Efficient and non-reflecting far-field boundary conditions for incompressible flow calculations

Traditionally, the artificial compressibility (AC) method of Chorin is used for simulation of low-speed and incompressible flows. In this method, the difficulty of continuity and momentum equations decoupling is removed by adding an artificial time derivative of pressure to the continuity equation....

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Bibliographic Details
Published in:Applied mathematics and computation 2014-03, Vol.230, p.248-258
Main Authors: Hashemi, M.Y., Zamzamian, Kamiar
Format: Article
Language:English
Subjects:
Artificial compressibility
Boundaries
Boundary conditions
Characteristics method
Computation
Computational fluid dynamics
Decoupling
Far-field boundary conditions
Fluid flow
Incompressible flow
Mathematical analysis
Navier–Stokes equations
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Summary:Traditionally, the artificial compressibility (AC) method of Chorin is used for simulation of low-speed and incompressible flows. In this method, the difficulty of continuity and momentum equations decoupling is removed by adding an artificial time derivative of pressure to the continuity equation. For the first time, a fully two-dimensional upwind scheme was presented for AC equations by using characteristic structure of equations by the authors. In this paper, a new remote boundary calculation method is presented by using the idea of characteristics for these equations. Instead of simple boundary conditions which usually are employed for incompressible flows, the flow quantities at the far-field boundaries are evaluated by compatibility relations of characteristic equations. This is implemented by assuming a row of ghost cells outside of the far-field boundary and using the flux calculation method based on characteristics similar to the inside of computational domain. The idea in conjunction with multidimensional characteristic based scheme was tested for incompressible flow around circular cylinder in comparison with conventional far-field boundary condition and showed good improvements in the terms of accuracy and convergence speed.
ISSN:0096-3003
1873-5649
DOI:10.1016/j.amc.2013.12.089