KR101687360B1 - Air generating system for absorption type dryer - Google Patents

Abstract

The present invention relates to a regeneration air supply device for an adsorptive dryer, comprising: a first adsorption tower for adsorbing oxygen through a filled adsorbent by receiving high pressure compressed air from a high pressure compressor; And a low-pressure air supply unit for supplying low-pressure compressed air to the second adsorption tower.
Unlike the prior art, a separate facility for depressurization is not needed compared to the existing system in which high pressure compressed air is supplied to the adsorption tower for regeneration after decompression by separately supplying low pressure compressed air to the adsorption towers for regeneration, It is possible to reduce the operating cost by preventing the loss of power due to the loss of air, and it is possible to transfer the high-pressure compressed air to the working site as much as possible, thereby reducing the capacity of the high-pressure compressor.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an air-

The present invention relates to a regeneration air supply apparatus for an adsorptive dryer, and more particularly, to a regeneration air supply apparatus for a regeneration air supply apparatus for regenerating a regeneration air supplied to a regeneration adsorption tower , The loss of power due to the loss of high-pressure compressed air is prevented, and the recovery of the adsorptive dryer capable of reducing the capacity of the high-pressure compressor by transferring the high-pressure compressed air to the working site as much as possible Air supply device.

Generally, the compressed air drying device that removes the moisture contained in the air is widely used in various automation equipment requiring dry air, a production line of a semiconductor manufacturing process, a coating line, a chemical process causing a chemical reaction during moisture contact, .

Particularly, when the compressed air drying apparatus is roughly divided, the temperature of the compressed air using the refrigeration compressor is lowered, and then the moisture contained in the air is condensed to dehumidify, and then the humidifier is passed through the tank filled with the dehumidifying agent, There are adsorption equipments which produce dry air by adsorbing to many micropores of the desiccant.

The adsorption drying apparatus is classified into a non-heating type requiring no heat source and a heater type requiring a heat source according to the regeneration method. In the non-heating type, there is a disadvantage that the energy consumption is large due to a large amount of recycled air because there is no heat source, and the heater type has a merit that the energy consumption is less than that of the non-heating type because the recycling air consumption is small.

The compressed air drying apparatus is proposed in Korean Patent Laid-Open No. 10-2014-0107925 (titled "Method and Apparatus for Cooling Compressed Air in a Recycling Tank Using Compressed Dry Air").

Conventional compressed air drying apparatuses supply compressed air of a high pressure supplied from a compressor to a regeneration air while being reduced in pressure by a suction type dryer, so that unnecessary power is used, thereby increasing power consumption.

Therefore, there is a need to improve this.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide an adsorption tower for regeneration, in which a low pressure compressed air is separately supplied to an adsorption tower for regeneration, And it is an object of the present invention to provide a regeneration air supply device of a suction type dryer for preventing a loss of power due to loss of high-pressure compressed air.

In addition, since the present invention does not branch the high-pressure compressed air to the adsorption towers for regeneration, it is possible to transfer as much high-pressure compressed air as possible to the work site, thereby reducing the capacity of the high- The purpose of the device is to provide.

The regeneration air supply device of the adsorptive dryer according to the present invention comprises: a high-pressure compressor for producing high-pressure compressed air; And a suction type dryer that receives compressed air at a high pressure from the high pressure compressor and dries the compressed air, wherein the adsorption type dryer includes a first adsorption unit that receives high pressure compressed air from the high pressure compressor and adsorbs oxygen through a packed adsorbent, Adsorption towers; A second adsorption tower for guiding the moisture contained in the adsorbent to the atmosphere using low pressure compressed air; And a low-pressure air supply unit for supplying low-pressure compressed air to the second adsorption tower.

The low pressure air supply unit includes a low pressure air supply line connected to the second adsorption tower; And a low pressure compressor which generates low pressure compressed air and supplies the compressed air to the second adsorption tower through the low pressure air supply line.

Pressure compressed air generated in the high pressure compressor can be conveyed through a high pressure air supply line and dried high pressure air passing through the first adsorption tower can be conveyed through a conveyance line, Pressure air can be intermittently supplied to the second adsorption tower, and the branch line can connect the low-pressure air supply unit.

The low pressure compressed air or the high pressure compressed air conveyed through the branch line can be heated by the heater and then supplied to the second adsorption tower.

As described above, the regeneration air supply device of the adsorptive dryer according to the present invention differs from the prior art in that a low pressure compressed air is separately supplied to the adsorption tower for regeneration, thereby supplying high pressure compressed air to the adsorption tower for regeneration after decompression It is possible to reduce the operating cost by preventing the loss of the power due to the loss of the high-pressure compressed air.

