JP2000202882A - Operation control device for mold - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an operation control device for a mold having a simple structure and capable of certainly opening a mold in determined order in a mold for a synthetic resin performing mold opening at least at two places. SOLUTION: A release lever 12 is attached to a fixed plate member 11 and a holding member 18 is attached to a movable plate member 17. A lock member 22 having a lock pawl provided to one end part thereof is attached to the holding member 18 in a freely revolvable manner by a lock pin and a fixing member 29 is attached to an intermediate plate member 28. In such a state that the respective plate members constituting a mold 34 are closed, the lock pawl is locked to the fixing member 29. The release lever 12 releases the lock pawl from the fixing member 29 in such a stage that the intermediate plate member 28 and the fixed plate member 11 constituting the mold 34 are opened by a predetermined distance.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an operation control device for a mold provided on a molding die for synthetic resin comprising a plurality of plate members, wherein the plate member is divided into two or more portions and a molded product is taken out. It is.

[0002]

2. Description of the Related Art Conventionally, gate systems of molding dies for synthetic resins are generally classified into a pin gate type and a side gate type. In particular, in the case of the pin gate type, the runner can be automatically cut from the molded product. This pin gate type molding die has at least two divided surfaces, and by controlling the mold opening in a predetermined order, the runner can be cut from the molded product, and the cut runner or molded product can be cut. Can be automatically taken out of the molding die.

[0003] The opening sequence of a pin gate type molding die is ideally such that a predetermined division surface starts opening the mold first, and then the next division surface starts opening the mold. However, since this molding die is provided with a special means for controlling the order of opening the molds, it is completely uncertain which split face is opened first. For this reason, when the order of opening the molds is reversed, the mold may be moved to the next step and closed with the molded product remaining in the mold. As a result, damage to the cavity or the core was induced, or the molding operation was interrupted each time, and the molded product was removed from the molding die, so that the movable ratio of the molding die was significantly reduced.

[0004] Accordingly, the operation control device for the mold has been disclosed in
No. 46990 (B29C 45/26) discloses a mold sequencer. The mold operation control device 100 is attached to the side surface of the molding die 101, and when the injection of the molten resin (not shown) from the molten resin injection port 114 is completed, the fixed side plate member 103 and the intermediate plate The first mold division plane PL11 which is a division plane with the member 104, and the second mold division plane PL12 which is a division plane between the intermediate plate member 104 and the movable side plate member 105 are in a mold closed state (FIG. 23). . Fixed side plate member 10
Reference numeral 3 denotes a fixed platen of a molding machine (not shown) via a fixed side mounting plate 102, and a movable side plate member 105
6, mounted on a movable platen of a molding machine (not shown) via a spacer block 107 and a movable-side mounting plate 108.

[0005] Then, when the process proceeds to the next step of taking out a molded product (not shown) from the mold closed state, the movable platen of the molding machine starts operating. In this case, the lock pin 110 attached to the intermediate plate member 104 and attached to the housing 109 of the mold operation control device 100 is moved by the spring 111 to the notch 1 of the latch bar 112.
12A, the intermediate plate member 104 is always urged in the direction of the release bar 113.
It is moved downward in the figure while being locked in A (FIG. 24). By this operation, the first mold division surface PL11 is opened, and although not shown, the runner and the molded product are separated at this time.

[0006] Since the intermediate plate member 104 and the movable plate member 105 are integrally combined via the latch bar 112 and the lock pin 110 and move downward, at this time, the second mold division plane PL12 is formed. Are prevented from opening. When the movable platen is further operated, the notch 112A of the latch bar 112 is located beside the notch 113A of the release bar 113. As a result, the lock pin 110 can move in the direction of the release bar 113, and the projection 110A of the lock pin 110 is urged by the spring 111 to move from the inside of the notch 112A of the latch bar 112 to the inside of the notch 113A of the release bar 113. Moving.

By this operation, the intermediate plate member 104
The lock pin 110 attached to the fixed plate 102 via the housing 109 is locked by a release bar 113 attached to the fixed-side attachment plate 102, and the intermediate plate member 104 stops moving downward. When the latch bar 112 continues to move further downward, the intermediate plate member 104 is stopped from moving downward by the fixed-side mounting plate 102 via the lock pin 110 and the release bar 113. The second mold division plane PL2 between the movable plate member 104 and the movable plate member 105 was opened, and a molded product (not shown) protruded from the movable plate member 105.

[0008]

However, when the lock pin of the mold operation control device is moved by the urging force of the spring, the lock pin is attached to the movable platen, which is attached to the movable platen and is operated by the movable plate. The protrusion of the lock pin is locked to the latch bar, and the intermediate plate member has been moved downward. Due to this operation, a load that rotates in the direction orthogonal to the moving direction occurs at the protrusion of the lock pin, and the lock pin may malfunction in the housing, and the next mold opening is not performed. In some cases, it did.

[0009] Further, the mold operation control device has a problem that the opening dimension between the fixed side plate member and the intermediate plate member is limited by the engagement of the lock pin with the notch of the release bar.

The present invention has been made in order to solve the problems of the prior art, and relates to a molding die for a synthetic resin having at least two mold openings, which has a simple structure and a predetermined structure. An object of the present invention is to provide a mold operation control device that can surely open a molding die in order.

[0011]

According to a first aspect of the present invention, there is provided a mold operation control device including a plurality of plate members including a fixed plate member, a movable plate member, and an intermediate plate member. It is provided in a molding die for synthetic resin, the plate member is divided into at least two places, and a molded product is taken out. The release lever attached to the fixed side plate member and the release lever attached to the movable side plate member. A holding member, a lock member rotatably attached to the holding member by a hinge pin and having a lock claw at one end, and a fixing member attached to the intermediate plate member, wherein each plate member is closed. In this state, the lock claw is locked by the fixing member, and when the intermediate plate member and the fixed plate member are opened a predetermined distance, the release lever is fixed to the fixing portion. Is obtained so as to release the locking pawl from.

Further, in the mold operation control device according to the second aspect of the present invention, in addition to the above, the locking claw and the fixing member are configured to be wide, and the locking claw and the fixing member are locked at a predetermined acute angle. Things.

According to a third aspect of the present invention, in addition to the first or second aspect, the mold operation control device further includes a support portion provided at the other end of the release lever, and the support portion is provided with a lock claw. It is provided on the opposite surface.

Further, in the mold operation control device according to the fourth aspect of the present invention, in addition to the first, second or third aspect, an engaging projection is provided at the other end of the lock member. The collision portion is projected from the other surface of the lock claw.

Further, in the mold operation control device according to the fifth aspect of the present invention, in addition to the first aspect, the center of the hinge pin is brought closer to the surface of the locking member provided on the locking member.

[0016]

Next, an embodiment of the present invention will be described in detail with reference to the drawings. FIG. 1 is a perspective view of a molding die 34 for a synthetic resin to which the mold operation control device 10 of the present invention is applied, FIG. 2 is a top view of the mold operation control device 10 of the present invention, and FIG. FIG. 4 is a longitudinal sectional front view of the mold operation control device 10 of the present invention, and FIG. 5 is a side view of the mold operation control device 10 of the present invention. I have. In the drawings, the components denoted by the same reference numerals are the same.

The mold operation controller 10 opens a synthetic resin molding mold 34 composed of a plurality of plate members and having at least two mold openings in a predetermined order.
Holding member 18, locking member 22, fixing member 29,
And a release lever 12. The holding member 18 is made of a strong metal such as iron, and has a length of about 10 mm.
It has a shape of 3 mm, a width of about 30 mm, and a thickness of about 36 mm. A recess 19 is provided at the center of the holding member 18, and the recess 19 has a depth of about 28 mm on one side in the width direction (in this case, the engagement section 20 side) and a depth of about 27 mm on the other side. (FIGS. 6 and 7). On one side of the recess 19, an engaging portion 20 cut out to a depth of about 4 mm and a width of about 47 mm is formed (FIG. 8).

