JP2020131228A - Forging press device and molding method - Google Patents

Abstract

To smoothly perform a mold release work by a knock-out device.SOLUTION: A forging press device 1 comprises: paired metal molds 31, 32; a drive mechanism 11 to 13 which applies press operation to the paired metal molds; a knock-out device 50 having a knock-out pin 51 which extrudes a molded material in the metal mold, and a hydraulic device 53 which applies extrusion operation to the knock-out pin; and a control device 2 which controls the hydraulic device to operate the knock-out pin according to a specified operation pattern. The press device comprises detection parts 57 to 59 which detect characteristic value concerning the extrusion operation of the knock-out pin. The control device executes failure corresponding processing when the characteristic value detected by the detection part is out of the specified range.SELECTED DRAWING: Figure 7

Description

The present invention relates to a forging press device and a molding method.

Some forging press devices include a knockout device for projecting a forged object to be molded from a mold and a transfer feeder for transporting the object to be forged (see, for example, Patent Document 1).
In such a forging press device, it is necessary to smoothly release the object to be molded from the die in order to stably perform from the pressing operation to the transfer.

Japanese Unexamined Patent Publication No. 2003-117628

In order to smoothly release the object to be molded, the mold is preliminarily coated with a lubricant that promotes the release of the object to be molded.
However, even when the lubricant is applied to the mold, the lubricating film is not formed on the mold surface due to various causes such as when the mold is not sufficiently warmed, and the force required for mold release increases. In some cases, smooth demolding was impeded.

An object of the present invention is to facilitate the mold removal work.

The forging press device according to the present invention is
A pair of molds and
A drive mechanism that imparts a press operation to the pair of dies,
A knockout device having a knockout pin for extruding an object to be molded in the mold and a hydraulic device for imparting an extrusion operation to the knockout pin.
A forging press device including a control device that controls the hydraulic device and operates the knockout pin according to a specified operation pattern.
It is provided with a detection unit that detects characteristic values related to the pushing operation of the knockout pin.
The control device is configured to execute a malfunction handling process when the characteristic value detected by the detection unit is out of the specified range.

The molding method according to the present invention
A knockout having a pair of dies, a drive mechanism for imparting a pressing operation to the paired dies, a knockout pin for pushing out an object to be molded in the die, and a hydraulic device for imparting a pushing operation to the knockout pin. A molding method using a forging press device including a device and a control device that controls the hydraulic device and operates the knockout pin according to a specified operation pattern.
In addition to detecting the characteristic value related to the pushing operation of the knockout pin, when the detected characteristic value is out of the specified range, the malfunction handling process is executed.

According to the present invention, the mold release work by the knockout device can be smoothly performed.

It is a block diagram which shows the forging press apparatus of embodiment of this invention. It is a block diagram of a knockout device. FIG. 3A is an operation diagram in the vertical direction of the slide holding the upper mold, and FIG. 3B is an operation diagram in the vertical direction of the slide and the knockout pin. It is a diagram which shows the temporal change of the operating pressure, position, and acceleration of a knockout pin detected in a proper release operation. It is a diagram which shows the temporal change of the operating pressure and the position of the knockout pin detected in a malfunctioning release operation. It is a diagram which shows the time change of the position and acceleration of a knockout pin detected in a malfunctioning release operation. It is a diagram which shows the temporal change of the position of the knockout pin based on the specified operation pattern and the corrected operation pattern. It is a flowchart which shows the operation control which a control device executes in a molding operation.

[Outline of forging press equipment]
Hereinafter, each embodiment of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a configuration diagram showing a forging press device 1 according to an embodiment of the present invention.

As shown in FIG. 1, the forging press device 1 includes a crown 21, an upright 22, a bed 23, a slide 18, a guide 19, and a bolster 24. The lower mold 32 is fixed to the upper part of the bolster 24. The upper mold 31 is fixed to the lower part of the slide 18.

A plurality of upper molds 31 and lower molds 32 are provided side by side in the left-right direction of the paper surface in FIG. 1 (only one is shown in the figure). The upper mold 31 and the lower mold 32 are formed so that the mold shape approaches the final shape of the molded product according to the order of arrangement.
Therefore, the object to be molded is sequentially pressed by the upper die 31 and the lower die 32 from left to right in the drawing to obtain the final shape of the molded product.

The crown 21, the upright 22, and the bed 23 are frame portions that support each drive portion of the forging press device 1. The crown 21, the upright 22 and the bed 23 are fastened to each other by inserting the tie rod 25a into them and tightening them with the tie rod nut 25b.

The bolster 24 is fixed to the bed 23. The slide 18 is guided by the guide 19 so as to be able to move forward and backward, for example, in the vertical direction. The guide 19 is supported by a frame portion such as an upright 22. By lowering the slide 18, the upper die 31 and the lower die 32 come close to each other, and the workpiece can be forged between them. The direction in which the slide 18 moves forward and backward is not particularly limited, but in the present embodiment, it will be described as moving forward and backward in the vertical direction.

