KR102592265B1 - Carbon dioxide Capture and Sequestration System - Google Patents

Abstract

The present invention relates to a carbon dioxide capture system, and more specifically, to an absorption tower that removes carbon dioxide in exhaust gas by reacting exhaust gas containing carbon dioxide with an absorption liquid, and receiving an absorption liquid that absorbs carbon dioxide from the absorption tower, A regeneration tower that removes carbon dioxide, a heat exchanger that exchanges heat between the absorption liquid that absorbs the carbon dioxide supplied from the absorption tower and the absorption liquid that removes the carbon dioxide supplied from the regeneration tower, and a condensation of the mixed gas of carbon dioxide and water vapor discharged from the regeneration tower. It relates to a carbon dioxide capture system that includes a condenser for absorbing carbon dioxide and has a centrifuge on the flow path of the absorption liquid supplied from the absorption tower to the regeneration tower to separate foreign substances contained in the absorption liquid that has absorbed the carbon dioxide.

Description

Carbon dioxide capture and sequestration system

The present invention relates to a carbon dioxide capture system, and more specifically, to an absorption tower that removes carbon dioxide in exhaust gas by reacting exhaust gas containing carbon dioxide with an absorption liquid, and receiving an absorption liquid that absorbs carbon dioxide from the absorption tower, A regeneration tower that removes carbon dioxide, a heat exchanger that exchanges heat between the absorption liquid that absorbs the carbon dioxide supplied from the absorption tower and the absorption liquid that removes the carbon dioxide supplied from the regeneration tower, and a condensation of the mixed gas of carbon dioxide and water vapor discharged from the regeneration tower. It relates to a carbon dioxide capture system that includes a condenser for absorbing carbon dioxide and has a centrifuge on the flow path of the absorption liquid supplied from the absorption tower to the regeneration tower to separate foreign substances contained in the absorption liquid that has absorbed the carbon dioxide.

To reduce carbon dioxide, an acidic gas in exhaust gas, many technologies such as chemical absorption, adsorption, membrane separation, and deep cooling are being developed. Chemical absorption uses an absorbent liquid to absorb and capture carbon dioxide, making it a highly efficient and stable process. That is why it is applied the most.

The conventional carbon dioxide capture system of FIG. 1 includes an absorption tower (91) that removes carbon dioxide from exhaust gas by combining it with an absorbent, a heat exchanger (93) for receiving the absorbent that absorbs carbon dioxide through a pump (P) and exchanging heat with it, It includes a regeneration tower (92) to remove carbon dioxide chemically bound to the heat exchanged absorbent. Accordingly, the carbon dioxide absorption and removal device uses the above configurations to perform a carbon dioxide absorption process and a regeneration process (stripping process) of the absorption liquid, and the regenerated absorption liquid is re-supplied to the absorption tower 91.

However, the synthesis of carbon dioxide and absorption liquid performed in the absorption tower 91 is an exothermic reaction, so for continuous reaction, an additional cooling method is required in the absorption tower, and the exhaust gas contains foreign substances such as dust salts and plankton, which are mixed into the absorption liquid. This results in a decrease in the efficiency of the overall system.

Furthermore, in order to capture carbon dioxide from exhaust gas emitted from ships, etc., there is a problem that carbon dioxide capture must be performed within a limited space.

Korean Patent Publication No. 10-1709867 (2017.02.17.)

The present invention was devised to solve the above problems,

The object of the present invention is to provide an absorption tower for removing carbon dioxide in exhaust gas by reacting exhaust gas containing carbon dioxide with an absorption liquid, a regeneration tower for removing carbon dioxide from the absorption liquid by receiving an absorption liquid absorbing carbon dioxide from the absorption tower, and the absorption It includes a heat exchanger that exchanges heat between an absorption liquid that absorbs carbon dioxide supplied from the tower and an absorption liquid that removes carbon dioxide supplied from the regeneration tower, and a filter is provided on the flow path of the absorption liquid supplied from the regeneration tower to the absorption tower to remove the carbon dioxide. The purpose is to provide a carbon dioxide capture system that separates foreign substances contained in the absorbent liquid to be absorbed and reused.

Another object of the present invention is that the absorption tower takes out the absorption liquid collected in the lower collecting part and supplies it to the regeneration tower, and the absorption liquid from which the carbon dioxide supplied from the regeneration tower is removed is heat-exchanged through the heat exchanger and then supplied to the absorption tower. The purpose is to provide a carbon dioxide capture system that can effectively use the heat energy applied during the chemical treatment process between the absorbent liquid and carbon dioxide by forming a circulation line of the absorbent liquid.

Another object of the present invention is to provide a carbon dioxide collection system in which damage such as corrosion is prevented by filtering the relatively low-temperature absorption liquid, wherein the filter is provided on a flow path that transports the absorption liquid from which carbon dioxide has been removed from the heat exchanger toward the absorption tower. It is provided.

Another object of the present invention is to provide a carbon dioxide capture system that saves space by installing the filter in direct connection with the flow path as a membrane filter having pores of different sizes on the flow path.

Another object of the present invention is that the filter of the present invention includes a filter body through which absorbent liquid flows in and out, a filter unit that filters the absorbent liquid inside the filter body, and an automatic cleaning unit that backwashes foreign substances attached to the filter unit, The automatic cleaning unit is an automatic cleaning type that includes a driving unit that drives the automatic cleaning unit by control, a suction unit that is connected to and drives the driving unit and sucks foreign substances attached to the filter, and a discharge unit that discharges foreign substances sucked in from the suction unit. It provides a carbon dioxide capture system that is equipped with a filter and can remove accumulated foreign substances without replacing the filter provided in the complicated flow path.

Another object of the present invention is to form a single backwash line by connecting the suction part to the discharge part while penetrating the lower surface of the filter body and communicating the discharge route of foreign substances to be washed from the filter body, enabling compact space use. It is characterized by

Another object of the present invention is to further include a bypass connecting the flow path from the heat exchanger to the filter and the flow path from the filter to the absorption tower, so that the absorption liquid transferred from the regeneration tower through the heat exchanger does not pass through the filter. It provides a foreign carbon dioxide collection system that minimizes overload due to the difference in capacity between the absorbent liquid used for carbon dioxide capture and the absorbent liquid processed in the filter by transporting it to the absorption tower or circulating the absorbent liquid discharged from the filter through the bypass. .

