RU49460U1 - FOAM MASS EXCHANGE MACHINE - Google Patents

Abstract

The utility model relates to techniques for wet cleaning of gases and can be used in devices for conducting heat and mass transfer processes. The technical result of the utility model is the creation of a new foam mass transfer apparatus with high work efficiency. The technical result is achieved in the design of a foam mass transfer apparatus comprising a vertical housing I, nozzles for supplying 2 and gas outlet 3, a collection of cleaning fluid 4 located in the lower part of the housing I, nozzles for supplying 5 cleaning fluid and its discharge 6, gas distribution contact device, made in the form of an absorption plate, including one or more grids 7, and the pipe 2 for supplying the gas to be cleaned is made passing through the side wall of the housing I, and the outlet of the pipe 2 is deepened below the contact device into the subgrid space 8, in which there is a jet filter, which includes a spray installed along the axis of the housing I of the apparatus with the output of the cleaning fluid directed to the side walls of the housing I, while the spray can be made in the form of nozzles 9, for example centrifugal, rotating or blast-jet, the sprayer can also be made in the form of a set of separate inkjet solid-fuel nozzles I0 installed around the circumference of the pipe II supplying the cleaning liquid from the collection 4. The cleaned gas is supplied to atrubok 2 by a fan

I2, and the purified gas is discharged through the pipe 3, bypassing the droplet separator I4, while the supply of the cleaning liquid to the pipe 5 for irrigation of the grid 7 of the absorption plate and to the pipe II of the jet filter sprayer, made in the form of nozzles 9, I0, is carried out by pump I3. 5 p.p .; 2 ill.

Description

The utility model relates to techniques for wet gas purification and can be used in devices for conducting heat and mass transfer processes, for example, foam scrubbers used for gas purification in the chemical, petrochemical, pulp and paper, metallurgical and other industries.

Known foam scrubber, consisting of a housing, inside of which is placed one or more grids (plates) of a failure type, or with overflow devices and a sprinkler. When irrigation fluid is supplied, a layer of mobile foam is formed on the grate, which absorbs gaseous components or gas stream dust (M. Pozin et al. Foam gas scrubbers, heat exchangers and absorbers. D., Goskhimizdat, I959. P. 47-5I)

The disadvantages of the known design are the relatively low gas velocity in the hollow section, usually not exceeding 2-2.3 m / s and a small foam layer height (about I00 mm). With a decrease in gas productivity, the height of the foam layer decreases, its structure enlarges,

reducing the surface of the gas contact. The operating mode of the apparatus goes into bubbling with a small living cross-section of the lattice or the lattice is completely exposed due to the free flow of liquid through the holes with a large living cross-section of the lattice. An increase in gas productivity leads to the formation of a wave regime on the grating, which leads to exposure of the grating sections and free passage of untreated volumes of gas through them.

In both cases, the efficiency of the apparatus decreases sharply.

Known foam gas scrubber, comprising a housing with gas inlet and outlet nozzles, inside which is a failure-type plate, as well as a foam stabilizer, an irrigation device and a separator (USSR author's certificate No. 434969, class B 0I d I7 / 04, publ. 06.07.74 .).

The use of a cellular foam stabilizer, which is located directly on the grill, can significantly improve the operating conditions of the apparatus, eliminate the formation of the wave regime, increase the gas velocity in the hollow section to 3 m / s and the height of the foam to I50 mm.

However, a foam scrubber with a foam stabilizer has an insufficient height of the foam layer, and as a result, a small gas-liquid contact surface, which is often insufficient for effective gas purification and entails the installation of multi-deck devices.

In order to increase the contact surface of the phases and reduce the specific hydraulic resistance, the known apparatus is equipped with a foam dispenser installed between the plate and the foam stabilizer and made in the form

multilayer mesh (USSR author's certificate No. 590002, class B 0I D 27/04. publ. 0I.02.78.).

The main disadvantage of such a foam apparatus is that it cannot be used to clean gases contaminated with impurities, prone to the formation of deposits. During operation, it is necessary to frequently stop such an apparatus for cleaning the grate, violating the hydrodynamic regime, which negatively affects the stability of the foam layer.

The specified disadvantage is eliminated in the device according to the patent of the USSR No. 1834692, class. B 0I D 47/04, publ. I5.08.93), which contains a dispersant, made in the form of a collector with nozzles for dispersing the washing liquid, located under the distribution grid, while the nozzles are oriented in the direction of gas flow in the flow part of the housing. With this orientation of the nozzles on the distribution grid, a layer of highly turbulent liquid emulsion is formed, which, together with the preliminary contact of the dispersed washing liquid with gas in the subgrid space, provides only dust cleaning of the gas. This design is not able to create a foam layer on the distribution grid sufficient to clean the gas from harmful impurities.

