RU2621096C1 - Kochetov's packed scruber - Google Patents

Abstract

FIELD: machine engineering.

SUBSTANCE: packed scrubber comprising a housing with connections for dusted and cleaned gas, an irrigation nozzle device, support grids, between which the nozzle is located, and a device for discharging the sludge. The nozzle is made of a toroidal shape having a section of a circle, in which the blind recesses are made, the nozzle of the irrigation device is made with a perforated spray disk and comprises a cylindrical housing with a fitting having a cylindrical hole connected with a diffuser, and an atomizer is connected to the housing by means of three spokes, made in the form of a perforated disc, the disc of the nozzle atomizer is formed by two surfaces of the spokes with the elements of the propeller type arranged radially and by form can be made straight or curved, the atomizer is made of hard material, tungsten carbide. The housing of the nozzle element is made in the form of three hemispherical surfaces connected to each other with a gap by means of a fastening element through the ring-type spacer elements, and the elements increasing the contact area of the flow with the nozzle are made in the form of corrugated elements located with the gaps relative to the hemispherical surfaces of the nozzle element housing. Hemispherical element surfaces of the nozzles are made perforated.

EFFECT: improving the efficiency and reliability of the dust collection process, reducing the metal-intensity and vibroacoustic activity of the device in general.

6 dwg

Description

The invention relates to techniques for wet dust collection and can be used in chemical, textile, food, light and other industries for the purification of dusty gases.

A known apparatus for wet cleaning of dusty air according to the patent of the Russian Federation No. 2411063, class. B01D 47/06, comprising a housing, a water sprinkler, a gas stream inlet, a clean gas outlet pipe and a sludge outlet device.

The disadvantage of the prototype is the relatively low efficiency of the dust collection process due to the underdeveloped surface of the nozzle.

The technical result is an increase in the efficiency and reliability of the dust collection process, as well as a decrease in the metal consumption and vibroacoustic activity of the apparatus as a whole.

This is achieved by the fact that in a nozzle scrubber containing a housing with nozzles for dusty and purified gas, an irrigation device with nozzles, support grids between which the nozzle is located, and a device for removing sludge, the nozzle is made of a toroidal shape having a circle in cross section in which non-through recesses were made on one and the other side of the diameter, the recesses having an elongated cross-sectional shape in the direction parallel to the axis of the torus, and the recess on one side is located between two adjacent recesses made with on the other hand, and the nozzle of the irrigation device is made with a perforated spray disk and contains a cylindrical body with a fitting rigidly connected to the body and coaxially located in the upper part of the body and having a cylindrical hole for supplying fluid connected to the diffuser, axisymmetric body and fitting, and to the body , in its lower part, by means of at least three spokes a sprayer is connected, located perpendicular to the axis of the housing and made in the form of a perforated disk.

In FIG. 1 shows a nozzle scrubber with transverse irrigation, in FIG. 2 shows a countercurrent nozzle scrubber; FIG. 3 - nozzle in the form of through holes in the surface of the torus, in FIG. 4 shows a general view of the nozzle of an irrigation device; FIG. 5, 6 illustrate options for nozzle elements.

The nozzle scrubber comprises a housing 1 with nozzles 2 and 3 for dusty and purified gas, an irrigation device 6, support grids 4 between which the nozzle 5 is located, and a device for removing sludge (Fig. 1 and Fig. 2).

In order to increase the degree of purification of the gas stream from dust or the target component by increasing the area of contact between the dusty stream and the nozzle, the nozzle 5 is made of a toroidal shape with an axis of symmetry 17 (Fig. 3), having a cross section 7 with an axis of symmetry 8, in which recesses 9, 11, 13, 15 on the one hand and through holes 10, 12, 14, 16 on the other side of the diameter. The recesses are elongated in cross section in the direction parallel to the axis of the torus, and the recess on one side is located between two adjacent recesses made on the other side.

The nozzle 5 is made of porous polymeric materials, glass, porous rubber, composite materials, wood, stainless steel, titanium alloys, precious metals.

