KR101103565B1 - Cooling tower having double fillers - Google Patents

Abstract

PURPOSE: A cooling tower having a double pillar structure is provided to improve heat exchange efficiency by providing a space between upper and lower pillars for direct heat exchange between exterior air and hot water. CONSTITUTION: A cooling tower having a double pillar structure comprises a main body, a pillar unit(30), and a fan unit. The main body has an air inlet on the outer side, a hot water inlet on the upper side, and an outlet on the bottom. The pillar unit is installed in the main body so that the hot water drawn in through the hot water inlet flows downward along the exterior of the pillar unit. The fan unit is installed on a side of the main body, draws exterior air into the main body through the air inlet, and discharges the exterior air to outside through the pillar unit.

Description

Cooling tower having double filler structure

The present invention relates to a cooling tower having a double filler structure, and more particularly, by providing a space that can be directly heat exchanged between the outside air and hot water between the upper filler and the lower filler to significantly improve the heat exchange efficiency of the outside air and hot water. It relates to a cooling tower having a double filler structure.

In general, the cooling tower uses the latent heat of evaporation by the direct contact of the cooling water and air as a cooling method. The counterflow type cooling tower, the cross flow type cooling tower and the parallel flow type ( parallel flow type).

Here, the counterflow type cooling tower is a cooling tower in which the high temperature coolant flows vertically downward and the air flows upward and the heat exchange occurs while the coolant and the air face each other, and the crossflow cooling tower is the high temperature coolant flowing vertically downward and the air flows horizontally. Therefore, the cooling water and the air crosses each other and the heat exchange is a cooling tower, and the parallel flow type cooling tower is a cooling tower in which the heat exchange occurs while the air and the cooling water flow in the same direction.

Among them, a cross-flow cooling tower having a high volume ratio of cooling water and air and having a relatively low maintenance and repair cost compared to other cooling towers is mainly used.

1 is a cross-sectional view of a conventional cross-flow cooling tower.

As shown in FIG. 1, the conventional cross-flow cooling tower 100 includes a main body 110 having an air inlet 111 formed at one side of an outer surface, a fan unit 120 installed at one side of the main body 110, and a main body 110. ) Is composed of a filler unit 130 installed inside.

The conventional cross-flow cooling tower 100 is heat exchanged with the hot water that is moved downward along the filler unit 130 by the outside air flowing into the main body 110 by the fan unit 120 is lowered the temperature of the hot water , The hot water is lowered in temperature, that is, cold water is discharged to the outside through the outlet 112 formed in the lower portion of the main body 110 and passes through a heat exchanger (not shown) provided on the outside, the hot water is the temperature rise while passing through the heat exchanger The pump unit (not shown) is introduced into the main body 110 and moves downward along the filler part 130, and the above process is repeated.

However, the cross-flow cooling tower 100 of the related art exchanges heat with the filler unit 130 as well as hot water, which is moved downwardly along the filler unit 130, by the fan unit 120. As a result, the heat exchange efficiency of the external air and hot water is lowered.

In addition, the conventional cross-flow cooling tower 100 is the hot water flowing into the main body 110 only in the direction of the filler unit 130 when the hot water flows quickly downwards by the weight of the hot water while the hot water and The heat exchange time of the external air is shortened, thereby causing a problem that the heat exchange efficiency of hot water and external air is significantly reduced.

The present invention has been made to solve the above problems, the object of the present invention is to install the upper filler and the lower filler spaced apart from each other in the vertical direction can be directly heat exchanged between the outside air and hot water between the upper filler and the lower filler. It is to provide a cooling tower having a double filler structure that can significantly improve the heat exchange efficiency of the outside air and hot water by providing a space.

In addition, another object of the present invention is that the falling water and the through-holes formed in the first filler plate attached to the lower portion of the upper filler and the second pillar plate attached to the lower pillar, respectively, are formed to cross each other, the hot water dropped into the dropping hole into the passage hole. It is to provide a cooling tower having a double pillar structure to be uniformly introduced into the second filler plate while being dispersed before being introduced.

In addition, another object of the present invention is to provide a vibration buffer means on the bottom of the main body, the hot water from the filler portion by the external vibration transmitted to the main body by preventing the vibration generated from the outside by the vibration buffer means to be transmitted to the main body It is to provide a cooling tower having a double filler structure that can prevent the removal in advance.

