The steady flow due to a rotating sphere at low and moderate Reynolds numbers

Dennis, S. C. R.; Singh, S. N.; Ingham, D.B.

doi:10.1017/s0022112080001656

Cited by 290 publications

(103 citation statements)

References 5 publications

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“…The drag torque is included, because it was found to dampen the particle angular velocity fluctuation considerably. The drag torque is modelled by (Takagi 1977;Dennis, Singh & Ingham 1980;Yamamoto et al 2001)…”

Section: Particle-gas Forcesmentioning

confidence: 99%

Turbulence attenuation in particle-laden flow in smooth and rough channels

Vreman

2015

J. Fluid Mech.

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Results of point-particle direct numerical simulations of downward gas-solid flow in smooth and rough vertical channels are presented. Two-way coupling and inter-particle collisions are included. The rough walls are shaped as fixed layers of tiny spherical particles with diameter much smaller than the viscous wall unit. The turbulence attenuation induced by the free solid particles in the gas flow is shown to be enhanced with increasing wall roughness. The so-called feedback force, the force exerted by the free particles on the gas, is decomposed into three contributions: the domain average of the mean feedback force, the non-uniform part of the mean feedback force and the fluctuating part of the feedback force. Since the non-uniformity of the mean feedback force increases with wall roughness, the effect of the non-uniform part of the mean feedback force is investigated in detail. For both smooth and rough walls, the non-uniform part of the mean feedback force is shown to contribute significantly to the particle-induced turbulence attenuation.

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Section: Particle-gas Forcesmentioning

confidence: 99%

Turbulence attenuation in particle-laden flow in smooth and rough channels

Vreman

2015

J. Fluid Mech.

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“…For the case of a sphere rotating in an ambient fluid, no similarity solution was found in the vicinity of the equator, and the nature of the flow in this region has been discussed by Stewartson [17], Banks [18], [19], Singh [20], and Dennis et al [21]. Ingham [22] has studied the rotating flow in the vicinity of the equator of a rotating sphere numerically and found that no unique solution exists.…”

Section: Introductionmentioning

confidence: 99%

Unsteady MHD rotating flow over a rotating sphere near the equator

2003

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Summary. The unsteady rotating flow of a laminar incompressible viscous electrically conducting fluid over a rotating sphere in the vicinity of the equator has been studied. The fluid and the body rotate either in the same direction or in opposite directions. The effects of surface suction and magnetic field have been included in the analysis. There is an initial steady state that is perturbed by a sudden change in the rotational velocity of the sphere, and this causes unsteadiness in the flow field. The nonlinear coupled parabolic partial differential equations governing the boundary-layer flow have been solved numerically by using an implicit finite-difference scheme. For large suction or magnetic field, analytical solutions have also been obtained. The magnitude of the radial, meridional and rotational velocity components is found to be higher when the fluid and the body rotate in opposite directions than when they rotate in the same direction. The surface shear stresses in the meridional and rotational directions change sign when the ratio of the angular velocities of the sphere and the fluid k ! k 0 . The final (new) steady state is reached rather quickly which implies that the spin-up time is small. The magnetic field and surface suction reduce the meridional shear stress, but increase the surface shear stress in the rotational direction.

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“…Magnus force: the particle angular velocity, p  , can be obtained from particle conservation of angular momentum equation 37,38 :…”

Section: Discrete Phase Modellingmentioning

confidence: 99%