JPH06559A - Press device - Google Patents

Abstract

PURPOSE:To make it easy to move a hoop material by making the hoop material and a die for press, etc., easy to slide each other in the press device in which the hoop material is intermittently fed and pressed. CONSTITUTION:A magnetic field generating unit 6 generating an alternating field H is provided at the inlet and the outlet of a space 21 to pass through a hoop material 6 of a press device body 1. A direct current (i) is allowed to flow to the hoop material with a power source 8, the alternating field H is applied to the hoop material 6 by the magnetic field generating unit 9, the hoop material 6 is finely vibrated by the magnetic force operating on the hoop material 6, and the friction force between the dies 2, 3 for press and the hoop material 6 is made smaller.

Description

Detailed Description of the Invention

[0001]

FIELD OF THE INVENTION The present invention relates to a press machine. Specifically, the present invention relates to a pressing device for intermittently pressing a hoop material.

[0002]

BACKGROUND ART In the conventional pressing apparatus, when feeding or carrying a thin hoop material, an air feeder utilizing air pressure is used to pull out the hoop material from the outlet side of the pressing die. I am trying.

However, when the hoop material is fed by the air feeder, a sudden pulling force is applied to the hoop material, and the hoop material 6 is placed at the position of the press die 3 as shown in FIG.
When slack or flexure occurs in the press die 3 due to static friction between the press die 3 and the hoop material 6.
There is a problem in that the slack and flexure of the hoop member 6 cannot be released because it is caught at the corners of the.

Further, there is a problem that a slight static friction between the press die and the hoop material causes a catch when the hoop material is pulled by the air feeder, resulting in a feeding error.

Further, since the hoop material is accurately positioned and pressed in the press die, the hoop material is pressed as shown in FIGS. 10 (a) and 10 (b).
As shown in FIG. 2, pilot holes 6a are provided in the hoop material 6 at regular intervals, and a substantially streamlined pilot pin 4 for fitting the pilot holes 6a in the press die 2 on the upper side of the pressing device. An escape hole 3a for allowing the pilot pin 2a to escape is provided in the protruding press die 3 on the lower side.

Then, as shown in FIG. 10 (a), after the hoop material 6 is fed by an air feeder by a predetermined amount, the upper and lower pressing dies 2, 3 are closed, as shown in FIG. 10 (b). Then, the pilot pin 4 is inserted into the pilot hole 6 a of the hoop material 6. At this time, the edge of the pilot hole 6a is pushed and moved by the outer peripheral surface of the pilot pin 4, and the hoop member 6
There the axis C ₁ of the press mold 3 the center of the upper are forced to move to the y direction of the arrow pilot hole 6a C ₂ and the pilot pin 4 is forced alignment, the hoop material 6 of the upper and lower It is positioned in the press dies 2 and 3.

However, when the hoop member 6 is difficult to slip due to the static frictional force between the hoop member 6 and the pressing die 3, when the pilot pin 4 is forcibly inserted into the pilot hole 6a, as shown in FIG. As shown in FIG.
The edge of was crushed by pilot pin 4,
There was a problem that the hoop material 6 was damaged.

Therefore, in the conventional pressing apparatus, various inconveniences have occurred due to the static friction between the hoop material and the pressing die or the like.

[0009]

SUMMARY OF THE INVENTION The present invention has been made in view of the problems of the above conventional examples, and an object of the present invention is to provide a press device for intermittently feeding a hoop material and performing press working. In order to facilitate the movement of the hoop material by allowing it to slip easily between the hoop material and the pressing die or the like.

[0010]

A first press device of the present invention is a press device for intermittently feeding a hoop material to press the hoop material, wherein a portion of the pressing die that is in sliding contact with the hoop material is pressed. It is characterized in that it is provided with a vibration imparting means for slightly vibrating.

Further, the second pressing device of the present invention comprises means for supplying a direct current to the hoop material, and a changing magnetic field in a direction non-parallel to the direct current flowing direction in the hoop material being supplied with the direct current. It is characterized in that the hoop material is vibrated at a portion which is in sliding contact with the pressing die.

