RU2623768C1 - Absorber - Google Patents

Abstract

FIELD: machine engineering.

SUBSTANCE: in an absorber containing a vertical cylindrical body with inlet and outlet gas connections, horizontal mass transfer plates, a sprinkler and a drop catcher in the form of two horizontal partitions, between which the droplet shells are concentrically placed, a piston suspended on a spring is placed in the central shell, a gap between the partitions is provided with at least one additional horizontal partition and a vertically installed radial wall, forming two chambers limited in height by upper and lower partitions, one of which is connected to the cavity of the central shell via a window made along the entire height of this chamber, and is provided with entrance windows in the channels between the shells, and the second chamber is provided with exit windows of the mentioned channels and a central exit window made in the upper partition, according to the invention the sprinkler's injector comprises a hollow body with a nozzle and a central core, the body is made with a channel for feeding liquid and comprises a coaxial sleeve, rigidly fixed to the body, with a nozzle fixed at it lower part, made in the form of cylindrical two-step sleeve, which upper cylindrical step is connected to the central core coaxial to it via thread connection, which has a cenrtal hole, and moounted with an annular gap relative to the inner surface of the cylindrical sleeve. The mentioned annular gap is communicated with at least three radial channels made in the mentioned two-step sleeve to communicate it with annular cavity formed by sleeve inner surface and top cylindrical step outer surface. The annular cavity is connected with the body channel for liquid supply to the central core, in its bottom part the sprayer is rigidly secured, made as truncated cone coaxial with the central hole of the core, and secured by its top base to the base of the cylinder of the central core, and to bottom base of the truncated cone by means of at least three spikes the sprayer is secured, which is made in the form of the end face round plate, which edges are bent towards the annular gap, and on the external side surface of the truncated cone there are helical grooves, at the dividier, which is attached to the lower base of the truncated cone by means of at least three spokes and made in form of the end face round plate with edges bent towards the annular gap, axisymmetrically to the central hole of the central core an orifice hole is made.

EFFECT: increased efficiency of drop catching at variable gas flow rates.

2 cl, 5 dwg

Description

The invention relates to column mass transfer apparatuses and is intended for wet purification of air from gaseous hazards.

The closest known technical solution in its essence and the achieved effect is an absorber containing a vertical cylindrical body with gas inlets, horizontal mass transfer plates, an irrigator and a droplet eliminator in the form of two horizontal partitions, between which droplet precipitation shells are concentrically placed (RF patent No. 8630 (prototype )).

A disadvantage of the known device is that in the absorber, with changes in gas flow, part of the concentric channels between the shells are closed or manually opened using rotary valves, which ensures the required gas velocity along the channels and the separation intensity. However, due to the difficulty in determining the moment when such an adjustment is necessary, the latter is carried out untimely and tentatively, and in the case when there is a frequent change in gas flow, such adjustment is not performed due to the fact that the absorber needs to be stopped and partially disassembled .

The technical result is an increase in droplet collection efficiency with variable gas flow rates.

This is achieved by the fact that in the absorber containing a vertical cylindrical body with gas inlet and outlet nozzles, horizontal mass transfer plates, an irrigator and a droplet eliminator in the form of two horizontal partitions, between which droplet precipitation shells are concentrically placed, a piston is suspended on the spring, a gap between the partitions is equipped with at least one additional horizontal partition and a vertically mounted radial wall forming two chambers height and height of the upper and lower partitions, one of which communicates with the cavity of the central shell through a window made to the entire height of this chamber, and is equipped with entrance windows into the channels between the shells, and the second chamber is equipped with exit windows of these channels and a central exit window made in the upper partition, the nozzle of the sprinkler contains a hollow body with a nozzle and a central core, the body is made with a channel for supplying fluid and contains a coaxial sleeve rigidly connected to it with a fixed in its lower hour and a nozzle made in the form of a cylindrical two-stage sleeve, the upper cylindrical step of which is connected via a threaded connection to a central core coaxial with it and having a central hole and installed with an annular gap relative to the inner surface of the cylindrical sleeve, while the annular gap is connected to at least three radial channels made in a two-stage sleeve connecting it with an annular cavity formed by the inner surface of the sleeve and the outer surface the upper cylindrical stage, and the annular cavity is connected with the channel of the housing for supplying fluid to the central core, in its lower part, a spray gun is made rigidly, made in the form of a truncated cone, coaxial with the central hole of the core and attached with its upper base to the base of the cylinder of the central core, and a divider is attached to the lower base of the truncated cone by means of at least three spokes, which is made in the form of an end circular plate, the edges of which are bent in to the annular gap, and on the outer lateral surface of the truncated cone there are screw grooves, and in the divider, which is attached to the lower base of the truncated cone by at least three spokes and made in the form of an end round plate, the edges of which are bent towards the annular gap, axisymmetrically to the central a throttle hole is made to the hole of the central core.

