KR20190006781A - Evaporative condenser - Google Patents

Abstract

An objective of the present invention is to provide an evaporative condenser, increasing cooling efficiency, simplifying manufacturing, and reducing an installation space. To this end, the evaporative condenser (100) comprises: a single flat tube (110) in which a passage of a cooling fluid is formed, and which is bent to be formed in the zigzag direction; an evaporation water supply unit (150) supplying evaporation water to the flat tube (110); and a blower (160) supplying the air to the flat tube (110) in the direction opposite to the flow direction of the evaporation water.

Description

Evaporative condenser < RTI ID = 0.0 >

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an evaporative condenser, and more particularly, to an evaporative condenser capable of improving cooling efficiency, simplifying manufacture, and reducing installation space.

As is known, the condenser is a heat exchanger for cooling and liquefying the high-temperature and high-pressure refrigerant vapor supplied from the compressor. The condenser serves to discharge the heat in the refrigeration cycle to the outside. Depending on the cooling medium, do.

The evaporative condenser is a mixture of water-cooled and air-cooled functions, in which water is sprayed to the tube through which the cooling fluid passes, the air supplied from the blower flows to the surface of the tube, and vaporized water vapor is discharged from the surface of the tube To cool the cooling fluid.

As an example of the prior art related to the evaporative condenser, FIG. 1 shows a heat exchanger for an indirect evaporative liquid cooler disclosed in Korean Patent No. 10-1480830.

The indirectly evaporative liquid cooler heat exchanger shown in FIG. 1 has a vertical cooling fluid passage through which a cooling fluid can flow, and is arranged in a multi-row arrangement spaced apart from each other along a direction crossing the air advancing direction and the air advancing direction A plurality of flat tubes (10); A heat transfer fin (20) provided between the plurality of flat tubes (10) and passing air therethrough; And a heat transfer plate (30) disposed between the plurality of flat tubes (10) and the heat transfer fins (20) for guiding the evaporation water to be uniformly distributed to the flat tubes (10) And an air blower (not shown) for supplying air in a horizontal direction crossing the flow direction of the evaporation water (not shown).

The conventional evaporative condenser constructed as described above is characterized in that the flat tube 10 is provided with a multi-row flat tube 10 which is separated from the vertical direction of the air moving direction and horizontally and separated from each other, At both ends, a plurality of head portions (not shown) are provided for connecting the flow of the cooling fluid between adjacent flat tubes 10.

In addition, the heat transfer plate 30 is in surface contact with both sides of the flat tube 10 in order to improve a non-uniform distribution phenomenon in which evaporation water is deflected and flowed into a spaced space between the flat tubes 10 in a row .

However, in the conventional evaporative condenser constructed as described above, the number of the head portions for connecting the adjacent flat tubes 10 is excessively required, which makes it difficult to manufacture and is a major cause of fluid leakage. In addition, since the flat tubes 10 and the heat transfer plates 30 are provided in multiple rows, the volume of the evaporative condenser (heat exchanger) becomes large, and a manufacturing process due to the assembly of a plurality of heads is difficult.

Further, the evaporation water supply unit is provided on the upper side of the flat tube 10, and the blower is provided on one side of the flat tube 10, so that the entire volume of the evaporative condenser becomes large and the occupied area is increased, There is a problem that is difficult to do.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an evaporative condenser which is improved in cooling efficiency, is easy to manufacture, and can reduce installation space.

The evaporative condenser 100 according to the present invention for realizing the above object comprises a single flat tube 110 formed inside the flow channel of the cooling fluid and bent in the zigzag direction, And an air blower 160 for supplying air to the flat tube 110 in a direction opposite to the flow direction of the evaporation water.

The flat tube 110 includes a plurality of flat portions 110a arranged in the longitudinal direction and spaced apart from each other by a predetermined distance in the lateral direction and a plurality of curved portions 110b connecting between both side ends of the adjacent flat portion 110a, (110b).

