JP2010099664A - Forging press, and knockout control method in forging press - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a forging press which can prevent the occurrence of deviation in a knockout start timing, and to provide a knockout control method in the forging press. <P>SOLUTION: The forging press is provided with a knockout device, and the knockout device comprises: a knockout pin N; and a knockout pin operating means 10 operating the knockout pin N. The knockout pin N is composed of a plurality of axial members NP arranged side by side along the elevation direction thereof, and the respective axial members NP are arranged at a die D and a plurality of members supporting the die D so as to be elevatable, respectively. The knockout pin operating means 10 comprises: an elevation part elevating the driving axial member NP4; and a control part 20 controlling the operation of the elevation part. The control part 20 comprises a stroke play memory unit 22 memorizing the movement amount of the driving axial member NP1 in a state where the tip of the contact axial member NP1 is made into the same as the upper face Da of the die D as a stroke play. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a forging press and a knockout control method in a forging press. More specifically, the present invention relates to a forging press provided with a knockout device that controls the operation of a knockout pin by a servo mechanism, and a knockout control method in the forging press.

The forging press includes a knockout device for releasing the forged workpiece from the mold. Such a knockout device is composed of a knockout pin provided so as to be able to protrude and retract from the upper surface of a mold, and a drive mechanism for raising and lowering the knockout pin. Conventionally, such a drive mechanism has a mechanical or hydraulic drive mechanism. It has been adopted.
For example, in the case of a mechanical drive mechanism, an upper cam provided on an eccentric shaft, an upper cam lever whose tip swings following the upper cam, and a tip of the upper cam lever are connected via a rod. The lower lever and a rocker arm fixed to the lower lever shaft and provided below the knockout pin.
If the knockout device adopts such a mechanical drive mechanism, the rocker arm swings up and down in response to the rotation of the eccentric shaft, so that the knockout pin moves up and down in response to the rocker arm swinging. Can be made.

  However, in the case of the knockout device as described above, the raising / lowering operation (knockout motion) of the knockout pin is determined by the profile of the upper cam and the rotation of the eccentric shaft, so the upper cam needs to be replaced to adjust the knockout motion. It becomes. Then, if the forged product is changed, the knockout motion must also be changed.To change the knockout motion, the upper cam must be replaced, which increases the man-hour for changing the forged product. There were problems such as long working hours.

As a technique for solving such a problem, a technique for operating a knockout pin by a servo mechanism has been developed (for example, Patent Documents 1 to 4).
Patent Documents 1 and 2 disclose a mechanism in which a rocker arm or a swing arm that operates a knockout pin is connected to a servomotor, and the operation of the knockout pin is controlled by the servomotor.
Patent Documents 3 and 4 disclose techniques for controlling a knockout pin operation by connecting a rocker arm for operating a knockout pin to a rod of a hydraulic cylinder and controlling the operation of the hydraulic cylinder by a hydraulic circuit. Yes.
With these technologies, the operation timing of servo motors and hydraulic cylinders can be set freely without being constrained by the rotation of the eccentric shaft. Can be done.

Here, in the forging press, since the rocker arm for operating the knockout pin is usually provided below the bed, the knockout pin is disposed so as to penetrate from the mold to the bed.
However, if a knockout pin that penetrates from the mold to the bed is provided as described above, when replacing the mold alone or the mold with the die holder, the knockout pin can be replaced with a mold, etc. Get in the way.

  Therefore, the knockout pin is composed of a plurality of shaft-like parts (shaft-like members), and each shaft-like member is provided on a mold or a member that supports the mold (die holder, hard plate, bed, etc.) Arrangement is made so that the shaft-like members are aligned on the same shaft. Then, if the shaft-like member provided on the bed located at the lowermost layer is moved up and down by the rocker arm, the shaft-like member at the uppermost layer provided on the die is moved to the die via the plurality of shaft-like members. It can be infested from the top surface.

  However, when the knockout pin is constituted by a plurality of shaft-shaped members as described above, the end surface of each shaft-shaped member is a bed for holding each shaft-shaped member or the like so that each shaft member does not become an obstacle to mold replacement. It is arrange | positioned so that it may be in the state slightly retracted from the end surface. For this reason, a gap is formed between the end surfaces of the adjacent shaft-like members.

  Then, even if the shaft-shaped member provided in the bed is activated, the mold is kept until there is no gap between the adjacent shaft-shaped members, in other words, until all the adjacent shaft-shaped members are in contact with each other. Since the provided shaft-shaped member does not operate, a time lag occurs between the operation of the shaft-shaped member provided on the bed and the operation of the shaft-shaped member provided on the mold. When such a time lag occurs, there is a deviation in the timing at which the knockout is started. Therefore, there is a possibility that the knockout motion of the shaft-like member provided in the mold may deviate from the knockout motion planned by the servo mechanism. .

  The knockout motion of the knockout pin is adjusted so that the workpiece is lifted up to a predetermined position during the clamping operation of the transfer feeder that transports the workpiece. If such a deviation occurs, the transfer feeder clamps the workpiece normally. This is not possible, and there is a possibility that the conveyance of the workpiece may be obstructed.

Further, as the forging operation progresses, the knockout pin wears and its length is shortened. Therefore, if the forging operation is continuously performed for a long period of time, the time lag as described above becomes further larger, and the conveyance of the workpiece is obstructed. The possibility is even higher.
On the other hand, if the wear state of the knockout pin is examined in a short period of time, it is possible to prevent the time lag from changing, but the facility is frequently stopped, resulting in a decrease in production efficiency.

