The rotor of a typical wind turbine rotates at a speed of 20-200 rpm. In conventional wind power plants the generator is coupled to the turbine via a gear so that it can typically rotate at a speed of 1000 or 1500 rpm. The wind power plant can be simplified by eliminating the gear and by using a low-speed generator. The rotor of which rotates at the same speed as the rotor of the turbine. The hypothesis in this work is that the typical generator-gear solution in the wind power plant can be replaced by a low speed Pm synchronous generator. This thesis deals with the electromagnetic design and the optimisation of two types of low speed generators for gearless wind turbines. The generators designed are radial-flux permanent magnet synchronous machines excited by NdFeB magnets. The machines have different kinds of stator windings. The first machine has a conventional three-phase, diamond winding. The second machine has a three-phase, unconventional single coil winding consisting of coils which are placed in slots around every second tooth. The electromagnetic optimisation of the machine is done by the finite element method and by a genetic algorithm combined with the finite element method. The rated powers of the machines optimised are 500kW, 10kW and 5.5 kW. Two prototypes machines were built and tested. The optimisation of the machines shows that the cost of active materials is smaller and the pull out torque per the cost of active materials higher in the conventional machines than in the single coil winding machines. The torque ripple can be reduced to a low level by choosing a suitable magnet and stator slot shape in both the designs. The demagnetisation of permanent magnets is easier to avoid in the single-coil winding machines than in the conventional deigns. The investigation of various rotor designs shows that the rotor equipped with curved surface-mounted magnets has various advantages compared with the other rotor designs, for the instance pole shoe versions. The analysis of the machines also that the load capacity of the machine is lower than that when connected directly to a sinusoidal grid.

Types and design of synchronous machines For low speed applications

MANCHIKALAPUDI, VENU KUMAR
2015/2016

Abstract

The rotor of a typical wind turbine rotates at a speed of 20-200 rpm. In conventional wind power plants the generator is coupled to the turbine via a gear so that it can typically rotate at a speed of 1000 or 1500 rpm. The wind power plant can be simplified by eliminating the gear and by using a low-speed generator. The rotor of which rotates at the same speed as the rotor of the turbine. The hypothesis in this work is that the typical generator-gear solution in the wind power plant can be replaced by a low speed Pm synchronous generator. This thesis deals with the electromagnetic design and the optimisation of two types of low speed generators for gearless wind turbines. The generators designed are radial-flux permanent magnet synchronous machines excited by NdFeB magnets. The machines have different kinds of stator windings. The first machine has a conventional three-phase, diamond winding. The second machine has a three-phase, unconventional single coil winding consisting of coils which are placed in slots around every second tooth. The electromagnetic optimisation of the machine is done by the finite element method and by a genetic algorithm combined with the finite element method. The rated powers of the machines optimised are 500kW, 10kW and 5.5 kW. Two prototypes machines were built and tested. The optimisation of the machines shows that the cost of active materials is smaller and the pull out torque per the cost of active materials higher in the conventional machines than in the single coil winding machines. The torque ripple can be reduced to a low level by choosing a suitable magnet and stator slot shape in both the designs. The demagnetisation of permanent magnets is easier to avoid in the single-coil winding machines than in the conventional deigns. The investigation of various rotor designs shows that the rotor equipped with curved surface-mounted magnets has various advantages compared with the other rotor designs, for the instance pole shoe versions. The analysis of the machines also that the load capacity of the machine is lower than that when connected directly to a sinusoidal grid.
ING - Scuola di Ingegneria Industriale e dell'Informazione
27-apr-2016
2015/2016
Tesi di laurea Magistrale
Tesi di laurea Magistrale
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10589/121433