The present invention relates to a feeding apparatus for metal strips and a manufacturing apparatus for heat exchanger fins.
As depicted in
In addition, in the heat exchanger fin 100 depicted in
The heat exchanger fin 100 depicted in
The wide metal strip 120 first undergoes a burring process B that forms small holes to be used for the collar-equipped through-holes 104 through punch machining (burring) and the wide metal strip 120 in which the small holes have been formed is then subjected to an ironing process A that draws the peripheries of the punched out small holes to increase the diameters of the through-holes 106 while raising the heights of the collars 108 and a reflare process F that forms brim portions by bending the front ends of the collars 108. A louver machining process L that forms the louvers 112 is also carried out.
In this way, a plurality of collar-equipped through-hole rows, each of which is composed of a plurality of the louvers 112 and the collar-equipped through-holes 104 formed in the length direction of the wide metal strip 120, are formed in the width direction of the wide metal strip 120.
Next, after a punching process N in which the corner cut portions 110 formed in the side surfaces of the wide metal strip 120 and the punched-out portions 114 located between the collar-equipped through-hole rows are punched out, the wide metal strip 120 is cut by a cutter process S into separate collar-equipped through-hole rows to produce narrow metal strips 123. Next, the narrow metal strips 123 are cut into short strips by a cutting out process C to produce heat exchanger fins 100 like that depicted in
The various processes that produce the heat exchanger fin 100 depicted in
In the manufacturing apparatus depicted in
In this way, the wide metal strip 120 in which the collar-equipped through-holes 104, the louvers 112, the corner cut portions 110, and the punched-out portions 114 have been formed is supplied to a cutter 210 and cut in the length direction to produce the narrow metal strips 123 before such narrow metal strips 123 are cut into short strips. The heat exchanger fins 100 depicted in
The heat exchanger fins 100 depicted in
The wide metal strip 120 is supplied to the lower mold 208a from the direction of the arrow X. Formation stages for forming the collar-equipped through-holes 104, the louvers 112, the corner cut portions 110, and the punched-out portions 114 in the wide metal strip 120 are successively disposed in a region 209 on the supply entrance side for the wide metal strip 120. The cutter 210 that cuts the wide metal strip 120 in the length direction to produce the narrow metal strips 123 is provided on the exit side of the lower mold 208a.
A feeding apparatus 212 is provided on the exit side of the cutter 210 of the lower mold 208a depicted in
However, in recent years, due to demands for miniaturization of heat exchangers, there has been an increase in the number of corner cut portions 110 formed in the heat exchanger fin 100 depicted in
There is also demand to operate the press apparatus 200 at high speed and increase the production of the heat exchanger fins 100.
On the other hand, if the press apparatus 200 is operated at high-speed (high speed rotation) to increase production of the heat exchanger fins 100 and the wide metal strip 120 is fed into the cutter 210 and the narrow metal strips 123 are pulled out from the cutter 210 by a feeding apparatus 212 provided on the exit side of the cutter, it has been established that there is a tendency for tearing, kinking, stretching, and the like to occur at the parts of the narrow metal strips 123 where the corner cut portions 110 are formed. This is believed to be due to an excessive load being applied if the force that also feeds the wide metal strip 120 into the cutter 210 is applied to the narrow metal strips 123.
Although it is possible to prevent kinking and the like of the narrow metal strips 123 by reducing the speed at which the narrow metal strips 123 are pulled out from the cutter 210 (i.e., by reducing the operating speed of the press apparatus 200), this lowers the rate at which the heat exchanger fins 100 can be produced.
Also, even when manufacturing heat exchanger fins in which the corner cut portions 110 are not formed as in
For this reason, the present invention aims to provide a feeding apparatus for metal strips and a manufacturing apparatus for heat exchanger fins that (i) solve the problem of an existing feeding apparatus for metal strips and manufacturing apparatus for heat exchanger fins in that kinking and the like of the narrow metal strips tend to occur when a wide metal strip in which a plurality of through-holes are formed in a length direction and a width direction with predetermined gaps is fed into a cutter and narrow metal strips, which have the through-holes formed in only the length direction and are produced by cutting the wide metal strip in the length direction between the through-holes, are pulled out from the cutter, and (ii) are capable of preventing kinking and the like of the narrow metal strips when the wide metal strip is fed into the cutter and also when the narrow metal strips are pulled out from the cutter.
