Migration of particles undergoing pressure-driven flow in a circular conduit

Hampton, Rachel; Mammoli, Andrea; Graham, Alan L.; Tetlow, Nicholas; Altobelli, Stephen A.

doi:10.1122/1.550863

Cited by 220 publications

(188 citation statements)

References 0 publications

Supporting

Mentioning

169

Contrasting

Order By: Relevance

“…To be complete, we used a different method than the method introduced by Hampton and coworkers [24] because high correlations between the different parameters were obtained when using their method. Figure A5.…”

Section: Appendix C Characterization Of Recovery Lengthmentioning

confidence: 99%

Modelling Shear Induced Diffusion Based Particle Segregation: A Basis for Novel Separation Technology

Drijer

Schroën

2018

Applied Sciences

View full text Add to dashboard Cite

Shear induced diffusion (SID) based flow segregation is a technique that can be used for concentration and fractionation purposes, and it has the potential to become an economical and sustainable alternative for e.g., membrane separation. When compared to conventional microfiltration, problems related to fouling and cleaning are expected to be minimal. To make the best use of the opportunities that this technique holds, detailed insights in flow and particle behavior are needed. Modelling this process allows for us to chart particle segregation in flow, as well as the effect of suspension removal through a pore and the restoration of the flow profile after the pore. As a starting point, we take the computation fluid dynamics (CFD) model that is presented in a previous study. A difference in channel height to particle diameter ratio influences the entrance length of the SID profile as well as its fully developed profile. When extracting liquid through one pore, particles are systematically transmitted at a lower concentration (59-78%) than is present in the bulk. The recovery lengths of the SID profile after the pore were short, and thus pores can be placed at realistic distances, which forms a good foundation for further design of this novel separation technology that will ultimately be applied for fractionation of particles taking relatively small differences in diffusive behavior as a starting point.

show abstract

Section: Appendix C Characterization Of Recovery Lengthmentioning

confidence: 99%

Modelling Shear Induced Diffusion Based Particle Segregation: A Basis for Novel Separation Technology

Drijer

Schroën

2018

Applied Sciences

View full text Add to dashboard Cite

show abstract

“…In conditions of very low Reynolds number and high concentration, particles migrate towards the center of the pipe and blunt the velocity profile, see for instance [10]. This effect which would tend to reduce the effective viscosity in the pipe is suspected to be present for the 780 µm particles in pipe D 1 for φ ≥ 0.25 (see in figure 3).…”

mentioning

confidence: 99%

Transition to Turbulence in Particulate Pipe Flow

2003

View full text Add to dashboard Cite

We investigate experimentally the influence of suspended particles on the transition to turbulence. The particles are monodisperse and neutrally-buoyant with the liquid. The role of the particles on the transition depends both upon the pipe to particle diameter ratios and the concentration. For large pipe-to-particle diameter ratios the transition is delayed while it is lowered for small ratios. A scaling is proposed to collapse the departure from the critical Reynolds number for pure fluid as a function of concentration into a single master curve.PACS numbers: 83.80.Hj, 83.50.Ha More than a century after Reynolds' work [1], understanding how turbulent regions grow in a pipe and bring the laminar Poiseuille flow to fully developed turbulence is still not completely achieved. Above a critical Reynolds number, the laminar flow is observed to be unstable, turbulent regions grow and are convected in the pipe. This flow regime is called intermittent. When the flow rate is further increased, the flow becomes fully turbulent [2]. In fact, the transition happens to be subcritical and the flow is linearly stable for all flow rates [3]. A finite amplitude perturbation is needed to trigger the transition and the critical Reynolds depends upon its amplitude. For small perturbations, laminar motion is observed as far as Re ≈ 10 5 but the transition in pure fluid can be reached for Re ≈ 2100 provided that the perturbation is strong enough to allow the growth of turbulent "puffs" [2]. Recent studies have investigated with different kinds of perturbations the nature of the unstable modes, either in the inlet region or in the fully developed flow [4,5].The objective of the present work is to examine how transition to turbulence is affected by the presence of suspended particles in the simplest case of neutral buoyancy. More specifically, we focus upon determining the transition threshold between the laminar and the intermittent regime as a function of the particle volume fraction φ of the suspension. Because the particles are neutrally buoyant and largely drag-free, the present study is related to recent work which has examined global subcritical stability behavior of plane Couette flow forced by the presence of a single spherical bead or a spanwise wire [6,7]. This work also has a practical aspect as it is related to pipeline flow of slurries.Experiments are performed with four sets of spherical polystyrene particles having density ρ = 1.0510 ± 0.001 g.cm −3 and diameters d presented in table I. To obtain neutral buoyancy, the densities of the fluid and of the particles are matched. We choose as a fluid a mixture of 22 % glycerol and 78 % water by mass. The temperature of the mixture is maintained at 25 ± 1 • C by using a thermostated bath as a fluid reservoir in the fluid circulating loop. At this temperature, the viscosity of the mixture is µ = 1.64 ± 0.03 cP. The experimental set-up consists of a straight and horizontal cylindrical glass tube of 2.6 m length mounted on a rigid support structure. Two different tubes havi...

show abstract

“…Over all ranges of the shear-rate and all volume forces applied, we find for the ratio of the characteristic time scales ν app ∕ D ≫ 1, and therefore t equil;diff ≫ t equil;flow . This is also known from experiments [72].…”

Section: Profile Development Dynamicsmentioning

confidence: 97%

“…The channel has a width of L M;y ¼ 50 mm. From experimental studies [72], we can expect that with a resolution of approximately 40 lattice points, the characteristics of profiles of u and ϕ can be resolved in sufficient detail. We therefore chose Δx M ¼ 1.25 mm.…”

Section: Fig 21mentioning

confidence: 99%