RU188323U1 - Indoor respiratory atmosphere control device - Google Patents

Abstract

The utility model relates to air conditioning devices. The device for controlling the respiratory atmosphere in the room includes a compressor 1, a desiccant 4, adsorbers 8, 9, 10 filled with a solid adsorbent that adsorbs carbon dioxide and water vapor well, a membrane module 14, as well as electromagnetic valves 2,3, 5-7, 11-13, 15-20. The device operates in the mode of air purification from carbon dioxide and water vapor and in the mode of oxygen enrichment in the room. In the air purification mode of the room from carbon dioxide and water vapor, the compressor 1 delivers the air contained in the room through the valve 3, the valve 2 is closed, in the dryer 4, where the preliminary drying occurs, then the dried air through the valve 5, while the valve 18 is closed displaces from the pre-filled adsorber 8 air, purified from carbon dioxide, water vapor and enriched with oxygen, through the valve 11, part of which is supplied to the inlet of the membrane 14, and the other part to the adsorber 9 through the valve 12 to fill it to operating pressure,while valves 6 and 19 are closed. At the same time, pressure is released from the adsorber 10 through the valve 20 into the external medium, while the valve 7 is closed, gas that has not passed through the membrane is supplied from the output of the membrane module to purge and regenerate the adsorbent in the adsorber 10 through the valve 17, while the valve 13 is closed . After filling the adsorber 9 to the operating pressure, the adsorbers change stages. The adsorber 8 goes to the discharge and regeneration stage, oxygen enriched and purified from carbon dioxide and water vapor are displaced from the adsorber 9, and the adsorber 10 is filled to the working pressure with a part of the flow displaced from the adsorber 9. The gas passed through the membrane is supplied to the room. The mode of enrichment of air in the room with oxygen differs from the mode of purification of air in the room from carbon dioxide and water vapor in that the air into the system using compressor 1 through valve 2 is supplied from the external environment.

The technical result consists in component-wise adjustment of the composition of the isolated atmosphere through the use of membrane and sorption technologies. This allows you to effectively clean the gas from carbon dioxide and water vapor and reduce energy consumption.

Description

The utility model relates to air conditioning devices and is designed to create respiratory atmospheres in confined spaces, including residential, office and other workrooms, vehicles, fitness rooms, medical chambers, hospital wards and other localized breathing zones.

A known method and design based on it (RF patent No. 2484384, F24F 3/14, С01В 13/02, publ. 06/10/2013). In this method, a compressed external gas stream formed from atmospheric air is subjected to component-wise separation in the membrane modules by supplying and passing along the surface of the selective membrane in the high-pressure region of the modules. The method uses at least two membrane modules forming a multi-stage installation. The gas stream from the high-pressure areas of the membrane modules is combined and fed into an intermediate tank with a nitrogen content of 92-99 vol. %, and the gas stream from the low-pressure areas of the membrane modules is fed into an intermediate tank with an oxygen content of 90-99 vol. % The formation of the respiratory atmosphere occurs by mixing gas from two intermediate containers.

The disadvantages of the method include the following:

- The gas stream enriched with oxygen will also be enriched with carbon dioxide, which will ultimately lead to its accumulation in the workspace;

- to maintain balance, the air in the room is discharged into the outdoor atmosphere, which leads to a decrease in energy efficiency.

The known method and design based on it (RF patent No. 2431784, F24F 3/14, F24F 3/16, publ. 10/20/2011). According to this patent, in this method the external gas stream undergoes double component gas separation on selective membranes. A supply stream from the outside atmospheric air enters an additional membrane module, and a stream enriched in carbon dioxide and oxygen is obtained from the low-pressure area of the module. From the high-pressure region of the additional module, the flow enters the main membrane module. In the low-pressure region of the main membrane module, a stream predominantly enriched in oxygen is obtained. From the high pressure region of the main membrane module, a stream depleted in oxygen and carbon dioxide is obtained. From certain parts of these three streams, a stream of the required gas composition is formed and fed into the room.

The disadvantages of the method include the following:

- at the selected operating mode, with an additional membrane module, air with a high CO2 content is supplied to the room;

- to maintain balance, the air in the room is discharged into the outdoor atmosphere, which leads to a decrease in energy efficiency.

The closest in design and adopted for the prototype is a system for regulating the respiratory atmosphere in the room (RF patent No. 123505, F24F 5/00, publ. 27/12/2012). The control system of the respiratory atmosphere in the room contains a compressor, the inlet of which is configured to alternately connect with the room and the outside air, an oxygen enrichment membrane module and a carbon dioxide membrane removal module, each of which is connected to the compressor output through a control valve to switch the compressed air flow gas from the compressor between the membrane modules, while one of the outputs of each membrane module is connected to the room, and the other to the line wasp the atmosphere, drying system comprising a cooler and a separator heaters before membrane modules, at the outlet of membrane module oxygen concentration installed vacuum pump and a cooler.

