JP2020146694A - Press device and press method - Google Patents

Abstract

To carry out plural molding in a single press operation without using a mold having a complicated structure.SOLUTION: A press device 100 is a device for molding a plate 9 using a mold 2 having an upper die 4 and an upper movable metal mold 6 provided to be advanced and retreated with respect to the upper die 4. The device comprises: a pair of upper stationary plates 10 which are provided separating from each other in a press direction in which the mold 2 presses the plate 9 and are driven by a servomotor to lift the upper die 4 with respect to the plate 9; and the upper movable plates 20, 30 provided displaceably in the press direction with respect to the plates 10 between the pair of upper stationary plates 10 and pressing the plate in the press direction so as to change the pressing force of the upper movable metal mold 6 to the plate 9 in pressing by the upper stationary plates 10.SELECTED DRAWING: Figure 1

Description

The present invention relates to a pressing device and a pressing method.

Patent Document 1 discloses a press molding apparatus that performs secondary molding of trimming, piercing, burring, bending, or coining of a plate material while performing shape forming by drawing the plate material in one press operation.

Japanese Patent No. 4611205

However, in the press forming apparatus of Patent Document 1, in order to perform the secondary forming while forming the shape of the plate material, the dies are sequentially processed in the process of raising and lowering the press. Therefore, the structure of the mold is complicated.

The present invention has been made in view of the above problems, and an object of the present invention is to perform a plurality of moldings in one pressing operation without using a die having a complicated structure.

According to an aspect of the present invention, a press device for molding a plate material by a mold having an upper mold and an upper movable mold provided so as to be able to advance and retreat to the upper mold is a press in which the mold presses the plate material. The press on the upper fixing plate between a pair of upper fixing plates provided apart from each other in the direction and driven by a driving mechanism to raise and lower the upper die with respect to the plate material and the pair of upper fixing plates. It is provided so as to be displaceable in the direction, and includes an upper movable plate that presses in the pressing direction so that the pressing force of the upper movable mold against the plate material can be changed when pressed by the upper fixing plate.

Further, according to an aspect of the present invention, in a pressing method in which a plate material is formed by a mold having an upper mold and an upper movable mold provided so as to be able to move forward and backward with respect to the upper mold, the mold presses the plate material. The process of forming the plate material by pressing the upper mold with the upper fixing plate that moves in the pressing direction, and pressing the upper movable mold with the upper movable plate pressed by the upper fixing plate so that the pressing force can be changed. It includes a process of molding a plate material.

In the above aspect, an upper movable plate that can be displaced with respect to the upper fixing plate in the pressing direction and is pressed by the upper fixing plate is provided. Further, when the upper movable plate is pressed by the upper fixing plate, the upper movable plate is pressed in the pressing direction so that the pressing force of the upper movable mold against the plate material can be changed. Therefore, a plurality of moldings can be performed by the upper mold of the mold provided on the upper fixing plate and the upper movable mold connected to the upper movable plate. Therefore, since a plurality of moldings can be performed by providing the upper fixed plate and the upper movable plate, it is not necessary to make the mold a complicated structure. Therefore, it is possible to perform a plurality of moldings in one pressing operation without using a die having a complicated structure.

FIG. 1 is a block diagram of a press device according to a first embodiment of the present invention. FIG. 2 is a diagram illustrating a first step in a pressing method using a press device. FIG. 3 is a diagram illustrating a second step in a pressing method using a pressing device. FIG. 4 is a diagram illustrating a third step in a pressing method using a press device. FIG. 5 is a diagram illustrating a fourth step in a pressing method using a press device. FIG. 6 is a block diagram of a press device according to a second embodiment of the present invention. FIG. 7 is a diagram illustrating a first step in a pressing method using a press device. FIG. 8 is a diagram illustrating a second step in a pressing method using a press device. FIG. 9 is a diagram illustrating a third step in a pressing method using a pressing device. FIG. 10 is a diagram illustrating a fourth step in a pressing method using a press device. FIG. 11 is a diagram illustrating a fifth step in a pressing method using a pressing device. FIG. 12 is a diagram illustrating a sixth step in a pressing method using a pressing device. FIG. 13 is a diagram illustrating a seventh step in a pressing method using a press device. FIG. 14 is a diagram for explaining the sixth step and the seventh step in detail. FIG. 15 is a block diagram of a press device according to a third embodiment of the present invention. FIG. 16 is a diagram illustrating a first step in a pressing method using a pressing device. FIG. 17 is a diagram illustrating a second step in a pressing method using a press device. FIG. 18 is a diagram illustrating a third step in a pressing method using a press device. FIG. 19 is a diagram illustrating a fourth step in a pressing method using a press device. FIG. 20 is a diagram illustrating a fifth step in a pressing method using a press device.

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

(First Embodiment)
Hereinafter, the press device 100 according to the first embodiment of the present invention and the press method using the press device 100 will be described with reference to FIGS. 1 to 5.

First, the overall configuration of the press device 100 will be described with reference to FIG. FIG. 1 is a configuration diagram of a press device 100.

The press device 100 is a servo press device in which a slide 1 driven by a servomotor (not shown) as a drive mechanism moves up and down. The press device 100 press-molds the plate material 9 with the die 2. The press device 100 includes a pair of upper fixed plates 10, a pair of upper movable plates 20 and 30, and a pair of upper rods 25 and 35.

In each of the following embodiments, the direction in which the die 2 moves when the plate material 9 is pressed (vertical direction in FIG. 1) is referred to as "pressing direction" or "vertical direction".

First, the die 2 mounted on the press device 100 and used will be described.

The mold 2 has an upper mold 4, a lower mold 5, and an upper movable mold 6. Here, the die 2 performs drawing processing, piercing processing, and trim processing on the plate material 9 in one press operation (one stroke).

The upper mold 4 is attached to the lower part of the lower upper fixing plate 10. The upper mold 4 is provided so as to face the upper side in the pressing direction with respect to the plate material 9. The upper mold 4 has a trim mold portion 4a. The upper die 4 is provided with an upper movable die 6 that can move forward and backward in the pressing direction with respect to the upper die 4.

The inner circumference of the trim mold portion 4a is formed to have the same shape as the outer shape of the product to be molded. The trim mold portion 4a is formed by punching the outer periphery of the plate material 9 pressed by the pressing portion 6a described later to form the outer shape of the product.

The lower mold 5 is provided so as to face the lower side in the pressing direction with the plate material 9 sandwiched between the upper mold 4. The lower mold 5 is attached to the upper part of the lower fixing plate 42 supported by the base 41 described later. The lower mold 5 has a pressing portion 5a, a drawing die 5b, a pair of piercing dies 5c, a trim die 5d, and plate material supporting portions 5e and 5f.

The pressing portion 5a holds the plate material 9 sandwiched between the pressing portion 5a and the pressing portion 6a.

The drawing die 5b draws the plate material 9 together with the drawing punch 6b described later. The drawing punch 6b enters the accommodating hole of the drawing die 5b during drawing.

The piercing die 5c performs piercing processing on the plate material 9 together with the piercing punch 6c described later. The piercing punch 6c enters the accommodating hole of the piercing die 5c during piercing processing.

The trim die 5d trims the plate material 9 together with the trim mold portion 4a. The trim die 5d is formed in a block shape having the same outer shape as the shape of the product to be molded. The trim mold portion 4a enters the outer peripheral space of the trim die 5d during trim processing.

The plate material support portion 5e supports the supplied plate material 9 from below. The plate material support portion 5e is urged upward by the spring 5g. The plate material support portion 5e sandwiches and holds the plate material 9 between the plate material support portion 6d and the plate material support portion 6d.

Similarly, the plate material support portion 5f supports the supplied plate material 9 from below. The plate material support portion 5f is urged upward by the spring 5h. The plate material support portion 5f is held by sandwiching the plate material 9 with the pressing portion 6a.

The upper movable mold 6 is provided so as to be able to advance and retreat with respect to the upper mold 4 to form the plate material 9. The upper movable mold 6 has a pressing portion 6a, a drawing punch 6b, a pair of piercing punches 6c, and a plate material supporting portion 6d.

The pressing portion 6a presses the upper surface of the plate material 9 when drawing, piercing, and trimming the plate material 9. The pressing portion 6a is formed in a block shape having the same outer shape as the shape of the product to be molded. The pressing portion 6a is pressed so as to form the plate member 9 in a state where the upper rod 35 is in contact with the pressing portion 6a.

The pressing portion 6a is urged downward by the spring 6f. When the upper fixing plate 10 is lowered by a predetermined stroke or more in the pressing direction, the pressing portion 6a is pressed against the plate material 9 by the upper movable plate 30 via the upper rod 35. In this way, the pressing force of the pressing portion 6a can be changed in two stages, that is, a state in which the pressing portion 6a is urged by the spring 6f and a state in which the pressing portion 6a is pressed by the upper movable plate 30.

Specifically, the pressing portion 6a is urged in the pressing direction by the spring 6f when the plate material 9 is drawn. On the other hand, when the plate member 9 is pierced and trimmed, the pressing portion 6a is urged in the pressing direction with a urging force larger than the urging force of the spring 6f via the upper rod 35.