As a result of investigating the problem described above, the present inventors discovered that by providing, at an entrance side of the cutter, a feeding-in apparatus that feeds the wide metal strip in which the through-holes are formed into the cutter, providing, at the exit side of the cutter, a pulling out apparatus that pulls out the individual narrow metal strips cut out by the cutter from the cutter, and operating the feeding-in apparatus and the pulling-out apparatus in concert, it is possible to prevent kinking and the like of the narrow metal strips when pulling the narrow metal strips out from the cutter.
That is, as a means of solving the problem described above, one aspect of the present invention is a feeding apparatus for metal strips that feeds a wide metal strip, in which a plurality of through-holes are formed with predetermined gaps in a length direction and a width direction, into a cutter and pulls narrow metal strips, which are formed by cutting the wide metal strip between the through-holes in the length direction so that through-holes are formed along only the length direction of the narrow metal strips, out of the cutter, the feeding apparatus including: a feeding-in apparatus that is provided on an entrance side of the cutter and feeds the wide metal strip into the cutter; and a pulling-out apparatus that is provided on an exit side of the cutter and pulls out the narrow metal strips, which have been cut out by the cutter, from the cutter, wherein a linking member that drives the feeding-in apparatus and the pulling-out apparatus in concert so that the wide metal strip is fed into the cutter together with the narrow metal strips being pulled out from the cutter is provided.
As another means of solving the problem described above, another aspect of the present invention is a manufacturing apparatus for heat exchanger fins including the feeding apparatus for metal strips described above.
As means of solving the problem described above, the present inventors have also proposed the following preferred aspects.
The feeding-in apparatus may include: a first reciprocating body provided so as to be capable of moving reciprocally with respect to the cutter; and first pins provided on the first reciprocating body and capable of moving up and down so that front end portions thereof are inserted into and withdrawn from through-holes of the wide metal strip, the front end portions being inserted into the through-holes of the wide metal strip when the wide metal strip is fed into the cutter, the pulling-out apparatus may include: a second reciprocating body provided so as to be capable of moving reciprocally with respect to the cutter; and second pins provided on the second reciprocating body and capable of moving up and down so that front end portions thereof are capable of being inserted into and withdrawn from through-holes of the narrow metal strips, the front end portions being inserted into the through-holes of the narrow metal strips when the narrow metal strips are pulled out of the cutter, and the feeding apparatus may further include: a driving apparatus that drives the first reciprocating body and the second reciprocating body in a predetermined direction; and the linking member that causes the first reciprocating body and the second reciprocating body to move in concert so that the wide metal strip is fed into the cutter together with the narrow metal strips being pulled out from the cutter.
By providing, as the linking member, a coupling member that couples the first reciprocating body and the second reciprocating body and an adjusting unit that adjusts the length of the coupling member, it is possible to adjust the gap between the first reciprocating body and the second reciprocating body and prevent the force applied to the narrow metal strips from becoming excessive.
Also, by providing the feeding-in apparatus with a first stopper operable when the first pins move in an opposite direction to a feeding direction of the wide metal strip, to become inserted into a through-hole of the wide metal strip to prevent movement in the opposite direction to the feeding direction of the wide metal strip and also operable when the first pins move in the feeding direction of the wide metal strip, to become withdrawn from the through-hole of the wide metal strip to enable the wide metal strip to move in the feeding direction, it is possible to reliably feed the wide metal strip into the cutter.
In addition, by providing the pulling-out apparatus with a second stopper operable when the second pins move in an opposite direction to a feeding direction of the narrow metal strips, to become inserted into through-holes of the narrow metal strip so as to prevent movement in the opposite direction to the feeding direction of the narrow metal strips and also operable, when the second pins move in the feeding direction of the narrow metal strip, to become withdrawn from the through-holes of the narrow metal strips so as to enable the narrow metal strips to move in the feeding direction, it is possible to reliably pull the narrow metal strips out of the cutter.
By providing the cutter, the feeding-in apparatus, the pulling-out apparatus, and the linking member inside a mold that forms the through-holes in the wide metal strip, it is possible to install a mold incorporating the feeding apparatus for metal strips in a press apparatus.
Here, by using a wide metal strip that has punched-out portions formed between the through-holes as the wide metal strip and forming narrow metal strips in which corner cut portions, where side edges are cut away, are formed, it is possible to effectively prevent tearing, kinking, or stretching of the corner cut portions when the narrow metal strips are pulled out from the cutter.
