The viscosity of a concentrated suspension of spherical particles

Abstract

Einstein's viscosity equation for an infinitely dilute suspension of spheres is extended to apply to a suspension of finite concentration. The argument makes use of a functional equation which must be satisfied if the final viscosity is to be independent of the sequence of stepwise additions of partial volume fractions of the spheres to the suspension. For a monodisperse system the solution of the functional equation is n{long right leg}τ = exp 2.5φ 1 - kφ where ηr is the relative viscosity, φ the volume fraction of the suspended spheres, and k is a constant, the self-crowding factor, predicted only approximately by the theory. The solution for a polydisperse system involves a variable factor, λij, which measures the crowding of spheres of radius rj by spheres of radius ri. The variation of λij with ri rj is roughly indicated. There is good agreement of the theory with published experimental data. © 1951.