KR20100080983A - Cross flow type cooling tower - Google Patents

Abstract

PURPOSE: A cross flow cooling tower is provided to maintain the uniform level of cooling water by discharging the cooling water with reduced spraying force to the upper water tank. CONSTITUTION: A cross flow cooling tower comprises a main body(10), filler(20), an upper water tank(30), a cooling water supply pipe(40), and a cooling water distribution device(50). The main body is filled with the filler, and the filler heat-exchanges cooling water with air. The upper water tank is installed on the top of the filler and temporarily stores the cooling water. Multiple spraying nozzles are installed on the bottom of the upper water tank and spray the cooling water to the filler. The cooling water supply pipe is connected to the upper water tank and forms a cooling water passage. The cooling water distribution device reduces spraying force of the cooling water sprayed from the cooling water supply pipe and supplies the cooling water to the upper water tank.

Description

Cross flow type cooling tower

The present invention relates to a crossflow cooling tower, and more particularly, to a crossflow cooling tower having improved heat exchange efficiency through improved cooling water distribution.

In general, a heat exchanger such as a refrigerator or an air conditioner is provided with a cooling tower for continuously recirculating and supplying low-temperature cooling water by cooling the heat of hot water sent from a high-temperature condenser after heat exchange.

In addition, various types of structures and methods are applied to the cooling tower to remove heat from the cooling water that has become a high temperature, and a cooling method using air is widely used.

As a method of using air in this way, a method of spraying hot water into the air or dripping it into the air, and blowing the air by forced ventilation by natural ventilation, a blower, or the like, is used to cool the cooling water.

Such a cooling tower has a counter flow type in which high temperature coolant flowing down and air sucked from the outside face each other in a reverse direction, and a high temperature coolant cools down. It is roughly classified as a cross flow type in which air cools at a high temperature while crossing air in an orthogonal manner.

1 is a schematic cross-sectional view showing a conventional cross-flow cooling tower, Figure 2 is a plan view showing a top water tank and the water supply of the conventional cross-flow cooling tower schematically, Figure 3 is a cross-sectional cooling tower of the conventional A cross-sectional view showing a state in which cooling water is injected into the upper tank.

As shown in Figure 1 and 3, the conventional cross-flow cooling tower is provided with a filler 120 on the inside of the main body 110, the upper tank 130 is provided on the upper side of the filler 120.

The coolant supply pipe 140 is connected to the upper water tank 130, and the coolant supplied through the coolant supply pipe 140 is injected into the upper water tank 130.

In addition, a plurality of through holes 133 are formed on the bottom surface of the upper water tank 130. Accordingly, the coolant discharged through the through holes 133 is dropped to the filler 120 provided on the lower side. It moves along the filler 120.

In addition, the coolant introduced into the filler 120 is heat-exchanged while being in contact with the air passing through the filler 120.

However, the conventional cooling tower has the following problems.

First, as the cooling water discharged from the cooling water supply pipe is concentrated in a part of the upper tank, the cooling water is prevented from accumulating around the portion (E) where the cooling water is injected by the force from which the cooling water is injected, and thus, the cooling water is injected. There is a problem that the amount of the coolant flowing into the filler through the portion is reduced.

Second, as the coolant discharged from the coolant supply pipe is concentrated in a part of the upper tank, the amount of coolant stored in the portion E of the coolant jet or in the corner portion F of the upper tank is relatively smaller than that of the other parts. There is a problem that the cooling water is not uniformly distributed in the upper tank as a whole.

Third, as the cooling water does not flow into the filler in a uniform distribution in all parts of the upper tank, the amount of the cooling water that moves through the filler decreases, thus reducing the heat exchange efficiency of the cooling water.

Fourth, as the cooling water supply pipe is provided on the upper side of the main body and is exposed to the outside, it may be directly exposed to external stimuli, which may cause damage, and the appearance may not be beautiful, and lines such as mountains, buildings, or structures in the background of the sky or There is also a problem that the skyline (skyline) meaning the contour is also hurt.

In order to solve the above problems, the present invention is to provide a cross-flow cooling tower with improved heat exchange efficiency through improved cooling water distribution.

