KR102341665B1 - Cooling towers including middle tank - Google Patents

Abstract

The present invention relates to a cooling tower having an intermediate water bath. The cooling tower of the present invention has a plurality of intermediate water tanks on the flow path in which the cooling water flows from the upper water tank to the lower water tank in order to improve the cooling efficiency of the air introduced into the filler, so that the cooling water saturated with heat exchange is redistributed through the intermediate water tank do. To this end, the cooling tower of the present invention includes first to third fillers stacked on each other in multiple stages between the upper water tank and the lower water tank, and first and second intermediate water tanks installed between each of the intermediate materials. The first and second intermediate water tanks adjust the supply amount of cooling water differently from the area where external air is introduced between the upper water tank and the lower water tank toward the area where the air introduced through the filler is discharged, or uniformly mix the temperature of the stored cooling water. to supply cooling water to the filler at the bottom. According to the present invention, the cooling efficiency of the cooling tower can be improved by mixing or redistributing cooling water saturated with heat exchange in different regions of the filler and supplying it to the filler.

Description

COOLING TOWERS INCLUDING MIDDLE TANK

The present invention relates to a cooling tower, and more particularly, to improve cooling efficiency of air introduced into a filler, cooling water having a plurality of intermediate water tanks on a flow path in which cooling water flows from an upper water tank to a lower water tank, so that heat exchange is saturated It relates to a cooling tower to redistribute through the intermediate water bath.

A cooling tower is a heat exchanger with a relatively simple function that cools water that has been used as cooling water and reuses it by cooling it with air. It is a water saving device that uses the latent heat of evaporation of water and recovers 99% of the cooling water, and at the same time, it is an environmental resource protection device that prevents the temperature rise of the river. In the air conditioning system, the flow of cooling heat is finally discharged from the cooling tower to the atmosphere through the central air conditioner, cold water pump line, refrigerator, and cooling water pump line. The performance of the cooling tower heat dissipation function is directly related to the energy consumption of all air conditioners in the flow of heat load, so it can be viewed as the maximum energy saving device.

In general, a cooling tower is an indoor unit of a centralized cooling system, that is, a device that is used for cooling in an indoor air conditioner and lowers the temperature of the heated coolant. There are two closed types that lower the temperature of the cooling water by using the latent heat of evaporation of the evaporation water sprayed on the

Among them, the open type cooling tower is again divided into a counter flow type cooling tower, a cross flow type cooling tower, and a non-powered cooling tower.

The counterflow cooling tower is a type of counter-flow type cooling tower, by opposing the external air flowing in through the inlet opened at the bottom of the side wall and passing upward through the filler and the cooling water sprayed from the spray nozzle disposed above the filler and falling through the filler by gravity. It uses the principle of cooling the cooling water by heat transfer that occurs when the outside air comes into contact with the relatively high temperature cooling water.

In addition, the cross-flow cooling tower has a relatively low temperature by making the external air flowing in through the inlet open on the side wall and passing through the filler horizontally and the cooling water sprayed from the injection nozzle disposed above the filler and falling through the filler by gravity are orthogonal to each other. It uses the principle of cooling the cooling water by heat transfer that occurs when the outside air comes into contact with the relatively high temperature cooling water.

In a counter-flow type cooling tower, air flows vertically upward and cooling water flows vertically downward, and air and cooling water contact and heat exchange occurs. In a cross-flow cooling tower, air flows horizontally and cooling water flows vertically downward.

However, in the existing cross-flow cooling tower, the temperature of the cooling water flowing from the upper water tank to the lower water tank increases from the front to the rear, that is, toward the inside of the cooling tower, where air is introduced. There is a problem that the efficiency is lowered.

Republic of Korea Patent Publication No. 10-1093811 (published on Dec. 19, 2011) Republic of Korea Patent Publication No. 10-1121174 (published on March 16, 2012) Republic of Korea Patent Publication No. 10-1203323 (published on November 20, 2012) Republic of Korea Patent Publication No. 10-1627775 (published on 2016.06.07.

A cooling tower having an intermediate water tank according to the present invention has the following problems.

