KR20110001745A - Apparatus for collecting carbon dioxide - Google Patents

Abstract

PURPOSE: A carbon dioxide collecting apparatus is provided to improve the dispersibility of mixed gas inside an absorption housing without increasing the volume of the absorption housing. CONSTITUTION: A carbon dioxide collecting apparatus(100) comprises an absorption housing(110) and a desorption housing(130). The absorption housing includes an absorbent, and generates a carbon dioxide saturated absorbent by reacting carbon dioxide inside mixed gas supplied through a supplying line with the absorbent, before discharging the mixed gas without the carbon dioxide. The desorption housing receives the carbon dioxide saturated absorbent to separate into the carbon dioxide and the absorbent, for discharging the carbon dioxide and returning the absorbent to the absorption housing.

Description

CO2 Recovery Equipment {APPARATUS FOR COLLECTING CARBON DIOXIDE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a carbon dioxide recovery apparatus, and more particularly, to a carbon dioxide recovery apparatus for recovering carbon dioxide in a mixed gas discharged from a power plant by wet.

Due to the development of the industry, the increase in the concentration of carbon dioxide (CO ₂ ) in the atmosphere is accelerating the global warming problem, and there is an urgent need for a solution to solve it.

The biggest cause of the increase in carbon dioxide concentration in the atmosphere is the use of fossil fuels in coal, petroleum, and LNG.

Accordingly, research is being actively conducted to develop a technology for reducing carbon dioxide concentration in the atmosphere by separating and recovering carbon dioxide generated by the use of fossil fuels.

In general, the carbon dioxide separation technology is classified into absorption method, adsorption method, membrane separation method and deep cooling method.

Among them, absorption is the most widely used technology to separate carbon dioxide from large-capacity carbon dioxide sources.

An apparatus for separating carbon dioxide using the absorption method includes an absorption housing and a stripping housing.

The absorption housing receives a mixed gas discharged from a power plant or the like and reacts with the absorbent to cause carbon dioxide to chemically react with the absorbent, and the remaining mixed gas is discharged from the absorption housing.

In the stripping housing, the absorber having a chemical reaction with the carbon dioxide is supplied, the carbon dioxide and the absorbent are separated before the reaction by thermal energy, and the carbon dioxide is discharged to the stripping housing, and the absorbent is transferred to the absorbing housing again.

In the case of the above device, when the mixed gas is supplied into the absorbent housing, it is supplied through one inlet formed in the lower part of the absorbent housing, and is gradually dispersed into the absorbent housing while moving upwardly.

Therefore, since a predetermined distance is required from the point of mixing the mixed gas to the complete dispersion into the absorption housing, the volume of the absorption housing is increased.

In order to solve this problem, a technique of installing a cone-shaped dispersion plate inside the absorbent housing has been proposed, but in this case, the differential pressure inside the absorbent housing may increase, and thus there is a problem that a considerable power is required when the mixed gas is injected.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is to provide an improved carbon dioxide recovery apparatus capable of preventing an increase in volume of an absorption housing and an increase in internal differential pressure.

An apparatus for recovering carbon dioxide according to the present invention includes an absorbent housing accommodating an absorbent, reacting carbon dioxide in the mixed gas introduced through a supply line with the absorbent to produce a saturated carbon dioxide absorbent, and discharging the mixed gas from which the carbon dioxide has been removed; And a stripping housing receiving the carbon dioxide saturated absorbent, separating the carbon dioxide and the absorbent, and discharging the carbon dioxide and transferring the absorbent to the absorbent housing, wherein the absorbent housing is in communication with the supply line. A housing and an inner tube housing accommodated in the outer housing, wherein the inner tube housing is provided with a plurality of slots are spaced apart to provide an inflow path so that the mixed gas flowing through the supply line flows into the inner tube housing.

The inner tube housing may have a cylindrical shape, and the plurality of slots may be disposed at intervals within 15 to 20 degrees with respect to a central axis of the inner tube housing.

The plurality of slots may be formed within a range of 30 ~ 330 degrees with respect to the central axis of the supply line.

The plurality of slots may be within 15-20.

The widths of the slots (hereinafter, referred to as a first group) disposed within 60 to 120 degrees and 240 to 300 degrees with respect to the central axis of the inner tube housing among the plurality of slots are slots disposed at other angles (hereinafter, referred to as a first group). , Second group).

The width of the first group may be within 14 to 20 degrees with respect to the central axis of the inner tube housing.

The width of the second group may be within 8 to 12 degrees with respect to the central axis of the inner tube housing.

The plurality of slots may be formed at the same height as the supply line.