According to one side of the present invention for achieving the above object, an air inlet is formed on one side of the outer surface, a hot water inlet is formed to enter the hot water on one side of the upper surface, the main body formed with a discharge port on one side of the bottom, the main body It is installed on one side of the inside, and the hot water introduced into the hot water inlet is installed in the filler portion and the main body is moved downward along the outer surface, the outside air is introduced into the main body through the air inlet and the It includes a fan unit for discharging to the outside after the outside air introduced into the main body after passing through the filler unit, the filler unit is coupled to the upper filler and the lower portion of the upper filler flows into the upper portion of the hot water inlet And a first filler plate having a plurality of drop holes formed at one side thereof, and spaced apart from the upper filler under the upper pillar. It provides a cooling tower having a double pillar structure is coupled to the lower pillar and the lower pillar is installed, and a second filler plate formed with a plurality of through holes in a position that is mutually different from the plurality of falling holes of one side. .

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In addition, the first pillar plate may include a plurality of protrusions protruding upward from the upper surface, and drop holes may be formed in the centers of the upper surfaces of the plurality of protrusions, respectively.

In addition, the second pillar plate is preferably formed to be curved downward in the center.

And, the inside of the main body is installed above the upper filler, the hot water introduced through the hot water inlet is temporarily stored, and may further include a temporary storage tank in which a plurality of sprinkling holes are formed on one side.

In addition, it is preferable to further include at least one vibration damping means which is installed on one side of the lower surface of the main body, and buffers the vibration transmitted from the ground to the main body.

According to the present invention as described above, by installing the upper filler and the lower filler spaced apart from each other in the vertical direction by providing a space that can be directly heat exchanged between the outside air and hot water between the upper filler and the lower filler heat exchange efficiency of the outside air and hot water There is an effect that can be significantly improved.

The first and second pillar plates attached to the upper pillar lower portion and the second pillar plate attached to the lower pillar upper portion are alternately formed so that the hot water dropped into the drop hole is dispersed before being introduced into the through hole. 2 It is effective to uniformly flow into the filler plate.

In addition, a vibration buffer means is provided on the bottom of the main body, and the vibration generated from the outside by the vibration buffer means is prevented from being transmitted to the main body to prevent hot water from being removed from the filler part by external vibration transmitted to the main body. It can be effective.

1 is a cross-sectional view of a conventional cross-flow cooling tower,
2 is a cross-sectional view of a cooling tower having a double filler structure according to an embodiment of the present invention;
3 is a sectional view of a filler unit according to an embodiment of the present invention;
4 is a view showing the entire flow of hot water passing through the cooling tower having a double filler structure according to an embodiment of the present invention,
5 is a view showing the flow of hot water passing through the filler unit according to an embodiment of the present invention;
6 is a perspective view of a first pillar plate according to another embodiment of the present invention;
7 is a view showing the flow of hot water passing through the filter unit according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a cross-sectional view of a cooling tower having a double filler structure according to an embodiment of the present invention, Figure 3 is a cross-sectional view of the filler unit according to an embodiment of the present invention.

2 to 3, the cooling tower 1 having a double filler structure according to an embodiment of the present invention is the main body 10, the fan unit 20, the filler unit 30, the temporary storage tank ( 40) and the vibration damping means (50).

The main body 10 is formed in a substantially rectangular parallelepiped shape, and a hot water inlet 11 through which hot water is introduced by a pump unit is formed at one upper side, and an air inlet 12 through which external air is introduced at one side of an outer side thereof. On one side of the bottom is formed a discharge port 13 is discharged to the outside after the hot water introduced into the heat exchange with the outside air.

The main body 10 provides an installation space of the filler unit 30 therein and provides a movement path of the external air so that the outside air flows in the direction of the filler unit 30 by the fan unit 20 to be described later. It serves to provide a heat exchange space between the hot water moved downward along the filler unit 30 and the external air introduced into the inside.

The fan unit 20 includes a driving unit 21 installed on one side of the upper portion of the main body 10 and a fan member 22 coupled to the driving unit 21, and the external air is introduced into the air inlet 12. Through the main body 10 to be introduced into the hot water and the outside air flowing into the main body 10 serves to heat exchange.

