JP2705393B2 - Cushion pin pressure equalizer for press machine - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cushion pin pressure equalizing device for a press machine.

[0002]

2. Description of the Related Art Conventionally, this type of pressure equalizer is disclosed in, for example, Japanese Utility Model Publication No. 2-39622 or Japanese Utility Model Application Laid-Open No. 1-6072.
No. 1 has been disclosed.

As shown in FIG. 2 which is incorporated by reference from the above-mentioned publication, a plurality of cushion pins 7 for supporting a material to be pressed W at a predetermined level of a lower mold 3 through a ring-shaped wrinkle retainer 6.
To 7 are connected to a cushion pad 10 of a die cushion 9, respectively. Each of the hydraulic cylinders 8 to 8 is connected to a common oil passage 15, and this oil passage 15 is a flexible tube. It is connected to the oil supply means 20 via the check valve 16 and the check valve 21.

As described above, each of the hydraulic cylinders 8 to 8 is connected to the oil supply means 20 via the check valve 21,
When the oil pressure in each of the hydraulic cylinders 8 to 8 becomes lower than the set preload oil pressure set by the oil supply means 20, oil is supplied from the oil supply means 20 into the hydraulic cylinder 8,
Conversely, even if the oil pressure in the hydraulic cylinder 8 becomes higher than the set preload oil pressure, the oil is not flowed back to the oil supply means 20 side.

According to the pressure equalizing device configured as described above,
Variations in cushion pressure between the cushion pins 7 to 7 are absorbed, and the wrinkle pressing force acting on the material to be pressed W is maintained at a uniform pressure, so that highly accurate press forming can be performed.

The die cushion 9 has a cushion cylinder 11 for supporting a cushion pad 10. The cushion cylinder 11 receives compressed air of a predetermined pressure set by an air regulator 13 from an air pressure source 12. It is configured to be supplied through

[0007]

However, the conventional pressure equalizer has the following problems. That is, when the movable mold (upper mold) 1 descends and collides with the material to be pressed W during press molding, each cushion pin 7
To 7, a shocking load is applied, and this shock load is transmitted to the die cushion 9 via the hydraulic cylinders 8 to 8.

Here, since the air pressure of the die cushion 9 is generally lower than the hydraulic pressure in the hydraulic cylinder 8, the case portion 8a of the hydraulic cylinder 8 fixed to the cushion pad 10 by the impact load is used. Moves instantaneously downward by a distance larger than the cushion pin 7, that is, the piston portion 8b of the hydraulic cylinder 8, and the piston portion 8b cannot follow the case portion 8a. A phenomenon occurs in which the oil pressure in the oil tank instantaneously becomes lower than the set preload oil pressure set on the oil supply means 20 side. As a result, oil is instantaneously supplied to the hydraulic cylinders 8 to 8,
After the completion of one rod, the preload hydraulic pressure of each hydraulic cylinder 8 at the time when the upper die 1 reaches the top dead center is higher than the preload hydraulic pressure before the collision.

The above-described phenomenon is repeated for each rod, and the preload hydraulic pressure gradually increases, whereby the absorbing function such as a cushion pin length error of each hydraulic cylinder 8 to 8 and the shock absorbing ability are extremely reduced. Eventually, however, oil leakage or breakage of the hydraulic cylinder 8 is caused.

The present invention has been made to solve this problem, and an object of the present invention is to provide a cushion pin pressure equalizing device for a press machine which can always maintain a preload hydraulic pressure of each hydraulic cylinder at an appropriate value. And

[0011]

According to the present invention, in order to solve the above-mentioned conventional problems, a plurality of cushion pins for supporting a material to be pressed are connected to a die cushion via a hydraulic cylinder, while the hydraulic cylinder is connected to an oil passage. A pressure pin connected to a lubricating means and a check valve for interposing a check valve for allowing oil to pass only in a direction in which oil is supplied to a hydraulic cylinder. An on-off valve for opening and closing the valve, and an on-off valve controller for closing the on-off valve before the movable mold collides with the material to be pressed and holding the closed state at least until the hydraulic pressure of the hydraulic cylinder returns to the set preload hydraulic pressure. Is added.

[0012]

According to the above construction, at least immediately before the movable die collides with the material to be pressed, the opening / closing valve operates to the closing side to shut off the oil passage between the hydraulic cylinder and the oil supply means. The hydraulic pressure of the hydraulic cylinder is maintained until it returns from a state lower than the set preload hydraulic pressure to a higher level, and the hydraulic pressure in each hydraulic cylinder instantaneously becomes lower than the set preload hydraulic pressure in the event of a movable collision. However, no oil is supplied into the hydraulic cylinder.

