KR101915791B1 - Operation Structure of Slide Core for Double Injection Mold - Google Patents

Abstract

The present invention relates to an operation structure of a slide core for a double injection mold. As features of the configuration, the operation structure includes: an operation block having a coupling groove connected to one or more slide cores on one side, and an inclined groove guiding forward/backward movement according to opening/closing of a mold on the other side of the coupling groove; an operation pin including a first injection unidirectional inclined pin coupled to the inclined groove in accordance with the opening and closing of the mold and advancing the operation block, and a second injection bi-directional inclined pin restraining and reversing the advanced operating block; and at least one operation means having a latching pin selectively operating backing power in cooperation with the operation pin on the operation block, and a spring interposed between the operating means for imparting elastic force in one direction to the coupling pin. Accordingly, the present invention has an effect of improving the quality of the overall product by improving the structure in which the up-and-down movement of the mold and the forward and backward movement of the slide core are selectively interlocked instead of unilaterally interlocking with each other.

Description

Technical Field [0001] The present invention relates to an operation structure of a slide core for a dual injection mold,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a slide core for a dual injection mold, and more particularly, to a slide core for a double injection mold, more specifically, a slide core for a dual injection mold improved in structure in which a vertical movement of a die and a forward / backward movement of a slide core are selectively interlocked To an operating structure.

In general, injection molding is performed by injecting and filling a molten resin at a proper temperature and a proper pressure in a cavity of a mold having a product shape and then filling and filling the filled resin for a predetermined time, The molded product is taken out. In this case, a double injection mold is often used for injection molding of a composite product having different kinds of resin or different parts of hue, and a double injection mold includes a turn-table type, a rotary type, , Die slide injection type (DSI type), and the like.

Such double injection molds are disclosed in Korean Patent Publication No. 10-1339032 entitled " Double injection mold having a sliding core for reinforcing structural fragile parts in a mold ". According to the disclosed document, a primary side upper mold having a primary nozzle and a secondary side upper mold having a secondary nozzle are provided on the secondary side. Between the primary mold on the upper side and the upper mold on the secondary side, And a lower mold made up of a mold and a secondary side lower mold.

The primary side lower mold and the secondary side lower mold are formed symmetrically with each other and have a structure that is rotated 180 degrees by a turn table. Therefore, the molten resin on the primary side is injected into the primary cavity between the primary mold and the primary mold through the primary nozzle, and after the primary product is molded, the primary mold is rotated 180 degrees so that the primary mold is placed on the secondary mold The product is injected through the secondary nozzle to complete the product.

In the case where an undercut or hole is formed in the product, a slide core must be used. The slide core basically operates to move the core back and forth based on the up and down movement of the die (angular pin) so that the product can be taken out. That is, when the metal mold is lowered, the slide core advances to form a cavity, and when the metal mold is lifted and lowered, the slide core is moved backward to open the cavity, thereby performing an operation of interlocking with the lifting and lowering of the metal mold.

However, as described above, in the case of the double injection molding, the primary and secondary molding are separately performed. In each of the primary molding and the secondary molding, the slide core repeatedly advances and retracts to cause defects. That is, the slide core is inserted into the undercut portion or the hole portion provided in the primary molded product during the secondary molding. In this process, the resin is deformed due to shrinkage, relaxation or insertion shock.

Recently, in order to solve such similar problems, Korean Registered Patent No. 10-1156512 entitled "Slide Core Device for Injection Mold and Method of Manufacturing Leadframe Insert Mold Using the Same" and Korean Patent Publication 10- 1604265 (entitled " Dual Injection Mold Slide Assembly "). According to the proposed literature, it is possible to move the slide core to its original position after the sliding forward operation in the secondary molding. However, since it has a relatively complicated structure, not only the cost is increased, but also there is a problem that the noise is large and the failure rate is high.

Korean Patent Publication No. 10-1339032 (entitled "Double injection mold having a sliding core for reinforcing a structural weak part in a mold) Korean Registered Patent No. 10-1156512 (Name of the Invention: Slide Core Device for Injection Mold and Method of Manufacturing Leadframe Insert Mold Using the Same) Korean Registered Patent No. 10-1604265 (Title of Invention: Slide Assembly for Double Injection Mold)

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a method of selectively and interlocking a vertical movement of a die and a slide movement of a slide core, The present invention aims at providing an operation structure of a slide core for a dual injection mold, which can reduce the failure rate and the construction cost as well as improve the quality of products.