According to the carbon dioxide recovery apparatus according to the present invention, while forming a plurality of slots which are a moving path of the mixed gas 15 to 20 at intervals of 15 to 20 degrees within the range of 30 to 330 degrees with respect to the central axis of the absorption housing, 60 ~ By forming the width of the slots disposed within 120 degrees, 240-300 degrees larger than the widths of the slots disposed at other angles, the mixing of the mixed gas in the absorption housing without increasing the differential pressure in the absorption housing and without increasing the volume of the absorption housing. It can improve acidity.

Hereinafter, a carbon dioxide recovery apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic view schematically showing a carbon dioxide recovery apparatus according to an embodiment of the present invention, FIG. 2 is a front view schematically showing an absorption housing of the carbon dioxide recovery apparatus of FIG. 1, and FIG. 3 is a II ′ of FIG. 2. A plan cross-sectional view schematically shown along a line.

1 to 3, the carbon dioxide recovery apparatus 100 according to the present invention includes an absorption housing 110, a stripping housing 130, a transfer line 140, a retransmission line 150, and a heat exchanger. 160.

The absorption housing 110 and the stripping housing 130 are connected by the transfer line 140 and the retransmission line 150, and the heat exchanger 160 is disposed on the transfer line 140 and the retransmission line 150. Are installed respectively.

The absorption housing 110 includes an exterior housing 111 and an inner tube housing 112 spaced apart from the exterior housing 111.

The exterior housing 111 has a cylindrical shape, a supply line 120 to which a mixed gas is supplied is connected to a lower portion thereof, the transfer line 140 is connected to a lower portion thereof, and a gas discharge pipe 114 is formed at an upper portion thereof.

The inner tube housing 112 may have a cylindrical shape and may be formed at the same height as the supply line 120, and the mixed gas introduced through the supply line 120 and supplied into the outer housing 111 may be provided in the inner tube housing. A plurality of slots 113 are provided that provide a travel path to be fed into the 112.

The plurality of slots 113 may be arranged at intervals within 15 to 20 degrees with respect to the central axis C of the inner tube housing 112 in which the central axis of the supply line 120 extends.

Here, the plurality of slots 113 has a range other than -30 to 30 degrees when a point connected to the central axis C of the inner tube housing 112, that is, the center axis of the supply line 120 is 0 degrees, That is, it may be disposed in the range of 30 ~ 330 degrees.

When the plurality of slots 113 are arranged at intervals within 15 to 20 degrees within a range of 30 to 330 degrees, the dispersibility of the mixed gas supplied into the inner tube housing 112 through the plurality of slots 113. Can be maximized.

That is, when the slots 113 are formed within -30 to 30 degrees based on the central axis C of the inner tube housing 112, the mixed gas supplied through the supply line 120 is within -30 to 30 degrees. The fraction of the mixed gas supplied directly to the slots 113 and exited to the slots 113 formed at different angles becomes very low, making it impossible to evenly disperse the inner tube housing 112, and over a long period of time. It is easily worn by direct contact with the high velocity mixed gas.

Therefore, the plurality of slots 113 is preferably formed when the 15 to 20 when arranged at intervals within 15 to 20 degrees within the range of 30 to 330 degrees.

When the number of slots 113 exceeds 20 by reducing the width between the slots 113, the dispersion degree of the mixed gas supplied into the absorption housing 110 is not large, and the slot 113 is increased. It is not desirable to reduce the spacing between them, because of the high possibility of wear during long-term operation.

On the other hand, when the width of the slots 113 also differs depending on the position where it is possible to increase the dispersibility of the mixed gas supplied through the slots 113.

That is, the widths of the slots 113 disposed at positions 60 to 120 degrees and 240 to 300 degrees A based on the central axis C of the absorption housing 110 may include the slots disposed at other positions B. May be larger than the width of 113).

This is because the tangential velocity is superior to the slots 113 disposed at the 60-120 degree and the 240-300 degree positions A, and the parallel velocity is provided to the slots 113 disposed at the other position B. This is because the flow rate of the mixed gas flowing into the absorption housing 110 through the slots 113 disposed at the 60 to 120 degrees and the 240 to 300 degrees positions is relatively smaller than that of other parts.

Therefore, in the 60 to 120 degrees and 240 to 300 degrees position (A), the width of the slot 113 is increased to increase the width of the slot 113 than the other position (B) to facilitate the inflow of the mixed gas to improve the dispersibility of the mixed gas have.

Here, the width of the slots 113 disposed in the 60 to 120 degrees and 240 to 300 degrees position A may be formed within a range of 14 to 20 degrees with respect to the central axis C of the inner tube housing 112. In addition, the width of the slots 113 disposed at the other position B may be formed within a range of 8 to 12 degrees.

According to the absorption housing 110 having the above structure, it is possible to improve the dispersibility of the mixed gas supplied therein without increasing the differential pressure in the absorption housing 110.

Carbon dioxide recovery by the carbon dioxide recovery apparatus 100 of the above structure is made by the following process.

