Vortices, Complex Flows and Inertial Particles

Hunt, John M.; Delfos, R.; Eames, I.; Perkins, Richard J.

doi:10.1007/s10494-007-9096-0

Cited by 23 publications

(22 citation statements)

References 41 publications

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“…The fate of the suspended droplets is determined by drawing an analogy with multiphase particle-laden clouds as arises in a variety of geophysical systems such as riverine outflows or industrial waste discharges (e.g. Scorer 1978;Socolofsky, Crounse, & Adams 2002;Bush, Thurber, & Blanchette 2003;Hunt et al 2007).…”

Section: Observationsmentioning

confidence: 99%

Violent expiratory events: on coughing and sneezing

2014

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Violent respiratory events such as coughs and sneezes play a key role in transferring respiratory diseases between infectious and susceptible individuals. We present the results of a combined experimental and theoretical investigation of the fluid dynamics of such violent expiratory events. Direct observation of sneezing and coughing events reveals that such flows are multiphase turbulent buoyant clouds with suspended droplets of various sizes. Our observations guide the development of an accompanying theoretical model of pathogen-bearing droplets interacting with a turbulent buoyant momentum puff. We develop in turn discrete and continuous models of droplet fallout from the cloud in order to predict the range of pathogens. According to the discrete fallout model droplets remain suspended in the cloud until their settling speed matches that of the decelerating cloud. A continuous fallout model is developed by adapting models of sedimentation from turbulent fluids. The predictions of our theoretical models are tested against data gathered from a series of analogue experiments in which a particle-laden cloud is ejected into a relatively dense ambient. Our study highlights the importance of the multiphase nature of respiratory clouds, specifically the suspension of the smallest drops by circulation within the cloud, in extending the range of respiratory pathogens.

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Section: Observationsmentioning

confidence: 99%

Violent expiratory events: on coughing and sneezing

2014

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“…The settling velocity V fall is taken uniform and, when needed for comparison with experiments, equal to that of a single particle in the quiescent fluid. Note that the above modelling ignores inertial effects on particle motion, in particular their ejection from the core of vortices and their clustering (Bec et al 2007;Hunt et al 2007). We also limit the discussion to dilute suspensions, i.e.…”

Section: Flow Modelsmentioning

confidence: 99%

Transport relaxation time and length scales in turbulent suspensions

2011

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We show that in a turbulent flow transporting suspended sediment, the unsaturated sediment flux $q(x,t)$ can be described by a first-order relaxation equation. From a mode analysis of the advection-diffusion equation for the particle concentration, the relaxation length and time scales of the dominant mode are shown to be the deposition length $H U/V_{\rm fall}$ and deposition time $H/V_{\rm fall}$, where $H$ is the flow depth, $U$ the mean flow velocity and $V_{\rm fall}$ the sediment settling velocity. This result is expected to be particularly relevant for the case of sediment transport in slowly varying flows, where the flux is never far from saturation. Predictions are shown to be in quantitative agreement with flume experiments, for both net erosion and net deposition situations.Comment: 16 pages, 8 figures, accepted for publication in J. Fluid Mec

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“…Advances in computational capabilities allow in some cases the performance of detailed simulations, but in many practical engineering applications, parts of the flow field are modelled rather than solved. 2 Turbulence and particle submodels are among these models that may be used to calculate the behavior of particulate two-phase systems. In the two-phase flow coupled with engineering models (e.g., k À e turbulence model), the governing equations of fluid phase are generally described in Eulerian form, whereas the equations governing the motion of the particle can be either Eulerian or Lagrangian.…”

Section: Discussionmentioning

confidence: 99%

“…Integral measures (such as impulse, circulation, and kinetic energy) have been used as diagnostic tools to study vortical and turbulent flows. 2 However, in the field of dispersed multiphase flows, integral measures have only been applied in a few instances (see Ref.…”

Section: Introductionmentioning

confidence: 99%

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Fluid velocity fluctuations in a collision of a sphere with a wall

et al. 2011

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A study of thermal counterflow using particle tracking velocimetry Phys. Fluids 23, 107102 (2011) Particle accumulation on periodic orbits by repeated free surface collisions Phys. Fluids 23, 072106 (2011) We report on the results of a combined experimental and numerical study on the fluid motion generated by the controlled approach and arrest of a solid sphere moving towards a solid wall at moderate Reynolds number. The experiments are performed in a small tank filled with water for a range of Reynolds numbers for which the flow remains axisymmetric. The fluid agitation of the fluid related to the kinetic energy is obtained as function of time in the experiment in a volume located around the impact point. The same quantities are obtained from the numerical simulations for the same volume of integration as in the experiments and also for the entire volume of the container. As shown in previous studies, this flow is characterized by a vortex ring, initially in the wake of the sphere, that spreads radially along the wall, generating secondary vorticity of opposite sign at the sphere surface and wall. It is also observed that before the impact, the kinetic energy increases sharply for a small period of time and then decreases gradually as the fluid motion dies out. The measure of the relative agitation of the collision is found to increase weakly with the Reynolds number Re. The close agreement between the numerics and experiments is indicative of the robustness of the results. These results may be useful in light of a potential modelling of particle-laden flows. Movies illustrating the spatio-temporal dynamics are provided with the online version of this paper.

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Vortices, Complex Flows and Inertial Particles

Cited by 23 publications

References 41 publications

Violent expiratory events: on coughing and sneezing

Violent expiratory events: on coughing and sneezing

Transport relaxation time and length scales in turbulent suspensions

Fluid velocity fluctuations in a collision of a sphere with a wall

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