KR101479662B1 - Non-Purge and non-heater air dryer system using heat of compression and air drying method - Google Patents

Abstract

The present invention relates to an adsorption type air drying system of a non-purge method. According to the present invention, the air drying system comprises: a compressor to supply all of compressed air as high temperature air for recycling by compressing air flowing from an outside; an adsorption column for recycling filled with an adsorbent inside, to heat and recycle the adsorbent while the high temperature air for recycling supplied through the compressor passes from an upper part to a lower part in a first step, and to cool and recycle the adsorbent while low temperature air for recycling passes from a lower part to an upper part; an adsorption column for dehumidifying filled with an adsorbent inside, and to dehumidify air for dehumidifying from a lower part to an upper part in the first and second steps; a first cooler to cool air for recycling discharged from the adsorption column for recycling and to supply the air for dehumidifying to the adsorption column for dehumidifying in the first step, and to cool high temperature air for recycling supplied from the compressor and to supply low temperature air for recycling to the adsorption column for recycling in the second step; and a second cooler to cool air for recycling discharged from the adsorption column for recycling and to supply the air for dehumidifying to the adsorption column for dehumidifying in the second step.

Description

TECHNICAL FIELD [0001] The present invention relates to a non-heater non-purge air drying system and a non-heater air dryer system using compressed heat,

The present invention relates to a non-heater non-purging air drying system and an air drying method using compressed heat, and more particularly, to a non-heater non-purging air drying system and an air drying method that use a compressed heat to perform dehumidification and regeneration using a compressed heat, The present invention relates to an air drying system and an air drying method.

Generally, dry air with moisture removed from air is widely used in various automation equipment, semiconductor manufacturing process, and production line of chemical process that causes chemical reaction during water contact.

The air drying system for producing the dry air includes a freezing air drying system for reducing the temperature of the compressed air by using a refrigeration compressor and then dehumidifying the moisture contained in the compressed air by condensing the moisture and a desiccant And a desiccant type air drying system for adsorbing and dehumidifying air contained in moist air.

The general structure and function of the adsorption type air drying system related to the present invention will be described as follows.

The adsorption type air drying system includes a pair of adsorption towers in which an adsorbent is incorporated, a direction switching valve that changes the direction of the compressed air so that the dehumidification and the regeneration processes are alternately performed in the pair of adsorption towers, And a control section including a solenoid valve for controlling operation and a timer.

In general, the adsorption type air drying system having the above-described structure is composed of a heat adsorption type air drying system for regenerating an adsorbent using a predetermined heat source in accordance with a regeneration method of an adsorbent and a non-heat adsorption type air drying system .

In addition, the heat adsorption type air drying system includes a circulation heat adsorption type air drying system (hereinafter, referred to as a non-purge type air drying system) that recycles the adsorbent by circulating the compressed air in the compressor in accordance with reuse of the regeneration air ), A non-circulating heat adsorption type air drying system (hereinafter referred to as a purge type air drying system) for regenerating an adsorbent with air dried by compressed air and discharging used air to the outside. ).

Among them, the non-purge type air drying system related to the present invention is characterized in that as described in Korean Patent Registration No. 10-0825391 (Apr. 21, 2008), most of the compressed air supplied from a compressor is cooled by dehumidifying air , And a part of the compressed air (for example, about 30%) was heated using an electric heater and used as air for heating and regeneration. Such a conventional air drying system requires a separate electric heater, which requires additional energy, which is a waste of energy, and increases the processing cost for air drying.

Korean Patent No. 10-0825391 (Apr. 21, 2008)

Accordingly, it is an object of the present invention to provide a non-heater and non-purge air drying system and an air drying method using the compressed heat, which can overcome the above-described conventional problems.

Another object of the present invention is to provide a non-heater and non-purge air drying system and an air drying method using compressed heat which can reduce energy consumption and processing cost by using the entire compressed air compressed by the compressor for regeneration I have to.

