KR102191901B1 - A tube for heat exchanger - Google Patents

Abstract

The present invention relates to a tube for a heat exchanger, and more particularly, a first reinforcement portion bonded to the curved surface of the tube and a second reinforcement portion bonded to the first reinforcement portion are formed at both ends of the inner fin, thereby forming both ends in the air flow direction of the tube. It relates to a tube for a heat exchanger that can increase the strength of.

Description

Tube for heat exchanger{A TUBE FOR HEAT EXCHANGER}

The present invention relates to a tube for a heat exchanger, and more particularly, a first reinforcement portion bonded to the curved surface of the tube and a second reinforcement portion bonded to the first reinforcement portion are formed at both ends of the inner fin, thereby forming both ends in the air flow direction of the tube. It relates to a tube for a heat exchanger that can increase the strength of.

Among the parts constituting the air conditioner for automobiles, the heat exchanger changes the state of the heat exchange medium or performs cooling or heating by heat exchange with external air.

The heat exchanger includes a pair of header tanks spaced apart from each other by a predetermined distance, and a tube having both ends fixed to the header tank to form a heat exchange medium flow path, and a fin interposed between the tubes.

The tube may be manufactured in an extrusion method and a FOLDED TUBE method, and is selectively used according to specifications (size, weight, pressure resistance, heat exchange medium flow, etc.) required according to the type of heat exchanger.

The folding-type tube has a disadvantage of lower material strength while the productivity is better than that of the extrusion-type tube.

In addition, in the tube of the method of folding the plate material, certain regions of both ends of the plate material are bonded to each other to form a space (heat exchange medium flow path) in which the heat exchange medium flows.

As a tube of a method of folding a plate, Japanese Patent Application Laid-Open No. 2005-214511 (the name of the invention is a heat exchanger) has been proposed, which is shown in FIG.

The tube 5 of the heat exchanger shown in FIG. 1 is formed by bending a plate material 5a having a cladding material 5c formed on the outer surface thereof, and the joints 47 bent in the left direction of the drawing are joined to each other, and the inner space In Figure 1 shows an example in which the cladding materials 49b and 49c are formed on both sides of the plate material 49a being bent to form the inner pin 49.

The tube shown in FIG. 1 has a joint portion formed in the left direction of the drawing to reinforce strength, but there is a problem in that it is difficult to have sufficient durability because only a plate material for forming the tube exists on the opposite side.

Particularly, when the heat exchanger is used as a condenser for a vehicle, portions corresponding to the left and right sides of FIG. 1 are areas that are highly likely to be damaged by splashing foreign substances, and thus, there is a problem in that there is a risk of damage as it is.

In addition, the need to reduce weight along with miniaturization has recently emerged, and thus a heat exchanger having sufficient durability while saving materials is required.

Japanese Patent Laid-Open No. 2005-214511 (the name of the invention heat exchanger)

The present invention has been conceived to solve the above-described problems, and an object of the present invention is to form a first reinforcement portion bonded to the curved surface of the tube at both ends of the inner pin and a second reinforcement portion bonded to the first reinforcement portion By doing so, it is to provide a tube for a heat exchanger that can increase the strength of both ends in the air flow direction of the tube.

In particular, it is an object of the present invention to provide a tube for a heat exchanger capable of securing durability by reinforcing strength while securing productivity by manufacturing a tube and an inner pin using a thin plate.

In addition, an object of the present invention is to reduce the defect rate by forming a first extension portion and a second extension portion, respectively, at the ends of the first and second barrier rib forming portions of the tube forming the barrier rib, and for a heat exchanger that is easy to manufacture. It is to provide a tube.

In addition, an object of the present invention is to form the first partition wall by forming the first partition wall forming portion and the second partition wall forming portion of the tube at a junction region and the first partition wall forming portion and the second partition wall forming portion at a first angle from the junction region. It is to provide a tube for a heat exchanger capable of preventing corrosion due to the cladding material by forming a space forming region capable of forming a space where a cladding material can be collected between the part, the second partition wall forming part, and the inner fin.