Further, the third pressing device of the present invention comprises means for passing an alternating current through the hoop material, and a constant magnetic field in a direction non-parallel to the direction of the alternating current flowing through the hoop material being fed with the alternating current. Alternatively, it is characterized in that a means for applying a fluctuating magnetic field is provided, and the hoop material is vibrated at a portion which is in sliding contact with the pressing die.

In particular, in the above-mentioned pressing device, the pressing die or the hoop material may be vibrated in the vicinity of the hoop material positioning pilot pin provided in the pressing die.

The fourth pressing device of the present invention is a pressing device for positioning a hoop material by inserting a pilot pin provided in a pressing die into a pilot hole of the hoop material, and performing press working on the hoop material. In the above, it is characterized in that it is provided with a vibration imparting means for slightly vibrating the positioning pilot pin provided in the pressing die.

[0015]

In the first pressing device of the present invention, since the portion of the pressing die that makes sliding contact with the hoop material can be slightly vibrated, the pressing die and the hoop material can remain even when the hoop material is stationary. Dynamic friction can be generated between the hoop members, the frictional force when the hoop member is stationary can be reduced, and the hoop member can be easily moved.

Further, in the second and third pressing devices of the present invention, the magnetic field causes an electromagnetic force to act on the hoop material and the direction of the electromagnetic force to act on the hoop material fluctuates, so that the hoop material vibrates. . As a result, dynamic friction can be generated between the pressing die and the hoop material even when the hoop material is stationary, and the frictional force of the hoop material when stationary can be reduced to facilitate movement of the hoop material.

As a result, according to these press machines,
Since the slippage between the hoop material and the pressing die or the like is improved, the hoop material can be released from the slack and flexure in the pressing die by sliding the hoop material out of the pressing die. In addition, when the hoop material is pulled and sent by an air feeder or the like, the hoop material moves smoothly, and feeding errors are less likely to occur. Further, even when the pilot pin is inserted and positioned in the pilot hole, the hoop material is easily slid and moved by the pilot pin, and there is no fear that the edge of the pilot hole is crushed by the pilot pin.

Further, in the fourth pressing apparatus of the present invention, the positioning pilot pin attached to the pressing die is slightly vibrated, so that when the pilot pin comes into contact with the edge of the pilot hole of the hoop material. The hoop material can be slightly vibrated, and thus the frictional force between the hoop material and the pressing die or the like when stationary can be reduced.

Therefore, even in this press machine,
When the pilot pin is inserted and positioned in the pilot hole, the hoop material is easily slid by the pilot pin, and the hoop material can be reliably positioned without pushing the edge of the pilot hole by the pilot pin. In addition, since slippage between the hoop material and the pressing die etc. is improved, when the hoop material is positioned by the pilot pin immediately before the press working, the hoop material slides out of the pressing die and It is possible to release the slack and bending of the hoop material.

[0020]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows a press device A according to an embodiment of the present invention.
It is a schematic side view which shows. A space 21 for continuously passing the hoop material 6 is formed in the press device main body 1, and press dies 2, 3 are arranged above and below the space 21. A punching rod (not shown) that is punched in a minute distance by a piezoelectric element, etc.
Has been paid.

On the inlet side and the outlet side of the space 21, a magnetic field generator 9 for exerting a magnetic field on the hoop material 6,
9 is provided. 2 (a) and 2 (b) are a side view and a front view showing an electromagnet type magnetic field generator 9, in which an exciting coil 11 is wound around a C-shaped core 10a.
Both ends of 1 are connected to an AC power supply 12. Therefore, the magnetic flux generated in the coil 11 passes through the core 10a and crosses the air gap 10b, and since an alternating current flows in the coil 11, the magnetic field H in the air gap 10b is an alternating magnetic field that is inverted at a constant cycle. Has become. This magnetic field generator 9
1, is attached to the press device body 1 so that the direction of the magnetic field H in the air gap 10b is substantially perpendicular to the surface of the hoop material 6.

