Event

The Fluid Dynamics Reviews Seminar Series: Dr. George Ilhwan Park

Thursday, May 2, 2024
3:00 p.m.
DeWalt Seminar Room 2164 Glenn L. Martin Hall
Robert Herschbach
301-405-5273
jola@umd.edu

THE BURGERS PROGRAM FOR FLUID DYNAMICS
THE FLUID DYNAMICS REVIEWS SEMINAR SERIES

SPEAKER
DR. GEORGE ILHWAN PARK
Assistant Professor
Mechanical Engineering and Applied Mechanics
University of Pennsylvania

TITLE
Wall-Modeled LES: Nonequilibrium Flows and Convergence

ABSTRACT
Predictive and affordable simulation of wall-bounded turbulent flows remains as a pacing item in CFD, and significant progress has been made over the past decade in near-wall models for large-eddy simulation (LES) to this end. In this talk, I will summarize the research conducted in my group on wall-modeled LES, focusing on the assessment of the state-of-the-art wall models in nonequilibrium flows, and establishing the notion of convergence in inherently under-resolved WMLES calculations.

Application of widely used wall models to two spatially developing three-dimensional turbulent boundary layers (3DTBL), with and without flow separation, reveals that the flow direction near the wall has separable contributions from the equilibrium and nonequilibrium
parts, where the latter controls the accuracy of the near-wall flow direction in wall models. For pressure gradient flows, wall models accounting for more of the near-wall physics tend to perform better in the adverse pressure gradient (APG) region. However, in the favorable
pressure gradient (FPG) region, an opposite trend (discussed rarely) is found with overshoot in the skin friction, which we show resulting from the erroneous response of a dynamic model to FPG. In general, the mean and turbulence quantities away from the wall are predicted
equally well with different wall models. An on-going application of WMLES to a rough-wall boundary layer for simulation of atmospheric surface layer over a New Mexico sand dunes will be discussed, focusing on the internal boundary layer development from a smooth-to-rough
transition. Lastly, numerical experiments that indicate the convergence rate of WMLES is controlled by the extent of the wall-modeled region will be presented, suggesting that one may converge WMLES at the desired grid resolution.

made
over the past decade in near-wall models for large-eddy simulation (LES) to this end. In this talk, I will summarize the research conducted in my group on wall-modeled LES, focusing on the assessment of the state-of-the-art wall models in nonequilibrium flows, and establishing
the notion of convergence in inherently under-resolved WMLES calculations.
Application of widely used wall models to two spatially developing three-dimensional turbulent boundary layers (3DTBL), with and without flow separation, reveals that the flow direction near the wall has separable contributions from the equilibrium and nonequilibrium
parts, where the latter controls the accuracy of the near-wall flow direction in wall models. For pressure gradient flows, wall models accounting for more of the near-wall physics tend to perform better in the adverse pressure gradient (APG) region. However, in the favorable
pressure gradient (FPG) region, an opposite trend (discussed rarely) is found with overshoot in the skin friction, which we show resulting from the erroneous response of a dynamic model to FPG. In general, the mean and turbulence quantities away from the wall are predicted
equally well with different wall models. An on-going application of WMLES to a rough-wall boundary layer for simulation of atmospheric surface layer over a New Mexico sand dunes will be discussed, focusing on the internal boundary layer development from a smooth-to-rough
transition. Lastly, numerical experiments that indicate the convergence rate of WMLES is controlled by the extent of the wall-modeled region will be presented, suggesting that one may converge WMLES at the desired grid resolution.

BIO
George Park is an Assistant Professor of Mechanical Engineering and Applied Mechanics at the University of Pennsylvania. He received his Ph.D. and M.S. in Mechanical Engineering (ME) from Stanford University in 2014 and 2011, respectively, and his B.S. in ME from Seoul National University, South Korea, in 2009. He worked as a postdoctoral fellow and an engineering research associate at the Center for Turbulence Research (Stanford) prior to joining UPenn as a faculty member. His research interests include high-fidelity numerical simulation of complex wall-bounded turbulent flows, computational methods with unstructured grids, non-equilibrium turbulent boundary layers, and fluid-structure interaction.