According to an embodiment of the present invention, there is provided an air drying system comprising: a compressor for compressing air introduced from the outside and supplying all of the compressed air to high temperature regeneration air; In the first step, the high-temperature regeneration air supplied through the compressor passes through from the upper portion to the lower portion so that the adsorbent is heated and regenerated. In the second step, low-temperature regeneration air flows from the lower portion to the upper portion A recovery adsorption tower through which the adsorbent is cooled and regenerated while passing through the adsorption tower; An adsorption tower for dehumidifying which is filled with an adsorbent therein and is dehumidified while the dehumidifying air passes through from the bottom to the top in the first and second steps; In the first step, the regeneration air discharged from the regeneration adsorption tower is cooled and supplied to the adsorption tower for dehumidification as the dehumidification air. In the second step, the high temperature regeneration air supplied from the compressor is cooled And supplying it to the adsorption tower for regeneration as low-temperature regeneration air; And a second cooler for cooling the regeneration air discharged from the adsorption tower for regeneration in the second step and supplying it to the adsorption tower for dehumidification with the desiccant air.

The air drying system includes a first adsorption tower and a second adsorption tower in which an adsorbent is charged, respectively, and the first adsorption tower and the second adsorption tower are alternately switched to the regeneration adsorption tower or the desorption tower for dehumidification .

The air drying system includes a first adsorption tower and a second adsorption tower, which are installed at the lower part of the first adsorption tower and the second adsorption tower and are connected to the first adsorption tower and the second adsorption tower, A one-way switching valve; And a second direction switching valve provided on the first adsorption tower and the second adsorption tower for switching the direction of air flowing into the first adsorption tower and the second adsorption tower or discharged from the first adsorption tower and the second adsorption tower Wherein the first direction switching valve comprises a first on-off valve and a second on-off valve for respectively introducing dehumidification air to the dehumidifying adsorption tower, and a third on / off valve for circulating air regenerated from the regeneration adsorption tower, Closing valve for discharging the air dehumidified by the adsorption tower for dehumidification to the outside, and a fifth opening / closing valve for opening / And a seventh opening / closing valve and an eighth opening / closing valve for injecting or discharging the gas into / from the adsorption tower for adsorption.

The first step is a step of regenerating the regeneration adsorption tower by using all of the compressed air compressed and supplied by the compressor as high temperature regeneration air to regenerate the regeneration air discharged from the regeneration adsorption tower, And the second step is a step of cooling the high temperature regeneration air supplied from the compressor to regenerate the regeneration air to the low temperature regeneration air A cooling regeneration and dehumidification process for cooling the regeneration tower for regeneration and cooling the regeneration air discharged from the regeneration tower for dehumidification and dehumidifying the regeneration air in the adsorption tower for dehumidification to discharge dry air to the outside .

According to an embodiment of the present invention to achieve some of the above-mentioned technical problems, there is provided a method of recovering a first adsorption tower and a second adsorption tower, which are filled with an adsorbent in accordance with the present invention, The method comprising: a first step of supplying all the compressed air compressed through the compressor from the outside as high-temperature regeneration air; A second step of heating and regenerating the regeneration adsorption tower while the high temperature regeneration air supplied from the compressor passes through the regeneration adsorption tower in a downward direction; A third step of heating and regenerating the regeneration tower for regeneration, cooling the regeneration air to be discharged and supplying it to the adsorption tower for dehumidification as dehumidification air; And a fourth step of drying the dehumidifying air in the adsorption tower for dehumidification to discharge the dry air to the outside.

According to an embodiment of the present invention to achieve some of the above-mentioned technical problems, there is provided a method of recovering a first adsorption tower and a second adsorption tower, which are filled with an adsorbent in accordance with the present invention, The method comprising: a first step of supplying all the compressed air compressed through the compressor from the outside as high-temperature regeneration air; A second step of cooling the high-temperature regeneration air supplied from the compressor and supplying the low-temperature regeneration air to the regeneration adsorption tower; A third step of cooling and regenerating the adsorption tower for regeneration while the low temperature regeneration air passes through the regeneration adsorption tower from the bottom to the top; The regeneration tower is cooled and regenerated, the regeneration air is cooled again, and the regeneration air is supplied to the adsorption tower for dehumidification as dehumidification air, and the dehumidification air is dried in the adsorption tower for dehumidification to discharge the dry air to the outside And a fourth step.

As described above, according to the present invention, all the compressed air compressed through the compressor is used for regeneration, thereby reducing energy consumption and processing cost. In addition, the process can be simplified by the first process and the second process, and the dehumidification and regeneration process time can be reduced.