In order to achieve the above technical problem, the present invention forms a main body; A filler provided inside the main body to allow the coolant to exchange heat with air; An upper tank provided at an upper side of the filler to the inside of the main body to temporarily receive the cooling water, and a plurality of injection nozzles are installed on the bottom plate formed to correspond to the upper portion of the filler to allow the cooling water to be injected into the filler. ; A cooling water supply pipe which forms a movement path of the cooling water and is connected to the upper water tank and is located inside the main body so as not to be exposed to the outside: and is connected to the cooling water supply pipe, and the cooling water is supplied through the plurality of injection nozzles. It provides a cross-flow cooling tower comprising a cooling water distribution device for supplying to the upper water tank by reducing the injection force of the cooling water injected from the cooling water supply pipe to uniformly spray flow into.

Here, the cooling water distribution device is connected to the cooling water supply pipe, is provided in the longitudinal direction of the upper tank in the inner side of the upper tank, the distribution pipe for forming a spray hole to spray the cooling water, and surrounds the distribution pipe It is preferably made to include a distribution plate to reduce the injection force of the cooling water injected from the distribution pipe to supply to the upper water tank.

In addition, the injection hole is formed to be symmetrical with respect to the center of the distribution pipe at a predetermined interval along the longitudinal direction of the distribution pipe, it is preferably formed at a predetermined angle of inclination in both directions.

In addition, the distribution plate is provided in the longitudinal direction of the distribution pipe and the body portion surrounding the distribution pipe, and extending from the body portion, corresponding to the injection direction of the cooling water injected from the injection hole contains the cooling water injected It is preferably made to include a damper portion is formed so that the injection force of the cooling water is reduced to be discharged to the upper water channel.

In addition, it is preferable that a drain portion for discharging the cooling water is formed between the end of the damper portion and the distribution pipe along the longitudinal direction of the upper tank.

In addition, the distribution pipe is connected to the cooling water supply pipe provided through the side wall of the upper tank is preferably provided below the upper surface of the main body.

The cooling water supply pipe is branched from the inside of the main body and connected through both sides of the upper water tank, and the cooling water supplied through the cooling water supply pipe is introduced from both sides of the cooling water distribution device.

Referring to the effect of the cross-flow cooling tower according to the present invention.

First, a distribution plate is provided outside the distribution pipe in which the injection hole is formed, and both sides of the distribution plate correspond to the injection direction of the cooling water injected from the injection hole, and a damper part is formed so as to temporarily contain the cooling water injected. The injection force may be discharged to the upper tank in a reduced state.

Second, since the jetting force of the coolant can be discharged to the upper tank so that the coolant can be accommodated in the upper tank while maintaining a constant water level, a uniform discharge of coolant is achieved through all the distribution holes formed in the upper tank. Can be.

Third, since the coolant discharged through the distribution hole can achieve a uniform and constant flow rate, not only the flow rate falling into the filler increases, but also moves in a uniform distribution, thereby improving heat exchange efficiency.

Fourth, it is possible to supply a wider and more stable cooling water to the upper tank by providing the distribution pipe and the drain portion along which the cooling water is discharged along the longitudinal direction of the upper tank.

Fifth, the cooling water supply pipe provided through the side wall of the upper tank and the cooling water distribution device connected to the cooling water supply pipe can be located inside the main body to be protected from magnetic poles from the outside, and the appearance is improved The skyline can also improve.

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

Figure 4 is a perspective view showing a cross-flow cooling tower according to a first embodiment of the present invention, Figure 5 is a plan view showing an upper water tank and the cooling water distribution device of the cross-flow cooling tower according to a first embodiment of the present invention, Figure 6 5 is a cross-sectional view taken along the line AA, Figure 7 is a plan view showing the upper tank and the distribution pipe of the cross-flow cooling tower according to the first embodiment of the present invention.

