KR101499438B1 - Apparatus for cooling of die-casting mold - Google Patents

Abstract

The present invention relates to a cooling apparatus for a die casting mold, in particular, when a molten metal penetrates into a cooling apparatus through a crack generated in the mold, the molten metal is prevented from moving to the outside of the cooling apparatus by blocking the movement of the molten metal. Which not only shortens the maintenance cost of the die and the working time, but also provides the safety of the operator.

Die casting mold, cooler head, water pipe, water valve, drain valve

Description

[0001] Apparatus for cooling die-casting mold [0001]

The present invention relates to a die casting die cooling apparatus, and more particularly, to a die casting die cooling apparatus capable of blocking the movement of molten metal when a molten metal penetrates into a cooling apparatus through a crack generated in the die.

Generally, a die casting mold circulates cooling water with a pipe inserted and disposed inside a mold to cool the mold. The cooling method of die casting mold is classified into line type cooling method and spot type cooling method.

The Line type cooling system is installed in a part where the molding space of the mold to be molded is gentle so as to perform overall cooling. In the spot type cooling system, the shape of the molding space of the mold is narrow and cooling of the product in the deep part is essential .

In the spot type cooling method, since the shape of the molding space of the mold is narrow and deep, the thickness of the mold from the hole through which the pipe is fitted to the molding space is thin, so that the mold can not overcome the casting pressure, May occur.

When cracks are generated in the mold as described above, the molten metal infiltrates into the inside of the pipe from the molding space through cracks. The molten metal permeating into the inside of the pipe is pressurized at a higher pressure than the cooling water supplied to the inside of the pipe So that the cooling water that is supplied is pushed out and scattered to the outside of the cooling apparatus.

As described above, if the molten metal is scattered, the mold parts including the cooling device are damaged, and the molten molten metal must be melted to remove the molten molten metal after the molten metal is solidified. There has been a problem in the safety of the operator by the above.

The present invention prevents the molten metal from being scattered to the outside of the cooling device by blocking the movement of the molten metal when the molten metal penetrates into the cooling device through the cracks generated in the mold, thereby shortening the maintenance and working time of the mold due to the repair of the mold The present invention also provides a cooling apparatus for a die casting mold capable of ensuring the safety of an operator.

According to an aspect of the present invention, there is provided a cooling device comprising: a cooler head having a water passage and a water passage communicated with a water drain passage disposed inside a mold for cooling a metal mold; Wherein the water supply pipe is provided at one end of the water supply pipe and supplies the cooling water to the water supply pipe when the pressure of the cooling water supplied is larger than the pressure inside the water supply pipe, A water supply valve disposed at the other end of the water supply pipe and connected to the water supply passage and the water discharge passage, and when the pressure of the cooling water discharged from the water discharge passage is less than a predetermined pressure, And a drain valve for supplying the cooling water and blocking the discharge of the cooling water discharged from the drainage passage when it is large It provides a cooling device of the casting mold.

The cooling device of the die casting mold according to the present invention prevents the molten metal from splashing to the outside of the cooling device by blocking the movement of the molten metal when the molten metal penetrates into the cooling device through cracks generated in the metal mold Therefore, it is possible not only to shorten the repairing cost and the working time of the mold due to the repair of the mold, but also to ensure the safety of the operator.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0028] Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view illustrating a cooling apparatus of a die casting mold according to an embodiment of the present invention.

1, a cooling apparatus for a die-casting mold according to the present invention includes an outer pipe 20 disposed inside a mold 10, and an outer pipe 20 inserted into an inner space of the outer pipe 20, A water supply passage 35 to which the water supply passage 35 is connected and a drainage passage 25 through which the cooling water is discharged and a passage 45 connected to the water supply passage 35 and the drainage passage 25, And a head (40).

A water supply port connector 50 and a drain port connector 60 are inserted into one side of the cooler head 40. The water supply port connector 50 and the drain port connector 60 are respectively connected to a hose The cooling water supplied to the cooler head 40 is supplied to the cooler head 40 via the water inlet connector 50 and the coolant head 40 is cooled by moving the water supply passage 35 and then moved to the drain passage 25 And then moved to the cooler head 40 and then discharged to the outside of the mold through the drain connector 60.

The moving passage 45 of the cooler head 40 is formed by closing one end in the longitudinal direction of the cooler head 40 and opening the other end and communicating with the water supply port connector 50 and the drain port connector 60 on one side .

The outer pipe 20 and the inner pipe 30 are inserted into the movement passage 45 formed by opening the other end of the cooler head 40. [

A water supply pipe 70 for receiving cooling water from the water supply port connector 50 is disposed in the moving passage 45 of the cooler head 40 so as to be spaced apart from the outer pipe 20 and the inner pipe 30.