In FIG. 1 shows a diagram of an absorber; FIG. 2 is a view along section AA, in FIG. 3 is a view along section BB, in FIG. 4 is a sectional view of CC, in FIG. 5 is a diagram of the sprinkler 6 in the form of a spray nozzle.

The absorber contains a vertical cylindrical body 1 with inlet and outlet nozzles 2 and 3 for gas, horizontal mass transfer plates 4 with a nozzle 5, an irrigator 6 and a droplet eliminator in the form of two horizontal partitions 7 and 8, between which drop-settling shells 9 are concentrically placed.

A piston 12 suspended on a spring 11 is placed in the central shell 10. The gap between the partitions 7 and 8 is provided with at least one additional partition 13. The specified gap is also provided with a vertically mounted radial wall 14, which forms two chambers 15 and 16. The chambers 15 and 16 are limited by the height of the upper and lower partitions 7 and 8.

The chamber 16 is in communication with the cavity of the central shell 10 through the window 17, made to the entire height of this chamber, and is equipped with input windows 18 into the separation channels between the shells 9.

The camera 15 is equipped with output windows 19 of the channels between the shells 9 and the Central output window 20, made in the upper partition 7.

The partitions 13 are provided with holes 22 and trays 23 for collecting the separated liquid flowing off the shells 9. The trays 23 are connected to the vertical tubes 24. The lower end of the tubes 24 is placed at the visor 25 for draining the trapped liquid on the wall of the housing 1. The lower part of the housing 1 is equipped with a nozzle 26 to drain contaminated fluid. The upper part of the Central shell 10 is provided with a stop 21.

The absorber works as follows.

The irrigating liquid is fed into the absorber and sprayed over the cross section using the sprinkler 6. The liquid wets the nozzle 5 on the upper plate 4 and, falling down, moistens the same nozzle on the lower plate 4. Next, the liquid flows into the lower part of the housing and is discharged from the absorber through the nozzle 26 .

Contaminated gas through the pipe 2 enters the housing, passes the perforation of the plates 4, liquefying the nozzle 5, and is cleaned of harmful substances. Then the gas enters the droplet eliminator through the cavity of the central shell 10, raises the piston 12 with its pressure to establish an equilibrium between the weight of the piston and the gas pressure, and then through the window 17 enters the chamber 16, from where it goes through the windows 18 to the separation curvilinear channels between the shells 9, where under the action of centrifugal forces, liquid droplets are deposited on the walls of the shells 9. The gas purified from the droplet liquid through the outlet windows 19 enters the chamber 15 and through the window 20 of the upper horizontal partition 7 (Fig. 3) Xia through conduit 3 to the consumer.

With an increase in gas flow, the piston 12 rises up and opens the window 17 of the central shell to a higher height, therefore, the gas enters the separation not only into the lower channels bounded by the lower partition 8 and the adjacent additional partition 13, but also into the overlying tier of the channels, limited by additional by partitions 13. With a further increase in gas flow and increasing its pressure, the piston 12 rises to the stop 21, opening all the tiers of the separation channels.

With a decrease in gas flow, the piston 12, under the influence of its weight, stretches the spring 11 and lowers down, closing part of the height of the window 17 and stopping the access of gas to the separation in the upper tiers of the separation channels.

Thus, the greater the gas flow rate, the higher the cross-sectional area of the separation channels through which the gas passes with simultaneous separation, and vice versa, the lower the gas flow rate, the lower the cross-sectional area of these channels. This ensures a constant gas velocity along the channels with optimal separation. The liquid trapped on the surface of the shells flows down in the form of a film and through the holes 22 it enters the trays 23, from where it is directed through the vertical tubes 24 to the visor 25 and then flows down the wall of the housing 1 in the form of a film.

In FIG. 5 is a diagram of sprinkler 6 in the form of a spray nozzle.

The nozzle comprises a cylindrical hollow body 27 with a channel 29 for supplying fluid and a coaxial sleeve 28 rigidly connected to the body with a nozzle fixed in its lower part, made in the form of a cylindrical two-stage sleeve 30, the upper cylindrical step 32 of which is connected by a threaded connection with it coaxial a Central core 33 having a Central hole 35, and installed with an annular gap 36 relative to the inner surface of the cylindrical sleeve 30.

The annular gap 36 is connected with at least three radial channels 31 made in a two-stage sleeve 30, connecting it with an annular cavity 34 formed by the inner surface of the sleeve 28 and the outer surface of the upper cylindrical stage 32, and the annular cavity 34 is connected with the channel 29 of the housing 27 for fluid supply.

