JP2756009B2 - Fin supply device in temporary assembly device of heat exchanger core - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a fin supply device in a temporary assembly device for a heat exchanger core.

[Conventional technology]

Conventionally, a vehicle is equipped with a heat exchanger composed of a radiator for cooling an engine, and a heat exchanger core of such a heat exchanger is disclosed in, for example, Japanese Patent Application Laid-Open No. 59-174238. The heat exchanger core is assembled by a temporary assembling apparatus.

The heat exchanger core temporary assembling device disclosed in this publication includes a tube alignment member having tube alignment grooves each having a tube alignment groove, and a tube alignment member disposed below the tube alignment member. And a compression plate disposed on both sides of the tube alignment member.

In such a heat exchanger core temporary assembling device, the number of tubes required for the heat exchanger core and the holding plate arranged outside the heat exchanger core are inserted into the tube alignment grooves of the tube alignment pieces, respectively. After placing the fins between these tubes and between the tube and the holding plate, lower the alignment plate, pull out the lower part of the tube alignment piece from the mounting groove of the alignment plate, and pull the holding plate from both sides to the center with a compression plate. By pressing and compressing to a predetermined size, the heat exchanger core is temporarily assembled.

However, in such a heat exchanger core temporary assembling device, the tubes and the holding plates are inserted into the tube alignment grooves of the tube alignment pieces, and the fins are arranged between the tubes and between the tubes and the holding plate. Since it is necessary to release the fixing of these tube alignment pieces and compress the holding plate by the compression plate, it takes time and effort to temporarily assemble the heat exchanger core, and the structure of the temporary assembling device becomes complicated,
This causes a problem that maintenance becomes difficult.

Then, in order to solve such a problem, the present applicant previously filed an application for a temporary assembly device of a heat exchanger core (filing date: November 27, 1999).

7 and 8 show a temporary assembling apparatus for a heat exchanger core, which was previously filed by the present applicant.
Shows a transfer device for transferring the component parts.

The transfer device 11 includes a base 13 on which components constituting a heat exchanger core slide, a one-sided cylindrical bar 15 disposed on one side of the base 13, and another base disposed on the other side of the base 13. And a side cylindrical bar 17.

The components include a reinforce 18 and a rod-shaped component 20 of a tube 19 disposed on both sides of the heat exchanger core, and fins 21 disposed between the tubes 19 and between the tube 19 and the reinforce 18.

Further, a spiral groove 23 in the right rotation direction is formed in the one cylindrical rod 15, and a spiral groove 25 in the left rotational direction is formed in the other cylindrical rod 17.

The transfer device 11 is provided with a material supply section 27 to which the component parts are supplied and a temporary assembly section 29 for temporarily assembling the heat exchanger core.

Pitch P of spiral concave grooves 23 and 25 in material supply section 27
_1, it is formed larger than the length plus the thickness t ₂ of the thickness t ₁ and the rod-shaped part 20 of the fin 41 (t ₁ + t _2), whereas, the temporary assembling unit 29
The pitch P ₂ of the spiral grooves 23, 25 in the
(T ₁ + t ₂ ) that is the sum of the thickness t ₁ of the rod 20 and the thickness t ₂ of the bar 20
Is formed.

Also, the interval L ₁ between the spiral convex portions 31 and 33 in the temporary assembly portion 29
There are formed in the fin length L ₀ when the heat exchanger core assembly.

In this embodiment, the material supply unit 27 of the transfer device 11 is used.
Is divided into a rod-shaped component supply section 35 and a fin supply section 37, and the fin supply section 37 is formed on the temporary assembly section 29 side of the material supply section 27.

Spiral groove 23 of cylindrical rod 15, 17 in fin supply part 37,
Width of 25 B ₁ is formed substantially in the thickness t ₂ of the rod-shaped part 20, the width B ₂ is the width of the helical grooves 23 and 25 in the material supply section 27 B
₁ broadly formed than the width B ₂ is rod-shaped part 20 can be rod-shaped part 20 is easily inserted is a width falling over.

Of material supply section 27, the pitch P ₁ of the spiral grooves 23 and 25 in the fin supply section 37, the thickness t ₁ and the rod-shaped part 2 of the fin 21
It is formed larger than the length (t ₁ + t ₂ ) obtained by adding the thickness t _{2 of} 0.

