Modeling and Optimization of a New Magnetic Coupler Topology for DIPT Systems

The application of dynamical inductive power transfer (DIPT) systems is currently seen as one of the possible solutions to improve the autonomy of embedded power devices. In this context, electromagnetic field emissions play a crucial role in the system's design. In this article, a new coil top...

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Veröffentlicht in:	IEEE transactions on magnetics 2023-05, Vol.59 (5), p.1-4
Hauptverfasser:	de Moraes, Vinicius T. M., Kabbara, Wassim, Bensetti, Mohamed, Phulpin, Tanguy
Format:	Artikel
Sprache:	eng
Schlagworte:	Coils Couplers Coupling coefficient Coupling coefficients Couplings dynamical inductive power transfer (DIPT) electromagnetic compatibility (EMC) Electromagnetic fields Electronic devices Engineering Sciences Finite element method finite-element method (FEM) magnetic coupler magnetic field radiation Magnetic fields Magnetic noise Magnetic shielding Magnetism Modelling Optimization Physics Power transfer shielding Topology
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container_title	IEEE transactions on magnetics
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creator	de Moraes, Vinicius T. M. Kabbara, Wassim Bensetti, Mohamed Phulpin, Tanguy
description	The application of dynamical inductive power transfer (DIPT) systems is currently seen as one of the possible solutions to improve the autonomy of embedded power devices. In this context, electromagnetic field emissions play a crucial role in the system's design. In this article, a new coil topology for magnetic couplers in DIPT systems is proposed, based on the use of adjacent current loops, which can improve the tradeoff between reducing the magnetic field emissions near the magnetic coupler and maintaining almost the same system's efficiency. To evaluate the topology's performance, finite-element method (FEM) simulations are carried out to determine the impact on the magnetic field emissions and the coupling coefficient, permitting optimization of the coil geometry. Finally, a DIPT system prototype is developed for a transfer power of 500 W, validating the results obtained by modeling.
doi_str_mv	10.1109/TMAG.2023.3246768
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subjects	Coils Couplers Coupling coefficient Coupling coefficients Couplings dynamical inductive power transfer (DIPT) electromagnetic compatibility (EMC) Electromagnetic fields Electronic devices Engineering Sciences Finite element method finite-element method (FEM) magnetic coupler magnetic field radiation Magnetic fields Magnetic noise Magnetic shielding Magnetism Modelling Optimization Physics Power transfer shielding Topology
title	Modeling and Optimization of a New Magnetic Coupler Topology for DIPT Systems
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