KR101508207B1 - Carbon dioxide reduction system and calcium carbonate manufacturing method using the same - Google Patents

Abstract

The present invention relates to a system by which the carbon dioxide level in the ship′s exhaust gas can be reduced and the carbon dioxide is used to produce calcium carbonate (CaCO3). The carbon dioxide reduction system comprises: a micro-bubble-generating unit (120) that generates carbon dioxide-based bubbles using ballast water in the ship; a mixed liquid storage unit (130) that stores suspension liquid mixed with calcium ions and alkaline solutions; a spray unit (140) that sprays out the mixture at a high speed; a first reaction vessel (150) that processes the first round of carbonation of the carbon dioxide-based micro-bubbles; a second reaction vessel (160) that processes the second round of carbonation of the carbon dioxide-based micro-bubbles with the mixture reacted with the micro-bubbles; a recovery unit (170) that separates calcium carbonate out of the mixture from the secondary reaction from the second reaction vessel (160); a selection unit (180) that selects the calcium carbonate provided from the recovery unit (170) by size; a storage unit (190) that stores the calcium carbonate selected by size; and a control unit (300) that controls the whole working of the invention including the micro-bubble-generating unit (120), the spray unit (140), the first reaction vessel (150), the second reaction vessel (160), the recovery unit (170), and the selection unit (180).

Description

Technical Field [0001] The present invention relates to a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas, and a method for manufacturing calcium carbonate using the same. BACKGROUND ART [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a carbon dioxide reduction system, and more particularly, to a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas and a method of manufacturing calcium carbonate using the system

As the use of fossil fuels increases, carbon dioxide emitted in large quantities is designated as one of the greenhouse gas (GHG) that causes global warming.

Although carbon dioxide is lower than greenhouse gases due to the Global Warming Index, it accounts for approximately 80% of total greenhouse gas emissions and is also classified as a very important greenhouse gas in terms of regulating emissions.

Increasing interest in increasing atmospheric carbon dioxide concentration has limited the amount of carbon dioxide that can be emitted by each country. In recent years, there has been a growing interest in carbon dioxide emissions from ships, and there is a growing movement to regulate the amount of carbon dioxide emitted from ships.

Looking at the status of the marine engine emissions, it is generally assumed that the Lloyds-Fairplay Database is used as the basis for the data observed in relation to the estimation of emissions from marine engines (mostly diesel engines) .

According to this, the total number of athletes in 2007 was 45,620, and the emission of carbon dioxide was calculated as 83,995 million tons in 36,638 cargo ships, 93,67 million tons in 2,801 passenger ships, and 6,281 ships in 400 GT class and 9.82 million tons in carbon dioxide Of total emissions were 943.44 million tons.

Therefore, it can be inferred that carbon dioxide contributes greatly to marine pollution. Therefore, 'International Maritime Organization' is also pushing for such regulations.

On the other hand, the composition of ship exhaust gas is approximately 95.48% of CO2, 2.76% of NO2, 1.10% of SO2, 0.11% of CO, 0.33% of HC and 0.22% of PM (MAN Diesel standard 2004). In 2007, the global emissions of carbon dioxide from 45,620 vessels totaled 943.44 million tons, and regulations on CO2 emissions, which are the main cause of air pollution resulting from international ship operations, are being tightened.

Accordingly, in order to solve the conventional problems, in order to prevent the stability of the ship from being lowered as the center of gravity of the ship becomes higher due to the buoyant force when the cargo is taken out of the ship, the ship equilibrium Carbon dioxide micro bubbles are generated using ballast water and carbon dioxide discharged from the ship and then carbon dioxide is reduced in the mixed solution containing the basic solution and suspension to reduce the carbon dioxide of the ship and use carbon dioxide A carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas providing calcium carbonate, and a method for producing calcium carbonate using the same.

Korea Patent Registration No. 10-1036553 (Registration date May 17, 2011, "Method for producing carbonates using carbon dioxide microbubbles")

Accordingly, a problem to be solved by the present invention is to provide a carbon dioxide reduction system for reducing carbon dioxide in ship exhaust gas, which can provide high quality calcium carbonate by removing carbon dioxide from exhaust gas discharged from a ship, And a method for producing calcium carbonate using the same.

Another object of the present invention is to provide a carbon dioxide abatement system for reducing carbon dioxide in a ship exhaust gas which can improve the carbonation reaction through the microbubble device in the production of calcium carbonate using carbon dioxide of ship exhaust gas, And an object of the present invention is to provide a method for producing calcium carbonate.

According to a first aspect of the present invention, there is provided a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas, the system comprising the steps of: generating carbon dioxide microbubbles by using exhaust gas discharged from a ship and ship equilibrium water contained in the vessel; A micro bubble generator 120 for generating a micro bubble; A mixed solution storage part 130 for storing a mixed solution in which a suspension containing calcium ions and a basic solution are mixed; A jetting unit 140 for jetting the mixed solution at a high speed; A first reaction tank (150) for receiving the mixed solution injected from the injecting unit (140) and performing a primary carbonation reaction by receiving the carbon dioxide microbubbles therein; A second reaction tank 160 for performing a second carbonation reaction between the mixed solution reacted with the carbon dioxide microbubbles in the first reaction tank 150 and the carbon dioxide microbubbles; A recovery unit 170 for separating the calcium carbonate and the mixed solution produced in the second carbonated mixed solution in the second reaction tank 160; A sorting unit 180 for sorting the calcium carbonate provided in the collecting unit 170 by size; A storage unit 190 for storing the calcium carbonate selected by size; And controlling the driving of the micro bubble generating unit 120, the jetting unit 140, the first reaction tank 150, the second reaction tank 160, the recovery unit 170, and the sorting unit 180 And a control unit 300 for controlling the display unit.

