Four-way coupled simulations of small particles in turbulent channel flow: The effects of particle shape and Stokes number

Zhao, Fuquan; George, William K.; Wachem, Berend G. M. van

doi:10.1063/1.4927277

Cited by 47 publications

(26 citation statements)

References 45 publications

(63 reference statements)

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“…In this section we will only consider spherical particles. Collision algorithms for non-spherical particles have also been developed and studied [ 93 , 122 ]. Zhao et al [ 122 ] considered ellipsoidal particles and used an extension of a collision search algorithm for spherical particles by treating each ellipsoid as a set of overlapping fictitious spheres, whose hull approximately corresponds to the shape of the ellipsoid.…”

Section: Dns With Point-particle Approachmentioning

confidence: 99%

Point-Particle DNS and LES of Particle-Laden Turbulent flow - a state-of-the-art review

Kuerten

2016

Flow Turbulence Combust

151

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Particle-laden or droplet-laden turbulent flows occur in many industrial applications and in natural phenomena. Knowledge about the properties of these flows can help to improve the design of unit operations in industry and to predict for instance the occurrence of rain showers. This knowledge can be obtained from experimental research and from numerical simulations. In this paper a review is given of numerical simulation methods for particle-laden flows. There are various simulation methods possible. They range from methods in which all details, including the flow around each particle, are resolved, via point-particle methods, in which for each particle an equation of motion is solved, to Eulerian methods in which equations for particle concentration and velocity are solved. This review puts the emphasis on the intermediate class of methods, the Euler-Lagrange methods in which the continuous phase is described by an Eulerian approach and the dispersed phase in a Lagrangian way with equations of motion for each individual particle.

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Section: Dns With Point-particle Approachmentioning

confidence: 99%

Point-Particle DNS and LES of Particle-Laden Turbulent flow - a state-of-the-art review

Kuerten

2016

Flow Turbulence Combust

151

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“…Here, the fiber orientation is a result of the competition between alignment by mean velocity gradients and randomization by fluctuating velocity gradients [11]. This can lead to either an alignment parallel to the flow direction [14,15] or at an angle with the wall [16][17][18][19][20][21][22]. However, most of the studies in shear flows have been done by numerical simulations, addressing the simplified case of inertial point-like fibers without gravity.…”

mentioning

confidence: 99%

Statistics of rigid fibers in strongly sheared turbulence

et al. 2019

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Practically all flows are turbulent in nature and contain some kind of irregularly-shaped particles, e.g. dirt, pollen, or life forms such as bacteria or insects. The effect of the particles on such flows and vice-versa are highly non-trivial and are not completely understood, particularly when the particles are finite-sized. Here we report an experimental study of millimetric fibers in a strongly sheared turbulent flow. We find that the fibers show a preferred orientation of −0.38π ± 0.05π (−68 ± 9 • ) with respect to the mean flow direction in high-Reynolds number Taylor-Couette turbulence, for all studied Reynolds numbers, fiber concentrations, and locations. Despite the finite-size of the anisotropic particles, we can explain the preferential alignment by using Jefferey's equation, which provides evidence of the benefit of a simplified point-particle approach. Furthermore, the fiber angular velocity is strongly intermittent, again indicative of point-particle-like behavior in turbulence. Thus large anisotropic particles still can retain signatures of the local flow despite classical spatial and temporal filtering effects.

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“…Modeling is calculated by the in-lab code Multi-Flow [40]. In CFD frame, the calculation domain has same width and length as the experimental fluidized bed (30 mm × 120 mm) but considering the computational efficiency, the height of numerical model is 600 mm.…”

Section: Simulation Conditionsmentioning

confidence: 99%

A Mixing Behavior Study of Biomass Particles and Sands in Fluidized Bed Based on CFD-DEM Simulation

Wang¹,

Zhong²

2019

Energies

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The present paper studied the mixing characteristics of biomass and sands in a fluidized bed. A three dimensional model is calculated on the basis of computational fluid dynamics (CFD) and the discrete element method (DEM), while the lab-scale experiments under similar conditions are conducted. To investigate the mixing behavior of biomass and sands, particle distribution, particles time averaged kinetic motion and the Lacey index are analyzed and the effects of gas velocity and biomass size are discussed. Gas velocity provides the basic motion for particle movement and biomass particles gain a lot more kinetic motion than sands due to their large size. The biomass mixing process in a horizontal direction is more sensitive to gas velocity than in a vertical direction. Biomass size could slightly affect the mixing quality and a well mixing in fluidized bed could be reached if the size of biomass to sands is smaller than 4 times.

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Four-way coupled simulations of small particles in turbulent channel flow: The effects of particle shape and Stokes number

Cited by 47 publications

References 45 publications

Point-Particle DNS and LES of Particle-Laden Turbulent flow - a state-of-the-art review

Point-Particle DNS and LES of Particle-Laden Turbulent flow - a state-of-the-art review

Statistics of rigid fibers in strongly sheared turbulence

A Mixing Behavior Study of Biomass Particles and Sands in Fluidized Bed Based on CFD-DEM Simulation

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