JP 2003-251430 A JP-A-11-138226 Japanese Patent Laid-Open No. 7-164091 JP 2001-47299 A

  In view of the above circumstances, an object of the present invention is to provide a forging press and a knockout control method in a forging press that can prevent a shift in the knockout start timing.

(Knockout method)
The knockout control method in the forging press of the first invention is a control method for controlling the operation of the knockout pin in a forging press including a knockout device for operating the knockout pin to release the forged product from the mold, The knockout device includes a reaction force detection unit that detects a reaction force applied to the knockout pin, and the knockout pin includes a plurality of shaft-like members arranged side by side in the ascending / descending direction. Each of the shaft-shaped members is disposed so as to be movable up and down on a plurality of members that support the mold disposed side by side in the ascending / descending direction. The amount of movement to move from the position to the knockout start position where the reaction force detected by the reaction force detection unit becomes the specified reaction force is set as the play stroke amount, Before Kkuautopin starts releasing motion, the as drive shaft-like member is positioned at the knock-out start position, and moving the drive shaft member.
The knockout control method for a forging press according to a second aspect of the present invention is the knockout control method according to the first aspect, wherein the reaction force is different from the prescribed reaction force when the drive shaft member is moved by the play stroke amount. A release motion is started from a position where the prescribed reaction force is obtained.
The knockout control method for a forging press according to a third aspect of the present invention is the knockout control method according to the first or second aspect, wherein the reaction force when the drive shaft member is moved by the play stroke amount is different from the prescribed reaction force. The play stroke amount is changed to a movement amount of the drive shaft member from the reference position until the reaction force becomes the specified reaction force.
(Knockout device)
A forging press according to a fourth aspect of the present invention is a forging press provided with a knockout device, wherein the knockout device includes a knockout pin and a knockout pin operating means for operating the knockout pin, and the knockout pin is moved up and down. A plurality of shaft-shaped members arranged side by side along the direction, and each shaft-shaped member is disposed side by side along the ascending / descending direction and supports a mold and a plurality of molds The knockout pin actuating means is arranged to be movable up and down on each member, and the knockout pin actuating means raises and lowers a drive shaft-like member located at the lowermost layer among the plurality of shaft-like members, and operates the raising and lowering portions. A control unit for controlling, and a reaction force detection unit for detecting a reaction force applied to the knockout pin. The control unit moves the drive shaft member from the reference position to the reaction force. The movement amount of the reaction force detected by the detection unit is defined moved to the reaction force to become knockout starting position, characterized in that it comprises a play stroke storage unit for storing a play stroke.
The forging press according to a fifth aspect of the present invention is the forging press according to the fourth aspect, wherein the control unit is configured such that the reaction force when the drive shaft member is moved by the play stroke amount is different from the prescribed reaction force. The knockout pin is controlled so as to start a release motion from a position where becomes a prescribed reaction force.
The knockout control method for a forging press according to a sixth aspect of the present invention is the fourth or fifth aspect of the invention, wherein the control unit is configured such that the reaction force when the drive shaft member is moved by the play stroke amount is the predetermined reaction force. In a different cycle, the play stroke amount stored in the play stroke amount storage unit is changed to an amount of movement for moving the drive shaft member from the reference position to a position where the reaction force becomes a prescribed reaction force. And a quantity changing unit.

(Knockout method)
According to the first aspect of the present invention, the drive shaft member is disposed at the knockout start position at the timing of starting knockout. Then, since it is possible to start knockout from a state in which the shaft-shaped members are in contact with each other and the tips of the contact shaft-shaped members are in contact with the forged product, it is possible to prevent a deviation from occurring at the timing of starting the knockout.
According to the second aspect of the present invention, it is possible to prevent the occurrence of deviation in the knockout start timing even in cycles in which the forged states are different.
According to the third invention, since the play stroke amount can be changed during the forging operation, it is possible to prevent the occurrence of deviation in the knockout start timing even if the knockout pin is worn or the like.
(Knockout device)
According to the fourth aspect of the invention, since the play stroke amount is stored in the play stroke amount storage unit, if the drive shaft member is moved by the play stroke amount, the drive shaft member is knocked out at the timing of starting knockout. Can be placed at the starting position. Then, since it is possible to start knockout from a state in which the shaft-shaped members are in contact with each other and the tips of the contact shaft-shaped members are in contact with the forged product, it is possible to prevent a deviation from occurring at the timing of starting the knockout.
According to the fifth aspect of the present invention, it is possible to prevent a deviation from occurring at the knockout start timing even if the forging states are different cycles.
According to the sixth invention, since the play stroke amount can be changed during the forging operation, it is possible to prevent the occurrence of deviation in the knockout start timing even if the knockout pin is worn or the like.

Next, an embodiment of the present invention will be described with reference to the drawings.
FIG. 2 is a schematic explanatory view of a knockout device in the forging press of the present embodiment. In the same figure, the code | symbol D has shown the lower mold | type (henceforth only the metal mold | die D) in a pair of upper and lower molds. The mold D is held by a die holder H, and the die holder H is attached to the upper surface of the bed B via a hard plate P. That is, the mold D is supported by the bed B, the hard plate P, and the die holder H.
The bed B, the hard plate P, and the die holder H correspond to a plurality of members that support the mold D in the claims.