On the other hand, a drum 5 wound with an extremely thin hoop material 6
a is rotatably set in the stock section 22,
The hoop material 6 drawn out from the drum 5a of the stock portion 22 passes through the air gap 10b of the magnetic field generator 9 on the inlet side, passes between the pressing dies 2 and 3, and then the magnetic field generator 9 on the outlet side. It passes through the air gap 10b and is wound around the drum 5b of the winding portion 23.

In the stock portion 22, the hoop material 6 is electrically grounded via the drum 5a and brushes.
In the winding section 23, the hoop material 6 is formed by the insulator 7.
The drum 5b is insulated from the ground potential, and one terminal of the direct current source 8 is connected to the hoop member 6 via the drum 5b or a brush, and the other terminal is grounded. A minute DC current i is supplied to 6. Therefore, the direct current i flows through the hoop material 6 in the direction opposite to the feeding direction. The press device body 1 is also insulated from the ground potential.

However, when, for example, a through hole is formed in the hoop material 6, the upper and lower pressing dies 2 and 3 are driven to sandwich the hoop material 6 from above and below, and the punching rod is punched out to form the hoop material 6 Make a through hole in. After that, the pressing dies 2 and 3 are opened, and the hoop material 6 is pulled from the outlet side by an air feeder (not shown) or the like to feed the hoop material 6 for a predetermined distance, and the hoop material 6 is wound on the drum 5b.

At this time, a direct current i is flowing in the longitudinal direction of the hoop material 6, and the surface of the hoop material 6 is caused by the magnetic field generators 9 and 9 on the inlet side and the outlet side of the pressing dies 2 and 3. Since an alternating magnetic field H is applied to the hoop member 6 substantially perpendicularly, electromagnetic force (Lorentz force) f as shown in FIG.
Works in the width direction. Moreover, since the magnetic field H is an alternating magnetic field, the strength and the direction of the electromagnetic force f acting on the hoop material 6 change at a constant cycle, and the hoop material 6 vibrates in the width direction. here,
The vibration of the hoop material 6 is a minute vibration, and the strength of the current i and the magnetic field H and the alternating frequency of the magnetic field H are adjusted so as not to deform the hoop material 6.

In this way, since the hoop material 6 vibrates slightly, the friction acting between the hoop material 6 and the pressing die 3 is made to be dynamic friction (dynamic friction coefficient <static friction coefficient) even when the hoop material 6 is stationary. Therefore, the frictional force between the hoop material 6 and the pressing die 3 can be reduced. As a result, the hoop material 6 can be made to move easily, or the hoop material 6 can be made slippery. Therefore, it is possible to prevent an error in conveyance of the hoop material 6 due to the frictional force between the hoop material 6 and the pressing dies 2, 3. Also, when the hoop material 6 is sent, the pressing dies 2, 3
Even if the hoop member 6 is loosened or bent (see FIG. 9), the hoop member 6 is slightly vibrated and slips easily.
Of the press dies 2 and 3 are released from the inlet side, the slack and bending between the press dies 2 and 3 are released, and the hoop member 6 is held flat between the press dies 2 and 3. .

The hoop material 6 is insulated from the ground potential in both the stock portion 22 and the winding portion 23, and the current source 8 may be connected to either the stock portion 22 or the winding portion 23. . However, for safety reasons, it is desirable to ground the hoop member 6 on the side opposite to the side to which the current source 8 is connected as in the above embodiment.

Although not shown, in the same configuration as that of the embodiment of FIG. 1, the magnetic field generator 9 generates a direct magnetic field (constant magnetic field), and the current source 8 causes an alternating current to flow through the hoop material 6. Good. For example, as such a magnetic field generator 9, a permanent magnet is used, or the exciting coil 1 is used.
1 may be an electromagnet or the like connected to a DC power source, and the current source 8 may be a series circuit of an AC current source and an impedance. Also with such a configuration, it is possible to apply the electromagnetic force f (Lorentz force) to the hoop material 6 and change the electromagnetic force f to slightly vibrate the hoop material 6.