Another object of the present invention is to further include a buffer tank on the flow path to the filter, wherein the buffer tank temporarily stores the absorbent liquid supplied from the heat exchanger on the side of the regeneration tower and then flows it to the bypass or filter. The aim is to provide a carbon dioxide capture system that can separate foreign substances multiple times.

Another object of the present invention is to further include a second filter on the flow path through which the absorption liquid absorbing carbon dioxide is supplied from the absorption tower to the regeneration tower, to remove foreign substances in the absorption liquid, which are included in the absorption liquid supplied to the regeneration tower. The goal is to provide a carbon dioxide capture system that separates and removes contaminants.

Another object of the present invention is to provide a carbon dioxide capture system in which the second filter is provided on a passage through which the absorption liquid is supplied from the absorption tower to the heat exchanger to prevent damage such as corrosion caused by the high-temperature absorption liquid.

Another object of the present invention is to provide a scrubber that is installed on a ship to remove harmful substances in the exhaust gas by spraying cleaning water while allowing the exhaust gas generated by the operation of the ship to flow inside, and to remove the exhaust gas that has passed through the scrubber. An absorption tower that removes carbon dioxide from the exhaust gas by reacting it with the absorption liquid, a regeneration tower that receives the absorption liquid absorbing carbon dioxide from the absorption tower and removes carbon dioxide from the absorption liquid, an absorption liquid that absorbs the carbon dioxide supplied from the absorption tower, and It includes a heat exchanger for heat exchanging the absorption liquid from which carbon dioxide has been removed from the regeneration tower, and a filter is provided on the flow path of the absorption liquid supplied from the regeneration tower to the absorption tower to separate foreign substances contained in the absorption liquid from which the carbon dioxide has been removed. The purpose is to provide a carbon dioxide capture system for ships that captures carbon dioxide from exhaust gases generated from ship operations.

Another object of the present invention is a plurality of absorption towers for removing carbon dioxide in the exhaust gas by reacting the exhaust gas discharged from the scrubber with the absorption liquid, and a plurality of absorption towers for removing carbon dioxide in the exhaust gas between the scrubber and the plurality of absorption towers. It includes a manifold that supplies carbon dioxide to an absorption tower and a plurality of regeneration towers that receive the absorption liquid absorbing carbon dioxide and remove carbon dioxide from the absorption liquid, and supply the carbon dioxide to the plurality of absorption towers from the plurality of regeneration towers through at least one heat exchanger. The aim is to provide a marine carbon dioxide capture system in which at least one of the above filters is provided on the flow path of the absorbent liquid to enable smooth distribution according to the difference in exhaust gas treatment capacity between the scrubber and the absorption tower.

Another object of the present invention is to provide a carbon dioxide capture system that efficiently separates foreign substances by including a centrifuge in the flow path through which the absorbent liquid flows.

Another object of the present invention is to provide a carbon dioxide capture system that has a compact configuration for removing foreign substances in the passageway in a ship with a narrow structure and is easy to install, replace, and dismantle.

In order to achieve the above-described object, the present invention is implemented by an embodiment having the following configuration.

According to one embodiment of the present invention, the present invention is an absorption tower that removes carbon dioxide in the exhaust gas by reacting exhaust gas containing carbon dioxide with an absorption liquid, and receiving an absorption liquid that absorbs carbon dioxide from the absorption tower to remove carbon dioxide from the absorption liquid. It includes a regeneration tower for stripping, a heat exchanger for heat exchange between an absorption liquid absorbing carbon dioxide supplied from the absorption tower and an absorption liquid removing carbon dioxide supplied from the regeneration tower, and on a flow path of the absorption liquid supplied from the regeneration tower to the absorption tower. It is characterized by having a filter to separate foreign substances contained in the absorption liquid that has absorbed the carbon dioxide.

According to another embodiment of the present invention, the absorption tower of the present invention takes out the absorption liquid collected in the lower collecting part and supplies it to the regeneration tower, and the absorption liquid from which the carbon dioxide supplied from the regeneration tower is removed is used in the heat exchanger. It is characterized in that the heat is exchanged through the absorption tower and then supplied to the absorption tower to form a circulation line of the absorption liquid.

According to another embodiment of the present invention, the filter of the present invention is characterized in that it is provided on a flow path that transports the absorption liquid from which carbon dioxide is removed from the heat exchanger toward the absorption tower.

According to another embodiment of the present invention, the filter of the present invention is characterized in that it is provided as a membrane filter with pores of different sizes formed on the flow path.

According to another embodiment of the present invention, the filter of the present invention includes a filter body through which absorbent liquid flows in and out, a filter unit that filters the absorbent liquid inside the filter body, and an automatic cleaning unit that backwashes foreign substances attached to the filter body. The automatic cleaning unit includes a driving unit that drives the automatic cleaning unit by control, a suction unit that is connected to and drives the driving unit and sucks foreign substances attached to the filter, and a discharge unit that discharges foreign substances sucked in from the suction unit. It is characterized by being provided with a self-cleaning type filter.

According to another embodiment of the present invention, the filter body of the present invention includes a lower surface forming the lowermost surface of the filter body, an upper surface forming the uppermost surface, and a partition having an opening between the upper surface and the lower surface. One side of the filter part is fixed to the partition wall and the other side is fixed to one side of the filter body, so that the absorbent liquid flowing into one side of the filter body passes through the partition wall and is discharged to the other side.

According to another embodiment of the present invention, the suction part penetrates the lower surface of the filter body and is connected to the discharge part, and a single backwash line is formed by communicating the discharge route of foreign substances washed from the filter body. It is characterized by

According to another embodiment of the present invention, the present invention further includes a bypass connecting the flow path from the heat exchanger to the filter and the flow path from the filter to the absorption tower, and the absorption liquid transferred from the heat exchanger is transferred to the filter. It is characterized in that it is transferred to the absorption tower without passing through, or the absorption liquid discharged from the filter is circulated through the bypass.

