KR102014459B1 - Device and method for removing moisture of compressed air - Google Patents

Abstract

The method for removing moisture of compressed air may include a drying step of supplying compressed air to one of the first and second dryer tanks filled with an adsorbent to remove moisture from the compressed air, and in one of the dryer tanks. A part of the dry compressed air discharged is drawn out through the distribution pipe and the blower, and a hot air generating step of generating a dry hot air by heating with a heater and supplying the dry hot air to the other one of the first dryer tank and the second dryer tank. And a regenerating step of heating the adsorbent. The drying step, the hot air generating step and the regenerating step are performed at the same time, and the drying step and the regenerating step are repeatedly executed while changing the order of input of the first dryer tank and the second dryer tank.

Description

DEVICE AND METHOD FOR REMOVING MOISTURE OF COMPRESSED AIR

The present invention relates to an apparatus and method for removing moisture from compressed air, and more particularly, to an apparatus and method for removing moisture from compressed air installed between an air compressor and an air tank to remove moisture from the compressed air.

An air compressor sucks and compresses air in the atmosphere to produce high pressure air. Compressed air is supplied to and used in various manufacturing facilities, precision analysis instruments, and robot operation facilities in steel mills.

However, condensate is generated in the process of compressing air, and the generated condensate accumulates downward. Decayed condensate can cause corrosion and failure of the plant and can be oxidized or carbonized in chemical reactions by high temperature frictional heat to produce large amounts of oil mist. In addition, condensate causes water freezing in winter, greatly reducing site productivity and work efficiency.

Accordingly, a water removal device is installed between the air compressor and the air tank. The conventional water removal device may be a freeze drying method of condensing water in compressed air by using an evaporator through which a refrigerant flows. However, the freeze-drying method has a considerable difficulty in completely removing the moisture and condensate in the compressed air.

The present invention is to solve the above-mentioned problems, to provide a condensed water does not occur during the water removal process, and to provide a water removal device and method of compressed air that can remove the water in the compressed air with high efficiency.

The apparatus for removing moisture of compressed air according to an embodiment of the present invention includes a first dryer tank, a second dryer tank, a compressed air supply unit, a discharge pipe, and a regeneration unit. The first dryer tank and the second dryer tank are filled with an adsorbent therein and include a first port located at a lower end and a second port located at an upper end, respectively. The compressed air supply alternately supplies compressed air to the first port of the dryer tanks at least once. The discharge pipe is connected to the second port of the dryer tanks to discharge dry compressed air. The regeneration unit includes a heater, a distribution pipe connected to the discharge pipe to extract a part of the dry compressed air, a blower for supplying the dry compressed air of the distribution pipe to the heater, and a hot air pipe for discharging the dry hot air discharged from the heater. The alternate hot air is alternately supplied at least once to the second port of the dryer tanks in the reverse order of the air supply.

The compressed air supply unit includes an inlet pipe that enters compressed air from the air compressor, and a first branch pipe and a second branch pipe branched from the inlet pipe and connected to the first port of the first dryer tank and the first port of the second dryer tank, respectively. It may include. A first shutoff valve and a second shutoff valve, which are alternately opened to each of the first branch pipe and the second branch pipe, may be installed.

Each of the second port of the first dryer tank and the second port of the second dryer tank may be connected to the discharge pipe by a third branch pipe and a fourth branch pipe, and alternately to each of the third branch pipe and the second branch pipe. The first actuating valve and the second actuating valve which are opened may be installed respectively. The first actuation valve may be opened in conjunction with the first shutoff valve, and the second actuation valve may be opened in conjunction with the second shutoff valve.

The hot air pipe may include a hot air discharge pipe connected to the outlet of the heater, and a sixth branch pipe and a seventh branch pipe branched from the hot air discharge pipe and connected to the third branch pipe and the fourth branch pipe, respectively. Each of the sixth branch pipe and the seventh branch pipe may be provided with a first regeneration valve and a second regeneration valve which are alternately opened. The first regeneration valve may be opened in conjunction with the second shutoff valve, and the second regeneration valve may be opened in conjunction with the first shutoff valve.

