Evolution of a two-dimensional axisymmetrical vortex laden with solid
heavy particles is studied analytically and numerically. The particula
te phase is assumed to be dilute enough to neglect the effects of part
icle-particle collisions. Only sufficiently small particle Stokes (St)
and Reynolds numbers are considered, for which an approximate solutio
n for the particle velocity can be derived. An analytical solution to
a Cauchy problem is obtained for initially uniform concentration of pa
rticles in a circular flow describing the accumulation of particles in
the form of a kinematic wave and the corresponding modification of th
e carrier flow. According to this solution, a steep peak of the concen
tration develops forming the wave crest which propagates out of the vo
rtex. Due to the interaction between the two phases, a fluid velocity
component directed towards the vortex center is generated, so that in
the vicinity of the crest the vortex acquires a spiral-like shape. At
later stages, the growth of the crest is inhibited and its propagation
velocity decreases. Analysis of the problem for particles with larger
Stokes numbers shows that the accumulation process is most intense wh
en St is close to a critical value St which generally depends on the
vortex structure and, for the flow considered, is of the order unity.