Abstract
Coaxial counter-rotating propellers have been widely applied in ships and helicopters for improving the propulsion efficiency and offsetting system reactive torques. Lately, the counter-rotating concept has been introduced into the wind turbine design. Distributed wind power generation systems often require a novel approach in generator design. In this paper, prototype development of axial-flux generator with a counter-rotating field and armature is presented. The design process was composed of three main steps: analytical calculation, FEM simulation and prototype experimental measurements. The key aspect in the prototype development was the mechanical construction of two rotating components of the generator. Sturdy construction was achieved using two points of contact between both rotors via the placement of the bearing between the inner and outer rotor. The experimental analysis of the prototype generator has been conducted in the laboratory at the dynamometer test stand equipped with a torque sensor. The general premise for the development of such a machine was an investigation into the possibility of developing a dual rotor wind turbine. The proposed solution had to meet certain criteria such as relatively simple construction of the generator and the direct coupling between the generator and the wind turbines. The simple construction and the lack of any gearbox would allow for such a system to be constructed relatively cheaply, which is a key aspect in further system development.
Highlights
The simple construction and the lack of any gearbox would allow for such a system to be constructed relatively cheaply, which is a key aspect in further system development
Distributed wind power generation systems often require a novel approach in generator design, especially for low power machines
The counter-rotating wind turbine (CRWT) concept assumes the use of kinetic energy remaining in the airstream behind the first rotor
Summary
Distributed wind power generation systems often require a novel approach in generator design, especially for low power machines. The use of a second wind rotor in the turbine increases the efficiency of wind energy conversion to a theoretical level of 64%, it creates mechanical problems when designing generator systems. It seems a very detailed analytical and FEM model presented in the paper [16] for dual rotor radial flux wind generators based on the equivalent magnetic circuit method This model was developed to predict the flux densities of the inner and outer air gaps, flux densities of the rotor and stator yokes, back electromotive force (EMF), electromagnetic torque, cogging torque, and some other characteristics important for generator design. If taking into account articles similar to subject and scope to this content, for example [15], it should be stated that there is a lack of details of the design, modelling and testing process of a particular dual-rotor generator
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