An Anisotropic Model for Magnetostriction and Magnetization Computing for Noise Generation in Electric Devices

An Anisotropic Model for Magnetostriction and Magnetization Computing for Noise Generation in Electric Devices

During the manufacturing process and use of ferromagnetic sheets, operations such as rolling, cutting, and tightening induce anisotropy that changes the material’s behavior. Consequently for more accuracy in magnetization and magnetostriction calculations in electric devices such as transformers, an...

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Bibliographic Details
Main Authors: Serigne Saliou Mbengue, Nicolas Buiron, Vincent Lanfranchi
Format: Article
Language:English
Published: MDPI AG 2016-04-01
Series:Sensors
Subjects:
anhysteretic
magnetostriction
magnetization
anisotropy
transformer
finite elements
vibration
noise
Online Access:http://www.mdpi.com/1424-8220/16/4/553
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spelling doaj-c87744c928dd4646be3d324feeaf64e42020-11-24T21:06:33ZengMDPI AGSensors1424-82202016-04-0116455310.3390/s16040553s16040553An Anisotropic Model for Magnetostriction and Magnetization Computing for Noise Generation in Electric DevicesSerigne Saliou Mbengue0Nicolas Buiron1Vincent Lanfranchi2Sorbonne universités, Université de Technologie de Compiègne (UTC) Laboratoire Roberval (CNRS UMR7337), 60203 Compiègne Cedex, FranceSorbonne universités, Université de Technologie de Compiègne (UTC) Laboratoire Roberval (CNRS UMR7337), 60203 Compiègne Cedex, FranceSorbonne universités, UTC Laboratoire Electromécanique de Compiègne (EA1006), 60203 Compiègne Cedex, FranceDuring the manufacturing process and use of ferromagnetic sheets, operations such as rolling, cutting, and tightening induce anisotropy that changes the material’s behavior. Consequently for more accuracy in magnetization and magnetostriction calculations in electric devices such as transformers, anisotropic effects should be considered. In the following sections, we give an overview of a macroscopic model which takes into account the magnetic and magnetoelastic anisotropy of the material for both magnetization and magnetostriction computing. Firstly, a comparison between the model results and measurements from a Single Sheet Tester (SST) and values will be shown. Secondly, the model is integrated in a finite elements code to predict magnetostrictive deformation of an in-house test bench which is a stack of 40 sheets glued together by the Vacuum-Pressure Impregnation (VPI) method. Measurements on the test bench and Finite Elements results are presented.http://www.mdpi.com/1424-8220/16/4/553anhystereticmagnetostrictionmagnetizationanisotropytransformerfinite elementsvibrationnoise
collection DOAJ
language English
format Article
sources DOAJ
author Serigne Saliou Mbengue
Nicolas Buiron
Vincent Lanfranchi
spellingShingle Serigne Saliou Mbengue
Nicolas Buiron
Vincent Lanfranchi
An Anisotropic Model for Magnetostriction and Magnetization Computing for Noise Generation in Electric Devices
Sensors
anhysteretic
magnetostriction
magnetization
anisotropy
transformer
finite elements
vibration
noise
author_facet Serigne Saliou Mbengue
Nicolas Buiron
Vincent Lanfranchi
author_sort Serigne Saliou Mbengue
title An Anisotropic Model for Magnetostriction and Magnetization Computing for Noise Generation in Electric Devices
title_short An Anisotropic Model for Magnetostriction and Magnetization Computing for Noise Generation in Electric Devices
title_full An Anisotropic Model for Magnetostriction and Magnetization Computing for Noise Generation in Electric Devices
title_fullStr An Anisotropic Model for Magnetostriction and Magnetization Computing for Noise Generation in Electric Devices
title_full_unstemmed An Anisotropic Model for Magnetostriction and Magnetization Computing for Noise Generation in Electric Devices
title_sort anisotropic model for magnetostriction and magnetization computing for noise generation in electric devices
publisher MDPI AG
series Sensors
issn 1424-8220
publishDate 2016-04-01
description During the manufacturing process and use of ferromagnetic sheets, operations such as rolling, cutting, and tightening induce anisotropy that changes the material’s behavior. Consequently for more accuracy in magnetization and magnetostriction calculations in electric devices such as transformers, anisotropic effects should be considered. In the following sections, we give an overview of a macroscopic model which takes into account the magnetic and magnetoelastic anisotropy of the material for both magnetization and magnetostriction computing. Firstly, a comparison between the model results and measurements from a Single Sheet Tester (SST) and values will be shown. Secondly, the model is integrated in a finite elements code to predict magnetostrictive deformation of an in-house test bench which is a stack of 40 sheets glued together by the Vacuum-Pressure Impregnation (VPI) method. Measurements on the test bench and Finite Elements results are presented.
topic anhysteretic
magnetostriction
magnetization
anisotropy
transformer
finite elements
vibration
noise
url http://www.mdpi.com/1424-8220/16/4/553
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