According to a second embodiment of the present invention, there is provided a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas, comprising: a carbon dioxide capture processor 210 for capturing carbon dioxide in a ship exhaust gas; A micro bubble generator 220 for generating carbon dioxide micro bubbles by receiving carbon dioxide and ship ballast water collected by the carbon dioxide capture processor 210; A carbonation reaction unit 230 storing a mixed solution of a suspension containing calcium ions and a basic solution, in which the carbon dioxide microbubbles are supplied to cause a carbonation reaction; A recovery unit 240 for separating the calcium carbonate and the mixed solution produced in the carbonated reaction mixture in the carbonation reaction unit 230; A sorting unit 250 for sorting the calcium carbonate provided by the collecting unit 240 by size; A storage unit 260 for storing the calcium carbonate selected by size; And a control unit 300 for controlling the operation of the carbon dioxide capture unit 210, the micro bubble generator 220, the carbonation unit 230, and the collection unit 240.

According to a third embodiment of the present invention, there is provided a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas, comprising: a basic solution storage unit 435 for storing a basic solution; A micro bubble generator (420) for generating exhaust gas discharged from a ship and a basic solution stored in the basic solution storage to generate carbon dioxide micro bubbles; A suspension reservoir 436 for storing a suspension containing calcium ions; A jetting part 440 for jetting the mixed solution at high speed; A first reaction tank 450 for receiving the mixed solution sprayed from the jetting unit 440 and then performing a primary carbonation reaction by receiving the carbon dioxide microbubbles; A second reaction tank 460 for performing a second carbonation reaction of the mixed solution reacted with the carbon dioxide microbubbles in the first reaction tank 450 and the carbon dioxide microbubbles; A recovery unit 470 for separating the calcium carbonate and the mixed solution produced in the second carbonated mixed solution in the second reaction tank 460; A sorting unit 480 for sorting the calcium carbonate provided in the collecting unit 470 by size; A storage unit 490 for storing the calcium carbonate selected by size; And the driving of the micro bubble generator 420, the jetting unit 440, the first reaction tank 450, the second reaction tank 460, the recovery unit 470, and the sorting unit 480 And a control unit 300 for controlling the display unit.

The carbon dioxide capture processing unit 210 controls opening and closing operations of a collecting valve Vn formed in each of the plurality of gas channels to selectively distribute the ship exhaust gas to at least one of the plurality of gas channels A multi-channel valve port 211; And a carbon dioxide collecting part (212) for collecting carbon dioxide after removing impurity gas in the exhaust gas provided from the multi-channel valve port (211).

The collecting valve Vn may be a gate valve, a globe valve, a control valve, a check valve, a butterfly valve, a ball valve, And a diaphragm valve valve.

The collecting valve Vn is controlled electronically or mechanically according to a control signal of the controller 300. [

The suspension is characterized in that the concentration of the compound containing calcium ions is 0.05 to 0.5 M per liter of the suspension, further comprising an electrolyte, and the electrolyte is sodium chloride (NaCl).

The basic solution is characterized in that it is one selected from the group consisting of sodium hydroxide (NaOH), barium hydroxide (Ba (OH) 2), potassium hydroxide (KOH), ammonium hydroxide (NH4OH) and lithium hydroxide (LiOH).

The first reaction vessels 150 and 450 may be provided with pH sensors 151 and 451, conductivity measurement sensors 152 and 452, and temperature measurement units 151 and 452 so as to confirm completion of the reaction in the primary carbonation reaction process through acidity, conductivity, The second reaction vessels 160 and 460 are provided with pH sensors 161 and 461 for confirming the completion time of reaction in the secondary carbonation reaction process through acidity, conductivity and temperature, Conductivity measuring sensors 162 and 462, and temperature measuring sensors 163 and 463 are provided.

A method of manufacturing calcium carbonate using a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas according to claim 1 for solving the above problems is characterized in that in a micro bubble generator (120), carbon dioxide Generating a micro bubble (S110); A mixed solution injection step (S120) of injecting a mixed solution in which the suspension containing calcium ions and the basic solution mixed in the mixed solution storage part (130) is injected into the first reaction chamber (150) by the injection part (140); Performing a primary carbonation reaction (S130) in which a mixed solution in which a suspension containing calcium ions and a basic solution are mixed in the first reaction tank (150) and the carbon dioxide microbubbles are supplied to perform a primary carbonation reaction; Performing a secondary carbonization reaction (S140) in which the carbon dioxide microbubbles are supplied to the second reaction tank (160) to perform the secondary carbonation reaction after the primary carbonated mixed solution is received in the second reaction tank (160); A calcium carbonate recovery step (S150) for recovering calcium carbonate from the second carbonated mixed solution; A calcium carbonate selection step (S160) of sorting the recovered calcium carbonate by size; And a calcium carbonate storage step (S170) for storing calcium carbonate sorted by size.