According to another embodiment of the present invention, the present invention further includes a buffer tank on the flow path from the heat exchanger to the filter, wherein the buffer tank temporarily stores the absorbent liquid supplied from the heat exchanger and then stores the absorbent liquid supplied from the heat exchanger. It is characterized by flowing through a pass or filter.

According to another embodiment of the present invention, the present invention further includes a second filter for removing foreign substances in the absorption liquid on the flow path through which the absorption liquid absorbing carbon dioxide is supplied from the absorption tower to the regeneration tower.

According to another embodiment of the present invention, the second filter of the present invention is characterized in that it is provided on a flow path through which the absorption liquid is supplied from the absorption tower to the heat exchanger.

According to another embodiment of the present invention, the present invention is a scrubber that is installed on a ship and sprays cleaning water to remove harmful substances in the exhaust gas while allowing the exhaust gas generated due to the operation of the ship to flow inside, the scrubber. An absorption tower that receives the exhaust gas that has passed through and reacts it with the absorption liquid to remove carbon dioxide in the exhaust gas, a regeneration tower that receives the absorption liquid that has absorbed carbon dioxide from the absorption tower and removes carbon dioxide from the absorption liquid, and a regeneration tower that removes carbon dioxide from the absorption liquid. It includes a heat exchanger for heat exchange between the absorption liquid that has absorbed carbon dioxide and the absorption liquid from which carbon dioxide is removed supplied from the regeneration tower, and a filter is provided on the flow path of the absorption liquid supplied from the regeneration tower to the absorption tower, so that the absorption liquid that has absorbed the carbon dioxide is provided. It is characterized by separating contained foreign substances.

According to another embodiment of the present invention, the carbon dioxide capture system for ships of the present invention includes a plurality of absorption towers that remove carbon dioxide in the exhaust gas by reacting the exhaust gas discharged from the scrubber with an absorbent liquid, the scrubber, and a plurality of absorbers. It includes a manifold that supplies exhaust gas discharged from the scrubber between the towers to a plurality of absorption towers, and a plurality of regeneration towers that receive an absorption liquid absorbing carbon dioxide and remove carbon dioxide from the absorption liquid, and at least Characterized in that at least one or more filters are provided on a flow path of the absorption liquid supplied to the plurality of absorption towers through one or more heat exchangers.

According to another embodiment of the present invention, the present invention is characterized in that a plurality of filters are provided on a flow path that transports the absorption liquid absorbing carbon dioxide from the plurality of regeneration towers toward the heat exchanger.

According to another embodiment of the present invention, the present invention provides at least one agent for removing foreign substances in the absorption liquid on a flow path through which the absorption liquid absorbing carbon dioxide is supplied from at least one absorption tower to at least one or more regeneration towers. It is characterized in that it further includes two filters.

The present invention can achieve the following effects by combining the above-mentioned embodiment with the configuration, combination, and use relationship described below.

The present invention relates to an absorption tower that removes carbon dioxide in exhaust gas by reacting exhaust gas containing carbon dioxide with an absorption liquid, a regeneration tower that receives an absorption liquid that absorbs carbon dioxide from the absorption tower and removes carbon dioxide from the absorption liquid, and an absorption tower that removes carbon dioxide from the absorption liquid. It includes a heat exchanger for heat exchange between the absorption liquid that absorbs the supplied carbon dioxide and the absorption liquid that removes the carbon dioxide supplied from the regeneration tower, and a filter is provided on the flow path of the absorption liquid supplied from the regeneration tower to the absorption tower to absorb the carbon dioxide. Provides a carbon dioxide capture system that separates foreign substances contained in reused absorbent liquid.

In the present invention, the absorption tower takes out the absorption liquid collected in the lower collecting part and supplies it to the regeneration tower, and the absorption liquid from which the carbon dioxide supplied from the regeneration tower is removed is heat exchanged through the heat exchanger and then supplied to the absorption tower. By forming a circulation line, the heat energy applied during the chemical treatment process between the absorbent liquid and carbon dioxide can be effectively used.

The present invention has the effect of providing a carbon dioxide capture system in which damage such as corrosion is prevented by filtering the relatively low temperature absorbent liquid, wherein the filter is provided on a flow path that transports the absorbent liquid from which carbon dioxide has been removed from the heat exchanger toward the absorption tower. give.

In the present invention, the filter of the present invention is provided as a membrane filter with pores of different sizes formed on the flow path, and is installed directly connected to the flow path, thereby achieving the effect of saving space.

According to the present invention, the filter of the present invention includes a filter body through which absorbent liquid flows in and out, a filter unit that filters the absorbent liquid inside the filter body, and an automatic cleaning unit that backwashes foreign substances attached to the filter unit. It is equipped with a self-cleaning type filter including a driving part that drives the automatic cleaning unit by control, a suction part that is connected and driven to the driving part and sucks foreign substances attached to the filter, and a discharge part that discharges foreign substances sucked in from the suction part. Accumulated foreign substances can be removed without replacing the filter provided in the complicated flow path.

In the present invention, the suction part penetrates the lower surface of the filter body and is connected to the discharge part, and the discharge route of foreign substances washed from the filter part is communicated to form a single backwash line, which has the effect of enabling compact space use.

The present invention further includes a bypass connecting the flow path from the heat exchanger to the filter and the flow path from the filter to the absorption tower, and transfers the absorption liquid transferred from the regeneration tower through the heat exchanger to the absorption tower without passing through the filter. Alternatively, the absorbent liquid discharged from the filter is circulated through the bypass to minimize overload due to the difference in capacity between the absorbent liquid used for carbon dioxide capture and the absorbent liquid processed in the filter.

The present invention further includes a buffer tank on the flow path to the filter, wherein the buffer tank temporarily stores the absorbent liquid supplied from the heat exchanger on the side of the regeneration tower and then flows it to the bypass or filter to separate foreign substances. Can be performed multiple times.

The present invention further includes a second filter for removing foreign substances in the absorption liquid on the flow path through which the absorption liquid absorbing carbon dioxide is supplied from the absorption tower to the regeneration tower to separate foreign substances contained in the absorption liquid supplied to the regeneration tower. It has a removal effect.