[Transfer feeder]
In addition to the above configuration, the forging press device 1 includes a drive mechanism that performs a pressing operation, a transfer feeder (not shown) that is a transfer device for the object to be molded, and a knockout that releases the object to be molded from the lower die 32. It includes a device 50, a supply device that supplies a mold release agent to the upper die 31 and the lower die 32 by a movable nozzle 40 between press operations, and a control device 2 that controls each part.

When the upper mold 31 and the lower mold 32 are separated from each other, the transfer feeder supplies new molding materials to the upper mold 31 and the lower mold 32 on the most upstream side, or a plurality of upper molds arranged in a row. The object to be molded is sequentially conveyed to the mold 31 and the lower mold 32.

The transfer feeder is equipped with gripping claws that grip multiple objects to be molded in the transport direction from both sides, and (1) clamp → (2) lift → (3) advance → (4) down → (5) unclamp → ( 6) Each object to be molded can be transported by operating in the order of return.

[Drive mechanism]
The forging press device 1 includes a motor 11, a flywheel 12, a clutch brake 13, a transmission shaft 14, a speed reducer 15, an executor shaft 16, and a connecting rod 17 as a configuration for raising and lowering the slide 18. Of these, the motor 11, the flywheel 12, and the clutch brake 13 correspond to the drive mechanism.

The motor 11 is fixed to a frame portion such as a crown 21. The spindle portion 16a of the eccentric shaft 16 is rotatably supported by a frame portion such as a crown 21 or an upright 22 via a bearing 41. The clutch brake 13 and the speed reducer 15 are supported by a frame portion such as a crown 21 or an upright 22 via a support frame.

The motor 11 is, for example, an induction motor and generates power for raising and lowering the slide 18. The power of the motor 11 is transmitted to the flywheel 12 via, for example, the belt 11a, and rotates the flywheel 12.

The clutch brake 13 can interrupt the flywheel 12 and the transmission shaft 14, and when these are connected, the rotational motion of the flywheel 12 is transmitted to the transmission shaft 14. Further, the clutch brake 13 can interrupt the transmission shaft 14 and the fixed portion. The fixed portion is, for example, a frame portion such as an upright 22 or a member fixed to the frame portion.

The eccentric shaft 16 has a hollow portion penetrating along the rotation center axis. The transmission shaft 14 is rotatably arranged in the hollow portion relative to the eccentric shaft 16. The transmission shaft 14 transmits the rotational movement of the flywheel 12 to the speed reducer 15. The speed reducer 15 decelerates the rotational movement of the transmission shaft 14 and transmits it to the eccentric shaft 16.

The eccentric shaft 16 has an eccentric portion 16b that is eccentric with respect to the spindle portion 16a, and the eccentric portion 16b is connected to the connecting rod 17. The connecting rod 17 connects the eccentric shaft 16 and the slide 18, converts the rotational motion of the eccentric shaft 16 into a linear motion, and transmits the linear motion to the slide 18.

Since the eccentric shaft 16 is configured to rotate once in one cycle of the forging press, the rotation speed is low. On the other hand, in the present embodiment, by having the transmission shaft 14 and the speed reducer 15, the rotational speeds of the motor 11 and the flywheel 12 can be increased as compared with the configuration in which the flywheel and the eccentric shaft are directly connected. .. As a result, the forging press device 1 can be operated efficiently.

[Knockout device]
FIG. 2 is a configuration diagram of the knockout device 50.
As shown in the figure, the knockout device 50 has a knockout pin 51 that penetrates the bolster 24 and the lower mold 32 and pushes out an object to be molded in the lower mold 32, and a hydraulic cylinder 52 that moves the knockout pin 51 up and down. The connection state of the hydraulic pump 53 for supplying hydraulic pressure to the hydraulic cylinder 52, the tank 54 for storing oil, the accumulator 56 for temporarily storing pressure oil, and the hydraulic cylinder 52 and the hydraulic pump 53 is switched. The accumulator 56 is provided with a flow control valve (servo valve) 55 that controls the amount of oil supplied by using the hydraulic pressure stored in the accumulator 56. The hydraulic cylinder 52, the hydraulic pump 53, the flow rate adjusting valve 55, and the accumulator 56 correspond to the hydraulic device of the present invention.

Further, the knockout device 50 includes a pressure sensor 57 as a pressure detection unit that detects the operating pressure of the knockout pin 51, a position sensor 58 as a position detection unit that detects the position of the knockout pin 51 in the advancing / retreating direction, and a knockout pin. An acceleration sensor 59 is provided as an acceleration detection unit that detects the acceleration in the advancing / retreating direction of 51. These correspond to detection units that detect characteristic values (operating pressure, position, speed, acceleration, etc.) related to the pushing operation of the knockout pin 51.

