KR102156132B1 - Cooling Tower Integrated Freezer With Leakage Prevention Device And Cooling System - Google Patents

Abstract

The present invention relates to a cooling tower integrated freezer provided with a water leakage prevention device and a cooling system. The cooling tower installed in a structure includes: a heat exchange part formed by an inlet through which the outside air flows inwards and an outlet through which the outside air is discharged to the outside; a supply part for supplying cooling water to the heat exchange part to perform heat exchange with the outside air; a blowing fan formed at the inlet or the outlet; and a first recovery part in which the cooling water heat-exchanged by the heat exchange part is collected, wherein the first recovery part discloses the cooling tower, characterized in that an upper surface of the structure is shared as a lower surface, thereby remarkably improving the space utilization of the structure, and the cooling system using the same.

Description

Cooling Tower Integrated Freezer With Leakage Prevention Device And Cooling System {Cooling Tower Integrated Freezer With Leakage Prevention Device And Cooling System}

The present invention relates to a cooling tower and a cooling system, and more particularly, to a cooling tower installed in a structure and a cooling system using the same.

The cooling tower is installed outside the building and is connected to a refrigerator installed inside the machine room to provide cooling inside. At this time, it is included in the building area by a partition (roof or ceiling) formed between the machine room roof, that is, the machine room and the cooling tower. Therefore, there was a problem in that the space utilization of the building was deteriorated, and in the case of a large building requiring large-capacity cooling, it emerged as an important problem in that the size of the machine room was required in proportion.

In addition, when a plurality of cooling towers are used, there is a problem in that the installation space is increased while a pipe supplying cooling water to each cooling tower is generally located in the center.

An embodiment of the present invention has been conceived to solve the above problems, and an object of the present invention is to provide a cooling tower integrated refrigerator and cooling system provided with a leakage preventing device capable of remarkably improving the space utilization of a cooling tower installation location.

A cooling tower according to an embodiment of the present invention is provided in a cooling tower installed in a structure to solve the above problems, comprising: a heat exchanger formed of an inlet through which outside air is introduced and an outlet through which outside air is discharged; A supply unit supplying cooling water to the heat exchange unit to heat exchange with the outside air; A blowing fan formed at the inlet or the outlet; And a first recovery unit for collecting the coolant heat-exchanged in the heat exchange unit, wherein the first recovery unit shares an upper surface of the structure as a bottom surface.

A second recovery unit for recollecting the coolant leaking from the first recovery unit; And a drain passage connected to the second recovery unit to discharge the recollected cooling water.

It may further include a vibration isolator formed on one side of the blower fan to prevent transmission of vibration due to operation.

The bottom surface of the first recovery unit sharing the upper surface of the structure may be formed of a plurality of plate members, and in this case, the second recovery unit is formed under the first recovery unit corresponding to a position where the different plate members contact each other. It is desirable.

A cooling system according to an embodiment of the present invention includes a plurality of cooling towers formed of a heat exchange unit, a supply unit, and a blowing fan, and formed on an upper portion of the structure; A recovery unit for collecting coolant heat exchanged by the heat exchange unit; A cooling water passage connected to each of the supply units and formed outside the cooling tower to supply the cooling water; And a case disposed outside to accommodate the cooling tower and the cooling water passage, wherein the recovery unit is formed under the cooling tower to collect the cooling water, and shares an upper surface of the structure as a bottom surface.

The recovery unit includes a first recovery unit for collecting the cooling water heat-exchanged with outside air in the heat exchange unit, a second recovery unit for recollecting the cooling water leaking from the first recovery unit, and It may be formed as a drain passage for discharging the collected cooling water.

The cooling tower is formed on one side of the blowing fan, and a vibration isolator for preventing vibration transmission due to operation; may be further formed.

The cooling water passage is preferably formed eccentrically between different cooling towers, and the bottom surface of the first recovery unit sharing the upper surface of the structure may be formed of a plurality of plate members. In this case, the second recovery unit It is preferable that the plate member is formed under the first recovery part in correspondence with the contact position.

As described above, according to the problem solving means of the present invention, various effects including the following can be expected. However, the present invention is not established when all of the following effects are exhibited.