Closest to the claimed technical essence and the achieved result is the design of a foam mass transfer apparatus containing a vertical housing, nozzles for supplying and discharging gas, a collection of cleaning liquid located in the lower part of the housing, nozzles for supplying liquid and draining it, and also a gas distribution contact

a device made in the form of an absorption plate, including one or several grids, and the gas supply pipe is made passing through the side wall of the housing, and the outlet of the pipe is buried below the contact device in the subgrid space (RF patent No. 2165283 class B 0I D 3/28, 47 / 02, published April 20, 2006 - prototype).

The disadvantages of the known foam mass transfer apparatus are:

- uneven passage of the purified gas through the grid, which is a consequence of the lateral gas supply to the subgrid space, caused by the requirements of the compactness of the apparatus;

- uneven distribution of the cleaning fluid on the lower grid of the absorption plate, caused by the uneven distribution of the velocity of the gas capturing the liquid from the collector over the subgrid space from the side inlet of the gas to be cleaned.

The uneven distribution of the gas velocity arises due to a sharp change in the direction of gas flow in the space between the collector fluid and the lower grid. In addition, in this case, the liquid from the collector, trapped in a gas stream, penetrates through the lower grid only on one side.

Under such conditions, the gas supplied to the bottom grid from the side primarily passes through the grid at the nearest edge, since the resistance to gas passage through the grid should be equal to the resistance to gas passage in the subgrid space, constrained by the cleaning liquid. Local increases in gas velocity in the subgrid space knock the foam to the side formed on the lower grid when

the passage of gas from below through it, which reduces the resistance to gas movement in this place, increasing the passage of untreated gas through the lower grid, and through the upper grid with a two-grid design of the absorption plate. The number of such passes increases with increasing mesh size.

Thus, the uneven passage of the gas to be cleaned through the nets and the uneven distribution of the cleaning liquid over the surface of the nets are the reasons for the low degree of gas purification, and therefore the poor efficiency of the foam mass transfer apparatus.

The technical result of the utility model is the creation of a new design of a foam mass transfer apparatus with high work efficiency.

The technical result is achieved when creating the design of a foam mass transfer apparatus containing a vertical housing, nozzles for supplying and removing gas, a collection of cleaning fluid located in the lower part of the housing, nozzles for supplying cleaning fluid and draining it, as well as a gas distribution contact device made in the form of an absorption plates, including one or more grids, and the pipe for supplying the gas to be cleaned is made passing through the side wall of the housing, and the outlet of the pipe is deepened below the contour device in the subgrid space, in which, according to the invention, in the subgrid space there is a jet filter that includes a spray gun mounted along the axis of the apparatus body with the outlet of the cleaning fluid directed to the side walls of the housing.

The sprayer can be, for example, a centrifugal nozzle, a rotating or baffle nozzle, which create a continuous curtain in front of the grid, or it can be a set of separate jet whole-nozzle nozzles mounted around the circumference of the nozzle supplying the cleaning fluid from the collector.

In this design of the foam mass transfer apparatus, one part of the cleaned gas stream coming laterally into the subgrid space in the axial region passes to the lower grid of the absorption plate, capturing only the finely divided fraction of the cleaning liquid stream created by the atomizer, and the other part of the gas stream being cleaned is mixed with a droplet-liquid stream, created by the sprayer moves with it and undergoes primary cleaning in a swirling axisymmetric gas-liquid flow.

The gas stream exits the jet both in the upper and lower directions in the region of the subgrid space, forming a vortex and capturing the finely divided part of the droplets formed when large droplets hit the body walls. Due to the capture of part of the gas by liquid jets, the movement of the gas stream passing through the jet filter becomes axisymmetric and uniform. In addition, the stability of the gas flow increases due to the presence of a significant amount in the gas stream of fine droplets of cleaning liquid. This allows you to maintain a uniform layer of foam in height on the nets and increase its stability.

Thus, installation in the subgrid space

the proposed design of the jet filter, allows to achieve a technical result, which consists in increasing the efficiency of cleaning gas passing through the foam mass transfer apparatus.

A comparative analysis of the inventive foam mass transfer apparatus and the prototype reveals the distinctive features of the claimed utility model in comparison with the closest analogue, which allows us to conclude that the claimed device meets the criterion of utility model "novelty".