The knockout pin 51 is mounted on the piston of the hydraulic cylinder 52, and the moving direction of the piston is directed in the vertical direction.
The hydraulic cylinder 52 is a double-acting type and includes a port for raising the piston and a port for lowering the piston. Then, these ports are connected to the hydraulic pump 53 on one side and the tank 54 on the other side and the tank 54 on the other side and the hydraulic pump 53 on the other side by the flow rate adjusting valve 55. It can be switched to the blocked state without being connected.
As a result, the hydraulic cylinder 52 can be switched to any of the advanced (raised) state, the retracted (lowered) state, and the current position of the knockout pin 51.
The switching operation of the flow rate adjusting valve 55 is controlled by the control device 2.

Further, the flow rate adjusting valve 55 can arbitrarily control the flow rate of the pressure oil supplied to the hydraulic cylinder 52 by using the accumulator 56 under the control of the control device 2. Thereby, the speed of the knockout pin 51 when extruding the object to be molded in the lower mold 32 can be controlled.

The pressure sensor 57 is a sensor that detects the hydraulic pressure applied to the port that raises the piston, thereby detecting the operating pressure of the knockout pin 51.
The position sensor 58 is a linear sensor connected to the piston of the hydraulic cylinder 52, and detects the vertical position of the knockout pin 51. Further, the moving speed of the knockout pin 51 in the vertical direction can be obtained from the amount of change in the detection position by the position sensor 58 per unit time. That is, the position sensor 58 also functions as a speed detection unit.
The acceleration sensor 59 is provided on the knockout pin 51 or the piston of the hydraulic cylinder 52, and can detect the acceleration in the vertical direction thereof.

[Forming operation of forging press equipment]
The control device 2 is a so-called sequencer that is configured by incorporating hardware such as a CPU, a memory, and peripheral circuits, and integrally controls the forging press device 1, and executes various processes described later by a program.
As shown in FIGS. 1 and 2, the control device 2 is connected to a pressure sensor 57, a position sensor 58, and an acceleration sensor 59, and the operating pressure and knockout pin of the knockout pin 51 detected by each of these sensors. The vertical position of the 51, the acceleration of the knockout pin 51, and the like are input.
Further, the eccentric shaft 16 described above is provided with an encoder (not shown) for detecting the shaft angle thereof, and the encoder detects the shaft angle of the eccentric shaft 16 and inputs it to the control device 2. It should be noted that the configuration may include a linear sensor that detects the height of the slide 18 instead of the axis angle of the eccentric shaft 16, and other detection means.

Further, the control device 2 is connected to a motor 11, an electromagnetic valve (not shown) for operating the clutch brake 13, a flow rate adjusting valve 55 for the knockout device 50, and a servomotor (not shown) for operating the transfer feeder, and these motor 11 and the clutch brake are connected. 13. The operation of the knockout device 50 and the transfer feeder can be controlled.
Further, a display unit 26 is connected to the control device 2 to display various information such as a control state of the forging press device 1.

In the molding operation, the control device 2 rotationally drives the motor 11, connects torque to the transmission shaft 14 by the clutch brake 13, and decelerates and rotates the eccentric shaft 16 through the speed reducer 15. One rotation of the eccentric shaft 16 causes the slide 18 to move up and down once via the connecting rod 17. As a result, the upper die 31 approaches the lower die 32, and a pressing operation is performed on the object to be molded.
On the other hand, when the slide 18 passes the bottom dead center, the control device 2 controls the flow rate adjusting valve 55 of the knockout device 50 to perform an ascending operation and a descending operation of the knockout pin 51. As a result, the knockout pin 51 collides with the object to be molded in the lower mold 32 and is separated from the lower mold 32.
Then, the control device 2 controls the servomotor of the transfer feeder to supply a new object to be molded or transfer the demolded object to be molded.
After that, the molding operation is repeatedly executed by switching between connecting and disconnecting the clutch brake 13 while the motor 11 is still being driven.

[Various operating characteristics in normal extrusion operation of knockout pins]
FIG. 3A is a vertical operation diagram of the slide 18 holding the upper mold 31. The horizontal axis shows time and the vertical axis shows height. In the continuous molding operation, the slide 18 repeatedly moves the slide 18 up and down for one stroke and pauses at the top dead center under the control of the control device 2. The forging press device 1 executes the pressing operation by the upper die 31 and the lower die 32 with the total time of the operation time and the pause time of one stroke as one cycle. When the mold is released smoothly, one cycle of this pressing operation becomes a constant value (specified cycle). In this way, the control for executing the press operation at a predetermined cycle is defined as the first press operation control.
The control device 2 may be provided with a control panel so that the specified cycle can be arbitrarily set.

FIG. 3B is an operation diagram of the slide 18 and the knockout pin 51 in the vertical direction. In this figure, the slide 18 is an enlarged diagram showing a portion A which is a part of the ascending / descending motion including the bottom dead center shown in FIG. 3 (A).
As shown in FIG. 3B, when the encoder provided on the eccentric shaft 16 detects that the slide 18 has passed the bottom dead center, the control device 2 controls the flow rate adjusting valve 55 to control the knockout pin 51. It starts ascending operation, stays for a certain period of time when it reaches the highest position, and then lowers to the lowest position.
Set values are set in advance for the ascending time t1, residence time t2, descending time t3, ascending amount h1 and descending amount h1 of the knockout pin 51 of the knockout pin 51, and the knockout pin 51 is shown in FIG. 3 (B). ), The release operation is executed according to the specified operation pattern. The trapezoidal defined operation pattern shown in FIG. 3B is an operation diagram based on the command value for the knockout pin 51, and the actual operation of the knockout pin 51 causes some fluctuations and delays. ..

