RU21033U1 - DUST SEPARATION SEPARATION PLANT - Google Patents

Abstract

1. Installation for separating pulverized waste containing a fan and a serially connected loading hopper, a separation cyclone and a dust collecting device, characterized in that the dust collecting device is made in the form of a vortex inertial dust collector, to the upper axial outlet of which a fan inlet is connected, and the upper output of the separation cyclone connected through the first control valve to the suction pipe, on which the second control valve is installed, with the upper inlet pulverized of the actuator and, optionally, through the third control valve and curler with the lower inlet of the dust collector, while the upper outlet of the separation cyclone is located on its axis below the outlet pipe and is directed downward, and the lower entrance of the separation cyclone is located in the lower part of the cyclone body and directed upward. 2. Installation according to claim 1, characterized in that the separation cyclone is made two-stage and with two gates that are installed between the steps, while the ratio of the diameter of the lower stage to the diameter of the upper stage is 1: (1.3-3) .3. Installation according to claim 1, characterized in that on it in the places necessary for the experiments, fittings for connecting control and measuring devices are installed. Installation according to claim 1, characterized in that the feed hopper contains a screw feeder.

Description

Dust separation plant.

The utility model relates to the technique of separation and classification of bulk and dusty materials and can be used to separate dusty waste with different densities, as well as for cleaning polluted air in various industries. At the same time, it can be used as an experimental setup for studying the processes of separation of pulverized wastes.

A known experimental installation for cleaning air from dust including an inertial vortex dust collector connected in series with pipelines with a fabric filter, the suction of which is carried out by a fan (see the description of the utility model of the Russian Federation No. 13615 according to the application No. 99120351).

A disadvantage of the known installation is the inability to separate pulverized wastes with different densities, i.e. separation of fractions of bulk or dusty materials.

The known installation for separating sludge-like waste containing a fan, a hopper, a separating cyclone and a dust collecting device in the form of series-connected cyclones and a bag filter (see the description of the invention for USSR copyright certificate No. 997829, IPC VOCh 7/00 publication 28.02.83. )

The disadvantage of this well-known installation, adopted for the nrototype, is the insufficient efficiency of cleaning polluted air from dust with high windage of particles and low efficiency of its use

MGHVSHS 7/00, 9/00

as an experimental setup for studying the influence of speed on the separation of pulverized waste.

The task to which the claimed utility model is directed is to increase the efficiency of separation of waste into fractions, as well as expand the functionality of the installation, i.e. giving it the functions of an experimental setup.

This is achieved by the claimed combination of features.

The dryness of the utility model lies in the fact that in the installation for the separation of dusty waste containing a fan and a series-connected loading hopper, a separation cyclone and dust collection, its device. The dust collecting device is made in the form of an inertial vortex dust collector, to the upper axial output of which a fan suction inlet is connected. The upper outlet of the cyclone is connected through the first control valve to the suction nozzle, on which the second control valve is installed, as well as to the upper entrance of the dust collector and additionally through the third control valve and swirl with the lower entrance of the dust collector, and the upper entrance of the separation cyclone is located on its axis below the suction nozzle and is directed downward, and the lower entrance is axially located at the bottom of the separation cyclone and is directed upward.

In addition, the separation cyclone is made two-stage and with two gates, which are installed near the transition between the steps, while the ratio of the stage diameter of the lower stage to the diameter of the upper stage is 1: ().

In addition, at the installation in the places necessary for the experiment, fittings were installed for connecting control and measuring instruments.

In addition, the feed hopper contains a feed feeder.

This allows you to increase the efficiency of separation of pulverized waste into fractions (heavy and light) and to expand the functionality of the installation.

The essence of the utility model is illustrated by the drawing, where FIG. 1 shows a plant for the separation of pulverized waste, the general scheme.