The drawing punch 6b is pressed against the plate material 9 by the upper movable plate 20 via the upper rod 25. The drawing punch 6b is pressed so as to form the plate material 9 in a state where the upper rod 25 is in contact with the drawing punch 6b. The drawing punch 6b draws the plate material 9 together with the drawing die 5b.

The piercing punch 6c is attached to the lower part of the lower upper fixing plate 10. The piercing punch 6c performs piercing processing on the plate material 9 together with the piercing die 5c.

The plate material support portion 6d supports the supplied plate material 9 from above. The plate material support portion 6d is urged downward by the spring 6g. The plate material support portion 6d holds the plate material 9 sandwiched between the plate material support portion 6d and the plate material support portion 5e.

The upper mold 4 is detachably provided with respect to the upper fixing plate 10, and the lower mold 5 is detachably provided with respect to the lower fixing plate 42. Further, the upper rods 25 and 35 and the upper movable mold 6 are only in contact with each other when pressing the plate material 9. The mold 2 can be replaced in a state where the upper mold 4 is removed from the upper fixing plate 10 and the lower mold 5 is removed from the lower fixing plate 42 and the upper rods 25 and 35 are separated from the upper movable mold 6.

In this way, all the configurations for generating the machining force in the mold 2 are integrated in the cage 10A, so that the mold 2 does not need to have a complicated structure, and the mold 2 is miniaturized and modularized. Is possible. Further, since the mold 2 can be easily removed, the mold 2 can be easily replaced. Therefore, for example, a mold for producing a relatively small amount of parts can be easily manufactured.

Next, the press device 100 will be described.

The pair of upper fixing plates 10 are provided in parallel with each other in the pressing direction. The upper fixing plate 10 is driven by a servomotor via the slide 1 to move the upper mold 4 up and down with respect to the plate material 9.

The pair of upper fixing plates 10 are fixed to each other by a pair of vertical plates 11 provided in parallel with each other in a direction perpendicular to the pressing direction. The pair of upper fixing plates 10 and the pair of vertical plates 11 form a rectangular cage 10A. The cage 10A is attached to the bottom of the slide 1. The cage 10A moves integrally with the slide 1 when the slide 1 driven by the servomotor moves in the pressing direction.

Further, a guide 12 is provided between the pair of upper fixing plates 10. The guide 12 is provided along the pressing direction and inserts a pair of upper movable plates 20 and 30.

Gas cylinders 23 and 33 are attached to the lower surface of the upper fixing plate 10 on the upper side. The gas cylinders 23 and 33 move in the pressing direction together with the upper fixing plate 10. The lower upper fixing plate 10 has an insertion hole through which the upper rods 25 and 35 are inserted, and a guide hole 13 through which the guide 26 is inserted. A stop block 45 and a plate material support portion 46a are provided on the lower surface of the lower upper fixing plate 10.

The stop block 45 faces the stop block 44 attached to the lower fixing plate 42. The stop block 45 defines the bottom dead center of the slide 1 when it comes into contact with the stop block 44.

The plate material support portion 46a faces the plate material support portion 46b attached to the lower fixing plate 42. The plate material support portion 46a supports the supplied plate material 9 from above. The plate material support portion 46a holds the plate material 9 sandwiched between the plate material support portion 46a and the plate material support portion 46b.

A plurality of upper movable plates 20 and 30 are provided, and are arranged so as to be laminated in the press direction between the pair of upper fixing plates 10, that is, in the cage 10A. Here, a pair of upper movable plates 20 and 30 is provided, but three or more may be provided depending on the pressing work performed by the pressing device 100.

The upper movable plates 20 and 30 are provided so as to be displaceable in the press direction with respect to the upper fixing plate 10. The upper movable plates 20 and 30 are pressed by the upper fixing plate 10 while the upper fixing plate 10 is moving in the pressing direction.

The upper movable plate 20 has a base plate 21, a rod holding plate 22, and a guide hole 24. When the cage 10A descends in the pressing direction, the gas cylinder 23 comes into contact with the upper movable plate 20. The upper movable plate 20 is pressed by the slide 1 via the gas cylinder 23 and moves in the pressing direction. The upper movable plate 20 corresponds to the first upper movable plate, and the gas cylinder 23 corresponds to the first cylinder.

The base plate 21 is provided parallel to the upper fixing plate 10. The base plate 21 can move up and down while maintaining a state parallel to the upper fixing plate 10. The upper end of the upper rod 25 comes into contact with the lower surface of the base plate 21.

The rod holding plate 22 comes into contact with the lower surface of the base plate 21. The rod holding plate 22 holds the upper rod 25 and the guide 26 so as to be perpendicular to the base plate 21. The rod holding plate 22 has the same area in the horizontal direction orthogonal to the pressing direction as the base plate 21, but may be formed smaller than the base plate 21 as long as the upper rod 25 can be held.

The guide hole 24 allows the upper movable plate 20 to be moved only in the press direction by the guide 12 through which it is inserted.

The guide 26 inserts the upper movable plate 30 and the lower upper fixing plate 10. The guide 26 guides the movement of the upper movable plates 20 and 30 with respect to the upper fixed plate 10 in the pressing direction.

The upper movable plate 30 is laminated and arranged on the lower side of the upper movable plate 20. The upper movable plate 30 has a base plate 31, a rod holding plate 32, a guide hole 34, a through hole 36, and a through hole 37. When the cage 10A descends in the pressing direction, the gas cylinder 33 comes into contact with the upper movable plate 30. The upper movable plate 30 is pressed by the slide 1 via the gas cylinder 33 and moves in the pressing direction. The upper movable plate 30 corresponds to the second upper movable plate, and the gas cylinder 33 corresponds to the second cylinder.

When the upper movable plate 30 is pressed by the slide 1 via the cage 10A, the upper movable plate 30 presses the pressing portion 6a in the pressing direction so that the pressing force of the pressing portion 6a on the plate material 9 can be changed.

The base plate 31 is provided parallel to the upper fixing plate 10. The base plate 31 can move up and down while maintaining a state parallel to the upper fixing plate 10. The upper end of the upper rod 35 comes into contact with the lower surface of the base plate 31.

The rod holding plate 32 comes into contact with the lower surface of the base plate 31. The rod holding plate 32 holds the upper rod 35 so as to be perpendicular to the base plate 31. The rod holding plate 32 has the same area in the horizontal direction orthogonal to the press direction as the base plate 31, but may be formed smaller than the base plate 31 as long as the upper rod 35 can be held.

The gas cylinder 33 is separated from the upper movable plate 30 when the gas cylinder 23 presses the upper movable plate 20 to form the plate material 9 with the drawing punch 6b.

As a result, it is possible to provide a time lag between the processing by the upper movable mold 6 pressed by the upper movable plate 20 and the upper movable mold 6 pressed by the upper movable plate 30. Therefore, a plurality of moldings can be performed in order in one pressing operation.

The guide hole 34 allows the upper movable plate 30 to be moved only in the press direction by the guide 12 through which it is inserted.

The upper rod 25 is inserted into the through hole 36. That is, the upper rod 25 connected to the upper movable plate 20 arranged above is arranged so as to penetrate the upper movable plate 30 arranged below. A guide 26 is inserted through the through hole 37.

The upper rods 25 and 35 are attached at arbitrary positions within the range of the pressing surfaces of the upper movable plates 20 and 30. The mounting positions of the upper rods 25 and 35 with respect to the upper movable plates 20 and 30 can be changed according to the position of the upper movable mold 6.

As a result, the upper rods 25 and 35 can be arranged corresponding to the positions where the upper movable mold 6 is provided even when the mold 2 is replaced.

The upper rod 25 is connected to the upper movable plate 20. The upper rod 25 is provided so as to be able to advance and retreat with respect to the upper movable mold 6, and presses the drawing punch 6b against the plate material 9 in the pressing direction.

The upper rod 35 is connected to the upper movable plate 30. The upper rod 35 is provided so as to be able to advance and retreat with respect to the upper movable mold 6, and presses the pressing portion 6a against the plate material 9 in the pressing direction.

As described above, in the press device 100, the upper movable plates 20 and 30 that can be displaced with respect to the upper fixing plate 10 in the pressing direction and are pressed by the upper fixing plate 10 are provided. Further, when the upper movable plates 20 and 30 are pressed by the upper fixing plate 10, they are pressed in the pressing direction so that the pressing force of the upper movable mold 6 against the plate material 9 can be changed. Therefore, a plurality of moldings can be performed by the upper mold 4 of the mold 2 provided on the upper fixed plate 10 and the upper movable mold 6 connected to the upper movable plates 20 and 30. Therefore, since a plurality of moldings can be performed by providing the upper fixed plate 10 and the upper movable plates 20 and 30, it is not necessary to make the mold 2 a complicated structure. Therefore, it is possible to perform a plurality of moldings in one pressing operation without using a die having a complicated structure.

Further, the press device 100 has a base 41 and a lower fixing plate 42.

The base 41 is formed in a flat plate shape and is installed on the floor surface. The base 41 supports each component constituting the press device 100.

The lower fixing plate 42 is provided between the base 41 and the lower mold 5 so as to be separated from the base 41. A stop block 44 and a plate material support portion 46b are provided on the upper surface of the lower fixing plate 42.