First, in the cooling tower according to the present invention, a plurality of fillers are stacked in multiple stages in order to improve cooling efficiency on a flow path through which cooling water flows between an upper water tank and a lower water tank, and a plurality of fillers are installed between the fillers to mix the cooling water and redistribute it. Intermediate tanks are provided.

Second, the cooling tower according to the present invention differentiates the supply amount of cooling water supplied from the intermediate water tank to the filler by area of the filler in order to supply a smaller amount of cooling water to the area of the filler where the cooling efficiency is reduced due to the close to the wet-bulb temperature of the outside air. is to do it

Third, the cooling tower according to the present invention regulates the temperature of the cooling water stored in the intermediate water tank so as to supply the cooling water at an equal temperature as the filler regardless of the area of the filler.

The problems to be solved of the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above objects, the cooling tower of the present invention is provided with a plurality of intermediate water tanks on the flow path in which the cooling water flows from the upper water tank to the lower water tank to redistribute the cooling water saturated with heat exchange through the intermediate water tank. . As such, the cooling tower of the present invention has a plurality of intermediate water tanks to redistribute the cooling water saturated with heat exchange and supply it as a filler, so that the cooling water of the filler is uniformly supplied regardless of the area in which external air is introduced or air is discharged to the outside. Cooling efficiency can be improved.

The cooling tower of the present invention according to this feature includes: a housing having both sides partially opened to allow air to be introduced from the outside; a blower fan installed in the upper center of the housing to discharge the introduced air to the outside; an upper water tank installed on the inner upper portion of the housing and storing coolant supplied from the outside; a plurality of fillers installed to be stacked at least two on the lower portion of the upper water tank to cool the cooling water flowing in from the upper water tank through air introduced from the outside; a lower water tank installed under the housing to collect cooling water supplied from the upper water tank through the filler; And at least one is installed between the fillers between the upper tank and the lower tank to collect and store cooling water supplied from the upper fillers among the fillers, and redistribute the stored cooling water to the lower fillers among the fillers. at least one intermediate water tank.

In one embodiment of this feature, the filler is installed on both sides of the housing opposite to both sides of the blowing fan in multiple stages; The intermediate water tank is installed between the upper and lower fillers in each of the respective fillers.

In another embodiment, each of the fillers is provided with first to third fillers stacked on each other in multiple stages; The intermediate water tank includes a first intermediate water tank installed between the first and second fillers, and a second intermediate water tank installed between the second and third fillers.

In another embodiment, the intermediate water tank; A plurality of supply holes for supplying a smaller amount of cooling water toward a second region from which air is discharged from the filler than the first region through which the air of the filler is introduced is provided on the lower surface thereof.

In another embodiment, the intermediate water tank; The arrangement density of the supply holes decreases from the first region to the second region.

In another embodiment, the intermediate water tank; Diameters of the supply holes gradually decrease from the first region to the second region.

In another embodiment, the intermediate water tank further includes a cooling water mixing device for uniformly adjusting the temperature of the cooling water by mixing the stored cooling water, and a plurality of temperature sensors are installed in the cooling water mixing device to be spaced apart, and the measured temperature difference When out of the preset temperature range, the cooling water mixing device is driven.

A cooling tower according to another aspect of the present invention includes: a housing having both sides partially opened to allow air to be introduced from the outside; a blower fan installed in the upper center of the housing to discharge the introduced air to the outside; an upper water tank installed on the inner upper portion of the housing and storing coolant supplied from the outside; first and second fillers stacked on the lower part of the upper water tank in multiple stages to cool the cooling water flowing in from the upper water tank through air flowing in from the outside; a lower water tank installed under the housing to collect cooling water supplied from the upper water tank through the first and second fillers; and between the first and second fillers stacked on each other between the first and second fillers, respectively, between the upper water tank and the lower water tank, and between the second filler and the third filler, the first and first and second intermediate water tanks for collecting and storing the cooling water supplied from each of the second fillers, and redistributing the stored cooling water to each of the second and third fillers.