That is, the recess 19 formed in the holding member 18
An engaging portion 20 is provided on one side, and a slope having a depth of about 28 mm on one side in the width direction and a depth of about 27 mm on the other side is formed continuously with the engaging portion 20. The recess 19 has an engaging portion 20.
A through hole 21 having a diameter of about 6 mm is provided on the opening side of the recess 19 with a small interval. The through hole 21 is the holding member 1
8 is provided to extend in the longitudinal direction, and a hinge pin 26 is configured to be insertable, and a lock member 22 described later is rotatably supported by the hinge pin 26. 18A, 18A are bolt insertion holes, 18B
Is an auxiliary spring insertion hole.

The lock member 22 is configured to control the opening order of the first mold division plane PL1 and the second mold division plane PL2 of the synthetic resin molding mold 34 described later. . That is, the lock member 22 is connected to the second mold dividing surface PL2.
Is closed, the first mold division plane PL1 can be opened first. The lock member 22 is made of a strong metal such as iron, like the holding member 18, and is formed to be as wide as about 69 mm in length, about 8 mm in thickness, and about 30 mm in width. (FIGS. 9 and 10).

The lock member 22 is provided with a lock claw 23. The lock claw 23 is provided at one longitudinal end of the lock member 22. The lock claw 23 projects at an acute angle about 18 mm inward from one end of the lock member 22 (in this case, projects about 6 mm while being inclined toward the other end).
It is configured such that it does not easily come off when locked to a claw engaging portion 30 of a fixing member 29 described later. The tip end of the lock claw 23 is formed with an inclined portion 23A that extends a little in the direction of one end and reaches the rear plate thickness. That is, the lock claw 23 is formed at an acute angle so as to protrude from one surface of one end portion of the lock member 22 in the longitudinal direction, and is provided to extend in the entire width direction. 22A is an auxiliary spring insertion hole.

An engaging projection 24 is provided at the other end of the lock member 22.
And protrude to the opposite side. This engaging projection 2
Reference numeral 4 is provided so as to protrude from the lock member 22 by about 4 mm, and is provided so as to extend about 10 mm from one end to the other end. That is, the engagement protrusion 24 is provided so as to protrude from the other surface of the lock member 22, and is configured to be engaged with the engagement portion 20 of the holding member 18. In addition, the lock member 22
An engagement hole 25 having a diameter of about 6 mm is provided at the other end of the lock member 22. The engagement hole 25 extends in the width direction of the lock member 22 and is provided therethrough. That is, the engagement hole 25 is provided in parallel with the engagement protrusion 24 and the center is provided near the one surface side of the lock member 22.

The fixing member 29 is made of a metal such as iron having a high strength, like the holding member 18, and is about 103 mm long and about 1 mm thick.
8 mm and a width of about 24 mm (see FIG. 1).
1, FIG. 12). Approximately 55 m wide on one side of the center of the fixing member 29
m claw engagement portions 30 are formed.
Are formed so as to have the same slope as the lock claw 23 (FIG. 13). The width of about 20 is approximately at the center of the fixing member 29.
The lever insertion portion 31 having a depth of about 13.5 mm and a depth of about 13.5 mm is formed. The release lever 12 described later is inserted into the lever insertion section 31 and is movable.
Reference numeral 29A denotes an inclined portion, which is configured so that the inclined portion 23A formed at the tip of the lock claw 23 can move smoothly without being caught. Reference numeral 32 denotes a bolt insertion hole for fixing to the intermediate plate member 28 with a bolt (not shown).

The release lever 12 is used to release the lock member 22 locked by the fixing member 29. The release lever 12 is made of a strong metal, such as iron, like the holding member 18, and has a length of about 12 mm.
It has a size of 5 mm, a width of about 18 mm, and a thickness of about 6 mm (FIGS. 14 and 15). A support portion 13 is provided on one side of the release lever 12 in the longitudinal direction.
Has a height of about 7.5 mm. The support part 13 is formed at a position of about 5 mm to 12 mm from one end of the release lever 12, and slope parts 14, 14 formed at about 30 degrees are provided on both sides of the support part 13.

The support portion 13 of the release lever 12 is configured to push up the lock claw 23 of the lock member 22 and release the lock claw 23 locked by the claw engagement portion 30 of the fixing member 29. Further, the support portion 1 of the release lever 12
3 is an engaging projection 24 formed at the other end of the lock member 22.
And push the lock claw 23 to the claw engaging portion 3 of the fixing member 29.
It is configured to lock to zero.

A mounting portion 15 is formed on the other side of the release lever 12, and the mounting portion 15 has a length of about 29.
mm, a height of about 7 mm, and protruding from the side opposite to the support portion 13. The mounting portion 15 is provided with mounting holes 16, 16, and a bolt (not shown) is inserted into the mounting holes 16, 16 so that the release lever 12 is fixed to a fixed-side plate member 11 described later. I have.

On the other hand, the molding die 34 is composed of the fixed side plate member 11, the movable side plate member 17, and the intermediate plate member 28 provided between the fixed side plate member 11 and the movable side plate member 17. (FIG. 16).
The fixed-side plate member 11 is attached to a fixed-side mounting plate 35, and the movable-side plate member 17 is
It is mounted on a movable mounting plate 38 via a spacer block 37. A first mold division plane PL1 is defined between the fixed plate member 11 and the intermediate plate member 28, and a second mold division plane PL2 is defined between the intermediate plate member 28 and the movable plate member 17.

Then, the claw engaging portion 30 of the fixing member 29 is located on the fixed side plate member 11 side, a bolt (not shown) is inserted into the bolt insertion hole 32, and the fixing member 29 is fixed to the intermediate plate member 28. Further, the support portion 13 of the release lever 12 is located on the intermediate plate member 28 side and installed on the fixed side plate member 11. Then, the mounting holes 16, 1
A bolt (not shown) is inserted into 6 and the release lever 12 is fixed to the fixed-side plate member 11. In this case, the mounting portion 15 protruding from the release lever 12 is fixed facing the fixed side plate member 11 side, and the support portion 1 is fixed.
3 is movably mounted in a lever insertion portion 31 formed in the fixing member 29.

Next, the lock member 22 is attached to the holding member 18. In this case, a through hole 21 provided in the holding member 18 with the auxiliary spring insertion hole 18B provided in the recess 19 of the holding member 18 and the auxiliary spring insertion hole 22A provided in the lock member 22 facing each other, The hinge pin 26 is inserted into the engagement hole 25 and the through hole 21 by communicating with the engagement hole 25 provided in the lock member 22. A stopper 27 such as an E-ring is attached to an end of the hinge pin 26 so that the hinge pin 26 inserted into the engagement hole 25 does not come off. This hinge pin 26 allows the lock member 2
2 is rotatably attached to the holding member 18. Next, bolt insertion holes 18A, 1A provided in the holding member 18 are provided.
A bolt (not shown) is inserted into 8A, and the holding member 18 is fixed to the movable side plate member 17. Reference numeral 33 denotes an auxiliary coil spring for urging the lock member 22 toward the fixing member 29.

That is, when the molding die 34 is in the mold closed state (the state in which the first mold division plane PL1 and the second mold division plane PL2 are closed), the lock claw 23 of the lock member 22 is fixed to the fixing member 2.
9 is locked by being engaged with the claw engaging portion 30 of the lock member 22, and the support portion 13 of the release lever 12 abuts on the other end of the opposite surface of the engaging protrusion 24 formed on the other end of the lock member 22. Is configured. As a result, the lock claw 23 is pressed toward the claw engagement portion 30 with the hinge pin 26 as a fulcrum, so that the lock claw 23 is securely engaged with the claw engagement portion 30 and the second mold split surface PL2 (intermediate). The plate member 28 and the movable side plate member 17) are securely locked without opening.