In order to achieve the above object, the present invention provides an operation structure of a slide core for a dual injection mold, comprising: a coupling groove connected to one or more slide cores on one side; and a guide groove formed on the other side of the coupling groove, An operation block in which an inclined groove is formed; An actuating pin having a first injection unidirectional tapered pin engaged with the tapered groove in accordance with opening and closing of the mold and advancing the operation block, and a second injection tapered bi-directional taper pin for restraining and advancing the advanced operation block; And at least one actuating means having a latching pin for selectively exerting a retraction force in cooperation with the actuating pin on the actuating block, and a spring for imparting a resilient force in one direction to the retaining pin.

At this time, the latching pin according to the present invention is mounted on the operation block in a direction crossing the inclined grooves, and the engaging pin protrudes and retracts according to the operation pin inserted into the inclined grooves, selectively exerting a backward force.

Further, the unidirectional beveling pin according to the present invention is characterized in that the avoiding surface is formed in a direction parallel to the protruding engaging pin, and the bi-directional beveling pin is formed in a direction perpendicular to the protruding engaging pin.

In addition, the latching pin according to the present invention is characterized in that an inclined surface is formed to minimize mutual friction at a contact portion depressed from the inclined groove by the bidirectional inclined fin.

It should be understood, however, that the terminology or words of the present specification and claims should not be construed in an ordinary sense or in a dictionary, and that the inventors shall not be limited to the concept of a term It should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be properly defined. Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It is to be understood that equivalents and modifications are possible.

As described above, according to the present invention, while adopting the conventional structure in which the slide core is moved forward and backward by only up and down movement of the mold without using a separate actuator, the present invention does not operate unilaterally to the up- In the molding process, the slide core is moved forward, and during the secondary molding, the variable structure is employed to push backward to the original position after advancing, thereby improving the quality of the product. The variable operating structure is then improved to a thin and simple structure The overall construction cost can be reduced and the failure rate can be significantly reduced.

1 is a perspective view showing an operating structure of a slide core according to the present invention;
Fig. 2 is an exploded view showing the operating structure of Fig. 1 separately. Fig.
FIG. 3 is an enlarged view of the main part of FIG. 2; FIG.
4 to 6 are sectional views showing the operation of the slide core of the present invention.

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

The present invention relates to an operation structure of a slide core 1 for a dual injection mold M and is characterized in that it has a structure in which the operation block 10 and the actuating pin 20 and the actuating means 30, It is the operating structure of the slide core. The main object of the present invention is to improve the overall product quality by improving the structure in which the up-and-down movement of the mold (M) and the forward / backward movement of the slide core (1) are selectively interlocked without interlocking with each other.

As shown in FIG. 1, the operation block 10 according to the present invention is a slide block which is disposed at the periphery of the lower mold M to move the slide core 1 forward and backward. An inclined groove (15) is integrally formed on one side and the other side. The engagement grooves 11 serve to guide the connection with the at least one slide core 1. The inclined grooves 15 interlock with the operation pins 20 to be described later according to the opening and closing of the mold M, Thereby inducing operation.

Here, the inclined groove 15 is formed as a U-shaped cross section opened at the center of the operation block 10 in the other direction, and is inclined at a forward / backward angle with an appropriate stroke in accordance with the upward / downward movement of the operation pin 20. The actuating block 10 is formed so that an actuating hole 10a for guiding the engagement of the actuating means 30 to be described later is communicated with the inclined groove 15. Therefore, the actuating means 30 fastened to the inclined groove 15 does not operate unilaterally according to the up-and-down movement of the actuating pin 20, and only desired operation can be realized.

The operation pin 20 according to the present invention is an angular pin which is mounted on the upper mold M and gives an actuating force to move the slide core 1 forward and backward as shown in FIG. 1, and includes an unidirectional beveled pin 21 And bi-directional beveled pins 25, respectively. The bidirectional inclined fin 21 is mounted on the upper mold M for primary injection to engage with the inclined groove 15 to advance the operation block 10 and the bi- The upper mold M is engaged with the inclined groove 15 to restrain the operation block 10 in the advanced state and to move back to the original position.

