RU137933U1 - REGENERATIVE CARTRIDGE OF INSULATING RESPIRATORY APPARATUS - Google Patents

Abstract

1. The regenerative cartridge of an insulating breathing apparatus, including a sealed enclosure with an inhalation-expiration nozzle and a breathing bag nozzle, a perforated shell mounted in a housing with an annular gap relative to the side wall of the housing and made with a central channel with perforated walls, a regenerative product located in the perforated cavity shells, heat and gas distributor located in the volume of the regenerative product, while the specified Central channel is connected to the pipe inhalation-exhalation and said annular gap is connected to the nozzle of the breathing bag, characterized in that the heat and gas distributor is made in the form of perforated plates radially mounted between the perforated shell and the central channel in the volume of the regenerative product, one of the sides of each perforated plate is made with a longitudinal U-shaped in transverse section bending, the walls of the U-shaped bends of adjacent perforated plates are connected in series with each other with the formation of a Central channel, limited about the shelves of the U-shaped bends. 2. The regenerative cartridge according to claim 1, characterized in that the body and perforated shell are cylindrical. The regenerative cartridge according to claim 1, characterized in that the sections of the perforated plates placed in the volume of the regenerative product are made with a longitudinal bend. The regenerative cartridge according to claim 1, characterized in that the central channel in its lower part is blocked by a swab made of a gas-permeable material, crushed under the action of mechanical forces, and installed with the possibility of

Description

The invention relates to respiratory protection devices, in particular to self-rescuing self-rescuers with chemically bonded oxygen, used in mining, chemical and other industries.

Self-rescuers are designed for emergency short-term respiratory protection in emergency situations associated with the formation of an environment unsuitable for breathing.

The main indicators of consumer properties of self-rescuers are: the time of the protective action, breathing resistance, temperature of the gas mixture, weight and dimensions, simplicity and manufacturability of the design.

As a rule, a self-rescuer includes a sealed case with means for carrying a self-rescuer (belts, buckles, etc.), a regenerative cartridge placed in the case and filled with a regenerative product, a starting device connected to a regenerative cartridge, means that realize a closed self-rescuer operation cycle and a selected movement pattern gas mixture (corrugated tube connecting the human respiratory system with a self-rescuer, a breathing bag, a system of gas channels in a regenerative cartridge). To reduce the temperature of the regenerative product and its uniform distribution over the volume of the regenerative product, as a rule, a heat and gas distributor is installed in the cavity of the regenerative cartridge in the volume of the regenerative product.

According to the gas mixture movement pattern, among the known self-rescuers, two groups can be distinguished - self-rescuers with the sequential movement of the gas mixture and self-rescuers with the pendulum scheme of the gas mixture.

In self-rescuers with the sequential movement of the gas mixture, the exhaled gas mixture enters the regenerative product, where carbon dioxide, moisture, and oxygen are enriched in the gas mixture. The purified gas mixture enters the breathing bag. When inhaling, the gas mixture from the breathing bag enters the respiratory system. That is, in one “inhale-exhale” cycle, the gas mixture passes once through the volume of the regenerative product.

In self-rescuers with a pendulum gas mixture flow pattern, the exhaled gas mixture flows to the regenerative product, where carbon dioxide, moisture, and oxygen are enriched in the gas mixture. The purified gas mixture enters the breathing bag. When inhaling, the gas mixture from the breathing bag passes in the opposite direction through the regenerative product, where it is further purified from carbon dioxide, additionally enriched with oxygen and supplied to the respiratory system. In one “inhale-exhale” cycle, the gas mixture passes twice through the volume of the regenerative product, which increases the degree of regeneration of the gas mixture with the same characteristics of the self-rescuer.

In addition, known self-rescuers can be divided in the direction of movement of the gas mixture through the regenerative cartridge — with an axial direction when the gas mixture passes through the regenerative product along the longitudinal axis of the cartridge, and with a radial direction when the gas mixture is directed through the regenerative product perpendicular to the longitudinal axis of the cartridge, as as a rule, using a central perforated tube for supplying (discharging) a gas mixture.

Given the design features of the inventive regenerative cartridge, the known solutions were subject to analysis, in which a pendulum scheme of the gas mixture with a radial passage of the gas mixture through the regenerative cartridge using a central perforated tube was implemented.

