KR20240003146A - Recycling apparatus and recycling control method of absorption type air dryer system - Google Patents

Abstract

It relates to a regeneration device and a regeneration control method of an adsorption air dryer system, comprising: an additional compressed air supply passage provided between a discharge line and an outlet direction change unit; It includes a second on/off valve and a first flow rate setting valve installed in the additional compressed air supply passage, and in the heating and regeneration stage, the compressed air is supplied to the regenerative adsorption air dryer through the first on/off valve and the first flow rate setting valve of the regeneration passage. supply, and in the cooling regeneration stage, compressed air for regeneration is supplied to the regenerative adsorption air dryer through the first opening/closing valve and the first flow rate setting valve of the regeneration passage, while simultaneously setting the second opening/closing valve and the second flow rate setting of the additional compressed air supply passage. Through the technology configuration that additionally supplies compressed air for regeneration to the valve, the regeneration efficiency can be greatly improved by using an appropriate amount of regenerative compressed air in the heating regeneration stage and using a larger amount of regenerative compressed air in the cooling regeneration stage than the heating regeneration stage. This makes it possible to shorten the time required for playback.

Description

Regeneration device and regeneration operation control method of adsorption air dryer system {RECYCLING APPARATUS AND RECYCLING CONTROL METHOD OF ABSORPTION TYPE AIR DRYER SYSTEM}

The present invention relates to a regeneration device and a regeneration operation control method of an adsorption air dryer system. More specifically, while moisture is removed from compressed air through one of a pair of adsorption air dryers, the other adsorption air dryer performs regeneration. This relates to increasing the regeneration efficiency of an adsorption air dryer in an adsorption air dryer system.

The demand for the Compressed Air Supplying System, which supplies compressed air, an essential power source to factory automation equipment and various factories, is gradually increasing.

This increase in demand for compressed air supply systems has a negative impact on the environment due to noise and oil leaks generated from power sources such as electric motors. Therefore, power sources are changing to utilize compressed air for facilities that use power. Because there is.

In general, compressed air contains harmful substances such as moisture, dust, and lubricants. Moisture and other harmful substances in compressed air act as harmful factors in quality, productivity, and durability in product production, so compressed air The supply system requires an air dryer system to remove moisture contained in compressed air.

The air dryer system uses a refrigeration compressor to lower the temperature of the compressed air and then condenses the moisture contained in the compressed air to dehumidify it, and uses an adsorbent (or dehumidifier or hygroscopic agent) to adsorb the air contained in the humid air. It is classified into an adsorption type for dehumidification.

The adsorption air dryer system consists of a pair of adsorption air dryers filled with adsorbent; A direction change valve that changes the direction of compressed air so that dehumidification and regeneration processes are performed alternately in a pair of adsorption air dryers; Includes a control unit that controls the operation of the direction change valve.

Depending on the regeneration method of the adsorbent, the regeneration device of the adsorption air dryer system is divided into a heating adsorption method that regenerates the adsorbent using a predetermined heat source and a non-heating adsorption method that regenerates the adsorbent using only regeneration air. Heated adsorption method Depending on whether the air for regeneration is reused, there is a non-purge method, which is a circular heating method that regenerates the adsorbent by circulating compressed air from the compressor, or a non-purge method that regenerates the adsorbent by sucking in external air and discharges the used air to the outside. It is classified into a purge method, which is a non-circulating heating method.

The present invention particularly relates to a regeneration device for a purge type adsorption air dryer system that regenerates the adsorbent using air compressed in a compressor and discharges the used compressed air to the outside.