In addition, an object of the present invention is that the first angle is 5 to 15 °, and the second angle contacting the outside of the tube of the first and second bulkheads is formed at 10 to 30 °, thereby increasing the bonding strength and reducing the defect rate. It is to provide a tube for a heat exchanger.

The heat exchanger tube 1000 according to the present invention is connected between the header tanks 310 and 320 of the heat exchanger 1000 to form a heat exchange medium flow path, and the inner fin 120 is provided in the tube 100. In this case, the tube 100 includes a flat portion 101 parallel in the air flow direction, and a curved portion 102 connecting the flat portion 101 in a curved shape on both sides in the air flow direction, and the inner The first reinforcement part 131 joined to the curved part 102 inside the tube 100 at both ends of the fin 120, and the first reinforcement part 131 extending from the first reinforcing part 131 again. ) It is characterized in that the second reinforcement portion 132 bonded to the inner surface is formed.

In addition, the heat exchanger tube 100 is formed by bending one first plate material 110, the first partition wall forming portion 111 and the second partition wall forming portion which are predetermined regions of both ends of the first plate member 110 It is characterized in that (112) are bonded to each other to form a partition wall 103 that divides the inner space of the tube 100 into a first space part 100a and a second space part 100b in the air flow direction.

In addition, the inner pin 120 is characterized in that one second plate 121 is bent to divide the spaces of the first and second spaces 100a and 100b into a plurality of spaces.

In addition, the heat exchanger tube 100 has an end portion of the first partition wall forming part 111 extended and bonded to the opposite surface of the first partition wall forming part 111 in contact with the second partition wall forming part 112. The first extension part 111-1 and the end of the second partition wall forming part 112 are extended and bonded to the opposite surface of the second partition wall forming part 112 in contact with the first partition wall forming part 111 It is characterized in that the second extension (112-1) is formed.

In addition, the first partition wall forming part 111 and the second partition wall forming part 112 have a certain area of the first partition wall forming part 111 and the second partition forming part 112 from the outside of the tube 100. From the bonding area A1 and the bonding area A1 to be bonded to each other, the remaining areas of the first and second barrier ribs 111 and 112 form a first angle α. A space forming region A2 is formed between the partition wall forming part 111, the second partition forming part 112, and the inner pin 120 to form the third space part 100c.

In this case, the first angle (α) is characterized in that 5 to 15 °, the first partition wall forming portion 111 and the second partition wall forming portion 112 is in contact with the outside of the tube 100 It is characterized in that the angle β is 10 to 30 °.

On the other hand, the inner pin 120 connects the end of the second reinforcement part 132 with a reference line L perpendicular to the air flow direction based on the center of the radius of curvature C of the curved part 102. It is preferable that the third angle γ between the lines L132 is 10 to 45°.

In addition, the heat exchanger tube 100 may be coated with a cladding material 110a on the outer surface of the first plate material 110 and a cladding material 121a on both surfaces of the second plate material 121.

In addition, the heat exchanger tube 100 is coated with cladding materials 110a and 121a on both surfaces of one of the first plate 110 and the second plate 121, and cladding materials 110a and 121a on the other. It is characterized in that it is not applied.

In addition, the first plate 110 has a thickness D110 of 0.1 to 0.2 mm, and the second plate 121 has a thickness D121 of 0.05 to 0.12 mm.

Accordingly, the heat exchanger tube of the present invention has a first reinforcement portion bonded to the curved surface of the tube at both ends of the inner fin and a second reinforcement portion bonded to the first reinforcement portion, thereby increasing the strength of both ends in the direction of air flow of the tube. There is an advantage that can be increased.

In particular, the tube for a heat exchanger according to the present invention has the advantage of securing durability by reinforcing strength while securing productivity by manufacturing a tube and an inner pin using a thin plate.

In addition, the heat exchanger tube of the present invention can reduce the defect rate by forming a first extension part and a second extension part respectively at the ends of the first and second bulkhead formation parts of the tube forming the partition wall, thereby reducing the defect rate and making it easy to manufacture. There is an advantage.

