KR101328853B1 - Core unit for molding - Google Patents

Abstract

The present invention relates to a core unit of a mold of a new structure that can reduce the number of parts of the core unit or the core unit operating the ejector and the cost by reducing the volume.
According to the present invention, the core shaft 4 equipped with the core 2 at the tip extends through the support plate 6 supporting the movable mold, and its proximal end is adjustable in the fixed plate 8 or the ejector plate. In the slidably coupled core unit 10, slidably coupled to the slide groove 12 formed on the upper surface of the fixed plate 8 or the ejector plate, and a plurality of oilless bearings 15 are embedded in the outer surface. A shaft mounting groove 18 is rotatably coupled to the slide block 13 through a slide block 13 and both end rotation shafts 17 and the core shaft 4 is inserted therein. It is screwed to be embedded in the adjusting member 19 of the rotating member 16 and the rotating member 16 is provided through the adjustment hole 19 is formed through the screw thread on the inner circumferential surface of the shaft mounting hole (18) Through-hole 33 is formed in the center The core unit of the mold including a two bolt 32 and a fixing bolt 36 passing through the through hole 33 of the tannery bolt 32 and screwed into the bottom surface of the proximal end of the core shaft 4. This is provided.

Description

Core unit for molding

The present invention relates to a core unit of a mold, and more particularly, to a core unit of a mold having a new structure that can reduce the number of parts and reduce the volume of the core unit for operating the core or ejector of the mold. .

In the injection molding mold, a core unit for operating a slide core used for forming a molded article having an undercut or an ejector mechanism (hereinafter referred to as a core unit) for releasing the molding from the mold is used. 1 and 2 show the structure of such a core unit in the prior art. As shown, a core shaft 4 equipped with a core 2 such as a slide core or a deformation core (ejector) extends through the support plate 6 supporting the movable mold and its proximal end is an ejector plate. It is coupled to the top plate 8. In this case, as shown in FIG. 2, the coupling portion between the proximal end of the core shaft 4 and the fixed plate 8 includes a plurality of oilless bearings 15 in the slide groove 12 formed on the bottom surface of the fixed plate 8. The embedded slide block 13 is slidably coupled, and the slide block 13 is rotatably coupled to the rotating member 16 on which the pivot shaft 17 protrudes at both ends. The upper surface of the rotating member 16 is formed with a shaft mounting groove 18 into which the core shaft 4 is inserted, through which the shaft mounting groove 18 penetrates downward from the bottom and has a thread formed on the inner circumferential surface thereof. 19).

The adjusting bolt 20 is screwed to the adjustment hole 19 has a hollow portion 21 formed therein, so that the front end of the adjustment bolt 20 protrudes through the bottom of the shaft mounting groove 18 so as to protrude from the core shaft. (4) By regulating the position of the core shaft 4 in contact with the end face of the proximal end, as a result, the length of the core shaft 4 is adjusted. An outer surface of the adjusting bolt 20 is provided with a fixing nut 22 for fixing the adjusting bolt 20 to abut the bottom surface of the rotating member 16. The fixing bolt 24 is penetrated through the hollow portion 21 of the adjusting bolt 20 to be screwed to the bottom surface of the base end of the core shaft 4 to fix the core shaft 4. The guide rail 26 is coupled to the bottom of the fixing plate 8 outside the fixing nut 22 to guide the reciprocating movement of the slide block 13.

However, such a conventional injection molding core unit has a relatively complicated structure for guiding the slide of the core shaft 4 base end and fixing the core shaft 4 to be adjustable in length, and for guiding the slide operation of the base end of the core shaft 4. There is a lot of problems. That is, the fixing bolt 24 and the adjusting bolt 20 protrudes outward from the lower fixing plate 8 to occupy a lot of space, thereby increasing the size of the injection molding apparatus, and also sliding grooves for inserting the slide block 13 ( There was a problem that the depth of 12) takes a lot of processing time of the slide groove 12.

Patent No. 10-0887386

The present invention has been proposed in view of the problems of the core unit of the conventional mold as described above, the present invention is excellent in assembling, while the cost is reduced because the number of parts and the size is small, the core unit of the mold of a compact structure Is to provide.