In addition, since the high-pressure compressed air is not branched to the adsorption towers for regeneration, the maximum amount of high-pressure compressed air can be transferred to the worksite, thereby reducing the capacity of the high-pressure compressor.

FIG. 1 is a configuration diagram of a regeneration air supply device of a suction type dryer according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an embodiment of a regeneration air supply apparatus for a suction type dryer according to the present invention will be described with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

FIG. 1 is a configuration diagram of a regeneration air supply device of a suction type dryer according to an embodiment of the present invention.

Referring to FIG. 1, a regeneration air supply apparatus for a desiccant dryer according to an embodiment of the present invention includes a high pressure compressor 10 and a desiccant dryer 100.

The adsorptive dryer 100 includes a first adsorption tower 110, a second adsorption tower 120, and a low-pressure air supply unit 130.

In particular, the high-pressure compressor 10 produces high-pressure compressed air. The high-pressure compressed air produced from the high-pressure compressor 10 is supplied to the first adsorption tower 110 along the high-pressure air supply line 20.

The cooler 30, the receiver tank 40, the first filter 50, the cooling dryer 60 and the second filter 70 are arranged in the order of the adsorption type dryer 100 in the high pressure air supply line 20 .

Thus, the high-pressure compressed air is cooled to a temperature near room temperature through a cooler 30, and moisture is removed through a receiver tank 40. The receiver tank 40 temporarily stores high-pressure compressed air in addition to filtering moisture, and provides buffering effect in supplying compressed air.

Further, the high-pressure compressed air that has been compressed and passed through the cooler 30 and the receiver tank 40 is filtered through oil and contaminants through the first filter 50. The high pressure compressed air is then passed through a cooling dryer 60. The high-pressure compressed air is subjected to heat exchange with a heat exchanger (not shown) in the cooling dryer 60 to remove moisture and lower the temperature.

Thereafter, the high-pressure compressed air passes through the second filter 70, and moisture and contaminants are filtered once more.

Then, the sufficiently filtered high-pressure compressed air is sent to the adsorptive dryer 100.

At this time, the adsorptive dryer 100 serves to dry compressed air by receiving high-pressure compressed air from the high-pressure compressor 10. The adsorptive dryer 100 includes a first adsorption tower 110 having a function of adsorbing oxygen from high-pressure compressed air, And a second adsorption tower (120) serving as a regeneration function.

In particular, the first adsorption tower 110 and the second adsorption tower 120 are formed of at least one pair, and each one is provided for convenience.

In addition, the first adsorption tower 110 and the second adsorption tower 120 can perform the adsorption function and the regeneration function alternately.

For convenience, it is assumed that the first adsorption tower 110 performs an adsorption function and the second adsorption tower 120 performs a regeneration function.

More specifically, the first adsorption tower 110 receives high pressure compressed air from the high-pressure compressor 10 and adsorbs oxygen through a packed adsorbent (not shown). Thus, the high pressure compressed air passes through the first adsorption tower 110 and loses oxygen. Thereafter, the high pressure compressed air is conveyed along the transfer line 140 to the set position of the work site.

The second adsorption tower 120 regenerates the adsorbent by discharging the moisture contained in the adsorbent (not shown) to the atmosphere by using the compressed air at low pressure. The low-pressure compressed air having the regenerating function is exhausted.

In particular, the high-pressure air supply line 20 branches to a first distribution line 112 and a second distribution line 122. The first distribution line 112 is connected to the first adsorption tower 110 and the second distribution line 122 is connected to the second adsorption tower 120. In addition, the first distribution line 112 has a first intermittent valve 114 for interrupting the flow of the high-pressure compressed air, and the second distribution line 122 has a second intermittent valve 124.

More specifically, it is assumed that the first adsorption tower 110 and the second adsorption tower 120 operate in pairs. Oxygen is adsorbed in the first adsorption tower 110 and the second adsorption tower 120, which form a pair, and nitrogen of high purity is produced.

In addition, the low-pressure air supply unit 130 directly supplies low-pressure compressed air to the second adsorption tower 120.

At this time, the second adsorption tower 120 can be supplied together with the low-pressure compressed air by the low-pressure air supply unit 130 after a part of the high-pressure compressed air is decompressed for regeneration.

Here, the low-pressure air supply unit 130 includes a low-pressure air supply line 132 and a low-pressure compressor 134.

The low pressure air supply line 132 is connected to the second adsorption tower 120 and the low pressure compressor 134 generates and supplies low pressure compressed air to the low pressure air supply line 132. Thus, the low-pressure compressed air generated from the low-pressure compressor 134 is directly supplied to the second adsorption tower 120.

Pressure compressed air that has passed through the second adsorption tower 120 is exhaust-guided along the second distribution pipe and the exhaust line 126. At this time, the exhaust line 126 has an exhaust valve 128 for interrupting the flow of the low-pressure compressed air.

