Performance enhancement of the artificial neural network– based reinforcement learning for wind turbine yaw control
Ver/
Fecha
2019-11-03Autor
Sáenz Aguirre, Aitor
Zulueta Guerrero, Ekaitz
Fernández Gámiz, Unai
Metadatos
Mostrar el registro completo del ítem
Wind Energy 23 : 676-690 (2020)
Resumen
The yaw angle control of a wind turbine allows maximization of the power absorbed
from the wind and, thus, the increment of the system efficiency. Conventionally, classical
control algorithms have been used for the yaw angle control of wind turbines. Nevertheless,
in recent years, advanced control strategies have been designed and
implemented for this purpose. These advanced control strategies are considered to
offer improved features in comparison to classical algorithms. In this paper, an
advanced yaw control strategy based on reinforcement learning (RL) is designed and
verified in simulation environment. The proposed RL algorithm considers multivariable
states and actions, as well as the mechanical loads due to the yaw rotation of the wind
turbine nacelle and rotor. Furthermore, a particle swarm optimization (PSO) and Pareto
optimal front (PoF)‐based algorithm have been developed in order to find the optimal
actions that satisfy the compromise between the power gain and the mechanical loads
due to the yaw rotation. Maximizing the power generation and minimizing the mechanical
loads in the yaw bearings in an automatic way are the objectives of the proposed RL
algorithm. The data of the matrices Q (s,a) of the RL algorithm are stored as continuous
functions in an artificial neural network (ANN) avoiding any quantification problem. The
NREL 5‐MWreference wind turbine has been considered for the analysis, and real wind
data from Salt Lake, Utah, have been used for the validation of the designed yaw control
strategy via simulations with the aeroelastic code FAST.