KR20240051458A - Improved cooling performance of core fins for die-casting molds Dissimilar material cooling device and manufacturing method thereof - Google Patents

Abstract

The present invention has a pipe structure that is open on one side, one side is connected to a discharge line that discharges coolant, the other side is a discharge pipe inserted into the mold, and has a pipe structure that is open on both sides, and one side supplies coolant. It is connected to a supply line, and the other side includes a supply pipe portion inserted and disposed inside the discharge pipe portion, and a spiral discharge guide groove is formed on the inner peripheral surface of the discharge pipe portion in one direction from the other side of the discharge pipe portion, and the supply pipe portion Provided is a dissimilar material cooling device for improving cooling performance of a core pin for a die casting mold in which a spiral discharge guide protrusion is formed from one side of the supply pipe to the other side on the outer peripheral surface of a dissimilar material cooling device and a manufacturing method therefor.

Description

Improved cooling performance of core fins for die-casting molds Dissimilar material cooling device and manufacturing method thereof}

The present invention relates to a dissimilar material cooling device for improving core pin cooling performance for a die casting mold that cools the mold by supplying coolant to the inside of the die casting mold and then discharging the heated coolant to the outside and a method of manufacturing the same.

In general, die casting and injection molding produce a product with the desired shape by putting high-temperature materials into the mold and then pressing them or cooling them over a certain period of time.

At this time, when the heat of the high-temperature material is transferred to the mold, the mold is deformed, shortening its lifespan, and bubbles are generated in the finished product, forming a cooling path through which the coolant passes inside the mold.

In addition to supplying coolant to the cooling path of the mold, a cooling device is provided to discharge the heated coolant that has circulated through the cooling path back to the outside. Alternatively, the mold may be cooled while the cooling device is inserted and installed inside the mold and the coolant circulates through the cooling device.

However, in the conventional mold cooling device, when the coolant is transported inside the mold through the supply pipe and then circulated through the discharge pipe, the coolant is not discharged stably and consistently through the discharge pipe, thereby reducing the cooling efficiency of the mold. There is a problem with this. In addition, because the coolant is not discharged in an evenly distributed state depending on the pressure or flow rate inside the discharge pipe, there is a problem that the cooling location is biased when cooling the mold through the discharge pipe.

Such related technology for mold cooling devices is presented in Republic of Korea Patent No. 0800118 (January 25, 2008) and Republic of Korea Patent Publication No. 2008-0101974 (November 24, 2008).

Republic of Korea Patent No. 0800118 (2008.01.25), Republic of Korea Patent Publication No. 2008-0101974 (2008.11.24)

The present invention provides a dissimilar material cooling device for improving the cooling performance of core pins for die casting molds and a manufacturing method thereof that ensures stable cooling of the mold while allowing the coolant to be evenly distributed and contacted with the cooling pipes when the coolant is circulated through the cooling pipes. The purpose is to do this.

The present invention has a pipe structure that is open on one side, one side is connected to a discharge line that discharges coolant, the other side is a discharge pipe inserted into the mold, and has a pipe structure that is open on both sides, and one side supplies coolant. It is connected to a supply line, and the other side includes a supply pipe portion inserted and disposed inside the discharge pipe portion, and a spiral discharge guide groove is formed on the inner peripheral surface of the discharge pipe portion in one direction from the other side of the discharge pipe portion, and the supply pipe portion A dissimilar material cooling device for improving cooling performance of a core pin for a die casting mold is provided, which includes a spiral discharge guide protrusion on the outer peripheral surface from one side of the supply pipe to the other side.

In addition, one side of the discharge pipe may be provided with a connection body in which a discharge passage connected to the discharge line and a supply passage connected to the supply line are formed.

Additionally, the discharge guide protrusion may have a circular or square cross-section.