A sprayer made in the form of a truncated cone 37 coaxial to the central hole 35 of the core and fastened with its upper base to the base of the cylinder of the central core 33 and to the lower base of the truncated cone 37 by at least three spokes 39 attached divider 38, which is made in the form of an end round plate, the edges of which are bent towards the annular gap 36.

On the outer side surface of the truncated cone 37 there are helical grooves (not shown) that contribute to more intensive atomization of the liquid.

In the divider 38, which is attached to the lower base of the truncated cone 37 by means of at least three knitting needles 39 and made in the form of an end round plate, the edges of which are bent towards the annular gap 36, a throttle hole 40 is made axisymmetrically to the central hole 35 of the central core 33.

An option is possible when an external diffuser 41 is coaxially attached to the sleeve 28, rigidly connected to the housing 27, in its lower part, and to the lower base of the truncated cone 37 of the atomizer, rigidly attached to the central core 33, in its lower part, while on the outer side the surface of the truncated cone 37 has helical grooves, the inner perforated diffuser 42 is coaxially attached, so that the output sections of the outer 41 and inner 42 of the diffusers lie in the same plane.

The nozzle is as follows.

Liquid under pressure is supplied into the cavity of the nozzle body 28 and then flows in two directions: first, into the annular cavity 34 through radial channels 31, then into the annular gap 36 between the nozzle and the central core 33. At inlet pressures of more than 0.2 MPa, the liquid accelerates with the formation of a liquid film, which does not come off its outer surface and acquires rotational motion on the helical outer surface of the truncated cone 37.

The second direction in which the fluid enters is through the channel 29 for supplying fluid into the cavity of the central hole 35 of the central core 33, and then through the cavity of the truncated cone 37 enters the divider 38, which is made in the form of an end round plate, the edges of which are bent towards the annular gap 36, with multiple crushing of droplet fluid flows flowing out in these directions.

The presence of gas inclusions in a liquid additionally perturbs its surface, which leads to wave formation and volumetric crushing of the liquid film. The loss of mechanical energy during external acceleration (on the external conical surface) is reduced compared with the same acceleration in a closed channel.

In addition, the nozzle can be used in various technological processes, in which it is required to ensure high efficiency of heat and mass transfer processes when spraying liquids.

The technical and economic efficiency of the proposed absorber is to improve the quality of dropping up to 15-20% due to automatic adjustment of the living section of the separation channels between the shells depending on the change in gas flow due to the use of a piston suspended on the spring, which changes its position by using the gas pressure energy height and thereby regulates the bore of the separation channels between the shells.

Claims (2)

1. An absorber containing a vertical cylindrical body with gas inlet and outlet nozzles, horizontal mass transfer plates, an irrigator and a droplet eliminator in the form of two horizontal partitions, between which drop-settling shells are concentrically placed, a piston suspended on a spring is placed on the central shell, the gap between the partitions is provided with at least one additional horizontal partition and a vertically mounted radial wall that forms two chambers, limited by the height of the upper th and lower partitions, one of which is connected with the cavity of the central shell through a window made to the entire height of this chamber, and is equipped with entrance windows into the channels between the shells, and the second chamber is equipped with exit windows of these channels and a central output window made in the upper partition, characterized in that the nozzle of the sprinkler contains a hollow body with a nozzle and a central core, the body is made with a channel for supplying fluid and contains a coaxial sleeve rigidly connected to it with fixed in its lower part with a filling made in the form of a cylindrical two-stage sleeve, the upper cylindrical step of which is connected by a threaded connection with a central core coaxial with it and having a central hole and installed with an annular gap relative to the inner surface of the cylindrical sleeve, while the annular gap is connected to at least three radial channels made in a two-stage sleeve connecting it with an annular cavity formed by the inner surface of the sleeve and the outer surface the upper cylindrical stage, and the annular cavity is connected with the channel of the housing for supplying fluid to the Central core, in its lower part, a spray gun is made rigidly, made in the form of a truncated cone, coaxial with the Central hole of the core and attached with its upper base to the base of the cylinder of the Central core, and a divider is attached to the lower base of the truncated cone by means of at least three spokes, which is made in the form of an end circular plate, the edges of which are bent to the side well, an annular gap, and on the outer lateral surface of the truncated cone there are helical grooves, and in the divider, which is attached to the lower base of the truncated cone by at least three spokes, and made in the form of an end round plate, the edges of which are bent towards the annular gap, axisymmetrically to the central a throttle hole is made to the hole of the central core. 2. The absorber according to claim 1, characterized in that the external diffuser is coaxially attached to the sleeve rigidly connected to the nozzle body in its lower part, and to the lower base of the truncated cone of the atomizer, rigidly attached to the central core, in its lower part, while on the outer side surface of the truncated cone there are screw grooves, an internal perforated diffuser is coaxially attached, so that the output sections of the external and internal diffusers lie in the same plane.

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