RU2768831C1 - Method for purification of a gas mixture from carbon dioxide - Google Patents

Abstract

FIELD: gas purification.

SUBSTANCE: invention relates to the field of purification of gas mixtures from carbon dioxide impurities and can be used in various fields of science and technology. The gas stream to be cleaned is bubbled using a divider through a suspension of finely crushed carbonate of at least one alkaline earth metal while stirring the suspension solution in a bubbling chamber. The specified suspension saturated with carbon dioxide is filtered on a dynamic filtration unit through a rotating membrane filter in the ultrasound field. The filtrate is placed in the degassing chamber, and the unfiltered part is returned to the bubbling chamber.

EFFECT: invention provides an increase in the efficiency of carbon dioxide extraction from gas mixtures.

7 cl

Description

The invention relates to the field of purification of gas mixtures from carbon dioxide impurities and can be used in various fields of science and technology.

Known (RU, patent 2244586, publ. 20.01.2005) absorber of carbon dioxide from gas mixtures, obtained by impregnation of porous aluminum oxide with potassium carbonate, and aluminum oxide is pre-treated with an alkaline solution, then potassium carbonate is introduced into the pores of the thus prepared alumina by impregnation. Also known is a method for removing carbon dioxide from gas mixtures, incl. for adsorption separation of carbon dioxide from atmospheric air in cyclic processes under conditions of thermal regeneration or short-cycle non-heating adsorption. The method is characterized in that it is carried out at a temperature of 20-200°C and the specified absorber is used.

The known technical solution does not effectively remove carbon dioxide.

Known (JP, application 08040715, publ. 13.02.1996) method of removing carbon dioxide by porous materials (activated carbon, alumina, zeolite, kieselguhr or mixtures thereof) coated with potassium carbonate and/or sodium hydrate. The sorbent is regenerated by steam. The active component of the absorber, which ensures its high capacity, is alkali metal carbonate dispersed in the pores of the matrix.

The disadvantage of the known method should be recognized that the absorber is a highly reactive compound capable of entering into irreversible chemical interactions with certain carriers. This leads to a decrease in the sorption capacity of the absorber in the high-cycle mode of operation.

десорбцию ведут при температуре 70-90, а указанный обедненный раствор возвращают на стадию абсорбции полностью без дополнительной очистки.There is also known (RU, patent 2566661, publ. 06/06/2018) a method for removing carbon dioxide from gas mixtures by absorbing carbon dioxide with an aqueous solution of MEA monoethanolamine absorbent - to obtain an absorbent solution saturated with carbon dioxide, desorption of carbon dioxide from this saturated absorbent solution when heated with obtaining carbon dioxide and an absorbent solution depleted in carbon dioxide and returning it to the absorption stage, using an absorbent solution containing monoethanolamine 10-14 wt. %, the degree of saturation of the absorption solution is not less than 0.65

desorption is carried out at a temperature of 70-90, and the specified depleted solution is returned to the absorption stage completely without additional purification.

Known (PCT, application 2010142716, publ. 12/16/2010) method of removing carbon dioxide. According to the known method of removing carbon dioxide from gas mixtures, removal is carried out by absorbing carbon dioxide with an aqueous solution of an absorbent, then desorption of carbon dioxide from a saturated absorbent solution is carried out when heated to 120°C. Among the listed absorbents, monoethanolamine MEA is mentioned. The stream withdrawn from the bottom zone of the desorber at a temperature of 120°C is fed into an external boiler, where the temperature (130-140°C) is maintained, which ensures the evaporation of the absorbent. The absorbent vapor is then returned to the desorber and the liquid phase is withdrawn. This technique allows you to increase the depth of extraction of CO ₂ . At the same time, a vacuum is created at the exit from the top of the desorber using a vacuum pump or an ejector. Carbon dioxide and water vapor are removed from the top of the desorber and passed through a condenser. Water condensate is returned to the desorber, purified carbon dioxide is sent for processing.

The disadvantage of the known method is to recognize its complexity.

This technical solution is accepted as the closest analogue of the developed method.

The technical problem solved by using the developed method is to develop a new approach to the problem of cleaning gas mixtures from carbon dioxide impurities.

The technical result achieved as a result of the developed method is to increase the efficiency of carbon dioxide extraction from gas mixtures.

To achieve this technical result, it is proposed to use the developed method for cleaning gas mixtures from carbon dioxide. According to the developed method, the gas stream to be purified is subjected to bubbling using a splitter through a suspension of finely divided carbonate of at least one alkaline earth metal, while stirring the suspension solution in the bubbling chamber, filtering the specified suspension saturated with carbon dioxide on a dynamic filtration unit through a rotating membrane filter in field of ultrasound, the filtrate is placed in the degassing chamber, and the unfiltered part is returned to the bubbling chamber.

Preferably, a suspension with a particle size of 10 to 50 µm and a solids content of 5 to 10% is used.

Preferably, an ultrasonic field with a frequency of 20 to 30 kHz is used to ensure the preferential transmission of acoustic power to cavitation. Ceramics, for example, based on aluminum oxide, or porous titanium or a polymer film with a thickness of 50 to 500 µm, pierced with conical holes with a narrow end diameter of 1 µm to 10 µm and an outlet diameter of 2 to 50 µm, and the symmetry axis of the conical holes is perpendicular to the plane of the film with a deviation from perpendicularity of no more than 20 angular degrees.

In some embodiments of the developed method, carbon dioxide is removed from the degassing chamber.

The developed method is based on the idea of the process of cleaning the air from carbon dioxide in the variant when the sorbing solution goes through a cycle: the same portion of the solution repeatedly purifies the air. This is called the carbonate-bicarbonate cycle.