First, the mixed gas is supplied to the outer housing 111 of the absorption housing 110 through the supply line 120 and is evenly introduced into the inner tube housing 112 through the slots 113 formed in the inner tube housing 112.

Carbon dioxide in the mixed gas introduced into the inner tube housing 112 causes a chemical reaction with an absorbent composed of an amine-based, amino acid salt, inorganic salt-based solution, ammonia water, or the like alone or in a mixture in the inner tube housing 112.

Here, the slots 113 of the inner tube housing 112 are formed under the conditions described above, so that the mixed gas is evenly dispersed when the mixed gas flows into the inner tube housing 112, thereby improving the chemical reaction between the absorbent and the carbon dioxide.

The mixed gas excluding the carbon dioxide is discharged to the outside through the gas discharge pipe 114 formed on the upper portion of the absorption housing 110, and the absorber reacting with the carbon dioxide (hereinafter referred to as a saturated carbon dioxide absorbent) is a transfer line 140 ) Is transferred to the stripping housing 130 via the heat exchanger 160.

The carbon dioxide saturated absorbent transferred to the stripping housing 130 moves downward and carbon dioxide is stripped by steam or thermal energy generated from the reboiler 131 under the stripping housing 130, and the absorbent is regenerated.

The regenerated absorbent is transferred back to the absorption housing 110 via the heat exchanger 160 through the retransmission line 150, and the stripped carbon dioxide is a carbon dioxide discharge pipe 132 formed on the stripping housing 130. After discharged to the reflux drum (not shown) through the water (H ₂ O) component contained in the carbon dioxide is separated and only carbon dioxide is transferred to the carbon dioxide recovery and treatment process is recovered.

According to the carbon dioxide recovery apparatus 100 as described above, the plurality of slots 113 which are the moving paths of the mixed gas are spaced 15 to 20 degrees within a range of 30 to 330 degrees with respect to the central axis C of the absorption housing 110. 15 to 20, but the width of the slots 113 disposed within 60 to 120 degrees, 240 to 300 degrees larger than the width of the slots 113 arranged at other angles, the absorption housing 110 It is possible to improve the dispersibility of the mixed gas in the absorption housing 110 without increasing the differential pressure in) and without increasing the volume of the absorption housing 110.

Reference numeral 170 is a pump.

1 is a schematic diagram schematically showing a carbon dioxide recovery apparatus according to an embodiment of the present invention.

Figure 2 is a front view schematically showing an absorption housing of the carbon dioxide recovery device of Figure 1;

3 is a plan sectional view schematically shown along the line II ′ of FIG. 2;

<Description of the symbols for the main parts of the drawings>

100 ... CO2 recovery 110 ... Absorption housing

111 ... external housing 112 ... internal housing

113 ... slot 120 ... supply line

130 ... Removal housing 140 ... Transfer line

150 ... Refeed Line 160 ... Heat Exchanger

170 ... pump

Claims (8)

An absorbent housing accommodating and absorbing carbon dioxide in the mixed gas introduced through the supply line and the absorbent to produce a saturated carbon dioxide absorbent, and an exhaust housing discharging the mixed gas from which the carbon dioxide has been removed; And a stripping housing receiving the carbon dioxide saturated absorbent and separating the carbon dioxide from the absorbent and discharging the carbon dioxide and transferring the absorbent to the absorbent housing. The absorbent housing includes an outer housing in communication with the supply line and an inner tube housing housed in the outer housing. A plurality of slots are formed in the inner tube housing spaced apart from the carbon dioxide recovery apparatus, characterized in that to provide an inflow path so that the mixed gas flowing through the supply line into the inner tube housing. The method according to claim 1, The inner tube housing is cylindrical, carbon dioxide recovery apparatus characterized in that the plurality of slots are arranged at intervals within 15 to 20 degrees with respect to the central axis of the inner tube housing. The method according to claim 2, The plurality of slots is a carbon dioxide recovery apparatus, characterized in that formed in the range of 30 ~ 330 degrees with respect to the central axis of the supply line. The method according to claim 3, The plurality of slots carbon dioxide recovery apparatus, characterized in that less than 15 to 20. The method according to claim 3, The widths of the slots (hereinafter, referred to as a first group) disposed within 60 to 120 degrees and 240 to 300 degrees with respect to the central axis of the inner tube housing among the plurality of slots are slots disposed at other angles (hereinafter, referred to as a first group). CO2 recovery apparatus, characterized in that greater than the width of. The method according to claim 5, Width of the first group is carbon dioxide recovery apparatus, characterized in that within 14 to 20 degrees with respect to the central axis of the inner tube housing. The method according to claim 5, The second group of the width of the carbon dioxide recovery apparatus, characterized in that within 8 to 12 degrees with respect to the central axis of the inner tube housing. The method according to claim 1, And the plurality of slots are formed at the same height as the supply line.

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