  As shown in FIG. 2, the mold D, the die holder H, the hard plate P, and the bed B (hereinafter referred to as the mold D) stacked in the vertical direction have through holes Dh and Hh penetrating through the vertical direction. , Ph, Bh (hereinafter referred to as through-holes Dh) are respectively formed. The molds D and the like are arranged so that the central axes of the through holes Dh and the like are positioned coaxially (on the axis CL in FIG. 2) when stacked in the vertical direction. That is, the mold D and the like are arranged so that a hole penetrating from the mold D to the bed B is formed.

  As shown in FIG. 2, a knockout pin N is disposed in a hole penetrating from the mold D to the bed B. The knockout pin N is composed of a plurality of shaft-like members NP1 to NP4, and each shaft-like member NP1 to NP4 is attached to each through hole Dh or the like of the mold D or the like.

  Each of the shaft-like members NP1 to NP4 is provided so as to be movable up and down with respect to each mold D and the like. In addition, the shaft-like members NP1 to NP4 can be extracted upward from the through holes Dh and the like, but are configured not to move more than a certain amount downward. That is, each shaft-like member NP1 to NP4 is provided so as not to drop downward from each through hole Dh or the like.

  In addition, the axial length of each of the shaft-like members NP1 to NP4 is shorter than the thickness (length in the vertical direction) of the mold D or the like in which each of the shaft-like members NP1 to NP4 is provided. Is formed. Moreover, in the state where the shaft-like members NP1 to NP4 are located at the lowest position in the through holes Dh and the like (states of FIGS. 2 and 3C), the upper and lower ends thereof are the upper surface of the mold D and the like. It is hold | maintained at the metal mold | die D etc. so that neither may protrude from a lower surface.

For this reason, in the state where the mold D or the like is stacked, the shaft-like members NP1 to NP4 can be in a state where they do not contact each other, that is, a state where a gap is formed between the end surfaces of the adjacent shaft-like members. In addition, the shaft-like members NP1 to NP4 may not exist at the position of the boundary between the molds D and the like that are in contact with each other (for example, the boundary between the lower surface of the mold D and the upper surface of the die holder H).
Therefore, since each shaft-like member NP1 to NP4 constituting the knockout pin N can be prevented from becoming an obstacle at the time of exchanging the mold D, the mold D can be replaced without removing the knockout pin N. Work can be performed.

As shown in FIG. 2, the lower end of the bed B is provided with a hydraulic cylinder 11 that is an elevating part of the knockout pin operating means 10 via a stay ST. The hydraulic cylinder 11 raises and lowers the knockout pin N, and is arranged with its rod facing upward. Moreover, the rod of the hydraulic cylinder 11 is inserted from the lower end of the through hole Bh, and the tip thereof is positioned below the lower end of the lowermost shaft member NP4 (hereinafter referred to as drive shaft member NP4).
The operation of the hydraulic cylinder 11 is controlled by the operation control unit 21 of the control unit 20. Specifically, the hydraulic circuit provided in the operation control unit 21 controls the timing and expansion / contraction speed of the hydraulic cylinder 11.

  The operation of the hydraulic cylinder 11 may be simply controlled such that the rod moves by a predetermined amount at a predetermined timing, or the movement amount of the rod (that is, the expansion / contraction amount of the hydraulic cylinder 11) is not shown in the drawing. May be detected at all times and the amount of movement may be servo-controlled. When performing servo control, a signal related to the amount of expansion / contraction of the hydraulic cylinder 11 is transmitted from the sensor to the operation control unit 21.

Since it is the above structure, if the hydraulic cylinder 11 is operated by the control part 20, the drive-shaft-like member NP4 can be raised / lowered with a predetermined | prescribed stroke, a timing, and a predetermined | prescribed speed.
When the drive shaft member NP4 rises, the upper end of the drive shaft member NP4 comes into contact with the shaft member NP3 and pushes up the shaft member NP3 from below. Similarly, the shaft member NP2 is pushed up by the shaft member NP3, and the shaft member NP1 is pushed up by the shaft member NP2. Conversely, when the drive shaft member NP4 is lowered from the raised state, the shaft members NP1 to NP3 are moved downward by their own weight as the drive shaft member NP4 is lowered.
That is, if the control cylinder 20 operates the hydraulic cylinder 11 to raise and lower the drive shaft-like member NP4, the upper end of the shaft-like member NP1 (hereinafter referred to as the contact shaft-like member NP1) located at the uppermost layer of the knockout pin N Since the upper surface Da of the mold D can be made to appear and disappear, the forged product W can be knocked out from the mold D by the knockout pin N.

  Here, when the hydraulic cylinder 11 is contracted, there is a gap between adjacent shaft members (see FIGS. 2 and 3C). A slight time lag occurs before the shaped member NP1 starts knocking out. Then, the knockout motion of the contact shaft-like member NP1 may be deviated from the knockout motion planned by the control unit 20.

  However, in the forging press of the present application, the control unit 20 of the knockout pin actuating means 10 has the following configuration, and the knockout pin actuating means 10 has the reaction force detection unit 30, so that the contact shaft The knockout motion of the shaped member NP1 and the knockout motion scheduled by the control unit 20 can be reliably matched.

