JP2005138342A - Molding machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a molding machine capable of enhancing not only reliability and certainty at the time of quick return of an ejector plate but also the life of parts. <P>SOLUTION: In a case equipped with an ejector plate quick return mechanism 9 constituted so as to allow the ejector plate 16 to cooperate with the mold closing operation of a mold 5 to return the same to the original standby position, the ejector plate quick return mechanism 9 is equipped with the pusher pin 25 cooperating with the on-off operation of the mold 5 to move in an on-off direction, the slide cam 26 supported by the ejector plate 16 and arranged so as to be movable between the locking position with the pusher pin 25 and an unlocking position where the locking with the pusher pin 25 is released and a release bar 27 for locating the slide cam 26 at the locking position when the mold 5 starts mold closing operation and moving the slide cam 26 to the unlocking position when the ejector plate 16 is moved to the standby position. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

The present invention relates to a molding machine provided with an ejector plate quick return mechanism that quickly returns an ejector plate to its original standby position in conjunction with a mold closing operation of a mold.

For example, in a molding machine in which a semiconductor element is sealed with a resin and an insert molded product is injection-molded by a mold, the ejector plate separated from the mold by pushing up the molded product molded by the mold is used as the mold. There is a case where an ejector plate quick return mechanism is provided in which the quick return to the original standby position is interlocked with the mold closing operation of the mold.

As this type of ejector plate quick return mechanism, conventionally, an L-shaped engaging member is fixed to each of a mold and an ejector plate, and the other engaging member is formed in a fitting hole formed in one engaging member when the die is opened. There is a type in which the protrusion formed on the joint member is inserted and fitted, and the ejector plate is quickly returned to the original position by the fitting force between the protrusion and the fitting hole when the mold is closed (see Patent Document 1). ).

Also, a push bar is attached to the fixed side template, a push bar receiving frame with movable roller pins is attached to the ejector plate, a guide rail with roller pin relief grooves is attached to the movable side template, and pushed when the die is closed. There is one in which a bar pushes a roller pin to quickly return an ejector plate to its original position (see, for example, Patent Document 2).
JP-A-11-77752 Japanese Utility Model Publication No. 6-46927

However, when the ejector plate is quickly returned by inserting the conventional protrusion into the fitting hole, a fitting force is applied to the protrusion in the direction of coming out of the fitting hole. There is a problem that it is inferior in reliability and certainty. Here, when the fitting force between the protruding portion and the fitting hole is increased to prevent the protrusion from being detached, there is a problem that wear due to the attachment and detachment between the protruding portion and the fitting hole is likely to occur, and the component life is shortened.

In addition, when the ejector plate is quickly returned to its original position by pressing the roller pin with the conventional push bar, the roller pin always slides, so that the roller pin is likely to be worn or damaged, and the component life is shortened as described above. There is a problem of becoming.

The present invention has been made in view of the above-described conventional situation, and can improve the reliability and certainty when the ejector plate is quickly returned, and further can suppress the shortening of the component life due to wear. The purpose is to provide.

According to the present invention, there is provided an ejector plate quick-return mechanism that returns an ejector plate that pushes and separates a molded product molded from a mold to the original standby position in conjunction with the mold closing operation of the mold. In the molding machine provided, the ejector plate quick return mechanism includes a pusher pin that moves in an opening / closing direction in conjunction with an opening / closing operation of the mold, an engagement position that is supported by the ejector plate and engages with the pusher pin, A slide cam arranged to be movable between an engagement release position for releasing the engagement with the pusher pin, and the slide cam is moved to the engagement position when the mold starts a mold closing operation. And a release bar that moves the slide cam to the disengagement position when the ejector plate moves to the standby position.

In the ejector plate quick return mechanism of the present invention, the pusher pin moves and engages the slide cam in conjunction with the mold closing operation of the mold, and the pusher pin waits for the ejector plate via the slide cam by the mold closing force of the mold. When the ejector plate moves to the standby position, the slide cam moves to the disengagement position. As a result, the pusher pin is released from the engagement with the slide cam and becomes free, and the mold closing operation of the mold is completed after the ejector plate returns to the standby position.

