Design of a Zero-Voltage-Switching Large-Air-Gap Wireless Charger with Low Electric Stress for Electric Vehicles

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

doi:10.1049/iet-pel.2012.0615

Design of a Zero-Voltage-Switching Large-Air-Gap Wireless Charger with Low Electric Stress for Electric Vehicles

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

Kettering University

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

Abstract

This study proposes a design and development of a wireless power transfer system to charge the battery in electric vehicles. A parallel–parallel topology is adopted to realise 10–15 cm-distance power transfer using the resonance theory. Finite-element method is used to extract the coil parameters. The advantages of the proposed design compared with the previous similar research are (i) low operational frequency (42 kHz) which avoids the electromagnetic interference to the on-board automotive electronics equipment and (ii) low electric stress to the semi-conductor 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
Journal	The Institution of Engineering and Technology
Volume	6
DOIs	https://doi.org/10.1049/iet-pel.2012.0615
State	Published - Nov 1 2013

Keywords

Air gaps
Automotive electronics
Battery chargers
Finite element analysis
Coils
Zero voltage switching
Power semiconductor switches
Battery powered vehicles
Microwave power transmission

Disciplines

Electrical and Computer Engineering

Access to Document

10.1049/iet-pel.2012.0615License: CC BY

https://digital-library.theiet.org/content/journals/10.1049/iet-pel.2012.0615

Cite this

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title = "Design of a Zero-Voltage-Switching Large-Air-Gap Wireless Charger with Low Electric Stress for Electric Vehicles",

abstract = " This study proposes a design and development of a wireless power transfer system to charge the battery in electric vehicles. A parallel–parallel topology is adopted to realise 10–15 cm-distance power transfer using the resonance theory. Finite-element method is used to extract the coil parameters. The advantages of the proposed design compared with the previous similar research are (i) low operational frequency (42 kHz) which avoids the electromagnetic interference to the on-board automotive electronics equipment and (ii) low electric stress to the semi-conductor 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%.",

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AU - Taylor, Allan

AU - Bai, Kevin Hua

PY - 2013/11/1

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N2 - This study proposes a design and development of a wireless power transfer system to charge the battery in electric vehicles. A parallel–parallel topology is adopted to realise 10–15 cm-distance power transfer using the resonance theory. Finite-element method is used to extract the coil parameters. The advantages of the proposed design compared with the previous similar research are (i) low operational frequency (42 kHz) which avoids the electromagnetic interference to the on-board automotive electronics equipment and (ii) low electric stress to the semi-conductor 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 study proposes a design and development of a wireless power transfer system to charge the battery in electric vehicles. A parallel–parallel topology is adopted to realise 10–15 cm-distance power transfer using the resonance theory. Finite-element method is used to extract the coil parameters. The advantages of the proposed design compared with the previous similar research are (i) low operational frequency (42 kHz) which avoids the electromagnetic interference to the on-board automotive electronics equipment and (ii) low electric stress to the semi-conductor 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 - Air gaps

KW - Automotive electronics

KW - Battery chargers

KW - Finite element analysis

KW - Coils

KW - Zero voltage switching

KW - Power semiconductor switches

KW - Battery powered vehicles

KW - Microwave power transmission

UR - https://digitalcommons.kettering.edu/electricalcomp_eng_facultypubs/9

UR - https://digital-library.theiet.org/content/journals/10.1049/iet-pel.2012.0615

U2 - 10.1049/iet-pel.2012.0615

DO - 10.1049/iet-pel.2012.0615

M3 - Article

VL - 6

JO - The Institution of Engineering and Technology

JF - The Institution of Engineering and Technology

ER -

Design of a Zero-Voltage-Switching Large-Air-Gap Wireless Charger with Low Electric Stress for Electric Vehicles

Abstract

Keywords

Disciplines

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