KR101301801B1 - Heat exchanger for having a simple assembly process - Google Patents

Abstract

The heat radiating tube with long length is divided into left and right lengths, and the connecting parts at both left and right ends are bent in a semicircle, and the same width as that of the refrigerant radiating tube is used in the heat dissipating tube for constant space between the left, right, and top rows. Using a long aluminum thin plate as the size of the interval between the upper and lower rows of the heat dissipation tube for the refrigerant, the upper and lower folded ends are zigzag-folded to make a triangular shape to form a heat sink.
Refrigerant heat dissipation tube upper and lower The upper and lower parts of the heat dissipation tube for refrigerant are easily combined by inserting the inner peripheral half of the refrigerant dissipation tube into several inlets formed on the upper and lower sides of the zigzag heat sink by inserting the inner space between the upper and lower intervals. Several chambers formed at the top and bottom by moving the zigzag heat sink inserted into the gap between each row from the left and right sides to the center at the same time to move each aluminum thin plate that forms the inclination angle of the zigzag heat sink with the upper and lower sides triangulated. Heat exchanger with easy assembly process that makes the inlet closer to the outer circumference of the heat dissipation tube to improve thermal conductivity

Description

Heat exchanger for having a simple assembly process

The present invention relates to a heat exchanger having a simple assembly process that can easily combine the heat radiation pipe for a long length of the refrigerant in the heat exchanger and the heat sink dissipating the internal heat to the outside in contact with the outer periphery of the heat pipe.

형의 알루미늄띠로서 나선형으로 밀착되게 전체적으로 감아서 냉매용 방열관의 내부열기를 방열관의 외부주연에 감긴 방열띠를 통해 외부로 발산하도록 하는 구성이나 냉매용 방열관이 길이가 긴 방열관을 상하, 좌우 여러 층으로 배열시킨 상태에서 각 층의 방열관 외부주연에 단면이

형의 알루미늄띠로서 전체적으로 밀착되게 나선형으로 감기가 매우 난이하여 제조공정에 시간이 많이 소요되고 또한 방열관의 외부주연에 나선형으로 감은 단면이

형의 알루미늄띠가 고온도에 의한 열팽창과 단면이

형의 알루미늄띠의 자체 탄성에 의해 방열관 외부주연과 단면이

형 알루미늄띠와의 사이에 틈이 벌어지면서 열전도율이 떨어져 방열효과가 저하되는 원인이 되었다.In constituting the heat dissipation tube for the refrigerant of the heat exchanger, the long heat dissipation tube is divided into a certain length, and the connecting portions at both ends of the heat exchanger are bent in a semicircle to be arranged in multiple layers at regular intervals vertically or horizontally. In order to maximize the cross-section

Aluminum strip, which is wound in a spiral shape so that the inside heat of the heat dissipation tube for refrigerant is radiated to the outside through the heat dissipation band wound around the outer periphery of the heat dissipation tube, In cross-section of the left and right layers,

As the aluminum strip of the shape, it is very difficult to wind spirally to be in close contact with the whole, which takes a lot of time in the manufacturing process, and the cross section wound spirally on the outer periphery of the heat dissipation tube

The aluminum strip of the mold has thermal expansion and cross section

The outer periphery and cross section of the heat sink are

As a gap is formed between the aluminum strips, the thermal conductivity drops and the heat dissipation effect is lowered.

In constituting the heat radiating tube for refrigerant of heat exchanger, the long heat radiating tube is divided into a certain length, and both sides of the left and right sides are bent up and down, left and right and arranged in multiple layers. Zig-zag aluminum plates folded in a constant width so as to be in contact with each other are inserted into the gaps between the layers, and the upper and lower widths of the zig-zag heat sinks inserted into the gaps between the layers are enlarged. It was necessary to keep the top and bottom of the zigzag heat sink close to the periphery.

In the present invention, a long length of heat dissipation tube is divided into left and right predetermined lengths, and the connecting portions at both left and right ends are bent in a semi-circular shape, so that the heat dissipation tube for refrigerant is wide in the heat dissipation tube for a constant space between the left and right, top and bottom rows. The length of the aluminum thin plate with the same width as the width of each of the upper and lower rows of the heat sink for the refrigerant to fold in a zigzag shape so that the folded ends of the upper and lower sides in a triangular shape to configure the heat sink

Refrigerant heat dissipation tube upper and lower The upper and lower parts of the heat dissipation tube for refrigerant are easily combined by inserting the inner peripheral half of the refrigerant dissipation tube into several inlets formed on the upper and lower sides of the zigzag heat sink by inserting the inner space between the upper and lower intervals. Several chambers formed at the top and bottom by moving the zigzag heat sink inserted into the gap between each row from the left and right sides to the center at the same time to move each aluminum thin plate that forms the inclination angle of the zigzag heat sink with the upper and lower sides triangulated. The inlet was brought into close contact with the outer periphery of the heat dissipation tube to improve the thermal conductivity.

