This application is based on Japanese Patent Application No. 2009-119123 filed on May 15, 2009, the disclosure of which is incorporated herein by reference.
The present invention relates to a method for a bending process and a processing machine thereof, which is preferably applied to, for example, a manufacturing process of a corrugated fin for a heat exchanger.
A bending process for a corrugated product is known in the art, for example, as disclosed in the following patent publications:
Patent Publication No. 1: JP Patent Publication No. 2008-087033;
Patent Publication No. 2: JP Patent Publication No. 2006-136896;
Patent Publication No. 3: JP Patent Publication No. 2003-115567;
Patent Publication No. 4: JP Patent Publication No. 2006-015388;
Patent Publication No. 5: JP Patent Publication No. H11-179438;
Patent Publication No. 6: JP Patent Publication No. H09-155460.
According to one of conventional machines for the bending process, for example, as shown in
According to another prior art method for forming multiple corrugated portions by one press work, for example, as disclosed in the Patent Publication No. 1 (JP 2008-087033), a corrugated portion formed in a strip metal plate is held by a temporal holding portion, and then further corrugated portions (two corrugated portions) are sequentially formed by one press work in the strip metal plate in a direction from the temporarily held corrugated portion toward a material feeding portion. As above, the multiple corrugated portions are sequentially formed one after another in one press work.
According to a further prior art, for example, as shown in
The corrugated shape of the material M is likely to restore to its original flat shape to some extent by its elasticity, when the material M is processed by the press work at the first press work point. According to the above method, the press work is further carried out to the corrugated portion at the second press work point, so that the corrugated shape of the material M is maintained.
In a case that a larger number of corrugated portions will be formed, it will be necessary to carry out the press work at a higher speed. A method for forming multiple corrugated portions is proposed in the art, according to which multiple corrugated portions are formed in one stroke with time differences between respective press works. For example, as shown in
A further method for forming multiple corrugated portions is known in the art, for example, as disclosed in the Patent Publication No. 3 (JP 2003-115567), according to which multiple first punches and multiple second punches are arranged in a comb-shaped condition so that the first and second punches are opposing to each other. According to the prior art, a corrugated fin having a rectangular cross section is manufacture.
According to the Patent Publication No. 4 (JP 2006-15388), each of two press punches is alternately moved up and down so as to continuously manufacture a concavo-convex fin having a rectangular cross section from a flat thin metal plate.
Furthermore, a method for alternately moving two press punches up and down is disclosed in the Patent Publication No. 6 (JP H09-155960).
According to the Patent Publication No. 5 (JP H11-179438), upper and lower press punches are alternately operated in a sequential manner having a time difference between alternate operations of the upper and lower press punches, so as to carry out press works to a strip metal plate.
According to the conventional method, for example, as disclosed in the Patent Publication No. 1, the multiple corrugated portions can be formed by one press work in order to increase a working efficiency. However, it may have a problem that the breaking of the material or a shape distortion (such as a bowing of a product as shown in
According to the other convention method, for example, as disclosed in the Patent Publication No. 2, it is possible to continuously form the multiple corrugated portions by the movement of the movable cam. The movable cam 3 has the pressing surface at its forward end, wherein the pressing surface is inclined by 45 degrees with respect to the moving direction of the movable cam 3. Each of the press punches 2 are moved down by the predetermined stroke “d”, when the movable cam 3 is operated in the forward direction. However, an aspect ratio of the stoke “d” with respect to a width “P” of the press punch 2 is generally smaller than 1. In other words, a direction of movement of the cam 3 is in parallel to the line in which the multiple press punches are arranged, that is, the width direction of the press punches. Therefore, even when the pressing surface of the movable cam 3 having the 45-degree inclined surface is moved by the width “P”, the stroke “d” of the press punch 2 is smaller than “P” (P>d). As a result, in case of the material having a large aspect ratio or a high Young's modulus, the shape distortion may occur.
According to the Patent Publications Nos. 3 to 6, the upper dies and lower dies are moved up and down with the time differences. However, nothing is disclosed in the above prior art about the material having the large aspect ratio or the high Young's modulus.
A further proposal is made as shown in
According to the above structure, however, since only a one side of the press punch 2, that is, a rear side end of the press punch 2 is in contact with the movable cam 3 (so-called a one-side contacting condition), a forward end of the press punch 2 may be lifted up.
The present invention is made in view of the above problems. It is an object of the present invention to provide a bending process and a processing machine, according to which multiple press punches are sequentially moved with a time difference in order to carry out press works to a thin metal plate, so that a product of a corrugated shape having no breaking and/or bowing of material can be manufactured.