If the pressure of the cooling water supplied from the water supply port connector 50 is larger than the pressure inside the water supply pipe 70, cooling water is supplied to the water supply pipe 70, If the pressure is lower than the pressure, the water supply valve 80 is connected to shut off the reverse flow of the cooling water from the water supply pipe 70.

When cracks are generated in the mold 10 and the molten metal penetrates the water supply passage 35 and the drain passage 25, the internal pressure of the water supply pipe 70 increases due to the infiltration pressure of the molten metal. The pressure of the cooling water supplied from the water supply port connector 50 to the moving passage 45 of the cooler head 40 becomes smaller than the pressure inside the water supply pipe 70. At this time, the water supply valve 80 blocks the reverse flow of the cooling water, thereby blocking the flow of the molten metal.

The water supply valve 80 may be a check valve, which is a valve that controls the cooling water to flow only in one direction and blocks the reverse flow of the cooling water, or a solenoid valve that is a valve that can flow or shut off the cooling water by using electromagnetic. However, in the present embodiment, the water supply valve 80 is disposed not to be the check valve or the solenoid valve but to be movable in the water supply valve movement space 42 formed inside the cooler head 40, 42, the cooling water can be supplied to or blocked from the water supply pipe 70.

The water supply valve 80 is disposed so as to be movable by a distance f in the water supply valve movement space 42, as shown in Fig. 4 (a).

The other end of the water supply pipe 70 is connected to the water supply passage 35 and the water discharge passage 25. When the pressure of the cooling water discharged from the water discharge passage 25 is smaller than the set pressure, And a drain valve 90 for shutting off the discharge of the cooling water discharged from the drain passage 25 is connected if the pressure of the cooling water discharged from the drain passage 25 is larger than the set pressure.

When a crack is generated in the mold 10 and the molten metal penetrates the water supply passage 35 and the drainage passage 25, the internal pressure of the drainage passage 25 increases due to the infiltration pressure of the molten metal. 25 is increased and becomes larger than the set pressure, the drain valve 90 blocks the discharge of the cooling water discharged from the drain passage 25, thereby blocking the flow of the molten metal.

The drain valve 90 may be a check valve or a solenoid valve in the same manner as the water supply valve 80. In this embodiment, The cooling water is discharged from the water discharge passage 25 by being moved to the inner side of the water discharge valve moving space 44 by the pressure of the cooling water discharged from the water discharge passage 25, Or block.

The cooler head 40 is formed with an elastic member seating space 46 extending in the drain valve moving space 44 and formed smaller in diameter than the drain valve moving space 44. In the elastic member seating space 46, An elastic member 100 for resiliently urging the drain valve 90 is disposed.

The elastic member 100 is formed of a coil spring, and the water supply pipe 70 penetrates.

The elastic member 100 supports the drain valve 90 by a predetermined elastic force such that the drain valve 90 is drained by the pressure of the cooling water discharged through the drain passage 25, When the metal mold is cracked and the molten metal penetrates into the water supply passage 35 and the drain passage 25, the drain valve 90 is opened by the infiltration pressure of the molten metal, Has an elastic force capable of being moved in the drain valve movement space (44).

That is, when the elastic force of the elastic member 100 acts as the set pressure and the pressure of the cooling water discharged through the drain passage 25 is smaller than the elastic force of the elastic member 100, the drain valve 90 is connected to the water supply passage 35 and the drain valve 90 prevents the discharge of the cooling water discharged from the drain passage 25 when the pressure of the cooling water discharged through the drain passage 25 is larger than the elastic force of the elastic member 100 do.

2 is a detailed view and a perspective view of the water supply valve 80 shown in Fig.

1 and 2, as the water supply valve 80 is moved in the water supply valve movement space 42, the water supply valve 80 is brought into close contact with the inner wall of the water supply valve movement space 42 formed obliquely, An inclined portion 85 for supplying or cutting off the cooling water is formed.

The water supply valve 80 includes a water supply pipe inserting portion 82 having a predetermined depth so that the water supply pipe 70 can be inserted therein, a fine cooling water water supply portion 84 extending from the water supply pipe inserting portion 82, At least one cooling water inflow portion 86 branched from the portion 84 and extending to the outer surface of the water supply valve 80 is formed.

The cooling water supply unit 84 is not formed through the water supply valve 80 but is formed at a predetermined depth in the water supply valve 80.

A plurality of cooling water inflow portions 86 may be formed in the circumferential direction of the water supply valve 80. In order to smoothly supply cooling water to the water supply pipe 70, It is preferable that the area is substantially equal to the cross sectional area of the cooling water supply portion 84. [

The water supply valve 80 has a first annular shape in which the cooling water supply portion 84 is formed smaller in diameter than the water supply pipe insertion portion 82 and the water supply pipe 70 is inserted into the water supply pipe insertion portion 82, A jaw portion 88 is formed.

