KR20200075496A - Evaporative heat exchanger - Google Patents

Abstract

An objective of the present invention is to provide an evaporative heat exchanger that can be miniaturized. To this end, the evaporative heat exchanger comprises: a heat exchange part in which a plurality of heat exchange units having inner spaces through which a refrigerant flows are formed between a pair of opposite plates, wherein the inner spaces of the plurality of heat exchange units can be coupled to be connected to each other; and at least one tank provided in a side portion of the plurality of heat exchange units to supply cooling water to an air passage through which air passes between a pair of adjacent heat exchange units.

Description

Evaporative heat exchanger

The present invention relates to an evaporative heat exchanger, and more particularly, to an evaporative heat exchanger capable of miniaturizing the size of the heat exchanger.

An evaporative heat exchanger is a device in which a refrigerant flow path is formed inside the heat exchange part and a cooling air flow path is formed outside the heat exchange part, and a cooling effect is generated by latent heat of evaporation of water by spraying water into the flow path through which the cooling air flows.

Korean Patent Publication No. 10-2006-0083498 has been published as a prior art for an evaporative heat exchanger.

The evaporative heat exchanger shown in the prior art includes an evaporative cooling heat exchanger including a heat transfer tube through which a refrigerant flows, and a sprinkling part provided on the evaporative cooling heat exchanger to sprinkle cooling water in the evaporative cooling heat exchanger It is done.

According to such a conventional evaporative heat exchanger, there is a problem that the size of the device is increased because the sprinkling portion is provided on the upper portion of the heat exchanger.

In addition, there is a problem in that the distance between the sprinkling part and the heat exchanger increases, so that the cooling water consumption increases.

The present invention has been made to solve the above-mentioned problems, and has an object to provide an evaporative heat exchanger capable of miniaturization.

Another object of the present invention is to provide an evaporative heat exchanger that minimizes consumption of cooling water and improves cooling efficiency.

Another object of the present invention is to provide an evaporative heat exchanger capable of miniaturizing the size of a device and minimizing the consumption of cooling water by locating the location where the cooling water is supplied as close to the heat exchange fin as possible.

In order to achieve the above object, the evaporative heat exchanger of the present invention is provided with a plurality of heat exchange units having an internal space in which refrigerant flows between a pair of plates facing each other, and the internal spaces of the plurality of heat exchange units are A heat exchange unit coupled to communicate; It includes at least one tank provided on the side of the plurality of heat exchange units to supply cooling water to the air passage through which the air between the pair of heat exchange units adjacent to each other in the plurality of heat exchange units.

In the air passage, a first heat exchange pin is respectively attached to a pair of opposite plates of neighboring heat exchange units to exchange heat with air passing through the air passage; Cooling water supplied from the tank may be adsorbed on the surface of the first heat exchange pin.

At least one main water pipe protruding outward of the tank so as to be at least partially positioned on the air passage; A plurality of pouring holes for supplying the cooling water to the air passage may be formed in the pouring pipe.

The inner space of the tank and the inner space of the main water pipe are provided to communicate with each other, and the cooling water in the inner space of the tank flows through the main water pipe and is discharged through the main water hole to adsorb on the surface of the first heat exchange pin. Can be.

The at least one tank is composed of a first tank and a second tank respectively provided on one side and the other side of the heat exchange unit; The water pipe may be formed of a first water pipe coupled to the first tank, and a second water pipe coupled to the second tank.

The first water pipe is provided so that one end is coupled to the first tank and the other end is spaced apart from the second tank to cross at least a portion of the air passage; The second water pipe may be provided such that one end is coupled to the second tank and the other end is spaced apart from the first tank to cross at least a portion of the air passage.

The first water pipe and the second water pipe can be respectively inserted into a plurality of insertion grooves concavely formed on the surface of the plate.

The insertion groove is formed long from the first end portion of the plate toward the second end portion, and the first insertion groove into which the first water pipe is inserted and the long end towards the first end portion from the second end portion of the plate. It can be made of a second insertion groove into which the second water pipe is inserted.