Further, the interval L ₂ between the spiral convex portions 31 and 33 of the fin supply portion 37
But the heat exchanger core fin length during assembly L ₀ is formed longer than a cylindrical rod 15, 17 temporarily assembling portion 29 from the fin supply section 37
Is gradually diverging toward the, thereby, distance L ₁ between the spiral protrusions 31 and 33 in the temporary assembling unit 29 is formed in the fin length L ₀ when the heat exchanger core assembly.

Furthermore, the width B of the spiral groove 23, 25 in the temporary assembly 29
₃ are wider than the thickness t ₂ of the rod-shaped part 20.

In addition, the one-sided cylindrical rod 15 and the other-sided cylindrical rod 17 are moved in a direction R by a rotary drive device 39 such as a motor to push the rod-shaped component 20 having both ends inserted into the spiral concave grooves 23 and 25 toward the base 13. Has been rotated.

In the temporary assembly device of the heat exchanger core configured as described above, first, in the rod-shaped component supply unit 15 of the transfer device 11, all the rod-shaped components 20 constituting the heat exchanger core are spirally wound at both ends. The rod-shaped part 20 is inserted into the grooves 23 and 25 and the spiral groove 2
Located between 3,25. Thereafter, by rotating the cylindrical rods 15 and 17, the rod-shaped component 20 is transferred to the fin supply unit 37, where the fin is supplied between the spiral convex portions 31 and 33 located between the rod-shaped components 20. 21 is arranged.

Next, the cylindrical rods 15 and 17 are rotated, and the helical concave grooves 23 and 25 formed in the cylindrical rods 15 and 17 cause the rod-shaped component 20 to move the fins 2.
While being transferred to the temporary assembling part 29 of the transfer device 11 together with 1, the distance between the rod-shaped parts 20 and the fin length L ₀ are almost regulated to the final shape at the time of assembling the heat exchanger core, and the heat exchanger core is temporarily assembled. You.

Then, as shown in FIG. 8, in a state width b ₁ of the fin 21 is greater than the width b ₂ of the rod-like component 20, which presses the upper surface of the temporarily assembled thermal exchanger core, the rod-shaped part By pushing both ends of the fin 20 upward, the bar-shaped component 20 is positioned at the center of the fin 21. Thereafter, the heat exchanger core is compressed to a predetermined size by the compressor, and in this state, the heat exchanger core is withdrawn upward.

Thus, in the heat exchanger core temporary assembling device configured as described above, the material supply unit 27 and the temporary assembly unit 29 are formed in the transfer device 11, and the spiral groove 23, 2 in the material supply unit 27 is provided.
The pitch P ₁ of 5 is formed to be larger than the length plus the thickness of the fins 21 and the rod-shaped parts _{20 (t 1 + t 2)} , almost the pitch P ₂ of the spiral grooves 23 and 25 in the temporary assembling unit 29 Fin 21 and rod-shaped part 20
(T ₁ + t ₂ ), and the interval L ₁ between the spiral convex portions 31 and 33 in the temporary assembly portion 29 is set to the fin length L ₀ when assembling the heat exchanger core. Since it was formed, the bar-shaped part supply section
At 35, the bar-shaped component 20 is disposed between the spiral grooves 23, 25, and the cylindrical bars 15, 17 are rotated to transfer the bar-shaped component 20 to the fin supply unit 37. The fins 21 are arranged between the spiral projections 31 and 33 of the cylindrical rods 15 and 17 located at the positions. Thereafter, by rotating the cylindrical rods 15 and 17, the helical concave grooves 23 and 25 form the rod-shaped parts. while 20 is transferred to the temporarily assembled unit 29 of the transfer device 11 with the fins 21, spacing and fins length L ₀ between the rod-like component 20, it is regulated to the final shape during approximately the heat exchanger core assembly, the heat exchanger core It is easier to temporarily assemble than before,
The structure of the temporary assembling device of the heat exchanger core can be greatly simplified as compared with the related art.

Further, the material supply unit 27 of the transfer device 11 is
And the fin supply section 37, and the fin supply section 37 is formed on the temporary assembly section 29 side of the material supply section 27, and the width of the spiral concave grooves 23, 25 of the cylindrical rods 15, 17 in the fin supply section 37. since the B ₁ was formed substantially in the thickness t ₂ of the rod-shaped part 20, the rod-shaped part 20 which is arranged in an inclined state with the rod-like component supply section 35, filed in normal state in the fin supply section 37, the rod-shaped parts 20 Can be reliably prevented from being assembled in an inclined state.

