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Time-Averaged Wind Turbine Wake Flow Field Prediction Using Autoencoder Convolutional Neural Networks

Zexia Zhang, Christian Santoni, Thomas Herges, Fotis Sotiropoulos, Ali Khosronejad

2021Energies50 citationsDOIOpen Access PDF

Abstract

A convolutional neural network (CNN) autoencoder model has been developed to generate 3D realizations of time-averaged velocity in the wake of the wind turbines at the Sandia National Laboratories Scaled Wind Farm Technology (SWiFT) facility. Large-eddy simulations (LES) of the SWiFT site are conducted using an actuator surface model to simulate the turbine structures to produce training and validation datasets of the CNN. The simulations are validated using the SpinnerLidar measurements of turbine wakes at the SWiFT site and the instantaneous and time-averaged velocity fields from the training LES are used to train the CNN. The trained CNN is then applied to predict 3D realizations of time-averaged velocity in the wake of the SWiFT turbines under flow conditions different than those for which the CNN was trained. LES results for the validation cases are used to evaluate the performance of the CNN predictions. Comparing the validation LES results and CNN predictions, we show that the developed CNN autoencoder model holds great potential for predicting time-averaged flow fields and the power production of wind turbines while being several orders of magnitude computationally more efficient than LES.

Topics & Concepts

AutoencoderWakeTurbineConvolutional neural networkWind powerFlow (mathematics)Large eddy simulationComputer scienceWind speedField (mathematics)SimulationArtificial neural networkArtificial intelligenceMarine engineeringMeteorologyEngineeringAerospace engineeringPhysicsMechanicsMathematicsTurbulenceElectrical engineeringPure mathematicsWind Energy Research and DevelopmentWind and Air Flow StudiesFluid Dynamics and Vibration Analysis
Time-Averaged Wind Turbine Wake Flow Field Prediction Using Autoencoder Convolutional Neural Networks | Litcius