KR20230049543A - Exhaust gas treatment apparatus - Google Patents

Abstract

The present invention is to improve carbon dioxide reduction performance by utilizing waste liquid treated with exhaust gas. To this end, according to an embodiment of the present invention, an exhaust gas treatment apparatus may comprise: a gas-liquid reactor which brings exhaust gas into contact with treatment liquid and absorbs the emission regulated gas contained in the exhaust gas into the treatment liquid; a treatment liquid supply tank which supplies the treatment liquid to the gas-liquid reactor; a gas-liquid separation unit which separates the emission regulated gas from the treatment liquid, which absorbs the emission regulated gas drained from the gas-liquid reactor, and regenerates the treatment liquid; and an ion separation unit which ionizes the treatment liquid regenerated in the gas-liquid separation unit and supplies the treatment liquid enriched in negative ions to the gas-liquid separation unit, and supplies the treatment liquid enriched in positive ions to the treatment liquid supply tank.

Description

Exhaust gas treatment device {EXHAUST GAS TREATMENT APPARATUS}

The present invention relates to an exhaust gas treatment device for treating exhaust gas.

As regulations on exhaust gases discharged from ships are gradually strengthened, research on effectively removing sulfur oxides and carbon dioxide from exhaust gases discharged from ships has been continuously conducted.

In order to process the exhaust gas, an exhaust gas treatment device is installed in the ship, and the exhaust gas treatment device may treat the exhaust gas by injecting a treatment liquid into the exhaust gas. In the exhaust gas treatment system, seawater may be used as a treatment liquid. When seawater is used as a treatment liquid, sulfur oxides can be removed from the exhaust gas. However, since only a small amount of carbon dioxide can be removed, it is difficult to implement carbon dioxide reduction performance that can satisfy the Energy Efficiency Design Index of the International Maritime Organization under the United Nations.

Therefore, there is a need for a method capable of more effectively removing carbon dioxide from exhaust gas.

An object of the present invention is to improve carbon dioxide reduction performance by utilizing a waste treatment liquid that has treated exhaust gas.

Exhaust gas treatment apparatus according to an embodiment of the present invention, a gas-liquid reactor for absorbing the emission control gas contained in the exhaust gas into the treatment liquid by contacting the exhaust gas with the treatment liquid, and a treatment liquid supply for supplying the treatment liquid to the gas-liquid reactor tank, a gas-liquid separation unit for regenerating the treatment liquid by separating the emission regulation gas from the waste treatment liquid, which is the treatment liquid absorbing the emission regulation gas drained from the gas-liquid reactor, and ionizing the treatment liquid recovered in the gas-liquid separation unit to generate negative ions. An ion separation unit may be provided to supply the concentrated treatment liquid to the gas-liquid separation unit and to supply the treatment liquid enriched in cations to the treatment liquid supply tank.

In this embodiment, the ion separation unit may include an ion permeable membrane or an ion exchange resin.

In this embodiment, a waste treatment liquid formed in the gas-liquid reactor moves to the gas-liquid separation unit, a waste treatment liquid drain pipe and a booster pump coupled to the waste treatment liquid drain pipe to flow the waste treatment liquid to the gas-liquid separation unit. can include

In the present embodiment, a circulation pipe connecting the ion separation unit and the waste treatment liquid drain pipe may be further included, and the ion separation unit may supply the treatment liquid enriched with negative ions to the booster pump through the circulation pipe. .

In this embodiment, a particulate matter filtration unit coupled to the waste treatment liquid drain pipe to filter particulate matter included in the waste treatment liquid may be further included.

In this embodiment, the waste treatment liquid flowing into the gas-liquid separation unit may have a lower pH than the waste treatment liquid drained from the gas-liquid reactor.

In the present embodiment, the treatment liquid supply unit for supplying the treatment liquid to the treatment liquid supply tank is further included, and the treatment liquid supplied from the treatment liquid supply tank to the gas-liquid reactor is the treatment liquid supplied from the treatment liquid supply unit. pH may be higher.

