Incorporating the Soft Magnetic Material Degradation to Numerical Simulations

Gereon Goldbeck; Marco Cossale; Martin Kitzberger; Gerd Bramerdorfer; Dietmar Andessner; Wolfgang Amrhein

doi:10.1109/TIA.2020.2986703

Incorporating the Soft Magnetic Material Degradation to Numerical Simulations

Gereon Goldbeck, Marco Cossale, Martin Kitzberger, Gerd Bramerdorfer, Dietmar Andessner, Wolfgang Amrhein

Institute of Electrical Drives and Power Electronics

Research output: Contribution to journal › Article › peer-review

Abstract

This article focuses on the numerical implementation of a continuous model for local degradation in soft magnetic materials. Cutting and punching processes required for producing electric machines impact the magnetic properties of soft magnetic materials. A simplified but effective model for considering local degradation of soft magnetic materials is defined and experimentally validated. The proposed model is then implemented in the source code of numerical simulation tool to assign directly at the mesh level the material characteristics as a function of the distance from the cut edge. The procedure as well as the flow chart for the implementation is described in detail. The proposed method allows avoiding the drawbacks of multilayer approaches and consequently increased model complexity and a required finer mesh density. A comparison between simulation results and measurements of lamination rings is presented and discussed.

Original language	English
Article number	9064531
Pages (from-to)	3584–3593
Number of pages	10
Journal	IEEE Transactions on Industry Applications
Volume	56
Issue number	4
DOIs	https://doi.org/10.1109/TIA.2020.2986703
Publication status	Published - 2020

Fields of science

202 Electrical Engineering, Electronics, Information Engineering
202009 Electrical drive engineering
202011 Electrical machines
202025 Power electronics
202027 Mechatronics

JKU Focus areas

Digital Transformation
Sustainable Development: Responsible Technologies and Management

Access to Document

10.1109/TIA.2020.2986703

Cite this

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title = "Incorporating the Soft Magnetic Material Degradation to Numerical Simulations",

abstract = "This article focuses on the numerical implementation of a continuous model for local degradation in soft magnetic materials. Cutting and punching processes required for producing electric machines impact the magnetic properties of soft magnetic materials. A simplified but effective model for considering local degradation of soft magnetic materials is defined and experimentally validated. The proposed model is then implemented in the source code of numerical simulation tool to assign directly at the mesh level the material characteristics as a function of the distance from the cut edge. The procedure as well as the flow chart for the implementation is described in detail. The proposed method allows avoiding the drawbacks of multilayer approaches and consequently increased model complexity and a required finer mesh density. A comparison between simulation results and measurements of lamination rings is presented and discussed.",

author = "Gereon Goldbeck and Marco Cossale and Martin Kitzberger and Gerd Bramerdorfer and Dietmar Andessner and Wolfgang Amrhein",

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AU - Goldbeck, Gereon

AU - Cossale, Marco

AU - Kitzberger, Martin

AU - Bramerdorfer, Gerd

AU - Andessner, Dietmar

AU - Amrhein, Wolfgang

PY - 2020

Y1 - 2020

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AB - This article focuses on the numerical implementation of a continuous model for local degradation in soft magnetic materials. Cutting and punching processes required for producing electric machines impact the magnetic properties of soft magnetic materials. A simplified but effective model for considering local degradation of soft magnetic materials is defined and experimentally validated. The proposed model is then implemented in the source code of numerical simulation tool to assign directly at the mesh level the material characteristics as a function of the distance from the cut edge. The procedure as well as the flow chart for the implementation is described in detail. The proposed method allows avoiding the drawbacks of multilayer approaches and consequently increased model complexity and a required finer mesh density. A comparison between simulation results and measurements of lamination rings is presented and discussed.

U2 - 10.1109/TIA.2020.2986703

DO - 10.1109/TIA.2020.2986703

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