KR101077574B1 - Apparatus and method for continuous capture of carbon dioxide - Google Patents

Abstract

The present invention relates to an apparatus and method for continuously collecting exhaust gas carbon dioxide using calcium hydroxide, and in detail, by measuring the pH of the absorbent liquid in real time, when the pH of the absorbent liquid is lower than the reference value, the removal efficiency is lowered. After the reaction is discharged to the outside, and measuring the water level of the absorbent liquid relates to a continuous collection device and method for exhaust gas carbon dioxide continuous capture using calcium hydroxide to automatically replenish the new absorbent liquid.

Description

Apparatus and method for continuously collecting exhaust gas carbon dioxide using calcium hydroxide {APPARATUS AND METHOD FOR CONTINUOUS CAPTURE OF CARBON DIOXIDE}

The present invention relates to an apparatus and method for continuously collecting exhaust gas carbon dioxide using calcium hydroxide, and more particularly, by measuring the pH of an absorbent liquid mixed with Ca (OH) ₂ and an additive in real time, the pH of the absorbent liquid is lower than a reference value, thereby lowering the removal efficiency. In case of loss, the absorbent liquid is re-reacted with the incoming exhaust gas and discharged to the outside, and when the level of the absorbent liquid is lowered, the exhaust gas carbon dioxide continuously using calcium hydroxide is replenished with a new absorbent liquid to enable continuous operation. It relates to a collecting device and a method.

With the development of the industry, the problem of global warming due to the increase in atmospheric concentration of carbon dioxide is emerging. The biggest cause of the increase in atmospheric carbon dioxide concentration is the fossil fuel such as coal, petroleum and liquefied natural gas used in the energy industry. Is the use of.

From the early 19th century, when the industrialization began, the concentration of greenhouse gases such as carbon dioxide (CO ₂ ), methane (CH ₄ ), hydrogen sulfide (H ₂ S) and carbonyl sulfide (COS) increased in the atmosphere, and rapidly increased since the mid-20th century. It was.

As global warming is accelerating due to this increase in greenhouse gases, regulations on emissions and treatments are becoming more stringent. The United Nations Conference on Environment and Development in Rio, Brazil, in June 1992 has raised international interest in global warming, and developed countries, including the United States and Japan, have decided to reduce global greenhouse gas emissions by 5.2% in 2010 compared to 1990. International agreements are being made on ways to reduce acid gases, including agreements. In particular, the separation of carbon dioxide, which makes up about 80% of the greenhouse gases that cause global warming, has emerged as an important issue.

Techniques for suppressing carbon dioxide emissions include energy saving technologies for reducing emissions, separation recovery of emitted carbon dioxide, technology for using or immobilizing carbon dioxide, and renewable energy technologies that do not emit carbon dioxide.

As a carbon dioxide separation recovery technology studied so far, absorption, adsorption, membrane separation, deep cooling, etc. have been proposed as realistic alternatives. In particular, the absorption method is easy to treat a large amount of gas and is suitable for low concentration gas separation, which is easily applied to most industrial and power plants, and is currently in commercial operation.

Conventional carbon dioxide separation and recovery technology using the absorption method consists of a process of absorbing carbon dioxide into the absorber by reacting the absorbent and the exhaust gas in the absorption tower and then transporting the carbon dioxide to the stripping column to remove carbon dioxide from the absorbent.

The inside of the absorption tower is filled with a porous filler for the dispersion of the absorbent, the liquid absorbent is dispersed in the upper portion of the absorption tower, a mixed gas containing carbon dioxide is supplied to the lower portion of the absorption tower.

According to the absorption tower configured as described above, the liquid absorbent is dispersed into the porous packing material, and the exhaust gas rises to pass through the packing material and undergo a countercurrent reaction with the absorbent material. Through this reaction, carbon dioxide contained in the mixed gas is absorbed by the absorbent.

Carbon dioxide separated by stripping reaction after absorption is stored on land or seabed. However, the cost of separating and storing carbon dioxide is enormous, so the alternative process is to collect CO ₂ as recycled calcium carbonate (CaCO ₃ ) using calcium hydroxide (Ca (OH) ₂ ), which is a liquid absorbent. Desulfurization agent, cement factory raw materials). In this case, the reaction was performed by adding and mixing sodium hydroxide as a reaction continuum and magnesium oxide as a reaction retardant in an aqueous solution of calcium hydroxide (Ca (OH) ₂ ) prepared by dissolving water in quicklime as calcium oxide.