In addition, in the heat exchanger tube of the present invention, the first partition wall forming portion and the second partition wall forming portion of the tube form a bonding region, and the first partition wall forming portion and the second partition forming portion form a first angle from the bonding region. It is possible to form a space forming region A2 between the partition wall forming part, the second partition forming part, and the inner pin to form a space in which the cladding material can be collected, thereby preventing corrosion due to the cladding material.

In addition, the heat exchanger tube of the present invention has a first angle of 5 to 15°, and a second angle of 10 to 30° contacting the outside of the tube of the first and second partitions, thereby increasing the bonding strength and reducing the defect rate. There is an advantage that can be reduced.

1 is a view showing a tube for a conventional heat exchanger.
Figure 2 is a perspective view showing a heat exchanger using a heat exchanger tube according to the present invention.
3 is a cross-sectional view of a tube for a heat exchanger according to the present invention.
4 is another cross-sectional view of the tube for a heat exchanger according to the present invention.
Figure 5 is a partial enlarged view of the heat exchanger tube shown in Figure 4; (Part of the partition formation)
6 and 7 are enlarged views of other parts of the heat exchanger tube shown in FIG. 4.
8 is an exploded view of a first plate of the tube for a heat exchanger according to the present invention.
9 is an exploded view of a second plate (inner pin formation) of the tube for a heat exchanger according to the present invention.

Hereinafter, a heat exchanger tube 100 of the present invention having the above-described characteristics will be described with reference to the accompanying drawings.

The heat exchanger tube 100 of the present invention is connected between a pair of header tanks 310 and 320 to form a heat exchange medium flow path, and an inner pin 120 is provided therein.

2 is a perspective view showing a heat exchanger 1000 using a heat exchanger tube 100 according to the present invention, and shows an example in which the heat exchanger tube 100 of the present invention is used as a condenser.

The heat exchanger 1000 (condenser) is a heat exchange medium and is a configuration in which a high-temperature, high-pressure gaseous refrigerant discharged from a compressor is exchanged with outside air, condensed into a high-temperature, high-pressure liquid, and discharged to an expansion valve. And a cooling module together with the shroud assembly (not shown).

The configuration of the condenser will be described in detail, a pair of header tanks 310 and 320, an inlet pipe 410 formed in the header tanks 310 and 320 to introduce a refrigerant and an outlet pipe 420 to discharge , A heat exchanger tube 100 fixed at both ends of the header tanks 310 and 320, an outer pin 200 interposed between the tube 100 from the outside of the tube 100, a liquid refrigerant and a gaseous refrigerant And a gas-liquid separator 500 that separates and supplies only a liquid refrigerant.

The tube 100 for a heat exchanger of the present invention may be used in the condenser, and in addition, it may be used for other heat exchangers including an evaporator.

The evaporator is a heat exchanger (1000) that cools the air discharged to the vehicle interior through an endothermic action by the latent heat of evaporation of the refrigerant by evaporating the low pressure liquid refrigerant throttled by the expansion valve through heat exchange with air blown toward the vehicle interior. As such, the configurations other than the gas-liquid separator 500 are similar to those of the condenser.

3 is a cross-sectional view of the tube 100 for a heat exchanger according to the present invention. The tube 100 for a heat exchanger of the present invention forms a curved portion 102 having both ends curved in the air flow direction, and the inner pin 120 ) To form a first reinforcement portion 131 and a second reinforcement portion 132 at both ends.

In Fig. 3, the direction of air flow is indicated by arrows.

The heat exchanger tube 100 of the present invention includes a flat portion 101 parallel in the air flow direction, and a curved portion 102 connecting the flat portion 101 in a curved shape on both sides in the air flow direction. A flow path through which the heat exchange medium flows is formed, and the inner pin 120 is provided therein.

In this case, the heat exchanger tube 100 is formed by bending one first plate 110.

In addition, the heat exchanger tube 100 divides the internal heat exchange medium flow path into a first space part 100a and a second space part 100b by a partition wall 103, and both ends of the first plate material 110 are constant. The first partition wall forming part 111 and the second partition wall forming part 112, which are regions, are joined to each other to form the partition wall 103.