According to a feature of the present invention, a bending machine has a first and a second die unit opposing to each other for bending a material of a thin metal plate. The first die unit includes multiple first die portions, each of which has a forward end for a bending process and is neighboring to each other in a direction of movement of the material. The second die unit includes multiple second die portions, each of which has a forward end for the bending process and is neighboring to each other in the direction of movement of the material. Each of the first die portions is opposing to each of the second die portions to form a pair of the first and second die portions. Each pair of the first and second die portions is sequentially operated so that at least one of the first and second die portions is relatively moved toward the other die portion, in order to continuously carry out the bending process so as to form the material in a corrugated shape. A method for the bending process comprises:
a step for feeding the material toward a press work area between the first and second die units;
a step for relatively moving the second die portion toward the first die portion so as to form a clearance between the forward ends of the first and second die portions at a material feeding position shortly before a press-work operating position for the bending process; and
a step for carrying out the bending process to the material at the press-work operating position,
wherein a pulling force of the material during the bending process is controlled by the clearance.
According to the above feature, a shape distortion of the material (such as bowing, breaking or the like) at the material feeding position, which is shortly before the press-work operating position by the first and second die portions, can be prevented.
According to another feature of the present invention, a bending machine has a first and a second die unit opposing to each other for bending a material of a thin metal plate, the material being fed toward a press work area between the first and second die units. The first die unit includes multiple die portions, each of which has a forward end for a bending process and is neighboring to each other in a direction of movement of the material. The second die unit includes multiple second die portions, each of which has a forward end for the bending process and is neighboring to each other in the direction of movement of the material. Each of the first die portions is opposing to each of the second die portions to form a pair of the first and second die portions, and each pair of the first and second die portions being sequentially operated so that at least one of the first and second die portions is relatively moved toward the other die portion, in order to continuously carry out the bending process so as to form the material in a corrugated shape. In the bending machine, a clearance is formed between the forward ends of the first and second die portions at a material feeding position shortly before a press-work operating position for the bending process, when the second die portion is relatively moved toward the first die portion, so as to control a pulling force of the material during the bending process.
According to the above feature, an excessive external force can not be applied to the material, so that a shape distortion of the material (such as bowing, breaking or the like) can be prevented.
According to a further feature of the present invention, a bending machine has a first and a second die unit opposing to each other for bending a material of a thin metal plate. The first die unit includes multiple first die portions, each of which has a forward end for a bending process and is neighboring to each other in a direction of movement of the material. The second die unit includes multiple pairs of a cam member and a press punch having a forward end for the bending process. The press punch is neighboring to each other in the direction of movement of the material, and has a width in the direction of movement of the material. Each pair of the cam member and the press punch is sequentially operated so that the press punch is relatively moved toward the first die portion, in order to continuously carry out the bending process so as to form the material in a corrugated shape. A method for the bending process comprises:
a step for feeding the material toward a press work area between the first and second die units;
a step of sequentially moving the cam members of the second die unit in a cam operating direction, which is perpendicular to the direction of movement of the material, so that the press punches are sequentially pushed toward the first die portions in a predetermined stroke in order to carry out the bending process to the material,
wherein the width of the press punch is smaller than the predetermined stroke thereof.
According to the above feature of the invention, the press punch can be moved in the larger stroke with a simple structure, so that a product having a higher aspect ratio can be manufactured.
According to a still further feature of the present invention, a bending machine has a first and a second die unit opposing to each other for bending a material of a thin metal plate, the material being fed toward a press work area between the first and second die units. The first die unit includes multiple first die portions, each of which has a forward end for a bending process and is neighboring to each other in a direction of movement of the material. The second die unit includes multiple pairs of a cam member and a press punch having a forward end for the bending process, and the press punches are neighboring to each other in the direction of movement of the material. Each pair of the cam member and the press punch of the second die unit is sequentially operated so that the press punch is relatively moved toward the first die portion, in order to continuously carry out the bending process so as to form the material in a corrugated shape. The press punch has a width in the direction of movement of the material. The cam member is movable in a cam operating direction, which is perpendicular to the direction of movement of the material. Each of the cam members is operatively brought into and out of engagement with each of the press punches via multiple inclined engaging portions, so that the press punch is pushed toward the first die portion when the cam member is moved in the cam operating direction in a predetermined stroke, wherein the width of the press punch is smaller than the predetermined stroke thereof.
