JP3117041B2 - Temporary assembly device for heat exchanger core - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for temporarily assembling heat exchanger cores.

[0002]

2. Description of the Related Art In manufacturing a heat exchanger to be mounted on a vehicle, a temporary assembling apparatus according to the application of the present applicant is conventionally known as a temporary assembling apparatus for a heat exchanger core (Japanese Patent Application Laid-Open No. HEI 3-3-1). No. 166023).

FIG. 4 shows a temporary assembling device for such a heat exchanger core. The temporary assembling device 1 includes a base 3 on which components constituting the heat exchanger core slide, and two sides of the base 3. The heat exchanger core is composed of a pair of left and right worm guides 5 and 7, and the components constituting the heat exchanger core are rod-shaped components such as a reinforcement 9 and a tube 11 arranged on both sides of the heat exchanger core. And fins 13 arranged between the tubes 11 and between the reinforcement 9 and the tubes 11.

A spiral groove 15 of one worm guide 5 is formed in the clockwise direction, and a spiral groove 17 of the other worm guide 7 is formed in the counterclockwise direction.
In addition, the temporary assembling device 1 includes a reinforcement 9 and a tube 1.
Material supply unit 1 to which components such as fins 13 are supplied
9 and a temporary assembly part 21 for temporarily assembling the heat exchanger core.

Thus, the spiral concave in the material supply section 19
Pitch P of grooves 15, 17₁Is the thickness t of the fin 13₁When
The thickness t of the tube 11_Two(T)₁+ T_Two)
And the spiral shape of the temporary assembly 21
Pitch P of concave grooves 15, 17_TwoIs approximately the thickness t of the fin 13
₁And the thickness t of the tube 11_Two(T)₁+
t _Two) Is formed. On the other hand, in the temporary assembly part 21
Spacing L between spiral convex portions 23 and 25₁But heat exchanger core assembly
Fin length L at time₀Is formed.

In the temporary assembling apparatus 1, the material supply section 19 is further divided into a rod-shaped component supply section 27 and a fin supply section 29, and the fin supply section 29 is provided in the temporary assembly section 21 of the material supply section 19. Formed on the side.

The width B ₁ of the spiral grooves 15, 17 of the worm guides 5, 7 in the fin supply section 29 is formed to be slightly larger than the thickness t ₂ of the tube 11, and the rod-shaped component supply Width B of the spiral grooves 15, 17 in the portion 27
₂ is formed wider than the width B ₁ , and the width B ₂ is such that the reinforcement 9 and the tube 11 can be easily inserted and these members do not fall down.

Further, the pitch P ₁ of the spiral grooves 15 and 17 in the fin supply section 29 of the material supply section 19 is
The thickness t ₁ and the length plus the thickness t ₂ of the tube 11 of the fins 13 (t ₁ + t ₂₎ is formed larger than, after providing the tube 11 in a spiral groove 15 and 17, the tube The fins 13 are easily inserted between the fins 11.

The interval L ₂ between the spiral projections 23 and 25 in the fin supply unit 29 is formed to be longer than the fin length L ₀ when assembling the heat exchanger core, that is, the interval L ₁ . The warm guides 5 and 7 are moved from the fin supply section 29 to the temporary assembly section 2.
It is sequentially increased in diameter toward the 1, Thus, the interval L ₁ between the in spiral protrusions 23 and 25 to the temporarily assembled unit 21, are formed in the fin length L ₀ when the heat exchanger core assembly. The width of the helical groove 15, 17 is sequentially enlarged from B ₁ to B _3,
The pitch of the helical grooves 15 and 17 are also sequentially smaller from the pitch P ₁ to the pitch P _2. Furthermore, the width B ₃ of the spiral grooves 15, 17 in the temporary assembling part 21 is the same as the width of the tube 11.
Is formed to be wider than the thickness t ₂ .

The worm guides 5 and 7 are helically grooved by a rotary drive device 31 such as a motor.
7 is rotated in a direction R for pushing the tube 11 and the like inserted into the base 3.