The method for producing calcium carbonate using the carbon dioxide reduction system for reducing carbon dioxide in the ship exhaust gas according to claim 2 for solving the above problems is characterized in that the carbon dioxide capture processing unit 210 is used to collect carbon dioxide Step S210: A carbon dioxide microbubble generation step (S220) of receiving carbon dioxide and ship ballast water collected in S210 from microbubble generator 220 to generate carbon dioxide microbubbles; A carbonation reaction step (S230) of injecting the carbon dioxide microbubbles into a mixed solution in which a calcium ion-containing suspension and a basic solution are mixed in the carbonation reaction part 230 to perform a carbonation reaction; A step (S240) of recovering calcium carbonate by separating the calcium carbonate produced through the carbonation reaction from the mixed solution; A step (S250) of selecting calcium carbonate to sort the recovered calcium carbonate by size; And a calcium carbonate storage step (S260) for storing calcium carbonate sorted by size.

The method for manufacturing calcium carbonate using the carbon dioxide reduction system for reducing carbon dioxide in the ship exhaust gas according to claim 3 for solving the above problems is characterized in that the microbubble generator (420) is supplied with the ship exhaust gas and the basic solution, Generating a bubble (S410); A suspension injecting step (S420) of injecting a calcium ion-containing suspension stored in the suspension storing section (436) into the first reaction tank (450) at the jetting section (440); Performing a primary carbonation reaction (S430) for receiving a suspension containing calcium ions and the carbon dioxide microbubbles in the first reaction tank (450) and performing a primary carbonation reaction; Performing a secondary carbonation reaction step (S140) for receiving the primary carbonated suspension in the second reaction tank (160) and then supplying the carbon dioxide microbubbles again to perform a secondary carbonation reaction; A calcium carbonate recovery step (S150) of recovering calcium carbonate from the secondary carbonated suspension; A calcium carbonate selection step (S160) of sorting the recovered calcium carbonate by size; And a calcium carbonate storage step (S170) for storing calcium carbonate sorted by size.

According to the carbon dioxide reduction system for reducing carbon dioxide in the ship exhaust gas according to the embodiment of the present invention and the method for producing calcium carbonate using the same, the carbon dioxide in the exhaust gas discharged from the ship can be reduced.

Further, it has an advantage that calcium carbonate used for foods, papermaking and road packing materials can be produced by using the carbon dioxide captured in the exhaust gas of a ship.

In the present invention, since use of microbubbles, in the manufacture of calcium carbonate the air diffuser (air diffuser, AD) for which the rate of reaction than the cell using can accelerate up to 240%, CaCO ₃ of CO ₂ for each reaction vessel The conversion rate of CO ₂ can be maximally increased and the amount of CaCO ₃ production can be maximally increased.

1 is a block diagram showing a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas according to a first embodiment of the present invention.
FIG. 2A is a block diagram showing a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas according to a second embodiment of the present invention. FIG.
FIG. 2B is a block diagram showing the carbon dioxide capture processing unit shown in FIG. 2A in more detail.
3 is a block diagram showing a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas according to a third embodiment of the present invention.
4 is a flowchart illustrating a method of manufacturing calcium carbonate using a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas according to a first embodiment of the present invention.
5 is a flowchart illustrating a method of manufacturing calcium carbonate using a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas according to a second embodiment of the present invention.
FIG. 6 is a flowchart illustrating a method for manufacturing calcium carbonate using a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas according to a third embodiment of the present invention shown in FIG. 3;

BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects, features, and advantages of the present invention will become more readily apparent from the following description of preferred embodiments with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein but may be embodied in other forms.

Rather, the embodiments disclosed herein are provided so that the disclosure can be thorough and complete, and will fully convey the concept of the invention to those skilled in the art. In this specification, when an element is referred to as being on another element, it may be directly formed on another element, or a third element may be interposed therebetween. Also in the drawings

The thickness of the components is exaggerated for an effective description of the technical content.

Embodiments described herein will be described with reference to cross-sectional views and / or plan views that are ideal illustrations of the present invention. In the drawings, the thicknesses of the films and regions are exaggerated for an effective description of the technical content.

Thus, the shape of the illustrations may be modified by manufacturing techniques and / or tolerances. Accordingly, the embodiments of the present invention are not limited to the specific forms shown, but also include changes in the shapes that are produced according to the manufacturing process. For example, the etched area shown at right angles may be rounded or may have a shape with a certain curvature.

Thus, the regions illustrated in the figures have attributes, and the shapes of the regions illustrated in the figures are intended to illustrate specific forms of regions of the elements and are not intended to limit the scope of the invention. Although the terms first, second, etc. have been used in various embodiments of the present disclosure to describe various components, these components should not be limited by these terms. These terms have only been used to distinguish one component from another. The embodiments described and exemplified herein also include their complementary embodiments.

The terminology used herein is for the purpose of illustrating embodiments and is not intended to be limiting of the present invention. In the present specification, the singular form includes plural forms unless otherwise specified in the specification. The terms "comprises" and / or "comprising" used in the specification do not exclude the presence or addition of one or more other elements. Hereinafter, the present invention will be described in detail with reference to the drawings.

In describing the specific embodiments below, various specific details have been set forth in order to explain the invention in greater detail and to assist in understanding it. However, it will be appreciated by those skilled in the art that the present invention may be understood by those skilled in the art without departing from such specific details.

In some instances, it should be noted that portions of the invention that are not commonly known in the description of the invention and are not significantly related to the invention do not describe confusing reasons to explain the present invention.