Ca (OH) ₂ + CO ₂ → CaCO ₃ + H ₂ O

However, since the calcium hydroxide solution reacts rapidly with carbon dioxide, it contains magnesium oxide (MgO), a reaction retardant, to remove carbon dioxide while controlling the reaction rate.

However, in the case of the above process, there is a problem that the absorption tower volume required for the contact of the liquid absorbent and carbon dioxide required for the reaction in the absorption tower is too large.

The present invention is to solve the above problems, sampling the absorbent liquid falling from the upper portion of the absorption tower, and if the pH of the sampled absorbent liquid is lower than the reference value when the removal efficiency is lowered after re-reacting the absorbent liquid with the incoming exhaust gas It is an object of the present invention to provide an apparatus and method for continuously collecting exhaust gas carbon dioxide using calcium hydroxide through continuous operation for discharging to the outside.

Another object of the present invention is to provide an apparatus and method for continuously collecting exhaust gas carbon dioxide using calcium hydroxide through continuous operation, by measuring the water level of the absorbent liquid and automatically replenishing the new absorbent liquid so that the continuous operation is possible. .

Features of the present invention for achieving the above object,

An absorption tower storing an absorbent liquid mixed with Ca (OH) ₂ and an additive in the lower end, supplied with exhaust gas into the absorbent liquid, and discharging clean gas through the upper part; A circulation line for circulating the absorption liquid of the absorption tower above the absorption tower; It is installed at the upper end of the absorbent liquid level of the absorption tower to collect a portion of the absorbent liquid falling through the circulation line to measure the pH and discharge the absorbent liquid to the outside when the pH is less than the reference value as a result of the measurement, and the absorbent liquid if the pH is above the reference value It characterized in that it comprises a sampler discharged to the absorption tower.

Here, the continuous exhaust gas carbon dioxide capture device using the calcium hydroxide further includes a storage tank for storing the absorption liquid of the absorption tower discharged from the sampler.

Here, the continuous exhaust gas carbon dioxide capture device using the calcium hydroxide includes a supply tank for storing the new absorbent liquid to supply the new absorbent liquid to the absorption tower; The water level of the absorption liquid of the absorption tower by measuring the water level is less than a certain level further comprises a level gauge for supplying the new absorption liquid of the supply tank to the absorption tower.

Here, pH of the said novel absorption liquid is 11.0-13.0.

Herein, the sampler includes a main body having a through hole formed therein so that a majority of the absorbent liquid flows into the inside, and a discharge gas is raised, the upper end of which is wide and the lower end of which is a funnel; A collection tank having a diameter corresponding to a lower end diameter of the main body and having an upper end opening in a cylindrical shape so as to collect an absorbing liquid discharged through the main body, and a discharge pipe formed at a bottom thereof; A three-way solenoid valve installed in the discharge pipe of the collection tank to change the flow path under external control to discharge the absorbing liquid to the absorption tower or to discharge the storage tank; And installed inside the collection tank to measure the pH of the absorbent liquid, if the pH is greater than the reference value measurement liquid is discharged to the absorption tower, and if the pH is less than the reference value, the flow path of the three-way solenoid valve is changed to the absorbent liquid It consists of a pH meter that is discharged into a reservoir.

Here, the through-hole of the main body is formed so that the absorption liquid fall prevention plate is inclined downward on the upper end.

Here, the reference value of the said pH is 7.0-9.0.

According to another aspect of the present invention,

A method of capturing carbon dioxide using an exhaust gas carbon dioxide continuous capture device using calcium hydroxide, the method comprising: supplying exhaust gas into an absorption tower to react with a stored absorbent liquid to remove carbon dioxide; A re-reaction step of circulating the absorbent liquid of the absorption tower through the circulation line to the upper portion of the absorption tower and re-reacting with the rising gas; A measurement step of measuring the pH of the absorption liquid falling in the absorption tower in real time with a pH meter; A discharge step of discharging the absorbent liquid to the storage tank when the pH is less than the reference value as a result of the measurement; And an absorbent liquid supply process of measuring the absorbent liquid level of the absorber in real time using a level gauge to supply a new absorbent liquid stored in a supply tank to the absorber if the level is less than a predetermined level.

Here, the discharge process discharges the absorbent liquid to the absorption tower when the pH is greater than the reference value as a result of the measurement.

Here, the reference value of the pH is 7.0-9.0.

Here, pH of the said novel absorption liquid is 11.0-13.0.

