KR19980033543A - Cooling plate for cooling tower - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cooling plate (Fill) installed in a cooling tower, and in a conventional cooling plate in which a ridge of the same length is formed, water flowing on a plate is biased to one side by contact resistance with air.

Therefore, the contact area between the water and the cooling plate is reduced. In order to prevent this, the plate is formed in a parallelogram shape and installed inclined in the cooling tower. However, the residence time of the water on the cooling plate is increased, the amount of circulation of the water is reduced, the problem that the total volume and weight of the cooling tower increases. Therefore, in the present invention, the ratio of lengths (A: B) of the protrusions 11 formed on the cooling plate body 10 to be inclined by about 15 ° to the louver side by the sum of the vector amounts according to the length ratios is 1. It consists of 1.5. As a result, water flows inclined toward the louver side, and the inclined water flows vertically on the cooling plate by air resistance sucked into the louver side. Therefore, since the cooling plate may be rectangular and installed vertically in the cooling tower, it is possible to reduce the total volume and weight of the cooling tower.

Description

Cooling plate for cooling tower

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cooling plate installed in a cooling tower, which is a cooling water circulation cooling treatment device. In particular, the amount of circulation of water is increased while adjusting the flow of water flowing on the plate body of the cooling plate to increase the contact area of air and water. It is configured to increase the cooling efficiency by increasing the.

Heat generated from an air conditioning system or industrial heat exchanger, etc., must be removed as cooling at an appropriate temperature for cooling the room or cooling the equipment.

In order to remove this heat, a cooling tower using cooling water as a medium with high cooling efficiency is installed at a suitable location on the roof or ground of a building. The cooling tower circulates the cooling water, and directly contacts the surrounding air with the cooling water to provide a cooling effect. Get At this time, the contact time and the contact area of water and air, which have a significant influence on the cooling performance, are increased by the cooling plate installed in the cooling tower.

In the cooling tower of the above-described configuration, when the conventional cooling plate is installed vertically in the cooling tower, the cooling plate is influenced by the air flowing into the cooling plate side from the louver side by the fan to the water supplied in the upper water tank. The plate body is inclined about 15 ° from the vertical longitudinal line to the eliminator side and flows to one side. Therefore, water does not flow in the lower part of the plate body of the cooling plate located adjacent to the louver, and a loss of the contact area between the water and the cooling plate occurs. Therefore, there is a problem that the cooling efficiency of the cooling tower is reduced.

In order to solve the above problems, conventionally, in the cooling tower, a cooling plate is formed in a parallelogram inclined by about 15 ° from the vertical longitudinal line to the louver. However, the installation of such a cooling plate has problems such as increasing the total volume and weight of the cooling tower.

The configuration of the cooling plate in this regard is shown in FIGS. 5 and 6 and 7. 5 is a longitudinal sectional view showing the use of a conventional cooling plate, FIG. 6 is a sectional view of a conventional cooling plate, and FIG. 7 is a sectional view showing a flow of water on a conventional cooling plate body.

As shown in FIGS. 5 and 6, the conventional cooling plate 20 includes a composite cooling plate in which louvers 15 and an eliminator 16 are integrally formed at both sides (hereinafter, the composite cooling plate is a cooling plate). And a protruding protrusion 11 having the same lengths A and B on the plate body of the cooling plate 20. The ridges 11 having the same length have an angle of about 60 °, It is formed continuously in a mold to form a channel on the cold plate body. The shape of the entire cooling plate 20 of the above structure is formed in a parallelogram inclined at an angle of about 15 ° to the louver 15 side in the vertical longitudinal axis. As a result, the conventional cooling plate is installed in the cooling tower 1 inclined at an angle of about 15 ° from the vertical longitudinal line to the louver side.

Next, the flow and cooling action of water flowing in the conventional cooling plate body 20 installed in the cooling tower 1 will be described with reference to the drawings illustrated in FIGS. 5 and 7.

When water is evenly distributed on the cooling plate body through the dispersion nozzle 41 installed in the lower part of the upper water tank 40, the water dispersed on the cooling plate body is placed on the plate body of the cooling plate. The water flows along the ridges 11 formed in the shape, and the water flows in the vertical direction on the cooling plate body by the sum 62 of the vector amounts according to the length ratio of the ridges 11 formed with the same lengths A and B. The vertical flowing water is cooled in direct contact with the air sucked through the louver by a large fan at the top of the cooling tower. At this time, the air sucked through the louver gives resistance to the water flowing vertically on the cooling plate, and by the contact resistance of the air, the water is inclined at an angle of about 15 ° to the eliminator 16 in the vertical direction and shifted to one side. Will flow. Due to this problem, the water supplied from the dispersion nozzle 41 is not supplied to the lower portion of the cooling plate body 20 positioned adjacent to the louver 15. Therefore, there is a problem in that the cooling area of the cooling tower is reduced by reducing the contact area between the water and the cooling plate.

