KR100748726B1 - Heat exchanger - Google Patents

Abstract

A heat exchanger is provided to mount a discharging unit for condensed water in a space among a lower header tank, tubes and fins for discharging the condensed water to the outside by introducing the condensed water into a path thereof by surface tension acting between a surface of the path and the condensed water. A heat exchanger includes a discharging unit(700) for discharging condensed water staying in a space(400) formed by a lower header tank(200), tubes(600) and fins(300), which has an end positioned in the space and the other end positioned facing the outside of the lower header tank, wherein a path is formed between the both ends for discharging the condensed water to the outside.

Description

Heat Exchanger

1 is a view showing a conventional heat exchanger.

FIG. 2 is a view in which condensate accumulates under the heat exchanger of FIG. 1.

3 is a view used a condensate discharger of the present invention heat exchanger.

4 is a perspective view of the condensate discharger of FIG. 3.

5 is another perspective view of the condensate ejector of FIG. 3.

Figure 6 is a perspective view of the three condensate discharger of Figure 3 integrally formed.

7 is a height lowered to the discharge end of Figure 4;

8 is a cross-sectional view showing a condensate discharger of the present invention heat exchanger.

9 is a cross-sectional view showing another condensate discharger of the present invention heat exchanger.

<Description of the symbols for the main parts of the drawings>

200: lower header tank 300: pin

400: condensate water storage space 600: tube

700: condensate discharge

The present invention relates to a heat exchanger, and more particularly to a heat exchanger comprising a discharger of condensed water accumulated under the heat exchanger core.

A heat exchanger is a device that transfers heat from a high temperature fluid to a low temperature fluid through a heat transfer wall and is used in a heater, a cooler, an evaporator, and a condenser. Hereinafter, an evaporator using a heat exchanger will be described.

The evaporator works as a part of a cooling device (not shown) together with a compressor, a condenser, and an expansion valve, and when the low temperature low pressure refrigerant gas is compressed into a compressor, the evaporator becomes a high pressure gas, and the high temperature high pressure refrigerant gas is converted into a condenser. It is introduced and cooled by the external air to form a refrigerant liquid of low temperature and high pressure, and the refrigerant liquid is sent to the expansion valve, and when passing through the small hole of the expansion valve, both the pressure and the temperature are lowered to become the refrigerant liquid of the low temperature and low pressure. The low pressure refrigerant liquid moves along the tube of the evaporator, absorbs heat from the surroundings, and evaporates into the low temperature low pressure refrigerant gas. At this time, if the hot air of the room is blown by the blower between the tubes of the cold evaporator, the air becomes cold air, and the air is cooled by supplying the air to the room.

As shown in Figure 1 and 2, the conventional evaporator is composed of a core 10 and an external connection pipe 70, one end of which is connected to one side of the core 10. The core 10 has an upper header tank 50 made of a coarse and long tube, a lower header tank 20 having the same shape as the upper header tank 50 and positioned parallel to the lower portion thereof, and one end of the upper header tank. A plurality of tubes 60 in communication with the other end 50 and in communication with the lower header tank 20 and between the adjacent tube 60 and the tube 60 in the upper header tank 50 at the lower header tank. Up to 20 is made of a pin (30) continuously formed in the form of wrinkles.

The conventional evaporator configured as described above takes a lot of heat from the surroundings during operation, and since the surface of the core 10 becomes colder than the surroundings, water vapor around the core 10 condenses on the surface of the core 10 to form condensed water. Which is discharged downward through the lower header tank 20 by gravity.

However, the above-described evaporator is not condensed water is completely discharged below the lower header tank 20 at the end of operation, the condensate pool space that is the space between the bottom of the tube 60 and the fin 30 and the lower header tank 20 At 40, the surface tension acting between the condensate holding space 40 and the condensate is greater than the gravity acting on the condensate so that a part of the condensate remains in the condensate holding space 40. At this time, the remaining condensate can inhabit mold or bacteria, causing problems of hygiene and deterioration of durability.

Accordingly, the present invention has been invented to solve the problems of the prior art, a surface tension greater than the surface tension between the condensate pool space and the condensate and the condensate between the bottom of the tube and the fin and the lower header tank is generated between the condensate and The purpose of the condensate discharger is to discharge the condensate accumulated in the condensate holding space to the outside to promote durability and cleanliness of the evaporator.

The heat exchanger of the present invention for achieving the above object and the plurality of tubes and the upper and lower header tanks and the upper and lower ends provided in the upper and lower header tanks are connected to each other in communication with each other and arranged in a horizontal direction And a condensate discharger for discharging the condensate accumulated in the space formed by the lower header tank, the tube, and the fins provided between the plurality of tubes, wherein one end of the condensate discharger is located in the space and the other end. Is positioned to face the outside of the lower header tank, and a flow path is formed between both ends so that condensate accumulated in the space is discharged to the outside.

