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PIER PIER B PIER C PIER M PIER Letters
2023-07-29
Finite Element Analysis on Doubly Salient Singly Excited Machine for Electrified Transportation Systems
By
Prabhu Sundaramoorthy,

    Dr. Prabhu Sundaramoorthy

    Department of Electrical and Electronics Engineering

    Sree Vidyanikethan Engineering College

    India

    Homepage

Vijayakumar Arun,

    Prof. Vijayakumar Arun

    Mohan Babu University

    India

    Homepage

Balaji Mahadevan,

    Professor Balaji Mahadevan

    Faculty of Electrical and Electronics Engineering

    Sri Sivasubramaniya Nadar College of Engineering

    India

    Homepage

Peruthambi Venkatesh,

    Dr. Peruthambi Venkatesh

    Department of Electrical and Electronics Engineering

    Mohan Babu University

    India

    Homepage

Puluru Venkata Aravindha Reddy,

    Dr. Puluru Venkata Aravindha Reddy

    Department of Electrical and Electronics Engineering

    Sree Vidyanikethan Engineering College

    India

    Homepage

Sane Siva Mohan,

    Dr. Sane Siva Mohan

    Department of Electrical and Electronics Engineering

    Sree Vidyanikethan Engineering College

    India

    Homepage

Sareddy Raju Kumar Reddy,

    Dr. Sareddy Raju Kumar Reddy

    Department of Electrical and Electronics Engineering

    Sree Vidyanikethan Engineering College

    India

    Homepage

Somu Santhosh Kumar Reddy

    Dr. Somu Santhosh Kumar Reddy

    Department of Electrical and Electronics Engineering

    Sree Vidyanikethan Engineering College

    India

    Homepage

Progress In Electromagnetics Research C, Vol. 135, 145-156, 2023
doi:10.2528/PIERC23050102 | Google Scholar

Abstract
Doubly Salient Singly Excited Machine (DSSEM) inbuilt with the features as high torque density, high speed density, compactness, low maintenance, but the machine reduces its application due to its demerits as torque ripple. This study enhances the performance of switched reluctance motor (SRM) in the track of electromagnetic and mechanical characteristics. A 290 Volts, 10 Amps, 3000 rpm, 4 N-m SRM undergoes finite element (FE) characterization in the view of parameters like torque ripple. In the regard of torque characterization, the ripple torque is estimated under rated condition. FE analysis gives accurate results by 2D analysis. Torque ripple is the main concern in electrical machines, because these two are responsible for producing harmonics, vibration, and noise. So, a novel machine is designed to reduce the torque ripple content. The losses are considered as heat generation as a source of temperature rise in a motor, and the heat distribution is analyzed. The experimental setup is arranged to evaluate the simulation results with the current profile of FE analysis and prototype for verification.
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Citation
Prabhu Sundaramoorthy, Vijayakumar Arun, Balaji Mahadevan, Peruthambi Venkatesh, Puluru Venkata Aravindha Reddy, Sane Siva Mohan, Sareddy Raju Kumar Reddy, and Somu Santhosh Kumar Reddy, "Finite Element Analysis on Doubly Salient Singly Excited Machine for Electrified Transportation Systems," Progress In Electromagnetics Research C, Vol. 135, 145-156, 2023.
doi:10.2528/PIERC23050102
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