KR101093812B1 - cooling tower - Google Patents

Abstract

The present invention relates to a cooling tower that effectively prevents the generation of white smoke of air discharged by heat exchange in a filler. Cooling tower according to an embodiment of the present invention comprises a body, a filler, a fan assembly and a heat exchange unit. Here, the main body forms an outline. The filler is provided inside the main body to allow heat exchange with the air flowing from the outside of the main body. The fan assembly is provided at the top of the main body so that the heat exchanged air is discharged to the outside of the main body while passing through the filler. And, the heat exchange unit is provided with a plurality of predetermined intervals between the filler and the fan assembly to form an air flow path for guiding the flow of humid air discharged from the filler and the heat exchange water movement to transfer the high-temperature heat exchanger from the inside The eliminator is formed of a structure that is formed by the heat is heated by the high-temperature heat exchange water, the air is heated and discharged, the first tank is provided on one side of the eliminator to supply the high-temperature heat exchange water to the inside of the eliminator, and the eliminator It includes a second water tank provided on the other side to collect the heat exchange water passing through the eliminator to supply to the filler material to prevent the coolant from scattering from the filler material, and to guide the flow of humid air discharged from the filler material to heat the fan White smoke from the air exiting the assembly It is to be suppressed, and the outside of the structure is formed to protrude into the air flow path, the bending formed in the opposite direction of the air flow conveyed through the air flow path to trap the moisture vapor contained in the air moving through the air flow path The addition is formed.

Heat exchanger unit, eliminator, cooling tower, white smoke, water vapor, removal

Description

Cooling tower

The present invention relates to a cooling tower, and more particularly to a cooling tower that effectively prevents the generation of white smoke of air discharged to the outside after heat exchange with the cooling water.

In general, a cooling tower is used in a heat exchanger or an air conditioner such as a refrigerator to cool down the heat of hot water sent from a high-temperature condenser after heat exchange and continuously recycle the low-temperature cooling water.

In order to remove heat from the cooling water, which has become a high temperature, various types of structures and methods have been applied. Such cooling towers are frequently used for cooling with air.

As a method of using air, a method of spraying or dropping high-temperature cooling water onto a filling material, and forcibly blowing air to the filling material by means of natural ventilation or a blower is used to cool the cooling water.

These cooling towers are roughly divided into cross flow type, counter flow type and hybrid type according to the heat exchange method. The cross flow type crosses the hot cooling water and the air introduced from the outside at right angles. The cooling water is cooled, and the counterflow type allows the cooling water to cool as the hot cooling water and the air introduced from the outside face each other in opposite directions. In addition, the hybrid type is made of a combination of cross-flow type and countercurrent type so that the cooling water is cooled.

However, the conventional cooling tower has the following problems.

First, the air cooled by the coolant in the filling material contains a large amount of water vapor, and as air in this state is discharged to the outside, a plume phenomenon occurs, which may be misunderstood as harmful substances emitted when viewed from the outside. Have possession.

Second, as the air that cools the cooling water in the filler includes a large amount of water vapor, there is a problem that the blowing fan or the blowing fan drive unit, which is in contact with a lot of air, is frozen in winter, and thus the performance of the device may be degraded.

Therefore, there is a need for a cooling tower that not only effectively removes water vapor contained in the air discharged after heat exchange, but also implements a device for removing water vapor more economically.

In order to solve the above problems, the technical problem to be achieved by the present invention is to provide a cooling tower that effectively prevents the generation of white smoke of air discharged to the outside after heat exchange with the cooling water.

