RU2809171C1 - Carbon dioxide and hydrogen recycling system - Google Patents

Abstract

FIELD: spacecraft equipment.

SUBSTANCE: regenerative physical and chemical life support systems for the crew of a spacecraft (SC) with a maximally closed cycle. The proposed system contains a unit for processing carbon dioxide (CO₂) and hydrogen (H₂), a unit for electrolytic decomposition of water, a battery and an H₂ absorber with an intermetallic compound. Between the CO₂ and H₂ processing unit and the H₂ absorber, a membrane module with filter elements is installed to separate H₂ and feed it into the H₂ absorber. This module is also connected to a CO₂ adsorber, into which unreacted CO₂ and carbon monoxide (CO) formed as a result of the reaction are sent. CO, having passed through the CO₂ adsorber, is sent to the CO collection, with subsequent use in the spacecraft orbit correction engine, or is removed overboard, while the CO₂ adsorber is connected to its concentrator.

EFFECT: maximum utilization of the initial reagents and final products, preventing the accumulation of excess CO₂, eliminating the joint supply of unreacted CO₂ and H₂ and the resulting CO into the H₂ absorber, obtaining ultra-pure H₂ due to the separation of impurity gases.

1 cl, 1 dwg

Description

The proposed invention relates to the field of creating regenerative physico-chemical maximally closed life support systems for the crew of a long-term operating spacecraft.

The invention can also be used in air, ground, underground, surface and underwater special pressurized facilities.

When carrying out space flights outside the earth's orbit and creating alien bases, it is advisable to make maximum use of substances released during the life of the crew, i.e. the system should be as closed as possible and based on the regeneration principle.

There is a known general approach to creating a closed physicochemical life support system with an air regeneration subsystem (B.G. Grishaenkov. Regeneration and air conditioning. Fundamentals of space biology and medicine. Generally edited by O.G. Gazenko and M. Calvin. M. : Nauka, 1975. T. 3, pp. 70-121; A. S. Guzenberg. Regeneration and air conditioning. Space biology and medicine. Under the general editorship of O. G. Gazenko, A. I. Grigoriev and A. E. Nikoghosyan, S. R. Molera (M.: Nauka, 1994. T. 2, pp. 252-296).

The closest in technical essence to the proposed technical solution is the regeneration life support system for the crew of a spacecraft, and the carbon dioxide and hydrogen processing system included in this main system was chosen as a prototype. This carbon dioxide and hydrogen processing system (prototype) includes: a carbon dioxide and hydrogen processing unit, an electrolytic water decomposition unit, a hydrogen accumulator with an intermetallic compound, an oxygen adsorber, a carbon monoxide afterburner with a palladium catalyst, a hydrogen absorber with an intermetallic compound (Klimarev S.I. ., Sinyak Yu.E., Gavrilov L.I. et al. Regeneration life support system for the crew of a spacecraft. Patent RU No. 2500590. 2013).

The disadvantages of the carbon dioxide and hydrogen processing system are:

- excessive accumulation of carbon dioxide;

- the use of oxygen to burn carbon monoxide to carbon dioxide in the afterburner;

- joint supply of impurity gases in hydrogen (unreacted carbon dioxide and formed carbon monoxide), reducing the rate of hydrogen absorption in its absorber and the sorption capacity of the intermetallic compound;

- use of carbon dioxide in the greenhouse, which is located in the living compartment;

- removal of carbon dioxide overboard, containing a significant amount of oxygen.

The task and technical result is to create a system for processing carbon dioxide and hydrogen that maximally processes both the initial reagents (carbon dioxide and hydrogen) and the products of their interaction; in eliminating the oxidation of carbon monoxide to carbon dioxide and its removal overboard the spacecraft; in preventing the accumulation of excess carbon dioxide; in the absence of a joint supply of unreacted carbon dioxide and hydrogen and the resulting carbon monoxide to the hydrogen absorber; in the production of ultrapure hydrogen by separating impurity gases (carbon dioxide and carbon monoxide).

The problem is solved by the fact that in a carbon dioxide and hydrogen processing system containing a carbon dioxide and hydrogen processing unit, an electrolytic water decomposition unit, a hydrogen accumulator with an intermetallic compound, an oxygen adsorber, a carbon monoxide afterburner with a palladium catalyst, a hydrogen absorber with an intermetallic compound, between the processing unit carbon dioxide and hydrogen and a hydrogen absorber, a membrane module with filter elements is installed to separate hydrogen and supply it to the hydrogen absorber; the membrane module is also connected to a carbon dioxide adsorber, into which unreacted carbon dioxide and carbon monoxide formed as a result of the reaction are sent; Carbon monoxide, having passed through the carbon dioxide adsorber, is sent to a carbon monoxide collector for subsequent use in the spacecraft orbit correction engine, or is removed overboard, while the carbon dioxide adsorber is connected to its concentrator.

For example, a zeolite that absorbs high-frequency electromagnetic energy can be used as an adsorbent in a carbon dioxide adsorber.

In the carbon dioxide and hydrogen processing unit, an alternating current glow discharge, a microwave discharge, or a combination of both can be used as heating elements.

To absorb hydrogen in its battery and hydrogen absorber, an intermetallic compound based on the LaNis alloy is used (Kolachev B.A., Ilyin A.A., Lavrenko V.A., Levinsky Yu.V. / Hydride systems. Directory. M. Metallurgy. 1992 . 352 pp.).

