In bin/hoppers filled with densely packed hulk materials, upon opening of t
he outlet, a narrow plug-type flow zone propagates upward and widens. With
progressing discharge, this zone grows, eventually reaching the top of the
material and possibly the walls of the bin. Based on small-scale model test
s, a theoretical model of the evolution of the plug flow zone in plane and
axisymmetric bin/hoppers is presented. The model is purely kinematic and ap
proximate; however, it accounts for the observed lower than initial density
of the flowing material, and the general form of the flow pattern. This is
accomplished by separating flow into two regions, radial and vertical, sep
arated from the stagnant material by density shocks. Comparison between the
model and plane flow experiments shows satisfactory agreement providing ad
ditional assumptions relating the radial and vertical flow are introduced.
The model may find application in predicting transition from plug to mass f
low. (C) 2000 Elsevier Science S.A. All rights reserved.