KR20130139109A - Co2 absorption device using heat of reboiler steam condensate - Google Patents

Abstract

The present invention relates to a carbon dioxide capture device using heat of reboiler steam condensate. The carbon dioxide capture device according to the present invention comprises an absorption column for generating a saturable absorber for carbon dioxide by making a mixed gas including carbon dioxide react with an absorber; a stripper for receiving the saturable absorber for carbon dioxide, separating carbon dioxide and regenerating the absorber; a transfer flow path for connecting the absorption column with the stripper and flowing the saturable absorber for carbon dioxide from the absorption column to the stripper; a reboiler for heating the saturable absorber for carbon dioxide introduced from the stripper; a steam generator for supplying steam to the regenerator; and a first heat exchanger arranged on the transfer flow path and transferring the heat of steam condensate condensed by the reboiler to the saturable absorber for carbon dioxide.

Description

CO2 Absorption Device using heat of reboiler steam condensate}

The present invention relates to a carbon dioxide capture device using the heat of the regasifier steam condensate, in particular by heat-exchanging the heat of the steam condensate used in the regasifier for heating the carbon dioxide saturable absorber in the stripping column with the carbon dioxide saturable absorbent flowing into the stripping column The present invention relates to a carbon dioxide capture device using heat of a regasifier steam condensate with an improved structure to reduce operating costs.

The present invention is derived from the research conducted as part of the Energy Resources Convergence Source Technology Development Greenhouse Gas Treatment Technology Development Project of the Ministry of Knowledge Economy. [Task No.:2010201020006D, Research Title: CO ₂ Collection Process Improvement and Power Plant Integration Technology Development] ]

The present invention relates to an apparatus for collecting acidic gas containing carbon dioxide using a wet absorbent or the like. Wet absorption technology is a technology that selectively separates or removes a specific desired component by using gas solubility in the liquid phase or chemically reacting properties by contacting the liquid absorbent.

Absorption can be classified into a physical absorption method of physically dissolving the target gas in the absorbent and a chemical absorption method absorbed by chemical reaction between the solute component and the gas component in the absorbent. Basically, there are no process differences in physical or chemical absorption methods, but the form of the process is slightly different due to the amount of heat required for desorption of the absorbed carbon dioxide.

This is because carbon dioxide desorption energy absorbed by the physical bonding force is about 4 times lower than that of chemical absorption. In general, the physical absorption method is used when the partial pressure of the gas component is high, and the chemical absorption method is effective when the partial pressure of carbon dioxide is low, such as combustion exhaust gas.

Combustion carbon capture process using a liquid absorbent of the exhaust gas is the ability to absorb the absorption for superior amine-based absorbent with significant absorption of carbon dioxide, the exhaust gas containing the CO ₂ is brought into contact at a suitable temperature pressure to the technique for selectively collecting the CO ₂ It consists of a tower, a stripping tower for regeneration of the absorbent, a condenser and regasifier of the stripping tower, a heat exchanger, a pump and a pressure regulator including a blower, a compressor, and the like.

An example of a conventional separation and recovery of carbon dioxide has been disclosed in Korea Patent Publication No. 10-2011-0073163 (publication number). Figure 1 schematically shows the conventional separation and recovery of carbon dioxide.

The carbon dioxide separation and recovery apparatus according to FIG. 1 includes an absorption tower 1 and a stripping column 2. The absorption tower 1 is a configuration for generating a carbon dioxide saturated absorbent by reacting exhaust gas containing carbon dioxide and an absorbent with each other, and the stripping column 2 receives the carbon dioxide saturated absorbent to separate the carbon dioxide and the absorbent. It is equipped to play again. Since this configuration is a general configuration, detailed description thereof will be omitted.

As shown in FIG. 1, the stripping column 2 is supplied with a carbon dioxide saturable absorber, and the carbon dioxide saturable absorber is heated by the regasifier 5 to separate carbon dioxide from the carbon dioxide saturable absorber again. The steam generated by the steam supply device 6 is supplied to the regasifier 5, and the steam passed through the regasifier 5 is condensed and discharged.

Therefore, the high temperature condensed steam (steam condensed water) is discharged as it is, there is a problem that the operating cost of the facility increases.

On the other hand, referring to Figure 1, when the exhaust gas is injected into the absorption tower 1, a pressure regulator 3, such as a fan, a compressor, a blower, is coupled to the front end of the absorption tower 1. After increasing the pressure of the exhaust gas at the front end of the absorption tower 1, the exhaust gas is injected into the absorption tower 1 using the pressure.

