SU542123A1 - Apparatus for determining the flowability of dispersed materials - Google Patents

Description

(54) DEVICE FOR DETERMINATION OF THE VIABILITY OF DISPERSED MATERIALS

The invention relates to devices for determining the concavity of dispersed materials.

A device is known for determining the strength of powdered and granular materials 1, which contains a base, a funnel, a rack, a receiving cup (container), and a flap. However, it is not possible to determine the flowability of powders, especially fine ones, since they live in a funnel, showing zero flowability.

A device 2 is known for determining the flow of powders, including an outflow vessel with a nozzle and a shutter and a filling vessel. The outflow vessel is cylindrical and equipped with a paddle agitator, and a flat valve is used as a gate. However, rotation of the blade in the bulk material leads to heating of some powder materials, which changes their strength, in the volume of the vessel with bulk material during rotation of the blades, sometimes a fluidized state occurs, corresponding to a decrease in the internal friction coefficient, which also changes the strength, rotation of the blade. to the abrasion of the granules and their separation into fractions, which changes the strength. All this reduces the accuracy of determining the flowability of powder materials and does not

permits the determination of the fineness of fine powders with an average particle diameter of 150 microns and below.

Also known is a device 3 for determining the concavity, comprising a base on which a rack is mounted for fixing on it a funnel of outflow of the studied bulk material. The device has a flap that closes the outlet, and the receiving cup, into which the test material is expired. At the same time, the diameter of the outlet depends on the diameter of the largest granule size; therefore, replaceable matrices are installed on the outlet of the device, the internal cavity of which is made in the form of a cone, as a continuation of the funnel and has a cylindrical part. In a replaceable set of dies, there are several cylindrical holes of equal height that are different in diameter. The receiving cup is graded and placed on a plate, which is reported to have a horizontally directed vibration from the vibrator to level the angle of repose of the bulk material in the cup. In the instrument's funnel, nozzles of various configurations are installed, which are given a vertically directed vibration to destroy the arches, if

bulk material hangs in the funnel. Nesmogr on complex automation, the results of measured flowability on this device are subjective, as it is difficult to determine the difference in the required interchangeable matrices, nozzles and the time of their vibration. This reduces the accuracy of the flowability test. A large number of auxiliary equipment is required for operation of the device, therefore it cannot be used for rapid analysis. The device is intended for the study of granular (granular) materials. It is possible to use it for dispersed materials, as they will hang in the device funnel.

The purpose of the invention is to demonstrate the versatility of the device and the accuracy of measuring the strength of granular and powder materials. For this, the measles of the electrovibrator and the funnel are connected by a large and small diameter of the cone in the form of a rigid frame, the upper end of which is hinged on the stand and the lower end is pressed by a shock absorber placed between the bark and the stand. With this device design, the electrovibrator transmits oscillatory movements of the funnel below the outlet, which, in combination with the upper hinge, creates reciprocating oscillatory movement of the funnel with increasing amplitude from the hinge to the outlet, i.e. provides a minimum oscillation and compaction of the bulk material in the upper part of the funnel and maximum oscillation with an amplitude of 0.2-0.3 mm in the area of the outlet, i.e. in the place where it is necessary to prevent the formation of the arch, or to destroy it.

The drawing schematically shows the proposed vibrator, offensive appearance.

The device contains a base 1, a rack mounted on it 2, into the screw hole of which a device is screwed, which serves as a shock absorber 3. The threaded end 4 of the latter, together with lock nut 5, adjusts the gap Z between the electromagnet 6 and the bark 7 constituting the vibrator. On the rack 2, hinges 8 are reinforced, with which the funnel 9 is connected to the upright 2 through the bracket 10. The strap 11 connects the funnel to the bark 7, forming a rigid frame. The outlet 12 of the funnel 9 is closed by a flap 13, which is adjusted by the height of the column 16 with the help of a nut 14 and lock nut 15. The device has a receiving cup 17, a casing 18 and a cover 19.

The instrument for detecting rash works as follows.

Remove the cover 19 and in the funnel 9 zastayut sample of the investigated powder. When the valve is closed, 13 turns on the device and gives a preliminary vibration of 20 seconds duration. What is needed is the stability of the instrument readings. At this stage, a kor 7 moment is attracted to the electromagnet 6 and rotates the funnel 9 relative to the stand 2 by swiveling the loop 8 and the bracket 10. The funnel 9 returns to the initial position with a shock absorber 3. After 20 seconds. the device opens the flap 13. At the end of the flow of the powder into the receiving cup 17, the stopwatch is turned off.

Honor is calculated by the formula G

Vc -: pgde G - weight of the hinge; t - time is up.

The device is adjusted as follows.

When removing the casing 18 by means of a threaded end 4 of the shock absorber 3, adjust the gap Z between the electromagnet 6 and the core 7, providing a predetermined amplitude of oscillation of the funnel 9. The gap between the valve 13 and the nozzle of the outlet 12 of the funnel 9 is adjusted by the nut 16 and the lock nut 1 5 relative to the rack 16.

Claims (3)

1.Samsonov G.V., et al. Production of iron powder, M.L., 1947, pp. 218-219. 2. Avt. swith USSR N2 285338, C 01 N 11/06, 1968. 3. US Patent No. 3376753, 73-432, 1972.