The present invention is a heat sink folded in a zigzag shape such that the ends thereof are triangular in size between the upper and lower rows of the coolant heat dissipating tube and the upper and lower rows of the coolant heat dissipating tube having a constant gap between the left and right and upper and lower rows. A few inlets formed at the upper and lower sides are inserted so that the outer circumferential half of the heat dissipation tube for the refrigerant is inserted to facilitate the coupling, and the zig-zag heat dissipation plate inserted into the space between the upper and lower rows of the heat dissipation tube for the refrigerant is pushed toward the center. The upper and lower ends are folded in a triangle to move each aluminum sheet having an inclination angle in a vertical state, so that several inlets of the upper and lower ends are brought into close contact with the outer circumference of the heat dissipation tube, thereby improving thermal conductivity.

1 is an exploded perspective view showing the configuration of the present invention
2 is a combined perspective view of the present invention
3 is a combined front view of the present invention.
4 is an overall perspective view of a zigzag heat sink
5 is a partially enlarged perspective view illustrating a structure in which a zig-zag type heat sink is inserted between upper and lower rows of the heat dissipation tube for refrigerant;
Figure 6 is an enlarged perspective view showing the structure of one part of the zigzag heat sink
Figure 7a is a partially enlarged cross-sectional view showing the structure of the upper and lower inlet of the heat sink is fitted to the outer periphery of the heat sink
FIG. 7B is a partially enlarged cross-sectional view showing a structure in which the heat sink is narrowed toward the center and the connecting blade protruding at an angle of 90 ° to the upper and lower inlets close to the heat dissipating tube.

Refrigerant configured by dividing the long heat radiating tube 1 into left and right fixed lengths to form three horizontal and ten vertical rows, and connecting the connecting portions at the left and right ends in a semi-circular shape with the same diameter to uniformly space the spaces between the left and right and top and bottom rows. In the heat dissipation tube 10

A long aluminum thin plate 2 having a width equal to the width of the three horizontal rows of the refrigerant heat dissipation tube 10 is obtained by adding the gap size between the upper and lower rows of the refrigerant heat dissipation tube and the diameter size of the heat dissipation tube 1. Fold the zigzag shape continuously so that the folded ends of the upper and lower sides are triangular in a wide size, and the heat dissipating plate 20 having a constant interval between the zigzag is formed to be the left and right compartment lengths of the heat dissipating pipe 10 for the refrigerant.

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Half of the outer periphery of the heat dissipation tube 1 may be inserted at positions where the three horizontal rows of the heat dissipation tubes 1 of the refrigerant dissipation tube 10 may contact each other at the upper and lower sides of the zigzag-shaped heat dissipation plate 20. 3 semi-circular inlets (21) can be formed

The semi-circular inlet 21 is formed with a semicircular edge with a resilient convex portion 22 to protrude outward at a 90 ° angle to the outside of the folded end triangle, and at the end of the contact blade 23. It was made by forming the curved fixing claws 24 upward and downward.

When assembling the zigzag-type heat sink 20 in the heat dissipation tube 10 for the refrigerant in three horizontal rows and 10 vertical rows, the end of the zigzag heat dissipation plate 20 folded into the space between the vertical ten rows of the refrigerant heat dissipation pipe 10. Insert the inside of the refrigerant from the left and right sides of the heat dissipation tube 10 so that the outer peripheral half of the heat dissipation tube 1 in three horizontal rows is inserted into the three inlets 21 formed at the upper and lower ends of the triangle.

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Three rows of end triangles folded by a zigzag heat sink 20 are included in the horizontal three rows of heat pipes 1 exposed to the upper and lower portions of the refrigerant heat pipe 10 into which the zigzag heat sink 20 is inserted into each layer. Covered in the upper and lower portions so that the outer peripheral half of the heat dissipation tube 1 in three horizontal rows in the inlet 21, the three inlets 21 exposed to the upper and lower sides of the zigzag heat sink 20, the heat dissipation tube for the refrigerant 10 semi-circular support rods (40) of the left and right lengths of (10) are placed so that the semi-circular outer periphery is embedded, and the heat dissipating tube for heat dissipation (10), 10 transverse semi-circular connectors (11) on both sides and five kinds of semi-circular connectors ( 12) and the two semi-circular through holes 33 on the upper and lower edges and the ten transverse holes 31, the five longitudinal holes 32, and the upper and lower edges corresponding to the three semi-circular support rods 40 on the upper and lower sides. The support plates 30 are inserted inward from the left and right sides of the heat dissipation tube 10 for the refrigerant, and the inward surfaces of both support plates 30 are zigzag-shaped. By engaging the left and right ends of the heat sink 20 in contact with each other between the heat sink tube 1 in the vertical ten rows of the refrigerant type heat dissipating tube 10, and put 11 zigzag type heat sinks 20 in the upper and lower portions, The top and bottom of the heat sinks of three horizontal columns, each of ten vertical columns, are completely embedded in the three semicircular inlets 21 formed at the top and bottom of the zigzag-shaped heat sink enclosed at the top and bottom.

