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Inducted currents analysis in multiply connected conductors using reluctance – resistance networks

Inducted currents analysis in multiply connected conductors using reluctance – resistance networks
Inducted currents analysis in multiply connected conductors using reluctance – resistance networks
The paper develops a reluctance-resistance network (RRN) formulation for determining the induced current distributions in a 3D space of multiply connected conducting systems. The proposed method has been applied to solve Problem No. 7 of the International TEAM Workshops. The induced currents in the conductive plate with an asymmetrically situated ‘hole’ have been analysed. The RRN equations have been formed by means of the finite element method using the magnetic vector potential A and the electric vector potentials T and T0. The block relaxation method (BRM) combined with the Cholesky decomposition procedure has been applied to solve the resultant RRN equations. Selected results of the analysis are presented and discussed.
978-2-84832-115-8
Wojciechowski, R.
69f13603-b50e-426a-ae22-931fae8503e5
Demenko, A.
4f2e9586-6a46-44e6-8573-ce6613cc3032
Sykulski, J.K.
d6885caf-aaed-4d12-9ef3-46c4c3bbd7fb
Wojciechowski, R.
69f13603-b50e-426a-ae22-931fae8503e5
Demenko, A.
4f2e9586-6a46-44e6-8573-ce6613cc3032
Sykulski, J.K.
d6885caf-aaed-4d12-9ef3-46c4c3bbd7fb

Wojciechowski, R., Demenko, A. and Sykulski, J.K. (2009) Inducted currents analysis in multiply connected conductors using reluctance – resistance networks. XIVth International Symposium on Electromagnetic Fields in Mechatronics Electrical and Electronic Engineering, ISEF’09, , Arras, France. 10 - 12 Sep 2009.

Record type: Conference or Workshop Item (Paper)

Abstract

The paper develops a reluctance-resistance network (RRN) formulation for determining the induced current distributions in a 3D space of multiply connected conducting systems. The proposed method has been applied to solve Problem No. 7 of the International TEAM Workshops. The induced currents in the conductive plate with an asymmetrically situated ‘hole’ have been analysed. The RRN equations have been formed by means of the finite element method using the magnetic vector potential A and the electric vector potentials T and T0. The block relaxation method (BRM) combined with the Cholesky decomposition procedure has been applied to solve the resultant RRN equations. Selected results of the analysis are presented and discussed.

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More information

Published date: 10 September 2009
Additional Information: Event Dates: 10th - 12th September 2009
Venue - Dates: XIVth International Symposium on Electromagnetic Fields in Mechatronics Electrical and Electronic Engineering, ISEF’09, , Arras, France, 2009-09-10 - 2009-09-12
Organisations: EEE

Identifiers

Local EPrints ID: 267863
URI: http://eprints.soton.ac.uk/id/eprint/267863
ISBN: 978-2-84832-115-8
PURE UUID: 89625f49-26c0-4ec9-b0a0-0ec8fad9698f
ORCID for J.K. Sykulski: ORCID iD orcid.org/0000-0001-6392-126X

Catalogue record

Date deposited: 14 Sep 2009 07:41
Last modified: 15 Mar 2024 02:34

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Contributors

Author: R. Wojciechowski
Author: A. Demenko
Author: J.K. Sykulski ORCID iD

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