In the temporary assembling apparatus 1 configured as described above, first, in the rod-shaped component supply section 27, the reinforcement 9 and the tube 11 forming the heat exchanger core are formed by spiral grooves with both ends. 15 and 17 are inserted and arranged. Thereafter, by rotating the worm guides 5 and 7, the reinforce 9 and the tube 11 are transferred to the fin supply unit 29, and the fin 13 is interposed between the tubes 11 and between the tube 11 and the reinforce 9 in the fin supply unit 29. Be placed.

Next, the worm guides 5 and 7 are rotated,
While the reinforce 9 and the tube 11 are transferred to the temporary assembling part 21 together with the fin 13 by the spiral concave grooves 15 and 17, the distance between the reinforce 9 and the tube 11 and the fin length L ₀ are substantially changed by the heat exchanger. The heat exchanger core 33 is temporarily assembled under the regulation of the final shape at the time of assembling the core.

Thereafter, although not shown, a seat plate is assembled to the temporarily assembled heat exchanger core 33, and the heat exchanger core 33 is compressed to a predetermined size by a compressor in a compression section.
As described above, conventionally, after temporarily assembling the heat exchanger core 33 with the temporary assembling apparatus 1 as described above, the heat exchanger core 33 is compressed by a compressor in the next step, and a seat plate is assembled for each heat exchanger core 33. I have.

Conventionally, in this type of temporary assembling apparatus for heat exchanger cores, as shown in FIGS. 5 and 6, the bases 3 on which the reinforces 9 and the tubes 11 slide are arranged in parallel on the same plane. is composed of a plurality of set plate 3a which is, then, to allow adjusting the distance L ₃ between the two worm guides 5 and 7 in accordance with the core size of the temporarily assembled heat exchanger core, the set plate 3a and the worm guide 5,7
Are supported by the link mechanism 35.

[0015]

And Thus [0008], when Such a spread by adjusting the interval L ₃ between the two worm guides 5 and 7 in accordance with the core size the link mechanism 35, the set plate 3a
The gap m between the worm guides 5 and 7 and the set plate 3a is sequentially opened. When the gap m is increased (for example, when the gap is 35 mm or more), the fins 13 hang down from the gap to temporarily assemble the heat exchanger core. In fact, the distance between the worm guides 5 and 7 cannot be increased beyond a predetermined width.

Therefore, conventionally, the heat exchanger core of the downflow type heat exchanger is temporarily assembled, and the heat exchanger core of the side flow type heat exchanger is also used as the temporary assembly. I couldn't do that.

That is, the heat exchanger cores of the downflow type heat exchanger and the sideflow type heat exchanger have significantly different lengths of tubes and fins. If the space between the two worm guides is widened according to the core size of the exchanger, the space between the set plates becomes too large and the fins hang down from there, making it impossible to temporarily assemble the heat exchanger core.

The present invention has been devised in view of the above circumstances, and the distance between both worm guides can be greatly increased without causing fin dripping according to the core size of the heat exchanger core to be temporarily assembled. It is an object of the present invention to provide a temporary assembling apparatus for a heat exchanger core that can be used for temporary assembling of a heat exchanger core of a downflow type heat exchanger and a side flow type heat exchanger.

[0019]

SUMMARY OF THE INVENTION In order to achieve the above object, the present invention provides a base in which a rod-like component such as a tube constituting a heat exchanger core or a fin slides, and is disposed on both sides of the base. In a temporary assembly device of a heat exchanger core equipped with a pair of worm guides for transferring rod-shaped parts and fins,
A worm mounting bracket is movably mounted on both sides of the base via a moving means in a direction orthogonal to the direction of transport of the rod-shaped component.The worm guides are mounted on both worm mounting brackets, and the base is connected to both worms. A strip-shaped fixed set plate placed along the worm guide in the middle of the mounting bracket, and a number of strip-shaped moving set plates are installed along the fixed set plate. It consists of a pair of variable bases attached in a fold-like shape on the top, and both variable bases engage with a set plate connecting chain with a sprocket mounted with a fixed set plate in between, and one end is fixed to each of the above worm mounting brackets And the other end was attached below the fixed set plate. Is characterized in that is are respectively connected to the anti-cylinder.