In addition, by chamfering corner portions of the punched-out portions and corner cut portions into arc shapes, it is possible to prevent tearing, kinking, or stretching of the corner cut portions when the narrow metal strips are pulled out from the cutter significantly more effectively.
According to the feeding apparatus for metal strips proposed by the present inventors, a wide metal strip is fed into the cutter by a feeding-in apparatus provided on the entrance side of the cutter. Even if a feeding-in force that feeds the wide metal strip into the cutter is applied to the wide metal strip that has not been cut into narrow metal strips by the cutter, the wide metal strip has sufficient durability. This means that it is possible to feed the wide metal strip into the cutter without kinking or the like.
In addition, a pulling-out apparatus that pulls the narrow metal strips, which are obtained by cutting the wide metal strip using the cutter, out of the cutter is provided on the exit side of the cutter. For this pulling-out apparatus, it is sufficient to apply a pulling force that pulls the narrow metal strips out from the cutter to the narrow metal strips, and it is not necessary to apply a force to feed the wide metal strip into the cutter. This means that it is possible to prevent tearing, kinking, or stretching that are caused by an excessive pulling force being applied to the narrow metal strips.
In addition, the feeding-in apparatus and pulling-out apparatus are driven in concert by a linking member so that the feeding-in operation that feeds the wide metal strip into the cutter and the pulling-out operation that pulls the narrow metal strips out from the cutter are linked. This means that it is possible to smoothly feed the wide metal strip into the cutter and to smoothly pull the narrow metal strips out from the cutter.
Therefore, according to the feeding apparatus for metal strips proposed by the present inventors, it is possible to prevent kinking and the like of the narrow metal strips even if the narrow metal strips are pulled out from the cutter at high speed. As a result, according to a press apparatus equipped with the feeding apparatus for metal strips proposed by the present inventors, it is possible for the press apparatus to operate at high speed.
Also, according to a manufacturing apparatus for heat exchanger fins equipped with the feeding apparatus for metal strips proposed by the present inventors, it is possible to increase the production of heat exchanger fins.
A feeding apparatus for metal strips proposed by the present inventors is incorporated into a mold of the press apparatus 200 (see
The wide metal strip 120 depicted in
A feeding-in apparatus 16 that feeds the wide metal strip 120 in which the collar-equipped through-holes 104, the louvers 112, the corner cut portions 110, and the punched-out portions 114 have been formed into the cutter 14 is provided on an entrance side of the cutter 14. In addition, a pulling-out apparatus 18 that pulls the narrow metal strips 123, which have been produced by the cutter 14 cutting the wide metal strip 120, out from the cutter 14 is provided on the exit side of the cutter 14.
In the feeding-in apparatus 16, a first reference plate 20 is provided on the entrance side of the cutter 14. The first reference plate 20 spans above fixed members 21a, 21b fixed at a predetermined gap on a lower mold base 11, and has a plurality of elongated holes 20a, 20a, . . . formed in the feeding direction of the wide metal strip 120.
Below the first reference plate 20, a first reciprocating body 22 is provided so as to be capable of moving reciprocally between the fixed members 21a, 21b fixed along the cutter 14. The first reciprocating body 22 moves along shafts 24, 24 that are perpendicular to the fixed members 21a, 21b.
In addition, in the pulling-out apparatus 18, a second reference plate 26 is provided on the exit side of the cutter 14. The second reference plate 26 spans above fixed members 27a, 27b fixed at a predetermined gap on the lower mold base 11 and has a plurality of elongated holes 26a, 26a, . . . formed in the feeding direction of the narrow metal strips 123.
Below the second reference plate 26, a second reciprocating body 28 is provided so as to be capable of moving reciprocally between the fixed members 27a, 27b fixed alongside the cutter 14. The second reciprocating body 28 moves along shafts 30, 30 that are perpendicular to the fixed members 27a, 27b.
The first reciprocating body 22 and the second reciprocating body 28 are coupled by a coupling plate 32 as a coupling member and both move in the same direction.
The first reciprocating body 22 and the second reciprocating body 28 are driven by a driving apparatus depicted in
With this driving apparatus, when the crank 34 rotates and the eccentric pin 36a reaches the 36a′ position depicted in
As depicted in
As depicted in
On the adjustment portion 33, an L-shaped front end portion 35a of the first coupling portion 32a and an L-shaped front end portion 35b of the second coupling portion 32b are slidably combined using a screw 37. A front end of a screw portion 37a of the screw 37 is screwed to the L-shaped front end portion 35a of the first coupling portion 32a. A first elongated hole 39 that is wider than the screw portion 37a and narrower than a brim portion 37b of the screw 37 is formed in the L-shaped front end portion 35b of the second coupling portion 32b through which the screw portion 37a is inserted, and a second elongated hole 41 that is wider than the brim portion 37b is formed above the first elongated hole 39.
