Abstract EN:

The present thesis proposes a new concept of electrical machine, the dual-rotor Permanent Magnet Induction Machine, as an alternative to existing electrical machines for electric traction applications. The concept of dual-rotor Permanent Magnet Induction Machine (PMIM), its operating principle, advantages and disadvantages compared to classical machines as well as design and sizing methodologies are studied. Two analytical pre-sizing methods are thus proposed in this thesis: Stator Geometry Based Method (SGBM) where the sizing algorithm begins from a given stator geometry and Output Power Based Method (OPBM) where the sizing algorithm starts from an imposed output power. The analytical approach is complemented by a study using the Finite Element Method for comparing the PMIM with the IM (Induction Machine) and the PMSM (Permanent Magnet Synchronous Machine) based on their performance, electromagnetic torque, losses and output power. Analysis of the influence of different types of magnetic and conductive materials on the performance of the PMIM is also performed, as well as an investigation on its thermal behavior. The last part of the thesis focuses on the control of the PMIM which required a prior identification of parameters of the equivalent electric circuit. The control strategy, which is based on the Field Oriented Control and is composed of two loops, one asynchronous loop for the cage rotor and one synchronous loop for the PM rotor, is then proposed to validate the dynamic behavior of the PMIM. The validation is done by comparing the results obtained by co-simulation (FEM and External control) and Park model. All obtained results allow building a prototype of the PMIM.