According to one feature of the invention, a core shaft (4) equipped with a core (2) at its tip extends through a support plate (6) supporting a movable mold, the proximal end of which has a length at a fixed plate (8) or an ejector plate. In the core unit 10 that is adjustable and slidably coupled, a plurality of oilless bearings 15 are slidably coupled to a slide groove 12 formed on an upper surface of a fixed plate 8 or an ejector plate. The buried slide block 13 and the shaft mounting groove 18 in which the core shaft 4 is inserted and mounted are rotatably coupled to the slide block 13 through the rotating shaft 17 at both ends thereof. And a rotating member 16 having a control hole 19 formed therein and downwardly penetrating from the bottom of the shaft mounting hole 18 and having a screw thread formed on an inner circumferential surface thereof, and being embedded in the adjusting hole 19 of the rotating member 16. Screwed and through hole 33 in the center And a fixing bolt 36 formed through the formed tannery bolt 32 and a through hole 33 of the tannery bolt 32, the tip of which is screwed to the bottom surface of the proximal end of the core shaft 4. The core unit of the mold is provided.

According to another feature of the invention, the slide block 13 coupled to the slide groove 12 of the fixing plate 8 is composed of a pair of cross-sectional L-shaped block, and the bottom surface of the slide block 13 and The oilless bearing 15 is embedded in the upper surface of the stepped portion 14, and a hinge hole 31 to which the pivot shaft 17 of the pivot member 16 is coupled to an opposite surface of the upright portion of the slide block 13. ) Is formed, and the core unit of the mold, characterized in that the guide rail 26 in sliding contact with the upper surface of the stepped portion 14 of the slide block 13 is mounted on the upper surface adjacent to the fixing plate (8) Is provided.

According to the present invention, in the core unit of the injection molding die, the adjustment of the rotating member 16 is rotatably coupled to the slide block 13 inserted into the fixed groove 8 or the slide groove 12 of the upper surface of the ejector plate The tannery bolt 32 is screwed to be embedded in the ball 19, and the core unit is screwed into the bottom surface of the proximal end of the core shaft 4 by inserting the fixing bolt 36 through the tannery bolt 32. The length of the core shaft 4 can be adjusted firmly and firmly without protruding from the bottom of the fixing plate 8. In addition, since the tannery bolt 32 does not protrude to the outside of the lower end of the rotating member 16, the head portion of the tannery bolt 32 may collide with the peripheral member of the fixing plate 8 when the rotating member 16 rotates. There is little concern, which improves the reliability of operation.

In addition, the slide groove 12 of the upper surface of the fixed plate 8 is formed relatively relatively deep, and the slide block 13 inserted into the slide groove 12 is manufactured to have a cross-sectional L-shape to form the slide block 13. Since the part is made to protrude above the fixed plate 8 and is constructed so that the guide rails 26 are placed on the stepped portions 14 of the slide convex 13, it is not necessary to process the slide groove 12 deeply. It can reduce machining time and reduce manufacturing cost.

1 is a configuration diagram of a conventional injection mold core unit
2 is a main configuration diagram of the core unit
3 is a schematic structural diagram of an embodiment of the present invention;
4 is an enlarged view of main parts of the embodiment;
Figure 5 is an exploded perspective view of the main part of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. Figure 3 is a schematic configuration diagram of an embodiment of the present invention, Figure 4 is an enlarged view of the main portion, Figure 5 is an exploded perspective view of the main part of the present invention. As shown, the core unit 10 according to the present invention is inclined through the support plate 6 supporting the movable mold by the core shaft 4 equipped with the core 2 at the tip thereof, and the proximal end thereof is fixed plate 8. ) Is combined. The core 2 is a core for molding an undercut in an injection mold or an ejector (deformation core) for releasing a molding from a movable mold, and the fixing plate 8 corresponds to an ejector plate when the core 2 is an ejector. do.

