KR101194644B1 - Adsorbent box and adsorption tower using the same - Google Patents

Abstract

PURPOSE: An absorbent receiving frame and an automatically absorbent exchangeable absorption column using the same are provided to minimize the waste of absorbent and to keep the purification efficiency of the absorbent receiving frame constant. CONSTITUTION: An absorbent receiving frame includes a receiving container(130), a supplying part(140), and a storing part. An inlet and an outlet are formed at one upper end part and another lower end part of the receiving container. A first filtering net and a second filtering net are installed in the receiving container, and the permeation of absorbent through the filtering nets are prevented. The first filtering net is arranged to the upper vertical direction of the inlet. The second filtering net is arranged to the lower vertical direction of the outlet.

Description

Adsorbent storage frame and adsorption tower for automatic exchange of adsorbent using the same {ADSORBENT BOX AND ADSORPTION TOWER USING THE SAME}

The present invention relates to an adsorbent storage frame and an adsorption tower capable of automatically replacing an adsorbent using the same. More specifically, the adsorbent storage frame and the adsorbent automatic exchange which maintain the constant purification efficiency of the adsorbent storage frame and minimize the waste of the adsorbent, It relates to a possible adsorption tower.

The present invention relates to an adsorbent storage frame and an adsorption tower capable of automatic exchange of adsorbent.

Existing adsorbent and adsorption tower 10, as shown in Figure 1, includes a main body 11 formed with an inlet 12 and an outlet 13 on one side and the other side, respectively, from one side to the other side of the main body 11 It includes a plurality of receiving frames 14, 15, 16 installed to face each other.

However, the storage frame 14, 15, 16 is a structure that must replace all the adsorbents filled in at once, not only incurs an uneconomic caused by waste of the adsorbent, but also very short in the case of the storage frame installed on the inlet side There is a problem that the function of the adsorbent is lost in time and the adsorption efficiency is greatly reduced.

The structure of the existing storage frame or adsorption tower is as disclosed in the Republic of Korea Patent Publication No. 10-0266235. However, even in the case of the adsorption tower disclosed in the registered patent publication, such a problem cannot be solved.

An object of the present invention devised to solve the above problems is an adsorbent receiving frame including an adsorbent receiving frame including an input port and an ejection opening formed therein and a supply unit for supplying an adsorbent to the receiving container and a discharge port through which the adsorbent is discharged from the receiving container. Adsorbent storage frame and adsorbent to maintain a constant purification efficiency of the adsorbent storage frame and minimize waste of the adsorbent by allowing a predetermined amount of adsorbent to be exchanged every predetermined cycle without replacing all the adsorbents at once It is to provide an adsorption tower capable of automatic exchange.

According to a feature of the present invention for achieving the object as described above, the present invention comprises an adsorbent containing an adsorbent therein and installed in the adsorption adsorption tower to purify contaminated gas, the inlet for the adsorbent is introduced into the And a receiving container having discharge ports for discharging the adsorbents located at the lower end of the inner and outer sides thereof, respectively; A supply unit storing an adsorbent therein and connected to an upper side of the inlet to supply an adsorbent to the storage container; And a storage unit installed under the discharge port to receive and store the adsorbent discharged through the discharge port, wherein the inlet and the discharge port are respectively formed at an upper end and a lower other end of the accommodating cylinder, and are absorbed in the accommodating cylinder. A first filter net and a second filter net are not installed. The first filter net is disposed in the vertical downward direction of the inlet, and the upper and lower ends are spaced apart from the inner upper and lower sides of the storage container, respectively. The second filter net may be disposed in a vertically upward direction of the discharge port, and the upper end may be spaced apart from the inner upper end of the storage container, and the lower filter part may be in close contact with the inner lower end of the storage container.

At this time, the discharge port is characterized in that the discharge means for opening and closing the discharge port is installed so that the adsorbent inside the housing is discharged to the storage.

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According to another feature of the present invention for achieving the above object, in the adsorption-type adsorption tower, the inlet for the gas is introduced and the outlet for the inlet gas is discharged comprises a main body respectively formed on one side and the other side, the inside of the body There is provided a plurality of adsorbent receiving frame according to claim 2 so as to face each other from one side to the other side, characterized in that the inlet of the adsorbent storage frame is provided with a gate valve for opening and closing the inlet.