1 is a schematic view showing a configuration of a non-purge air drying system according to an embodiment of the present invention,
FIG. 2 is a schematic view showing the heating regeneration and dehumidification process of FIG. 1,
FIG. 3 is a schematic view showing the cooling regeneration and dehumidification process of FIG. 1;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings without intending to intend to provide a thorough understanding of the present invention to a person having ordinary skill in the art to which the present invention belongs.

Hereinafter, a detailed description of known configurations and functions of the constituent elements of the present invention will be omitted when it is determined that the gist of the present invention may be blurred. It is to be noted that, among the constituent elements shown in the drawings, the same constituent elements are denoted by the same reference numerals even though they are shown in different drawings.

1 is a schematic diagram showing the construction of a non-purge adsorption-type air drying system according to an embodiment of the present invention.

1, a non-purge adsorption type air drying system according to an embodiment of the present invention includes a pair of adsorption columns 110, a compressor 120, a first cooler 150, a second cooler 170, And the like. In addition, essential components well known to those skilled in the art may be additionally provided.

The air drying system according to an embodiment of the present invention includes a first process and a second process.

In the first step, the heating / regeneration process is performed on the adsorption tower for regeneration using all of the compressed air as the regeneration air, the regeneration air subjected to the heat regeneration process is cooled, and the regeneration air is dehydrated through the adsorption tower for dehumidification Thereby discharging dry air.

In the second step, the cooling regeneration process is performed on the regeneration adsorption tower using all of the compressed air as the regeneration air, the regeneration air subjected to the cooling regeneration process is cooled again, and the regeneration air is used as the dehumidification air, And then drying air is discharged.

The pair of adsorption towers 110 are provided for the first adsorption tower 112 and the second adsorption tower 114 having the same shape and structure to produce air by adsorbing moisture contained in humid air.

Each of the first adsorption tower 110 and the second adsorption tower 114 is formed into a closed cylindrical shape having a predetermined length and is filled with an adsorbent therein. An inlet and an outlet are respectively installed. In order to prevent the loss of the adsorbent, a screen mesh (Mesh) made of stainless steel and a mesh mesh (not shown) for dispersing the flow of air (dehumidifying and regenerating air) are appropriately dispersed in upper and lower portions of the adsorption towers 112 and 114 An air distributor is provided.

Activated alumina, silica gel, alumina silica gel, molecular sieves, and the like can be used as the adsorbent to be charged in each of the adsorption towers 112 and 114.

Each of the first adsorption tower 110 and the second adsorption tower 114 is alternately used as an adsorption tower for regeneration and a desorption tower for dehumidification.

When the first adsorption tower 110 or the second adsorption tower 114 is used for regeneration, it may be referred to as an adsorption tower for regeneration and may be referred to as an adsorption tower for dehumidification when it is used for dehumidification. For example, when the first adsorption tower 112 is used for dehumidification and the second adsorption tower 114 is used for regeneration, the first adsorption tower 112 becomes the adsorption tower for dehumidification and the second adsorption tower 114 becomes the adsorption tower for dehumidification, Adsorption tower. When the first adsorption tower 112 is used for regeneration and the second adsorption tower 114 is used for dehumidification, the first adsorption tower 112 serves as the adsorption tower for regeneration and the second adsorption tower 114 serves as the adsorption tower for dehumidification do.

Hereinafter, for convenience of understanding, the first adsorption tower 112 is referred to as an adsorption tower for regeneration and the second adsorption tower 114 is referred to as an adsorption tower for dehumidification.

The compressor 120 is located at the extreme end of the air drying system according to an embodiment of the present invention to compress the humid air introduced from the outside to a predetermined pressure (about 7.0 kg / cm 2) A compressor or a turbo-type compressor may be used.

In the screw type compressor, compressed heat is generated at about 140 to 160 DEG C during compression, and compressed heat is generated at about 100 to 120 DEG C in the turbo type compressor. The compressed air, which is compressed through the compressor 120, And has a temperature of about 100 to 160 ° C.

Herein, the high temperature means 100 DEG C or higher, and the low temperature means 50 DEG C or lower.

The compressor 120 supplies all of the compressed air to the high-temperature regeneration air.