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 A connecting blade 23 protruding at an angle of 90 ° to the edge of the semi-circular inlet 21 contacts the outer periphery of the heat dissipation tube 1, thereby passing the refrigerant heat inside the heat dissipation tube 1 through the zigzag heat dissipation plate 20. It is to diverge to the outside as much as possible.

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In addition, the zig-zag type heat dissipation plate 20 is inserted into the heat dissipation tube 10 as described above, and both support plates 30 are simultaneously centered as shown in FIG. If the gap between the upper and lower sides of the zigzag type heat sink 20 folded in a triangular manner is narrowed to a certain degree, the aluminum foil plate is folded in a triangle at the top and bottom of the zigzag type heat sink 20 to form an inclination angle as shown in FIG. 7B. (2) is moved vertically, the connecting blades 23 protruding at an angle of 90 ° with the elastic convex part 22 at the edge of the semi-circular inlet 21 of each aluminum sheet (2) according to the 90 ° angle The entire outer surface of the wing is completely in contact with the outer periphery of the heat dissipation tube 1, and the elastic convex portion 22 further closely adheres to the elasticity so that the thermal conductivity is continuously maintained and the upper and lower ends of the wing 23 are connected. By curved paper To the fixed claw (24) which forms the compressed outer periphery of the heat radiating pipe (1) like a wedge will be fixed as it is in a full staggered heat sink 20 is moved toward the center in accordance with both the base plate (30) state.

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In the zigzag heat sink, a plurality of triangular concave-convex grooves 25 are formed in the center of each of the aluminum thin plates 2 having the upper and lower sides triangularly folded in a lateral direction to be processed into an aluminum thin plate 21. The heat dissipation effect is enhanced by maximizing the heat dissipation area while reinforcing the strength of).

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1: heat dissipation tube
2: aluminum sheet
10: heat sink for refrigerant
11: transverse semi-circular connectors
12: longitudinal semicircular connector
20: heat sink
21: semicircular inlet
22: elastic convex part
23: connection wing
24: Claw for fastening
25: triangular uneven groove
30: both support plates
31: The horizontal ball
32: Finisher
33: semicircular through hole
40: semicircular support bar

Claims (5)

Long length heat pipe (1) is divided into left and right fixed lengths to be horizontally arranged in three rows and vertically in ten rows. In the heat radiation tube 10 for refrigerant
A long aluminum thin plate 2 having a width equal to the width of the three horizontal columns of the coolant heat dissipating tube 10 is the sum of the gap size between the upper and lower rows of the coolant heat dissipating tube and the diameter size of the heat dissipating tube 1. Fold the zigzag shape continuously so that the folded ends of the upper and lower sides are triangular in a wide size, and the heat dissipating plate 20 having a constant interval between the zigzag is formed to be the left and right compartment lengths of the heat dissipating pipe 10 for the refrigerant.
Half of the outer periphery of the heat dissipation tube 1 may be inserted at positions where the three horizontal rows of the heat dissipation tubes 1 of the refrigerant dissipation tube 10 may contact each other at the upper and lower sides of the zigzag-shaped heat dissipation plate 20. 3 semi-circular inlets (21) can be formed
The semicircular inlet 21 is formed to protrude outward of the folded end triangle at a 90 ° angle with the elastic convex part 22 at the semicircular edge.
When assembling the zigzag-type heat sink 20 in the heat dissipation pipe 10 for the three rows of heat and the vertical ten rows, the triangular folds of the zigzag heat sink 20 into the spaces between the ten vertical rows of the heat dissipation pipe 10 for the refrigerant. Assembly process by inserting the inside of the refrigerant heat dissipation tube 10 from both left and right sides so that the outer periphery half of the heat dissipation tube 1 in three horizontal rows is inserted into the three inlets 21 formed at the upper and lower ends thereof. This easy heat exchanger delete delete The heat exchanger according to claim 1, wherein a fixing claw (24) is formed at the end of the connecting blade (23) so as to be bent upward and downward. According to claim 1, the zigzag-type heat sink (1) is inserted into each layer of the heat dissipation tube (10) for the refrigerant, and both support plates 30 are pushed toward the center at the same time while the support plates (30) are engaged at both left and right sides. 90 ° angle with the elastic convex part 22 at the edge of the semi-circular inlet 21 formed on the zigzag-type heat sink 20 and the lower part by narrowing the interval between the zigzag-type heat sink 20 whose lower end is triangularly folded. Heat exchanger for easy assembly process by contacting the entire outer surface of the connection blade 23 formed to the outer periphery of the heat dissipation tube 1

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