As shown in Figures 4 to 7, the cross-flow cooling tower is preferably made of a main body 10, the filler 20, the upper water tank 30, the cooling water supply pipe 40 and the cooling water distribution device 50. . Here, the filler 20 is provided inside the main body 10, and the upper water tank 30 is preferably provided above the filler 20. In addition, it is preferable that the coolant is supplied to the upper water tank 30 through the cooling water distribution device 50 connected to the cooling water supply pipe 40. In this case, the cooling water distribution device 50 is the upper water tank 30. Distributing tube 60 is provided in the longitudinal direction of the upper water tank 30 to the inside of the upper water tank 30 so as to spray the cooling water, and is provided to surround the distribution tube 60 from the outside of the distribution tube 60 It is preferable to include the plate 70. In addition, the distribution plate 70 is preferably formed with a damper portion 73 to reduce the injection force of the cooling water injected from the distribution pipe (60). Therefore, the cooling water injected from the distribution pipe 60 is reduced by the injection force by the distribution plate 70 is supplied to the upper tank 30 can be accommodated in a uniform distribution, through which the cooling water is Not only can the filler 20 be introduced into a wider and wider range, but also the flow rate is increased, thereby improving heat exchange efficiency.

Here, the cooling water refers to a circulating water circulated in the cross-flow cooling tower is the hot water of the hot water by the high temperature condenser and then heat-exchanged with the air in the filler and continuously recycled to the low temperature cooling water.

In detail, the main body 10 forms the outer shape of the crossflow cooling tower, and a space is formed inside the main body 10.

In addition, the air inlet 13 may be formed in the main body 10 so that external air may flow into the main body 10.

In this case, the air inlet 13 is preferably formed on both sides of the main body 10, respectively.

In addition, the filler 20 is preferably provided in the inner space of the main body 10 so as to be connected to the air inlet 13.

Here, the filler 20 may be formed by overlapping a plurality of filler plates 23, the filler 20 is introduced through the coolant and the air inlet 13 introduced from the upper water tank 30 to be described later. Heat is exchanged while the air is in contact with the cooling water.

To this end, the filling plate 23 may be formed in a curved shape so that the contact area between the cooling water and the air can be increased.

In addition, the filling plate 23 is a flow of the cooling water so that the cooling water flowing along the filling plate 23 is prevented from flowing out or splashing out of the filling plate 23 by the flow direction of the air by the blowing force of the air It is preferably formed to guide the direction downward.

In addition, the filler plate 23 may be made of various materials such as wood, synthetic resin, metal thin plate (薄板) or asbestos plate, and is not limited to any particular material.

On the other hand, it is preferable that the upper water tank 30 is provided on the upper side of the filler 20 to the inside of the main body 10.

Here, the upper water tank 30 is formed in a container shape to accommodate the cooling water.

In addition, the bottom plate 31 of the upper tank 30 is preferably formed to correspond to the top shape of the filler 20, it is preferable that a plurality of distribution holes 33 are formed in the bottom plate 31.

Through this, the cooling water accommodated in the upper water tank 30 is discharged through the distribution hole 33 is dropped to the upper portion of the filler 20, the cooling water falling along the filler 20 to the lower side Will flow down.

Here, each of the distribution holes 33 may be further provided with a separate injection nozzle (not shown) for more efficient injection of the cooling water, through which, a plurality of injection nozzles are provided on the lower side of the upper water tank 30 Can be installed.

On the other hand, the upper water tank 30 is preferably connected to the cooling water supply pipe 40 to form a movement path of the cooling water.

In addition, the cooling water supply pipe 40 provided in the main body 10 of the cooling water supply pipe 40 is preferably located inside the main body 10 so as not to be exposed to the outside.

In this case, the cooling water supply pipe 40 may be branched into the first cooling water supply pipe 43 and the second cooling water supply pipe 45 through the connector 41 used to divide the flow of the fluid.

In addition, each of the branched cooling water supply pipes 43 and 45 may be connected to the inside of the upper water tank 30 through the side wall 35 of the upper water tank 30, respectively.

In addition, each of the cooling water supply pipes 43 and 45 is preferably connected to the cooling water distribution device 50. At this time, the cooling water distribution device 50 is preferably located inside the upper water tank (30).

Accordingly, not only the cooling water supply pipe 40 but also the cooling water distribution device 50 is positioned below a cover (not shown) which may be provided to cover the upper surface of the main body 10 or the upper water tank 30. So that it may not be exposed to the outside.