However, this conventional technique acts as a factor of raising the temperature and enthalpy of the exhaust gas by adding the pressure regulator 3 to the front end of the absorption stage 1, the absorption efficiency of carbon dioxide in the absorption tower 1 is lowered This causes a problem of increasing the overall operating energy.

In addition, FIG. 2 schematically illustrates the prior art for solving the above-described problem of FIG. Referring to Figure 2, in order to solve the problem that the temperature and enthalpy of the exhaust gas is increased by the pressure regulator 3 installed in front of the absorption tower 1, the heat exchanger 4 at the rear end of the pressure regulator 3 ) Shows a method of lowering the temperature and enthalpy by installing a cooling pump.

However, in the carbon dioxide separation and recovery apparatus according to FIG. 2, since the pressure regulator 3, the heat exchanger 4, or the cooling pump must be additionally installed, the initial installation cost increases and the use of the cooling water increases, thereby increasing the overall process. There is a problem that reduces the economics of.

The present invention has been made to solve the above problems, by reducing the operating cost by heat exchange of the heat of the steam condensate used in the regasifier for heating the carbon dioxide saturated absorbent in the stripping column with the carbon dioxide saturated absorbent flowing into the stripping tower. By using the heat of the re-vaporizer steam condensate to reduce the cost by reducing the overall operating energy during operation of the carbon dioxide capture device, so that the mixed gas containing carbon dioxide can be easily introduced into the absorption tower. It is an object to provide a carbon dioxide collection device.

The carbon dioxide capture device using the heat of the regasifier steam condensed water according to the present invention for solving the above problems, the absorption tower to produce a carbon dioxide saturated absorbent by reacting the mixed gas containing carbon dioxide and the absorbent; A stripping column receiving the carbon dioxide saturated absorbent to separate carbon dioxide and regenerating the absorbent; A transfer passage connecting the absorption tower and the stripping column, wherein the carbon dioxide saturated absorbent flows from the absorption tower to the stripping column; A regasifier for heating the carbon dioxide saturable absorber introduced into the stripping column; A steam generator for supplying steam to the regasifier; And a first heat exchanger provided on the transfer passage and heat-exchanging the heat of the steam condensed water condensed in the regasifier with the carbon dioxide saturating absorber.

In addition, it is preferable to include a second heat exchanger provided on the transfer passage and exchanging heat of the absorbent regenerated in the stripping column and the saturated carbon dioxide absorbent.

In addition, the carbon dioxide saturated absorbent is preferably passed through the first heat exchanger after passing through the second heat exchanger.

In addition, the regeneration absorber regenerated in the stripping column is provided with a return flow path to the absorption tower, the regeneration absorbent is preferably supplied to the absorption tower via the regasifier and the second heat exchanger.

In addition, the steam generator, the regasifier, and the first heat exchanger are connected by a circulation passage, and the steam supplied from the steam generator and the steam condensed water condensed in the regasifier are circulated along the circulation passage.

In addition, the discharge pipe for discharging the mixed gas from which the carbon dioxide has been removed is coupled to the absorption tower, the discharge pipe is preferably provided with a blower for sucking the mixed gas from which the carbon dioxide is removed from the inside of the absorption tower. .

In addition, the mixed gas is preferably supplied into the absorption tower in accordance with the pressure decrease in the absorption tower while the mixed gas from which the carbon dioxide is removed to the discharge pipe when the blower is driven.

In addition, the regeneration absorbent is supplied to the upper side of the absorption tower via the return flow path and falls, the regenerating absorbent falling is preferably dispersed by a porous reaction promoting block provided on the upper side of the absorption tower.

The carbon dioxide capture device using the heat of the regasifier steam condensate according to the present invention, the operating cost by heat exchange of the heat of the steam condensate used in the regasifier for heating the carbon dioxide saturable absorber in the stripping column with the carbon dioxide saturated absorbent flowing into the stripping tower Provides the effect of saving.

In addition, the mixed gas containing carbon dioxide can be easily introduced into the absorption tower, and the mixed gas from which the carbon dioxide has been removed from the absorption tower is easily discharged through the discharge pipe, so that the overall operating energy during operation of the carbon dioxide collecting device is reduced. It saves money by saving money.

1 is a view showing an example of a conventional carbon dioxide separation recovery apparatus,
2 is a view showing another example of a conventional carbon dioxide separation recovery apparatus,
3 is a schematic diagram of a carbon dioxide collecting device according to an embodiment of the present invention;
4 is a cross-sectional view of FIG.
5 and 6 are graphs showing the effect of the present invention.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 3 is a schematic diagram of a carbon dioxide capture device according to an embodiment of the present invention, Figure 4 is a cross-sectional view of FIG.