In one embodiment of this feature, each of the first and the second intermediate water tank; A plurality of lower surfaces such that a smaller amount of cooling water is supplied toward a second area from which air is discharged from the second or third filler than a first area through which the air of the second or third filler is introduced It has two supply holes.

In another embodiment, each of the first and the second intermediate water tank; The arrangement density of the supply holes decreases from the first region to the second region.

In another embodiment, each of the first and the second intermediate water tank; Diameters of the supply holes gradually decrease from the first region to the second region.

In another embodiment, each of the first and the second intermediate water tank; A coolant mixing device is further installed to mix the stored coolant to uniformly control the temperature of the coolant, and a plurality of temperature sensors are installed in the coolant mixing device to be spaced apart, and when the measured temperature difference is out of a preset temperature range, coolant mixing the device is driven

A cooling tower having an intermediate water tank according to the present invention has the following effects.

First, the cooling tower of the present invention is provided with a plurality of intermediate water tanks to redistribute the cooling water saturated with heat exchange and supply it as a filler, thereby improving cooling efficiency.

Second, the cooling tower of the present invention has a plurality of supply holes on the bottom surface of the intermediate water tank so that a smaller amount of cooling water is supplied toward the second area where the air is discharged from the filler than the first area through which the air of the filler is introduced. By being formed on the surface, it is possible to lower the temperature of the cooling water regardless of the position of the filler.

Third, the cooling tower of the present invention circulates and mixes the cooling water stored in the intermediate water tank and supplies it as a filler, thereby supplying cooling water of a uniform temperature as a filler to improve cooling efficiency.

Effects of the present invention are not limited to those mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a perspective view showing the configuration of a cooling tower according to the present invention;
2 is a plan view of the cooling tower shown in FIG. 1;
3 is a side view of the cooling tower shown in FIG. 1;
4 is an AA' cross-sectional view of the cooling tower shown in FIG. 2;
5 is a perspective view showing a partial configuration in which a plurality of intermediate water tanks are provided between the upper water tank and the lower water tank of the cooling tower shown in FIG. 4;
6 is a view for explaining the cooling method of the prior art and the present invention, and
7 to 9 are views showing the configuration of the lower surface according to the embodiment of the intermediate water tank shown in FIG.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described so that those of ordinary skill in the art can easily carry out the present invention. As can be easily understood by those of ordinary skill in the art to which the present invention pertains, the embodiments described below may be modified in various forms without departing from the concept and scope of the present invention. Wherever possible, identical or similar parts are denoted by the same reference numerals in the drawings.

The terminology used herein is for the purpose of referring to specific embodiments only, and is not intended to limit the present invention. As used herein, the singular forms also include the plural forms unless the phrases clearly indicate the opposite.

The meaning of "comprising," as used herein, specifies a particular characteristic, region, integer, step, operation, element and/or component, and other specific characteristic, region, integer, step, operation, element, component and/or It does not exclude the presence or addition of groups.

All terms including technical terms and scientific terms used in this specification have the same meaning as commonly understood by a person of ordinary skill in the art to which the present invention belongs. Terms defined in the dictionary are additionally interpreted as having a meaning consistent with the related art literature and the presently disclosed content, and unless defined, are not interpreted in an ideal or very formal meaning.

The cooling tower according to the present invention is provided with a plurality of fillers and a plurality of intermediate water tanks in multiple stages between an upper water tank and a lower water tank in which cooling water is stored in order to improve cooling efficiency, and the path of the cooling water flowing from the upper water tank to the lower water tank through this is provided to control the temperature of the cooling water by mixing the cooling water saturated with heat exchange in each of the multi-stage intermediate water tanks, and to redistribute the temperature-controlled cooling water as a filler to re-cool it with the introduced air.

To this end, the cooling tower of the present invention includes an upper water tank for storing cooling water supplied from the outside, a plurality of fillers installed to be stacked at least two to cool the cooling water flowing from the upper water tank through air flowing in from the outside, and the fillers. to collect the cooling water supplied from the upper water tank, and at least one between the upper water tank and the lower water tank is installed between the fillers, collects the cooling water supplied from the upper water tank and circulates the cooling water so that the temperature of the cooling water is controlled, and at least one intermediate water tank for redistributing the circulated cooling water to the filling material and supplying the cooling water to the filling material so that the cooled cooling water is stored in the lower water tank.

