Turbulent Dispersed Multiphase Flow

Balachandar, S.; Eaton, John K.

doi:10.1146/annurev.fluid.010908.165243

Cited by 1,346 publications

(951 citation statements)

References 118 publications

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“…In summary, the current measurements show that the axial evolution of velocity and concentration decay, as well as jet expansion, of the two-phase jet is lower than similar single-phase jets consistent with current knowledge of particle-laden jets (Balachandar & Eaton 2010). This difference between the current two-phase jet and single-phase jets increases with Stokes number, and is more prominent in the concentration distribution when compared to the velocity distribution.…”

Section: Jet Expansionsupporting

confidence: 83%

“…This near-field influence can be deduced to augment the already well-known trend, which is also evident here, in which the rates of spread and streamwise decay of a turbulent jet decrease with an increase in Stokes number (Fan et al 1997;Mostafa et al 1989;Hardalupas et al 1989;Prevost et al 1996). The well-known explanation for this is that inertia of the particles relative to the gas-phase increases with Sk 0 (Balachandar & Eaton 2010). Figure 10 presents the centreline velocity decay of the jet for all three Stokes numbers.…”

Section: Jet Exit Profilessupporting

confidence: 77%

“…In addition, without detailed inflow profiles of velocity and concentration of both the jet and co-flow, none are suitable for detailed model validation. Indeed, the paucity of two-dimensional experimental data in two-phase turbulent flows has been identified as a major impediment to the advancement of computational fluid dynamic (CFD) models (Balachandar & Eaton 2010;Fairweather & Hurn 2008).…”

Section: Introductionmentioning

confidence: 99%

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Influence of Stokes number on the velocity and concentration distributions in particle-laden jets

Lau

Nathan

2014

J. Fluid Mech.

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The first measurement of the influence of Stokes number on the distributions of particle concentration and velocity at the exit of a long pipe are reported, together with the subsequent influence on the downstream evolution of these distributions through a particle-laden jet in co-flow. The data were obtained by simultaneous particle image velocimetry and planar nephelometry using four cameras to provide high resolution through the first 30 jet diameters and also correction for optical attenuation. These data provide much more detailed information than is available from previous measurements. From them, new understanding is obtained of how the Stokes number influences the flow at the jet exit plane and how this influence propagates throughout the jet.

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Section: Jet Expansionsupporting

confidence: 83%

Section: Jet Exit Profilessupporting

confidence: 77%

Section: Introductionmentioning

confidence: 99%

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Influence of Stokes number on the velocity and concentration distributions in particle-laden jets

Lau

Nathan

2014

J. Fluid Mech.

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“…Even if φ v is low, a substantial portion of the total kinetic energy can reside in the particle phase if the particles are denser than the carrier fluid. Such particles are inertial and there is a lag in their response to changes in the surrounding flow that leads not only to a net slip in the velocity between the two phases but also to an inertial bias where the particles tend to accumulate in regions of high strain rate or low vorticity in the flow (Balachandar & Eaton 2010). So even if the particles are initially randomly dispersed they can develop clusters at scales larger than the particle size which in turn can have a dynamic effect back on the turbulence.…”

Section: Introductionmentioning

confidence: 99%

Droplets in turbulence: a new perspective

Maxey

2017

J. Fluid Mech.

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Stirring olive oil and vinegar to make salad dressing creates an emulsion of vinegar droplets in oil. More vigorous stirring gives smaller droplets, while if left to sit the droplets will begin to coalesce and the two fluids will separate. In this vein, Dodd & Ferrante (J. Fluid Mech., vol. 806, 2016, pp. 356-412) present a new analysis of how homogeneous turbulence in a carrier fluid interacts with a suspension of droplets of an immiscible liquid. Based on a set of direct numerical simulations, the authors provide new insights on how turbulence affects the motion of the droplets, their shape and size; then in turn how the droplets alter the flow including effects of interfacial surface energy on the kinetic energy of the flow.

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“…Several studies focused on the alteration of turbulent flows by the momentum two-way coupling between phases of particle-laden flows (Boivin, Simonin & Squires 1998;Elghobashi & Truesdell 1993;Ferrante & Elghobashi 2003;Ahmed & Elghobashi 2000;Druzhinin & Elghobashi 2001Eaton 2009). It was found that depending on the mass loading of the particles, their density and diameter, the turbulent kinetic energy of the fluid can be attenuated or enhanced (Tanaka & Eaton 2008;Balachandar & Eaton 2010). Zonta, Marchioli & Soldati (2008) focused on heat transfer in a particle-laden turbulent channel flow with both mechanical and thermal coupling.…”

Section: Introductionmentioning

confidence: 99%

Turbulent thermal convection driven by heated inertial particles

et al. 2016

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This is an author-deposited version published in: http://oatao.univ-toulouse.fr/ Eprints ID: 18470Open Archive Toulouse Archive Ouverte (OATAO) OATAO is an open access repository that collects the work of Toulouse researchers and makes it freely available over the web where possible. The heating of particles in a dilute suspension, for instance by radiation, chemical reactions or radioactivity, leads to local temperature fluctuations in the fluid due to the non-uniformity of the disperse phase. In the presence of a gravity field, the fluid is set in motion by the resulting buoyancy forces. When the particle density is different than that of the fluid, the fluid motion alters the spatial distribution of the particles and possibly strengthens their concentration inhomogeneities. This in turn causes more intense local heating. Direct numerical simulations in the Boussinesq limit show this feedback loop. Various regimes are identified depending on the particle inertia. For very small particle inertia, the macroscopic behaviour of the system is the result of many thermal plumes that are generated independently of each other. For significant particle inertia, clusters of particles are observed and their dynamics controls the flow. The emergence of very intermittent turbulent fluctuations shows that the flow is influenced by the larger structures (turbulent convection) as well as by the small-scale dynamics that affect particle segregation and thus the flow forcing. Assuming thermal equilibrium between the particles and the fluid (i.e. infinitely fast thermal relaxation of the particle), we investigate the evolution of statistical observables with the change of the main control parameters (namely the particle number density, the particle inertia and the domain size), and propose a scaling argument for these trends. Concerning the energy density in the spectral space, it is observed that the turbulent energy and temperature spectra follow a power law, the exponent of which varies continuously with the Stokes number. Furthermore, the study of the spectra of the temperature and momentum forcing (and thus of the concentration/temperature and velocity/temperature correlations) gives strong support to the proposed feedback loop mechanism. We then discuss the intermittency of the flow, and analyse the effect of relaxing some of the simplifying assumptions, thus assessing the relevance of the original studied configuration. To cite this version:

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Turbulent Dispersed Multiphase Flow

Cited by 1,346 publications

References 118 publications

Influence of Stokes number on the velocity and concentration distributions in particle-laden jets

Influence of Stokes number on the velocity and concentration distributions in particle-laden jets

Droplets in turbulence: a new perspective

Turbulent thermal convection driven by heated inertial particles

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