FIG. 4 shows a pressure sensor 57, a position sensor 58, and an acceleration sensor when the release operation by the knockout pin 51 is smoothly performed based on the command value of the specified trapezoidal operation pattern shown in FIG. 3 (B). It is a diagram which shows the temporal change of the working pressure, position (height), and acceleration of the knockout pin 51 obtained from the detection value detected by 59.
In the figure, the solid line L1 indicates the command value of the specified operation pattern, the broken line L2 indicates the detection position of the knockout pin 51, the solid line L3 indicates the detection operating pressure of the knockout pin 51, and the dotted line L4 indicates the detection acceleration of the knockout pin 51. The horizontal axis represents time, and the vertical axis represents position, pressure, and magnitude of acceleration.

The knockout (KO) timing on the horizontal axis indicates the timing at which the knockout pin 51 collides with the object to be molded in the lower mold 32.
As shown by the broken line L2, the knockout pin 51 causes a delay at the rising edge of the start of ascending, but after accelerating and colliding with the object to be molded, it ascends at a speed higher than the command value (reference numeral F) and performs a mold release operation. Is done.

As shown in the solid line L3, the working pressure of the knockout pin 51 rises sharply after the knockout pin 51 starts to rise and collides with the object to be molded, and the pressure drops sharply after the object to be molded is released to a low pressure. The state is maintained, and the pressure rises again before the highest position of the command value of the knockout pin 51 to maintain a constant pressure output by the hydraulic pump 53.

As shown by the dotted line L4, the acceleration of the knockout pin 51 increases momentarily immediately after the start of the ascent of the knockout pin 51, then immediately decreases and turns to a rapid increase, reaches the maximum value at the knockout timing, and becomes the object to be molded. After colliding with, it drops sharply. Then, the low pressure state is maintained, the knockout pin 51 temporarily rises before the highest position, and then reaches the lowest value.

[Various operating characteristics in the extrusion operation that caused the knockout pin malfunction]
Next, the operating characteristics when the object to be molded from the lower mold 32 is not smoothly released and the load on the knockout pin 51 becomes large will be described.
FIG. 5 shows the detection detected by the pressure sensor 57 and the position sensor 58 when the knockout pin 51 is not smoothly released from the command value of the operation pattern specified in FIG. 3 (B). It is a diagram which shows the time change of the working pressure, the position (height) of the knockout pin 51 obtained from the value.
Further, FIG. 6 is detected by the position sensor 58 and the acceleration sensor 59 when the release operation of the knockout pin 51 is not smoothly performed with respect to the command value of the operation pattern specified in FIG. 3 (B). It is a diagram which shows the position (height) of the knockout pin 51, and the temporal change of acceleration obtained from the detected value.

In FIG. 5, the solid line L1 indicates the command value of the specified operation pattern, the alternate long and short dash line L2a indicates the detection position of the knockout pin 51, and the solid line L3a indicates the detection operating pressure of the knockout pin 51. Further, for reference, the detection position and the detection operating pressure of the knockout pin 51 when the mold release is good are shown by the broken line L2 and the dotted line L3.
As shown in the solid line L3a, if the mold release is not performed smoothly, the operating pressure tends to rise sharply until the pressure becomes higher than usual at the knockout timing, and then decreases to the normal working pressure after the mold release. ..
Further, in this case, as shown by the alternate long and short dash line L2a, the knockout pin 51 rises to a higher position than usual at the time of knockout. Further, at this time, the knockout pin 51 rises sharply, so that the knockout pin 51 reaches a speed higher than the normal climbing speed.

In FIG. 6, the solid line L1 indicates the command value of the specified operation pattern, the alternate long and short dash line L2a indicates the detection position of the knockout pin 51, and the solid line L4a indicates the detection acceleration of the knockout pin 51. Further, for reference, the detection position and the detection acceleration of the knockout pin 51 when the mold release is good are shown by the broken line L2 and the dotted line L4.
As shown by the solid line L4a, if the mold release is not performed smoothly, the acceleration tends to rise sharply until the value becomes higher than usual at the time of mold release, and then decreases to the normal acceleration after mold release. Shown.