The cooling tower according to the present invention may be excluded from the building area by sharing the upper surface of the structure on which the cooling tower is installed as the lower surface of the first recovery part through which cooling water is collected. Therefore, the space utilization of the structure can be remarkably improved.

At this time, the upper surface of the structure forming the lower surface of the first recovery unit is formed of a plurality of plate members to facilitate installation, and a second recovery unit is formed at the position where different plate members abut to prevent leakage through the gap for maintenance. Reduce costs.

In addition, a vibration isolator is formed on one side of the blower, absorbing the vibration generated by the operation of the fan, and extending the path through which the vibration is transmitted to the structure to secondaryly cancel the vibration. Therefore, it has the effect of reducing the vibration transmitted to the structure.

The cooling system according to the present invention includes a cooling tower having the above effect, and a cooling water passage for supplying cooling water to each of the plurality of cooling towers is formed eccentrically between different cooling towers, thereby reducing the installation space of the cooling system.

In addition, it further includes a case for accommodating a plurality of cooling towers and cooling water passages formed outside to improve the appearance quality of the structure.

1 is a perspective view of a structure to which a cooling system according to an embodiment of the present invention is applied.
Figure 2 is a schematic diagram for explaining a state in which the cooling system of Figure 1 is installed in the structure. 3 is an enlarged view of the first and second recovery units of FIG. 2.
4 is a view showing a state in which the heat transfer fluid flow path is installed in the direction A of FIG. 2.

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

However, since the cooling system according to an embodiment of the present invention includes a cooling tower according to the present invention, the cooling tower is included in a detailed description of the cooling system in order to omit the same description. In addition, in describing the present invention, detailed descriptions of known functions or configurations will be omitted in order not to distract the subject matter of the present invention.

1 is a perspective view of a structure to which the cooling system according to an embodiment of the present invention is applied, and FIG. 2 is a schematic diagram illustrating a state in which the cooling system of FIG. 1 is installed on the structure. 3 is an enlarged view illustrating the first and second recovery units of FIG. 2, and FIG. 4 is a view illustrating a state in which a cooling water passage is installed in a direction A of FIG. 2.

1 to 4, the cooling system 10 according to an embodiment of the present invention is formed of a heat exchange unit 110, a supply unit 120, and a blowing fan 130, and is formed on the upper portion of the structure 20. A plurality of cooling towers 100, a recovery unit 200 for collecting the heat transfer fluid heat-exchanged by the heat exchange unit 110, and connected to each of the supply units 120 to supply the heat transfer fluid to the outside of the cooling tower 100 And a case 400 disposed outside to accommodate the formed heat transfer fluid flow path and the cooling tower 100 and the heat transfer fluid flow path, and the recovery unit 200 includes the cooling tower 100 to collect the heat transfer fluid. Doedoe formed in the lower portion of the structure 20 is characterized in that to share the bottom surface 212.

The cooling system 10 of the present invention refers to a system that is connected to a refrigerator and cools the heat transfer fluid supplied from the refrigerator through heat exchange with outside air and returns to the refrigerator. Accordingly, the cooling system 10 of the present invention is a system having the same function as the cooling tower 100 and includes a plurality of cooling towers 100, and is defined as a system. The cooling tower 100 is installed in the structure 20, a heat exchange unit 110 formed of an inlet 111 through which outside air flows into the inside, an outlet 112 through which outside air is discharged, and heat exchange with the outside air. As much as possible, the supply unit 120 for supplying the heat transfer fluid to the heat exchange unit 110, the blowing fan 130 formed in the inlet 111 or the outlet 112, and the heat transfer fluid heat-exchanged in the heat exchange unit 110 It includes a first recovery unit 210 is collected, the first recovery unit 210 is characterized by sharing the upper surface of the structure 20 as the bottom surface 212.

At this time, the cooling tower 100 may be further formed with a vibration isolator 140 formed on one side of the blowing fan 130 to prevent transmission of vibration due to operation.

The heat exchange unit 110 is formed of an inlet 111 through which outside air flows into the cooling tower 100 from the outside, and an outlet 112 through which outside air heat-exchanged with the heat transfer fluid inside the cooling tower 100 is discharged back to the outside. do. At this time, in the case of the open-type cooling tower 100, an eliminator 113 is formed between the inlet 111 and the outlet 112 to facilitate heat exchange between the heat transfer fluid sprayed from the supply unit 120 and the outside air. .

