KR20210003459A - Adsorption device and air separation plant having the same - Google Patents

Abstract

Disclosed is an adsorption device for an air separation facility. The adsorption device of an air separation facility for separating oxygen, nitrogen, and argon in air according to an embodiment of the present invention includes: a bed in which an adsorbent for adsorbing moisture and carbon dioxide in raw material air is embedded; a filter pipe connected to an outlet of the bed and having a built-in filter unit for filtering foreign substances in the raw material air that has passed through the bed; a backwash pipe connected to the inside of the filter pipe and providing a fluid for cleaning the filter unit; and a discharge pipe connected to the filter pipe and discharging foreign substances separated from the filter unit to the outside of the filter pipe.

Description

Adsorption device and air separation equipment having the same {ADSORPTION DEVICE AND AIR SEPARATION PLANT HAVING THE SAME}

The present invention relates to an adsorption device of an air separation facility and an air separation facility having the same, and more particularly, to an adsorption device capable of automatic filter cleaning and an air separation facility having the same.

In general, steel mills have an air separation facility that separates oxygen, nitrogen, and argon contained in the air due to a difference in boiling point by inhaling and compressing air in the atmosphere and then reducing the temperature while expanding it again.

In the air separation facility, the raw material air in the atmosphere sucked through the air filter is sucked into the air compressor, compressed, and then supplied to the washing cooling tower. Then, it is cooled to room temperature by spraying the cooling water supplied to the washing cooling tower, and at the same time, it removes water-soluble dust in the air, enters the adsorber, which is an impurity adsorption facility, to remove moisture and carbon dioxide contained in the air, and is supplied to the expansion turbine for adiabatic expansion. It is sent to the rectifying tower to separate and produce liquid gas by boiling point.

Meanwhile, as shown in FIG. 1, the bed 1 of the adsorber is filled with an adsorbent 2 for removing moisture and carbon dioxide contained in the compressed raw air, and the bed 1 contains an adsorbent 2 There is a built-in filter (3) to remove foreign substances from the raw material air that has passed through.

The adsorbent (2) contained in the bed (1) is cured when used for a long period of time, and the cured adsorbent (2) is finely broken and powdered by the high-pressure raw material air flowing into the bed (1). 1) Clog the filter (3) located inside.

If the filter (3) is clogged, stop the operation of the air separation facility, disassemble the filter (3) with the flange (4) located at the outlet of the bed (1) removed, and then use a crane to remove the bed (1). ), the filter 3 was lifted and put down on the ground, and the operator performed cleaning.

For this reason, the air separation facility must be stopped for a long time to replace the filter, and the air separation facility must be restarted for a long time to operate to normal, resulting in a problem of lowering production.

Korean Patent Publication No. 2006-0024352 (published on March 16, 2006)

Embodiments of the present invention are to provide an adsorption device capable of performing automatic cleaning of a filter and an air separation facility having the same.

According to an aspect of the present invention, as an adsorption device of an air separation facility for separating oxygen, nitrogen, and argon in air, a bed having an adsorbent for adsorbing moisture and carbon dioxide from raw air, and an outlet of the bed, are connected, A filter pipe with a built-in filter unit that filters foreign substances from the raw air that has passed through the bed, is connected to the inside of the filter pipe, and is connected to a backwash pipe providing a fluid for washing the filter unit and the filter pipe, and the filter unit An adsorption device of an air separation facility may be provided including a discharge pipe for discharging the foreign matter separated from the filter pipe to the outside of the filter pipe.

In addition, the filter pipe includes an inlet pipe connected to the outlet of the bed, a pair of branch pipes branched from the inlet pipe and each of which the filter unit is embedded, and an outlet pipe to which the pair of branch pipes merge.

In addition, the discharge pipe may be connected to the pair of branch pipes, respectively, in which discharge valves for controlling the flow of fluid are installed.

In addition, each of the pair of branch pipes includes an expansion part in which the filter part is located.

In addition, the filter unit includes a filter net and a nozzle rod that is rotatably installed inside the filter net and has a plurality of nozzles that receive fluid from the backwash pipe and spray the filter net.