The stop block 44 faces the stop block 45 attached to the upper fixing plate 10. The stop block 44 defines the bottom dead center of the slide 1 when it comes into contact with the stop block 45.

The plate material support portion 46b faces the plate material support portion 46a attached to the upper fixing plate 10. The plate material support portion 46b supports the supplied plate material 9 from below. The plate material support portion 46b is urged in the press direction by the spring 46c. The plate material support portion 46b sandwiches and holds the plate material 9 between the plate material support portion 46a and the plate material support portion 46a.

The base 41 and the lower fixing plate 42 are fixed to each other by a pair of vertical plates 43 provided in parallel with each other in a direction perpendicular to the pressing direction. The base 41, the lower fixing plate 42, and the pair of vertical plates 43 form a rectangular cage 40A.

Next, a pressing method using the pressing device 100 will be described with reference to FIGS. 2 to 5. 2 to 5 are diagrams for explaining the first to fourth steps in the pressing method using the pressing device 100, respectively.

As shown in FIG. 2, when the slide 1 lowers the cage 10A in the pressing direction, the pressing portion 6a comes into contact with the plate material 9 and pushes down the plate material 9 as it is in the pressing direction. Similarly, the plate material support portion 6d and the plate material support portion 46a come into contact with the plate material 9 and push down the plate material 9 as it is in the pressing direction. Then, the plate material 9 is held between the pressing portion 6a and the pressing portion 5a, between the plate material supporting portion 6d and the plate material supporting portion 5e, and between the plate material supporting portion 46a and the plate material supporting portion 46b.

At this time, the plate material support portion 5e is pushed down by the plate material support portion 6d to compress the spring 5g. The plate material support portion 5f is pushed down by the pressing portion 6a to compress the spring 5h. The plate material support portion 46b is pushed down by the plate material support portion 46a to compress the spring 46c. As a result, the lower surface of the plate member 9 comes into contact with the pressing portion 5a.

As shown in FIG. 3, when the slide 1 further lowers the cage 10A in the pressing direction, the gas cylinder 23 comes into contact with the upper movable plate 20. The gas cylinder 23 presses the upper movable plate 20 in the pressing direction. The pressing force of the gas cylinder 23 is transmitted from the upper movable plate 20 to the drawing punch 6b via the upper rod 25. As a result, the drawing punch 6b presses the plate material 9 against the drawing die 5b to perform drawing.

At this time, the pressing portion 6a is urged by the spring 6f, and the force for pressing the plate member 9 is in a relatively small state suitable for drawing.

As shown in FIG. 4, when the slide 1 further lowers the cage 10A in the pressing direction, it is pushed up by the upper rod 35 to raise the upper movable plate 30 and come into contact with the gas cylinder 33. The gas cylinder 33 presses the upper movable plate 30 in the pressing direction. The pressing force of the gas cylinder 33 is transmitted from the upper movable plate 30 to the pressing portion 6a via the upper rod 35.

At the same time, a pair of piercing punches 6c attached to the lower part of the lower upper fixing plate 10 enters the piercing die 5c to perform piercing processing to make a hole in the plate material 9.

At this time, the pressing portion 6a is pressed by the upper movable plate 30, and the force for pressing the plate material 9 is in a relatively large state suitable for piercing and trimming. That is, the pressing force of the pressing portion 6a on the plate material 9 is changed.

As shown in FIG. 5, when the slide 1 further lowers the cage 10A in the pressing direction, a trim process is performed in which the trim die portion 4a of the upper die 4 shears the plate material 9 with the trim die 5d of the lower die 5. ..

At this time as well, the pressing portion 6a is pressed by the upper movable plate 30, and the force for pressing the plate material 9 is in a relatively large state suitable for piercing and trimming.

As described above, by changing the force with which the pressing portion 6a presses the plate material 9 during the pressing operation, the plate material 9 can be drawn, pierced, and trimmed in one pressing operation (one stroke). It can be carried out. Therefore, it is possible to perform a plurality of moldings in one pressing operation without using a die having a complicated structure.

According to the above first embodiment, the following effects are obtained.

The press device 100 for molding the plate material 9 by the mold 2 having the upper mold 4 and the upper movable mold 6 provided so as to be able to move forward and backward with respect to the upper mold 4 is in the pressing direction in which the mold 2 presses the plate material 9. A pair of upper fixing plates 10 provided apart from each other and driven by a servomotor to raise and lower the upper die 4 with respect to the plate material 9 and a pair of upper fixing plates 10 are pressed against the upper fixing plate 10. The upper movable plates 20 and 30 are provided so as to be displaceable in the direction and press the upper movable mold 6 in the pressing direction so that the pressing force of the upper movable mold 6 against the plate material 9 can be changed when pressed by the upper fixing plate 10.

Further, in the pressing method of forming the plate material 9 by the mold 2 having the upper mold 4 and the upper movable mold 6 provided so as to be able to advance and retreat with respect to the upper mold 4, the pressing direction in which the mold 2 presses the plate material 9. The process of forming the plate material 9 by pressing the upper mold 4 with the upper fixed plate 10 moving to, and pressing the upper movable mold 6 with the upper movable plates 20 and 30 pressed by the upper fixed plate 10 so that the pressing pressure can be changed. A step of forming the plate material 9 is provided.

In these configurations, the upper movable plates 20 and 30 which can be displaced in the pressing direction with respect to the upper fixing plate 10 and are pressed by the upper fixing plate 10 are provided. Further, when the upper movable plates 20 and 30 are pressed by the upper fixing plate 10, they are pressed in the pressing direction so that the pressing force of the upper movable mold 6 against the plate material 9 can be changed. Therefore, a plurality of moldings can be performed by the upper mold 4 of the mold 2 provided on the upper fixed plate 10 and the upper movable mold 6 connected to the upper movable plates 20 and 30. Therefore, since a plurality of moldings can be performed by providing the upper fixed plate 10 and the upper movable plates 20 and 30, it is not necessary to make the mold 2 a complicated structure. Therefore, it is possible to perform a plurality of moldings in one pressing operation without using a die having a complicated structure.

Further, a plurality of upper movable plates 20 and 30 are provided, and are arranged so as to be laminated in the press direction between the pair of upper fixing plates 10.

Further, an upper rod 25, 35 which is connected to the upper movable plates 20 and 30 and is provided so as to be able to advance and retreat to the upper movable mold 6 and press the upper movable mold 6 against the plate material 9 in the pressing direction is provided. The upper rod 25 connected to the upper movable plate 20 arranged in the above is arranged so as to penetrate the upper movable plate 30 arranged below.

Further, the upper rods 25 and 35 are attached to arbitrary positions within the range of the pressing surfaces of the upper movable plates 20 and 30, and the attachment positions with respect to the upper movable plates 20 and 30 are set according to the position of the upper movable mold 6. It can be changed.

In these configurations, the mounting positions of the upper rods 25 and 35 connected to the upper movable plates 20 and 30 stacked in the press direction are changed within the range of the pressing surfaces of the upper movable plates 20 and 30. It is possible. Therefore, even when the mold 2 is replaced, the upper rods 25 and 35 can be arranged corresponding to the position where the upper movable mold 6 is provided.

Further, the press device 100 has a gas cylinder 23 that moves in the pressing direction together with the upper fixing plate 10 and presses the upper movable plate 20, and a gas cylinder that moves in the pressing direction together with the upper fixing plate 10 and presses the upper movable plate 30. 33 is further provided, and the gas cylinder 33 is separated from the upper movable plate 30 when the gas cylinder 23 presses the upper movable plate 20 to form the plate material 9 with the upper movable mold 6.

According to this configuration, it is possible to provide a time difference between the processing by the upper movable mold 6 pressed by the upper movable plate 20 and the upper movable mold 6 pressed by the upper movable plate 30. Therefore, a plurality of moldings can be performed in order in one pressing operation.

Further, the upper movable mold 6 is pressed so as to form the plate material 9 with the upper rods 25 and 35 in contact with each other.

Further, the upper mold 4 is provided detachably with respect to the upper fixing plate 10, the lower mold 5 is provided detachably with respect to the lower fixing plate 42, and the upper mold 4 is provided with the upper fixing plate 42 in the mold 2. The lower mold 5 is removed from the lower fixing plate 42 and the upper rods 25 and 35 can be replaced in a state of being separated from the upper movable mold 6.

According to these configurations, the upper rods 25 and 35 and the upper movable mold 6 are only in contact with each other when the plate member 9 is pressed. Therefore, the mold 2 can be easily replaced by simply removing the upper mold 4 and the lower mold 5 from the upper fixing plate 10 and the lower fixing plate 42, respectively, and separating the upper rods 25 and 35.

In this way, all the configurations for generating the machining force in the mold 2 are integrated in the cage 10A, so that the mold 2 does not need to have a complicated structure, and the mold 2 is miniaturized and modularized. Is possible. Further, since the mold 2 can be easily removed, the mold 2 can be easily replaced. Therefore, for example, a mold for producing a relatively small amount of parts can be easily manufactured.

(Second Embodiment)
Next, with reference to FIGS. 6 to 14, the press device 200 according to the second embodiment of the present invention and the press method using the press device 200 will be described. In each of the following embodiments, the points different from those of the first embodiment will be mainly described, and the same reference numerals will be given to the configurations having the same functions, and the description thereof will be omitted.

