RU170042U1 - Device for collecting and binding dust - Google Patents

Abstract

The utility model relates to the field of aero- and hydro-dusting of air and can be used in any industry when transporting bulk materials, in particular, on coal supply paths of mines. The purpose of the utility model is to increase the efficiency of the device due to the intensification of the process of wetting dust particles. The essence of the utility model lies in the fact that the device for collecting and binding dust, containing an aspiration cover for the conveyor belt with transported dust-free material, a suction pipe connected with it, connected to a traction drive, a dust collection device made in the form of an elliptical body connected to a tangential pipe , and a conical elliptical diffuser installed in the elliptical housing coaxially with the formation of an annular gap, and the device for removing the weight dust air is an outlet element located in front of the entrance to the suction shelter, and the nozzle of the output element is made in the form of an arc of a circle, the center of which is located on the inlet side of the suction shelter, the lateral part of the suction shelter is convex, and the end part opposite the entrance to the suction shelter , made rounded and concave inward of the suction shelter and mated with its lateral parts, while tapering towards the inner walls of the elliptical housing to their outlet openings in the elliptical body, slotted nozzles, the lateral faces of which are concave, and the outlet openings of the nozzle nozzles are made with increasing cross-sectional area in the direction of movement of the recirculated air in the elliptical housing toward the nozzle of the tangential nozzle, while in the outlet openings of the slotted nozzles slotted panels are installed that form perimeter closed slotted channels and connected to dusty air supply pipes, and slotted nozzles with Uniform feed nozzles with foam. 3 ill.

Description

The utility model relates to the field of aero- and hydro-dusting of air and can be used in any industry when transporting bulk materials, in particular, on coal supply paths of mines, as well as on transport paths of bulk materials of construction industry enterprises.

The invention is known (AC No. 358518, E21F 5/00, published January 1, 1972), a dust collecting unit including a cyclone, a fan, a sludge separator, nozzles, a fairing and an inner pipe.

The closest technical solution is the invention (A.S. SU 1580033 A1, E21F 5/00, published July 23, 1990), an OTUO-2 dust collecting and binding device comprising an aspiration cover of a conveyor belt with transported dust-free material, the suction pipe connected with it connected to the traction stimulator and the dust collection device made in the form of an elliptical body connected to the tangential pipe, which is made arcuate, and dust removal of air is carried out through the outlet an element located in front of the entrance to the aspiration shelter, the nozzle of the output element being in the form of an arc of a circle, the center of which is located on the entrance side of the aspiration shelter, the lateral part of the aspiration shelter is convex, and the end part opposite the entrance to the aspiration shelter is rounded and concave inside the aspiration shelter and is associated with its lateral parts.

However, this device does not have a high enough efficiency due to the lack of wetting of dust particles returned to the feed.

The objective of the utility model is to increase the efficiency of the device due to the intensification of the process of wetting the dust particles returned to the stream of transported material with foam bubbles that provide minimal moisture and increase the time of use of foam bubbles compared to drops of dispersed liquid.

The essence of the utility model lies in the fact that the device for collecting and binding dust, containing an aspiration cover for the conveyor belt with transported dust-free material, a suction pipe connected with it, connected to a traction drive, a dust collection device made in the form of an elliptical body connected to a tangential pipe , and a conical elliptical diffuser installed in the elliptical housing coaxially with the formation of an annular gap, and the device for removing the weight dust air is an outlet element located in front of the entrance to the suction shelter, and the nozzle of the output element is made in the form of an arc of a circle, the center of which is located on the inlet side of the suction shelter, the lateral part of the suction shelter is convex, and the end part opposite the entrance to the suction shelter , made rounded and concave inward of the suction shelter and mated with its lateral parts, while tapering towards the inner walls of the elliptical housing to their outlet openings in the elliptical body, slotted nozzles, the lateral faces of which are concave, and the outlet openings of the nozzle nozzles are made with increasing cross-sectional area in the direction of movement of the recirculated air in the elliptical housing toward the nozzle of the tangential nozzle, while in the outlet openings of the slotted nozzles slotted panels are installed that form perimeter closed slotted channels and connected to dusty air supply pipes, and slotted nozzles with Uniform feed nozzles with foam.

The technical result. The installation of slotted panels connected to the nozzles for supplying dusty air in the outlet openings of the slotted nozzles connected to the nozzles for the supply of foam makes it possible to intensify the mixing of dust particles in a dense, constantly mixed stream of foam bubbles due to the fact that the air leaving the slot panels from the center to the periphery of the crevice nozzles, in addition to ejecting, also contributes to inflating foam bubbles along the internal volume of the elliptical body, creating additional conditions for intensification with achivaniya dust particles in considerably enlarged space. In this case, the supply of foam into the active zone of binding of dust particles, into the annular gap between the conical elliptical diffuser and the elliptical body, through perimeter closed slotted channels provides more intense interaction with dusty air leaving the slotted panels in the form of expanding jets. The device allows air purification from dust with an efficiency of 93.6%, which exceeds the efficiency of known devices by 2-3%.

The essence of the utility model is illustrated by the drawing, where in FIG. 1 shows a device for collecting and binding dust, side view; in FIG. 2 - device, axonometry; in FIG. 3 - crevice nozzles with crevice panel, axonometry.