As described above, according to the present invention, it is possible to move between the pusher pin that moves in conjunction with the mold closing operation of the mold, the engagement position that engages with the pusher pin, and the engagement release position that releases the engagement. A slide bar, and a release bar that moves the slide cam to the disengagement position when the ejector plate moves to the standby position when the mold is closed. Since the mold closing force is applied in the direction of engagement between the pusher pin and the slide cam, the engagement between the two does not come off or come off, and the reliability and certainty when the ejector plate is quickly returned can be improved. .

Since the pusher pin is engaged with the slide cam when the mold is closed and the ejector plate is returned to the standby position, the friction resistance is higher than when a conventional protrusion is fitted in the fitting hole or the roller pin is slid. Can be reduced, and the life of the parts can be extended.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

FIGS. 1 to 12 are views for explaining a molding machine according to an embodiment of the present invention, FIGS. 1 and 2 are schematic configuration diagrams of a mold, FIG. 3 is a sectional view of a mold in a closed state, 4 is a sectional view of the mold in the mold open state, FIGS. 5 to 10 are diagrams showing the configuration and operation of the ejector plate quick return mechanism, and FIGS. 11 and 12 are perspective views and exploded perspective views of the ejector plate quick return mechanism. FIG.

In the figure, reference numeral 1 denotes a molding machine in which a hoop insert molded product A such as an electronic component is injection-molded, which includes a movable mold member 3 and a fixed mold member 4 on a fixed base 2. The mold 5 provided, the eject mechanism 8 that pushes up the hoop insert molded product A injection-molded by the mold 5 by the ejector pin 7 and separates it from the mold 5, and the ejector pin 7 when the mold is closed. Ejector plate quick-return mechanism 9 for returning to the position is integrally mounted, and a hydraulic drive unit (not shown) for opening and closing the mold 5 between the mold opening position and the mold closing position is mounted under the fixed base 2. It has a structure.

The hoop insert molded product A is held by the hoop 10, and the hoop 10 is intermittently conveyed in the B direction. Reference numeral 11 denotes a hoop guide that movably supports the hoop 10.

The movable mold member 3 has a structure in which a runner plate 13 is disposed above the movable mold plate 12 and a nozzle touch plate 14 is disposed above the runner plate 13. The fixed mold member Reference numeral 4 denotes a structure in which an ejector plate 16 is disposed below the fixed mold 15 facing the movable mold 12 and a fixed plate 17 is disposed below the ejector plate 16. The fixed plate 17 is fixed on the fixed base 2.

3 and 4, first, the mold 5 is opened between the movable side mold plate 12 and the runner plate 13, and the insert molded product A and the runner C are connected to the gates 12a and 12a. Then, the movable mold plate 12 and the fixed mold plate 15 are opened, the ejector pins 7 are pushed up to separate the insert molded product A from the fixed mold plate 15, and then sent out in the direction B by the hoop 10, Subsequently, the runner plate 13 and the nozzle touch plate 14 are opened to take out the runner C to the outside. Reference numeral 20 denotes a nozzle that supplies a molding material, and 21 denotes a nozzle bush that serves as a guide for the molding material.

The eject mechanism 8 can be projected and retracted between a protruding position where the ejector pin 7 fixed to the ejector plate 16 protrudes from the upper surface of the fixed-side mold plate 15 and a standby position where the ejector pin 7 is inserted into the fixed-side mold plate 15. It has a supported structure. The ejector plate 16 is configured to be driven up by a lift drive unit such as a cylinder.