The inner pin 120 is a configuration in which one second plate 121 is bent to divide the first space part 100a and the second space part 100b into a plurality of spaces, and in more detail, the tube (100) A partition portion 133 for partitioning the inner space (the first space portion 100a and the second space portion 100b), and the flat portion of the tube 100 by bending from the partition portion 133 ( It includes a joint portion 134 that is formed in parallel with 101 and is joined to the flat portion 101 of the tube 100.

3 and 4, 10 partitions 133 are formed in the first space 100a to divide the first space 100a into 11 spaces in the airflow direction, and An example is shown in which 10 is formed in the two-space part 100b and divides the second space part 100b into 11 spaces in the air flow direction.

In addition to the examples shown in Figs. 3 and 4, the tube 100 for a heat exchanger of the present invention controls the number of bending of the inner pin 120 to variously adjust the number of formations of the partition unit 133. The spaces inside the part 100a and the second space part 100b may be more variously adjusted.

At this time, the portion of the joint portion 134 of the inner pin 120 where the partition wall 103 is formed has one side joined to the inner surface of the flat portion 101 of the tube 100, and the other side is the first It is bonded to the partition wall forming part 111 and the second partition wall forming part 112.

The heat exchanger tube 100 of the present invention has a first reinforcement part 131 bonded to the inside of the curved part 102 at both ends of the inner fin 120 and extends from the first reinforcement part 131 A second reinforcing part 132 is formed to be bonded to the inner surface of the first reinforcing part 131.

That is, the first reinforcing portion 131 is a portion that primarily reinforces the region where the curved portion 102 of the tube 100 is formed, and one side of the reinforcing portion is joined to the inner side of the curved portion 102 and the other side The surface is bonded to the second reinforcing part 132.

The second reinforcing portion 132 is a portion extending from the first reinforcing portion 131 to secondaryly reinforce an area where the curved portion 102 of the tube 100 is formed.

Accordingly, the heat exchanger tube 100 of the present invention includes a first reinforcing portion 131 and a first reinforcing portion 131 bonded to the curved portion 102 of the tube 100 at both ends of the inner fin 120 Since the second reinforcing part 132 to be bonded is formed, there is an advantage of increasing the strength of both ends in the air flow direction of the tube 100.

In particular, in the case of the condenser, it is provided in the front of the vehicle, and there is a risk that the portion where the curved portion 102 is formed may be damaged by an impact caused by foreign matters while driving. ) Since the first reinforcement part 131 and the second reinforcement part 132 are formed in the formation region, there is an advantage that durability can be further improved.

4 is another cross-sectional view of the tube 100 for a heat exchanger according to the present invention, wherein the tube 100 for a heat exchanger of the present invention includes a first extension part 111-1 and a first extension part 111-1 on the first partition wall forming part 111, respectively. A second extension part 112-1 may be further formed in the second partition wall forming part 112.

The first extension part 111-1 has an end of the first partition wall forming part 111 extending so that the opposite surface of the first partition wall forming part 111 in contact with the second partition wall forming part 112 (Fig. In 4, it is the surface of the first partition wall forming part 111 in contact with the first space part 100a, and is a part joined to the left surface of the first partition wall forming part 111 in FIG. 4).

In addition, the second extension part 112-1 has an opposite surface of the second partition wall forming part 112 in contact with the first partition wall forming part 111 by extending the end of the second partition wall forming part 112. (In FIG. 4, it is a surface of the second partition wall forming portion 112 in contact with the second space portion 100b, and is a portion joined to the right side of the second partition wall forming portion 112 in FIG. 4).

In the heat exchanger tube 100 of the present invention, since the first extension part 111-1 and the second extension part 112-1 are formed, the partition wall 103 can be stably formed without bonding defects, further improving manufacturability. There is an advantage that can be increased.

5 is an enlarged view of a portion of the partition wall 103 formed in the heat exchanger tube 100 shown in FIG. 4, wherein the first partition wall forming part 111 and the second partition wall forming part 112 are inside the tube 100 from the outside. The bonding region A1 and the space forming region A2 may be formed in a direction (in the case of FIG. 5, from a lower side to an upper side).

The bonding area A1 is an area where a predetermined area of the first and second barrier ribs 111 and 112 is bonded to each other from the outside of the tube 100.