Further, the one-sided cylindrical rod 15 and the other-sided cylindrical rod 17 were rotated in the direction R in which the rod-shaped part 20 having both ends inserted in the spiral concave grooves 23 and 25 was pushed toward the base 13 side. And the fins 21 are prevented from rising from the base 13 and are rod-shaped parts.
The fins 20 and the fins 21 can be reliably transferred to the temporary assembling part 29 by the cylindrical rods 15 and 17.

Further, the pitch P ₁ of the spiral grooves 23 and 25 in the fin supply section 37, larger than the thickness t ₁ and the thickness t ₂ the sum length of the rod-shaped part 20 of the fin 21 (t ₁ + t ₂₎ since the formed, the fin supply section 57, the spacing between the rod-shaped part 20 is formed larger than the thickness t ₁ of the fins 21, spiral protrusions 31 and 33
The fin 21 can be easily inserted therebetween.

Further, an interval L between the spiral convex portions 31 and 33 of the fin supply portion 37 is provided.
₂ is formed to be longer than the fin length L ₀ at the time of assembling the heat exchanger core, and the diameter of the cylindrical rods 15 and 17 is gradually increased from the fin supply section 37 toward the temporary assembly section 29. Convex part 23,2
The fins 21 can be easily inserted between the fins 5 and the fin length L ₀ gradually increases when the heat exchanger core is assembled.
It can be compressed to L _0.

Further, the width B ₃ of the spiral groove 23, 25 in the temporary assembly part 29,
Since wider than the thickness t ₂ of the rod-shaped part 20, for example,
When the heat exchanger core temporarily assembled in the temporary assembling section 29 is taken out in a compressed state, both ends of the rod-shaped component 20 can be easily taken out from the spiral grooves 23, 25.

[Problems to be solved by the invention]

However, the temporary assembly device of heat exchanger core, for example, to compress the fins 21 in the temporary assembly portion 29, the fin length L ₀ is than the distance L ₂ between the helical protrusion 31 and 33 of the fin feeder 37 Is also formed long, and in the fin supply unit 37, when the fins 21 are simply dropped and supplied between the rod-shaped parts 20 located between the cylindrical rods 15 and 17, which are transfer members,
As shown in FIG. 9, there is a possibility that both ends or one end of the fin 21 may be supplied in a state where the fin 21 rides on the cylindrical rods 15 and 17.

As a result, the fins 21 may be deformed in the process of being transferred to the temporary assembling section 29, and the heat exchanger core may be temporarily assembled in an incomplete state.

The present invention has been made in order to solve the above-mentioned problems, and even when the fin length is long, a fin having a heat exchanger core that can reliably supply fins between moving members located between rod-shaped parts is provided. It is an object to provide a fin supply device in a temporary assembling device.

[Means for solving the problem]

In the fin supply device in the heat exchanger core temporary assembling device of the present invention, a rod-shaped component such as a tube constituting the heat exchanger core and a base on which the fin slides, and the rod-shaped component disposed on both sides of the base and In a transfer device including a transfer member that transfers fins, a bar-shaped component supply unit in which the bar-shaped component is disposed between the transfer members, and the fin is disposed between the transfer members positioned between the bar-shaped components. The fin supply section and the temporary assembly section for temporarily assembling the heat exchanger core are sequentially formed, and the fins are individually arranged by disposing a plurality of partition members at predetermined intervals above the fin supply section. A partition case is provided in which a plurality of fin storage portions are formed in the height direction of the fins. Further, below the partition case, the fins are supplied to the partition case when the fins are supplied to the partition case. Down is one that at the time of supply to the inter placed on the rod-shaped part of the fin formed by arranging the mounting member that allowed to drop between the rod-shaped part from both end portions of the fin.

(Operation)

In the fin supply device in the temporary assembling device of the heat exchanger core of the present invention, the partition case in which the fins are stored in the fin storage portion is disposed above the fin supply portion, and is disposed below the partition case. When the fin is placed between the rod-shaped parts by the placing member on which the fin is placed, after the both ends of the fin are dropped between the transfer members located between the rod-shaped parts, the center part of the fin is placed between the rod-shaped parts. Be dropped.

〔Example〕

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

FIG. 1 and FIG. 2 show an embodiment of a fin supply device in a temporary assembling device for a heat exchanger core of the present invention.
In the figure, reference numeral 45 indicates a transfer device of the heat exchanger core temporary assembling device, which was previously filed by the present applicant.

