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Transfer Learning-Based Design Method for Cogging Torque Reduction in PMSM With Step-Skew Considering 3-D Leakage Flux

Yun-Jae Won, Jae-Hyun Kim, Soo-Hwan Park, Ji‐Hyeon Lee, Soo-Min An, Doo-Young Kim, Myung‐Seop Lim

2023IEEE Transactions on Magnetics19 citationsDOI

Abstract

Step-skew is a common technique for eliminating the cogging torque of a target harmonic order in permanent magnet synchronous motors (PMSMs). However, when step-skew is applied to the rotor, the cogging torque of the target harmonic order is not completely eliminated due to 3-D leakage flux. Therefore, the 3-D leakage flux should be considered in designing a PMSM with step-skew for cogging torque reduction. The most accurate way to consider the 3-D leakage flux is to perform 3-D finite element analysis (FEA), but it has the disadvantage of high computation time. To resolve this challenge, this article proposes a design method that utilizes transfer learning to reduce the time for 3-D FEA while maintaining accuracy. Through the proposed method, a large amount of 2-D FEA-based data and a small amount of 3-D FEA-based data are used instead of a large amount of 3-D FEA-based data, with similar accuracy as using a large amount of 3-D FEA-based data, and the computational time is highly reduced. Finally, a prototype is fabricated and tested to verify the validity of the proposed design method for cogging torque reduction.

Topics & Concepts

Cogging torqueSkewFinite element methodMagnetic flux leakageTorqueControl theory (sociology)Leakage (economics)Computer scienceMagnetHarmonic analysisMechanical engineeringEngineeringPhysicsElectronic engineeringStructural engineeringArtificial intelligenceMacroeconomicsEconomicsThermodynamicsControl (management)TelecommunicationsElectric Motor Design and AnalysisSensorless Control of Electric MotorsMagnetic Properties and Applications