International audienceThe settling velocity of inertial particles falling in homogeneous turbulence is investigated by making use of Direct Numerical Simulation (DNS) at moderate Reynolds number that include momentum exchange between both phases (two-way coupling approach). Effects of particle volume fraction, particle inertia and gravity are presented for flow and particle parameters similar to the experiments of Aliseda et al. [1]. A good agreement is obtained between the DNS and the experiments for the settling velocity statistics, when overall averaged but as well when conditioned on the local particle concentration. Both DNS and experiments show that the settling velocity further increases with increasing volume fraction and local conc...
We present a numerical study of settling and clustering of small inertial particles in homogeneous a...
International audienceSettling experiments were conducted in a turbulence column to investigate the ...
The Stokes drag force and the gravity force are usually sufficient to describe the behavior of sub-K...
International audienceThe settling velocity of inertial particles falling in homogeneous turbulence ...
International audienceVoronoï diagrams are used to analyze one-way coupling direct numerical simulat...
International audienceDispersed two phase flows are relevant to many fields, as they occur in both n...
International audienceParticle laden flows are of a great interest in many industrial and natural sy...
International audienceWe present an experimental study on the settling velocity of dense sub-Kolmogo...
We investigate the settling speeds and root mean square (r.m.s.) velocities of inertial particles in...
Despite decades of investigations, there is still no consensus on whether inertial particles augment...
The settling of (inertial) particles is studied in homogeneous shear turbulence. A drift velocity pe...
We analyse numerically the motion of small inertial particles, subject to gravity, in two simple vel...
Numerical studies [10, 1] show that the influence of gravity and turbulence on the motion of small a...
We investigate the behaviour of microscopic heavy particles settling in homogeneous air turbulence. ...
We investigate the influence of shear on the gravitational settling of heavy inertial particles in h...
We present a numerical study of settling and clustering of small inertial particles in homogeneous a...
International audienceSettling experiments were conducted in a turbulence column to investigate the ...
The Stokes drag force and the gravity force are usually sufficient to describe the behavior of sub-K...
International audienceThe settling velocity of inertial particles falling in homogeneous turbulence ...
International audienceVoronoï diagrams are used to analyze one-way coupling direct numerical simulat...
International audienceDispersed two phase flows are relevant to many fields, as they occur in both n...
International audienceParticle laden flows are of a great interest in many industrial and natural sy...
International audienceWe present an experimental study on the settling velocity of dense sub-Kolmogo...
We investigate the settling speeds and root mean square (r.m.s.) velocities of inertial particles in...
Despite decades of investigations, there is still no consensus on whether inertial particles augment...
The settling of (inertial) particles is studied in homogeneous shear turbulence. A drift velocity pe...
We analyse numerically the motion of small inertial particles, subject to gravity, in two simple vel...
Numerical studies [10, 1] show that the influence of gravity and turbulence on the motion of small a...
We investigate the behaviour of microscopic heavy particles settling in homogeneous air turbulence. ...
We investigate the influence of shear on the gravitational settling of heavy inertial particles in h...
We present a numerical study of settling and clustering of small inertial particles in homogeneous a...
International audienceSettling experiments were conducted in a turbulence column to investigate the ...
The Stokes drag force and the gravity force are usually sufficient to describe the behavior of sub-K...
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