Patent Document 1 below includes a first tower and a second tower in which an adsorbent is accommodated, and in which an air drying process and a regeneration process of regenerative heating and regenerative cooling of the adsorbent are alternately performed; A compressor that compresses moist air coming in from the outside; a supply line for supplying compressed air supplied from the compressor to the first tower and the second tower; a regeneration line that branches off from the supply line and moves compressed air for the adsorbent regeneration process of the first and second towers; a discharge line through which dry air from which moisture has been removed is discharged from the first and second towers; a pressure delivery line branched from the discharge line and connected to the regeneration line, and transporting dry air from the discharge line by a blower for regeneration heating and regeneration cooling of the adsorbents in the first and second towers; a confluence line that connects the first tower and the second tower and the supply line, and moves air that has undergone regenerative heating or regenerative cooling of the adsorbent of either the first tower or the second tower to the supply line; It branches off from the supply line and connects to the confluence line, and includes a cooling regeneration line that moves compressed air from the supply line to be used for regenerative cooling of the first tower and the second tower, wherein the regenerative cooling of the first tower and the second tower is A hybrid type adsorption air dryer system is disclosed, wherein either a cooling method through a pressure delivery line or a cooling method through a cooling regeneration line is selectively used depending on the required dew point.

In Patent Document 2 below, the compressed air discharged from the dehumidifying tank is depressurized and moved to the regenerating tank, and the flow rate is controlled by improving the flow control means to prevent it from moving toward the dehumidifying tank. A control method for an adsorption air dryer device is disclosed, which reduces costs associated with manufacturing and installing the means and further improves the efficiency of maintenance and management of the flow control means.

Patent Document 3 below discloses a wet adhesion air dryer system that allows the use of electric or steam heaters by mounting a heater, which is a regenerative heat source, on the outside and improves dehumidification efficiency by regenerating the adsorbent.

Republic of Korea Patent Publication No. 10-1883736 (registered on July 25, 2018) Republic of Korea Patent Publication No. 10-1817154 (registered on January 4, 2018) Republic of Korea Patent Publication No. 10-1954772 (registered on February 27, 2019)

The regeneration device and regeneration operation control method of the adsorption air dryer system according to the prior art, including Patent Documents 1 to 3, supply heated regeneration air into the adsorption air dryer to regenerate the adsorbent during heat regeneration and after heat regeneration. When performing cooling regeneration to cool the adsorbent heated in the heating and cooling process by supplying unheated regeneration air into the adsorption air dryer, the same amount of regeneration air was supplied in all cases, which may cause heat exchange loss or a regeneration cycle during the heating and regeneration process. There was a problem that dehumidification performance deteriorated as it became longer.

For example, if a large amount of regeneration air is supplied during the heating and regeneration process and the flow rate increases, the heat of the heated regeneration air is not completely transferred to the adsorbent and is discharged to the outside, resulting in heat exchange loss and reducing the power consumption of the heater. If the amount of regeneration air is reduced, the regeneration cycle becomes too long and the adsorbent of the adsorption air dryer on the other side becomes saturated, deteriorating dehumidification performance.

The present invention is intended to solve the problems of the regeneration device and regeneration operation control method of the adsorption air dryer system, and its purpose is to set the regeneration air supply amount in the heating regeneration stage and the regeneration air supply amount in the cooling regeneration stage to be different from each other. The purpose is to provide a regeneration device and a regeneration operation control method for an adsorption air dryer system that can improve regeneration efficiency and cooling regeneration efficiency.

In order to achieve the above-described object, the regeneration device of the adsorption air dryer system according to the present invention includes a first adsorption air dryer and a second adsorption air dryer that adsorb and remove moisture contained in compressed air through an adsorbent filled therein. dryer; An inlet direction switching unit installed in the inlet line provided between the compressor and the inlet portion of the pair of adsorption air dryers, and capable of selectively supplying the compressed air of the compressor to only one of the pair of adsorption air dryers; It is installed in the discharge line provided between the discharge part of a pair of adsorption air dryers and the equipment requiring compressed air, and compressed air from which moisture has been removed is supplied through one of the pair of adsorption air dryers. An outlet direction change unit that transfers to the discharge line; A heater installed in the regeneration passage provided between the discharge line and the outlet direction change unit and heating the compressed air for regeneration; A first opening/closing valve and a first flow rate setting valve installed on the heater inlet side of the regeneration passage; An additional compressed air supply passage provided between the discharge line and the outlet direction switching unit; It is characterized in that it further includes a second opening/closing valve and a first flow rate setting valve installed in the additional compressed air supply passage.