In the present specification, the knockout motion means a motion (mold release motion) from when the knockout of the forged product W is actually started until the knockout pin N returns to the original position. In other words, in the knockout motion, after the drive shaft member NP4 is raised until the contact shaft member NP1 and the forged product W come into contact with each other (see FIG. 3A), the drive shaft member NP4 is positioned at the lowest position. This means the movement until the state becomes the state (the state in which the hydraulic cylinder 11 is contracted, see FIG. 3C).
In the following, the position where the drive shaft member NP4 is lowered to the lowest position is referred to as a reference position. The reference position is a position that is appropriately determined according to the forged product W, die, die holder, or the like to be knocked out. For example, the position of the drive shaft member NP4 when the hydraulic cylinder 11 is completely contracted may be used as the reference position, or the position of the drive shaft member NP4 when the hydraulic cylinder 11 is slightly extended may be used as the reference position. It may be.

  First, as shown in FIG. 2, the knockout pin actuating means 10 includes a reaction force detection unit 30 that detects a reaction force applied from the forged product W to the knockout pin N. The reaction force detection unit 30 has a function of detecting a reaction force from the forged product W applied to the knockout pin N and outputting a signal corresponding to the detected reaction force. And the reaction force detection part 30 is comprised so that this signal may be supplied to the operation control part 21 and the play stroke amount memory | storage part 22 of the control part 20 which are mentioned later.

The reaction force detection unit 30 is not particularly limited as long as it has the above function, and for example, a pressure sensor, a load cell, or the like can also be employed.
In particular, when the knockout pin N is operated by the hydraulic cylinder 11 as shown in FIG. 2, the reaction force from the forging W applied to the knockout pin N can be detected as the hydraulic pressure of the hydraulic cylinder 11. Therefore, in such a configuration, a pressure sensor that detects the hydraulic pressure of the hydraulic cylinder 11 can be employed as the reaction force detection unit 30. Then, there exists an advantage that installation of the reaction force detection part 30 and detection of reaction force become easy.

  As shown in FIG. 2, the control unit 20 includes an operation control unit 21, a play stroke amount storage unit 22, and a reaction force storage unit 23.

First, the operation control unit 21 has a function of servo-controlling the operation of the hydraulic cylinder 11 as described above.
Specifically, the operation control unit 21 stores a hydraulic circuit that supplies and discharges hydraulic oil to and from the hydraulic cylinder 11, and information on a predetermined knockout motion (reference motion) of the contact shaft member NP1. And. The operation control unit 21 has a function of operating the hydraulic circuit so that the contact shaft member NP1 is operated in the reference motion.
The reference motion information is information in which the press slide lifting / lowering timing is associated with the amount of movement of the drive shaft member NP4. That is, it is information that determines at what timing the operation of the drive shaft-like member NP4 is started and at what timing the drive shaft-like member NP4 is moved.

  The play stroke amount storage unit 22 has a function of storing a play stroke amount. The idle stroke amount means the extension amount of the hydraulic cylinder 11 from when the hydraulic cylinder 11 starts to operate until the knockout pin N starts the knockout motion. More specifically, from the state where the hydraulic cylinder 11 is contracted (the state where the drive shaft member NP4 is disposed at the reference position), there is no gap between the adjacent shaft members NP, and the adjacent shaft members are separated from each other. This means the amount of expansion of the hydraulic cylinder 11 until the reaction force detected by the reaction force detector 30 reaches the specified reaction force, that is, the amount of movement of the drive shaft member NP4.

The prescribed reaction force means that there is no gap between adjacent shaft members NP so that the adjacent shaft members are completely in contact with each other, and the tip of the contact shaft member NP1 is flush with the upper surface Da of the mold D. This is a reaction force that is a reference for determining the state of the forging, and is set to an appropriate value according to each forged product (that is, according to the die shape, the material of the forged product, etc.) The prescribed reaction force may be set based on experience, or may be set based on a value measured during a trial operation of the press facility (for example, reaction force applied to a knockout pin). Well, the method for determining the prescribed reaction force is not particularly limited.
Further, the drive shaft shape in a state in which there is no gap between the adjacent shaft-like members NP, the adjacent shaft-like members NP are completely in contact with each other, and the reaction force detected by the reaction force detection unit 30 becomes the specified reaction force. Hereinafter, the position of the member NP4 is referred to as a knockout start position.

  The reaction force storage unit 23 has a function of storing a prescribed reaction force. Based on a command from the operation control unit 21, information on the stored prescribed reaction force is stored in the operation control unit 21. It has a function to transmit.

  Since it is the above structure, the control part 20 controls the action | operation of the knockout pin N as follows in a knockout cycle.

First, as shown in FIG. 1 (A), when the control unit 20 starts a knockout cycle, the hydraulic circuit of the operation control unit 21 controls the supply and discharge of the hydraulic oil to and from the hydraulic cylinder 11 to drive the idle stroke amount. The shaft member NP4 is raised. Then, the tip of the contact shaft member NP1 is in a state where it is flush with the upper surface Da of the mold D (a reaction force is a prescribed reaction force), and the tip is in contact with the forged product W ( FIG. 3 (A)).
Subsequently, the supply and discharge of oil is controlled by the hydraulic circuit of the operation control unit 21 so that the drive shaft member NP4 moves in the reference motion. Then, the contact shaft-shaped member NP1 operates in a reference motion from a state where the tip of the contact shaft-shaped member NP1 is in contact with the forged product W, and when the forged product W is moved by the transfer feeder, the drive shaft-shaped member NP4 is lowered to the reference position. The knockout ends.