The first insertion groove and the second insertion groove are formed in the plate, and may be alternately formed one by one along the direction in which the air passes.

The water pipe may at least partially protrude from the surface of the first plate or the second plate toward the air passage.

The main water pipe may be provided with a plurality of spaced apart along the air passage.

A pair of openings may be formed in the first plate and the second plate, the refrigerant may be introduced through any one of the pair of openings, and the refrigerant may be discharged through the other one.

A second heat exchange pin may be provided in the space between the pair of plates.

The tank may be provided with direct water, and a flow control means for adjusting the flow rate of the supplied direct water may be provided.

According to the present invention, the size of the device can be downsized by integrating a tank for supplying coolant into a heat exchanger.

In addition, it is possible to improve cooling efficiency while minimizing the consumption of cooling water by arranging a main water pipe for supplying cooling water on an air flow path inside the heat exchanger.

In addition, a heat exchange fin is provided between a pair of neighboring heat exchange units, and cooling water is supplied at a position adjacent to the heat exchange fin, thereby miniaturizing the size of the device and minimizing consumption of cooling water.

1 is a perspective view showing an evaporative heat exchanger according to the present invention.
2 is an exploded perspective view showing an evaporative heat exchanger according to the present invention.
3 is a front view showing an evaporative heat exchanger according to the present invention.
4 is a cross-sectional view taken along line AA of FIG. 3.
5 is a cross-sectional view taken along line BB of FIG. 3.
6 is a cross-sectional view taken along line CC of FIG. 3.

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

1 and 2, the evaporative heat exchanger 100 according to the present invention includes a heat exchange unit 150 through which a refrigerant flows, and at least one tank provided at a side of the heat exchange unit 150 (110,120).

The heat exchange unit 150 is composed of a plurality of heat exchange units 150-1, 150-2, 150-3, 150-4, 150-5 having an inner space in which the refrigerant flows between a pair of plates facing each other.

The plurality of heat exchange units 150-1, 150-2, 150-3, 150-4, 150-5 are spaced apart from neighboring heat exchange units to form air passages P (FIG. 4) through which air flows. Water is supplied to the air flowing through the air passage (P), and the refrigerant in the internal space of the heat exchange unit is cooled by evaporation of the water.

The inner spaces of the plurality of heat exchange units 150-1,150-2,150-3,150-4,150-5 are coupled to communicate with each other.

That is, in the first heat exchange unit 150-1, the edges of the first plate 151 and the second plate 152 facing each other are joined, and the refrigerant flows in the inner space. A first opening portion 151a and a second opening portion 151c, in which a portion of the plate is cut, are formed at upper and lower edges of one side of the first plate 151. In addition, the first opening 152a and the second opening 152c are formed on the second plate 152 in the same shape at positions corresponding to the first opening 151a and the second opening 151c.

In addition, the third heat exchange unit (150-3), the fourth heat exchange unit (150-4), including a second heat exchange unit (150-2) provided adjacent to the first heat exchange unit (150-1), The 5 heat exchange units 150-5 are also provided so that the edges of the pair of plates facing each other are joined to allow refrigerant to flow in the inner space, and the first openings 151a, 152a and the second openings 151c, 152c are provided. The first opening and the second opening are respectively formed in the same shape at a position corresponding to.

The first openings 151a and 152a and the second openings 151c and 152c are both formed in the same shape. In this case, the first opening 151a and the second opening 151c formed in the first plate 151 are upper portions of the first flange 151b and the second flange 151d protruding from the surfaces of the first plate 151. Respectively. In addition, the first opening 152a and the second opening 152c formed in the second plate 152 also have upper portions of the first flange 152b and the second flange 152d protruding from the surface of the second plate 152. Respectively. In this case, the first and second flanges 151b and 151d of the first plate 151 protrude in opposite directions to the first and second flanges 152b and 152d of the second plate 152.