A radiating fin 140 disposed in the longitudinal direction and in contact with the planar portion 110a may be provided between the adjacent planar portions 110a.

The evaporation water supplied from the evaporation water supply unit 150 flows downward through a space between the flat tube 110 and the radiating fin 140. The air supplied from the blower 160 flows through the flat tube 110, Can flow upwardly through the space between the heat sink fin (110) and the radiating fin (140).

The radiating fins 140 may have a predetermined angle and alternately be bent in one direction and the other direction so that the curved ends of the radiating fins 140 are in contact with the flat portion 110a.

A first head 120 having a cooling fluid inlet 121 is connected to one end of the flat tube 110 and a second head 120 having a cooling fluid outlet 131 formed at the other end of the flat tube 110. And a part 130 may be connected.

The first baffle 122 is located inside the first head part 120 and is located below the cooling fluid inlet 121 and divides the inside of the first head part 120 up and down, 2, a second baffle 132 may be disposed on the upper side of the cooling fluid outlet 131 to divide the inside of the second head part 130 up and down.

The cooling fluid inlet 121 may be formed at an upper side of the first head 120 and the cooling fluid outlet 131 may be formed at a lower side of the second head 130.

A plurality of partition walls 111 for vertically dividing the inner space of the flat tube 110 are provided in the flat tube 110 and the cooling fluid flows between the partition walls 111 arranged vertically adjacent to each other. A channel 112 may be formed.

The cooling fluid introduced through the cooling fluid inlet 121 flows through the first head portion 120 and the flat tube 110 by the first baffle 122, the second baffle 132, And the second head part 130, and then discharged through the cooling fluid outlet 131. In this case,

The flow direction of the cooling fluid may be opposite to the flow direction of the air.

The surface of the flat tube 110 and the radiating fin 140 may be coated with a hydrophilic coating 113.

According to the evaporative condenser of the present invention, since the single flat tube is constituted by the bending and the supine type structure, evaporation water sprayed from the evaporation water supply unit is uniformly distributed over the entire surface of the flat tube, The heat exchange between the cooling fluid flowing inside the tube can be smoothly performed, and the cooling efficiency of the cooling fluid can be improved.

Further, since the baffle is provided inside the head portion connected to both ends of the flat tube, the flow direction of the cooling fluid can be switched while using a single flat tube, so that the flow path of the cooling fluid flowing inside the flat tube So that the cooling efficiency can be improved and the flow path of the cooling fluid can be realized in the same manner as in the case of using a flat tube of a single row but a multi-row flat tube.

In addition, since a plurality of partition walls are provided in the inside of the flat tube to form a plurality of channels in the space between the partition walls, the heat transfer area where the cooling fluid flowing inside the flat tube contacts the partition wall can be increased to improve the cooling efficiency .

Further, the cooling efficiency of the cooling fluid can be improved by configuring the macroscopic flow direction of the cooling fluid and the air flow direction to be opposite to each other.

Further, by using a single flat tube, the number of the head parts for switching the flow path of the cooling fluid can be reduced, and the design and manufacture of the product can be facilitated, the volume of the product can be reduced, and the installation space can be utilized efficiently.

In addition, since the flow direction of the evaporation water and the flow direction of the air are parallel to the gravity direction and are opposed to each other, space for installing the evaporation water supply unit and the blower can be reduced.

In addition, by arranging the flat tube and the radiating fin in the longitudinal direction, the evaporated water ejected from the evaporating water supply unit can be smoothly discharged in the gravity direction through the space between the flat tube and the radiating fin. Therefore, And it is possible to apply various types of heat radiating fins.

Further, by coating the surface of the flat tube and the radiating fin with a hydrophilic coating, it is possible to provide an evaporative heat exchanger having hydrophilicity, antibacterial property, and corrosion resistance.

