RU2448747C1 - Device for contaminated air preservation and cleaning - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to contaminated air cleaning and preservation. Proposed device comprises blower with inlet and outlet communicated via aid ducts with premise. Air cleaning unit is arranged at intake air duct while foam generator is arranged at discharge air duct and provided with foam generating fluid source. Foam destructor with separator is arranged between air cleaning unit and protected premise. Intake air duct communicates via its section with premise top zone and, via additional air duct, with inflatable envelopment arranged outside of said premise. Ejector-type foam generator comprises casing with flanges on end faces to accommodate foam forming solution feed nozzle. Casing side surfaces have air feed holes. Mixing chamber is arranged inside said casing. Ejector made up of tapered shell with cowl representing 2nd-order surface of revolution, i.e. ball, ellipsoid, is arranged inside nozzle. Ejector is attached to nozzle by three ejector tubes Mixing chamber is arranged aligned with said nozzle and made up of aligned confuser, cylindrical section and diffuser with its larger base secured to the flange.

EFFECT: higher efficiency of cleaning.

1 cl, 2 dwg

Description

The invention relates to the field of air purification and regeneration, for example, for the purification of heavily polluted air in sealed rooms under conditions of a deficit of clean air and the impossibility of removing polluted air outside the premises into the environment.

The closest in technical essence and the achieved result is a device for air purification in the room, containing a fan, the inlet and outlet of which is connected to the protected room by air ducts with shut-off and control valves, while an air-cleaning unit is installed on the intake duct, and a foam generator is additionally installed on the discharge duct equipped with a source of foaming liquid (RF patent 2161056, class AB 11/00 - prototype).

However, the occurrence of high gas contamination is often accompanied by a significant increase in pressure indoors (for example, during depressurization of containers with toxic volatile substances in a room, when depressurization of process equipment, in the event of a fire indoors, etc.). In these cases, a strong increase in pressure inside the sealed room can cause its depressurization and lead to the penetration of harmful impurities into adjacent rooms, which further complicates the further cleaning process and increases the cleaning time. This circumstance is a disadvantage of the known solutions.

A technically achievable result is an increase in cleaning efficiency by increasing its speed and quality.

This is achieved by the fact that in the device for preservation and purification of contaminated air containing a fan, the inlet and outlet of which are connected to the protected room by air ducts with shut-off and control valves, an air-cleaning unit is installed on the intake duct, and a foam generator is additionally installed on the discharge duct, equipped with a source of foaming fluid, located on the suction duct between the air-cleaning unit and the protected room is a foam destructor, equipped a separator, wherein said suction duct between the fan and the air-cleaning unit is additionally connected to the upper zone of the room to be protected by a duct section with shut-off and control valves, and between the foam destructor and the air-cleaning unit, this suction duct is simultaneously connected by an additional duct equipped with shut-off and control valves to the upper zone of the protected rooms and an additional air duct - with an inflatable shell located outside the protected room In this case, the foam generator is made of an ejection type and contains a cylindrical body with flanges at the ends, in one of which there is a nozzle for supplying an aqueous solution of a foaming agent, and holes for supplying air are made in the side surface of the housing, a mixing chamber is mounted inside the housing opposite the nozzle and attached with a large base to flange opposite the nozzle.

Figure 1 shows a device for the preservation and purification of polluted air, figure 2 is a diagram of a foam generator.

A device for the preservation and purification of polluted air (Fig. 1) consists of a fan 1, the inlet and outlet of which is connected to the protected room 2 by air ducts 3 with shut-off and control valves 4, 5, of an air-cleaning unit 6 mounted on the suction duct. A foam generator 7 is installed on the discharge duct, which is connected to the protected space 2 by the duct 8 and is provided with a source of foaming liquid. On the suction duct between the air-cleaning unit 6 and the protected room 2 is a foam 9 equipped with a separator. In addition, the line of the suction duct between the fan 1 and the air-cleaning unit 6 is additionally connected to the upper zone of the protected room 2 by a section of the duct 10 with shut-off and control valves 11, and the line of the suction duct between the foam destructor 9 and the air-cleaning unit 6 is connected by an additional air duct 12 equipped with a shut-off control valves 13, with the upper zone of the protected room 2 and an additional duct 14 with an inflatable shell 15 located outside the protected Oia 2.

The ejection-type foam generator (Fig. 2) comprises a cylindrical body 16 with a flange 17 fixed at one of its ends, in which a hole 19 is made for supplying an aqueous solution of a foaming agent. A nozzle 18 of a conical shell for attaching an aqueous solution of a foaming agent is turned to the flange 17 coaxially to the housing 16, facing the tip of the cone in the direction opposite to the flange 17. Inside the nozzle 18 there is an ejector 21 made in the form of a conical shell 20 with a cowl 6 forming with a conical shell 20 conical cavity 22, and the fairing 6 in shape is made in the form of a surface of revolution of the second order, for example a ball, ellipsoid, paraboloid, etc.

