SU1706735A1 - Dust control devices - Google Patents

Abstract

The invention relates to aero-hydro-dusting of air and can be used in any industry, in particular when moving hot bulk materials, in which wet methods of dust suppression are applicable. In order to reduce the dust content of the air in the working area of the production room, the sole of each section of the device and the visor mating with it are spherical, its throat is a truncated cone inclined in the direction from the visor, inside which the sprinkler is located opposite the suction air flow, and inside the sole also irrigator is installed , located in conjunction with this flow, where the device on the side of the visors has injectors by the number of sections, each with its concave slot the output exit section and the central axis of symmetry are directed to the center of the suction throat section. guilt ending in moisture condenser. 1 il. i to

Description

The invention relates to aero-hydro-dusting of air and can be used in any industry, in particular when moving hot bulk materials where wet methods of dust suppression are applicable, for example, when transporting burned molding sand and knocking out castings on gratings in foundries.

An irrigated gas duct is known when a number of nozzles or sprinklers are built into a gas duct or chimney to create water curtains in the path of dusty air.

An aspiration shelter for belt conveyors is known, including a rectangular section and suction funnels.

An aspiration device of a burning machine is known, consisting of three separate aspiration shelters with local suction tubes, through holes in the vertical walls and air inlets.

The closest in technical essence and the achieved effect is an OTUO-1 device for trapping dust aerosol and air purification from dust, which includes an aspiration shelter in the form of separate mutually installed sections with soles in the form of a rectangular parallelepiped placed horizontally in the neck.

ABOUT

one

coke

ng-mi, filled in the form of a horizontal prism with a trapezoid in x h. :: g, lnni, and canopies, as well as from the Oootopka along the contour, all suction pipes and sprinklers.

However, the known design does not allow to achieve a sufficiently high degree of dust reduction in the working area air, especially under the condition of providing constant access to the aspirated technological equipment, due to the presence in the cavity of each section of such structural elements of the inner surface (space of bending, joining and fracture ), which contribute to the emergence of turbulent air zones in the suction sections. Reducing the degree of capture of dust particles from the air of the working zone. Often encountered in practice is the need to ensure continuous access to the aspirated technological equipment during its operation, moreover, it requires removal in the known device of the relevant parts of the surface of each section, which causes a sharp change in the aerodynamic properties of the suction of their Torches, and therefore - a decrease in the efficiency of dusting.

The aim of the invention is to increase the efficiency of dust collection and improve performance. i

The goal is achieved by the fact that, in the proposed device, the sole of each section and the visor mating to it are spherical, its neck is made in the form of a truncated elliptical cone inclined from the visor, inside which the sprinkler is located in a temporarily suctioned air flow, and inside the sole a sprinkler is installed, located in conjunction with this flow, and the device on the side of the visors has injectors for the number of sections, each with its own concave slit outlet with cheniem and the central axis of symmetry directed toward the center of the suction mouth sectional okanchivayuscheys capacitor moisture.

The drawing shows the device, General view, axonometric.

STUO-V device for removing dust aerosol and cleaning air

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0 5 0 5

five

spirit from the dust, installed above the blade of the knock-out lattice 1 and the conveyor section 2 with castings in the molds, is made in the form of two sections that were adopted in conjunction with the soles 3 and necks, b. From the point of interface of these sections, there is a common vertical flanging 5 of flexible heat-resistant material (asbestos cloth) from the bottom, s is formed from the top of the groove inclined towards the lower edge of the sole 3. Each sole 3 is designed as a portion of a spherical surface, which is open from the side of constant access to the technical equipment and mates with a spherical visor 6, additionally covering the source of dust emission. The lower edge of the bottom of the 3 sections of the ZUDA section is launched under the Fish Grid 1 cloth. The ratio of the radii of the spherical sole R (and the spherical cap R, depending on the geometric and design features of the aspirated technological equipment, can be as follows: with a transverse source size of 1.3 to 1.5 m with a transverse source size of up to 1.3 m

“kg” Each neck k is made in the form of a truncated elliptical cone inclined from the visor 6, the axis of which passes through the point M of the maximum lift of the spherical surface 3. The bottom base of the neck kt lying on the spherical surface of the sole 3 is the cross section for air from the cavity of the sole 3, and on its upper base mounted condenser 7 moisture. The cavities of the capacitors 7 are connected to the suction pipe of the fan-dust separator 10 by means of air ducts 8 connected to a common collector 9 by means of air ducts 11 connected to the discharge pipes 12 of the device, which are installed on the side of peaks 6 according to the number of sections. Each injection nozzle 12 is made in the form of a triangular prism, two flat edges of which form a right angle, and the third face is a concave slit outlet nozzle facing the suction section of the throat kt and the central axis of symmetry of the nozzle 12 is directed towards the center of this section necks k so that it passes through the point M of the maximum rise of the spherical surface of the sole 3. On the surface of the neck, the sprinkler 13 of the device is reinforced with a sprinkler 13 so that its outlet nozzle is located inside the neck s k and directed along its axis but meeting the suction air flow, and sprinkler 1 is mounted on the surface of the visor 6 so that its outlet nozzle is arranged inside sole 3 wake suction air flow. Sprinklers 13 and b are intended for pneumohydrogen-spraying and therefore provide for the supply of liquid and compressed air.