The regeneration device of the adsorption air dryer system according to the present invention is characterized by further comprising a control unit that controls the operation of the inlet direction change unit, the outlet direction change unit, the heater, the first open/close valve, and the second open/close valve.

The regeneration control method of the adsorption air dryer system according to the present invention includes a dehumidification regeneration conversion step in which the adsorption air dryer in dehumidifying operation is converted to regeneration operation through a control unit; A heating and regeneration step in which compressed air drawn from the discharge line is heated through a heater in the regeneration line and supplied to a regenerative adsorption air dryer, and after heating and regenerating the adsorbent, it is discharged into the atmosphere through a purge passage provided in the inlet direction switching unit; A cooling regeneration step of supplying the compressed air drawn from the discharge line to a regenerative adsorption air dryer through an inoperative heater, and discharging it into the atmosphere through a purge passage provided in the inlet direction change unit after cooling and regenerating the adsorbent. .

In the regeneration control method of the adsorption air dryer system according to the present invention, in the heating and regeneration step, the control unit operates the heater installed in the regeneration passage and simultaneously opens the first opening/closing valve to allow compressed air drawn from the discharge line and entering the regeneration passage to be discharged. It is supplied to the heater through one on-off valve and the first flow rate setting valve, and the compressed air heated through the heater is supplied to the regenerative adsorption air dryer.

The regeneration control method of the adsorption air dryer system according to the present invention proceeds with the cooling regeneration step when the heating regeneration set time has elapsed, and the control unit stops the operation of the heater and opens the second opening/closing valve to regenerate the water drawn from the discharge line. Compressed air is supplied to the outlet direction change unit through the first opening/closing valve and first flow setting valve of the regenerative flow path, and the disabled heater, and is simultaneously discharged through the second opening/closing valve and the second flow setting valve of the additional compressed air supply flow channel. It is characterized by being additionally supplied to the direction change unit and supplied to the regenerative adsorption air dryer.

In the regeneration control method of the adsorption air dryer system according to the present invention, when the cooling regeneration set time has elapsed, the control unit closes the first on-off valve and the second on-off valve at the same time to block the supply of compressed air to the regenerative adsorption air dryer and perform regeneration. Characterized by ending.

According to the regeneration device and regeneration operation control method of the adsorption air dryer system according to the present invention, the amount of regeneration compressed air supplied to the adsorption air dryer in the heating regeneration stage and the amount of regeneration compressed air supplied to the adsorption air dryer in the cooling regeneration stage are adjusted. You can set them differently.

According to the regeneration device and regeneration operation control method of the adsorption air dryer system according to the present invention, power consumption of the heater can be reduced by supplying an appropriate amount of regeneration compressed air to the regeneration adsorption air dryer in the heating and regeneration stage, and regeneration at an appropriate flow rate. Compressed air can be supplied, preventing heat loss, greatly improving heating and regeneration efficiency, and shortening the regeneration cycle.

According to the regeneration device and regeneration operation control method of the adsorption air dryer system according to the present invention, a larger amount of regeneration compressed air can be supplied to the regeneration adsorption air dryer in the cooling regeneration stage than in the heating regeneration stage, thereby increasing the flow rate around the adsorbent. As a result, the adsorbent and water molecules whose bonding force is weakened due to heating in the heating and regeneration stage can be shaken off at high speed, thereby greatly improving the cooling and regeneration efficiency.

According to the regeneration device and regeneration operation control method of the adsorption air dryer system according to the present invention, a suitable amount of regeneration compressed air is used in the heating regeneration step, and a larger amount of regeneration compressed air is used in the cooling regeneration step than the heating regeneration step. Efficiency can be greatly improved and the time required for regeneration can be shortened.

According to the regeneration device and regeneration operation control method of the adsorption air dryer system according to the present invention, an additional compressed air supply passage that allows additional supply of compressed air in the cooling regeneration step is provided separately from the regeneration passage in which the heater is installed. In the process of additional supply of compressed air, no load is placed on the heater side of the regeneration passage, and vibration or noise of the heater due to additional supply of compressed air is not caused.