In this embodiment, the emission control gas is sulfur oxide or carbon dioxide, and the treatment liquid may be seawater or an alkaline aqueous solution.

In this embodiment, a heat exchanger may be connected to the treatment liquid supply tank to cool the treatment liquid stored in the treatment liquid supply tank.

According to an embodiment of the present invention, since the treatment liquid enriched in cations is supplied to the treatment liquid supply tank using the ion separation unit and the treatment liquid enriched in anions is supplied to the gas-liquid separation unit, the gas-liquid reactor absorbs carbon dioxide more effectively. can do. In addition, the gas-liquid separation unit can more effectively separate the emission control gas.

1 is a diagram schematically showing an exhaust gas treatment device according to an embodiment of the present invention;

In order to help understand the characteristics of the present invention as described above, an exhaust gas treatment device related to an embodiment of the present invention will be described in more detail below.

The embodiments described below will be described based on the most suitable embodiments for understanding the technical characteristics of the present invention, and the technical characteristics of the present invention are not limited by the described embodiments, but the following It is to illustrate that the present invention can be implemented like the embodiments. Therefore, the present invention can be implemented with various modifications within the technical scope of the present invention through the embodiments described below, and these modified embodiments will be said to fall within the technical scope of the present invention. In addition, in the reference numerals described in the accompanying drawings to help understanding of the embodiments described below, among components that perform the same action in each embodiment, related components are indicated by the same or extended numbers.

1 is a diagram schematically showing an exhaust gas treatment device according to an embodiment of the present invention.

Referring to FIG. 1 , the exhaust gas treatment device 100 of this embodiment may include a gas-liquid reactor 200, a treatment liquid supply tank 300, a gas-liquid separation unit 400, and an ion separation unit 700. .

Exhaust gas discharged from an exhaust gas discharge device (not shown) such as an engine or a boiler may be introduced into the gas-liquid reactor 200 and flow therein. Further, in the gas-liquid reactor 200, the exhaust gas and the treatment liquid are brought into contact so that the emission control gas included in the exhaust gas is absorbed into the treatment liquid and removed. The emission control gas may be, for example, sulfur oxides or carbon dioxide. However, the emission regulating gas may be any emission regulating gas, as long as emission to the atmosphere such as nitrogen oxide is regulated. The gas-liquid reactor 200 may include a housing 210 and a treatment liquid injection unit 220 .

The housing 210 may be connected to an exhaust gas exhaust device. The housing 210 may include an inlet 211 , an outlet 212 , and a drain 213 . As shown in FIG. 1, the inlet 211 is provided on the lower side of the housing 210, the outlet 212 is provided on the upper surface of the housing 210, and the drain 213 is provided on the lower surface of the housing 210. may be provided. However, the portion of the housing 210 provided with the inlet 211, the outlet 212, or the drain 213 is not particularly limited.

The inlet 211 may be connected to an exhaust gas discharge device. Accordingly, the exhaust gas discharged from the exhaust gas discharge device may be introduced into the housing 210 through the inlet 211 and flow inside the housing 210 .

The treatment liquid may be injected into the housing 210 by the treatment liquid spray unit 220 . Accordingly, the exhaust gas flowing into the housing 210 may come into contact with the treatment liquid. In this way, when the exhaust gas comes into contact with the treatment liquid, emission control gases, such as sulfur oxides or carbon dioxide, contained in the exhaust gas are absorbed into the treatment liquid and can be removed from the exhaust gas. Exhaust gas from which the emission control gas has been removed may be discharged through the outlet 212 . In addition, the waste treatment liquid, which is the treatment liquid that has absorbed the emission control gas, may be drained through the drain port 213 .

A packing 230 may be provided inside the housing 210 . The contact area and contact time between the exhaust gas and the treatment liquid may be increased by the packing 230 . As a result, the treatment efficiency of the exhaust gas by the treatment liquid can be improved. The packing 230 may include a plurality of members having a plurality of holes formed therein.

