2.4 kW prototype of on-road Wireless Power Transfer: Modelling concepts and practical implementation

This article focuses on Wireless Power Transfer, adapted to a dynamic charging infrastructure. The authors present a high-efficiency 2.4 kW prototype of electric road, designed according to an analysis based on phasor diagrams to size the key-elements of the SS resonant converter. It involves 50-cm...

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Main Authors: Caillierez, A., Gori, P.-A, Sadarnac, D., Jaafari, A., Loudot, S.
Format: Conference Proceeding
Language:English
Subjects:
Charging Infrastructure for EV's
Coils
Contactless Energy Transfer
Contactless Power Supply
Electric vehicle
Inverters
Prototypes
Resonant converter
Roads
Soft switching
Transmission of electrical energy
Vehicle dynamics
Vehicles
Voltage measurement
Wireless power transmission
ZVS converter
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creator Caillierez, A.
Gori, P.-A
Sadarnac, D.
Jaafari, A.
Loudot, S.
description This article focuses on Wireless Power Transfer, adapted to a dynamic charging infrastructure. The authors present a high-efficiency 2.4 kW prototype of electric road, designed according to an analysis based on phasor diagrams to size the key-elements of the SS resonant converter. It involves 50-cm square coils, with an air-gap of 15 cm between the ground and the on-board sides, for an automotive application. The system uses a ZPA method control on both ground and on-board parts of the air-transformer, implemented with a varying-frequency inverter. The experimental results show a very steady and stable on-board voltage despite the evolutive magnetic coupling with the displacement of the load, from -18 cm to 18 cm. The efficiency measures presented in this article reach 91% and never falls below 70%. These data being measured with an emitted voltage of 30 V (half the operating voltage), the operating efficiency reaches even higher values. The efficiency is also very stable with displacement. Furthermore, the system has a very good dynamic response: the switch between one coil to the next during the motion of the load does not exceed 4 ms, and the adaptive response to a 280 W output power step lasts only 1.1 ms before the permanent regime.
doi_str_mv 10.1109/EPE.2015.7311706
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source IEEE Electronic Library (IEL) Conference Proceedings
subjects Charging Infrastructure for EV's
Coils
Contactless Energy Transfer
Contactless Power Supply
Electric vehicle
Inverters
Prototypes
Resonant converter
Roads
Soft switching
Transmission of electrical energy
Vehicle dynamics
Vehicles
Voltage measurement
Wireless power transmission
ZVS converter
title 2.4 kW prototype of on-road Wireless Power Transfer: Modelling concepts and practical implementation
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