200 research outputs found
Numerical Simulations of Bouncing Jets
Bouncing jets are fascinating phenomenons occurring under certain conditions
when a jet impinges on a free surface. This effect is observed when the fluid
is Newtonian and the jet falls in a bath undergoing a solid motion. It occurs
also for non-Newtonian fluids when the jets falls in a vessel at rest
containing the same fluid.
We investigate numerically the impact of the experimental setting and the
rheological properties of the fluid on the onset of the bouncing phenomenon.
Our investigations show that the occurrence of a thin lubricating layer of air
separating the jet and the rest of the liquid is a key factor for the bouncing
of the jet to happen.
The numerical technique that is used consists of a projection method for the
Navier-Stokes system coupled with a level set formulation for the
representation of the interface. The space approximation is done with adaptive
finite elements. Adaptive refinement is shown to be very important to capture
the thin layer of air that is responsible for the bouncing
Adaptive Finite Element Methods for Elliptic Problems with Discontinuous Coefficients
Elliptic partial differential equations (PDEs) with discontinuous diffusion
coefficients occur in application domains such as diffusions through porous
media, electro-magnetic field propagation on heterogeneous media, and diffusion
processes on rough surfaces. The standard approach to numerically treating such
problems using finite element methods is to assume that the discontinuities lie
on the boundaries of the cells in the initial triangulation. However, this does
not match applications where discontinuities occur on curves, surfaces, or
manifolds, and could even be unknown beforehand. One of the obstacles to
treating such discontinuity problems is that the usual perturbation theory for
elliptic PDEs assumes bounds for the distortion of the coefficients in the
norm and this in turn requires that the discontinuities are matched
exactly when the coefficients are approximated. We present a new approach based
on distortion of the coefficients in an norm with which
therefore does not require the exact matching of the discontinuities. We then
use this new distortion theory to formulate new adaptive finite element methods
(AFEMs) for such discontinuity problems. We show that such AFEMs are optimal in
the sense of distortion versus number of computations, and report insightful
numerical results supporting our analysis.Comment: 24 page
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