KR20180000854A - Air dryer - Google Patents

Abstract

Disclosed is an air dryer. According to an embodiment of the present invention, the air dryer comprises: a pair of drying tanks having a desiccant formed therein, and performing a drying process in which humid compressed air passes and is dried and a regeneration process in which the desiccant which has absorbed moisture in the drying process is dried; and a high-temperature air supply unit supplying high-temperature air heated by introducing outside air into each of the drying tanks when each of the drying tanks performs a regeneration process, wherein when one of the pair of drying tanks alternatively performs the drying process, the remainder performs the regeneration process, and the high-temperature air supplied into the drying tank, in which the regeneration process is performed, among the pair of drying tanks by the high-temperature air supply unit is discharged to the outside of the drying tank, in which the regeneration process is performed, to preheat outside air introduced into the high-temperature air supply unit. According to the present invention, it is possible to prevent energy from being wasted in the process of drying compressed air.

Description

Air dryer {Air dryer}

The present invention relates to an air dryer, and more particularly to an air dryer for drying moist compressed air.

Generally, ships store compressed air for various applications.

The compressed air can be compressed and stored through an air compressor or the like. Compressed air may contain moisture during the compression process. The moisture contained in such compressed air may damage equipment using compressed air.

An air dryer is usually used to solve the above problems. The air dryer can dry humidified compressed air containing moisture. For example, the air drier may include a drying tank in which a desiccant is formed. In this case, the drying tank can perform a drying process in which moist compressed air passes and drying, and a regeneration process in which hot air is supplied into the drying tank to dry the moisture absorbent absorbing moisture in the drying process.

On the other hand, the high-temperature air used in the regeneration process can be supplied by heating the air outside the drying tank. At present, the high-temperature air thus supplied is discharged to the outside of the ship with a considerable amount of heat after being used in the regeneration process. Therefore, there is a problem that considerable energy is wasted in the process of drying the compressed air.

An embodiment of the present invention is to provide an air dryer capable of preventing waste of energy in the process of drying compressed air.

According to an aspect of the present invention, there is provided a drying apparatus comprising: a pair of drying tanks for performing a drying process in which a moisture absorbent is formed therein and humidified compressed air passes through the drying process and a regeneration process for drying the moisture absorbent in the drying process; And a high-temperature air supply unit for supplying high-temperature air heated by flowing outside air into each of the drying tanks when the drying tanks perform the regeneration process, wherein the pair of drying tanks are alternately The high temperature air supplied to the inside of the drying tank in which the high temperature air supply unit is regenerated among the pair of the drying tanks is discharged to the outside of the drying tank in which the regeneration process is performed, An air dryer may be provided to preheat the outside air flowing into the hot air supply unit.

Wherein the high-temperature air supply unit includes: a blowing device for introducing outside air into the pair of drying tanks; A pair of supply valves interposed between the drying tanks and the blower; And a heating device for heating the outside air supplied by the blowing device, wherein each of the supply valves is opened when the corresponding drying tank performs the regeneration process, and can be closed when performing the drying process.

Wherein the outside air is supplied to each of the drying tanks through a supply line, the supply line includes an inlet line and a pair of branch lines branched from the inlet line and connected to the respective drying tanks, And each of the supply valves may be disposed on each branch line.

The heating devices may be provided as a pair, and each of the heating devices may be disposed on each of the branch lines.

Each of the branch lines may extend into each of the drying tanks, and each of the heating devices may be disposed inside each of the drying tanks.

The heating device may be disposed on the inflow line.

Wherein each of the drying tanks is provided with a hot air discharge line for discharging the hot air when each drying tank performs the regeneration process, a discharge valve is disposed in each of the hot air discharge lines, A corresponding drying tank is opened when performing the regeneration process and may be closed when performing the drying process.

Each of the hot air discharge lines may have a heat exchangeable structure with a supply line for supplying outside air to the drying tanks.

Each of the high temperature air discharge lines may be combined to form an integrated discharge line, and the integrated discharge line may have a structure capable of exchanging heat with a supply line for supplying external air to the respective drying tanks.

According to the embodiment of the present invention, the waste heat generated during the regeneration process can be reused for preheating the outside air supplied to the drying tank for the regeneration process, thereby saving energy for heating the outside air used for the regeneration process.

1 is a view showing an air dryer according to an embodiment of the present invention.
Fig. 2 is a view showing a modification of the heating apparatus of Fig. 1;
3 and 4 are views for explaining the operation of the air dryer according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Referring to the accompanying drawings, the same or corresponding components are denoted by the same reference numerals, do. In the following description, terms such as first and second terms are used to describe various components, and the meaning is not limited to itself, and is used only for the purpose of distinguishing one component from another component do.