Therefore, the cooling water supply pipe 40 and the cooling water distribution device 50 can be protected from the magnetic poles from the outside, the appearance can be improved and the skyline can be improved.

On the other hand, the cooling water distribution device 50 preferably comprises a distribution pipe 60 and the distribution plate 70.

Here, one end of the distribution pipe 60 is connected to the first cooling water supply pipe 43, the other end is preferably connected to the second cooling water supply pipe 45.

In addition, the distribution pipe 60 is preferably provided in the longitudinal direction of the upper tank 30 in the inner side of the upper tank (30).

Through this, the cooling water supplied through the cooling water supply pipe 40 may branch and move to flow toward the center of the distribution pipe 60 from both sides of the distribution pipe 60.

At this time, the distribution pipe 60 is preferably located in the center portion in the width direction of the upper tank (30).

In addition, the distribution pipe 60 is preferably formed with a spray hole 65 so that the cooling water introduced into the distribution pipe 60 can be discharged to the outside while moving.

Therefore, as the coolant flows from both sides of the distribution pipe 60, the cooling water distribution in the interior of the distribution pipe 60 can be made uniform than when the cooling water flows from only one side of the distribution pipe. Cooling water injected through the injection hole 65 may be more uniformly supplied to the upper water tank (30).

Here, the injection hole 65 is preferably formed through a predetermined interval along the longitudinal direction of the distribution pipe (60).

In addition, the injection hole 65 is preferably formed to be symmetrical with respect to the center of the distribution tube 60, and may be formed to extend at a predetermined angle in both directions.

In addition, the injection hole 65 may be formed in a zigzag shape with respect to the center of the distribution tube 60, the injection hole 65 may be further provided with a separate nozzle (not shown).

Therefore, when the injection hole 65 is formed obliquely downward, the cooling water moving through the distribution pipe 60 can be injected obliquely downward through the injection hole 65.

In addition, the outer side of the distribution pipe 60 is preferably provided with a distribution plate 70 to surround the distribution pipe (60).

Here, the distribution plate 70 is provided in the longitudinal direction of the distribution pipe 60, the body portion 71 surrounding the distribution pipe 60, and the damper portion 73 extending from the body portion 71 It is preferred to include).

First, the body portion 71 is provided so that the upper portion is in contact with the upper portion of the distribution pipe 60, it may be formed to be inclined at an inclination of a predetermined angle in both directions.

In this case, the body portion 71 may be coupled to the distribution pipe 60 by welding or bolting.

In addition, the damper portion 73 extends at both ends of the body portion 71 and is formed to be bent inward to correspond to the spraying direction of the coolant sprayed from the spraying hole 65 to be sprayed from the spraying hole. It is preferably formed to contain the cooling water.

In this case, the damper portion 73 is formed such that the portion that primarily collides with the cooling water is located farthest from the injection hole 65 so that the injection force of the cooling water injected from the injection hole 65 can be effectively reduced. This is preferred.

In addition, the damper portion 73 may be concave and rounded at both sides to prevent the first impacted cooling water from being immediately introduced into the upper water tank 30.

Accordingly, the coolant injected from the injection hole 65 may be stored in the damper portion 73 for a while by hitting the damper portion 73 so that the injection force may be reduced.

In addition, the coolant accommodated in the damper unit 73 is discharged through the drain portion 75 in a state in which the injection force is reduced is preferably introduced into the upper water tank (30).

Here, the drain portion 75 is preferably formed as the end of each damper portion 73 at a predetermined distance from the distribution pipe 60, through which, the drain portion 75 is the upper portion It is formed along the longitudinal direction of the water tank (30).

Therefore, the cooling water discharged through the drainage portion 75 provided in the longitudinal direction at the center of the upper water tank 30 may be discharged more widely without being locally discharged at any point of the upper water tank 30. And, it is possible to be discharged in a state in which the injection force is reduced by the distribution plate (70).

At this time, the drain portion 75 may be located to be submerged in the cooling water accommodated in the upper water tank 30 or higher than the level of the cooling water accommodated in the upper water tank 30, and is limited to be provided at a specific position. It is not.

Through this, it is possible to maintain a uniform level of water in the upper water tank 30 without a separate device, such as a flow control valve (flow control valve).