Installation for separating pulverized waste contains a fan 1 and a series connected loading hopper 2, a separation cyclone 3 (performing the function of winding off a light fraction of dust), a dust collecting device 4, which is made in the form of a vortex inertial bullet collector. The suction inlet 6 of fan 1 is connected to the upper axial output 5 of the dust collector 4.

In this case, the upper outlet 7 of the cyclone 3 is connected via a nepBjoo control valve 8 to the suction pipe 9, on which the second control valve O is installed, with the upper input 11 of the dust collector 4 and, additionally, through the third control valve 12, and the twist 13, with the lower input 14 of the dust collector 4. The upper inlet 15 of the separation cyclone 3 is located on its axis below the outlet pipe 7 and is directed downward. The lower inlet 16 of the separation cyclone 3 is located in the lower part of the cyclone body 3 and is directed upward.

Separation cyclone 3 is made two-stage with steps

17 and 18 and with two gates 19 and 20, which are installed on steps 17 and

18 near the transition 21 between them, while the ratio of the diameter of the lower stage 18 to the diameter of the upper stage 17 is 1: (1.3-s3).

At the installation in places necessary for the experiment, fittings 22 are installed for connecting control and measuring instruments (not shown in the drawing).

The loading hopper 2 contains a screw feeder 23.

The separated product is unloaded from the hopper 24 of the vortex inertial dust collector 4 and from the hopper 25 of the separation cyclone 3.

Installation works as follows:

From the feed hopper 2, dusty waste is fed through inlet 15 by a screw feeder 23 and into a separation cyclone 3. The product passes into cyclone 3 and mixes with the suction through inlet 16 s

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using fan 1 by air, in cyclone 3 there is a separation of pulverized waste into two fractions: the heavy fraction falls down, and the light fraction is discharged and through the upper inlet 7 of cyclone 3 is fed into the vortex inertial dust collector 4. In this case, the air stream containing the light fraction of waste passes through the first control valve 8 and enters the upper input 11 of the dust collector 4 and through the second control valve 12 and the remote twist 13 to the lower input 14 of the dust collector 4.

The air purified in the dust collector exits through the upper axial outlet 5 and is sent to the atmosphere through the suction inlet 6 of the fan 1.

The light fraction of waste released in the cyclone-separator 3 is discharged, as necessary, from the hopper 25. The heavy fraction of the waste is discharged from the hopper 24 of the vortex inertial dust collector 4.

The inventive utility model allows experimental studies of the speeds of soaring, transportation, moving off of pulverized wastes, the results of which make it possible to determine their dependence on the particle sizes of the fractions of pulverized wastes. For these purposes, the installation is equipped with fittings 22 for instrumentation. To cut off and study fractions, gates 19 and 20 are provided in the separation cyclone. For the same purposes, control valves 8,10,12 are used.

The design of the utility model improves the separation efficiency of dusty products and extends the functionality of the installation. General Director of Association LLC

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Claims (4)

1. Installation for separating pulverized waste containing a fan and a serially connected loading hopper, a separation cyclone and a dust collecting device, characterized in that the dust collecting device is made in the form of a vortex inertial dust collector, to the upper axial outlet of which a fan inlet is connected, and the upper output of the separation cyclone connected through the first control valve to the suction pipe, on which the second control valve is installed, with the upper inlet pulverized of the actuator and, optionally, through the third control valve and curler, with the lower inlet of the dust collector, while the upper outlet of the separation cyclone is located on its axis below the outlet pipe and is directed downward, and the lower entrance of the separation cyclone is located in the lower part of the cyclone body and is directed upward.  2. Installation according to claim 1, characterized in that the separation cyclone is made two-stage and with two gates that are installed between the steps, while the ratio of the diameter of the lower stage to the diameter of the upper stage is 1: (1.3-3).  3. Installation according to claim 1, characterized in that on it, in the places necessary for the experiments, fittings for connecting control and measuring devices are installed. 4. Installation according to claim 1, characterized in that the feed hopper contains a screw feeder.