In the conventional air drying system, only about 30% of the compressed air supplied through the compressor 120 is used for heating and regenerating, and about 70% is used for dehumidifying. Since relatively little air is used in order to be used, it is necessary to heat the air to 200 ° C or more by using an electric heater to ensure the efficiency of regeneration.

However, in the present invention, since all the compressed air compressed is used for regeneration, a separate electric heater is not required, and energy saving and processing cost for generating dry air are reduced.

A pretreatment filter 130 is provided at a downstream end of the compressed air outlet of the compressor 120. The pretreatment filter 130 removes foreign matter (moisture, oil and dust) from the compressed air, .

In addition, the pre-treatment filter 130 automatically opens the bypass valve to prevent a pressure drop at the outlet due to an excessive differential pressure in the adsorption tower 110 and malfunction of various valves, .

The preprocessing filters 130 are provided in parallel with each other so that they can be replaced when a filter is replaced or when a failure occurs.

The preprocessing filter 130 may not be provided. Since the air discharged from the compressor 120 is at a high temperature of 100 ° C or higher and there are not many foreign substances, the pre-processing filter 130 may be omitted.

In the first step, the first cooler 150 regenerates the adsorption tower in the adsorption tower 112 for regeneration, and the regeneration air to be discharged is cooled to about 40 ° C. and supplied to the adsorption tower 114 for dehumidification do. In the second step, the entire regeneration air in the high-temperature and high-pressure state supplied to the compressor 120 is cooled to approximately 40 ° C or lower and supplied to the adsorption tower 114 for dehumidification as dehumidification air.

The first separator 160 provided at the discharge port side of the first cooler 150 is for separating moisture contained in the dehumidifying air cooled by the first cooler 150 and may be a conventional cyclone type, Or a demister type separator may be used.

The second cooler 170 is not used in the first process and is used in the second process. The regenerating adsorption tower 112 performs a cooling regeneration process and cools the regeneration air to be discharged, And is supplied to the adsorption tower 114 for dehumidification.

The second separator 180 provided at the discharge port side of the second cooler 170 is for separating moisture contained in the dehumidifying air cooled by the second cooler 170 and may be a conventional cyclone type, Or a demister type separator may be used.

Here, the switching to the dehumidifying air or the regeneration air, the switching from the first step to the second step, and the switching from the second step to the first step are carried out in such a manner that the dehumidifying air and the plurality Closing control of the opening / closing valves 240 of the control valve 240.

When the first adsorption tower 112 and the second adsorption tower 114 are alternately used as the adsorption tower for regeneration and the adsorption tower for dehumidification, the feeding direction of the dehumidifying air and the regeneration air is switched, A plurality of first directional control valves 260 and a plurality of second directional control valves 270 are provided for appropriately introducing and discharging the gas into and from the second adsorption tower 112 and the second adsorption tower 114.

The first direction switching valve 260 is connected to the circulation line of the dehumidifying air and the regeneration air located below the first adsorption tower 112 and the second adsorption tower 114, And the transfer direction of the dehumidifying and regenerating air that is introduced into the second adsorption tower (114) or discharged from the first adsorption tower (112) and the second adsorption tower (114).

The second direction switching valve 270 is connected to the circulation line of the dehumidifying air and the regeneration air located in the upper part of the first adsorption tower 112 and the second adsorption tower 114, ) And the transfer direction of the dehumidifying and regenerating air that is introduced into the second adsorption tower (114) or discharged from the first adsorption tower (112) and the second adsorption tower (114).

The first directional control valve 260 and the second directional control valve 270 each include four on-off valves 262, 264, 266, 268 and 272, 274, 276, 278, It is possible to intermittently dehumidify and regenerate the first adsorption tower 112 and the second adsorption tower 114 by selectively interrupting the transfer of the dehumidifying air and the regeneration air.

At this time, a total of four opening / closing valves constituting the first directional control valve 260 are referred to as a first open / close valve 262, a second open / close valve 264, a third open / close valve 266 and a fourth open / Closing valves 272, 274, 276, 276, 276, 276, 276, 276, 276, 276, 278, It will be referred to as an on-off valve 278.