The first heat exchange unit 150-1 and the second heat exchange unit 150-2 are coupled to neighbor each other. That is, the top surface of the first flange 152b formed on the second plate 152 of the first heat exchange unit 150-1 is the first flange formed on the first plate 151 of the second heat exchange unit 150-2. It is joined against the top surface of (151b).

In addition, the upper surface of the second flange 152d formed on the second plate 152 of the first heat exchange unit 150-1 is the second flange formed on the first plate 151 of the second heat exchange unit 150-2. It is joined against the top surface of (151d).

When engaged in this way, the first opening 152a formed in the first flange 152b and the first opening 151a formed in the first flange 151b are connected, and formed in the second flange 152d. The second opening 152c and the second opening 151c formed in the second flange 151d are connected to the interior space of the first heat exchange unit 150-1 and the inside of the second heat exchange unit 150-2. The spaces communicate with each other.

A first opening and a second opening are not formed on the second plate of the fifth heat exchange unit 150-2 provided at the end of the heat exchange unit 150, and may be formed in a closed shape. In this case, one of the first opening 151a and the second opening 151c formed in the first plate 151 of the first heat exchange unit 150-1 becomes a refrigerant inlet through which the refrigerant flows, and the other one It may be a refrigerant outlet through which refrigerant is discharged.

Therefore, the refrigerant introduced through the refrigerant inlet of the first heat exchange unit (150-1) is a second heat exchange unit (150-2), a third heat exchange unit (150-3), a fourth heat exchange unit (150-4), Is introduced into each internal space of the first to fifth heat exchange units 150-1,150-2,150-3,150-4,150-5 through the first opening formed in the first plate 151 of the fifth heat exchange unit 150-5 , The refrigerant that has undergone heat exchange while flowing through the interior space is discharged through the refrigerant outlet of the first heat exchange unit (150-1).

Meanwhile, a plurality of insertion grooves 151f, 151g, 152f, and 152g concave when viewed from the outside of the heat exchange unit are formed on the surfaces of the first plate 151 and the second plate 152, respectively.

In the first heat exchange unit 150-1, the insertion grooves 151f and 151g of the first plate 151 are convex toward the second plate 152, and the second plate 152 The insertion grooves 152f and 152g are convex toward the first plate 151. When the edges of the first plate 151 and the second plate 152 are joined to each other by welding or the like, the inner surface of the insertion grooves 151f and 151g of the first plate 151 and the second The inner surfaces of the insertion grooves 152f and 152g of the plate 152 come into contact with each other, and serve to support the first plate 151 and the second plate 152 so as not to be deformed.

The insertion grooves 151f and 151g of the first plate 151 include a plurality of first insertion grooves 151f formed long from a first end on one side to the second end on the other side of the first plate 151, and It consists of a plurality of second insertion grooves (151g) formed long from the second end of the first plate 151 toward the first end.

In addition, the insertion grooves 152f and 152g of the second plate 152 are formed with a plurality of first insertion grooves 152f formed long from the first end of one side of the second plate 152 toward the second end of the other side. , Consisting of a plurality of second insertion grooves 152g formed long from the second end of the second plate 152 toward the first end.

In this case, the plurality of first insertion grooves 151f and the plurality of second insertion grooves 151g of the first plate 151 are alternately formed from the top to the bottom, and the plurality of the second plates 152 are formed. The first insertion groove 152f and the plurality of second insertion grooves 152g are also alternately formed from the top to the bottom. In addition, in this case, the end of the first insertion groove (151f, 152f) and the second end of the first and second plates (151,152) are spaced apart, and the end of the second insertion groove (151g,152g) The first and second ends of the first and second plates 151 and 152 are also spaced apart.

Zigzag-shaped refrigerant passages are formed inside each heat exchange unit 150-1, 150-2, 150-3, 150-4, 150-5 by such a structure.

The first plate 151 has a plurality of first protrusions 151e protruding toward the outside of the heat exchange unit, and the second plate 152 has a position corresponding to the first protrusions 151e. A plurality of second protrusions 152e protruding toward the outside of the heat exchange unit opposite to the first protrusions 151e are formed.

