SU1580033A1 - Device for dust collection and binding - Google Patents

Abstract

This invention relates to aerial and hydrodusting. The goal is to increase the efficiency of the device by pre-warning dust emission into the working area from the material being transported by removing and collecting dust in the recirculated air flow. For this purpose, the dust collection device 8 is made in the form of an elliptical body 7 connected to a tangential nozzle 12 and a conical elliptical diffuser 13. The latter is installed in the body 7 to form an annular gap 14 in which slotted nozzles are placed at the inner walls 15 of the body. The side and end faces of the slit nozzles are made concave inside these nozzles. One of the slit nozzles is installed with the possibility of the formation of a narrowing down to the outlet of the stream along the flow in the housing 7 of the slotted channel. The outlets of the slotted channels are made with an increasing cross-sectional area in the direction towards the inlet of the tangential nozzle 12, and foggers are installed in them that are connected to the air mixture supply system. At the surface of the face, air is discharged, due to which a part of the dusty directional air flow is separated from the zone of the suction plume to the side surface of the housing 7 and forms a countercurrent. 1 hp ff. 5 il.

Description

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oo

Vodoozdushia

mixture

GO 00

1

The invention relates to the field of air dehydration and air decontamination and can be used in any industry for the transportation of bulk materials, in particular on the coal supply paths of mines.

The purpose of the invention is to increase the efficiency of the device by pre-warning dust emission into the work area from the transported material by removing and collecting dust in the re-circulated air flow.

FIG. 1 shows a device for trapping and binding dust, side view; in fig. 2 shows section A-A in FIG. one; in fig. 3 shows a section BB in FIG. one; in fig. 4 - slot nozzles, axonometrics; in fig. 5 - device, axonometrics.

A device for collecting and binding dust consists of an aspiration cover 1 placed under the conveyor belt 2 with the dust-removing material being transported 3. The aspiration cover 1 is connected on one side to the suction inlet 4 and on the other to the booster 5 tons. At the same time, the suction inlet 6 of the suction inlet 4 of the booster 5 tons is connected to the central part of the elliptical body 7 of the dust removal device 8, and the outlet 9 of the suction inlet 4 is communicated by means of air ducts 10 with slotted nozzles 11. The elliptical body 7 is connected to the tangential nozzle 12 and a conical elliptical diffuser 13, which is installed in the elliptical case 7 coaxially with the formation of an annular gap 14, in which the inner walls 15 of the elliptical case 7 are placed with Along the outlet openings 16 along the flow in the elliptical body, slotted nozzles I. The side faces 17 of the slotted nozzles are concave, while the outlet openings 16 of the slotted nozzles 11 are made with an increasing cross-sectional area in the direction of the recirculated air in the elliptical case 7 in the direction of the inlet 18 of the tangential nozzle-12. In the outlets 16, a fogging generator 19 is installed, connected to the water-air mixture supply system 20. The tangential nozzle 12 connected to the elliptical body 7 is arcuate, and its output element 21 is placed in front of the 22-hour entrance aspiration shelter 1. The nozzle 23 of the output element 21 is made in the form of a circular arc, the center of which (HP is shown) is placed on the side of the 22 aspiration cover 1. The side part 24 of the aspiration shelter 1 is made convex, and the end part 25, located opposite the entrance 22 to the aspiration shelter 1, is made rounded and concave inside the aspiration shelter 1

and adjoins with its (cover) side part 24. Face 26 on the side of inlets 27 of slotted nozzles 11 is made as part of a side surface of cylinder 28, the longitudinal axis 29 of which coincides with the central axis of the elliptical body 7.

The device works as follows.