The transfer device 45 includes a base 47 on which components constituting the heat exchanger core slide, and transfer members 49 and 51 disposed on both sides of the base 47.

The transfer member 49 is a one-sided cylindrical bar 53 disposed on one side of the base 47, and the transfer member 51 is a second-sided cylindrical bar 55 disposed on the other side of the base 47.

The components are composed of rod-shaped components 57 such as a reinforcement and a tube arranged on both sides of the heat exchanger core, and fins 59 arranged between the tubes and between the tube and the reinforcement.

Further, a spiral concave groove 61 in the right rotation direction is formed in the one-sided cylindrical bar 53, and a spiral concave groove 63 in the left-handed rotational direction is formed in the other cylindrical rod 55.

The transfer device 45 includes a bar-shaped component supply unit (not shown) in which a bar-shaped component 57 is disposed between the transfer members 49 and 51, and a fin supply in which a fin 59 is disposed between the transfer members 49 and 51 positioned between the bar-shaped components 57. The part 65 and a temporary assembly part (not shown) for temporarily assembling the heat exchanger core are sequentially formed.

A partition case 67 is disposed above the fin supply unit 65. The partition case 67 is configured by forming four fin storage portions 69 in which the fins 59 are individually stored in the height direction of the fins 59. This partition case 67 merely partitions the fins 59, and as shown in FIG.
The bottom surface of the partition case 67 is open downward. The width B ₄ of the fin receiving portion 69 is substantially the same as the height H ₁ of the fin 59.

The fin housing portion 69 is formed by arranging five partition members 71 at predetermined intervals, and the interval between the partition members 71 is substantially equal to the interval between the rod-shaped parts 57 transferred by the transfer device 45. It is formed the same.

Further, these partition members 71 extend on both left and right sides of the fin supply unit 65, and a bottom plate 73 is fixed to their ends. The left bottom plate 73 extends leftward and serves as a fin placement plate 74 on which the fins 59 are placed to accommodate the fins 59 in the fin storage section 69.

Further, below the partition case 67 located between the bottom plates 73, the fins 59 are placed when the fins 59 are supplied to the partition case 67, and when the fins 59 are supplied between the bar-shaped parts 57, the fins 59 are provided from both ends. A mounting member that can be dropped between rod-shaped parts 57
75 are located.

The placing member 75 is divided into three placing members 77, 79, 79 in the longitudinal direction of the fin 59 accommodated in the partition case 67.
As shown in FIG. 1, these divided placing members 77, 79, 81
Extraction devices 83 for extracting 9,81 are arranged respectively.

These drawing devices 83 are composed of cylinders 84 fixed to the heat exchanger core temporary assembling device, and piston rods 85 of these cylinders 84, and the piston rods 85 are divided into separate mounting members 77, 79, 81. Each is fixed. After the split placement members 77 and 81 at both ends are pulled out from below the partition case 67 and removed by these pulling devices 83, the split placement member 79 at the center is pulled out and removed from below the partition case 67. Is done.

Further, the partition case 67 compresses the fin length to, for example, the same as the fin length when assembling the heat exchanger core, and
Fin length adjustment member 87 positioned so as to be between 49 and 51
Are respectively arranged, and these fin length adjusting members
On the 87, four fin compression legs 88 for compressing the fins 59 in the longitudinal direction are formed. Two fin length adjusting members 87
Is driven by the driving device 89 from the longitudinal direction of the fin 59.
Driven towards the center of 59.

The fin compression leg 88 on the right side in FIG. 1 is always inserted between the fin housing portions 69, serves as a stopper when the fin 59 enters, and is movable only in the left-right direction. Also,
The left fin compression leg 88 is disposed above the fin storage portion 69, and when the fin 59 is stored in the fin storage portion 69, the fin compression leg 88 is lowered and inserted into the fin storage portion 69. In this state, the fin 59 is moved to the right to compress the fin 59. These fin compression legs 88 position the fins 59 so as to enter between the transfer members 49 and 51.

Above the partition case 67, an extruding member 91 that pushes out from both ends of the fin 59 toward the bar-shaped component 57 is disposed corresponding to the placing member 75. The push-out member 91 is constituted by split push-out members 92, 93, 94 divided into three in the longitudinal direction of the fin 59 accommodated in the partition case 67, and these split push-out members 92, 93, 94 The heat exchanger core is moved up and down by a driving device (not shown) fixed to the temporary assembling device. These split push members 92, 93, 94 are moved corresponding to the mounting member 75, and after the split push members 92, 94 on both sides are moved down, the central split push member 93 is moved down. You.