  As described above, in the forging press according to the present embodiment, after the drive shaft-like member NP4 is raised by the play stroke amount, that is, from the state where the drive shaft-like member NP4 is arranged at the knockout start position, Move. Therefore, even when there is a gap between the shaft-like members NP in a state where the hydraulic cylinder 11 is contracted, that is, in a state where the drive shaft-like member NP4 is disposed at the reference position, a deviation occurs at the timing of starting knockout. Can be prevented.

Hereinafter, of the operation control of the hydraulic cylinder 11 by the operation control unit 21, the control for raising the drive shaft member NP4 by the play stroke amount from the contracted state of the hydraulic cylinder 11 is referred to as play correction control.
Further, there is no gap between the adjacent shaft-shaped members, the adjacent shaft-shaped members are completely in contact with each other, and the reaction force detected by the reaction force detection unit 30 becomes the specified reaction force, in other words, the contact shaft From the state in which the tip of the shaped member NP1 is flush with the upper surface Da of the mold D (hereinafter referred to as the play correction end state), control is performed to expand and contract the hydraulic cylinder 11 so that the knockout pin N is operated in the reference motion. This is called knockout operation control.

(Set play stroke amount)
Here, in order to perform the play correction control described above, the play stroke amount must be set, but the play stroke amount can be set by the following method.
The play stroke amount setting operation will be described below with reference to FIGS.

  First, the forging press is operated and forging work is started. At this time, the play stroke amount is not set, or the play stroke amount when the previous forging operation is performed is set.

  When the first forging is completed, the hydraulic cylinder 11 is operated by the operation control unit 21 of the control unit 20, the hydraulic cylinder 11 is extended, and the drive shaft member NP4 is raised as the hydraulic cylinder 11 is extended. Then, the shaft-shaped member NP3, the shaft-shaped member NP2, and the shaft-shaped member NP1 are sequentially pushed up, and eventually all the gaps between the adjacent shaft-shaped members disappear and all the shaft-shaped members NP1 to NP4 are in contact with each other (FIG. 3 (B)).

  Even after all the shaft-like members NP1 to NP4 are in contact with each other, the operation (extension) of the hydraulic cylinder 11 is further continued. Then, a force is applied to the forged product W from the upper end of the contact shaft member NP1 to push the forged product W upward, so that a reaction force from the forged product W is applied to the knockout pin N.

Further, when the operation of the hydraulic cylinder 11 is continued so that the drive shaft member NP1 urges the forged product W upward, the reaction force applied to the knockout pin N increases.
When the reaction force applied to the knockout pin N reaches the specified reaction force, the operation of the hydraulic cylinder 11 is temporarily stopped. Then, the operation amount (extension amount) of the hydraulic cylinder 11 from the start of operation to the current state, in other words, the amount of movement of the drive shaft member NP4 from the reference position until the specified reaction force is detected (up to the knockout start position) is idle. The play amount is stored in the play stroke amount storage unit 22 as a stroke amount.

  After the idle stroke amount is set, knockout operation control is executed by the operation control unit 21, and the knockout pin N is operated in the reference motion. Then, from the next knockout cycle, play correction control based on the set play stroke amount and knockout operation control are executed in order.

In the above embodiment, the play stroke amount is set in one knockout cycle. However, the play stroke amount may be set based on a plurality of knockout cycles.
That is, as shown in FIG. 4B, during a plurality of cycles (for example, 10 cycles) from the press operation, the drive shaft-like member NP4 until the specified reaction force is detected from the reference position in each cycle by the above method. Is stored in the play stroke amount storage unit 22. In addition, when the movement amount of the drive shaft member NP4 is obtained a predetermined number of times, the play stroke amount may be calculated based on the stored movement amount. The method for calculating the play stroke amount is not particularly limited. For example, an average value of the total movement amounts may be set as the play stroke amount, or a minimum value or the like may be set as the play stroke amount.

(Adjustment for each cycle)
In addition, depending on the forging situation, there is a cycle in which the reaction force when the drive shaft member NP4 is moved by the play stroke amount exceeds the allowable range and deviates from the specified reaction force. In such a case, when the reaction force detection unit 30 detects the prescribed reaction force, the drive shaft member NP4 may be controlled to move in the reference motion (FIG. 5).
For example, when the prescribed reaction force is reached before the play stroke amount is moved, the reaction force detected by the reaction force detector 30 is the prescribed reaction force even if the drive shaft member NP4 is not moved by the play stroke amount. Control is performed so that the movement of the drive shaft member NP4 is stopped at this timing, and the state is maintained until the timing at which the reference motion is started.
On the other hand, if the prescribed reaction force is not obtained even if the play stroke amount is moved, the drive shaft member NP4 moves until the prescribed reaction force is reached, and the reaction force detected by the reaction force detection unit 30 is the prescribed reaction force. At this time, the movement of the drive shaft member NP4 is stopped, and control is performed so that the state is maintained until the timing of starting the reference motion.
Then, even if there is a cycle in which the forging state is greatly deviated from the normal cycle, stable knockout can be performed.