The housing 210 may have a rectangular cross section. Also, the housing 210 may be installed inside a stack (not shown) of a ship (not shown).

The treatment liquid injection unit 220 may inject the treatment liquid into the exhaust gas flowing through the housing 210 . The treatment liquid spray unit 220 may include a treatment liquid flow pipe 221 and a treatment liquid spray nozzle 222 .

The treatment liquid flow pipe 221 may be connected to the treatment liquid supply tank 300 . The treatment liquid flow pipe 221 may be connected to the treatment liquid supply tank 300 through the treatment liquid supply pipe LP. A treatment liquid supply pump (PP) may be provided in the treatment liquid supply pipe (LP). Also, when the treatment liquid supply pump PP is driven, the treatment liquid stored in the treatment liquid supply tank 300 may flow through the treatment liquid flow pipe 221 .

The treatment liquid flow pipe 221 may pass through one surface of the housing 210 and be provided inside the housing 210 . In addition, the treatment liquid injection nozzle 222 may be partially provided in the treatment liquid flow pipe 221 provided inside the housing 210 . Accordingly, the treatment liquid supplied to the treatment liquid flow pipe 221 may be injected into the exhaust gas flowing inside the housing 210 through the treatment liquid injection nozzle 222 .

The treatment liquid supply tank 300 may supply the treatment liquid to the gas-liquid reactor 200 . Accordingly, the treatment liquid may be stored in the treatment liquid supply tank 300 . The treatment liquid stored in the treatment liquid supply tank 300 may be, for example, seawater or an alkaline aqueous solution such as an aqueous sodium hydroxide solution. However, the treatment liquid stored in the treatment liquid supply tank 300 is not particularly limited, and is sprayed into the exhaust gas to contact the exhaust gas to absorb the emission control gas included in the exhaust gas and to discharge it from the gas-liquid separation unit 400. As long as the regulating gas can be separated and regenerated, any well-known gas can be used.

One end of the treatment liquid supply pipe LP may be connected to the treatment liquid supply tank 300 . The other end of the treatment liquid supply pipe LP may be connected to the treatment liquid flow pipe 221 of the treatment liquid spray unit 220 . Also, when the treatment liquid supply pump PP of the treatment liquid supply pipe LP is driven, the treatment liquid in the treatment liquid supply tank 300 may be supplied to the treatment liquid injection unit 220 through the treatment liquid supply pipe LP. there is.

In addition, one end of the second recovery pipe LR2 may be connected to the treatment liquid supply tank 300 . The other end of the second recovery pipe LR1 may be connected to the ion separation unit 700 .

A heat exchanger HE may be connected to the treatment liquid supply tank 300 . The heat exchanger HE may perform heat exchange with the treatment liquid stored in the treatment liquid supply tank 300 to cool the treatment liquid to a temperature capable of relatively well absorbing the emission control gas included in the exhaust gas. The treatment liquid absorbs the emission control gas included in the exhaust gas in the gas-liquid reactor 200 to become a waste treatment liquid, and the temperature may rise due to the hot exhaust gas. In this way, when the waste treatment liquid whose temperature is higher than that of the treatment liquid before being injected into the gas-liquid reactor 200 is regenerated in the gas-liquid separation unit 400, the regenerated treatment liquid is also higher than the treatment liquid before being injected into the gas-liquid reactor 200. The temperature may rise. When the treatment liquid whose temperature has risen as described above is supplied to the treatment liquid supply tank 300, the temperature of the treatment liquid stored in the treatment liquid supply tank 300 also rises, so that the emission regulation gas absorption rate of the treatment liquid may decrease. Accordingly, the exhaust gas treatment device of the present embodiment cools the temperature of the treatment liquid stored in the treatment liquid supply tank 300 to a temperature that can relatively well absorb the emission control gas contained in the exhaust gas by using the heat exchanger (HE). . Accordingly, it is possible to prevent a decrease in the emission control gas absorption rate of the treatment liquid due to an increase in the temperature of the treatment liquid.