The divided extruded members 92, 93 and 94 are formed with four extruded portions 95 inserted between the partition members 71, and the fins 59 accommodated in the partition case 67 are downwardly moved by these extruded portions 95. Extruded.

In the fin supply device in the temporary assembling device of the heat exchanger core configured as described above, when the fins 59 are supplied between the rod-shaped parts 57, as shown in FIG. The split placement members 77, 79, 81 are arranged, and the left fin length adjustment member 87 is arranged above the partition case 67.

Then, the fins 59 placed on the fin placement plate 74 are slid to the right and inserted into the fin storage section 69 of the partition case 67,
The right end of the fin 59 is moved until it contacts the fin compression leg 88 of the right fin length adjusting member 87, and the fin 59 is stored in the fin storage section 69 of the partition case 67.

Next, the fin compression leg 88 of the left fin length adjusting member 87 disposed above the partition case 67 is lowered and inserted into the left end of the fin housing 69, and the fin length adjusting members 87 on both sides are lowered.
Is moved to the fin 59 side, and the fin
The fin 59 housed in 69 is compressed to a length substantially equal to the distance between the transfer members 49,51.

Then, the split placement members 77, 8 at both ends on which the fins 59 are placed.
1 is removed from below the partition case 67, and
Both ends of 9 are rod-shaped parts 57 by split extrusion members 92 and 94 at both ends.
As shown in FIGS. 4 and 5, both ends of the fins 59 mounted on the split mounting members 77, 81 at both ends are transferred between the rod members 57, 51, as shown in FIGS. Dropped in between.

Next, the central split mounting member 79 is removed from below the partition case 67, and at the same time, the central portion of the fin 59 is pushed out between the rod-shaped parts 57 by the central split extruding member 93, and the central split mounting member 79 is removed. The central part of the fin 59 placed on the member 79 is dropped between the bar-shaped parts 57.

Then, while the split pushing members 92, 93, 94 are raised, the split placing members 77, 79, 81 are inserted below the partition case 67, and the left and right fin length adjusting members 87 are respectively moved left and right, and The fin compression leg 88 of the fin length adjusting member 87 is raised.

Thus, in the fin supply device in the heat exchanger core temporary assembling device configured as described above, the base 47 on which the rod-shaped components 57 and the fins 59 slide, and the transfer members 49 disposed on both sides of the base 47 are provided. , 51, and a bar-shaped component supply section, a fin supply section 65, and a temporary assembly section are sequentially formed, and when the fins 59 are supplied between the bar-shaped parts 57,
Above the fin supply section 65, there is arranged a partition case 67 formed by forming four fin storage sections 65 in which the fins 59 are individually stored in the height direction of the fins 59, and further below the partition case 67. Since the placing member 75 composed of the divided placing members 77, 79, 81 divided into three in the longitudinal direction of the fin 59 is disposed, the fin housing portion 69 is provided when the fin 59 is supplied to the partition case 67. A partition case 67 in which fins 59 are stored is disposed above the fin supply section 65, and the split placement members 77 and 81 at both ends are removed from below the partition case 67, and the fins 59 are removed.
Are dropped between the transfer members 49 and 51 located between the rod-shaped parts 57, and the divided mounting member 79 at the center is moved to the partition case 67.
And the center of the fin 59 is dropped between the rod-shaped parts 57, and even if the fin length is long,
Can be reliably supplied between the transfer members 49 and 51 located between the rod-shaped parts 57.

Further, in the fin supply device in the heat exchanger core temporary assembling device configured as described above, the fin 59 stored in the fin storage portion 69 of the partition case 67 is replaced with the fin length adjusting member 87 having the fin compression leg 88. By adjusting the fin length, the fin 59 stored in the fin storage portion 69 of the partition case 67 by the fin length adjusting member 87 becomes, for example, approximately the same length as the length at the time of the temporary assembly of the heat exchanger core. The fins 59 can be reliably supplied between the transfer members 49 and 51 located between the rod-shaped parts 57 even when the fin length is adjusted.

