KR101062650B1 - heat transmitter - Google Patents

Abstract

The present invention relates to a heat exchanger, and more particularly to a heat exchanger that improves the drainage of condensate by forming a hole or a bent portion at a predetermined portion of the wire fin in a heat exchanger using a wire fin.

Accordingly, the present invention is a tube 110 formed of a plurality of flow paths 112 are formed therein so as to communicate with the tank 140 formed at the end; A wire pin 200 interposed between the tubes 110 to form a plurality of meshes by crossing a plurality of wires 201 in a longitudinal and horizontal direction; It characterized in that it comprises a condensate drainage means formed in the wire pin 200 so as to smoothly discharge the condensate generated on the surface of the wire pin 200.

Heat exchanger, evaporator, tube, wire fin, condensate

Description

Heat exchanger

1 is a schematic perspective view showing a conventional evaporator,

2 is an enlarged perspective view showing part A in FIG. 1;

3 is a perspective view showing an evaporator according to the present invention,

4 is an exploded perspective view showing a tube of an evaporator according to the present invention;

5 is an enlarged perspective view showing a state in which a hole is formed in a wire pin of an evaporator according to the present invention;

6 and 7 are enlarged perspective views showing a state in which a bent portion is formed on the wire pin of the evaporator according to the present invention;

8 is an enlarged perspective view illustrating a state in which wires are inclined at a predetermined angle in a wire pin of an evaporator according to the present invention.

Description of the Related Art [0002]

100: evaporator 101: inlet pipe

102: outlet pipe 110: tube

111: plate 112: euro

113: compartment bead 114: cup

120,120a: Manifold tube 121,121a: Manifold                 

130: endplate 140: tank

150: baffle

200: wire pin 201: wire

210: mesh deformation portion 211: hole

212: bend

The present invention relates to a heat exchanger, and more particularly to a heat exchanger that improves the drainage of condensate by forming a hole or a bent portion at a predetermined portion of the wire fin in a heat exchanger using a wire fin.

The heat exchanger has a flow path through which a heat exchange medium flows, and is used to heat exchange the heat exchange medium and the outside air, and is used in various air-conditioning apparatuses. Various types of things, such as an evaporator, a condenser, a radiator, and a heater core, are used. .

Among the heat exchangers, the evaporator is classified according to the structural type of the refrigerant passage, such as a serpentine type in which a single extruded tube is bent in multiple stages, a laminate type in which a dimple-shaped plate is laminated, and the like. The multiple extruder tube type evaporator used is introduced.

As an example of the conventional evaporator 1, Japanese Laid-Open Utility Model Publication No. 58-7082 (1983.01.18) is provided between the tubes 2 bent in multiple stages in a constant shape, as shown in Figs. Via wire fins 3 for promoting heat exchange, both ends of the tube 2 are provided with inlet and outlet pipes 5 and 6 so as to allow the refrigerant to flow in and out. Here, the wire pin 3 is bonded to the wire (3a) of a constant diameter in the form of a grid and then bent in the form of a wave is disclosed a technique interposed between the tube (2).

In the tube 2 of the evaporator 1, a refrigerant having a lower temperature than the air flows in through the inlet pipe 5, where air passes through the wire pins 3 interposed between the tubes 2 to exchange heat. As a result, the temperature drops and the air becomes cold.

On the other hand, when the air passes through the tube (2) and the wire pin (3) in the above action, the heat exchange occurs to the low-temperature air, when the temperature is lower than the dew point temperature, the moisture in the air is the tube and wire It is condensed on the surface of the fin 3 and flows down by gravity.

However, although the evaporator 1 using the wire fins 3 is advantageous in thinning and increases the heat exchange surface area by the wire fins 3, the portion of the lattice-shaped wire fins 3 which is in contact with the condensed water has a structure. There was a problem that the drainage of the condensate is not good, such as the condensate can not easily flow in the direction of gravity.

Therefore, as the drainage of the condensate is not good, the scattering phenomenon is caused by the blown air, and the flow resistance is received by the condensate to increase the noise and decrease the heat exchange efficiency. It is becoming.

 An object of the present invention for solving the above problems is to provide a heat exchanger that improves the drainage of condensate generated on the surface of the wire fin by forming a mesh deformation portion such as a hole or a bent portion in a predetermined portion of the wire fin.