After the hydraulic pressure in the hydraulic cylinder has returned to or above the set preload hydraulic pressure, the on-off valve operates to the open side,
Thereby, the oil passage between each hydraulic cylinder and the oil supply means is connected again, and if the preload oil pressure in the hydraulic cylinder is lower than the set preload oil pressure, oil is supplied from the oil supply means into each hydraulic cylinder.

[0014]

Next, an embodiment of the present invention will be described with reference to FIG. In FIG. 1, the configuration of the press machine main body side (left side of the flexible tube 16 in the drawing) does not need to be changed except for the point that a movable type detecting means 27 described later is attached, so that the description thereof is omitted and each component is omitted. Are indicated by the same reference numerals. The refueling means 20 is also configured in the same manner as in the prior art. The same applies only when the oil pressure in each of the hydraulic cylinders 8 to 8 becomes lower than the set preload oil pressure set by the refueling means 20 by the check valve 21. The oil supply means 20 is configured to supply oil to each of the hydraulic cylinders 8 to 8. The oil supply means 20 is connected to hydraulic cylinders 8 to 8 on the press machine main body via a flexible tube 16 and a check valve 21 as shown in the figure.

An on-off valve 25 is connected in the middle of the pipe between the flexible tube 16 and the check valve 21. The on-off valve 25 is, for example, a two-position electromagnetic on-off valve, and is connected to the hydraulic cylinders 8 to 8 and the oil supply means 20 so as to be able to switch between communicating and shutting off.

On the other hand, a movable-type detecting means 27 for detecting the timing at which the movable upper die 1 passes a predetermined position is provided on the press machine main body side. The movable type detecting means 27 includes limit switches 27a and 27b.
The limit switch 27b is mounted so as to operate when reaching the position immediately before the collision with the upper mold 1 and when the upper mold 1 reaches the bottom dead center. It is installed so that the passage timing can be distinguished and detected.

The movable detection means 27 is connected to an on-off valve controller (hereinafter, simply referred to as a "controller") 26 by relaying. The controller 26 is a sequencer in which a predetermined program is stored. The movable type detecting means 27 is connected to the input side of the controller 26, and the open / close valve 25 is connected to the output side.

The controller 26 uses the above program to open and close the on-off valve 25 according to the timing at which the upper mold 1 detected by the movable mold detecting means 27 reaches a predetermined position.
Activate That is, when the upper die 1 descends from the top dead center and reaches a position immediately before colliding with the material to be pressed W, the limit switch 27a is operated, and this detection signal is input to the controller 26, whereby the controller 26 The on-off valve 25 is operated to the closed side to shut off the oil passage 15. This shut-off state is maintained until the upper die 1 reaches the bottom dead center. Next, when the upper die 1 reaches the bottom dead center, the limit switch 27b is operated, and a detection signal thereof is input to the controller 26, whereby the controller 26 operates the opening / closing valve 25 to the open side, and The hydraulic cylinders 8 to 8 are connected again.

At this time, when the upper die 1 reaches the bottom dead center, the hydraulic pressure in the hydraulic cylinder 8 is already higher than the set preload hydraulic pressure. This timing is set to the timing of operating to the open side, and this timing is before the timing when the hydraulic pressure in the hydraulic cylinder 8 instantaneously becomes lower than the set preload hydraulic pressure and returns to a higher hydraulic pressure even before that time. What is necessary is just to set suitably.

When the upper die 1 rises from the bottom dead center, the open / close valve 2 is opened even if the limit switch 27a is operated.
The controller 26 is programmed so that 5 does not operate from the open side to the closed side.

This embodiment is constructed as described above.
According to this configuration, the following operation and effect can be obtained. First, when the upper die 1 is at the top dead center, the on-off valve 25 is held on the open side, and the oil supply means 20 and the hydraulic cylinders 8 to 8 are in a connected state. When the hydraulic pressure (preload hydraulic pressure) in the hydraulic cylinder 8 at this time is lower than the set preload hydraulic pressure set on the oil supply means 20 side, oil is supplied to each hydraulic cylinder 8 side and the preload hydraulic pressure is set to the set preload hydraulic pressure. Is corrected to match.