In order to achieve the above technical problem, the present invention forms a main body; A filler provided inside the main body to exchange heat between the air introduced from the outside of the main body and the cooling water; A fan assembly provided at an upper portion of the main body to allow the heat exchanged air to be discharged to the outside of the main body while passing through the filler; And provided between the filler and the fan assembly to prevent cooling water from scattering from the filler and to guide the flow of humid air discharged from the filler to generate white smoke of air discharged to the fan assembly. It comprises a heat exchange unit to be suppressed, the heat exchange unit is provided with a plurality at predetermined intervals to form an air flow path for guiding the flow of humid air discharged from the filler and the inside of the high temperature heat exchange water transfer A heat exchanger is formed so that a heat exchanger moving path is formed to be heated by the high temperature heat exchanger, and is provided on one side of the eliminator so that the air is heated and discharged, and the high-temperature heat exchanger is supplied to the inside of the eliminator. The first tank and the table And a second water tank provided on the other side of the eliminator to collect heat exchange water passing through the eliminator to supply the filler to the outside of the structure, and protrude into the air flow passage on the outside of the structure, through the air flow passage. It provides a cooling tower is formed in the opposite direction of the air flow to be conveyed to form a trap for filtering the wet steam contained in the air moving through the air flow path.

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Here, the heat exchange water movement path is preferably divided into a plurality of one or more partitions formed in the longitudinal direction of the heat exchange water movement path,

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Referring to the effect of the cooling tower according to the present invention.

First, the heat exchange unit comprises a heated eliminator so that the hot and humid air discharged from the filling material is heated and vaporized while passing through the eliminator, and the eliminator further includes a collecting part for filtering the wet steam in the air to form wet steam in the air. By removing, the occurrence of white smoke in the air discharged to the outside of the cooling tower can be effectively prevented.

Second, when the heating of the eliminator is made by high temperature cooling water (heat exchange water) circulated, economical efficiency can be improved since a separate device for heating the eliminator becomes unnecessary.

With reference to the accompanying drawings, preferred embodiments of the present invention that can specifically realize the above technical problem will be described.

1 is a front view schematically showing the configuration of a cooling tower according to a first embodiment of the present invention, Figure 2 is an exploded perspective view showing a heat exchange unit of the cooling tower according to the first embodiment of the present invention, Figure 3a and Figure 3b is a plan sectional view showing a heat exchange unit of a cooling tower according to the first embodiment of the present invention. In the cooling tower according to the present embodiment, a cross-flow cooling tower will be described as an example.

First, as shown in Figures 1 to 3a, the cooling tower is preferably made of a main body 10, the filler 20, the fan assembly 30 and the heat exchange unit 40. Here, in the filler 20 provided inside the main body 10, the air flowing in from the outside of the main body 10 and the coolant are heat-exchanged, and the heat-exchanged air is transferred to the main body through the fan assembly 30. It is discharged to the outside of the (10). On the other hand, the heat exchange unit 40 is preferably provided between the filler 20 and the fan assembly 30. In addition, the heat exchange unit 40 preferably includes a heating wire 47 and an eliminator 41. Here, the plurality of eliminators 41 may be provided at predetermined intervals to guide the flow of air discharged from the filler 20, and prevent the coolant from scattering from the filler 20. In addition, it is preferable that the heating wire 47 is provided inside the eliminator 41 to generate heat. Accordingly, while the air passing through the eliminator 41 is heated, wet steam in the air can be removed. Through this, the occurrence of the white smoke phenomenon of the air discharged to the main body 10 can be suppressed.

Here, the cooling water refers to water that is recycled to a high temperature hot water by a high temperature condenser and then to a low temperature through heat exchange with air in the filler.

In detail, a fan assembly 30 is provided on an upper portion of the main body 10 forming the external shape of the cooling tower, wherein the fan assembly 30 includes a cylinder 31 connected to an upper portion of the main body 10; It may be made including a blowing fan 33 provided on the inside of the cylinder (31).

In addition, the air inlet portion 11 is formed on both side surfaces of the main body 10 so that outside air may flow into the inside of the main body 10, and the air inlet flows as the blowing fan 33 rotates. Air is introduced into the main body 10 through the unit 11.