According to the above feature, the cam member is arranged to be movable to the press punch in the longitudinal direction of press punch and the cam member is operatively engaged with or disengaged from the press punch via the multiple inclined engaging portions. Therefore, the press punch can be moved up and down with a simple structure and a lift-up of the press punch caused by the one-side contacting condition can be avoided.
According to a still further feature of the present invention, a bending machine has a first and a second die unit opposing to each other for bending a material of a thin metal plate. The first die unit includes multiple first cam members and multiple first press punches, and the first press punches are neighboring to each other and straightly arranged in a longitudinal direction of the material. Each of the first cam members is operatively brought into and out of engagement with each of the first press punches, so that the first press punch is moved toward the second die unit when the first cam member is operated The second die unit includes multiple second cam members and multiple second press punches, and the second press punches are neighboring to each other and straightly arranged in the longitudinal direction of the material. Each of the second cam members is operatively brought into and out of engagement with each of the second press punches, so that the second press punch is moved toward the first die unit when the second cam member is operated. A method for the bending process comprises:
a step for feeding the material toward a press work area between the first and second die units; and
a step of sequentially operating the respective first and second cam members of the first and second die units in a cam operating direction, which is perpendicular to the longitudinal direction of the material, so that the respective press punches are sequentially pushed to each other in a punch operating direction, which is perpendicular to a plane of the material, in order to continuously carry out the bending process to the material and to thereby form the material in a corrugated shape.
According to the above feature, the material is interposed between the first and second press punches and each of the first and second press punches is opposing to each other. Each of the first and second cam members is moved along the respective longitudinal directions of the first and second press punches so that the first and second press punches are moved in the punch operating direction to continuously carry out the press work to the material.
According to a still further feature of the present invention, in the step of sequentially operating the respective first and second cam members of the first and second die units in the cam operating direction, first and second center cam members, which are respectively arranged in a center of the straightly arranged first and second cam members, are operated at first, and first and second cam members neighboring to and arranged at both sides of the first and second center cam members are sequentially operated in a symmetric manner.
According to the above feature, the external force to be applied to the material may not be unevenly distributed, and thereby it is possible to manufacture the product having little shape distortion, such as the bowing or the like.
According to a still further feature of the present invention, a bending machine has a first and a second die unit opposing to each for bending a material of a thin metal plate. The first die unit includes multiple first cam members and multiple first press punches, and the first press punches are neighboring to each other and straightly arranged in a longitudinal direction of the material. The second die unit includes multiple second cam members and multiple second press punches, and the second press punches are neighboring to each other and straightly arranged in the longitudinal direction of the material. Each of the first and second cam members are movable in a cam operating direction, which is perpendicular to the longitudinal direction of the material. Each of the first cam members is operatively brought into and out of engagement with each of the first press punches via an inclined engaging portion, so that the first press punch is pushed toward the second die unit in a punch operating direction perpendicular to a plane of the material, when the first cam member is moved in the cam operating direction. Each of the second cam members is operatively brought into and out of engagement with each of the second press punches via an inclined engaging portion, so that the second press punch is pushed toward the first die unit in the punch operating direction, when the second cam member is moved in the cam operating direction. The respective first and second cam members are sequentially operated, so that the respective press punches are sequentially pushed to each other in order to continuously carry out the bending process to the material and to thereby form the material in a corrugated shape.
According to the above feature, the material is interposed between the first and second press punches and each of the first and second press punches is opposing to each other. Each of the first and second cam members is moved along the respective longitudinal directions of the first and second press punches, so that each of the cam members is brought into and out of the engagement with each of the press punches via the respective inclined engaging portions. As a result, the first and second press punches are sequentially moved to the other so as to continuously carry out the bending process to the material.
According to a still further feature of the present invention, the method for the bending process further comprises a step of carrying out a finishing bending process in order to keep the corrugated shape of the material, after the step for carrying out the bending process to the material at the press-work operating position.
According to the above feature, even in a case that the material is partly restored to its original shape by its elasticity, the shape of the corrugated product can be assured by carrying out an additional step of the finishing bending process to the entire area for the bending process.
According to a still further feature of the present invention, the method for the bending process further comprises a step of carrying out a primary bending process to the material, before the step for feeding the material toward the press work area between the first and second die units.
According to the above feature, even in a case that the material is partly restored to its original shape by its elasticity, the shape of the corrugated product can be stably obtained by the primary bending process and its subsequent (secondary) bending process.
According to the present invention, the product of the corrugated shape can be obtained, according to which deficiency (such as the bowing, the breaking or the like) of the material may not be generated in the bending process to form the material in the waveform.