Known regenerative cartridge insulating breathing apparatus according to the patent of the Russian Federation for invention No. 2091099, IPC A62B 19/00, filing date 07/19/1997.

The regenerative cartridge contains an oval-shaped housing in which a shell is mounted coaxially with an annular gap relative to its inner surface. Along the longitudinal axis of the cartridge housing is a central perforated tube in which the filter is located. A granular regenerative product is poured between the shell and the central tube. Above the regenerative product is a starting briquette. A trigger device and nozzles for attaching a breathing bag and a respiratory isolation unit are fixed on the lid.

The shell has an oval shape. The surface of the shell is made with perforated and non-perforated sections. Non-perforated sections are located on opposite sides of the shell relative to its larger axis along the entire height of the shell. Perforated sections are located on opposite sides of the shell along its entire height. The width of the perforated and non-perforated sections is selected experimentally, taking into account the size of the layer of the regenerative product, the grain size of the regenerative product, the speed of the circulating air flow. The direction of air flow in the cartridge is radial, that is, perpendicular to the longitudinal axis of the cartridge.

The assembly of the cartridge is carried out in the usual way for such products. A regenerative product is poured into the casing with a central tube pre-installed in it, a starting briquette is installed and the casing is closed with a housing with a lid. Then a filter is installed in the central tube.

According to the applicant, the invention allows to simplify the design of the regenerative cartridge and to increase the manufacturability of its manufacture while ensuring the efficient operation of the regenerative product.

Common features of the analogue and the claimed solution are: a regenerative cartridge of an insulating breathing apparatus, including a sealed enclosure with a nozzle of an inhalation-expiration and a nozzle of a breathing bag, a perforated shell mounted in a housing with an annular gap relative to the side wall of the enclosure and made with a central channel with perforated walls, regenerative the product is placed in the cavity of the perforated shell, while the specified Central channel is connected to the pipe inhalation-expiration, and the specified number The front clearance is connected to the nozzle of the breathing bag.

In the process of regeneration of the exhaled gas-air mixture in the regenerative product, exothermic reactions occur with the release of a large amount of heat. As a result, local zones with a high temperature arise in the volume of the regenerative product, in which melting of the components of the regenerative product is possible. The occurrence of such zones affects the gas dynamics of the passage of gases through the volume of the regenerative product, reduces the degree of use (development) of the regenerative product. The air coming from the regenerative cartridge through the corrugated tube to the respiratory system has a high temperature. Hot air introduces additional stress to the user in an emergency, and can lead to disconnection from the device. The execution of the shell and shell oval, as well as the presence of non-perforated sections of the shell, cause uneven development of the regenerative product due to the uneven distribution of flows of the gas-air mixture in the volume of the regenerative product.

For uniform temperature distribution in the volume of the regenerative product in known regenerative cartridges, heat and gas distributors are used that prevent the occurrence of local zones with high temperature, ensure uniform temperature distribution and the removal of excess thermal energy outside the cartridge.

Thus, the regenerative cartridge of an insulating breathing apparatus according to the German patent for invention No. 2852240, IPC A62B 19/00, the filing date of 02/02/1978, including an oval-shaped housing with a lid and a bottom, a shell with a perforated coaxially installed in the housing with perforated sections located on opposite sides, is known sides of the shell symmetrically with respect to the minor axis of the cross section of the shell. Crescent-shaped gaps are formed between the inner surface of the housing and the perforated sections of the shell. A central perforated tube is located in the housing. A regenerative product is placed in the cavity between the tube and the shell, which is divided into layers by metal nets. In addition, intermediate U-shaped elements are installed on the grids, the presence of which together with the grids contributes to a uniform temperature distribution over the volume of the regenerative product and the removal of the reaction heat.

Common features of the analogue and the claimed solution are: a regenerative cartridge of an insulating breathing apparatus, including a sealed enclosure with a nozzle of an inhalation-expiration and a nozzle of a breathing bag, a perforated shell mounted in a housing with an annular gap relative to the side wall of the enclosure and made with a central channel with perforated walls, regenerative product placed in the cavity of the perforated shell, heat and gas distributor placed in the volume of the regenerative product.

The presence in the volume of the regenerative product of many horizontal grids with intermediate U-shaped elements complicates the product, increases its mass. The need for layer-by-layer filling of the regenerative product into the cartridge during the successive installation of horizontal grids in it significantly increases the complexity of the product collections.

