Abstract
Abstract. Individual pitch control (IPC) is a well-known approach to reduce blade loads on wind turbines. Although very effective, IPC usually requires high levels of actuator activities, which significantly increases the pitch actuator duty cycle (ADC). This will subsequently result in an increase of the wear on the bearings of the blades and a decrease of the wind turbine reliability. An alternative approach to this issue is to reduce the actuator activities by incorporating the output constraints in IPC. In this paper, a fully data-driven IPC approach, which is called constrained subspace predictive repetitive control (cSPRC), is introduced. The output constraints can be explicitly considered in the control problem formulation via a model predictive control (MPC) approach. The cSPRC approach will actively produce the IPC action for the necessary load reduction when the blade loads violate the output constraints. In this way, actuator activities can be significantly reduced. Two kinds of scenarios are simulated to illustrate the unique applications of the proposed method: wake–rotor overlap and turbulent sheared wind conditions. Simulation results show that the developed cSPRC is able to account for the output constraints into the control problem formulation. Since the IPC action from cSPRC is only triggered to prevent violating the output constraints, the actuator activities are significantly reduced. This will help to reduce the pitch ADC, thus leading to an economical viable load control strategy. In addition, this approach allows the wind farm operator to design conservative bounds to guarantee the safety of the wind turbine control system.
Highlights
Over the past decades, wind energy has expanded by leaps and bounds in the international energy mix
The second contribution is the unique application of the constrained subspace predictive repetitive control (cSPRC) approach to two independent scenarios: one where the wind turbine is impinged and overlapped by the wake shed from the upstream turbine and one where the turbulent sheared wind condition is present, respectively
The wind farm wake shed from the upstream turbine propagates from left to right sectors of the rotor, leading to the wake–rotor overlap on the downstream turbine
Summary
Wind energy has expanded by leaps and bounds in the international energy mix (van Kuik et al, 2016). In order to approach the goal of introducing output constraints in wind turbine control, a novel IPC approach is presented in this paper It is based on a constrained subspace predictive repetitive control (cSPRC). Once the blade loads induced by the wind turbulence and wind farm wake increase and violate the output constraints, cSPRC will actively produce the IPC action for the necessary load mitigation. This is achieved by penalizing the control inputs only in the control objectives, which ensures that the controller will be inactive if the blade loads are lower than the safety bounds.
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