The present invention for achieving the above object is a tube formed in a plurality of passages formed in the interior to communicate with the tank formed at the end is laminated a plurality; A wire pin interposed between the tubes and crossing the plurality of wires in a longitudinal direction to form a plurality of meshes; It characterized in that it comprises a condensate drainage means formed in the wire pin to smoothly discharge the condensate generated on the surface of the wire pin

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

Figure 3 is a perspective view showing an evaporator according to the present invention, Figure 4 is an exploded perspective view showing a tube of the evaporator according to the invention, Figure 5 is an enlarged perspective view showing a state in which a hole is formed in the wire pin of the evaporator according to the present invention. 6 and 7 are enlarged perspective views illustrating a state in which a bent portion is formed on a wire pin of an evaporator according to the present invention, and FIG. 8 is a state in which wires are inclined at a predetermined angle in a wire pin of the evaporator according to the present invention. It is an enlarged perspective view showing.

First, the wire fin 200, which is a feature of the present invention, will be found in advance that the same applies to all heat exchangers such as an evaporator, a condenser, a radiator, and a heater core.

The evaporator 100 of the present invention is formed by joining two plates 111 having a pair of cups 114 formed in parallel with each other at an upper end thereof, and a pair of tanks by cups 114 joined to each other. 140 is formed therein, and therein, a “U” -shaped flow path 112 for communicating a pair of tanks 140 with respect to the partition bead 113 formed vertically between the pair of tanks 140 by a predetermined length. ) Is formed and a plurality of tubes 110,

It is interposed in the form bent between the tubes 110 and the grid-shaped wire pins formed a plurality of mesh (cross) by crossing the plurality of wires 201 in the longitudinal direction to widen the heat transfer area to promote heat exchange 200,

It comprises an end plate 130 which is installed on the outermost to reinforce the tube 110 and the wire pin 200.

In addition, among the tubes 110, a manifold tube 120 protruding toward one side of the tank 140 to communicate with the inside and having an inlet manifold 121 connected to the inlet pipe 101 to introduce a refrigerant therein is formed. ) And a manifold tube 120a having an outlet side manifold 121a connected to the outlet pipe 102 to discharge the refrigerant is also used.

In addition, a baffle 150 is formed in one tank 140 in which the inlet and outlet side manifolds 121 and 121a are formed to partition the refrigerant flowing into and the refrigerant flowing out.

Therefore, the refrigerant flowing into the inlet pipe 101 is the external air by heat exchange with the external air in the course of sequentially passing through the tubes 110 on one side and the tubes 110 on the other side separated by the baffle 150. After cooling it is discharged through the outlet pipe (102).

In the evaporator 100, the wire fin 200 is formed with a condensate drainage means to smoothly discharge the condensate generated on the surface of the wire fin 200.                     

The condensate drainage means is made of a mesh deformation part 210 that deforms the mesh of the wire pin 200.

That is, the mesh deformation part 210 is formed by forming a drainage space so that condensed water can be smoothly discharged by cutting or bending a predetermined portion of the wire pin 200 or changing an arrangement. Referring to each of the drawings in detail as follows.

First, the mesh deformation part 210 illustrated in FIG. 5 is formed by penetrating a hole 211 at a predetermined portion of the wire pin 200.

Here, the hole 211 is preferably formed larger than one mesh size.

That is, by forming a plurality of holes 211 by cutting a portion of the wires 201 arranged in the longitudinal and lateral directions at regular intervals, the condensed water can be quickly discharged in the gravity direction through the holes 211. will be.

The hole 211 is preferably formed to penetrate the wire pin 200 interposed between the tubes 110 in the vertical direction, and is formed only at a portion that does not contact the side surface of the tube 110. desirable.

Next, the mesh deformation portion 210 illustrated in FIGS. 6 and 7 may be bent portion 212 at a straight portion of the wire 201 arranged in a transverse direction with respect to the air flow direction passing between the tubes 110. ) Is formed.

That is, the bent portion 212 is formed by bending the horizontally arranged wires 201 at regular intervals, so that the condensed water can be quickly discharged in the direction of gravity through the space formed by the bent portion 212. It is.