1 is a view showing an air dryer according to an embodiment of the present invention.

Referring to FIG. 1, an air dryer 100 according to an embodiment of the present invention includes a pair of drying tanks 110a and 110b and a hot air supply unit 120, and can dry humidified compressed air.

Each of the drying tanks 110a and 110b performs a drying process and a regeneration process.

The drying process is a process in which wet compressed air passes through the inside of the drying tanks 110a and 110b and is dried.

To this end, a moisture absorbent (not shown) is formed in each of the drying tanks 110a and 110b. The moisture absorber can be made of various materials capable of absorbing moisture. In this case, moist compressed air can be absorbed by moisture absorbed in the moist compressed air and dried.

1, compressed air inflow lines 161a and 161b through which wet compressed air flows and compressed air inflow lines 161a and 161b for opening and closing compressed air inflow lines 161a and 161b are formed in one side of each of the drying tanks 110a and 110b, Inlet valves 162a and 162b may be formed. Compressed air discharge lines 164a and 164b for opening and closing compressed air discharge lines 163a and 163b and compressed air discharge lines 163a and 163b through which dry compressed air is discharged are provided on the other side of each of the drying tanks 110a and 110b. May be formed.

In this case, wet compressed air flows through the compressed air inflow lines 161a and 161b of the drying tanks 110a and 110b where the drying process is performed, and the dried compressed air is supplied to the drying tanks 110a and 110b ) Compressed air discharge lines 163a, 163b.

The regeneration step is a step of drying the moisture absorbent absorbing moisture in the drying step. At this time, the moisture absorbent can be dried by evaporating the moisture by the hot air supplied by the hot air supply unit 120 described later.

The pair of drying tanks 110a and 110b alternately perform one drying process and the remainder perform the regeneration process. In other words, the pair of drying tanks 110a and 110b can alternately perform the drying process and the regeneration process in succession.

When the drying tanks 110a and 110b perform the regeneration process, the hot air supply unit 120 supplies hot air heated by flowing the outside air into the drying tanks 110a and 110b. In other words, the hot air supply unit 120 can selectively supply the hot air to the drying tanks 110a and 110b in which the regeneration process is performed among the pair of the drying tanks 110a and 110b.

Here, the outside air may be air introduced from the air outside the air dryer 100 or air introduced from an air storage tank (not shown) provided separately.

In this embodiment, the hot air supply unit 120 may include a blower 121, a pair of supply valves 122a and 122b, and heating devices 123a and 123b.

The air blowing device 121 introduces outside air and supplies it to the pair of drying tanks 110a and 110b. For example, the blowing device 121 may include a blower (not shown), but this is merely an example, and it is needless to say that various devices capable of moving and moving outside air are possible.

At this time, the outside air can be supplied to the drying tanks 110a and 110b through the supply line 130. [ Such a supply line 130 may include an inlet line 131 and a pair of branch lines 132a and 132b.

The inflow line 131 extends outside the pair of drying tanks 110a and 110b so that the outside air moves toward the pair of drying tanks 110a and 110b as shown in FIG.

The pair of branch lines 132a and 132b branch off the inflow line 131 and are connected to the drying tanks 110a and 110b.

The blowing device 121 may be disposed on the inflow line 131 as shown in Fig. In this case, the outside air is introduced into the air blowing device 121 through the inflow line 131 by the operation of the air blowing device 121, and is supplied to the pair of drying tanks 110a, 110b.

On the other hand, although not shown, the blowing devices are provided as a pair, and can be disposed on the pair of branch lines, respectively.

A pair of supply valves 122a and 122b are interposed between the drying tanks 110a and 110b and the air blowing device 121. [ At this time, the supply valves 122a and 122b may be disposed on the respective branch lines 132a and 132b. In this case, the supply valves 122a and 122b can open and close the branch lines 132a and 132b.

Each of the supply valves 122a and 122b is opened when the corresponding drying tanks 110a and 110b perform the regeneration process and is closed when performing the drying process. In this case, the outside air can be selectively supplied to the drying tanks 110a and 110b in which the regeneration process is performed among the pair of the drying tanks 110a and 110b by the opening and closing operations of the supply valves 122a and 122b.

The heating devices 123a and 123b heat the outside air supplied by the air blowing device 121. [

For example, the heating devices 123a and 123b may be provided as a pair as shown in FIG. At this time, the heating devices 123a and 123b are disposed on the respective branch lines 132a and 132b. In this case, the heating devices 123a and 123b can heat the outside air moving through the branching lines 132a and 132b by the air blowing device 121. [

1, the branching lines 132a and 132b extend into the drying tanks 110a and 110b and the heating devices 123a and 123b may be disposed inside the drying tanks 110a and 110b have. In this case, the outside air moving through the branch lines 132a and 132b is heated inside the drying tanks 110a and 110b to become hot air, and each of the branch lines 132a and 132b supplies hot air to each drying tank 110a , 110b.

