RU2654734C1 - Conical jet scrubber with vortex sprayer - Google Patents

Abstract

FIELD: instrument engineering.

SUBSTANCE: invention relates to wet dust collecting equipment. Conical nozzle scrubber with a vortex sprinkler, containing a body with spigots for dusty and clean gas, a spray nozzle, support and restrictive plates between which the nozzle is located, a splatcher made in the form of a nozzle layer located between the supporting and restricting trays, and a device for removing slurry, the support plates being elastic, the nozzle positioned above the lower support plate is made of resilient materials, for example in the form of polyethylene balls, and a vibrator is mounted on the lower support plate, the nozzle is made in the form of hollow balls, on the spherical surface of which a screw groove is cut, or the nozzle is made in the form of a screw line formed on a spherical surface and having a section perpendicular to the helical line, a type of a circle, a polygon, a Berl saddle or an Itallox saddle, characterized in that the irrigation device consists of a cylindrical part with an external thread for connecting a distributing pipeline leading to the liquid, a conical transition part and a cylindrical part with a large diametrical cross-section and with an internal threaded surface, and coaxially with the body in its lower part a nozzle is attached, formed by the cylindrical surface with an external thread interacting with the cylindrical part of the body, the cylindrical surface of the nozzle passes into the conical surface and closes the end perpendicular to the axis of the housing by a blind partition with a jet in its center made with an axisymmetric nozzle consisting of a cylindrical and conical throttle holes, connected in series, the larger diameter of the conical opening being located on the blind partition of the nozzle, the body and nozzle forming three coaxial inner cylindrical chambers, and on the nozzle on the side opposite the liquid supply, an additional row of jets is formed which are formed by at least three pairs of mutually perpendicular vertical channels for passage of liquid and horizontal channels that intersect on the conical side surface of the nozzle and form the outlets of each nozzle, wherein the pair channels are arranged at right angles to each other in the longitudinal planes of the housing, the conical side surface of the nozzle is formed with an apex angle of 90°, and the jet, made in the center of a blind partition and consisting of a cylindrical and conical throttle holes, has helical surfaces on the internal surfaces of both the cylindrical and conical throttle openings, while on the inner surfaces of the nozzle channels of the nozzle, which intersect on its conical lateral surface and which are formed by at least three pairs of mutually perpendicular vertical and horizontal channels for passage of liquid, screw surfaces are made, the direction of the helical surfaces in these channels is made in an opposite direction, the three inner-cylindrical chambers co-axially formed by the body and the nozzle, one of which serves to supply liquid, the other is an expansion chamber, and the third is the function of a pressure chamber of increased pressure, filled with an elastic mesh element, or shavings of non-ferrous metal, or plastic shavings, to the end surface of the cylindrical body part is attached a diffuser, covering the conical surface of the nozzle with a blind partition and a jet, and in the outlet section of the diffuser attached to the end surface of the cylindrical body part, a perforated barrier is installed to which at least two spokes are fixed to one end at the point of its intersection with the axis of the atomizer, the second end of which is fixed to the inner surface of the diffuser in such a way that the spokes are perpendicular to the inner surface of the diffuser, and on the spokes in their central part are freely installed additional sprayers, made in the form of screw drums, which are fixed on the spokes with the help of stops.

EFFECT: increasing dust collection process efficiency and reliability.

3 cl, 5 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.

The closest technical solution to the claimed object is a scrubber according to the patent of the Russian Federation No. 2322425 (prototype), comprising a housing consisting of a cylindrical part, a conical part, the lower part of which is connected to a cylindrical part and a conical sludge collector, nozzles, respectively, for dusty and purified gas, an irrigation device made in the form of a nozzle installed in the center of the housing.

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

EFFECT: increased efficiency and reliability of the dust collection process by increasing the degree of liquid atomization by nozzles.