(Change of play stroke amount)
Further, if the forging operation is performed for a long time, the end portions of the shaft-like members NP1 to NP4 may be worn and the length thereof may be shortened. In addition, when thermal expansion or the like of the mold occurs, a situation equivalent to the case where the shaft-like member NP1 is shortened occurs. Then, even if the drive shaft member NP4 is moved to the knockout start position, the tip of the contact shaft member NP1 and the upper surface Da of the mold D are not flush with each other, and the tip of the contact shaft member NP1 is gold. It will be arranged at a position recessed from the upper surface Da of the mold D. In such a state, the knockout motion is displaced, so that the knockout pin N is replaced if it is a normal forging press.

  However, in the forging press of the present embodiment, since the reaction force detection unit 30 as described above is provided, the control unit 20 includes the operation control unit 21, the play stroke amount storage unit 22, and the reaction force storage unit 23. In addition, if the play stroke amount changing unit 24 is provided, the play stroke amount can be adjusted while performing the forging operation, so that the knockout motion can be corrected.

The play stroke amount changing unit 24 of the control unit 20 obtains the play stroke amount changed due to wear of each of the shaft members NP1 to NP4, that is, the play stroke amount in the current state, and stores the play stroke amount in the play stroke amount storage unit 22. It has a function of changing the amount of play stroke that is being played to the amount of play stroke in the current state.
This idle stroke amount changing unit 24 is based on the reaction force signal transmitted from the reactive force detecting unit 30 and the movement amount of the drive shaft member NP4 (in other words, the actuation amount of the hydraulic cylinder 11). The play stroke amount stored in the amount storage unit 22 is changed. Specifically, the reaction force (reaction force at the end of play correction) when the drive shaft member NP4 moves by the play stroke amount is compared with the specified reaction force, and the reaction force at the end of play correction is different from the specified reaction force. In this case, the function of changing the amount of play stroke stored in the amount of play stroke storage unit 22 to the amount of movement of the drive shaft member NP4 until the reaction force detected by the reaction force detection unit 30 reaches the specified reaction force. have.

  Further, when the reaction force at the end of the play correction is smaller than the prescribed reaction force, the play stroke amount changing unit 24 stops the play control from the play correction control to the knockout operation control and performs the play correction control. It also has a function of sending a command to continue (play correction continuation command). Note that the continuation of the play correction control means that the drive shaft member NP4 is moved at the same speed as that during the play correction control.

  Further, when the reaction force detected by the reaction force detection unit 30 is the same as the prescribed reaction force, the play stroke amount changing unit 24 controls the operation control unit 21 from play correction control to knockout operation control. It also has a function of sending a command for switching (control switching command).

  Next, an operation of changing the play stroke amount when the play stroke amount changing unit 24 is provided as described above will be described with reference to FIG.

(Change work when the amount of play stroke is long)
As shown in FIG. 6, when the forging process of each forging cycle is completed, a knockout cycle is started and play correction control of the operation control unit 21 of the control unit 20 is executed. Then, the hydraulic cylinder 11 is operated so that the drive shaft-like member NP4 is raised by the play stroke amount.
The reaction force detector 30 detects the reaction force applied to the knockout pin N even during a period in which the drive shaft member NP4 rises by the amount of the play stroke, and information about the detected reaction force is sequentially changed in the amount of play stroke. Is transmitted to the unit 24.

Eventually, when the drive shaft-shaped member NP4 rises by the amount of play stroke, the reaction force (reaction force at the end of play correction) and the prescribed reaction force transmitted from the reaction force detection unit 30 in this state by the play stroke amount changing unit 24 Are compared.
If the reaction force at the end of play correction is the same reaction force as the specified reaction force, no signal is transmitted from the play stroke amount changing unit 24 to the operation control unit 21. In this case, the control of the hydraulic cylinder 11 by the operation control unit 21 is switched from the play correction control to the knockout operation control, and the knockout pin N is operated in the reference motion.

On the other hand, if the reaction force at the end of play correction is smaller than the prescribed reaction force, a play correction continuation command is transmitted from the play stroke amount changing unit 24 to the operation control unit 21. Then, the play correction control is continued by the operation control unit 21, and the operation of the hydraulic cylinder 11 is controlled so that the drive shaft-like member NP4 rises at the moving speed at the play correction control.
During this time, the reaction force detection unit 30 detects the reaction force applied to the knockout pin N, and information on the detected reaction force is sequentially transmitted to the play stroke amount changing unit 24.

As the drive shaft member NP4 rises, the tip of the contact shaft member NP1 comes into contact with the forged product W. If the drive shaft member NP4 continues to rise after the tip of the contact shaft member NP1 contacts the forged product W, the reaction force detected by the reaction force detector 30 will eventually become the same magnitude as the specified reaction force. Become.
Then, the idle stroke amount stored in the idle stroke amount storage unit 23 is changed by the idle stroke amount changing unit 24 to the movement amount of the drive shaft member NP4 up to the present in this cycle.
At the same time as the change of the play stroke amount or after the change of the play stroke amount, a control switching command is transmitted from the play stroke amount change unit 24 to the operation control unit 21. Therefore, the control by the operation control unit 21 controls the play correction control. Is switched to the knockout operation control, and the knockout operation control is executed. Then, the knockout pin N is operated with the reference motion from the current state. That is, the movement of the knockout pin N is stopped until a predetermined timing, and the knockout pin N is operated so as to knock out the forged product W from the predetermined timing.