A slide groove 12 is formed on the upper surface of the fixing plate 8 according to the present invention. And the slide block 13 is slidably coupled to the slide groove 12 in the horizontal direction. The slide block 13 has an L-shaped cross section, and an oilless bearing 15 is embedded in the bottom face and the stepped portion 14. In addition, a hinge hole 31 is formed on an opposing surface of the upright portion of the slide block 13, and the hinge hole 31 is coupled with both ends of the rotation shaft 17 of the rotation member 16 to rotate the member 16. ) Is rotated. The upper surface of the rotating member 16 is formed with a shaft mounting groove 18 into which the core shaft 4 is inserted. The adjustment hole has a screw thread formed on the inner circumferential surface of the shaft mounting hole 18. 19 is provided. Preferably, a lower chamfer is formed at the lower end of the core shaft 4, and correspondingly, the shaft mounting groove 18 is also formed in a substantially semi-circular shape in which the chamfer is formed so that the core shaft does not rotate without a separate key groove or key member.

The adjustment hole 19 of the rotation member 16 is coupled to the tannery bolt 32 is screwed and fitted from the bottom surface of the rotation member 16. The tannery bolt 32 is preferably fastened by engaging a wrench to a wrench coupling groove not shown so as to be fully inserted into the pivot member 16. The upper end of the tannery bolt 32 abuts the bottom surface of the core shaft 4 so as to finely adjust the protruding length of the core shaft 4, so that the length of the core shaft 4 can be adjusted. And the through-hole 33 without a thread is formed in the center of the tannery bolt 32. The fixing bolt 36 is inserted through the through hole 33 from the bottom of the tannery bolt 32 to be screwed into the screw hole 5 formed at the bottom of the core shaft 4 to fix the core shaft 4. Let's do it.

As such, the tannery bolts 32 are screwed to be embedded in the adjusting holes 19 of the rotation member 16, and the fixing bolts 36 are inserted through the tannery bolts 32 so that By screwing on the bottom of the proximal end, the core unit according to the present invention can be fixedly and firmly adjustable while controlling the length of the core shaft 4 without protruding to the lower outer side of the fixed plate 8. In addition, since the tannery bolt 32 does not protrude to the outside of the lower end of the rotating member 16, the head portion of the tannery bolt 32 may collide with the peripheral member of the fixing plate 8 when the rotating member 16 rotates. There is less concern, which increases the reliability of operation.

In addition, according to the present invention, the slide block 13 is formed in the L-shaped cross section is coupled to the slide groove 12 formed on the upper surface of the fixed plate (8). A guide rail 26 which supports the slide block 13 to be slidable from the outside and prevents the slide block 13 from being separated is supported by the stepped portion 14 having the low height of the slide block 13. . According to this structure, even if a part of the slide block 13, that is, the upright portion is exposed from the fixing plate 8, the slide block 13 is supported on the guide rail 26 through the stepped portion 14, so that the departure is prevented, It is possible to configure the device as a relatively relatively deeper depth of the slide groove 12 into which the slide block 13 is inserted. Accordingly, since the slide groove 12 does not need to be deeply processed, the processing cost is reduced because the processing is easy and the processing time is shortened.

Claims (2)

A core shaft (4) equipped with a core (2) at its tip extends through the support plate (6) supporting the movable mold, and its proximal end is slidably and slidably coupled to the fixed plate (8) or ejector plate. In the core unit 10, the slide block 13 is slidably coupled to the slide groove 12 formed on the upper surface of the fixing plate 8 or the ejector plate, and the plurality of oilless bearings 15 are embedded in the outer surface. And a shaft mounting groove 18 in which the core shaft 4 is inserted and rotatably coupled to the slide block 13 through both end pivot shafts 17, and the shaft mounting hole 18. Rotating through the bottom of the bottom and the rotating member 16 is provided with a control hole 19, the thread formed on the inner circumferential surface, and screwed to be embedded in the control hole 19 of the rotating member 16 and through hole ( 33, the tanned bolt 32 is formed, and Through the through-holes 33 of the two bolts 32, the tip comprises a screw-fixing bolt 36 is at the bottom surface base end portion of the core shaft (4),
The slide block 13 coupled to the slide groove 12 of the fixing plate 8 is composed of a pair of cross-sectional L-shaped blocks, the bottom surface of the slide block 13 and the upper surface of the stepped portion 14 An oilless bearing 15 is embedded, and a hinge hole 31 to which the pivot shaft 17 of the pivot member 16 is coupled is formed on an opposite surface of the upright portion of the slide block 13. (8) the core unit of the mold, characterized in that the guide rail 26 in sliding contact with the upper surface of the stepped portion 14 of the slide block (13) is mounted. delete

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