This is achieved by the fact that in a conical nozzle scrubber with a vortex sprinkler containing a housing with nozzles for dusty and purified gas, a nozzle irrigation device, support and restriction plates, between which there is a nozzle, a spray catcher made in the form of a nozzle layer located between the support and restriction plates, and a device for removing sludge, and the supporting plates are made elastic, the nozzle placed above the lower supporting plate is made of elastic materials, for example, in the form of a floor ethylene balls, and a vibrator is mounted on the lower support plate, and the nozzle is made in the form of hollow balls, on the spherical surface of which a helical groove is cut, or the nozzle is made in the form of a helix formed on a spherical surface and having a cross-section perpendicular to the helical profile a circle, a polygon, a “Berl saddle” or an Itallox saddle, the irrigation device consists of a cylindrical part with an external thread for connecting to the fitting of the distribution pipe supplying liquid a conical transition part and a cylindrical part with a large diameter and an internal threaded surface, and a nozzle formed by a cylindrical surface with an external thread interacting with the cylindrical part of the body coaxially with the casing in its lower part, the cylindrical surface of the nozzle becomes conical the surface is closed by the end, perpendicular to the axis of the housing by a blank partition with a nozzle in its center, made by an axisymmetric nozzle and consisting of a cylindrical th and conical throttle holes connected in series, the larger diameter of the conical hole being located on the blind partition of the nozzle, while the casing and the nozzle form three coaxial inner cylindrical chambers, and an additional row of nozzles are made on the nozzle from the side opposite to the fluid supply, which formed by at least three pairs of mutually perpendicular vertical channels for the passage of fluid and horizontal channels that intersect on a conical lateral surface nozzles and form the outlet openings of each nozzle, while the paired channels are located at right angles to each other in the longitudinal planes of the casing, the conical lateral surface of the nozzle is made with an angle at the apex equal to 90 °, and the nozzle made in the center of the blind partition and consists of a cylindrical and conical throttle holes, has helical surfaces on the inner surfaces of both cylindrical and conical throttle holes, while on the inner surfaces of the nozzle nozzle channels that are not are cut on its conical lateral surface and which are formed by at least three pairs of mutually perpendicular vertical and horizontal channels for fluid passage, screw surfaces are made, while the direction of the screw surfaces in these channels is made in the opposite direction, and three internal coaxial formed by the body and nozzle cylindrical chambers, one of which serves to supply fluid, the other is an expansion chamber, and the third acts as a discharge high-pressure chambers are filled with an elastic mesh element, or non-ferrous metal chips, or plastic chips, a diffuser is attached to the end surface of the cylindrical part of the body, covering the conical surface of the nozzle with a blank partition and a nozzle, and in the outlet section of the diffuser attached to the end surface of the cylindrical part of the body, a perforated partition is installed, to which at least two spokes are fixed at one point at its intersection with the axis of the sprayer, the second end of the cat The latter is fixed on the inner surface of the diffuser in such a way that the spokes are perpendicular to the inner surface of the diffuser, and additional sprays are freely mounted on the spokes in their central part, made in the form of screw drums, which are fixed on the spokes with the help of stops.

In FIG. 1 shows a conical nozzle scrubber with a movable nozzle; FIG. 2 - nozzle in the form of hollow balls, on the spherical surface of which a helical groove is cut, FIG. 3 - nozzle in the form of cylindrical rings, on the side surface of which a helical groove is cut, in FIG. 4 - a nozzle in the form of cylindrical rings, on the lateral surface of which a helical groove is cut, having in cross section perpendicular to the helical line a profile of the Berl saddle or Itallox saddle, in FIG. 5 is a diagram of an irrigation device.

The conical nozzle scrubber with a vortex sprinkler contains a housing consisting of a cylindrical part 1, a conical part 2, the lower part of which is connected to a cylindrical part 3 and a conical sludge collector 4, with nozzles for dusty and purified gas, respectively. The irrigation device 7 is made in the form of a nozzle mounted in the center of the housing. The spray catcher is made in the form of a nozzle layer 9 located between the support 5 and restrictive 6 plates (Fig. 1). A nozzle layer is also located on the lower support plate 8. The lower 5 and 8 support plates and nozzle 9 are made of elastic materials. The nozzle placed above the lower support plate is made of elastic materials, for example, in the form of plastic balls. In FIG. 2 shows a variant of the nozzle 10 in the form of hollow balls, on the spherical surface of which a helical groove is cut, in FIG. 3 is a variant of a nozzle in the form of cylindrical rings, on the side surface of which a helical groove is cut, in FIG. 4 is a variant of a nozzle in the form of cylindrical rings, on the lateral surface of which a helical groove is cut, having in cross section perpendicular to the helical line a profile of the Berl saddle or Itallox saddle. A vibrator (not shown) may be mounted on the lower support plate 8. The nozzle can be made of elastic polymeric materials, composite materials and obtained by molding or sintering.

The irrigation device (Fig. 5) consists of a cylindrical part 11 with an external thread for connecting to the nozzle of the distribution pipe for supplying liquid, a conical transition part 12 and a cylindrical part 13 with a large diameter section with an internal threaded surface.

Coaxial to the casing in its lower part is a nozzle fixed by a cylindrical surface 16 with an external thread interacting with the cylindrical part 13 of the casing. The cylindrical surface 16 of the nozzle goes into a conical surface 14 and closes the end, perpendicular to the axis of the housing by a blank partition 15 with a nozzle 20 in its center, made by an axisymmetric nozzle and consisting of a cylindrical and conical throttle holes connected in series, and the larger diameter of the conical hole is located on the blind partition 15 nozzles. Moreover, the nozzle 20, made in the center of the blind partition 15 and consisting of a cylindrical and conical throttle holes, has helical surfaces on the inner surfaces of both the cylindrical and conical throttle holes (not shown).