With the adjustment portion 33, by loosening the attachment of the L-shaped front end portions 35a, 35b by the screw 37, it is possible to enable the screw 37 to move along the first elongated hole 39. This means that the L-shaped front end portions 35a, 35b slide and adjust the length of the coupling plate 32, which makes it possible to adjust the gap between the first reciprocating body 22 and the second reciprocating body 28.
In this way, by adjusting the gap between the first reciprocating body 22 and the second reciprocating body 28, it is possible to prevent the force applied to the narrow metal strips 123 cut by the cutter 14 from becoming excessive.
Also, as should be clear from
Since the first reciprocating body 22 on which the first pins 54 are provided and the second reciprocating body 28 on which the second pins 56 are provided have substantially the same construction, the construction of the first reciprocating body 22 will be described with reference to
Note that in
Front end portions of the first pins 54 provided on the first reciprocating body 22 are energized by springs 58 as energizing members in the direction of the wide metal strip 120 that moves above the elongated holes 20a in the first reference plate 20. The front end surface of each first pin 54 is formed in an inclined surface that is inclined on the opposite side to the feeding direction of the wide metal strip 120.
For this reason, as depicted in
On the other hand, as depicted in
Accordingly, by moving reciprocally between the fixed members 21a, 21b, the first reciprocating body 22 is capable of feeding the wide metal strip 120 into the cutter 14.
At this time, even if the first pin 54 applies a feeding force that feeds the wide metal strip 120 depicted in
In addition, it is also possible to pull the narrow metal strips 123, which are cut out by the cutter 14, out of the cutter 14 using the second pins 56 of the second reciprocating body 28 that moves reciprocally in concert with the first reciprocating body 22. For this second reciprocating body 28, it is sufficient to apply a pulling force that pulls the narrow metal strips 123 out from the cutter 14 to the narrow metal strips 123, and it is not necessary to apply a force to feed the wide metal strip 120 into the cutter 14, which means that it is possible to transport the narrow metal strips 123 in which cutaway portions 122 have been formed without tearing, kinking, or stretching.
This means that with a manufacturing apparatus for heat exchanger fins where a mold incorporating the feeding-in apparatus 16 and the pulling-out apparatus 18 depicted in
In particular, by chamfering corner portions of the corner cut portions 110 and the punched-out portions 114 depicted in
However, with the feeding-in apparatus 16 depicted in
For this reason, it is preferable to provide a stopper that forcibly stops movement of the wide metal strip 120 when the first reciprocating body 22 moves in a direction away from the cutter 14 (in the direction of the arrow B).
An example of a stopper is depicted in
In the feeding-in apparatus 16 depicted in
Accordingly, it is possible to forcibly stop movement of the wide metal strip 120 in the opposite direction to the feeding direction due to the front ends of the first pins 54 moving in the direction away from the cutter 14 (in the direction of the arrow B) while rubbing the rear surface of the wide metal strip 120.
Also, as the stopper, it is possible to use the stopper depicted in
As depicted in
On the other hand, as depicted in
Note that in
The first pins 54 provided on the first reciprocating body 22 depicted in
For the above reason, the first pins 54 and the second pins 56 depicted in
With the first pins 54 depicted in
On the other hand, when the first reciprocating body 22 moves in the direction away from the cutter 14 (in the direction of the arrow B) as depicted in
According to the first pins 54 depicted in
To insert and withdraw the first pins 54 into and from the collar-equipped through-holes 104 of the wide metal strip 120 as depicted in
Although the feeding apparatus for the metal strip described above is incorporated inside the mold and installed in the press apparatus 200, such feeding apparatus may be installed in a cutter provided outside the press apparatus.
It should also be obvious that the feeding apparatus for the metal strip described above can be used as a feeding apparatus for metal strips in which a plurality of through-holes are formed.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2009/068985 | 11/6/2009 | WO | 00 | 4/25/2012 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2011/055448 | 5/12/2011 | WO | A |
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1-166823 | Jun 1989 | JP |
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Number | Date | Country | |
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20120216664 A1 | Aug 2012 | US |