The program included: collection of data on changes in the moisture content of the coal during different seasons of the year; observations of fuel evacuation; determining the stagnancy zones and their sizes for various levels of moisture content of the fuel; recording and analyzing the processes that occur in the bunker.
Method: measurement of the configuration of the fuel level in the bunkers during its evacuation; measurement of the rate of decrease in fuel levels and the flow velocity in the flow zone of coal; calculation of the main flow diameters from the measured fuel velocity and flow rate; determination of the effective volume of the bunker; calculation of the initial resistance to shear τ0 based on measurements in real bunkers.
Results:
1. A grading of fuels by flowability is proposed.
2. A relationship was found between fuel flowability and the following processes:
a. Variations in the velocity and diameter of the coal flow along the depth of the bunker.
b. The stage at which contiguous flows and mass flow form.
c. The presence of a second bunker.
d. The presence of internal shear.
e. The conditions causing the fuel to cave in.
f. The formation of a stagnant zone.
3. For each flowability class, we determined:
a. The variation in the angle of slip of coal on coal along the depth of the bunker.
b. Coal flow forms for earth group of coal flowability..
c. The effectiveness of various methods for improving the operation of the bunkers.
d. The required measures for improving the operation of the bunkers as a function of the fuel flowability.