KR100290872B1 - Flat tube-type heat-exchanger - Google Patents

Abstract

PURPOSE: A flat pipe heat exchanger is provided to prevent condensed water from being dispersed in discharging air by draining condensed water, and to improve heat exchange efficiency by reducing resistance of air path. CONSTITUTION: A flat pipe heat exchanger is composed of first and second header pipes(11,12) arranged and separated; plural refrigerant outlet pipes(14) and inlet pipes(13) installed in first and second header pipes; first flat tubes(161) inclined on the level, and installed along header pipes to move refrigerant from the second header pipe to the first header pipe; and first and second wire fins(171) installed in the first flat tubes to radiate heat of refrigerant flowing through first flat tubes. Dispersion of condensate is prevented with draining condensed water on flat tubes and wire fins. Noise is reduced, and heat exchange efficiency is improved with reducing resistance of condensate. Productivity is improved, and expenses are reduced with installing wire fins in flat tubes conveniently.

Description

Flat tube heat exchanger {Flat tube-type heat-exchanger}

The present invention relates to a heat exchanger, and more particularly, to a flat tube heat exchanger having a wide cross section of a tube serving as a passage through which a refrigerant moves.

In general, the flat tube heat exchanger is a heat exchanger mainly used as a condenser for automobiles. 1 is a front view of a conventional flat tube heat exchanger, Figure 2 is a longitudinal sectional view of the main portion of the conventional flat tube heat exchanger, Figure 3 is a partial perspective view showing a part of the flat fin of the conventional flat tube heat exchanger. 1-3, a conventional flat tubular heat exchanger includes: first and second header pipes (1) (2) positioned laterally opposite to each other; A refrigerant outflow pipe (3) (4) installed in the first header pipe (1) so that refrigerant flows in and out of the first header pipe (1); A plurality of flat tubes 6, one end of which is installed in the first header pipe 1 and the other end of which is provided in the second header pipe 2, to allow the refrigerant to flow between the first and second header pipes 1 and 2. Wow; A separation membrane (5) provided inside the first and second header pipes (1) and (2) for guiding the refrigerant flowing in the first and second header pipes (1) and (2) in a predetermined direction; In order to transfer the heat of the refrigerant flowing along the flat tube (6) is provided with a flat plate 7 is bent in a long W-shape provided between each flat tube (6). Here, the wide surfaces of the flat tube 6 and the flat plate pin 7 are provided in parallel with the horizontal plane.

When the flat tube heat exchanger having such a configuration is used as a condenser of an automobile, a refrigerant having a temperature higher than air is introduced into the first header pipe 1 through the refrigerant inlet pipe 3, and the refrigerant is then provided with a plurality of flat tubes. 6 and the second header pipe (2) is introduced into the inside of the second header pipe (2) while the direction is guided by the separation membrane (5) repeatedly moved between the first and second header pipe (1) (2) and then the refrigerant outlet pipe (4) Spills through. In the process of moving the refrigerant, the heat of the high temperature refrigerant is transferred to the flat tube 6 and the flat fin 7. At this time, when the air passes between the flat plate pins 7 by the movement of the vehicle or forced convection by the fan, heat exchange is performed between the high temperature refrigerant and the low temperature refrigerant.

In addition, when the conventional flat tube heat exchanger is used as an evaporator of a cooling device such as an air conditioner used at home, a refrigerant having a lower temperature than the air flows into the flat tube 6 so that the low temperature refrigerant heat is transferred to the flat tube 6. Heat is transferred to the plate fins (7). Accordingly, when air passes between the plate fins 7, the low temperature refrigerant and the high temperature air exchange heat. However, during the heat exchange process, when the high temperature air exchanges with the low temperature refrigerant and changes to cold air, if the temperature is lower than the dew point temperature, the moisture in the air condenses on the flat tube 6 and the flat plate 7 surface. do. When the amount of condensate increases, the condensate flows down by gravity, and since the wide surfaces of the flat tube 6 and the flat fin 7 are horizontally installed, the heat exchanger will be described later as an evaporator of the air conditioner. The problem is as follows.

First, condensate is accumulated on the horizontal upper surface of the flat tube 6 and the flat fin 7 so that it does not easily flow in the direction of gravity, and thus, the condensate is directly discharged with the air when the air passes through the heat exchanger. The phenomenon occurs and as air is subjected to flow path resistance by the condensate, noise is increased and heat exchange efficiency is lowered.

Second, due to the difference between the inflow rate of external air when used as a condenser of a car and the inflow rate of external air when used as an evaporator of a home air conditioner, the design of a fin suitable for the use of an evaporator is not achieved. This was degraded.

Third, the shape of the flat plate pin is complicated, and the process of fixing the flat plate pin of such a complicated shape between the flat tube is difficult to reduce the productivity as well as increase the manufacturing cost.