In addition, a filler 20 is provided inside the main body 10, wherein the filler 20 may be provided at both sides of the main body 10 so as to be connected to the air inlet 11.

Here, the filler 20 is formed with a flow path through which the air flowing through the air inlet 11 is passed, for this purpose, the filler 20 is composed of a plurality of filling plates provided at a predetermined interval. Can be.

And, the upper side of the filler 20 is provided with an upper water tank 13 through which the coolant at a high temperature flows through heat exchange. At this time, the cooling water flowing into the upper water tank 13 may be supplied through the cooling water supply pipe 15.

The upper water tank 13 is formed to correspond to the upper surface shape of the filler 20, a plurality of decomposition holes may be formed on the bottom surface to discharge the introduced water.

Through this, the high temperature cooling water introduced into the upper water tank 13 can be uniformly dropped in the entire upper portion of the filler 20, the cooling water falling down while flowing down along the filler 20 Heat exchanged in contact with the air flowing through the air inlet 11 and moving.

Therefore, the cooling water passing through the filler 20 is cooled, and the air is in a high temperature and high humidity state.

Meanwhile, one side of the filler 20 through which air is discharged is preferably provided on the heat exchange unit 40, and the heat exchange unit 40 may include an eliminator 41 and a heating wire 47.

And, the eliminator 41 may be composed of a plurality of structures 42, the structure 42 is provided at a predetermined interval along the width direction of the filler 20 to discharge the air of the filler 20 It can be installed to correspond to the entire surface.

Here, the structure 42 is preferably formed to a height corresponding to the height of the filler 20, it may be formed to have a zigzag shape in the flow direction of the air discharged from the filler (20).

Accordingly, an air flow path 44 for guiding the flow of air discharged from the filler 20 is provided between the structures 42 provided at predetermined intervals along the width direction of the filler 20. Will be formed.

In this case, since the air flow path 44 has a zigzag shape by the shape of the structure 42, the structure (even if the coolant that has moved downward in the filler 20 is scattered to the outside of the filler 20). 42), it becomes difficult to pass through the air flow path 44.

Therefore, even though the coolant is scattered from the filler 20, it is prevented from being discharged through the air flow path 44 so that the recovery rate of the coolant collected after passing through the filler 20 can be maintained well.

In addition, the structure 42 preferably has a space 43 formed therein, and the space 43 is preferably provided with the heating wire 47.

At this time, the hot wire 47 is preferably provided to be widely distributed in the space 43 inside the structure 42 at uniform intervals.

Here, the heating wire 47 may be a heating wire that generates heat by receiving power, and a power unit (not shown) for supplying power may be connected to the heating wire 47.

Accordingly, the structure 42 is heated by the heat generated from the hot wire 47, the material of the structure 42 is excellent in heat transfer so that efficient heating is achieved by the heat generated from the hot wire 47 It is preferably made of a material.

In addition, the structure 42 is preferably made of a material having excellent heat resistance so that the shape is not deformed or broken by heat provided from the hot wire 47.

Therefore, the hot and humid air passing through the filler 20 can be vaporized while being further heated by the heat of the structure 42 while passing through the air flow path 44, whereby the wet steam in the air effectively Can be removed.

As the air from which the wet steam is removed is discharged to the outside of the main body 10 through the fan assembly 30, the white smoke phenomenon of the discharged air may be prevented.

On the other hand, it is preferable that a plurality of collecting portions 45 are formed to protrude further from the outside of the structure 42, wherein one end of the collecting portion 45 of the air flow moving through the air flow path 44 It is preferable to bend in the opposite direction.

In addition, the collecting unit 45 is preferably formed to extend in the height direction of the structure 42, accordingly, the collecting unit 45 is the air flow over the entire length of the structure 42 Protruding to 44 is formed.

Through this, when the hot and humid air discharged from the filler 20 is moved through the air flow path 44, the wet steam in the air is trapped by the collecting unit 45, the wet steam in the air is further filtered. It can be effectively removed.