Also known is the regenerative cartridge of the insulating breathing apparatus according to the patent of Ukraine for utility model No. 56898, IPC A62B 19/00, A62B 7/08, application filing date 08/12/2010, consisting of a body with an inhalation-expiration nozzle for connecting an air duct, a cover with fixed to mesh (made of metal mesh) shell and central tube. The shell is installed with an annular gap relative to the housing. The annular gap is connected to the pipe inhalation-exhalation. The central tube is connected to the cavity of the respiratory sac. Inside the shell (between the shell and the central tube) is a regenerative product and a plate heat and gas distributor. The heat and gas distribution plates are mounted radially relative to the central tube and are interconnected by a peripheral hoop. Plates are not perforated. The regenerative product is pressed down with springs. Between the regenerative product and the housing cover, as well as between the regenerative product and the bottom, fiberglass layers are placed to prevent the gas-air mixture from passing along the surfaces of the cover and the bottom, bypassing the granules of the regenerative product. The cartridge case has a round shape, which ensures uniform processing of the layers of the regenerative product in all directions, reduces the mass of the regenerative product, breathing resistance and temperature of the inhaled air. The manufacture of a shell and a central tube from a metal mesh makes it possible to reduce the cost of production by reducing the metal consumption of the regenerative cartridge and the possibility of using regenerative products of different fractions in the cartridge.

Regenerative cartridge works as follows.

During exhalation, a gas mixture with a high content of carbon dioxide through the nozzle enters the annular gap between the cartridge housing and the mesh shell, passes through the mesh shell and the regenerative product, in which carbon dioxide absorption and oxygen evolution reactions occur. The gas-air mixture then flows through the central tube into the breathing bag. During inspiration, the gas-air mixture, in which the regeneration reactions have already passed, comes from the breathing bag in the opposite direction, additionally enriched with oxygen.

Common features of the analogue and the claimed solution are: a regenerative cartridge of an insulating breathing apparatus, including a sealed enclosure with a nozzle of an inhalation-expiration and a nozzle of a breathing bag, a perforated shell mounted in a housing with an annular gap relative to the side wall of the enclosure and made with a central channel with perforated walls, regenerative product placed in the cavity of the perforated shell, heat and gas distributor placed in the volume of the regenerative product.

The pendulum scheme of the movement of the gas-air mixture, involving the connection of the inhalation-exhalation pipe with an annular gap between the shell and the body with the connection of the cavity of the breathing bag with a central perforated tube, increases the volume of the gas-air mixture that does not participate in the regeneration process (the so-called "harmful volume"), which leads to an increase in carbon dioxide in the gas mixture inhaled by the user.

The peripheral hoop connecting the plates of the heat and gas distributor increases breathing resistance and “obscures” the regenerative product adjacent to the hoop, impairing the uniform penetration of the gas mixture into the regenerative product.

The absence of perforation of the heat exchanger plates worsens the gas dynamics of the regeneration process, since it complicates the penetration of the gas-air mixture deep into the volume of the regenerative product.

As a prototype, the regenerative cartridge of an insulating breathing apparatus according to the patent of the Russian Federation for invention No. 2414941, IPC A62B 19/00, the filing date of the application was December 23, 2009.

The regenerative cartridge of the insulating breathing apparatus includes an oval sealed enclosure, a perforated oval shell with a lid and a central channel formed by a perforated tube placed along the longitudinal axis of the cartridge. A perforated shell is installed in the housing with a gap relative to the side wall of the housing. The upper end of the perforated tube is connected to the inhalation-exhalation pipe, the lower end is closed. The gap between the housing and the perforated shell is connected to the nozzle of the breathing bag. In the cavity of the perforated shell is a regenerative product. A heat and gas distributor is placed in the volume of the regenerative product. The heat and gas distributor is made in the form of a cylinder of three interconnected coaxial perforated shells. The average perforated shell is made corrugated. In this case, the end parts of the heat and gas distributor are in contact with the cover of the perforated shell.

Regenerative cartridge works as follows.

The gas-air mixture from the user's respiratory system enters the central channel formed by a perforated tube. Further, through the perforation of the tube, the gas-air mixture enters the cavity of the perforated shell filled with the regenerative product, where the regeneration process begins - the absorption of water vapor and carbon dioxide and the evolution of oxygen by the regenerative product. The heat energy released during exothermic processes goes to heat the regenerated air that enters sequentially through the shells of the heat and gas distributor - first through the internal, then through the middle and then through the external perforator oval shell. In this case, most of the heat from the regenerated air flow as a result of the high thermal conductivity of the metal is transferred to the heat and gas distributor, then to the shell cover through the contact surfaces and further to the metal housing of the cartridge, from which thermal energy is dissipated into the environment. Less thermal energy is accumulated by the regenerative product.