The device works as follows 2 times.

Dust aerosol released during the operation of the aspirated technological equipment, over which the device is installed, delivers 2 suction plugs of the sole 3 into the zone of action. At the same time, it encounters counter-propagating liquid aerosol dispersed to a mist condition and coming out of the sprinklers 13 . 3 The resulting dust-liquid-liquid aero-. The sol, in which the process of heterocoagulation is already beginning, enters the cavity of neck 1, where, narrowing, enters the cavity of neck 4, where it decreases, falls into the condenser 7 of moisture. In this case, the general nature and sequence of stages (aspiration, coagulation of dust and droplets, moisture condensation, dust particles binding among themselves and 4 removal of sludge) of the process of dedusting under the conditions of external aerodynamic, thermal and hydrodynamic effects are similar to using the prototype. However, the spherical shape of the sole 3 of each section smoothes the inflection points of the inner surface of the sole 3.

The shape of the neck C (narrowing upwards in all directions) increases the degree of coagulation by increasing the likelihood of collision.

and trapping dust particles and liquid droplets, and increasing the degree of binding of dust particles among themselves and removing the resulting sludge by increasing the probability of collision of aggregates

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(primidine) with the inner surface of the neck C.

The moisture entering the condenser 7, the flow of air with the remaining dust particles, droplets, liquids and their aggregates cools, as a result of which the moisture with which this stream is saturated condenses and intensifies the process of binding the dust particles together and removing the sludge by additional moistening. At the same time, the moisture condenser 7, which is a cylindrical cavity broadened with respect to the upper outlet section of the neck 1, inside which is a tube spiral that narrows down the air flow with cooling liquid flowing through it, allows condensable moisture to flow to the inner walls of the neck k and, therefore, improves the process of removing sludge from the walls of the device, which prevents the possibility of secondary dust formation on these walls. The purified air from the condenser 7 moisture through the ducts 8 and the collector 9 enters the suction side of the fan-pad of the separator 10, from the discharge pipe of which is distributed by air ducts 11 to the discharge pipes 12. The ejection and installation of the discharge pipes 12 ensure the ejection dusty air from the working area by creating a flat compact, directed stream of air into the open part of the spherical sole 3. The visor 6 at the same time additionally shields the air flow ejected from the working area and installed th thereon Sprinkler 1 due to the properties pnevmogidroorosheni provides additional flame ejection stream shadowed.

. The enhancement of the effect of suction of this flow into the cavity of the sole 3 of the neck k is provided by the nature of the inclination and cross section of the neck. Ultimately, this also leads to a decrease in the dust concentration in the work area in the presence of an open area for access. As a result, the ejected air flow, mixed with the liquid aerosol in the TD spray, is directed into the cavity of the sole and merged with the air aspirated from the process equipment. Depending on the design and geometric features (in OS71

the longitudinal size of the aspirated technological equipment, the device may include any number of sections, based on the requirements for compactness and uniform distribution of the values of aero- and hydrodynamic and thermal parameters in the working volume of each section (at the rate of one section for every 1.0-1, 5 meters of dust equipment length). At the same time, the presence of flanging 5 at the junction points of the sections additionally ensures compliance with the above requirements and at the same time free transportation of materials along the equipment surface between the sections.

The sludge resulting from the operation of each section flows down the inner walls of the section and is thus removed beyond the technological equipment, and the sludge formed during the operation of the fan, the dust-separator 10, flows into the chute at the interface point when the sludge is discharged sections and it is also removed beyond the technological equipment.

Thus, the stages of the process are both dusting: aspiration, coagulation of dust and drops (heterocoagulation), condensation of moisture, binding of dust particles to each other, and removal of sludge takes place in the inventive device

intensively, dynamically and concentrated in volume, which reduces the dust content of the air in the working area of the production room.

Claims (1)

Formula invented and A device for trapping dust aerosol and air purification from dust, including an aspiration shelter in the form of concurrently installed separate sections with soles, mouths and canopies, flanging along the outer contour, suction nozzles and sprinklers, characterized by that, in order to increase trapping efficiency and improve operational characteristics, the device is equipped with a moisture condenser, the base of each section and the visor mating with it are spherical, the neck of the section is inclined in the direction of They are installed inside the cone and directed oppositely to the intake air flow and inside the sole and directed towards this flow, the device is equipped with discharge pipes for the number of sections on the side of the hoods, each of the pipes is concave and has a slit nozzle directed to the center of the suction section of the neck. Mr w / trpzh No. in & / Pp DVXQ T