JP2016176659A - Process of manufacture for heat exchanger and heat exchanger - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technology capable of increasing a fin connecting strength.SOLUTION: This process of manufacture includes the steps for temporarily fixing each of fins [53 to 56] to both surfaces of each of bottom parts [51a, 52a] of a first divided segment and a second divided segment [51, 52] to attain first and second temporary fixing segments [81, 82]; laser welding the right and left side walls [51b, 51b] of the first divided segment [51] with the right and left side walls [52b, 52b] of the second divided segment [52] to connect the first temporary fixing segment [81] with the second temporary fixing segment [82] to attain a side wall part connecting segment [83]; final welding fins [53, 54] to the first divided segment [51] by laser welding, final welding other fins [55, 56] to the second divided segment [52] by laser welding to attain a heat exchanging tube [50].SELECTED DRAWING: Figure 6

Description

  The present invention relates to a technique for manufacturing a heat exchanger.

  A heat exchanger that performs heat exchange between a first heat medium that flows inside the heat exchange tube and a second heat medium that flows outside the heat exchange tube is known. As a conventional technique related to such a heat exchanger, there is a technique disclosed in Patent Document 1.

  The heat exchanger as shown in Patent Document 1 includes a plurality of heat exchange tubes. The heat exchange tube includes a tube main body that has an oval shape when viewed from the flow direction of the first heat medium, and fins that are built into the tube main body and brazed to the tube main body.

  By the way, the fin is repeatedly affected by heat from the medium. From the viewpoint of extending the life of the heat exchanger, it is desired to more firmly join the fin to the tube body.

JP 2006-118830 A

  An object of the present invention is to provide a technique capable of increasing the bonding strength of fins.

According to the invention of claim 1, in the method of manufacturing a heat exchanger,
Raising both ends of a substantially rectangular plate to obtain a first divided body and a second divided body;
Temporarily fixing fins to both surfaces of the bottom of the first divided body to obtain a first temporary fixing body;
Temporarily fixing fins different from the fins on both surfaces of the bottom of the second divided body to obtain a second temporary fixing body;
The first temporary body is laser welded to the side wall portions raised from both ends of the bottom portion of the first divided body and the side wall portions raised from both ends of the bottom portion of the second divided body, respectively. Joining the stopper and the second temporary stopper to obtain a side wall joined body;
And heat welding the fin to the first divided body by laser welding, and finally welding the other fin to the second divided body by laser welding to obtain a heat exchange tube. An exchange manufacturing method is provided.

According to the invention according to claim 2, in the method of manufacturing a heat exchanger,
Raising both ends of a substantially rectangular plate to obtain a first divided body and a second divided body;
Temporarily fixing fins to both surfaces of the bottom of the first divided body to obtain a first temporary fixing body;
Temporarily fixing fins different from the fins on both surfaces of the bottom of the second divided body to obtain a second temporary fixing body;
The fins temporarily fixed to the first divided body are each welded to the first divided body by laser welding one by one, and the other fins temporarily fixed to the second divided body are respectively A step of performing main welding to the second divided body by laser welding one by one;
Side walls raised from both ends of the bottom portion of the first divided body where the fins were main-welded and raised from both ends of the bottom portion of the second divided body where the other fins were main-welded And a step of laser welding the side wall.

  As described in claim 3, preferably, the method includes a step of laser-welding both ends of the heat exchange tube to a pair of end plates to obtain a heat exchange tube assembly.

As described in claim 4, preferably, in the step of obtaining the first temporary fixing body, the fin is temporarily fixed to the first divided body by laser welding,
In the step of obtaining the second temporary fixing body, the another fin is temporarily fixed to the second divided body by laser welding.

According to the invention of claim 5, a cylindrical core case, a pair of end plates that close both ends of the core case, and heat exchange tubes in which both ends are supported by these end plates and the first heat medium flows inside In the heat exchanger that performs heat exchange between the first heat medium and the second heat medium that flows outside the heat exchange tube,
The heat exchange tube is
The first divided body and the second divided body both having a substantially U-shape when viewed from the flow direction of the first heat medium,
The first divided body and the second divided body are arranged facing each other, and are formed into a cylindrical shape by laser welding the side wall portions,
A first fin is laser welded to the surface facing the inside of the bottom of the first divided body,
A second fin is laser welded to a surface facing the outside in the bottom of the first divided body,
A third fin is laser welded to the surface facing the inside of the bottom of the second divided body,
A heat exchanger is provided in which a fourth fin is laser-welded to a surface facing the outside in the bottom of the second divided body.