At this time, from the outlet side to the inlet side, the adsorbent stored in the storage unit of the adsorbent storage frame is characterized in that it comprises a connecting pipe connected to be supplied to the supply of the adsorbent storage frame adjacent.

In addition, the connecting pipe is characterized in that the pump is installed so that the adsorbent stored in the storage unit of the adsorbent housing frame can be supplied to the supply of the adsorbent storage frame adjacent.

According to the present invention as described above, it is possible to provide an adsorption tower and an adsorption tower capable of automatically changing the adsorbent storage frame and minimizing the waste of the adsorbent while maintaining a constant purification efficiency of the adsorbent storage frame.

1 is a view showing the configuration of the adsorption column according to the prior art.
2 is a block diagram of the adsorbent housing frame according to a preferred embodiment of the present invention.
3 is a block diagram of the adsorbent housing frame according to another embodiment of the present invention.
4 and 5 is a configuration diagram showing the configuration of the adsorption tower capable of automatic exchange of adsorbent according to the present invention.
6 is a graph showing the adsorption rate by residence time for pollutant gas (H 2 S) in each adsorbent storage frame.
Figure 7 is a comparison graph for comparing the adsorption rate for the conventional adsorbent storage frame according to the type of pollutant gas and the adsorbent storage frame according to the present invention.
8 is a comparison graph for comparing the total replacement life of the adsorbent contained in the adsorbent storage frame for the adsorbent storage frame according to the present invention and the existing adsorbent storage frame according to the type of contaminated gas.

Advantages and features of the present invention and methods for achieving them will be apparent with reference to the embodiments described below in detail with the accompanying drawings.

The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Hereinafter, the present invention will be described with reference to the drawings for explaining an adsorbent storage frame and an adsorption tower capable of automatically replacing an adsorbent using the same according to embodiments of the present invention.

The adsorbent storage frame according to the present invention will be described first, and then the adsorption tower capable of automatic exchange of adsorbent using the adsorbent storage frame according to the present invention will be described.

absorbent Storage frame (100)

2 is a block diagram of the adsorbent housing frame according to a preferred embodiment of the present invention.

The adsorbent housing frame 100 according to the preferred embodiment of the present invention relates to a housing frame including an adsorbent therein and installed in an adsorption type adsorption tower to purify contaminated gas.

Specifically, the adsorbent receiving frame 100 according to the present invention has an inlet 131 through which the adsorbent is introduced into the inner container and a discharge port 132 through which the adsorbent located at the inner lower end thereof is discharged to the outside. And, the adsorbent is stored therein and connected to the inlet 131, the supply unit 140 for supplying the adsorbent, and the storage unit 150 is installed under the discharge port to receive and store the adsorbent discharged through the discharge port 150 It includes.

That is, the adsorbent housing frame 100 according to the present invention includes a housing 130 in which the inlet 131 and the outlet 132 are formed, and the supply unit 140 and the storage unit 150.

The storage container 130 is a container means for allowing the contaminated gas to pass through the adsorbent is contained therein and various contaminants are adsorbed to the adsorbent.

An injection hole 131 is formed on the upper side of the storage container 130 to allow the adsorbent to be introduced into the storage container 130.

In addition, a discharge port 132 is formed at the lower side of the storage container 30 to allow the adsorbent included in the interior of the storage container 130 to be discharged to the outside of the storage container 130. .

That is, when the discharge port 132 is opened, the adsorbent included in the receiving container 130 will be discharged downward through the discharge hole 132 by gravity.

The supply unit 140 connected to the inlet 131 is installed above the storage container 130.

The supply unit 140 stores the adsorbent to be supplied into the storage container 130 and is connected to the inlet 131 so that the stored adsorbent can be introduced into the storage container 130 through the inlet 131.

The storage unit 150 is installed below the storage container 130 to receive and store the adsorbent discharged through the discharge port 132 from the storage container 130.

That is, the storage unit 150 is installed below the storage container 130 so as to receive and store the adsorbent discharged through the discharge port 132 from the storage container 130.

Discharge means 160 is installed in the discharge port 132.

That is, the discharge means 160 is a means for opening and closing the discharge port 132, when the discharge means 160 closes the discharge port 132, the adsorbent contained in the receiving container 130 is not discharged out, When the discharge means 160 opens the discharge port 132, the adsorbent included in the receiving container 130, mainly the adsorbent located at the bottom of the receiving container is discharged through the discharge port 132 is received in the storage unit 150 Stored.