First, referring to Figure 3, the carbon dioxide capture device using the heat of the regasifier steam condensed water according to an embodiment of the present invention, the absorption tower 10, stripping column 20, transfer passage 30, regasifier 40 , Steam generator 50, and first heat exchanger 60.

The absorption tower 10 is provided to react a mixed gas containing carbon dioxide and an absorbent, and the carbon dioxide contained in the absorbent and the mixed gas reacts to generate a carbon dioxide saturated absorbent. The mixed gas is supplied to the lower end of the absorption tower 10 through the supply pipe 150.

According to this embodiment, as the absorbent, an amine-based, amino acid salt, inorganic salt-based solution, ammonia water or a mixture thereof is used. According to the present embodiment, the regenerated absorbent regenerated in the stripping column 20 to be described later is led from the stripping tower 20 to the upper part of the absorption tower 10 again through the regasifier 40 and the inside of the absorption tower 10. Is supplied.

The discharge pipe 150 is coupled to the absorption tower 10. The discharge pipe 150 is provided to discharge the mixed gas from which carbon dioxide is removed after the mixed gas containing carbon dioxide reacts with the absorbent. In this embodiment, the discharge pipe 150 is coupled to the upper end of the absorption tower (10).

The stripping column 20 is provided to receive carbon dioxide saturated absorbent generated in the absorption tower 10 to separate carbon dioxide from the carbon dioxide saturated absorbent and regenerate the absorbent.

The stripping tower 20 is connected to a condenser 160, a reflux drum (not shown), etc. to subsequently process the separated carbon dioxide. Since the process after the stripping tower 20 is generally known, a detailed description thereof will be omitted.

The transfer passage 30 connects the absorption tower 10 and the stripping column 20. Specifically, one end of the transfer passage 30 is coupled to the lower end of the absorption tower 10, the other end is connected to the upper end of the stripping column (20). The saturated carbon dioxide absorbent generated in the absorption tower 10 is introduced into the stripping column 20 via the transfer channel 30.

The regasifier 40 is provided to heat the carbon dioxide saturated absorbent introduced into the stripping column 20.

The steam generator 50 supplies steam to the regasifier 40. The steam generated from the steam generator 50 is condensed as it passes through the regasifier 40 to become steam condensed water, and the heat of the steam is provided to the stripping tower 20 to heat the carbon dioxide saturable absorber.

The first heat exchanger (60) is a component that forms a key feature of the present invention, and is provided on the transfer passage (30). The first heat exchanger 60 is provided to exchange heat of the steam condensed water condensed through the regasifier 40 with the carbon dioxide saturated absorbent.

In the present embodiment, the steam generator 50, regasifier 40, and the first heat exchanger 60 is connected by a circulation passage (90). Steam generated from the steam generator 50 is supplied to the regasifier 40, the steam is condensed through the regasifier 40, the phase changes to steam condensate water through the first heat exchanger (60) After returning to the steam generator 50 again.

In the circulation process of the steam and steam condensed water, the first heat exchanger 60 supplies heat to the carbon dioxide saturated absorbent flowing from the absorption tower 10 to the stripping tower 20, and flows into the stripping tower 20. The temperature of the saturated carbon dioxide absorbent is increased. Thus, the amount of heat to be supplied to heat the carbon dioxide saturable absorber by the regasifier 40 is reduced.

In addition, the carbon dioxide capture device using the heat of the regasifier steam condensed water according to the present embodiment, the return flow path 70, the second heat exchanger 80, the blower 100, and the reaction promoting block 110. .

The return flow path 70 is a flow path for the regeneration absorbent regenerated by the stripping column 20 to return to the absorption tower 10. Referring to FIG. 3, the carbon dioxide saturable absorbent introduced into the stripping tower 20 is separated from carbon dioxide while circulating through the stripping tower 20 and the regasifier 40. The regenerated absorbent regenerated by removing the carbon dioxide is supplied to the absorption tower 10 via the return flow path 70. One end of the return flow path 70 is connected to the regasifier 40, the other end is connected to the upper side of the absorption tower (10).

The second heat exchanger 80 is provided on the transfer passage 30. The second heat exchanger 80 is provided to exchange heat of the regeneration absorbent regenerated in the stripping column 20 and the carbon dioxide saturated absorbent.

That is, the regeneration absorbent is supplied to the absorption tower 10 via the regasifier 40 and the second heat exchanger 80, while the carbon dioxide saturable absorbent is transferred to the transfer channel 30 and the second heat exchanger. It moves to the stripping tower 20 via 80.

