JP2792405B2 - Heat exchanger - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat exchanger, and is particularly effective when used in a radiator for a vehicle or a heater core of a hot water type heating device.

[0002]

2. Description of the Related Art Conventionally, for example, a flat tube 24 of a heater core of a hot water type heating apparatus is formed by bending a thin brass plate at one end 24a, as shown in FIG. By the way, in the heat exchanger for vehicles, the thickness of the flat tube 24 tends to be reduced as the size and weight are reduced.

When the tube width L of the flat tube 24 is increased, a greater pressure is applied in the direction of the upper surface 24b and the lower surface 24c in the figure due to the pressure of the heat exchange fluid flowing inside. When a large pressure is applied in the direction of the upper and lower surfaces 24b, 24c to the peripheral end 24d having a semicircular cross section that supports the upper and lower surfaces 24b, 24c, a corresponding amount of stress is applied, and the flat tube 24 is deformed. There is a problem above. In this way, the strength of the flat tube 24 is insufficient if the bent tube is directly widened, and there is a limit in configuring the flat tube 24 to increase the tube width L.

For this reason, when the flat tubes 24 are applied to a heat exchanger having a wide width, they are used in a plurality of rows as shown in FIG. When the flat tubes 24 are arranged in a plurality of rows, the flat tubes 24 arranged in a plurality of rows are arranged.
A dead space 25 is formed during which no cooling water flows and does not contribute to heat exchange. Therefore, the passage area of the cooling water is reduced by the dead space 25.

Accordingly, reference number 29 of the Nippon Denso Publication Technical Report
-193 (issued in January 1983), as shown in FIG. 4, a flat tube 23 is provided with a folded portion 23b formed at the center thereof so as to be continuous with one side surface 23a forming the tube. To the other side 2
The flat tube 23 is welded to the inner peripheral surface 23d of 3c.
Are shown to reinforce it.

[0006]

When aluminum is used as the material of the above-mentioned flat tube 23 shown in FIG. 4, its thickness is formed to about 0.3 [mm]. In this case, since the specific gravity is higher than that of aluminum, it is formed with a thickness of about 0.1 [mm] for weight reduction. As described above, the flat tube 23 is formed to be thin, and the tip 23e of the folded back 23b is also formed to be thin.
The contact area of 3c with the inner peripheral surface 23d is small. Since the contact area is small, the front end 23e of the folded back 23b is
It is difficult to reliably join to 3d.

In order to fix the flat tube 23 by soldering, the solder must be poured from the outer peripheral surface of the flat tube 23 to the space between the adjacent turnbacks 23b, between the tip 23e and the inner peripheral surface 23d. No. However, in the flat tube 23, since the distal end portion 23e is thin, the surface tension at the distal end portion 23e is small, and the poured solder is unlikely to collect between the distal end portion 23e and the inner peripheral surface 23d, so that the solder can be securely joined. Can not.

Accordingly, an object of the present invention is to provide a heat exchanger that can securely join a reinforcing portion at the center of a flat tube.

[0009]