According to the apparatus and method for continuously collecting the exhaust gas carbon dioxide using the calcium hydroxide of the present invention configured as described above, the exhaust gas is injected into the vortex in the absorbent liquid stored at the lower end of the absorption tower through the diffuser so that the exhaust gas and the absorbent liquid are mixed to discharge the exhaust gas. It is possible to increase the removal time of carbon dioxide by increasing the residence time and the contact time.

According to the present invention, the absorbent liquid falling from the upper part of the absorption tower is sampled and the pH of the sampled absorbent liquid is measured in real time, so that when the pH of the absorbent liquid is lower than the reference value and the removal efficiency is lowered, the absorbent liquid may be automatically discharged to the storage tank. .

In addition, according to the present invention, the exhaust gas and the absorbent liquid are respectively transported through the pump to be mixed sprayed through the injection pipe in the upper part of the absorption tower.

1 is a schematic diagram schematically showing the configuration of the exhaust gas carbon dioxide continuous collection device using calcium hydroxide according to the present invention.
Figure 2 is a perspective view showing the configuration of the diffuser installed in the absorption tower of the exhaust gas carbon dioxide continuous capture device and method using calcium hydroxide according to the present invention.
Figure 3 is a perspective view showing the configuration of the sampler body of the exhaust gas carbon dioxide continuous collection device using calcium hydroxide according to the present invention.
Figure 4 is a process chart for explaining the exhaust gas carbon dioxide continuous capture method using calcium hydroxide according to the present invention.

Hereinafter, with reference to the accompanying drawings, the configuration of the exhaust gas carbon dioxide continuous collection device using calcium hydroxide according to the present invention will be described in detail.

In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intentions or customs of the user, the operator, and the like. Therefore, the definition should be based on the contents throughout this specification.

1 is a schematic diagram schematically showing the configuration of the exhaust gas carbon dioxide continuous capture device using calcium hydroxide according to the present invention, Figure 2 is a configuration of the diffuser installed in the absorption tower of the exhaust gas carbon dioxide continuous capture device using calcium hydroxide according to the present invention 3 is a perspective view showing the configuration of the sampler body in the exhaust gas carbon dioxide continuous capture device using calcium hydroxide according to the present invention.

1 to 3, the exhaust gas carbon dioxide continuous collection device 1 using calcium hydroxide according to the present invention includes an absorption tower 10, a circulation line 20, a sampler 30, and a storage tank 40. ), The supply tank 50, and the water level gauge 60.

First, the absorption tower 10 has a conventional structure in which the absorbent liquid in which Ca (OH) ₂ and the additives are mixed is stored in the lower end, the exhaust gas is supplied by the blower 11 into the absorbent liquid, and clean gas is provided through the upper part. To discharge. At this time, the absorbent liquid absorbs carbon dioxide (CO ₂ ) contained in the exhaust gas and discharges clean gas that does not react with the absorbent liquid.

Here, the absorption tower 10 is provided inside the stirrer 13 to agitate the absorption liquid mixed with Ca (OH) ₂ and additives, and a demister installed at the inner top to remove moisture contained in the clean gas ( 15) and a diffuser 17 to supply exhaust gas into the absorbent liquid in a vortex form.

Meanwhile, as shown in FIG. 2, the diffuser 17 is radially formed around the main pipe 17-1 and the main pipe 17-1 whose one end is bent vertically downward, and each end thereof is On the inclined surface 17-3a of the branch pipe 17-3 and the branch pipe 17-3 which are bent in one direction, and the inclined surface 17-3a which becomes narrow toward the lower end from the upper end to the end is formed, It is composed of a mesh network (17-5) coupled to finely disperse bubbles.

In addition, the circulation line 20 pumps the absorption liquid of the absorption tower 10 through the circulation pump 21 to continuously circulate the upper portion of the absorption tower 10.

The sampler 30 includes a main body 31, a collection tank 33, a three-way solenoid valve 35, and a pH meter 37.

As shown in FIG. 3, the main body 31 has a plurality of through holes 31-1 formed therein so that most of the absorbent liquid flows into the inside and falls, and the discharge gas is raised, and the upper end is wide and the lower end is narrow. It is formed in the form of a funnel. Here, the absorbent liquid drop prevention plate 31-3 is formed to be inclined downward at the upper end of the through hole 31-1 of the main body 31.

The collection tank 33 has a diameter corresponding to the lower diameter of the lower body of the main body 31 to collect the absorbing liquid discharged through the main body 31 and is formed in a cylindrical shape with an open upper end, and the discharge pipe 33-1 is formed on the bottom surface. do.