Meanwhile, in the exhaust gas treatment device 100 of the present embodiment, the treatment agent supply unit 600 may be supplied to the treatment liquid supply tank 300 through the treatment agent supply pipe LT connected to the treatment liquid recovery pipe LR.

Here, the treatment agent may be an alkaline treatment agent such as sodium hydroxide, and the treatment agent supply pipe LT may be connected to the second recovery pipe LR2. Accordingly, the treatment agent may be introduced into the treatment liquid supply tank 300 by flowing through the treatment agent supply pipe LT and the second recovery pipe LR2. However, the configuration of the present invention is not limited thereto, and various modifications are possible as necessary, such as omitting the treatment agent supply pipe LT and directly connecting the treatment agent supply unit 600 to the treatment liquid supply tank 300 .

The gas-liquid separation unit 400 separates the emission regulation gas from the waste treatment liquid, which is the treatment liquid that has absorbed the emission regulation gas drained from the gas-liquid reactor 200, and regenerates the treatment liquid into the treatment liquid, and regenerates the treatment liquid into the treatment liquid supply tank. (300) side can be supplied. In this way, since the treatment liquid can be recycled and reused, the cost required for treating the exhaust gas can be reduced.

One end of the waste treatment liquid drain pipe LD may be connected to the drain 213 of the gas-liquid reactor 200, and the other end of the waste treatment liquid drain pipe LD may be connected to the gas-liquid separation unit 400. Accordingly, the waste treatment liquid discharged through the drain 213 of the gas-liquid reactor 200 may flow to the gas-liquid separation unit 400 through the waste treatment liquid drain pipe LD. At this time, a drain pump (PM) may be provided in the waste treatment liquid drain pipe (LD) for smooth flow of the waste treatment liquid.

In addition, a filtering treatment unit (WTS) may be provided in the waste treatment liquid drain pipe LD to filter and treat contaminants other than emission control gases included in the waste treatment liquid. Contaminants other than the emission control gas included in the waste treatment liquid include, for example, particulate matter and oil. The filtration treatment unit (WTS) may filter pollutants other than emission control gases included in the waste treatment liquid flowing into the gas-liquid separation unit 400 through the waste treatment liquid drain pipe (LD). Accordingly, for example, particulate matter, oil, etc. included in the waste treatment liquid are filtered by the filtration treatment unit (WTS), and contaminants included in the treatment liquid regenerated in the gas-liquid separation unit 400 are minimized, thereby minimizing gas-liquid The performance of the gas-liquid separation membrane 420 included in the separation unit 400 can be protected. The filtration treatment unit (WTS) may include, for example, a filter (not shown) or may filter particulate matter, oil, and the like from the waste treatment liquid by using centrifugal force or the like. However, the configuration in which the filtration treatment unit (WTS) filters particulate matter, oil, etc. from the waste treatment liquid is not particularly limited, and any known configuration is possible.

The treatment liquid recovery pipe LR is a flow path through which the regenerated treatment liquid discharged from the gas-liquid separation unit 400 flows into the treatment liquid supply tank 300, and includes a first recovery pipe LR1 and a second recovery pipe LR2. can include

One end of the first recovery tube LR1 may be connected to the gas-liquid separation unit 400 and multiple stages may be connected to the ion separation unit 700 . Also, one end of the second recovery pipe LR2 may be connected to the ion separation unit 700 and the other end may be connected to the treatment liquid supply tank 300 . Accordingly, at least a part of the treatment liquid regenerated by the gas-liquid separation unit 400 may be supplied to the treatment liquid supply tank 300 through the treatment liquid recovery pipe LR and reused as the treatment liquid.