In addition, the plurality of nozzles may be arranged such that two adjacent nozzles face different directions so that the nozzle rod may self-rotate using the spraying force of the sprayed fluid.

In addition, an upper valve and a lower valve for controlling the flow of fluid may be installed in the branch pipes positioned above and below the expansion part.

In addition, a backwash valve for controlling a fluid flow for washing the filter unit may be installed in the backwash pipe.

In addition, the outlet pipe may be provided with an outlet valve for controlling the flow of fluid toward the main heat exchanger of the air separation facility.

In addition, at least two or more beds may be provided.

According to another aspect of the present invention, in an air separation facility including an air compressor, a flush cooling tower, an adsorption device, a main heat exchanger, and a rectifying tower, the adsorption device is connected to an inlet pipe provided with compressed air discharged from the flush cooling tower. And a bed with an adsorbent therein, and a pair of branch pipes branched from the inlet pipe connected to the outlet of the bed and each having a filter unit built in, and the pair of branch pipes merge, and passing through the filter unit. An outlet pipe providing compressed air to the main heat exchanger, a backwash pipe each connected to the pair of branch pipes, and providing a fluid for cleaning to the filter unit, and the components located above and below the filter unit Each of the upper and lower valves installed in the engine and the filter unit is connected to the pair of branch pipes to discharge foreign substances from the filter unit to the outside when washing, and each includes a pair of discharge pipes equipped with discharge valves. Air separation equipment may be provided.

Embodiments of the present invention can reduce the time and manpower consumption when replacing and cleaning the filter of the adsorption device, so that the productivity of the air separation facility is significantly improved.

1 shows an adsorption device of a conventional air separation facility.
Figure 2 schematically shows an air separation equipment according to an embodiment of the present invention.
3 illustrates an adsorption device according to an embodiment of the present invention.
4 is a cross-sectional view showing the inside of a filter pipe according to an embodiment of the present invention.
5 shows a nozzle rod according to an embodiment of the present invention.
6 shows the fluid flow of the adsorption device during normal operation of the adsorption device according to an embodiment of the present invention.
7 is a diagram illustrating a fluid flow when washing the adsorption device according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments introduced below are provided as examples in order to sufficiently convey the idea of the present invention to those of ordinary skill in the art. The present invention is not limited to the embodiments described below and may be embodied in other forms. In order to clearly describe the present invention, parts irrelevant to the description are omitted from the drawings, and in the drawings, the width, length, thickness, etc. of components may be exaggerated and expressed for convenience. The same reference numbers throughout the specification denote the same elements.

Figure 2 schematically shows an air separation equipment according to an embodiment of the present invention.

2, the air separation equipment 10 according to the embodiment of the present invention includes an air compressor 12, a flushing cooling tower 13, an adsorption device 20, a main heat exchanger 17, and a rectifying tower 18. Include.

The air compressor 12 receives purified raw material air through the air filter 11 and compresses it with high-pressure compressed air having a high pressure.

The raw material air provided from the air filter 11 is generated by high-pressure compressed air while undergoing a multi-stage compression process in the air compressor 12 and then supplied to the washing cooling tower 13.

The air compressor 12 includes a cooler that performs cooling after compression in order to increase compression efficiency.

The washing cooling tower 13 performs heat exchange by directly contacting the high-temperature and high-pressure raw material air provided from the air compressor 12 with cooling water.

The flush cooling tower 13 performs primary heat exchange with medium-temperature cooling water in the middle of the flush cooling tower 13 with the high-temperature air supplied from the bottom, and cools by exchanging heat with low-purity nitrogen provided from the chiller tower in the upper portion. The secondary heat exchange with the low-temperature cooling water is performed to cool the raw material air, and at the same time, water-soluble dust is removed and then provided to the adsorption device 20.

The adsorption device 20 removes impurities such as moisture and carbon dioxide contained in the compressed raw material air using an adsorbent.