The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description made with reference to the accompanying drawings. In the drawings:
A first embodiment of the present invention for a method for a bending process will be explained with reference to the drawings. A thin metal plate, which can be easily and plastically deformed, is used as a material to be processed.
Such a material, which has relatively a small specific gravity and which is flexible, capable of plastic deformation and malleable (for example, a light metal such as aluminum) is used as the thin metal plate.
In the present embodiment, an example for manufacturing a corrugated fin, which is used in a radiator for a vehicle engine, will be explained.
The corrugated fin is made of metal plate and formed in a waveform, wherein the wave-formed portions (the corrugated portions) are arranged at equal intervals. The corrugated fins are arranged between neighboring tubes, through which working fluid (such as, engine cooling water, refrigerant or the like) flows, so as to enhance radiation of heat from the working fluid flowing in the tubes to the surrounding air. A material for the corrugated fin, for example, a rolled thin metal plate, is pulled out from a roll and pulled into a processing machine, so that the corrugated fins are manufactured.
A processing machine is known in the art, for example, as disclosed in the Patent Publication No. 1 (JP 2008-087033), according to which a material to be processed is wound in a roll shape.
The processing machine of this kind has a feeding portion for feeding the material to be processed from the roll and a processing portion for forming the fed-in material into the waveform.
As explained below, the feeding portion feeds such an amount of the material to be processed, which corresponds to a predetermined number of the waveforms to be processed by one cycle of a bending process.
As shown in
In the present embodiment, the first die unit 11 is composed of the multiple first die portions (block members) 11b supported by a lower die 11a, while the second die unit 12 is composed of multiple second die portions (press punches) 12b supported by an upper die 12a.
The multiple first die portions (the block members) 11b are continuously arranged on the lower die 11a, wherein each of the block members 11b forms a receiving side for processing the material (the thin metal plate) M into the waveform. In each of the block members 11b, a concave portion is formed at its forward end for the bending process, that is, a bending process surface.
In a similar manner, the multiple second die portions (press punches) 12b are continuously arranged at the upper die 12e. Each of the press punches 12b is downwardly moved toward the bending process surface of the block member 11b of the lower die 11a, so that a pressing force of a predetermined value is applied to the material (the thin metal plate) M in order to plastically deform it into the waveforms.
The press punches 12b are operated to move downwardly by a die operating mechanism (not shown) provided at the upper die 12a, in such a manner that each of the press punches 12b is downwardly moved one after the other with a predetermined time difference so as to carry out the bending process (the press work). In this operation of the press punches 12b, a timing for moving down the respective press punch 12b is adjusted depending on a speed for feeding the material M, an aspect ratio and so on.
In the embodiment shown in
According to the processing machine 10, the material M is fed to the press work area between the lower die 11a and the upper die 12a in such a manner that the thin metal plate M is distanced from the forward end of the block member 11b of the lower die 11a with a clearance C as explained below.
In the above press work, in addition to the adjustment of the move-down timing of the respective press punches 12b, a processing curvature radius R is controlled by way of a curvature radius Rm of a single-side bending process by the press punch 12b, in order to carryout the press work in a favorable condition. Stabilization of processed (finished) shape of the final product (for example, the corrugated fins) is realized based on the following parameters (
RD: a curvature radius at the forward end at the bending process surface of the block member 11b;
Fb: a bending resistance (which is in an inverse proportion to R);
Ff: a frictional force between the forward end of the bending process surface and the material M;
L: a pull-in amount of the material M (which is in proportion to F);
C: a clearance between the press punch 12b and the forward end of the block member 11b (the bending process surface);
F: a tensility (a pulling force) (F=Fb+Ff).
The clearance C is a distance between the press punch 12b and the forward end of the block member 11b at a position shortly before a press work position. As a result of existence of the clearance C, the pull-in, amount L of the material M can be controlled by the tensility F which is generated in the material M during the press work, wherein the tensility F is based on the frictional force Ff and the bending resistance Fb. Accordingly, the press work can be carried out in a favorable manner without causing a breaking in the material M.
A process of the press work, which is carried out by the above explained processing machine 10, will be explained.
The upper die 12a of the processing machine 10 moves up and down relative to the lower die 11a between a lower-most position in which the upper die 12a is closed to the lower die 11a and an upper-most position in which the upper die 12a is opened from the lower die 11a. Each of the press punches 12b is moved downwardly one after the other with the predetermined time difference by the die operating mechanism (not shown) fixed to the upper die 12a, so as to carry our the press work to the material (thin metal plate) M.