The apparatus for removing moisture of compressed air may further include a hot air discharge unit. The hot air discharge unit may include an eighth branch pipe connected to the first branch pipe, a ninth branch pipe connected to the second branch pipe, and a silencer connected to a joining point of the eighth branch pipe and the ninth branch pipe. A first regenerative shutoff valve and a second regenerative shutoff valve which are alternately opened to each of the eighth branch pipe and the ninth branch pipe may be installed. The first regenerative shutoff valve may be opened in conjunction with the second shutoff valve, and the second regenerative shutoff valve may be opened in conjunction with the first regenerative shutoff valve.

In the method for removing moisture from compressed air according to an embodiment of the present invention, a drying step of supplying compressed air to any one of the first and second dryer tanks filled with the adsorbent to remove the moisture in the compressed air And a hot air generating step of extracting a part of the dry compressed air discharged from one of the dryer tanks through a distribution pipe and a blower, and heating it with a heater to generate dry hot air, and another one of the first dryer tank and the second dryer tank. Regeneration step of heating the adsorbent by supplying dry hot air to the dryer tank of the. The drying step, the hot air generating step and the regenerating step are performed at the same time, and the drying step and the regenerating step are repeatedly executed while changing the order of input of the first dryer tank and the second dryer tank.

According to this embodiment, since the compressed air can be continuously dried by using two dryer tanks alternately, the efficiency and productivity of the drying operation can be improved. In addition, by regenerating the adsorbent of the other dryer tank at the same time as the drying of the compressed air, it is possible to prevent the process delay due to the regeneration.

1 is a flow chart of a pneumatic system in which a water removal device according to an embodiment of the present invention is installed.
2 is a perspective view of a water removing apparatus according to an embodiment of the present invention.
3 is a configuration diagram of the water removal device shown in FIG. 2.
4 is a photograph of activated alumina gel.
5 is a flowchart illustrating a method of removing moisture from compressed air according to an embodiment of the present invention.
6 and 7 are configuration diagrams of the water removing apparatus showing the operation process of the second step and the third step shown in FIG.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention.

1 is a flow chart of a pneumatic system in which a water removal device according to an embodiment of the present invention is installed.

Referring to FIG. 1, air in the atmosphere is introduced into the air compressor 20 after the contaminants and the dust are removed through the inlet filter 11. The air compressor 20 may be a turbo type air compressor including an impeller and a diffuser.

The impeller rotates by the power of the main motor and accelerates the intake air to increase the pressure. The accelerated air decelerates under the influence of expansion due to the change of cross-sectional area in the diffuser, increasing the pressure. The diffuser slows down the accelerated air flow and converts the dynamic pressure into a constant pressure.

Compressed air produced by the air compressor 20 flows into the water removing apparatus 100 according to the present embodiment through the silencer 30 and the primary filter unit 12. The primary filter unit 12 filters out contaminants in the compressed air first. The water removal device 100 of the present embodiment is configured with a heater external adsorption type air dryer, and a detailed structure description will be described later.

The compressed air dried by the water removal device 100 is stored in the air tank 40 via the secondary filter unit 13 and supplied to the place of use. The secondary filter unit 13 filters and removes contaminants in the dried compressed air. In Fig. 1, reference numeral 50 denotes an electric chamber panel, 60 denotes a cooling tower, 70 denotes a cooling tower pump, and 80 denotes a flow meter.

2 is a perspective view of a water removal device according to an embodiment of the present invention, Figure 3 is a block diagram of the water removal device shown in FIG.

2 and 3, the water removal device 100 includes a first dryer tank 110 and a second dryer tank 120 filled with an adsorbent therein, a first dryer tank 110 and a second dryer. Hot air is supplied to the compressed air supply unit 130 alternately supplying the compressed air to the tank 120 one by one, and the first dryer tank 110 and the second dryer tank 120 in the reverse order to the compressed air supply unit 130. It includes a regeneration unit 160 to supply alternately once.

