KR100730295B1 - Cooling tower - Google Patents

Abstract

In order to improve the flow of air flowing inside the cooling tower, the cooling tower according to the present invention comprises a main body having an air inlet formed in the side; A filler provided inside the main body and guiding movement of the coolant to facilitate heat exchange between the outside air and the coolant sucked from the air inlet; A cooling fan that sucks outside air from the air suction port and blows the air through the filler; And provided in the air inlet, the guide portion is arranged in a multi-stage with a cross section is formed gradually closer to the horizontal toward the air inlet and the slope is smaller, and the outside air sucked in the front end of each of the guide portion to the guide portion smoothly Including the round portion is formed to be rounded, it is preferable that the air to be guided to be sucked with inertia in the horizontal direction along the guide portion arranged in multiple stages.

Cooling Tower, Filling Material, Air Guide, Shut Off Guide

Description

Cooling tower

1 is a partial cutaway front view of a cooling tower according to the prior art;

Figure 2 is a partial cutaway front view of a cooling tower according to an embodiment of the present invention.

Figure 3 is a perspective view of the air guide provided in the cooling tower according to an embodiment of the present invention.

Figure 4 is a partial cutaway front view of a cooling tower according to another embodiment of the present invention.

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

10: main body 12: cooling fan

14: air intake port 16: upper water tank

18: nozzle 20: filler

22: baffle 24: fan cylinder

30: blocking guide 40: air guide

42: guide portion 44: round portion

46: coupling portion 100: cooling tower

The present invention relates to a cooling tower, and more particularly to a cooling tower having an improved structure.

In general, the cooling tower is a type of heat exchanger that cools the cooling water by directly contacting the outdoor air in order to use the cooling water used in the condenser of the refrigerator again. That is, the cooling tower is a part of the cooling water is evaporated when the high-temperature cooling water after the heat exchange in the refrigerator, heat exchanger or well-known conditioning equipment and the like contact with the low-temperature dry air, at this time takes the latent heat required for evaporation to lower the water temperature It is a device converting into cooling water.

In addition, the cooling tower may be classified according to the relative relationship between the intake air and the flow of cooling water to be sprinkled, the counterflow type cooling tower is a structure in which the air flow in the charging section is moved in the vertical direction to cross the heat exchange and cross the heat exchange, Ryu cooling tower is a structure in which the air flow in the charging section is moved in the horizontal direction to cross the heat exchange with the coolant at a right angle.

The cross-flow cooling tower is subdivided by the number of layers and air intakes of the fillers associated with each top plate, and the two-sided suction type and one that induces air through the two inlets and the fillers located at two locations on both sides of the case. It may be subdivided into a single suction with a suction port and one filler and the remaining three directions.

1 is a partial cutaway front view of a cooling tower according to the prior art.

As shown in FIG. 1, the cooling tower 100 is installed on a rooftop of a building, and is provided at an upper portion of the cooling tower 100 to cool air 12 to suck external air, and to drive the cooling fan 12. Air inlet 14 through which external air is introduced, an upper water tank 16 containing high temperature and high humidity coolant, a nozzle 18 provided below the upper water tank 16, and an air intake air 14 through which external air is sucked. It consists of a filler 20 provided inside the.

Here, the upper tank 16 having the nozzle 18 in the lower portion is a high-temperature cooling water is introduced after the heat exchange, the high-temperature cooling water introduced into the upper tank 16 is provided in the lower portion of the upper tank (16). It is injected through the nozzle 18 and flows through the filler 20 provided inside the air inlet 14 through which the outside air is sucked.

In addition, the high-temperature cooling water flowing through the filler 20 is provided on the cooling tower 100 to exchange heat with external air introduced from the air intake port 14 by the driving of the cooling fan 12 that sucks the external air. Will be

At this time, a part of the cooling water evaporates while the high temperature cooling water flowing through the filler 20 comes into contact with the external air introduced through the air inlet 14, and in this process, the temperature of the cooling water is lowered by taking away the heat required for evaporation. .

Here, the external air introduced into the air inlet 14 must be dried at low temperature for efficient heat exchange of the cooling water flowing through the filler 20, and the external air introduced into the air inlet 14 must pass through the filler 20 evenly. Needs to be.

However, the conventional cooling tower described above has the following problems.