As shown in
When the press punch 12b is moved downwardly by the die operating mechanism at a press-work operating position, a portion of the material M to be processed is interposed between the press punch 12b and the forward end of the block member 11b of the lower die 11.
At the position shortly before starting the press work, since the clearance C is formed between the press punch 12b and the forward end of the block member 11b of the lower die 11, the material M is bent against the bending resistance Fb from the forward end of the block member 11b (which is in the press-work operation) in such a shape having the curvature radius Rm in the single-side bending condition.
At the press-work operating position, the bending resistance Fb and the tensility F based on the frictional force Ff are applied to the material M (more exactly, to a portion of the material M to be press worked). As a result, the material M is pulled into a press-working portion between the upper and lower dies (11b, 12b) by the pull-in amount L, which is in proportion to the tensility F.
As above, the press-work operation is sequentially carried out, wherein the clearance C is formed between the press punch 12b and the forward end of the block member 11b at the position shortly before starting the press work so as to control the pull-in amount of the material M depending on the tensility F. As a result, the material (the thin metal plate) M is formed in a desired wave form without causing the breaking in the material M.
A dimension of the clearance C is preferably smaller than a height of the corrugated portion (i.e. a height of the waveform).
A processing machine 20 of a second embodiment is shown in
The processing machine 20 has multiple movable dies 21 (the press punches) neighboring to each other, each of which is movable in the punch operating direction perpendicular to the plane of the material M. Although not shown in the drawing, the processing machine 20 has a lower die similar to that of the first embodiment, so that each of the movable dies (the press punches) 21 is opposing to each forward end of the respective block members of the lower die to form multiple pairs of the upper and lower dies. Furthermore, the processing machine 20 has multiple cam members 22 neighboring to each other, each of which is operatively engaged with the respective movable die 21. The cam member 22 is movable relative to the movable die 21 in the cam operating direction perpendicular to the direction of movement of the material M. The neighboring cam members 22 are sequentially moved in the cam operating direction.
Each of the movable dies 21 and cam members 22 has multiple inclined engaging portions 23. When the cam member 22 is moved in the cam operating direction, the movable die 21 is pushed downwardly along the inclined engaging portions 23. The movable die 21 is downwardly moved by a predetermined stroke so as to carry out the press work to the material (the thin metal plate) M.
Each of the movable dies (the press punches) 21 is arranged in such a way that a longitudinal direction of the movable die 21 is directed in a width direction of the material M, which is perpendicular to the direction of movement of the material M. A length of the movable die 21 is almost equal to a width of the material (the thin metal plate of a strip shape) M. Each of the movable dies 21 is independently movable from the neighboring movable dies 21.
The cam member 22 is generally engaged with the movable die 21 via the inclined engaging portions 23 and the cam member 22 is brought out of engagement from the movable die 21 when the cam member 22 is moved to its maximum stroke position.
As explained above, the lower die (not shown) is provided below the material M. The lower die, which may be composed of multiple block members like the first embodiment, has a bending process surface of a rectangular waveform in cross section.
As shown in
According to the above structure, when the cam member 22 is moved in the cam operating direction (in a leftward direction in the drawings), the movable die 21 is pushed downwardly along the inclined surfaces 222 of the cam member 22, so that the movable die 21 is moved downwardly by a stroke “d”. A thickness of the movable die (the press punch) 21 is “p”, so that an aspect ratio is “d/p”. Since the stroke “d” is larger than the thickness “p”, the aspect ratio “d/p” becomes larger than “1” (d/p>1).
According to the processing machine 20 of the second embodiment, the cam member 22 is movably arranged in the cam operating direction, which is perpendicular to the direction of the movement of the material M, in order that the movable die (the press punch) 21 is moved in the punch operating direction, which is perpendicular to the plane of the material M, by the stroke “d”.
When compared with the conventional processing machine, in which a cam member is moved in a direction along a direction of movement of a material, the aspect ratio of the present embodiment becomes larger than that of the conventional machine. Therefore, it is possible to sequentially move the multiple press punches 21 in a larger stroke than that of the conventional machine to form the corrugated shape.
