Abstract
The improvement of wind turbine performance poses a constant challenge to researchers and designers in the field. As a result, the literature presents new concepts of wind turbines (WTs), such as: counter-rotating wind turbines (CRWTs) with two coaxial wind rotors revolving in opposite directions, WTs with higher-efficiency and downsized transmission systems, or WTs with counter-rotating electric generators (CREGs). Currently, there are a few solutions of WTs, both containing counter-rotating components; however, they can only be used in small-scale applications. Aiming to extend the use of WTs with counter-rotating wind rotors (CRWRs) and CREGs to medium- and large-scale applications, this paper introduces and analyzes a higher-performance WT solution, which integrates two counter-rotating wind rotors, a 1 degree of freedom (DOF) planetary speed increaser with four inputs and outputs, and a counter-rotating electric generator. The proposed system yields various technical benefits: it has a compact design, increases the output power (which makes it suitable for medium- and large-scale wind turbines) and allows a more efficient operation of the electric generator. The kinematic and static computing methodology, as well as the analytical models and diagrams developed for various case studies, might prove useful for researchers and designers in the field to establish the most advantageous solution of planetary speed increasers for the CRWTs with CREGs. Moreover, this paper extends the current database of WT speed increasers with an innovative concept of 1 DOF planetary gearbox, which is subject to a patent application.
Highlights
In recent years, wind power has increasingly become a feasible alternative in providing electrical energy to fossil fuels, it is site-dependent and its conversion is influenced by the equipment performance
The literature presents new concepts of WTs that meet the requirements for increased performance and optimal use of wind potential, such as large-capacity WTs using multiple, smaller rotors in different spatial arrangements [11], counter-rotating wind turbines (CRWTs) with two coaxial wind rotors revolving in opposite directions [10,12,13], or counter-rotating electric generators (CREGs) composed by both mobile rotors and stators turning with opposite speeds, which increase the output power of WTs
Aiming to extend the use of type (d) WTs to medium- and large-scale applications, this paper introduces and analyzes a higher-performance WT solution, which integrates two counter-rotating wind rotors (CRWRs), a 1 degree of freedom (DOF)
Summary
Wind power has increasingly become a feasible alternative in providing electrical energy to fossil fuels, it is site-dependent and its conversion is influenced by the equipment performance. Due to the relatively low capacity of the CREGs, solution (c) is suitable to be implemented in the built environment This type of electric generators—characterized by increased efficiency as compared to the classical ones—can be combined with wind rotors with two rows of blades, which are more efficient than those with a single row of blades, leading to wind systems with higher electrical power than the conventional ones. The behavior of such electric generators under dynamic conditions and their optimal functioning are approached in [41,42].
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