Meanwhile, the bent portion 212 may be bent in the forward and backward directions with respect to the air flow direction as shown in FIG. 6, or may be bent downward as shown in FIG. 7. In this case, when bending in the front and rear directions, it is preferable to bend the pair of neighboring wires 201 arranged in the transverse direction in the opposite direction to form a larger space in which the condensed water can be discharged.

In addition, the longitudinal wire 201 disposed in the bent portion 212 may be disposed at the center of the bent portion 212 or disposed at both sides of the bent portion 212 to discharge the condensed water more efficiently. .

Next, the mesh deformation part 210 illustrated in FIG. 8 passes between the tubes 110 so that the condensate flowing along the wire pin 200 can easily flow to the side of the tube 110. The wires 201 arranged in the transverse direction with respect to the air flow direction are arranged to be inclined at an angle in the air flow direction.

That is, all the wires 201 may be arranged at a constant angle, may be arranged to alternately form a predetermined angle, or may be configured to mix a predetermined angle.

Therefore, the condensate flowing along the wire pin 200 is easily flowed to the side of the tube 110 along the inclined wire 201 at a predetermined angle, and then quickly discharged in the direction of gravity along the tube 110. .

On the other hand, although not shown in the drawing, the bending direction of the wire pin 200 interposed between the tubes 110 may be bent downward to allow the condensed water to be smoothly discharged.

As described above, according to the evaporator 100 of the present invention, by forming a mesh deformation portion 210 so that the condensed water can be quickly discharged by cutting or bending a predetermined portion of the wire pin 200 or an arrangement different, Condensate generated on the surface of the wire pin 200 is quickly discharged in the direction of gravity.

As described above, the wire fin 200, the mesh deformation portion 210 is formed can be applied to all the heat exchanger having the tube 110 and at the same time can achieve the same effect, more diverse within the claims of the present invention Of course, it can be modified.

As described above, according to the present invention, by forming a mesh deformation part in which a predetermined portion of the wire pin is cut or bent or arranged differently, drainage of condensate generated on the surface of the wire pin is improved.

In addition, the condensate is quickly discharged to prevent the scattering of the air is blown, the flow resistance is minimized, noise reduction and heat exchange efficiency is improved, the odor can be prevented in advance.

Claims (4)

delete A tube 110 having a plurality of flow paths 112 formed therein so as to communicate with a tank 140 formed at an end thereof and being stacked in plurality; A wire pin 200 interposed between the tubes 110 to form a plurality of meshes by crossing a plurality of wires 201 in a longitudinal and horizontal direction; Containing condensate drainage means formed on the wire pin 200 so as to smoothly discharge the condensate generated on the surface of the wire pin 200, The condensate drainage means is made of a mesh deformation portion 210 deformed the mesh (mesh) of the wire pin 200, The mesh deformation part 210 is formed by penetrating a hole 211 in a predetermined portion of the wire fin 200, the heat exchanger characterized in that the hole 211 is formed larger than one mesh size . A tube 110 having a plurality of flow paths 112 formed therein so as to communicate with a tank 140 formed at an end thereof and being stacked in plurality; A wire pin 200 interposed between the tubes 110 to form a plurality of meshes by crossing a plurality of wires 201 in a longitudinal and horizontal direction; Containing condensate drainage means formed on the wire pin 200 so as to smoothly discharge the condensate generated on the surface of the wire pin 200, The condensate drainage means is made of a mesh deformation portion 210 deformed the mesh (mesh) of the wire pin 200, The mesh deformation portion 210 is formed by forming a bent portion 212 on a straight portion of the wire 201 arranged in the transverse direction with respect to the air flow direction passing between the tubes (110) heat transmitter. A tube 110 having a plurality of flow paths 112 formed therein so as to communicate with a tank 140 formed at an end thereof and being stacked in plurality; A wire pin 200 interposed between the tubes 110 to form a plurality of meshes by crossing a plurality of wires 201 in a longitudinal and horizontal direction; Containing condensate drainage means formed on the wire pin 200 so as to smoothly discharge the condensate generated on the surface of the wire pin 200, The condensate drainage means is made of a mesh deformation portion 210 deformed the mesh (mesh) of the wire pin 200, The mesh deformation part 210 is transverse to the air flow direction passing between the tubes 110 so that the condensate flowing along the wire pin 200 can easily flow to the side of the tube 110. Heat exchanger, characterized in that formed by forming a wire 201 arranged in a direction inclined at a predetermined angle in the air flow direction.

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