SPHEROIDAL PARTICLE FLOW IN A CYLINDRICAL TUBE.

Abstract

Viscous flow in a circular cylindrical tube containing an infinite line of rigid spheroidal particles equally spaced along the axis of the tube is considered for (a) uniform axial translation of the spheroids (b) flow past a line of stationary spheroids and (c) flow of the suspending fluid and spheroids under an imposed pressure gradient. The fluid is assumed to incompressible and Newtonian. The Reynolds number is assumed to be small and the equations of creeping flow are used. Two types of solutions are developed for each case (i) an exact solution in the form of infinite series which is valid for ratios of the spheroid diameter to the tube diameter up to 0.80. (ii) an approximate solution using lubrication theory which is valid for spheroids which nearly fill the tube. The drag on each spheroid and the pressure drop are computed for all cases. Both prolate and oblate spheroids are considered. The results show that the drag and pressure drop depend on the spheroidal diameter perpendicular to the axis of tube primarily and the effects of the spheroidal thickness and spacing are secondary. The results are of interest in connection with mechanics of capillary blood flow, sedimentation, fluidized beds, and fluid-solid transport. (Author)

Document Details

Document Type

Technical Report

Publication Date

Nov 01, 1968

Accession Number

AD0680455

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