  As described in claim 6, preferably, the first fin and the third fin are separated from each other.

  In the first and second aspects of the invention, the fin is main-welded to the first divided body by laser welding, and the fin is main-welded to the second divided body by laser welding. Compared to the case where the fins are brazed to the respective divided bodies, the bonding strength of the fins can be increased. The life of the heat exchanger can be extended.

  In particular, in the invention according to claim 1, after the first temporary fixing body and the second temporary fixing body are joined, the respective fins are finally welded to the respective divided bodies. In the main welding of the fins, the assembly process can be reduced because three pieces of each divided body and the fins on both sides thereof are welded simultaneously. However, since it is necessary to increase the heat input in order to weld three pieces at the same time, there is a possibility that the divided body is deformed. If it is deformed, the combination of the divided bodies becomes worse. Prior to the main welding of the fin, the heat exchange tube can be manufactured smoothly by joining the first and second temporary fixing bodies.

  In particular, in the invention according to claim 2, after the step of obtaining the first temporary fixing body and the second temporary fixing body, the fins on both sides of each divided body are finally welded one by one. Since each divided body and two fins on both sides thereof are welded, heat input can be lowered, deformation of the divided body can be suppressed, and more stable joining can be achieved.

  In the invention which concerns on Claim 3, the both ends of a heat exchange tube are laser-welded to a pair of end plate, and a heat exchange tube assembly is obtained. Compared with the case where the heat exchange tube is brazed to the end plate, a high bonding strength can be obtained. Contributes to extending the life of heat exchangers.

  In the invention which concerns on Claim 4, in the process of obtaining each temporary fixing body, a fin is temporarily fixed to a division body by laser welding. In making the heat exchange tube, all welding is performed by laser welding. Compared to the case where a plurality of joining methods are used, the number of apparatuses required for producing the heat exchange tube can be reduced.

  In the invention which concerns on Claim 5, each fin is joined to each division body by laser welding. Compared to the case where the fins are brazed to the respective divided bodies, the bonding strength of the fins can be increased. The life of the heat exchanger can be extended.

  In the invention which concerns on Claim 6, the 1st fin and the 3rd fin are spaced apart. It is conceivable that each divided body bends inward due to the pressure from the second heat medium. At this time, if the first fin and the third fin are in contact with each other, each of the divided bodies is bent, and these fins are pressed against each other. For this reason, a load is applied to the first and third fins. By separating the first and third fins, the load that can be applied to them can be reduced. Contributes to extending the life of heat exchangers.

It is a perspective view of the heat exchanger by Example 1 of this invention. FIG. 2 is a sectional view taken along line 2-2 of FIG. FIG. 3 is a sectional view taken along line 3-3 in FIG. 1. It is a figure explaining from the process of obtaining a 1st division body and a 2nd division body to the process of obtaining the 1st and 2nd temporary fix | stop body. It is a perspective view of the 1st and 2nd temporary fix | stop body shown by FIG. It is a figure explaining from the process of obtaining a side wall part zygote to the process of obtaining a heat exchange tube. FIG. 7 is an enlarged view of part 7 of FIG. 6. It is a perspective view of the heat exchange tube shown by FIG. It is a figure explaining the process of obtaining a heat exchange tube assembly. It is sectional drawing along the flow direction of the exhaust gas of the heat exchanger by Example 2 of this invention. It is sectional drawing seen from the flow direction of the exhaust gas of the heat exchanger by Example 3 of this invention.

  Embodiments of the present invention will be described below with reference to the accompanying drawings. The drawings are viewed in the direction of the reference numerals.

  First, an embodiment of the present invention will be described with reference to the drawings.

<Example 1>
Please refer to FIG. For example, the heat exchanger 30 according to the present invention is used for preheating air with exhaust gas.

  As indicated by the arrows, the exhaust gas is introduced into the heat exchanger 30 from the exhaust gas introduction pipe 22 (first heat medium introduction pipe 22), and the exhaust gas discharge pipe 21 (first heat medium discharge pipe 21). To the outside of the heat exchanger 30.

  As indicated by the white arrow, air is introduced into the heat exchanger 30 from the air introduction pipe 23 (second heat medium introduction pipe 23), and from the air discharge pipe 24 (second heat medium discharge pipe 24). It is discharged outside the heat exchanger 30.