(Change work when the amount of play stroke is shortened)
In the above example, the case where the reaction force at the end of play correction is smaller than the prescribed reaction force has been described. However, when the reaction force at the end of play correction is larger than the prescribed reaction force, in other words, the drive shaft member NP4 In some cases, the reaction force detected by the reaction force detection unit 30 before rising by the stroke amount has the same magnitude as the specified reaction force.
In such a case, when the reaction force detected by the reaction force detection unit 30 is the same as the prescribed reaction force, the play stroke amount changing unit 24 sets the play stroke amount stored in the play stroke amount storage unit 23 to the reference position. To the amount of movement of the drive shaft-like member NP4 until the specified reaction force is detected (FIG. 6).
Simultaneously with the change of the idle stroke amount or after the idle stroke amount is changed, the idle stroke amount changing unit 24 transmits a control switching command to the operation control unit 21. Then, the control by the operation control unit 21 is switched from the play correction control to the knockout operation control, the knockout operation control is executed, and the movement of the knockout pin N is stopped until a predetermined timing. It is actuated to knock out.

As described above, the play stroke amount changing unit 24 can adjust the play stroke amount to an appropriate amount. Therefore, even if the knockout pin N is worn or the like, the tip of the contact shaft member NP1 remains on the upper surface of the mold D. The movement of the knockout pin N can be started based on the reference motion from a state where it is flush with Da. Therefore, even if it forges for a long time, it can prevent generating a shift | offset | difference at the knockout start timing.
Moreover, in the forging press according to the present embodiment, if a predetermined knockout stroke (lift amount from the die D of the forged product W) can be secured, the knockout pin N can be knocked out even if the worn knockout pin N is continuously used as it is. It is possible to prevent the motion from being shifted.
Therefore, since the service life of the knockout pin N can be increased, the frequency of maintenance of the knockout pin N and the like can be suppressed, and the production efficiency is improved.

  Here, in the above example, at the end of the knockout motion, the drive shaft member NP4 is lowered to the reference position. Therefore, if play correction control is performed, the drive shaft member NP4 is surely placed at the knockout start position at the timing of starting the knockout. There is an advantage that it can be arranged.

  On the other hand, instead of the play correction control, the operation of the hydraulic cylinder 11 is controlled so that there is no gap between the adjacent drive shaft members NP during the period from the end of the knockout motion to the timing of starting the knockout. May be. This is preferable because the operation control of the knockout pin N is quick and easy.

  Specifically, when the movement amount of the drive shaft member NP4 (the extension amount of the hydraulic cylinder 11) matches the idle stroke amount in the state where the knockout pin N is operating in the reference motion by the control unit 20, the timing Then, the operation of the hydraulic cylinder 11 is stopped, and control is performed so that the operation of the hydraulic cylinder 11 is stopped until the timing of starting the knockout. In this case, the play correction control is performed only in the first cycle after the press operation, and in the subsequent cycles, there is always no play stroke, in other words, knock out from the state where there is no gap between the adjacent drive shaft members NP. The pin N can be actuated (FIG. 1B). Then, since it is sufficient to perform the play correction control only in the first cycle, the operation control of the knockout pin N is quicker and easier than in the case where the play correction control is performed every cycle.

  In the period from the end of the knockout motion to the timing at which the knockout is started, the method for setting the gap between the adjacent drive shaft members NP is not limited to the above method. For example, in the knockout motion, the hydraulic cylinder 11 is operated so as to rise by the play stroke amount immediately after the drive shaft member NP4 returns to the reference position, and then the operation of the hydraulic cylinder 11 is stopped until the timing of starting the knockout. You may perform control which maintains in the state which carried out.

Further, in the above example, the case where the forged product W is formed in a state where the upper surface of the contact shaft-shaped member NP1 is not in contact with the forged product W after molding unless the drive shaft-shaped member NP4 is raised to the knockout start position will be described. (FIGS. 2 and 3). In other words, the case where the upper surface of the contact shaft member NP1 is not in contact with the forged product W in the state where the contact shaft member NP1 is located at the lowest position in the through hole Dh of the mold D has been described.
However, depending on the forged product W, even when the contact shaft-like member NP1 is positioned at the lowest position in the through hole Dh of the mold D, the upper surface of the contact shaft-like member NP1 may contact the forged product W after molding. is there. That is, the upper surface of the contact shaft member NP1 may also function as a part of a mold for forming the forged product W (see FIG. 7).
In such a case, if there is no gap between the adjacent drive shaft-like members NP, it is possible to prevent deviation from occurring at the timing of starting the knockout. The amount of movement of the drive shaft-like member NP4 until there is no state may be the amount of play stroke. In this case, the position of the drive shaft member NP4 in a state where there is no gap between the adjacent drive shaft members NP is the knockout start position.

(Example using different lifting parts)
In the above example, the case where the hydraulic cylinder 11 is employed as the lifting unit has been described. However, the lifting unit may be configured as shown in FIG.

  In FIG. 8, reference numeral 12 denotes a servo motor disposed with the main shaft facing upward, and the screw shaft 13a of the ball screw 13 is connected to the main shaft of the servo motor 12 via a coupling 12a. Has been. A nut 13b is screwed to the screw shaft 13a, and the nut 13b is connected to the lower end of the drive shaft member NP4 via the connecting member 14. The connecting member 14 does not rotate with the screw shaft 13a. In other words, the nut 13b of the ball screw 13 does not rotate even if the screw shaft 13a rotates.

