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Bibliographic Details
Main Authors: Balakumar, P., Iyer, Prahladh S.
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2602.11377
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author Balakumar, P.
Iyer, Prahladh S.
author_facet Balakumar, P.
Iyer, Prahladh S.
contents Wall-modeled large-eddy simulation (WMLES) is performed for flow over a wing with a focus on documenting grid resolution requirements to predict both the laminar and turbulent regions accurately. Flow over a spanwise extruded NACA0012 airfoil at 0-degree angle of attack and freestream chord-based Reynolds numbers of 3 million is simulated using an unstructured-grid finite-volume solver. An equilibrium wall function with the first off-wall grid point as the exchange location is used. Two scenarios are simulated wherein either the entire airfoil surface, or only a portion of it, is assumed turbulent based on linear stability calculations. For the latter scenario, the regular no-slip wall boundary condition is imposed in laminar regions. Using the same grid that was employed in the fully turbulent case, WMLES captured the skin friction in the turbulent region close to the RANS results. However, the skin friction is not well captured in the laminar region, due to far few grid points inside the boundary layer. When the near-wall grid was refined in the wall normal direction, the laminar region was captured accurately, but the turbulent region was not resolved well because the first off-wall point moved below the buffer-layer. To reconcile differing resolution requirements in the laminar and turbulent regions, a grid was generated based on the varying boundary layer thickness estimated from a precursor RANS simulation with a specified transition location. This grid produced improved results in the laminar region but resulted in a delayed transition location. Unsteady disturbances with the most amplified frequencies were introduced upstream of the neutral point. The transition process in the laminar region and the skin friction in the turbulent region were then captured satisfactorily.
format Preprint
id arxiv_https___arxiv_org_abs_2602_11377
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle On Capturing Laminar/Turbulent Regions Over a Wing Using WMLES
Balakumar, P.
Iyer, Prahladh S.
Fluid Dynamics
Computational Physics
Wall-modeled large-eddy simulation (WMLES) is performed for flow over a wing with a focus on documenting grid resolution requirements to predict both the laminar and turbulent regions accurately. Flow over a spanwise extruded NACA0012 airfoil at 0-degree angle of attack and freestream chord-based Reynolds numbers of 3 million is simulated using an unstructured-grid finite-volume solver. An equilibrium wall function with the first off-wall grid point as the exchange location is used. Two scenarios are simulated wherein either the entire airfoil surface, or only a portion of it, is assumed turbulent based on linear stability calculations. For the latter scenario, the regular no-slip wall boundary condition is imposed in laminar regions. Using the same grid that was employed in the fully turbulent case, WMLES captured the skin friction in the turbulent region close to the RANS results. However, the skin friction is not well captured in the laminar region, due to far few grid points inside the boundary layer. When the near-wall grid was refined in the wall normal direction, the laminar region was captured accurately, but the turbulent region was not resolved well because the first off-wall point moved below the buffer-layer. To reconcile differing resolution requirements in the laminar and turbulent regions, a grid was generated based on the varying boundary layer thickness estimated from a precursor RANS simulation with a specified transition location. This grid produced improved results in the laminar region but resulted in a delayed transition location. Unsteady disturbances with the most amplified frequencies were introduced upstream of the neutral point. The transition process in the laminar region and the skin friction in the turbulent region were then captured satisfactorily.
title On Capturing Laminar/Turbulent Regions Over a Wing Using WMLES
topic Fluid Dynamics
Computational Physics
url https://arxiv.org/abs/2602.11377