Hereinafter, the configuration and function of the cooling tower of the present invention will be described in detail with reference to the drawings. In the embodiment of the present invention, the technical features of the present invention are described in detail using the configuration and function of the cross-flow cooling tower, but this is merely described by way of example, and various types within the scope without departing from the technical spirit of the present invention In addition to being applicable to the cooling tower of

1 is a perspective view showing the configuration of a cooling tower according to the present invention, FIG. 2 is a plan view of the cooling tower shown in FIG. 1, FIG. 3 is a side view of the cooling tower shown in FIG. 1, and FIG. 4 is FIG. It is an AA' cross-sectional view of the shown cooling tower.

1 to 3, the cooling tower 100 of the present invention includes a plurality of fillers 120 and 122 stacked in multiple stages between the upper water tank 110 and the lower water tank 112 for a high-efficiency cooling method, A plurality of intermediate water tanks 114 and 116 respectively installed between the stacked fillers 120 and 122 are provided, thereby extending the supply path of the cooling water supplied from the upper water tank 110 to the lower water tank 112, and , mix the cooling water saturated with heat exchange in each of the multi-stage intermediate water tanks 114 and 116 and re-cool it through the introduced air.

The cooling tower 100 of the present invention is, for example, installed on the roof of a building, in the surrounding space of the building, etc., used for cooling in the indoor unit (not shown) of the centralized cooling system of the building, and heats the coolant with the outside air. Lowers the temperature of the coolant by contact.

To this end, the cooling tower 100 of the present invention largely includes a housing 102 , a blower fan 104 , water tanks 110 to 116 , and a plurality of fillers 120 and 122 . In addition, although not shown in the drawing, the cooling tower 100 of the present invention is a typical cooling tower configuration, for example, an eliminator that prevents scattering, which is a phenomenon in which small water droplets of cooling water come with a blower fan 104, and an upper water tank. It further includes a spray nozzle (Spray Nozzle) for supplying cooling water to 110 .

The housing 102 is a case in which the components of the cooling tower 100 are accommodated or installed, and fixed to the floor of the installation site, and may be provided in, for example, a rectangular parallelepiped, a cylindrical shape, or the like. The housing 102 is provided to introduce external air into the fillers 120 and 122 by opening a portion of opposite side surfaces thereof. A blowing fan 104 is installed on the upper portion of the housing 102 , and the air introduced into the fillers 120 and 122 through the blowing fan 104 is discharged to the outside. In the housing 102 , fillers 120 and 122 are installed on both sides of the central portion constituting the inflow of external air to flow in the direction of the blowing fan 104 .

In addition, the housing 102 has a cooling water supply port provided on one side of the upper portion and connected to an external cooling water supply pipe (not shown) to supply cooling water to the upper water tank 110 , and a cooling water supply port provided on the lower side of the one side and stored in the lower water tank. A cooling water discharge port for discharging the cooling water to an external cooling water discharge line (not shown) is installed. Devices for supplying, circulating, and discharging cooling water, for example, a pump and a refrigerator, are provided between the cooling water discharge port and the cooling water supply port, and the cooling water is circulated and supplied from the cooling water discharge port to the cooling water supply port.

The blower fan 104 is provided with, for example, an axial fan in which the flow direction of air is parallel to the rotation axis, a centrifugal fan that blows air out in the circumferential direction by centrifugal force according to the rotation of the blades, etc., It rotates so that air is discharged to the upper part of the housing 102 . The blower fan 104 may be provided with blades made of, for example, Fiber Reinforced Plastics (FRP) or aluminum (AL), high efficiency of about 80% and low noise fan.