According to the present invention, in order to achieve the above object, according to the first aspect of the present invention, there is provided a flat tube through which a heat exchange fluid flows, and a heat transfer joined to the flat tube in a heat conductive manner. In the heat exchanger including fins, the flat tube includes a first rectangular short plate portion and the first short plate portion.
A first flat plate portion formed substantially continuously at a right angle from the long side of the short plate portion, a first curved portion having a semicircular cross section formed continuously from the first flat plate portion, A second flat plate portion formed continuously from one rounded portion and provided substantially parallel to the first flat plate portion; and a substantially right angle continuous from the second flat plate portion and formed at a substantially right angle; A rectangular second short plate portion provided substantially adjacent to and in parallel with the plate portion; and a substantially right angle continuous with the second short plate portion, the first short plate portion being formed with respect to the second short plate portion. A third flat plate portion provided in a direction facing the flat plate portion, a second circular curved portion having a semicircular cross section continuously formed from the third flat plate portion, and a continuous circular shape formed from the second circular curved portion. A fourth flat plate portion formed substantially in parallel with the third flat plate portion and provided in a direction facing the second flat plate portion with respect to the second short plate portion. A third rectangular short plate portion formed substantially continuously at a right angle to the fourth flat plate portion and provided substantially parallel and adjacent to the second short plate portion; Joining between one short plate portion and the second short plate portion, and between the second short plate portion and the third short plate portion provided adjacent to each other,
A space surrounded by the first short plate portion, the second flat plate portion, the first circumferential curved portion, and the second flat plate portion forms a first flow path into which the heat exchange fluid flows, A heat exchanger in which a space surrounded by a third flat plate portion, the second curved portion, the fourth flat plate portion, and the third short plate portion forms a second flow path into which the heat exchange fluid flows. The technical means of providing is adopted.

[0010] According to the second aspect of the present invention, in the heat exchanger including the flat tube through which the heat exchange fluid flows and the heat transfer fin joined to the flat tube so as to be able to conduct heat, the flat tube has a rectangular shape. A first short plate portion and the first short plate portion;
A first flat plate portion formed substantially continuously at a right angle from the long side of the short plate portion, a first curved portion having a semicircular cross section formed continuously from the first flat plate portion, A second flat plate portion formed continuously from one rounded portion and provided substantially parallel to the first flat plate portion; and a substantially right angle continuous from the second flat plate portion and formed at a substantially right angle; A rectangular second short plate portion provided substantially adjacent to and in parallel with the plate portion; and a rectangular third short plate formed continuously from the second short plate portion to be folded substantially in parallel and provided adjacent to the second short plate portion. A short plate portion, a third flat plate portion which is continuous from the third short plate portion and extends substantially at right angles in a direction facing the second flat plate portion, and a cross section formed continuously from the third flat plate portion A semicircular second curved portion, formed continuously from the second curved portion, substantially parallel to the third flat plate portion, and in the direction of the third short plate portion; A fourth flat plate portion having a rectangular shape, and a fourth short plate portion having a rectangular shape formed substantially at right angles to the fourth flat plate portion and substantially parallel to and adjacent to the third short plate portion. And between the first short plate portion and the second short plate portion provided adjacent to each other, between the second short plate portion and the third short plate portion provided adjacent to each other, and adjacent to each other. The third short plate portion and the fourth short plate portion provided by joining the first short plate portion,
A space surrounded by the first flat plate portion, the first curved portion, the second flat plate portion, and the second short plate portion forms a first flow path into which the heat exchange fluid flows, and 3 short plate portions, the third
A space surrounded by the flat plate portion, the second curved portion, the fourth flat plate portion, and the fourth short plate portion includes a heat exchanger forming a second flow path into which the heat exchange fluid flows. It adopts the technical means of:

The length of the second short plate portion and the length of the third short plate portion may be shorter than the distance from the second flat plate portion to the first flat plate portion. The length of the plate portion and the length of the fourth short plate portion are shorter than the distance from the second flat plate portion to the first flat plate portion.
The technical means of providing the described heat exchanger is employed.

[0012]

According to the heat exchanger of the present invention, the space surrounded by the first short plate portion, the first flat plate portion, the first curved portion, and the second flat plate portion is formed. The first flow path into which the heat exchange fluid flows is formed, and the space surrounded by the third flat plate portion, the second circumferential curved portion, the fourth flat plate portion, and the third short plate portion forms the first flow passage. A second flow path is formed.

The first short plate portion, the second short plate portion, and the third short plate portion located between the first flow passage and the second flow passage form a reinforcing member as the entire flat tube. In this flat tube, between the first flow path and the second flow path, between the first short plate portion and the second short plate portion provided adjacently, and the second short plate portion provided adjacently And the third short plate portion are joined between the respective surfaces, so that the area at the time of joining is larger than that of the conventional end face joining. Since the first short plate portion, the second short plate portion, and the third short plate portion can be reliably bonded to each other because of the large area.