The adsorbent may be activated alumina gel having an excellent water adsorption effect. 4 is a photograph of activated alumina gel. Activated alumina gel is present in the form of small grains.

Referring back to Figures 2 and 3, the adsorbent may be made of a material other than the active alumina gel, and commonly in the form of small granules in the interior of the first dryer tank 110 and the second dryer tank 120 Are accepted. The compressed air passes through the granules to remove moisture, and the adsorbent which adsorbs the moisture is regenerated through a heating process.

First ports P11 and P12 through which compressed air flows are formed at lower ends of each of the first dryer tank 110 and the second dryer tank 120. The compressed air supply unit 130 is branched from the inlet pipe 131 through which the compressed air flows from the air compressor 20 and the inlet pipe 131 to each of the first dryer tank 110 and the second dryer tank 120. The connected 1st branch pipe L10 and the 2nd branch pipe L20 are included.

The first shutoff valve V11 and the second shutoff valve V12 are respectively provided in the first branch pipe L10 and the second branch pipe L20. In addition, the first safety valve (V21) and the second safety valve (V22) are installed in each of the first branch pipe (L10) and the second branch pipe (L20). The first silencer 141 and the second silencer 142 are respectively connected to the first safety valve V21 and the second safety valve V22.

The first safety valve (V21) and the second safety valve (V22) are partially opened when the pressure of the compressed air is excessive to relieve the pressure, the first silencer 141 and the second silencer 142 is compressed air Reduce the noise generated when it is discharged.

The compressed air supply unit 130 alternately opens the first shutoff valve V11 and the second shutoff valve V12 one by one to alternate the compressed air to the first dryer tank 110 and the second dryer tank 120 once. To supply. The compressed air introduced into the first dryer tank 110 or the second dryer tank 120 is dried while passing through the adsorbent.

Second ports P21 and P22 through which the compressed compressed air is discharged are formed at upper ends of each of the first dryer tank 110 and the second dryer tank 120. The water removal device 100 includes a compressed air discharge part 150 for supplying the compressed compressed air to the air tank 40.

The compressed air discharge unit 150 is a discharge pipe 151 connected to the secondary filter unit 13 and a branch branched from the discharge pipe 151 and connected to each of the first dryer tank 110 and the second dryer tank 120. It includes a three branch pipe (L30) and the fourth branch pipe (L40).

The third branch pipe L30 is provided with a first operation valve V31 which is a one-way valve that allows only a flow in a direction from the first dryer tank 110 toward the air tank 40. The second branch valve L40 is provided with a second operation valve V32 which is a one-way valve that allows only a flow in a direction from the second dryer tank 120 toward the air tank 40.

The first actuation valve V31 may be opened in conjunction with the first shutoff valve V11, and the second actuation valve V32 may be opened in conjunction with the second shutoff valve V12. The compressed air dried through the first dryer tank 110 or the second dryer tank 120 is transferred to the air tank 40 through the secondary filter unit 13 through the compressed air discharge unit 150.

The regeneration unit 160 alternately supplies hot air to the first dryer tank 110 and the second dryer tank 120 one by one in a reverse order to the compressed air supply unit 130. That is, when compressed air flows into the first dryer tank 110, the regeneration unit 160 supplies hot air to the second dryer tank 120, and when compressed air flows into the second dryer tank 120, The regeneration unit 160 supplies hot air to the first dryer tank 110.

Since the adsorbent adsorbed moisture from the compressed air is reduced in water absorption, the regeneration unit 160 applies hot air to the adsorbent adsorbed moisture in the previous step and heats it. The moisture adsorbed on the adsorbent is then removed by heat to regenerate the adsorbent.