Next, the mold operation control device 1 having the above-described configuration is used.
The operation of 0 will be described. The fixed-side mounting plate 35 is attached to a fixed platen of a molding machine (not shown), and the movable-side mounting plate 38 is attached to a movable platen of a molding machine (not shown). In addition, the mold operation control device 10 is provided on a pair of front and rear surfaces of the molding mold 34 (in this case, substantially at the center of the vertical width).
Shall be provided. In the figure, reference numeral 39 denotes a support pin for loosely fitting the fixed-side plate member 11 via the fixed-side mounting plate 35, and a stopper 39A provided at the end to prevent the first mold division plane PL1 from opening more than a predetermined stroke. The intermediate plate member 28 is controlled.

Reference numeral 40 denotes a guide pin which is slidably fitted to the intermediate plate member 28 and guides the intermediate plate member 28 when opening and closing the mold (when opening and closing the second mold split surface PL2). The movable side plate member 17 is matched with the intermediate plate member 28 by the guide pin 40, and the cavity surface 28A formed on the fixed side plate member 11 is formed.
And a cavity for forming a molded product when the mold is closed.

The runner 45 and the cavity surface 28A are formed with a predetermined gradient in the direction of the movable plate member 17 with respect to the intermediate plate member 28, and the core surface 17A formed on the movable plate member 17 is The opening is formed at a predetermined gradient in the direction of the fixed side plate member 11. Thus, the molded product 44 is configured to be easily released from the cavity surface 28A and the core surface 17A. Reference numeral 41 denotes an ejector pin for pushing out a molded product, reference numeral 42 denotes a spring for separating the fixed side plate member 11 from the intermediate plate member 28, and reference numeral 43 denotes a molten resin injection port.

When the injection of the molten resin from the molten resin injection port 43 is completed and the molded product is cooled, the movable mounting plate 38 is moved by the operation of the movable platen.
5, the lock claw 23 of the lock member 22
Moves rightward in the figure while being locked by the engaging portion 20 of the holding member 18. By this operation, the first mold division surface PL1, which is the mating surface between the fixed side plate member 11 and the intermediate plate member 28, is opened. In this operation, since the lock member 22 is engaged with the fixed member 29 by the lock claw 23, the movable side plate member 17 and the intermediate plate member 28 are integrally combined and simultaneously moved rightward by the urging force of the spring 42. Go. Thereby, the second mold dividing surface PL
First, only the first mold division plane PL1 is opened without opening (FIGS. 17 and 18).

Then, in the process of moving the movable side mounting plate 38 away from the intermediate plate member 28, the release lever 12 moves toward the lock claw 23, and the support portion 13 moves to the lock member 22.
The lock member 22 locked by the fixing member 29 by pushing up the end is released. When the movable-side mounting plate 38 further moves away from the intermediate plate member 28, the lock claw 23 is pushed up along the inclined portion 14 formed on the support portion 13 of the release lever 12 (FIG. 19).

At this time, since the support portion 13 of the release lever 12 moves from the other end of the lock member 22 to the lock claw 23 side, the lock claw 23 is easily pushed up by the support portion 13 and the claw of the fixing member 29 is caught. It is released from the engagement part 30. When the lock claw 23 is released from the claw engaging portion 30, the stopper 39A provided at the end of the support pin 39 comes into contact with the intermediate plate member 28, and the intermediate plate member 28 is stopped from further moving. , Will be held in that position.

When the movable platen 38 continues to move rightward due to the operation of the movable platen, the mating surface between the intermediate plate member 28 and the movable plate member 17 is separated, and the second mold dividing surface is separated. PL2 is opened, and at this stage, the molded product 44 is projected from the movable-side mounting plate 38. The movement of the release lever 12 is stopped at an appropriately set position by stopping the movable platen of the molding machine, and the mold opening process ends (FIGS. 20, 21, and 22). Although not shown, at this time, the runner 45 is chipped at a predetermined position and
And separated.

When one molding process is completed and the stage of the mold opening state is shifted to the mold closing process, first, the movable plate member 17 is moved in the direction of the fixed plate member 11 by the movable platen of the molding machine, and the second metal member is moved. The mold parting plane PL2 closes. In this case, the fixed side plate member 1 is
1 and the intermediate plate member 28 are urged in the direction away from each other, so that the second mold dividing surface P is preceded by the first mold dividing surface PL1.
L2 closes. With this operation, the lock claw 23 is formed by the inclined portion 23A provided at the tip of the lock claw 23 and the slope portion 14 provided at the tip of the support portion 13 of the release lever 12.
Rides on the support portion 13 of the release lever 12. As a result, the support portion 13 of the release lever 12 can easily be locked by the lock claw 23.
Is inserted underneath.

Then, the mold closing step further proceeds, so that the intermediate plate member 28 and the fixed side plate member 11 come into contact with each other to close the first mold division plane PL1. By this operation, the support portion 13 of the release lever 12 is inserted to the other end of the lock member 22 and the support member 13 locks the lock member 2.
2 is supported, and the lock claw 23 is a hinge pin 26
Is securely pressed to the claw engaging portion 30 side with the fulcrum as a fulcrum,
It is also pressed by the auxiliary coil spring 33. As a result, the lock claw 23 is securely engaged with the claw engaging portion 30 as described above, and the first mold division plane PL1 and the second mold division plane PL2 are engaged.
Is closed and becomes a mold clamping state, and this is repeated.
4 is performed.

As described above, while each plate member is closed, the lock claw 23 is locked by the fixing member 29, and when the intermediate plate member 28 and the fixed side plate member 11 are opened by a predetermined distance, the release lever 12 is released. The lock claw 23 is released from the fixing member 29. When the movable plate member 17 is separated from the fixed plate member 11, the lock claw 23 is locked by the fixed member 29 to prevent the intermediate plate member 28 and the movable plate member 17 from opening. Then, the mold opening of the intermediate plate member 28 and the fixed side plate member 11 is performed. Subsequently, in the process in which the movable side plate member 17 is separated from the fixed side plate member 11, the lock claw 23 is released from the fixed member 29 by the release lever 12. The intermediate plate member 28 and the movable plate member 17 are released.
Is opened. As a result, the molds can be opened in a predetermined order.

Further, since the intermediate plate member 28 is not held by the lock claw 23 provided on the movable plate member 17 and the release lever 12 provided on the fixed plate member 11, the fixed plate member 11 and the intermediate plate The distance in which the member 28 is divided and opened is not limited. Thereby, for example, it is possible to open to a distance regulated by the molding die 34 and perform maintenance of the molding die 34.

Further, since the locking claw 23 and the fixing member 29 are configured to be wide, the center of the molding die 34 in the width direction can be locked even if the mounting of the die operation control device 10 is slightly shifted. Becomes As a result, the stress of the mold opening can be attracted in parallel without being biased from the center of the molding die 34, so that it is possible to prevent malfunction due to displacement.

Further, since the locking claw 23 and the claw engaging portion 30 of the fixing member 29 are locked at a predetermined acute angle, it is possible to apply a stress in the direction in which the locking claw 23 and the fixing member 29 are separated from each other. It becomes possible. As a result, the locking claw 23 and the fixing member 29 can be reliably locked, and the locking claw 23 is disengaged from the fixing member 29 even with an impact load instantaneously generated at the start of opening of the molding die 34. Can be prevented.

Further, the supporting portion 1 is attached to the other end of the release lever 12.
3 and the support portion 13 is provided on the side opposite to the lock claw 23, so that the lock claw 23 is fixed to the fixing member 29.
In this state, the other end of the lock member 22 can be supported. As a result, the locking claw 23 is reliably pressed toward the claw engaging portion 30 with the hinge pin 26 as a fulcrum, so that the locking claw 23 can be securely locked to the fixing member 29.