In the space forming region A2, the first partition wall forming portion 111 and the remaining regions of the second partition forming portion 112 form a first angle α from the junction region A1. The third space portion 100c between the formation portion 111, the second partition wall forming portion 112 and the inner pin 120 (the junction portion 134 of the portion of the inner pin 120 where the partition wall 103 is formed) To form.

The third space part 100c is formed by the first partition wall forming part 111, the second partition wall forming part 112, and the inner pin 120, and the first space part ( As a separate space partitioned from 100a) and the second space portion 100b, a hollow space is formed as shown in FIG. 5 in the temporary assembly state of the first plate 110 and the second plate 121, and then In the brazing process, a space where the cladding members 110a and 121a of the first plate 110 or the second plate 121 gather is formed, and in the finished product state, the third space portion 100c is formed by the cladding members 110a and 121a. ) A certain area or the whole of the space may be blocked.

When a large amount of cladding materials 110a and 121a for bonding in the brazing process are located inside the tube 100, erosion may be caused by the cladding materials 110a and 121a. The machine tube 100 has the advantage of preventing this in advance by forming the third space portion 100c.

In this case, it is preferable that the first angle α formed by the first partition wall forming part 111 and the second partition wall forming part 112 from the junction area A1 is 5 to 15°.

When the first angle α is less than 5°, the formation area of the third space part 100c is inevitably narrowed, so it is difficult to expect the advantages of the formation of the third space part 100c. When the first angle α is greater than 15°, the space for forming the first and second spaces 100a and 100b through which the heat exchange medium flows may be reduced, which may adversely affect the overall heat exchange performance.

Accordingly, the heat exchanger tube 100 of the present invention is characterized in that the first angle α is formed to be 5 to 15 °.

In addition, the heat exchanger tube 100 of the present invention has a second angle β between the first and second partition forming portions 111 and 112 that are in contact with the outside of the tube 100 from 10 to 30. It is preferably °.

6 and 7 are diagrams illustrating a third angle γ in all other partially enlarged views of the heat exchanger tube 100 shown in FIG. 4. In more detail, FIG. 6 shows a third angle (γ) defined based on the radius of curvature of the curved portion 102, and FIG. 7 is a reference line (L) connecting both ends of the curved portion 102. A defined third angle (γ) is shown.

First, as an example shown in FIG. 6, the inner pin 120 has a reference line L perpendicular to the air flow direction and the second reinforcement based on the center of the radius of curvature (C) of the curved portion 102. It is preferable that the third angle (γ) between the line L132 connecting the ends of the portion 132 is 10 to 45°, and the center of the radius of curvature (C) of the curved portion 102 is the curved portion 102 It means the center of the circle (C) based on the outer surface of ). In FIG. 6, a circle based on the outer surface of the curved portion 102 is indicated by a dotted line. In addition, the reference line (L) perpendicular to the air flow direction refers to a line perpendicular to the air flow direction passing through the curvature radius center (C), and the flat portion 101 of the tube 100 is the air flow direction. It is formed parallel to the bar, the reference line (L) is formed perpendicular to the flat portion 101 of the tube (100). The line L132 connecting the end of the second reinforcing part 132 is connecting the center of the curvature radius C and the end of the second reinforcing part 132. That is, the third angle (γ) is the reference line (L) and the second reinforcement, which are regions in which the second reinforcement part 132 is not formed based on the center of the curvature radius (C) of the curved surface part 102. It means the angle between the line (L132) connecting the ends of the portion 132, the heat exchanger tube 100 of the present invention, the third angle (γ) is formed at an angle of 10 to 45 °. When the third angle γ exceeds 45°, it is difficult to sufficiently perform the role of reinforcing the curved portion 102 by the second reinforcing portion 132. In addition, when the third angle (γ) is less than 10 °, as reinforcing the curved portion 102 more than necessary, the length of the inner pin 120 is unnecessarily increased to increase the weight of the tube 100 itself. The weight of the entire heat exchanger can be increased. In this case, it causes an increase in manufacturing cost, and may have a weak effect on fuel economy by increasing the weight of the entire vehicle. That is, in the heat exchanger tube 100 of the present invention, the third angle (γ) is 10 to 10 to determine the optimal position at which the second reinforcing part 132 is formed while being able to sufficiently reinforce the curved part 102 Formed at an angle of 45 °.

