Litcius/Paper detail

Toward control co-design of utility-scale wind turbines: Collective vs. individual blade pitch control

Christian Santoni, Ali Khosronejad, Peter Seiler, Fotis Sotiropoulos

2022Energy Reports24 citationsDOIOpen Access PDF

Abstract

A large-eddy simulation framework has been coupled with controller modules to systematically investigate the impacts of collective (CPC) and individual (IPC) pitch control strategies on utility-scale wind turbine energy production and fatigue loads. Wind turbine components were parameterized using an actuator surface model to simulate the rotor blades and the turbine nacelle. The baseline CPC and IPC algorithms, consisting of single-input single-output proportional–integral controllers and two integral controllers, respectively, were incorporated into the numerical framework. A series of simulations were carried out to investigate the relative performance of the two controllers under various turbulent inflow conditions, spanning hub-height velocities of 7 to 14 m/s. The numerical simulation results of this study showed that, in comparison to the CPC, the IPC controller could successfully reduce the damage equivalent loads of utility-scale turbines at regions 2 and 3 of turbine operation by about 3% and 40%, respectively, without any penalty on the power production of the turbine. It was also shown that, despite its minor impact on the turbulence kinetic energy of the wake, the IPC controller did not influence the recovery of the turbine wake.

Topics & Concepts

TurbineBlade pitchWakeController (irrigation)Wind powerControl theory (sociology)InflowRotor (electric)Pitch controlTurbine bladeNacelleTurbulence kinetic energyTurbulenceMarine engineeringSimulationComputer scienceEngineeringAerospace engineeringMechanicsMechanical engineeringControl (management)PhysicsElectrical engineeringAgronomyBiologyArtificial intelligenceWind Energy Research and DevelopmentWind and Air Flow StudiesFluid Dynamics and Turbulent Flows