The gas-liquid separation unit 400 includes a gas-liquid separation membrane 420 through which gas passes but liquid does not pass. The gas flow path 412 may be partitioned. Therefore, in the gas-liquid separation unit 400, gaseous emission regulation gas passes through the gas-liquid separation membrane 420, but liquid waste treatment liquid may not pass through the gas-liquid separation membrane 420. For example, the gas-liquid separation membrane 420 may be a hollow fiber membrane.

A low partial pressure may be formed in the gas flow path 412 . Accordingly, the emission control gas absorbed in the waste treatment liquid may move to the gas flow path 412 having a low partial pressure while flowing through the liquid flow path 411 . Here, the low partial pressure means a state in which the concentration of the emission control gas is low. Taking carbon dioxide among the emission control gases as an example, since the concentration of carbon dioxide is low in the gas flow path 412, a low partial pressure of carbon dioxide is formed. The lower the partial pressure, the lower the solubility of the gas in the liquid, so that the emission control gas absorbed in the waste treatment liquid flows through the liquid flow path 411 and passes through the gas-liquid separation membrane 420 to the gas flow path 412. do. In order to form a low partial pressure in the gas flow passage 412, the gas flow passage 412 may be formed at a negative pressure.

As described above, the gas-liquid separation unit 400 of the present embodiment can regenerate the waste treatment liquid into a treatment liquid that can be reused by separating the emission control gas from the waste treatment liquid. In the case of using such a method, since the amount of the treatment agent to be supplied to the recycled treatment fluid can be reduced, the cost required for regenerating the waste treatment fluid can be reduced. Accordingly, the cost required for treating the exhaust gas can be reduced.

The gas-liquid separation unit 400 may include a separation unit body 410 . The interior of the separation unit body 410 may be partitioned into a liquid flow path 411 and a gas flow path 412 by the gas-liquid separation membrane 420 .

The waste treatment liquid drain pipe (LD) connected to the drain 213 of the gas-liquid reactor 200 is connected to one side of the liquid flow path 411, and the other side of the liquid flow path 411 is connected to the treatment liquid recovery pipe (LR). It may be connected to the treatment liquid supply tank 300 . Accordingly, the waste treatment liquid discharged through the drain 213 of the gas-liquid reactor 200 may flow into the liquid flow path 411 and flow through the liquid flow path 411 . In addition, while flowing through the liquid flow path 411, the emission regulation gas is separated and the regenerated treatment liquid flows into the treatment liquid recovery pipe LR and flows into the treatment liquid supply tank 300 through the treatment liquid recovery pipe LR. can do.

A gas recovery pipe (LG) equipped with a vacuum pump (PV) may be connected to one side of the gas flow path 412 . Accordingly, when the vacuum pump PV is driven, negative pressure may be formed in the gas flow path 412 . In addition, an air inlet pipe (LA) equipped with a flow control valve (VC) may be connected to the other side of the gas flow path 412 . Accordingly, in a state in which the vacuum pump (PV) is driven, the flow control valve (VC) is operated to adjust the flow rate of the air introduced into the air inlet pipe (LA), thereby reducing the internal pressure of the gas flow passage (412). It can be adjusted lower than the surroundings.

When high-sulfur fuel is used in the exhaust gas exhaust device, a relatively large amount of sulfur oxides is included in the exhaust gas discharged from the exhaust gas exhaust device. As such, when the exhaust gas containing a large amount of sulfur oxides flows into the housing 210 of the gas-liquid reactor 200, the treatment liquid injected into the exhaust gas by the treatment liquid injection unit 220 releases the sulfur oxides contained in the exhaust gas. is mainly removed from the exhaust gas. That is, in the gas-liquid reactor 200, exhaust gas is desulfurized by the treatment liquid. In this way, the waste treatment liquid from which sulfur oxides are removed from the exhaust gas contains sulfur oxides, and the gas-liquid separation unit 400 separates sulfur oxides, such as sulfur dioxide, from the waste treatment liquid, emission control gases.