In the present invention, the second filter is provided on the flow path through which the absorption liquid is supplied from the absorption tower to the heat exchanger to prevent damage such as corrosion caused by the high temperature absorption liquid.

The present invention is a scrubber that is installed on a ship and sprays cleaning water to remove harmful substances in the exhaust gas while allowing the exhaust gas generated by the operation of the ship to flow inside, and receives the exhaust gas that has passed through the scrubber and uses an absorbent liquid and An absorption tower that removes carbon dioxide in the exhaust gas by reacting, a regeneration tower that receives the absorption liquid absorbing carbon dioxide from the absorption tower and removes carbon dioxide from the absorption liquid, an absorption liquid absorbing carbon dioxide supplied from the absorption tower, and the regeneration tower. It includes a heat exchanger for heat exchanging the absorption liquid from which the supplied carbon dioxide has been removed, and a filter is provided on the flow path of the absorption liquid supplied from the regeneration tower to the absorption tower to separate foreign substances contained in the absorption liquid from which the carbon dioxide has been removed, which are generated from ship operations. Carbon dioxide from exhaust gas can be captured.

The present invention provides a plurality of absorption towers for removing carbon dioxide in the exhaust gas by reacting the exhaust gas discharged from the scrubber with an absorption liquid, and supplying the exhaust gas discharged from the scrubber to the plurality of absorption towers between the scrubber and the plurality of absorption towers. It includes a manifold and a plurality of regeneration towers that receive an absorption liquid absorbing carbon dioxide and remove carbon dioxide from the absorption liquid, and a flow path for the absorption liquid supplied from the plurality of regeneration towers to the plurality of absorption towers through at least one heat exchanger. At least one of the above filters is provided on the top to ensure smooth distribution according to the difference in exhaust gas processing capacity between the scrubber and the absorption tower.

The present invention has the effect of providing a carbon dioxide capture system that efficiently separates foreign substances by including a centrifuge on the flow path through which the absorbent liquid flows.

The present invention has a compact configuration for removing foreign substances in the passageway in ships with a narrow structure, and is easy to install, replace, and dismantle.

1 is a diagram showing a conventional carbon dioxide absorption system.
Figure 2 is a diagram showing a carbon dioxide capture system according to an embodiment of the present invention.
Figure 3 is a cross-sectional view of the absorption tower 110 according to a preferred embodiment of the present invention.
Figure 4 is an exploded perspective view of a self-cleaning type filter according to an embodiment of the present invention.
Figure 5 is a cross-sectional view of a self-cleaning type filter according to an embodiment of the present invention.
Figure 6 is a diagram showing the connection between a self-cleaning type filter and the first supply passage 210 according to an embodiment of the present invention.
7 to 9 are diagrams showing a carbon dioxide capture system according to another embodiment of the present invention.
Figure 10 is a diagram showing a centrifuge 310 according to an embodiment of the present invention.
Figure 11 is a view showing a marine carbon dioxide capture system installed on a ship according to an embodiment of the present invention.
Figure 12 is a diagram showing the scrubber 160 and absorption tower 110 connected according to an embodiment of the present invention.
13 to 16 are diagrams showing a carbon dioxide capture system for ships according to another embodiment of the present invention.

Hereinafter, the carbon dioxide capture system according to the present invention will be described in detail with reference to the attached drawings. It should be noted that like elements in the drawings are represented by like symbols wherever possible. Additionally, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the gist of the present invention are omitted. Unless otherwise specified, all terms in this specification have the same general meaning as understood by a person skilled in the art to which the present invention pertains, and if there is a conflict with the meaning of the terms used in this specification, this specification Follow the definitions used in the specification.

Throughout the specification, when a part "includes" a certain component, this does not mean excluding other components unless specifically stated to the contrary, but also means that other components may also be included. Terms such as “~unit” described mean a unit that processes at least one function or operation. In addition, when certain components are said to be "connected," this is not limited to the components being directly contacted and fastened to each other, but also includes being connected through other components, and even if not connected, a certain amount of force or energy can be transmitted. It may mean that it is arranged so that Hereinafter, the present invention will be described in detail by explaining preferred embodiments of the present invention with reference to the accompanying drawings.

Figure 2 is a conceptual diagram of a carbon dioxide capture system 100 according to a preferred embodiment of the present invention. The carbon dioxide capture system captures carbon dioxide in the exhaust gas through a chemical reaction between the absorption liquid and carbon dioxide in the absorption tower, removes carbon dioxide from the absorption liquid in the regeneration tower, and then resupplies it to the absorption tower, removing dust, salt, and even carbon dioxide. It can prevent a decrease in the absorption efficiency of carbon dioxide due to the incorporation of foreign substances such as plankton or fine-sized waste. The carbon dioxide capture system 100 includes an absorption tower 110, a regeneration tower 120, a heat exchanger 130, a reboiler 140, and a condenser 150.

The absorption tower 110 is configured to remove carbon dioxide in the exhaust gas by combining it with the absorption liquid. This can be accomplished by absorbing the carbon dioxide in the exhaust gas supplied to the absorption tower 110 into the absorption liquid through a chemical reaction. The absorbent liquid may be amine-based, amino acid salt, inorganic salt solution, aqueous ammonia, etc.

Referring to the cross-sectional view of the absorption tower 110 shown in FIG. 3, the exhaust gas flowing in through the exhaust gas inlet 111 provided on one side of the absorption tower 110 flows upward within the absorption tower and undergoes the process described later. Carbon dioxide is removed through a chemical reaction with the absorption liquid supplied through the second recovery passage 240 and uniformly sprayed into the absorption tower 110 by the absorption liquid injection unit 113. The exhaust gas from which carbon dioxide has been removed is discharged through the exhaust gas outlet 115 provided at the top of the absorption tower 110, and the absorption liquid containing the carbon dioxide collected in the lower collecting part 117 is discharged through the first supply flow path (described later) It is transferred to the regeneration tower 120 through the heat exchanger 130 through 210). The absorption tower 110 may extract at least a portion of the absorption liquid collected in the lower water collection portion and supply it to the regeneration tower.