Three-way solenoid valve 35 is installed in the discharge pipe (33-1) of the collection tank 33, the flow path is changed in accordance with the external control to discharge the absorbent liquid to the absorption tower 10 or storage tank 40 to be described later To be discharged. At this time, the opening and closing degree of the three-way solenoid valve 35 is such that the absorbent liquid is always maintained at a constant level in the collection tank (33).

The pH meter 37 is installed inside the collection tank 33 to measure the pH of the absorbent liquid. If the pH is greater than or equal to the reference value, the pH meter 37 discharges the absorbent liquid to the absorption tower 10. The flow path of the solenoid valve 35 is changed and the absorbing liquid is discharged to the storage tank 40. At this time, the reference value of the pH is preferably 8.0, because the pH of the sampled absorbent liquid is about 0.5 lower than the pH of the absorbent liquid stored in the absorption tower 10, and if the pH of the absorbent liquid is less than 8.5, the carbon dioxide removal efficiency rapidly decreases. .

In addition, the storage tank 40 pumps and stores the absorption liquid discharged through the discharge pipe 33-1 of the collection tank 33 by the discharge pump 41. At this time, the reservoir 40 may be located at the lower end of the absorption tower 10 to be naturally discharged by the pressure difference.

On the other hand, the supply tank 50 stores the new absorbent liquid, and the new absorbent liquid is stored to supply the new absorbent liquid to the absorption tower 10 through the pumping of the supply pump 51. At this time, the pH of the new absorbent liquid is preferably 12.5 or more, because the carbon dioxide removal efficiency is high when the pH of the absorbent liquid is 12.5 or more.

In addition, the level gauge 60 measures the level of the absorbent liquid of the absorption tower 10 and supplies the new absorbent liquid of the supply tank 50 to the absorption tower 10 when the level is less than a predetermined level. At this time, the water level measuring device 60 supplies a new absorption liquid by operating the supply pump 51 installed between the supply tank 50 and the absorption tower 10.

Hereinafter, with reference to the accompanying drawings, the exhaust gas carbon dioxide continuous capture method using calcium hydroxide according to the present invention will be described in detail as follows.

Figure 4 is a process chart for explaining the exhaust gas carbon dioxide continuous capture method using calcium hydroxide according to the present invention.

First, when the exhaust gas is supplied into the absorbent liquid through the blower 11 and the diffuser 17 in the state in which the absorbent liquid is stored in the absorption tower 10, vortices are generated in the absorbent liquid by the exhaust pressure to be included in the exhaust gas. The carbon dioxide is reacted with the absorbent liquid so that the exhaust gas from which the carbon dioxide is removed, that is, the clean gas, is raised (S100). At this time, the stirrer 13 stirs the absorbent liquid to prevent the sludge from being absorbed by the absorption tower 10 and being precipitated. Then, as the exhaust gas is mixed with the absorbent liquid, the residence time of the exhaust gas and the contact time with the absorbent liquid are increased to increase the absorption efficiency of carbon dioxide in the absorbent liquid.

In addition, since the gas is raised to the upper portion of the absorption tower 10 and the absorbent liquid is injected into the upper portion of the absorption tower 10 through the circulation pump 21 of the circulation line 20 and is re-reacted while being in contact with the rising gas. The reaction time and the contact area may be increased to increase the removal efficiency of carbon dioxide (S110).

When the absorbing liquid falling is collected in the main body 31 of the sampler 30 and dropped and stored in the collecting tank 33, the pH measuring unit 37 measures the pH of the absorbing liquid stored in the collecting tank 33. (S120).

If the pH is less than the reference value as a result of the measurement, the pH meter 37 changes the flow path of the three-way solenoid valve 35 (S131), and operates the discharge pump 41 to discharge the absorbent liquid to the storage tank 40 (S132). On the contrary, if the measured pH is greater than or equal to the reference value, the pH meter 37 maintains the flow path of the three-way solenoid valve 35 as shown in FIG. 5, and the absorbent liquid passes through the discharge pipe 33-1 to the absorption tower 10. To be discharged.

On the other hand, the water level measuring instrument 60 measures the water level of the absorbent liquid in the absorption tower 10 in real time, when the absorbent liquid is discharged to the reservoir 40, the water level drops below the reference level, the water level measuring instrument 60 is the supply tank 50 Supplying the new absorbent liquid stored in the absorption tower to maintain a constant absorbent level (S140).

Therefore, the absorbent liquid having a low pH is automatically discharged, and when the level of the absorbent liquid is lowered, the new absorbent liquid is automatically supplied to enable continuous operation.