Fillers (or fillers) (Fill) 120 and 122 are disposed on both sides of the housing 102 is partly opened. The fillers 120 and 122 introduce external air through the open portion of the housing 102 . The fillers 120 and 122 introduce cooling water from the upper water tank 110 and cool the cooling water by contacting the introduced external air. The fillers 120 and 122 are provided in a plurality of plate types using, for example, a PVC material, a metal material, or the like, to form a large surface area. The fillers 120 and 122 form a thin film on the surface of the cooling water and heat exchange in contact with air while it flows down, and an improvement in heat transfer rate per unit volume and low air resistance are required. A plurality of fillers 120 and 122 are stacked on each other on one side and the other side of the housing 102 in a multi-stage structure.

The upper water tank 110 is installed on the inner upper portion of the housing 102 to store the coolant supplied through the coolant supply port 106 . The upper water tank 110 is provided on both sides of the housing 102 to correspond to each of the fillers 120 and 122 . Each upper water tank 110 has a filler 120a coupled to its lower surface, and supplies the stored cooling water to the lower filler 120a. Of course, the upper water tank 110 may be provided as one to supply cooling water to the fillers 120 and 122 on both sides.

The intermediate water tanks 114 and 116 are provided between the fillers 120a to 120c stacked at least one between the upper water tank 110 and the lower water tank 112 . Each of the intermediate water tanks 114 and 116 collects and stores cooling water supplied from the upper filler 120a or 120b, and re-supply the stored cooling water to the lower filler 120b or 120c. The intermediate water tanks 120 and 122 circulate and mix cooling water saturated with heat exchange by external air and redistribute it as a filler in the next stage to improve the cooling efficiency of the cooling tower 100 .

And the lower water tank 112 is installed in the lower portion of the housing 102 to correspond to the upper water tank 110 . The lower water tank 112 collects cooling water flowing through the fillers 120 and 122 from the upper water tank 110 . The lower water tank 112 discharges the collected cooling water to the outside through the cooling water discharge port 108 .

The standard design condition of the cooling tower 100 is that the cooling water inlet temperature is about 37 °C, the cooling water discharge temperature is about 32 °C, and the exhaust air wet bulb temperature is about 27 °C.

Specifically, the configuration and function for improving the cooling water efficiency of the cooling tower according to the present invention will be described in detail.

5 is a perspective view illustrating a partial configuration in which a plurality of intermediate water tanks are provided between the upper water tank and the lower water tank of the cooling tower shown in FIG. 4 , and FIG. 6 is a view for explaining the cooling method of the prior art and the present invention.

5 and 6, in the cooling tower 100 of the present invention, a plurality of fillers (120: 120a to 120c, 122: 122a to 122c) are stacked on both sides of the central part of the housing 102 in multiple stages. . Fillers (120: 120a ~ 120c, 122: 122a ~ 122c) are disposed between the upper water tank 110 and the lower water tank (112). Each of the upper water tanks 110 provided on both sides is provided with cooling water supply ports 106a and 106b connected to the cooling water supply port 106 to receive cooling water. In addition, the intermediate water tank (114, 116) is provided between at least one of the stacked fillers (120a ~ 120c, 122a ~ 122c). The lower water tank 112 may be provided on both sides corresponding to the upper water tank 110, respectively, and as shown in FIG. 5 , one is provided to collect and store the cooling water supplied from the upper water tanks 110 on both sides. can

In this embodiment, the three fillers 120a to 120c and 122a to 122c are stacked on each of the fillers 120 and 122 . That is, each of the fillers 120 and 122 includes the first fillers 120a and 122a, the second fillers 120b and 122b and the third fillers 120c and 122c, and the intermediate water tanks 114 and 116 are respectively Two of the fillers 120 and 122 are provided.

Specifically, a first intermediate water tank 114 is installed between the first fillers 120a and 122a and the second fillers 120b and 122b, and between the second fillers 120b and 122b and the third fillers 120c and 122c. A second intermediate water tank 116 is installed.

Each of the first to third fillers 120a to 120c and 122a to 122c receives cooling water from the upper water tank 110 , the first intermediate water tank 114 , or the second intermediate water tank 116 . In addition, each of the first to third fillers 120a to 120c and 122a to 122c introduces outside air from one side.

Each of these first and second intermediate water tanks 114 and 116 is filled with fillers 120b to 120c, 122b according to the cooling efficiency of the lower fillers 120b to 120c and 122b to 122c among the stacked fillers 120 and 122. ~ 122c), the amount of cooling water is supplied differently for each area.