In order to solve this problem, the plate body of the cooling plate 20 was formed in a parallel slope shape and installed inclined in the cooling tower 1.

However, since the cooling plate must be installed inclined inside the cooling tower, a problem arises in that the total volume and weight of the cooling tower become large. Therefore, the installation site is restricted, that is, it is impossible to install on the rooftop and narrow places of high-rise buildings.

In addition, even if the cooling plate is installed inclined in the cooling tower to increase the contact area between the cooling plate body and the water, the water flowing on the cooling plate body flows obliquely, so that the residence time on the cooling plate is increased. Therefore, the amount of circulation of water is reduced, which is a factor to lower the cooling efficiency of the cooling tower.

In addition, when the cooling plate is manufactured, since the cooling plate body must be formed in a parallelogram, there is a problem in that a loss or waste of material occurs, and the installation work is difficult when installing the cooling plate. This increases the manufacturing and installation costs of the cooling tower.

In addition, since the protrusions formed on the cooling plate are formed only in the shape of a mountain, water flowing through the plate collides with the bent portion of the protrusions in the traveling direction thereof. As a result, the flow of water flowing on the cooling plate becomes undesirably increased, and the residence time of the water in the cooling plate is increased, and the breakage at the mountain-shaped bent portion or the strength decreases.

An object of the present invention is to provide a cooling tower cooling plate that can improve the cooling efficiency of the water by improving the shape of the projections arranged on the cooling plate so that the water flowing on the cooling plate flows inclined toward the louver side naturally.

Another object of the present invention is to provide a cooling plate for a cooling tower that can be installed vertically in the cooling tower, thereby reducing the total volume and weight of the cooling tower.

Another object of the present invention is to provide a cooling plate cooling plate for improving the strength of the cooling plate, and no loss or waste of materials during the manufacture of the cooling plate, and easy installation work to reduce the manufacturing cost of the cooling tower. It is.

1 is an overall perspective view of a cooling tower provided with a cooling plate of the present invention.

Figure 2 is a longitudinal sectional view showing the use of the cooling plate of the present invention.

3 is a front view of the cooling plate of the present invention.

4 is a cross-sectional view showing the flow of water on the cooling plate body of the present invention.

5 is a longitudinal sectional view showing the use of a conventional cooling plate.

6 is a front view of a conventional cooling plate.

7 is a cross-sectional view showing the flow of water on a conventional cooling plate body.

* Explanation of symbols for main parts of the drawings

1: cooling tower 10: cooling plate

11: ridged stone 12: rounding

15: louver 16: eliminator

30: fan 40: upper water tank

41: dispersion nozzle

Cooling plate for the cooling tower of the present invention that can increase the cooling efficiency of the cooling plate while reducing the total volume and weight of the cooling tower, as shown in Figures 1 to 3, the louver 15 and the eliminator on both sides It is formed by the composite cooling plate 10 in which 16 is integrally formed. On the plate body of the above-mentioned cooling plate has an angle of about 60 degrees The ridges 11 are formed continuously in a mold, and the length ratio A: B of the ridges 11 is 1: 1.5. In addition, the rounded portion 12 is formed in the bent portion of the mountain-shaped protrusion 11 that is continuously formed along the traveling direction 65 of the water, and the plate shape of the entire cooling plate 10 is formed into a rectangle.

By the above configuration, when the cooling plate 10 formed of the rectangular plate body is installed in the cooling tower 1 as shown in FIG. 2, the cooling plate 10 is installed vertically under the upper water tank 40.

Next, as illustrated in FIG. 4, the flow and cooling action of water flowing through the plate of the cooling plate 10 of the present invention installed in the cooling tower 1 will be described.