As described above, if the release operation is not performed smoothly, the operating pressure and acceleration of the knockout pin 51 rise to values that cannot normally occur, and the height and climbing speed of the knockout pin 51 at the time of knockout also rise. There is an increase in height and ascent rate that is not normally reached.
Therefore, as shown in FIG. 5 or 6, the control device 2 predetermined and stores the threshold values Pe and Ge of the working pressure and acceleration of the knockout pin 51, which are values that reach during a malfunction and do not normally reach. Depending on whether or not the detected operating pressure or the detected acceleration during operation exceeds the respective threshold values Pe and Ge, it is possible to detect the occurrence of a malfunction in the mold release operation in which the mold release is not smoothly performed.
Further, as shown in FIG. 5 or 6, the control device 2 predetermines and stores a threshold value Ie of a value that is reached at the time of malfunction and is not normally reached for the height of the knockout pin 51 at the time of knockout, and knocks out. Depending on whether or not the detection position at the time exceeds the threshold value Ie, the occurrence of malfunction of the mold release operation can be detected.
Further, regarding the ascending speed of the knockout pin 51 obtained from the change in the detection position at the time of knockout, a threshold value Ve of a value reached at the time of malfunction and not normally reached is predetermined and stored, and the ascending speed obtained from the change at the detection position at the time of knockout is stored. Depending on whether or not the speed exceeds the threshold value Ve, the occurrence of malfunction of the mold release operation can be detected.

[Problem handling (1)]
The control device 2 determines thresholds Pe, Ge, Ie, and Ve for each of the operating pressure of the knockout pin 51, the acceleration of the knockout pin 51, the height of the knockout pin 51 at the time of knockout, and the ascending speed of the knockout pin 51 at the time of knockout. If any one of the detected working pressure, acceleration, height, and ascending speed exceeds the threshold value set for each, it is determined that the release operation has malfunctioned.
Then, the control device 2 executes the malfunction handling process (1) at the next release operation.
In the malfunction handling process (1), in the release operation of the knockout pin 51, the control device 2 executes the release operation according to the corrected operation pattern instead of the above-mentioned specified operation pattern.

FIG. 7 is a diagram showing a defined operation pattern as a solid line and a corrected operation pattern as a broken line. The vertical axis indicates the position (height) of the knockout pin 51, and the horizontal axis indicates time.
As described above, in the specified operation pattern, the ascending time t1, the residence time t2, the descending time t3 of the knockout pin 51, and the ascending amount h1 and the descending amount h1 of the knockout pin 51 are set as the specified values.
On the other hand, in the corrected operation pattern, the residence time t2, the descent time t3, and the ascending amount and the descending amount of the knockout pin 51 are the same values as the specified operation pattern, but the ascending time t1a is the specified operation pattern. It is a value obtained by multiplying the rising time t1 of the above by a coefficient k.
t1a = k · t1 (however, k> 1)

That is, in the corrected operation pattern, the knockout pin 51 is raised at a lower speed than the specified operation pattern. The ascending speed of the knockout pin 51 is adjusted by controlling the flow rate adjusting valve 55 of the knockout device 50 to change the flow rate of the pressure oil supplied to the hydraulic cylinder 52.

Further, in the control device 2, when the molding is repeatedly executed a plurality of times, the operating pressure, the acceleration, and the height detected in the current molding are detected even though the malfunction handling process (1) is performed in the current molding. If any one of the ascending speeds exceeds the threshold value set for each, the malfunction handling process (1) is performed again at the time of the next molding.
In that case, the corrected operation pattern is defined as a new increase time t1b by multiplying the increase time t1a in the previously corrected operation pattern by a coefficient k.
t1b = k · t1a

Therefore, when the resolution of the malfunction of the release operation is not detected by the malfunction handling process (1), the coefficient k is superimposed on the rise time in the corrected operation pattern.
However, an upper limit is set for the number of times the malfunction handling process (1) is repeated. Then, if all of the detected working pressure, acceleration, height, and ascending speed do not fall below the threshold values set for each even if the upper limit value is exceeded, the control device 2 is set to the forging press device 1. It is determined that an irresolvable abnormality has occurred, and the abnormality notification process and the stop of the molding operation are executed.
The abnormality notification process includes, for example, displaying a notification screen for notifying an abnormality of the release operation on the display unit 26, outputting a notification sound when the display unit 26 includes a voice output unit, and the like.
Further, when the molding operation is stopped, the entire configuration of the forging press device 1 including the stop of the motor 11, the braking of the flywheel 12 by the clutch brake 13, the stop of the knockout device 50, and the stop of the transfer feeder is stopped. The control device 2 maintains the stopped state of each of the above configurations unless an input for returning the operation is input from the control panel.
It should be noted that the abnormality notification process and the stop of the molding operation may be configured to execute only one of them.

[Measures to prevent productivity decline due to malfunction handling (1)]
As described above, the forging press apparatus 1 executes continuous forming operations at regular intervals. Then, in the continuous molding operation, the release operation by the knockout device 50 and the transfer operation of the object to be molded by the transfer feeder are performed by sewing between the ascending / descending operations of the slide 18 which are periodically performed.
In this case, the time from when the slide 18 reaches the bottom dead center to the start of the lowering operation of the slide 18 at the time of the next molding is set as the working time T0 for performing the release operation and the transfer operation, and the release by the knockout device 50 is performed. Assuming that the time required for the operation is T1 and the time required for the transfer operation of the transfer feeder is T2, it is required that T0 ≧ T1 + T2.

