KR20130052810A - Adsorption type drier for compressed air using ejector - Google Patents

Abstract

PURPOSE: An adsorption type drier for compressed air using an ejector is provided to remarkably reduce energy by reducing the consumption of dried and compressed air, and to simplify the structure of the drier using the ejector. CONSTITUTION: An adsorption type drier for compressed air includes two left and right drying chambers(1, 1') filled with an absorber, an injection line, a discharging line, a chamber decompression line, and a regeneration cooling line. The injection line selectively injects compressed air into the drying chambers. The discharging line discharges the dried compressed air from the drying chambers. The chamber decompression line decreases the internal pressure inside the drying chambers. The regeneration cooling line inserts external air and the dried compressed air into the drying chambers for regenerating the absorber, or cools the drying chambers. The external air for the regeneration cooling line is inhaled by an ejector(5).

Description

Adsorption Type Drier For Compressed Air Using Ejector}

The present invention relates to an adsorption drying apparatus for compressed air for adsorption and removal of moisture contained in high pressure air used in pneumatic equipment, and more particularly, a predetermined amount of compressed air used for regeneration of an adsorbent for adsorption and removal of moisture. The present invention relates to an adsorption drying apparatus for compressed air using an ejector that replaces external air sucked through an ejector to reduce energy required for regeneration of the adsorbent.

In general, compressed air discharged from an air compressor is concentrated and mixed with moisture, dust, pollutants, and lubricating oil in the air. Therefore, if the compressed air in such a state is used in a compressed air system, the piping It causes various problems such as corrosion.

Here, solids such as dust, pollutants and lubricants are completely removed by the filter, but moisture is not. To this end, the compressed air system is constructed by installing a drying device for compressed air to remove moisture contained in the compressed air at the discharge port side of the air compressor.

Such a drying device for compressed air is classified into a freezing type, an absorption type and an adsorption type according to a method of removing moisture in the compressed air, and the freezing type condenses moisture by lowering the temperature to dew point (dew point) by exchanging the compressed air with a refrigerant or the like. To remove it. The absorption type is a method of absorbing and removing moisture by using a liquid water-soluble absorbent such as lithium chloride or lithium bromide.

Adsorption is a method of removing moisture by introducing compressed air into a drying chamber filled with an adsorbent such as silica gel and activated alumina, which adsorbs moisture.

The compressed air adsorption drying apparatus includes two left and right side drying chambers filled with an adsorbent; An injection line configured to selectively inject compressed air into two drying chambers; A discharge line configured to discharge the compressed air dried through the drying chamber; A chamber pressure reducing line configured to reduce the internal pressure of the drying chamber; It is composed of a regeneration cooling line configured to regenerate the adsorbent or cool the drying chamber while injecting external air and compressed air dried in the drying chamber.

Therefore, in normal operation, the compressed air is injected into two drying chambers at the same time through an injection line and dried, and then the dried compressed air is discharged through the discharge line.

During regeneration, compressed air is injected into only one of the two drying chambers through the injection line, and then another drying chamber into which the compressed air is not injected is operated in order to regenerate the adsorbent by operating the chamber decompression line and the regeneration cooling line. do.

In addition, when the regeneration of the drying chamber is completed, it is possible to continuously dry the compressed air by repeating the above process again.

However, the above-described conventional adsorption drying apparatus for compressed air has a problem in that it is not possible to construct the drying apparatus compactly as the structure is complicated by using a blow or a fan to suck external air when configuring the regenerative cooling line. there was.

In addition, there is a problem that energy saving is not effective because additional power is input to use a blow or a fan.

Accordingly, an object of the present invention is to provide an adsorptive drying apparatus for compressed air using an ejector, which is capable of compactly configuring a drying apparatus while simultaneously reducing energy used in regeneration of an adsorbent filled in a drying chamber.

The present invention has been invented to solve the above problems, two left and right side drying chambers filled with an adsorbent; An injection line configured to selectively inject compressed air into two drying chambers; A discharge line configured to discharge the compressed air dried through the drying chamber; A chamber pressure reducing line configured to reduce the internal pressure of the drying chamber; In the adsorption drying apparatus for compressed air composed of a regenerative cooling line configured to regenerate an adsorbent or cool the drying chamber while injecting external air and dried compressed air into a drying chamber, the external air used in the regenerative cooling line is ejector. It provides an adsorption drying apparatus for compressed air using an ejector, characterized in that configured to be sucked through.