  Please refer to FIG. The heat exchanger 30 includes an exhaust gas introduction member 35 (first heat medium introduction member 35) to which the exhaust gas introduction pipe 22 is connected, an upstream end plate 34 connected to the exhaust gas introduction member 35, A substantially rectangular tube-shaped core case 40 connected to the upstream end plate 34, a downstream end plate 32 attached to the downstream end of the core case 40, and the downstream end plate 32 Both ends are supported by an exhaust gas discharge member 31 (first heat medium discharge member 31) to which the exhaust gas discharge pipe 21 is connected and the upstream and downstream end plates 34 and 32, and the exhaust gas is internally contained. And a heat exchange tube 50 through which air flows.

  The upstream end plate 34 disposed on the upstream side (right side of the drawing) with respect to the flow direction of the exhaust gas has a substantially rectangular upstream plate bottom 34a and downstream from each side of the upstream plate bottom 34a. And an upstream plate side wall portion 34b (only the upper and lower upstream plate side wall portions 34b are shown in the figure).

  The exhaust gas introduction member 35 and the core case 40 are joined to the upstream plate side wall 34b.

  Tube insertion holes 34c and 34c for inserting upstream ends of the heat exchange tubes 50 and 50 are formed in the upstream plate bottom 34a.

  The downstream end plate 32 disposed on the downstream side has a substantially rectangular downstream plate bottom portion 32a, and downstream plate side wall portions 32b extending from the respective sides of the downstream plate bottom portion 32a toward the upstream side (in the drawing). Only the upper and lower downstream plate side wall portions 32b are shown).

  The exhaust gas discharge member 31 and the core case 40 are joined to the downstream side plate side wall 32b.

  Tube insertion holes 32c and 32c for inserting downstream ends of the heat exchange tubes 50 and 50 are formed in the downstream plate bottom 32a.

  Both the air introduction pipe 23 and the air discharge pipe 24 are provided on the same surface of the core case 40.

  Please refer to FIG. The core case 40 has a substantially rectangular shape when viewed from the flow direction of the exhaust gas. The core case 40 is composed of a lower case 41 and an upper case 42 which are divided into two parts in the vertical direction and both have a substantially U shape. The upper case 42 is superimposed on the lower case 41 that opens upward, and is joined to each other.

  The lower case 41 includes a lower case bottom 41a and left and right lower case side walls 41b and 41b respectively raised from both ends.

  The upper case 42 includes an upper case bottom portion 42a and left and right upper case side wall portions 42b and 42b extending downward from both ends. Both ends of the left and right upper case side walls 42b and 42b are bulged portions 42c and 42c that bulge outward. These bulging portions 42c and 42c are overlapped with the tips of the lower case side wall portions 41b and 41b.

  In the heat exchange tube 50, a first divided body 51 and a second divided body 52, both of which are substantially U-shaped when viewed from the flow direction of the exhaust gas, are disposed facing each other and joined together. The first and second fins 53 and 54 (fins 53 and 54) are joined to each other, and the third and fourth fins 55 and 56 (other fins 55 and 56) are joined to the second divided body 52. . Corrugated fins are employed for the first to fourth fins 53 to 56.

  FIG. 3 shows an example in which the same parts are used for the first and second divided bodies 51 and 52, and the same parts are also used for the first to fourth fins 53 to 56. About these, a different component can also be employ | adopted suitably.

  The first divided body 51 is raised toward the second divided body 52 from both ends of the first divided body bottom 51a extending vertically and the first divided body bottom 51a (the bottom 51a of the first divided body). 1st division body side wall parts 51b and 51b (side wall part 51b, 51b of the 1st division body).

  The second divided body 52 extends from the upper and lower ends of the second divided body bottom 52a (the bottom 52a of the second divided body) and the upper and lower ends of the second divided body 52a toward the first divided body 51. The second divided body side wall portions 52b and 52b (second divided body side wall portions 52b and 52b).

  Exhaust gas flows through the inside of the tube formed by the first divided body 51 and the second divided body 52, and air flows outside. That is, the heat exchange tube 50 divides the flow path through which the exhaust gas flows and the flow path through which the air flows, and these flow paths are arranged adjacent to each other. The heat of the exhaust gas is transmitted to the air through the first and second divided bodies 51 and 52 and the first to fourth fins 53 to 56.

