Abstract EN:

This work deals with the study of low power electric motors manufactured in mass production by the car industry with particulary strong technical and economical constraints. The application concerns more precisely dc commutator motors with permanent magnet driving a fan in an engine cooling system. Faced with the multiplication of electrical system per car, the manufacturers objective is to decrease each motor bulk and as far as possible to rise their efficiency. The aim of this thesis lies in the development of a software for optimisation and design assistance. A first phase concerns the development of an analytical model which allows, from a motor geometry and the characterisation of its materials, to predict magnetic and electromechanical performances for a running point or on an operating range. The principal originality of the modelling is to take into account the phenomena related to commutation and more particulary the fact taht some coils are short-circuited by brushes during the armature rotation. The results obtained by the analytical model are confirmed by numerical simulations and validated by experimental results on an automated bench developed in the laboratory. The results are in very good agreement and thus allow, in a second phase, the implementation of the analytical model in an optimising procedure PASCOSMA (optimisation software developed at the laboratory of electrical engineering of Grenoble) to generate a design application. The performances expected for a running point as well as the constraints on various parameters are introduced by a convivial user interface. Automatic design of the motor is realised by respecting all the constraints and by minimising the objective function. The optimisation procedure, applied to a given motor, allowed an increase of 3. 5 points of its efficiency with a reduction of 45% of its axial bulk, in accordance with the design specifications. This work is finalised by the product of an assistance software for motor design which allows to impose constraints and to obtain the best adapted motor geometry for the imposed criteria.