Modular MV Naturally Balanced Converter With High-Frequency Isolation and No DC-Link Capacitor for EV Fast Charging

Andrei Blinov; Andrii Chub; Naki Guler; Sertac Bayhan; Leila Parsa; Dmitri Vinnikov

doi:10.1109/TTE.2024.3399329

Modular MV Naturally Balanced Converter With High-Frequency Isolation and No DC-Link Capacitor for EV Fast Charging

Andrei Blinov^*, Andrii Chub, Naki Guler, Sertac Bayhan, Leila Parsa, Dmitri Vinnikov

^*Corresponding author for this work

QEERI - Energy Center

Research output: Contribution to journal › Article › peer-review

Abstract

This article presents and verifies the concept of a converter for a medium-voltage (MV) electric vehicle (EV) charging station that employs high-frequency (HF) galvanic isolation and features no dc link capacitor. The system is based on multicell boost (MCB) topology; however, instead of a conventional two-stage configuration with dc link, isolated current source converter (iCSC)-based cells are used. They perform power factor correction (PFC) while also providing HF galvanic isolation and are connected in series at the input and in parallel at the output. The exceptional feature of such configuration lies in inherent voltage balancing among the cells, which significantly simplifies the control and protection and improves scalability. The concept is verified with a scaled 4 kW prototype having three iCSC cells.

Original language	English
Pages (from-to)	1141-1150
Number of pages	10
Journal	IEEE Transactions on Transportation Electrification
Volume	11
Issue number	1
DOIs	https://doi.org/10.1109/TTE.2024.3399329
Publication status	Published - 2025

Keywords

Electric vehicle (EV) charger
off-board charger (OBC)
power factor correction (PFC)
single-stage ac-dc converter

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10.1109/TTE.2024.3399329

Cite this

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title = "Modular MV Naturally Balanced Converter With High-Frequency Isolation and No DC-Link Capacitor for EV Fast Charging",

abstract = "This article presents and verifies the concept of a converter for a medium-voltage (MV) electric vehicle (EV) charging station that employs high-frequency (HF) galvanic isolation and features no dc link capacitor. The system is based on multicell boost (MCB) topology; however, instead of a conventional two-stage configuration with dc link, isolated current source converter (iCSC)-based cells are used. They perform power factor correction (PFC) while also providing HF galvanic isolation and are connected in series at the input and in parallel at the output. The exceptional feature of such configuration lies in inherent voltage balancing among the cells, which significantly simplifies the control and protection and improves scalability. The concept is verified with a scaled 4 kW prototype having three iCSC cells.",

keywords = "Electric vehicle (EV) charger, off-board charger (OBC), power factor correction (PFC), single-stage ac-dc converter",

author = "Andrei Blinov and Andrii Chub and Naki Guler and Sertac Bayhan and Leila Parsa and Dmitri Vinnikov",

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doi = "10.1109/TTE.2024.3399329",

language = "English",

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T1 - Modular MV Naturally Balanced Converter With High-Frequency Isolation and No DC-Link Capacitor for EV Fast Charging

AU - Blinov, Andrei

AU - Chub, Andrii

AU - Guler, Naki

AU - Bayhan, Sertac

AU - Parsa, Leila

AU - Vinnikov, Dmitri

PY - 2025

Y1 - 2025

N2 - This article presents and verifies the concept of a converter for a medium-voltage (MV) electric vehicle (EV) charging station that employs high-frequency (HF) galvanic isolation and features no dc link capacitor. The system is based on multicell boost (MCB) topology; however, instead of a conventional two-stage configuration with dc link, isolated current source converter (iCSC)-based cells are used. They perform power factor correction (PFC) while also providing HF galvanic isolation and are connected in series at the input and in parallel at the output. The exceptional feature of such configuration lies in inherent voltage balancing among the cells, which significantly simplifies the control and protection and improves scalability. The concept is verified with a scaled 4 kW prototype having three iCSC cells.

AB - This article presents and verifies the concept of a converter for a medium-voltage (MV) electric vehicle (EV) charging station that employs high-frequency (HF) galvanic isolation and features no dc link capacitor. The system is based on multicell boost (MCB) topology; however, instead of a conventional two-stage configuration with dc link, isolated current source converter (iCSC)-based cells are used. They perform power factor correction (PFC) while also providing HF galvanic isolation and are connected in series at the input and in parallel at the output. The exceptional feature of such configuration lies in inherent voltage balancing among the cells, which significantly simplifies the control and protection and improves scalability. The concept is verified with a scaled 4 kW prototype having three iCSC cells.

KW - Electric vehicle (EV) charger

KW - off-board charger (OBC)

KW - power factor correction (PFC)

KW - single-stage ac-dc converter

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Modular MV Naturally Balanced Converter With High-Frequency Isolation and No DC-Link Capacitor for EV Fast Charging

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Keywords

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