A device for collecting and binding dust consists of an aspiration shelter 1 located above the conveyor belt 2 with transported dust-free material 3. The aspiration shelter 1 is connected to the suction pipe 4 and communicates with the traction stimulator 5. In this case, the suction hole 6 of the suction pipe 4 is communicated with the central part of the elliptical housing 7 of the dust collecting device 8, and the outlet 9 of the traction motor 5 is communicated by means of air ducts 10 with slotted nozzles 11. The elliptical housing 7 is connected to the tangential pipe 12 and the conical elliptical diffuser 13 which is installed in the elliptical housing 7 coaxially with the formation of an annular gap 14, in which slotted nozzles 11 are placed at the inner walls 15 of the elliptical housing 7. and 17 slotted nozzles 11 are made concave, while the output sections of the nozzles 11 are made with an increasing cross-sectional area in the direction of movement of the recirculated air in the elliptical housing 7 towards the nozzle 18 of the tangential nozzle 12. In the output sections of the slotted nozzles 11 there are slotted panels 19 forming perimeter closed slotted channels 16 and connected to the nozzles 20 for supplying dusty air, and nozzles 11 are connected to the pipe 26 for supplying foam through the nozzles 21 for supplying foam. The tangential branch pipe 12 connected to the elliptical housing 7 is made arcuate, and its output element 22 is placed in front of the inlet 23 of the suction shelter 1. The nozzle 18 of the output element 22 is made in the form of a circular arc, the center of which is located on the inlet 23 of the suction shelter 1. Lateral part 24 of the suction shelter 1 is convex, and the end part 25, located opposite the entrance 23 to the suction shelter 1, is rounded and concave inward of the suction shelter 1 and mates with the side part 24 of the shelter.

The device operates as follows.

When moving bulk materials 3 belt conveyor 2 due to abrasion, the formation of dust particles throughout the volume of this material. In addition, a certain number of dust particles can be in the layer of the transported material 3 after it is reloaded from the conveyor to the conveyor. The material to be transported falls into the zone of action of the flow flowing out of the nozzle 18 of the tangential nozzle 12, where, thanks to the design of this nozzle, a compact directed jet of air is organized, the aerodynamic parameters of which are amplified along the axis of the tape, and, consequently, the transported material in the direction of the inlet 23 of the suction shelter 1. In this case, both particles of dust are blown both from the surface and from the volume of the transported material, which without using the device for any disorganized external influences (mechanical, aerodynamic or other) can go into suspension and entail an increase in dust concentration in the air of the working area. Traction 5 inducer provides air intake. A smooth transition of the suction air in the elliptical housing 7 ensures the stability of the aerodynamic parameters of the specified suction torch over the entire surface of the material covered by this suction shelter, as well as the elimination of zones of aerodynamic stagnation in the suction shelter 1 and intensive removal of dust into the cavity of the elliptical housing 7. In the central part of the elliptical housing 7 organized dusty directed air flow, part of which is sent to the suction hole 6 of the suction pipe 4, and then through the air ducts 10 it is supplied in full through the nozzles 20 for supplying dusty air to the slotted panels 19 installed in the outlet sections of the slotted nozzles 11. From the foam supply pipe 26, the prepared foam is fed through the nozzles 21 for supplying the foam to the slotted nozzles 11, filling all of them volume and going into the annular gap, between the conical elliptical diffuser and the elliptical body, through perimeter closed slotted channels provides more intense interaction with dusty air leaving the slot x panels in the form of expanding jets.

The increase in the cross-sectional area of each nozzle 11 in the direction of movement of the recirculated air in the elliptical housing 7 towards the nozzle of the tangential nozzle 12 and the increase in the cross-sectional area of the corresponding nozzle 20 for supplying dusty air increases the flow rate of the air pumped into the gap as the nozzles 11 approach the tangential nozzle 12, and therefore, the ejection effect in the cavity of the pipe 12, which creates the conditions for the organization of a stable air flow through the pipe 12 and its nozzle 18 layer of transported material 3. The installation of slotted panels 19 connected to the nozzles 20 for supplying dusty air in the outlets of the slotted nozzles 11 connected to the nozzles 21 for supplying foam allows one to intensify the mixing of dust particles in a dense, constantly stirred stream of foam bubbles due to the fact that the air leaving the slit panels 19 from the center to the periphery of the slit nozzles 11 contributes, in addition to ejection, to inflate the bubbles of the foam leaving the perimeter closed slot channel 16, the internal volume of the elliptical body 7 by creating additional conditions for enhanced wetting dust particles in considerably enlarged space. In this case, the supply of foam into the active zone of binding of dust particles, into the annular gap 14, between the conical elliptical diffuser 13 and the elliptical case 7, through perimeter closed slotted channels 16, provides more intense interaction with dusty air leaving the slotted panels 11 in the form of expanding jets . Thus, all dust particles that have fallen into the suction torch of the traction stimulator 5 in the elliptical body 7 are necessarily subjected to complex effects by intensive hydrodynamic and vortex aerodynamic factors.

Claims (1)

A device for collecting and binding dust, comprising an aspiration cover for a conveyor belt with transported dust-free material, a suction pipe connected to it connected to a traction drive, a dust collection device made in the form of an elliptical body connected to a tangential pipe, and a conical elliptical diffuser installed in elliptical housing coaxially with the formation of an annular gap, and the device for removing dust free air is an output an element placed in front of the entrance to the aspiration shelter, the nozzle of the output element being made in the form of an arc of a circle, the center of which is located on the entrance side of the aspiration shelter, the lateral part of the aspiration shelter is convex, and the end part opposite the entrance to the aspiration shelter is rounded and concave inside the suction shelter and is associated with its side parts, while tapering to its outlet holes along the flow in the ellipse are located at the inner walls of the elliptical body the slotted nozzles, the lateral faces of which are concave, and the outlet holes of the nozzle nozzles are made with an increasing cross-sectional area in the direction of movement of recirculated air in the elliptical housing toward the nozzle of the tangential nozzle, characterized in that slotted panels are installed in the outlet sections of the slotted nozzles forming perimeter closed slotted channels and connected to the nozzles of the supply of dusty air.

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