That is, the first directional control valve 260 includes a first on-off valve 262 and a second on-off valve 264 for injecting dehumidification air into the dehumidifying adsorption tower, And a second on-off valve (268) for circulating the dehumidified air from the dehumidifying adsorption tower, respectively, and the second direction switching valve (270) A fifth on-off valve 272 and a sixth on-off valve 274, and a seventh on-off valve 276 and an eighth on-off valve 278 for injecting or discharging the regeneration air into the regeneration adsorption tower have.

The drying air dried through the adsorption tower for dehumidification (112 or 114) is controlled by the second direction switching valve (270) to be discharged to the outside for use in various places of use.

The drying air is further removed by the post-treatment filter 140 to remove foreign matter (water, oil, and dust) before being discharged to various uses, thereby preventing damage to various equipment using the dried air.

In addition, the post-treatment filter 140 is also automatically opened to prevent a pressure drop at the outlet due to excessive differential pressure in the adsorption tower 110 and operation failure of various valves, as in the case of the preprocessing filter 130 Thereby maintaining the pressure of the outlet at a constant level.

Also, the post-processing filters 140 are provided in parallel with each other like the preprocessing filter 130, so that the post-processing filters 140 can be replaced when a filter is replaced or when a failure occurs.

The plurality of on-off valves 240 regenerates the adsorbent by circulating the regeneration air and the air supplied to the compressor 120, and converts the regenerated air into dehumidifying air for use. The first step and the second step are performed.

The operation of the air drying system having the above-described structure will be described with reference to FIGS. 2 to 3. FIG.

Here, the first step and the second step are performed simultaneously in the pair of adsorption towers 112 and 114. In this embodiment, the first adsorption tower 112 regenerates and the second adsorption tower 114 performs dehumidification , It is assumed that the adsorption tower for dehumidification is the second adsorption tower 114 and the adsorption tower for regeneration is the first adsorption tower 112. [

Hereinafter, the moving path of the dehumidifying air is indicated by a solid line arrow along with the dry air and the moving path of the regeneration air is indicated by a dotted arrow.

Fig. 2 is a schematic view showing the air flow in the first process (heating regeneration and dehumidification process) in Fig.

2, the humid air introduced from the outside is compressed at a high temperature (about 100 to 160 ° C.) and a high pressure (about 7.0 kg / cm 2) by the compressor 120, .

The high-temperature regeneration air removes foreign matter through the pretreatment filter 130.

The high-temperature regeneration air from which the foreign substance is removed flows into the upper portion of the first adsorption tower 112 which is the adsorption tower for regeneration. The fifth and eighth open / close valves 272 and 278 of the second directional control valve 270 are controlled such that the high temperature regeneration air flows into the first adsorption tower 112 and is not introduced into the second adsorption tower 114 And the sixth and seventh open / close valves 274 and 276 should be opened.

Also, the on-off valves 244, 246, and 252 provided on the circulation pipe for cooling regeneration are closed, and the on-off valves 242, 248, and 254 provided on the circulation pipe for the heating regeneration must be opened. This is because the high temperature regeneration air is directly sent to the first cooler 150 or the second adsorption tower 114 without passing through the first adsorption tower 112 or the regeneration air passed through the first adsorption tower 112 is moved to another place So that it is transferred to the first cooler 150 without leaking.

The high-temperature regeneration air introduced into the first adsorption tower 112 desorbs the moisture of the adsorbent charged therein and then flows into the first cooler 150 by opening the third on-off valve 266 and the on- (Not shown). The air for regeneration passes downward from the upper portion of the first adsorption tower 112.

The regeneration air that has passed through the first adsorption tower 112 is cooled to about 40 ° C by the first cooler 150. After foreign substances including moisture are removed from the first separator 160, 254 to the second adsorption tower 114 through the dehumidifying air.

At this time, the second and third opening / closing valves 264 and 266 of the first direction switching valve 260 are opened, the first opening / closing valve 262 and the fourth opening / closing valve 268 are closed, Accordingly, the dehumidifying air flowing through the opening / closing valve 254 flows into the lower side of the second adsorption tower 114.

The dehumidifying air passes through the lower part of the second adsorption tower 114 in an upward direction.