1 is a perspective view of a heat exchanger for an indirect evaporative liquid cooler disclosed in Korean Patent No. 10-1480830,
2 is a perspective view of an evaporative condenser using a single flat tube of the present invention,
Fig. 3 is a plan view of Fig. 2,
4 is a sectional view taken along line AA in Fig. 3,
5 is a developed sectional view of the evaporative condenser of the present invention,
6 is a cross-sectional view showing a state in which a surface of a tube is coated with a hydrophilic film.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 to 6, the evaporative condenser 100 of the present invention includes: a single flat tube 110 formed with a flow path of a cooling fluid therein and bent in a zigzag direction; An evaporation water supply unit 150 for supplying evaporation water to the tube 110 and an air blower 160 for supplying air to the flat tube 110 to flow in a direction opposite to the flow direction of the evaporation water, do.

A first head 120 having a cooling fluid inlet 121 is connected to one end of the flat tube 110 and a cooling fluid outlet 131 is formed at the other end of the flat tube 110. 2 head portion 130 are connected.

In addition, the outer surface of the flat tube 110 is provided so as to be in contact with the radiating fin 140.

The flat tube 110 is formed by bending a flat tube and serpentine type, that is, it is connected serpentine in a zigzag direction. The flat tube 110 is arranged in the longitudinal direction and is arranged at a predetermined interval And a plurality of curved portions 110b connecting the plurality of spaced apart planar portions 110a and the two side ends of the adjacent planar portions 110a to switch the flow path of the cooling fluid.

4, the flat tube 110 includes a plurality of partition walls 111 for vertically partitioning the inner space of the flat tube 110, and a cooling fluid flows between the partition walls 111 disposed vertically adjacent to each other. A channel 112 is formed. Both ends of the partition 111 are provided to contact the inner surface of the flat tube 110 so that the heat transferred from the cooling fluid is transferred to the flat tube 110 through the partition 111. Since the plurality of partitions 111 are provided in the flat tube 110, the heat transfer area between the cooling fluid flowing inside the flat tube 110 and the partition wall 111 is increased to improve the cooling efficiency of the cooling fluid. .

The first head portion 120 and the second head portion 130 are configured to switch the flow direction of the cooling fluid flowing along the inside of the flat tube 110.

The first baffle 122 is located inside the first head part 120 and is located below the cooling fluid inlet 121 and divides the inside of the first head part 120 up and down, 2, a second baffle 132 is located inside the head part 130 and is located above the cooling fluid outlet 131 and divides the inside of the second head part 130 up and down.

The cooling fluid inlet 121 is formed on one side of the upper portion of the first head portion 120 and the cooling fluid outlet 131 is formed on the lower side of the second head portion 130 . Therefore, the inner space of the first head part 120 is divided into a first space S1 on the upper side and a third space S3 on the lower side with respect to the first baffle 122, 130 are divided into a second space S2 on the upper side and a fourth space S4 on the lower side with reference to the second baffle 132. [

Referring to FIGS. 4 and 5, the cooling fluid introduced into the first space S1 through the cooling fluid inlet 121 flows toward the lower side of the first baffle 122 Flows through the channel 112 formed in the upper part of the flat tube 110 and flows in the direction toward the second head part 130. The cooling fluid flowing into the second space S2 of the second head part 130 is blocked from flowing to the lower side of the second baffle 132 so that the flow direction is switched to the center of the vertical height of the flat tube 110 And flows in a direction toward the first head part 120 through the channel 112 formed in the first head part 120. The cooling fluid flowing into the third space S3 of the first head part 120 flows again through the channel 112 formed in the lower part of the cooling tube 110 and flows through the second head part 130, Flows into the fourth space S4 of the second head part 130, and is discharged through the cooling fluid outlet 131. [

The cooling fluid introduced through the cooling fluid inlet 121 is passed through the first baffle 122 and the second baffle 132 and the partition wall 111 to the first head 120 and the flat tube 110 and the second head portion 130 and then discharged through the cooling fluid outlet 131. [

The first baffle 122 is provided in the first head part 120 and the second baffle 132 is provided in the second head part 130 so that the single flat tube 110 is used The length of the flow path of the cooling fluid flowing inside the flat tube 110 can be made long.