The present invention can significantly reduce energy by reducing the consumption of dried compressed air by regenerating the adsorbent by using an appropriate amount of mixed air and dried compressed air through an ejector, and the structure of the drying apparatus is simplified through the ejector. Therefore, the drying device can be compactly manufactured, which makes manufacturing simple and reduces the manufacturing cost. Also, by using only the energy of the dried compressed air to suck the outside air, the outside air is supplied from the outside as before. It is effective to save energy more effectively than the structure that was inhaled.

1 is a device diagram clearly indicated by the thick solid line regeneration cooling line constituting the adsorption-type drying apparatus for compressed air of the present invention.
Figure 2 is a device diagram clearly indicated by the thick solid line injection line constituting the adsorption drying apparatus for compressed air of the present invention.
Figure 3 is a device diagram clearly showing the discharge line constituting the adsorptive drying device for compressed air of the present invention in a thick solid line.
Figure 4 is a device diagram clearly showing the reduced pressure line forming a thick solid line constituting the adsorption drying apparatus for compressed air of the present invention.

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

Adsorption drying apparatus 100 for compressed air using the ejector of the present invention includes two left and right side drying chambers (1) (1`) filled with an adsorbent; An injection line configured to selectively inject compressed air into the two drying chambers 1 and 1 '; A discharge line configured to discharge the compressed air dried through the drying chamber; A chamber pressure reducing line configured to reduce the internal pressure of the drying chamber; It is composed of a regeneration cooling line configured to regenerate the adsorbent or cool the drying chamber while injecting external air and compressed air dried in the drying chamber.

Here, as shown in FIG. 1, the regeneration cooling line has a bypass tube 2 connected to an upper end of each drying chamber 1 and 1 ′, one end of which is connected to the discharge line and the other end of which is branched; A first opening / closing valve (3) installed at the inflow side of the bypass pipe (2) for introducing or blocking the compressed air dried in the bypass pipe (2); It is installed in the bypass pipe (2) between the first opening and closing valve (3) and the drying chamber (1), and dried by automatically sucking the outside air to the inlet side of the outside air in which the air filter (4) is installed by the dried compressed air An ejector 5 which mixes and discharges compressed air and external air into the bypass pipe 2; A heater (6) installed in the discharge side bypass pipe (2) of the ejector (5) to heat mixed air mixed with dried compressed air and external air; It is installed in the lower part of the drying chamber (1) (1`) to discharge the mixed air introduced into the drying chamber (1) (1`) through the bypass pipe (2), the second opening and closing valve (7) on the discharge side A mixed air discharge pipe 8 (8 ′) provided with 7 ′; Sensors 9 (9 ') installed in the drying chamber 1 to operate the heater 6; It is provided on the inlet side of the ejector 5 and consists of a third open / close valve 10 for manipulating the inflow of external air.

Here, the ejector 5 is a device for automatically inhaling the second fluid (external air) through the first fluid (compressed air) that is ejected from the highway and mixing (mixed air) the first fluid and the second fluid. .

As shown in FIG. 2, one end of the injection line is connected to the air compressor, and the other end of the injection line is connected to the lower portion of each drying chamber 1, 1 ′, so that the inside of the drying chamber 1, 1 ′ is connected. An injection tube 11 for injecting compressed air into the furnace; It is composed of a pair of fourth open / close valves 12 and 12 'installed at the other end of the injection pipe 11 to selectively inject compressed air into the drying chamber 1, 1'.

As shown in FIG. 3, the discharge line is branched at one end and connected to each drying chamber 1, 1 ′, respectively, the other end is connected to one, and bypassed at the other end through which the dried compressed air is discharged. It consists of a dry air discharge pipe 13 connected to the inlet side of the pipe (2).

As shown in FIG. 4, the chamber pressure reducing line is installed in the mixed air discharge pipe 8, 8 ′ to reduce the pressure inside the drying chamber 1, 1 ′ 14. It consists of.

In the bypass pipe 2 and the dry air discharge pipe 13, a plurality of check valves 15 are provided in each drying chamber to prevent backflow of the compressed air and the mixed air dried by the drying chambers 1 and 1 ′. (1) (1 ') is provided corresponding to the position.