In this case, since the adsorbent is filled in the storage container 130, when the adsorbent is discharged to the storage 150 through the discharge port 132 while the discharge means 160 is opened, the supply unit ( The adsorbent stored in the 140 is introduced into the storage container 130 through the inlet 131 by the amount of the adsorbent corresponding to the amount of the adsorbent discharged to the storage unit 150.

At this time, the discharge means 160 is preferably made of a valve (rotary valve) or the like that can be repeated to open and close the discharge port 132 every predetermined period.

The rotary valve rotates at a predetermined time and operates to repeat opening and closing of the discharge port 132 every predetermined time, and various conventional rotary valves may be used.

That is, the discharge port 132 is opened and closed at a predetermined cycle by the rotary valve, so that the adsorbent in the storage container 130 is discharged to the storage 150 through the discharge port 132 at each predetermined cycle. A corresponding amount of new adsorbent may be introduced into the receiving container 130 from the supply unit 140 through the inlet 131.

By the above configuration, it is possible to provide the adsorbent storage frame 100 which can automatically exchange the adsorbent filled in the storage container 130 into a new adsorbent by a predetermined amount at each predetermined cycle.

The inlet 131 is preferably provided with a gate valve 120 to allow the adsorbent stored in the supply unit 140 to be isolated from the housing 130.

When the adsorbent in the receiving container 130 is discharged to the storage 150 through the discharge means 160, the gate valve 120 has an amount of adsorbent corresponding to the discharged adsorbent from the supply unit 140. 131 is opened to be replenished and supplied to the container 130, and after the adsorbent is replenished in the container 130, the inlet 131 is closed to close the container 130 and the supply 140. It serves to block.

The gate valve 120 blocks the contaminated air from flowing into the supply unit 140 while the contaminated gas is introduced into the storage container 130 to be purified to prevent the adsorbent stored in the supply unit 140 from being contaminated. For sake.

The gate valve 120 and the discharge means 160 may be used a variety of valves such as a sliding gate valve or a general rotary valve.

3 is a block diagram of the adsorbent housing frame according to another embodiment of the present invention.

Adsorbent housing frame 100 according to another embodiment of the present invention includes an inlet 131 and the outlet 132 is formed containing a container 130, the supply unit 140 and the storage unit 150, the inlet 131 ) Is formed at one end of the upper side of the housing 130, and the discharge port 132 is formed at the other end of the lower side of the housing 130 (see FIG. 3).

In this case, a first filter net 191 and a second filter net 192 having a mesh structure through which the adsorbent does not penetrate are installed in the housing 130.

In this case, the first filter net 191 is disposed in the vertical downward direction of the inlet 131, the upper end and the lower end are installed so as to be spaced apart from the inner upper side and the lower side of the receiving container 130, respectively. In addition, the second filter net 192 is disposed in the vertical upper direction of the discharge port 132, the upper end is spaced apart from the inner upper side of the receiving container 130 and the lower end and the inner lower surface of the receiving container 130 and It is installed to be in close contact (see FIG. 3).

In this case, the first filter net 191 is spaced apart between the lower end of the first filter net 191 and the inner lower side of the housing 130 is the upper end of the first filter net 192 and the receiving cylinder 130 It is preferable that the inner upper side of the is installed to be formed larger than the spaced apart.

In addition, the upper end of the second filter net 192 is preferably installed to be located at the same height or lower than the height of the lower end of the first filter net 191.

That is, the first and second filter nets 191 respectively provided at the inlet 131 and the outlet 132 and the inlet 131 and the outlet 132, respectively, formed at the upper end and the lower end of the housing 130. The adsorbent filled in the housing 130 by the second filter net 192 is moved along the flow as shown by the arrow shown in FIG.

At this time, the discharge means 132 is provided with the discharge means 160 as described above, and the adsorbent filled in the receiving container 130 in accordance with the opening and closing operation of the discharge port 132 by the discharge means 160 is also shown in FIG. You will follow the same path as the arrow shown in 3.

In this case, the discharge means 160 may be a valve or a rotary valve or a gate valve as described above.

Next will be described with respect to the adsorption tower capable of automatic exchange of the adsorbent using the adsorbent storage frame according to the present invention.