The body and nozzle form three coaxial inner cylindrical chambers. The chamber 17 serves to supply fluid, the chamber 18 is an expansion chamber, the chamber 19 performs the functions of a pressure chamber.

An additional row of nozzles is made on the nozzle from the side opposite the fluid supply, which are formed by at least three pairs of mutually perpendicular vertical channels 22 for the passage of liquid and horizontal channels 21, which intersect on the conical side surface 14 of the nozzle and form the outlet openings of each nozzle. In this case, the vertical channels 22 are connected to the cavity of the expansion chamber 18, and the horizontal channels 21 are connected to the cavity of the injection chamber 19.

Paired channels 21 and 22 are located at right angles to each other in the longitudinal planes of the housing. The conical side surface 14 of the nozzle is made with an angle at the apex equal to 90 °.

On the inner surfaces of the channels of the nozzle nozzles 14, which intersect on the conical lateral surface of the nozzle and which are formed by at least three pairs of mutually perpendicular vertical channels 22 for the passage of fluid and horizontal channels 21, screw surfaces are made, while the direction of the screw surfaces in these channels is opposite directional. This allows you to increase the fineness of the sprayed liquid due to the interaction of the vortex flows at the outlet of the nozzles.

A variant is possible when three inner cylindrical chambers formed by the body and nozzle are interconnected, one of which (chamber 17) serves to supply fluid, the other (chamber 18) is an expansion chamber, and the third (chamber 19) acts as a pressure chamber, filled with an elastic mesh element, or non-ferrous metal chips, or plastic chips (not shown in the drawing). A diffuser 23 is attached to the end surface of the cylindrical part 13 of the housing, covering the conical surface 14 of the nozzle with a blank partition 15 and the nozzle 20.

The operation of the irrigation device is as follows.

The irrigation device is installed in an upright state. When liquid is supplied to the housing under the action of a pressure drop of 0.4 ... 0.8 MPa, oncoming channels of liquid are formed in channels 21 and 22, rushing to the outlet openings of the nozzles formed by these channels.

After the collision of the fluid flows in the channels 21 and 22 and the outflow through the nozzle outlets, a fan-shaped gas-liquid flow in the form of a shroud occurs, i.e. a liquid droplet crushing mechanism is implemented, but the generated swell-like flow deviates from the horizontal plane by a larger angle, in the range from 45 to 60 °, in the direction of the central region of the irrigated surface located directly under the nozzle 20 in the blind partition 15 of the atomizer. This distribution of the sprayed liquid allows to increase the uniformity of the spraying of the liquid over the Central part of the irrigated surface.

The proposed sprinkler can be used in fire fighting equipment, for example, as part of sprinkler or deluge fire extinguishing systems, in agriculture for spraying various types of substances on sown areas and in industrial premises, in chemical technology devices and in the power system for fuel spraying, as well as in technical branches, where the generation of atomized finely dispersed fluid flows is required in both closed and open spaces.

It is possible that in the output section of the diffuser 23 attached to the end surface of the cylindrical part 13 of the housing, a perforated partition 24 is installed, to which at least two spokes 25 and 26 are fixed at one point at its intersection with the spray axis, the second end of which is fixed to the inner surface of the diffuser 23 so that the spokes 25 and 26 are perpendicular to the inner surface of the diffuser 23, and additional sprays made in the form of screw are freely mounted on the spokes in their central part drums 27 and 29, which are fixed on the knitting needles with stops.

It is possible that in the output section of the diffuser 23 between the perforated baffle 24 and additional nozzles fixed to it by means of spokes 25 and 26, made in the form of screw drums 27 and 29, fixed on the spokes with the help of stops, a perforated conical shell 28 is installed, the top of the conical surface which is fixed on the perforated partition 24 at the point of intersection with the axis of the spray.

It is possible that the cavity 30 between the perforated conical shell 28, the top of the conical surface of which is fixed on the perforated partition 24, at the point of intersection with the axis of the atomizer, and the surface of the perforated partition 24 is filled with an elastic mesh element, or non-ferrous metal shavings, or plastic shavings , which increases the fineness of the phase of the sprayed liquid.

Conical nozzle scrubber with a vortex sprinkler works as follows.