Here, the regions of the fillers 120a to 120c and 122a to 122c include a first region (A in FIG. 7) through which air is introduced, a third region (C in FIG. 7) through which air is discharged, and a first region (A) and It is divided into a third area (B of FIG. 7 ) located in the middle between the second areas (C).

This is because the temperature of the cooling water cooled by the air introduced from each of the fillers 120a to 120c and 122a to 122c increases from the first region to the third region in the conventional cooling tower as in FIG. This is to solve the problem that the cooling efficiency in the Here, in the existing cooling tower, one filler 30 is provided between the upper water tank 10 and the lower water tank 20 , and additional cooling is not required in the first area by the air flowing into the filler 30 , but the third As the cooling water becomes saturated with heat exchange toward the region, the temperature of the cooling water approaches the ambient wet-bulb temperature, and the cooling efficiency decreases.

Therefore, as shown in (b) of FIG. 6, the first intermediate water tank 114 prevents the cooling efficiency of the air and the coolant introduced from the first area (A) from being lowered toward the third area (C). To this end, the cooling water supplied from the upper water tank 110 is stored, and the stored cooling water is supplied to the lower fillers 120b and 122b by differentiating the supply amount for each of the first to third areas A to C. In addition, the second intermediate water tank 116 stores the cooling water supplied from the first intermediate water tank 114, and differentiates the supply amount of the stored cooling water for each first to third areas A to C, so that the lower fillers 120c and 122c ) is supplied. At this time, each of the first and second intermediate water tanks 114 and 116 circulates and mixes the cooling water in the first to third regions A to C to uniform the temperature of the stored cooling water, and the mixed cooling water to the second And the third fillers (120b, 122b and 120c, 122c) may be supplied to each.

Therefore, in the present invention, by mixing the cooling water saturated with heat exchange by each of the first and second intermediate water tanks 114 and 116 installed between the fillers 120a to 120c and 122a to 122c, the lower fillers 120b to 120c, 122b ~ 122c) are redistributed and supplied.

7 to 9 are views showing the configuration of the lower surface according to the embodiment of the intermediate water tank shown in FIG. 5 .

Referring to Figure 7, the intermediate water tank (114, 116) according to the present invention is a lower surface (114a, 116a) on the outside of the filler (120b ~ 120c, 122b ~ 122c) is installed, the filler (120b ~ 120c, 122b ~) In order to supply cooling water to 122c), a plurality of supply holes 114b are formed in the lower surfaces 114a and 116a.

The intermediate water tanks 114 and 116 of this embodiment have a structure in which a plurality of supply holes 114b having the same diameter on the lower surfaces 114a and 116a are arranged at different densities for each area A to C. That is, the bottom surfaces 114a and 116a of the intermediate water tanks 114 and 116 are directed in the direction in which air is introduced and discharged with respect to the lower fillers 120b to 120c and 122b to 122c, that is, the first air is introduced. The supply holes 114b are gradually sparsely arranged from the region A to the third region C from which the air is discharged. Also, the number of supply holes 114b may decrease from the first area A to the third area C of the lower surfaces 114a and 116a.

This is because the cooling efficiency of the cooling water decreases as the air flowing into the third region C passes through the first and second regions A and B of the fillers 120b to 120c and 122b to 122c, so the third region C This is because the cooling water supplied to ) becomes saturated with heat exchange. Accordingly, it is necessary to supply a smaller amount of coolant supplied to the filler from the third region C than the amount of coolant supplied to the filler from the first region A. That is, the amount of cooling water supplied from the first region A to the lower fillers 120b to 120c and 122b to 122c is supplied from the third region C to the lower fillers 120b to 120c and 122b to 122c. A smaller amount of the cooling water is supplied than the supply amount, and the cooling water stored in the third region (C) is supplied more slowly to lower the temperature of the cooling water in the corresponding region.