The present invention configured as described above is used for the purpose of removing moisture contained in the compressed air.

In particular, the present invention is characterized by simplifying the structure of the drying apparatus 100 while reducing the energy required during regeneration of the adsorbent filled in the drying chamber (1) (1`).

This will be described in detail through the drying process of the compressed air as follows.

First, the compressed air compressed by the compressor is introduced into the drying chamber 1 (1`) through the injection pipe 11 of the injection line.

At this time, the injection pipe 11 is provided with a pair of fourth open / close valves 12 and 12 'so as to allow compressed air to flow into only one of the pair of drying chambers 1 and 1'.

That is, when the compressed air flows into the drying chamber 1` positioned on the left side when the fourth open / close valve 12` positioned on the left side is opened on the basis of the drawings, the fourth opening / closing valve side of the drying chamber 1 located on the right side ( As 12) is closed, the right side of the branched injection tube 11 is blocked to prevent the compressed air from flowing into the drying chamber 1 located on the right side.

Therefore, the compressed air flows into only the drying chamber 1` located on the left side and is dried.

In addition, the second opening / closing valve 7` and the pressure reducing valve 14` constituted in the drying chamber 1` located on the left side are closed, and compressed air does not leak through the mixed air discharge pipe 8`.

The compressed air introduced into the drying chamber 1` located on the left side is contacted with the adsorbent filled in the drying chamber 1`, and the water is removed to be discharged through the dry air discharge pipe 13 of the discharge line.

At this time, the plurality of check valve 15 is bypass pipe (2) to prevent the dried compressed air from flowing back into the bypass pipe from the dry air discharge pipe (13) integrated with the bypass pipe (2) And dry air discharge pipes 13, respectively.

In addition, the right drying chamber 1, which is blocked from injecting compressed air, operates the pressure reducing valve 14 constituting the chamber decompression line to regenerate the adsorbent, and pressurizes the pressure inside the drying chamber 1 to the mixed air discharge pipe 8. It is discharged through the drop.

When the pressure in the right drying chamber 1 decreases below a certain pressure, the heater 6 of the regenerative cooling line is operated, and at the same time, the first open / close valve 3 and the second open / close valve 7 open to dry the compressed air. Is introduced into the bypass pipe (2) from the dry air discharge pipe (13).

The drying chamber (1) located on the left side is a state in which the compressed air injected from the injection line is continuously discharged through the discharge line while continuously drying.

When compressed air dried in the bypass pipe 2 is introduced as described above, the compressed air flows along the bypass pipe 2 to the drying chamber 1 located on the right side.

At this time, the dried compressed air moves at high speed along the bypass pipe 2 as it is a high pressure, and sucks the outside air while passing through the ejector 5 installed in the bypass pipe 2.

The sucked external air has the same pressure and speed as the dried compressed air, and is mixed with the dried compressed air to be mixed air, and the mixed air is heated to a high temperature while passing through the heater (6) and dried on the right side. Flows into the chamber (1).

Here, as the pressure of the dried compressed air flowing through the dry air discharge pipe 13 is lower than the pressure of the mixed air flowing along the bypass pipe 2, the closing of the check valve 15 is maintained firmly, so that the dry air discharge pipe 13 is maintained. This prevents backflow of the mixed air.

In addition, the ejector 5 may suck external air without energy supplied from the outside in addition to the kinetic energy of the dried compressed air. Energy can be saved effectively.

In addition, when the equipment such as a fan is installed to suck external air as in the related art, the volume of the drying apparatus increases, but the compact structure of the drying apparatus 100 is achieved by using the ejector 5 which is smaller than the fan and has a simple structure. This becomes possible.

In addition to this, the structure of the drying apparatus 100 is simplified, so that the risk of malfunction is eliminated, maintenance and repair can be simplified, and manufacturing cost can be reduced.

In addition, the filter 4 is installed at the inflow side of the ejector 5 to remove the contaminants such as dust contained in the external air and flow into the bypass pipe 2.

Referring back to the operation of the drying apparatus 100 as follows.

The high temperature mixed air introduced into the drying chamber 1 heats the adsorbent to separate water from the adsorbent, and discharges the separated water from the inside of the drying chamber 1 through the mixed air discharge pipe 8.