Further, according to the heat exchanger of the present invention having the configuration of claim 2, the first short plate portion, the first flat plate portion, the first circumferentially curved portion,
A space surrounded by the second flat plate portion and the second short plate portion forms a first flow path into which the heat exchange fluid flows, and the third short plate portion and the third short plate portion
A space surrounded by the flat plate portion, the second curved portion, the fourth flat plate portion, and the fourth short plate portion forms a second flow path into which the heat exchange fluid flows.

The first short plate portion, the second short plate portion, the third short plate portion, and the fourth short plate portion located between the first flow path and the second flow path constitute the flat tube as a whole. It becomes a reinforcing member. With this flat tube, between the first short plate portion and the second short plate portion provided adjacently between the first flow path and the second flow path,
The second short plate portion and the third short plate portion provided adjacent to each other, and the third short plate portion and the fourth short plate portion provided adjacent to each other are joined between the respective surfaces. Therefore, the area at the time of joining is larger than that of the conventional end face joining. Since the first short plate portion, the second short plate portion, the third short plate portion, and the fourth short plate portion can be reliably bonded to each other because of the large area.

Further, according to the heat exchanger of the present invention, when the flat tubes and the heat transfer fins are assembled, the length variation and the transfer length of the first short plate portion and the fourth short plate portion are improved. Variations in the height of the heat fins can be absorbed, and buckling of the fins can be prevented.

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below based on an embodiment shown in the drawings. FIG. 1 is a perspective view showing a heat exchanger of the present invention. This heat exchanger serves as a heater core of a hot water heater of an automobile, and heats the air as it passes in the direction of arrow A. In the illustrated embodiment, the heater core includes a plurality of rows of tubes 1 arranged in a row in the width direction in the air flow direction A and spaced in the horizontal direction with respect to the air flow direction A. And a corrugated fin 2 connected to the side surface and connected to each tube row. Each tube 1 is a flat tube formed so that cooling water of an automobile engine flows therein, and is usually formed of brass. The corrugated fin 2 is made of copper. In addition, the tube 1 and the fins 2 may be made of aluminum or the like having good heat conductivity in addition to copper.

Both ends of each tube 1 are connected to header plates 6 and 7 made of brass, respectively, to complete the core 3.
Tanks 4 and 5 are respectively attached to the header plates 6 and 7 in a well-known manner. The upper tank 4 is provided with a cooling water inlet pipe 8 and a cooling water outlet pipe 9. FIG.
Are the tube 1 and the corrugated fin 2 in this embodiment.
FIG. 3 shows a perspective view and an enlarged view of the tube 1. As shown in the perspective view of FIG. 3A, the tube 1 has a rectangular first short plate portion 11 that is short in the vertical direction in the figure and long in the depth direction.
A first flat plate portion 12 formed continuously from the upper side in the depth direction and provided substantially at right angles to the first short plate portion 11;
A first circumferential portion 13 having a semicircular cross section formed continuously from the first flat portion 12 and a substantially parallel portion formed continuously from the first circumferential portion 13 and spaced apart from the first flat portion 12; And a second flat plate portion 14 provided in the second flat plate portion 14, the second flat plate portion 14 is formed continuously from the second flat plate portion 14, and substantially perpendicular to the second flat plate portion 14.
A rectangular second short plate portion 15 provided substantially parallel to the short plate portion 11, and a second short plate portion 15 formed continuously from the second short plate portion 15;
A third flat plate portion 16 provided substantially at right angles to the short plate portion 15 and on the same plane as the first flat plate portion 12, and a semicircular cross-section formed continuously from the third flat plate portion 16; The second circumferential curved portion 17 is formed continuously from the second circumferential curved portion 17, provided substantially parallel to the third flat plate portion 16 at an interval, and provided on the same plane as the second flat plate portion 15. A fourth flat plate portion 18 having a flat plate shape, and a third short plate portion 19 having a rectangular shape formed continuously and substantially perpendicular to the fourth flat plate portion 18 and provided substantially in parallel with the second short plate portion 15. Consists of

