Aerodynamic Characterization of the IEA 15 MW Reference Wind Turbine by Code-to-Code Comparison

Aerodynamic Characterization of the IEA 15 MW Reference Wind Turbine by Code-to-Code Comparison

The consistency of different aerodynamic formulations applied to the analysis of a modern multi-megawatt horizontal axis wind turbine rotor is investigated. The proposed code-to-code comparison involves specific implementations of a hierarchy of solvers based on Blade Element Momentum Theory ( AEOLI...

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Veröffentlicht in:Journal of physics. Conference series 2024-06, Vol.2767 (2), p.22040
Hauptverfasser: Tieghi, Lorenzo, Morici, Vincenzo, Castorrini, Alessio, Aryan, Navid, Greco, Luca
Format: Artikel
Sprache:eng
Schlagworte:
Actuators
Aerodynamics
Blade tips
Computational fluid dynamics
Flow separation
Fluid dynamics
Horizontal Axis Wind Turbines
Momentum theory
Panel method (fluid dynamics)
Rotors
Solvers
Suction
Uniform flow
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container_issue 2
container_start_page 22040
container_title Journal of physics. Conference series
container_volume 2767
creator Tieghi, Lorenzo
Morici, Vincenzo
Castorrini, Alessio
Aryan, Navid
Greco, Luca
description The consistency of different aerodynamic formulations applied to the analysis of a modern multi-megawatt horizontal axis wind turbine rotor is investigated. The proposed code-to-code comparison involves specific implementations of a hierarchy of solvers based on Blade Element Momentum Theory ( AEOLIAN ), Actuator Line Modelling ( OpenFOAM ), free-wake Panel Method ( FUNAERO ) and blade-resolved Computational Fluid Dynamics ( OpenFOAM ). The analysis addresses local and integral aeroloads and flow physical quantities concerning the state-of-the-art IEA 15 MW reference wind turbine in axial uniform flow conditions. The proposed solvers predict consistent rotor performance and blade aeroloads (also in line with data from of IEA Task 47). However, differences emerge close to blade root, where blade-resolved CFD reveals a significant flow separation on the suction side. Furthermore, scattering of induction factors computations is observed, especially in the axial direction. Different methodologies and numerical setup used in blade-resolved simulations allow achieving physically-consistent induction values, especially at blade tip. Finally, flow-field predictions by Computational Fluid Dynamics (CFD) and Panel Method are consistent upstream and close to the disk downstream (except where significant flow separation occurs), whilst a more detailed study on the effect of extending wake refinement zone in CFD simulation is advisable.
doi_str_mv 10.1088/1742-6596/2767/2/022040
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subjects Actuators
Aerodynamics
Blade tips
Computational fluid dynamics
Flow separation
Fluid dynamics
Horizontal Axis Wind Turbines
Momentum theory
Panel method (fluid dynamics)
Rotors
Solvers
Suction
Uniform flow
title Aerodynamic Characterization of the IEA 15 MW Reference Wind Turbine by Code-to-Code Comparison
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