RU154725U1 - DEVICE FOR DUST COUPLING AND BINDING "OTUO-2-3" - Google Patents

Abstract

A device for collecting and binding dust, containing 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 device for removing dust free air is an output 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 entrance 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, is rounded and concave inside the suction shelter and mates with its side parts, characterized in that the inner walls of the housing are ring elliptical nozzles made in the form of a truncated elliptic cone, inside each of which along its central axis there is a pipe for supplying foam flow, to its small Hovhan attached dusty air feed conduit and the large base of the annular gap nozzle with the foam flow supply connected to the system generating and supplying foam.

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.

The invention is known (AS SU 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 No. 1580033 A1, E21F 5/00, published July 23, 1990), an OTUO-2 dust collecting and binding device containing an aspiration cover for a conveyor belt with transported dust-free material communicated with it a suction pipe connected to a traction stimulator and a dust collection device made in the form of an elliptical body connected to a 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 into the suction shelter and is associated with its lateral parts.

However, this device does not have 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, ensuring its minimum 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 the device for removing dust free air is an output element located in front of the entrance to the suction shelter, and the nozzle exit of the second element is 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 inward of the aspiration shelter and mates with its lateral parts, this, annular elliptical nozzles made in the form of a truncated elliptical cone are placed at the inner walls of the housing, inside each of which a nozzle is placed along its central axis foam flow supply, a dusty air supply pipe is connected to its small base, and a large base is an annular gap with a foam flow supply pipe connected to a foam generation and supply system.

The technical result. The installation of annular elliptical nozzles at the inner walls of the housing provides a continuous supply of foam into the internal cavity of the elliptical housing. In this case, the air leaving the annular cross section of the elliptical nozzles contributes to the ejection of foam bubbles in its central part and dust particles in its peripheral part, creating additional conditions for the intensification of the wetting of dust particles in a dense, constantly mixed stream of foam bubbles. At the same time, the use of foam ensures a minimum liquid flow rate for moistening dust particles, significantly reducing the overmoistening of the transported material. The device allows air purification from dust with an efficiency of 85.5%, which exceeds the efficiency of known devices by 5-7%.

The essence of the utility model is illustrated by the drawing, where in FIG. 1 shows a device for collecting and binding dust, a perspective view; in FIG. 2 - annular elliptical nozzles, 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 exhaust outlet 9 of the traction motor 5 is communicated by means of ducts 10 with annular elliptical nozzles 11. The elliptical housing 7 is connected to the tangential pipe 12, and at the inner walls elliptical casing 7 placed annular elliptical nozzles 11, expanding along the flow in the elliptical casing 7 and made in the form of a truncated elliptical cone 13, inside of which the foam flow supply pipe 14 is placed along its central axis, and the dusty air supply pipe 10 is connected to its small base, the large base being an annular gap 15 with the foam flow supply pipe 14 connected to the foam generation and supply system. The tangential nozzle 12 connected to the elliptical housing 7 is made arcuate, and its output element 16 is placed in front of the inlet 17 to the suction shelter 1. The nozzle 18 of the output element 16 is made in the form of a circular arc, the center of which is located on the side of the inlet 17 of the suction shelter 1. Side part 19 of the suction shelter 1 is convex, and the end part 20, located opposite the entrance 17 to the suction shelter 1, is rounded and concave inside the suction shelter 1 and is associated with its (shelter) side part 19.

The device operates as follows.

When moving bulk materials (transported dust-free material) 3 by the conveyor belt 2 due to abrasion, dust particles are formed throughout the entire 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 transported material falls into the range of the flow flowing from the nozzle 18 of the output element 16, where, thanks to the design of this nozzle, a compact directional jet of air is organized, the aerodynamic parameters of which are amplified along the axis of the belt, and therefore, the transported material in the direction of the inlet 17 of the suction cover 1. When this occurs blowing both from the surface and from the volume of the transported material 3 of those dust particles that without using the device for any unorganized external exposure (mechanical, aerodynamic or other) can go into suspension and cause 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 traction stimulator 5, and then through the supply pipes of dusty air 10 is supplied in full to the annular elliptical nozzles 11. The increase in the ratio of the areas of the annular gap 15 of each nozzle 11 and the corresponding pipe supply of dusty air 10 provides an increase in the flow rate of the air pumped into the gap as the nozzles 11 approach the tangential pipe 12, and therefore, the ejection effect in the cavity of the pipe 12, which creates the conditions for organizing a stable air flow through the pipe 12 and its nozzle 18 to the transported layer material 3.

The location of the nozzles 14 for supplying the foam flow directly along the axis of the annular elliptical nozzles And allows you to provide a volumetric ejection effect in the cavity of each nozzle 11, rationally redistribute the aerodynamic and hydrodynamic parameters by achieving their maximum values in one zone, that is, at the outlet sections of the nozzles 11. the air leaving the annular cross section 15 of the elliptical nozzles 11 contributes to the ejection of foam bubbles in its central part and dust particles in its peripheral part Creating additional conditions for the intensification of the wetting of the dust particles in a dense, constantly mixing flows of foam bubbles. Moreover, the use of foam provides a minimum liquid flow rate for moistening dust particles, significantly reducing the overmoistening of the transported material 3.

Due to the installation of nozzles 11 in the cavity of the elliptical body 7, a vortex is created, which provides additional air supply, due to which the core of the vortex is formed, and a dusty liquid aerosol directed into the zone of the suction torch of the traction stimulator 5 undergoes additional mixing, which intensifies the wetting process by increasing the area contact surfaces of dust particles with foam bubbles. 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, containing 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 device for removing dust free air is an output 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 entrance 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, is rounded and concave inside the suction shelter and mates with its side parts, characterized in that the inner walls of the housing are ring elliptical nozzles made in the form of a truncated elliptic cone, inside each of which along its central axis there is a pipe for supplying foam flow, to its small Hovhan attached dusty air feed conduit and the large base of the annular gap with the pipe feeding the foam flow, coupled with a system for generating and supplying foam.

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