In such a configuration, the movement amount of the drive shaft member NP4 can be controlled by the rotation amount of the main shaft of the servo motor 12 instead of the expansion / contraction amount of the hydraulic cylinder 11 and the movement amount of the drive shaft member NP4. Then, the movement amount of the drive shaft member NP4 can be accurately controlled, and the play stroke amount can be grasped more accurately.
Further, when the force required for driving the knockout pin N increases, the servo motor 12 increases the amount of current required to maintain a predetermined rotational speed. That is, as the reaction force applied to the knockout pin N increases, the amount of current supplied to the servo motor 12 increases. Therefore, as shown in FIG. 6, when the knockout pin N is driven by the servomotor 12, instead of the reaction force applied to the knockout pin N, based on the change in the amount of current supplied to the servomotor 12. The contact between the forged product W and the contact shaft member NP1 can be determined. Then, since it is not necessary to provide the special reaction force detection part 30, a knockout apparatus can be made into a simple structure.

  The knockout control method in the forging press of the present invention is suitable for a forging press equipped with a knockout device that controls the operation of a knockout pin by a servo mechanism.

5 is a flowchart of the knockout control method of the present embodiment, where (A) is a flowchart of the knockout control method when play correction control is performed every cycle, and (B) is a knockout when play correction control is performed only once. It is a flowchart of a control method. It is a schematic explanatory drawing of the knockout apparatus in the forge press of this embodiment. It is the figure explaining the action | operation of the apparatus in the knockout operation | work by the knockout control method of this embodiment. It is a flowchart of the operation | work which sets the amount of idle strokes, Comprising: (A) is a flowchart in the case of setting the amount of idle strokes in one cycle, (B) is the flowchart in the case of setting the amount of idle strokes in the average of several cycles. It is. It is a flowchart of the operation | work when the reaction force when moving by the amount of play strokes has shifted | deviated from the regulation reaction force. It is a flowchart of play stroke amount change work. It is a schematic explanatory drawing of the knockout apparatus in the forge press of other embodiment. In the forge press of this embodiment, it is a schematic explanatory drawing of the knockout apparatus which employ | adopted a different raising / lowering part.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Knockout pin operation means 11 Hydraulic cylinder 12 Servo motor 13 Ball screw mechanism 20 Control part 21 Operation control part 22 Play stroke amount memory | storage part 23 Reaction force memory | storage part 24 Play stroke amount change part P Knockout pin NP Shaft member NP1 Contact shaft shape Member NP4 Drive shaft member D Mold B Bed

Claims (6)

In a forging press equipped with a knockout device that operates a knockout pin to release a forged product from a mold, a control method for controlling the operation of the knockout pin,
The knockout device is
A reaction force detection unit for detecting a reaction force applied to the knockout pin;
The knockout pin is
It is composed of a plurality of shaft-like members arranged side by side along the ascending / descending direction,
Each shaft-shaped member
A plurality of members that support the mold are arranged so as to be movable up and down along the ascending / descending direction.
A movement amount for moving the drive shaft-shaped member from a reference position to a knockout start position where a reaction force detected by the reaction force detection unit becomes a specified reaction force is set as a play stroke amount.
A knockout control method in a forging press, wherein the drive shaft-shaped member is moved so that the drive shaft-shaped member is positioned at the knockout start position before the knockout pin starts mold release motion. In a cycle in which the reaction force when the drive shaft member is moved by the play stroke amount is different from the specified reaction force, a mold release motion is started when the reaction force becomes the specified reaction force. The knockout control method for a forging press according to claim 1, wherein In a cycle in which the reaction force when the drive shaft member is moved by the play stroke amount is different from the prescribed reaction force,
3. The knockout control in the forging press according to claim 1, wherein the play stroke amount is changed to an amount of movement of the drive shaft member from the reference position until the reaction force becomes the specified reaction force. 4. Method. A forging press equipped with a knockout device,
The knockout device is
With a knockout pin,
A knockout pin actuating means for actuating the knockout pin;
The knockout pin is
It is composed of a plurality of shaft-like members arranged side by side along the ascending / descending direction,
Each shaft-shaped member
A plurality of members that support the mold and the mold disposed side by side along the ascending / descending direction are disposed so as to be movable up and down.
The knockout pin operating means is
Among the plurality of shaft-shaped members, a lifting unit that lifts and lowers the drive shaft-shaped member located in the lowest layer,
A control unit for controlling the operation of the elevating unit;
A reaction force detector for detecting a reaction force applied to the knockout pin,
The control unit
A play stroke amount storage unit for storing, as a play stroke amount, a movement amount for moving the drive shaft-shaped member from a reference position to a knockout start position where a reaction force detected by the reaction force detection unit becomes a prescribed reaction force; Forging press characterized by having. The controller is
In a cycle in which the reaction force when the drive shaft member is moved by the play stroke amount is different from the prescribed reaction force, the knockout pin starts a release motion from a position where the reaction force becomes the prescribed reaction force. The forging press according to claim 4, wherein the forging press is controlled as follows. The controller is
In a cycle in which the reaction force when the drive shaft-shaped member is moved by the play stroke amount is different from the prescribed reaction force, the play stroke amount stored in the play stroke amount storage unit is changed from the reference position to the reference position. The forging press according to claim 4 or 5, further comprising an idle stroke amount changing portion that changes the amount of movement of the drive shaft member to a position where the reaction force becomes a prescribed reaction force.

Images