Adsorption tower with automatic exchange of adsorbent

4 and 5 is a configuration diagram showing the configuration of the adsorption tower capable of automatic exchange of adsorbent according to the present invention.

Adsorption tower capable of automatic exchange of adsorbent according to the present invention relates to an adsorption type adsorption tower, and the adsorbent housing frame 100 according to the present invention described above is used.

That is, the adsorption tower capable of automatic exchange of the adsorbent according to the present invention has a structure in which any one of the adsorbent storage frames 100 according to the present invention is installed in the adsorption tower main body 200, and its specific configuration is as follows.

That is, the inlet 210 through which the gas is introduced and the outlet 220 through which the introduced gas is discharged include a main body 200 formed on one side and the other side, and the adsorbent according to the present invention described above in the main body 200. Any one of the adsorbent housing frame is provided in plurality so as to face each other from one side to the other side.

At this time, the adsorbent adsorbent storage frame according to the present invention, as described above, the inlet 131 through which the adsorbent is introduced into the inside and the discharge port 132 through which the adsorbent located in the lower end of the discharge is discharged to the outside, respectively, formed in the upper side and the lower side, respectively. 130, a supply unit 140 that stores an adsorbent therein and is connected to an upper side of the inlet 131 to supply an adsorbent to the storage container 130, and is provided below the discharge port 132 and the discharge port 132. In the adsorbent storage frame (hereinafter referred to as the 'first adsorbent storage frame'), or the first adsorption storage frame including a storage unit 150 for receiving and storing the adsorbent discharged through the), the inlet 131 And the discharge holes 132 are respectively formed at the upper end and the lower end of the receiving container 130, and the first filter net 191 and the second filter net through which the absorbent does not penetrate the inside of the housing 130. 192 is installed, but the first filter network 191 is It is disposed in the vertical direction of the inlet 131, and the upper end and the lower end are installed so as to be spaced apart from the inner upper side and the lower side of the receiving container 130, respectively, the second filter net 192 is perpendicular to the discharge port 132 It is disposed in the upper direction and the upper end is spaced apart from the inner upper end of the receiving container 130, the lower end is installed so as to be in close contact with the inner lower end of the receiving container 130 (hereinafter referred to as 'second adsorbent receiving frame') ).

In this case, as described above, the discharge means 160 may be installed in the discharge port 132 constituting the first adsorbent housing frame and the second adsorbent housing frame.

At this time, the contents of the discharge means 160 is as described above.

That is, the adsorption type adsorption tower according to the present invention includes a main body 200 and the adsorbent housing frame 100.

Since the description of the adsorbent storage frame 100, that is, the first adsorbent storage frame or the second adsorbent storage frame has been described above, the description thereof will be omitted.

The main body 200 has an inlet 210 through which contaminated gas is introduced into the main body on one side, and an outlet 220 through which the inlet gas is discharged is formed on the other side.

In this case, a plurality of the first adsorbent storage frame or the second adsorbent storage frame is provided in the main body 200 so that one of the first adsorbent storage frame or the second adsorbent storage frame is opposite to the other side, that is, the inlet port 210 side.

That is, the polluted gas introduced into the main body 200 through the inlet 210 passes through a plurality of adsorbent storage frames 100 arranged to face each other from one side of the main body 200 to the other side, and each adsorbent storage frame Contaminants are adsorbed and purified by the adsorbent included therein and then discharged to the outlet 220.

At this time, the adsorbent included in each adsorbent housing frame 100 may be replaced by a predetermined amount every predetermined period as described above.

In particular, the discharge means 160, that is, a valve or a rotary valve may be installed in the discharge port 132 so that the replacement of the adsorbent may be automatically performed.

In this case, the adsorbent housing frame 100 installed to face each other in the main body 200 is connected to the supply unit 140 and the storage unit 150 of two adjacent adsorbent storage frame 100 by a connection pipe 170. You can do that.

At this time, the connection between the supply unit 140 and the storage unit 150 of the two adjacent adsorbent storage frame 100 by the connecting pipe 170, the two adsorbents sequentially adjacent to the inlet 210 side from the outlet 220 side The storage unit 150 and the supply unit 140 are connected between the storage frame 100.