The presence of distinctive features makes it possible to obtain a positive effect, which consists in creating a new device for a foam mass transfer apparatus that increases the efficiency of gas purification.

The use of the claimed utility model in the manufacture of devices that implement heat transfer processes, in particular foam scrubbers, ensures that it meets the criterion of "industrial applicability".

The inventive foam mass transfer apparatus is shown in the drawing, in which Fig. I shows a General view of it in section, and figure 2 is a section along aa with a top view of the spray gun, made in the form of a set of separate inkjet solid torch nozzles.

Foam mass transfer apparatus includes a vertical housing I, nozzles for supplying 2 and gas outlet 3, a collection of cleaning fluid 4 located in the lower part of housing I, nozzles 5 for supplying cleaning fluid and its discharge 6, as well as a gas distribution contact device made in the form of an absorption plate including one or

several grids 7, and the nozzle 2 for supplying the gas to be cleaned is made passing through the side wall of the housing I, and the outlet of the nozzle 2 is recessed below the contact device into the subgrid space 8, in which there is a jet filter, the atomizer of which is installed along the axis of the housing I with the outlet of the cleaning liquid, directed to the side walls of the housing I of the apparatus.

In such a foam mass transfer apparatus, the atomizer can be made in the form of a nozzle 9, made, for example, by centrifugal, rotating or jack-off. The sprayer can also be made in the form of a set of separate inkjet solid torch nozzles I0 located around the circumference of nozzle II, which supplies cleaning fluid from collector 4 to them.

The foam mass transfer apparatus operates as follows. The crude gas enters the apparatus housing I through the nozzle 2 under the influence of fan I2 into the subgrid space 8, where under the action of the sprayed cleaning liquid an axisymmetric gas-liquid flow is formed, which enters the upper surface of the grid 7, uniformly distributed over it in the form of foam. At the same time, fine droplets participate in the formation of foam, which are formed not only when the liquid exiting the atomizer is crushed, but also when the stream of atomized liquid strikes the side walls of the housing I. Thus, the subgrid space 8 is filled with a gas-liquid axisymmetric jet, forming a jet filter, in which is the primary gas purification from harmful impurities. Saturation of the gas stream with finely divided drops of a cleaning liquid,

moving with it, increases the inertia of the gas stream, further stabilizing the movement of gas when it hits the grid. Gas passes through the lower grid 7 together with small drops of cleaning liquid, which, partially settling on the grid, form a foam layer, in which droplets that have not settled on the grid are also trapped. Next, the gas stream passes through the upper grid 7 with a foam layer, which is formed by irrigation of it from above through the pipe 5 of the cleaning fluid.

In the case of a two-grid type of absorption plate, the mesh can be made of both a failure and an overflow design. In the case of performing the lower overflow mesh, the liquid forming the foam is continuously drained through the overflow pipe 6 to the cleaning fluid collector 4 or to another container, from where the cleaning fluid is again pumped into the apparatus by pump I3 through the pipes 5 and II. Next, the gas passes through droplet eliminator I4 and leaves purified through pipe 3.

In the inventive design of the foam mass transfer apparatus, the absorption plate can be made both woven from polymer or metal threads, and non-woven plastic or metal.

The inventive design of the foam mass transfer apparatus, having a more efficient gas purification, compares favorably with the prototype.

Claims (5)

1. Foam mass transfer apparatus comprising a vertical housing, nozzles for supplying and discharging gas, a collection of cleaning fluid located at the bottom of the housing, nozzles for supplying cleaning fluid and draining it, as well as a gas distribution contact device made in the form of an absorption plate including one or several grids, and the pipe for supplying the gas to be cleaned is made passing through the side wall of the housing, and the outlet of the pipe is buried below the contact device in the subgrid space, characterized in that in the subgrid space there is a jet filter, which includes a spray installed along the axis of the apparatus with the output of the cleaning fluid directed to the side walls of the housing. 2. Foam mass transfer apparatus according to claim 1, characterized in that the atomizer is made in the form of a centrifugal nozzle. 3. Foam mass transfer apparatus according to claim 1, characterized in that the atomizer is made in the form of a rotating nozzle. 4. Foam mass transfer apparatus according to claim 1, characterized in that the sprayer is made in the form of a jack-off nozzle. 5. Foam mass transfer apparatus according to claim 1, characterized in that the atomizer is made in the form of a set of separate inkjet solid torch nozzles installed around the circumference of the nozzle supplying the cleaning liquid from the collection.