A Generic Matrix Method to Model the Magnetics of Multi-Coil Air-Cored IPT Systems

Prasanth Venugopal; Soumya Bandyopadhyay; Pavol Bauer; Jan Abraham Ferreira

doi:10.20944/preprints201705.0191.v1

A Generic Matrix Method to Model the Magnetics of Multi-Coil Air-Cored IPT Systems

Prasanth Venugopal, Soumya Bandyopadhyay, Pavol Bauer, Jan Abraham Ferreira

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Abstract

This paper deals with a generic methodology to evaluate the magnetic parameters of contactless power transfer systems. Neumann's integral has been used to create a matrix method that can model the magnetics of single coils (circle, square, rectangle). The principle of superposition has been utilised to extend the theory to multi-coil geometries such as double circular, double rectangle and double rectangle quadrature assuming linearity of magnetics. Numerical and experimental validation has been performed to validate the analytical models developed. A rigorous application of the analysis has been carried out to study misalignment and hence the efficacy of various geometries to misalignment tolerance. Comparison of single-coil and multi-coil shapes considering coupling variation with misalignment, power transferred and maximum efficiency is carried out.

Original language	English
Publisher	Preprints
Number of pages	17
DOIs	https://doi.org/10.20944/preprints201705.0191.v1
Publication status	Published - 26 May 2017
Externally published	Yes

Keywords

Air-cored
Contactless
Coupling
Inductive Power Transfer (IPT)
Magnetics
Matrix
Modelling
Multi-coil

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10.20944/preprints201705.0191.v1Licence: CC BY

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abstract = "This paper deals with a generic methodology to evaluate the magnetic parameters of contactless power transfer systems. Neumann's integral has been used to create a matrix method that can model the magnetics of single coils (circle, square, rectangle). The principle of superposition has been utilised to extend the theory to multi-coil geometries such as double circular, double rectangle and double rectangle quadrature assuming linearity of magnetics. Numerical and experimental validation has been performed to validate the analytical models developed. A rigorous application of the analysis has been carried out to study misalignment and hence the efficacy of various geometries to misalignment tolerance. Comparison of single-coil and multi-coil shapes considering coupling variation with misalignment, power transferred and maximum efficiency is carried out.",

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N2 - This paper deals with a generic methodology to evaluate the magnetic parameters of contactless power transfer systems. Neumann's integral has been used to create a matrix method that can model the magnetics of single coils (circle, square, rectangle). The principle of superposition has been utilised to extend the theory to multi-coil geometries such as double circular, double rectangle and double rectangle quadrature assuming linearity of magnetics. Numerical and experimental validation has been performed to validate the analytical models developed. A rigorous application of the analysis has been carried out to study misalignment and hence the efficacy of various geometries to misalignment tolerance. Comparison of single-coil and multi-coil shapes considering coupling variation with misalignment, power transferred and maximum efficiency is carried out.

AB - This paper deals with a generic methodology to evaluate the magnetic parameters of contactless power transfer systems. Neumann's integral has been used to create a matrix method that can model the magnetics of single coils (circle, square, rectangle). The principle of superposition has been utilised to extend the theory to multi-coil geometries such as double circular, double rectangle and double rectangle quadrature assuming linearity of magnetics. Numerical and experimental validation has been performed to validate the analytical models developed. A rigorous application of the analysis has been carried out to study misalignment and hence the efficacy of various geometries to misalignment tolerance. Comparison of single-coil and multi-coil shapes considering coupling variation with misalignment, power transferred and maximum efficiency is carried out.

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KW - Contactless

KW - Coupling

KW - Inductive Power Transfer (IPT)

KW - Magnetics

KW - Matrix

KW - Modelling

KW - Multi-coil

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A Generic Matrix Method to Model the Magnetics of Multi-Coil Air-Cored IPT Systems

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