  The first fin 53 is joined to the surface facing the inside of the first divided body bottom 51a, and the second fin 54 is joined to the surface facing the outside. Both the first and second fins 53 and 54 are joined to the first divided body 51 by laser welding.

  The 3rd fin 55 is joined to the surface which faces the inside of the 2nd division bottom 52a, and the 4th fin 56 is joined to the surface which faces the outside. Both the third and fourth fins 55 and 56 are joined to the second divided body 52 by laser welding.

  The first fin 53 includes a first fin bottom portion 53a joined to the first divided body bottom portion 51a, a first fin rising portion 53b raised from an end portion of the first fin bottom portion 53a, and the first fin 53 A first fin top portion 53c extending substantially parallel to the first fin bottom portion 53a from the upper end of the fin rising portion 53b, and a first fin lowered from the end portion of the first fin top portion 53c toward the adjacent first fin bottom portion 53a. The fin falling portion 53d is repeated.

  The same applies to the second to fourth fins 54 to 56. That is, the second fin 54 has a shape that repeats the second fin bottom 54a, the second fin rising portion 54b, the second fin top 54c, and the second fin falling portion 54d. The 3rd fin 55 is made into the shape which repeats the 3rd fin bottom part 55a, the 3rd fin rise part 55b, the 3rd fin top part 55c, and the 3rd fin fall part 55d. The 4th fin 56 is made into the shape which repeats the 4th fin bottom part 56a, the 4th fin rise part 56b, the 4th fin top part 56c, and the 4th fin fall part 56d.

  The first fin top portion 53c and the third fin top portion 55c are spaced apart. That is, the height of each fin is adjusted so that the 1st fin top part 53c and the 3rd fin top part 55c do not contact. In addition, a mutual position can also be shifted so that the 1st and 3rd fin top parts 53c and 55c may space apart.

  The lower case bottom 41 a is formed with a lower recess 41 d that is recessed toward the heat exchange tube 50. In the upper case bottom portion 42a, a recess is formed toward the heat exchange tube 50 between a portion to which the air introduction pipe 23 (see FIG. 1) is connected and a portion to which the air discharge pipe 24 (see FIG. 1) is connected. The upper concave portion 42d is formed. The heat exchange tubes 50 and 50 and the core case 40 are separated from each other.

  By forming the lower and upper concave portions 41d and 42d, the air flow paths above and below the heat exchange tubes 50 and 50 are narrowed. Thereby, the air introduced into the heat exchanger 30 can be guided in the vicinity of the heat exchange tube 50. In addition, the strength of the core case 40 can be increased by having the lower and upper recesses 41d and 42d. The method for manufacturing the heat exchanger 30 will be described with reference to FIG.

  Please refer to FIG. As shown in FIG. 4A, first, a substantially rectangular plate material 71 is prepared.

  Next, as shown in FIG. 4B, both ends of the plate material 71 are raised to obtain the first divided body 51. The first divided body 51 can be formed by press molding, for example. The molding method is not limited to press molding.

  Next, as shown in FIG. 4C, a jig 60 and fins 53 and 54 are prepared.

  The jig 60 includes a first jig 61 on the fixed side, and a second jig 62 that can move toward the first jig 61. The first jig 61 has a pin 61a on which the bottom 53a of the fin 53 is placed, and a hole 61b that faces the bottom 53a of the fin 53 while avoiding a portion where the pin 61a is provided. The second jig 62 has a pin 62a on which the bottom 54a of the fin 54 is placed, and a hole 62b that faces the bottom 54a of the fin 54 while avoiding the portion where the pin 62a is provided. The pins 61a and 62a are provided facing each other when viewed from the flow direction of the first heat medium so that the positions of the bottom portions 53a and 54a of the fins 53 and 54 coincide.

  Then, the fins 53 are placed on the first jig 61, the first divided body 51 is placed on the fins 53, the fins 54 are further placed from above, and the second jig 62 is placed. At this time, the tip of the first divided body side wall 51 b may be disposed toward the first jig 61 or may be disposed toward the second jig 62. Further, the first jig 61 may move and the second jig 62 may be fixed.

  For example, the first and second jigs 61 and 62 are formed with a plurality of pins 61a and 62a for placing the fins 53 and 54 at predetermined positions. As shown in FIG. 4D, the fins 53 and 54 are arranged at predetermined positions by fixing the second jig 62 to the first jig 61. In the state where the first and second jigs 61 and 62 are fixed, the bottom 54a of the fin 54 is located above the bottom 53a of the fin 53 disposed below, with the first divided body 51 interposed therebetween. ing. That is, in the first fin placement step in which the fins 53 and 54 are placed on both sides of the first divided body bottom 51a, the bottoms 53a and 54a of the fins 53 and 54 are placed in alignment with each other.

