Wall accumulation and spatial localization in particle-laden wall flows

Sardina, Gaetano; Schlatter, Philipp; Brandt, Luca; Picano, Francesco; Casciola, Carlo Massimo

doi:10.1017/jfm.2012.65

Cited by 145 publications

(187 citation statements)

References 41 publications

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“…Particles with Stokes numbers St + = 10 and St + = 50 share the same wall and centerline concentration. These results are in agreement with previous DNS results at the same friction Reynolds number in the flat case and similar values of the Stokes number [3]. In the right panel of Fig.…”

Section: Resultssupporting

confidence: 93%

Particle-Laden Turbulent Channel Flow with Wall-Roughness

Milici

Marchis

Sardina

et al. 2015

Direct and Large-Eddy Simulation IX

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Section: Resultssupporting

confidence: 93%

Particle-Laden Turbulent Channel Flow with Wall-Roughness

Milici

Marchis

Sardina

et al. 2015

Direct and Large-Eddy Simulation IX

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“…Similar to the carrier phase, cyclic boundary conditions are used for the dispersed phase in the axial direction. This Lagrangian particle tracking module is verified and validated for a classical particleladen turbulent channel flow against Sardina et al [22]. The implementation, validation and verification of the particle tracking module are reported by Noorani [15].…”

Section: Governing Equations and Numerical Methodsmentioning

confidence: 96%

Particle Velocity and Acceleration in Turbulent Bent Pipe Flows

Noorani

Sardina

Brandt

et al. 2015

Flow Turbulence Combust

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We study the dynamics of dilute micro-size inertial particles in turbulent curved pipe flows of different curvature by means of direct numerical simulations with one-way coupled Lagrangian particle tracking. The focus of this work is on the first and second order moments of the velocity and acceleration of the particulate phase, relevant statistics for any modelling effort, whereas the particle distribution is analysed in a previous companion paper. The aim is to understand the role of the cross-stream secondary motions (Dean vortices) on the particle dynamics. We identify the mean Dean vortices associated to the motion of the particles and show that these are moved towards the side-walls and, interestingly, more intense than those of the mean flow. Analysis of the streamwise particle flux reveals a substantial increase due to the secondary motions that brings particles towards the pipe core while moving them towards the outer bend. The in-plane particle flux, most intense in the flow viscous sub-layer along the side walls, increases with particle inertia and pipe curvature. The particle reflections at the outer bend, previously observed also in other strongly curved configurations, locally alter the particle axial and wall-normal velocity and increase turbulent kinetic energy.

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“…Particles whose density differs from the suspending medium exhibit more complex behaviour (e.g. they can accumulate at walls in turbulent channel flows; see [9,10]). …”

Section: Introductionmentioning

confidence: 99%

Dispersion of swimming algae in laminar and turbulent channel flows: consequences for photobioreactors

Croze

Sardina

Musse

et al. 2013

J. R. Soc. Interface.

100

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Shear flow significantly affects the transport of swimming algae in suspension. For example, viscous and gravitational torques bias bottom-heavy cells to swim towards regions of downwelling fluid (gyrotaxis). It is necessary to understand how such biases affect algal dispersion in natural and industrial flows, especially in view of growing interest in algal photobioreactors. Motivated by this, we here study the dispersion of gyrotactic algae in laminar and turbulent channel flows using direct numerical simulation (DNS) and a previously published analytical swimming dispersion theory. Time-resolved dispersion measures are evaluated as functions of the Péclet and Reynolds numbers in upwelling and downwelling flows. For laminar flows, DNS results are compared with theory using competing descriptions of biased swimming cells in shear flow. Excellent agreement is found for predictions that employ generalized Taylor dispersion. The results highlight peculiarities of gyrotactic swimmer dispersion relative to passive tracers. In laminar downwelling flow the cell distribution drifts in excess of the mean flow, increasing in magnitude with Péclet number. The cell effective axial diffusivity increases and decreases with Péclet number (for tracers it merely increases). In turbulent flows, gyrotactic effects are weaker, but discernable and manifested as non-zero drift. These results should have a significant impact on photobioreactor design.

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Wall accumulation and spatial localization in particle-laden wall flows

Cited by 145 publications

References 41 publications

Particle-Laden Turbulent Channel Flow with Wall-Roughness

Particle-Laden Turbulent Channel Flow with Wall-Roughness

Particle Velocity and Acceleration in Turbulent Bent Pipe Flows

Dispersion of swimming algae in laminar and turbulent channel flows: consequences for photobioreactors

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