Therefore, the intermediate water tanks 114 and 116 of this embodiment are the fillers 120b ~ 120c, 122b ~ 122c of the lower portion when the cooling water is supplied, the fillers 120b ~ 120c, 122b ~ 122c corresponding to the first area (A). By providing a smaller amount of cooling water to the fillers 120b to 120c and 122b to 122c corresponding to the third area C, the cooling water supplied to the third area C and saturated with heat exchange is transferred to the intermediate water tank ( The temperature of the cooling water can be effectively lowered by the air flowing into the fillers 120b to 120c and 122b to 122c by lowering the temperature to a certain extent in the 114 and 116 to supply them.

Referring to FIG. 8, the intermediate water tanks 114' and 116' of this embodiment are provided with a plurality of supply holes 114d having different diameters on the lower surfaces 114c and 116c.

7, the bottom surfaces 114c and 116c of the intermediate water tanks 114' and 116' are formed with respect to the lower fillers 120b to 120c, 122b to 122c, the first area A ) to the third region (C), the diameter of the supply holes (114b) is provided to gradually decrease toward the third region (C) than the fillers (120b ~ 120c, 122b ~ 122c) corresponding to the first region (A) (C) By providing a smaller amount of cooling water to the fillers 120b to 120c, 122b to 122c corresponding to The temperature can be effectively lowered.

Also referring to FIG. 9, the intermediate water tanks 114 ", 116" of this embodiment are provided with supply holes 114f of the same diameter on the lower surfaces 114e and 116e, and the intermediate water tanks 114 ", 116 on the inner side. In order to adjust the temperature of the cooling water stored in "), the cooling water mixing device 140 for circulating and mixing the cooling water is further provided. The cooling water mixing device 140 is a component of the cooling tower 100, for example, a cooling fan 104, or a device for supplying and discharging cooling water (eg, a valve, a pump, a refrigerator, etc.) (not shown). They are electrically connected to the control unit 130 that controls them. The controller 130 is provided with, for example, a controller, a programmable logic controller (PLC), a computer, or the like, and controls and drives the cooling water mixing device 140 .

The cooling water mixing device 140 may be provided as, for example, a small blower fan, a pump, or the like. Of course, the cooling water mixing device 140 may be installed in each of the intermediate water tanks 114, 114', 116, and 116' of FIGS. 7 and 8 for the same function.

In addition, the intermediate water tanks 114" and 116" are not shown in the drawing, but a plurality of temperature sensors (not shown) for measuring the temperature of the coolant stored in different positions inside may be installed. In this case, the temperature sensors are electrically connected to the control unit 130, measure the temperature of the cooling water stored in the intermediate water tanks 114", 116" at different positions, and when the temperature difference between the measured temperatures is outside the set temperature range , the control unit 130 drives the cooling water mixing device 140 to mix the cooling water.

Therefore, the intermediate water tanks 114 ", 116" of this embodiment circulate and mix the stored coolant to uniformly control the coolant temperature in the first to third zones A to C, and the lower fillers 120b to 120c, 122b ~ 122c) can be supplied. As a result, similarly to FIGS. 7 and 8 , the cooling water whose temperature is increased by the first fillers 120a and 122a is temperature-controlled and supplied to the fillers 120b to 120c and 122b to 122c. By providing, the first to third regions Regardless of (A to C), it is possible to effectively lower the temperature of the coolant by the air flowing into the fillers (120b to 120c, 122b to 122c).

The embodiments described in this specification and the accompanying drawings are merely illustrative of some of the technical ideas included in the present invention. Therefore, since the embodiments disclosed in the present specification are for explanation rather than limiting the technical spirit of the present invention, it is obvious that the scope of the technical spirit of the present invention is not limited by these embodiments. Modifications and specific embodiments that can be easily inferred by those skilled in the art within the scope of the technical idea included in the specification and drawings of the present invention should be interpreted as being included in the scope of the present invention.

