A class of Cartesian grid embedded boundary algorithms for incompressible flow with time-varying complex geometries

We present a class of numerical algorithms for simulating viscous fluid problems of incompressible flow interacting with moving rigid structures. The proposed Cartesian grid embedded boundary algorithms employ a slightly different idea from the traditional direct-forcing immersed boundary methods: t...

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Vydáno v:Physica. D Ročník 240; číslo 20; s. 1583 - 1592
Hlavní autoři: Lee, Long, Vankova, Irena
Médium: Journal Article
Jazyk:angličtina
Vydáno: Elsevier B.V 01.10.2011
Témata:
Cartesian grid
Direct forcing
Immersed boundary method
Incompressible Navier–Stokes equations
MAC scheme
Moving rigid structures
MAC scheme
Moving rigid structures
Incompressible Navier–Stokes equations
Cartesian grid
Immersed boundary method
Direct forcing
ISSN:0167-2789, 1872-8022
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Shrnutí:We present a class of numerical algorithms for simulating viscous fluid problems of incompressible flow interacting with moving rigid structures. The proposed Cartesian grid embedded boundary algorithms employ a slightly different idea from the traditional direct-forcing immersed boundary methods: the proposed algorithms calculate and apply the force density in the extended solid domain to uphold the solid velocity and hence the boundary condition at the rigid-body surface. The principle of the embedded boundary algorithm allows us to solve the fluid equations on a Cartesian grid with a set of external forces spread onto the grid points occupied by the rigid structure. The proposed algorithms use the MAC (marker and cell) algorithm to solve the incompressible Navier–Stokes equations. Unlike projection methods, the MAC scheme incorporates the gradient of the force density in solving the pressure Poisson equation, so that the dipole force, due to the jump of pressure across the solid–fluid interface, is directly balanced by the gradient of the force density. We validate the proposed algorithms via the classical benchmark problem of flow past a cylinder. Our numerical experiments show that numerical solutions of the velocity field obtained by using the proposed algorithms are smooth across the solid–fluid interface. Finally, we consider the problem of a cylinder moving between two parallel plane walls. Numerical solutions of this problem obtained by using the proposed algorithms are compared with the classical asymptotic solutions. We show that the two solutions are in good agreement. ► We propose a class of numerical algorithms for simulating solid–fluid interaction. ► The algorithms incorporate the gradient of the force density in the pressure equation. ► The algorithms improve the direct-forcing immersed boundary methods. ► The algorithms are robust for moving structures with complex geometries.
ISSN:0167-2789
1872-8022
DOI:10.1016/j.physd.2011.06.013