Vortex Flows and Related Numerical Methods II
ESAIM: Proceedings,
Vol. 1, 1996, pp. 65-76
Hybrid Vortex/Magnet Methods
for Flow Over a Solid Boundary
David M. Summers
Mathematics Department
Napier University
219 Colinton Road
Edinburgh, EH14 1DJ, Scotland
Alexandre J. Chorin
Department of Mathematics
University of California
Berkeley, CA94720, USA
Abstract
Boundary conditions, in particular no-slip boundary conditions, are usually
imposed in vortex methods through the creation of vorticity. In three
dimensions, this is typically done by creating vortex "blobs" or
"segments". However, with these computational elements, one compromises
accuracy by losing the divergence-free nature of the vorticity field.
Furthermore, these methods preclude the use of hairpin removal strategies
for simplifying the calculation. We explore remedies for this problem
through the use of discrete elements of fluid impulse (also known as
"magnets"). In particular, two strategies for evolving impulse from a
boundary, consistent with the no-slip condition, are proposed; they
correspond to two choices of gauge. Sheet-like elements are created at
walls to carry this impulse; as these elements diffuse away from the wall
into the flow interior they are transformed into vortex loops of equal
impulse. In this way hybrid vortex algorithms are determined for
three-dimensional incompressible bounded flow. These ideas are illustrated
by numerical experiment with high Reynolds number flow past a sphere.
Vortex Flows and Related
Numerical Methods II
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