In addition, the condensate discharge unit is installed in a reverse direction in the ventilation direction, is positioned to surround at least a portion of the lower header tank, the other end may extend downward along the outer peripheral surface of the space. The condensate discharge unit may be connected to another condensate discharge unit and a rod, and may include a synthetic resin that is injection molded, and the width thereof may be formed to be equal to or smaller than the separation distance between the tubes.

The flow path may be formed such that an inflow portion is formed toward the space, a discharge portion is formed outside the lower header tank, and at least a portion thereof is opened upward. The length of the inlet may be formed smaller than the width of the pin or header tank, the length of the discharge portion may be formed smaller than the height of the header tank and the depth of the flow path may be gradually lowered toward the end.

At least one flow path may be formed, and a mountain may be formed between the adjacent flow paths, and the cross-sectional shape of the mountain may be formed in a triangular or upwardly curved semicircle shape, and the upper end of the mountain may be in line contact with the pin. have. In addition, the flow path may be a semicircle whose cross-sectional shape is curved downward, the width of the open top may be formed shorter than the width of the flow path interruption, the bottom surface is half or three of the height of the condensate discharger It may be formed at a position lower than two quarters.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

3 is a view showing the condensate discharger of the present invention heat exchanger, Figure 4 is a perspective view of the condensate discharger of Figure 3, Figure 5 is another perspective view of the condensate discharger of Figure 3, Figure 6 is three condensate discharger of Figure 3 Is a perspective view formed integrally, Figure 7 is a view that the height is lowered to the discharge end of Figure 4. 8 is a view showing a cross-sectional view of the heat exchanger condensate discharger of the present invention, Figure 9 is a view showing another cross-sectional view of the heat exchanger condensate discharger of the present invention.

According to an embodiment of the present invention, an evaporator in which a heat exchanger is used, the evaporator is accumulated in the condensate holding space 400 formed by the upper end of the lower header tank 200 and the lower end of the tube 600 and the fin 300. And a condensate discharger 700 for discharging the condensate.

The condensate discharger 700 is positioned to surround at least a portion of the lower header tank 200, and the other end thereof extends downward along an outer circumferential surface of the condensate holding space 400. In addition, the condensate ejector 700 made of a material including a synthetic resin to be injection molded is installed in the reverse direction in the ventilation direction flowing into the evaporator, the inlet 730 and the inlet condensate inflow in the condensate pool 400 The discharge part 740 for discharging condensate introduced through the inlet part 730 includes flow paths formed at both ends thereof. The inlet 730 and the outlet 740 extend downward along the lower header tank 200 in the condensate holding space 400 so as to be located outside the condensate holding space 400 and the lower header tank 200, respectively. Is formed.

The length of the inflow portion 730, which is a portion located at the upper end of the lower header tank 200, is formed to be smaller than the width of the pin 300 or the header tank 200, and is formed at the side portion of the lower header tank 200. The length of the discharge part 740, which is located, is formed to be smaller than the height of the header tank 200. And, preferably, as shown in Figure 7 the discharge portion 740 may be formed so that the depth of the flow path gradually toward the end thereof.

Meanwhile, as illustrated in FIG. 8 or 9, the cross section of the condensate discharger 700 has a shape in which three peaks 710 (preferably two or more peaks) and a floor 720 are formed therebetween. In the cross section, the boundary between the mountain 710 and the floor 720 is the first point at which the slope of the tangent starting at the floor of the floor 720 changes rapidly. The cross-sectional shape of the mountain 710 is formed in a triangular or upwardly curved semicircle, so that the top of the mountain 710 is in line contact with the bottom of the pin (300). In addition, the flow path is a space portion between the upper ends of the adjacent mountains 710, and one or more flow paths are formed as shown in FIG.

Preferably, the flow path is formed in such a way that at least a portion thereof is opened upward, and the floor 720 has a semicircular shape in which the floor 720 is curved downward, and the width between the adjacent boundaries, which is the width of the open top of the flow path, is the floor. 720 is formed shorter than the width of the interruption, the flow path bottom is formed at a position lower than half or two-thirds of the height of the inlet 730.

The height of the inlet 730 of the condensate discharge 700 is equal to the height between the bottom of the fin 300 and the top of the lower header tank 200, and the width of the condensate discharge 700 is between the adjacent tubes 600. It is formed equal to or smaller than the separation distance of. Preferably, as shown in FIG. 6, a connecting rod 760 is formed between adjacent condensate outlets 700 so that two or more condensate outlets 700 may be connected.

Hereinafter, the operation of the evaporator condensed water discharger using the heat exchanger of the present invention made according to the above-described configuration will be described.