First, the overall configuration of the press device 200 will be described with reference to FIG. FIG. 6 is a block diagram of the press device 200.

The press device 200 is a servo press device in which the slide 1 driven by a servomotor (not shown) as a drive mechanism moves up and down. The press device 200 press-molds the plate material 9 with the mold 202. The press device 200 includes a pair of upper fixing plates 10, an upper movable plate 20, an upper rod 25, a base 41, a lower fixing plate 42, and a lower movable plate 50.

First, the die 202 mounted on the press device 200 and used will be described.

The mold 202 has an upper mold 204, a lower mold 205, an upper movable mold 206, and a lower movable mold 207. Here, the die 202 performs a first drawing process, a trim processing, a flange processing, a piercing process, and a second drawing process on the plate material 9 in one pressing operation.

The upper mold 204 is attached to the lower part of the lower upper fixing plate 10. The upper mold 204 is provided so as to face the upper side in the pressing direction with respect to the plate material 9. The upper die 204 is provided with an upper movable die 206 that can move forward and backward in the pressing direction with respect to the upper die 204. The upper die 204 has a piercing punch 204c and a drawing punch 204e.

The piercing punch 204c is attached to the lower part of the lower upper fixing plate 10. The piercing punch 204c performs piercing processing on the plate material 9 together with the piercing die 207c described later. A plurality of piercing punches 204c are provided side by side in the depth direction (vertical direction on the paper surface).

The drawing punch 204e is integrally formed with the piercing punch 204c. Therefore, a plurality of diaphragm punches 204e are also provided side by side in the depth direction. The drawing punch 204e performs drawing processing on the plate material 9 together with the drawing die 207e described later.

The piercing punch 204c is formed at the tip of the rod. The drawing punch 204e is formed on the outer circumference at a position slightly separated from the tip of the same rod. In this way, since the piercing punch 204c and the drawing punch 204e are integrally formed on the same rod, the piercing and drawing can be continuously performed in one press operation (one stroke) simply by lowering the rod in the pressing direction. Can be done.

The lower mold 205 is provided so as to face the lower side in the pressing direction with the plate material 9 sandwiched between the upper mold 204. The lower mold 205 is attached to the upper part of the lower fixing plate 42 supported by the base 41. The lower mold 205 has a trim die 205d.

The trim die 205d trims the plate material 9 together with the trim punch 206d described later. The trim die 205d is formed in a block shape having the same outer shape as the shape of the intermediate member formed by the trim processing. The trim punch 206d enters the inner peripheral space of the trim die 205d during trim processing. The trim die 205d is supported by the lower fixing plate 42 via a spring 205f.

The upper movable mold 206 is provided so as to be able to advance and retreat with respect to the upper mold 204 to form the plate material 9. The upper movable mold 206 has a pressing portion 206a, a drawing punch 206b, a trim punch 206d, and a drawing punch 206g.

The pressing portion 206a presses the plate material 9 when performing the first drawing processing, trim processing, flange processing, piercing processing, and second drawing processing on the plate material 9. The pressing portion 206a is formed in a block shape having the same outer shape as the shape of the product to be molded. The pressing portion 206a is pressed by the lower upper fixing plate 10 via the spring 206f.

The drawing punch 206b is pressed against the plate material 9 by the upper movable plate 20 via the upper rod 25. The drawing punch 206b is pressed so as to form the plate material 9 in a state where the upper rod 25 is in contact with the drawing punch 206b. The drawing punch 206b draws the plate material 9 together with the drawing die 207b described later.

The inner circumference of the trim punch 206d is formed to have the same shape as the outer shape of the intermediate member to be molded. The trim punch 206d punches the outer periphery of the plate material 9 pressed by the pressing portion 206a to form the outer shape of the intermediate member formed by the trim processing.

The drawing punch 206g is formed integrally with the trim punch 206d on the inner circumference of the trim punch 206d. The drawing punch 206g is drawn on the plate material 9 together with the drawing die 207g described later.

The lower movable mold 207 is provided so as to be able to advance and retreat with respect to the lower mold 205 to form the plate material 9. The lower movable mold 207 has a pressing portion 207a, a drawing die 207b, a piercing die 207c, a drawing die 207e, a drawing die 207g, and a plate material supporting portion 207h.

The pressing portion 207a holds the plate member 9 sandwiched between the pressing portion 207a and the pressing portion 206a.

The drawing die 207b draws the plate material 9 together with the drawing punch 206b. The drawing punch 206b enters the drawing die 207b during drawing. The drawing die 207b is integrally formed with the upper end portion of the pressing portion 207a.

The piercing die 207c performs piercing processing on the plate material 9 together with the piercing punch 204c. The piercing punch 204c enters the accommodating hole of the piercing die 207c during piercing. A plurality of piercing dies 207c are provided side by side in the depth direction (vertical direction on the paper surface). The pierce die 207c is integrally formed with the upper end portion of the pressing portion 207a. The piercing die 207c is formed on the inner circumference of the drawing die 207b.

The drawing die 207e performs drawing processing on the plate material 9 together with the drawing punch 204e. The drawing punch 204e enters the drawing die 207e during drawing. The drawing die 207e is formed integrally with the piercing die 207c. Therefore, a plurality of diaphragm dies 207e are also provided side by side in the depth direction.

The drawing die 207g performs drawing processing on the plate material 9 together with the drawing punch 206g. The drawing punch 206g enters the space between the outer circumference of the drawing die 207g and the trim die 205d during drawing. The drawing die 207g is formed on the outer circumference of the pressing portion 207a.

The plate material support portion 207h holds the plate material 9 between the trim die 205d and the trim punch 206d when the plate material 9 is trimmed.

The upper mold 204 is detachably provided with respect to the upper fixing plate 10, and the lower mold 205 is detachably provided with respect to the lower fixing plate 42. Further, the upper rod 25 and the upper movable mold 206 are only in contact with each other when pressing the plate material 9. The mold 202 can be replaced in a state where the upper mold 204 is removed from the upper fixing plate 10 and the lower mold 205 is removed from the lower fixing plate 42 and the upper rod 25 is separated from the upper movable mold 206.

As described above, since all the configurations for generating the processing force in the mold 202 are integrated in the cage 10A and the cage 40A, it is not necessary to make the mold 202 a complicated structure, and the mold 202 can be miniaturized. And modularization is possible. Further, since the mold 202 can be easily removed, the mold 202 can be easily replaced. Therefore, for example, a mold for producing a relatively small amount of parts can be easily manufactured.

Next, the press device 200 will be described.

The pair of upper fixing plates 10 are provided in parallel with each other in the pressing direction. The pair of top fixing plates 10 together with the pair of vertical plates 11 form a rectangular cage 10A.

A pair of gas cylinders 23 are attached to the lower surface of the upper fixing plate 10 on the upper side. The gas cylinder 23 moves in the pressing direction together with the upper fixing plate 10. The lower upper fixing plate 10 has an insertion hole through which the upper rod 25 is inserted. A stop block 45 is provided on the lower surface of the lower upper fixing plate 10.

The upper movable plate 20 is arranged between the pair of upper fixing plates 10, that is, in the cage 10A. Here, a single upper movable plate 20 is provided.

The upper movable plate 20 has a base plate 21 and a rod holding plate 22. The gas cylinder 23 is in contact with the upper surface of the upper movable plate 20. When the cage 10A descends in the pressing direction, the gas cylinder 23 contracts. When the slide 1 lowers the cage 10A, the upper movable plate 20 rises in the cage 10A while contracting the gas cylinder 23.

The base plate 21 is provided parallel to the upper fixing plate 10. The base plate 21 can move up and down while maintaining a state parallel to the upper fixing plate 10. The upper end of the upper rod 25 comes into contact with the lower surface of the base plate 21.

The rod holding plate 22 comes into contact with the lower surface of the base plate 21. The rod holding plate 22 holds the upper rod 25 and the guide 26 so as to be perpendicular to the base plate 21. The rod holding plate 22 has the same area in the horizontal direction orthogonal to the pressing direction as the base plate 21, but may be formed smaller than the base plate 21 as long as the upper rod 25 can be held.

The upper rod 25 is connected to the upper movable plate 20. The upper rod 25 is provided so as to be able to advance and retreat with respect to the upper die 204, and presses the drawing punch 206b against the plate material 9 in the pressing direction.

The base 41 is formed in a flat plate shape and is installed on the floor surface. The base 41 supports each component constituting the press device 200. The gas cylinder 63 is inserted into the base 41 from below.

The lower fixing plate 42 is provided between the base 41 and the lower mold 205 so as to be separated from the base 41. A stop block 44 is provided on the upper surface of the lower fixing plate 42. A guide 65 is provided on the lower surface of the lower fixing plate 42.

The base 41 and the lower fixing plate 42 are fixed to each other by a pair of vertical plates 43 provided in parallel with each other in a direction perpendicular to the pressing direction. The base 41, the lower fixing plate 42, and the pair of vertical plates 43 form a rectangular cage 40A.

The guide 65 is provided along the pressing direction and inserts a guide hole 66 formed in the lower movable plate 50. The guide 65 guides the lower movable plate 50 so that it can move up and down while maintaining a parallel state.