However, if the malfunction handling process (1) is repeated and the coefficient k is superimposed on the rising time of the knockout pin 51, the time required for the release operation T1 becomes long, and T0 <T1 + T2 may occur. ..
In this case, the control device 2 controls the clutch brake 13 to extend the pause time at the top dead center of the slide 18. Assuming that the working time extended by the extension of the pause time is T0a, the control device 2 adjusts so that T0a = T1 + T2.
As a result, the release operation by the knockout device 50 and the transfer operation of the transfer feeder can be completed by the start of the raising / lowering operation of the next slide 18.

However, extending the working time to T0a temporarily extends the cycle of the molding operation, which causes a decrease in the productivity of the continuous molding operation.
Therefore, the control device 2 shortens the next working time when all of the detected working pressure, acceleration, height, and rising speed are within the normal range in the molding operation from the next time onward. The clutch brake 13 is controlled. In that case, it is desirable that the shortened working time is T0a-T0, which is the extension of the previous time, and the shortened working time T0b is T0b = T0- (T0a-T0).
In this way, the control for executing the press operation in a cycle shorter than the specified cycle by shortening the working time is referred to as the second press operation control.

Further, when the working time is extended or shortened, the control device 2 displays on the display unit 26 the cycle of the molding operation based on the immediately preceding working time and the cycle of the molding operation based on the extended or shortened working time. Execute display control to display.

[Problem handling (2)]
In the control device 2, if any one of the working pressure, acceleration, height, and ascending speed detected in the molding operation exceeds the threshold value set for each, a malfunction of the mold release operation occurs. As a result, the malfunction handling process (2) is executed together with the malfunction handling process (1).
In the malfunction handling process (2), the control device 2 displays a notification screen on the display unit 26 for notifying the occurrence of a malfunction in the release operation.

[Control of molding operation]
FIG. 8 is a flowchart showing the operation control executed by the control device 2 in the molding operation.
The control of the forming operation will be described based on this flowchart. This flowchart shows the processing in one molding operation when the molding operation is continuously performed.

First, when the slide 18 starts the descending operation by driving the motor 11 (step S1), the control device 2 monitors the arrival of the bottom dead center of the slide 18 (step S3).
Then, when the arrival of the bottom dead center of the slide 18 is detected by the encoder, the control device 2 starts the mold release operation by the knockout device 50 based on the operation pattern selected in the previous molding operation (step S5).

The control device 2 determines whether or not a malfunction in the release operation has occurred from the operating pressure, position, ascending speed, and acceleration of the knockout pin 51 detected during the release operation or at the knockout timing (step S7).
As a result, when it is determined that the mold release operation is not malfunctioning, the control device 2 determines to execute the mold release operation during the next molding operation in a predetermined operation pattern (step S9). ..

Further, in the molding operation before the current molding operation, it is determined whether or not the cycle of the molding operation is extended due to the extension of the working time T0a by the malfunction handling process (1) (step S11).
Then, when the cycle is extended, the control device 2 selects a cycle based on the shortened working time T0b for the next molding operation (step S13). At this time, the control device 2 displays the cycle of the current molding operation and the cycle of the next molding operation on the display unit 26 (step S15), and ends the current molding operation.
On the other hand, if the cycle is not extended, the control device 2 selects a cycle based on the normal working time T0 for the next molding operation (step S17), and ends the current molding operation.

On the other hand, if it is determined in step S7 that a malfunction of the release operation has occurred, the control device 2 determines whether or not the number of consecutive malfunctions is equal to or less than a predetermined upper limit value ( Step S19).
As a result, when the number of consecutive occurrences of malfunction exceeds the upper limit value, the control device 2 displays an abnormality notification screen on the display unit 26 and stops the molding operation (step S21). Then, the molding operation this time ends as it is.

On the other hand, when the number of continuous occurrences of malfunction is equal to or less than the upper limit value, the control device 2 causes the display unit 26 to display a notification screen for the occurrence of malfunction in the release operation (step S23).
Further, it is determined to execute the mold release operation during the next molding operation with the corrected operation pattern (step S25). Further, at this time, the control device 2 calculates the rise time t1a or t1b in the operation pattern of the mold release operation during the next molding operation (step S27).

Next, the control device 2 determines whether or not T0 ≥ T1 + T2, which is the time required for the release operation by the knockout device 50 and the time required for the transfer operation of the transfer feeder, with respect to the work time T0. (Step S29).
As a result, when T0 ≧ T1 + T2, the control device 2 selects a cycle based on the normal working time T0 for the next molding operation (step S31), and ends the current molding operation.

On the other hand, when T0 <T1 + T2, the control device 2 selects a cycle based on the extended working time T0a for the next molding operation (step S33). Then, the control device 2 displays the cycle of the current molding operation and the cycle of the next molding operation on the display unit 26 (step S15), and ends the current molding operation.