An engaging protrusion 24 is provided at the other end of the lock member 22 and the engaging protrusion 24 is
, The engaging projection 24 can be engaged with the engaging portion 20 of the holding member 18. Thus, the engagement projection 24 can be engaged with the holding member 18 attached to the movable plate member 17 in a state where the lock claw 23 is locked by the fixing member 29 attached to the intermediate plate member 28. Becomes Accordingly, even if the diameter of the hinge pin 26 is reduced, the lock member 22 can be made to cope with a strong pulling force, and
6 can be greatly reduced.

Since the center of the hinge pin 26 is close to the surface of the lock claw 23 provided on the lock member 22,
It is possible to make the opening direction of the molding die 34 close to the center of the lock claw 23 and the center of the hinge pin 26 in parallel. Thereby, the angle of the lock claw 23 can be approximated to a substantially right angle, and the stress acting on the lock claw 23 in the detaching direction from the claw engaging portion 30 can be reduced.

In the embodiment, the release lever 12 has been described as having a predetermined length. However, the present invention is not limited to this. By changing the length of the release lever 12, the first mold division surface PL1 is opened by a predetermined distance. It goes without saying that the second mold division plane PL2 can be opened at the stage.

Since the lock claw 23 is pressed by the support portion 13 provided on the release lever 12 toward the claw engaging portion 30 with the hinge pin 26 as a fulcrum, the lock claw 23 is urged toward the fixing member 29. The auxiliary coil spring 33 may be omitted.

[0048]

As described in detail above, according to the first aspect of the present invention, the release lever attached to the fixed side plate member, the holding member attached to the movable side plate member,
The holding member is provided with a lock member rotatably attached by a hinge pin and provided with a lock claw at one end, and a fixed member attached to the intermediate plate member, and the lock claw is provided when each plate member is closed. Since the release lever releases the lock claw from the fixed member when the intermediate plate member and the fixed side plate member are opened by a predetermined distance while being locked by the fixed member, the movable side plate member is moved from the fixed side plate member. At the stage of separation, the lock pawl is locked by the fixed member to prevent the opening of the intermediate plate member and the movable side plate member, and in this state, first, the opening of the intermediate plate member and the fixed side plate member is performed, and Then, in the process in which the movable side plate member is separated from the fixed side plate member, the release lever is moved from the fixed member to the lock claw. Since release, mold opening between the intermediate plate and the movable plate member is performed at that stage. As a result, the molds can be opened in a predetermined order, and the molded product or the runner can be reliably taken out of the molding die.

In particular, since the intermediate plate member is not held by the lock pawl provided on the movable side plate member and the release lever provided on the fixed side plate member, the distance between the fixed side plate member and the intermediate plate member is limited. Not restricted. Therefore, for example, even when the maintenance of the molding die is performed, the opening can be opened up to the opening width regulated by the molding die, and the practical effect is extremely large.

According to the second aspect of the present invention, in addition to the above, the locking pawl and the fixing member are configured to be wide, so that
Even if the mounting of the mold operation control device is slightly shifted, the center in the width direction of the molding mold can be locked. This makes it possible to open the mold in a parallel manner without biasing the opening stress. Accordingly, it is possible to greatly improve the operation failure of the molding die caused by the displacement of the mounting position of the operation control device for the die.

In particular, since the locking claw and the fixing member are locked at a predetermined acute angle, it is possible to exert a stress in the direction in which the locking claw and the fixing member are separated from each other.
Therefore, the lock claw and the fixing member can be reliably locked, and it is possible to prevent the lock claw from being detached from the fixing member even by an impact load that is instantaneously generated at the beginning of opening of the molding die. That is what you can do.

According to a third aspect of the present invention, in addition to the first or second aspect, a support portion is provided at the other end of the release lever, and the support portion is provided on a surface opposite to the lock claw. Therefore, it is possible to support the other end of the fixing member in a state where the lock claw is locked by the fixing member. As a result, the lock claw is pressed against the fixing member, and the lock claw can be securely locked to the fixing member. Therefore, for example, the mold can be clamped without using an urging member for urging the lock claw. Thereby, the lock claw can be automatically locked to the fixing member. Therefore, the mold opening operation can be reliably performed in a predetermined mold opening order.

According to the fourth aspect of the present invention, in addition to the first, second or third aspect, an engaging projection is provided at the other end of the lock member, and the engaging projection is locked. Since the claw is projected to the other surface side, the engagement protrusion can be engaged with the holding member. With this, in a state where the lock claw is locked to the fixing member attached to the intermediate plate member, the opposite side of the engaging protrusion provided on the lock member is pushed up by the support portion, and the holding member attached to the movable side plate member is pushed up. The engagement protrusion can be engaged. Therefore, the load applied to the hinge pin can be greatly reduced, and the locking member can be made to respond to a strong pulling force, so that the reliability of the mold operation control device can be greatly improved.

According to the invention of claim 5, according to claim 1,
In addition, since the center of the hinge pin is closer to the surface of the lock claw provided on the lock member, for example, the mold opening direction of the molding die and the center of the lock claw and the hinge pin can be closer to parallel. Thereby, the angle of the lock claw can be approximated to a substantially right angle, and it is possible to reduce the stress acting on the lock claw in the detaching direction from the claw engaging portion. Therefore, the locking member can be securely locked to the fixing member.

[Brief description of the drawings]

FIG. 1 is a perspective view of a synthetic resin molding die to which a mold operation control device of the present invention is applied.

FIG. 2 is a top view of the mold operation control device of the present invention.

FIG. 3 is a front view of the mold operation control device of the present invention.

FIG. 4 is a vertical sectional front view of the mold operation control device of the present invention.

FIG. 5 is a side view of the mold operation control device of the present invention.

FIG. 6 is a top view of a holding member that constitutes the mold operation control device of the present invention.

FIG. 7 is a side view of FIG. 6;

FIG. 8 is a front view cut along the line AA of FIG. 6;

FIG. 9 is a top view of a lock member constituting the mold operation control device of the present invention.

FIG. 10 is a vertical sectional front view of FIG. 9;

FIG. 11 is a top view of a fixing member constituting the mold operation control device of the present invention.

FIG. 12 is a side view of FIG. 11;

FIG. 13 is a front view cut along the line BB of FIG. 11;

FIG. 14 is a top view of a release lever constituting the mold operation control device of the present invention.

FIG. 15 is a vertical sectional front view of FIG. 14;

FIG. 16 is a longitudinal sectional front view of a molding die to which the operation control device for a die according to the present invention is applied.

FIG. 17 is an enlarged vertical sectional front view of the vicinity of a mold operation control device of a molding mold in a state where a first mold division surface is opened.

FIG. 18 is a vertical sectional front view of the mold operation control device showing a state where the first mold division surface is opened and the lock claw of the lock member is released by the release lever.

FIG. 19 is an enlarged front view of the vicinity of the mold operation control device of FIG. 18;

FIG. 20 is a longitudinal sectional front view of a molding die showing a state where a first die division surface and a second die division surface are opened.

FIG. 21 is an enlarged front view of the mold operation control device of FIG. 20;

FIG. 22 is a top view of FIG. 20.

FIG. 23 is a perspective view of a molding die to which a conventional die operation control device is applied.

FIG. 24 is a front view of a conventional mold operation control device.

[Explanation of symbols]

 REFERENCE SIGNS LIST 10 Mold operation control device 11 Fixed side plate member 12 Release lever 13 Support portion 17 Movable side plate member 18 Holding member 19 Depression 20 Engagement portion 22 Lock member 23 Lock claw 24 Engagement protrusion 26 Hinge pin 28 Intermediate plate member 29 Fixing member 30 Claw engaging portion 31 Lever insertion portion 34 Molding die 35 Fixed side mounting plate 36 Receiving plate 37 Spacer block 38 Movable side mounting plate 44 Molded product PL1 First die split surface PL2 Second die split surface

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[Procedure amendment]

[Submission date] December 7, 1999 (1999.12.
7)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction contents]

[Document Name] Statement

[Title of the Invention] Operation control device for mold

[Claims]

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an operation control device for a mold provided on a molding die for synthetic resin comprising a plurality of plate members, wherein the plate member is divided into two or more portions and a molded product is taken out. It is.