The present invention has a pipe structure that is open on one side, one side is connected to a discharge line that discharges coolant, and the other side has a discharge pipe portion inserted into the mold and a pipe structure that is open on both sides, and one side supplies coolant. In the method of manufacturing a dissimilar material cooling device for improving cooling performance of a core pin for a die casting mold including a supply pipe portion connected to a supply line and the other side inserted into the discharge pipe portion, one side of the supply pipe portion is placed on the outer peripheral surface when processing the supply pipe portion. A method of manufacturing a dissimilar material cooling device for improving cooling performance of a core pin for a die casting mold is provided, which includes manufacturing a spiral discharge guide protrusion integrally with the supply pipe portion in the other direction.

The dissimilar material cooling device for improving the cooling performance of core pins for die casting molds according to the present invention has a spiral discharge guide groove formed on the inner peripheral surface of the discharge pipe portion inserted into the mold, and is supplied to the inside of the discharge pipe portion through the supply pipe portion. In addition to increasing the area in contact with the inner surface of the discharge pipe, the moving coolant flows in a turbulent form and evenly contacts the inner surface of the discharge pipe, thereby improving the cooling efficiency of the core pin of the mold through the discharge pipe.

Figure 1 is a cross-sectional view of the configuration of a dissimilar material cooling device for improving cooling performance of core pins for die casting molds according to an embodiment of the present invention.
Figure 2 is an enlarged view of an embodiment of a dissimilar material cooling device for improving cooling performance of a core pin for a mold according to an embodiment of the present invention and a discharge guide protrusion.

The detailed description of the present invention described below refers to the accompanying drawings, which show by way of example specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention.

It should be understood that the various embodiments of the invention are different from one another but are not necessarily mutually exclusive. For example, specific shapes, structures and characteristics described herein with respect to one embodiment may be implemented in other embodiments without departing from the spirit and scope of the invention.

Additionally, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the invention. Accordingly, the detailed description that follows is not intended to be taken in a limiting sense, and the scope of the invention is limited only by the appended claims, together with all equivalents to what those claims assert, if properly described. Similar reference numbers in the drawings refer to identical or similar functions across various aspects.

Hereinafter, in order to enable those skilled in the art to easily practice the present invention, preferred embodiments of the present invention will be described in detail with reference to the attached drawings.

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

Figure 1 is a cross-sectional view of a dissimilar material cooling device for improving core pin cooling performance for a die casting mold according to an embodiment of the present invention. Referring to FIG. 1, a dissimilar material cooling device for improving core pin cooling performance for a die casting mold according to an embodiment includes an discharge pipe portion 100 and a supply pipe portion 200.

The discharge pipe portion 100 is a pipe member that guides the cooling water supplied from the supply pipe portion 200, which will be described later, to be discharged back to the outside. That is, the discharge pipe unit 100 delivers the cold air of the coolant supplied from the supply pipe unit 200 to the core pins of the mold in order to cool the core pins (not shown) of the mold, and then discharges the coolant to the outside. Here, the discharge pipe portion 100 is preferably made of beryllium copper, but is not limited to this, and can of course be made of a material with excellent thermal conductivity, strength, corrosion resistance, and heat resistance.

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

Figure 1 is a cross-sectional view of a dissimilar material cooling device for improving core pin cooling performance for a die casting mold according to an embodiment of the present invention. Referring to FIG. 1, a dissimilar material cooling device for improving core pin cooling performance for a die casting mold according to an embodiment includes an discharge pipe portion 100 and a supply pipe portion 200.

The discharge pipe portion 100 is a pipe member that guides the cooling water supplied from the supply pipe portion 200, which will be described later, to be discharged back to the outside. That is, the discharge pipe unit 100 delivers the cold air of the coolant supplied from the supply pipe unit 200 to the core pins of the mold in order to cool the core pins (not shown) of the mold, and then discharges the coolant to the outside. Here, the discharge pipe portion 100 is preferably made of beryllium copper, but is not limited to this, and can of course be made of a material with excellent thermal conductivity, strength, corrosion resistance, and heat resistance.

One side of the discharge pipe portion 100 is open, and the other side of the discharge pipe portion 100 has a closed pipe structure. At this time, the discharge pipe part 100 is arranged to be inserted into the mold. More specifically, the other side of the discharge pipe part 100 is arranged to be inserted into the mold, and one side of the discharge pipe part 100 discharges the coolant to the outside of the mold. It is connected to the discharge line (not shown).

