KR100800118B1 - Cooling apparatus of a mold - Google Patents

Abstract

A cooling apparatus of a mold is provided to facilitate installation of a plurality of cooling apparatuses by changing position of conveying lines of an external hose and connecting the external hose with a supply hose joint and with a discharge hose joint. A cooling apparatus of a mold comprises a supply hose joint(100), a supplied water pipe(200), a discharge hose joint(300), a discharged water pipe(400), a discharged water conveying pipe(500), a supplied water conveying pipe(600), sealing members(700a,700b), and fastening rings(800a,800b). The supply hose joint includes a vertical inlet(110) and supply holes(120). The vertical inlet is connected with an external hose to flow coolant. The supply holes are formed at two ends of the supply hose joint. The supplied water pipe includes a horizontal inlet(210) and a supplied water hole(220) and enters the supply hose of the supply hose joint. The discharged hose joint includes a vertical outlet(310) and discharge holes(320). The vertical inlet is connected with the external hose to discharge coolant. The discharge holes are formed at two ends of the supply hose joint. The discharged water pipe includes horizontal discharge lines at two ends thereof and a discharged water hole, and enters the discharge hole. One end of the discharged water pipe is coupled to the supplied water pipe. The discharged water conveying pipe is connected to the discharged water pipe at one end and communicated with the horizontal discharge lines and configured to discharge coolant circulating in a mold to the outside. The supplied watery conveying pipe is connected to the supplied water pipe, communicated with the horizontal inlet to send coolant to the mold. The sealing members are each inserted into two ends of the supplied water pipe and the discharged water pipe. The fastening rings are inserted to the discharged water pipe and the supplied water pipe, adjacent to the sealing member.

Description

Cooling apparatus of a mold

1 is a state diagram showing a cooling apparatus of a conventional mold;

2 is a perspective view of a cooling apparatus of a mold according to an embodiment of the present invention;

3 is an exploded perspective view of FIG. 2;

4 is a cross-sectional view of FIG. 2.

<Explanation of symbols for the main parts of the drawings>

100: supply hose connector 110: vertical inlet

120: supply hole 200: supply water piping

210: horizontal inflow path 220: supply water through

300: discharge hose connector 310: vertical discharge furnace

320: discharge hole 400: discharge water pipe

410: horizontal discharge path 420: discharge water through

500: discharge water transport pipe 600: supply water transport pipe

700a, 700b: sealing member 800a, 800b: retaining ring

The present invention relates to a cooling device, and more particularly, to a cooling device for a mold to supply the cooling water to the mold and the mold pin to discharge the heated cooling water to the outside.

In general, the die casting and injection mold is a product of the desired shape by cooling the material in a high temperature state after pressing the mold or take a certain time to cool.

In this case, when the heat of the material in the high temperature state is transferred to the mold, the life of the finished product is reduced due to deformation of the mold, and bubbles of the finished product are generated.

A cooling device for supplying the cooling water to the cooling path of the mold and discharging the cooling water in a heated state circulated through the cooling path to the outside is provided.

Such a cooling apparatus for supplying and discharging the cooling water to the cooling furnace of the mold is disclosed in Korean Patent Laid-Open Publication No. 1998-016125, Korean Patent Registration No. 0422678, and Korean Patent Publication No. 2000-0056091.

However, the conventional cooling device 10 for cooling the mold (1) is connected to the external supply hose (2) as shown in Figure 1 for the cooling of the supply pipe 20 and the mold 1 to which the coolant is supplied. The discharge pipe 30 is connected to the discharge hose (3) for discharging the cooling water circulated through the cooling furnace (4) to the outside is fastened to each other according to the position of the external supply hose (2) and the discharge hose (3) This is not an easy problem.

That is, when the external supply hose (2) or the discharge hose (3) is coupled to the supply pipe 20 and the discharge pipe 30 in a state not located on the same straight line with each other, the supply hose (a) 2) or the discharge hose 3 is in a bent state, there is a problem that the cooling water leaks while the damage caused by the concentration of stress occurs at the connection end with the supply pipe 20 and the discharge pipe (30).