When water is distributed and supplied to the plate body of the cooling plate 10 through the dispersion nozzle 41 of the upper water tank 40, the dispersed water flows along the ridges 11 having different lengths. At this time, water flowing on the plate body of the cooling plate 10 by the sum of the vector amounts 65 according to different length ratios (that is, length ratio A: B is 1: 1.5) is about 15 ° from the vertical longitudinal line to the louver side. It is inclined at an angle and flows to one side, and water flowing at an angle of about 15 ° toward the louver 15 side is cooled by being in direct contact with the air 33 sucked through the louver 15 by a large fan. At this time, the air 33 sucked to the louver 15 side gives resistance to the water flowing at an angle of about 15 ° to the louver side, and by the contact resistance of the air 33, the water flows in the vertical direction of the cooling plate 10. do. Thus, water flows evenly on the cooling plate, thereby reducing the loss of the contact area between the cooling plate and the water and improving the cooling effect of the water.

As described above, since the cooling plate of the present invention can be installed vertically in the cooling tower, it is possible to reduce the total volume and weight of the cooling tower. Therefore, it becomes possible to install a cooling tower on the roof or narrow place of a high-rise building, and since the water distributed in the upper tank flows in the vertical direction on the cooling plate, the residence time of the water on the cooling plate is reduced and the circulation amount of water is increased. . This improves the cooling efficiency of the cooling tower.

In addition, when the cooling plate is manufactured, since the plate body of the cooling plate is formed in a rectangular shape, there is no loss or waste of material, and the operation of clamping or aligning the cooling plate inside the cooling tower is facilitated. This has the effect of being reduced.

Another effect of the present invention is the smoothing of the flow of water by the rounding 12 formed in the bent portion of the mountain-shaped protrusions 11, the strength in the bent portion is increased to increase the durability and life of the cooling plate.

Example 1

Table 1 below shows the installation of the cooling plate of the present invention and the conventional cooling plate in the cooling tower in the cooling tower by the American Industrial Association of Cooling Towers (CTI) of the cooling tower under the same air wet bulb temperature and the same heating conditions by CODE STD-201. As a result of testing the cooling capacity, the cooling plate of the present invention, which adjusted the flow of water flowing on the cooling plate, had a 9.2% increase in circulating water than the existing cooling plate, and the equivalent CRT, which is an indicator of the cooling capacity of the cooling tower, When the cooling efficiency of the cooling tower is calculated by Equation 1 below, the cooling plate of the present invention is about 10.8% higher than the conventional inclined parallelogram cooling plate, except that the circulation water is increased. Improved.

In Equation 1, η is the cooling efficiency of the cooling tower, T _h is the cooling plate inlet, that is, the hot water temperature distributed to the cooling plate body in the upper water tank, and T _c is the cooling plate outlet, Cold water temperature, T _b is the wet bulb temperature of the air.

According to the present invention, the flow of water is inclined at an angle of about 15 ° from the vertical longitudinal line to the louver side by the sum of the vector amounts according to the length ratios of the continuously formed protrusions, and is shifted to one side and about 15 ° angle from the vertical axis line perpendicular to the louver side. The biased water flows on the cooling plate vertically by the contact resistance with the air sucked through the louver, so that the residence time of the water on the cooling plate is reduced, the circulation of water is increased, and the cooling plate can be installed vertically in the cooling tower. Will be. As a result, the cooling efficiency of the cooling tower can be improved, and the total volume and weight of the cooling tower can be reduced, so that the cooling tower can be installed on a rooftop or a narrow place of a building.

Claims (2)

The same length of ridge on the plate of the composite cold plate has an angle of about 60 In the cooling plate for a cooling tower which is continuously formed in a die shape, the plate body shape of the entire cooling plate in which the mountain-shaped protrusions are formed is formed in a parallelogram and inclined to the cooling tower. A mountain-shaped protrusion 11 is formed continuously in a mold, and the length ratio A: B of the mountain-type protrusion 11 is composed of 1: 1.5, and the cooling plate 10 having the above-mentioned mountain-shaped protrusion 11 is formed. ) The overall plate shape is formed into a rectangle, and the cooling plate 10 formed in the rectangle is vertically installed in the cooling tower 1 so that the flow of water flowing in the cooling plate body 10 is equal to the length ratio of the mountain-shaped protrusion 11. A: A cooling plate for a cooling tower, characterized in that it is configured to be inclined at an angle of about 15 ° to the louver 15 side by a sum of the vector amounts 65 according to B) and to flow to one side. The cooling plate for a cooling tower according to claim 1, wherein a rounding (12) is formed at a bent portion of the ridge according to the traveling direction of the water with respect to the continuously formed ridge (11).