First, the external air introduced into the air inlet 14 formed at the side of the cooling tower 100 is sucked in the diagonal direction by the cooling fan 12 provided on the upper side. Thus, as shown in the figure, a rectangular area A in which the external air does not flow smoothly is generated in the inner lower region of the filler 20. For this reason, the external air may not evenly pass through the filler 20, and it may not efficiently exchange heat with the cooling water flowing through the filler 20.

Second, some of the hot and humid air discharged from the cooling fan 12 provided in the upper portion of the main body has a problem that the cooling tower 100 is introduced again through the air inlet 14. Therefore, the flow of the outer portion of the flow of air discharged to the outside through the cooling fan 12 is often introduced into the cooling tower 100 due to the resistance and gravity of the outside of the central portion often occurs in the cooling tower 100 The efficiency will be lowered.

Third, since the air introduced into the filler 20 of the cooling tower 100 by the driving of the cooling fan 12 has a property of flowing through the least resistance part, a part of the flow, in particular, the top of the filler It may also be introduced into the space generated by the top of the 20 and the bottom of the upper tank (16).

In addition, although the baffle 22 is installed at the side of the space formed by the upper end of the filler 20 and the lower end of the upper water tank 16 so that outside air does not directly enter, some flow passes through the filler 20. Not enough heat exchange. In addition, in some regions of the filler 20, there is a problem in that a stagnant region occurs due to a partial flow through the filler 20, thereby failing to obtain a desired performance of the cooling tower 100.

Fourth, since the end of the filler 20 is exposed to the outside of the cooling tower 100 in which the outside air is introduced, the filler 20 is exposed to direct sunlight as it is, the filler 20 is easily aged by ultraviolet rays, foreign matter from the outside Or there was a problem that the cooling tower 100 is easily damaged by rain or the like.

In order to solve the above problems, an object of the present invention is to provide a cooling tower that can efficiently exchange heat between the external air and the cooling water flowing through the filler by allowing the external air introduced into the air inlet to pass evenly through the filler. will be.

In order to achieve the above object, the cooling tower according to a preferred embodiment of the present invention is the air inlet formed in the side body; A filler provided inside the main body and guiding movement of the coolant to facilitate heat exchange between the outside air and the coolant sucked from the air inlet; A cooling fan that sucks outside air from the air suction port and blows the air through the filler; And provided in the air inlet, the guide portion is formed in a multi-stage with a cross-section is formed gradually closer to the horizontal toward the air inlet and the slope becomes smaller, and the outside air sucked in the front end of each guide portion smoothly guides to the guide portion Including the round portion is formed to be rounded, it is preferable that the air to be guided to be sucked with inertia in the horizontal direction along the guide portion arranged in multiple stages.

In this case, the air guide may be provided in multiple stages at a predetermined interval on the air inlet.

In addition, the air guide is provided with a coupling portion on the side wall to be coupled to the edge of the air intake.

Meanwhile, a downward curved blocking guide may be provided on the upper portion of the air inlet so that the hot and humid air discharged from the air outlet formed in the upper portion of the cooling tower main body is not re-inhaled to the air inlet side.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the cooling tower according to the present invention.

2 is a partial cutaway front view of a cooling tower according to an embodiment of the present invention.

As shown in Figure 2, the cooling tower 100 according to an embodiment of the present invention is preferably made of a main body 10, the cooling fan 12, the filler 20, and the air guide 40.

Here, the fan cylinder 24 is installed in the upper center of the main body 10, and the upper water tank 16 is provided on both upper sides. In addition, a plurality of nozzles 18 are provided on the bottom surface of the upper tank 16 for the injection of cooling water stored in the upper tank 16.

At this time, the inside of the upper water tank 16 is circulated by the high temperature cooling water is received by the circulation pump is received, the high temperature cooling water through the nozzle 18 provided on the bottom surface of the upper water tank (16) It is sprayed toward the filler material 20.

On the other hand, the cooling fan 12 is provided in the fan cylinder 24, the outside air is sucked from the air intake port 14 formed on both sides of the main body by the driving of the cooling fan 12, The outside air passes through the filler 20 provided inside the air suction port 14 and is discharged to the outside through the fan cylinder 24 provided with the cooling fan 14. In this case, the coolant flowing through the external air and the filler 20 is heat-exchanged, and as the coolant is evaporated, latent heat of evaporation is discharged to the outside to lower the temperature of the coolant.