Common features of the prototype and the proposed solution are: a regenerative cartridge of an insulating breathing apparatus, including a sealed enclosure with a nozzle of an inhalation-expiration and a nozzle of a breathing bag, a perforated shell mounted in a housing with an annular gap relative to the side wall of the housing and made with a central channel with perforated walls, regenerative product placed in the cavity of the perforated shell, heat and gas distributor placed in the volume of the regenerative product, while bonded central channel is connected with a branch pipe breaths, and said annular gap is connected to the breathing bag nozzle.

The disadvantages of the regenerative cartridge, selected as a prototype, include the following:

- the absence of heat and gas distribution elements in the most active zone of exothermic reactions - around the central channel - increases the likelihood of local high-temperature zones with possible melting of the components of the regenerative product, which worsens the gas dynamics of the passage of gases through the volume of the regenerative product, reduces the degree of use of the regenerated product;

- low efficiency of heat removal to the shell (design with a sufficiently high heat capacity), since the elements of the heat and gas distributor do not contact directly with the shell, which limits the possibilities of heat removal from the volume of the regenerative product;

- the execution of the shell and the oval shell causes uneven development of the regenerative product due to the uneven distribution of the flows of the gas-air mixture in the volume of the regenerative product.

All of the above worsens the conditions of heat and mass transfer in the regenerative cartridge, reduces the efficiency of the process of regeneration of the gas-air mixture.

In addition, it should be noted that the location of the cylindrical heat and gas distributor in the cavity of the shell in the axial direction with emphasis on the cover of the shell causes technical problems of maintaining the regenerative product in a constantly compressed state. In the process of shrinkage of the regenerative product in its upper part, the formation of cavities is possible through which the gas-air mixture will pass, bypassing the regenerative product, which reduces the efficiency of regeneration.

The utility model is based on the task of improving the regenerative cartridge of an insulating breathing apparatus, in which, by improving the heat and mass transfer conditions in the regenerative cartridge, the efficiency of the gas-air mixture regeneration process increases without reducing the manufacturability of the product.

The problem is solved in that in the regenerative cartridge of an insulating breathing apparatus, including a sealed enclosure with a nozzle of an inhalation-expiration and a nozzle of a breathing bag, a perforated shell mounted in a housing with an annular gap relative to the side wall of the enclosure and made with a central channel with perforated walls, a regenerative product located in the cavity of the perforated shell, heat and gas distributor located in the volume of the regenerative product, with the specified central the channel is connected to the inspiratory-expiration pipe, and the specified annular gap is connected to the pipe of the breathing bag, according to the utility model, the heat and gas distributor is made in the form of perforated plates radially mounted between the perforated shell and the central channel in the volume of the regenerative product, one of the sides of each perforated the plate is made with a longitudinal U-shaped bend in cross section, the walls of the U-shaped bends of adjacent perforated plates are connected in series between battle with the formation of the central channel, limited by the shelves of the U-shaped bends.

These features are essential features of a utility model.

It is advisable that the body and perforated shell be made cylindrical, which ensures uniform development of the regenerative product in all directions.

It is advisable that the sections of the perforated plates placed in the volume of the regenerative product be made with a longitudinal bend to increase the contact area of the perforated plates with the regenerative product and the gas-air mixture.

It is advisable to block the central channel in its lower part with a tampon made of a gas-permeable material crumpled by mechanical forces and install it with the possibility of supporting it into the bottom of the body. The specified design feature allows you to constantly maintain a compressed state of the regenerative product.

It is also advisable to make perforated plates from a metal mesh, which increases the manufacturability of the structure.

The essential features of the utility model are in a causal relationship with the result achieved.

Thus, the distinguishing features of the utility model (the heat and gas distributor is made in the form of perforated plates radially mounted between the perforated shell and the central channel in the volume of the regenerative product, one of the sides of each perforated plate is made with a longitudinal U-shaped cross section in the cross section, the walls of the U-shaped bends adjacent perforated plates are connected in series with each other to form a central channel bounded by shelves of U-shaped bends) in conjunction with uschestvennymi features common with the prior art, provide improved efficiency of the regeneration process the gas mixture by improving the conditions of heat and mass in a regenerative cartridge.