The adsorption device 20 is filled with an adsorbent, and various kinds of adsorbents each adsorb the target moisture and impurities to prevent them from going to the post process, so that only necessary components such as nitrogen, oxygen, and argon in the raw material air are the post process. It is provided by the main heat exchanger (17).

The adsorption device 20 may be operated with two beds as a tank, and when one adsorber is used, the other adsorber performs a regeneration process using impurity nitrogen provided from the rectification tower 18.

Part of the raw material air from which moisture and carbon dioxide have been removed while passing through the adsorption device 20 is transferred to the rectification tower 18 through the main heat exchanger 17, and the other part is transferred to the rectification tower 18 through the expansion turbine 16. Is transferred to.

A specific configuration of the adsorption device 20 will be described later.

The main heat exchanger 17 exchanges heat with the room temperature raw material air compressed by the air compressor 12 and the cryogenic cold gas (oxygen, nitrogen, argon, impurity nitrogen) from the rectification tower 18 to cool the raw material air at room temperature. Phosphorus is lowered to -170℃, and the cryogenic cold gas is recovered to room temperature (15℃) by heat exchange with raw material air.

The expansion turbine 16 is a device that generates cold by adiabatic expansion of raw material air, and compensates for the cooling loss of the main heat exchanger 17 due to radiant heat and liquid extraction during normal operation, and during the cooling operation, the main heat exchanger 17 and It serves to gradually liquefy the raw material air by supplying cold cooling to the rectifying tower 18.

The rectifying tower 18 continuously repeats the process of concentrating and purifying in the rectifying tower 18 according to the boiling point difference according to the pressure and temperature of the raw material air to separate and produce oxygen, nitrogen, and argon gases.

In the rectification process in the rectification tower 18, raw material air is supplied to the lower tower of the rectification tower 18, and a Re-Boiler Condenser and a rectifying tray are installed in the upper part of the lower tower to allow heat exchange between the upper and lower towers. The raw material air of the lower tower is liquefied by heat exchange through the flow path and the temperature of the upper liquid oxygen decreases in the liquid oxygen of the upper tower, and the liquid oxygen of the upper tower is vaporized by increasing the temperature of the raw material air of the lower tower. Is liquefied and flows down to the rectifying tray to liquefy a large amount of oxygen in the rising raw material air, leaving only nitrogen-based gas at the top of the lower tower. In the upper tower, the gas containing nitrogen and argon in the liquid acid is vaporized first because the boiling point is lower than that of oxygen, and is placed in the upper column, and is purified with more than 99.5% oxygen in the lower part of the upper tower. In addition, pure nitrogen is formed in the upper part of the lower tower, an impurity nitrogen layer is formed in the middle part, and liquid air corresponding to about 40% of oxygen is concentrated in the lower part.

The upper tower of the rectification tower 18 distributes pure liquid nitrogen, impurity liquid nitrogen, and liquid air generated in the lower tower at appropriate flow rates to the upper, middle, and middle portions of the upper tray. A pure nitrogen layer is formed, an impurity nitrogen layer is formed under it, a crude argon layer is formed at the bottom, and an oxygen layer and liquid oxygen are formed at the bottom.

The argon gas concentrated to 8% in the upper tower of the rectification tower 18 is fed to the crude argon rectification tower 18a, and the oxygen component having a high boiling point is liquefied by heat exchange with the liquid air at the top in the boiler condenser, and is collected under the tray. , This liquid oxygen is sent back to the upper tower of the rectifying tower 18, and the argon component is vaporized while passing through the tray due to the low boiling point and collected at the top. If this process continues, 8% of the argon component is concentrated to 99.3% or more of the argon component.

In order to remove the nitrogen component equivalent to 0.7% of the high-purity argon components generated in the crude argon rectification tower (18a), the rectification process in the rectification tower (18) through the Re-Boiler Condenser in the high-purity argon rectification tower (18b) and Likewise, nitrogen in argon is separated by using the difference in boiling point to produce pure argon products.

