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Bibliographic Details
Main Authors: Piwonski, Albert, Dular, Julien, Rezende, Rodrigo Silva, Schuhmann, Rolf
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2307.00814
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author Piwonski, Albert
Dular, Julien
Rezende, Rodrigo Silva
Schuhmann, Rolf
author_facet Piwonski, Albert
Dular, Julien
Rezende, Rodrigo Silva
Schuhmann, Rolf
contents Power cables have complex geometries in order to reduce their ac resistance. Although there are many different cable designs, most have in common that their inner conductors' cross-section is divided into several electrically insulated conductors, which are twisted over the cable's length (helicoidal symmetry). In previous works, we presented how to exploit this symmetry by means of dimensional reduction within the $\mathbf{H}-φ$ formulation of the eddy current problem. Here, the dimensional reduction is based on a coordinate transformation from the Cartesian coordinate system to a helicoidal coordinate system. This contribution focuses on how this approach can be incorporated into the magnetic vector potential based $\mathbf{A}-v$ formulation.
format Preprint
id arxiv_https___arxiv_org_abs_2307_00814
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Finite Element Modeling of Power Cables using Coordinate Transformations
Piwonski, Albert
Dular, Julien
Rezende, Rodrigo Silva
Schuhmann, Rolf
Numerical Analysis
Power cables have complex geometries in order to reduce their ac resistance. Although there are many different cable designs, most have in common that their inner conductors' cross-section is divided into several electrically insulated conductors, which are twisted over the cable's length (helicoidal symmetry). In previous works, we presented how to exploit this symmetry by means of dimensional reduction within the $\mathbf{H}-φ$ formulation of the eddy current problem. Here, the dimensional reduction is based on a coordinate transformation from the Cartesian coordinate system to a helicoidal coordinate system. This contribution focuses on how this approach can be incorporated into the magnetic vector potential based $\mathbf{A}-v$ formulation.
title Finite Element Modeling of Power Cables using Coordinate Transformations
topic Numerical Analysis
url https://arxiv.org/abs/2307.00814