In the cooling tower 100 of an example, the inlet 111 is formed on one side, the outlet 112 is formed on the upper side, and the internal outdoor air is discharged to the outside according to the operation of the blower fan 130 installed in the outlet 112 According to this, a suction-blowing cooling tower 100 through which outside air is sucked through the inlet 111 is used.

The supply unit 120 is formed in a heat exchange unit 110 comprising an inlet 111 and an outlet 112 to supply heat transfer fluid so that heat can be exchanged with outside air. Therefore, in the case of the open type cooling tower 100, the supply unit 120 is formed by spray to spray the heat transfer fluid, and in the case of the closed type cooling tower 100, it is formed as a plurality of pipes so that the heat transfer fluid flows into the pipe.

In addition, the supply unit 120 is formed in communication with the heat transfer fluid flow path so that the heat transfer fluid with an increased temperature is supplied from the refrigerator.

The blowing fan 130 is formed adjacent to the outlet 112 so that the outside air inside the cooling tower 100 is discharged to the outside. Accordingly, a flow of outside air is generated in the heat exchange unit 110 to facilitate heat exchange between the outside air and the heat transfer fluid. Therefore, it is preferable that the blowing fan 130 is formed across the outlet 112.

At this time, since the blowing fan 130 is generally formed of a driving unit (motor) that drives the rotation of the wing portion and the wing portion, vibration is generated by the operation of the cooling tower 100. Accordingly, it is preferable that the cooling system 10 of the present invention further includes a vibration isolator 140.

The vibration isolator 140 is formed on one side of the blowing fan 130 and absorbs or cancels the vibration generated by the rotation of the blade unit to minimize the vibration transmitted to the structure 20. In the case where a plurality of cooling towers 100 are used, vibrations transmitted to the structure 20 may overlap and thus noise and vibration problems may occur in the surroundings, so this is prevented in advance.

In particular, the vibration isolator 140 is formed on one side of the driving unit (motor) to block vibration transmitted to the outer wall of the cooling tower 100. To this end, the anti-vibration unit 140 is a prevention pad, a dust-proof soup

It may be formed of a ring, etc., and vibrations that are not absorbed by the prevention unit must be transmitted along the outer wall of the cooling tower 100 in order to be transmitted to the structure 20, so the vibration path is increased to reduce the vibration transmitted to the structure 20. Can be minimized.

Therefore, the blowing fan 130 of the present invention is preferably formed on the upper side of the cooling tower 100, and the vibration isolator 140 is preferably formed between the blowing fan 130 and the outer wall of the cooling tower 100. An example of the vibration isolator 140, as shown in Figure 2, the blowing fan 130 is disposed across the upper outlet 112 of the cooling tower 100, the vibration isolator 140 is a blowing fan 130 It is formed between the lower side of, that is, between the blowing fan 130 and the outer wall of the cooling tower 100.

The recovery unit 200 collects the heat transfer fluid heat-exchanged with outside air in the heat exchange unit 110 and reuses the heat transfer fluid. Specifically, the recovery unit 200 includes a first recovery unit 210 that collects heat transfer fluid that is heat-exchanged from the heat exchange unit 110 and falls off, and a first recovery unit 210 that collects all heat fluid leaking from the first recovery unit 210. It is formed of a 2 recovery part 220 and a drain passage 230 connected to the second recovery part 220 to discharge the re-collected total heat fluid.

In addition, it is preferable that the recovery unit 200 is formed under the cooling tower 100 and protrudes into the structure 20 so as to reduce energy used for circulation of the cooling water. At this time, in the case of the cooling tower 100 in which the blowing fan 130 is formed on the inlet 111 side, the recovery part 200 is formed to protrude only from a part of the lower surface of the cooling tower 100, and the blowing fan 130 is formed It is formed so as not to protrude so that the inner space of the structure 20 can be secured to the maximum.

The first recovery unit 210 is disposed under the cooling tower 100 and is formed of a side surface 211 formed to enclose all directions and a bottom surface 212 connected to each side surface 211 to form a water tank.