Meanwhile, the impurity nitrogen generated in the rectification tower 18 is discharged through the impure nitrogen discharge line, and heat exchanged with the raw material air through the main heat exchanger 17 to recover to room temperature, and then some enter the chiller tower 15. The cooling water is heat-exchanged to reduce the temperature, and then released to the atmosphere, and the other part is supplied to the adsorption device 20, which is a device for removing impurities from raw air, and used as a regeneration gas to remove moisture and carbon dioxide contained in the adsorbent, and then to the atmosphere. Is released

3 is a view showing an adsorption device according to an embodiment of the present invention, FIG. 4 is a cross-sectional view showing the inside of a filter pipe according to an embodiment of the present invention, and FIG. 5 is a nozzle rod according to an embodiment of the present invention. I did it.

3 to 5, the adsorption device 20 according to an embodiment of the present invention includes a bed 30 containing an adsorbent 31 for adsorbing moisture and carbon dioxide from raw air, and an outlet of the bed 30. A filter pipe (50) connected to (33) and having a filter part (40) that filters foreign substances from the raw air that has passed through the bed (30), and a backwash pipe that provides a fluid for cleaning the filter part (40) ( 60) and a discharge pipe 70 for discharging the foreign matter separated from the filter unit 40 to the outside.

The bed 30 of the present embodiment can be used by operating two units as a unit, and only the adsorbent 31 is accommodated in the bed 30. The adsorbent 31 accommodates an adsorbent such as an alumina gel having a property of adsorbing moisture while the raw material air passes through the gel, and a moriculasive gel having a property of adsorbing carbon dioxide.

In addition, foreign substances of the raw material air passing through the adsorbent 31 are removed by the filter unit 40 accommodated in the filter pipe 50 connected separately from the bed 30.

Since the adsorption capacity of the adsorbent 31 in the bed 30 decreases when the adsorption process is performed for a certain period of time, it must undergo a regeneration process to remove moisture and carbon dioxide adsorbed by the adsorbent 31. Therefore, while one bed 30 is being regenerated, two units may be provided in a set to operate the other bed 30.

The inlet 32 of the bed 30 is connected to the air compressor 12 and the inlet pipe 21 through which the raw material air passed through the water washing cooling tower 13 is provided, and the outlet 33 of the bed 30 is a filter pipe ( 50).

The inlet pipe 21 is branched so as to be connected to each inlet 32 of the pair of beds 30, and the branched inlet pipe 21 has an inlet valve that controls the flow of raw material air flowing into the bed 30 ( 22) is installed.

The filter pipe 50 includes an inlet pipe 51 connected to the outlet 33 of the bed 30, a pair of branch pipes 52a and 52b branching from the inlet pipe 51, and a pair of branch pipes. It includes an outlet pipe 53 where (52a, 52b) merges.

Filter units 40a and 40b for filtering foreign substances of the raw material air are disposed in the pair of branch pipes 52a and 52b, respectively.

Filter parts (40a, 40b) are arranged in the expansion parts (54a, 54b) each having an enlarged diameter in the branch pipes (52a, 52b), and receive flow resistance like the environment in which the filter is built in the existing bed (30). It can be provided so as not to.

The filter units 40a and 40b each include a filter net 41 and a nozzle rod 42 that is rotatably installed in the filter net 41.

The filter net 41 may be formed in a conical shape with an open top, and the nozzle rod 42 is formed in a cylindrical shape having a long length vertically, and a hollow hole (not shown) through which fluid is introduced is formed therein.

On the outer surface of the nozzle rod 42, a plurality of nozzles 43 for spraying the fluid flowing into the nozzle rod 42 to the outside are disposed, and the plurality of nozzles 43 The nozzles 43 may be arranged to face different directions.

The nozzle rod 42 may rotate itself by the spraying force of the fluid ejected by the two nozzles 43 arranged in different directions.

Both upper and lower ends of the nozzle rod 42 may be supported by the bearing 44 so that self-rotation by the injection force of the fluid ejected by the plurality of nozzles 43 is facilitated.

An upper support 55 and a lower support 56 may be installed above and below the expansion portions 54a and 54b for rotation of the nozzle rod 42.