As shown in FIG. 3B, the structure 42a and the collecting part 45a may be formed in a streamlined shape having a gentle shape so that the flow resistance of the air discharged from the filler 20 may be reduced. Of course, various shapes can be applied without being limited to the illustrated.

On the other hand, Figure 4 is a front view schematically showing the configuration of the cooling tower according to the second embodiment of the present invention, in the present embodiment will be described as the cooling tower is a countercurrent type cooling tower, the heat exchange unit of the present embodiment Since the basic configuration is the same as that of the first embodiment described above, the description is omitted.

As shown in Figure 4, the fan assembly 130 is provided on the upper portion of the main body 110 forming the outer shape of the cooling tower.

In addition, the air inlet 111 is formed through the lower side of the main body 110 so that the outside air flows into the inside of the main body 110.

In addition, the filler 120 is provided inside the main body 110. In this case, the filler 120 is preferably provided above the air inlet 111.

In addition, the upper side of the filler 120 may be supplied through the cooling water supply pipe 115 through the heat exchanger to the high temperature cooling water is injected through the distribution nozzle 116 to uniformly fall over the entire upper portion of the filler 120. The falling coolant flows down along the filler material 120 while flowing through the air inlet 111 and is then heat-contacted with the air moving upwards, whereby the coolant is cooled and air. Will be in a high temperature and high humidity state.

On the other hand, the upper side of the cooling water supply pipe 115 is preferably provided with a heat exchange unit 140 comprising an illuminator 141 and a heating wire 147, wherein the heat exchange unit 140 is the filler 120 It is preferable that all the air passing through) correspond to the horizontal cross section of the main body 110 so as to pass through the heat exchange unit 140.

Through this, the hot and humid air passing through the filler 120 may be vaporized while being further heated by the structure 142 of the heat exchange unit 140 while passing through the air flow path 144 of the heat exchange unit 140. Moisture vapor in the air can be effectively removed.

As the air from which the wet steam is removed is discharged to the outside of the main body 110 through the fan assembly 130, the white smoke phenomenon of the discharged air may be prevented.

5 is a front view schematically showing the configuration of a cooling tower according to a third embodiment of the present invention, Figure 6 is an exploded perspective view showing a heat exchange unit of a cooling tower according to a third embodiment of the present invention, Figure 7 3 is a planar view showing the eliminator of the cooling tower according to the third embodiment of the present invention. The cooling tower according to the present embodiment will be described as a cross-flow cooling tower as an example, and the configuration of the body, the fan assembly, the filler and the upper water tank of the cross-flow cooling tower is the same as the first embodiment described above and will not be described.

5 to 7, the fan assembly 30 is provided on the upper portion of the main body 10 forming the outer shape of the cooling tower, and the air inlet 11 is formed on both side surfaces of the main body 10. .

In addition, a filler 20 is provided inside the main body 10 to form a flow path through which the air introduced through the air inlet 11 passes.

In addition, the upper side of the filler 20 is provided with an upper water tank 13 through which the coolant at a high temperature flows through heat exchange, so that the coolant is supplied to the filler 20.

Meanwhile, it is preferable that a heat exchange unit 240 is provided at one side of the filler 20 through which air is discharged, and the heat exchange unit 240 includes an eliminator 241, a first tank 250, and a second tank 255. It can be made, including).

Here, the eliminator 241 is provided at a predetermined interval along the width direction of the filler 20 may be made of a plurality of structures 242 to be provided on the air discharge surface of the filler 20 as a whole. have.

Therefore, the structure 242 is preferably formed to a height corresponding to the height of the filler 20, it may be formed to have a zigzag shape in the flow direction of the air discharged from the filler (20).

Accordingly, an air flow path 244 for guiding the flow of air discharged from the filler 20 is provided between the structures 242 provided at predetermined intervals along the width direction of the filler 20. Will be formed.