The nozzle (Fig. 4) of the irrigation device 6 is made with a perforated spray disk and contains a cylindrical body 18 with a fitting 19 rigidly connected to the body and coaxially located in the upper part of the body and having a cylindrical hole 20 for supplying fluid connected to the diffuser 21, axisymmetric to the body and fitting. A sprayer 22 connected perpendicular to the housing axis and made in the form of a perforated disk with holes 25 is connected to the housing 18, in its lower part, by means of at least three spokes 26. The sprayer disk 22 is formed by two surfaces, one of which is facing to the side diffuser 21, a curved surface, and the line forming this surface is an nth-order curved line, for example, elliptical, parabolic, etc., and the second is a plane.

The spokes 23, by means of which the atomizer disk is attached to the body, are arranged radially with respect to the axis of the body and can be made straight (not shown) and curved in shape, moreover, they are attached to the body by means of screws 24 and to the disk, or by means of a detachable connection , for example threaded, or one-piece, for example by contact welding.

The perforation holes 25 in the disk 22 have axes intersecting at a point lying on the end surface of the housing and which is the center of the largest circumference of the diffuser 21, while the nozzle atomizer can be made of solid materials, such as tungsten carbide.

A variant is possible when, on the spokes 23, by means of which the nozzle atomizer disk is attached to the housing, propeller-type elements 26 are located.

A nozzle scrubber operates as follows.

The dusty gas stream enters the housing 1 through the nozzle 2 and meets a curtain from the nozzle 5, which is wetted with water or other absorbent from the irrigation device 6. The flow rate of irrigation fluid in countercurrent nozzle scrubbers is accepted in the range from 1.3 to 2.6 l / m ³ . In nozzle scrubbers with transverse irrigation for better wetting of the surface of the nozzle, the 5th layer of the nozzle is inclined by 7 ... 10 ° in the direction of the gas flow. The flow rate of irrigation fluid in them is taken in the range from 0.15 to 0.5 l / m ³ . The dust collection process proceeds in the optimal hydrodynamic mode, since the hydraulic resistance of the nozzle 5 is 20% less than the hydraulic resistance of the outlet pipe 3 of the purified gas. To reduce the vibro-acoustic activity of the apparatus and its metal consumption, as well as increase its reliability, the proposed device provides the following measures: a layer of soft vibration-damping material, for example, VD-17 mastic, is applied to the surface of the parts, and the ratio between the thickness of the metal and the vibration-damping coating is in the optimal range of values: 1 / (2.5 ... 4). To remove sludge, a device is used to remove sludge in the form of a channel in the bottom of the housing or a separate mechanism.

The nozzle with a perforated spray disk operates as follows. The liquid is supplied through a cylindrical hole 20 to the diffuser 21, and from it enters the nozzle 22 under pressure, with this, additional droplets of liquid are crushed due to turbulence of the outlet stream, and the finely dispersed stream leaves the nozzle with a wide spray nozzle (solution).

The nozzle scrubber can be used to clean fine dust and humidify air in ventilation units and air conditioning units, as well as in trapping mists, readily soluble dust, as well as in the process of dust collection, gas cooling and absorption of nozzle scrubbers. The effectiveness of the proposed design of the nozzle scrubber increases due to the larger interaction surface of the nozzle in the above processes and when collecting dust particles larger than 2 μm in size is about 95%.

In FIG. 5, 6 show options for nozzle elements.

A variant of the nozzle element is possible (Fig. 5), which is made in the form of a housing containing at least three coaxially located hemispherical surfaces 27, 28, 29, interconnected with a gap by means of a fastening element, for example, in the form of a bolt 30 with a nut 31 through axisymmetrically spaced mounting elements 32 and 33, for example, in the form of rings. The mounting elements 32 and 33 can be made in the form of coil springs (not shown). Hemispherical surfaces 27, 28, 29 of the body of the nozzle element can be perforated.

The cavities between the hemispherical surfaces 27, 28, 29 of the body of the nozzle element are filled with elements that increase the area of contact of the contaminated stream (dusty or gassed stream or stream with the target component) with the nozzle, made in the form of corrugated elements 34 and 35, the surfaces of which, along the surface of their generatrix are equidistant with hemispherical surfaces 27, 28, 29 of the body of the nozzle element. Corrugated elements 34 and 35 are located with gaps relative to the hemispherical surfaces 27, 28, 29 of the body of the nozzle element.