The upper support 55 and the lower support 56 are radially extended from the hubs 55a and 56a located at the center of the expansion parts 54a and 54b and the hubs 55a and 56a to expand the pipes 54a and 54b. ) And a plurality of support rods (55b, 56b) supported on the inner wall.

The upper end of the nozzle rod 42 may be supported so as to rotate within the hub 55a of the upper support body 55, and the lower end of the nozzle rod 42 may rotate within the hub 56a of the lower support body 56. Can be supported.

An opening hole 55c opened laterally is formed in the hub 55a of the upper support 55, and the opening hole 55c may be connected to the backwash pipe 60.

A plurality of inlet holes 42a for introducing the fluid provided to the opening hole 55c through the backwash pipe 60 into the nozzle rod 42 may be formed in the upper portion of the nozzle rod 42 along the circumferential direction. have.

Airtightness may be maintained by sealing members 57a and 57b installed between the hub 55a of the upper support 55 and the nozzle rod 42 above and below the plurality of inlet holes 54a.

The backwash pipe 60 is a pipe that provides a fluid for cleaning the filter unit 40, and has one end connected to a fluid supply source (not shown) composed of compressed air or a cleaning solution, and the other end connects the expansion pipes 54a and 54b. It may penetrate through and be connected to the opening hole 55c formed in the hub 55a of the upper support 55.

The backwash pipe 60 may be provided with a plurality of backwash valves 61a and 61b for controlling the flow of fluid for cleaning the filter units 40a and 40b.

The discharge pipes 70a and 70b may be positioned below the expansion portions 54a and 54b, respectively, and discharge valves 71a and 71b for controlling the opening and closing of the discharge pipes 70a and 70b may be installed.

Meanwhile, an upper valve 58 and a lower valve 59 for controlling the fluid flow inside the filter unit 40 may be installed in the branch pipes 52a and 52b located above and below the expansion parts 54a and 54b. have.

In addition, an outflow valve 53a for controlling a fluid flow may be installed in an outflow pipe 53 connected to the main heat exchanger 17 by discharging the raw material air from which foreign substances are filtered by the filter unit 40. The outlet valve 53a may be selectively opened or closed depending on whether or not the adsorbent 31 is regenerated.

The valves disclosed in this embodiment may be configured as electromagnetic valves that are automatically turned on and off according to a control signal from the valve control unit.

Hereinafter, a method of operating the adsorption device according to an embodiment of the present invention will be described.

First, as shown in FIG. 6, raw material air discharged through one bed 30 during normal operation of the air separation facility 10 is limited through an inlet pipe 51 connected to the outlet 33 of the bed 30. It is provided to the filter unit 40a through one of the pair of branch pipes 52a and 52b.

According to the long-term use of the adsorption device 20, the adsorbent 31 in the bed 30 is hardened and is finely broken by the high-pressure raw material air passing through it to become powder, and this powder is formed into a filter net of the filter unit 40a. 41).

At this time, when the differential pressure between the front end and the rear end of the filter unit 40a becomes more than a certain pressure, the raw material air that has passed through one bed 30 is passed through the other one 52b of the pair of branch pipes 52a and 52b. The upper and lower valves 58b and 59b are gradually opened to provide to the filter unit 40b.

And, as shown in Figure 7, when the pressure in the two filter parts (40a, 40b) is the same, the upper and lower valves (58a, 59a) installed in one branch pipe (52a) are closed, and the discharge valve (71a) ) Opens the backwash valve 61a so that the fluid is supplied to the filter unit 40a through the backwash pipe 60 in the opened state.

The fluid supplied through the backwash pipe 60 is discharged through the plurality of nozzles 43 along the inside of the nozzle rod 42 of the filter unit 40a, and is discharged by the plurality of nozzles 43 The nozzle rod 42 is sprayed onto the filter net 41 while rotating.

The gel powder adhered to the filter net 41 by the fluid sprayed on the filter net 41 of the filter part 40a is removed and then discharged to the outside through the discharge pipe 70a.