In addition, when a plurality of cooling devices 10 are installed in the mold 1, the supply pipe 20 and the discharge pipe 30 are located in one direction, so that the supply hose 2 and the discharge hose 3 also move in one direction. As the location is formed, there is a problem in that the installation is not easy when the cooling furnace 4 is narrow.

The present invention was created to solve the above problems, even if the position of the supply hose for supplying the cooling water from the outside and the discharge hose for discharging the cooling water circulated in the mold is changed, the bending is not generated when combined with the supply pipe and the discharge pipe, respectively. Therefore, the object of the present invention is to provide a cooling device for a mold capable of preventing damage due to bending at the connecting end and facilitating installation in the mold.

Other objects and advantages of the invention will be described below and will be appreciated by the embodiments of the invention. Furthermore, the objects and advantages of the present invention can be realized by means and combinations indicated in the claims.

Cooling apparatus of the mold of the present invention for achieving the above object, is connected to the external hose therein to form a vertical inflow path in which the coolant is introduced, the opposite side portion of the supply hole in communication with the vertical inflow path A feed hose connector; A supply water pipe having a horizontal inflow path opened to one side and inserted into the supply hole of the supply hose connector in a state of forming a supply water through hole communicating with the horizontal inflow path; A discharge hose connector having a discharge hole connected to an external hose inside to discharge the cooling water circulated inside the mold to the outside, and having opposite discharge portions communicating with the vertical discharge path; A discharge water pipe having a horizontal discharge path opened to both sides facing each other, inserted into a discharge hole of the discharge hose connector in a state of forming a discharge water through hole communicating with the horizontal discharge path, and having one end coupled to the supply water pipe; ; A discharge water transport pipe having one end coupled to the discharge water pipe so as to be in communication with the horizontal discharge path so that the cooling water circulated in the mold is transferred to the outside; A feed water feed pipe having one end coupled to the feed water pipe in an interpolated state in the discharge water feed pipe, the feed water transport pipe communicating with the horizontal inflow path to transfer the coolant flowing from the outside into a mold; And a sealing member which is extrapolated to both ends of the supply water pipe and the discharge water pipe so that the cooling water does not leak while the supply water pipe and the discharge water pipe are inserted into the supply hose connector and the discharge hose connector, respectively. do.

Here, one end of the discharge water pipe and the supply water pipe is preferably provided with an extrapolation of the fixing ring adjacent to the sealing member.

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

Prior to this, terms or words used in the specification and claims should not be construed as having a conventional or dictionary meaning, and the inventors should properly explain the concept of terms in order to best explain their own invention. It should be interpreted as meanings and concepts corresponding to the technical idea of the present invention based on the principle of definition.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

Figure 2 is a perspective view of a cooling apparatus of a mold according to an embodiment of the present invention, Figure 3 is an exploded perspective view of Figure 2, Figure 4 is a cross-sectional view of FIG.

As shown, the cooling apparatus of the mold according to the present invention, the supply hose connector 100, supply water pipe 200, discharge hose connector 300, discharge water pipe 400, discharge water transport pipe 500, supply water The pipe 600 and the sealing members 700a and 700b are provided.

The supply hose connector 100 is a member whose one end is connected to an external hose to allow the coolant to flow from the outside.

The inside of the supply hose connector 100 is connected to the external hose to form a vertical inlet path 110 to allow the cooling water to flow.

In addition, the supply hose connector 100 preferably has a supply hole 120 that is open to both sides facing each other.

Here, the vertical inflow path 110 and the supply hole 120 is preferably in communication.

Therefore, the cooling water introduced into the vertical inlet path 110 of the supply hose connector 100 can be transferred to the supply hole 120.

The supply water pipe 200 is a pipe member inserted into the supply hole 120 of the supply hose connector 100.

The supply water pipe 200 has a horizontal inflow path 210 opened to one side, and forms at least one supply water through hole 220 in communication with the horizontal inflow path 210.

And, both ends of the supply water pipe 200 is preferably provided with a sealing member (700a) in an extrapolated state, respectively.

The sealing member 700a is sealed at both ends in such a state as to have an inner space between the inner circumferential surface of the supply hose connector 100 and the outer circumferential surface of the supply water pipe 200 so that the cooling water does not leak through both ends. do.

Here, it is preferable that the sealing member 700a uses a rubber resin or a flexible synthetic resin.

