Abstract
A few studies have been conducted recently in order to improve the aerodynamic performance of Darrieus vertical-axis wind turbines with straight blades (H-type VAWTs). The blade pitch angle control is proposed to enhance the performance of H-type VAWTs. This paper aims to investigate the performance of an H-type VAWT in terms of its power output and self-starting capability using an intelligent blade pitch control strategy based on a multi-layer perceptron artificial neural network (MLP-ANN) method. The performance of the proposed blade pitch controller is investigated by adding a conventional controller (PID) to the MLP-ANN controller (i.e., a hybrid controller). The dynamics of an H-type VAWT is mathematically modeled in a nonlinear state space for the stability analysis in the sense of Lyapunov. The effectiveness of the proposed pitch control system is validated by building an H-type VAWT prototype model that is extensively tested outdoors under different conditions for both fixed and variable pitch angle configurations. Results demonstrated that the blade-pitching technique enhanced the power output of an H-type VAWT by approximately 22%. The hybrid controller that used a high percentage of the MLP-ANN controller achieved a better control performance by reducing the overshoot of the control response at high rotor speeds.
Highlights
IntroductionFor a number of years, two main types of wind turbines have been adopted for the extraction of power from wind: horizontal-axis wind turbines (HAWTs) and vertical-axis wind turbines (VAWTs)
Stand-alone power supply systems, such as wind turbines, are suitable solutions for producing the electricity needed for rural and remote areas, and economical alternatives because they can contribute to a reduction in the cost of grid extensions [1].For a number of years, two main types of wind turbines have been adopted for the extraction of power from wind: horizontal-axis wind turbines (HAWTs) and vertical-axis wind turbines (VAWTs)
VAWTs offer a number of advantages over HAWTs: VAWTs can receive wind blowing from any direction so that a yaw mechanism is unnecessary; the simplicity of the blade design means that the cost is relatively low [2]; and VAWT maintenance is comparatively quick and easy because the transmission equipment and generator are located at ground level [3]
Summary
For a number of years, two main types of wind turbines have been adopted for the extraction of power from wind: horizontal-axis wind turbines (HAWTs) and vertical-axis wind turbines (VAWTs). VAWTs offer a number of advantages over HAWTs: VAWTs can receive wind blowing from any direction (i.e., omni-directional) so that a yaw mechanism is unnecessary; the simplicity of the blade design means that the cost is relatively low [2]; and VAWT maintenance is comparatively quick and easy because the transmission equipment and generator are located at ground level [3]. An important parameter associated with VAWT blades is the operating tip speed ratio (TSR), λ. A key factor in the selection of the TSR is wind speed, as given in [4]: ωr R λ=
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