When low-sulfur fuel is used in the exhaust gas exhaust device, the exhaust gas discharged from the exhaust gas exhaust device contains relatively little sulfur oxides. As such, when the exhaust gas containing a small amount of sulfur oxide is introduced into the housing 210 of the gas-liquid reactor 200, the treatment liquid injected into the exhaust gas by the treatment liquid injection unit 220 removes carbon dioxide contained in the exhaust gas. It is mainly removed from the exhaust gas. In this way, the waste treatment liquid from which carbon dioxide is removed from the exhaust gas contains carbon dioxide, and the gas-liquid separation unit 400 separates the carbon dioxide from the waste treatment liquid.

The ion separation unit 700 may be installed at the rear end of the gas-liquid separation unit 400, and may ionize the treatment liquid regenerated in the gas-liquid separation unit to separate anions and cations.

To this end, the ion separation unit 700 may include a separation membrane or an ion exchange resin. However, it is not limited thereto, and various modifications are possible as long as the treatment liquid can be ionized into anions and cations.

Anions separated in the ion separation unit 700 may be used as an acidification inducing substance that lowers the pH of the treatment solution, and cations may be used as a basicization inducing substance that increases the pH of the treatment solution.

The exhaust gas treatment device 100 according to the present embodiment may supply a treatment liquid in which positive ions are concentrated among the regenerated treatment liquid to the treatment liquid supply tank 300 . Accordingly, the basicity of the treatment liquid may be increased.

In this way, when the basicity of the treatment liquid is increased, the amount of carbon dioxide absorbed by the treatment liquid in the gas-liquid reactor 200 may be increased. In the case of carbon dioxide, it can be absorbed only when a treatment liquid having a higher basicity than sulfur oxides is supplied. However, when the treatment agent having a high basicity is continuously supplied from the treatment agent supply unit 600 in consideration of the absorption of carbon dioxide, there is a problem in that the cost greatly increases.

However, since the exhaust gas treatment device 100 of the present embodiment can continuously supply the treatment liquid enriched in cations to the treatment liquid supply tank 300 through the ion separation unit 700, the treatment agent supplied from the treatment agent supply unit 600 amount can be minimized. Therefore, it is possible to minimize the cost required for removing carbon dioxide from exhaust gas.

On the other hand, among the treatment liquids regenerated by the ion separation unit 700, the treatment liquid in which anions are concentrated passes through the circulation pipe LF connecting the ion separation unit 700 and the waste treatment liquid drain pipe (LD) to the waste treatment liquid drain pipe ( LD) can be supplied. Accordingly, the treatment liquid with concentrated anions may be combined with the waste treatment liquid discharged through the drain 213 of the gas-liquid reactor 200 and supplied to the gas-liquid separation unit 400 again. In this case, since the H+ ion of the waste treatment liquid is increased by the increased anion, the pH can be lowered. In addition, as H+ ions increase, carbonic acid or carbon dioxide absorbed in the waste treatment liquid can be easily vaporized, so that carbon dioxide can be more effectively separated from the waste treatment liquid.

It may also include a gas processing unit 500 of the exhaust gas processing device 100 according to the present embodiment. The gas treatment unit 500 may process the emission control gas separated from the waste treatment liquid in the gas-liquid separation unit 400 .

In the gas processing unit 500, it is possible to process the emission control gas by dissolving it in seawater in an environmentally friendly ionic state. For example, in the gas treatment unit 500, carbon dioxide, which is an emission control gas, can be treated by dissolving carbon dioxide in seawater with eco-friendly ionizing substances in a natural state such as carbonic acid, bicarbonate, and carbonate, and in the case of sulfur oxides, natural state such as sulfuric acid and sulfate It is an eco-friendly ionized material that can be treated by dissolving it in seawater.

