WO2013098927A1 - Multistage press device and multistage press method - Google Patents

Abstract

Provided is a multistage press device capable of preventing uneven loading during press processing. This multistage press device (100) comprises a lower stage mold (10) and an upper stage mold (20) arranged in series in the press direction, wherein the lower stage mold (10) and the upper stage mold (20) form a side outer part (L1) and a side outer part (R2) comprising a bottom lower part (10D) and a bottom lower part (20D), respectively, which are in plane symmetry. The lower stage mold (10) and the upper stage mold (20) are arranged such that the bottom lower part (10D) of the side outer part (L1) and the bottom lower part (20D) of the side outer part (R2) are in plan symmetry with respect to a surface perpendicular to the press direction.

Description

Multistage press apparatus and multistage press method

The present invention relates to a technique for a multistage press apparatus and a multistage press method.

The press device is a device that presses metal (drawing, bending, shearing, etc.) using a mold. A multi-stage press apparatus, which is one of the press apparatuses, can be installed in a factory in a space-saving manner. A multi-stage press apparatus arranges a plurality of pairs of dies in series in the press direction and presses them with a common press drive source (for example, Patent Document 1).

When a large press part such as an automobile part is pressed by a multi-stage press device, the press load is remarkably increased. When the press load is remarkably large, the mold or equipment may receive an uneven load due to the press reaction force, and the mold may tilt. The inclination of the mold causes molding defects of the press product, galling of the slide part of the mold, or galling of the slide part of the press device.

JP 2000-015496 A

The problem to be solved by the present invention is to provide a multi-stage press apparatus and a multi-stage press method capable of suppressing an uneven load during press working.

The problems to be solved by the present invention are as described above. Next, means for solving the problems will be described.

That is, in claim 1, a multi-stage press apparatus in which a plurality of pairs of forming dies are arranged in series in the press direction, wherein a pair of forming dies among the plurality of pairs of forming dies, and the plurality of pairs of forming dies are arranged. The other pair of molds are for molding the first molded product and the second molded product, each of which is symmetrical with respect to each other, and a part of the first molded product, The pair of molds and the other pair of molds are arranged so that a portion of the second molded product is plane-symmetric with respect to a plane perpendicular to the pressing direction.

Claim 2 is the multistage press apparatus according to claim 1, wherein the first molded product and the second molded product are symmetrical with each other.

The multi-stage pressing method according to claim 3, wherein a plurality of pairs of molding dies are arranged in series in a pressing direction and molded, wherein the pair of molding dies among the plurality of pairs of molding dies, and the plurality of pairs of molding dies. The other pair of molds are for molding the first molded product and the second molded product, each of which is partially symmetrical with respect to each other, and a part of the first molded product, The pair of molding dies and another pair of molding dies are arranged and molded so that a part of the second molded product is plane-symmetric with respect to a plane perpendicular to the pressing direction.

Claim 4 is the multistage press method according to claim 3, wherein the first molded product and the second molded product are symmetrical with each other.

According to the multi-stage press apparatus and multi-stage press method of the present invention, it is possible to suppress uneven loads during press working.

The schematic diagram which shows the structure of the multistage press apparatus which is embodiment of this invention. The schematic diagram which shows a lower mold and an upper mold. The schematic diagram which shows the effect | action of a multistage press apparatus. The schematic diagram which shows the lower stage metal mold | die and upper stage metal mold | die which are another embodiment.

The multistage press apparatus 100 will be described with reference to FIG.
In addition, below, it demonstrates according to the press direction which is the perpendicular direction shown by FIG. 1 or FIG. 2, the width direction, or the depth direction.

The multi-stage press apparatus 100 is an embodiment according to the press apparatus of the present invention. The multistage press apparatus 100 is an apparatus that places a plurality of pairs (two pairs in this embodiment) of dies in series in the press direction and presses them with a common press drive source. The multistage press apparatus 100 is assumed to press the side outer of an automobile.

The configuration of the multistage press apparatus 100 will be described.
The multi-stage press apparatus 100 generally includes a press facility and a plurality of pairs of molds (molding dies). Each mold is configured as a lower mold 10 and an upper mold 20. The lower die 10 is disposed on the lower side in the pressing direction in the multi-stage press apparatus 100. The lower mold 10 includes a lower-stage lower mold 11 and a lower-stage upper mold 12. The upper die 20 is arranged on the upper side in the pressing direction in the multi-stage press apparatus 100. The upper die 20 includes an upper lower die 21 and an upper upper die 22.

