In this paper a dual-three phase synchronous reluctance machine is optimized for fault-tolerant applications. The main objective of such a design is improving the fault-tolerant capability by means of a proper motor geometry and winding arrangement paying attention to the torque density, torque ripple, mutual magnetic coupling and the maximum short circuit currents in several operating conditions. Finally, a prototype is manufactured and tested in order to validate the simulation predictions yielding good results.
Babetto C., Bianchi N., Torreggiani A., Bianchini C., Davoli M., Bellini A. (2019). Optimal Design and Experimental Validation of a Synchronous Reluctance Machine for Fault-Tolerant Applications. Institute of Electrical and Electronics Engineers Inc. [10.1109/ECCE.2019.8911855].
Optimal Design and Experimental Validation of a Synchronous Reluctance Machine for Fault-Tolerant Applications
Bellini A.
2019
Abstract
In this paper a dual-three phase synchronous reluctance machine is optimized for fault-tolerant applications. The main objective of such a design is improving the fault-tolerant capability by means of a proper motor geometry and winding arrangement paying attention to the torque density, torque ripple, mutual magnetic coupling and the maximum short circuit currents in several operating conditions. Finally, a prototype is manufactured and tested in order to validate the simulation predictions yielding good results.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