The present invention has been made to solve the above-mentioned conventional problems, especially when the condensed water condensed on the surface of the flat tube and the fin during the heat exchange process when used as an evaporator of a cooling device such as a domestic air conditioner condensed water It is intended to improve the heat exchange efficiency by reducing the flow path resistance of the air by the condensate to prevent the phenomenon that the condensed water is scattered to the outside during the discharge of the air by allowing the rapid flow down.

According to an aspect of the present invention for achieving the above object, the first and second header pipes spaced apart by a predetermined interval up and down; A plurality of refrigerant outlet pipes installed in the first header pipe and a plurality of refrigerant inlet pipes installed in the second header pipe; A plurality of first flat tubes, one end of which is installed along the first header pipe inclined to a horizontal plane and the other, and the other end of which is installed along the second header pipe to move the refrigerant introduced into the second header pipe to the first header pipe; ; A flat tube heat exchanger having a plurality of first and second wire fins, each of which is fixed in a checkerboard shape in a front and rear direction of a first flat tube and dissipates heat of a refrigerant moving along each first flat tube, is provided.

1 is a front view of a conventional flat tube heat exchanger

2 is a longitudinal sectional view of main parts of a conventional flat tube heat exchanger;

Figure 3 is a partial perspective view showing a part of the flat fin of the conventional flat tube heat exchanger

4 is a front view showing a first embodiment of the flat tube heat exchanger of the present invention;

5 is a side view of FIG. 4

6 is a side view showing a second embodiment of the flat tube heat exchanger of the present invention;

Explanation of symbols for main parts of the drawings

11, 12. First and second header pipe 13. Refrigerant inlet pipe

14. Refrigerant outlet pipe 161, 162. First and second flat tubes

171, 172, 173. 1st, 2nd, 3rd wire pin

4 is a front view showing a first embodiment of the flat tube heat exchanger of the present invention, and FIG. 5 is a side view of FIG. 4 and 5, the flat tubular heat exchanger of the present invention and the first and second header pipes (11) (12) spaced apart by a predetermined interval up and down; A plurality of refrigerant inlet pipes (13) installed in the second header pipe (12) so that refrigerant flows into the second header pipe (12); A plurality of refrigerant outlet pipes (14) installed in the first header pipe (11) such that refrigerant flows into the first header pipe (11); A separation membrane (15) provided in said first and second header pipes (11) and (12) to guide refrigerant in a predetermined direction in said first and second header pipes (11) and (12); An upper end is connected according to the first header pipe 11 and a lower end is connected according to the second header pipe 12 to move the refrigerant introduced into the second header pipe 12 to the first header pipe 11. A plurality of first flat tubes 161; A plurality of first and second wire pins 171 and 172 are installed in front and rear of the first flat tube 161 to radiate heat of the refrigerant moving along the first flat tube 161. The first and second wire pins 171 and 172 are welded in a checkerboard shape by crossing each wire pin horizontally and vertically.

In addition, the first flat tube 161 connecting the first and second header pipes 11 and 12 is inclined at a predetermined angle with respect to a horizontal plane so that the first flat tube 161 and the first and second wire pins are inclined. Condensate condensed in the (171) (172) to be able to flow easily. The inclination angle of the first flat tube 161 is limited to a range of 65 ° to 85 °. When the inclination angle of the first flat tube 161 is 65 ° or less, condensed water does not flow smoothly, and noise is increased and heat transfer performance is increased. Can be degraded. In addition, when the inclination angle of each of the first flat tube 161 is 85 ° or more, the air conditioner itself becomes large due to the evaporator itself standing up, so that the inclination angle of the first flat tube 161 is 65 to 85 °. It is suitable to make a range.

In addition, the diameters of the first and second wire pins 171 and 172 are in the range of 2 to 4 mm, and the vertical interval V and the horizontal distance of each of the first and second wire pins 171 and 172. (H) is limited to the range of 2-7 mm. The reason for this limitation is that when the diameters of the first and second wire pins 171 and 172 are 4 mm or more and the vertical and horizontal spacings V are less than 2 mm, the air and the first and second wire pins are 2 mm or less. This is because the contact area with the (171) and (172) increases, thereby increasing the heat exchange efficiency, but conversely, condensate generation is intensified, resulting in difficulty in treating the condensate. In addition, when the diameters of the first and second wire pins 171 and 172 are 2 mm or less and the vertical and horizontal spacings V and H of the first and second wire pins 171 and 172 are 7 mm or more, respectively. This is because the contact area between the air and the first and second wire fins 171 and 172 is reduced, thereby reducing the generation of condensed water and decreasing heat exchange efficiency.

On the other hand, Figure 6 is a side view showing a second embodiment of the flat tubular heat exchanger of the present invention, if only specifically described with respect to the configuration different from the first embodiment of the present invention.

