KR101717026B1 - Slide core assembly for processing under cut with multi angles at a time - Google Patents

Abstract

The present invention relates to a slide core assembly, and more specifically, to a slide core assembly for simultaneously processing undercuts with multiple angles, which, when the sliding direction is limited, processes undercuts having multiple directions (angles) by synchronizing slide cores in an inclined direction. According to the present invention, the slide core assembly comprises: a base block which has an inclined surface formed in an upper part thereof, and an open guide surface having a step-like shape formed on a back surface thereof; an upper slide core whose bottom surface performs a linear sliding motion along the inclined surface of the base block, and which includes a locking bar protruding on the bottom surface thereof; and a lower slide core which has, on the upper surface thereof, a guide groove having the locking bar of the upper slide core mounted therein, and which, according to a movement of the upper slide core, moves in sync with the movement while forming an acute angle with the movement, and moves linearly along the guide surface of the base block.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a slide core assembly for simultaneous multi-directional undercut machining,

The present invention relates to a slide core assembly, and more particularly, to a multi-directional undercut simultaneous processing slide capable of simultaneously processing undercuts having various directions (angles) by interlocking the slide cores in an oblique direction in a situation where the slide direction is limited Core assembly.

Generally, a slide core is used to process an undercut during the production of an injection mold. When the angle at which the undercut is to be processed is determined, the slide core is machined by giving an angle to the core- Make a separate slide core for the angle.

On the other hand, a mold apparatus for the inner and outer double undercut processing capable of easily changing the structure without fully replacing the mold apparatus when locally changing the shape of the undercut portion and the double undercut portion formed on the inner and outer sides of the molded product has been developed (See KR Registration Utility Model No. 0451371).

Wherein the inner and outer double undercut processing mold apparatuses are formed by projecting into a cavity space of upper and lower molds and lower molds forming a cavity space therein, and an inner slide pin is inserted into the cavity together with a spring, And an inner core portion having a main through hole formed on one side thereof so as to be exposed.

The slide core includes a slide core having an angular pin and an angular ball which are provided in the upper die and horizontally moved on the die under the mold starting from the die. The slide core is inserted into the second hole formed at the other side of the inner core, So that the slide core pin is configured to press the inner slide pin.

And an actuating pin which is provided in a lowered shape so as to face the slide core pin and meshes with an end of the inner slide pin to control retraction movement.

However, although the conventional undercut processing mold apparatus can process double undercuts formed on the inner and outer sides, when the undercut portion has two angles, it is necessary to separately manufacture slide cores corresponding to each angle .

In order to solve such a problem, the applicant of the present invention has proposed a slide core assembly capable of simultaneously processing two undercuts by moving one slide core without manufacturing an individual slide core for each angle of undercut by double-coupling the blocks in an oblique direction (KR Patent Application No. 2015-0070747).

KR registered utility model 0451371 (2010.12.06) KR Patent Application No. 2015-0070747 (May 2015, 201)

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve the problems of the prior art as described above, and it is an object of the present invention to provide a slide core in which a slide core is slidably coupled It is an object of the present invention to provide a slide core assembly for simultaneous processing of a multi-direction undercut which can simultaneously process undercuts in various directions (with angles).

In order to achieve the above object, the present invention provides a slide core assembly for simultaneous multi-directional undercut machining, wherein a slant surface is formed at an upper portion of the slide core assembly, and a guide surface opened in a stepwise manner is formed on a downwardly bent surface of the slant surface A base block; An upper slide core in which a bottom surface slides linearly along an inclined surface of the base block and a latching bar protrudes downward on a bottom surface; And a guide groove on which an engagement bar of the upper slide core is seated is formed on an upper surface of the lower slide core, and the lower slide core is linearly moved along a guide surface of the base block while interlocking with the movement direction of the upper slide core. And a control unit.

The upper slide core includes: a main slide core having a bottom surface slidably moved along an inclined surface of the base block; And a connection slide core coupled to a rear side of the main slide core and having a latch bar protruding downward from a bottom surface thereof; And a control unit.

Preferably, the rear bottom surface of the connecting slide core is seated on a projecting surface formed obliquely to the rear upper surface of the lower slide core, and a space And a groove is formed.

Preferably, a flange protruding from the side wall of the guide block of the base block protrudes along both lower sides of the connecting slide core.

The slide core assembly for simultaneous treatment of multi-direction undercut according to the present invention having the above-described structure has a simple structure for connecting the remaining slide cores in the oblique direction in a situation in which the direction of travel is restricted by any slide core, (Having an angle) without simultaneously performing the undercut operation.

1 is a perspective view showing a slide core assembly for simultaneous multi-directional undercut according to the present invention;
2 is a plan view showing a slide core assembly for simultaneous multi-directional undercut according to the present invention;
3 is a perspective view showing a base block and a lower slide core of a slide core assembly for simultaneous multi-direction undercut according to the present invention;
4 is a perspective view showing an upper slide core of a slide core assembly for simultaneous multi-directional undercut according to the present invention;
5 is a perspective view showing the use state of the slide core assembly for simultaneous multi-direction undercut according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present embodiment, the same names are used for the same components, and further description thereof will be omitted.

FIG. 1 is a perspective view showing a slide core assembly for simultaneous multi-direction undercut according to the present invention, FIG. 2 is a plan view showing a slide core assembly for simultaneous multi-direction undercut according to the present invention, and FIG. FIG. 4 is a perspective view showing an upper slide core of a slide core assembly for simultaneous multi-directional undercut according to the present invention. FIG. 4 is a perspective view showing a base block and a lower slide core of a slide core assembly for directional undercutting.