As shown in FIGS. 4 and 5, a case in which three adsorbent storage frames 100 are installed from one side to the other side of the main body 200, that is, the inlet 210 to the outlet 220, will be described as an example. As follows. In this case, the adsorbent storage frame 100 is composed of a first adsorbent storage frame, a second adsorbent storage frame, and a third adsorbent storage frame, and each of the first adsorbent storage frame, the second adsorbent storage frame, and the third adsorbent storage frame is provided. The storage container 130, the inlet 131, the discharge port 132, the supply unit 140, the storage unit 150, the discharge means 160 and the like as described above will be included. That is, the first adsorbent 130a and the first discharge port 130a formed with the first inlet 131a and the first discharge port 132a are installed in the first adsorbent housing, the first discharge means 160a installed in the first discharge port 132a, and the first agent. A first gate valve 132a installed at the first inlet 132a, a first supply unit 140a connected to the first inlet 132a, and an adsorbent discharged through the first outlet 132a; 1 storage unit 150a and the like. In addition, the second adsorbent housing frame is also similarly provided with a second container 130b having a second inlet 131b and a second outlet 132b, and second discharge means 160b provided at the second outlet 132b. And a second gate valve 132b installed at the second inlet 132b, a second supply unit 140b connected to the second inlet 132b, and an adsorbent discharged through the second outlet 132b. And a second storage unit 150b for storing. Similarly, in the case of the third adsorbent housing frame, the third storage container 130c having the third inlet 131c and the third discharge port 132c is formed, and the third discharge means 160c installed in the third discharge port 132c. And a third gate valve 132c installed at the third inlet 132c, a third supply unit 140c connected to the third inlet 132c, and an adsorbent discharged through the third outlet 132c. The third storage unit 150c may be stored.

At this time, the third storage part 132c of the third adsorbent housing frame and the second supply unit 131b which is a supply unit of the second adsorbent storage frame are connected by the second connecting pipe 170b to allow the third storage unit ( The adsorbent stored in 150c is moved to the second supply part 140b, and the second storage part 132b of the second adsorbent storage frame and the first supply part 131a which is a supply part of the first adsorbent storage frame are the first. It is connected by a connection pipe 170a to move the adsorbent stored in the second storage part 150b to the first supply part 140a. In this case, a pump, that is, a first pump 180b is installed in the second connection pipe 170b, and a second pump 180a is installed in the first connection pipe 170a.

That is, the adsorption tower capable of automatic exchange of adsorbent according to the present invention sequentially from the outlet 220 side to the inlet 210 side, and the adsorbent storage frame 100 adjacent to the adsorbent stored in the storage unit 150 of the adsorbent storage frame 100. It includes a connection pipe 170 connected to be supplied to the supply unit 140 of the).

This is because the contamination degree of the adsorbent contained in the adsorbent accommodating frame 100 by the gas introduced by the adjoining inlet 210 becomes larger, and the contamination degree becomes smaller as the adjoining outlet 220 becomes smaller. By allowing the adsorbent contained in the installed adsorbent storage frame 100 to be reused in the adsorbent storage frame 100 installed on the inlet 210 side, the waste of the contaminated gas in the adsorbent storage frame 100 is minimized while minimizing unnecessary waste of the adsorbent. This is to maintain the maximum purification efficiency.

In this case, each of the connection pipes 170 is provided with a pump 180 to allow the adsorbent stored in the storage unit of the adsorbent housing frame to be supplied to the supply unit of the adjacent adsorbent storage frame.

That is, the adsorbent included in each adsorbent storage frame 100 is discharged by a predetermined amount to each storage unit 150 at predetermined intervals by the discharge means 160, and accordingly, each pump 180 operates to store the adsorbent. The adsorbent stored in the unit 150 is pumped and moved to the supply unit 140 of the adsorbent receiving frame 100 adjacent to the adsorbent receiving frame 100 through the inlet 131. As described above, the moving structure of the adsorbent is installed so as to be sequentially formed from the outlet 220 to the inlet 210.

At this time, a new adsorbent is stored and supplied to the supply unit 140 of the adsorbent storage frame 100 closest to the outlet 220, and the storage unit of the adsorbent storage frame 100 closest to the inlet 210 is provided ( The adsorbent discharged to 150 is no longer reused and can be disposed of.

That is, unlike the existing adsorbent storage frame or adsorption tower, which has to replace all the adsorbents contained in the adsorbent storage frame at once, the adsorption tower capable of automatic exchange of the adsorbent according to the present invention having the above-described configuration is each adsorbent storage frame 100 respectively. The adsorbent is exchanged automatically every time, or the adsorbent is moved and reused along each adsorbent storage frame 100 installed from the outlet 220 side to the inlet 210 side, thereby maintaining the maximum purification capacity of the contaminated gas. And minimize the waste of the adsorbent.