As those skilled in the art would realize, the described embodiments may be modified in various ways, all without departing from the spirit or scope of the present invention. It is to be understood, however, that the present invention is not limited to the specific forms referred to in the description, but rather includes all modifications, equivalents, and substitutions within the spirit and scope of the invention as defined by the appended claims. Should be.

10: absorption tower 20: circulation line
30: sampler 40: reservoir
50: supply tank 60: level gauge

Claims (11)

An absorption tower storing an absorbent liquid mixed with Ca (OH) ₂ and an additive in the lower end, supplied with exhaust gas into the absorbent liquid, and discharging clean gas through the upper part;
A circulation line for circulating the absorption liquid of the absorption tower above the absorption tower;
It is installed at the upper end of the absorbent liquid level of the absorption tower to collect a portion of the absorbent liquid falling through the circulation line to measure the pH and discharge the absorbent liquid to the outside when the pH is less than the reference value as a result of the measurement, and the absorbent liquid if the pH is above the reference value Emission gas carbon dioxide continuous capture device using calcium hydroxide, characterized in that it comprises a sampler discharged to the absorption tower. The method of claim 1,
The exhaust gas carbon dioxide continuous collection device using the calcium hydroxide,
And a storage tank for storing the absorbent liquid of the absorption tower discharged from the sampler. The method of claim 2,
The exhaust gas carbon dioxide continuous collection device using the calcium hydroxide,
A supply tank in which the new absorbent liquid is stored to supply the new absorbent liquid to the absorption tower;
And a level gauge for measuring the water level of the absorption liquid of the absorption tower to supply the new absorption liquid of the supply tank to the absorption tower when the level is less than a predetermined level. The method of claim 2,
PH of the new absorbent liquid,
Emission gas carbon dioxide continuous capture device using calcium hydroxide, characterized in that 11.0 ~ 13.0. The method of claim 2,
The sampler is,
A main body having a through hole formed therein so that a majority of the absorbent liquid flows into the inside, and the exhaust gas is raised, and has a wide top and a narrow funnel;
A collection tank having a diameter corresponding to a lower end diameter of the main body and having an upper end opening in a cylindrical shape so as to collect an absorbing liquid discharged through the main body, and a discharge pipe formed at a bottom thereof;
A three-way solenoid valve installed in the discharge pipe of the collection tank to change the flow path under external control to discharge the absorbing liquid to the absorption tower or to discharge the storage tank; And
It is installed inside the collection tank to measure the pH of the absorbent liquid, and if the pH is greater than or equal to the reference value, the absorbent liquid is discharged to the absorption tower. Emission gas carbon dioxide continuous capture device using calcium hydroxide, characterized in that consisting of a pH meter to discharge. The method of claim 5, wherein
The through hole of the main body,
Absorption liquid carbon dioxide continuous capture device using calcium hydroxide, characterized in that the absorption liquid fall prevention plate is formed to be inclined downward. The method according to claim 6,
The reference value of the pH is,
Emission gas carbon dioxide continuous capture device using calcium hydroxide, characterized in that 7.0 ~ 9.0. In the carbon dioxide capture method using the exhaust gas carbon dioxide continuous capture device using the calcium hydroxide of claim 1,
A reaction process of supplying exhaust gas into the absorption tower to react with the stored absorption liquid to remove carbon dioxide;
A re-reaction step of circulating the absorbent liquid of the absorption tower through the circulation line to the upper portion of the absorption tower and re-reacting with the rising gas;
A measurement step of measuring the pH of the absorption liquid falling in the absorption tower in real time with a pH meter;
A discharge step of discharging the absorbent liquid to the storage tank when the pH is less than the reference value as a result of the measurement; And
Calcium hydroxide characterized in that the absorbent liquid level of the absorption tower is measured in real time with a water level measuring device is a liquid absorbing step of supplying a new absorbent liquid stored in the supply tank to the absorption tower to maintain a constant level of the absorbent liquid when the level is less than a certain level. Continuous collection method of exhaust gas carbon dioxide. The method of claim 8,
The discharge process,
A method for continuously collecting exhaust gas carbon dioxide using calcium hydroxide, characterized in that the absorbing liquid is discharged to the absorption tower when the pH is greater than or equal to the measurement result. The method of claim 8,
The reference value of the pH is,
Continuous collection method of exhaust gas carbon dioxide using calcium hydroxide, characterized in that 7.0 ~ 9.0. The method of claim 8,
PH of the new absorbent liquid,
Continuous collection method of exhaust gas carbon dioxide using calcium hydroxide, characterized in that 11.0 ~ 13.0.

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