The regeneration tower 120 may be provided to regenerate the absorption liquid by receiving the absorption liquid that has absorbed carbon dioxide from the absorption tower 110 and removing the carbon dioxide chemically bound in the absorption liquid. The absorption liquid from which carbon dioxide has been removed from the regeneration tower 120 is heat-exchanged through a heat exchanger 130, which will be described later, and then supplied to the absorption tower. After being transferred from the absorption tower 110 to the regeneration tower 120, the carbon dioxide is removed and returned again. It can be transferred to the absorption tower 110 to form a circulation line for the absorption liquid used to absorb carbon dioxide from the exhaust gas.

The heat exchanger 130 is provided to exchange heat between the absorption liquid that absorbs the carbon dioxide supplied from the absorption tower 110 and the absorption liquid from which the carbon dioxide is removed supplied from the regeneration tower 120, a preferred embodiment of the present invention. In the absorption tower 110, the absorption liquid absorbing the carbon dioxide transferred from the absorption tower 110 to the regeneration tower 120 is heat exchanged with the absorption liquid from which the carbon dioxide is removed and the carbon dioxide transferred from the regeneration tower 120 to the absorption tower 110 is exchanged within the absorption tower 110. The carbon dioxide absorption and carbon dioxide removal processes within the regeneration tower 120 can be performed smoothly. Since the chemical bonding between carbon dioxide and the absorption liquid performed within the absorption tower 110 corresponds to an exothermic reaction, and the removal of carbon dioxide performed within the regeneration tower 120 corresponds to an endothermic reaction, the temperature within the absorption tower 110 is It is advantageous to keep the temperature of the absorption liquid sprayed from the absorption tower 110 low while maintaining it low, and in the regeneration tower 120, on the contrary, it is advantageous to maintain the environment within the regeneration tower at a high temperature. Therefore, the heat exchanger 130 of the present invention exchanges heat with the high-temperature absorption liquid absorbed from the regeneration tower 120 with the low-temperature absorption liquid supplied from the absorption tower 110 to the regeneration tower 120, thereby performing heat exchange in the absorption tower and the regeneration tower. Carbon dioxide absorption and removal reactions can be performed smoothly.

The reboiler 140 can supply heat energy to the regeneration tower 120 to vaporize carbon dioxide captured in the absorption liquid. That is, the regeneration tower 120 receives heat energy from the reboiler 140 and performs an absorption liquid regeneration process. At this time, the vaporized and separated carbon dioxide 51 is discharged to the top of the regeneration tower 120, and the absorption liquid from which the carbon dioxide is separated can be transferred to the absorption tower 110 and regenerated.

The condenser 150 is provided to condense the mixed gas of carbon dioxide and water vapor discharged from the regeneration tower 120. The condenser 150 includes a cooler 151 that cools the mixed gas of carbon dioxide and water vapor by exchanging heat with cooling water, etc., a separation drum 153 that separates the cooled mixed gas of carbon dioxide and water vapor into gaseous carbon dioxide and liquid water, and the separation device. It may include a return pump 155 that is connected to the drum 153 to separate condensate and supply it back to the stripping tower 11.

Referring again to FIG. 2, when explaining the circulation line of the absorbent liquid and the flow path for transferring the absorbent liquid according to an embodiment of the present invention, the absorbent liquid collected in the water collection portion 117 of the absorption tower 110 is supplied through the first supply flow path 210. ) is transferred to the heat exchanger (130). The absorbent liquid whose temperature has been raised through the heat exchanger 130 is transferred to the regeneration tower 120 through the second supply passage 220, and is connected to one side of the regeneration tower 120, so that the absorbent liquid absorbing carbon dioxide is sprayed into the regeneration tower. It can be. The carbon dioxide removed from the absorption liquid in the regeneration tower 120 and the reboiler 140 is discharged to the condenser 150, and the absorption liquid from which the carbon dioxide has been removed is transferred to the heat exchanger 130 through the first recovery passage 230 and absorbed. After heat-exchanging with the low-temperature absorption liquid transferred from the tower 110, the absorption liquid is returned to the absorption tower 110 through the second recovery passage 240, thereby forming a circulation line for the absorption liquid.

In addition, a filter 410 is provided on the flow path of the absorption liquid supplied from the regeneration tower 120 to the absorption tower 110, that is, on the recovery passage, to filter out foreign substances in the absorption liquid. In a preferred embodiment of the present invention, the filter 410 is provided on the second recovery passage 240, which transports the absorption liquid from which carbon dioxide has been removed from the heat exchanger toward the absorption tower, so that the carbon dioxide in the absorption liquid is removed from the regeneration tower 120. If foreign substances are included in the absorption liquid during the process of removing or absorbing carbon dioxide in the exhaust gas in the absorption tower 110, the absorption liquid flows from the heat exchanger 130 to the absorption tower 110 to filter out the foreign substances before being reused. can do. The absorption liquid from which carbon dioxide has been removed from the first recovery passage 230 before entering the heat exchanger 130 is in a relatively high temperature state, and the carbon dioxide after heat exchange with the low-temperature absorption liquid heading from the absorption tower 110 toward the regeneration tower 120 is Since the removed absorption liquid is at a relatively low temperature, corrosion can be further prevented by providing the filter 410 between the absorption tower 110 and the heat exchanger 130.

In one embodiment of the present invention, the filters 410 and 420 are formed by overlapping meshes of various grid sizes or are provided as membrane filters with pores of different sizes formed on the flow path to separate foreign substances in the absorbent liquid. By forming the mesh and/or pores of the membrane filter to be smaller, foreign substances larger than the mesh and/or pores can be collected. The membrane filter is formed to a predetermined length within or surrounding the flow path and can absorb foreign substances in the absorbent liquid.

The filter 410 according to an embodiment of the present invention shown in FIGS. 4 and 5 may be a self-cleaning type filter for separating foreign substances of various sizes in the absorbent liquid. Unlike the case where the absorbent liquid simply contains foreign substances such as fine plankton and dust floating in the solution, the absorbent liquid contains foreign substances or pollutants separated from the exhaust gas generated from engines such as ships with seawater or ballast water. In this case, the absorbent liquid may contain foreign substances of various sizes, such as marine debris, floating objects, and pieces of fish and shellfish. In addition, in the case of ships, etc., for the unique purpose of securing a wide space, spaces such as machine rooms are designed to be relatively narrow, so the installation and replacement of filters must be minimized. Therefore, it is preferable that the filters 410 and 420 according to an embodiment of the present invention are equipped to automatically clean filtered foreign substances without replacing or dismantling the part that filters foreign substances. The self-cleaning type filter 410 may include a filter body 411, a filtering unit 412, and an automatic cleaning unit 413.

