Design of a Zero-voltage-switching Large-air-gap Wireless Charger with Low Electrical Stress for Plugin Hybrid Electric Vehicles

Chen Duan; Chenguang Jiang; Allan Taylor; Kevin Hua Bai

Design of a Zero-voltage-switching Large-air-gap Wireless Charger with Low Electrical Stress for Plugin Hybrid Electric Vehicles

Chen Duan, Chenguang Jiang, Allan Taylor, Kevin Hua Bai

Kettering University

Research output: Contribution to conference › Presentation

Abstract

This paper proposes a design and development of a wireless power transfer system to charge the battery in the Plugin Hybrid Electric Vehicles. A Parallel-Parallel topology is adopted to realize 15 cm-distance power transfer using resonance theory. Finite Element Method is used to extract the coil parameters. The advantages of the proposed design compared to the previous similar research are 1) low operational frequency (42 kHz) to avoid the electromagnetic interference to on-board automotive electronics equipment, and 2) low electrical stress to the semiconductor switches through using zero-voltage-switching technique. A 2 kW prototype to charge 200 V battery was built to experimentally verify the theoretical analysis. The overall system efficiency is ~86%.

Original language	American English
State	Published - Aug 1 2013
Event	IEEE Xplore - Duration: May 24 2016 → …

Conference

Conference	IEEE Xplore
Period	5/24/16 → …

Keywords

Wireless power transfer
Battery charger
Plugin hybrid electric vehicle
CoolMOS
Soft switching
Zero voltage switching

Disciplines

Electrical and Computer Engineering

Access to Document

https://ieeexplore.ieee.org/abstract/document/6574507

Cite this

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title = "Design of a Zero-voltage-switching Large-air-gap Wireless Charger with Low Electrical Stress for Plugin Hybrid Electric Vehicles",

abstract = " This paper proposes a design and development of a wireless power transfer system to charge the battery in the Plugin Hybrid Electric Vehicles. A Parallel-Parallel topology is adopted to realize 15 cm-distance power transfer using resonance theory. Finite Element Method is used to extract the coil parameters. The advantages of the proposed design compared to the previous similar research are 1) low operational frequency (42 kHz) to avoid the electromagnetic interference to on-board automotive electronics equipment, and 2) low electrical stress to the semiconductor switches through using zero-voltage-switching technique. A 2 kW prototype to charge 200 V battery was built to experimentally verify the theoretical analysis. The overall system efficiency is ~86%.",

keywords = "Wireless power transfer, Battery charger, Plugin hybrid electric vehicle, CoolMOS, Soft switching, Zero voltage switching",

author = "Chen Duan and Chenguang Jiang and Allan Taylor and Bai, {Kevin Hua}",

year = "2013",

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day = "1",

language = "American English",

note = "IEEE Xplore ; Conference date: 24-05-2016",

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TY - CONF

T1 - Design of a Zero-voltage-switching Large-air-gap Wireless Charger with Low Electrical Stress for Plugin Hybrid Electric Vehicles

AU - Duan, Chen

AU - Jiang, Chenguang

AU - Taylor, Allan

AU - Bai, Kevin Hua

PY - 2013/8/1

Y1 - 2013/8/1

N2 - This paper proposes a design and development of a wireless power transfer system to charge the battery in the Plugin Hybrid Electric Vehicles. A Parallel-Parallel topology is adopted to realize 15 cm-distance power transfer using resonance theory. Finite Element Method is used to extract the coil parameters. The advantages of the proposed design compared to the previous similar research are 1) low operational frequency (42 kHz) to avoid the electromagnetic interference to on-board automotive electronics equipment, and 2) low electrical stress to the semiconductor switches through using zero-voltage-switching technique. A 2 kW prototype to charge 200 V battery was built to experimentally verify the theoretical analysis. The overall system efficiency is ~86%.

AB - This paper proposes a design and development of a wireless power transfer system to charge the battery in the Plugin Hybrid Electric Vehicles. A Parallel-Parallel topology is adopted to realize 15 cm-distance power transfer using resonance theory. Finite Element Method is used to extract the coil parameters. The advantages of the proposed design compared to the previous similar research are 1) low operational frequency (42 kHz) to avoid the electromagnetic interference to on-board automotive electronics equipment, and 2) low electrical stress to the semiconductor switches through using zero-voltage-switching technique. A 2 kW prototype to charge 200 V battery was built to experimentally verify the theoretical analysis. The overall system efficiency is ~86%.

KW - Wireless power transfer

KW - Battery charger

KW - Plugin hybrid electric vehicle

KW - CoolMOS

KW - Soft switching

KW - Zero voltage switching

UR - https://digitalcommons.kettering.edu/electricalcomp_eng_conference/7

UR - https://ieeexplore.ieee.org/abstract/document/6574507

M3 - Presentation

T2 - IEEE Xplore

Y2 - 24 May 2016

ER -

Design of a Zero-voltage-switching Large-air-gap Wireless Charger with Low Electrical Stress for Plugin Hybrid Electric Vehicles

Abstract

Conference

Keywords

Disciplines

Access to Document

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Cite this