Vibration Suppression of an Input-Constrained Wind Turbine Blade System

During the actual wind power generation process, turbines are often affected by side effects such as blade vibrations, input constraints, and actuator faults. This can lead to a reduction in efficiency even result unforeseen losses. study discusses robust adaptive fault-tolerant boundary control approach address issues of input-constrained actuator-fault problems turbine vibration control. By employing projection mapping techniques hyperbolic tangent functions, novel controller based on online dynamic updates is constructed constrain compensate for unknown disturbance upper bounds, ensure robustness coupled system. Additionally, considering possibility faults during proposed effectively suppress elastic vibrations system presence The effectiveness validated through numerical simulations.