The filter body 411 forms the external skeleton of a self-cleaning type filter, and the absorbent liquid flowing inside through the inlet 4111 of the filter body 411 passes through a filtration unit located within the filter body 411. After foreign matter is filtered and treated, it is discharged through the outlet portion 4112 of the filter body 411. As shown in FIG. 9, the interior of the filter body 411 has a lower surface 4115 forming the lowermost surface of the filter body 411 with the inlet 4111 in between, and a partition forming the middle surface ( In the portion formed by (4114), the absorbent liquid before treatment flowing into the inlet portion (4111) is temporarily stored and then passes through the filter portion (412) to filter out foreign substances. Thereafter, the filtered absorbent liquid is temporarily stored in the portion formed by the partition wall 4114 and the upper surface 4113 that forms the uppermost surface of the filter body 411 with the outlet portion 4112 in between, and then is stored in the outlet portion 4112. ) may flow out into the supply channel or recovery channel. An opening is formed through the upper surface 4113 to allow the filtering unit 412 to enter the filter body 411, and can be closed after the filtering unit 412 is installed. An opening may be formed through the partition wall 4114 to allow the absorbent liquid temporarily stored at the lower side to flow into the filter unit 412.

The filtering unit 412 is configured to filter the absorbent liquid flowing into the filter body 411 to remove foreign substances, etc. The lower side is fixed to the partition wall 4114 and the upper side is fixed to the upper surface 4113. You can. The filtering unit 412 may preferably be formed by overlapping a plurality of layers of cylindrical mesh having various grid sizes, and thus foreign substances of different particle sizes can be filtered out step by step in the plurality of mesh layers. Since foreign matter accumulates on the inner peripheral surface of the filter unit 412 and the filtration function deteriorates, foreign substances on the inner peripheral surface of the filter unit 412 can be removed by the automatic cleaning unit 413, which will be described later.

The automatic cleaning unit 413 is configured to backwash foreign substances attached to the filtering unit 412. For this purpose, the automatic cleaning unit 413 is a driving unit that drives the automatic cleaning unit by a signal from a control unit (not shown). (4131), a suction unit 4132 that is connected to the driving unit 4131 and moves to suck in foreign substances attached to the filtering unit 412, and a discharge unit 4133 that discharges foreign substances sucked in from the suction unit 4132. may include.

The driving unit 4131 provides power for the automatic cleaning unit 413 to operate, and uses this power to rotate and/or move the suction unit 4132, which will be described later, up and down, and generally provides driving power. It may include a drive motor, one end of which is connected to the drive motor to rotate and/or move up and down, and a drive shaft that rotates and/or moves up and down in conjunction with a suction unit 4132, which will be described later, connected to the other end. At this time, a pair of limit switches for specifying a vertical movement interval are disposed on the drive shaft, so that the drive shaft can move up and down.

The suction unit 4132 is a part that is connected to the driving unit 4131 and moves to suck in foreign substances attached to the filter unit 412. One end extending toward the filter unit 412 contacts or is very close to the inner peripheral surface of the filter unit. As it gets closer, foreign substances and backwash water pass through the inlet formed in the center (i.e., due to the suction pressure from the inlet, the filtered absorbent liquid outside the filter passes back inside and is sucked in along with the attached foreign substances, which is called 'backwash water'). ), etc. are sucked in, and the sucked foreign substances, backwash water, etc. are moved to the discharge part 4133, which will be described later, through a pipe formed in the longitudinal direction, so that they can be discharged.

The discharge part 4133 is a part that discharges foreign substances sucked in from the suction part 4132. One end communicates with the suction part 4132 and the other end communicates with the outside to discharge foreign substances etc. to the outside. One side of the discharge part 4133 is a part that is connected to one side of the discharge part 4133 and provides suction force for suction/discharge of foreign substances attached to the filter 20, and is controlled by a control unit (not shown). An exhaust valve can be connected. That is, the air pressure inside the suction unit 4132 is adjusted by the exhaust valve, and foreign substances attached to the inner peripheral surface of the filtering unit 412 are sucked in.

Furthermore, in one embodiment of the present invention, in order to solve the problem that the space for installing a self-cleaning type filter is very narrow in the special environment of a ship, the suction part 4132 penetrates the lower surface 4115 to the discharge part 4133. It is connected so that the passage through which foreign substances are discharged from the discharge unit 4133 is located at the lower part of the body 411 rather than the upper part, and all of the discharge routes of foreign substances washed from each filtering unit 412 are communicated to create one By forming a backwash line, the device can be compactized and installation, replacement, and disassembly work is also made easier.

Referring to FIG. 6, in one embodiment of the present invention, the second recovery passage 240 may be provided to form a bypass 245 and/or a buffer tank 243 in relation to the filter 410. . The hourly flow rate at which the absorption liquid is sprayed, taken out, and transported in the absorption tower 110 and/or the regeneration tower 120 to capture carbon dioxide in the exhaust gas is different from the hourly flow rate of the absorption liquid that can be processed through the filter 410. can do. In this case, separation of the foreign matter phase can be performed efficiently through the bypass 245 and/or the buffer tank 243.

The absorbent liquid transferred from the supply end 241 of the second recovery passage on the heat exchanger side may be temporarily stored in the buffer tank 243 provided on the passage to the filter. The bypass 245 may be provided to connect the flow path from the heat exchanger to the filter and the flow path from the filter to the absorption tower, that is, the supply end 241 and the outlet end 247.

The absorbent liquid temporarily stored in the buffer tank 243 is transferred from the supply end 241 to the outlet end 247 through the bypass 245 without passing through the filter 410, or the absorbent liquid discharged from the outlet is controlled. It is circulated through a bypass and stored in the buffer tank 243, and then transferred back to the filter 410, and the foreign matter phase can be separated. In another embodiment of the present invention, even if there is no buffer tank, the absorbent liquid can flow to the bypass 245 and/or the filter 310 through the valve.