The regeneration unit 160 may include a heater 161, a blower 162 that provides compressed air to the heater 161, and hot air generated by the heater 161. The first dryer tank 110 and the second dryer tank ( 120) includes a hot air pipe to supply to any one. The heater 161 may be an electric heater and is installed outside the first dryer tank 110 and the second dryer tank 120.

The blower 162 may supply a part of the dried compressed air discharged from the first dryer tank 110 or the second dryer tank 120 to the heater 161. To this end, a fifth branch pipe (distribution pipe, L50) is installed between the discharge pipe 151 and the blower 162, and a part of the compressed air discharged to the air tank 40 passes through the fifth branch pipe (L50). Supplied to the inlet of 161. The third shutoff valve V40 is installed in the fifth branch pipe L50.

The hot air pipe is a hot air discharge pipe 163 connected to the outlet of the heater 161 and a sixth branch pipe branched from the hot air discharge pipe 163 and connected to each of the third branch pipe L30 and the fourth branch pipe L40 ( L60) and a seventh branch pipe L70. The sixth branch pipe L60 is connected between the first dryer tank 110 and the first operation valve V31, and the seventh branch pipe L70 is connected to the second dryer tank 120 and the second operation valve V32. ) Is connected.

The sixth branch pipe L60 is provided with a first regeneration valve V51 that is a one-way valve that allows only a flow in a direction from the heater 161 to the third branch pipe L30. The seventh branch pipe L70 is provided with a second regeneration valve V52 that is a one-way valve that allows only a flow in the direction from the heater 161 to the fourth branch pipe L40.

The first regeneration valve V51 may be opened in cooperation with the second shutoff valve V12, and the second regeneration valve V52 may be opened in cooperation with the first shutoff valve V11. The hot air of the heater 161 is introduced into the first dryer tank 110 or the second dryer tank 120 through the hot air pipe and the second ports P21 and P22 to regenerate the adsorbent.

The water removal device 100 includes a hot air discharge unit 170 for exhausting hot air used for regeneration. The hot air discharge unit 170 includes an eighth branch pipe L80 connected to the first branch pipe L10, a ninth branch pipe L90 connected to the second branch pipe L20, and an eighth branch pipe ( L80) and a third silencer 143 connected to the confluence point of the ninth branch pipe (L90).

The eighth branch pipe L80 is connected between the first shutoff valve V11 and the first safety valve V21, and the ninth branch pipe L90 is the second shutoff valve V12 and the second safety valve. It is connected between (V22). A first regenerative shutoff valve V61 and a second regenerative shutoff valve V62 are provided in each of the eighth branch pipe L80 and the ninth branch pipe L90.

The first regenerative shutoff valve V61 may be opened in conjunction with the second shutoff valve V12, and the second regenerative shutoff valve V62 may be opened in conjunction with the first shutoff valve V11. have.

The hot air introduced into the first dryer tank 110 and used for regeneration is discharged to the first branch pipe L10 through the first port P11, and the eighth branch pipe L80 and the third silencer 143 are discharged. Through the outside. The hot air introduced into the second dryer tank 120 and used for regeneration is discharged to the second branch pipe L20 through the first port P12, and the ninth branch pipe L90 and the third silencer 143 are discharged. Through the outside.

The water removal apparatus 100 of this embodiment regenerates the adsorbent in the other dryer tank while drying the compressed air in one dryer tank. Therefore, the moisture in the compressed air can be removed with high efficiency without the process delay caused by the regeneration, and the production quality of the steel mill can be improved.

5 is a flowchart illustrating a method of removing moisture from compressed air according to an embodiment of the present invention.

Referring to FIG. 5, the method of removing moisture of compressed air according to the present embodiment includes a drying step S10, a hot air generating step S20, and a regenerating step S30.