In addition, the low-pressure air supply line 132 may be provided with a low-pressure manual intermittent valve 136 capable of manually interrupting the flow of the low-pressure compressed air. Further, the low-pressure air supply line 132 may be provided with a low-pressure automatic intermittent valve 138 that can automatically control the flow of the low-pressure compressed air. Of course, the low-pressure air supply line 132 may be provided with at least one of the low-pressure manual intermittent valve 136 and the low-pressure automatic intermittent valve 138.

Meanwhile, the branch line 150 branched from the transfer line 140 is provided with a group of high-pressure intermittent valves 160 for controlling the supply of high-pressure compressed air to the second adsorption tower 120 or controlling the flow rate thereof.

The high pressure valve unit group 160 includes a high pressure manual valve 162 that can supply the depressurized high pressure compressed air after drying in the event of failure of the low pressure compressor 134 to the second adsorption tower 120 manually. The high pressure valve group 160 includes a high pressure automatic valve 164 capable of automatically supplying the decompressed high pressure compressed air to the second adsorption tower 120.

It is assumed that the high pressure automatic intermittent valve 162 and the high pressure automatic intermittent valve 164 are provided at the same time and the high pressure automatic intermittent valve 164 is disposed adjacent to the second adsorption tower 120 for convenience.

At this time, the low-pressure air supply line 132 of the low-pressure air supply unit 130 is connected to the branch line 150.

In addition, the low-pressure compressed air or the high-pressure compressed air conveyed through the branch line 150 can be heated by the heater 170 and then supplied to the second adsorption tower 120. This is because the compressed air is supplied to the second adsorption tower 120 in a heated state to improve the regeneration ability.

Particularly, the low-pressure air supply line 132 is connected to the corresponding branch line 150 between the heater 170 and the high-pressure automatic valve 164.

When the low-pressure compressor 134 is operated after the low-pressure manual intermittent valve 136 and the low-pressure automatic intermittent valve 138 are opened with the high-pressure manual intermittent valve 162 and the high-pressure automatic intermittent valve 164 closed, And the low pressure compressed air is directly supplied to the second adsorption tower 120. As a result, all the high-pressure compressed air can be transferred to the worksite.

Pressure manual intermittent valve 136 or the low-pressure automatic intermittent valve 138 is closed and the high-pressure manual intermittent valve 162 and the high-pressure automatic intermittent valve 164 are closed Is opened.

As a result, a portion of the high-pressure compressed air is supplied to the second adsorption tower 120.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand. Accordingly, the true scope of the present invention should be determined by the following claims.

10: high pressure compressor 20: high pressure air supply line
30: cooler 40: receiver tank
50: first filter 60: cooling dryer
70: second filter 100: adsorptive dryer
110: first adsorption tower 120: second adsorption tower
130: Low pressure air supply unit 132: Low pressure air supply line
134: Low pressure compressor 136: Low pressure manual valve
138: Low-pressure automatic regulator valve 140: Transfer line
150: branch line 160: high-pressure valve group
162: High-pressure manual intermittent valve 164: High-pressure automatic intermittent valve
170: heater

Claims (4)

A high-pressure compressor for producing high-pressure compressed air; And a desiccant dryer for drying the compressed air,
The adsorptive dryer includes a first adsorption tower for receiving compressed air of high pressure from the high pressure compressor and adsorbing oxygen through a filled adsorbent; And a second adsorption tower for discharging the moisture contained in the adsorbent to the atmosphere,
The adsorptive dryer includes a low-pressure air supply unit,
The low-pressure air supply unit includes a low-pressure compressor that produces low-pressure compressed air that is lower in pressure than compressed air produced through the high-pressure compressor. The low-pressure air supply unit is connected to a part of the high-pressure compressed air passing through the first adsorption tower Wherein the first adsorption tower is directly fed to the second adsorption tower to increase the amount of the high-pressure compressed air that can be supplied to the work site after passing through the first adsorption tower.
The method according to claim 1,
The low pressure air supply unit includes a low pressure air supply line connected to the second adsorption tower,
Pressure compressed air produced by the low-pressure compressor is supplied to the second adsorption tower through the low-pressure air supply line.
3. The method according to claim 1 or 2,
Pressure compressed air generated in the high-pressure compressor is delivered through a high-pressure air supply line,
The dried high-pressure air having passed through the first adsorption tower is transferred through the transfer line,
Wherein the transfer line branches the branch line and supplies the dried high pressure air to the second adsorption tower intermittently,
And the branch line connects the low-pressure air supply unit.
The method of claim 3,
Wherein the low pressure compressed air or high pressure compressed air conveyed through the branch line is heated by a heater and then supplied to the second adsorption tower.

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