The lower movable plate 50 is arranged between the base 41 and the lower fixing plate 42, that is, in the cage 40A. The lower movable plate 50 is provided so as to be displaceable in the press direction with respect to the lower fixing plate 42. The lower movable plate 50 is supported by the base 41 via the fixing block 62 in a state where the fixing block 62 described later is inserted. The lower movable plate 50 is supported upward by the gas cylinder 63 when the fixing block 62 is not inserted.

A holding portion 207a of the lower movable mold 207 is provided on the upper surface of the lower movable plate 50. When the cage 10A is lowered, the lower movable plate 50 is lowered so as to be separated from the lower fixed plate 42 by pressing the pressing portion 207a by the upper movable mold 6.

The gas cylinder 63 is inserted from below the base 41 and advances and retreats with respect to the lower movable plate 50. The gas cylinder 63 can come into contact with the lower movable plate 50. The gas cylinder 63 is driven so as to move in the vertical direction by an actuator such as an air cylinder or an electric motor.

A fixing block 61 for fixing the position of the upper movable plate 20 in the pressing direction with respect to the upper fixing plate 10 is detachably provided between the upper surface of the upper movable plate 20 and the lower surface of the upper fixing plate 10.

The fixed block 61 is inserted in the depth direction (the direction perpendicular to the paper surface). In the state where the fixing block 61 is not inserted, the upper movable plate 20 can ascend in the cage 10A while contracting the gas cylinder 23. On the other hand, in the state where the fixing block 61 is inserted, the upper movable plate 20 cannot move in the pressing direction from the position (position shown in FIG. 6) in contact with the lower upper fixing plate 10.

Similarly, a fixing block 62 for fixing the position of the lower movable plate 50 in the pressing direction with respect to the base 41 is detachably provided between the lower surface of the lower movable plate 50 and the upper surface of the base 41.

The fixed block 62 is inserted in the depth direction (paper surface vertical direction). In the state where the fixing block 62 is not inserted, the lower movable plate 50 can rise in the cage 40A while contracting the gas cylinder 63. On the other hand, in the state where the fixing block 62 is inserted, the lower movable plate 50 cannot move in the pressing direction from the position in contact with the lower fixing plate 42 (the position shown in FIG. 6).

The fixed block 61 and the fixed block 62 are each driven by an actuator such as an air cylinder or an electric motor.

Next, a pressing method using the pressing device 200 will be described with reference to FIGS. 7 to 13. 7 to 13 are diagrams for explaining the first to seventh steps in the pressing method using the pressing device 200, respectively.

As shown in FIG. 7, when the slide 1 lowers the cage 10A in the pressing direction, the pressing portion 206a comes into contact with the plate material 9. The pressing portion 206a is pressed against the plate member 9 by the urging force of the spring 206f. The pressing portion 206a holds the plate material 9 between the pressing portion 206a and the pressing portion 207a.

At this time, the fixing block 61 is inserted between the upper fixed plate 10 and the upper movable plate 20. Therefore, the upper movable plate 20 is in a state where it cannot move in the pressing direction with respect to the upper fixing plate 10. Further, a fixing block 62 is inserted between the lower fixed plate 42 and the lower movable plate 50. Therefore, the lower movable plate 50 is in a state where it cannot move in the pressing direction with respect to the lower fixed plate 42.

As shown in FIG. 8, when the slide 1 further lowers the cage 10A in the pressing direction, the drawing punch 206b comes into contact with the plate material 9. Since the upper movable plate 20 descends together with the cage 10A, the force with which the slide 1 lowers the cage 10A is transmitted to the throttle punch 206b via the upper rod 25. As a result, the drawing punch 206b presses the plate material 9 against the drawing die 207b, and the first drawing process is performed.

At this time, the pressing portion 6a is urged by the spring 206f, and the force for pressing the plate member 9 is in a relatively small state suitable for drawing.

Next, as shown in FIG. 9, the slide 1 raises the cage 10A slightly so that no force is transmitted to the fixed block 61. In this state, the fixed block 61 is removed. When the fixing block 61 is removed, the upper movable plate 20 can move in the pressing direction with respect to the upper fixing plate 10.

At the same time, the gas cylinder 63 pushes up the lower movable plate 50 and presses it against the lower fixed plate 42. As a result, the force is not transmitted from the lower movable plate 50 to the fixed block 62. In this state, the fixed block 62 is removed. When the fixing block 62 is removed, the lower movable plate 50 can move in the pressing direction with respect to the lower fixing plate 42.

As shown in FIG. 10, when the slide 1 further lowers the cage 10A in the pressing direction, the trim punch 206d lowers the cage 10A while holding the plate member 9 between the plate member support portion 207h and the plate member support portion 207h. As a result, trim processing is performed in which the trim punch 206d shears the plate material 9 with the trim die 205d. As a result, the outer shape of the plate member 9 is formed into a predetermined shape.

At this time, the drawing punch 206b is pressed in the pressing direction by the upper rod 25, and the drawing die 207b moves so as to push down the lower movable plate 50 by this pressing force. As the drawing die 207b is lowered in this way, the trim die 205d is relatively raised, and the plate material 9 can be trimmed with the trim punch 206d.

Next, as shown in FIG. 11, the slide 1 raises the cage 10A, and the gas cylinder 63 pushes up the lower movable plate 50 to a position where the lowered lower movable plate 50 comes into contact with the lower fixing plate 42. Push up. Then, the fixing block 62 is inserted again between the lower fixed plate 42 and the lower movable plate 50. As a result, the lower movable plate 50 cannot move in the pressing direction with respect to the lower fixed plate 42.

As shown in FIG. 12, when the slide 1 lowers the cage 10A again in the pressing direction, the upper movable plate 20 is pushed up by the upper rod 25 and rises apart from the lower upper fixing plate 10. At this time, the gas cylinder 23 is compressed and contracted by the force transmitted from the upper movable plate 20.

At the same time, the piercing punch 204c attached to the lower part of the lower upper fixing plate 10 enters the piercing die 207c to perform piercing processing to make a hole in the plate material 9.

At this time, the throttle punch 206b is pressed by the upper movable plate 30 and functions as a holding portion. The force with which the drawing punch 206b presses the plate material 9 is in a relatively large state suitable for piercing.

At the same time, the drawing punch 206g enters the space around the holding portion 207a. As a result, the drawing punch 206g draws the outer circumference of the plate material 9 together with the drawing die 207g.

As shown in FIG. 13, when the slide 1 further lowers the cage 10A in the pressing direction, the piercing punch 204c attached to the lower portion of the lower upper fixing plate 10 is further lowered. As a result, the drawing punch 204e formed integrally with the piercing punch 204c comes into contact with the plate material 9. As a result, the drawing punch 204e presses the plate material 9 against the drawing die 207e to perform the second drawing process to narrow the circumference of the hole formed by the piercing punch 204c. In this way, the piercing punch 204c for piercing is first contacted with the plate material 9 to perform molding, and then the drawing punch 206g for second drawing is in contact with the plate material 9 for molding.

Here, with reference to FIGS. 14 (a) to 14 (e), the piercing process shown in FIG. 12 and the drawing process shown in FIG. 13 will be described in detail.

As shown in FIG. 14A, when the slide 1 lowers the cage 10A in the pressing direction, the tip of the piercing punch 204c comes into contact with the plate material 9. When the cage 10A is further lowered as it is, as shown in FIG. 14B, the pierced punch 204c presses the plate material 9, and the pressed portion of the plate material 9 projects downward to form a protruding portion 9a. The periphery thereof is deformed so as to bulge downward to form a bulging portion 9b.

As shown in FIG. 14 (c), when the slide 1 further lowers the cage 10A in the pressing direction, the tip of the piercing punch 204c pierces the plate material 9. At this time, since the bulging portion 9b is not supported from below, the piercing punch 204c pierces the plate material 9, and at the same time, the bulging portion 9b around the piercing hole formed by the piercing is pre-drawn. Is done.

As shown in FIG. 14D, when the slide 1 further lowers the cage 10A in the pressing direction, the tapered portion 204f that swells in a tapered shape on the outer circumference of the piercing punch 204c pushes the piercing hole toward the outer circumference.

As shown in FIG. 14E, when the cage 10A is further lowered as it is, the drawing punch 204e comes into contact with the plate material 9. Then, the drawing punch 204e draws the plate material 9 with the drawing die 207e. As a result, the bulging portion 9b that has been bulged by the preliminary drawing process during the piercing process can be formed into a target shape. At the same time, since the large diameter portion 204g formed continuously with the tapered portion 204f of the piercing punch 204c is inserted into the piercing hole, the inner diameter of the piercing hole can also be formed to the target inner diameter.

Usually, in press working, it is common to perform piercing after drawing. However, in the press device 200, the preliminary drawing, the piercing, and the drawing are continuously performed as shown in FIGS. 14 (a) to 14 (e), so that the drawing is performed after the piercing. Can be done.

As described above, in the press device 200, the slide 1 rises and falls after the first first drawing, and trimming or piercing is performed before the second second drawing. Specifically, the piercing process is performed after the first drawing process and the trim processing are performed, and the second drawing process is performed after the piercing process. Therefore, the first drawing process, the trim processing, the piercing process, and the second drawing process can be performed on the plate material 9 in one pressing operation. Therefore, it is possible to perform a plurality of moldings in one pressing operation without using a die having a complicated structure.

