The deformation of restrained flocs has been studied in a vertically-orient
ed flow chamber in an effort to quantify the response of aggregate structur
es exposed to hydrodynamic stress. These results have been used in turn as
part of the analysis of an expulsion process occurring when large kaolin-po
lymer flocs are discharged from a micropipette tip under the influence of i
ncreasing upstream pressure. The deformation experiments complement breakag
e trials in which changes in the floc size distribution were monitored in a
stirred, baffled tank. By measuring the power input (mean dissipation rate
) and the average size of fragments produced by an increase in stirring rat
e, it is possible to estimate the strength with which fragments were bound
to the parent structure. These data show that the ratio of fragment size to
mean floc size decreases as the power input increases; they also show frag
ment size decreases (with stirring rate) much more sharply than the Kolmogo
rov microscale. This study has provided quantitative data regarding both fl
oc deformation and breakage that can be used for the improved design and op
eration of flocculation processes.