In one embodiment, in which the hourly flow rate of the absorption liquid transferred from the absorption tower 110 and/or the regeneration tower 120 is designed to be the same or correspond to the hourly flow rate filtered by the filter 410, the relationship between the recovery passage and the filter is as follows. Bypass and/or buffer tanks may not be provided. Additionally, it can be understood by those skilled in the art that even when the filter 410 is provided between the heat exchanger 130 and the absorption tower 110, the above-described configuration can be included in the second supply passage 220.

In another embodiment of the present invention, as shown in Figures 2 and 7, a second filter 420 is installed on the flow paths 230 and 240 through which the absorption liquid from which carbon dioxide has been removed is supplied from the absorption tower 110 to the regeneration tower 120. , 420') may be additionally included.

The second filters 420 and 420' are provided on the first supply passage 210 and/or the second supply passage 220 to separate and discharge the foreign matter phase in the absorption liquid that has absorbed carbon dioxide. The second filter 420 is preferably located in front of the heat exchanger 130, that is, between the heat exchanger 130 and the absorption tower 110, to centrifuge the absorption liquid treated at a relatively low temperature in order to further prevent corrosion. It may be provided on the first supply passage 210.

In another embodiment of the present invention shown in FIGS. 8 and 9, a centrifuge 310 is used instead of the filters 410 and 420 on the circulation line of the absorption liquid formed between the absorption tower 110 and the regeneration tower 120. , 320) may be provided. The centrifuges (310, 320) are provided to replace at least part of the filters (410, 420) on the flow path connecting the absorption tower (110), the regeneration tower (120), and the heat exchanger (130), or are provided as replacements for the filters (410, 420). 420) and is provided in series and/or parallel to filter out foreign substances in the absorbent liquid.

Referring to FIG. 10, the centrifuge 310 can separate the foreign material phase and the absorbent liquid by receiving the absorbent liquid and forcing the foreign material phase with a large specific gravity to flow from the center to the outside using centrifugal force caused by rotation. The centrifuge 310 may include a separator inlet 311, a rotor 312, a separation disk 313, an isolation space 314, a separator outlet 315, and a foreign matter tank 316. The centrifuge 310 may be made of a corrosion-resistant material to minimize or prevent corrosion caused by the absorbent liquid. In a preferred embodiment of the present invention, the centrifuge 310 may be made of a material such as stainless steel or nickel chromium alloy.

The separator inlet 311 receives the absorption liquid flowing from the absorption tower side and may be formed to be connected to the supply passage. The rotor 312 includes a plurality of separation disks 313 therein and is provided to rotate together with the absorbed absorbent liquid. The rotor may include an outlet port at the edge to discharge foreign matter that has drifted outward within the rotor. The outflow port may be formed as an opening that is always open so that foreign matter flowing beyond the separation disk 313 flows out into the isolation space below, but is temporarily opened and closed to allow fluid communication with the outside by a separately provided controller or sensor. It can also be formed as a port that can be used.

The isolation space 314 may be formed by surrounding the rotor 312 from the outside of the rotor so that foreign matter separated from the rotor accumulates. The separator outlet 315 discharges the absorbent liquid from which foreign substances have been removed, allowing the absorbent liquid that has absorbed carbon dioxide to be transferred to the regeneration tower 120 with the foreign substances removed. The foreign matter tank 316 may be provided to temporarily store and discharge foreign substances discharged from the isolation space.

When the centrifuge 310 is provided between the absorption tower 110 and the heat exchanger 130, the separator inlet 311 and the separator outlet 315 are connected to the first supply passage 210 to remove foreign substances. The absorbed liquid can be transferred to the heat exchanger (130).

Referring to FIG. 11 to describe another embodiment of the present invention, the present invention may be a marine carbon dioxide capture system 100 installed on a ship. The marine carbon dioxide capture system 100 is installed on a ship and can absorb carbon dioxide from exhaust gas containing pollutants generated from engines, etc., and emit purified exhaust gas. The marine carbon dioxide capture system 100 may further include a scrubber 160.

Referring to FIG. 12, the scrubber 160 removes harmful substances in the exhaust gas by spraying cleaning water while allowing the exhaust gas generated due to ship operation to flow inside. The scrubber 160 is preferably a wet scrubber, and contaminants can be removed by washing water sprayed or supplied from inside the scrubber while the exhaust gas passes through packing, dispersion means, etc. in the scrubber. The sprayed washing water may be seawater. Since the particles of the sprayed seawater are relatively small and the upward flow of the exhaust gas is relatively strong, foreign substances in the washing water may be mixed into the exhaust gas. The exhaust gas that has passed through the scrubber 160 may flow into the inlet 111 of the absorption tower 110 along the exhaust gas supply passage 250. Since the high-temperature exhaust gas flowing from the engine is cooled by the washing water while passing through the scrubber 160, a process of incidentally cooling the exhaust gas in the absorption tower 110 to absorb carbon dioxide from the exhaust gas is performed. It is omitted, allowing efficient carbon dioxide capture.

Referring to another embodiment of the present invention shown in FIGS. 13 to 16, the present invention may further include a manifold 170 that distributes the exhaust gas discharged from the scrubber 160. In the case of a marine carbon dioxide capture system, unlike the absorption tower 110 and regeneration tower 120 installed on land, there is a height limit (to prevent radar dead zone). Therefore, in one embodiment of the present invention, a plurality of absorption towers 110 and/or regeneration towers 120 may be provided to collect carbon dioxide in the plurality of absorption towers and/or regeneration towers. The manifold 170 may be provided between the scrubber 160 and the plurality of absorption towers 110 to supply exhaust gas discharged from the scrubber to the plurality of absorption towers. While the flow of the liquid absorption liquid can be controlled by a valve or the like in the passage between the plurality of absorption towers 110 and the regeneration tower 120, the exhaust gas flowing from the scrubber 160 to the absorption tower 110 is a gas. Since it is a phase, efficient distribution of exhaust gas is possible by providing a manifold.