As another example, the heating device 123 'may be disposed on the inflow line 131 as shown in FIG. In this case, one heating device 123 'may be provided. 2 is a view showing a modification of the heating apparatus of FIG.

According to the present embodiment, the hot air supplied to the inside of the drying tanks 110a and 110b in which the hot air supply unit 120 performs the regeneration process among the pair of the drying tanks 110a and 110b is supplied to the drying tank (110a, 110b) and preheats the outside air flowing into the hot air supply unit (120).

1, hot air discharge lines 140a and 140b for discharging hot air may be formed in the drying tanks 110a and 110b when the drying tanks 110a and 110b perform the regeneration process .

Discharge valves 141a and 141b may be disposed in the respective hot air discharge lines 140a and 140b. In this case, the discharge valves 141a and 141b can open / close the respective hot air discharge lines 140a and 140b.

Each of the discharge valves 141a and 141b is opened when the corresponding drying tanks 110a and 110b perform the regeneration process and can be closed when performing the drying process. In this case, the high-temperature air supplied into the drying tanks 110a and 110b in which the regeneration process is performed is a drying tank in which the regeneration process is performed through the high-temperature air discharge lines 140a and 140b after drying the moisture absorbent (not shown) (110a, 110b).

At this time, the hot air discharged to the outside of the drying tanks 110a and 110b can maintain a high temperature state. The hot air can preheat the outside air flowing into the hot air supply unit 120 at a relatively low temperature.

In this case, the high-temperature air supply unit 120 can save energy for heating the outside air to supply hot air by recycling the waste heat used in the regeneration process and preheating the outside air flowing into the drying tanks 110a and 110b .

For example, although each hot air discharge line is not shown, it may have a heat exchangeable structure with a supply line for supplying outside air to each drying tank.

As another example, each of the hot air discharge lines 140a and 140b may be combined to form an integrated discharge line 150 as shown in FIG. At this time, the integrated discharge line 150 may have a heat exchange structure with the supply line 130 for supplying the outside air to the drying tanks 110a and 110b.

For example, a portion of the integrated discharge line 150 may be formed in the form of a coil around a portion of the supply line 130, as shown in FIG. In this case, the integrated discharge line 150 in the form of a coil may increase the area of heat exchange with the supply line 130.

It is needless to say that various methods of heat exchange with the outside air having a relatively low temperature state in which the hot air having a relatively high temperature moving through the supply line is possible.

3 and 4 are views for explaining the operation of the air dryer according to an embodiment of the present invention.

3 and 4, the operation of the air dryer 100 according to an embodiment of the present invention will be described. The air dryer 100 according to the present embodiment is installed in a ship (not shown) to dry the compressed air necessary for the ship.

3 and 4, the drying tank 110a on the left side is referred to as a first drying tank 110a and the drying tank 110a on the right side is referred to as a drying tank 110a. The tank 110a is referred to as a second drying tank 110a and the lines and valves corresponding to the drying tanks 110a and 110b are given first and second reference numerals.

Referring to FIG. 3, the first drying tank 110a may perform a drying process.

In this case, the first compressed air inlet valve 162a is opened, and the humidified compressed air flows into the first drying tank 110a through the first compressed air inflow line 161a. The first compressed air discharge valve 164a is opened and the dried compressed air is discharged to the outside of the first drying tank 110a through the first compressed air discharge line 163a.

Then, the first supply valve 122a is closed, and the first heating device 123a stops operating. In this case, the hot air is prevented from being supplied into the first drying tank 110a. Further, the first drying tank 110a can be prevented from mixing the compressed air and the hot air while the drying process is performed.

While the first drying tank 110a performs the drying process, the second drying tank 110b can perform the regeneration process.

In this case, the second compressed air inlet valve 162b is closed, and the second compressed air outlet valve 164b is closed. In this case, the second drying tank 110b is prevented from entering wet compressed air during the regeneration process.

And the second supply valve 122b is opened. In this case, the outside air introduced by the air blowing device 121 can be moved to the second drying tank 110b through the second branch line 132b.

The second heating device 123b operates. In this case, the hot air is supplied into the second drying tank 110b to dry the moisture absorbent (not shown).

The second discharge valve 141b is opened and the hot air dried by the moisture absorbent is discharged to the outside of the second drying tank 110b through the second hot air discharge line 140b. At this time, the hot air moving through the second hot air discharge line (140b) moves to the heat exchange area of the integrated discharge line (150), preheats the outside air moving through the inflow line (131) And can be discharged to the outside.

