KR101048123B1 - Core pin unit for die casting - Google Patents

Abstract

The present invention is installed in the mold to form a hole in the casting to prevent the bending phenomenon of the core pin body due to the melt action force flowing into the cavity, and at the same time to prevent damage to the cooler due to the flow of the core pin body, To increase the service life and improve the production utilization rate

A die-casting core pin unit installed inside a movable mold composed of a core die and a core holder to form a hole in a casting, wherein the front end is inserted into the core die and the core holder so that the front end of the core die protrudes. A core pin body protruding toward the rear side of the core holder and having a locking end formed along an outer circumferential surface at an outer center thereof; A locking screw mounted to the core holder in a state in which a rear end of the core pin body is inserted; A spring interposed between the core pin body and the locking screw in the core holder; And a cooler mounted at a rear end of the core pin body in a state of being inserted into the core pin body from the rear of the core pin body to cool the core pin body.

Die Casting, Core Pin Unit, Core Pin Body, Spring, Locking Screw, Cooler

Description

Core pin unit for die casting {CORE PIN UNIT FOR DIE CASTING}

The present invention relates to a core pin unit for die casting, and more particularly, to a die casting core pin unit installed in a mold to form a hole in a casting.

In general, die casting is also referred to as die casting, which is a precision casting method in which molten metal is injected into a steel die that is accurately machined to perfectly match the required casting shape. This product is called die cast casting.

This method of die casting has the advantage of hardly needing to be refined since the casting dimensions are accurate, and it has excellent mechanical properties and is capable of mass production. The metals used are zinc, aluminum, tin, copper, etc. It is an alloy, which is cast by pneumatic pressure, hydraulic pressure, hydraulic pressure, etc. using a die cast casting machine, and the product is cast by casting.

The metal mold | die used for said die casting is a metal mold | type, Usually, it is divided into a movable side holder and a fixed side holder, and the said movable side holder is equipped with a mold unit.

That is, the mold unit is provided with a core die on all sides of the movable side holder, a core holder for supporting it is mounted on the rear of the core die, the core holder and the operating rod of the core cylinder mounted on the cylinder base and Connected.

Here, the core die 101 is provided with a plurality of core pin units 100 for forming various holes in the casting.

As shown in FIG. 1, the core pin unit 100 includes a core pin body 110 inserted into the core die 101, a locking screw 111 mounted on the core holder 103, Spring 113 interposed between the core pin body 110 and the locking screw 111 and the cooler 115 is inserted into the core pin body 110 through the locking screw 111 to supply the coolant. It consists of

Since the core pin unit 100 is known in the application number 10-2005-0113236, a more detailed description of the configuration, and the description of the operation will be omitted.

However, the conventional core pin unit as described above absorbs the action force of the molten metal through a spring to prevent the core pin from being bent by the molten metal. There is a problem that the forward and backward movement of the core pin body impacts the assembly of the cooler and the cooler is broken.

In addition, as the cooler is damaged by the forward and backward movement of the core pin body, the coolant leaks, thereby causing a defect in the material, thereby causing a problem in that the operation rate of the production line is lowered.

Therefore, the present invention was invented to solve the problems as described above, the object of the present invention is to install the mold in order to form a hole in the casting to bend the phenomenon of the core pin body by the melt action force flowing into the cavity The present invention provides a die-casting core pin unit that prevents damage to the cooler due to flow of the core pin body, thereby increasing the life of the cooler and improving the production operation rate.

In the die-casting core pin unit according to an embodiment of the present invention for achieving the above object, in the die casting core pin unit is installed in the movable mold consisting of the core die and the core holder to form a hole in the casting,

A core pin body inserted into the core die and the core holder so that a front end portion protrudes toward the front side of the core die, a rear end portion protrudes toward the rear side of the core holder, and a locking end is formed along an outer circumferential surface at an outer center thereof; A locking screw mounted to the core holder in a state in which a rear end of the core pin body is inserted; A spring interposed between the core pin body and the locking screw in the core holder; And a cooler mounted to a rear end of the core pin body in a state of being inserted into the core pin body from the rear of the core pin body to cool the core pin body.

The core fin body may have a cooling groove formed in the longitudinal direction to insert the cooler, and a thread may be formed at a rear end thereof.

The locking screw may have a through hole formed therein so that the core pin body is inserted therein, and a thread is formed on the front outer circumferential surface thereof to be screwed to the core holder.

When the locking screw is mounted to the core holder, a tool groove may be formed at a rear end thereof so as to be mounted through a dedicated tool.

The cooler has a front end screwed to the rear end of the core pin body, the mounting connector has a flow path therein; A cooling water supply nipple integrally mounted at one rear end of the mounting connector and connected to the cooling pump to receive the cooling water; A cooling water supply pipe which is integrally connected to the cooling water supply nipple through the flow path at the front of the mounting connector and is inserted into the core pin body to supply the cooling water to the core pin body; And a cooling water discharge nipple connected integrally with the rear end of the mounting connector to be discharged to the outside through the cooling water supply pipe to discharge the used cooling water to the outside.