In addition, the filler 20 is provided inside the air inlet 14 formed on the side of the main body 10, the cooling water injected through the nozzle 18 provided on the bottom surface of the upper tank 16, the filler ( 20) to flow aboard. At this time, the material of the filler may be used wood, bamboo, vinyl chloride, polyester resin, metal thin plate, asbestos plate, duct. In addition, the inner surface of the filler 20 is provided with an eliminator (eliminator) to prevent splashing inside the blowing fan, the outer surface of the filler 20 exposed to the inlet side to block the cooling water outflow. It is preferable that a louver is provided.

Here, the external air sucked from the air inlet 14 formed at the side by the driving of the cooling fan 12 and the nozzle 18 is injected through the nozzle 18 to allow the cooling water flowing through the filler 20 to exchange heat with each other. do. At this time, it is necessary to evenly pass the filler 20 to the outside air sucked through the air inlet (14).

On the other hand, the air guide 40 is provided in the air inlet 14 to guide the outside air sucked from the air inlet 14 to move inertia in the horizontal direction. Here, the air guide 40 is preferably made to include a guide portion 42 formed to be close to the horizontal slope becomes smaller toward the air intake port (14).

Further, the front end of the guide portion 42 is preferably provided with a round portion 44 is formed rounded so as to smoothly guide the external air sucked into the guide portion 42. In addition, the round part 44 may be formed to be rounded so that the cross section is close to the guide part 42 so that the outside air sucked from the air inlet 14 may be smoothly guided to the guide part 42. .

In addition, as shown, the air guide 40 is preferably provided in the multi-stage at a predetermined interval on the air intake port (14). At this time, the external air is guided between the air guides 40 spaced apart by a predetermined interval. That is, the external air is guided along the lower surface of the upper air guide and the upper surface of the lower air guide, and suctioned with inertia in the horizontal direction.

In addition, the suctioned outside air may be gently separated by the round portion 44 formed at the front end of the air guide 40 and then easily sucked between the neighboring guide portions 42.

On the other hand, the outside air flowing into the air intake port 14 is guided to have inertia in the horizontal direction along the guide portion 42 formed closer to the horizontal toward the air intake port 14 side of the air guide 40 air intake port Passes the filler provided in the inside of 14 evenly.

At this time, the external air is guided between the air guides 40 spaced apart by a predetermined interval. That is, the external air is guided along the lower surface of the upper air guide and the upper surface of the lower air guide, and suctioned with inertia in the horizontal direction. In particular, the outside air sucked into the air inlet 14 passes through the upper and center regions of the filler 20 as well as the lower and lower regions.

3 is a perspective view of an air guide provided in a cooling tower according to an embodiment of the present invention.

As shown in FIG. 3, the air guide 40 provided in the cooling tower 100 according to the exemplary embodiment of the present invention includes a guide part 42, a round part 44, and a coupling part 46. desirable.

Here, the guide portion 42 has a downward curved shape whose cross section is inclined toward the air inlet 14 formed at the side of the cooling tower main body 10 to become horizontal. Thus, by guiding the outside air sucked into the air suction port 14 horizontally, the sucked outside air can pass evenly to the lower inner region of the filler 20 with inertia in the horizontal direction.

In addition, the round portion 44 is formed to be round so as to smoothly guide the outside air sucked from the outside to the guide portion, it is preferable that the cross section is formed to be rounded so as to be close to the guide portion 42.

In addition, the coupling part 46 is formed at both sides of the air guide and is coupled to the edge of the air intake port 14 formed at the side of the cooling tower body 10.

Figure 4 is a partial cutaway front view of a cooling tower according to another embodiment of the present invention.

As shown in Figure 4, the cooling tower 100 according to another embodiment of the present invention is provided with a blocking guide 30 on the upper end of the air inlet 14 formed on the side of the cooling tower body 10, the blocking Air guide 40 is preferably provided in multiple stages with a predetermined interval from the guide 30.

Here, the blocking guide 30 is formed in a downward curve, the lower portion is formed to be open so that air can be introduced.

The cooling tower of the present invention having the configuration as described above serves as follows.