1 is a configuration diagram of a regeneration device of an adsorption air dryer system according to the present invention;
Figure 2 is a control configuration diagram of the regeneration device of the adsorption air dryer system according to the present invention;
Figure 3 is a control flow chart of the regeneration control method of the adsorption air dryer system according to the present invention;
Figure 5 is a heating and regeneration control state diagram of the regeneration control method of the adsorption air dryer system according to the present invention;
Figure 5 is a cooling regeneration control state diagram of the regeneration control method of the adsorption air dryer system according to the present invention.

Hereinafter, the regeneration device and regeneration operation control method of the adsorption air dryer system according to the present invention will be described in detail based on the attached drawings.

Hereinafter, “upward,” “downward,” “front,” and “rear” and other directional terms are defined based on the states shown in the drawings.

Figure 1 is a configuration diagram of a regeneration device of an adsorption air dryer system according to the present invention, and Figure 2 is a control configuration diagram of a regeneration device of an adsorption air dryer system according to the present invention.

The regeneration device 100 of the adsorption air dryer system according to the present invention includes a first adsorption air dryer 110, a second adsorption air dryer 120, an inlet direction change unit 130, an outlet direction change unit 140, and a heater. (150), including a control unit (180).

The first adsorption air dryer 110 and the second adsorption air dryer 120 are parts that adsorb and remove moisture contained in compressed air through an adsorbent filled therein.

The inlet part of each adsorption air dryer (110) (120) is connected to a compressor (not shown) through the inlet line (L1), and the outlet part of the adsorption air dryer (110) (120) supplies dry air through the discharge line (L2). It is connected to the equipment that requires it.

The inlet direction switching unit 130 is a part that allows compressed air from the compressor to be selectively supplied to only one of the pair of adsorption air dryers 110 and 120, and is installed in the inlet line (L1).

The outlet direction switching unit 140 transfers compressed air from which moisture has been removed through one of the pair of adsorption air dryers 110 and 120 to the discharge line (L2). It is partially installed in the discharge line (L2).

The heater 150 is a part that heats the compressed air used in the heating and regeneration process, and is installed in the regeneration passage (L3) provided between the discharge line (L2) and the outlet direction switching unit (140).

A first opening/closing valve 161 and a first flow rate setting valve 162 are installed on the inflow side of the heater 150 of the regeneration passage L3.

The regeneration device 100 of the adsorption air dryer system according to the present invention is provided with an additional compressed air supply passage (L4) separate from the regeneration passage (L3) between the discharge line (l2) and the outlet direction switching unit (140), A second opening/closing valve 171 and a second flow rate setting valve 172 are installed in the additional compressed air supply passage (L4).

The control unit 180 controls the operation of the inlet direction change unit 130, the outlet direction change unit 140, the heater 150, the first open/close valve 161, and the second open/close valve 171.

The regeneration device 100 of the adsorption air dryer system according to the present invention is a regeneration device in which a first opening and closing valve 161 and a first flow rate setting valve 162 are installed between the discharge line (L2) and the outlet direction switching unit 140. Since the flow path (L3) and the additional compressed air supply flow path (L4) installed with the second on-off valve (171) and the second flow rate setting valve (172) are provided, the amount of compressed air supplied in the heating regeneration process can be changed to the compressed air in the cooling regeneration process. The supply amount can be set differently.

Like the adsorption air dryer system according to the prior art, the regeneration device 100 of the adsorption air dryer system according to the present invention includes one of a pair of adsorption air dryers 110 and 120. It is controlled so that adsorbent regeneration for the other adsorption air dryer (110) (120) is performed while moisture in the compressed air supplied from the compressor is adsorbed and removed.

For example, while removing moisture from compressed air through the adsorbent charged in the first adsorption air dryer 110, regeneration is controlled to remove moisture from the adsorbent charged in the second adsorption air dryer 120, and It is controlled so that regeneration is performed to remove moisture from the adsorbent charged into the first adsorption air dryer 110 while moisture from the compressed air is removed through the adsorbent charged into the second adsorption air dryer 120.

Figure 3 is a control flow diagram of the regeneration control method of the adsorption air dryer system according to the present invention.