[Technical Effects of Embodiments of the Invention]
The forging press device 1 includes a pressure sensor 57, a position sensor 58, and an acceleration sensor 59 as detection units for detecting characteristic values related to the pushing operation of the knockout pin 51, and the control device 2 uses these sensors 57, 58, 59. When the detected operating pressure of the knockout pin 51, the acceleration of the knockout pin 51, the height of the knockout pin 51 at the time of knockout, and the ascending speed of the knockout pin 51 at the time of knockout exceed the threshold value (when it is out of the specified range). Execute the malfunction handling process (1) and (2).
Therefore, the operator can recognize the occurrence of the malfunction of the mold release operation, or the process of suppressing the malfunction of the mold release operation is executed, and the mold release operation can be facilitated.

Further, the control device 2 controls the flow rate adjusting valve 55 of the hydraulic device so that the knockout pin 51 operates according to the corrected operation pattern instead of the specified operation pattern as the malfunction handling process (1).
Therefore, by changing the operation pattern, it is possible to eliminate the malfunction of the mold release operation and facilitate the mold release work.

Further, the control device 2 clearly displays the release operation to the operator by displaying the notification screen for notifying the occurrence of the release operation malfunction on the display unit 26 as in the malfunction response process (2). It is possible to recognize the occurrence of the malfunction.

Further, the forging press device 1 includes a pressure sensor 57 that detects the operating pressure of the knockout pin 51 as a detection unit, and the control device 2 performs a mold release operation when the detected operating pressure exceeds a threshold value which is a specified value. Since the malfunction response processing (1) and (2) are executed as the malfunction occurrence, the malfunction occurrence of the release operation can be appropriately detected, and the malfunction response processing (1) and (2) can be appropriately processed. it can.

Similarly, the forging press device 1 includes a position sensor 58 that detects the operating speed of the knockout pin 51 as a detection unit, and the control device 2 has a specified value of the height or operating speed of the knockout pin 51 at the time of knockout. Even when the threshold value is exceeded, the malfunction response processing (1) and (2) are executed as the malfunction occurrence of the mold release operation, so that the malfunction occurrence of the mold release operation can be appropriately detected, and the malfunction response process (1) , (2) can be processed appropriately.

Similarly, the forging press device 1 includes an acceleration sensor 59 that detects the acceleration of the knockout pin 51 as a detection unit, and the control device 2 malfunctions in the release operation even when the acceleration exceeds a threshold value which is a specified value. Since the malfunction response processing (1) and (2) are executed as the occurrence, the malfunction occurrence of the release operation can be appropriately detected, and the malfunction response processing (1) and (2) can be appropriately processed. ..

Further, since the control device 2 uses the corrected operation pattern in the malfunction handling process (1) as a pattern in which the moving speed of the knockout pin 51 in the pushing direction is slower than the specified operation pattern, the operation pattern is from the lower mold 32. The mold release of the object to be molded is gradually promoted, and good mold release can be realized.

Further, the control device 2 sets the corrected operation pattern as a pattern in which the moving speed of the knockout pin 51 is slower than that of the previously corrected operation pattern when the malfunction handling process (1) is continuously executed. Therefore, the knockout pin 51 can be adjusted to an appropriate moving speed according to the degree of malfunction of the mold release, and a better mold release can be realized.

Further, the control device 2 has a first press operation control that controls the clutch brake 13 of the drive mechanism so as to execute a press operation of the upper die 31 and the lower die 32 that are paired at a predetermined cycle, and a corrected operation. When a delay due to the pattern occurs, the second press operation control that controls the clutch brake 13 so as to execute the press operation in a cycle shorter than the specified cycle is executed.
Therefore, it is possible to reduce or eliminate the delay in the press operation that may occur due to the malfunction handling process (1), and suppress or avoid the decrease in productivity.

Further, when the press operation cycle of the upper die 31 and the lower die 32 is changed, the control device 2 displays the press operation cycle before and after the change by the display unit 26, so that the operator can see it. It is possible to effectively recognize the change in the press operation cycle.

Further, in the control device 2, even if the knockout pin 51 is pushed out by the corrected operation pattern a specified number of times, the characteristic value detected by the detection unit consisting of the sensors 57, 58, 59 remains out of the specified range. In some cases, both the abnormality notification process and the stop of the molding operation are executed.
As described above, when the malfunction of the mold release operation is not resolved even if the repetitive operation pattern is corrected, it is highly possible that the malfunction of the mold release operation is not the cause that can be resolved by changing the motion. Therefore, in such a case, it is possible to notify the operator that the cause is another and to obtain an opportunity for inspection by stopping the notification process or the molding operation.

[Other]
Each embodiment of the present invention has been described above. However, the present invention is not limited to the above embodiment. For example, the details shown in the embodiment of the forging press apparatus 1 can be appropriately changed without departing from the spirit of the invention.
Further, although the control device 2 exemplifies a sequencer that realizes various mechanisms by a program, the same function may be realized by using various circuits that are hardware.