Hemispherical surfaces 27, 28, 29 of the body of the nozzle element can be made of porous polymeric materials, glass, porous rubber, composite materials, wood, stainless steel, titanium alloys, precious metals.

A variant is possible (Fig. 6) when coaxially located hemispherical surfaces interconnected with a gap by means of a fastener form closed cavities by means of perforated radially arranged rings 36 and 37 located in a plane perpendicular to the axis of the fastener 30 and rigidly connected to hemispherical surfaces 27, 28, 29 of the body of the nozzle element.

It is possible that the cavities between the hemispherical surfaces 27, 28, 29 of the body of the nozzle element are filled with elements 38 that increase the contact area of the contaminated stream (dusty or gassed stream or stream with the target component) with the nozzle made in a spherical shape with dimensions larger than the size of the perforation of hemispherical surfaces .

The nozzle element for dust and gas cleaning apparatus works as follows.

The contaminated stream enters the apparatus through the input of a dusty gas stream and meets a curtain of nozzle elements on its way, which is wetted with water or other absorbent from the irrigation device. In this case, processes occur: wet dust collection, absorption, adsorption, capture of the target component. For example, the flow rate of irrigation fluid in countercurrent nozzle scrubbers is taken in the range from 1.3 to 2.6 l / m ³ . In nozzle scrubbers with transverse irrigation, for better wetting of the nozzle surface, the nozzle layer is inclined by 7 ... 10 ° in the direction of the gas flow. The flow rate of irrigation fluid in them is taken in the range from 0.15 to 0.5 l / m ³ . The dust collection process proceeds in the optimal hydrodynamic mode, since the hydraulic resistance of the nozzle is 20% less than the hydraulic resistance of the outlet pipe of the purified gas.

For example, a nozzle scrubber with nozzle elements can be used to clean fine dust and humidify air in ventilation units and air conditioning units, as well as for trapping mists, highly soluble dust, as well as for the process of dust collection, gas cooling and absorption of nozzles gas washers. The efficiency of the nozzle scrubber with nozzle elements of the proposed design increases due to the larger interaction surface of the nozzle in the above processes and amounts to about 95% when collecting dust particles larger than 2 microns in size.

Claims (1)

A nozzle scrubber comprising a housing with nozzles for dusty and purified gas, an irrigation device with nozzles, support grids between which the nozzle is located, and a device for removing sludge, while the nozzle is made of a toroidal shape having a cross-section in cross section in which through holes are made with one and on the other hand of the diameter, and the recesses are elongated in cross section in the direction parallel to the axis of the torus, and the recess on one side is located between two adjacent recesses made on the other hand, the nozzle of the irrigation device is made with a perforated spray disk and contains a cylindrical housing with a fitting rigidly connected to the housing and coaxially located in the upper part of the housing and having a cylindrical hole for supplying fluid connected to the diffuser, an axisymmetric housing and the fitting, and to the housing, in its lower parts, through at least three spokes connected to the atomizer, located perpendicular to the axis of the housing and made in the form of a perforated disk, the disk of the atomizer nozzle images two surfaces, one of which, facing the diffuser, is a curved surface, and the line forming this surface is an nth-order curved line, and the second is the plane, the spokes through which the nozzle atomizer disk is attached to the body are can be made straight and curved radially with respect to the housing axis and in shape, the perforation holes in the nozzle disk have axes intersecting at a point lying on the end surface of the housing and which is the center of the largest circle d a fuser, the nozzle atomizer is made of solid materials, for example tungsten carbide, characterized in that on the spokes through which the nozzle atomizer disk is attached to the body, there are propeller-type elements, the nozzle element body is made in the form of at least three hemispherical coaxially arranged surfaces interconnected with a gap by means of a fastening element through axisymmetrically arranged spacing elements in the form of rings, and elements that increase the contact area flow and with the nozzle, made in the form of corrugated elements, the surfaces of which, along the surface of their generatrix, are equidistant with the hemispherical surfaces of the body of the nozzle element, while the corrugated elements are located with gaps relative to the hemispherical surfaces of the body of the nozzle element, while the hemispherical surfaces of the nozzle element are perforated.

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