In addition, the tube 100 for a heat exchanger of the present invention may have the third angle γ differently defined. The third angle γ shown in FIG. 7 is based on the center C of the reference line L connecting both ends of the curved portion 102, and the reference line L and the second reinforcing portion 132 It represents the angle between the line (L132) connecting the ends of ). Both ends of the curved portion 102 refer to the boundary in contact with the flat portion 101, and are indicated by reference numeral B in FIG. 7. In this case, the reference line (L) refers to a line connecting both ends of the curved portion (102), which is a portion where the flat portion (101) starts, and the third angle (γ) is the reference line (L) It means between the reference line L and the line L132 connecting the center C of and the end of the second reinforcing part 132. Also in the form shown in FIG. 7, the third angle γ is formed at an angle of 10 to 45°, and the meaning is as described above. In this case, the center C and the reference line L shown in FIGS. 6 and 7 are the same positions even though they are defined differently.

In addition, the heat exchanger tube 100 of the present invention is a line connecting an auxiliary reference line (L') parallel to the flat portion 101 and an end portion of the second reinforcement portion 132 with respect to the center (C). The fourth angle (δ) between (L132) is 45 to 80°. The auxiliary reference line (L') and the fourth angle (δ) are shown in FIG. 7. That is, in the heat exchanger tube 100 of the present invention, the fourth angle (δ) is formed at 45 to 80 ° so that the second reinforcing part 132 reinforces the curved part 102 and has an appropriate length. desirable. At this time, the fourth angle δ is shown in FIG. 7, but the auxiliary reference line L'passing through the center C and the fourth angle δ defined accordingly are applied in the form shown in FIG. It is natural that you can.

Meanwhile, FIG. 8 is an exploded view of the first plate material 110 of the heat exchanger tube 100 according to the present invention, and FIG. 9 is a second plate material 121 (inner pin 120) of the heat exchanger tube 100 according to the present invention. ) Formation) In the exploded view, FIGS. 8 and 9, drawing numbers corresponding to the configurations of the tube 100 and the inner pin 120 formed by bending are indicated.

At this time, the first plate material 110 shown in FIG. 8 shows an example in which the cladding material 110a is applied on both sides, and the second plate material 121 shown in FIG. 9 is a cladding material ( 121a) was applied.

In the heat exchanger tube 100 of the present invention, when the cladding material 110a is applied to the outer surface of the first plate material 110, the cladding material 121a may be applied on both sides of the second plate material 121 .

In addition, in the case of the heat exchanger tube 100 of the present invention, when the cladding material 110a is applied to both sides of the first plate material 110, the second plate material 121 is not coated with the cladding material 121a. It can be used in a state, and when the cladding material 110a is not applied to both sides of the first plate material 110, the second plate material 121 may be coated with the cladding material 121a on both sides of the first plate material 110. .

In particular, the heat exchanger tube 100 of the present invention has a thickness (D110) of 0.1 to 0.2 mm of the first plate material 110, and a thickness (D121) of 0.05 to 0.12 mm of the second plate material 121 Likewise, by manufacturing the tube 100 and the inner pin 120 using a thin plate, the weight can be reduced, productivity can be secured, strength is reinforced, and durability can be secured.

The present invention is not limited to the above-described embodiments, and of course, various modifications can be made without departing from the gist of the present invention as claimed in the claims.

1000: heat exchanger
100: tube for a heat exchanger according to the present invention
100a: first space part
100b: second space part
100c: third space
101: flat portion 102: curved portion
103: bulkhead
110: first plate 110a: clad material
D110: thickness of the first plate
111: first partition wall forming portion 111-1: first extension portion
112: second partition wall forming portion 112-1: second extension portion
α: first angle
β: second angle
A1: bonding area A2: space forming area
120: inner pin
121: second plate 121a: cladding
D121: thickness of the second plate
131: first reinforcement part 132: second reinforcement part
133: division part 134: junction
200: outer pin
310: first header tank
20: second header tank
410: inlet pipe
420: exit pipe
500: gas-liquid separator
γ: third angle δ: fourth angle
L: baseline C: center
L': auxiliary baseline
L132: A line connecting the end and center of the second reinforcement part