When a worker introduces one end of the condensate discharger 700 into the evaporator condensate holding space 400 and operates the cooling unit, the evaporator operates as part of a cooling unit (not shown) together with the compressor, the condenser and the expansion valve. At this time, the surface of the tube 600 is cooled because the refrigerant liquid introduced along the inlet connection pipe of the evaporator absorbs the surrounding heat while passing through the inside of the lower header tank 200 and evaporates along the tube 600. Surrounding water vapor condenses on the tube 600 surface. Accordingly, condensate is generated on the surface of the tube 600 and is discharged downward according to the action of gravity. When the evaporator is still in operation, the condensed water is continuously generated and discharged below the lower header tank 200. However, when the evaporator is stopped, no more condensate is generated, and a part of the condensate is in the condensate holding space 400. Will remain.

The residual condensate must be moved downward due to the influence of gravity, but as described above, the surface tension, which is an attraction force acting between the condensate holding space 400 and the condensate in the condensate holding space 400, is greater than the gravity acting on the condensate. Some of the condensate accumulates in the condensate holding space 400. At this time, the condensate accumulated in the condensate holding space 400 is because the surface tension between the surface of the flow path and the condensate of the pre-installed condensate ejector 700 is greater than the surface tension acting between the condensate holding space 400 and the condensate. Inflow to the inlet (730). When the condensed water introduced into the inlet 730 increases and starts to be discharged to the condensed water outlet 740, the condensed water introduced by the attraction force between the condensed water continues to be discharged. Preferably, the flow path of the condensate discharger 700 may be inclined downward toward the discharge port to facilitate discharge of the condensate.

According to the present invention as described above, it is possible to quickly and quickly discharge the condensed water accumulated in the space between the bottom of the tube and the fin and the lower header tank of the lower part of the heat exchanger core to maintain the hygiene and durability of the heat exchanger core.

Claims (16)

delete delete Upper and lower header tanks provided above and below; A plurality of tubes whose ends are connected to the upper and lower header tanks so as to communicate with each other and are spaced apart in a horizontal direction; A pin provided between the plurality of tubes; A condensate discharger for discharging condensate accumulated in the space formed by the lower header tank, the tube and the pin; The condensate discharger is configured to be connected to the load and other adjacent condensate discharger, One end of the condensate discharger is located in the space, the other end is positioned to face the outside of the lower header tank, a flow path is formed between the both ends so that the condensate accumulated in the space is discharged to the outside group. delete Upper and lower header tanks provided above and below; A plurality of tubes whose ends are connected to the upper and lower header tanks so as to communicate with each other and are spaced apart in a horizontal direction; A pin provided between the plurality of tubes; A condensate discharger for discharging condensate accumulated in the space formed by the lower header tank, the tube, and the fin; Consists of including The condensate discharger is installed in a reverse direction to the ventilation direction, one end of the condensate discharger is located in the space, the other end is located to face the outside of the lower header tank, a flow path is formed between both ends condensate accumulated in the space Heat exchanger characterized in that the discharge to the outside. Upper and lower header tanks provided above and below; A plurality of tubes whose ends are connected to the upper and lower header tanks so as to communicate with each other and are spaced apart in a horizontal direction; A pin provided between the plurality of tubes; A condensate discharger for discharging condensate accumulated in the space formed by the lower header tank, the tube, and the fin; Consists of including The width of the condensate discharger is formed to be equal to or less than the separation distance between the tubes, one end of the condensate discharger is located in the space, the other end is located to face the outside of the lower header tank, the flow path between the both ends And a condensate accumulated in the space to be discharged to the outside. The method according to any one of claims 3, 5 or 6, The flow path is a heat exchanger, characterized in that the inlet is formed in the space side, the discharge portion is formed to the outside of the lower header tank, at least a portion is opened to the top. The method according to claim 7, The length of the inlet is formed smaller than the width of the fin or header tank heat exchanger. The method according to claim 7, The discharge portion is characterized in that the length is formed smaller than the height of the header tank. The method according to claim 7, The heat exchanger, characterized in that the depth of the flow path is gradually lowered toward the end. The method according to any one of claims 3, 5 or 6, And at least one flow path is formed. The method according to claim 11, An acid is formed at an adjacent portion between the flow path and the flow path, and the cross-sectional shape of the acid is formed in a triangular or upwardly curved semicircular shape, and an upper end of the acid is in line contact with the fin. The method according to claim 12, The flow path is a heat exchanger, characterized in that the semicircular cross-sectional shape of the cross section except for the acid portion is formed to be curved downward. The method according to claim 13, And the width of the open upper portion of the flow path is shorter than the width of the flow path interruption. The method according to claim 7, And the flow path is formed at a position whose bottom surface is lower than half of the height of the inlet portion. The method according to claim 7, And the flow path is formed at a position whose bottom surface is lower than two thirds of the height of the inlet portion.

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