The filler part 30 includes an upper filler 31 installed below the hot water inlet 11 among the inside of the main body 10, a lower filler 32 installed downwardly from the upper filler 31 by a predetermined distance, and an upper portion thereof. It comprises a first filler plate 33 is coupled to the lower end of the filler 31 and the second filler plate 34 coupled to the upper end of the lower filler 32, so that the hot water moved downward stays for a while The heat exchange time between the hot water and the external air is increased, and the hot water and the external air are directly heat-exchanged, thereby increasing the heat exchange efficiency of the hot water and the external air.

Here, a plurality of upper pillars 31 and lower pillars 32 are coupled to the frame portions 31a and 32a and the frame portions 31a and 32a having a generally rectangular shape, respectively, and introduced into the main body 10. It is configured to include a concave-convex portion (31b, 32b) to move downward along the outer surface, between the concave-convex portion (31b, 32b) and the concave-convex portion (31b, 32b) the outside air flowing into the main body 10 A plurality of through holes 31c and 32c passing through are formed.

The upper filler 31 and the lower filler 32 are such that the movement path of the hot water moved downwards is increased and spaced spaces are formed between the upper filler 31 and the lower filler 32 so that the hot water and the external filler are formed. While providing air space for direct heat exchange The heat exchange time of the hot water is increased to improve the heat exchange efficiency of the hot water and the outside air.

The first pillar plate 33 is formed in a substantially plate shape, and a plurality of drop holes 33b are formed at one side thereof so that the hot water passing through the upper pillar 31 passes through the drop hole 33b to the second pillar plate 34. ) To fall to).

The second pillar plate 34 is formed in a substantially plate shape, and a plurality of through holes 34a are formed at one side thereof so that the warm water dropped through the drop holes 33b of the first pillar plate 33 passes through the holes 34a. ) Serves to flow into the lower filler (32).

At this time, it is preferable that the second pillar plate 34 is formed such that the position where the plurality of passage holes 34a are formed is shifted from the position where the drop hole 33b of the first pillar plate 33 is formed. The reason why the formation positions of the 34a and the falling holes 33b are shifted is that hot water dropped downward through the falling holes 33b of the first pillar plate 33 collides with the second pillar plate 34. This is to allow the hot water to flow into the lower filler 32 uniformly by flowing through the upper surface of the second filler plate 34 in the dispersed state and flowing into the through hole 34a.

In addition, since the center of the second pillar plate 34 is bent downward, the hot water dropped to the upper surface of the second pillar plate 34 is moved outward of the second pillar plate 34 to the lower pillar 32. It is preferable to prevent the inflow of the second pillar plate 34 out of the second pillar plate 34 without being introduced.

The first pillar plate 33 and the second pillar plate 34 are installed to be spaced apart from each other in the vertical direction, and the hot water falling through the drop hole 33b through the separation space and the external air introduced into the main body directly. In addition to providing a space for heat exchange, the hot water that has passed through the upper pillar 31 falls on the upper surface of the first pillar plate 33 and then moves to the drop hole 33b and falls from the first pillar plate 33. After the hot water falls on the upper surface of the second filler plate 34, the hot water stays in the first pillar plate 33 and the second pillar plate 34 for the time that is moved to the through hole 34a. It serves to significantly increase the heat exchange time of the air.

Temporary storage tank 40 is installed on one side of the hot water inlet 11 of the inner upper surface of the main body 10, the storage tank 41 formed with a plurality of sprinkling holes (41a) on one side, and the water of the storage tank 41 It comprises a spraying nozzle 42 extending downward from one side formed with a ball (41a), and after storing the hot water flowing through the hot water inlet 11 for a predetermined time, the spraying hole (41a) and the spraying nozzle (42) It serves to uniformly flow into the upper filler (31) through.

The vibration damping member includes an upper support part 51 fixed to one side of the bottom surface of the main body 10, a lower support part 52 and an upper support part 51 and a lower support part fixed to the ground so as to face the upper support part 51. It is configured to include an elastic member 53 is installed between the 52, by preventing the vibration generated from the outside to be transmitted to the main body 10 by the external vibration transmitted to the main body 10 by the filler unit 30 )from In addition to preventing the removal in advance and serves to prevent the body 10 is damaged by an external impact.