The conical shell 20 of the ejector is aligned with the conical shell 18 of the nozzle, the conical surfaces of the nozzle 18 and the ejector 21 having equal angles at the vertices of the cone forming them. Between the conical shells of the nozzle 18 and the ejector 20 there is a gap 24 of the annular type with a variable cross-section, which ensures an increase in the speed of the foaming agent aqueous solution, the velocity of the ejected air and, consequently, the formation of finely dispersed foam.

The ejector 21 is attached to the nozzle 18 by means of at least three ejection tubes 25, one end of which is located in the cavity 22 and the other in the cavity of the cylindrical body 16. A cylindrical horizontal duct 23 is coaxially attached to the cone shell 20 of the ejector, at the cut of which are placed at least three radial ducts 26 located in a plane perpendicular to the axis of the housing and fixed at one end to the housing 16, their axes being radially and uniformly in this plane, and the free end of the radial air of the ducts is located at the cut of the horizontal duct 23. Opposite and coaxial to the nozzle 18, a mixing chamber is installed, consisting of a coaxial confuser 27, a cylindrical part 28 and a diffuser 29, attached by a large base to a flange (not shown) for foam exit. The diffuser 29 may be made mesh.

A device for the preservation and purification of polluted air works as follows.

The device can operate in three main modes: in conservation mode, in pre-cleaning mode and in final cleaning mode.

In the preservation mode, the shut-off and control valves 4, 5 are successively closed, the shut-off and control valves 11, 13 are opened, the fan 1 is turned on and the foam-forming liquid is supplied to the foam generator 7.

An aqueous solution of the foaming agent in the foam generator 7 is supplied under pressure through the inlet openings of the nozzle 18 and enters the annular gap 24. Due to the kinetic energy of the jet, the air in the internal cavity of the housing is sucked in by the outer surface of the jet moving at high speed through the ducts 25 and 26 into the mixing chamber , which contributes to the variable cross section of the annular gap 24. This air, being in a confined space inside the jet, is guaranteed to be delivered to the mixing chamber, where the formation of foam is required emoy multiplicity. Between the conical shells of the nozzle 18 and the ejector 20 there is a gap 24 of the annular type with a variable cross-section, which ensures an increase in the speed of the foaming agent aqueous solution, the velocity of the ejected air and, consequently, the formation of finely dispersed foam. In this case, the contaminated air is sucked out of the protected room 2 through the duct 10 through the duct 10 and mixed with the foaming liquid in the foam generator 7, and the foam formed during mixing is introduced into the room 2 until it is completely filled. Excessive amount of polluted air (in the presence of increased pressure inside the protected room 2) through the ducts 12 and 14 enters the inflatable shell 15 located outside the protected room (for example, in an adjacent room).

When this mode is implemented, overpressure is released and the “packaging” of contaminated air into the foam bubbles, which prevents the possibility of further spread of pollution to adjacent rooms. If long-term storage of “packaged” (“preserved”) into the foam of contaminated air is assumed, then it seems advisable to use a foam of high multiplicity (a multiplicity of at least 1000), and additional additives with sorption and catalytic activity with respect to those contained in the foam-forming liquid should be additionally added. air pollution and contributing to the removal of toxic substances from the air. As such additives, finely dispersed activated carbon or other adsorbent, finely dispersed catalysts, liquid and solid chemisorbents, soluble in a foaming liquid, and various mixtures thereof can be used.

When implementing the pre-treatment mode, close the control and control valves 5, 10 and open the control and control valves 13, 4, turn on the fan 1 and supply the foaming liquid from the source 9 to the foam generator 7. Moreover, the contaminated air from the room 2 due to the vacuum created fan 1, through a section of duct 12 enters the air-cleaning unit 6, where it is cleaned of contaminants. Then the purified air is mixed in the foam generator 7 with a foaming liquid and introduced into the room. The excess amount of polluted air through the air ducts 12 and 14 enters the inflatable shell 15 located outside the protected room 2. As a result of this mode, polluted air is removed from the protected room with its subsequent cleaning in the air-cleaning unit 6, and the cleaned air is “packed” in foam and introduced into the protected room 2. Since during the implementation of this regime the "packaging" of purified air is made into foam, there is no mixing of clean and polluted air, but the displacement of polluted air from the room is carried out in a piston mode.

The third mode of operation of the device can be implemented if necessary after the implementation of the first or second mode. This mode is used for the final cleaning of the internal volume of the space to be protected and the removal of contaminants contained in the gas containers of the foam bubbles, in the foaming liquid and in the inflatable shell. To implement this mode, close the control and control valves 11, 13, open the control and control valves 4, 5 and turn on the fan 1. At the same time, the foaming liquid is not supplied to the foam generator 7 at all, or for some time at the beginning of the third mode, and then The fan 1 creates a vacuum in the intake air and the foam is sucked out of the room 2 into a foam destructor 9, equipped with a separator, where the gas phase is separated from the foaming liquid. Next, the gas phase passes through the air-cleaning unit, where contaminants are removed from it, and the purified gas mixture is fed into the upper zone of room 2, displacing the foam in room 2 into the foam destructor 9. At the same time, the contaminated air contained in the inflatable shell 15 due to rarefaction created by the fan 1 in the suction duct, and due to the rarefaction resulting from the removal of gaseous contaminants in the air cleaning unit 6, is gradually sucked out of the inflatable shell, cleaned and served in a protected room 2. It should be noted that in the event of a situation when, after removing the main volume of foam from the room, the inflatable shell is not yet completely blown away, it is possible by forced compression of the inflatable shell 7 to remove the remains of polluted air from it.