The use of a membrane module with filter elements between the carbon dioxide and hydrogen processing unit and the hydrogen absorber is a new technical solution. The filter elements of the membrane module are made on the basis of PdInRu alloy for separating unreacted hydrogen from a gas mixture of unreacted carbon dioxide and carbon monoxide formed as a result of the reaction (Slovetsky D.I. // Ultrapure hydrogen. New technologies. The Chemical Journal. January-February. 2010. From 33-35).

The presence of a carbon monoxide collector in the carbon dioxide and hydrogen processing system improves the operation of the system as a whole.

The proposed technical solution is illustrated by figure 1, which shows a block diagram of the life support system, where: 1 - living compartment; 2 - system for purifying the atmosphere from harmful impurities; 3 - unit for processing carbon dioxide and hydrogen; 4 - block of electrolytic decomposition of water; 5 - hydrogen battery with intermetallic compound; 6 - system for regeneration of solid and liquid crew waste; 7 - drinking water collection; 8 - metabolic water collector; 9 - waste collection; 10 - system for purifying the atmosphere from carbon dioxide and water vapor; 11 - carbon dioxide concentrator; 12 - membrane module with filter elements; 13 - hydrogen absorber with intermetallic compound; 14 - carbon dioxide adsorber; 15 - carbon monoxide collector.

The carbon dioxide and hydrogen processing system, which is part of the life support system, consists of: unit 3 for processing carbon dioxide and hydrogen; block 4 electrolytic decomposition of water; hydrogen battery 5 with intermetallic compound; membrane module 12 with filter elements; hydrogen absorber 13 with intermetallic compound; carbon dioxide adsorber 14; carbon monoxide collector 15.

The listed components and blocks of the carbon dioxide and hydrogen processing system are interconnected as follows: the electrolytic decomposition unit of water 4 is connected with the first output to the living compartment 1, and the second to the input of the hydrogen battery 5; the first input of the electrolytic decomposition block of water 4 is connected to the metabolic water collector 8; the output of the hydrogen battery 5 is connected to the second input of the carbon dioxide and hydrogen processing unit 3; the second input of the carbon dioxide processing unit 3 is connected to the carbon dioxide concentrator 11; the first output of the carbon dioxide and hydrogen processing unit 3 is connected to the input of the membrane module 12 with filter elements, and the second output of the unit 3 is connected to the second input to the electrolytic decomposition unit of water 4; the first output of the membrane module 12 with filter elements is connected to the input to the hydrogen absorber 13, the output of which, in turn, is connected to the second input to the hydrogen accumulator 5; the second output of the membrane module 12 is connected to the input of the carbon dioxide adsorber 14, from which, through the first output, carbon dioxide is desorbed into the carbon dioxide concentrator 11, and through the second output, carbon monoxide is supplied to the carbon monoxide collector 15, from which, as necessary, it is sent to the correction engine orbit or is removed overboard.

The carbon dioxide and hydrogen recycling system works as follows:

At the end of the process of concentrating carbon dioxide and sorption of hydrogen, the process of processing carbon dioxide and hydrogen is carried out in the following sequence: in the hydrogen accumulator 5, the intermetallic compound is heated by an electric heater; then carbon dioxide from the concentrator 11 and hydrogen from the battery 5 in a ratio of 1:2 are respectively discharged at a constant flow rate into the carbon dioxide and hydrogen processing unit 3; the pressure value in these blocks is selected experimentally to maintain a constant speed of the mixture of these gases, ensuring the maximum degree of conversion of carbon dioxide; the processing of carbon dioxide and hydrogen is carried out by the plasma-chemical method using an inertia-free glow or microwave discharge, or a combination thereof; The water formed as a result of hydrogenation of carbon dioxide is supplied to the electrolyzer 4 for decomposition into oxygen and hydrogen.

After the carbon dioxide and hydrogen processing system 3, the mixture of carbon monoxide, unreacted carbon dioxide and hydrogen is sent to a membrane module 12 with filter elements to separate hydrogen from carbon monoxide and carbon dioxide; then hydrogen is supplied to the hydrogen absorber 13; then the unreacted carbon dioxide and the carbon monoxide formed as a result of the reaction are sent to the carbon dioxide adsorber 14, in which the adsorption of carbon dioxide occurs, and the carbon monoxide is sent to its collector 15, while hydrogen from the absorber 13 at the end of the processing process is supplied to the hydrogen accumulator 5; After this, the system does not operate until the next processing cycle begins.

Thus, the proposed arrangement of components and blocks in the proposed technical solution allows for maximum processing of carbon dioxide and hydrogen; eliminate excessive accumulation of carbon dioxide and its removal overboard the spacecraft; stop using oxygen to oxidize carbon monoxide to carbon dioxide; ensure the supply of ultra-pure hydrogen to its absorber; store carbon monoxide in its collector for subsequent use, for example, in the correction engine of a spacecraft or for removal overboard.

Claims (1)

A carbon dioxide and hydrogen processing system containing a carbon dioxide and hydrogen processing unit, including heating elements, an electrolytic water decomposition unit, a carbon monoxide afterburner with a palladium catalyst, a hydrogen absorber with an intermetallic compound, a hydrogen accumulator with an intermetallic compound, an oxygen adsorber, characterized in that between the unit processing of carbon dioxide and hydrogen and a hydrogen absorber, a membrane module with filter elements is installed to separate hydrogen and supply it to the hydrogen absorber, and the membrane module is also connected to a carbon dioxide adsorber, into which unreacted carbon dioxide and carbon monoxide formed as a result of the reaction are sent, so that Carbon monoxide, having passed through the carbon dioxide adsorber, is sent to a carbon monoxide collector for subsequent use in the spacecraft orbit correction engine, or is removed overboard, while the carbon dioxide adsorber is connected to its concentrator.

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