Therefore, the cooling water flowing into the vertical inlet path 110 of the supply hose connector 100 is sealed by the sealing member 700a being sealed between the supply hose connector 100 and the supply water pipe 200. Through the feed water through hole 220 of the water pipe 200 is transferred to the horizontal inlet path (210).

In addition, one end of the supply water pipe 200 may be extrapolated with a fixing ring 800a adjacent to the sealing member 700a.

The fixing ring 800a supports the supply hose connector 100 in an extrapolated state to the supply water pipe 200, and thus an inner circumferential surface of the supply hose connector 100 and an outer circumferential surface of the supply water pipe 200. The internal space formed between them is always kept in a constant space.

As such, the supply hose connector 100 is rotatable in an extrapolated state to the supply water pipe 200, so that the position of the external hose connected to the supply hose connector 100 is changed even if the supply hose connector 100 is changed. The position can be changed by rotating) so that the external hose for supplying the coolant can be connected without bending.

The discharge hose connector 300 is a member that is connected to the external hose one end to discharge the cooling water circulated in the mold to the outside.

Such, the discharge hose connector 300 is connected to the external hose to form a vertical discharge path 310 to discharge the cooling water.

In addition, it is preferable that the discharge hose connector 300 has a discharge hole 320 open to both sides facing each other.

Here, the vertical discharge path 310 and the discharge hole 320 is preferably in communication.

Therefore, the cooling water circulated in the mold introduced into the discharge hole 320 of the discharge hose connector 300 can be transferred to the vertical discharge path 310.

The discharge water pipe 400 is a pipe member having one end coupled to the supply water pipe 200 while being inserted into the discharge hole 320 of the discharge hose connector 300.

Here, the discharge water pipe 400 and the supply water pipe 200 can be attached and detached by mutual thread coupling.

In addition, the discharge water pipe 400 has a horizontal discharge path 410 opened to both sides facing each other, it is preferable to form at least one discharge water through hole 420 in communication with the horizontal discharge path (410).

And, both ends of the discharge water pipe 400 is preferably provided with a sealing member 700b in an extrapolated state similarly to the supply water pipe 200 described above.

The sealing member 700b seals both ends in a state of having an inner space between the inner circumferential surface of the discharge hose connector 300 and the outer circumferential surface of the discharge water pipe 400 so that the cooling water does not leak through both ends. .

Here, it is preferable that the sealing member 700b uses a rubber resin or a flexible synthetic resin.

That is, the cooling water circulated inside the mold introduced into the horizontal discharge path 410 of the discharge water pipe 400 by sealing between the discharge hose connector 300 and the discharge water pipe 400 by the sealing member 700b. Is transferred to the vertical discharge path 310 of the discharge hose connector 300 through the discharge water through hole 420 of the discharge water pipe 400.

In addition, one end of the discharge water pipe 400 may be extrapolated to the fixing ring 800b adjacent to the sealing member 700b.

The fixing ring 800b supports the discharge hose connector 300 in a state of being extrapolated to the discharge water pipe 400, between the inner circumferential surface of the discharge hose connector 300 and the outer circumferential surface of the discharge water pipe 400. The internal space to be formed is always kept in a constant space.

As such, the discharge hose connector 300 is rotatable in an extrapolated state to the discharge water pipe 400 so that the discharge hose connector 300 is changed even though the position of the external hose connected to the discharge hose connector 300 is changed. It is possible to change the position by rotating so that no bending occurs when connecting with an external hose that discharges the coolant circulating in the mold.

The discharge water transfer pipe 500 is a pipeline to allow the cooling water circulated in the mold to be transferred to the outside.

The discharge water transport pipe 500 is connected to the horizontal discharge path 410 in a state in which one end is coupled to the discharge water pipe 400, and the other end is a space portion (not shown) into which cooling water is introduced into the mold. It is located at.

Therefore, the discharge water transfer pipe 500 allows the cooling water introduced into the mold to be transferred to the discharge hose connector 300 through the discharge water pipe 400 to be discharged to the outside.

The feed water transfer pipe 600 is a pipeline to allow the coolant flowing from the outside to be transferred to the space inside the mold.