Next, when the press machine operates and the upper die 1 descends to reach a position immediately before colliding with the material to be pressed W, this timing is detected by the movable die detecting means 27, and this detection signal is sent to the controller. 26. Thereby, the on-off valve 25 is switched to the closed side, and the connection between the oil supply means 20 and each of the hydraulic cylinders 8 to 8 is cut off. This shut-off state is maintained until the upper die 1 reaches the bottom dead center, during which no oil is supplied to each hydraulic cylinder 8.

When the upper die 1 reaches the bottom dead center, its timing is detected again by the movable die detecting means 27, and the detection signal is input to the controller 26. As a result, the on-off valve 25 switches to the open side again, and the connection between the oil supply means 20 and the hydraulic cylinder 8 returns to the connected state. Thereafter, this connection state is maintained until the upper die 1 reaches the top dead center and reaches a position immediately before the upper die 1 collides with the material to be pressed W again.

As described above, in one press-formed rod, the connection between the oil supply means 20 and each of the hydraulic cylinders 8 to 8 is made by the upper mold 1 colliding with the material to be pressed W and the hydraulic cylinders 8 to 8.
It shuts off while the oil pressure in the inside momentarily falls below the set preload oil pressure.

From this, even if the hydraulic pressure in each hydraulic cylinder 8 becomes lower than the set preload hydraulic pressure immediately after the collision of the upper mold 1, oil is not supplied from the oil supply means 20 into each hydraulic cylinder 8. Therefore, the preload hydraulic pressure in the hydraulic cylinder 8 does not rise for each rod. From this, it is possible to supply a press product of stable quality without causing deterioration in quality such as cracks, wrinkles or distortion of the product due to a decrease in the shock absorption function of the cushion pin during the production, Further, it is possible to eliminate problems such as oil leakage and breakage of the hydraulic cylinder, which have frequently occurred in the past.

Further, since the preload hydraulic pressure of the hydraulic cylinder 8 does not fluctuate for each rod and is always kept constant, it is possible to perform press forming with more stable quality.

In this embodiment, the on-off valve 25 is exemplified by a two-position solenoid valve. However, the present invention is not limited to this, and a mechanical or hydraulic / pneumatic on-off valve may be used.
In short, any device that can be operated by the controller 26 to shut off oil supply from the oil supply means 20 may be used.

The movable type detecting means 27 may be, for example, a non-contact type photoelectric sensor. Further, the movable type detecting means 27 does not directly detect the timing at which the upper die 1 passes a predetermined position, but for example, a press machine. May be configured to detect the crank angle indirectly by detecting the crank angle.

Further, by using a timer as the movable type detecting means 27, the opening / closing valve is closed when a predetermined time elapses after the upper mold 1 has descended from the top dead center. The controller may be configured to operate the on-off valve again to the open side.

The above embodiment is an embodiment of the present invention, and various embodiments can be implemented without departing from the scope of the claims.

[0031]

According to the present invention having the above-described structure, not only a problem such as breakage of a hydraulic cylinder in a cushion pin pressure equalizing device can be prevented, but also press forming with more stable quality can be performed. Will be able to do it.

[Brief description of the drawings]

FIG. 1 is an overall view of a cushion pin equalizing device according to an embodiment of the present invention.

FIG. 2 is an overall view of a conventional cushion pin pressure equalizing device.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Upper type (movable type) 7 ... Cushion pin 8 ... Hydraulic cylinder 9 ... Die cushion 20 ... Oil supply means 21 ... Check valve 25 ... On / off valve 26 ... On / off valve controller 27 ... Movable type detection means (27a, 27b ... Limit) Switch) W: Material to be pressed

Continuation of the front page (56) References JP-A-5-57362 (JP, A) JP-A-5-69050 (JP, A) JP-A-5-285556 (JP, A)

Claims (1)

(57) [Claims] 1. A plurality of cushion pins for supporting a material to be pressed are connected to a die cushion via a hydraulic cylinder, the hydraulic cylinder is connected to an oil supply means via an oil passage, and a hydraulic cylinder is connected to the oil passage. A cushion pin pressure equalizing device of a press machine having a check valve for allowing oil to pass only in the direction in which oil is supplied to the oil passage, wherein an open / close valve for opening / closing the oil passage and a movable mold for pressing the open / close valve are pressed. An on-off valve controller that closes before colliding with the material and maintains the closed state at least until the hydraulic pressure of the hydraulic cylinder returns to the set preload hydraulic pressure. apparatus.