Here, the upper support part 51 is formed with a first stopper 51a bent downward from the outer end portion so that the elastic member 53 is not separated outward when one end of the elastic member 53 is mounted.

The lower support portion 52 has a second stopper 51b bent upward from the outer end portion, and is firmly coupled to one side of the ground so as to face the upper support portion 51.

The elastic member 53 is preferably a coil spring is used, it is installed to provide an elastic force perpendicular to the bottom of the body (10).

4 is a view showing the entire flow of hot water passing through the cooling tower having a double filler structure according to an embodiment of the present invention, Figure 5 is a flow of hot water passing through the filler unit according to an embodiment of the present invention. One drawing.

Referring to Figures 5 and 6 attached to the operation of the cooling tower (1) having a double filler structure according to an embodiment of the present invention having such a configuration as follows.

First, the hot water passing through the heat exchanger H provided outside is introduced into the hot water inlet 11 of the main body 10 by the pump unit P, and the hot water introduced into the hot water inlet 11 is stored in a storage tank ( After being stored in 41 for a predetermined time, the water is sprayed uniformly to the upper filler 31 through the watering hole 41a and the watering nozzle 42.

The hot water sprinkled by the upper filler 31 moves downward along the outer surface of the uneven portion 31b of the upper filler 31, and the hot water moved downward moves the fan unit 20 while the air inlet of the main body 10 is moved. External air and hot water introduced into the main body 10 through 12 are primarily cooled.

The hot water passing through the upper filler 31 is dispersed while colliding with the upper surface of the first pillar plate 33, and the dispersed hot water is moved in the direction of the drop hole 33b to drop downward through the drop hole 33b. .

The hot water falling downward through the drop hole 33b is secondly cooled while directly exchanging heat with external air, and is dispersed while colliding with the second pillar plate 34.

The hot water impinged on the second pillar plate 34 and dispersed therein is introduced into the lower pillar 32 through the through hole 34a of the second pillar plate 34, and the outer surface of the uneven portion 32b of the lower pillar 32 is formed. While moving downward along the heat exchange with the outside air is cooled third.

As described above, the hot water, that is, the temperature of which the temperature is significantly lowered, that is, the cold water is discharged to the outside through the outlet 13 of the main body 10, and the cold water discharged to the outside is exchanged by the pump unit P. The heat exchanged with the object to be cooled is converted into hot water while being introduced into (H), and the converted hot water is introduced into the inlet hole of the main body 10 again by the pump unit P, and the above process is repeated.

In addition, the following table is a cooling tower having an integrated filler structure, that is, the conventional cooling tower and the cold water discharged as the temperature of the hot water introduced in order to compare and analyze the heat exchange efficiency of the cooling tower having a double filler structure according to the present invention Experimental data of detecting temperature

The experiment was carried out at a volume capacity of 1000m ³ , blower pressure of 35kgf / m ² and an outside air temperature of 12 ℃.

As shown in Table 1, it was found that the temperature of the cold water discharged from the cooling tower having the double filler structure as a whole has a temperature lower than the temperature of the cold water discharged from the cooling tower having the integrated filler structure.

In particular, the higher the temperature of the incoming hot water, the greater the difference between the cooling tower having a double filler structure and the temperature of the cold water discharged from the cooling tower having an integrated filler structure according to the present invention.

As the temperature of the hot water is higher, the difference in the temperature difference between the discharged cold water is greater than that in the conventional cooling tower, the hot water located near the uneven portion of the hot water moved downward along the uneven portion of the filler portion, that is, the hot water located inside. While the contact with external air is blocked by hot water positioned outside the hot water, in the present invention, the hot water introduced into the main body falls down through the upper filler and falls downward, while the hot water is directly exchanged with the external air as well as falling. This is because the hot water introduced into the main body is uniformly cooled while being in contact with external air in a state where the hot water collides with the second pillar plate and is dispersed.

Thus, the cooling tower having a double filler structure according to an embodiment of the present invention has a feature that can significantly increase the cooling efficiency of hot water by improving the heat exchange efficiency of the external air and hot water.

6 is a perspective view of a first filler plate according to another embodiment of the present invention, Figure 7 is a view showing the flow of hot water passing through the filter unit according to another embodiment of the present invention.