The system operates as follows. The system has two circuits: an oxygen enrichment circuit and a carbon dioxide purification circuit; operation is based on sequential switching between the two modes. In the oxygen enrichment circuit, outside air is sucked in from the street, then the air passes through a drainage system consisting of a cooler and a separator. Before being allowed into the oxygen enrichment module, the air is heated in the heating block to provide the best gas separation characteristics. Oxygen-enriched air in the membrane module is supplied to the room. Previously, the air can be cooled to the desired temperature in the cooler. In the carbon dioxide purification circuit, air is taken from the room by the compressor and, having passed the drainage system and the heating block, is supplied to the carbon dioxide removal module. The stream of carbon dioxide removed is discharged into the street, and the cleaned air is again fed into the room. There is also the possibility of parallel circuits.

The disadvantages of the utility model include the following:

- In the event of adverse outdoor conditions (high CO2 concentrations), a stream enriched with oxygen and carbon dioxide will be supplied to the room);

- To control the concentration of carbon dioxide in the room due to its low concentration (<1 vol.%) It will be necessary to process large volumes of gas, which will lead to large energy costs for the separation and preparation (heating, cooling) of the gas.

The technical task of the proposed utility model is to eliminate technological disadvantages indicated in the prototype.

The technical result achieved by the implementation of the claimed utility model consists in component-wise (oxygen, carbon dioxide, water vapor) adjustment of the composition of the isolated atmosphere, through the use of membrane and sorption technologies. This allows you to effectively clean the gas from carbon dioxide and reduce energy consumption.

The claimed utility model is illustrated by a drawing (Fig. 1), which shows a schematic diagram of a device for controlling the respiratory atmosphere in a room. The device diagram is made in the form of graphical symbols of elements that are functionally connected by the lines of movement of the flows of air, nitrogen, oxygen and carbon dioxide.

The device for controlling the respiratory atmosphere in the room includes a compressor 1, the inlet pipe of which is connected to the external environment through the valve 2 and the room through the valve 3. The output pipe of the compressor 1 is connected through a desiccant 4 and a group of valves 5, 6 and 7 with the inlet pipes of the adsorbers 8, 9, 10, respectively, the adsorbers are filled with a solid adsorbent that adsorbs carbon dioxide well; the outlet pipes of the adsorbers 8, 9, 10 through valves 11, 12 and 13 are respectively connected to the membrane module 14 and to each other. The outlet pipe through which the permeate stream of the membrane module 14 flows is connected to the room, and the outlet pipe through which the retentate stream of the membrane module 14 is connected through valves 15, 16, 17 to the adsorbers 8, 9, 10, respectively. Valves 18, 19, 20 are used to discharge gas from adsorbers 8, 9, 10, respectively.

The device for regulating the respiratory atmosphere in the room is as follows. The operation of the claimed device is carried out in two modes: the mode of purification of air in the room from carbon dioxide and the mode of enrichment with oxygen in the room.

The mode of purification of air in the room from carbon dioxide.

The compressor 1 delivers the air contained in the room through the valve 3, the valve 2 is closed, in the dryer 4, where the pre-drying takes place, then the dried air through the valve 5, while the valve 18 is closed, displaces carbon dioxide-free air from the pre-filled adsorber 8 gas and enriched with oxygen through the valve 11, part of which is supplied to the membrane module 14, and the other part is supplied to the adsorber 9 through the valve 12 to fill it to operating pressure, while valves 6 and 19 are closed. At this time, from the membrane module 14, air that has not passed through the membrane is supplied to the adsorber 10 through the valve 17, the valve 13 is closed to purge and regenerate the adsorbent, and then it is discharged through the valve 20 into the external environment, the valve 7 is closed. After filling the adsorber 9 to the operating pressure, the adsorbers change stages. The adsorber 8 goes to the discharge and regeneration stage, oxygen enriched and carbon-free air is displaced from the adsorber 9, and the adsorber 10 is filled to the working pressure with a part of the flow displaced from the adsorber 9. The air passing through the membrane is supplied to the room.

The mode of enrichment with oxygen in the room

This mode is characterized in that air is supplied to the device by means of compressor 1 through valve 2 from the external environment, providing an inflow of concentrated oxygen to the room from the external environment.

Claims (1)

A device for regulating the respiratory atmosphere in a room containing a compressor, the input of which is arranged to alternately connect to the room and to the outside air, a membrane module, one of whose outputs, with an oxygen enriched stream, is connected to the room, characterized in that the second membrane output module, with a stream depleted in oxygen, is connected to the inlet of the three-adsorption sorption system, consisting of three adsorbers filled with a solid sorbent, each of which has three nozzles, connected by triples, the first three nozzles through three electromagnetic valves are connected to the second output of the membrane module, the second three nozzles are made with the possibility of alternating with the atmosphere through three electromagnetic valves to vent gas from the adsorber and the compressor through three electromagnetic valves and a dryer to fill the adsorbers, and the third three branch pipes through three electromagnetic valves are interconnected and with the input of the membrane module.

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