The dusty gas stream enters the housing 1 through the inlet of the dusty gas stream, and meets a curtain from the nozzle 9, which is wetted with water or other absorbent from the irrigation device 7. To remove sludge, a device 4 is used to remove sludge in the form of a channel in the bottom of the housing or separate mechanism. To ensure free movement of the nozzle 9 in the gas-liquid mixture, its density should not exceed the density of the liquid. The process of dust collection takes place in the optimal hydrodynamic regime of a gas scrubber, characterized by a regime of fully developed fluidization. To intensify the hydrodynamic regime, a vibrator (not shown) is installed on the lower support plate 8. This will allow the scrubber to switch to the vibro-fluidized bed mode, in which the interaction efficiency of the nozzle 9, irrigated by the liquid, with the gas phase will increase, and therefore, will increase the overall efficiency of the apparatus. The implementation of the nozzle 9, the bottom 8 of the support plate of elastic material will allow under certain conditions to create a mode of oscillation or self-oscillation, which will also increase the efficiency of interaction of the nozzle 9 with the irrigated liquid.

The 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 packed gas washers. The effectiveness of the proposed design of the nozzle scrubber increases due to the larger interaction surface of the nozzle in the above processes, as well as the optimization of the hydrodynamic situation and amounts to about 97% when collecting dust particles larger than 2 microns in size.

Claims (3)

1. A conical nozzle scrubber with a vortex sprinkler, comprising a housing with nozzles for dusty and purified gas, a nozzle irrigation device, support and restriction plates, between which there is a nozzle, a spray trap made in the form of a nozzle layer placed between the support and restriction plates, and a device for removal of sludge, and the supporting plates are made elastic, the nozzle placed above the lower supporting plate is made of elastic materials, for example, in the form of plastic balls, and on a vibrator is mounted on the support plate, and the nozzle is made in the form of hollow balls on which a helical groove is cut on a spherical surface, or the nozzle is made in the form of a helix formed on a spherical surface and having in cross section perpendicular to the helix a profile such as a circle, polygon, " Berl saddles or Itallox saddles, characterized in that the irrigation device consists of a cylindrical part with an external thread for connection to the fitting of the distribution pipe supplying liquid, a conical transitional part and a cylindrical part with a large diameter and an internal threaded surface, and a nozzle formed by a cylindrical surface with an external thread interacting with the cylindrical part of the casing coaxially with the casing in its lower part, the cylindrical surface of the nozzle passes into a conical surface and closes the end, perpendicular to the axis of the housing by a blank partition with a nozzle in its center, made axisymmetric nozzle and consisting of a cylindrical and conical throttle holes connected in series, the larger diameter of the conical hole being located on the blind partition of the nozzle, while the casing and the nozzle form three coaxial inner cylindrical chambers, and an additional row of nozzles are formed on the nozzle from the side opposite to the fluid supply, which are formed at least three pairs of mutually perpendicular vertical channels for the passage of fluid and horizontal channels that intersect on the conical lateral surface of the la and form the outlet openings of each nozzle, while the paired channels are located at right angles to each other in the longitudinal planes of the housing, and the conical lateral surface of the nozzle is made with an angle at the apex equal to 90 °, and the nozzle, made in the center of a blank partition and consisting of cylindrical and conical throttle openings, has helical surfaces on the inner surfaces of both cylindrical and conical throttle openings, while on the inner surfaces of the nozzle nozzle channels are secluded on its conical lateral surface and which are formed by at least three pairs of mutually perpendicular vertical and horizontal channels for fluid passage, screw surfaces are made, while the direction of the screw surfaces in these channels is made in the opposite direction, and three internal coaxial formed by the body and nozzle cylindrical chambers, one of which serves to supply fluid, the other is an expansion chamber, and the third acts as a discharge chamber high pressure measures, filled with an elastic mesh element, or non-ferrous metal chips, or plastic chips, a diffuser is attached to the end surface of the cylindrical part of the body, covering the conical surface of the nozzle with a blank partition and a nozzle, and in the outlet section of the diffuser attached to the end surface of the cylindrical part of the body, a perforated partition is installed, to which at one point at least two spokes are fixed at one point at its intersection with the axis of the atomizer, the second end of which ı mounted on the inner surface of the diffuser so that the spokes are perpendicular to the inner surface of the diffuser, and additional sprays are freely mounted on the spokes in their central part, made in the form of screw drums, which are fixed on the spokes with the help of stops. 2. A conical nozzle scrubber with a vortex sprinkler according to claim 1, characterized in that in the output section of the sprinkler diffuser between the perforated baffle and additional sprays mounted on it by means of spokes, made in the form of screw drums fixed on the spokes with the help of stops, a perforated conical a shell, the top of the conical surface of which is fixed on a perforated partition, at the point of its intersection with the axis of the sprayer. 3. A conical nozzle scrubber with a vortex sprinkler according to claim 1, characterized in that the sprinkler cavity between the perforated conical shell, the top of the conical surface of which is fixed on the perforated partition, at the point of intersection with the axis of the spray gun and the surface of the perforated partition is filled with an elastic mesh element, or non-ferrous metal chips, or plastic chips, which increases the fineness of the phase of the sprayed liquid.

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