1 to 3, the slide core assembly for simultaneous multi-directional undercutting according to the present invention includes a base block 100, an upper slide core 200, and a lower slide core 300.

The base block 100 guides a moving direction of the slide cores. The base block 100 has a sloped surface 110 formed at an upper portion thereof and a guide surface 120 (see FIG. 1) opened in a stepped manner on a surface bent downward from a portion of the sloped surface, Is formed.

Hereinafter, the direction of the forward and backward directions will be referred to as a "room" and the direction of a leftward direction will be referred to as "a room", with reference to the drawings for convenience of explanation.

For example, as shown in FIG. 1, the base block 100 may include a sloped surface 110 along the upper side and a guide surface 120 at the upper side of the rear surface.

The bottom surface of the upper slide core 200 is brought into close contact with the sloped surface 110 of the base block 100 to slide linearly along the sloped surface 110 Exercise).

The upper slide core 200 is slidably protruded toward the lower side (in the embodiment, the front and rear inner and outer sides) of the latching bar 210 on the bottom surface.

The upper slide core 200 may include a main slide core 220 and a connection slide core 230.

The main slide core 220 slides along the slope 110 of the base block 100 and the connecting slide core 230 is coupled to the rear of the main slide core 210. In this embodiment, And the catch bar 210 protrudes downward from the bottom.

At this time, the coupling type of the main slide core 220 and the coupling slide core 230 can be various forms. For example, as shown in the drawing, the coupling members 221 and 231 formed on both sides of the main slide core 220, Can be inserted and combined.

The lower slide core 300 is formed with a guide groove 310 in which a latch bar 210 of the upper slide core 200 is inserted and seated on a front upper surface thereof, (D2 direction).

The lower slide core 300 is moved along the step guide surface 120 of the base block 100 while interlocking with the moving direction of the upper slide core 200 at an acute angle? The moving direction of the upper slide core 200 is restrained by the guide surface 10 and the moving direction of the upper slide core 200 forms an acute angle?

That is, when the latching bar 210 of the upper slide core 200 contacts and moves in an oblique direction to the side wall of the guide groove 310 and pushes or pulls the lower slide core 300, They can be linked together at different angles (angles) while forming an acute angle?.

In order to smoothly move the connection slide core 230 while keeping the gap between the sidewalls of the guide surface 120 of the base block 100 and the connection slide core 230 along both lower sides of the connection slide core 230, It is preferable that the flange 330 protrudes. The flange 330 contacts the side wall of the guide surface 120.

In order to smoothly interlock the connection slide core 230 and the lower slide core 300, the rear bottom surface of the connection slide core 230 is seated on the protruding surface 340 formed obliquely to the rear upper surface of the lower slide core desirable.

It is preferable that a spacing groove 320 is formed in the rear side of the guide groove 310 of the lower slide core 300 in a space between the connection slide core 230 and the lower slide core 300.

The operation of the slide core assembly for simultaneous processing of the multi-direction undercut according to the present invention having the above-described structure will now be described. The complex product P as shown in FIG. 5 needs to process multi-directional (multi-angle) undercuts at once, First, the upper slider core 200 moves in the oblique direction D1 to process the undercut.

The guide groove 310 of the lower slider core 300 is engaged with the engagement bar 210 of the upper slide core 200 so that the guide of the base block 100 While the moving direction is constrained by the surface 120, another undercut in the oblique direction D2, which forms an acute angle? With the moving direction of the upper slider core 200, is processed.

In the present invention, the relative angles of the upper slider core 200 and the lower slider core 300, that is, the relative positions of the guide grooves 310 and the engaging bars 210 and the contact angles are determined according to the shape Various design changes may be made.

It will be apparent to those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or scope of the invention as defined in the appended claims. It is self-evident to those who have.

Therefore, the above-described embodiments are to be considered as illustrative rather than restrictive, and the present invention is not limited to the above description, but may be modified within the scope of the appended claims and equivalents thereof.

100 ... base block 110 ... sloped surface
120 ... guide surface 200 ... upper slide core
210 ... hanging bar 220 ... main slide core
221 ... fastening groove 230 ... connected slide core
231 ... fastening groove 300 ... lower slide core
310 ... guide groove 320 ... spaced groove
330 ... protruding surface 340 ... flange

Claims (4)

A base block having a top surface formed with an inclined surface and a guide surface opened in a stepwise manner on a surface bent downward from a portion of the inclined surface ending the upward and downward inclination;
An upper slide core in which a bottom surface slides linearly along an inclined surface of the base block and a latching bar protrudes downward on a bottom surface; And
A lower slide core having a guide groove on which an engagement bar of the upper slide core is seated is formed on an upper surface of the lower slide core and is linearly moved along a guide surface of the base block while interlocking with the movement direction of the upper slide core, And a lower end of the slide core assembly. The method according to claim 1,
The upper slide core includes: a main slide core having a bottom surface slidably moved along an inclined surface of the base block; And
A coupling slide core coupled to a rear side of the main slide core and having a locking bar protruding downward from a bottom surface thereof; And a lower end of the slide core assembly. 3. The method of claim 2,
The rear bottom surface of the connecting slide core is seated on a projecting surface formed obliquely to the rear upper surface of the lower slide core and a spaced groove is formed in the rear of the guide groove of the lower slide core Wherein the slide core assembly comprises a plurality of slits. The method according to claim 2 or 3,
And a flange protruding from the side wall of the guide block of the base block protrudes along both lower sides of the connecting slide core.

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