Figure 6 is a graph showing the adsorption rate by residence time for the pollutant gas (H2S) in the adsorbent storage frame.

As shown in FIG. 6, it can be seen that the adsorption efficiency increases as the residence time of the polluted air in the adsorbent housing frame including the adsorbent increases.

Figure 7 is a comparison graph for comparing the adsorption rate for the conventional adsorbent storage frame according to the type of pollutant gas and the adsorbent storage frame according to the present invention.

Lines a1 to a4 in FIG. 7 indicate the adsorption rate retention period for the existing adsorbent storage frame, and line b shows the adsorption rate maintenance period for the adsorbent storage frame according to the present invention.

In this case, a1 represents a case in which both the dust and water are included in the polluted gas, a2 represents a case containing only water, a3 represents a case containing only dust, and a4 represents a case in which both dust and water are not included, b Indicates only cases that contain both dust and water.

As shown in FIG. 7, the conventional adsorbent housing frame is a case in which partial exchange of the adsorbent is not possible according to a predetermined cycle, and in the case of a1, the adsorption rate maintenance period is about full, and in the case of a2, about 3 months and 4 in the case of a3. In the case of months and a4, the adsorption rate retention period is about 5 months.

In contrast, in the case of the adsorbent housing frame according to the present invention, it can be seen that even in the case of the pollutant gas containing both dust and moisture, the adsorption rate maintenance period of about 6 months is shown.

8 is a comparison graph for comparing the total replacement life of the adsorbent contained in the adsorbent storage frame for the adsorbent storage frame according to the present invention and the existing adsorbent storage frame according to the type of contaminated gas.

As shown in FIG. 8, it can be seen that the life span of the adsorbent housing frame according to the present invention is excellent.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the foregoing detailed description, and all changes or modifications derived from the meaning and scope of the claims and the equivalents thereof are included in the scope of the present invention Should be interpreted.

100: adsorbent storage frame 120: gate valve
130: storage container 131: inlet
132: discharge port 140: supply unit
150: storage unit 160: discharge means
170: connector 180: pump
191: first filter network 192: second filter network

Claims (6)

In the adsorbent storage frame containing an adsorbent therein and installed inside the adsorption adsorption tower to purify the contaminated gas,
An accommodation port into which an adsorbent is introduced into the inside and a discharge port through which an adsorbent located at an inner lower end thereof is discharged to the outside, respectively; A supply unit storing an adsorbent therein and connected to an upper side of the inlet to supply an adsorbent to the storage container; And a storage unit installed under the discharge port to receive and store the adsorbent discharged through the discharge port.
The inlet and the outlet are respectively formed in the upper end and the other end of the lower end, the first filter net and the second filter net through which the sorbent is not penetrated are installed in the inner container. It is disposed in the vertical direction of the inlet and the upper end and the lower end are installed so as to be spaced apart from the upper side and the lower side of the inner container, respectively, the second filter net is disposed in the vertical upper direction of the discharge port and the upper end is the inner side of the container Adsorbent storage frame, characterized in that spaced apart from the top and the lower end is installed to be in close contact with the inner bottom of the housing.
The method of claim 1,
And a discharge means for opening and closing the discharge port so that the discharge hole is discharged to the storage part in the discharge port.
delete In the adsorption column,
An inlet for gas and an outlet for inlet gas are discharged to include a main body formed on one side and the other side,
The main body is provided with a plurality of adsorbent housing frame according to claim 2 so as to face each other from one side to the other side, the inlet of the adsorbent housing frame is provided with a gate valve for opening and closing the inlet Adsorption tower for automatic exchange of adsorbent.
The method of claim 4, wherein
Sequentially from the outlet side to the inlet side,
And a connecting tube connected to the adsorbent stored in the storage unit of the adsorbent storage frame so that the adsorbent can be supplied to the supply unit of the adjacent adsorbent storage frame.
The method of claim 5, wherein
The connection pipe is installed in the adsorption tower, characterized in that the pump is installed so that the adsorbent stored in the storage unit of the adsorbent storage frame can be supplied to the supply of the adsorbent storage frame adjacent.

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