The second embodiment of the present invention has an object to provide a flat tube exchanger having a more efficient heat exchange efficiency than the first embodiment. The flat tubular heat exchanger of the second embodiment includes: first and second header pipes (11) (12) having an elliptical cross section in a horizontal direction so as to expand a flow path width of a refrigerant; One end is installed along the first header pipe 11 and the other end is inclined at a predetermined angle to the horizontal plane at regular intervals in the front or rear direction of each of the first flat tubes 161 and the other end along the second header pipe 12. A plurality of second flat tubes 162 installed to move the refrigerant introduced into the second header pipe 12 to the first header pipe 11; Each of the third wire fins 173 is fixed to the outside of the second flat tube 162 to form a checker board to dissipate heat of the refrigerant moving along each of the second flat tubes 162. In the second embodiment of the present invention, only the second flat tube 162 is added, but according to another embodiment of the present invention, the third and fourth flat tubes may be added. In this case, the fourth and fifth wire pins may also be added. It is possible.

The operation according to the first and second embodiments of the present invention configured as described above will be described first from the first embodiment.

When the flat tube heat exchanger of the present invention is used as an evaporator of a cooling device such as an air conditioner, when a refrigerant having a temperature lower than air is introduced into the second header pipe 12 through the refrigerant inlet pipe 13, the introduced The refrigerant is guided in the predetermined direction by the separator 15 and is moved to the first header pipe 11 through the plurality of first flat tubes 161, and then the separator 15 in the first header pipe 12 is continued. By being guided in a predetermined direction by the flow through the plurality of refrigerant outlet pipe 14 installed in the first header pipe (11).

At this time, when the hot air flowing from the outside passes between the first and second wire pins 171 and 172, the heat exchange with the low-temperature hot air flowing through each of the flat tube 16. As such, condensed water is formed on the surfaces of each of the flat tube 161 and the first and second wire fins 171 and 172 during the heat exchange process. The condensate is inclined in a range of about 65 to 85 degrees of the inclination angle θ of each flat tube 161, and the flat wires are respectively flat because the first and second wire pins 171 and 172 have a rounded diameter. The tube and the first and second wire pins 171 and 172 flow smoothly in the direction of gravity.

On the other hand, only the operation according to the main portion of the operation of the second embodiment of the present invention will be described in detail as follows.

The second embodiment has a larger cross section of the first and second head pipes 11 and 12 than the first embodiment, and includes a second flat tube 162 in addition to the first flat tube 161. A large amount of refrigerant can be moved between the two head pipes 11 and 12, and in addition to the first and second wire pins 171 and 172 of the first embodiment, a third wire pin 173 is further provided. The heat exchange efficiency with can be increased as compared with the first embodiment.

As described above, the flat tubular heat exchanger of the present invention has the first and second flat tubes 161 and 162 connecting the first and second header pipes 11 and 12 to be inclined at an angle with respect to the horizontal line. The first, second, and third wire fins 171, 172, and 173 transfer heat of the refrigerant moving along the first and second flat tubes 161 and 162. (162), so that when the flat tube heat exchanger is used as the evaporator of the air conditioner, the first and second flat tubes (161, 162) and the first, second and third wire fins (171, 172) ( Even if condensate is generated on the surface of 173, the condensate does not stay long and flows immediately, so that condensate is not scattered with air, and the flow resistance caused by the condensate is reduced, thereby reducing heat. The efficiency is increased.

In addition, it is very easy to install the first, second, and third wire fins 171, 172, 173, which are used as heat transfer media, in the first, second flat tube 161, 162, thereby improving productivity. There is also a significant reduction in production costs.

Claims (4)

First and second header pipes spaced at a predetermined interval up and down; A plurality of refrigerant outlet pipes installed in the first header pipe and a plurality of refrigerant inlet pipes installed in the second header pipe; A plurality of first flat tubes installed at both ends along the first and second header pipes to be inclined at a predetermined angle with a horizontal plane to move the refrigerant introduced into the second header pipe to the first header pipe; Flat tubular heat exchanger is provided in the form of a checkerboard in the front and rear direction of the first flat tube, each of which has a plurality of first and second wire fins to dissipate heat of the refrigerant moving along each of the first flat tubes. group. The method of claim 1, First and second header pipes each having an elliptical cross section in a horizontal direction to extend a flow path width of the refrigerant; Both ends are installed along the first and second header pipes at predetermined intervals in the front or rear direction of each of the first flat tubes, and are inclined at a predetermined angle to the horizontal plane to supply the refrigerant introduced into the second header pipe to the first header pipe. A plurality of second flat tubes for moving to; And a plurality of third wire fins fixed to the outside of the second flat tube in the form of a checker board to dissipate heat of the refrigerant moving along the respective second flat tubes. The method according to claim 1 or 2, Flat angle heat exchanger, characterized in that the angle (θ) of the first and second flat tube to the horizontal plane is 65 to 85 °. The method of claim 3, wherein The diameters of the first, second, and third wire pins are 2 to 4 mm, and the vertical distance (V) and the horizontal distance (H) of each of the first, second, and third wire pins are 2 to 7 mm. heat transmitter.