Hereinafter, a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas according to an embodiment of the present invention and a method for producing calcium carbonate using the same will be described in detail with reference to the drawings.

1 is a block diagram showing a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas according to a first embodiment of the present invention.

As shown in FIG. 1, a carbon dioxide reduction system 100 for reducing carbon dioxide in a ship exhaust gas according to the first embodiment of the present invention uses carbon dioxide in exhaust gas generated from a boiler, an incinerator, and an engine of a ship The system for producing calcium carbonate includes a micro bubble generator 120, a mixed solution storage unit 130, a jetting unit 140, a first reaction tank 150, a second reaction tank 160, A sorting unit 180, a calcium carbonate storage unit 190,

The micro bubble generator 120 receives the exhaust gas discharged from the ship and the ballast water to generate carbon dioxide micro bubbles and provides the generated microbubbles to the first reaction vessel 150 and the second reaction vessel 160 .

For reference, a typical microbubble (MB) refers to a bubble present on an aqueous solution having a diameter of about 50 microns or less, and a device for generating the bubble is a microbubble generator (MBG) .

The mixed solution storage part 130 is a space in which a mixed solution in which a calcium ion-containing suspension and a basic solution are mixed is stored, wherein the concentration of the calcium ion-containing compound is 0.05 to 0.5M per 1 liter of the suspension And the suspension may further comprise an electrolyte. The compound containing calcium ion may be at least one selected from the group consisting of Ca (OH) 2 and CaSO4.2H2O. The electrolyte may be sodium chloride (NaCl). The basic solution may be one selected from the group consisting of sodium hydroxide (NaOH), barium hydroxide (Ba (OH) 2), potassium hydroxide (KOH), ammonium hydroxide (NH4OH) and lithium hydroxide (LiOH).

The injection unit 140 injects the mixed solution stored in the mixed solution storage unit 130 into the first reaction vessel 150.

The first reaction chamber 150 may be a space in which the mixed solution injected from the injector 140 and the carbon dioxide microbubbles are subjected to the primary carbonation reaction.

The second reaction tank 160 may be a space in which the mixed solution reacted with the carbon dioxide microbubbles in the first reaction tank 150 is again subjected to the secondary carbonation reaction with the carbon dioxide microbubbles.

The first reaction tank 150 is provided with an acidity sensor 151, a conductivity measurement sensor 152, and a temperature measurement sensor 153 so as to confirm completion of the reaction in the primary carbonation reaction process through acidity, conductivity and temperature .

Between the first reaction chamber 150 and the micro bubble generator 120, a carbon dioxide micro bubble supply valve Vm may be provided, and the carbon dioxide micro bubble supply valve Vm may be provided in the first reaction vessel 150 ) Of the carbon dioxide microbubbles injected into the gas-liquid separator.

The second reaction tank 160 is provided with an acidity sensor 161, a conductivity measurement sensor 162, and a temperature measurement sensor 163 so that the reaction completion time can be confirmed through acidity, conductivity and temperature in the secondary carbonation reaction And the acidity measurement value of the acidity sensor 161 may be set so that the reaction rate of the secondary carbonation reaction is 99% or more.

Like the first reaction vessel 150, the second reaction vessel 160 includes a carbon dioxide micro bubble supply valve Vm capable of controlling an inflow amount of the carbon dioxide micro bubbles supplied from the micro bubble generator 120 .

Here, the carbon dioxide microbubble supply valve Vm may be a gate valve, a globe valve, a control valve, a check valve, a butterfly valve, a ball valve, a ball valve, and a diaphragm valve. The control unit 300 controls the inflow amount by an electronic or mechanical method.

The recovery unit 170 performs a function of recovering calcium carbonate generated through carbonation in the first reaction tank 150 and the second reaction tank 160, respectively.

The sorting unit 180 performs a function of sorting the calcium carbonate provided in the collecting unit 170 by size.

The calcium carbonate storage unit 190 functions to store selected calcium carbonate by size.

FIG. 2A is a block diagram showing a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas according to a second embodiment of the present invention, and FIG. 2B is a block diagram showing the carbon dioxide capture processor shown in FIG. 2A in more detail.

2A, a carbon dioxide reduction system 200 for reducing carbon dioxide in a ship exhaust gas according to a second embodiment of the present invention includes a carbon dioxide capture processor 210, a micro bubble generator 220, A recovery unit 240, a sorting unit 250, a calcium carbonate storage unit 260, and a control unit 300.

Referring to FIG. 2B, the carbon dioxide capture unit 210 performs a function of collecting carbon dioxide from the exhaust gas of the ship. More specifically, the carbon dioxide capture unit 210 includes a multi-channel valve port 211 and a carbon dioxide capture unit 212.

The multi-channel valve port 211 is arranged such that a plurality of valves V1, V2, ..., Vn connected to the exhaust line of the ship are formed in a channel shape. Each of the channels is provided with a gas detection sensor 211a, and the gas detection sensor 211a detects the amount of exhaust gas flowing into each channel and whether or not the exhaust gas is introduced.

The control unit 300 controls the valves V1, V2, ..., Vn to control the amount of exhaust gas flowing into each of the channels CH1, CH2, ..., CHn according to the signals sensed by the gas sensor 211a. .

Here, the collecting valve Vn may be a gate valve, a globe valve, a control valve, a check valve, a butterfly valve, a ball valve, And a diaphragm valve. The collecting valve Vn may be electronically or mechanically controlled according to a control signal of the controller 300.