The dehumidifying air introduced into the second adsorption tower 114 is in contact with the adsorbent therein, and the moisture is completely removed to be replaced with the dry air, which is then discharged to the outside through the post-treatment filter 140. The fifth and eighth open / close valves 272 and 278 of the second direction switch valve 270 are closed so that the dehumidified dry air can be discharged to the outside, and the sixth and seventh open / close valves 274 and 276 are closed Should be open.

Fig. 3 is a schematic view showing the air flow in the second process (cooling regeneration and dehumidification process) in Fig. 1. Fig.

3, the humid air introduced from the outside is compressed to a high temperature (about 100 to 160 ° C.) and a high pressure (about 7.0 kg / cm 2) by the compressor 120, .

The high-temperature regeneration air removes foreign matter through the pretreatment filter 130.

The high-temperature regeneration air from which the foreign substance is removed flows into the first cooler 150.

The open / close valves 244, 246, and 252 provided on the circulation pipe for cooling regeneration are opened so that the high temperature regeneration air flows into the first cooler 150 and circulates through the circulation pipe for cooling regeneration, The on-off valves 242, 248, and 254 provided on the circulation pipe for the intake pipe 242 must be closed.

This is because the high temperature regeneration air flows directly into the first adsorption tower 112 without passing through the first cooler 150 or the regeneration air passing through the first adsorption tower 112 does not leak to another place, 170 so as to maintain a predetermined cooling regeneration circulation path.

The high-temperature regeneration air introduced into the first cooler 150 is cooled to about 40 ° C through the first cooler 150. After the foreign material including moisture is removed from the first separator 160, Closing valves 254 and 248 and opening of the opening and closing valve 252 are introduced into the first adsorption tower 112 through the third opening and closing valve 266 which is the first direction switching valve 260.

At this time, the first and fourth open / close valves 262 and 268 of the first directional control valve 260 are controlled so that the cooled regeneration air flows into the first adsorption tower 112 and is not introduced into the second adsorption tower 114 And the second and third open / close valves 264 and 266 should be in the open state.

In addition, the on-off valves 244, 246, and 252 provided on the circulation pipe for cooling regeneration are opened and the on-off valves 242, 248, and 254 provided on the circulation pipe for heating regeneration must be closed, 1 is transferred to the second cooler 170 without passing through the adsorption tower 112, and the path for the predetermined cooling regeneration and dehumidification process is maintained.

The air for regeneration passes through the lower part of the first adsorption tower 112 in the upper direction.

The regeneration air introduced into the first adsorption tower 112 desorbs moisture of the adsorbent charged therein and is discharged through the seventh open / close valve 276 and the open / close valve 244 to the second cooler 170 . The regeneration air that has passed through the first adsorption tower 112 is prevented from flowing into the first adsorption tower 112 or the first adsorption tower 112 due to the closing of the open / close valves 242, 248, do.

The regeneration air having passed through the first adsorption tower 112 is cooled to about 40 ° C. through the second cooler 170 and then the foreign material including moisture is removed from the second separator 180, And flows into the first direction switching valve 260 side by closing the opening / closing valve 254.

At this time, the second and third opening / closing valves 264 and 266 of the first direction switching valve 260 are opened, the first opening / closing valve 262 and the fourth opening / closing valve 268 are closed, Accordingly, the dehumidifying air flowing into the first directional control valve 260 flows into the lower portion of the second adsorption tower 114.

At this time, since the first on-off valve 262 and the fourth on-off valve 268 of the first direction switching valve 260 are closed, the dehumidifying air is not directly introduced into the first adsorption tower 112.

The dehumidifying air passes through the lower part of the second adsorption tower 114 in an upward direction.

The dehumidifying air introduced into the second adsorption tower 114 is in contact with the adsorbent therein, and the moisture is completely removed to be replaced with the dry air, which is then discharged to the outside through the post-treatment filter 140. The fifth and eighth open / close valves 272 and 278 of the second direction switch valve 270 are closed so that the dehumidified dry air can be discharged to the outside, and the sixth and seventh open / close valves 274 and 276 are closed Should be open.

As described above, according to the present invention, the entire compressed air compressed through the compressor 120 is used for the regeneration process, and the regenerated air is dehumidified and discharged as dry air, so that a separate heater is not required , Maximizing energy efficiency, and reducing the processing cost for dry air treatment. In addition, the process can be simplified by the first process and the second process, and the dehumidification and regeneration process time can be reduced.