This is explained by the following.

The implementation of the heat and gas distributor in the form of perforated plates radially mounted between the perforated shell and the central channel and in contact with them ensures a uniform distribution of temperature and air-gas mixture flows in the volume of the regenerative product, efficient heat removal from the most active zone of exothermic reactions (around the central channel), which prevents the emergence of local high-temperature zones with the possible melting of the components of the regenerative product that degrade gas the dynamics of the passage of gases through the volume of the regenerative product and reducing the degree of use of the regenerative product.

The perforated plates of the heat and gas distributor are in direct contact with the shell, which contributes to the efficient removal of heat from the volume of the regenerative product to the shell, as a structural element with a sufficiently high heat capacity, and further into the environment.

The cylindrical shape of the body and the shell provide uniform testing of the layers of the regenerative product in all directions.

The implementation of perforated plates with a longitudinal bend increases the area of their contact with the regenerative product and the gas-air mixture, facilitates the penetration of the gas-air mixture deep into the volume of the regenerative product.

All of the above is aimed at improving the conditions of heat and mass transfer in a regenerative cartridge, increasing the efficiency of the process of regenerating a gas-air mixture.

The manufacture of perforated plates the same, the use of a metal mesh for their manufacture, as well as the ability to connect the same plates with the simultaneous formation of a Central perforated channel significantly increases the manufacturability of the product.

The following is a detailed description of the inventive regenerative cartridge insulating breathing apparatus with reference to the drawings, which show:

Figure 1 - Regenerative cartridge insulating breathing apparatus, a longitudinal section.

Figure 2 - Regenerative cartridge insulating breathing apparatus, section aa in figure 1.

Figure 3 - Regenerative cartridge insulating breathing apparatus, perforated plate of the gas distributor.

Figure 4 - Regenerative cartridge insulating breathing apparatus, section bB in figure 3.

Figure 5 - Regenerative cartridge insulating breathing apparatus, gas distributor in the assembled state.

The regenerative cartridge of the insulating breathing apparatus includes a sealed cylindrical body 1 with a pipe 2 inhale-exhale for connection with a corrugated tube (not shown) and with a pipe 3 of a breathing bag (not shown), a perforated shell 4 installed in the housing 1 with an annular gap 5 relative to the side body walls 1. An annular gap 5 is connected to the nozzle 3 of the breathing bag. Along the longitudinal axis 6 of the regenerative cartridge, a central channel 7 with perforated walls is made, one end of which is blocked by a tampon 8, and the second is connected to the pipe 2 of the inhalation-exhalation. The tampon 8 is made of a gas-permeable material crushed under the action of mechanical forces. A regenerative product 9 is placed in the cavity of the perforated shell 4. The regenerative cartridge has a heat and gas distributor located in the volume of the regenerative product 9 and made in the form of identical perforated plates 10 radially mounted in the volume of the regenerative product 9 between the perforated shell 4 and the central channel 7. Perforated plates 10 can be made of metal mesh. The use of the same perforated plates 10 in the design of the heat and gas distributor and their execution from a metal mesh increases the manufacturability of the product. One of the sides of each perforated plate 10 is made with a longitudinal U-shaped cross-sectional bend 11. The walls 12 of the U-shaped bends 11 of the adjacent perforated plates 10 are connected in series by resistance welding. With such a connection, a central channel 7 is formed, which is limited by the shelves 13 of the U-shaped bends 11. The sections of the perforated plates 10 located in the volume of the regenerative product 9 are made with a longitudinal bend 14 to increase the contact area of the perforated plates 10 with the regenerative product 9. Perforated plates 10 can be made of metal mesh, which increases the manufacturability of the design.

Two cavities 15, 16, isolated from one another, are made in the upper part of the body and are separated by a cover 17. A cavity 15 connects the nozzle 2 of the exhalation breath with the central channel 7. The cavity 16 connects the nozzle 3 of the breathing bag with an annular gap 5 between the perforated shell 4 and the side wall housing 1. Filter 18 is installed in cavity 15. Cover 17 is spring-loaded relative to housing 1 by spring 19. In the lower part, the cartridge’s internal structure (perforated shell 4 with central channel 7, regenerative product 9, perforated astynom 10) abuts against the bottom 20 of the housing 1 through the swab 8, which is made of gas permeable material being crushed by mechanical forces. This design makes it possible to constantly maintain the compressed state of the regenerative product 9 with the force specified by the characteristics of the spring 19.