Next, a pressing apparatus according to another embodiment of the present invention will be described. 4A and 4B are a partially cutaway side view and a plan view showing the lower pressing die 3 in the pressing apparatus, and FIG. 5 is a partially enlarged sectional view of the pressing die 3.

In this pressing apparatus, the vibration generating parts 13 are provided at the corners of the hoop material passing part on the inlet side and the outlet side of the lower pressing die 3, respectively. The vibration generator 13 has recesses 3a formed at the corners of the press die 3 on the inlet side and the outlet side, and two electromagnetic coils 15 are vertically installed on the bottom surface of the recess 3a. A vibrating reed 14 having an L-shaped cross section made of a magnetic material is swingably attached to the upper surface of 15 and the vibrating reed 14 covers the recess 3 a. Further, the electromagnetic coil 15 has a winding 15b around the iron core 15a.
The lower end surface of the iron core 15a is a recess 3
It is fixed to the bottom surface of a and the vibrating piece 14 is attached to the upper end surface of the iron core 15a.
Supports the inner surface of. An air gap 16 is formed between the end of the resonator element 14 and the bottom surface and wall surface of the recess 3a. Therefore, when the electromagnetic coil 15 is excited, as shown in FIG. 6, a closed magnetic circuit is formed via the iron core 15a, the vibrating piece 14, the air gap 16 and the pressing die 3.

However, when an AC voltage is applied to the electromagnetic coil 15 to excite it, a magnetic attractive force is generated between the pressing die 3 and the vibrating piece 14 through the air gap 16, and the attractive force is the AC voltage. Since it fluctuates according to the voltage change
4 vibrates slightly. Due to the slight vibration of the vibrating piece 14, the hoop material 6 slidingly contacting the vibrating piece 14 can be vibrated slightly, and dynamic friction is generated between the hoop material 6 and the pressing die 3 even when the hoop material 6 is stationary. It is possible to reduce the frictional force. Therefore, also in this embodiment, it is possible to prevent a mistake in conveyance of the hoop material 6 due to the frictional force between the hoop material 6 and the pressing dies 2 and 3.

The gap 16 may be filled with a nonmagnetic material having elasticity.

FIG. 7 shows a pressing apparatus according to still another embodiment of the present invention. Pilot holes 6a are opened in the hoop material 6 at regular intervals, and a pilot pin 4 for fitting with the pilot holes 6a is formed in the pressing die 2 above.
And a relief hole 3a for allowing the pilot pin 4 to escape is provided in the lower press die 3.

Further, the relief holes 3a near the pilot pin 4 of the upper pressing die 2 and the lower pressing die 3 are formed.
Electromagnetic coil housing holes 17, 17 are provided in the vicinity of the so as to face each other, and the electromagnetic coil housing hole 1 is provided.
Electromagnetic coils 18 and 18 are vertically housed in 7 and 17, respectively.

Then, the hoop material 6 is supplied by the direct current source.
DC current is applied to the upper and lower electromagnetic coils 18, 1
When an alternating magnetic field is generated with the magnetic fields oriented in the same direction in 8, the hoop material 6 vibrates slightly in the width direction, and the hoop material 6 is smoothly fed. Particularly, in this embodiment, since the hoop material 6 is vibrated in the vicinity of the pilot pin 4, the hoop material 6 is positioned when the hoop material 6 is positioned by inserting the pilot pin 4 into the pilot hole 6a of the hoop material 6. Can be easily moved, and the hoop member 6 can be accurately positioned by the pilot pin 4 without being damaged.

FIG. 8 shows a pressing apparatus according to another embodiment of the present invention. In this pressing device, a notch 19 is provided in the vicinity of the base end of the pilot pin 4 in the pressing die 2, and the piezoelectric vibrator 20 is formed in the notch 19 so as to be orthogonal to the pilot pin 4. , And both ends of the piezoelectric vibrator 20 are pressed against both side wall surfaces of the cutout portion 19.