The foregoing description of the embodiments is merely illustrative of the present invention with reference to the drawings for a more thorough understanding of the present invention, and thus should not be construed as limiting the present invention. It will be apparent to those skilled in the art that various changes and modifications may be made without departing from the basic principles of the present invention.

110: adsorption tower 120: compressor
130: preprocessing filter 140: postprocessing filter
150: first cooler 160: first separator
170: second cooler 180: second separator
240: opening / closing valves 260: first direction switching valve
270: second direction switching valve

Claims (6)

A compressor for compressing the air introduced from the outside and supplying all the compressed air to the high-temperature regeneration air;
In the first step, the high-temperature regeneration air supplied through the compressor passes through from the upper portion to the lower portion so that the adsorbent is heated and regenerated. In the second step, low-temperature regeneration air flows from the lower portion to the upper portion A recovery adsorption tower through which the adsorbent is cooled and regenerated while passing through the adsorption tower;
An adsorption tower for dehumidifying which is filled with an adsorbent therein and is dehumidified while the dehumidifying air passes through from the bottom to the top in the first and second steps;
In the first step, the regeneration air discharged from the regeneration adsorption tower is cooled and supplied to the adsorption tower for dehumidification as the dehumidification air. In the second step, the high temperature regeneration air supplied from the compressor is cooled And supplying it to the adsorption tower for regeneration as low-temperature regeneration air;
And a second cooler for cooling the regeneration air discharged from the adsorption tower for regeneration in the second step and supplying it to the adsorption tower for dehumidification with the dehumidification air. The air drying system according to claim 1,
Wherein the first adsorption tower and the second adsorption tower are alternately used for the regeneration adsorption tower or the dehumidification adsorption tower for use in air drying system. The air drying system according to claim 2,
A first direction switching valve installed at a lower portion of the first adsorption tower and the second adsorption tower for switching a transfer direction of air introduced into the first adsorption tower and the second adsorption tower or discharged from the first adsorption tower and the second adsorption tower;
And a second direction switching valve installed on the first adsorption tower and the second adsorption tower for switching the direction of air flowing into the first adsorption tower and the second adsorption tower or air discharged from the first adsorption tower and the second adsorption tower However,
Wherein the first direction switching valve comprises a first on-off valve and a second on-off valve for respectively introducing dehumidification air to the dehumidifying adsorption tower, a third on-off valve for circulating air regenerated from the regeneration adsorption tower, A fourth on-off valve,
The second direction switching valve includes a fifth opening / closing valve and a sixth opening / closing valve for discharging the air dehumidified from the dehumidifying adsorption tower to the outside, and a seventh opening / closing valve for opening / An opening / closing valve, and an eighth open / close valve. The method according to claim 1,
The first step is a step of regenerating the regeneration adsorption tower by using all of the compressed air compressed and supplied by the compressor as high temperature regeneration air to regenerate the regeneration air discharged from the regeneration adsorption tower, Dehumidifying step for dehumidifying the dehumidifying adsorption tower and discharging the dry air to the outside,
The second step is a step of cooling the high temperature regeneration air supplied from the compressor and regenerating the regeneration adsorption tower as cold regeneration air to regenerate and regenerate the regeneration air discharged from the regeneration adsorption tower And dehumidifying the dehumidified air in the adsorption tower for desiccation and discharging the dry air to the outside as dehumidifying air. delete 1. An air drying method of an air drying system comprising a first adsorption tower and a second adsorption tower which are filled with an adsorbent and alternately switched to an adsorption tower for regeneration or an adsorption tower for dehumidification,
A first step of supplying all of the compressed air compressed through the compressor to the outside as high temperature regeneration air;
A second step of cooling the high-temperature regeneration air supplied from the compressor and supplying the low-temperature regeneration air to the regeneration adsorption tower;
A third step of cooling and regenerating the adsorption tower for regeneration while the low temperature regeneration air passes through the regeneration adsorption tower from the bottom to the top;
The regeneration tower is cooled and regenerated, the regeneration air is cooled again, and the regeneration air is supplied to the adsorption tower for dehumidification as dehumidification air, and the dehumidification air is dried in the adsorption tower for dehumidification to discharge the dry air to the outside And a fourth step of drying the air.

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