When the plurality of heat exchange units (150-1,150-2,150-3,150-4,150-5) are combined, a first protrusion 151e formed in one heat exchange unit and a second protrusion 152e formed in a heat exchange unit adjacent thereto are formed. It comes into contact with each other and becomes a structure supported by each other.

The tanks 110 and 120 are composed of a first tank 110 and a second tank 120 provided on one side and the other side of the heat exchange part 150. Cooling water is stored in the inner spaces 111 and 121 of the first tank 110 and the second tank 120. The cooling water may be supplied by being connected to a direct water pipe.

The tanks 110 and 120 are coupled with main water pipes 130 and 140 so as to protrude from the tanks 110 and 120 to supply the cooling water to the air passages P between a pair of heat exchange units adjacent to each other.

The water pipes 130 and 140 have at least a part of the air passage P provided that the first end of one side is coupled to the first tank 110 and the second end of the other side is spaced apart from the second tank 120. A first water pipe 130 traversing the air passage (P) is provided so that the first end of one side is coupled to the second tank 120 and the second end of the other side is spaced from the first tank 110 It consists of a second water pipe 140 that crosses at least a portion of.

The first tank 110 is coupled to the first water pipe 130 in three rows from top to bottom. That is, a plurality of first water pipes 130 are coupled in a row in a horizontal direction at an upper side of one side facing the second tank 120 from the first tank 110, and a plurality of firsts are disposed at the lower portion thereof. The main water pipe 130 is combined in two rows, and a plurality of first main water pipes 130 are combined in three rows at the bottom.

The second water tank 140 is coupled to the second tank 120 in two rows from the top to the bottom. That is, a plurality of second water pipes 140 are coupled in a row in a horizontal direction on one side facing the first tank 110 from the second tank 120, and a plurality of second weeks are located under the second tank 120. The water pipes 140 are combined in two rows.

The second water pipe 140 in the first row is positioned between the first water pipe 130 in the first row and the first water pipe 130 in the second row, and the second water pipe 140 in the second row is the second. It is positioned between the first water pipe 130 in the row and the first water pipe 130 in the third row.

As such, each of the first water pipe 130 and the second water pipe 140 may be formed of a plurality of columns and a plurality of rows.

A plurality of pouring holes 130a and 140a are formed in the first and second injection pipes 130 and 140 along the longitudinal direction, respectively. Cooling water is filled in the first tank 110, the second tank 120, and the main water pipes 130 and 140, and the cooling water is discharged through the main water holes 130a and 140a. The pouring holes 130a and 140a may be formed of fine nozzle holes. Cooling water inside the first tank 110 and the second tank 120 may allow direct water to flow in, and a small amount of cooling water may be supplied through the main water holes 130a and 140a by the pressure through which the direct water flows. have. In this case, a flow control means (not shown) may be further provided to control the flow rate of direct water flowing into the first tank 110 and the second tank 120. The cooling water supplied through the pouring holes 130a and 140a may be adjusted to be small.

Cooling water consumption can be minimized by such a configuration. In particular, a plurality of the first water pipe 130 and the second water pipe 140 are provided along the movement path of air between a pair of heat exchange units adjacent to each other, so that only a small amount of cooling water is passed through the water injection holes 130a and 140a. Even when discharged, sufficient cooling effect can be exhibited.

In addition, the cooling water discharged from the first tank 110 and the second tank 120 through the first water pipe 130 and the second water pipe 140 is collected from the lower portion of the heat exchanger 150. It may also be configured to be circulated back to the first tank 110 and the second tank 120 using a circulation pump (not shown).

A first heat exchange pin 160 (FIG. 5) may be provided in the air passage P to exchange heat with air passing through the air passage P. The first heat exchange pin 160 has one side bonded to the first plate 151 and the other side bonded to the second plate 152.