In addition, the carbon dioxide capture unit 210 may further include a carbon dioxide storage unit for storing the carbon dioxide collected in the carbon dioxide capture unit 212 provided for each channel in a liquid state or a liquid state.

The carbonation reaction part 230 stores a mixed solution in which a suspension containing calcium ions and a basic solution are mixed, and the carbon dioxide microbubbles generated in the microbubble generator 220 and the mixed solution, .

The suspension may have a concentration of the compound containing calcium ions of 0.05-0.5 M per liter of the suspension, and the suspension may further include an electrolyte. The compound containing calcium ion may be at least one selected from the group consisting of Ca (OH) 2 and CaSO4.2H2O. The electrolyte may be sodium chloride (NaCl). The basic solution may be one selected from the group consisting of sodium hydroxide (NaOH), barium hydroxide (Ba (OH) 2), potassium hydroxide (KOH), ammonium hydroxide (NH4OH) and lithium hydroxide (LiOH).

The microbubble generator 220 generates carbon dioxide microbubbles using the carbon dioxide and the ballast water collected in the carbon dioxide capture processor 210 and then supplies the generated carbon dioxide microbubbles to the carbonation reaction unit 230.

The carbon dioxide microbubble supply valve Vm may be provided between the microbubble generator 220 and the carbonation reaction unit 230. The carbon dioxide microbubble supply valve Vm may be provided between the carbonization reaction unit 230 and the carbon dioxide microbubble supply valve Vm, To control the inflow amount of the carbon dioxide microbubbles injected into the combustion chamber.

In the carbonation reaction part 230, there are provided an acidity sensor 231, a conductivity measurement sensor 232, and a temperature measurement sensor 233 so that the completion time of the carbon dioxide microbubbles and the reaction solution during the carbonation reaction of the mixed solution can be confirmed through the acidity, A sensor 233 may be provided.

Here, the acidity measurement value of the acidity sensor 231 is set so that the reaction rate of the carbonation reaction is 99% or more.

Here, the carbon dioxide microbubble supply valve Vm may be a gate valve, a globe valve, a control valve, a check valve, a butterfly valve, a ball valve, a ball valve, and a diaphragm valve. The control unit 300 controls the inflow amount by an electronic or mechanical method.

The recovery unit 240 performs a function of recovering calcium carbonate produced through carbonation.

The sorting unit 250 performs a function of sorting the calcium carbonate provided by the collecting unit 240 by size.

The calcium carbonate storage unit 260 functions to store calcium carbonate sorted by size.

3 is a block diagram showing a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas according to a third embodiment of the present invention.

3, the carbon dioxide reduction system 400 for reducing carbon dioxide in ship exhaust gas according to the third embodiment of the present invention uses carbon dioxide in the exhaust gas generated from a boiler, an incinerator, and an engine of a ship The system includes a micro bubble generating unit 420, a base aqueous solution storage unit 435, a current liquid storage unit 436, a jetting unit 440, a first reaction tank 450, A recovery unit 470, a sorting unit 480, a calcium carbonate storage unit 490,

The microbubble generator 420 receives the exhaust gas and the basic solution discharged from the ship and generates a carbon dioxide microbubble to be supplied to each of the first reaction vessel 150 and the second reaction vessel 160 do.

For reference, a typical microbubble (MB) refers to a bubble present on an aqueous solution having a diameter of about 50 microns or less, and a device for generating the bubble is a microbubble generator (MBG) .

The basic solution is stored in the basic solution storage part 435. The basic solution is a solution in which the basic solution is sodium hydroxide (NaOH), barium hydroxide (Ba (OH) 2), potassium hydroxide (KOH), ammonium hydroxide And lithium hydroxide (LiOH).

The suspension reservoir 436 is a space in which a calcium ion-containing suspension is stored. The suspension may have a concentration of the calcium ion-containing compound of 0.05-0.5 M per liter of the suspension, As shown in FIG. The compound containing calcium ion may be at least one selected from the group consisting of Ca (OH) 2 and CaSO4.2H2O. The electrolyte may be sodium chloride (NaCl).

The jetting unit 440 functions to jet the current sorbent stored in the suspension storage unit 436 into the first reaction tank 450.

The first reaction tank 450 may be a space in which the suspension injected from the jetting unit 440 and the carbon dioxide microbubbles are subjected to a primary carbonation reaction.

The second reaction tank 460 may be a space in which the suspension reacted with the carbon dioxide microbubbles in the first reaction tank 450 is again subjected to the secondary carbonation reaction with the carbon dioxide microbubbles.

Here, the first reaction tank 450 may include an acidity sensor 451, a conductivity measurement sensor 452, and a temperature measurement sensor 453 so as to confirm completion of reaction in the primary carbonation process through acidity, conductivity, and temperature .

A carbon dioxide microbubble supply valve Vm may be provided between the first reaction tank 450 and the microbubble generator 420 and the carbon dioxide microbubble supply valve Vm may be provided in the first reaction tank 450 ) Of the carbon dioxide microbubbles injected into the gas-liquid separator.

The second reaction tank 460 is provided with an acidity sensor 461, a conductivity measurement sensor 462, and a temperature measurement sensor 463 so as to confirm completion of the reaction in the secondary carbonation reaction process through acidity, conductivity and temperature And the acidity measurement value of the acidity sensor 461 may be set so that the reaction rate of the secondary carbonation reaction is 99% or more.