The press facility is a facility for pressing the lower mold 10 and the upper mold 20. The press facility includes a base 35, die plates 31, 32, and 33, a guide post 36, and a press drive source 40. The base 35 is a member that is configured in a substantially rectangular shape and supports the multistage press apparatus.

The die plates 31, 32, and 33 are rectangular plate members that are arranged with their plate surfaces (upper surface and lower surface) facing in the pressing direction. A lower lower mold 11 is fixed to the upper surface of the die plate 31. The lower upper mold 12 is fixed to the lower surface of the die plate 32, and the upper lower mold 21 is fixed to the upper surface of the die plate 32. An upper upper mold 22 is fixed to the lower surface of the die plate 33. The die plates 32 and 33 are configured to slide in the press direction along the guide posts 36 and 36 (hereinafter, slide).

The guide posts 36 and 36 are substantially cylindrical members extending in the pressing direction, and support the die plates 32 and 33 so as to be slidable in the pressing direction. The press drive source 40 is a device that drives the die plate 33 and the upper stage side upper die 22 in the press direction.

The lower mold 10 and the upper mold 20 will be described with reference to FIG.
In FIG. 2A, for easy understanding of the explanation, the shape of the side outer L1 is indicated by a broken line in a plan view of the lower die 10. In FIG. 2B, for easy understanding of the explanation, the molded shape of the side outer R1 is indicated by a broken line in a plan view of the upper mold 20.

The lower mold 10 is a pair of molds of a plurality of pairs of molds, and the upper mold 20 is another pair of molds of a plurality of pairs of molds. The lower mold 10 is for molding the side outer L1, and the upper mold 20 is for molding the side outer R1. The side outer L1 is a side outer on the left side of the automobile. The side outer R1 is a right side outer of an automobile (different in vehicle height) different from the automobile configured using the side outer L1.

The lower metal side 10 is divided into four areas in plan view, and each area is defined as a front lower part 10A, a front upper part 10B, a rear upper part 10C, and a rear lower part 10D. At the time of pressing, for example, a load of 20 is applied to the front lower part 10A, 20 to the front upper part 10B, 30 to the rear upper part 10C, and 100 to the rear lower part 10D. At this time, an uneven load is applied to the rear lower part 10D on the lower metal side 10.

Note that the unit of load is made dimensionless, and () of each part in FIG. 2 indicates the value of the dimensionless load.

Similarly, the upper die 20 is divided into four regions in plan view, and each region is defined as a front lower part 20A, a front upper part 20B, a rear upper part 20C, and a rear lower part 20D. At the time of press working, for example, a load of 30 acts on the front lower part 20A, 30 on the front upper part 20B, 40 on the rear upper part 20C, and 100 on the rear lower part 20D. At this time, an uneven load is applied to the rear lower portion 20D on the upper metal side 20.

Note that the side outer L1 and the side outer R1 are formed so that the rear lower portion 10D and the rear lower portion 20D are symmetrical with each other, and therefore the substantially same load acts on the rear lower portion 10D and the rear lower portion 20D.

Here, as a matter to be noted, in the multistage pressing device 100, a portion of the rear lower portion 10D of the side outer L2 pressed by the lower metal mold side 10 and a portion of the rear lower portion 20D of the side outer R2 pressed by the upper metal mold 20 However, the lower metal side 110 and the upper metal mold 120 are arranged so as to be plane-symmetric (mirror image) with the die plate 32 as a boundary (see FIG. 3).

That is, the lower metal side 10 and the upper metal mold 20 are configured so that the rear lower part 10D and the rear lower part 20D are in plane symmetry with respect to the plane in which the side outer L1 and the side outer R1 are perpendicular to the pressing direction. Is arranged.

The operation of the multistage press apparatus 100 will be described with reference to FIG.
FIG. 3 shows the lower metal mold side 10 and the upper metal mold 20 in front view. In FIG. 3, the description of the press facility is omitted for easy understanding.

In the multistage press apparatus 100, the side outer L1 is formed by the lower mold 10 (between the lower-stage lower mold 11 and the lower-stage upper mold 12), and the upper mold 20 (the upper-stage lower mold 21 and the upper-stage upper mold 22). The side outer R1 is formed between the two. The multistage press apparatus 100 drives the press drive source 40 (see FIG. 1), and slides the die plate 33 and the upper stage side upper mold 22 in the press direction.