The second main idea underlying the developed method is the process of cleaning liquid from carbon dioxide by dynamic filtering in the field of ultrasound. The fact is that ultrasound reduces the solubility of gases in water: under the action of ultrasound, the solution seems to “boil” and gas bubbles are released.

In the dynamic filtration method, the liquid is swirled together with the filter, and there a centrifuge effect occurs in the liquid. Therefore, gas bubbles that are lighter than the liquid are pressed to the center, that is, to the filter. Therefore, the simultaneous use of ultrasound and dynamic filtration ensures both the release of gas bubbles and their separation from the bulk of the liquid. The liquid can therefore be reused for gas flushing.

The third fundamental idea is the method of degassing the liquid. This removes both dissolved carbon dioxide and part of the carbon dioxide chemically bound into bicarbonates, the very ones that are called salts of temporary hardness.

The developed method consists in the fact that the initially purified stream is subjected to bubbling purification from carbon dioxide by blowing it through a suspension of finely divided calcium, magnesium, barium or strontium carbonate or a mixture thereof while stirring the solution in a bubbling chamber. In this case, a partial transition of the insoluble form of carbonates of these metals into the soluble form of hydrocarbonates occurs according to the chemical reaction:

Similarly for magnesium, barium or strontium. The purpose of the suspension is to increase the ability of the liquid (water) to dissolve carbon dioxide due to the reaction according to (1) compared to a pure liquid.

Then, said suspension saturated with carbon dioxide is filtered from the flow at a dynamic filtration unit of the UUDF-1 type [RU, patent 176937] through a rotating membrane filter in the ultrasound field. Under the action of ultrasound, the solubility of gases in a liquid decreases thousands of times, and at the same time, partial decomposition of bicarbonates occurs with the release of carbon dioxide:

Similarly for magnesium, barium or strontium.

Under the action of centrifugal force, lighter than liquid carbon dioxide is pressed against a cylindrical filter element [RU, patent 2699121], located in the center of the filter chamber and mainly passes through the filter. As a result, the solution (filtrate) passing through the filter is enriched with carbon dioxide, and the unfiltered part of the solution is partially purified from bicarbonates.

In this case, the filtrate is taken from inside the rotating filter element, enriched with carbon dioxide, and the main part of the unfiltered suspension is taken from the outer part of the chamber of the filter installation, depleted in carbon dioxide and carbonates. The carbon dioxide-enriched part of the liquid (filtrate) is transferred to a separate chamber, where it is degassed to extract carbon dioxide using ultrasonic treatment, pressure relief, or another method. At the same time, if necessary, carbon dioxide can be extracted for subsequent use. After that, the degassed part of the filtrate is combined with the main, unfiltered part of the liquid and sent to the next cycle to clean the flow into the bubbling chamber.

The technical result is achieved due to the fact that

1) The use of a dispersion of finely divided calcium carbonate as a medium for absorbing carbon dioxide increases the ability of the liquid phase to absorb carbon dioxide due to the chemical reaction according to (1).

2) When filtering a solution containing bicarbonates Ca (HCO ₃ ) ₂ , Mg (HCO ₃ ) ₂ , Sr (HCO ₃ ) ₂ , Ba (HCO ₃ ) ₂ in the ultrasound field, they decompose according to the reaction according to (2) with the release of carbon dioxide gas, due to the fact that under the action of ultrasound the solubility of gases in liquids decreases hundreds and thousands of times. When carbon dioxide is removed from the solution, the reaction equilibrium shifts according to (2) to the right.

3) In the dynamic filtration method, a partial transfer of torque from the filter element to the liquid occurs and the liquid swirls. As a result, due to the lower density compared to the liquid, carbon dioxide is concentrated in the center of the filter chamber under the action of centrifugal force. The solid precipitate of carbonates, on the contrary, is displaced to the periphery of the filter chamber. Thus, there is an effective purification of the bulk of the liquid from carbon dioxide.

4) The carbon dioxide-enriched filtrate is degassed to separate carbon dioxide and returned to the bubbling chamber for subsequent saturation with carbon dioxide. Thus, a cycle is implemented, the result of which is to obtain a gas stream depleted in carbon dioxide and a gas phase enriched in carbon dioxide.

5) The proposed scheme can be used in a non-cyclic mode for water purification from salts of temporary hardness (hydrocarbonates) according to the reaction according to (2) by passing through a dynamic filtration unit once.

Claims (7)

1. A method for cleaning gas mixtures from carbon dioxide, characterized in that the gas stream to be cleaned is bubbling using a splitter through a suspension of finely divided carbonate of at least one alkaline earth metal, while stirring the suspension solution in a bubbling chamber, filtering the specified suspension saturated with carbon dioxide , at the installation of dynamic filtration through a rotating membrane filter in the field of ultrasound, the filtrate is placed in the degassing chamber, and the unfiltered part is returned to the bubbling chamber. 2. The method according to p. 1, characterized in that a suspension with a particle size of 10 to 50 microns is used. 3. The method according to p. 1, characterized in that a suspension is used with a solids content of 5 to 10%. 4. The method according to claim 1, characterized in that an ultrasound field with a frequency of 20 to 30 kHz is used. 5. The method according to p. 1, characterized in that ceramics are used as a divider. 6. The method according to p. 1, characterized in that a polymer film with a thickness of 50 to 500 microns is used as a divider, penetrated by conical holes with a diameter of the narrow end of the hole from 1 to 10 microns and an outlet diameter of 2 to 50 microns, and the axis the symmetry of the conical holes is perpendicular to the plane of the film with a deviation from perpendicularity of no more than 20 angular degrees. 7. The method according to p. 1, characterized in that carbon dioxide is removed from the degassing chamber.