Direct Numerical Simulation of Transition and Turbulence in a Spatially Evolving Boundary Layer

A high-order-accurate finite-difference approach to direct simulations of transition and turbulence in compressible flows is described. The technique involves using a zonal grid system, upwind-biased differences for the convective terms, central differences for the viscous terms, and an iterative-im...

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Bibliographic Details
Published inJournal of computational physics Vol. 109; no. 2; pp. 169 - 192
Main Authors Rai, Man Mohan, Moin, Parviz
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier Inc 01.12.1993
Elsevier
Subjects
990200 > Mathematics & Computers
BOUNDARY LAYERS
CALCULATION METHODS
Classical and quantum physics: mechanics and fields
Classical mechanics of continuous media: general mathematical aspects
COMPRESSIBLE FLOW
Computational methods in fluid dynamics
COMPUTERIZED SIMULATION
ENGINEERING
Exact sciences and technology
FINITE DIFFERENCE METHOD
FLUID FLOW
Fluid mechanics: general mathematical aspects
GENERAL AND MISCELLANEOUS//MATHEMATICS, COMPUTING, AND INFORMATION SCIENCE
ITERATIVE METHODS
LAYERS
Mathematical methods in physics
Numerical approximation and analysis
Numerical simulation, solution of equations
NUMERICAL SOLUTION
Physics
SIMULATION 420400 > Engineering > Heat Transfer & Fluid Flow
TURBULENT FLOW
Transition
Boundary conditions
Numerical simulation
Turbulence
Numerical method
Boundary layers
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Summary:A high-order-accurate finite-difference approach to direct simulations of transition and turbulence in compressible flows is described. The technique involves using a zonal grid system, upwind-biased differences for the convective terms, central differences for the viscous terms, and an iterative-implicit time-integration scheme. The integration method is used to compute transition and turbulence on a flat plate. The main objective is to determine the computability of such a flow with currently available computer speeds and storage and to address some of the algorithmic issues such as accuracy, inlet and exit boundary conditions, and grid-point requirements. A novel feature of the present study is the presence of high levels of broad band freestream fluctuations. The computed data are in qualitative agreement with experimental data (from experiments on which the computation is modeled). The computational results indicate that the essential features of the transition process have been captured. Additionally, the finite-difference method presented in this study can, in a straightforward manner, be used for complex geometries.
Bibliography:None
ISSN:0021-9991
1090-2716
DOI:10.1006/jcph.1993.1210