The regeneration control method of the adsorption air dryer system according to the present invention uses the above-described regeneration device 100 of the adsorption air dryer system, and includes a dehumidification regeneration conversion step, a heating regeneration step, and a cooling regeneration step.

The dehumidification regeneration conversion step is a step in which the adsorption air dryers 110 and 120 in dehumidifying operation are switched to regeneration operation through the control unit 180.

Among the pair of adsorption air dryers (110 and 120) in the adsorption air dryer system, when one of the adsorption air dryers (110) and (120) that dehumidifies compressed air operates for a certain period of time, the corresponding adsorption air dryer (110) Moisture is excessively adsorbed on the adsorbent filled in (120), resulting in a decrease in adsorption efficiency.

At this time, the control unit 180 dehumidifies the compressed air with other adsorption air dryers 110 and 120 from which the moisture in the adsorbent has been removed, and at the same time controls the inlet direction to regenerate the adsorption air dryers 110 and 120 from which much moisture has been adsorbed. Controls the switching unit 160 and the outlet direction switching unit 170.

In the dehumidification regeneration conversion stage, when the dehumidification adsorption air dryers (110) (120) are converted to regeneration adsorption air dryers (110) (120), the regenerated adsorption air dryers (110) (120) are converted to dehumidification adsorption air dryers (110) (120). ) is converted to

In the heating and regeneration step, the compressed air drawn from the discharge line (L2) is heated by the heater (150) installed in the regeneration passage (L3) and supplied to the adsorption air dryer (110) (120).

In the heating and regeneration stage, high-temperature compressed air heated through the heater 150 is supplied to the regenerative adsorption air dryer 120, so that the moisture adsorbed on the adsorbent of the regenerative adsorption air dryer 110 and 120 can be quickly removed. do.

Figure 4 is a heating and regeneration control state diagram of the regeneration control method of the adsorption air dryer system according to the present invention.

In the heating and regeneration stage, the control unit 180 operates the heater 150 installed in the regeneration passage (L3) and simultaneously opens the first opening and closing valve (161) and the second opening and closing valve ( 171).

In the heating and regeneration stage, the compressed air drawn from the discharge line (L2) and entered into the regeneration passage (L3) is supplied to the heater 150 through the first on-off valve 161 and the first flow rate setting valve 162. The high-temperature compressed air heated through (150) is supplied to the inner upper part of the regenerative adsorption air dryer (120) through the outlet direction switching unit (140).

In the heating and regeneration stage, the high-temperature compressed air that enters the upper part of the regenerative adsorption air dryer (120) passes through the adsorbent filled inside the regenerative adsorption air dryer (120), removes moisture stuck to the adsorbent, and then contains moisture. It is discharged to the inlet direction change unit 130 connected to the bottom of the regenerative adsorption air dryer 120, and is discharged into the atmosphere through the purge passage L5 provided in the inlet direction change unit 130.

The heating regeneration stage proceeds for a set time, and when the heating regeneration set time elapses, the control unit 180 stops the operation of the heater 150 and simultaneously opens the second opening/closing valve 171 of the additional compressed air supply passage (L4). Open to proceed with the cooling regeneration step.

The cooling regeneration step is a step of cooling and dehumidifying the adsorbent of the heated regenerative adsorption air dryer 120 in the process of removing moisture stuck to the adsorbent of the regenerative adsorption air dryer 120 through the high temperature compressed air of the heating regeneration step. .

Figure 5 is a cooling regeneration control state diagram of the regeneration control method of the adsorption air dryer system according to the present invention.

In the cooling regeneration step, the compressed air drawn from the discharge line (L2) is supplied to the inner upper part of the regenerative adsorption air dryer (120) without being heated through the heater (150).

In the cooling regeneration stage, the control unit 180 stops operating the heater 150 installed in the regeneration passage (L3) and at the same time operates the additional compressed air supply passage (L4) along with the first opening/closing valve (161) of the regeneration passage (L3). Open the second opening/closing valve (171) installed in .