Thus, when implementing the third mode of operation of the device, the piston displacement effect is also realized, since there is practically no mixture of clean and polluted air.

The increase in cleaning speed is determined by the fact that during the operation of the device there is a piston effect of displacing contaminated air from the room, at which it does not mix with clean air.

The proposed technical solution has a particularly great advantage when it comes to gas contamination associated with a fire in a protected room. This is due to the fact that the foam has good fire extinguishing properties and therefore the processes of smoke removal and fire extinguishing can be combined. Moreover, in this case, it is possible not only to effectively eliminate the fire source and prevent the spread of fire products into adjacent rooms, but also to save a significant amount of oxygen contained in the air, since the implementation of the proposed technical solution involves the "packing" of oxygen into the foam, which prevents its access to the source fires.

The improvement in the quality of cleaning is explained by the fact that the foam, having a good washing action, removes toxic contaminants that have condensed and settled there on various objects and which are very slowly removed during the implementation of traditional ventilation schemes.

The proposed technical solution has a particularly great advantage in the quality of cleaning when it comes to the occurrence of a fire in a protected room. Obviously, the amount of contaminants that have settled, adsorbed and condensed on various objects in the room depends on the contact time of the pollution with these objects, and since the implementation of the proposed technical solution, starting from the moment of the fire, the fire products are isolated in foam bubbles, the duration (direct) contact of contaminants with objects in the room is negligible. In contrast, with traditional ventilation schemes, air purification can only begin some time after the fire is extinguished, since the immediate application of a traditional cleaning system is not possible, as this will impede the fire fighting process.

The improvement in cleaning quality is also due to the fact that the proposed device prevents the appearance of high excess pressure inside the protected room due to the discharge of part of the gas phase into the inflatable shell located in the adjacent room. Thus, the air pressure in adjacent rooms is equalized, and this prevents the leakage of harmful substances from the protected room. The fact that during the mixing of the gas phase and the foaming liquid there is a cooling effect of the gas phase and the effect of sorption absorption of a number of gaseous substances also contributes to the reduction of pressure inside the protected room.

On the other hand, foam, especially foam of high multiplicity, having good sorbing ability, provides partial preliminary purification of air from some aerosol and gaseous contaminants, which leads to lower costs of basic cleaning agents used in the air-cleaning unit.

All this allows to significantly increase the speed and quality of cleaning and, as a result, the overall cleaning efficiency as a whole.

The present invention can be used to preserve fire gases and purify the air of sealed rooms from fire products, for example, on orbital space stations and other spacecraft.

Claims (1)

A device for the preservation and purification of contaminated air, containing a fan, the inlet and outlet of which is connected to the protected room by air ducts with shut-off and control valves, an air-cleaning unit is installed on the suction duct, and a foam generator, equipped with a source of foaming liquid, is additionally installed on the suction duct, on the suction a foam destructor equipped with a separator is located between the air cleaning unit and the space to be protected, and the intake duct between the fan and the air-cleaning unit is additionally connected to the upper zone of the room to be protected by a duct section with shut-off and control valves, and between the foam destructor and the air-cleaning unit this suction duct is simultaneously connected by an additional duct equipped with shut-off and control valves with the upper zone of the room to be protected and an additional air duct - with an inflatable shell located outside the protected space, characterized in that The foam generator is made of an ejection type and contains a cylindrical body with flanges at the ends, in one of which a nozzle for supplying an aqueous solution of a foaming agent is installed, and holes for supplying air are made in the side surface of the body, a mixing chamber is installed inside the body opposite the nozzle and attached with a large base to the flange opposite the nozzle, and the nozzle is made of a conical shell facing the top of the cone in the direction opposite to the flange for supplying an aqueous solution of a foaming agent, and inside the nozzle an ejector is arranged in the form of a conical shell with a cowl forming a conical cavity with a conical shell, the cowling being shaped as a second-order rotation surface, for example, a ball, an ellipsoid, and the conical shell of the ejector is coaxial with the conical shell of the nozzle, between the conical shells of the nozzle and the ejector there is a gap of annular type with a variable cross-section, and the conical surfaces of the nozzle and ejector have equal angles at the vertices of the cone that forms them, and the ejector is attached to the nozzle at least three ejection tubes, one end of which is located in the cavity and the other in the cavity of the cylindrical body, with a cylindrical horizontal duct coaxially attached to the cone shell of the ejector, at the edge of which at least three radial ducts are located in a plane perpendicular to the housing axis, and fixed at one end to the housing, their axes being radially and uniformly in this plane, and the free end of the radial ducts is located at the cut of the air duct, and opposite and coaxial to the nozzle, a mixing chamber is installed, consisting of a confuser, a cylindrical part and a diffuser, coaxial with each other, attached to the flange with a large base.

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