Regenerative cartridge as part of an insulating breathing apparatus works as follows.

During exhalation, the gas-air mixture with a high content of carbon dioxide through the pipe 2 enters the cavity 15, passes through the filter 18 and enters the central channel 7. Further, the gas-air mixture passes through the perforated shelves 13 of the U-shaped bends 11 that define the central channel 7, and enters the volume of the regenerative product 9, in which the reactions of absorption of carbon dioxide and oxygen evolution occur. Perforated plates 10 contribute to a uniform distribution of heat in the volume of the regenerative product 9, prevent the occurrence of local high-temperature zones, remove heat to the walls of the housing 1 and further into the environment. Part of the gas-air mixture enters the interior of the regenerative product 9 along the perforated plates, which improves the gas dynamics of the regeneration process. Further, the gas-air mixture through the perforated shell 4 enters the annular gap 5 between the perforated shell 4 and the side wall of the housing 1 and through the cavity 16 enters the pipe 3 of the breathing bag.

During inspiration, the gas-air mixture, in which regeneration reactions have already taken place, comes from the breathing bag in the opposite direction, that is, in the direction “pipe 3 - cavity 16 - annular gap 5 - volume of the regenerative product 9 - central channel 7 - filter 18 - cavity 15 - branch pipe 2 ". In this case, the air-gas mixture is additionally subjected to regeneration.

Assembly is performed as follows.

A filter 18 with its fastening elements is installed in the cover 17. The cover 17 is connected to the perforated shell 4 by contact welding. The walls 12 of the U-shaped bends 11 of the adjacent perforated plates 10 are connected in series with each other with the formation of a central channel 7. The welded perforated plates 10, like a heat and gas distributor, are installed in the perforated shell 4 and fixed by contact welding. A tampon 8 is installed in the lower part of the central channel 7, which is made of a gas-permeable material that is wrinkled by mechanical forces, with the possibility of supporting the tampon 8 into the bottom 20 of the housing 1. The assembly thus assembled is installed in the housing 1, compressing the spring 19. The spring 19 is fixed in a compressed condition. Further into the cavity of the perforated shell 4, the regenerative product 9 is poured and compacted on a vibrator. Set the bottom 20, hermetically weld it with the housing 1. Remove the spring retainer 19. The cartridge is ready for use.

The constructive implementation of the inventive regenerative cartridge ensures uniform temperature and air-gas mixture flows in the volume of the regenerative product, prevents the occurrence of local high-temperature zones, which improves the conditions of heat and mass transfer in the regenerative cartridge and, as a result, increases the efficiency of the gas-air mixture regeneration process. The design of the regenerative cartridge is characterized by simplicity and high adaptability.

Claims (5)

1. The regenerative cartridge of an insulating breathing apparatus, including a sealed enclosure with an inhalation-expiration nozzle and a breathing bag nozzle, a perforated shell mounted in a housing with an annular gap relative to the side wall of the housing and made with a central channel with perforated walls, a regenerative product located in the perforated cavity shells, heat and gas distributor located in the volume of the regenerative product, while the specified Central channel is connected to the pipe inhalation-exhalation And said annular gap is connected to the pipe breathing bag, characterized in that the heat and gas distributor is made in the form of perforated plates radially mounted between the perforated shell and the central channel in the volume of the regenerative product, one of the sides of each perforated plate is made with a longitudinal U-shaped cross-section in the cross section, the walls of the U-shaped bends of adjacent perforated plates are connected in series between with the formation of a central channel bounded by shelves of U-shaped bends. 2. The regenerative cartridge according to claim 1, characterized in that the housing and perforated shell are cylindrical. 3. The regenerative cartridge according to claim 1, characterized in that the sections of the perforated plates placed in the volume of the regenerative product are made with a longitudinal bend. 4. The regenerative cartridge according to claim 1, characterized in that the central channel in its lower part is blocked by a tampon made of a gas-permeable material, crushed under the action of mechanical forces, and installed with the possibility of support in the bottom of the housing. 5. The regenerative cartridge according to claim 1, characterized in that the perforated plates are made of metal mesh.

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