In the cooling regeneration stage, the compressed air drawn from the discharge line (L2) and entered into the regeneration passage (L3) passes through the first on-off valve (161), the first flow rate setting valve (162), and the heater (150) in an inactive state. The compressed air supplied to the outlet direction switching unit (140), drawn from the discharge line (L2), and entered into the additional compressed air supply passage (L4) operates through the second on/off valve (171) and the second flow rate setting valve (172). It is additionally supplied to the outlet direction switching unit (140).

Therefore, in the cooling regeneration stage, compared to the heating regeneration stage in which compressed air is supplied only through the regeneration passage (L3) in which the first on-off valve 161 and the first flow rate setting valve 162 are installed, a larger amount of compressed air flows into the outlet direction switching unit. It is supplied to the regenerative adsorption air dryer (120) through (140).

The compressed air that enters the upper part of the regenerative adsorption air dryer (120) in the cooling regeneration step passes through the adsorbent filled inside the regenerative adsorption air dryer (120) and dehumidifies and regenerates the heated adsorbent in the heating regeneration step. It is discharged to the inlet direction change unit 130 connected to the bottom of the adsorption air dryer 120, and is discharged into the atmosphere through the purge passage L5 provided in the inlet direction change unit 130.

The cooling regeneration stage proceeds for a set time, and when the cooling regeneration set time elapses, the control unit 180 closes the first opening/closing valve 161 of the regeneration passage (L3) and simultaneously opens the additional compressed air supply passage (L4). 2 Close the on-off valve 171 to block the supply of compressed air to the regenerative adsorption air dryer 120 and end regeneration.

In the regeneration device and regeneration control method of the adsorption air dryer system according to the present invention, in the heating regeneration step, only the first on/off valve 161 installed in the regeneration passage (L3) is opened by the amount set in the first flow rate setting valve 162. The compressed air is heated through the heater 150 and then supplied to the regenerative adsorption air dryer 120.

Therefore, in the heating regeneration stage, the adsorbent can be regenerated at a lower flow rate and flow rate than in the cold regeneration stage, so that the heat of the regenerated compressed air heated by the heater 150 can be efficiently transferred to the adsorbent and heat loss can be minimized. There will be.

Meanwhile, in the cooling regeneration stage, the first opening and closing valve 161 installed in the regeneration passage (L3) and the second opening and closing valve 171 installed in the additional compressed air supply passage (L4) are opened, so that the first flow rate setting valve 162 The amount of regenerative compressed air set in and the amount of regenerated compressed air set in the second flow rate setting valve 172 are supplied to the regenerative adsorption air dryer 120, and the flow rate increases around the adsorbent of the regenerative adsorption air dryer 120 accordingly. As a result, the adsorbent and water molecules that are heated in the heating and regeneration stage and have weakened bonding can be shaken off at high speed, greatly improving cooling and regeneration efficiency.

In the regeneration device and regeneration control method of the adsorption air dryer system according to the present invention, the additional compressed air supply passage (L4) is a regeneration passage ( Since it is provided separately from L3), no load is placed on the heater 150 of the regeneration channel (L3) during the additional supply of compressed air in the cooling regeneration stage through the additional compressed air supply channel (L4), so there is no load on the heater 150 side of the regeneration channel (L3). Vibration or noise of the heater 150 is not caused.

In this way, the regeneration device and regeneration control method of the adsorption air dryer system according to the present invention can increase heating regeneration efficiency while preventing heat loss by supplying a relatively small amount of regenerative compressed air in the heating regeneration stage, and heat regeneration efficiency in the cooling regeneration stage. By supplying a larger amount of regenerative compressed air compared to the regeneration stage, cooling regeneration efficiency can be increased and the time required for regeneration can be shortened.

Although the invention made by the present inventor has been specifically described* according to the above-mentioned embodiments, the present invention is not limited to the above-mentioned embodiments and can of course be changed in various ways without departing from the gist of the invention.