Then, when the temperature of the drying chamber 1 reaches the thermal break point, the sensor 9 installed in the drying chamber 1 detects this to stop the operation of the heater 6. For reference, the operation of the heater 6 at the time of regenerating the adsorbent of the drying chamber 1` located on the left side is performed by the sensor 9` configured on the left side.

When the operation of the heater 6 is stopped in this way, the third open / close valve 10 installed at the suction side of the ejector 5 is closed to block external air, and the dried compressed air flowing into the bypass pipe 2 is closed. After cooling down to atmospheric pressure flows into the drying chamber (1) located on the right side to perform the cooling, it is discharged through the second opening and closing valve (7) installed in the mixed air discharge pipe (8).

When the cooling of the drying chamber 1 located on the right side is completed through the above process, the first opening / closing valve 3, the second opening / closing valve 7, and the pressure reducing valve 14 are closed, and the inside of the drying chamber 1 is closed. As the pressure rises, the compressed air is ready for drying.

And the regeneration of the adsorbent of the drying chamber (1`) located on the left side is made of the same process as the drying chamber (1) located on the right side as described above, as shown in the figure the configuration is symmetrically described It will be omitted.

Therefore, the adsorption drying apparatus 100 for compressed air using the ejector of the present invention regenerates the adsorbent using an appropriate amount of mixed air and dried compressed air through the ejector 5, thereby reducing energy consumption of the dried compressed air. Can be drastically reduced.

In addition, as the structure of the drying apparatus 100 is simplified through the ejector 5, the drying apparatus 100 may be compactly configured, the manufacturing may be simplified, and the manufacturing cost may be reduced.

In addition, by using only the energy of the dried compressed air to inhale the outside air can receive energy from the outside as in the prior art can reduce the energy more effectively than the structure to suck the outside air.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and in the technical field to which the present invention pertains that substitutions, modifications, and conversions can be made without departing from the spirit of the present invention. It will be evident to those who have knowledge of.

1, 1`: drying chamber 2: bypass tube
3: first open / close valve 4: filter
5: ejector 6: heater
7, 7`: 2nd open / close valve 8, 8`: mixed air discharge pipe
9, 9`: sensor 10: third open / close valve
11: Injection pipe 12, 12`: 4th opening and closing valve
13: dry air discharge pipe 14, 14`: pressure reducing valve
15: check valve 100: drying device

Claims (2)

Two left and right side drying chambers 1 '1' filled with an adsorbent; An injection line configured to selectively inject compressed air into the two drying chambers 1; A discharge line configured to discharge the compressed air dried through the drying chamber; A chamber pressure reducing line configured to reduce the internal pressure of the drying chamber; In the adsorption drying apparatus for compressed air composed of a regenerative cooling line configured to regenerate an adsorbent or cool the drying chamber while injecting external air and dried compressed air into a drying chamber, the external air used in the regenerative cooling line is ejector. Adsorption drying apparatus for compressed air using an ejector, characterized in that the suction through (5).
According to claim 1, wherein the regeneration cooling line has a bypass pipe (2) connected to the upper end of each drying chamber (1) (1`), one end is in communication with the discharge line, the other end is branched; A first opening / closing valve (3) installed at the inflow side of the bypass pipe (2) for introducing or blocking the compressed air dried in the bypass pipe (2); It is installed in the bypass pipe (2) between the first opening and closing valve (3) and the drying chamber (1), and dried by automatically sucking the outside air to the inlet side of the outside air in which the air filter (4) is installed by the dried compressed air An ejector 5 which mixes and discharges compressed air and external air into the bypass pipe 2; A heater (6) installed in the discharge side bypass pipe (2) of the ejector (5) to heat mixed air mixed with dried compressed air and external air; It is installed in the lower part of the drying chamber (1) (1`) to discharge the mixed air introduced into the drying chamber (1) (1`) through the bypass pipe (2), the second opening and closing valve (7) on the discharge side A mixed air discharge pipe 8 (8 ′) provided with 7 ′; Sensors 9 (9 ') installed in the drying chamber 1 to operate the heater 6; Adsorption drying apparatus for compressed air using an ejector which is installed on the inlet side of the ejector (5) and composed of a third open / close valve (10) for controlling inflow of external air.

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