The basic configuration of the embodiment of FIG. 6 is the same as that of the embodiment of FIGS. 1 and 2, but is formed in a structure in which hot water can be uniformly dropped from the first pillar plate 31. A plurality of protrusions 33a protruding upward are formed, and dropping holes 33b are formed in the center of the upper surfaces of the plurality of protrusions 33a.

The reason why the drop hole 33b is formed in the center of the upper surface of the protrusion 33a of the first pillar plate 31 is as follows: the warm water moved downward along the outer surface of the uneven portion 31b of the upper pillar 31 is the protrusion 33a. After a predetermined time is stored on the upper surface of the first pillar plate 33 by the height of the) and the height of the hot water stored on the upper surface of the first pillar plate 33 exceeds the height of the protrusion (33a) through the falling hole (33b) This is to allow the warm water to fall uniformly from the first pillar plate 33 by falling downward.

In addition, the first pillar plate 33 is preferably formed with the outer end bent upward so that the hot water passing through the upper filler 31 can be stored for a predetermined time by the height of the protrusion 33a.

As shown in FIG. 7, the cooling tower having the double filler structure according to another embodiment of the present invention stores hot water passing through the upper filler 31 on the upper surface of the first filler plate 33 for a predetermined time. When the height of the hot water stored on the upper surface of the filler plate 33 exceeds the height of the protrusion 33a, the hot water falls downward through the drop hole 33b by an amount exceeding the height of the protrusion 33a. By allowing the hot water to flow uniformly from the filler plate 33 to the second filler plate 34, the hot water is prevented from flowing in only one of the lower pillars 32, so that the hot water moves rapidly downward by the weight of the hot water. While the heat exchange efficiency of the hot water and the outside air is reduced, there is a feature that can be prevented in advance.

Since the rest of the structure is the same as the above-described basic embodiment, the rest of the description will be omitted.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it is possible to make various modifications or variations without departing from the spirit and scope of the invention. Accordingly, the appended claims will cover such modifications and variations as fall within the spirit of the invention.

1: cooling tower having a double filler structure 10: main body
11: hot water inlet 12: air inlet
13: outlet 20: fan unit
21: drive unit 22: fan member
30: filler part 31: upper filler
31a: frame portion 31b: uneven portion
31c: Through hole 32: Lower filler
32a: frame portion 32b: uneven portion
32c: through hole 33: first pillar plate
33a: protrusion 33b: drop hole
34: second pillar plate 34a: through hole
40: temporary storage 41: storage tank
41a: Sprayer 42: Sprayer Nozzle
50: vibration damping means 51: upper support
51a: first stopper 52: lower support part
52a: second stopper 53: elastic member

Claims (6)

An air inlet is formed at one side of the outer surface, a hot water inlet is formed at one side of the upper surface, and a main body is formed at the bottom of one side;
It is installed on the inner side of the main body, the hot water flowing into the hot water inlet is a filler unit which moves downward along the outer surface; And
Is installed on one side of the main body, and includes a fan unit to allow the outside air to enter the inside of the main body through the air inlet and to be discharged to the outside after passing through the filler unit, the outside air introduced into the main body,
The filler portion
An upper filler into which the hot water introduced into the hot water inlet is introduced;
A first pillar plate coupled to a lower end of the upper pillar and having a plurality of falling holes formed at one side thereof;
A lower filler installed below the upper pillar and spaced apart from the upper pillar; And
Cooling tower having a double pillar structure is coupled to the upper end of the lower pillar, comprising a second filler plate formed with a plurality of through holes in a position that is shifted from the plurality of falling holes of one side.
delete The method of claim 1,
The first pillar plate includes a plurality of protrusions protruding upward from the upper surface, the cooling tower having a double filler structure, characterized in that the drop hole is formed in the center of the plurality of protrusions, respectively.
The method of claim 1,
The second pillar plate is a cooling tower having a double pillar structure, characterized in that the center is formed to be curved downward.
The method of claim 1,
Cooling tower having a double filler structure is installed on the upper filler in the interior of the main body, the hot water introduced through the hot water inlet is temporarily stored, and further comprising a temporary storage tank formed with a plurality of sprinkler holes on one side.
The method of claim 1,
Cooling tower having a double pillar structure is installed on one side of the lower surface of the main body, further comprising at least one vibration buffer means for buffering the vibration transmitted from the ground to the main body.

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