When moving bulk materials 3 conveyor belt 2 due to abrasion, the formation of dust particles throughout the volume of this material. In addition, a certain number of dust particles may be in the layer of the transported material 3 after it is transferred from the conveyor to the conveyor. The material to be moved enters the zone of action of the flow from the nozzle 23 of the output element 21, where, thanks to the design of this nozzle, a compact directional laying air stream is arranged, the aerodynamic parameters of which are amplified along the belt axis and therefore the material being transported in the direction of the aspiration cover 22. When this happens, blowing out both from the surface and from the volume of the transported material 3 of those particles ached, which, without using the device with any unorganized external m exposure (mechanical, aerodynamic, or other) can go into a suspended state and cause an increase in the concentration of dust in the working area. The booster 5 ti gi provides air suction. A smooth transition of the aspiration air in the elliptical case 7 ensures the stability of the aerodynamic parameters of the specified suction plume over the entire surface of the material covered by this aspiration shelter, as well as the elimination of the aerodynamic stagnation zones in the aspiration shelter 1 and the intensive removal of dust in the cavity of the elliptical case 7. In the central part elliptical body 7 is organized dusty directional air flow, part of which is directed to the suction inlet 6 of the driver 5 tons of gigi, and Then, the ducts 10 are supplied in full to the slotted nozzles 11. The ratio of the area of the outlet 16 of each nozzle 11 and the diameter of the corresponding inlet duct 10 provides an increase in the discharge air flow into the gap as the nozzles 11 approach the tangential nozzle 12, and therefore, the ejection effect in the cavity of the nozzle 12, which creates conditions for the organization of a stable air flow through the nozzle 12 and its nozzle 21 to the layer of transported material 3. Due to the shape of the face 26 of the nozzles 11 o A stable vortex is secured, the core of which is located on the central vertical axis of the elliptical body 7. The location of the foggers 19 directly in the outlet openings 16 of the nozzles 11 ensures an additional ejection effect in the cavity of each nozzle 11: rationally redistribute the aerodynamic and hydrodynamic parameters by achieving them maximum values in one zone, i.e., at the outlet openings of nozzles 11. The choice of foggers 19 as sprinklers of the device is determined by the min -formal irrigation liquid flow rate at the maximum airflow saturated with moisture, and the approximation of dust particle sizes and dispersed liquid droplets, since it tumanoobrazova- Teli affords the most finely divided liquid mist. When this occurs, the mixing of dust particles and droplets of dispersed liquid in the air flow occurs, and the process of wetting the dust particles with liquid begins. Due to the shapes of the faces 17 of the nozzles 11, the said vortex creates additional air retention, which creates a vortex core, and a dust-like aerosol directed to the suction plume area of the 5 ton gouler undergoes additional mixing, which intensifies the wetting process dust with drops of liquid. At the same time, a vacuum of air is created at the surface of the face 17, due to which part of the dusty directional air flow is subject to separation from the suction plume zone to the side surface of the elliptical body 7 and a counter current is formed, which is stabilized due to the gap between the internal surface of the elliptical body 7 and the external surface of the diffuser 13, and also provides additional intensification of the process of wetting dust.

Thus, all dust particles trapped in the suction plume of the 5-gi booster, in the elliptical casing 7, are necessarily subjected to complex action by intense hydrodynamic and vortex aerodynamic factors.

Claims (3)

1. Device for trapping and binding ache, including aspiration covering the conveyor belt with the transported dedusted material, the suction nozzle connected with it connected to the thrust rod, and a device for dust removal and removal of dedusted air, characterized in that, in order to increase the efficiency of the device due to the preliminary warning of dust emission in the working area from the transported material by removing and collecting dust in the recirculated air flow, the dust removal device is made in the form of an elliptical body connected to the tangential pipe, and a conical elliptical diffuser installed in the housing coaxially to form an annular gap in which slit holes are located near the inner walls of the housing nozzle} the side and end faces of which are made concave inside the nozzle, while one of them is installed with the possibility of forming a narrowing to the exit the downstream opening in the elliptical case of the slotted channel, the outlet openings of the slotted channels are made with an increasing cross-sectional area in the direction to the inlet of the tangential nozzle and are fitted with foggers connected to the water-air mixture supply system, while the tangential nozzle is more arc-shaped, its output element is placed in front of the entrance to the aspiration shelter, and the nozzle of the output element is made in the form of an arc of a circle, the center of which is placed with the sides of the aspiration shelter entrance, the cone diffuser is conjugated with the upper part of the aspiration shelter, the side of which is convex, and the end part located opposite the entrance to the aspiration shelter is curved and concave inside 0 aspiration shelter and its adjoining side parts. 2. A device according to claim 1, characterized in that the end face on the side of the entrance to the slot nozzles is made as part of the side surface of the cylinder, the longitudinal axis 5 which coincides with the central axis of the elliptical body. fig.Z gz 2 3. I-, Figm fto3 VO ° b ° s 0I 22 18 eleven sixteen eight 1 15 FIG. five