  Next, the fins 53 and 54 are temporarily fixed to the first divided body 51 by the laser welding machine 75. The second jig 62 is formed with a plurality of dotted holes 62b. By passing through the hole 62b, the bottom 54a of the fin 54 is irradiated with laser. Thereby, the fin 54 is temporarily fixed to the 1st division body bottom part 51a. Next, these top and bottom are reversed, and the same process is performed. Thereby, the fin 53 is temporarily fixed to the 1st division body bottom part 51a. In this way, the first temporary fixing body 81 is obtained.

  The temporary fixing can also be performed by resistance spot welding performed by sandwiching the bottoms 53a and 54a of the fins 53 and 54.

  Please refer to FIG. In the first temporary fixing body 81, the fins 53 and 54 (only the upper fin 54 is shown) are joined to the first divided body bottom 51a by a plurality of points. Thus, since it temporarily fixes by spot welding, it can suppress that the 1st division body bottom part 51a bends with the heat | fever at the time of welding.

  A second temporary fixing body is obtained through the same steps as those shown in FIGS. 4 (a) to 4 (d).

  That is, as shown in FIG. 4A, first, a substantially rectangular plate material 72 is prepared. Next, as shown in FIG. 4B, both ends of the plate material 72 are raised to obtain the second divided body 52.

  Next, as shown in FIG. 4C, first and second jigs 61 and 62 and fins 55 and 56 (another fins 55 and 56) are prepared. Then, the fin 55 is placed on the first jig 61, the second divided body 52 is placed on the fin 55, the fin 56 is placed from above, and the second jig 62 is placed.

  As shown in FIG. 4D, the second jig 62 is fixed to the first jig 61. In a state where the first and second jigs 61 and 62 are fixed, the bottom portion 56a of the fin 56 is positioned above the bottom portion 55a of the fin 55 disposed below, with the second divided body 52 interposed therebetween. ing. That is, in the second fin placement step in which the fins 55 and 56 are placed on both surfaces of the second divided body bottom portion 52a, the bottom portions 55a and 56a of the other fins 55 and 56 are placed in alignment with each other.

  Next, the fins 55 and 56 are temporarily fixed to the second divided body 52 by the laser welding machine 75. Thereby, the 2nd temporary fix | stop body 82 (refer FIG. 5) is obtained.

  Please refer to FIG. As shown in FIG. 6A, the first divided body side wall portions 51b and 51b and the second divided body side wall portions 52b and 52b are overlapped. Next, as shown in FIG. 6B, the first divided body side wall portions 51b and 51b and the second divided body side wall portions 52b and 52b are laser-welded. As a result, the first temporary fixing body 81 and the second temporary fixing body 82 are bonded to obtain the side wall bonded body 83.

  As shown in FIG. 6C, the fins 53 and 54 are finally welded to the first divided body 51 by laser welding, and the fins 55 and 56 are laser welded to the second divided body 52. Thereby, the heat exchange tube 50 is obtained.

  In the step of obtaining the heat exchange tube, the laser is irradiated only toward the bottom portions 54a and 56a of the fins 54 and 56 located outside the tube formed by the first divided body 51 and the second divided body 52.

  As shown in FIG. 7A, the laser first melts the bottom 54 a of the fin 54. Next, as shown in FIG. 7B, the first divided body 51 is melted, and as shown in FIG. 7C, the bottom 53a of the fins 53 is melted. The weld mark B1 formed at this time becomes slightly narrower from the fin 54 directly irradiated with the laser toward the fin 53 not directly irradiated with the laser.

  In the step of obtaining the heat exchange tube, the laser is irradiated only toward the bottom 54 a of one fin 54. That is, of the fins 53 and 54 disposed on both surfaces of the first divided body 51, only one fin 54 is irradiated with laser, and the other fin 53 is not irradiated with laser.

  Please refer to FIG. By performing the main welding, the welding mark B2 is formed in a linear shape. The bottom portions 55 a and 56 a of the fins 55 and 56 are continuously joined to the second divided body 52. The same applies to the bottom portions 53a and 54a of the fins 53 and 54.

