Anisotropic turbulence modeling of the atmospheric surface layer: Validation of novel model settings and comparison with traditional two-equation models in flows over complex terrain

Anisotropic turbulence modeling of the atmospheric surface layer: Validation of novel model settings and comparison with traditional two-equation models in flows over complex terrain

For atmospheric flows, the limitations of the eddy viscosity assumption are even more critical in cases involving complex terrain and features, where secondary strains are influential. Reynolds Stress Models (RSMs) can account for these effects, but their numerical stiffness and crucially the lack o...

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Bibliographic Details
Published in:Journal of wind engineering and industrial aerodynamics Vol. 247; p. 105696
Main Authors: Dumont, Gabriel B., Petry, Adriane P.
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-04-2024
Subjects:
Atmospheric boundary layer
Boundary conditions
Complex terrain
OpenFoam
Turbulence modeling
OpenFoam
Boundary conditions
Turbulence modeling
Complex terrain
Atmospheric boundary layer
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Summary:For atmospheric flows, the limitations of the eddy viscosity assumption are even more critical in cases involving complex terrain and features, where secondary strains are influential. Reynolds Stress Models (RSMs) can account for these effects, but their numerical stiffness and crucially the lack of established guidelines for modelers regarding the appropriate boundary conditions and model settings, as exist for eddy-viscosity models (EVMs), have led to limited adoption. In order to circumvent the shortcomings of EVMs, the focus has been directed at large eddy simulations (LES), which have greater computational requirements that can be prohibitive. Thus, this work aims to extend the traditional methodology that has been applied to adapt EVMs to atmospheric flows to an RSM that incorporates near-ground effects. This results in suggestions for new model constants and novel boundary conditions, which can easily be adapted according to local atmospheric parameters and employed by modelers. The performance of the proposed RSM is compared with four distinct EVMs through real-life cases representing two distinct complex terrain configurations. The results showed that the RSM indeed outperformed the EVMs, and it was found that only its anisotropic formulation could capture more complex flow features that were observed experimentally. •A common method for CFD wind simulations is extended to a Reynolds stress model.•Novel, site-specific constants and boundary conditions are suggested for the model.•The Reynolds stress model outperforms typical models in complex terrain.•The Reynolds stress model can reproduce complex flows at a low computational cost.
ISSN:0167-6105
1872-8197
DOI:10.1016/j.jweia.2024.105696