Modeling and Minimization of the Parasitic ...
Type de document :
Article dans une revue scientifique: Article original
URL permanente :
Titre :
Modeling and Minimization of the Parasitic Capacitances of Single-Layer Toroidal Inductors
Auteur(s) :
Salomez, Florentin [Auteur]
L2EP - Équipe Électronique de puissance [EP]
Videt, Arnaud [Auteur]
L2EP - Équipe Électronique de puissance [EP]
IDIR, Nadir [Auteur]
L2EP - Équipe Électronique de puissance [EP]
L2EP - Équipe Électronique de puissance [EP]
Videt, Arnaud [Auteur]
L2EP - Équipe Électronique de puissance [EP]
IDIR, Nadir [Auteur]
L2EP - Équipe Électronique de puissance [EP]
Titre de la revue :
IEEE Transactions on Power Electronics
Nom court de la revue :
IEEE Trans. Power Electron.
Numéro :
37
Pagination :
12426-12436
Éditeur :
Institute of Electrical and Electronics Engineers (IEEE)
Date de publication :
2022-10
ISSN :
0885-8993
Mot(s)-clé(s) en anglais :
Common-mode chokes
electromagnetic compatibility (EMC)
equivalent parallel capacitance (EPC)
inductor
modeling
parasitic capacitance
electromagnetic compatibility (EMC)
equivalent parallel capacitance (EPC)
inductor
modeling
parasitic capacitance
Discipline(s) HAL :
Sciences de l'ingénieur [physics]
Résumé en anglais : [en]
High-frequency power converters need electromagnetic interferences filters using common and differential mode chokes with low parasitic capacitance to comply with the electromagnetic compatibility standards. This article ...
Lire la suite >High-frequency power converters need electromagnetic interferences filters using common and differential mode chokes with low parasitic capacitance to comply with the electromagnetic compatibility standards. This article proposes a modeling method of this capacitance and ways to minimize it. The studied components are ring core inductors with magnetic materials considered as perfect conductors or with high permittivity, such as nanocrystalline material and most Mn-Zn ferrite materials. In comparison to other work in the literature, the proposed approach takes into account the curvature of the turn, in addition to the coating of the core and the insulation layer of the wire. The hypotheses, used in this article to simplify the real geometry, are compatible with two-dimensional (2-D) approaches to compute the parasitic interturns and turn–core capacitances. These capacitances are evaluated thanks to the 2-D finite element method. The obtained model allows accurate evaluation of the effect of turn–core space on the parasitic capacitance, and enables to reduce its value with a limited impact on the volume of the magnetic component.Lire moins >
Lire la suite >High-frequency power converters need electromagnetic interferences filters using common and differential mode chokes with low parasitic capacitance to comply with the electromagnetic compatibility standards. This article proposes a modeling method of this capacitance and ways to minimize it. The studied components are ring core inductors with magnetic materials considered as perfect conductors or with high permittivity, such as nanocrystalline material and most Mn-Zn ferrite materials. In comparison to other work in the literature, the proposed approach takes into account the curvature of the turn, in addition to the coating of the core and the insulation layer of the wire. The hypotheses, used in this article to simplify the real geometry, are compatible with two-dimensional (2-D) approaches to compute the parasitic interturns and turn–core capacitances. These capacitances are evaluated thanks to the 2-D finite element method. The obtained model allows accurate evaluation of the effect of turn–core space on the parasitic capacitance, and enables to reduce its value with a limited impact on the volume of the magnetic component.Lire moins >
Langue :
Anglais
Comité de lecture :
Oui
Audience :
Internationale
Vulgarisation :
Non
Établissement(s) :
Université de Lille
Centrale Lille
Arts et Métiers Sciences et Technologies
Junia HEI
Centrale Lille
Arts et Métiers Sciences et Technologies
Junia HEI
Équipe(s) de recherche :
Équipe Électronique de puissance
Date de dépôt :
2022-11-18T09:38:40Z
2022-11-22T11:41:00Z
2023-01-01T15:34:27Z
2022-11-22T11:41:00Z
2023-01-01T15:34:27Z
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