At this time, the die plate 32, the upper stage lower mold 21 and the lower stage upper mold 12 receive the load in the pressing direction of the die plate 33 and the upper stage upper mold 22, and are similarly slid in the pressing direction. The multi-stage press apparatus 100 includes a material sandwiched between the lower stage lower mold 11 and the lower stage upper mold 12 and a material sandwiched between the upper stage lower mold 21 and the upper stage upper mold 22. At the same time, pressing is performed to form the side outer L1 and the side outer R1, respectively.

Here, on the lower metal side 10, an uneven load is applied to the rear lower part 10D. However, since the lower side lower mold 11 and the die plate 31 are supported by the base 35, they are not easily tilted. Therefore, an upward reaction force P1 in the pressing direction acts on the die plate 32, the upper lower mold 21 and the lower upper mold 12 as an offset load of the lower mold 10 (open arrow shown in FIG. 3).

Similarly, the upper metal side 20 is subject to an uneven load on the rear lower part 20D. However, since the upper die 22 and the die plate 33 are supported by the press drive source 40, they are difficult to tilt. Therefore, a downward reaction force P2 in the pressing direction acts on the die plate 32, the upper lower mold 21 and the lower upper mold 12 as an offset load of the upper mold 20 (white arrow shown in FIG. 3).

At this time, the die plate 32, the upper lower mold 21, and the lower upper mold 12 have an upward reaction force P <b> 1 in the pressing direction as the offset load of the lower mold 10 and the pressing direction as the offset load of the upper mold 20. The downward reaction force P2 acts simultaneously. Note that the magnitude of the reaction force P1 and the magnitude of the reaction force P2 are substantially the same because the rear lower portion 10D and the rear lower portion 20D are portions that form the same portion of the side outer L1 and the side outer R1.

However, in the multi-stage press apparatus 100 of the present embodiment, the rear lower part 10D and the rear lower part 20D are plane-symmetric with respect to the lower metal side 10 and the upper metal mold 20 with the side outer L1 and the side outer R1 being bordered by the die plate 32 ( (Mirror image).

Therefore, the upward reaction force P1 in the pressing direction as an offset load of the lower mold 10 and the downward reaction force P2 in the pressing direction as an offset load of the upper mold 20 are offset. By offsetting the unbalanced load of the lower mold 10 and the unbalanced load of the upper mold 20, the unbalanced loads of the die plate 32, the upper stage lower mold 21 and the lower stage upper mold 12 are suppressed.

The effect of the multistage press apparatus 100 will be described.
According to the multistage press apparatus 100, even when the side outer L1 and the side outer R1 are formed so as to be partially plane-symmetric, it is possible to suppress the uneven load during the press working.

A lower mold 110 and an upper mold 120 according to another embodiment will be described with reference to FIG.
In FIG. 4A, for easy understanding, the shape of the side outer L2 is indicated by a broken line in a plan view of the lower mold 110. In FIG. 2B, for easy understanding of the explanation, the molded shape of the side outer R2 is indicated by a broken line in a plan view of the upper die 120.

The multi-stage press apparatus 200 (not shown) is another embodiment according to the multi-stage press apparatus of the present invention using the lower mold 110 and the upper mold 120.

The lower mold 110 is a pair of molds of a plurality of pairs of molds, and the upper mold 120 is another pair of molds of a plurality of pairs of molds. The lower mold 110 is for molding the side outer L2, and the upper mold 120 is for molding the side outer R2. The side outer L1 is a side outer on the left side of the automobile. The side outer R2 is a right side outer of a vehicle of the same vehicle type. The side outer L2 and the side outer R2 are formed to be plane symmetric.

The lower metal side 110 is divided into four areas in plan view, and each area is defined as a front lower part 110A, a front upper part 110B, a rear upper part 110C, and a rear lower part 110D. At the time of pressing, for example, 20 is applied to the front lower part 110A, 20 is applied to the front upper part 110B, 30 is applied to the rear upper part 110C, and 100 loads are applied to the rear lower part 110D. At this time, an uneven load is applied to the rear lower portion 110D on the lower metal side 110.

It should be noted that the unit of load is made dimensionless, and () of each part in FIG. 4 indicates the dimensioned load value.

Similarly, the upper mold 120 is divided into four regions in plan view, and each region is defined as a front lower part 120A, a front upper part 120B, a rear upper part 120C, and a rear lower part 120D. At the time of pressing, for example, 20 is applied to the front lower part 120A, 20 is applied to the front upper part 120B, 30 is applied to the rear upper part 110C, and 100 loads are applied to the rear lower part 110D. At this time, an uneven load is applied to the rear lower portion 110D on the lower metal side 110.

