Abstract
This work presents a comparison study of the CFD modeling with two different turbulence modeling approaches viz. unsteady RANS and LES, on a full-scale model of the (New) MEXICO rotor wind turbine. The main emphasis of the paper is on the rotor and wake aerodynamics. Simulations are carried out for the three wind speeds considered in the MEXICO experiment (10, 15, and 24 ms−1). The results of uRANS and LES are compared against the (New) MEXICO experimental measurements of pressure distributions, axial, radial, and azimuth traverse of three velocity components. The near wake characteristics and vorticity are also analyzed. The pressure distribution results show that the LES can predict the onset of flow separation more accurately than uRANS when the turbine operates in the stall condition. The LES can compute the flow structures in wake significantly better than the uRANS for the stall condition of the blade. For the design condition, the mean absolute error in axial and radial velocity components along radial traverse is less than 10% for both the modeling approaches, whereas tangential component error is less than 2% from the LES approach. The results also reveal that wake recovers faster in the uRANS approach, requiring further research of the far wake region using both CFD modeling approaches.
Highlights
Wind energy is becoming an important source of renewable energy
A critical investigation is carried out to study the aerodynamic performance of the large eddy simulation (LES) and unsteady Reynolds-Averaged Navier-Stokes (uRANS) flow modeling approaches
The Phase-III Mexnext (New) Model Experiments In Controlled Conditions (MEXICO) rotor is chosen to carry out this numerical study, as it gives exhaustive information about the rotor measurements and flow field
Summary
Wind energy is becoming an important source of renewable energy. Due to low power density, wind turbines are clustered in wind farms to maximize energy output. An important limitation of such arrangement is the wake shed by the upstream turbines on the downstream turbines, which leads to lower power production and increased loads on the downstream wind turbines [1,2]. A wind turbine wake has flow scales ranging from millimeters to several hundred meters. It necessitates studying the dynamics of wind turbine wakes to design next-gen wind turbines and wind farms. To design efficient and reliable wind turbines, it is vital to have a proper understanding of rotor and wake aerodynamics. Bechmann et al [6] employed EllipSys3D CFD code, a RANS-based flow solver with k-ω SST turbulence model, to validate the MEXICO rotor measurements and extracted
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