[0002]

2. Description of the Related Art Conventionally, gate systems of molding dies for synthetic resins are generally classified into a pin gate type and a side gate type. In particular, in the case of the pin gate type, the runner can be automatically cut from the molded product. This pin gate type molding die has at least two divided surfaces, and by controlling the mold opening in a predetermined order, the runner can be cut from the molded product, and the cut runner or molded product can be cut. Can be automatically taken out of the molding die.

[0003] The opening sequence of a pin gate type molding die is ideally such that a predetermined division surface starts opening the mold first, and then the next division surface starts opening the mold. However, since this molding die is provided with a special means for controlling the order of opening the molds, it is completely uncertain which split face is opened first. For this reason, when the order of opening the molds is reversed, the mold may be moved to the next step and closed with the molded product remaining in the mold. As a result, damage to the cavity or the core was induced, or the molding operation was interrupted each time, and the molded product was removed from the molding die, so that the movable ratio of the molding die was significantly reduced.

[0004] Accordingly, the operation control device for the mold has been disclosed in
No. 46990 (B29C 45/26) discloses a mold sequencer. The mold operation control device 100 is attached to the side surface of the molding die 101, and when the injection of the molten resin (not shown) from the molten resin injection port 114 is completed, the fixed side plate member 103 and the intermediate plate The first mold division plane PL11 which is a division plane with the member 104, and the second mold division plane PL12 which is a division plane between the intermediate plate member 104 and the movable side plate member 105 are in a mold closed state (FIG. 23). . Fixed side plate member 10
Reference numeral 3 denotes a fixed platen of a molding machine (not shown) via a fixed side mounting plate 102, and a movable side plate member 105
6, mounted on a movable platen of a molding machine (not shown) via a spacer block 107 and a movable-side mounting plate 108.

[0005] Then, when the process proceeds to the next step of taking out a molded product (not shown) from the mold closed state, the movable platen of the molding machine starts operating. In this case, the lock pin 110 attached to the intermediate plate member 104 and attached to the housing 109 of the mold operation control device 100 is moved by the spring 111 to the notch 1 of the latch bar 112.
12A, the intermediate plate member 104 is always urged in the direction of the release bar 113.
It is moved downward in the figure while being locked in A (FIG. 24). By this operation, the first mold division surface PL11 is opened, and although not shown, the runner and the molded product are separated at this time.

[0006] Since the intermediate plate member 104 and the movable plate member 105 are integrally combined via the latch bar 112 and the lock pin 110 and move downward, at this time, the second mold division plane PL12 is formed. Are prevented from opening. When the movable platen is further operated, the notch 112A of the latch bar 112 is located beside the notch 113A of the release bar 113. As a result, the lock pin 110 can move in the direction of the release bar 113, and the projection 110A of the lock pin 110 is urged by the spring 111 to move from the inside of the notch 112A of the latch bar 112 to the inside of the notch 113A of the release bar 113. Moving.

By this operation, the intermediate plate member 104
The lock pin 110 attached to the fixed plate 102 via the housing 109 is locked by a release bar 113 attached to the fixed-side attachment plate 102, and the intermediate plate member 104 stops moving downward. When the latch bar 112 continues to move further downward, the intermediate plate member 104 is stopped from moving downward by the fixed-side mounting plate 102 via the lock pin 110 and the release bar 113. The second mold division plane PL2 between the movable plate member 104 and the movable plate member 105 was opened, and a molded product (not shown) protruded from the movable plate member 105.

[0008]

However, when the lock pin of the mold operation control device is moved by the urging force of the spring, the lock pin is attached to the movable platen, which is attached to the movable platen and is operated by the movable plate. The protrusion of the lock pin is locked to the latch bar, and the intermediate plate member has been moved downward. Due to this operation, a load that rotates in the direction orthogonal to the moving direction occurs at the protrusion of the lock pin, and the lock pin may malfunction in the housing, and the next mold opening is not performed. In some cases, it did.

[0009] Further, the mold operation control device has a problem that the opening dimension between the fixed side plate member and the intermediate plate member is limited by the engagement of the lock pin with the notch of the release bar.

The present invention has been made in order to solve the problems of the prior art, and relates to a molding die for a synthetic resin having at least two mold openings, which has a simple structure and a predetermined structure. An object of the present invention is to provide a mold operation control device that can surely open a molding die in order.

[0011]

According to a first aspect of the present invention, there is provided a mold operation control device including a plurality of plate members including a fixed plate member, a movable plate member, and an intermediate plate member. It is provided in a molding die for synthetic resin, the plate member is divided into at least two places, and a molded product is taken out. The release lever attached to the fixed side plate member and the release lever attached to the movable side plate member. A holding member, a lock member rotatably attached to the holding member by a hinge pin and having a lock claw at one end, and a fixing member attached to the intermediate plate member, wherein each plate member is closed. the locking pawl is locked to the fixed member while the intermediate pre
When the plate member and the fixed side plate member are opened a predetermined distance,
The release lever releases the lock claw from the fixed member,
A support portion is provided at the other end of the release lever, and
Note that the support is provided on the opposite side of the lock claw.
Sign.

According to a second aspect of the present invention, there is provided an operation control device for a mold.
The fixed side plate member, the movable side plate member, and the intermediate plate
A plate provided with a plurality of plate members
Provided in the molding die for synthetic resin, with fewer plate members
Are divided into two parts and the molded product is taken out.
Release lever attached to the fixed side plate member
And a holding member attached to the movable side plate member,
Rotatably attached to this holding member with hinge pins
A lock member provided with a lock claw at one end;
A fixing member attached to the inter-plate member,
When the plate member is closed, the lock claw is
Locked, the intermediate plate member and the fixed side plate member
The release lever is locked from the fixed member when it is opened a predetermined distance.
At the same time as releasing the pawl, the other end of the lock member has an engagement projection.
And the engaging projection projects toward the other side of the locking claw.
It is characterized by being put out.

According to a third aspect of the present invention, there is provided a mold operation control device,
The fixed side plate member, the movable side plate member, and the intermediate plate
A plate provided with a plurality of plate members
Provided in the molding die for synthetic resin, with fewer plate members
Are divided into two parts and the molded product is taken out.
Release lever attached to the fixed side plate member
And a holding member attached to the movable side plate member,
Rotatably attached to this holding member with hinge pins
A lock member provided with a lock claw at one end;
A fixing member attached to the inter-plate member,
When the plate member is closed, the lock claw is
Locked, the intermediate plate member and the fixed side plate member
The release lever is locked from the fixed member when it is opened a predetermined distance.
Release the pawl and provide a support at the other end of the release lever.
And the support portion is provided on a surface opposite to the lock claw.
In addition, an engagement protrusion is provided at the other end of the lock member,
In addition, this engaging projection projects to the other side of the lock claw.
It is characterized by the following.

[0014]

Next, an embodiment of the present invention will be described in detail with reference to the drawings. FIG. 1 is a perspective view of a molding die 34 for a synthetic resin to which the mold operation control device 10 of the present invention is applied, FIG. 2 is a top view of the mold operation control device 10 of the present invention, and FIG. FIG. 4 is a longitudinal sectional front view of the mold operation control device 10 of the present invention, and FIG. 5 is a side view of the mold operation control device 10 of the present invention. I have. In the drawings, the components denoted by the same reference numerals are the same.

The mold operation control device 10 opens a synthetic resin molding mold 34 composed of a plurality of plate members and having at least two mold openings in a predetermined order.
Holding member 18, locking member 22, fixing member 29,
And a release lever 12. The holding member 18 is made of a strong metal such as iron, and has a length of about 10 mm.
It has a shape of 3 mm, a width of about 30 mm, and a thickness of about 36 mm. A recess 19 is provided at the center of the holding member 18, and the recess 19 has a depth of about 28 mm on one side in the width direction (in this case, the engagement section 20 side) and a depth of about 27 mm on the other side. (FIGS. 6 and 7). On one side of the recess 19, an engaging portion 20 cut out to a depth of about 4 mm and a width of about 47 mm is formed (FIG. 8).