The regenerated absorbent regenerated in the stripping column 20 is hotter than the carbon dioxide saturated absorbent transferred from the absorbent 10, so that the heat of the regenerated absorbent is transferred to the carbon dioxide saturated absorbent.

According to the present embodiment, the carbon dioxide saturable absorber is configured to pass through the first heat exchanger 60 after first passing the second heat exchanger 80.

The heat of the regeneration absorbent is lower in temperature than the heat of steam condensate. Therefore, the carbon dioxide saturated absorbent is primarily heat exchanged by the regenerated absorbent and warmed, followed by the second heat exchanger is heated by steam condensed water that is hotter than the regenerated absorbent.

When the carbon dioxide saturated absorbent is first heat-exchanged by hot steam condensate, a higher flow rate must be supplied because the temperature difference between the carbon dioxide saturated absorbent and the steam condensate is larger than the temperature difference between the carbon dioxide saturated absorbent and the regenerated absorbent. That is, when the carbon dioxide saturated absorbent is heated twice by using the heat of the regenerative absorbent and the heat of the steam condensate, it is more preferable to preferentially perform heat exchange through the regenerative absorbent.

The blower 100 is provided in the discharge pipe 150. The blower 100 is provided to suck and discharge the mixed gas from which the carbon dioxide is removed from the inside of the absorption tower 10. In the present embodiment, a blower or a fan is used as the blower 100.

According to this embodiment, the mixed gas from which carbon dioxide is removed when the blower 100 is driven is discharged through the discharge pipe 150, and as the pressure inside the absorption tower 10 decreases, the absorption tower is performed. (10) The mixed gas containing carbon dioxide is supplied to the inside.

Therefore, the blower 100 easily discharges the mixed gas from which the carbon dioxide has been removed from the absorption tower 10 to the outside, and serves to easily supply the mixed gas into the absorption tower 10.

When the mixed gas introduced into the absorption tower 10 reacts with the absorbent to generate a carbon dioxide saturated absorbent, the carbon dioxide saturated absorbent is passed through the transfer flow path 30 by the first transfer pump 120. 20).

Meanwhile, in the stripping column 20, the absorbent that is separated and regenerated from the carbon dioxide saturating absorber is moved to the lower end of the stripping column 20 and returned to the second transfer pump 130 through the regasifier 40. It is supplied to the upper side of the absorption tower 10 via the flow path (70).

4, the reaction promoting block 110 is provided to promote the reaction of the carbon dioxide and the absorbent contained in the mixed gas. The reaction promoting block 110 is disposed inside the absorption tower 10 and is made of a porous metallic material. The reaction promoting block 110 is provided below the discharge pipe 150 and the return flow path (70).

The regeneration absorbent supplied to the upper side of the absorption tower 10 via the return flow path 70 drops inside the absorption tower 10. When the mixed gas introduced into the lower portion of the absorption tower 10 rises, the mixed gas reacts with the regenerative absorbent dispersed by hitting the reaction promoting block 110 to promote reaction with the mixed gas.

Hereinafter, the operation of the carbon dioxide capture device using the regasifier steam condensed water heat according to the above configuration will be described in detail.

First, the mixed gas is introduced into the absorption tower 10 through the supply pipe 140. Specifically, the process of introducing the mixed gas is as follows. The blower 100 is driven to reduce the internal pressure of the absorption tower 10, and the mixed gas is introduced into the absorption tower 10 as the internal pressure of the absorption tower 10 decreases.

The introduced mixed gas rises and reacts with the regeneration absorbent. At this time, the regeneration absorbent is dispersed by the reaction promoting block 110 while falling from the upper side of the absorption tower 10 to improve the reaction efficiency with the mixed gas.

When carbon dioxide is removed by reacting the mixed gas and the absorbent, the mixed gas from which carbon dioxide is removed is discharged through the discharge pipe 150, and the saturated carbon dioxide absorbent absorbing carbon dioxide is transferred to the stripping column 20 through the transfer channel 30. Move.

At this time, the carbon dioxide saturated absorbent is primarily heat exchanged with the regeneration absorbent revolving from the stripping tower 20, and then heat exchanged with the steam condensed water condensed in the regasifier 40 to the stripping tower 20 in a warmed state. It will flow in.

As such, the carbon dioxide capture device using the heat of the regasifier steam condensate in accordance with an embodiment of the present invention, the carbon dioxide saturable absorber before recovering the heat of the high-temperature steam used to separate the carbon dioxide from the carbon dioxide saturable absorber before entering the stripping tower Heat exchange with and reduces the heat to be finally provided to the stripping column, thus providing the effect of reducing the overall operating energy.