Cooling water supplied through the pouring hole (130a, 140a) is adsorbed on the surface of the first heat exchange pin (160). In this case, when the surface of the first heat exchange pin 160 is coated with a hydrophilic material, the cooling water spreads along the surface of the first heat exchange pin 160 and the cooling water spreads over the entire surface of the first heat exchange pin 160. Evaporation capacity is improved.

In the past, the cooling water consumption was high as the cooling water was injected from the upper portion to the lower portion of the heat exchanger. However, as described above, the water pipes 130 and 140 are provided at adjacent positions of the first heat exchange fins 160, and the water pouring holes 130a When a small amount of cooling water flows through the ,140a) and spreads through the surface of the first heat exchange pin 160, the consumption of cooling water can be reduced.

2, a first assembly in which a plurality of first water pipes 130 are coupled to the first tank 110, and a second in which a plurality of second water pipes 140 are coupled to the second tank 120 are shown in FIG. The assembly is shown. When the first assembly and the second assembly are coupled to the heat exchange unit 150 in which a plurality of heat exchange units 150-1, 150-2, 150-3, 150-4, 150-5 are coupled, the plurality of first water pipes 130 are The first insertion groove 151f of the first plate 151 and the first insertion groove 152f of the second plate 152 are inserted, and the plurality of second water pipes 140 is the first plate 151 It is inserted into the second insertion groove (151g) and the second insertion groove (152g) of the second plate (152). When combined in this way, it becomes the evaporative heat exchanger 1 shown in FIG. 1.

3 to 6, each of the cross section and the internal structure of the heat exchanger 150 is shown.

Referring to FIG. 4, a first water pipe 130 is integrally formed on one side of the first tank 110. The inner space 111 of the first tank 110 communicates with the inner space 130b of the first water pipe 130. The injection hole 130a of the first injection pipe 130 is formed to discharge cooling water in an air passage P direction (ie, a direction perpendicular to the flow direction of air).

If the surface of the first plate 151 is compared with the surface of the first water pipe 130, the surface of the first water pipe 130 is partially compared to the surface of the first plate 151 toward the air passage P. Is protruding. In addition, when comparing the surface of the second plate 152 and the surface of the first water pipe 130, the surface of the first water pipe 130 is compared to the surface of the second plate 152 toward the air passage P. Some are protruding. Therefore, the cooling water discharged through the pouring hole 130a of the first pouring pipe 130 falls on the surface of the first heat exchange pin 160 provided on the air passage P.

5, a plurality of heat exchange units (150-1,150-2,150-3,150-4,150-5) are combined in a stacked structure. A first tank 110 and a second tank 120 may be coupled to both ends of the plurality of heat exchange units 150-1, 150-2, 150-3, 150-4, 150-5, respectively.

The upper surface of the second flange 151d of the first plate 151 and the upper surface of the second flange 152d of the second plate 152 contact, and the second opening 151c of the second flange 151d and the The second opening 152c of the second flange 152d is connected, so that the inner spaces of the heat exchange units adjacent to each other communicate with each other. Therefore, the internal spaces of the entire plurality of heat exchange units 150-1, 150-2, 150-3, 150-4, 150-5 communicate with each other.

Referring to FIG. 6, a first heat exchange pin 160 may be provided in an air passage P between adjacent heat exchange units. The first heat exchange pin 160 may have a wave shape in cross section, and may have a hydrophilic coating treatment on its surface. Cooling water discharged from the main water holes 130a and 140a is diffused on the surface of the first heat exchange pin 160 to cause evaporation and evaporative cooling.

In the internal space of the heat exchange unit, a second heat exchange pin 170 may be provided to improve the heat exchange efficiency between the refrigerant and the cooling water.

According to the above configuration, the size of the apparatus can be reduced by integrating the tanks 110 and 120 for supplying cooling water into the heat exchanger. In addition, it is possible to improve cooling efficiency while minimizing the consumption of cooling water by arranging the main water pipes 130 and 140 for supplying cooling water on the air flow path inside the heat exchanger.

