High resolution methods for computing turbulent flows

William J. Rider; Dimitris Drikakis

High resolution methods for computing turbulent flows

William J. Rider, Dimitris Drikakis

Faculty Of Engineering

Research output: Chapter in Book/Report/Conference proceeding › Chapter

2 Citations (Scopus)

Abstract

Over the past decade there has been an increasing amount of evidence that high resolution numerical methods for hyperbolic partial differential equations have an embedded (or "implicit") turbulence model. The present chapter describes this general class of methods and outlines the basic structure of high resolution methods as an effective turbulence model in the context of large eddy simulation (LES). This discussion is an extension of the MILES concept introduced by Boris, where monotone numerical algorithms are used for LES (MILES is an acronym for monotone integrated LES). We show that the implicit modeling includes elements of nonlinear eddy viscosity, scale-similarity and an effective dynamic model. In addition, we give examples of both success and failures with currently available methods and examine the effects of the embedded modeling in contrast to widely used subgrid scale (SGS) models

Original language	English
Title of host publication	Turbulent Flow Computation
Publisher	Springer Netherlands
Pages	43-74
Number of pages	32
Volume	66
ISBN (Print)	978-1-4020-0523-7
Publication status	Published - 2004

Publication series

Name	Fluid Mechanics and Its Applications
Publisher	Springer Netherlands
Volume	66
ISSN (Print)	0926-5112

Keywords

compressible flows
high resolution methods
incompressible flows
large eddy simulation
MILES
subgrid models
turbulence

Cite this

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abstract = "Over the past decade there has been an increasing amount of evidence that high resolution numerical methods for hyperbolic partial differential equations have an embedded (or {"}implicit{"}) turbulence model. The present chapter describes this general class of methods and outlines the basic structure of high resolution methods as an effective turbulence model in the context of large eddy simulation (LES). This discussion is an extension of the MILES concept introduced by Boris, where monotone numerical algorithms are used for LES (MILES is an acronym for monotone integrated LES). We show that the implicit modeling includes elements of nonlinear eddy viscosity, scale-similarity and an effective dynamic model. In addition, we give examples of both success and failures with currently available methods and examine the effects of the embedded modeling in contrast to widely used subgrid scale (SGS) models",

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TY - CHAP

T1 - High resolution methods for computing turbulent flows

AU - Rider, William J.

AU - Drikakis, Dimitris

PY - 2004

Y1 - 2004

N2 - Over the past decade there has been an increasing amount of evidence that high resolution numerical methods for hyperbolic partial differential equations have an embedded (or "implicit") turbulence model. The present chapter describes this general class of methods and outlines the basic structure of high resolution methods as an effective turbulence model in the context of large eddy simulation (LES). This discussion is an extension of the MILES concept introduced by Boris, where monotone numerical algorithms are used for LES (MILES is an acronym for monotone integrated LES). We show that the implicit modeling includes elements of nonlinear eddy viscosity, scale-similarity and an effective dynamic model. In addition, we give examples of both success and failures with currently available methods and examine the effects of the embedded modeling in contrast to widely used subgrid scale (SGS) models

AB - Over the past decade there has been an increasing amount of evidence that high resolution numerical methods for hyperbolic partial differential equations have an embedded (or "implicit") turbulence model. The present chapter describes this general class of methods and outlines the basic structure of high resolution methods as an effective turbulence model in the context of large eddy simulation (LES). This discussion is an extension of the MILES concept introduced by Boris, where monotone numerical algorithms are used for LES (MILES is an acronym for monotone integrated LES). We show that the implicit modeling includes elements of nonlinear eddy viscosity, scale-similarity and an effective dynamic model. In addition, we give examples of both success and failures with currently available methods and examine the effects of the embedded modeling in contrast to widely used subgrid scale (SGS) models

KW - compressible flows

KW - high resolution methods

KW - incompressible flows

KW - large eddy simulation

KW - MILES

KW - subgrid models

KW - turbulence

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M3 - Chapter

SN - 978-1-4020-0523-7

VL - 66

T3 - Fluid Mechanics and Its Applications

SP - 43

EP - 74

BT - Turbulent Flow Computation

PB - Springer Netherlands

ER -

High resolution methods for computing turbulent flows

Abstract

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Keywords

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