5 and 6 show the difference in effects between the two processes of recovering the waste heat according to the present invention when the heat of the steam condensed water of the conventional regasifier as it is.

Referring to FIG. 5, the final temperature of the carbon dioxide saturated absorbent introduced into the stripping column 10 is increased by about 2 degrees Celsius than when the heat of the steam condensate is heat-exchanged with the carbon dioxide saturated absorbent. It can be seen that the amount of steam supplied decreases to 97 when the existing process is set at 100.

On the other hand, the carbon dioxide capture device using the heat of the regasifier steam condensed water according to the present invention, the blower 100 easily enters the mixed gas into the absorption tower 10, and when the mixed gas inflow Suppresses the increase in temperature and enthalpy.

That is, by connecting the blower 100 to the discharge pipe 150 to introduce the mixed gas into the absorption tower 10 during the operation of the blower 100, the mixed gas easily into the absorption tower 10 In order to improve the reaction efficiency of the absorbent and the mixed gas by increasing the temperature and enthalpy of the mixed gas is suppressed.

Conventionally, in the case of supplying the mixed gas to the absorption tower (1) by installing the pressure adjusting means (3) in front of the absorption tower (1), to increase the temperature and enthalpy of the mixed gas, a separate In the case of installing the heat exchanger 4 or the cooling pump, there is a problem of additional equipment cost and increase of the overall operating energy, but the carbon dioxide collecting device and the carbon dioxide collecting method including the blower according to the present invention have such problems. Provide the effect to solve.

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, and many modifications may be made without departing from the scope of the present invention.

10 ... absorption tower 20 ... stripping tower
30 ... transfer path 40 ... regasifier
50 ... Steam generator 60 ... First heat exchanger
70 ... second heat exchanger 80 ... return flow
90 ... Circulating flow path 100 ... Blower
110 ... Reaction promotion block 120 ... First transfer pump
130 ... 2nd transfer pump 140 ... Supply piping
150 ... Exhaust piping 160 ... Condenser

Claims (8)

An absorption tower for producing a carbon dioxide saturated absorbent by reacting a mixed gas containing carbon dioxide and an absorbent;
A stripping column receiving the carbon dioxide saturated absorbent to separate carbon dioxide and regenerating the absorbent;
A transfer passage connecting the absorption tower and the stripping column, wherein the carbon dioxide saturated absorbent flows from the absorption tower to the stripping column;
A regasifier for heating the carbon dioxide saturable absorber introduced into the stripping column;
A steam generator for supplying steam to the regasifier;
And a first heat exchanger provided on the conveying flow path and heat-exchanging the heat of the steam condensed water condensed in the regasifier with the carbon dioxide saturating absorber. The method of claim 1,
And a second heat exchanger provided on the transfer flow path, the second heat exchanger exchanging heat of the absorbent regenerated in the stripping tower and the carbon dioxide saturated absorbent. 3. The method of claim 2,
And the carbon dioxide saturable absorber passes through the first heat exchanger after passing through the second heat exchanger. 3. The method of claim 2,
A recirculating flow path for regenerating the absorbent regenerated from the stripping tower to the absorption tower is provided, and the regenerated absorbent is supplied to the absorption tower via the regasifier and the second heat exchanger. Carbon dioxide capture device using heat. The method of claim 1,
The steam generator, the regasifier, and the first heat exchanger are connected by a circulation passage, and steam supplied from the steam generator and steam condensed water condensed in the regasifier circulate along the circulation passage. Carbon dioxide capture device using heat of steam condensed water. The method of claim 1,
A discharge pipe for discharging the mixed gas from which the carbon dioxide has been removed is coupled to the absorption tower, and the discharge pipe includes a blower for sucking the mixed gas from which the carbon dioxide has been removed from the inside of the absorption tower. Carbon dioxide capture device using the heat of fire steam condensed water. The method of claim 5,
The mixed gas is supplied to the inside of the absorption tower according to the pressure decrease inside the absorption tower while the mixed gas from which the carbon dioxide is removed is discharged to the discharge pipe when the blower is driven. Carbon dioxide capture device using heat. 5. The method of claim 4,
The regeneration absorbent is supplied to the upper side of the absorption tower via the return flow path and falls, and the regenerated absorbent falling therein is dispersed by a porous reaction promoting block provided at the upper side of the absorption tower. Carbon dioxide capture device using heat of condensate.

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