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Author Momeneh, A. ♦ Castilla, M. ♦ van der Pijl, F.F.A. ♦ Moradi, M. ♦ Torres, J.
Source IEEE Xplore Digital Library
Content type Text
Publisher Institute of Electrical and Electronics Engineers, Inc. (IEEE)
File Format PDF
Copyright Year ©2015
Language English
Subject Domain (in DDC) Natural sciences & mathematics ♦ Physics ♦ Electricity & electronics ♦ Technology ♦ Engineering & allied operations ♦ Applied physics
Subject Keyword Inductance ♦ Multiple loads ♦ Capacitors ♦ RLC circuits ♦ Contactless system ♦ Modulation ♦ Magnetizing inductance ♦ Mobile communication ♦ Parallel capacitor ♦ Topology ♦ Clamps ♦ Resonant inverters
Abstract This paper proposes a novel inductive contactless energy transfer system for residential distribution networks. The system is based on a resonant inverter with sliding transformers, allowing high flexibility (the connection point of the loads is movable) and high safety (electrical shocks are avoided). A new resonant topology for driving the sliding transformers is proposed which behaves as an AC high-frequency voltage source. A very interesting feature of this voltage source is that the amplitude of the output voltages is nearly constant and independent of the load consumption. The paper presents a design procedure for calculating the components and parameters of the resonant circuit. The performance of the complete contactless system is evaluated, especially the efficiency and the transient response. The reported results show good performance validating the proposed topology.
Description Author affiliation: Tech. Univ. of Catalonia, Vilanova i la Geltru, Spain (Momeneh, A.; Castilla, M.; Moradi, M.; Torres, J.) || Dept. of Electr. Sustainable Energy, Delft Univ. of Technol., Delft, Netherlands (van der Pijl, F.F.A.)
Educational Role Student ♦ Teacher
Age Range above 22 year
Educational Use Research ♦ Reading
Education Level UG and PG
Learning Resource Type Article
Publisher Date 2015-09-08
Publisher Place Switzerland
Rights Holder EPE Association and IEEE
e-ISBN 9789075815221
Size (in Bytes) 1.45 MB
Page Count 10
Starting Page 1
Ending Page 10

Source: IEEE Xplore Digital Library