In addition, a spiral discharge guide groove 110 may be formed on the inner peripheral surface of the discharge pipe portion 100 extending from one side of the discharge pipe portion 100 to the other side. At this time, the discharge guide groove 110 is preferably formed to extend as long as the length of the discharge pipe portion 100 inserted into the inside of the mold, but of course, it is not limited thereto.

The discharge guide groove 110 increases the area in which the coolant, which is moved after being supplied to the inside of the discharge pipe 100 through the supply pipe 200, comes into contact with the inner surface of the discharge pipe 100 and is discharged. It is moved while evenly contacting the inner surface of the pipe 100. More specifically, the discharge guide groove 110 allows the coolant, which is discharged from the supply pipe part 200 to the inside of the discharge pipe part 100 and then moves from the other side of the discharge pipe part 100 to one direction, to flow in a turbulent form, By allowing the coolant to evenly contact the inner surface of the discharge pipe portion 100, the cooling efficiency of the core pins of the mold through the discharge pipe portion 100 disposed in the mold is improved. Here, the discharge guide groove 110 is formed to have a 'V' shaped cross section so that the width becomes narrower toward the inside of the discharge pipe portion 100, but is not limited to this and may be formed to have a 'U' shaped cross section or a semicircular cross section. Of course it is possible.

In addition, an auxiliary guide groove (not shown) may be additionally formed along the discharge guide groove 110 on the inner surface of the discharge pipe portion 100 where the discharge guide groove 110 is formed. These auxiliary guide grooves further increase the formation of turbulence in the coolant moving through the discharge guide groove 110 and provide the effect of increasing the contact area between the coolant and the discharge pipe portion 100.

In addition, a connection body 130 connected to the discharge line and the supply line may be provided on one side of the discharge pipe portion 100. Inside the connection body 130, there is a discharge passage (not shown) connecting the discharge line and the discharge pipe portion 100, and a supply passage (not shown) connecting the supply line and the supply pipe portion 200. can be formed. In addition, a screw groove (not shown) may be formed on the inside of the connection body 120 to allow one side of the supply pipe part 200 to be joined by a screw part.

At this time, the discharge pipe portion 100 may be divided into a plurality of unit pipe members 110a and 110b, and ends of the plurality of unit pipe members 110a and 110b that are in contact with each other may be coupled through screw coupling. , the parts joined through screw coupling may be provided with a sealing member to prevent leakage of coolant. That is, the plurality of unit pipe members have a pipe structure in which one side is open and the other side is closed, and the inner edge unit pipe member 110a has a discharge guide groove 110 formed in the direction from one side to the other side, and both sides are open. It may be composed of at least one connection unit pipe member (110b) sequentially connected to one side of the edge unit pipe member (110a) in the state. In this way, when the discharge pipe portion 100 is divided into a plurality of unit pipe members, the discharge guide groove 110 can be easily processed inside the discharge pipe portion 100, and foreign matter inside the discharge pipe portion 100 can be easily processed. If removal or replacement of the discharge pipe portion 100 is necessary, only the replacement part can be exchanged and used, thereby reducing maintenance costs.

The supply pipe part 200 is a pipe member that receives coolant through an external supply line and guides it to be discharged to the inside of the discharge pipe part 100. That is, the supply pipe unit 200 supplies cooling water to the discharge pipe unit 100 to cool the core pins (not shown) of the mold. Here, the supply pipe portion 200 is preferably made of beryllium copper, the same as the discharge pipe portion 100 described above, but is not limited to this and can be formed of a material with excellent thermal conductivity, strength, corrosion resistance, and heat resistance. Of course.

The supply pipe portion 200 has a pipe structure with both longitudinal sides open, and one longitudinal side of the supply pipe portion 200 is connected to a supply line for supplying cooling water, more specifically, a supply passage of the connection body 130. It is coupled and disposed on the inside of the connection body to be connected. And, the other longitudinal side of the supply pipe portion 200 is arranged to be inserted into the inside of the discharge pipe portion 100.