In the drying step (S10), the compressed air is supplied to any one of the first dryer tank and the second dryer tank filled with the adsorbent to remove the moisture in the compressed air. In the hot air generating step (S20), a part of the dry compressed air discharged from any one dryer tank is drawn out through the distribution pipe and the blower, and heated by a heater to become dry hot air. In the regeneration step (S30), dry hot air is supplied to the other one of the first drying tank and the second drying tank to heat and regenerate the adsorbent.

The drying step S10, the hot air generating step S20, and the regenerating step S30 are performed at the same time, and the drying step S10 and the regenerating step S30 are performed by the first dryer tank 110 and the second dryer tank 120. It is executed repeatedly, changing the order of input.

6 and 7 are configuration diagrams of the water removing apparatus showing the operation process of the second step and the third step shown in FIG. 6 illustrates a case where compressed air is introduced into a first dryer tank, and FIG. 7 illustrates a case where compressed air is introduced into a second dryer tank.

Referring to FIG. 6, the first shutoff valve V11 and the first operation valve V31 are open, and the second shutoff valve V12 and the second operation valve V32 are closed. The compressed air of the inflow pipe 131 is introduced into the first dryer tank 110 through the first branch pipe L10 and dried while passing through the adsorbent. The dried compressed air is transferred to the air tank 40 through the third branch pipe L30 and the discharge pipe 151.

The third shutoff valve V40 is in an open state, and a part of the compressed air flowing through the discharge pipe 151 is sucked by the blower 162 and supplied to the inlet of the heater 161 through the fifth branch pipe L50. . The second regeneration valve V52 is in an open state, and the first regeneration valve V51 is in a closed state. The hot air of the heater 161 flows into the second dryer tank 120 through the hot air discharge pipe 163, the seventh branch pipe L70, and the fourth branch pipe L40 to regenerate the adsorbent.

The second regeneration shutoff valve V62 is in an open state, and the second shutoff valve V12 is in a closed state. The hot air discharged from the second dryer tank 120 moves to the third silencer 143 through a part of the second branch pipe L20 and the ninth branch pipe L90, and passes through the third silencer 143. Emitted to the outside. The operating state shown in FIG. 6 can be maintained for approximately two hours.

Referring to FIG. 7, the second shutoff valve V12 and the second operation valve V32 are open, and the first shutoff valve V11 and the first operation valve V31 are closed. The compressed air of the inflow pipe 131 is introduced into the second dryer tank 120 through the second branch pipe L20 and dried while passing through the adsorbent. The dried compressed air is transferred to the air tank 40 through the fourth branch pipe L40 and the discharge pipe 151.

The third shutoff valve V40 is in an open state, and a part of the compressed air flowing through the discharge pipe 151 is sucked by the blower 162 and supplied to the inlet of the heater 161 through the fifth branch pipe L50. . The first regeneration valve V51 is in an open state, and the second regeneration valve V52 is in a closed state. The hot air of the heater 161 flows into the first dryer tank 110 through the hot air discharge pipe 163, the sixth branch pipe L60, and the third branch pipe L30 to regenerate the adsorbent.

The first regenerative shutoff valve V61 is in an open state, and the first shutoff valve V11 is in a closed state. The hot air discharged from the first dryer tank 110 moves to the third silencer 143 through a part of the first branch pipe L10 and the eighth branch pipe L80, and passes through the third silencer 143. Emitted to the outside. The operating state shown in FIG. 7 can be maintained for approximately two hours.

According to the drying method described above, it is possible to continuously dry the compressed air by using two dryer tanks alternately to increase the efficiency and productivity of the drying operation. In addition, by regenerating the adsorbent of the other dryer tank at the same time as the drying of the compressed air, it is possible to prevent the process delay due to the regeneration.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications and changes can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. Naturally, it belongs to the range of.