As described above, the first short plate portion 11 and the second flat plate portion 1
2, a space surrounded by the first curved portion 13 and the second flat plate portion 14 forms a first flow path 26 into which the heat exchange fluid flows,
The space surrounded by the third flat plate portion 16, the second circumferential curved portion 17, the fourth flat plate portion 18, and the third short plate portion 19 is the same as the first flow path 26, where the heat exchange fluid flows. The two flow paths 27 are formed. Both of the first flow path 26 and the second flow path 27
It becomes a flow path of the heat exchange fluid in the two flat tubes 1.

When brass is used as the material of the flat tube 1, the thickness of the tube is reduced to 0.1 in order to reduce the weight.
[Mm] is formed. Then, as shown in the enlarged view of the flat tube 1 in FIG. 3B, the distance between the first short plate portion 11 and the second short plate portion 15 arranged substantially in parallel, and the second
The gap between the short plate portion 15 and the third short plate portion 19 is formed to about 0.1 [mm] into which the solder melts.

The thus formed flat tube 1 is
The molten solder is passed through the molten solder layer in which the molten solder is stored, and solder is applied to the outer peripheral surface. At the same time, the interval between the first short plate portion 11 and the second short plate portion 15, and the second short plate portion 15 and the third short plate portion 1
9 and the molten solder flows into the space. As shown in FIG. 2, the core part 3 of the flat tube 1 passed through the molten solder layer is temporarily assembled via a corrugated fin 2. The temporarily assembled core portion 3 is baked through a baking furnace, and the space between the flat tube 1 and the corrugated fin 2 is firstly baked.
The space between the short plate portion 11 and the second short plate portion 15 and the space between the second short plate portion 15 and the third short plate portion 19 are soldered and fixed.

As described above, according to the configuration of the present invention, the first short plate portion 11 and the second short plate portion 15, and the second short plate portion 15 and the third short plate portion 19 are formed on the respective surfaces. So that it is securely fixed. When aluminum is used as the material of the flat tube 1, if the flat tube 1 is formed using an aluminum plate coated with a brazing material on both sides in advance, the first short plate portion 11 and the second short Plate part 15
And between the second short plate portion 15 and the third short plate portion 19 are brazed and fixed.

As described above, the first short plate portion 11, the second short plate portion 15, and the third short plate portion 19, which are soldered or brazed, form an inner reinforcing column 30 of the flat tube 1. When the flat tube 1 is formed as in the present configuration, even if internal pressure is applied to the flat tube 1, the reinforcing inner pillar 30 is formed at the center of the flat tube 1, so that the width L of the flat tube 1 is increased. Even in this case, deformation of the central portion of the flat tube 1 can be suppressed. In addition, the first peripheral portion 13 and the second peripheral portion 17 to which the maximum stress is applied from the central reinforcing inner column 30.
Since the length up to half of the lateral width L, the stress generated in the first and second peripheral portions 13 and 17 can be reduced as compared with the case where the central inner pillar 30 is not provided. . For this reason, it is possible to form a wide flat tube having a long width L.
Therefore, in a wide heat exchanger, as shown in FIG. 5 (B), the flat tubes 1 can be applied in one row without using a plurality of flat tubes.