According to the die-casting core pin unit according to the present invention as described above, to prevent the bending of the core pin body due to the molten metal flowing into the cavity by installing in the mold to form a hole in the casting, and at the same time the core pin body There is an effect of preventing breakage of the cooler due to flow.

In addition, by preventing the breaker of the cooler to increase the life of the cooler, there is also an effect that the production operation rate is improved by preventing material defects due to cooling water leakage.

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

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory only and are not restrictive of the invention, It should be understood that various equivalents and modifications may be present.

2 is a cross-sectional view of a movable mold to which a die casting core pin unit according to an embodiment of the present invention is applied, and FIG. 3 is an exploded perspective view of a die casting core pin unit according to an embodiment of the present invention.

Referring to the drawings, the die-casting core pin unit 1 according to an exemplary embodiment of the present invention is a movable mold 7 composed of a core die 3 and a core holder 5 to form a hole in a casting. It is installed inside.

The die-casting core pin unit 1 according to the exemplary embodiment of the present invention prevents bending of the core pin body 10 due to the molten metal flowing into the cavity by being installed in a mold to form a hole in a casting. And at the same time, by preventing the breakage of the cooler 40 due to the flow of the core pin body 10, to increase the life of the cooler 40, it is possible to improve the production operation rate.

To this end, the die-casting core pin unit 1 according to the present embodiment, as shown in Figures 2 and 3, the core pin body 10, the locking screw 20, the spring 30, and the cooler ( 40).

The core pin body 10 is inserted into the core die 3 and the core holder 5, the front end protrudes toward the front side of the core die 3, and the rear end protrudes to the rear side of the core holder 5.

Here, the core fin body 10 has a cooling groove 11 is formed in the longitudinal direction so that the cooler 40 is inserted, the locking end 13 is formed along the outer circumferential surface in the outer center.

In addition, a screw thread is formed at the rear end of the core pin body 10 to fasten the cooler 40.

The locking screw 20 is mounted to the core holder 5 with the rear end of the core pin body 10 inserted and penetrated.

Here, the locking screw 20 has a through hole 21 formed therein so that the core pin body 10 is inserted therein, and a thread is formed on the front outer circumferential surface to be screwed to the core holder 5.

When the locking screw 20 is mounted on the core holder 5, a tool groove 23 is formed at a rear end thereof so as to be mounted through the dedicated tool 50.

The locking screw 20 serves to prevent the core pin body 10 from being separated from the core die 3 and the core holder 5.

The spring 30 is interposed between the core pin body 10 and the locking screw 20 inside the core holder 5.

Here, one end of the spring 30 is supported by the locking end 13 of the core pin body 10, the other end is preferably made of a coil spring supported by the locking screw 20.

The spring 30 has a function of absorbing the melt action force to prevent the bending phenomenon of the core pin body 10 due to the action force generated from the melt flows during the casting operation.

In the present embodiment, the cooler 40 is inserted into the rear of the core pin body 10 so as to cool the core pin body 10 and mounted to the rear end of the core pin body 10, the mounting connector ( 41), a cooling water supply nipple (43), a cooling water supply pipe (45), and a cooling port discharge nipple (47).

First, the mounting connector 41 has a flow path 42 formed therein, and its front end is screwed to the core pin body 10 through a screw thread formed at the rear end of the core pin body 10.

The rear end side of the mounting connector 41 is integrally mounted with the cooling water supply nipple 43.

The cooling water supply nipple 43 is connected to a cooling pump not shown to receive the cooling water.

The cooling water supply nipple 43 is connected to the cooling water supply pipe 45 inserted into the cooling groove 13 of the core pin body 10.

The cooling water supply pipe 45 is integrally connected to the cooling water supply nipple 43 through the flow passage 42 in front of the mounting connector 41.

The cooling water supply pipe 45 supplies the cooling water supplied from the cooling water supply nipple 43 into the core pin body 10 to function to cool the core pin body 10 during the casting operation.

The cooling water discharge nipple 47 is integrally mounted to the rear end of the mounting connector 41.

The cooling water discharge nipple 47 is connected to the flow path 42 and is supplied into the core pin body 10 to discharge the used cooling water to the outside.

Hereinafter, the mounting and operation of the die casting core pin unit 1 according to the embodiment of the present invention configured as described above will be described in detail.

Figure 4 is a step-by-step mounting state of the die-casting core pin unit according to an embodiment of the present invention.

First, as shown in (S1) of FIG. 4, the core pin body 10 is inserted to penetrate the core holder 5 and the core die 3 behind the core holder 5 of the movable mold 7.