This, the feed water feed pipe 600 is coupled to the feed water pipe 200 so that one end is in communication with the horizontal inlet passage 210 of the discharge water feed pipe 500 in the state inserted into the discharge water transport pipe 500, The other end is located in the space inside the mold.

Therefore, the feed water feed pipe 600 is supplied to the cooling water introduced into the supply hole 120 of the feed water pipe 200 through the supply hose connector 100 is injected into the space inside the mold.

Thus, the operation of the cooling apparatus of the mold according to an embodiment of the present invention is described with reference to Figures 2 to 4 as follows.

First, the coolant transferred through the external hose is transferred to the supply hole 120 through the vertical inflow path 110 of the supply hose connector 100.

Then, the coolant enters the inner space between the supply hose connector 100 and the supply water pipe 200, and the coolant is again supplied through the supply water through hole 220 of the supply water pipe 200. It is transferred to the furnace 210, and is injected into the space portion of the mold through the feed water feed pipe 600 to cool the mold.

The cooling water that cools the mold by circulating the space formed in the mold is transferred back to the discharge water pipe 400 through the discharge water transport pipe 500, and through the discharge water through hole 420 of the discharge water pipe 400. It is filled while being transported to the internal space between the discharge water pipe 400 and the discharge hose connector 300.

Thereafter, the coolant circulated through the mold while being transferred to the external hose through the vertical discharge path 310 of the discharge hose connector 300 is discharged to the outside.

As such, in the cooling apparatus of the mold according to the present invention, the supply hose connector 100 and the discharge hose connector 300 connected to an external hose are extrapolated to the supply water pipe 200 and the discharge water pipe 400, respectively. Both ends are sealed by the sealing members 700a and 700b in a closed state, and the supply hose connector 100 and the discharge hose connector 300 are rotatable in an extrapolated state, so that the supply hose is changed when the position of the external hose is changed. It is also possible to change the position of the connector 100 and the discharge hose connector 300 is to prevent the bending of the external hose can be prevented leakage of the coolant due to the damage of the hose.

In addition, the position of the supply hose connector 100 and the discharge hose connector 300 is easy to change the position of the transfer line of the external hose can be adjusted to facilitate the installation even when a plurality of the cooling device is provided. Will be.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto and is described by the person of ordinary skill in the art to which the present invention pertains. Various modifications and variations are possible without departing from the scope of the appended claims.

As described above, in the mold cooling apparatus of the present invention, the supply hose connector and the discharge hose connector are extrapolated in a rotatable state to the supply water pipe and the discharge water pipe so that the position of the supply hose connector and the discharge hose connector is changed according to the position of the external hose. It is possible to prevent the damage of the hose by preventing the bending of the external hose, and can be coupled to the supply hose connector and the discharge hose connector in a different position of the transfer line of the external hose, it is easy to install a plurality of cooling devices To provide the effect.

Claims (2)

A supply hose connector having a supply hole connected to an external hose therein to form a vertical inflow path through which the coolant flows, and having opposite sides facing the vertical inflow path; A supply water pipe having a horizontal inflow path opened to one side and inserted into the supply hole of the supply hose connector in a state of forming a supply water through hole communicating with the horizontal inflow path; A discharge hose connector having a discharge hole connected to an external hose inside to discharge the cooling water circulated inside the mold to the outside, and having opposite discharge portions communicating with the vertical discharge path; A discharge water pipe having a horizontal discharge path opened to both sides facing each other, inserted into a discharge hole of the discharge hose connector in a state of forming a discharge water through hole communicating with the horizontal discharge path, and having one end coupled to the supply water pipe; ; A discharge water transport pipe having one end coupled to the discharge water pipe so as to be in communication with the horizontal discharge path so that the cooling water circulated in the mold is transferred to the outside; A feed water feed pipe having one end coupled to the feed water pipe in an interpolated state in the discharge water feed pipe, the feed water feed pipe communicating with the horizontal inflow path to transfer the coolant flowing from the outside into the mold; A sealing member which is extrapolated to both ends of the supply water pipe and the discharge water pipe so as to prevent the coolant from leaking while the supply water pipe and the discharge water pipe are inserted into the supply hose connector and the discharge hose connector, respectively; And, One end portion of the discharge water pipe and the supply water pipe comprises a fixing ring which is extrapolated to be adjacent to the sealing member. delete

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