Accordingly, the marine carbon dioxide capture system 100 according to the present invention flows from a plurality of absorption towers 110 through the first supply passage 210, the heat exchanger 130, and the second supply passage 220 to the regeneration tower 120. ), and transfer the absorption liquid from which carbon dioxide has been removed in the regeneration tower (120) through the first recovery passage (230), the heat exchanger (130), and the second recovery passage (240) to the absorption tower (110). ), forming a circulation line for the absorption liquid to be transferred to the absorption tower, and providing filters 410 on a plurality of passages supplied from the regeneration tower to the absorption tower. Preferably, the plurality of filters 410 are used to filter the absorption liquid from which carbon dioxide has been removed. It may be provided on a plurality of second recovery passages 240 that transport the heat exchanger 130 toward the absorption tower 110.

In addition, at least one second filter 420 for removing foreign substances in the absorption liquid may be provided on the flow path through which the absorption liquid absorbing carbon dioxide is supplied from at least one absorption tower to the regeneration tower, and the second filter 420 is preferably provided on the first supply passage 240 from the heat exchanger 130 to the absorption tower 110.

Furthermore, the plurality of filters 410 and/or the second filter 420 may be replaced by a plurality of centrifuges 310 and 320, or the filter may be provided together with the centrifuge to separate and remove foreign substances in the absorbent liquid. .

The above detailed description is illustrative of the present invention. Additionally, the foregoing is intended to illustrate preferred embodiments of the present invention, and the present invention can be used in various other combinations, modifications, and environments. That is, changes or modifications can be made within the scope of the inventive concept disclosed in this specification, a scope equivalent to the written disclosure, and/or within the scope of technology or knowledge in the art. The written examples illustrate the best state for implementing the technical idea of the present invention, and various changes required for specific application fields and uses of the present invention are also possible. Accordingly, the detailed description of the invention above is not intended to limit the invention to the disclosed embodiments. Additionally, the appended claims should be construed to include other embodiments as well.

100: Carbon dioxide capture system
110: absorption tower 120: regeneration tower
130: heat exchanger 140: reboiler
150: condenser 160: scrubber
170: manifold
210: 1st supply channel 220: 2nd supply channel
230: 1st recovery channel 240: 2nd recovery channel
250: Exhaust gas supply channel
310: centrifugal separator 311: separator inlet
312: rotor (312), 313: separation disk
314: Isolation space 315: Separator outlet
316: Foreign matter tank
410: Filter 411: Filter body
412: filtration unit 413: automatic cleaning unit

Claims (16)

A scrubber that removes harmful substances in the exhaust gas by spraying cleaning water while allowing the exhaust gas to flow inside,
A plurality of absorption towers that receive exhaust gas cooled by washing water while passing through the scrubber and remove carbon dioxide in the exhaust gas by reacting the exhaust gas with an absorption liquid;
A manifold between the scrubber and the plurality of absorption towers for supplying exhaust gas discharged from the scrubber to the plurality of absorption towers,
A plurality of regeneration towers that receive an absorption liquid absorbing carbon dioxide from the absorption tower, remove carbon dioxide from the absorption liquid, and transport the absorption liquid from which carbon dioxide is removed to the absorption tower;
A heat exchanger that exchanges heat between the absorption liquid that absorbs the carbon dioxide supplied from the absorption tower and the absorption liquid that removes the carbon dioxide supplied from the regeneration tower;
It includes a filter provided on the flow path of the absorption liquid supplied from the regeneration tower to the absorption tower to separate foreign substances flowing into the absorption liquid from the washing water,
The filter is a marine carbon dioxide capture system, characterized in that it is provided on a flow path through which the absorption liquid is supplied from the regeneration tower to the heat exchanger. delete delete The carbon dioxide capture system for ships according to claim 1, wherein the filter is a membrane filter having pores of different sizes. The method of claim 1, wherein the filter includes a filter body through which absorbent liquid flows in and out, a filtration unit that filters the absorbent liquid inside the filter body, and an automatic cleaning unit that backwashes foreign substances attached to the filter unit,
The automatic cleaning unit is an automatic cleaning type that includes a driving unit that drives the automatic cleaning unit by control, a suction unit that is connected to and drives the driving unit and sucks foreign substances attached to the filter, and a discharge unit that discharges foreign substances sucked in from the suction unit. A marine carbon dioxide capture system characterized by being equipped with a filter. The method of claim 5, wherein the filter body includes a lower surface forming a lowermost surface of the filter body, an upper surface forming an uppermost surface, and a partition having an opening between the upper surface and the lower surface,
A carbon dioxide capture system for ships, wherein one side of the filter part is fixed to the partition wall and the other side is fixed to one side of the filter body, so that the absorbent liquid flowing into one side of the filter body passes through the partition wall and is discharged to the other side. The method of claim 6, wherein the suction part penetrates the lower surface of the filter body and is connected to the discharge part,
A marine carbon dioxide capture system characterized by forming a single backwash line by communicating the discharge route of foreign substances washed from the filtration unit. The method of claim 5, further comprising a bypass connecting the flow path from the heat exchanger to the filter and the flow path from the filter to the absorption tower,
A carbon dioxide capture system for ships, characterized in that the absorbent liquid transferred from the regeneration tower through the heat exchanger is transferred to the absorption tower without passing through the filter, or the absorbent liquid discharged from the filter is circulated through the bypass. The method of claim 8, further comprising a buffer tank on a flow path from the heat exchanger to the filter, wherein the buffer tank temporarily stores the absorbent liquid supplied from the heat exchanger on the regeneration tower side and then flows to the bypass or filter. A marine carbon dioxide capture system characterized by flowing. The method according to any one of claims 1, 4 to 9, further comprising a second filter for removing foreign substances in the absorption liquid on a flow path through which the absorption liquid from which carbon dioxide has been removed is supplied from the absorption tower to the regeneration tower, The second filter is a marine carbon dioxide capture system, characterized in that it is provided on a flow path through which the absorption liquid is supplied from the absorption tower to the heat exchanger. The marine carbon dioxide capture system according to claim 10, wherein the second filter is provided on a flow path through which the absorption liquid is supplied from the absorption tower to the heat exchanger. delete delete delete delete delete

Images