Like the first reaction tank 450, the second reaction tank 460 includes a carbon dioxide micro bubble supply valve Vm capable of controlling the inflow amount of the carbon dioxide micro bubbles supplied from the micro bubble generator 420 .

Here, the carbon dioxide microbubble supply valve Vm may be a gate valve, a globe valve, a control valve, a check valve, a butterfly valve, a ball valve, a ball valve, and a diaphragm valve. The control unit 300 controls the inflow amount by an electronic or mechanical method.

The recovery unit 470 performs a function of recovering calcium carbonate generated through carbonation in the first reaction tank 450 and the second reaction tank 460, respectively.

The sorting unit 480 performs a function of sorting the calcium carbonate provided in the collecting unit 470 by size.

The calcium carbonate storage unit 490 functions to store calcium carbonate sorted by size.

4 is a flowchart illustrating a method of manufacturing calcium carbonate using the carbon dioxide reduction system according to the first embodiment.

1 and 4, a method (S100) for producing calcium carbonate using a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas according to a first embodiment of the present invention includes a carbon dioxide microbubble generation step (S110) The step of performing the primary carbonation reaction S130, the step of performing the secondary carbonation reaction S140, the step of recovering the calcium carbonate S150, the step of sorting the calcium carbonate S160 and the step S170 of storing the calcium carbonate, .

The carbon dioxide microbubble generation step (S110) may be a step of generating the carbon dioxide microbubbles by receiving the ship exhaust gas and the ship ballast water from the microbubble generator 120.

The mixed solution injecting step S120 includes injecting a mixed solution containing a calcium ion-containing suspension and a basic solution stored in the mixed solution storage part 130 into the first reaction chamber 150 through the spray part 140 Lt; / RTI >

The step of performing the primary carbonation reaction (S130) may include a step of performing a primary carbonation reaction by receiving a mixed solution in which a calcium ion-containing suspension and a basic solution are mixed in the first reaction tank 150 and the carbon dioxide microbubbles .

The step of performing the secondary carbonation reaction (S140) may be a step of injecting the carbon dioxide microbubbles into the primary carbonated mixed solution to perform a secondary carbonation reaction.

The recovering step (S150) may be a step of recovering the calcium carbonate produced through the secondary carbonation reaction by separating the calcium carbonate from the mixed solution.

The sorting step (S160) may be a step of sorting the recovered calcium carbonate by size.

The calcium carbonate storage step (S170) may be a step of storing the selected calcium carbonate by size.

5 is a flowchart illustrating a method of manufacturing calcium carbonate using a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas according to a second embodiment of the present invention.

2A and FIG. 5, a method (S200) for producing calcium carbonate using a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas according to a second embodiment of the present invention includes a carbon dioxide collection step (S210), a carbon dioxide microbubble (Step S220), a carbonation reaction step S230, a calcium carbonate recovery step S240, a calcium carbonate selection step S250, and a calcium carbonate storage step S260.

The carbon dioxide capture step (S210) may be a step of capturing carbon dioxide from the ship exhaust gas using the carbon dioxide capture processing unit (210).

The carbon dioxide microbubble generation step S220 may be a step of generating carbon dioxide microbubbles in the microbubble generator 220 using the carbon dioxide and the ballast water collected in the carbon dioxide capture step S210.

In the carbonation reaction step S230, carbon dioxide microbubbles may be injected into the mixed solution of the calcium ion-containing suspension and the basic solution, which are stored in the carbonation reaction unit 230, to perform the carbonation reaction.

The calcium carbonate recovery step (S240) may be a step of separating and recovering calcium carbonate produced through the carbonation reaction from the mixed solution.

The step of selecting calcium carbonate (S250) may be a step of sorting the recovered calcium carbonate by size.

The calcium carbonate storage step (S260) may be a step of storing the selected calcium carbonate by size.

6 is a flowchart illustrating a method of manufacturing calcium carbonate using a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas according to a third embodiment of the present invention.

3 and 6, a method (S400) for producing calcium carbonate using a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas according to a third embodiment of the present invention includes a step of generating carbon dioxide microbubbles (S410) A carbonic acid recovery step S450, a calcium carbonate selection step S460, and a calcium carbonate storage step S470 are performed in the same manner as the first carbonation step S430, the first carbonation step S430, the second carbonation step S440, .

The carbon dioxide microbubble generation step S110 may be a step of generating the carbon dioxide microbubbles by receiving the ship exhaust gas and the basic solution from the microbubble generator 420.

The suspension injecting step S420 may be a step of injecting the calcium ion-containing suspension stored in the suspension storing part 436 into the first reaction tank 450 through the jetting part 440. [

The step of performing the primary carbonation reaction (S430) may be a step of performing a primary carbonation reaction by receiving the suspension containing calcium ions and the carbon dioxide microbubbles in the first reaction tank 450.

The step of performing the secondary carbonation reaction (S440) may be a step of re-injecting the carbon dioxide microbubbles into the primary carbonated suspension to carry out a secondary carbonation reaction.

The recovering step (S450) may be a step of separating and recovering calcium carbonate produced through the secondary carbonation reaction from the suspension.

The sorting step S460 may be a step of sorting the recovered calcium carbonate by size.

The calcium carbonate storage step (S470) may be a step of storing the selected calcium carbonate by size.