In this embodiment, the notch 19 can be expanded and contracted by vibrating the piezoelectric vibrator 20 to vibrate the pilot pin 4. Therefore, the pilot pin 4 is connected to the pilot hole 6a of the hoop member 6.
, The hoop member 6 is slightly vibrated by the contact of the pilot pin 4 with the edge of the pilot hole 6a, and the friction of the hoop member 6 can be reduced. As a result, the hoop member 6 can be smoothly moved by inserting the pilot pin 4 into the pilot hole 6a, and the hoop member 6 can be accurately positioned by the pilot pin 4 without being damaged. Further, even if the hoop material 6 is loosened or bent between the pressing dies 2 and 3, the hoop material 6 is slid out of the pressing dies 2 and 3 at this time to press the pressing dies 2 and 3 together. The slack and flexure between the two are eliminated.

The driving source for vibrating the pilot pin by expanding and contracting the notch is not limited to the piezoelectric vibrator, and an electromagnetic coil may be used.

[0039]

According to the present invention, it is possible to reduce the friction between the hoop material and the pressing die by vibrating the hoop material and to make the hoop material easy to move.

As a result, even if the hoop material is loosened or bent in the pressing die when the hoop material is fed, the hoop material slides out of the pressing die and the looseness or bending is released.

Furthermore, since the hoop material moves smoothly, there is no risk of a feeding error when the hoop material is fed by an air feeder or the like.

Further, since the hoop material is slippery, when the pilot pin is inserted into the pilot hole, the hoop material is smoothly moved by the pilot pin, and there is no fear that the edge of the pilot hole will be crushed by the pilot pin. It can be positioned without damaging the material.

[Brief description of drawings]

FIG. 1 is a schematic side view showing a pressing device according to an embodiment of the present invention.

2A and 2B are a side view and a front view showing a magnetic field generator of the above.

FIG. 3 is a diagram showing a direction of an electromagnetic force acting on a hoop material.

4 (a) and 4 (b) are a side view and a plan view showing a pressing die of a pressing apparatus according to another embodiment of the present invention.

FIG. 5 is an enlarged cross-sectional view showing a vibration generating portion provided in the above pressing die.

FIG. 6 is a diagram showing magnetic flux generated in the vibration generator of the above.

FIG. 7 is a cross-sectional view showing a main part of a pressing device according to still another embodiment of the present invention.

FIG. 8 is a cross-sectional view showing the main parts of a pressing device according to still another embodiment of the present invention.

FIG. 9 is a partially cutaway side view showing a sliding contact portion with a hoop material of a pressing die in a conventional pressing device.

10A and 10B are cross-sectional views showing a positioning mechanism for a hoop material by a conventional pressing device.

FIG. 11 is a cross-sectional view showing the above problem.

[Explanation of symbols]

 2, 3 Press die 4 Pilot pin 6 Hoop material 9 Magnetic field generator 13 Vibration generator 15, 18 Electromagnetic coil 20 Piezoelectric vibrator

Claims (5)

[Claims] 1. A press device for intermittently feeding a hoop material to press the hoop material, comprising a vibration imparting means for slightly vibrating a portion of the pressing die that is in sliding contact with the hoop material. Press machine. 2. A press device for feeding a hoop material intermittently to press the hoop material, and a means for supplying a direct current to the hoop material, and supplying the direct current to the hoop material being supplied with the direct current. A pressing device comprising means for applying a fluctuating magnetic field in a direction non-parallel to the direction, and vibrating the hoop material at a portion in sliding contact with the pressing die. 3. A press device for intermittently feeding a hoop material to press the hoop material, wherein a means for applying an alternating current to the hoop material and a method for applying the alternating current to the hoop material being supplied with the alternating current. A pressing apparatus comprising means for applying a constant magnetic field or a varying magnetic field in a direction non-parallel to the direction, and vibrating the hoop material at a portion in sliding contact with the pressing die. 4. The pressing device according to claim 1, wherein the pressing die or the hoop material is vibrated in the vicinity of a pilot pin for positioning the hoop material provided in the pressing die. 5. A press device for positioning a hoop material by inserting a pilot pin provided in the die for pressing into a pilot hole of the hoop material and performing press working on the hoop material. A press device comprising a vibration applying means for slightly vibrating a positioning pilot pin.