  Please refer to FIG. The heat exchange tubes 50 and 50 are laser welded after both ends are inserted into the end plates 32 and 34. Thereby, the heat exchange tube assembly 84 is obtained.

  In addition, arbitrary methods can be employ | adopted for joining of the core case 40 (refer FIG. 2) to the end plates 32 and 34. FIG.

  According to the present invention described above, the following effects can be obtained.

  Reference is made to FIG. The fins 53 and 54 are finally welded to the first divided body 51 by laser welding, and the fins 55 and 56 are finally welded to the second divided body 52 by laser welding. Compared with the case where the fins 53 to 56 are brazed to the respective divided bodies 51 and 52, the bonding strength of the fins 53 to 56 can be increased. The life of the heat exchanger 30 can be extended.

  Further, the bottoms 53 a and 54 a of the fins 53 and 54 are aligned at the same position, and then laser welding is performed toward the bottom 54 a of one fin 54. The fins 53 and 54 can be welded to both surfaces of the 1st division body 51 by welding once. This contributes to shortening the time required for assembling the heat exchange tube 50.

  Reference is also made to FIG. After the first temporary fixing body 81 and the second temporary fixing body 82 are joined, the respective fins 53 to 56 are finally welded to the respective divided bodies 51 and 52. In the main welding of the fins 53 to 56, each of the divided bodies 51 and 52 and the three fins 53 to 56 on both sides thereof are welded simultaneously, so that the assembly process can be reduced. However, since it is necessary to increase the heat input in order to weld three pieces at the same time, there is a possibility that the divided bodies 51 and 52 are deformed. When deformed, the combination of the respective divided bodies 51 and 52 becomes worse. Prior to the main welding of the fins 53 to 56, the heat exchange tube 50 (see FIG. 3) can be manufactured smoothly by joining the first and second temporary fixing bodies 81 and 82 together.

  Please refer to FIG. Both ends of the heat exchange tubes 50, 50 are laser welded to the pair of end plates 32, 34 to obtain a heat exchange tube assembly 84. Compared with the case where the heat exchange tubes 50, 50 are brazed to the end plates 32, 34, a high bonding strength can be obtained. This contributes to extending the life of the heat exchanger 30 (see FIG. 3).

  In addition, this welding can also be performed after the process of obtaining a 1st temporary fix | stop body, and the process of obtaining a 2nd temporary fix | stop body, and before joining of each division body 51,52. At this time, it is desirable that the fins 53 and 54 temporarily fixed to both surfaces of the first divided body 51 are main-welded to the first divided body 51 one by one by laser welding. For example, after the fin 53 is main-welded to the first divided body 51 by laser welding, the fin 54 is main-welded to the first divided body 51 by laser welding. It is desirable that the fins 55 and 56 temporarily fixed to both surfaces of the second divided body 52 are also main-welded one by one to the second divided body 52 by laser welding. The order of these fins 53 to 56 can be arbitrarily selected as long as the main welding is performed by laser welding one by one, not two at a time.

  Since each of the divided bodies 51 and 52 and the fins 53 to 56 on both sides thereof are welded two by two, the heat input can be lowered, and the divided bodies 51 and 52 are deformed as compared with the case where the three pieces are welded simultaneously. Can be suppressed, and more stable joining can be achieved.

  Reference is made to FIG. In the step of obtaining the temporary fixing bodies 81 and 82, the fins 53 to 56 are temporarily fixed to the divided bodies 51 and 52 by laser welding. In the production of the heat exchange tube 50, all welding is performed by laser welding. Compared with the case where a plurality of joining methods are used, the number of apparatuses required for producing the heat exchange tube 50 can be reduced.

Further, the jig 60 used for temporary fixing includes a first jig 61 and a second jig 62 fitted to the first jig 61. The first jig 61 has a pin 61a on which the bottom 53a of the fin 53 is placed, and the second jig 62 is provided with a pin 62a on which the bottom 54a of the fin 54 is placed and a pin 62a. It has a hole 62b that faces the bottom 54a of the fin 54 while avoiding the formed portion. The pins 61a and 62a are provided facing each other when viewed from the flow direction of the first heat medium so that the positions of the bottom portions 53a and 54a of the fins 53 and 54 coincide. Thereby, the bottom parts 53a and 54a of the fins 53 and 54 can be match | combined easily.