According to the second embodiment described above, the following effects are obtained.

By a mold 202 having an upper mold 204, an upper movable mold 206 provided so as to be able to advance and retreat to the upper mold 204, a lower mold 205, and a lower movable mold 207 provided to be able to advance and retreat to the lower mold 205. The press device 200 for forming the plate material 9 is provided with the dies 202 separated from each other in the pressing direction for pressing the plate material 9, and is driven by a servomotor to move the upper mold 204 up and down with respect to the plate material 9. An upper movable plate that is provided between the plate 10 and the pair of upper fixing plates 10 so as to be displaceable in the pressing direction with respect to the upper fixing plate 10 and moves the upper movable mold 206 in the pressing direction with respect to the upper mold 204. 20 and the base 41, the lower fixing plate 42 provided apart from the base 41 between the base 41 and the lower mold 205, and the base 41 and the lower fixing plate 42. The lower movable plate 50 is provided so as to be displaceable in the press direction with respect to the lower fixed plate 42, and the lower movable mold 207 is moved in the press direction with respect to the 205 lower mold.

In this configuration, an upper movable plate 20 that can be displaced in the press direction with respect to the upper fixing plate 10 and a lower movable plate 50 that can be displaced in the pressing direction with respect to the lower fixing plate 42 are provided. Therefore, it is connected to the upper mold 204 provided on the upper fixing plate 10, the upper movable mold 206 connected to the upper movable plate 20, the lower mold 205 provided on the lower fixing plate 42, and the lower movable plate 50. A plurality of moldings can be performed by the lower movable mold 207. Therefore, since a plurality of moldings can be performed by providing the upper movable plate 20 and the lower movable plate 50, it is not necessary to make the mold 202 a complicated structure. Therefore, it is possible to perform a plurality of moldings in one pressing operation without using a die having a complicated structure.

Further, a mold having an upper mold 204, an upper movable mold 206 provided so as to be able to advance and retreat with respect to the upper mold 204, a lower mold 205, and a lower movable mold 207 provided so as to be movable with respect to the lower mold 205. In the pressing method of forming the plate material 9 by 202, the upper die 204 is moved in the pressing direction in which the die 202 presses the plate material 9 by the slide 1 driven by the servo motor, and the pressing methods are drawing, piercing, and pressing. After the first drawing, which is the first drawing including trimming, the slide 1 rises to make the lower movable mold 207 immovable, and then lowers again, which is the second drawing. Trim processing or piercing processing is performed before the second drawing processing.

In this configuration, the slide 1 lowered after the first first drawing is raised to make the lower movable mold 207 immovable, and then the slide 1 is lowered again to perform trimming or piercing. Do. As a result, when the slide 1 is raised, the fixing block 62 can be securely inserted to fix the position of the lower movable plate 50 with respect to the base 41 in the pressing direction. Therefore, the force with which the lower movable mold 207 presses the plate material 9 can be switched from a relatively small state suitable for the first drawing process to a relatively large state suitable for trim processing and piercing processing.

Further, the pressing method for forming the plate material 9 by the mold 202 having the upper mold 204 and the upper movable mold 206 provided so as to be able to advance and retreat to the upper mold 204 includes drawing processing and piercing processing, and piercing processing is performed. The piercing punch 204c to be performed and the drawing punch 204e to be drawn are integrally formed, and the piercing punch 204c to be pierced first contacts the plate material 9, and then the drawing punch 204e to be drawn hits the plate material 9. Perform molding in contact.

According to this configuration, the piercing punch 204c for piercing and the drawing punch 204e for drawing are integrally formed, so that the cage 10A can be lowered by the slide 1 to perform one pressing operation (one stroke). ) Can be used for piercing and drawing in succession.

(Third Embodiment)
Next, with reference to FIGS. 15 to 20, the press device 300 according to the third embodiment of the present invention and the press method using the press device 300 will be described.

First, the overall configuration of the press device 300 will be described with reference to FIG. FIG. 15 is a block diagram of the press device 300.

The press device 300 is a servo press device in which the slide 1 driven by a servomotor (not shown) as a drive mechanism moves up and down. The press device 300 press-molds the plate material 9 with the mold 302. The press device 300 includes a pair of upper fixed plates 10, an upper movable plate 20, a pair of upper rods 25, a base 41, and a pair of lower movable plates 50 and 52.

First, the die 302 mounted on the press device 300 and used will be described.

The mold 302 has an upper mold 304, a lower mold 305, an upper movable mold 306, and a lower movable mold 307. Here, the die 302 is subjected to a single pressing operation (one stroke), and the plate material 9 is subjected to the first drawing, trimming, flange processing, piercing, and second drawing, as in the second embodiment. It is to be processed.

The upper mold 304 is attached to the lower part of the lower upper fixing plate 10. The upper mold 304 is provided so as to face the upper side in the pressing direction with respect to the plate material 9. The upper die 304 is provided with an upper movable die 306 that can move forward and backward in the pressing direction with respect to the upper die 304. The upper die 304 has a trim punch 304d and a drawing punch 304g. Further, the upper mold 304 has a pierced punch 204c and a drawing punch 204e. Since the piercing punch 204c and the drawing punch 204e are the same as the pressing device 200 according to the second embodiment, detailed description thereof will be omitted.

The inner circumference of the trim punch 304d is formed to have the same shape as the outer shape of the intermediate member to be molded. The trim punch 304d trims the plate material 9 together with the trim die 307d described later. The trim punch 304d punches the outer periphery of the plate material 9 pressed by the pressing portion 306a, which will be described later, to form the outer shape of the intermediate member formed by the trim processing.

The drawing punch 304g is provided on top of the trim punch 304d. Therefore, in the drawing punch 304g, when the cage 10A is lowered, the trim punch 304d trims the plate material 9, and then the plate material 9 is continuously drawn. The drawing punch 304g is drawn together with the drawing die 305g on the plate material 9.

The lower mold 305 is provided facing the upper mold 304 on the lower side in the pressing direction with the plate material 9 interposed therebetween. The lower mold 305 is attached to the upper part of the base 41. The lower mold 305 has a pressing portion 305a, a drawing die 305b, a piercing die 305c, a drawing die 305e, and a drawing die 305g.

The pressing portion 305a holds the plate member 9 sandwiched between the pressing portion 306a and the pressing portion 306a described later.

The drawing die 305b draws the plate material 9 together with the drawing punch 306b described later. The drawing punch 306b enters the drawing die 305b during drawing. The drawing die 305b is integrally formed with the upper end portion of the pressing portion 305a.

The piercing die 305c pierces the plate 9 together with the piercing punch 204c. The piercing punch 204c enters the accommodating hole of the piercing die 305c during piercing. A plurality of piercing dies 305c are provided side by side in the depth direction (vertical direction on the paper surface). The pierce die 305c is integrally formed with the upper end portion of the pressing portion 305a. The piercing die 305c is formed on the inner circumference of the drawing die 305b.

The drawing die 305e performs drawing processing on the plate material 9 together with the drawing punch 204e. The drawing punch 204e enters the drawing die 305e during drawing. The drawing die 305e is integrally formed with the piercing die 305c. Therefore, a plurality of diaphragm dies 305e are also provided side by side in the depth direction.

The drawing die 305g performs drawing processing on the plate material 9 together with the drawing punch 304g. The drawing punch 304g enters the space around the drawing die 305g during drawing. The drawing die 305g is formed on the outer circumference of the pressing portion 306a.

The upper movable mold 306 is provided so as to be able to advance and retreat with respect to the upper mold 304 to form the plate material 9. The upper movable mold 306 has a pressing portion 306a and a drawing punch 306b.

The pressing portion 306a presses the plate material 9 when performing the first drawing processing, trim processing, flange processing, piercing processing, and second drawing processing on the plate material 9. The pressing portion 306a is formed in a block shape having the same outer shape as the shape of the product to be molded. The pressing portion 306a is pressed by the pressing member 327 described later via the spring 306f.

The drawing punch 306b is pressed against the plate material 9 by the upper movable plate 20 via the pair of upper rods 25. The drawing punch 306b is pressed so as to form the plate member 9 in a state where the upper rod 25 is in contact with the drawing punch 306b. The drawing punch 306b draws the plate material 9 together with the drawing die 305b. The drawing punch 306b is provided integrally with the pressing member 327 that receives the pressing force of the upper rod 25.

The pressing member 327 supports the pressing portion 306a via the spring 306f. The pressing member 327 is pressed by the upper rod 25 in a state where the cage 10A has not started to descend (the state shown in FIG. 14), and the lower surface is in contact with the upper surface of the drawing punch 304g. When the cage 10A is lowered to some extent, the lower surface of the pressing member 327 is separated from the upper surface of the drawing punch 304g, and the upper movable plate 20 is pushed up via the upper rod 25.

The lower movable mold 307 is provided so as to be able to advance and retreat with respect to the lower mold 305 to form the plate material 9. The lower movable mold 307 has a trim die 307d.