Claims (12)

In the tube 100 which is connected between the header tanks 310 and 320 of the heat exchanger 1000 to form a heat exchange medium flow path, the inner fin 120 is provided therein,
The tube 100 includes a flat portion 101 parallel in the air flow direction, and a curved portion 102 connecting the flat portion 101 in a curved shape on both sides in the air flow direction,
A first reinforcement part 131 joined to the curved part 102 inside the tube 100 at both ends of the inner pin 120, and the first reinforcement part extends from the first reinforcement part 131 again. (131) A second reinforcing portion 132 bonded to the inner surface is formed,
The second reinforcing part 132 is disposed to contact a part of the inner surface of the first reinforcing part 131,
The third angle between the reference line L perpendicular to the air flow direction and the line L132 connecting the ends of the second reinforcement part 132 with respect to the center of the curvature radius C of the curved part 102 (γ) is a tube for a heat exchanger, characterized in that 10 to 45 °.
The method of claim 1,
The tube 100 is
One first plate 110 is bent and formed, and the first partition wall forming part 111 and the second partition wall forming part 112, which are predetermined regions of both ends of the first plate 110 are bonded to each other, and the air flow direction As a heat exchanger tube, characterized in that forming a partition wall 103 that divides the inner space of the tube 100 into a first space portion (100a) and a second space portion (100b).
The method of claim 2,
The inner pin 120 is
A tube for a heat exchanger, characterized in that one second plate (121) is bent to divide the spaces of the first and second spaces (100a) and (100b) into a plurality of spaces.
The method of claim 3,
The tube 100 is
A first extension part 111-1 which extends at an end of the first partition wall forming part 111 and is joined to the opposite surface of the first partition wall forming part 111 in contact with the second partition wall forming part 112 ,
A second extension part 112-1, which extends at an end of the second partition wall forming part 112 and is joined to the opposite surface of the second partition wall forming part 112 in contact with the first partition wall forming part 111 Heat exchanger tube, characterized in that formed.
The method of claim 3,
The first partition wall forming part 111 and the second partition wall forming part 112 are
A bonding area A1 in which a predetermined area of the first and second barrier ribs 111 and 112 is bonded to each other from the outside of the tube 100 and
The remaining regions of the first and second partitions 111 and 112 from the junction region A1 form a first angle α, thereby forming the first partition 111 and the second partition. A heat exchanger tube, characterized in that a space forming region (A2) forming a third space part (100c) is formed between the partition wall forming part (112) and the inner fin (120).
The method of claim 5,
The first angle (α) is a heat exchanger tube, characterized in that 5 to 15 °.
The method of claim 5,
The first partition wall forming portion 111 and the second partition forming portion 112 has a second angle (β) contacting from the outside of the tube 100 is 10 to 30 ° for a heat exchanger tube.
The method of claim 1,
The curved portion 102, the first reinforcing portion 131 and the second reinforcing portion 132 share a center of curvature radius (C),
The center (C) is disposed on the reference line (L) connecting both ends of the curved portion (102),
Both ends of the curved portion 102 are a heat exchanger tube defined by a boundary in contact with the flat portion 101.
The method according to any one of claims 3 to 8,
The tube 100 is
A cladding material 110a is applied to the outer surface of the first plate material 110,
A heat exchanger tube, characterized in that a cladding material 121a is applied to both surfaces of the second plate material 121.
The method according to any one of claims 3 to 8,
The tube 100 is
For a heat exchanger, characterized in that cladding materials 110a and 121a are applied to both surfaces of one of the first plate 110 and the second plate 121 and the cladding materials 110a and 121a are not applied to the other tube.
The method according to any one of claims 3 to 8,
A heat exchanger tube, characterized in that the thickness (D110) of the first plate 110 is 0.1 to 0.2 mm.
The method of claim 11,
The thickness (D121) of the second plate (121) is a heat exchanger tube, characterized in that 0.05 to 0.12 mm.

Images