  Please refer to FIG. The first fin 53 and the third fin 55 are separated from each other. It is conceivable that the divided bodies 51 and 52 bend inward due to the pressure from the second heat medium. At this time, if the first fin 53 and the third fin 55 are in contact with each other, the divided bodies 51 and 52 are bent inward, so that the fins 53 and 55 are pressed against each other. . For this reason, a load is applied to the first and third fins 53 and 55. By separating the first and third fins 53 and 55, the load that can be applied to them can be reduced. This contributes to extending the life of the heat exchanger 30.

<Example 2>
Next, a second embodiment of the present invention will be described with reference to the drawings. FIG. 10 shows a cross-sectional configuration of the heat exchanger according to the second embodiment, which is shown corresponding to FIG.

  In the heat exchanger 30A according to the second embodiment, holes 53e to 56e are formed in place of the fins 53 to 56 (see FIG. 2) used in the heat exchanger 30 (see FIG. 2) according to the first embodiment. The first to fourth fins 53A to 56A having different lengths are employed. Other basic configurations are the same as those of the heat exchanger according to the first embodiment. About the part which is common in Example 1, while using a code | symbol, detailed description is abbreviate | omitted.

  Please refer to FIG. Holes 53e to 56e are formed in the first to fourth fins 53A to 56A used in the heat exchange tube 50A, respectively. The holes 53e to 56e are formed in the rising portion and / or the falling portion of the first to fourth fins 53A to 56A.

  In addition, the first and third fins 53A and 55A disposed inside the first and second divided bodies 51 and 52 are disposed outside the first and second divided bodies 51 and 52, respectively. It is longer than the second and fourth fins 54A and 56A.

  Even in such a heat exchanger 30A, a predetermined effect of the present invention can be obtained.

  In addition, holes 53e to 56e are opened in the first to fourth fins 53A to 56A, respectively. In each flow path, there are a part where the flow rate of the medium is large and a part where the medium is low. Since the holes 53e to 56e are opened in the fins 53A to 56A, the medium flows from a part with a large flow rate to a part with a small flow rate through the holes 53e to 56e. By making the flow rate of the medium more uniform, heat exchange can be performed efficiently.

  In addition, the first and third fins 53A and 55A disposed inside the first and second divided bodies 51 and 52 are disposed outside the first and second divided bodies 51 and 52, respectively. It is longer than the second and fourth fins 54A and 56A. The flow paths formed inside the first and second divided bodies 51 and 52 are linear and simple in shape. For this reason, the medium (exhaust gas) can flow smoothly. On the other hand, the flow path formed outside the first and second divided bodies 51 and 52 is more complicated than the internal flow path. For this reason, it is difficult for the medium (air) to flow smoothly compared to the internal flow path. Long fins 53A and 55A are arranged in the portion where the medium flows smoothly, and the medium is brought into contact with the fins 53A and 55A in a wider range. On the other hand, short fins 54A and 56A are arranged at a site where the medium does not flow smoothly, and the medium flows smoothly. Thereby, heat exchange can be performed more efficiently.

<Example 3>
Next, Embodiment 3 of the present invention will be described with reference to the drawings. FIG. 11 shows a cross-sectional configuration of a heat exchange tube used in the heat exchanger of the third embodiment.

  The heat exchange tubes 50B used in the heat exchanger according to the third embodiment have different heights instead of the fins 53 to 56 (see FIG. 2) used in the heat exchanger 30 (see FIG. 2) according to the first embodiment. First to fourth fins 53B to 56B are employed. Other basic configurations are the same as those of the heat exchanger according to the first embodiment. About the part which is common in Example 1, while using a code | symbol, detailed description is abbreviate | omitted.

  Please refer to FIG. The second and fourth fins 54B and 56B arranged outside the first and second divided bodies 51 and 52 are arranged inside the first and second divided bodies 51 and 52, respectively. 3 higher than the fins 53B and 55B.

  Even in such a heat exchanger, the predetermined effect of the present invention can be obtained.

  In addition, the second and fourth fins 54B and 56B arranged outside the first and second divided bodies 51 and 52 are arranged inside the first and second divided bodies 51 and 52, respectively. It is higher than the first and third fins 53B and 55B. The flow paths formed inside the first and second divided bodies 51 and 52 are linear and simple in shape. For this reason, the medium (exhaust gas) can flow smoothly. On the other hand, the flow path formed outside the first and second divided bodies 51 and 52 is more complicated than the internal flow path. For this reason, it is difficult for the medium (air) to flow smoothly compared to the internal flow path. The high fins 54B and 56B are arranged at a site where the medium is difficult to flow smoothly, and the medium is easily flowed smoothly and a large area contributing to heat exchange is secured. Thereby, heat exchange can be performed more efficiently.

