Drag and lift forces on a rotating sphere in a linear shear flow

Kurose, Ryoichi; Komori, Satoru

doi:10.1017/s0022112099004164

Cited by 298 publications

(213 citation statements)

References 21 publications

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“…In these simulations the details of the flow around individual particles were not resolved, and simulations were performed in "one-way" coupling mode, i.e., particles were passive tracers and did not influence fluid flow. The force models used include fluid-particle drag (43), lift (44), as well as forces due to the local pressure gradient and viscous stresses.…”

Section: Methodsmentioning

confidence: 99%

Unexpected trapping of particles at a T junction

Vigolo

Radl

Stone

2014

Proc. Natl. Acad. Sci. U.S.A.

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A common element in physiological flow networks, as well as most domestic and industrial piping systems, is a T junction that splits the flow into two nearly symmetric streams. It is reasonable to assume that any particles suspended in a fluid that enters the bifurcation will leave it with the fluid. Here we report experimental evidence and a theoretical description of a trapping mechanism for low-density particles in steady and pulsatile flows through Tshaped junctions. This mechanism induces accumulation of particles, which can form stable chains, or give rise to significant growth of bubbles due to coalescence. In particular, low-density material dispersed in the continuous phase fluid interacts with a vortical flow that develops at the T junction. As a result suspended particles can enter the vortices and, for a wide range of common flow conditions, the particles do not leave the bifurcation. Via 3D numerical simulations and a model of the two-phase flow we predict the location of particle accumulation, which is in excellent agreement with experimental data. We identify experimentally, as well as confirm by numerical simulations and a simple force balance, that there is a wide parameter space in which this phenomenon occurs. The trapping effect is expected to be important for the design of particle separation and fractionation devices, as well as used for better understanding of system failures in piping networks relevant to industry and physiology.fluid dynamics | bubble trapping | vortex breakdown | 3D simulations

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Section: Methodsmentioning

confidence: 99%

Unexpected trapping of particles at a T junction

Vigolo

Radl

Stone

2014

Proc. Natl. Acad. Sci. U.S.A.

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“…29 Thus, the magnitude of the shear-gradient induced lift force scales as F s / a 2 . [29][30][31][32] Assuming that F s is balanced by the Stokes drag (F D ¼ 3plaU L ), the lateral migration velocity of these particles scales with particle size as U L / a. Thus, the larger particles migrate faster across the streamlines toward the sheath flow.…”

Section: Separation Principle and Device Operationmentioning

confidence: 99%

Vortex-aided inertial microfluidic device for continuous particle separation with high size-selectivity, efficiency, and purity

2013

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In this paper, we report an inertial microfluidic device with simple geometry for continuous extraction of large particles with high size-selectivity (<2 lm), high efficiency ($90%), and high purity (>90%). The design takes advantage of a high-aspect-ratio microchannel to inertially equilibrate cells and symmetric chambers for microvortex-aided cell extraction. A side outlet in each chamber continuously siphons larger particles, while the smaller particles or cells exit through the main outlet. The design has several advantages, including simple design, small footprint, ease of paralleling and cascading, one-step operation, and continuous separation with ultra-selectivity, high efficiency and purity. The described approach is applied to manipulating cells and particles for ultraselective separation, quickly and effectively extracting larger sizes from the main flow, with broad applications in cell separations. V C 2013 AIP Publishing LLC.

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“…Hence they cannot be applied, strictly speaking, to the case of freely rotating spheres in shear flows. Kurose & Komori (1999) performed numerical simulations to determine the drag and lift forces on rotating spheres in an unbounded linear shear flow. Morris & Brady (1998) studied the migration of non-neutrally buoyant spheres in pressure driven flows of Newtonian fluids.…”

mentioning

confidence: 99%

Power law correlations for sediment transport in pressure driven channel flows

Patankar

Joseph

Wang

et al. 2002

International Journal of Multiphase Flow

115

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Lift forces acting on particles play a central role in many cases, such as sediment transport, proppant transport in fractured reservoirs, removal of drill cuttings in horizontal drill holes and cleaning of particles from surfaces. We study the problem of lift using 2D direct numerical simulations and experimental data. The lift-off of single particles and many particles in horizontal flows follow laws of similarity, power laws, which may be obtained by plotting simulation data on log-log plots. Data from slot experiments for fractured reservoirs is processed (for the first time) on log-log plots. Power laws with a parameter dependent power emerge as in the case of Richardson-Zaki correlations for bed expansion by drag.

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Drag and lift forces on a rotating sphere in a linear shear flow

Cited by 298 publications

References 21 publications

Unexpected trapping of particles at a T junction

Unexpected trapping of particles at a T junction

Vortex-aided inertial microfluidic device for continuous particle separation with high size-selectivity, efficiency, and purity

Power law correlations for sediment transport in pressure driven channel flows

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