At this time, the first recovery unit 210 shares the upper surface of the structure 20 as the bottom surface 212 and collects the heat transfer fluid heat-exchanged with outside air on the upper side of the structure 20. In other words, the bottom surface 212 of the first recovery unit 210 covers the upper surface of the structure 20 so that the roof formed between the conventional structure 20 and the cooling tower 100 can be removed, thereby providing the utilization space 21. to provide.

Specifically, if the structure 20 has a roof, it corresponds to the building area and is included in the total area of use of the structure 20. Therefore, the space in which the refrigerator connected to the cooling tower 100 is installed (for example, a machine room) is included in the building area, reducing the use of space for the structure 20, and in the case of a large building, such space is proportional to the size of the building. Therefore, space utilization is greatly reduced because it must be increased.

In addition, the bottom surface 212 of the first recovery unit 210, that is, the upper surface of the structure 20 is preferably formed of a plate member 2121, in a direction transverse to the direction in which the plate members 2121 are sequentially arranged. It is preferable that a reinforcing member is further formed to support the first recovery unit 210.

Specifically, the reinforcing member is disposed in a direction perpendicular to the plurality of plate members 2121 and fixed to each plate member 2121 to support the first recovery unit 210 to improve the stability of the cooling system 10. Accordingly, the first recovery unit 210 of the present invention provides a cooling system 10 having a stronger competitiveness because it has the effect of improving workability and reducing initial cost by facilitating transportation and installation, and also securing stability. do.

Specifically, the first recovery unit is formed under the cooling tower corresponding to the position of the supply unit to collect cooling water,

The second recovery unit 220 recollects the heat transfer fluid leaking from the first recovery unit 210 and discharges the heat transfer fluid to the outside, thereby preventing the heat transfer fluid from leaking into the lower utilization space 21. Accordingly, the second recovery unit 220 may be formed in plural according to the number of the gaps 2122, protect facilities installed in the utilization space 21, and reduce consumption of heat transfer fluid.

In addition, the second recovery unit 220 prevents anyone who may occur in the structure as rain or snow penetrates from the outside, moisture contained in cold air is condensed, or coolant leaks from the water tank of the cooling tower 100, It provides improved convenience to users and reduces maintenance costs.

Therefore, the second recovery unit 220 is formed on the lower side of the bottom surface 212 of the first recovery unit 210 and corresponds to the gap 2122 inevitably formed at a position where the different plate members 2121 contact each other. It is preferable to be installed, and since the second recovery unit 220 is also formed of the bottom surface 212 of the first recovery unit 210 as a plate member 2121, the second recovery unit 220 also has a modular size, etc. As it can be manufactured, it increases cost reduction effect.

The drain passage 230 is connected to each of the second recovery units 220 to discharge the heat transfer fluid recollected in each of the second recovery units 220 to the outside.

Therefore, the cooling tower 100 and the cooling system 10 including the same of the present invention include a first recovery unit 210 that shares the upper surface of the structure 20 as the bottom surface 212 to improve the space utilization of the structure 20. It significantly improves, and has the effect of reducing initial cost and maintenance cost by using the plate member (2121). In addition, it has an effect of significantly improving the user's convenience by providing the second recovery unit 220 to block leakage of water due to the gap portion 2122 inevitably generated by the use of the plate member 2121.

The cooling water passage 300 is connected to the cooling tower 100 to supply the heat transfer fluid supplied from the outside to the cooling tower 100. For example, when connected to a refrigerator, the cooling water, which is connected to the condenser and the supply unit 120, respectively, to increase the temperature of the condenser, is delivered to the supply unit 120. Therefore, the cooling water passage 300 is formed outside the cooling tower 100.

At this time, in the cooling system 10 of the present invention including a plurality of cooling towers 100, the cooling water flow path 300 is connected to the supply unit 120 formed in each cooling tower 100, and is formed between different cooling towers 100. do. At this time, the cooling water passage 300 is preferably formed to be eccentric from the center of the cooling tower (100).