  In addition, although the heat exchanger of this invention was applied to the fuel cell system in embodiment, it is applicable also to another use. Furthermore, it can be used not only for heat exchange between gas and gas but also for heat exchange between gas and liquid. That is, the present invention is not limited to the examples as long as the effects and effects are exhibited.

  The heat exchange tube of the present invention is suitable for a heat exchanger used in a fuel cell system.

30, 30A ... heat exchanger 32 ... downstream end plate (end plate)
34 ... Upstream end plate (end plate)
40 ... Core case 50, 50A, 50B ... Heat exchange tube 51 ... First divided body 51a ... First divided body bottom (bottom of the first divided body)
51b ... 1st division body side wall part (side wall part of 1st division body)
52 ... 2nd division body 52a ... 2nd division body bottom part (bottom part of 2nd division body)
52b ... 2nd division side wall part (side wall part of 2nd division body)
53, 53A, 53B ... first fin (fin)
54, 54A, 54B ... second fin (fin)
55, 55A, 55B ... Third fin (another fin)
56, 56A, 56B ... Fourth fin (another fin)
DESCRIPTION OF SYMBOLS 81 ... 1st temporary fix | stop body 82 ... 2nd temporary fix | fixed body 83 ... Side wall part joined body 84 ... Heat exchange tube joined body

Claims (6)

In the method of manufacturing a heat exchanger,
Raising both ends of a substantially rectangular plate to obtain a first divided body and a second divided body;
Temporarily fixing fins to both surfaces of the bottom of the first divided body to obtain a first temporary fixing body;
Temporarily fixing fins different from the fins on both surfaces of the bottom of the second divided body to obtain a second temporary fixing body;
The first temporary body is laser welded to the side wall portions raised from both ends of the bottom portion of the first divided body and the side wall portions raised from both ends of the bottom portion of the second divided body, respectively. Joining the stopper and the second temporary stopper to obtain a side wall joined body;
And heat welding the fin to the first divided body by laser welding, and finally welding the other fin to the second divided body by laser welding to obtain a heat exchange tube. Exchanger manufacturing method. In the method of manufacturing a heat exchanger,
Raising both ends of a substantially rectangular plate to obtain a first divided body and a second divided body;
Temporarily fixing fins to both surfaces of the bottom of the first divided body to obtain a first temporary fixing body;
Temporarily fixing fins different from the fins on both surfaces of the bottom of the second divided body to obtain a second temporary fixing body;
The fins temporarily fixed to the first divided body are each welded to the first divided body by laser welding one by one, and the other fins temporarily fixed to the second divided body are respectively A step of performing main welding to the second divided body by laser welding one by one;
Side walls raised from both ends of the bottom portion of the first divided body where the fins were main-welded and raised from both ends of the bottom portion of the second divided body where the other fins were main-welded And a step of laser welding the side wall portion.   The method for producing a heat exchanger according to claim 1 or 2, further comprising a step of laser welding both ends of the heat exchange tube to a pair of end plates to obtain a heat exchange tube assembly. In the step of obtaining the first temporary fixing body, the fin is temporarily fixed to the first divided body by laser welding,
4. The method according to claim 1, wherein, in the step of obtaining the second temporary fixing body, the another fin is temporarily fixed to the second divided body by laser welding. 5. Manufacturing method of heat exchanger. A cylindrical core case, a pair of end plates that close both ends of the core case, and a heat exchange tube that is supported at both ends by these end plates and into which the first heat medium flows, the first heat In the heat exchanger that performs heat exchange between the medium and the second heat medium that flows outside the heat exchange tube,
The heat exchange tube is
The first divided body and the second divided body both having a substantially U-shape when viewed from the flow direction of the first heat medium,
The first divided body and the second divided body are arranged facing each other, and are formed into a cylindrical shape by laser welding the side wall portions,
A first fin is laser welded to the surface facing the inside of the bottom of the first divided body,
A second fin is laser welded to a surface facing the outside in the bottom of the first divided body,
A third fin is laser welded to the surface facing the inside of the bottom of the second divided body,
A heat exchanger, wherein a fourth fin is laser welded to a surface of the bottom of the second divided body that faces the outside.   The heat exchanger according to claim 5, wherein the first fin and the third fin are separated from each other.

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