Further, the control device 2 performs the second press operation control in order to reduce or eliminate the delay of the press operation that may occur due to the malfunction handling process (1), but the present invention is not limited to this.
That is, regardless of whether the malfunction handling process (1) has been executed before the previous time, when the mold release operation is performed according to the specified operation pattern, the press operation cycle is reduced in the next press operation. It may be configured to execute the second press operation control for the purpose of.
In that case, it is preferable that the shortening time of the press operation cycle is shortened by a predetermined time or a predetermined ratio.
As a result, it is possible to improve productivity when the pressing operation is continuously executed.

Further, in the forging press device 1, the configuration in which the knockout device 50 is provided only on the lower die 32 side is illustrated, but the knockout device may also be provided on the upper die 31 side. In that case, the knockout device of the upper mold 31 may be configured to perform the same operation control as the knockout device 50.

1 Forging press device 2 Control device 11 Motor (drive mechanism)
12 Flywheel (drive mechanism)
13 Clutch brake (drive mechanism)
18 Slide 26 Display 31 Upper mold 32 Lower mold 50 Knockout device 51 Knockout pin 52 Hydraulic cylinder 53 Hydraulic pump 55 Flow control valve 56 Accumulator 57 Pressure sensor (detector)
58 Position sensor (detector)
59 Accelerometer (detector)

Claims (14)

A pair of molds and
A drive mechanism that imparts a press operation to the pair of dies,
A knockout device having a knockout pin for extruding an object to be molded in the mold and a hydraulic device for imparting an extrusion operation to the knockout pin.
A forging press device including a control device that controls the hydraulic device and operates the knockout pin according to a specified operation pattern.
It is provided with a detection unit that detects characteristic values related to the pushing operation of the knockout pin.
The control device executes a malfunction handling process when the characteristic value detected by the detection unit is out of the specified range.
Forging press equipment. The control device includes a case where the hydraulic device is controlled so that the knockout pin operates according to the corrected operation pattern instead of the specified operation pattern as the malfunction response process.
The forging press device according to claim 1. The detection unit includes a pressure detection unit that detects the operating pressure of the knockout pin.
The control device controls the hydraulic device so as to execute the malfunction response process when the operating pressure detected by the pressure detection unit exceeds a specified value.
The forging press device according to claim 2. The detection unit includes a speed detection unit that detects the operating speed of the knockout pin.
The control device controls the hydraulic device so as to execute the malfunction response process when the operating speed detected by the speed detection unit exceeds a specified value.
The forging press device according to claim 2 or 3. The detection unit includes an acceleration detection unit that detects the acceleration of the knockout pin.
The control device controls the hydraulic device so as to execute the malfunction response process when the acceleration detected by the acceleration detection unit exceeds a specified value.
The forging press device according to any one of claims 2 to 4. The detection unit includes a position detection unit that detects the position of the knockout pin.
When the knockout pin pushes out the object to be molded from the mold and the position detected by the position detecting unit exceeds a specified value, the control device causes the hydraulic device to execute the malfunction handling process. Control,
The forging press device according to any one of claims 2 to 5. The corrected operation pattern is a pattern in which the moving speed of the knockout pin in the pushing direction is slower than that of the specified operation pattern.
The forging press device according to any one of claims 2 to 6. The control device is
When the malfunction handling process is continuous,
The corrected operation pattern is a pattern in which the moving speed of the knockout pin in the pushing direction is slower than that of the previous corrected operation pattern.
The forging press device according to claim 7. The control device is
The first press operation control that controls the drive mechanism so as to execute the press operation of the pair of dies at a predetermined cycle, and
When the press operation of the die is delayed due to the slowing of the moving speed of the knockout pin due to the corrected operation pattern, the press operation after the press operation in which the delay occurs is shorter than the specified cycle. Executes with a second press motion control that controls the drive mechanism so as to execute in
The forging press device according to claim 7 or 8. The control device is
The first press operation control that controls the drive mechanism is executed so as to execute the press operation of the pair of dies at a predetermined cycle.
When the knockout pin is pushed out according to the specified operation pattern, the die pressing operation is executed in a cycle shorter than the previous cycle.
The forging press device according to any one of claims 7 to 9. When the cycle of the press operation of the die is changed, the control device displays the cycle of the press operation of the die before and after the change by the display unit.
The forging press device according to claim 9 or 10. The control device is
Even if the knockout pin pushing operation according to the corrected operation pattern is repeated a specified number of times, if the characteristic value detected by the detection unit remains outside the specified range, the abnormality notification process and the molding operation are stopped. Do one or both,
The forging press device according to any one of claims 2 to 11. The control device includes a case where the display unit notifies the occurrence of a malfunction as the malfunction response process.
The forging press device according to any one of claims 1 to 12. A knockout having a pair of dies, a drive mechanism for imparting a pressing operation to the paired dies, a knockout pin for pushing out an object to be molded in the die, and a hydraulic device for imparting a pushing operation to the knockout pin. A molding method using a forging press device including a device and a control device that controls the hydraulic device and operates the knockout pin according to a specified operation pattern.
A characteristic value related to the pushing operation of the knockout pin is detected, and when the detected characteristic value is out of the specified range, a malfunction handling process is executed.
Molding method.

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