[0020]

According to the present invention, when the two worm mounting brackets are moved by the moving means in accordance with the core size of the heat exchanger core to be temporarily assembled to expand the distance between the two worm guides, the variable base is moved in conjunction with the movement. It spreads between the worm guides, and at the same time, the tension of the variable base is maintained while the piston rod of the anti-sag cylinder is extended, so that the distance between the worm guides is expanded without changing the distance between the moving set plates. It will be.

On the other hand, in order to narrow the distance between the two worm guides according to the core size, the worm mounting bracket may be moved in the opposite direction by the moving means. While the piston rod is retracted, the tension of the variable base is maintained, and the space between the two worm guides is reduced.

[0022]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a temporary assembly apparatus for a heat exchanger core according to the present invention. FIG.
Are denoted by the same reference numerals.

In FIG. 1, reference numeral 37 denotes a base on which the tubes 11 and fins 13 constituting the heat exchanger core slide, and a pair of worm guides 5 and 7 are provided on both sides thereof.
1 and the fins 13 are installed so as to be movable in a direction (arrows B and C in the figure) orthogonal to the transfer direction of the fins 13 (arrow A in the figure).

That is, in the figure, reference numerals 39 and 41 denote worm mounting brackets opposed to each other with the base 37 interposed therebetween, and both worm mounting brackets 39 and 41 are provided with four bracket moving guide rails ( Attached so as to be movable in the directions of arrows B and C along a “guide rail” 45). Then, as shown in FIG. 2, one left and right screw shaft 5 having one end connected to a moving means 51 composed of a servomotor is attached to shaft insertion members 47, 49 provided at the bottoms of both worm mounting brackets 39, 41.
When the left and right screw shafts 53 rotate in one direction by the driving of the moving means 51, the worm mounting bracket 39 moves in the direction of arrow B in conjunction with the rotation of the worms 53a and 53b. Mounting bracket 41
Moves in the direction of arrow C, and when the left and right screw shafts 53 rotate in the opposite direction, the worm mounting bracket 39 moves in the direction of arrow C, and at the same time, the worm mounting bracket 4 moves.
1 moves in the direction of arrow B.

On the other hand, as shown in FIG. 1, the base 37 in the present embodiment comprises two worm mounting brackets 39, 41.
And a pair of variable bases 57, 59 disposed on the same plane with the fixed set plate 55 interposed therebetween. ing.

Each of the variable bases 57 and 59 has a plurality of strip-shaped moving set plates 61 mounted along a fixed set plate 55 on two set plate connecting chains 63 in the shape of a cage. One end is fixed to each of the worm mounting brackets 39, 41.
Then, as shown in FIG.
The set plate connecting chain 63 meshes with a sprocket 65 mounted with the fixed set plate 55 interposed therebetween, and the other end of the chain 63 is connected to the cylinder 67 for preventing dripping mounted below the fixed set plate 55 as shown in FIG. , Respectively. The core drooping prevention cylinder 67 always pulls the variable bases 57 and 59 downward (in the directions of arrows D and E in the figure) to keep the variable bases 57 and 59 in a tensioned state. 39 and 41 are arrows B and C, respectively.
When the piston rod 69 moves in the
While maintaining the tension, the variable bases 57 and 59 are maintained in tension.

Each of the moving set plates 61 is
It is mounted on the set plate connecting chain 63 at an interval n at which no fin droop occurs. In addition, FIG.
3, reference numeral 71 denotes a support stay of the sprocket 65 mounted on the base 43, and in FIG. 3, reference numeral 73 denotes a support stay of a fixed set plate.
Mounted on top.

Since the present embodiment is constructed as described above, the reinforcement 9 and the tube 11 are connected to the base 3 by the worm guides 5 and 7, similarly to the conventional temporary assembling apparatus shown in FIG.
7 is transferred in the direction of arrow A, and the fins 13 are sequentially arranged between the tubes 11 and between the tubes 11 and the reinforcements 9 with the transfer, so that the heat exchanger core is temporarily assembled.

According to the core size of the heat exchanger core to be temporarily assembled, for example, in order to expand the space between the two worm guides 5, 7, the moving means 51 is driven to rotate the left and right screw shafts 53 in one direction. For example, when the worm mounting bracket 39 moves in the direction of arrow B, the worm mounting bracket 41 moves in the direction of arrow C, and the variable bases 57 and 59 are deployed between the worm guides 5 and 7, and in conjunction with this movement. While the piston rod 69 extends, the variable base 57,
While maintaining the tension state of 59, the moving set plate 61
The space between the worm guides 5 and 7 is expanded without changing the interval n between them.

