The flow of closely fitting particles in tapered tubes

The flow of rigid spheres, truncated cones and elastic incompressible spheres in tapered tubes is investigated assuming that the Reynolds equation is valid in the fluid and the linear theory of elasticity is applicable in the solid. It is shown that leading terms in the asymptotic expansion of pressure drop in terms of minimum fluid film thickness for neutrally buoyant rigid spheres and truncated cones are of higher order of magnitude compared to the corresponding terms for the flow of these particles in circular cylindrical tubes. The effect of taper angle on pressure drop is reduced in the case of soft elastic particles because of particle deformations and significant velocities at the particle surface.