That is, the recess 19 formed in the holding member 18
An engaging portion 20 is provided on one side, and a slope having a depth of about 28 mm on one side in the width direction and a depth of about 27 mm on the other side is formed continuously with the engaging portion 20. The recess 19 has an engaging portion 20.
A through hole 21 having a diameter of about 6 mm is provided on the opening side of the recess 19 with a small interval. The through hole 21 is the holding member 1
8 is provided to extend in the longitudinal direction, and a hinge pin 26 is configured to be insertable, and a lock member 22 described later is rotatably supported by the hinge pin 26. 18A, 18A are bolt insertion holes, 18B
Is an auxiliary spring insertion hole.

The lock member 22 is configured to control the opening order of a first mold division plane PL1 and a second mold division plane PL2 of a synthetic resin molding mold 34 described later. . That is, the lock member 22 is connected to the second mold dividing surface PL2.
Is closed, the first mold division plane PL1 can be opened first. The lock member 22 is made of a strong metal such as iron, like the holding member 18, and is formed to be as wide as about 69 mm in length, about 8 mm in thickness, and about 30 mm in width. (FIGS. 9 and 10).

The lock member 22 is provided with a lock claw 23. The lock claw 23 is provided at one longitudinal end of the lock member 22. The lock claw 23 projects at an acute angle about 18 mm inward from one end of the lock member 22 (in this case, projects about 6 mm while being inclined toward the other end).
It is configured such that it does not easily come off when locked to a claw engaging portion 30 of a fixing member 29 described later. The tip end of the lock claw 23 is formed with an inclined portion 23A that extends a little in the direction of one end and reaches the rear plate thickness. That is, the lock claw 23 is formed at an acute angle so as to protrude from one surface of one end portion of the lock member 22 in the longitudinal direction, and is provided to extend in the entire width direction. 22A is an auxiliary spring insertion hole.

An engaging projection 24 is provided at the other end of the lock member 22.
And protrude to the opposite side. This engaging projection 2
Reference numeral 4 is provided so as to protrude from the lock member 22 by about 4 mm, and is provided so as to extend about 10 mm from one end to the other end. That is, the engagement protrusion 24 is provided so as to protrude from the other surface of the lock member 22, and is configured to be engaged with the engagement portion 20 of the holding member 18. In addition, the lock member 22
An engagement hole 25 having a diameter of about 6 mm is provided at the other end of the lock member 22. The engagement hole 25 extends in the width direction of the lock member 22 and is provided therethrough. That is, the engagement hole 25 is provided in parallel with the engagement protrusion 24 and the center is provided near the one surface side of the lock member 22.

The fixing member 29 is made of a metal such as iron having a high strength like the holding member 18 and has a length of about 103 mm and a thickness of about 1 mm.
8 mm and a width of about 24 mm (see FIG. 1).
1, FIG. 12). Approximately 55 m wide on one side of the center of the fixing member 29
m claw engagement portions 30 are formed.
Are formed so as to have the same slope as the lock claw 23 (FIG. 13). The width of about 20 is approximately at the center of the fixing member 29.
The lever insertion portion 31 having a depth of about 13.5 mm and a depth of about 13.5 mm is formed. The release lever 12 described later is inserted into the lever insertion section 31 and is movable.
Reference numeral 29A denotes an inclined portion, which is configured so that the inclined portion 23A formed at the tip of the lock claw 23 can move smoothly without being caught. Reference numeral 32 denotes a bolt insertion hole for fixing to the intermediate plate member 28 with a bolt (not shown).

The release lever 12 is used to release the lock member 22 locked by the fixing member 29. The release lever 12 is made of a metal such as iron having the same strength as the holding member 18 and has a length of about 12 mm.
It has a size of 5 mm, a width of about 18 mm, and a thickness of about 6 mm (FIGS. 14 and 15). A support portion 13 is provided on one side of the release lever 12 in the longitudinal direction.
Has a height of about 7.5 mm. The support part 13 is formed at a position of about 5 mm to 12 mm from one end of the release lever 12, and slope parts 14, 14 formed at about 30 degrees are provided on both sides of the support part 13.

The support portion 13 of the release lever 12 pushes up the lock claw 23 of the lock member 22 to release the lock claw 23 locked by the claw engagement portion 30 of the fixing member 29. Further, the support portion 1 of the release lever 12
3 is an engaging projection 24 formed at the other end of the lock member 22.
And push the lock claw 23 to the claw engaging portion 3 of the fixing member 29.
It is configured to lock to zero.

A mounting portion 15 is formed on the other side of the release lever 12, and the mounting portion 15 has a length of about 29.
mm, a height of about 7 mm, and protruding from the side opposite to the support portion 13. The mounting portion 15 is provided with mounting holes 16, 16, and a bolt (not shown) is inserted into the mounting holes 16, 16 so that the release lever 12 is fixed to a fixed-side plate member 11 described later. I have.

On the other hand, the molding die 34 is composed of the fixed side plate member 11, the movable side plate member 17, and the intermediate plate member 28 provided between the fixed side plate member 11 and the movable side plate member 17. (FIG. 16).
The fixed-side plate member 11 is attached to a fixed-side mounting plate 35, and the movable-side plate member 17 is
It is mounted on a movable mounting plate 38 via a spacer block 37. A first mold division plane PL1 is defined between the fixed plate member 11 and the intermediate plate member 28, and a second mold division plane PL2 is defined between the intermediate plate member 28 and the movable plate member 17.

Then, the claw engaging portion 30 of the fixing member 29 is located on the fixed side plate member 11 side, a bolt (not shown) is inserted into the bolt insertion hole 32, and the fixing member 29 is fixed to the intermediate plate member 28. Further, the support portion 13 of the release lever 12 is located on the intermediate plate member 28 side and installed on the fixed side plate member 11. Then, the mounting holes 16, 1
A bolt (not shown) is inserted into 6 and the release lever 12 is fixed to the fixed-side plate member 11. In this case, the mounting portion 15 protruding from the release lever 12 is fixed facing the fixed side plate member 11 side, and the support portion 1 is fixed.
3 is movably mounted in a lever insertion portion 31 formed in the fixing member 29.

Next, the lock member 22 is attached to the holding member 18. In this case, a through hole 21 provided in the holding member 18 with the auxiliary spring insertion hole 18B provided in the recess 19 of the holding member 18 and the auxiliary spring insertion hole 22A provided in the lock member 22 facing each other, The hinge pin 26 is inserted into the engagement hole 25 and the through hole 21 by communicating with the engagement hole 25 provided in the lock member 22. A stopper 27 such as an E-ring is attached to an end of the hinge pin 26 so that the hinge pin 26 inserted into the engagement hole 25 does not come off. This hinge pin 26 allows the lock member 2
2 is rotatably attached to the holding member 18. Next, bolt insertion holes 18A, 1A provided in the holding member 18 are provided.
A bolt (not shown) is inserted into 8A, and the holding member 18 is fixed to the movable side plate member 17. Reference numeral 33 denotes an auxiliary coil spring for urging the lock member 22 toward the fixing member 29.

That is, when the molding die 34 is in a mold closed state (a state in which the first mold division plane PL1 and the second mold division plane PL2 are closed), the lock claw 23 of the lock member 22 is fixed to the fixing member 2.
9 is locked by being engaged with the claw engaging portion 30 of the lock member 22, and the support portion 13 of the release lever 12 abuts on the other end of the opposite surface of the engaging protrusion 24 formed on the other end of the lock member 22. Is configured. As a result, the lock claw 23 is pressed toward the claw engagement portion 30 with the hinge pin 26 as a fulcrum, so that the lock claw 23 is securely engaged with the claw engagement portion 30 and the second mold split surface PL2 (intermediate). The plate member 28 and the movable side plate member 17) are securely locked without opening.