As described above, preferred embodiments of the present invention have been described in detail, but the present invention is not limited to the above-described embodiments, but is modified in various ways within the scope of the claims and detailed description of the invention and the accompanying drawings. It is possible to carry out and this also belongs to the present invention.

100: evaporative heat exchanger 110: first tank
120: second tank 130: first water pipe
140: second water pipe 130a, 140a: water hole
150: heat exchange unit 150-1,150-2,150-3,150-4,150-5: heat exchange unit
151: first plate 152: second plate
151a, 152a: first opening 151b, 152b: first flange
151c, 152c: second opening 151d, 152d: second flange
151e: first protrusion 151f, 152f: first insertion groove
151g, 152g: 2nd insertion groove 152e: 2nd protrusion
160: first heat exchange pin 170: second heat exchange pin

Claims (14)

A heat exchange unit having a plurality of heat exchange units in which an internal space in which a refrigerant flows is formed between a pair of plates facing each other, the heat exchange unit being coupled so that the internal spaces of the plurality of heat exchange units communicate with each other;
At least one tank provided on a side of the plurality of heat exchange units to supply cooling water to an air passage through which air between a pair of heat exchange units adjacent to each other passes in the plurality of heat exchange units;
Evaporative heat exchanger comprising a According to claim 1,
In the air passage, a first heat exchange pin is respectively attached to a pair of opposite plates of neighboring heat exchange units to exchange heat with air passing through the air passage;
Cooling water supplied from the tank is evaporative heat exchanger, characterized in that adsorbed to the surface of the first heat exchange pin According to claim 2,
At least one main water pipe protruding outward of the tank so as to be at least partially positioned on the air passage;
An evaporative heat exchanger characterized in that the main water pipe is provided with a plurality of main water holes for supplying the cooling water to the air passage. According to claim 3,
The inner space of the tank and the inner space of the main water pipe are provided to communicate with each other, and cooling water in the inner space of the tank flows through the main water pipe and is discharged through the main water hole to adsorb on the surface of the first heat exchange pin. Evaporative heat exchanger, characterized in that According to claim 3,
The at least one tank is composed of a first tank and a second tank respectively provided on one side and the other side of the heat exchange unit;
The water pipe is an evaporative heat exchanger, characterized in that it consists of a first water pipe coupled to the first tank, and a second water pipe coupled to the second tank. The method of claim 5,
The first water pipe is provided so that one end is coupled to the first tank and the other end is spaced apart from the second tank to cross at least a portion of the air passage;
The second water pipe is provided so that one end is coupled to the second tank and the other end is spaced apart from the first tank to cross at least a portion of the air passage;
Evaporative heat exchanger, characterized by The method of claim 5,
Evaporative heat exchanger, characterized in that the first water pipe and the second water pipe are respectively inserted into a plurality of insertion grooves formed concave on the surface of the plate The method of claim 7,
The insertion groove is formed long from the first end portion of the plate toward the second end portion, and the first insertion groove into which the first water pipe is inserted and the long end towards the first end portion from the second end portion of the plate. Evaporation heat exchanger, characterized in that it consists of a second insertion groove into which the second water pipe is inserted The method of claim 8,
The first insertion groove and the second insertion groove is formed in the plate, evaporative heat exchanger, characterized in that formed alternately one by one along the direction in which the air passes According to claim 3,
The main water pipe is an evaporative heat exchanger, characterized in that at least a part protrudes from the surface of the first plate or the second plate toward the air passage side. According to claim 3,
Evaporative heat exchanger, characterized in that the main water pipe is provided with a plurality of spaced apart along the air passage According to claim 1,
An evaporative heat exchanger characterized in that a pair of openings are formed in the first plate and the second plate, the refrigerant flows through any one of the pair of openings, and the refrigerant flows through the other one. According to claim 1,
An evaporative heat exchanger characterized in that a second heat exchange pin is provided in the space between the pair of plates. According to claim 1,
The tank is supplied with direct water, an evaporative heat exchanger, characterized in that a flow control means for adjusting the flow rate of the supplied direct water is provided.

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