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From Two-Equation Turbulence Models to Minimal Error Resolving Simulation Methods for Complex Turbulent Flows

Stefan Heinz

2022Fluids15 citationsDOIOpen Access PDF

Abstract

Hybrid RANS-LES methods are supposed to provide major contributions to future turbulent flow simulations, in particular for reliable flow predictions under conditions where validation data are unavailable. However, existing hybrid RANS-LES methods suffer from essential problems. A solution to these problems is presented as a generalization of previously introduced continuous eddy simulation (CES) methods. These methods, obtained by relatively minor extensions of standard two-equation turbulence models, represent minimal error simulation methods. An essential observation presented here is that minimal error methods for incompressible flows can be extended to stratified and compressible flows, which opens the way to addressing relevant atmospheric science problems (mesoscale to microscale coupling) and aerospace problems (supersonic or hypersonic flow predictions). It is also reported that minimal error methods can provide valuable contributions to the design of consistent turbulence models under conditions of significant modeling uncertainties.

Topics & Concepts

Reynolds-averaged Navier–Stokes equationsTurbulenceTurbulence modelingMesoscale meteorologyDetached eddy simulationLarge eddy simulationMicroscale chemistryK-epsilon turbulence modelApplied mathematicsAerodynamicsComputer scienceCompressible flowHypersonic speedFlow (mathematics)Computational fluid dynamicsSupersonic speedStatistical physicsCompressibilityMechanicsPhysicsMeteorologyMathematicsMathematics educationMeteorological Phenomena and SimulationsWind and Air Flow StudiesFluid Dynamics and Turbulent Flows
From Two-Equation Turbulence Models to Minimal Error Resolving Simulation Methods for Complex Turbulent Flows | Litcius