Here, a fastening end (not shown) having a threaded portion may be formed on one longitudinal outer peripheral surface of the supply pipe portion 200 to be screwed into the threaded groove of the connecting body 130.

In addition, a spiral discharge guide protrusion (not shown) may be formed to extend from the other edge of the longitudinal outer surface of the supply pipe portion 200 to one side of the longitudinal outer surface. These discharge guide protrusions, like the discharge guide groove 110 of the discharge pipe 100 described above, are supplied to the inside of the discharge pipe 100 through the supply pipe 200 and then connected to the discharge pipe 100 and the supply pipe 200. ) The coolant flowing through the space flows in a turbulent form, allowing the coolant to evenly contact the inner surface of the discharge pipe part 100, thereby improving the cooling efficiency of the core pin of the mold through the discharge pipe part 100 disposed in the mold. Let it happen.

In this way, the dissimilar material cooling device for improving core pin cooling performance for a die casting mold according to an embodiment has a spiral discharge guide groove 110 formed on the inner peripheral surface of the discharge pipe portion 100 inserted into the mold, and the supply pipe portion ( The coolant that moves after being supplied to the inside of the discharge pipe 100 through 200 increases the area in contact with the inner surface of the discharge pipe 100 and flows in a turbulent form on the inner surface of the discharge pipe 100. Due to even contact, the cooling efficiency of the core pin of the mold through the discharge pipe portion 100 is improved.

As shown in FIG. 2, the present invention includes a spiral discharge guide protrusion 120 on the outer peripheral surface of the supply pipe portion 200 from one side of the supply pipe portion to the other side.

The discharge guide protrusion 120 may have a circular or square cross section.

The discharge guide protrusion 120 expands the contact area with the coolant inside the cooling device and is effective in uniform cooling by forming a uniform vortex. Experimental results show that when the cross section is circular or square, it is effective in more uniform cooling performance. am.

Meanwhile, the spiral-shaped discharge guide protrusion 120 can be manufactured separately and inserted into the supply pipe part 200, and can also be manufactured by cutting it integrally with the supply pipe part 200. It is more effective in demonstrating cooling performance to manufacture the discharge guide protrusion 120 by cutting it integrally with the supply pipe portion 200.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true scope of technical protection of the present invention should be determined by the technical spirit of the attached claims.

100: Discharge pipe
110: Discharge guide groove
120: Discharge guide projection
130: Connection body
200: Supply pipe department

Claims (4)

A discharge pipe portion having a pipe structure with one side open, one side connected to a discharge line discharging coolant, and the other side inserted into the mold;
It has a pipe structure with both sides open, one side is connected to a supply line that supplies cooling water, and the other side is a supply pipe portion inserted and disposed inside the discharge pipe portion;
A spiral discharge guide groove is formed on the inner peripheral surface of the discharge pipe portion extending from the other side of the discharge pipe portion to one side,
A dissimilar material cooling device that improves cooling performance of core pins for die casting molds in which a spiral discharge guide protrusion is formed on the outer peripheral surface of the supply pipe from one side of the supply pipe to the other side.
In claim 1,
A dissimilar material cooling device for improving cooling performance of a core pin for a die casting mold, including a connection body having a discharge passage connected to the discharge line and a supply passage connected to the supply line on one side of the discharge pipe.
In claim 1,
The discharging guide protrusion is a dissimilar material cooling device for improving cooling performance of core pins for die casting molds, characterized in that the cross-section is circular or square.
It has a pipe structure that is open on one side, one side is connected to a discharge line that discharges coolant, and the other side is a discharge pipe inserted and placed inside the mold; and a pipe structure that is open on both sides, and one side is a supply line that supplies coolant. In the method of manufacturing a dissimilar material cooling device for improving cooling performance of core pins for die casting molds, including a supply pipe portion connected to and the other side inserted and disposed inside the discharge pipe portion,
A method of manufacturing a dissimilar material cooling device for improving cooling performance of a core pin for a die casting mold, including manufacturing a spiral discharge guide protrusion integrally with the supply pipe portion from one side of the supply pipe portion to the other side on the outer peripheral surface of the supply pipe portion when processing the supply pipe portion.