Adjoint Optimisation for Wind Farm Flow Control with a Free-Vortex Wake Model

Wind farm flow control aims to improve wind turbine performance by reducing aerodynamic wake interaction between turbines. Dynamic, physics-based models of wind farm flows have been essential for exploring control strategies such as wake redirection and dynamic induction control. Free vortex methods...

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Veröffentlicht in:	arXiv.org 2022-10
Hauptverfasser:	Maarten J van den Broek, De Tavernier, Delphine, Sanderse, Benjamin, Jan-Willem van Wingerden
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Sprache:	eng
Schlagworte:	Actuators Aerodynamics Algorithms Computer Science - Systems and Control Control algorithms Control theory Economic analysis Economic models Flow control Fluid dynamics Fluid flow Misalignment Optimization Physics - Fluid Dynamics Predictive control Steering Three dimensional models Turbines Two dimensional models Vortices Wakes Wind direction Wind farms Wind power Wind turbines Yaw
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creator	Maarten J van den Broek De Tavernier, Delphine Sanderse, Benjamin Jan-Willem van Wingerden
description	Wind farm flow control aims to improve wind turbine performance by reducing aerodynamic wake interaction between turbines. Dynamic, physics-based models of wind farm flows have been essential for exploring control strategies such as wake redirection and dynamic induction control. Free vortex methods can provide a computationally efficient way to model wind turbine wake dynamics for control optimisation. We present a control-oriented free-vortex wake model of a 2D and 3D actuator disc to represent wind turbine wakes. The novel derivation of the discrete adjoint equations allows efficient gradient evaluation for gradient-based optimisation in an economic model-predictive control algorithm. Initial results are presented for mean power maximisation in a two-turbine case study. An induction control signal is found using the 2D model that is roughly periodic and supports previous results on dynamic induction control to stimulate wake mixing. The 3D model formulation effectively models a curled wake under yaw misalignment. Under time-varying wind direction, the optimisation finds solutions demonstrating both wake steering and a smooth transition to greedy control. The free-vortex wake model with gradient information shows potential for efficient optimisation and provides a promising way to further explore dynamic wind farm flow control.
doi_str_mv	10.48550/arxiv.2208.11516
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subjects	Actuators Aerodynamics Algorithms Computer Science - Systems and Control Control algorithms Control theory Economic analysis Economic models Flow control Fluid dynamics Fluid flow Misalignment Optimization Physics - Fluid Dynamics Predictive control Steering Three dimensional models Turbines Two dimensional models Vortices Wakes Wind direction Wind farms Wind power Wind turbines Yaw
title	Adjoint Optimisation for Wind Farm Flow Control with a Free-Vortex Wake Model
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