In addition, the gas processing unit 500 may store and process the emission control gas separated from the waste treatment liquid in the gas-liquid separation unit 400 . In some areas of the sea (SEA), zero-discharge conditions may be required whereby no substances are discharged from ships or the like. Therefore, when a ship is operating in such an area, the gas treatment unit 500 can store the emission regulation gas separated from the waste treatment liquid in the gas-liquid separation unit 400. In this way, the emission regulation gas stored in the gas processing unit 500 can be supplied to a place of use that requires it, and for this purpose, the gas processing unit 500 may include a gas storage tank in which the emission regulation gas is stored. . For example, the gas processing unit 500 may liquefy the emission control gas and store the emission control gas in a gas storage tank in a liquid state.

As described above, when the exhaust gas treatment device according to the present invention is used, the waste treatment liquid can be regenerated by the gas-liquid separation unit that separates the emission control gas from the waste treatment liquid treated with the exhaust gas, and the waste treatment liquid treated with the exhaust gas The recycling rate of the treatment liquid can be increased, the cost for treating the exhaust gas in the exhaust gas treatment device can be reduced, and the size of the exhaust gas treatment device can be reduced.

In addition, since the treatment liquid enriched in cations is supplied to the treatment liquid supply tank using the ion separation unit, and the treatment liquid enriched in anions is supplied to the gas-liquid separation unit, carbon dioxide can be absorbed more effectively in the gas-liquid reactor, and the gas-liquid separation unit It is possible to more effectively separate the emission control gas from the

The exhaust gas treatment device described above is not limited to the configuration of the above-described embodiment, but the above embodiments may be configured by selectively combining all or part of each embodiment so that various modifications can be made. there is.

100: exhaust gas treatment device
200: gas-liquid reactor
300: treatment liquid supply tank
400: gas-liquid separation unit
500: gas treatment unit
600: treatment agent supply unit
700: ion separation unit

Claims (9)

a gas-liquid reactor for contacting the exhaust gas with the treatment liquid to absorb the emission control gas included in the exhaust gas into the treatment liquid;
a treatment liquid supply tank supplying a treatment liquid to the gas-liquid reactor;
a gas-liquid separation unit configured to separate the emission control gas from the waste treatment liquid drained from the gas-liquid reactor and absorb the emission control gas, and regenerate the treatment liquid; and
an ion separation unit for ionizing the treatment liquid regenerated in the gas-liquid separation unit, supplying the treatment liquid enriched in negative ions to the gas-liquid separation unit, and supplying the treatment liquid enriched in cations to the treatment liquid supply tank;
Exhaust gas treatment device comprising a.
The method of claim 1, wherein the ion separation unit,
An exhaust gas treatment device comprising an ion permeable membrane or an ion exchange resin.
According to claim 1,
a waste treatment liquid drain pipe through which the waste treatment liquid formed in the gas-liquid reactor moves to the gas-liquid separation unit; and
a drain pump coupled to the waste treatment liquid drain pipe to flow the waste treatment liquid to the gas-liquid separation unit;
Exhaust gas treatment device further comprising a.
According to claim 3,
Further comprising a circulation pipe connecting the ion separation unit and the waste treatment liquid drain pipe,
The ion separation unit supplies an anion-enriched treatment liquid to the drain pump through the circulation pipe.
According to claim 3,
and a particulate matter filtration unit coupled to the waste treatment liquid drain pipe to filter particulate matter included in the waste treatment liquid.
According to claim 1,
The waste treatment liquid flowing into the gas-liquid separation unit has a lower pH than the waste treatment liquid drained from the gas-liquid reactor.
According to claim 1,
Further comprising a treatment liquid supply unit supplying the treatment liquid to the treatment liquid supply tank,
The treatment liquid supplied from the treatment liquid supply tank to the gas-liquid reactor has a higher pH than the treatment liquid supplied from the treatment liquid supply unit.
The exhaust gas treatment device according to claim 1, wherein the emission control gas is sulfur oxide or carbon dioxide, and the treatment liquid is seawater or an alkaline aqueous solution.
The exhaust gas treatment device according to claim 1, wherein a heat exchanger is connected to the treatment liquid supply tank to cool the treatment liquid stored in the treatment liquid supply tank.

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