The trim die 307d trims the plate material 9 together with the trim punch 304d. The trim die 307d is formed in a block shape having the same outer shape as the shape of the intermediate member formed by the trim processing. The trim punch 304d enters the inner peripheral space of the trim die 307d during trim processing.

The upper surface of the trim die 307d supports the plate material 9 from below when the plate material 9 is trimmed between the trim die 307d and the trim punch 304d.

The upper mold 304 is detachably provided with respect to the upper fixed plate 10, and the lower mold 305 is detachably provided with respect to the lower movable plate 50. Further, the upper rod 25 and the upper movable mold 306 are only in contact with each other when pressing the plate material 9. The mold 302 can be replaced in a state where the upper mold 304 is removed from the upper fixed plate 10 and the lower mold 305 is removed from the lower movable plate 50 and the upper rod 25 is separated from the upper movable mold 306.

In this way, all the configurations for generating the machining force in the mold 302 are integrated in the cage 10A and between the base 41 and the lower movable plates 50 and 52, so that the mold 302 has a complicated structure. It is not necessary to do so, and the mold 302 can be miniaturized and modularized. Further, since the mold 302 can be easily removed, the mold 302 can be easily replaced. Therefore, for example, a mold for producing a relatively small amount of parts can be easily manufactured.

Next, the press device 300 will be described.

The pair of upper fixing plates 10 are provided in parallel with each other in the pressing direction. The pair of top fixing plates 10 together with the pair of vertical plates 11 form a rectangular cage 10A.

A pair of gas cylinders 23 are attached to the lower surface of the upper fixing plate 10 on the upper side. The gas cylinder 23 moves in the pressing direction together with the upper fixing plate 10. The lower upper fixing plate 10 has an insertion hole through which the upper rod 25 is inserted. A stop block 45 and a gas cylinder 46 are provided on the lower surface of the lower upper fixing plate 10.

The gas cylinder 46 faces the block 54 attached to the lower movable plate 50. The gas cylinder 46 comes into contact with the block 54 by lowering the cage 10A, and then presses the lower movable plate 50 downward through the block 54.

The upper movable plate 20 is arranged between the pair of upper fixing plates 10, that is, in the cage 10A. Here, a single upper movable plate 20 is provided.

The upper movable plate 20 has a base plate 21 and a rod holding plate 22. The gas cylinder 23 is in contact with the upper surface of the upper movable plate 20. When the cage 10A descends in the pressing direction, the gas cylinder 23 contracts. When the slide 1 lowers the cage 10A, the upper movable plate 20 rises in the cage 10A while contracting the gas cylinder 23.

The base plate 21 is provided parallel to the upper fixing plate 10. The base plate 21 can move up and down while maintaining a state parallel to the upper fixing plate 10. The upper end of the upper rod 25 comes into contact with the base plate 21.

The rod holding plate 22 comes into contact with the lower surface of the base plate 21. The rod holding plate 22 holds a pair of upper rods 25 and a pair of guides 26 so as to be perpendicular to the base plate 21. The rod holding plate 22 has the same area in the horizontal direction orthogonal to the pressing direction as the base plate 21, but may be formed smaller than the base plate 21 as long as the upper rod 25 can be held.

The upper rod 25 is connected to the upper movable plate 20. The upper rod 25 is provided so as to be able to advance and retreat with respect to the upper movable mold 306, and presses the drawing punch 206b against the plate material 9 in the pressing direction.

The base 41 is formed in a flat plate shape and is installed on the floor surface. The base 41 supports each component constituting the press device 300. A holding portion 305a, a stop block 44, a gas cylinder 47, a gas cylinder 48, and a guide 49 are vertically provided on the base 41 from the upper surface upward. Further, the base 41 is provided with an ejector 57 for removing the molded product from the lower mold 305.

When the lower movable plate 50 is lowered as the cage 10A is lowered, the gas cylinder 47 comes into contact with the lower surface of the lower movable plate 50 and supports the lower movable plate 50 from below.

The gas cylinder 48 inserts a through hole of the lower movable plate 50. The gas cylinder 48 is in contact with the lower surface of the lower movable plate 52 arranged on the lower movable plate 50, and supports the lower movable plate 52 from below.

The guide 49 inserts the lower movable plate 50. The guide 49 guides the movement of the lower movable plate 50 with respect to the base 41 in the pressing direction.

The lower movable plates 50 and 52 are provided in parallel with the base 41. The lower movable plates 50 and 52 are provided so as to be displaceable in the press direction with respect to the base 41. The lower movable plates 50 and 52 can be moved up and down while maintaining a state parallel to the base 41.

The lower movable plate 50 is supported from below by a spring 51 that abuts on the lower surface. When the lower movable plate 50 descends in the pressing direction while compressing the spring 51, it comes into contact with the gas cylinder 47. A trim die 307d and a pair of blocks 54 are vertically provided on the lower movable plate 50 from the upper surface upward.

The lower movable plate 52 is laminated and arranged on the upper side of the lower movable plate 50. A gas cylinder 48 is in contact with the lower surface of the lower movable plate 52. The lower movable plate 52 has a guide 53.

The guide 53 is provided downward from the lower movable plate 52. The guide 53 inserts the lower movable plate 50. The guide 53 guides the movement of the lower movable plate 52 with respect to the lower movable plate 50 in the pressing direction.

The block 54 is provided so as to surround the lower movable plate 52. The block 54 also guides the movement of the lower movable plate 52 with respect to the lower movable plate 50 in the pressing direction. When the cage 10A is lowered, the gas cylinder 46 comes into contact with the block 54.

The plate material support portion 56 is supported by the spring 56a while floating above the lower movable plate 52. The plate material support portion 56 is urged upward by the spring 56a. The plate material support portion 56 supports the plate material 9 supplied from the outside from below at the supplied height. The plate material support portion 56 is supported by sandwiching the plate material 9 with the pressing portion 306a.

Next, a pressing method using the pressing device 300 will be described with reference to FIGS. 16 to 20. 16 to 20 are views for explaining the first to fifth steps in the pressing method using the press device 300, respectively.

As shown in FIG. 16, when the slide 1 lowers the cage 10A in the pressing direction, the pressing portion 306a comes into contact with the plate member 9. The pressing portion 306a is pressed against the plate member 9 by the urging force of the spring 306f. The pressing portion 306a holds the plate material 9 between the pressing portion 306a and the plate material supporting portion 56.

As shown in FIG. 17, when the slide 1 further lowers the cage 10A in the pressing direction, the lower surface of the trim punch 304d comes into contact with the plate member 9. When the cage 10A is lowered as it is, the gas cylinder 46 comes into contact with the block 54 and presses downward. As a result, the lower movable plate 50 descends and comes into contact with the gas cylinder 47. At this time, the gas cylinder 48 is pressed downward by the lower movable plate 52 and contracts.

Further, the force of the trim punch 304d pressing the plate material support portion 56 downward overcomes the urging force of the spring 56a that urges the plate material support portion 56, and moves the plate material support portion 56 downward. At the same time, the lower surface of the trim die 307d comes into contact with the lower surface of the plate member 9 due to the lowering of the lower movable plate 52.

Then, when the slide 1 further lowers the cage 10A in the pressing direction, the drawing punch 306b comes into contact with the plate material 9. Since the upper movable plate 20 descends together with the cage 10A, the force with which the slide 1 lowers the cage 10A is transmitted to the throttle punch 306b via the upper rod 25. As a result, the drawing punch 306b presses the plate material 9 against the drawing die 305b, and the first drawing process is performed.

At this time, the pressing portion 306a is urged by the spring 306f, and the force for pressing the plate member 9 is in a relatively small state suitable for drawing.

As shown in FIG. 18, when the slide 1 further lowers the cage 10A in the press direction, the trim punch 304d is lowered. As a result, trim processing is performed in which the trim punch 304d shears the plate material 9 with the trim die 307d. As a result, the outer shape of the plate member 9 is formed into a predetermined shape.

At this time, the drawing punch 306b is pressed in the pressing direction by the upper rod 25, and the drawing punch 306b is moved so as to push up the upper movable plate 20 by this pressing force. As a result, the upper movable plate 20 rises apart from the lower upper fixing plate 10. At this time, the gas cylinder 23 is compressed and contracted by the force transmitted from the upper movable plate 20.

Further, the gas cylinder 48 is pressed downward by the lower movable plate 52 and contracts. The gas cylinder 47 and the spring 51 are also pressed downward by the lower movable plate 50 and contracted.

As shown in FIG. 19, when the slide 1 further lowers the cage 10A in the pressing direction, the upper movable plate 20 is pushed up by the upper rod 25 and is raised so as to be further separated from the lower upper fixing plate 10. The gas cylinder 23 is compressed by the force transmitted from the upper movable plate 20 and further contracts.

At the same time, the piercing punch 204c attached to the lower part of the lower upper fixing plate 10 enters the piercing die 305c to perform piercing processing to make a hole in the plate material 9.

At this time, the diaphragm punch 306b is pressed by the upper movable plate 20 and functions as a holding portion. The force with which the drawing punch 306b presses the plate material 9 is in a relatively large state suitable for piercing.

At the same time, the throttle punch 304g enters the space between the holding portion 305a and the outer circumference. As a result, the drawing punch 304g draws the outer circumference of the plate material 9 together with the drawing die 305g.