When cleaning of the filter net 41 of one filter part 40a is completed, cleaning of the filter net 41 of the other filter part 40b may be performed by the same method.

Therefore, there is no need to stop the air separation facility for replacement or cleaning of the filter disposed inside the bed of the existing adsorption device, and since there is no need to separate the filter from the bed, it is possible to reduce the work time and manpower waste resulting from this productivity. This will be greatly improved.

In the above, specific embodiments have been illustrated and described. However, it is not limited only to the above-described embodiments, and those of ordinary skill in the art to which the invention pertains will be able to perform various changes without departing from the gist of the technical idea of the invention described in the following claims.

10: air separation facility, 20: adsorption device,
30: bed, 31: adsorbent,
40: filter unit, 41: filter net,
42: nozzle rod, 43: nozzle,
50: filter pipe, 51: inlet pipe,
52a, 52b: branch pipe, 53: outlet pipe,
54a, 54b: expansion part, 58: upper valve,
59: lower valve, 60: backwash pipe,
61: back flush valve, 70: discharge pipe.

Claims (11)

As an adsorption device for air separation equipment that separates oxygen, nitrogen, and argon from the air,
A bed with a built-in adsorbent for adsorbing moisture and carbon dioxide from raw air;
A filter pipe connected to the outlet of the bed and having a built-in filter unit for filtering foreign substances of the raw material air passing through the bed;
A backwash pipe connected to the inside of the filter pipe and providing a fluid for washing the filter part; And
And a discharge pipe connected to the filter pipe and for discharging foreign matters separated from the filter part to the outside of the filter pipe. The method of claim 1,
The filter pipe is air separation including an inlet pipe connected to the outlet of the bed, a pair of branch pipes branched from the inlet pipe and each of which the filter unit is embedded, and an outlet pipe where the pair of branch pipes merge Equipment adsorption device. The method of claim 2,
An adsorption device of an air separation facility to which the discharge pipes are connected to each of the pair of branch pipes with discharge valves for controlling the flow of fluid. The method of claim 3,
Each of the pair of branch pipes includes an expansion pipe in which the filter unit is located. The method according to any one of claims 1 to 4,
The filter unit adsorption device of an air separation facility comprising a filter net, a nozzle rod rotatably installed inside the filter net and having a plurality of nozzles receiving fluid from the backwash pipe and spraying the filter net. The method of claim 5,
The plurality of nozzles are adsorption apparatus of an air separation facility in which two adjacent nozzles are arranged to face different directions so as to induce self-rotation of the nozzle rod using the injection force of the injected fluid. The method of claim 4,
An adsorption device of an air separation facility in which an upper valve and a lower valve for controlling the flow of fluid are installed in the branch pipes located above and below the expansion part. The method of claim 7,
An adsorption device of an air separation facility in which a backwash valve for controlling a fluid flow for washing the filter unit is installed in the backwash pipe. The method of claim 8,
An adsorption device of an air separation facility in which an outflow valve for controlling the flow of fluid toward the main heat exchanger of the air separation facility is installed in the outflow pipe. The method of claim 4,
Adsorption device of an air separation facility provided with at least two beds. In the air separation equipment including an air compressor, water washing cooling tower, adsorption device, main heat exchanger, and rectifying tower,
The adsorption device,
A bed connected to an inlet pipe through which compressed air discharged from the flushing cooling tower is provided, and having an adsorbent therein; And,
A pair of branch pipes branched from the inlet pipe connected to the outlet of the bed and each having a built-in filter unit; And,
An outlet pipe to which the pair of branch pipes are joined and to provide compressed air that has passed through the filter unit to the main heat exchanger; And,
Backwashing pipes each connected to the pair of branch pipes and providing a fluid for cleaning to the filter unit; And,
An upper valve and a lower valve installed in the branch pipes located above and below the filter unit; And
Air separation equipment comprising; a pair of discharge pipes each connected to the pair of branch pipes to discharge foreign substances separated from the filter part to the outside when washing the filter part, each discharge valve installed.

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