In addition, the cooling water can maintain the overall uniform level in the upper water tank 30, the cooling water discharged through the distribution hole 33 can also achieve a uniform and constant flow rate, and thus the filler 20 Flow rate falling to can be uniformly distributed.

At this time, the amount of cooling water injected through the injection hole 65 is greater than the amount of cooling water discharged through the distribution hole 33 so that the injection hole 65 can maintain a constant level in the upper water tank 30. And the distribution hole 33 is preferably formed appropriately.

On the other hand, the cooling tower may be applied to not only cross-flow type, but also hybrid type (hybrid type) in the form of a combination of counterflow type or cross-flow type and countercurrent type.

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.

Figure 1 is a schematic cross-sectional view showing a conventional cross-flow cooling tower.

Figure 2 is a plan view schematically showing an upper water tank and a water supply device of a conventional cross-flow cooling tower.

Figure 3 is an exemplary cross-sectional view showing a state in which the cooling water is injected into the upper water tank of the conventional cross-flow cooling tower.

Figure 4 is a perspective view of a cross-flow cooling tower according to a first embodiment of the present invention.

5 is a plan view showing an upper water tank and a cooling water distribution device of the cross-flow cooling tower according to the first embodiment of the present invention.

6 is a cross-sectional view taken along the line A-A of FIG.

7 is a plan view showing the upper tank and the distribution pipe of the cross-flow cooling tower according to the first embodiment of the present invention.

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

10,110: main body 20,120: filler

30,130: upper tank 33: distribution hole

35: side wall 40: cooling water supply pipe

43: first cooling water supply pipe 45: second cooling water supply pipe

50: cooling water distributor 60: distribution pipe

65: injection hole 70: distribution plate

71: body portion 73: damper portion

75: drain 140: cooling water supply piping

Claims (7)

A body forming an appearance; A filler provided inside the main body to allow the coolant to exchange heat with air; An upper tank provided at an upper side of the filler to the inside of the main body to temporarily receive the cooling water, and a plurality of injection nozzles are installed on the bottom plate formed to correspond to the upper portion of the filler to allow the cooling water to be injected into the filler. ; A coolant supply pipe forming a movement path of the coolant and connected to the upper water tank located inside the main body so as not to be exposed to the outside; and And a cooling water distribution device connected to the cooling water supply pipe and reducing the injection force of the cooling water injected from the cooling water supply pipe so that the cooling water is uniformly injected into the filler through the plurality of injection nozzles. Crossflow cooling tower. The method of claim 1, The cooling water distribution device Is connected to the cooling water supply pipe, the inner side of the upper tank is provided in the longitudinal direction of the upper tank, a distribution hole for forming a spray hole to spray the coolant, and is provided to surround the distribution pipe in the distribution pipe Crossflow cooling tower characterized in that it comprises a distribution plate for supplying the upper water tank by reducing the injection force of the injected coolant. The method of claim 2, The injection hole has a predetermined interval along the longitudinal direction of the distribution pipe is formed to be symmetrical with respect to the center of the distribution pipe, cross-flow cooling tower, characterized in that formed in the inclination of a predetermined angle in both directions. The method of claim 2, The distribution plate is provided in the longitudinal direction of the distribution pipe and the body portion surrounding the distribution pipe, and extending from the body portion, corresponding to the injection direction of the cooling water injected from the injection hole is formed to contain the cooling water is injected Cross-flow cooling tower characterized in that it comprises a damper for reducing the injection force of the cooling water is discharged to the upper water channel. The method of claim 4, wherein Cross-flow cooling tower, characterized in that between the end of the damper portion and the distribution pipe discharge portion for discharging the cooling water along the longitudinal direction of the upper tank. The method of claim 2, The distribution pipe is connected to the cooling water supply pipe provided through the side wall of the upper tank is cross-flow cooling tower, characterized in that provided below the upper surface of the main body. The method of claim 1, The cooling water supply pipe is branched from the inside of the main body is connected through both sides of the upper water tank, cross-flow cooling tower, characterized in that the cooling water supplied through the cooling water supply pipe is introduced from both sides of the cooling water distribution device.

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