At this time, since the air flow path 244 has a zigzag shape by the shape of the structure 242, even if the coolant that has moved downward in the filler 20 is scattered to the outside of the filler 20, the structure ( It is difficult to pass through the air flow path 244 by hitting the 242, it is possible to prevent the departure of the coolant.

In addition, the structure 242 preferably has a heat exchange water movement path 243 formed therein, and both ends of the structure 242 may be opened so that the heat exchange water movement path 243 is connected to the outside.

In addition, the first water tank 250 is provided on one side (preferably the lower side) of the eliminator 241, and the second water tank 255 is provided on the other side (preferably the upper side) of the eliminator 241. In this case, it is preferable that both ends of the structure 242 are connected to the first tank 250 and the second tank 255, respectively.

To this end, the first and second tanks 250 and 255 have coupling portions 251 having shapes corresponding to those of the structures 242 such that the ends of the structures 242 can be inserted or combined. The end of the structure 242 coupled to the coupling part 251 may be fixed by a method such as welding.

Accordingly, the inner side of the first tank 250, the structure 242 and the second tank 255 can communicate with each other.

In addition, a first heat exchange water supply pipe 252 may be connected to the first water tank 250, and the first heat exchange water supply pipe 252 may be cooled with a high temperature condenser by a high temperature condenser.

In addition, it is preferable that the second heat exchange water supply pipe 256 is connected to the second water tank 255, and the second heat exchange water supply pipe 256 is connected to the upper water tank 13.

At this time, a pump (not shown) may be further provided to allow the heat exchange water to move through the heat exchange water movement path 243. In addition, the inner side of the first tank 250 and the second tank 255 may be divided into a number of compartments (not shown) to correspond to the structure 242 is coupled, the heat exchange to each structure 242 A pump may be provided for each compartment so that the movement of the number can be performed smoothly.

Accordingly, the coolant, which has become high by a high temperature condenser, moves to the first water tank 250 through the first heat exchange water supply pipe 252, and the heat exchange water moving path connected to the first water tank 250 ( After moving upward through 243, the second tank 255 may be introduced.

Therefore, the respective structures 242 are heated by the high temperature heat exchange water passing through the heat exchange water movement path 243.

Then, the heat exchange water introduced into the second water tank 255 flows into the upper water tank 13 through the second heat exchange water supply pipe 256 and then falls to the filler 20 and flows into the air. After passing through the high temperature condenser again, the process of circulating to the first heat exchange water supply pipe 252 is performed.

On the other hand, as can be seen from the above, the heat exchange water is another name of the cooling water defined for convenience of description. That is, when the cooling water passes through the heat exchange unit 240 and the first and second heat exchange water supply pipes 250 and 255, it is referred to as heat exchange water, and when passing through the filler 20, the cooling water is referred to as cooling water.

Accordingly, the hot and humid air passing through the filler 20 may be further heated and vaporized by the heat of the respective structures 242 while passing through the air flow path 244. Can be effectively removed.

As the air from which the wet steam is removed is discharged to the outside of the main body 10 through the fan assembly 30, the white smoke phenomenon of the discharged air may be prevented.

As such, a separate device for heating the heat exchange unit 240 by being heated by heat exchange water (cooling water) circulating the heat exchange unit 240 for heating the high temperature and high humidity air passing through the filler 20 is It becomes unnecessary and the economical effect can be improved.

On the other hand, it is preferable that a plurality of collecting portions 245 are further protruded from the outside of the structure 242, wherein one end of the collecting portion 245 of the air flow to move through the air flow path 244 It is preferable to bend in the opposite direction.

In addition, the collecting part 245 is preferably formed to extend in the height direction of the structure 242, accordingly, the collecting part 245 is the air flow over the entire length of the structure 242 A protrusion is formed at 244.

Through this, when the hot and humid air discharged from the filler 20 is moved through the air flow path 244, the wet steam in the air is trapped by the collecting unit 245, the wet steam in the air is further filtered. It can be effectively removed.