At this time, the front end portion of the core pin body 10 protrudes forward of the constant interval core die 3, and the rear end protrudes rearward of the constant interval core holder 5.

Then, as shown in (S2) of Figure 4, the spring 30 is inserted from the rear of the core pin body (10).

The spring 30 is inserted along the outside of the core pin 10, one end of which is supported by the locking end 13 of the core pin body 10.

When the insertion of the spring 30 is completed, as shown in (S3) of FIG. 4, the locking screw 20 is inserted into the core holder 5, and as shown in (S4) of FIG. ) To lock the locking screw 20 to the core holder 5.

Here, the dedicated tool 50 has a locking projection 51 is formed at the tip to correspond to the tool groove 23 of the locking screw 20.

The dedicated tool 50 has an insertion hole 53 into which the core pin body 10 is inserted to prevent interference with the core pin body 10 when the locking screw 20 is fastened therein.

That is, the dedicated tool 50 is locked after inserting the catching protrusion 51 into the tool groove 23 of the locking screw 20 in a state in which the rear end of the core pin body 10 is inserted into the insertion hole 53. By rotating the screw 20, the locking screw 20 is fastened to the core holder 5.

When the locking screw 20 is fastened, the cooling water supply pipe 45 of the cooler 40 is inserted into the cooling groove 11 as shown in (S5) of FIG.

Then, by mounting the mounting connector 41 to the rear end of the core pin body 10, the mounting of the core pin unit 1 is completed.

As described above, the die casting core pin unit 1 according to the present embodiment may prevent the bending phenomenon of the core pin body 10 by absorbing the action force of the molten metal introduced during the casting operation through the spring 30.

Meanwhile, when absorbing the action force of the molten metal, the rear length of the core pin body 10 is extended to minimize the flow of the generated core pin body 10 to the cooler 40, and the cooler 40 is disposed at the rear end thereof. By installing, the impact force by the flow of the core pin body 10 is prevented from being directly transmitted to the cooler 40.

That is, by minimizing the impact force transmitted from the core pin body 10 to the cooler 40, it is possible to prevent damage and increase the life of the cooler 40.

Therefore, when applying the die-casting core pin unit according to an embodiment of the present invention configured as described above, the core pin body 10 by the melt action force flowing into the cavity by installing in the mold to form a hole in the casting product The warpage phenomenon can be prevented and damage to the cooler 40 due to the flow of the core pin body 10 can be prevented.

In addition, by preventing the breakage of the cooler 40 to increase the life of the cooler 40, it is possible to improve the production operation rate by preventing material defects due to the coolant leakage occurs when the cooler 40 is damaged.

As mentioned above, although this invention was demonstrated by the limited embodiment and drawing, this invention is not limited by this and is given by the person of ordinary skill in the art to the following, Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

1 is a configuration diagram of a core pin unit for die casting according to the prior art.

2 is a cross-sectional view of a movable mold to which a die-casting core pin unit according to an embodiment of the present invention is applied.

3 is an exploded perspective view of a die casting core pin unit according to an embodiment of the present invention.

Figure 4 is a step-by-step mounting state of the die-casting core pin unit according to an embodiment of the present invention.

Claims (5)

In the die-casting core pin unit installed in the movable mold consisting of the core die and the core holder to form a hole in the casting, A core pin body inserted into the core die and the core holder so that a front end portion protrudes toward the front side of the core die, a rear end portion protrudes toward the rear side of the core holder, and a locking end is formed along an outer circumferential surface at an outer center thereof; A locking screw mounted to the core holder in a state in which a rear end of the core pin body is inserted; A spring interposed between the core pin body and the locking screw in the core holder; And And a cooler mounted to a rear end of the core pin body in a state of being inserted into the core pin body from the rear of the core pin body to cool the core pin body. The locking screw has a through hole formed therein so that the core pin body is inserted, a thread is formed on the front outer peripheral surface is screwed to the core holder, When the locking screw is mounted to the core holder, a die groove core pin unit, characterized in that a tool groove is formed at the rear end to be mounted through a dedicated tool. The method of claim 1, The core pin body Cooling groove is formed in the longitudinal direction therein so that the cooler is inserted, the core pin unit for die casting, characterized in that the screw thread is formed at the rear end. delete delete The method of claim 1, The cooler A mounting connector having a front end screwed to the rear end of the core pin body and having a flow path formed therein; A cooling water supply nipple integrally mounted at one rear end of the mounting connector and connected to the cooling pump to receive the cooling water; A cooling water supply pipe which is integrally connected to the cooling water supply nipple through the flow path at the front of the mounting connector and is inserted into the core pin body to supply the cooling water to the core pin body; And The tie-casting, characterized in that made of the cooling water discharge nipple is integrally mounted to the other end of the rear end of the mounting connector to discharge the used cooling water supplied to the inside of the core pin body through the cooling water supply pipe connected to the flow path. Core pin unit.

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