On the other hand, the first drying tank 110a and the second drying tank 110b can alternately perform the drying process and the regeneration process according to the set conditions (for example, the set time).

Referring to FIG. 4, when the set conditions are satisfied, the first drying tank 110a that has performed the drying process can perform the regeneration process.

In this case, the first compressed air inlet valve 162a is closed, and the first compressed air outlet valve 164a is closed. In this case, the first drying tank 110a is prevented from entering the humidified compressed air during the regeneration process.

And the first supply valve 122a is opened. In this case, the outside air introduced by the air blowing device 121 can be moved to the first drying tank 110a through the first branch line 132a.

The first heating device 123a operates. In this case, the hot air is supplied into the first drying tank 110a to dry the moisture absorbent (not shown).

The first discharge valve 141a is opened and the hot air dried by the moisture absorbent is discharged to the outside of the first drying tank 110a through the first hot air discharge line 140a. At this time, the hot air moving through the first hot air discharge line (140a) moves to the heat exchange area of the integrated discharge line (150), preheats the outside air moving through the inflow line (131) And can be discharged to the outside.

While the first drying tank 110a performs the regeneration process, the second drying tank 110b performing the regeneration process may perform the drying process.

In this case, the second compressed air inlet valve 162b is opened, and the humidified compressed air flows into the second drying tank 110b through the second compressed air inflow line 161b. The second compressed air discharge valve 164b is opened and the dried compressed air is discharged to the outside of the second drying tank 110b through the second compressed air discharge line 163b.

Then, the second supply valve 122b is closed, and the second heating device 123b is stopped. In this case, the hot air is prevented from being supplied into the second drying tank 110b. In addition, the second drying tank 110b can be prevented from mixing the compressed air and the hot air while the drying process is performed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, many modifications and changes may be made by those skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims. The present invention can be variously modified and changed by those skilled in the art, and it is also within the scope of the present invention.

100: air dryer
110a, 110b: Drying tank
120: high temperature air supply
121: blower
122a and 122b:
123a, 123b, 123 ': Heating device
130: Supply line
131: Inflow line
132a, 132b: branch line
140a, 140b: hot air discharge line
141a, 141b: discharge valve
150: Integrated discharge line
161a, 161b: compressed air inflow line
162a, 162b: Compressed air inflow valve
163a, 163b: compressed air discharge line
164a, 164b: Compressed air discharge valve

Claims (9)

A pair of drying tanks for performing a drying process in which a moisture absorbent is formed inside and a wet compressed air is passed through and a regeneration process for drying the moisture absorbent in the drying process; And
And a high-temperature air supply unit for supplying high-temperature air heated by flowing outside air into the drying tanks when the drying tanks perform the regeneration process,
Wherein one of the pair of drying tanks alternately performs the drying process, the other performs the regeneration process,
Wherein the high temperature air supplied to the inside of the drying tank in which the regeneration process is performed is discharged to the outside of the drying tank in which the regeneration process is performed to preheat the outside air flowing into the hot air supply unit, Air dryer. The method according to claim 1,
Wherein the high-
A blowing device for introducing outside air into the pair of drying tanks;
A pair of supply valves interposed between the drying tanks and the blower; And
And a heating device for heating the outside air supplied by the air blowing device,
Wherein each of the supply valves is opened when a corresponding drying tank performs the regeneration process and is closed when performing the drying process. 3. The method of claim 2,
The outside air is supplied to each of the drying tanks through a supply line,
Wherein the supply line includes an inlet line and a pair of branch lines branched from the inlet line and connected to the respective drying tanks,
Wherein the blowing device is disposed on the inflow line,
Wherein each of the supply valves is disposed on each of the branch lines. The method of claim 3,
The heating apparatus is provided in a pair,
Wherein each of the heating devices is disposed on each of the branch lines. 5. The method of claim 4,
Each branch line extending into each drying tank,
Wherein each of the heating devices is disposed inside each of the drying tanks. The method of claim 3,
Wherein the heating device is disposed on the inflow line. The method according to claim 1,
Wherein each of the drying tanks is provided with a hot air discharge line for discharging the hot air when each drying tank performs the regeneration process,
A discharge valve is disposed in each of the hot air discharge lines,
Wherein each of the discharge valves is opened when a corresponding drying tank performs the regeneration process and is closed when performing the drying process. 8. The method of claim 7,
Wherein each of the hot air discharge lines has a heat exchangeable structure with a supply line for supplying outside air to each of the drying tanks. 8. The method of claim 7,
Wherein each of the hot air discharge lines combine to form an integrated discharge line,
Wherein the integrated discharge line has a heat exchangeable structure with a supply line for supplying outside air to each of the drying tanks.

Images