The eccentric cooling water passage 300 is formed to be eccentric in different directions from the center of each cooling tower 100, as shown in FIG. 4, so as not to interfere with each other installation positions. Therefore, the cooling system 10 of the present invention has an effect of reducing the installation space compared to the cooling water passage 300 formed in the center of the related art. In addition, the cooling water passage 300 is formed between the cooling tower 100 and the cooling water passage 300 is not disposed outside, thereby helping to improve the appearance quality.

The case 400 is disposed outside to accommodate the cooling tower 100 and the cooling water passage 300. At this time, it is formed so as to cover all of the plurality of cooling towers 100 to improve the appearance quality of the cooling system 10, and primarily prevents impurities from entering the cooling tower 100. In addition, the case 400 may be applied even when the cooling tower 100 is formed as one.

At this time, it is preferable that the case 400 has an opening corresponding to the positioning of the inlet 111 and the outlet of the cooling tower 100, and a grill is formed at the opening so that outside air flows into the cooling tower 100 and To facilitate the discharge to the outside of the cooling tower 100.

Therefore, the cooling tower 100 and the cooling system 10 including the same of the present invention have a recovery unit 200 to significantly improve the space utilization of the structure 20, and at the same time include the case 400, the cooling water passage 300 It has the effect of improving the appearance quality by specifying the placement position of ).

In the above, preferred embodiments of the present invention have been exemplarily described, but the scope of the present invention is not limited to such specific embodiments, and it is possible to appropriately change within the scope described in the claims falls within the protection scope of the present invention. do.

10 Cooling system 20 Structure 21 Space used
100 Cooling tower 110 Heat exchange part 111 Inlet
112 Outlet 113 Eliminator 120 Supply
130 Blower fan 140 Dustproof part
200 Recovery part 210 First recovery part 211 Side
212 Bottom 2121 Plate member 2122 Gap
220 Second recovery unit 230 Drain passage
300 electric heating fluid flow path
400 cases

Claims (12)

In the cooling tower installed in the structure,
A heat exchanger formed of an inlet through which outside air flows into and an outlet through which outside air is discharged;
A supply unit supplying cooling water to the heat exchange unit to heat exchange with the outside air;
A blowing fan formed at the inlet or the outlet;
A first recovery unit formed under the heat exchange unit in a state in which a plurality of plate members are arranged to collect the heat-exchanged cooling water;
A second recovery unit formed below the first recovery unit corresponding to a position where the different plate members contact each other to recollect the coolant leaking from the first recovery unit; And
A drain passage connected to the second recovery unit to discharge the recollected coolant; and
The cooling tower, characterized in that the first recovery unit is shared with the upper surface of the structure.
delete The method of claim 1,
A cooling tower comprising: a vibration isolator formed on one side of the blower fan to prevent vibration transmission by operation.
delete The method of claim 1,
The first recovery unit
A cooling tower, characterized in that formed to protrude from a lower side of the cooling tower.
A plurality of cooling towers formed of a heat exchange part, a supply part, a blowing fan, and a vibration isolator formed between the blowing fan and an outer wall to prevent vibration transmission by operation, and disposed on the left and right sides of the structure;
A recovery part formed under the heat exchange part to collect the coolant heat exchanged by the heat exchange part;
A cooling water passage connected to each of the supply units and formed outwardly being eccentric between the plurality of cooling towers to supply the cooling water; And
Including; a case disposed outside the plurality of the cooling tower and the cooling water passage to be accommodated,
The recovery unit
A first recovery unit for collecting the coolant heat-exchanged with outside air in the heat exchange unit, a second recovery unit for recollecting the coolant leaking from the first recovery unit, and a recollected unit connected to the second recovery unit. A cooling system, characterized in that it is formed as a drain passage for discharging the cooling water, and is disposed under the plurality of cooling towers to collect the cooling water and shared with the upper surface of the structure.
delete delete delete The method of claim 6,
The recovery unit
Cooling system, characterized in that formed to protrude from the lower side of the cooling tower.
The method of claim 6,
The bottom surface of the first recovery part is formed of a plurality of plate members,
The second recovery unit
A cooling system, characterized in that it is formed under the first recovery unit in correspondence with positions where the different plate members come into contact.
The method of claim 11,
And a reinforcing member for supporting the first recovery unit across a direction in which the plurality of plate members are arranged.

Images