Next, the operation control device 1 for a mold having the above-described configuration is used.
The operation of 0 will be described. The fixed-side mounting plate 35 is attached to a fixed platen of a molding machine (not shown), and the movable-side mounting plate 38 is attached to a movable platen of a molding machine (not shown). In addition, the mold operation control device 10 is provided on a pair of front and rear surfaces of the molding mold 34 (in this case, substantially at the center of the vertical width).
Shall be provided. In the figure, reference numeral 39 denotes a support pin for loosely fitting the fixed-side plate member 11 via the fixed-side mounting plate 35, and a stopper 39A provided at the end to prevent the first mold division plane PL1 from opening more than a predetermined stroke. The intermediate plate member 28 is controlled.

Reference numeral 40 denotes a guide pin which is slidably fitted to the intermediate plate member 28 and guides the intermediate plate member 28 when opening and closing the mold (when opening and closing the second mold split surface PL2). The movable side plate member 17 is matched with the intermediate plate member 28 by the guide pin 40, and the cavity surface 28A formed on the fixed side plate member 11 is formed.
And a cavity for forming a molded product when the mold is closed.

Further, the runner 45 and the cavity surface 28A are formed so as to expand toward the movable plate member 17 at a predetermined gradient with respect to the intermediate plate member 28, and the core surface 17A formed on the movable plate member 17 is The opening is formed at a predetermined gradient in the direction of the fixed side plate member 11. Thus, the molded product 44 is configured to be easily released from the cavity surface 28A and the core surface 17A. Reference numeral 41 denotes an ejector pin for pushing out a molded product, reference numeral 42 denotes a spring for separating the fixed side plate member 11 from the intermediate plate member 28, and reference numeral 43 denotes a molten resin injection port.

When the injection of the melted resin from the molten resin injection port 43 is completed and the molded product is cooled, the movable mounting plate 38 is moved by the operation of the movable platen to move the fixed mounting plate 3.
5, the lock claw 23 of the lock member 22
Moves rightward in the figure while being locked by the engaging portion 20 of the holding member 18. By this operation, the first mold division surface PL1, which is the mating surface between the fixed side plate member 11 and the intermediate plate member 28, is opened. In this operation, since the lock member 22 is engaged with the fixed member 29 by the lock claw 23, the movable side plate member 17 and the intermediate plate member 28 are integrally combined and simultaneously moved rightward by the urging force of the spring 42. Go. Thereby, the second mold dividing surface PL
First, only the first mold division plane PL1 is opened without opening (FIGS. 17 and 18).

In the process in which the movable-side mounting plate 38 moves away from the intermediate plate member 28, the release lever 12 moves in the direction of the lock claw 23, and the support portion 13 moves to the lock member 22.
The lock member 22 locked by the fixing member 29 by pushing up the end is released. When the movable-side mounting plate 38 further moves away from the intermediate plate member 28, the lock claw 23 is pushed up along the inclined portion 14 formed on the support portion 13 of the release lever 12 (FIG. 19).

At this time, since the support portion 13 of the release lever 12 moves from the other end of the lock member 22 to the lock claw 23 side, the lock claw 23 is easily pushed up by the support portion 13 and the claw of the fixing member 29 is moved. It is released from the engagement part 30. When the lock claw 23 is released from the claw engaging portion 30, the stopper 39A provided at the end of the support pin 39 comes into contact with the intermediate plate member 28, and the intermediate plate member 28 is stopped from further moving. , Will be held in that position.

When the movable platen 38 continues to move rightward by the operation of the movable platen, the mating surface between the intermediate plate member 28 and the movable plate member 17 is separated, and the second mold dividing surface is separated. PL2 is opened, and at this stage, the molded product 44 is projected from the movable-side mounting plate 38. The movement of the release lever 12 is stopped at an appropriately set position by stopping the movable platen of the molding machine, and the mold opening process ends (FIGS. 20, 21, and 22). Although not shown, at this time, the runner 45 is chipped at a predetermined position and
And separated.

When one molding step is completed and the mold is shifted from the mold open state to the mold closing step, first, the movable platen 17 is moved in the direction of the fixed plate member 11 by the movable platen of the molding machine, and the second metal member is moved. The mold parting plane PL2 closes. In this case, the fixed side plate member 1 is
1 and the intermediate plate member 28 are urged in the direction away from each other, so that the second mold dividing surface P is preceded by the first mold dividing surface PL1.
L2 closes. With this operation, the lock claw 23 is formed by the inclined portion 23A provided at the tip of the lock claw 23 and the slope portion 14 provided at the tip of the support portion 13 of the release lever 12.
Rides on the support portion 13 of the release lever 12. As a result, the support portion 13 of the release lever 12 can easily be locked by the lock claw 23.
Is inserted underneath.

Then, the mold closing step further proceeds, so that the intermediate plate member 28 and the fixed side plate member 11 come into contact with each other to close the first mold division plane PL1. By this operation, the support portion 13 of the release lever 12 is inserted to the other end of the lock member 22 and the support member 13 locks the lock member 2.
2 is supported, and the lock claw 23 is a hinge pin 26
Is securely pressed to the claw engaging portion 30 side with the fulcrum as a fulcrum,
It is also pressed by the auxiliary coil spring 33. As a result, the lock claw 23 is securely engaged with the claw engaging portion 30 as described above, and the first mold division plane PL1 and the second mold division plane PL2 are engaged.
Is closed and becomes a mold clamping state, and this is repeated.
4 is performed.

As described above, while each plate member is closed, the lock claw 23 is locked by the fixing member 29, and when the intermediate plate member 28 and the fixed side plate member 11 are opened by a predetermined distance, the release lever 12 is released. The lock claw 23 is released from the fixing member 29. When the movable plate member 17 is separated from the fixed plate member 11, the lock claw 23 is locked by the fixed member 29 to prevent the intermediate plate member 28 and the movable plate member 17 from opening. Then, the mold opening of the intermediate plate member 28 and the fixed side plate member 11 is performed. Subsequently, in the process in which the movable side plate member 17 is separated from the fixed side plate member 11, the lock claw 23 is released from the fixed member 29 by the release lever 12. The intermediate plate member 28 and the movable plate member 17 are released.
Is opened. As a result, the molds can be opened in a predetermined order.

Further, since the intermediate plate member 28 is not held by the lock claw 23 provided on the movable side plate member 17 and the release lever 12 provided on the fixed side plate member 11, the fixed side plate member 11 and the intermediate plate The distance in which the member 28 is divided and opened is not limited. Thereby, for example, it is possible to open to a distance regulated by the molding die 34 and perform maintenance of the molding die 34.

Further, since the locking claw 23 and the fixing member 29 are configured to be wide, even if the mounting of the mold operation control device 10 is slightly shifted, the center in the width direction of the molding mold 34 can be locked. Becomes As a result, the stress of the mold opening can be attracted in parallel without being biased from the center of the molding die 34, so that it is possible to prevent malfunction due to displacement.

Further, since the locking claw 23 and the claw engaging portion 30 of the fixing member 29 are locked at a predetermined acute angle, it is possible to apply a stress in the direction of separating the locking claw 23 and the fixing member 29 from each other. It becomes possible. As a result, the locking claw 23 and the fixing member 29 can be reliably locked, and the locking claw 23 is disengaged from the fixing member 29 even with an impact load instantaneously generated at the start of opening of the molding die 34. Can be prevented.

Further, the supporting portion 1 is provided at the other end of the release lever 12.
3 and the support portion 13 is provided on the side opposite to the lock claw 23, so that the lock claw 23 is fixed to the fixing member 29.
In this state, the other end of the lock member 22 can be supported. As a result, the locking claw 23 is reliably pressed toward the claw engaging portion 30 with the hinge pin 26 as a fulcrum, so that the locking claw 23 can be securely locked to the fixing member 29.

