Finite Volume Solutions of Convection-Diffusion Test Problems

Finite Volume Solutions of Convection-Diffusion Test Problems

The cell-vertex formulation of the finite volume method has been developed and widely used to model inviscid flows in aerodynamics: more recently, one of us has proposed an extension for viscous flows. The purpose of the present paper is two-fold: first we have applied this scheme to a well-known co...

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Veröffentlicht in:Mathematics of computation 1993-01, Vol.60 (201), p.189-220
Hauptverfasser: Mackenzie, J. A., Morton, K. W.
Format: Artikel
Sprache:eng
Schlagworte:
AERODYNAMICS
Approximation
BOUNDARY CONDITIONS
Boundary layers
CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS
CONVECTION
CONVERGENCE
DIFFUSION
ENERGY TRANSFER
Error bounds
Exact sciences and technology
Finite volume method
Fluid dynamics
FLUID FLOW
FLUID MECHANICS
Fundamental areas of phenomenology (including applications)
General theory
HEAT TRANSFER
MASS TRANSFER
MATHEMATICAL MODELS
Maximum principle
MECHANICS 661300 > Other Aspects of Physical Science-- (1992-)
ONE-DIMENSIONAL CALCULATIONS
Peclet number
Physics
Truncation errors
Vertices
VISCOUS FLOW
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Beschreibung
Zusammenfassung:The cell-vertex formulation of the finite volume method has been developed and widely used to model inviscid flows in aerodynamics: more recently, one of us has proposed an extension for viscous flows. The purpose of the present paper is two-fold: first we have applied this scheme to a well-known convection-diffusion model problem, involving flow around a 180⚬ bend, which highlights some of the issues concerning the application of the boundary conditions in such cell-based schemes. The results are remarkably good when the boundary conditions are applied in an appropriate manner. In our efforts to explain the high quality of the results we were led to a detailed analysis of the corresponding one-dimensional problem. Our second purpose is thus to gather together various approaches to the analysis of this problem and to draw attention to the supra-convergence phenomena enjoyed by the proposed methods.
ISSN:0025-5718
1088-6842
DOI:10.1090/S0025-5718-1993-1153168-0