Further, in the fin supply device in the temporary assembling device of the heat exchanger core configured as described above, above the partition case 67, from the both ends of the fin 59 to the rod-like component 57 side corresponding to the placing member 75. Since the extruding member 91 is arranged to be pushed out, the fins 59 stored in the fin housing portion 69 of the partition case 67 are pushed out from both ends by the extruding members 91 toward the rod-shaped component 57 side, and the divided mounting members 77, 79, 81 Even if the fins 59 are removed from below the partitioning case 67 and do not fall due to the weight of the fins 59, the fins 59 can be transferred between the rod-shaped parts 57.
It can be reliably supplied in between.

In the above embodiment, the placing member 75 is divided into the placing members 77 and 7.
Although the example constituted by 9, 81 has been described, the present invention is not limited to the above embodiment, for example, as shown in FIG. 6, even if the mounting member 97 is formed in a T shape, Almost the same effects as in the above embodiment can be obtained. And in this example, since only one extraction device 98 is required,
The structure can be simpler than the above embodiment.

Further, in the above embodiment, the example in which the fin compression legs 88 on both sides are moved toward the center toward the fins 59 has been described.
For example, even if the right fin compression leg is stopped and only the left fin compression leg is moved to the fin side, substantially the same effect as in the above embodiment can be obtained.

〔The invention's effect〕

In the fin supply device in the heat exchanger core temporary assembling device according to the present invention, the transfer device including the base on which the bar-shaped component and the fin slide, and the transfer member for transferring the bar-shaped component and the fin, includes a bar-shaped component supply unit. And a fin supply portion and a temporary assembly portion are sequentially formed, and a plurality of partition members are arranged at predetermined intervals above the fin supply portion to individually store the fins. A plurality of partitioning cases are arranged in the direction, and further below the partitioning case, the fins are placed when the fins are supplied to the partitioning case, and when the fins are supplied between the bar-like parts, the rod-like parts are placed from both ends of the fins. Since the placing member to be dropped in between is disposed, the partition case in which the fins are stored in the fin storage unit is disposed above the fin supply unit, and is disposed below the partition case. When the fin is placed between the rod-shaped parts by the placing member on which the fin is placed, after the both ends of the fin are dropped between the transfer members located between the rod-shaped parts, the center part of the fin is placed between the rod-shaped parts. The fins are dropped and the fins can be reliably supplied between the moving members located between the rod-shaped parts.

[Brief description of the drawings]

FIG. 1 is a perspective view showing one embodiment of a fin supply device in a temporary assembly device for a heat exchanger core according to the present invention. FIG. 2 is a cross-sectional view of the fin supply device in the heat exchanger core temporary assembling device of the present invention. FIG. 3 is a plan view showing the partition case of FIG. 1 and its vicinity. FIG. 4 is a cross-sectional view showing a state where the split mounting members on both sides of the mounting member are pulled out and removed. FIG. 5 is a cross-sectional view showing a state where both ends of the fin are dropped between the transfer members. FIG. 6 is a perspective view showing another example of the fin supply device in the heat exchanger core temporary assembling device of the present invention. FIG. 7 is a longitudinal sectional view showing a temporary assembling device of a heat exchanger core previously applied by the present applicant. FIG. 8 is a transverse sectional view taken along the line VIII-VIII in FIG. FIG. 9 is a cross-sectional view showing a state in which both ends of the fin ride on the transfer member. [Description of Signs of Main Parts] 45 Transfer Device 47 Base 49, 51 Transfer Member 57 Bar-Shaped Parts 59 Fin 65 Fin Supply Unit 67 Partition Case 69 Fin Storage Part 71: Partition member 75, 97: Mounting member.

Claims (1)

(57) [Claims] 1. A transfer comprising: a base on which a fin slides with a rod-shaped component such as a tube constituting a heat exchanger core; and a transfer member disposed on both sides of the base for transferring the rod-shaped component and the fin. In the apparatus, a bar-shaped component supply unit in which the bar-shaped component is disposed between the transfer members, a fin supply unit in which the fin is disposed between the transfer members positioned between the bar-shaped components, and the heat exchanger core. A fin storage section for individually storing the fins by forming a plurality of partition members at predetermined intervals above the fin supply section while forming temporary assembly sections to be temporarily assembled is formed in a height direction of the fins. A plurality of partition cases are arranged in
Below the partition case, a mounting member on which the fin is mounted when the fin is supplied to the partition case, and which is dropped between the bar-shaped components from both ends of the fin when the fin is supplied between the bar-shaped components. The fin supply device in the temporary assembling device of the heat exchanger core, wherein the fin supplying device is provided.