When the cooling tower 100 is operated, high temperature cooling water is injected into the filler 20 through the nozzle 18 and flows from the top to the bottom of the filler 20, and the air inlet 14 is operated by the operation of the cooling fan 12. The external low temperature dry air introduced into the heat exchanger is collected to the lower portion of the cooling tower 100 in a state where the temperature is lowered by exchanging heat with the high temperature cooling water injected from the nozzle 18 and used to cool the refrigerant of the air conditioner again.

Here, as the cooling fan 12 is driven, external air introduced through the air intake port 14 formed at the side of the cooling tower body 10 is provided with an air guide 40 provided at the edge of the air intake port 14. It is guided to have an inertia in the horizontal direction. To this end, the guide portion 42 of the air guide 40 is formed to be close to horizontal as the slope becomes smaller toward the air intake port (14).

Through such a structure, the external air may be moved in a diagonal direction due to the suction force of the cooling fan 12 provided on the upper side to prevent the external air from partially contacting the inner region of the lower portion of the filler 20.

That is, the outside air guided in the horizontal direction by the air guide 40 can be evenly passed to the inner region of the lower portion of the filler 20. As a result, the heat transfer area is increased and uniformized, thereby facilitating heat transfer between the coolant and the external air.

On the other hand, the hot and humid air discharged through the cooling fan 12 of the cooling tower 100 proceeds in a direction perpendicular to the ground, but gradually spread from side to side according to the conditions of gravity and outside air from the outside of the discharged air flow. Some of the discharged air flows back into the cooling tower 100.

Here, the flow of air to be introduced back into the cooling tower 100 is blocked by the blocking guide 30 to prevent the discharged air from being recycled to the cooling tower, and only the external low temperature dry air flows into the cooling tower 100. do.

In addition, the blocking guide 30 of the cooling tower 100 to block the direct sunlight irradiated to the side of the filler 20 exposed to the outside to prevent the aging phenomenon by the ultraviolet ray of the filler 20. In addition, the earth and sand, foreign matter and rainwater introduced from the outside can be prevented from entering the cooling tower (100).

Referring to the effects of the cooling tower according to the present invention described above are as follows.

First, by providing the air inlet formed in the side of the cooling tower main body in multiple stages to guide the external air to have inertia in the horizontal direction, the external air introduced into the air inlet can pass evenly to the lower inner region of the filler. Through this, heat exchange between the external air and the cooling water flowing in the filler may be efficiently performed.

Second, by providing a blocking guide at the upper end of the air inlet formed in the side of the cooling tower body, the flow of the outer portion of the air discharged to the outside through the cooling fan flows back into the cooling tower due to the resistance and gravity of the outside air in the center By preventing the phenomenon can increase the efficiency of the cooling tower.

Third, by providing a blocking guide at the upper end of the air inlet formed in the side of the cooling tower body to prevent the flow of the upper flow into the space generated by the upper end of the filler and the lower end of the upper tank, in some areas of the filler It is possible to prevent the phenomenon that the stagnant region is generated due to a part of the flow passing through the filling material generated to improve the performance of the cooling tower.

Fourth, as the blocking guide is provided on the side of the cooling tower, the filler provided inside the air intake port is exposed to direct sunlight to prevent the aging phenomenon easily by ultraviolet rays, and to prevent foreign substances or rainwater from being introduced from the outside. do.

Claims (7)

A main body having an air inlet formed in the side; A filler provided inside the main body and guiding movement of the coolant to facilitate heat exchange between the outside air and the coolant sucked from the air inlet; A cooling fan that sucks outside air from the air suction port and blows the air through the filler; And, It is provided in the air inlet, the guide portion is formed in a multi-stage with a cross-section is formed gradually closer to the horizontal toward the air inlet and the slope becomes smaller, and the outside air sucked in the front end of each guide portion to smoothly guide the guide portion A cooling tower comprising a air guide for guiding the suctioned air to be sucked with inertia in the horizontal direction along the guide portion disposed in multiple stages, including a round portion formed to be rounded. The method of claim 1, The air guide has a cooling tower, characterized in that provided in the air intake in a plurality of stages with a predetermined interval. delete The method of claim 1, The air guide is a cooling tower, characterized in that the coupling portion is provided on the side wall to be coupled to the edge of the air intake. delete delete The method of claim 1, Cooling tower, characterized in that the downward curved blocking guide is provided on the upper portion of the air intake port so that the hot and humid air discharged from the air discharge port formed in the upper portion of the main body is not re-intake to the air intake side.

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