Next, a second embodiment of the present invention will be described. FIG. 6 shows a perspective view and an enlarged view of the tube 1 in the second embodiment. As shown in the perspective view of FIG. 6A, the tube 1 has a rectangular first short plate portion 11 that is short in the vertical direction in the figure and long in the depth direction, and an upper side of the first short plate portion 11 in the depth direction. And a flat plate-shaped first flat plate portion 12 formed substantially at right angles to the first short plate portion 11.
A first curved portion 13 having a semicircular cross section formed continuously from the flat plate portion 12, and being formed substantially continuously from the first curved portion 13 and provided substantially in parallel with the first flat plate portion 12 at an interval. A second flat plate portion 14, which is formed in a continuous manner from the second flat plate portion 14, is substantially perpendicular to the second flat plate portion 14, and has a first short plate portion 1.
A rectangular second short plate portion 15 provided substantially in parallel with 1;
A third short plate portion 19 which is continuous with the second short plate portion 15 and is formed substantially in parallel with the second short plate portion 15 is provided substantially at right angles to the third short plate portion 19 and on the same plane as the second flat plate portion 14. A third flat plate portion 16 having a flat plate shape, a second circumferential curved portion 17 having a semicircular cross section formed continuously from the third flat plate portion 16, and a continuous formed from the second circumferential curved portion 17; A fourth flat plate portion 18 which is provided substantially in parallel with the third flat plate portion 16 at an interval and provided on the same plane as the first flat plate portion 12; The third short plate portion 19 is formed at a right angle, and includes a rectangular fourth short plate portion 40 provided substantially in parallel with the third short plate portion 19.

As described above, the first short plate portion 11 and the first flat plate portion 1
2, the first curved portion 13, and the space surrounded by the second flat plate portion 14 and the second short plate portion 15 form a first flow path 26 into which the heat exchange fluid flows, and the third short plate portion The space surrounded by the third flat plate portion 16, the second curved portion 17, the fourth flat plate portion 18, and the fourth short plate portion 40, like the first flow path 26, flows in the heat exchange fluid. A second flow path 27 is formed. The first of both
The flow path 26 and the second flow path 27 serve as a flow path of the heat exchange fluid in one flat tube 1.

When brass is used as the material of the flat tube 1, its thickness is reduced to 0.1 for weight reduction.
[Mm] is formed. Then, as shown in the enlarged view of the flat tube 1 in FIG. 6B, the interval between the first short plate portion 11 and the second short plate portion 15 arranged substantially in parallel, and the second short plate portion 15 The distance from the third short plate portion 19 and the third short plate portion 19
The distance between the first short plate portion 40 and the fourth short plate portion 40 is 0.1
It is molded to about [mm].

The thus formed flat tube 1 is
The molten solder is passed through the molten solder layer in which the molten solder is stored, and solder is applied to the outer peripheral surface. At the same time, the interval between the first short plate portion 11 and the second short plate portion 15, the interval between the second short plate portion 15 and the third short plate portion 19, and the third short plate portion 19 and the fourth short plate portion 40 And molten solder flows between them. The flat tube 1 passed through the molten solder layer is, as shown in FIG.
The core part 3 is temporarily assembled via. The temporarily assembled core portion 3 is baked through a baking furnace, and between the flat tube 1 and the corrugated fin 2, between the first short plate portion 11 and the second short plate portion 15, and the second short plate portion. 15 and the third short plate part 1
9, and between the third short plate portion 19 and the fourth short plate portion 40 are fixed by soldering.

As described above, according to the configuration of the present invention, the first short plate portion 11 and the second short plate portion 15, and the second short plate portion 15 and the third short plate portion
The short plate portion 19 and the third short plate portion 19 and the fourth short plate portion 40 are soldered on their respective surfaces, so that they are securely fixed.
When aluminum is used as the material of the flat tube 1, if the flat tube 1 is formed using an aluminum plate coated with a brazing material on both surfaces or one surface in advance, the first short plate portion 11 and the Between the two short plate portions 15, the second short plate portion 15 and the third short plate portion 19, and the third short plate portion 19 and the fourth short plate portion
The space between the short plate portions 40 is brazed and fixed.