In addition, one or more partitions 249 may be formed inside the heat exchange water moving path 243 in the longitudinal direction of the heat exchange water moving path 243. The heat exchange water can be more stably moved through the heat exchange water movement path 243 by being divided into two parts.

On the other hand, Figure 8 is a schematic front view showing the configuration of the heat exchange unit of the cooling tower according to the fourth embodiment of the present invention, in the present embodiment will be described as a case where the cooling tower is a countercurrent type cooling tower. Here, since the basic configuration of the heat exchange unit according to the present embodiment is the same as the above-described third embodiment, description thereof will be omitted.

As shown in Figure 8, the fan assembly 130 is provided on the upper portion of the main body 110 forming the outer shape of the cooling tower.

In addition, the air inlet 111 is formed through the lower side of the main body 110 so that the outside air flows into the inside of the main body 110.

In addition, the filler 120 is provided inside the main body 110, in which the filler 120 is provided above the air inlet 111.

In addition, the coolant at a high temperature through heat exchange is supplied to the upper side of the filler 120 through the cooling water supply pipe 315 to uniformly drop the entire upper portion of the filler 120 through the distribution nozzle 116. The falling coolant flows down along the filler material 120 and heat exchanges in contact with the air flowing upward through the air inlet 111 so that the coolant is cooled, and the air is hot and humid. It will be in a state.

On the other hand, the upper side of the cooling water supply pipe 315 is preferably provided with a heat exchange unit 340 comprising an eliminator 341, the first water tank 350 and the second water tank 355.

Here, the eliminator 341 is preferably formed to correspond to the horizontal cross section of the main body 110 so that all the air passing through the filler 120 may pass through the heat exchange unit 340.

The first tank 350 is provided at one side of the eliminator 341, and the second tank 355 is preferably provided at the other side of the eliminator 341. The eliminator 341 and the eliminator 341 are provided. The inner side of the first tank 350 and the second tank 355 is preferably connected to each other.

In addition, a first heat exchange water supply pipe 352 may be connected to the first water tank 350. Preferably, the first heat exchange water supply pipe 352 is transferred to the first heat exchange water supply pipe 352 by a high temperature condenser.

In addition, it is preferable that a second heat exchange water supply pipe 356 is connected to the second water tank 355, and the second heat exchange water supply pipe 356 is connected to the cooling water supply pipe 315.

Accordingly, the coolant, which has become high by the high temperature condenser, moves to the first water tank 350 through the first heat exchange water supply pipe 352 and moves the eliminator 341 connected to the first water tank 350. After moving through the second tank 355 can be introduced.

Thus, the eliminator 341 is heated by the high temperature heat exchange water passing through.

The heat exchange water introduced into the second water tank 355 is injected into the cooling water supply pipe 315 through the second heat exchange water supply pipe 356 and then sprayed to fall into the filler 120 to exchange heat with air. After passing through the high temperature condenser, the first heat exchange water supply pipe 352 is circulated.

Through this, the hot and humid air passing through the filler 120 can be vaporized while being further heated by the structure of the heat exchange unit 340 while passing through the air flow path of the heat exchange unit 340, and wet steam in the air. Can be effectively removed.

As the air from which the wet steam is removed is discharged to the outside of the main body 110 through the fan assembly 130, the white smoke phenomenon of the discharged air may be prevented.

9 is a front view schematically showing the configuration of a cross-flow cooling tower according to a fifth embodiment of the present invention. In the cross-flow cooling tower according to the present embodiment, the heat exchange water passing through the heat exchange unit described above in the third embodiment may have a separate circulation cycle, and other configurations are the same as in the above-described third embodiment, and thus description thereof is omitted.

