system is proposed to be done by using a 29-level modular multilevel converter (MMC) implemented in 3.3 kV SiC MOSFETs. On the EV side, there will be a 54 kV to 800 V/400 V fully isolated DC/DC converter implemented with 3.3 kV SiC MOSFETs on the primary side and 1.2 kV SiC MOSFETs or Schottky diodes on the secondary side. This paper presents experimentally calibrated converter simulation results demonstrating improved performance in the MVDC system and shows this is only possible with SiC MOSFET technology, as the losses using silicon IGBTs make the system less efficient than the existing AC transmission system.

Original language	English
Article number	e70092
Number of pages	12
Journal	IET Generation, Transmission & Distribution
Volume	19
Issue number	1
DOIs	https://doi.org/10.1049/gtd2.70092
Publication status	Published - 2 Jul 2025

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© 2025 The Author(s). IET Generation, Transmission & Distribution published by John Wiley & Sons Ltd on behalf of The Institution of Engineering and Technology.

Research Groups and Themes

Electrical Energy Management

Keywords

Power Electronics

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Full-text PDF (final published version) Final published version, 2.72 MBLicence: CC BY

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@article{c1ada53a282f478f9aac9f3d84ca9275,

title = "Rapid Electric Vehicle Charging Based on Silicon Carbide Enabled Medium Voltage DC Tranmission Systems",

abstract = "Rapid electric vehicle (EV) chargers with power ratings above 100 kW will become more common in the future. Reinforcing UK distribution networks with additional power handling capacity can be costly and disruptive. This is due to the limited headroom in 11 kV distribution networks and the high population densities where 11 kV/400 V transformers are located. This paper proposes a medium voltage DC (MVDC) system that bypasses the 33 kV/11 and 11 kV/400 V AC transformers by transmitting 54 kV DC power directly to the EV charging stations. The 33 kV AC to 54 kV rectification in this system is proposed to be done by using a 29-level modular multilevel converter (MMC) implemented in 3.3 kV SiC MOSFETs. On the EV side, there will be a 54 kV to 800 V/400 V fully isolated DC/DC converter implemented with 3.3 kV SiC MOSFETs on the primary side and 1.2 kV SiC MOSFETs or Schottky diodes on the secondary side. This paper presents experimentally calibrated converter simulation results demonstrating improved performance in the MVDC system and shows this is only possible with SiC MOSFET technology, as the losses using silicon IGBTs make the system less efficient than the existing AC transmission system.",

keywords = "Power Electronics",

author = "Arkadeep Deb and Gonzalez, \{Jose Ortiz\} and Ruizhu Wu and Walid Issa and Saeed Jahdi and Olayiwola Alatise",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). IET Generation, Transmission \& Distribution published by John Wiley \& Sons Ltd on behalf of The Institution of Engineering and Technology.",

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T1 - Rapid Electric Vehicle Charging Based on Silicon Carbide Enabled Medium Voltage DC Tranmission Systems

AU - Deb, Arkadeep

AU - Gonzalez, Jose Ortiz

AU - Wu, Ruizhu

AU - Issa, Walid

AU - Jahdi, Saeed

AU - Alatise, Olayiwola

PY - 2025/7/2

Y1 - 2025/7/2

N2 - Rapid electric vehicle (EV) chargers with power ratings above 100 kW will become more common in the future. Reinforcing UK distribution networks with additional power handling capacity can be costly and disruptive. This is due to the limited headroom in 11 kV distribution networks and the high population densities where 11 kV/400 V transformers are located. This paper proposes a medium voltage DC (MVDC) system that bypasses the 33 kV/11 and 11 kV/400 V AC transformers by transmitting 54 kV DC power directly to the EV charging stations. The 33 kV AC to 54 kV rectification in this system is proposed to be done by using a 29-level modular multilevel converter (MMC) implemented in 3.3 kV SiC MOSFETs. On the EV side, there will be a 54 kV to 800 V/400 V fully isolated DC/DC converter implemented with 3.3 kV SiC MOSFETs on the primary side and 1.2 kV SiC MOSFETs or Schottky diodes on the secondary side. This paper presents experimentally calibrated converter simulation results demonstrating improved performance in the MVDC system and shows this is only possible with SiC MOSFET technology, as the losses using silicon IGBTs make the system less efficient than the existing AC transmission system.

AB - Rapid electric vehicle (EV) chargers with power ratings above 100 kW will become more common in the future. Reinforcing UK distribution networks with additional power handling capacity can be costly and disruptive. This is due to the limited headroom in 11 kV distribution networks and the high population densities where 11 kV/400 V transformers are located. This paper proposes a medium voltage DC (MVDC) system that bypasses the 33 kV/11 and 11 kV/400 V AC transformers by transmitting 54 kV DC power directly to the EV charging stations. The 33 kV AC to 54 kV rectification in this system is proposed to be done by using a 29-level modular multilevel converter (MMC) implemented in 3.3 kV SiC MOSFETs. On the EV side, there will be a 54 kV to 800 V/400 V fully isolated DC/DC converter implemented with 3.3 kV SiC MOSFETs on the primary side and 1.2 kV SiC MOSFETs or Schottky diodes on the secondary side. This paper presents experimentally calibrated converter simulation results demonstrating improved performance in the MVDC system and shows this is only possible with SiC MOSFET technology, as the losses using silicon IGBTs make the system less efficient than the existing AC transmission system.

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U2 - 10.1049/gtd2.70092

DO - 10.1049/gtd2.70092

M3 - Article (Academic Journal)

SN - 1751-8695

VL - 19

JO - IET Generation, Transmission & Distribution

JF - IET Generation, Transmission & Distribution

IS - 1

M1 - e70092

ER -

Rapid Electric Vehicle Charging Based on Silicon Carbide Enabled Medium Voltage DC Tranmission Systems

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