As described above, the first short plate portion 11, the second short plate portion 15, and the third short plate portion 1, which are soldered or brazed, are used.
The ninth and fourth short plate portions 40 form the reinforcing inner pillar 30 of the flat tube 1. If the flat tube 1 is formed as in the present configuration, even if internal pressure is applied to the flat tube 1, the reinforcing inner pillar 30 is formed at the center of the flat tube 1,
Even if the width L of the flat tube 1 is increased, the deformation of the central portion of the flat tube 1 can be suppressed. In addition, since the length from the central reinforcing inner pillar 30 to the first peripheral curved portion 13 and the second peripheral curved portion 17 where the maximum stress is applied becomes half of the lateral width L, the case where the central reinforcing inner pillar 30 is not provided. The first rounded part 1
It is possible to reduce the stress generated in the third and second curved portions 17. For this reason, it is possible to form a wide flat tube having a long width L. Therefore, in a wide heat exchanger, FIG.
As shown in (B), the flat tubes 1 can be applied in one row without forming the flat tubes in a plurality of rows.

Next, a third embodiment of the present invention will be described.
In the heat exchanger of the second embodiment, as shown in FIG. 6B, the length of the second short plate portion 15 and the third short plate portion 19 is the distance between the second flat plate portion 14 and the first flat plate portion 12. The first short plate portion 11 and the fourth short plate portion 40 are formed shorter than the distance n between the second flat plate portion 14 and the first flat plate portion 12 by a distance m shorter than n.

Therefore, when assembling the flat tube 1 and the fin 2 using aluminum, variations in the length of the first short plate portion 11 and fourth short plate portion 40 and variations in the height of the fin 2 are absorbed. Therefore, there is also an effect that buckling of the fin 2 can be prevented. Next, another embodiment obtained by modifying the third embodiment is shown in FIG. This embodiment is different from the third embodiment in that a projection 42 having a thickness substantially equal to the tube thickness is provided between the first short plate portion 11 and the first flat plate portion 12 in a direction opposite to the first circumferentially curved portion 13. Short plate portion 40 and fourth flat plate portion 1
8, a projection 43 having a thickness substantially equal to the thickness of the tube is provided in a direction opposite to the second circumferentially curved portion 17, and a gap between both projections is provided by about 0.1 mm to abut each other.

In the above embodiment, the present invention is applied to a heater core of a hot water heater. However, the present invention is not limited to this. For example, a radiator for radiating cooling water for a vehicle engine may be used. Etc. can be similarly applied.

[Brief description of the drawings]

FIG. 1 is a perspective view of a heater core that is a heat exchanger of the present invention.

FIG. 2 is a perspective view of a core of the heat exchanger of the present invention.

FIG. 3A is a perspective view of a flat tube of the heat exchanger of the present invention. (B) is an enlarged view of a flat tube.

FIG. 4 is a perspective view of a conventional flat tube.

FIG. 5A is a perspective view of a conventional flat tube.
(B) is a top view of the core of the conventional heat exchanger.

FIG. 6A is a perspective view of a flat tube of the heat exchanger of the present invention. (B) is an enlarged view of a flat tube.

FIG. 7 is a sectional view of a flat tube of the heat exchanger of the present invention.

[Explanation of symbols]

 Reference Signs List 1 flat tube 2 corrugated fin 11 first short plate portion 15 second short plate portion 19 third short plate portion 30 inner column for reinforcement 31 brazing material 40 fourth short plate portion

──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Mikio Fukuoka 1-1-1, Showa-cho, Kariya-shi, Aichi Japan Inside Denso Corporation (72) Inventor Yoshifumi Aki 1-1-1, Showa-cho, Kariya-shi, Aichi Japan Nihon Denso Co., Ltd. (56) References Japanese Utility Model Application Sho 54-29464 (JP, U) (58) Fields investigated (Int. Cl. ⁶ , DB name) F28F 1/02 B21C 37/15 B21D 53/04

Claims (3)

