Direct measurements of the drag force on two interacting particles arr
anged in the longitudinal direction for particle Reynolds numbers (Re)
varying from 20 to 130 are conducted using a microforce measurement s
ystem. The system is capable of measuring the force up to 50 g with an
accuracy of 1 mg. The effects of the interparticle distance and Re on
the drag forces of both the trailing and leading particles are examin
ed. An empirical equation is obtained to describe the drag force varia
tion of a single particle trailing in the wake of a leading particle.
A mechanistic model is also developed to account for the motion of the
trailing particle in the wake region of the leading particle as well
as for their contact velocity. Moreover, a simultaneous flow-field vis
ualization is conducted to characterize the wake flow phenomena. The r
esults indicate that Re affects not only the magnitude of the drag for
ce of an interacting particle but also its variation with the interpar
ticle distance. At contact, the drag force of a trailing particle can
be less than one-fifth of the drag force of a single particle without
interparticle effects. Both the drag force measurements and the flow-f
ield visualization reflect that the wake-influenced region of the lead
ing particle can be longer at a lower Re. The mechanistic model sugges
ts that both the drag force and the Basset force should be included in
the description of the motion of the trailing particle in the wake re
gion of the leading particle. The model predicting the contact velocit
y of the two particles is reasonably validated with the experimental d
ata.