The ejector plate quick return mechanism 9 is configured to return the ejector plate 16 in the protruding position to a standby position in contact with the fixed plate 17 in conjunction with the mold closing operation of the mold 5 and prior to completion of the mold closing operation. Has been. Specifically, as shown in FIG. 5, the pusher pin 25 that moves in the opening and closing direction in conjunction with the opening and closing operation of the mold 5, the engagement position that engages with the pusher pin 25, and the engagement are released. The slide cam 26 disposed so as to be movable between the disengagement position and the slide cam 26 is positioned at the engagement position when the mold closing operation of the mold 5 is started, and the ejector plate 16 is set at the standby position. A release bar 27 is provided for moving the slide cam 26 to the disengagement position when it is moved, and has the following structure in detail. 5 (b) to 10 (b) are views seen in the direction of arrow a in FIGS. 5 (a) to 10 (a).

As shown in FIGS. 11 and 12, the pusher pin 25 has a prismatic shape, and the upper end portion of the pusher pin 25 is fastened and fixed to the outer surface of the movable side mold plate 12 by a bolt 30 with a spacer 29 interposed. . An engaging step portion 25c having an inclined surface 25a extending obliquely downward and a vertical surface 25b extending vertically downward following the inclined surface 25a is formed at the lower end of the pusher pin 25.

The slide cam 26 has a rectangular plate shape, and a cam portion 26a that is in surface contact with the engagement step portion 25c is formed at the tip of the slide cam 26. An engagement recess 26b is formed at the center of the slide cam 26.

The slide cam 26 is supported by a cam block 31 so as to be movable in a direction perpendicular to the opening / closing direction of the mold 5. The cam block 31 is divided into a block main body 32 and a slide member 33, and both 32, 33 are coupled by bolts 34, 34. The cam block 31 is disposed at a portion facing the engaging step portion 25c of the pusher pin 25, and is fastened and fixed to the upper surface of the ejector plate 16 by bolts 35 and 35.

The slide member 33 is formed with a slide groove 33a for slidably guiding and supporting the slide cam 26, and the block body 32 is formed with an engagement groove 32a with which the release bar 27 is slidably contacted. .

The release bar 27 has a substantially prismatic shape, and includes a vertical portion 27a extending in the vertical direction and an engaging portion 27b extending obliquely from the vertical portion 27a toward the pusher pin 25. The lower end portion is fastened and fixed to the fixing plate 17 by bolts 38 with a spacer 37 interposed. The engaging portion 27b is inserted through the engaging groove 32a and is engaged with the engaging recess 26b of the slide cam 26. Here, the amount of movement of the slide cam 26 can be adjusted by setting the inclination angle of the engaging portion 27b of the release bar 27, the engagement period between the cam block 31 and the slide cam 26, and the like.

Next, the operation of the ejector plate return mechanism 9 will be described.

When the injection molding of the hoop insert molded product A is completed in the mold 5, the mold opening operation of the mold 5 is started, and the pusher pin 25 rises as the movable side mold plate 12 rises, and the mold 5 is opened. The operation ends (see FIGS. 5 and 6). Then, the ejector plate 16 rises to the protruding position, and the ejector pin 7 pushes up the hoop insert molded product A from the fixed-side mold plate 15 (see FIG. 7).

On the other hand, when the ejector plate 16 is raised, the cam block 31 is raised accordingly, the release bar 27 moves the slide cam 26 in the engaging direction, and when the ejector plate 16 reaches the push-up position (upper limit), Synchronously with this, the slide cam 26 protrudes to the engagement position (see FIG. 7).

When the mold opening operation is completed and the mold closing operation of the mold 5 is started, the pusher pin 25 is lowered as the movable side mold plate 12 is lowered, and the engagement step portion 25c of the pusher pin 25 is positioned at the engagement position. It contacts the cam portion 26a of the slide cam 26 (see FIG. 8). When the movable side template 12 is further lowered in this state, the pusher pin 25 pushes down the slide cam 26 and lowers the ejector plate 16 via the cam block 31 (see FIG. 9). As the ejector plate 16 descends, the cam block 31 descends, the release bar 27 retracts the slide cam 26 in the disengagement direction, and the ejector plate 16 contacts the fixed plate 17 and reaches the standby position. Synchronously, the slide cam 26 moves to the disengagement position (see FIG. 10). Subsequently, the mold closing operation of the movable side mold plate 12 is performed, and the mold closing is completed (see FIG. 5).

