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First Thermal and Fluids Engineering Summer Conference

ISSN: 2379-1748
ISBN: 978-1-56700-430-4

Investigation of Dynamic Hybrid RANS-LES Modeling for Compressible Turbulent Flows

DOI: 10.1615/TFESC1.asp.013011
pages 165-186

D. Keith Walters
Mississippi State University, Starkville, MS 39759, USA

Parthiv Shah
ATA Engineering, Inc., San Diego, CA 92128, USA

Derek Berg
ATA Engineering, Inc., San Diego, CA 92128, USA

Edward A. Luke
Mississippi State University, Starkville, MS 39759, USA


KEY WORDS: turbulence, compressible flow, mixing layer, large eddy simulation

Abstract

Interior and exterior flowfields of hot, supersonic aircraft engine nozzles display complex flow features including attached turbulent boundary layers and separated turbulent shear layers. Effective design requires accurate prediction of these features using advanced computational fluid dynamics techniques. This paper presents results for two relevant validation test problems for high-speed nozzle analysis. The simulations used a novel dynamic hybrid RANS/LES (DHRL) modeling framework coupled to an advanced low-dissipation numerical scheme within the Loci-CHEM finite-volume flow solver. Results are presented for unsteady flow simulations of free-shear and wall-bounded flows on structured and unstructured grid topologies. Three modeling approaches are investigated: implicit LES, conventional hybrid RANS/LES in which turbulence model terms are functions of local mesh size, and a dynamic hybrid RANS-LES (DHRL) scheme that smoothly blends the boundary between RANS and LES regions of the flow field. The simulations also compared two numerical reconstruction schemes used within a Roe flux method: a traditional least-squares gradient method with standard limiting and a new optimization-based gradient reconstruction (OGRE) low-dissipation method. Results from computations using the DHRL framework with the OGRE scheme showed good agreement, particularly when compared to the traditional methods, to experimental mean streamwise velocity profiles as well as experimental fluctuating RMS velocities.

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