The cooling water inflow portion 86 is inclined downward from the outer surface of the water supply valve 80 toward the cooling water supply portion 84 in order to prevent the flow of the molten metal infiltrated into the cooling water supply portion 84 due to a crack in the metal mold .

3 is a detailed view and a perspective view of the drain valve 90 shown in Fig.

1 and 3, the drain valve 90 is formed with a through hole 95 which penetrates in the longitudinal direction and communicates with the water supply passage 35, and one end of the through hole 95 is provided with a water supply pipe 70 And an inner pipe insertion portion 94 into which the inner pipe 30 is inserted is formed at the other end of the through hole 95.

The drain valve 90 is disposed between the water supply pipe inserting portion 92 and the inner pipe inserting portion 94 and has a diameter smaller than that of the water supply pipe inserting portion 92 and the inner pipe inserting portion 94. Two annular jaw portions 96 are formed.

The water supply pipe 70 is mounted on the first annular step portion 88 formed at one end of the water supply valve 80 and inserted into the water supply pipe insertion portion 92 formed at the drain valve 90, 5 by the water supply pipe inserting portion 92 formed on the bottom wall 90 of the water supply pipe 90. As shown in Fig.

The drain valve 90 is provided with a packing 93 in close contact with the outer surface of the water supply pipe 70 in the water supply pipe insertion portion 92 to prevent the leakage of the cooling water.

The drain valve 90 is formed in an annular shape spaced apart from the through hole 95 and communicated with the drain passage 25 to form a cooling water discharge portion 98 having a predetermined depth.

The drain valve 90 is formed with at least one cooling water discharge hole 99 branched from the cooling water discharge portion 98 and extending to the outer surface of the drain valve 90.

A plurality of cooling water discharge holes 99 may be formed in the circumferential direction of the drain valve 90. In order to smoothly discharge the cooling water from the drainage passage 25, , And the drainage passage (25).

Fig. 4 is a steady state operation diagram of the water supply valve 80 shown in Fig. 1, and Fig. 5 is a steady state operation diagram of the drainage valve 90 shown in Fig.

Referring to FIGS. 1, 4 and 5, the operation of the cooling apparatus of the die-casting mold according to the present invention in a steady state will be described below.

First, the water supply valve 80 is initially set in the water supply valve movement space 42 with a clearance of f as shown in FIG. 4 (a), and the inclined portion 85 is inserted into the water supply valve movement space 42 The drain valve 90 is in contact with the upper side of the drain valve moving space 44 by the elastic force of the elastic member 100 and the water supply pipe 70 is in contact with the water supply pipe inserting portion 92, As shown in Fig. 5 (a), with a gap of h.

In this state, when cooling water is supplied from the water supply port connector 50 to the moving passage 45 of the cooler head 40, the cooling water pushes up the water supply valve 80, whereby the water supply valve 80 is rotated by f The inclined portion 85 maintains a gap of g as the inner wall of the water supply valve moving space 42, as shown in FIG. 4 (b).

At this time, the water supply pipe 70 is moved upward together with the water supply valve 80 by h in the water supply pipe insertion portion 92 of the drain valve 90, as shown in Fig. 5 (b).

On the other hand, in order for the water supply valve 80 to maintain the state as shown in Fig. 4 (b), it is preferable that the sectional area of g is smaller than the sectional area of c.

Thereafter, the cooling water is moved through the gap g to the cooling water supply portion 84 via the cooling water inflow portion 86 of the water supply valve 80 and then flows through the water supply pipe 70 into the second annular shape of the drain valve 90 Exchanged with the mold while moving through the water passage 35 via the jaw portion 96 and then moved to the drainage passage 25 to be discharged through the cooling water discharge hole 99 of the drainage valve 90 Is moved to the moving passage (45) of the cooler head (40), and then discharged to the outside through the drain connector (60).

Fig. 6 is an operation diagram of the water supply valve 80 shown in Fig. 1 in a molten metal infiltration state, and Fig. 7 is an operation diagram of the water infiltration state of the drain valve 90 shown in Fig.

Referring to FIGS. 1, 6 and 7, the operation of the cooling apparatus of the die casting mold according to the present invention in the molten metal infiltration state will be described below.