100: Regeneration device of adsorption air dryer system
110, 120: Adsorption air dryer
130: Inlet direction change unit
140: Exit direction switching unit;
150: heater
161: First opening/closing valve
162: First flow setting valve
171: Second opening/closing valve
172: Second flow setting valve
L1: Inflow line
L2: discharge line
L3: Regeneration flow path
L4: Additional compressed air supply channel
L5: Purge flow path

Claims (6)

A first adsorption air dryer 110 and a second adsorption air dryer 120 that adsorb and remove moisture contained in compressed air through an adsorbent filled therein;
It is installed on the inlet line (L1) provided between the compressor and the inlet portion of the pair of adsorption air dryers (110 and 120), and selectively operates on the compressor only to one of the pair of adsorption air dryers (110 and 120). Inlet direction switching unit 130 to supply compressed air;
It is installed on the discharge line (L2) provided between the discharge part of the pair of adsorption air dryers (110) (120) and the equipment requiring compressed air, and is installed in the discharge line (L2) of the pair of adsorption air dryers (110) (120). An outlet direction switching unit (140) that transfers compressed air from which moisture has been removed through one of the adsorption air dryers (110) and (120) to the discharge line (L2);
A heater (150) installed in the regeneration passage (L3) provided between the discharge line (L2) and the outlet direction switching unit (140) and heating the compressed air for regeneration;
It includes a first opening/closing valve 161 and a first flow rate setting valve 162 installed on the inlet side of the heater 150 of the regeneration passage (L3),
An additional compressed air supply passage (L4) provided between the discharge line (L2) and the outlet direction unit (140);
A regeneration device for an adsorption air dryer system, further comprising a second opening/closing valve (171) and a second flow rate setting valve (172) installed in the additional compressed air supply passage (L4). According to paragraph 1,
It further includes a control unit 180 that controls the operation of the inlet direction change unit 130, the outlet direction change unit 140, the heater 150, the first open/close valve 161, and the second open/close valve 171. A regeneration device for an adsorption air dryer system, characterized in that. A regeneration control method of an adsorption air dryer system using the regeneration device of the adsorption air dryer system described in paragraph 2,
A dehumidification regeneration conversion step in which the adsorption air dryers 110 and 120 in dehumidifying operation are switched to regeneration operation through the control unit 180;
The compressed air drawn from the discharge line (L2) is heated through the heater 150 of the regeneration passage (L3) and supplied to the regenerative adsorption air dryer (120), and after heating and regenerating the adsorbent, the purge provided in the inlet direction change unit (130) Heating and regeneration step of discharging into the atmosphere through flow path (L5);
Compressed air drawn from the discharge line (L2) is supplied to the regenerative adsorption air dryer (120) through the inoperative heater (150), and after cooling and regeneration of the adsorbent, through the purge passage (L5) provided in the inlet direction switching unit (130). A regeneration control method of an adsorption air dryer system, comprising a cooling regeneration step of discharging into the atmosphere. According to paragraph 3,
In the heating and regeneration stage, the control unit 180 operates the heater 150 installed in the regeneration passage (L3) and simultaneously opens the first opening and closing valve 161 to be withdrawn from the discharge line (L2) and enter the regeneration passage (L3). The compressed air is supplied to the heater 150 through the first on-off valve 161 and the first flow rate setting valve 162, and the compressed air heated through the heater 150 is supplied to the regenerative adsorption air dryer 120. A regeneration control method for an adsorption air dryer system, characterized in that: According to paragraph 4,
When the heating regeneration set time elapses, the cooling regeneration step is performed, and the control unit 180 stops the operation of the heater 150 and simultaneously opens the second opening/closing valve 171 to release the compression drawn from the discharge line (L2). Air is supplied to the outlet direction change unit 140 through the first opening/closing valve 161 and the first flow rate setting valve 162 of the regeneration passage (L3), and the disabled heater 150, and at the same time, an additional compressed air supply passage. Adsorption air is additionally supplied to the outlet direction change unit 140 through the second on/off valve 171 and the second flow rate setting valve 172 of (L4) and supplied to the regenerative adsorption air dryer 120. Regeneration control method of dryer system. According to clause 5,
When the cooling regeneration set time elapses, the control unit 180 closes the first on-off valve 161 and the second on-off valve 171 at the same time to block the supply of compressed air to the regenerative adsorption air dryer 120 and ends regeneration. A regeneration control method for an adsorption air dryer system, characterized in that:

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