What question did this study set out to answer?

The aim is to develop a current-waveform shaping method that eliminates radial-force fluctuation and torque ripple in switched reluctance motors.

April 28, 2026Open Access

Dual Flattening of Radial Force and Torque Waveforms in Switched Reluctance Motors

Key Points

The aim is to develop a current-waveform shaping method that eliminates radial-force fluctuation and torque ripple in switched reluctance motors.
Proposed a unified current profile for torque and radial-force control.
Compared performance against square-wave current and strategies focused on either vibration reduction or torque ripple.
Utilized experimental validation and finite-element analysis for performance assessment.
Demonstrated a significant reduction in radial-force fluctuation and torque ripple compared to conventional methods.
Improved smoothness of the torque waveform and flattened radial-force sum.
Achieved notable reduction in stator vibration during operation.

Abstract

This article presents a novel current-waveform shaping method for simultaneously eliminating radial-force fluctuation and torque ripple in switched reluctance motors. Unlike existing approaches that address these two issues separately, the proposed method unifies both objectives. The proposed current profile not only smooths the torque waveform but also flattens the radial-force sum, leading to a significant reduction in vibration. The proposed method is compared with the conventional square-wave current and with strategies dedicated solely to either vibration reduction or torque ripple minimization. Experimental validation and finite-element analysis are conducted to assess performance in terms of current, torque, radial force, and stator vibration.

Dual Flattening of Radial Force and Torque Waveforms in Switched Reluctance Motors

Key Points

Abstract

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