As described above, in the present embodiment, the pusher pin 25 descends and engages with the slide cam 26 in surface contact with the mold closing operation of the mold 5, and the pusher pin 25 is engaged with the slide cam 26 by the mold closing force of the mold 5. Then, the ejector plate 16 is lowered, and when the ejector plate 16 reaches the standby position, the slide cam 26 moves back to the disengagement position substantially simultaneously. As a result, the pusher pin 25 is disengaged from the slide cam 26 and becomes free, so that the mold closing operation of the mold 5 is completed after the ejector plate 16 returns to the standby position.

According to the present embodiment, the pusher pin 25 moves in conjunction with the mold closing operation of the mold 5, and moves between an engagement position that engages with the pusher pin 25 and an engagement release position that releases the engagement. The possible slide cam 26 and the slide cam 26 are moved to the engagement position when the mold closing operation of the mold 5 is started, and the slide cam 26 is moved to the engagement release position when the ejector plate 16 is moved to the standby position. Since the release bar 27 is provided, the mold closing force of the mold 5 is applied in the direction of engagement between the pusher pin 25 and the slide cam 26, so that the engagement between the two 25 and 26 does not come off or come off. The reliability and certainty when the ejector plate 16 is returned quickly can be improved.

Further, since the pusher pin 25 is engaged with the slide cam 26 when the mold is closed, and the ejector plate 16 is returned to the standby position, compared with the case where the conventional protrusion is fitted in the fitting hole or the roller pin is slid. Thus, the frictional resistance can be reduced and the life of the parts can be extended.

In the present embodiment, the pusher pin 25, the cam block 31 that supports the slide cam 26, and the release bar 27 are structured to be attached to the outer surface of each component of the mold 5, so that it can be retrofitted to an existing mold. Is possible. Further, since the disengagement state of the pusher pin 25 can be confirmed from the outside, the position of the pusher pin 25 can be easily adjusted.

Although the present embodiment is an example of vertical driving, it is naturally applicable to horizontal driving. In addition, this embodiment is an example of insert molding, but naturally it can also be applied to normal molding (single product molding that is not an insert).

It is a schematic block diagram of the metal mold | die for demonstrating the molding machine by one Embodiment of this invention. It is a schematic block diagram of the said metal mold | die. It is sectional drawing of the mold closed state of the said metal mold | die. It is sectional drawing of the mold open state of the said metal mold | die. It is a figure which shows the structure and operation | movement of the ejector plate quick return mechanism of the said molding machine. It is a figure which shows operation | movement of the said ejector plate quick return mechanism. It is a figure which shows operation | movement of the said ejector plate quick return mechanism. It is a figure which shows operation | movement of the said ejector plate quick return mechanism. It is a figure which shows operation | movement of the said ejector plate quick return mechanism. It is a figure which shows operation | movement of the said ejector plate quick return mechanism. It is a perspective view of the ejector plate quick return mechanism. It is a disassembled perspective view of the said ejector plate quick return mechanism.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Molding machine 5 Die 9 Ejector plate quick return mechanism 16 Ejector plate 25 Pusher pin 26 Slide cam 27 Release bar A Hoop insert molded product

Claims (1)

A molding machine equipped with an ejector plate quick return mechanism that returns an ejector plate that pushes and separates a molded product molded by a mold to the original standby position in conjunction with the mold closing operation of the mold. The ejector plate quick return mechanism includes a pusher pin that moves in the opening and closing direction in conjunction with an opening and closing operation of the mold, an engagement position that is supported by the ejector plate and engages with the pusher pin, and the pusher pin. A slide cam disposed so as to be movable between an engagement release position for releasing engagement, and the ejector plate that moves the slide cam to an engagement position when the mold starts a mold closing operation. And a release bar that moves the slide cam to the disengagement position when the slide cam moves to the standby position.

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