11: Inlet filter 12: Primary filter part
13: secondary filter 20: air compressor
30: silencer 40: air tank
100: moisture removal device 110: first dryer tank
120: second dryer tank 130: compressed air supply
141: first silencer 142: second silencer
143: third silencer 150: compressed air outlet
160: regeneration unit 161: heater
162: blower 163: hot air discharge pipe

Claims (9)

A first dryer tank and a second dryer tank each having an adsorbent filled therein and including a first port positioned at a lower end and a second port positioned at an upper end thereof;
An inlet pipe into which compressed air is introduced from an air compressor, and a first branch pipe and a second branch pipe branched from the inlet pipe and connected to the first port of the dryer tanks, respectively; A compressed air supply unit alternately supplying compressed air to the port at least once;
A discharge pipe connected to the second ports of the dryer tanks to discharge dry compressed air; And
A distribution pipe connected to the discharge pipe, a heater installed in the distribution pipe, a blower connected to the distribution pipe in front of the heater and sucking a part of dry compressed air flowing through the discharge pipe to the heater; And a hot air pipe for discharging dry hot air from the regenerator, and alternately supplying dry hot air to the second port of the dryer tanks at least once in a reverse order to the compressed air supply unit.
Including,
When the first safety valve and the first silencer is connected to the first branch pipe, and the second safety valve and the second silencer are installed to the second branch pipe, the first safety valve when the pressure of the compressed air is excessive. Or the second safety valve is partially opened to relieve pressure, and the first silencer or the second silencer reduces noise generated when the compressed air is discharged. The method of claim 1,
The compressed air supply unit,
And a first shutoff valve and a second shutoff valve which are installed in each of the first branch pipe and the second branch pipe, and alternately open to each other. The method of claim 2,
Each of the second port of the first dryer tank and the second port of the second dryer tank is connected to the discharge pipe by a third branch pipe and a fourth branch pipe;
And a first operation valve and a second operation valve which are alternately opened to each of the third branch pipe and the fourth branch pipe, respectively. The method of claim 3,
The first actuating valve is opened in conjunction with the first shutoff valve,
And the second actuating valve is opened in cooperation with the second shutoff valve. The method of claim 3,
The hot air pipe,
A hot air discharge pipe connected to an outlet of the heater;
A sixth branch pipe and a seventh branch pipe branched from the hot air discharge pipe and connected to the third branch pipe and the fourth branch pipe, respectively.
Including,
And a first regeneration valve and a second regeneration valve which are alternately opened to each of the sixth branch pipe and the seventh branch pipe, respectively. The method of claim 5,
The first regeneration valve is opened in cooperation with the second shutoff valve,
And the second regeneration valve is opened in cooperation with the first shutoff valve. The method of claim 2,
An eighth branch pipe connected to the first branch pipe;
A ninth branch pipe connected to the second branch pipe; And
A third silencer connected to a confluence point of the eighth branch pipe and the ninth branch pipe;
Further comprising a hot air discharge unit comprising a,
And a first regeneration shutoff valve and a second regeneration shutoff valve, which are alternately opened to each of the eighth branch pipe and the ninth branch pipe, respectively. The method of claim 7, wherein
The first regenerative shutoff valve is opened in cooperation with the second shutoff valve,
And the second regeneration shutoff valve is opened in cooperation with the first shutoff valve. In the water removal method of the compressed air using the water removal device of claim 1,
A drying step of supplying compressed air to any one of the first dryer tank and the second dryer tank filled with the adsorbent to remove moisture from the compressed air;
A hot air generating step of sucking a part of the dry compressed air discharged from the one dryer tank by the blower, drawing it out to the distribution pipe, and heating the heater to generate dry hot air; And
A regeneration step of heating the adsorbent by supplying dry hot air to the other one of the first dryer tank and the second dryer tank;
The drying step, the hot air generating step and the regeneration step are performed at the same time, and the drying step and the regeneration step are repeatedly performed while changing the order of input of the first dryer tank and the second dryer tank.
In the drying step, when the pressure of the compressed air is excessive, the first safety valve or the second safety valve is partially opened to relieve the pressure, and noise generated when the first silencer or the second silencer is discharged from the compressed air. To remove moisture from the compressed air.

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