Although the baffles 122 and 132 are provided in the first head part 120 and the second head part 130 in the present embodiment, the number of the baffles 122 and 132 may be more So that the number of times the flow path of the cooling fluid is switched can be further increased.

1 and 2, the radiating fin 130 is disposed in the longitudinal direction between the flat portions 110a of the adjacent flat tubes 110, and is formed at a predetermined angle and alternately in one direction and the other And the folded end portion is configured to abut the flat surface portion 110a disposed adjacent thereto. Although the radiating fin 130 is bent at a predetermined angle in the present embodiment, the radiating fin 130 may be formed to have a corrugated shape so that the protruding ends of the radiating fin 130 may be in contact with the adjacent flat portions 110a. have.

The evaporation water supply unit 150 is configured to supply evaporation water to the flat tube 110 and the radiating fin 140. The evaporation water supply unit 150 is provided on the upper side of the flat tube 110 and includes an evaporation water supply pipe And a plurality of nozzles (not shown) for spraying evaporated water.

The evaporated water sprayed from the evaporated water supply unit 150 is distributed to the surfaces of the flat tube 110 and the radiating fin 140 to absorb heat from the cooling fluid flowing along the inside of the flat tube 110, And the remaining cooling fluid that has not evaporated flows downward through a space between the flat tube 110 and the radiating fin 140 to be drained.

The blower 160 is provided below the flat tube 110 and air supplied from the blower 160 flows upward through a space between the flat tube 110 and the radiating fin 140. The air supplied from the blower 160 flows in a direction opposite to the flow direction of the evaporation water and the surface of the flat tube 110 and the radiating fin 140 is cooled while the flat tube 110 and the radiating fin 140 to cool the cooling fluid by promoting vaporization of the evaporating water flowing through the surface of the cooling fluid.

5, the macroscopic flow of the cooling fluid is transmitted to the upper portion of the flat tube 110, as shown in FIG. 5, since the evaporation water and the air flow opposite to each other in the opposite direction, So that the cooling fluid and the air flow opposite to each other in the opposite direction, so that the heat exchange efficiency between the cooling fluid and the air can be improved.

6, the hydrophilic coating 113 may be coated on the surfaces of the flat tube 110 and the radiating fin 140. In addition, as shown in FIG. According to such a configuration of the hydrophilic coating 113, the hydrophilicity, antibacterial and corrosion resistance of the flat tube 110 and the radiating fin 130 can be improved, and heat exchange efficiency and durability can be improved.

As described above, in the evaporative condenser 100 of the present invention, the number of the flat tubes 110 is formed by bending to have a supine type structure, so that the evaporated water sprayed from the evaporated water supply unit 150 flows to the flat tubes 110 So that the heat exchange between the evaporated water and the cooling fluid can be smoothly performed, thereby improving the cooling efficiency of the cooling fluid.

That is, in the case of using the flat tube 10 which is conventionally arranged in a plurality of rows, the heat transfer plate 30 is configured to solve the problem that the evaporation water flows in a deflected state to the space between the adjacent flat tubes 10, However, in the present invention, since the flat tube 110 is formed of a single tube, the evaporation water does not move due to deflection, so that the structure of the heat transfer plate 30 can be omitted, Making it easier to manufacture and less bulky.

Since only a single flat tube 110 is used in the present invention, only two head units 120 and 130 need to be installed at both ends of the flat tube 110, It is possible to reduce the number of the head parts to be mounted, thereby facilitating the design and manufacture of the product, reducing the volume of the product, and making efficient use of the installation space.

Since the baffles 122 and 132 are provided inside the head portions 120 and 130 connected to the opposite ends of the flat tube 110, the direction of flow of the cooling fluid can be switched using the single flat tube 110, The length of the flow path of the cooling fluid flowing in the inside of the flat tube 110 can be made long to improve the cooling efficiency and the conventional case of using the flat tube 10 of a plurality of rows while using the single flat tube 110 The flow path of the same cooling fluid can be realized.