Therefore, the carbon dioxide abatement system for reducing carbon dioxide in ship exhaust gas according to the first to third embodiments of the present invention and the method for producing calcium carbonate using the same can reduce carbon dioxide in the exhaust gas discharged from a boiler, an incinerator, an engine, .

In addition, there is an advantage that calcium carbonate used for food, papermaking and road packing materials can be produced by using the carbon dioxide captured from the exhaust gas discharged from the ship.

In the present invention, since use of microbubbles, in the manufacture of calcium carbonate the air diffuser (air diffuser, AD) for which the rate of reaction than the cell using can accelerate up to 240%, CaCO ₃ of CO ₂ for each reaction vessel The conversion rate of CO ₂ can be maximally increased and the amount of CaCO ₃ production can be maximally increased.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the present invention.

First Embodiment
100: CO2 reduction system
120: micro bubble generator 130: mixed solution storage part
140: jetting unit 150: first reaction tank
151 and 161: Acidity sensors 152 and 162: Conductivity measuring sensors
153, 163: Temperature measuring sensor 160: Second reaction tank
170: recovery unit 180: selection unit
190: calcium carbonate storage part 300: control part
Second Embodiment
200: CO2 reduction system
210: carbon dioxide capture processor 220: micro bubble generator
230: carbonation reaction unit 231: acidity sensor
232: Conductivity measuring sensor 233: Temperature measuring sensor
240: recovery unit 250: sorting unit
260: calcium carbonate storage part 300: control part
Third Embodiment
400: CO2 reduction system
420: micro bubble generator 435: basic solution storage part
436: Suspension storage part
440: jetting unit 450: first reaction tank
451, 461: Acidity sensors 452, 462: Conductivity measuring sensors
453, 463: Temperature measuring sensor 460: Second reaction tank
470: Recovery unit 480:
490: calcium carbonate storage unit 300: control unit
V1 to Vn: collection valve
Vm: CO2 micro bubble supply valve

Claims (12)