As shown in FIG. 20, when the slide 1 further lowers the cage 10A in the pressing direction, the piercing punch 204c attached to the lower portion of the lower upper fixing plate 10 is further lowered. As a result, the drawing punch 204e formed integrally with the piercing punch 204c comes into contact with the plate material 9. As a result, the drawing punch 204e presses the plate material 9 against the drawing die 305e to perform the second drawing process to narrow the circumference of the hole formed by the piercing punch 204c. In this way, the piercing punch 204c for piercing is first contacted with the plate material 9 to perform molding, and then the drawing punch 206g for second drawing is in contact with the plate material 9 for molding.

The details of the piercing process shown in FIG. 19 and the drawing process shown in FIG. 20 are as described with reference to FIGS. 14 (a) to 14 (e), and thus the description thereof will be omitted here.

According to the above-mentioned third embodiment, the following effects are obtained.

In the press device 300, trimming or piercing is performed after the first first drawing and before the second drawing. Specifically, the piercing process is performed after the first drawing process and the trim processing are performed, and the second drawing process is performed after the piercing process. Therefore, the first drawing process, the trim processing, the piercing process, and the second drawing process can be performed on the plate material 9 in one pressing operation. Therefore, it is possible to perform a plurality of moldings in one press operation (one stroke) without using a die having a complicated structure.

Further, the pressing method for forming the plate material 9 by the mold 202 having the upper mold 204 and the upper movable mold 206 provided so as to be able to advance and retreat to the upper mold 204 includes drawing processing and piercing processing, and piercing processing is performed. The piercing punch 204c to be performed and the drawing punch 204e to be drawn are integrally formed, and the piercing punch 204c to be pierced first contacts the plate material 9, and then the drawing punch 204e to be drawn hits the plate material 9. Perform molding in contact.

According to this configuration, the piercing punch 204c for piercing and the drawing punch 204e for drawing are integrally formed, so that the cage 10A can be lowered by the slide 1 to perform one pressing operation (one stroke). ) Can be used for piercing and drawing in succession.

Although the embodiments of the present invention have been described above, the above embodiments are only a part of the application examples of the present invention, and the technical scope of the present invention is limited to the specific configuration of the above embodiments. Absent.

100 Pressing device 200 Pressing device 300 Pressing device 2 Mold 4 Upper mold 5 Lower mold 6 Upper movable mold 9 Plate material 10 Upper fixed plate 20 Upper movable plate (1st upper movable plate)
23 Gas cylinder (1st cylinder)
25 Upper rod 30 Upper movable plate (second upper movable plate)
33 Gas cylinder (second cylinder)
35 Upper rod 41 Base 42 Lower fixed plate 50 Lower movable plate 52 Lower movable plate 202 Mold 204 Upper mold 205 Lower mold 206 Upper movable mold 207 Lower movable mold 302 Mold 304 Upper mold 305 Lower mold 306 Upper movable mold Mold 307 Lower movable mold

According to an aspect of the present invention, a press device for molding a plate material by a mold having an upper mold and an upper movable mold provided so as to be able to advance and retreat to the upper mold is a press in which the mold presses the plate material. The press on the upper fixing plate between a pair of upper fixing plates provided apart from each other in the direction and driven by a driving mechanism to raise and lower the upper die with respect to the plate material and the pair of upper fixing plates. displaceably provided in a direction, and an upper movable plate for pressing the pressing direction so as to allow changing the pressing force of the upper movable mold against Once pressed plate material by said upper fixed plate, said upper movable A plurality of plates are provided, and are arranged so as to be laminated in the press direction between the pair of upper fixing plates .

The upper mold 304 is attached to the lower part of the lower upper fixing plate 10. The upper mold 304 is provided so as to face the upper side in the pressing direction with respect to the plate material 9. The upper die 304 is provided with an upper movable die 306 that can move forward and backward in the pressing direction with respect to the upper die 304. The upper die 304 has a trim punch 304d (first upper die) and a drawing punch 304 g (second upper die) . Further, the upper die 304 has a piercing punch 204c and a drawing punch 204e. Since the piercing punch 204c and the drawing punch 204e are the same as the pressing device 200 according to the second embodiment, detailed description thereof will be omitted.

Claims (12)

A press device for forming a plate material with a die having an upper die and an upper movable die provided so as to be able to advance and retreat to the upper die.
A pair of upper fixing plates in which the dies are provided apart from each other in the pressing direction for pressing the plate material and driven by a drive mechanism to raise and lower the upper mold with respect to the plate material.
It is provided between the pair of upper fixing plates so as to be displaceable with respect to the upper fixing plate in the pressing direction, and when pressed by the upper fixing plate, the pressing force on the plate material of the upper movable mold can be changed. With an upper movable plate that presses in the pressing direction,
To prepare
A press device characterized by that. The press device according to claim 1.
A plurality of the upper movable plates are provided, and are arranged so as to be laminated in the pressing direction between the pair of upper fixing plates.
A press device characterized by that. The press device according to claim 2.
Further provided with an upper rod which is connected to the upper movable plate and is provided so as to be able to advance and retreat to the upper movable mold and press the upper movable mold against the plate material in the pressing direction.
The upper rod connected to the upper movable plate arranged above is arranged so as to penetrate the upper movable plate arranged below.
A press device characterized by that. The press device according to any one of claims 1 to 3.
The upper movable plate has a first upper movable plate and a second upper movable plate.
The press device is
A first cylinder that moves in the pressing direction together with the upper fixed plate and presses the first upper movable plate.
A second cylinder that moves in the pressing direction together with the upper fixing plate and presses the second upper movable plate is further provided.
The second cylinder is separated from the second upper movable plate when the first cylinder presses the first upper movable plate to form a plate material with the upper movable mold.
A press device characterized by that. A press device that forms a plate material with a mold having an upper mold, an upper movable mold provided so as to be able to advance and retreat to the upper mold, and a lower movable mold provided to be able to advance and retreat to the lower mold. There,
A pair of upper fixing plates in which the dies are provided apart from each other in the pressing direction for pressing the plate material and driven by a drive mechanism to raise and lower the upper mold with respect to the plate material.
An upper movable plate that is displaceable in the pressing direction with respect to the upper fixing plate between the pair of upper fixing plates and moves the upper movable mold in the pressing direction with respect to the upper mold.
Base and
A lower fixing plate provided between the base and the lower mold at a distance from the base,
A lower movable plate that is displaceable in the pressing direction with respect to the lower fixing plate between the base and the lower fixing plate, and moves the lower movable die in the pressing direction with respect to the lower mold. When,
To prepare
A press device characterized by that. The press device according to any one of claims 1 to 5.
Further provided with an upper rod which is connected to the upper movable plate and is provided so as to be able to advance and retreat to the upper movable mold and press the upper movable mold against the plate material in the pressing direction.
The upper movable mold is pressed so as to form a plate material in a state where the upper rod is in contact with the upper movable mold.
A press device characterized by that. The press device according to claim 6.
The upper mold is detachably provided with respect to the upper fixing plate.
The mold can be replaced in a state where the upper mold is removed from the upper fixing plate and the upper rod is separated from the upper movable mold.
A press device characterized by that. The press device according to any one of claims 1 to 7.
Further provided with an upper rod which is connected to the upper movable plate and is provided so as to be able to advance and retreat to the upper movable mold and press the upper movable mold against the plate material in the pressing direction.
The upper rod is attached to an arbitrary position within the range of the pressing surface of the upper movable plate, and the attachment position with respect to the upper movable plate can be changed according to the position of the upper movable mold.
A press device characterized by that. It is a pressing method in which a plate material is formed by a die having an upper die and an upper movable die provided so as to be able to advance and retreat to the upper die.
A process of forming a plate material by pressing the upper mold with an upper fixing plate in which the mold moves in the pressing direction for pressing the plate material.
A step of forming a plate material by pressing it in the pressing direction so that the pressing force on the plate material of the upper movable mold can be changed by the upper movable plate pressed by the upper fixed plate.
To prepare
A pressing method characterized by that. A press method in which a plate material is formed by a mold having an upper mold, an upper movable mold provided so as to be able to advance and retreat to the upper mold, and a lower movable mold provided to be able to advance and retreat to the lower mold. There,
The upper die is moved in the pressing direction in which the die presses the plate material by the slide driven by the servo press device.
The pressing method is
Including drawing, piercing, and trimming
After the first drawing process, which is the first drawing process, the slide rises to make the lower movable mold immovable, and then lowers again, and the second drawing process, which is the second drawing process. Perform the trim processing or the piercing processing before processing.
A pressing method characterized by that. The press method according to claim 9.
Including drawing, piercing, and trimming
After performing the drawing process and the trim processing, the piercing process is performed, and after the piercing process, the drawing process is performed again.
A pressing method characterized by that. It is a pressing method in which a plate material is formed by a die having an upper die and an upper movable die provided so as to be able to advance and retreat to the upper die.
Including drawing and piercing
The mold for performing the piercing process and the mold for performing the drawing process are integrally formed.
The mold to be pierced first comes into contact with the plate material to perform molding, and then the die to be drawn comes into contact with the plate material to perform molding.
A pressing method characterized by that.

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