In addition, since the side outer L2 and the side outer R2 are arranged so as to be plane-symmetric, corresponding portions (for example, the front lower portion 110A and the front lower portion 120A) are subjected to substantially the same load.

Here, as a matter of special note, in the multistage press apparatus 200, the side outer L2 pressed by the lower mold side 110 and the side outer R2 pressed by the upper mold 20 are plane-symmetric (mirror image) with the die plate 32 as a boundary. ), A lower metal side 110 and an upper metal mold 120 are arranged (not shown). That is, the lower metal side 110 and the upper metal mold 120 are disposed so that the side outer L2 and the side outer R2 are plane-symmetric with respect to a plane perpendicular to the pressing direction.

The operation of the multistage press apparatus 200 will be described.
In the multi-stage press apparatus 200 using the lower mold 110 and the upper mold 120, the die plate 32, the upper stage lower mold 121, and the lower stage upper mold 112 are pressed by the die plate 33 and the upper stage upper mold 122 at the time of pressing. It is slid in the press direction in response to the load in the direction.

At this time, the die plate 32, the upper lower mold 121, and the lower upper mold 112 have an upward reaction force P1 in the pressing direction as an offset load of the lower mold 110 and a pressing direction as an offset load of the upper mold 120. The downward reaction force P2 acts simultaneously. Note that the magnitude of the reaction force P1 and the magnitude of the reaction force P2 are substantially the same because the rear lower portion 110D and the rear lower portion 120D are portions that form the same portion of the side outer L1 and the side outer R1.

However, in the multi-stage press apparatus 200 of the present embodiment, the side outer L1 and the side outer R1 are arranged so as to be plane-symmetric (mirror image) with the die plate 32 as a boundary for the lower metal side 110 and the upper metal mold 120. .

Therefore, the upward reaction force P1 in the pressing direction as an offset load of the lower die 110 and the downward reaction force P2 in the pressing direction as an offset load of the upper die 120 are offset. By offsetting the unbalanced load of the lower mold 110 and the unbalanced load of the upper mold 120, the unbalanced loads of the die plate 32, the upper stage lower mold 121 and the lower stage upper mold 112 are suppressed.

In addition, about the side outer L1 and the side outer R1, for example, it is good also as a structure which forms a fuel filler port etc. in a post process only about either.

The effect of the multistage press apparatus 200 will be described.
According to the multistage press apparatus 200, the uneven load at the time of press work can be suppressed.

In the present embodiment, the lower upper mold 12 is fixed to the lower surface of the die plate 32, and the upper lower mold 21 is fixed to the upper surface of the die plate 32. However, the present invention is not limited to this. For example, a front-back integrated intermediate type structure in which the lower-stage upper mold 12 and the upper-stage lower mold 21 are integrally fixed without using the die plate 32 may be used.

The present invention can be used in a multistage press apparatus.

10 Lower die 11 Lower lower die 12 Lower upper die 20 Upper die 21 Upper lower die 22 Upper upper die 100 Multistage press machine L1 Side outer (left side)
R1 Side outer (right side)

Claims (4)

1. A multi-stage press device in which a plurality of pairs of molds are arranged in series in the press direction,
   The pair of molds of the plurality of pairs of molds and the other pair of molds of the plurality of pairs of molds are a first molded product and a second mold, each part of which is symmetrical with respect to each other. Each molded product is molded,
   The pair of molds and the other pair of molds so that a part of the first molded product and a part of the second molded product are plane-symmetric with respect to a plane perpendicular to the press direction. Is placed,
   Multi-stage press machine.
2. The multistage press device according to claim 1,
   The first molded product and the second molded product are plane-symmetric with each other.
   Multi-stage press machine.
3. A multi-stage press method in which a plurality of pairs of molds are arranged in series in the press direction and molded,
   The pair of molds of the plurality of pairs of molds and the other pair of molds of the plurality of pairs of molds are a first molded product and a second mold, each part of which is symmetrical with respect to each other. Each molded product is molded,
   The pair of molds and the other pair of molds so that a part of the first molded product and a part of the second molded product are plane-symmetric with respect to a plane perpendicular to the press direction. Place and mold,
   Multi-stage press method.
4. A multi-stage pressing method according to claim 3,
   The first molded product and the second molded product are plane-symmetric with each other.
   Multi-stage press method.

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