A micro bubble generator 120 for generating carbon dioxide micro bubbles using the exhaust gas discharged from the ship and the ballast water contained in the vessel;
A mixed solution storage part 130 for storing a mixed solution in which a suspension containing calcium ions and a basic solution are mixed;
A jetting unit 140 for jetting the mixed solution at a high speed;
A first reaction tank (150) for receiving the mixed solution injected from the injecting unit (140) and performing a primary carbonation reaction by receiving the carbon dioxide microbubbles therein;
A second reaction tank 160 for performing a second carbonation reaction between the mixed solution reacted with the carbon dioxide microbubbles in the first reaction tank 150 and the carbon dioxide microbubbles;
A recovery unit 170 for separating the calcium carbonate and the mixed solution produced in the second carbonated mixed solution in the second reaction tank 160;
A sorting unit 180 for sorting the calcium carbonate provided in the collecting unit 170 by size;
A storage unit 190 for storing the calcium carbonate selected by size; And
And controls the driving of the micro bubble generator 120, the jetting unit 140, the first reaction tank 150, the second reaction tank 160, the recovery unit 170, and the sorting unit 180 A system for reducing carbon dioxide in a ship exhaust gas containing a control unit (300).
A carbon dioxide capture processing unit 210 for capturing carbon dioxide in the ship exhaust gas;
A micro bubble generator 220 for generating carbon dioxide micro bubbles by receiving carbon dioxide and ship ballast water collected by the carbon dioxide capture processor 210;
A carbonation reaction unit 230 storing a mixed solution of a suspension containing calcium ions and a basic solution, in which the carbon dioxide microbubbles are supplied to cause a carbonation reaction;
A recovery unit 240 for separating the calcium carbonate and the mixed solution produced in the carbonated reaction mixture in the carbonation reaction unit 230;
A sorting unit 250 for sorting the calcium carbonate provided by the collecting unit 240 by size;
A storage unit 260 for storing the calcium carbonate selected by size; And
The control unit 300 controls the operation of the carbon dioxide capture unit 210, the micro bubble generator 220, the carbonation reaction unit 230, and the collection unit 240. In this case, Carbon dioxide abatement system
A basic solution storage part 435 for storing a basic solution;
A micro bubble generator (420) for generating exhaust gas discharged from a ship and a basic solution stored in the basic solution storage to generate carbon dioxide micro bubbles;
A suspension reservoir 436 for storing a suspension containing calcium ions;
A jetting part 440 for jetting the suspension at high speed;
A first reaction tank 450 for receiving a suspension injected from the jetting unit 440 and then performing a primary carbonation reaction with the carbon dioxide microbubbles;
A second reaction tank 460 for performing a second carbonation reaction between the suspension reacted with the carbon dioxide microbubbles and the carbon dioxide microbubbles in the first reaction tank 450;
A recovery unit 470 for separating calcium carbonate and suspension produced in the second carbonated suspension in the second reaction tank 460;
A sorting unit 480 for sorting the calcium carbonate collected in the collecting unit 470 by size;
A storage unit 490 for storing the calcium carbonate selected by size; And
And controls the driving of the micro bubble generator 420, the jetting unit 440, the first reaction tank 450, the second reaction tank 460, the collection unit 470, and the sorting unit 480 A system for reducing carbon dioxide in a ship exhaust gas containing a control unit (300).
3. The method of claim 2,
The carbon dioxide capture processing unit 210,
A multi-channel valve port (211) for controlling opening and closing operations of a collecting valve (Vn) formed in each of a plurality of gas channels to selectively distribute the ship exhaust gas to at least one of the plurality of gas channels; And
And a carbon dioxide collecting part (212) for collecting carbon dioxide after removing the impurity gas in the exhaust gas provided from the multi-channel valve port (211).
5. The method of claim 4,
The collection valve (Vn)
A gate valve, a globe valve, a control valve, a check valve, a butterfly valve, a ball valve, a diaphragm valve, Wherein the exhaust gas purifying system is a CO 2 reducing system for reducing carbon dioxide in a ship exhaust gas.
6. The method of claim 5,
The collection valve (Vn)
And is controlled electronically or mechanically according to a control signal of the control unit (300). The system for reducing carbon dioxide in a ship exhaust gas according to claim 1,
4. The method according to any one of claims 1 to 3,
The suspension,
Wherein the concentration of the calcium ion-containing compound is 0.05 to 0.5 M per 1 liter of the suspension, further comprising an electrolyte, and the electrolyte is sodium chloride (NaCl). The carbon dioxide reducing system .
8. The method of claim 7,
The basic solution,
Wherein the exhaust gas is one selected from the group consisting of sodium hydroxide (NaOH), barium hydroxide (Ba (OH) 2), potassium hydroxide (KOH), ammonium hydroxide (NH4OH) and lithium hydroxide Carbon dioxide reduction system.
The method according to claim 1 or 3,
The first reaction vessel (150, 450)
Acidity sensors 151 and 451, conductivity measurement sensors 152 and 452, and temperature measurement sensors 153 and 453 are provided so that the reaction completion time can be confirmed through acidity, conductivity, and temperature in the primary carbonation process,
The second reaction vessel (160, 460)
Conductivity sensors 161 and 461, conductance measurement sensors 162 and 462, and temperature measurement sensors 163 and 463, which are provided to confirm completion of reaction in the secondary carbonation process through acidity, conductivity and temperature, Wherein the carbon dioxide is reduced in the exhaust gas of the ship.
A method for producing calcium carbonate using a carbon dioxide reduction system for reducing carbon dioxide in ship exhaust gas according to claim 1,
A step (S110) of generating microbubbles of carbon dioxide using the ship exhaust gas and the ship ballast water in the microbubble generator 120;
A mixed solution injection step (S120) of injecting a mixed solution in which the suspension containing calcium ions and the basic solution mixed in the mixed solution storage part (130) is injected into the first reaction chamber (150) by the injection part (140);
Performing a primary carbonation reaction (S130) in which a mixed solution in which a suspension containing calcium ions and a basic solution are mixed in the first reaction tank (150) and the carbon dioxide microbubbles are supplied to perform a primary carbonation reaction;
Performing a secondary carbonization reaction (S140) in which the carbon dioxide microbubbles are supplied to the second reaction tank (160) to perform the secondary carbonation reaction after the primary carbonated mixed solution is received in the second reaction tank (160);
A calcium carbonate recovery step (S150) for recovering calcium carbonate from the second carbonated mixed solution;
A calcium carbonate selection step (S160) of sorting the recovered calcium carbonate by size; And
And a calcium carbonate storage step (S170) for storing calcium carbonate sorted by size. The method for producing calcium carbonate using the carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas.
A method for producing calcium carbonate using a carbon dioxide reduction system for reducing carbon dioxide in ship exhaust gas according to claim 2,
A carbon dioxide capture step (S210) of capturing carbon dioxide in the ship exhaust gas using the carbon dioxide capture processing unit (210);
A carbon dioxide microbubble generation step (S220) of receiving carbon dioxide and ship ballast water collected in S210 from microbubble generator 220 to generate carbon dioxide microbubbles;
A carbonation reaction step (S230) of injecting the carbon dioxide microbubbles into a mixed solution in which a calcium ion-containing suspension and a basic solution are mixed in the carbonation reaction part 230 to perform a carbonation reaction;
A step (S240) of recovering calcium carbonate by separating the calcium carbonate produced through the carbonation reaction from the mixed solution;
A step (S250) of selecting calcium carbonate to sort the recovered calcium carbonate by size; And
And a storage step (S260) of storing calcium carbonate for storing calcium carbonate sorted by size. The method for producing calcium carbonate using a carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas.
A method for producing calcium carbonate using a carbon dioxide reduction system for reducing carbon dioxide in ship exhaust gas according to claim 3,
A step S410 of generating microbubbles of carbon dioxide by receiving the ship exhaust gas and the basic solution from the microbubble generator 420;
A suspension injecting step (S420) of injecting a calcium ion-containing suspension stored in the suspension storing section (436) into the first reaction tank (450) at the jetting section (440);
Performing a primary carbonation reaction (S430) for receiving a suspension containing calcium ions and the carbon dioxide microbubbles in the first reaction tank (450) and performing a primary carbonation reaction;
Performing a secondary carbonation reaction step (S140) for receiving the primary carbonated suspension in the second reaction tank (160) and then supplying the carbon dioxide microbubbles again to perform a secondary carbonation reaction;
A calcium carbonate recovery step (S150) of recovering calcium carbonate from the secondary carbonated suspension;
A calcium carbonate selection step (S160) of sorting the recovered calcium carbonate by size; And
And a calcium carbonate storage step (S170) for storing calcium carbonate sorted by size. The method for producing calcium carbonate using the carbon dioxide reduction system for reducing carbon dioxide in a ship exhaust gas.

Images