An engaging protrusion 24 is provided at the other end of the lock member 22 and the engaging protrusion 24 is
, The engaging projection 24 can be engaged with the engaging portion 20 of the holding member 18. Thus, the engagement projection 24 can be engaged with the holding member 18 attached to the movable plate member 17 in a state where the lock claw 23 is locked by the fixing member 29 attached to the intermediate plate member 28. Becomes Accordingly, even if the diameter of the hinge pin 26 is reduced, the lock member 22 can be made to cope with a strong pulling force, and
6 can be greatly reduced.

Since the center of the hinge pin 26 is close to the surface of the lock claw 23 provided on the lock member 22,
It is possible to make the opening direction of the molding die 34 close to the center of the lock claw 23 and the center of the hinge pin 26 in parallel. Thereby, the angle of the lock claw 23 can be approximated to a substantially right angle, and the stress acting on the lock claw 23 in the detaching direction from the claw engaging portion 30 can be reduced.

In the embodiment, the release lever 12 has been described as having a predetermined length. However, the present invention is not limited to this. By changing the length of the release lever 12, the first mold division surface PL1 is opened by a predetermined distance. It goes without saying that the second mold division plane PL2 can be opened at the stage.

Further, since the lock claw 23 is pressed by the support portion 13 provided on the release lever 12 toward the claw engaging portion 30 with the hinge pin 26 as a fulcrum, the lock claw 23 is urged toward the fixing member 29 side. The auxiliary coil spring 33 may be omitted.

[0046]

As described above in detail, according to the present invention, the release lever attached to the fixed-side plate member, the holding member attached to the movable-side plate member, and the holding member rotatably by a hinge pin. A lock member is provided and provided with a lock claw at one end, and a fixing member attached to the intermediate plate member. The lock claw is locked to the fixing member when each plate member is closed, and the intermediate plate is Since the release lever releases the lock claw from the fixed member when the member and the fixed plate member are opened a predetermined distance, the lock claw is engaged with the fixed member when the movable plate member is separated from the fixed plate member. Locked to prevent the opening of the intermediate plate member and the movable side plate member, and in this state, first fixed to the intermediate plate member The release lever releases the lock pawl from the fixed member in the process of opening the plate member and subsequently separating the movable side plate member from the fixed side plate member. At this stage, the intermediate plate member and the movable side plate member are released. Is opened. As a result, the molds can be opened in a predetermined order, and the molded product or the runner can be reliably taken out of the molding die.

Further , since the intermediate plate member is not held by the lock claw provided on the movable plate member and the release lever provided on the fixed plate member, the distance between the fixed plate member and the intermediate plate member is limited. Not restricted. Therefore, for example, even when the maintenance of the molding die is performed, the opening can be opened up to the opening width regulated by the molding die, and the practical effect is extremely large.

In particular, according to the first and third aspects of the present invention,
For example, while providing a support at the other end of the release lever,
Since the support is provided on the opposite side of the lock claw,
Support the other end of the fixing member with the
Can be held. This locks the lock claw
Pressed against the member, securely lock the lock claw to the fixed member.
Lock claw, for example
Even without using the urging member that is urging the
Locking claw can be automatically locked to the fixing member
Become so. Therefore, the mold opening operation is reliably performed at the specified mold opening.
In order.

According to the second and third aspects of the present invention,
For example, an engaging projection is provided at the other end of the lock member, and
Since the engagement projection is projected to the other side of the lock claw,
The collision portion can be engaged with the holding member. this
With the fixed member attached to the intermediate plate member
With the lock claw locked, the lock provided on the lock member
The opposite side of the collision part is pushed up by the support part, and the movable side plate member
Engaging the engaging projection with the holding member attached to the
Becomes possible. Therefore, the load applied to the hinge pin is greatly reduced.
To make the lock member correspond to strong pulling force.
Can greatly improve the reliability of the mold operation control device.
It will be able to be raised.

[Brief description of the drawings]

FIG. 1 is a perspective view of a synthetic resin molding die to which a mold operation control device of the present invention is applied.

FIG. 2 is a top view of the mold operation control device of the present invention.

FIG. 3 is a front view of the mold operation control device of the present invention.

FIG. 4 is a vertical sectional front view of the mold operation control device of the present invention.

FIG. 5 is a side view of the mold operation control device of the present invention.

FIG. 6 is a top view of a holding member that constitutes the mold operation control device of the present invention.

FIG. 7 is a side view of FIG. 6;

FIG. 8 is a front view cut along the line AA of FIG. 6;

FIG. 9 is a top view of a lock member constituting the mold operation control device of the present invention.

FIG. 10 is a vertical sectional front view of FIG. 9;

FIG. 11 is a top view of a fixing member constituting the mold operation control device of the present invention.

FIG. 12 is a side view of FIG. 11;

FIG. 13 is a front view cut along the line BB of FIG. 11;

FIG. 14 is a top view of a release lever constituting the mold operation control device of the present invention.

FIG. 15 is a vertical sectional front view of FIG. 14;

FIG. 16 is a longitudinal sectional front view of a molding die to which the operation control device for a die according to the present invention is applied.

FIG. 17 is an enlarged vertical sectional front view of the vicinity of a mold operation control device of a molding mold in a state where a first mold division surface is opened.

FIG. 18 is a vertical sectional front view of the mold operation control device showing a state where the first mold division surface is opened and the lock claw of the lock member is released by the release lever.

FIG. 19 is an enlarged front view of the vicinity of the mold operation control device of FIG. 18;

FIG. 20 is a longitudinal sectional front view of a molding die showing a state where a first die division surface and a second die division surface are opened.

FIG. 21 is an enlarged front view of the mold operation control device of FIG. 20;

FIG. 22 is a top view of FIG. 20.

FIG. 23 is a perspective view of a molding die to which a conventional die operation control device is applied.

FIG. 24 is a front view of a conventional mold operation control device.

DESCRIPTION OF SYMBOLS 10 Mold operation control device 11 Fixed side plate member 12 Release lever 13 Support portion 17 Movable plate member 18 Holding member 19 Depression 20 Engagement portion 22 Lock member 23 Lock claw 24 Engagement projection 26 Hinge pin 28 Intermediate plate member 29 Fixing member 30 Claw engaging part 31 Lever insertion part 34 Molding die 35 Fixed side mounting plate 36 Receiving plate 37 Spacer block 38 Movable side mounting plate 44 Molded product PL1 First mold split surface PL2 Second Mold split surface

Claims (5)

[Claims] 1. A synthetic resin molding die provided with a plurality of plate members including a fixed side plate member, a movable side plate member, and an intermediate plate member, wherein the plate member is divided into at least two portions. A release lever attached to the fixed-side plate member, a holding member attached to the movable-side plate member, and a hinge pin rotatably attached to the holding member. A lock member is provided, the lock member having a lock claw provided at one end thereof, and a fixing member attached to the intermediate plate member, wherein the lock claw is locked to the fixing member in a state where each of the plate members is closed. When the intermediate plate member and the fixed side plate member are opened by a predetermined distance, the release lever is moved to the fixed portion. Mold for actuating control device is characterized in that so as to release the locking pawl from. 2. The operation control device for a mold according to claim 1, wherein the lock claw and the fixing member are configured to be wide, and the lock claw and the fixing member are locked at a predetermined acute angle. 3. The operation control device for a mold according to claim 1, wherein a support portion is provided at the other end of the release lever, and the support portion is provided on a surface opposite to the lock claw. 4. The lock member according to claim 1, further comprising an engaging projection provided at the other end of the locking member, and the engaging projection projecting toward the other surface of the locking claw. 3. An operation control device for a mold. 5. The operation control device for a mold according to claim 1, wherein a center of the hinge pin is close to a surface on a lock claw side provided on the lock member.