On the other hand, in order to narrow the space between the worm guides 5 and 7 according to the core size of the heat exchanger core, the moving means 51
Is driven to rotate the left and right screw shafts 53 in opposite directions, the worm mounting bracket 39 moves in the direction of arrow C, and the worm mounting bracket 41 moves in the direction of arrow B at the same time. 6
As the variable base 9 is retracted, the tensioned state of the variable bases 57, 59 is maintained, and the space between the two worm guides 5, 7 is reduced without changing the distance n between the moving set plates 61.

As described above, according to the present embodiment, the distance between the two worm guides 5 and 7 can be greatly increased without changing the distance n between the moving set plates 61 as compared with the prior art. The fins 13 do not hang from between the moving set plates 61 by the adjustment between the moving set plates 61 and 7, and the heat exchanger cores for the down-flow type heat exchanger and the side-flow type heat exchanger according to the present embodiment are the same. It became possible to temporarily assemble with one temporary assembling device.

[0032]

As described above, according to the present invention, the distance between the two worm guides can be greatly increased without changing the distance between the moving set plates, so that there is no danger of fin dripping. Then, the heat exchanger cores for the down-flow type heat exchanger and the side-flow type heat exchanger can be temporarily assembled by the temporary assembling apparatus of the present invention.

[Brief description of the drawings]

FIG. 1 is an overall perspective view of a device for temporarily assembling a heat exchanger core according to an embodiment of the present invention.

FIG. 2 is a schematic side view of the temporary assembling apparatus shown in FIG.

FIG. 3 is an enlarged side view of a main part of a base.

FIG. 4 is a schematic plan view of a conventional apparatus for temporarily assembling a heat exchanger core.

FIG. 5 is a schematic configuration diagram of a base in a conventional temporary assembling apparatus.

FIG. 6 is a schematic explanatory view of a conventional temporary assembling apparatus showing a method of adjusting a base according to a core size.

[Explanation of symbols]

 5, 7 Worm guide 37 Base 39, 41 Worm mounting bracket 45 Guide rail 51 Moving means 53 Left and right screw shaft 55 Fixed set plate 57, 59 Variable base 61 Movement set plate 63 Set plate connecting chain 65 Sprocket 67 Drip prevention cylinder

────────────────────────────────────────────────── ─── Continuation of front page (56) References JP-A-60-207731 (JP, A) JP-A-2-75594 (JP, A) JP-A-5-24621 (JP, A) JP-A-5-205 43029 (JP, A) JP-A-3-120108 (JP, A) JP-A-4-107709 (JP, U) JP-A-5-9832 (JP, U) JP-A-2-35630 (JP, U) (58) Field surveyed (Int. Cl. ⁷ , DB name) B23P 19/00-21/00 307 B65G 33/00-33/38

Claims (1)

(57) [Claims] 1. A tube (1) constituting a heat exchanger core.
1) The base (37) on which the bar-shaped component or the fin (13) slides is disposed on both sides of the base (37).
In a temporary assembling apparatus of a heat exchanger core provided with a pair of worm guides (5, 7) for transferring rod-shaped parts and fins (13), worm mounting brackets (39, 39) are provided on both sides of the base (37). 41) is movably mounted in a direction orthogonal to the direction of transport of the rod-shaped component via a moving means (51), and the worm guides (5, 7) are mounted on both worm mounting brackets (39, 41), respectively. Connect the base (37) to both worm mounting brackets (3
9, 41), a strip-shaped fixed set plate (55) arranged along the worm guide (5, 7), and the fixed set plate (55). A plurality of strip-shaped moving set plates (61) are formed along with a pair of variable bases (57, 59) mounted on a set plate connecting chain (63) in the shape of a cage. 59), a set plate connecting chain (63) meshes with a sprocket (65) mounted with a fixed set plate (55) interposed therebetween, and one end is fixed to each of the worm mounting brackets (39, 41).
A temporary assembling device for a heat exchanger core, characterized in that the other end is connected to a drip prevention cylinder (67) mounted below the fixed set plate (55).