100: cooling tower
102: housing
104: blow fan
110: upper water tank
112: lower tank
114, 116: middle tank
114a, 114c, 114e, 116a, 116c, 116c: lower surface of the middle water tank
114b, 114d, 114f, 116b, 116d, 116f: supply hole
120, 122: filler
120a ~ 120c, 122a ~ 122c: first to third fillers
130: control unit
140: cooling water mixing device

Claims (10)

In the cooling tower:
a housing having both sides partially opened to allow air to be introduced from the outside; a blower fan installed in the upper center of the housing to discharge the introduced air to the outside; an upper water tank installed on the inner upper portion of the housing and storing coolant supplied from the outside; a plurality of fillers installed to be stacked at least two in the lower part of the upper water tank to cool the cooling water flowing in from the upper water tank through air flowing in from the outside; a lower water tank installed under the housing to collect cooling water supplied from the upper water tank through the filler; and at least one is installed between the fillers between the upper water tank and the lower water tank, collects and stores cooling water supplied from the upper fillers among the fillers, and redistributes the stored cooling water to the lower fillers among the fillers. At least one intermediate water tank comprising:
The intermediate water tank further includes a cooling water mixing device configured to uniformly control the temperature of the cooling water by circulating and mixing the stored cooling water, and a plurality of temperature sensors are installed in the cooling water mixing device to be spaced apart, and the measured temperature difference is within a preset temperature range. When out, the cooling tower having an intermediate water tank, characterized in that the cooling water mixing device is driven. The method according to claim 1,
the filler is installed in multiple stages on both sides of the housing to face both sides of the blowing fan;
The intermediate water tank is a cooling tower having an intermediate water tank, characterized in that it is installed between the upper filler and the lower filler in each of the respective fillers. 3. The method according to claim 2,
Each of the fillers is provided with first to third fillers stacked on each other in multiple stages;
The intermediate water tank includes a first intermediate water tank installed between the first and second fillers, and a second intermediate water tank installed between the second and third fillers. . 4. The method according to any one of claims 1 to 3,
The intermediate water tank;
Intermediate water tank, characterized in that the lower surface has a plurality of supply holes for supplying a smaller amount of cooling water toward the second area where the air is discharged from the filler than the first area through which the air of the filler is introduced. A cooling tower comprising a. 5. The method according to claim 4,
The intermediate water tank;
A cooling tower having an intermediate water tank, characterized in that the arrangement density of the supply holes decreases from the first area to the second area. 5. The method according to claim 4,
The intermediate water tank;
A cooling tower having an intermediate water tank, characterized in that the diameter of the supply holes is gradually reduced from the first area to the second area. In the cooling tower:
a housing having both sides partially opened to allow air to be introduced from the outside; a blower fan installed in the upper center of the housing to discharge the introduced air to the outside; an upper water tank installed on the inner upper portion of the housing and storing coolant supplied from the outside; first and second fillers stacked on the lower part of the upper water tank in multiple stages to cool the cooling water flowing in from the upper water tank through air flowing in from the outside; a lower water tank installed under the housing to collect cooling water supplied from the upper water tank via the first and second fillers; and between the first and second fillers stacked with each other between the first and the second fillers between the upper water tank and the lower water tank, and between the second filler and the third filler, the first and first and second intermediate water tanks for collecting and storing the cooling water supplied from each of the second fillers, and redistributing the stored cooling water to each of the second and third fillers,
Each of the first and second intermediate water tanks is further provided with a cooling water mixing device that circulates and mixes the stored cooling water to uniformly adjust the temperature of the cooling water, and a plurality of temperature sensors are installed in the cooling water mixing device spaced apart, and the measured A cooling tower having an intermediate water tank, characterized in that the cooling water mixing device is driven when the temperature difference is out of a preset temperature range. 8. The method of claim 7,
each of the first and second intermediate water tanks;
A plurality of lower surfaces such that a smaller amount of cooling water is supplied toward a second region from which the air is discharged from the second or third filler than the first region through which the air of the second or third filler is introduced A cooling tower having an intermediate water tank, characterized in that it has four supply holes. 9. The method of claim 8,
each of the first and second intermediate water tanks;
A cooling tower having an intermediate water tank, characterized in that the arrangement density of the supply holes decreases from the first area to the second area. 9. The method of claim 8,
each of the first and second intermediate water tanks;
A cooling tower having an intermediate water tank, characterized in that the diameter of the supply holes is gradually reduced from the first area to the second area.

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