First, cracks are generated in the mold, and the molten metal penetrates into the water passage 35 and the drain passage 25. At this time, if the pressure of the molten metal penetrating into the water supply passage 35 is K and the pressure of the molten metal penetrating into the drain passage 25 is M, K is larger than the pressure of the cooling water pushing up the water supply valve 80 The molten metal infiltrated into the water supply passage 35 is moved to the water supply pipe 70 through the second annular step portion 96 of the drain valve 90 and then supplied to the cooling water supply portion 84 of the water supply valve 80 The water supply valve 80 is pushed downward by the inertial force of the molten metal as shown in FIG. 6 (b) so that the inclined portion 85 is moved in the water supply valve movement space 42 to close the flow of the molten metal.

When the molten metal flows into the cooling water discharging portion 98 of the drain valve 90 from the drain passage 25, since the M is larger than the elastic force of the elastic member 100, the drain valve 90 is connected to the elastic member 100, 7 (a) is moved downward in the figure so as to have a value of 0, so that the state shown in Fig. 7 (b) is reached, whereby the drain valve 90 is closed, The molten metal moved to the cooling water discharging portion 98 is moved to the drain valve moving space 44 through the cooling water discharging hole 99, but the flow of the molten metal no longer continues.

At this time, the water supply pipe 70 is also moved downward in the drawing together with the drain valve 90, whereby the water supply valve 80 is also moved downward in the drawing, and as shown in Fig. 6 (b) The portion 85 is brought into close contact with the inner wall of the water supply valve moving space 42 to block the flow of the molten metal.

1 is a cross-sectional view of a cooling apparatus of a die casting mold according to an embodiment of the present invention,

Fig. 2 is a detailed view and a perspective view of the water supply valve shown in Fig. 1,

FIG. 3 is a detailed view and a perspective view of the drain valve shown in FIG. 1,

Fig. 4 is a steady-state operation diagram of the water supply valve shown in Fig. 1,

Fig. 5 is a steady state operation diagram of the drain valve shown in Fig. 1,

Fig. 6 is an operation diagram of the water supply valve in the molten metal infiltration state shown in Fig. 1,

7 is an operational view of the drain valve shown in Fig. 1 in a molten metal infiltration state.

DESCRIPTION OF THE REFERENCE NUMERALS

10: mold 20: outer pipe

25: drainage passage 30: internal pipe

35: water passage 40: cooler head

42: Water supply valve movement space 44: Drain valve movement space

45: moving passage 46: elastic member seating space

50: water inlet connector 60: drain outlet connector

70: water supply pipe 80: water supply valve

82: Water supply pipe inserting portion 84: Cooling water supply portion

85: slope part 86: cooling water inflow part

88: first annular jaw 90: drain valve

92: water pipe insertion part 93: packing

94: inner pipe insertion portion 95: through-hole

96: second annular step portion 98: cooling water discharge portion

99: cooling water discharge hole 100: elastic member

Claims (5)

An outer pipe having an inner space formed therein and disposed inside the mold; An inner pipe inserted into the inner space of the outer pipe to define a water supply passage for supplying cooling water to the inner space and a drain passage for discharging the cooling water; A cooler head having a passage for connecting the water pipe and the drain pipe of the external pipe into which the internal pipe is inserted; A water supply valve installed in the cooler head so that the inner pipe is inserted and the cooling water is moved to the drain passage; And And a drain valve movably disposed inside the drain valve movement space formed in the inside of the cooler head, The water supply valve includes: A water supply pipe inserting portion having a predetermined depth to insert a water supply pipe connected to the movement passage to move the cooling water, A cooling water supply portion extending from the water supply pipe insertion portion, Wherein at least one cooling water inflow portion branched from the cooling water supply portion and extending to the outer side surface of the water supply valve is inclined downwardly toward the cooling water supply portion. The method according to claim 1, In the cooler head, A water supply valve movement space is formed so that the water supply valve is movable, Wherein the water supply valve is in contact with the inner wall of the water supply valve movement space or is sloped to supply or block the cooling water to the water supply pipe. The method according to claim 1, Wherein the water supply valve has a cooling water supply portion formed to be smaller in diameter than the water supply pipe insertion portion and a first annular tuck portion to be seated after the water supply pipe is inserted into the water supply pipe insertion portion. The method according to claim 1, Wherein the cooler head is provided with a drain valve movement space in which the drain valve is movable, An elastic member seating space extending in the drain valve movement space and having a diameter smaller than that of the drain valve movement space is formed, And an elastic member for resiliently urging the drain valve is disposed in the elastic member seating space. The water treatment system according to claim 1, A through hole communicating with the water supply passage is formed, A water pipe insertion portion into which the water supply pipe is inserted is formed at one end of the through hole and an internal pipe insertion portion into which the internal pipe is inserted is formed at the other end, A cooling water discharge portion formed to be spaced apart from the through hole and communicating with the drainage passage and having a predetermined depth, And at least one cooling water discharge hole branched from the cooling water discharge portion and extending to an outer surface of the drain valve is formed.

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