That is, in the primary injection, the unidirectional inclined fin 21 is lowered and moved upward while advancing the slide core 1, and in the secondary injection, the bidirectional inclined fin 25 is lowered to move the advanced slide core 1 After the injection molding in the state of restraint (fixed), the slide core 1 is moved backward as it is rising. The selective operation of the actuating pin 20 and the actuating block 10 is interlocked with the actuating means 30 described later and will be described later.

The actuating means 30 according to the present invention selectively interlocks with the upward and downward movement of the actuating pin 20 on the inclined groove 15 as shown in FIG. (35). The engagement pin 31 serves to selectively exert a backward force on the operation block 10 in cooperation with the operation pin 20 and the spring 35 imparts an elastic force in one direction to the engagement pin 31 . That is, the engaging pin 31 and the spring 25 are inserted into the tine bolt in the direction transverse to the inclined groove 15 on the operation block 10. Therefore, it is restrained and protruded according to the operation pin 20 inserted into the inclined groove 15 to selectively exert a backward force.

Here, the unidirectional inclined fin 21 has a circumferential surface 21a in a direction parallel to the protruding engaging pin 31 as shown in FIG. 3A, and the bi-directional inclined fin 25 has protruding engaging pins 35 as shown in FIG. And the engaging surface 25a is formed in a direction perpendicular to the above.

That is, the unidirectional inclined fin 21 does not interfere with the engaging pin 31 when inserted (lowered) into the inclined groove 15 by the avoiding surface 21a as shown in FIG. However, the actuating block 10 is advanced while being engaged with the inclined groove 15 at the time of descent. Therefore, even if the unidirectional inclined fin 21 performs the up-and-down reciprocation, the unidirectional inclined fin 21 only performs the action of advancing the operation block 10.

5, the bidirectional beveled fin 25 is formed to have a width corresponding to the beveled groove 15, so that the beveled pin 31 protruded at the time of insertion (descent) into the beveled groove 15 is inserted and inserted. When fully lowered, engages with the inclined groove 15 like the unidirectional inclined fin 21 to restrain the operation block 10 in the advanced state, and the engaging pin 31 protruded from the engaging surface 25a and engaged with each other do. Therefore, when the bi-directional inclined fin 25 is separated (lifted), the engaging pins 31 engaged with each other as shown in FIG. 6 are caught by the engaging surface 25a and are moved backward.

3C, the engaging pin 31 may be formed with an inclined surface 31a which is inclined at a predetermined angle to a contact portion which is recessed from the inclined groove 15 by the bi-directional inclined fin 25. [ That is, the inclined surface 31a minimizes the friction with the bi-directional inclined fin 25. [ Therefore, it is possible to reduce noise and abrasion due to the operation and to improve the overall service life.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined by the appended claims. It is therefore intended that such variations and modifications fall within the scope of the appended claims.

M: Mold 1: Slide core
10: actuating block 10a: actuating hole
11: fastening groove 15: inclined groove
20: Operation pin 21: One-way inclined pin
21a: avoiding surface 25: bidirectional inclined pin
25a: engaging surface 30: operating means
31: latching pin 35: spring
35a:

Claims (4)

An operation structure of a slide core for a dual injection mold, comprising:
An operation block having an engaging groove connected to one or more slide cores on one side and an inclined groove formed on the other side of the engaging groove for guiding forward and backward movement according to opening and closing of the mold;
An actuating pin having a first injection unidirectional tapered pin engaged with the tapered groove in accordance with opening and closing of the mold and advancing the operation block, and a second injection tapered bi-directional taper pin for restraining and advancing the advanced operation block; And
And at least one actuating means having a latching pin for selectively exerting a retraction force in cooperation with the actuating pin on the actuating block and a spring for giving a resilient force to the latching pin in the actuating block. Operation Structure of Slide Core for Mold. The method according to claim 1,
Wherein the engaging pin is mounted on the actuating block in a direction transverse to the inclined groove and selectively exerts a retracting force by projecting and retracting according to the actuating pin inserted into the inclined groove. 3. The method of claim 2,
Wherein the unidirectional beveled fin is formed with a circumferential surface in a direction parallel to the protruded engaging pin and the bi-directional beveled fin is formed with a retaining surface in a direction perpendicular to the protruding engaging pin. . The method of claim 3,
Wherein the engaging pin is formed with an inclined surface so as to minimize friction between the engaging pin and the contact portion which is recessed from the inclined groove by the bi-directional inclined fin.

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