In addition, since the flow direction of the evaporation water and the flow direction of the air are opposite to each other in parallel with the direction of gravity, space for installing the evaporation water supply unit 150 and the blower 160 can be reduced.

In addition, by arranging the flat tube 110 and the radiating fin 140 in the longitudinal direction, the evaporated water sprayed from the evaporating water supply unit 150 flows smoothly in the gravity direction through the space between the flat tube 110 and the radiating fin 140 And it is not necessary to form a separate through hole for draining the evaporating water to the radiating fin 140, unlike the prior art, so that various types of radiating fins can be applied and the compatibility of the product can be improved.

As described above, the present invention is not limited to the above-described embodiments, and various changes and modifications may be made without departing from the scope of the present invention as defined in the appended claims. And such modifications are within the scope of the present invention.

10: flat tube 20: heat transfer pin
30: Heat transfer plate 100: Evaporative condenser
110: flat tube 110a: flat portion
110b: curved surface portion 111: partition wall
112: channel 113: hydrophilic coating
120: first head part 121: cooling fluid inlet
122: first baffle 130: second head part
131: cooling fluid outlet 132: second baffle
140: radiating fin 150: evaporating water supply unit
160: blower

Claims (12)

A single flat tube (110) formed with a flow path of a cooling fluid therein and bent in a zigzag direction;
An evaporation water supply unit 150 for supplying evaporation water to the flat tube 110; And
A blower 160 for supplying air to the flat tube 110 in a direction opposite to the flow direction of the evaporation water; / RTI > The method according to claim 1,
The flat tube 110 includes a plurality of flat portions 110a arranged in the longitudinal direction and spaced apart from each other by a predetermined distance in the lateral direction and a plurality of curved portions 110b connecting between both side ends of the adjacent flat portion 110a, (110b). ≪ / RTI > 3. The method of claim 2,
And a radiating fin (140) arranged in the longitudinal direction and in contact with the planar portion (110a) is provided between the adjacent planar portions (110a). The method of claim 3,
The evaporation water supplied from the evaporation water supply unit 150 flows downward through a space between the flat tube 110 and the radiating fin 140,
Wherein the air supplied from the blower (160) flows upward through a space between the flat tube (110) and the radiating fin (140). The method of claim 3,
Wherein the heat radiating fins (140) have a predetermined angle and are alternately bent in one direction and the other direction, and are in contact with the flat portion (110a) where the bent ends are disposed adjacent to each other. The method according to claim 1,
A first head portion 120 having a cooling fluid inlet 121 is connected to one end of the flat tube 110,
And a second head (130) having a cooling fluid outlet (131) is connected to the other end of the flat tube (110). The method according to claim 6,
A first baffle 122 is disposed inside the first head part 120 and is located below the cooling fluid inlet 121 and divides the inside of the first head part 120 up and down.
And a second baffle 132 located above the cooling fluid outlet 131 and dividing the interior of the second head part 130 into upper and lower parts is provided in the second head part 130. [ Evaporative condenser. 8. The method of claim 7,
The cooling fluid inlet 121 is formed on one side of the upper portion of the first head portion 120,
And the cooling fluid outlet (131) is formed at a lower side of the second head part (130). 9. The method of claim 8,
A plurality of partition walls 111 for vertically dividing the inner space of the flat tube 110 are provided in the flat tube 110 and the cooling fluid flows between the partition walls 111 arranged vertically adjacent to each other. Wherein a channel (112) is formed in the upper surface of the evaporator. 10. The method of claim 9,
The cooling fluid introduced through the cooling fluid inlet 121 flows through the first head portion 120 and the flat tube 110 by the first baffle 122, the second baffle 132, And flows through the second head part (130) in a zigzag direction, and then is discharged through the cooling fluid outlet (131). 11. The method of claim 10,
Wherein the flow direction of the cooling fluid is opposite to the flow direction of the air. The method of claim 3,
Wherein a surface of the flat tube (110) and the radiating fin (140) is coated with a hydrophilic coating (113).

Images