(57) [Claims] 1. A heat exchanger including a flat tube through which a heat exchange fluid flows, and a heat transfer fin joined to the flat tube so as to be able to conduct heat, wherein the flat tube has a rectangular first short plate portion. A first flat plate portion formed substantially continuously at a right angle from the long side of the first short plate portion; and a first semicircular cross-section formed continuously from the first flat plate portion.
A circumferentially curved portion, a second flat plate portion formed continuously from the first circumferentially curved portion and provided substantially in parallel with the first flat plate portion, and a substantially right angle continuous from the second flat plate portion A rectangular second short plate portion formed substantially parallel to and adjacent to the first short plate portion; and a substantially right angle continuous from the second short plate portion; A third flat plate portion provided in a direction opposite to the first flat plate portion with respect to the portion, and a second semicircular cross-section formed continuously from the third flat plate portion.
A peripheral curved portion, formed continuously from the second peripheral curved portion, provided substantially parallel to the third flat plate portion, and in a direction facing the second flat plate portion with respect to the second short plate portion. A fourth flat plate portion having a rectangular shape, and a third rectangular portion formed substantially at right angles to the fourth flat plate portion and provided substantially parallel to and adjacent to the second short plate portion.
A short plate portion, between the first short plate portion and the second short plate portion provided adjacently, and between the second short plate portion provided adjacently and the third short plate portion.
A space surrounded by the first short plate portion, the first flat plate portion, the first curved portion, and the second flat plate portion joins between the short plate portions, and the heat exchange fluid flows into the space. A first flow path is formed, and a space surrounded by the third flat plate portion, the second circumferential curved portion, the fourth flat plate portion, and the third short plate portion is a space into which the heat exchange fluid flows. A heat exchanger that forms two flow paths. 2. A heat exchanger including a flat tube through which a heat exchange fluid flows and a heat transfer fin joined to the flat tube so as to be able to conduct heat, wherein the flat tube has a rectangular first short plate portion. A first flat plate portion formed substantially continuously at a right angle from the long side of the first short plate portion; and a first semicircular cross-section formed continuously from the first flat plate portion.
A circumferentially curved portion, a second flat plate portion formed continuously from the first circumferentially curved portion and provided substantially in parallel with the first flat plate portion, and a substantially right angle continuous from the second flat plate portion A rectangular second short plate portion formed and provided substantially parallel to and adjacent to the first short plate portion; and a second short plate portion being formed so as to be continuous and substantially parallel folded back from the second short plate portion and provided adjacent to the first short plate portion. A rectangular third short plate portion, a third flat plate portion that is continuous from the third short plate portion and extends substantially perpendicularly to a direction facing the second flat plate portion, and a third flat plate portion. From the semicircular cross section formed continuously from the second
A circumferentially curved portion, a flat plate-shaped fourth flat plate portion formed continuously from the second circumferentially curved portion and extending substantially in parallel with the third flat plate portion and in the direction of the third short plate portion; A fourth rectangular plate formed substantially at right angles to the fourth flat plate portion and provided substantially parallel to and adjacent to the third short plate portion.
A short plate portion, between the first short plate portion and the second short plate portion provided adjacently, and between the second short plate portion and the third short plate portion provided adjacently. And joining between the third short plate portion and the fourth short plate portion provided adjacent to each other, the first short plate portion, the first flat plate portion, the first curved portion, and the second short plate portion. A space surrounded by the flat plate portion and the second short plate portion forms a first flow path into which the heat exchange fluid flows, and the third short plate portion, the third flat plate portion, and the second circumferential curve A heat exchanger, wherein a space surrounded by the first part, the fourth flat plate part, and the fourth short plate part forms a second flow path into which the heat exchange fluid flows. 3. The second short plate portion and the third short plate portion have a length shorter than a distance from the second flat plate portion to the first flat plate portion. The heat exchanger according to claim 2, wherein the length of the four short plate portions is shorter than a distance from the second flat plate portion to the first flat plate portion.