In addition, the cam member 22 is brought into and/or out of engagement with the movable die (the press punch) 21 via the pair of the concave portions 211 formed in the press punch 21 and the pair of the convex portions 221 formed in the movable cam 22, and the cam member 22 is moved in the cam operating direction so that the press punch 21 is downwardly pushed by the inclined engaging portions 23, which has the inclined surfaces 212 and 222 inclined by 135 degrees from the cam operating direction in the anticlockwise direction. Therefore, when compared with the conventional machine, for example, as shown in
A processing machine 30 of a third embodiment is shown in
The processing machine 30 has multiple first and second press punches 31 and 32, which are respectively arranged in the direction of the movement of the material (the thin metal plate) M. Each of the press punches 31 and 32 extends in the direction perpendicular to the direction of the movement of the material M and has a length almost equal to a width of the material M. A forward end of each press punch 31 and 32 is directed toward the material M. Each of the press punches 31 and 32 is movable toward the material M in a vertical direction in the drawing. Each of the first press punches 31 is displaced from each of the second press punches 32 in the direction of the movement of the material M by a half pitch, so that a processing concave surface portion and a processing convex surface portion are formed between opposing forward ends of the first and second press punches 31 and 32. Multiple first and second cam members 33 and 34 are respectively provided at the first and second press punches 31 and 32, wherein each of the first and second cam members 33 and 34 is movable in a cam operating direction, which is perpendicular to the direction of the movement of the material M, that is a longitudinal direction of the press punches 31 and 32. When the cam member 33 or 34 is moved in the cam operating direction, the cam member 33 or 34 is engaged with the corresponding press punch 31 or 32 and then brought out of the engagement when the cam member is moved to its maximum stroke position.
As shown in
Each of the inclined surface portions 331 and 341 formed in the cam members 33 and 34 as well as each of the inclined surface portions 311 and 321 formed in the press punches 31 and 32 is inclined by almost 135 degrees from the cam operating direction.
In a similar manner to the second embodiment, a pair of concave portions may be formed in each of the press punches 31 and 32, while a pair of convex portions may be formed in each of the cam members 33 and 34, so that a pair of inclined engaging portions 35 may be respectively formed between the first press punches 31 and the first cam members 33 and between the second press punches 32 and the second cam members 34.
According to the above processing machine 30, the material (the thin metal plate) M is inserted into a space between the first and second press punches 31 and 32, and each of the first and second cam members 33 and 34 are sequentially moved back and forth in the cam operating direction (a width direction of the material M) at respective predetermined timings, so that two first press punches 31 neighboring to each other are lifted up while a corresponding second press punch 32 is downwardly moved. As a result, the material M is press worked and formed in a corrugated shape.
As above, the corresponding first press punch(es) 31 and second press punch(es) 32 are moved toward each other in a sequential manner to carry out the press work.
For example, as shown in
According to the above manufacturing method, the tensility F (=Fb+Ff) is generated in the material M at both sides of the center press punches 31 and 32 in the rightward and leftward directions, so that the material M is pulled in at the both sides of the press punches 31 and 32 by the pull-in amount L. As above, the press work to the material M can be carried out at the same time at the both sides of the press punches 31 and 32 in a symmetric manner. As a result, a strain and a warp can be suppressed. A stable press work can be realized.
In the above embodiments, the press work may be carried out, for example, in two stages. When a portion of the material M, which has been press worked in a first stage, is restored to its original shape by its elasticity, the material M can be press worked in a second stage so that the shape of the material M finally becomes to a desired shape defined by the processing surface of the press punches. As a result, the product of a higher quality can be manufactured.
For example, the press work for the first embodiment shown in
In case of the above press work of the two stages, the secondary press work may be applied to a first portion of the material M for which the primary press work has been done, and at the same time the primary press work is applied to a second portion of the material M which is next to the first portion of the material M, so that the corrugated shapes can be continuously formed by the two-stage press works.
In the above embodiments, the material M is sequentially fed to the press-work operating position between the press punch (the second die) 12b, 21 and the block member (the first die) 11b. However, multiple pairs of the first and second dies may be sequentially moved along the strip-shaped material M, each time when the press work will be done for another portion of the material M after the press work has been done for one portion of the material M, so that the press work can be also continuously carried out to the strip-shaped material M. In addition, a finishing press work may be applied to the material M, for which the press work has been done for one time.
The processing machine and/or the manufacturing method of the present invention should not be limited to such machine or method for manufacturing the product which is formed in the waveform, the processed surface of which has the predetermined curvature radius. The present invention may be applied to such a machine or method for manufacturing products having various kinds of corrugated shapes.
Furthermore, the present invention may be applied to a manufacturing method and/or apparatus for an off-set type corrugated fin, in which multiple fin portions are formed in each extending line of a corrugated fin and some of the fin portions are off-set from the remaining fin portions.