As shown in Figure 9, the upper water tank 13 provided on the upper side of the filler 20 can be supplied to the cooling water of the high temperature by the high temperature condenser through the cooling water supply pipe 15, the filler 20 The cooling water cooled while passing through is collected and circulated, and is heated again by the condenser to repeat the above-described process.

The heat exchange water passing through the heat exchange unit 440 may have a separate heat exchange water circulation cycle 400 different from the cooling water circulation cycle.

For example, the first heat exchange water supply pipe 452 connected to the first water tank 450 is connected to the second heat exchange water supply pipe 456 connected to the second water tank 455 to form the heat exchange water circulation cycle 400. ) Can be formed.

At this time, the heat exchange water circulation cycle 400 may be further provided with a pump 401 for allowing the heat exchange water to move and a heater 402 for heating the heat exchange water.

As described above, the present invention is not limited to the above-described specific preferred embodiments, and various modifications by those skilled in the art to which the present invention pertains without departing from the gist of the present invention claimed in the claims. Implementations are possible and such variations are within the scope of the present invention.

1 is a front view schematically showing the configuration of a cooling tower according to a first embodiment of the present invention.

Figure 2 is an exploded perspective view showing a heat exchange unit of the cooling tower according to the first embodiment of the present invention.

Figure 3a and Figure 3b is a cross-sectional view showing a heat exchange unit of the cooling tower according to the first embodiment of the present invention.

Figure 4 is a front view schematically showing the configuration of a cooling tower according to a second embodiment of the present invention.

5 is a front view schematically showing the configuration of a cooling tower according to a third embodiment of the present invention.

6 is an exploded perspective view showing a heat exchange unit of a cooling tower according to a third embodiment of the present invention.

7 is a planar view showing the eliminator of the cooling tower according to the third embodiment of the present invention.

8 is a front view schematically showing the configuration of a heat exchange unit of a cooling tower according to a fourth embodiment of the present invention.

9 is a front view schematically showing the configuration of a cross-flow cooling tower according to a fifth embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

10,110: main body 11,111: air inlet

13: Upper water tank 15,115,315: Cooling water supply pipe

20,120: filler 30,130: fan assembly

40,140,240,340,440: heat exchange unit

41,41a, 141,241,341: Eliminator

42,142,242: Structure 44,244: By air flow

45,45a, 245: collecting part 47,147: heating wire

243: heat exchange path 249: bulkhead

250, 350, 450: first tank 251: coupling portion

252,352,452: 1st heat exchange water supply pipe 255,355,455: 2nd water tank

256,356,456: second heat exchange water supply pipe 400: heat exchange water circulation cycle

Claims (6)

A body forming an appearance; A filler provided inside the main body to exchange heat between the air introduced from the outside of the main body and the cooling water; A fan assembly provided at an upper portion of the main body to allow the heat exchanged air to be discharged to the outside of the main body while passing through the filler; And It is provided between the filler and the fan assembly to prevent the coolant from scattering, and to guide the flow of humid air discharged from the filler while heating the air to generate white smoke of the air discharged to the fan assembly It comprises a heat exchange unit to be suppressed, The heat exchange unit is provided with a plurality of at a predetermined interval to form an air flow path for guiding the flow of humid air discharged from the filler and inside the heat exchange water movement path is formed to transfer the high temperature heat exchange water is formed An eliminator configured to be heated by heat exchange water to allow the air to be heated and discharged, a first water tank provided at one side of the eliminator to supply high-temperature heat exchange water to the inside of the eliminator, and the other side of the eliminator It is configured to include a second tank for supplying the filling material to the heat exchange water passing through the eliminator, An outer portion of the structure is formed to protrude into the air flow path, the bending portion formed in the opposite direction of the air flow conveyed through the air flow path to filter the moisture vapor contained in the air moving through the air flow path Cooling tower formed. delete delete The method of claim 1, The heat exchange water movement path is divided into a plurality of cooling towers by one or more partitions formed in the longitudinal direction of the heat exchange water movement path. delete delete

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