KR101482072B1 - Shot sleeve air vent apparatus and method for die-casting system - Google Patents

Abstract

The present invention provides an exhaust port on the upper end of the injection sleeve of the die casting apparatus and reduces the amount of air sent to the die casting mold by discharging the air at the upper end of the injection sleeve through the exhaust port before the plunger is filled 100% To an injection sleeve air vent apparatus and method for a die casting apparatus capable of minimizing air contained in a casting.

Description

TECHNICAL FIELD [0001] The present invention relates to an injection vent air vent apparatus and method for a die casting apparatus,

The present invention relates to an injection sleeve air vent apparatus and method for a die casting apparatus capable of securing an internal quality during production of a product by a die casting method.

The timing chain connects the crankshaft of the automobile and the camshaft which opens / closes the intake / exhaust valve of the cylinder head. The timing chain serves to adjust the opening and closing timing of the valve according to the position of the piston.

The timing chain is made of a metal material, which is semi-permanent, while driving noise is generated, and lubrication and cooling are required.

The timing chain cover is disposed outside the timing chain to reduce the noise generated from the timing chain and to support the timing chain as well as to pass and seal the engine oil and the antifreeze for lubrication, cooling, etc. of the timing chain .

An oil pump, a water pump, an alternator head cover and the like are attached to the outside of the timing chain cover, and the timing chain is rotated inside the chain cover.

At this time, the timing chain cover has its own sealing and leakage characteristics as a portion where the oil flows inside the timing chain, and a high pressure is also applied to the oil pump side.

Accordingly, since the timing chain cover is connected to the engine, rigidity is required, and high-pressure oil flows inside the chain cover, so that pressure tightness (airtightness) performance is required.

Meanwhile, the timing chain cover is produced by a die-casting method using aluminum as a raw material.

The die casting method is a casting method in which a molten raw material (usually aluminum) is injected into a mold at a high speed and a high pressure by a piston cylinder mechanism to form a product. Since the product precision is high, a thin casting can be produced. Therefore, it is widely used for manufacturing automobile parts.

FIG. 1 is a schematic view showing a die casting injection structure according to the prior art. Referring to the die casting method, the molten metal 4 is injected into the sleeve 3 through the molten metal injection port 2 while the mold 1 is closed.

Then the plunger 5 is advanced to mold the timing chain cover in such a manner that the molten metal 4 injected into the sleeve 3 is injected and filled into the mold 1 at high speed and high pressure.

Then, after the mold 1 is opened, the molded product is taken out.

However, in the die casting method, air is injected into the casting during the injection and filling process due to the nature of the method of injecting the raw material at high speed and high pressure, and the entrained air 6 enters into the mold 1 It is combined with the molten metal 4 to deteriorate the internal quality of the die casting product and cause defects such as bubbles and leaks.

For example, the gas mixed in the mold 1 and the gas injected from the injection part can not escape during the casting and become isolated, resulting in insufficient compactness of the casting structure.

Disclosure of the Invention The present invention has been made to solve the above problems, and it is an object of the present invention to provide a die casting apparatus in which an exhaust port is provided at the upper end of an injection sleeve and air in the upper end of an injection sleeve is exhausted through an exhaust port before the molten metal is filled in the sleeve by 100% The present invention provides an injection sleeve air vent apparatus and method for a die casting apparatus capable of minimizing the amount of air contained in a casting by reducing the amount of air sent toward a die casting mold.

In order to achieve the above object, an injection sleeve air vent apparatus for a die casting apparatus according to the present invention comprises: an injection sleeve having a hollow portion therein and having a molten metal injection port at a rear upper end; And an exhaust port formed at an upper end of the injection sleeve and communicating with the inside of the injection sleeve, wherein air in the injection sleeve is discharged at the time of injection to minimize air inflow into the mold.

And the injection sleeve includes a pipe inserted into an exhaust port to discharge air from the injection sleeve.

The pipe is connected to a vacuum device to effectively discharge the air inside the injection sleeve.

The pipe is connected to an air supply unit so that the pipe inlet and the inside of the injection sleeve can be cleaned through an air blow.

The injection sleeve air vent apparatus includes an air vent control unit for establishing an interface with the die casting apparatus to control the on / off time and duration of the air vent and the air blow.

And the exhaust port is composed of a vertical movement hole formed at the upper end of the front side of the injection sleeve and a horizontal movement groove formed in the axial direction in the axial direction.

The injection sleeve air vent method for a die casting apparatus according to the present invention comprises the steps of injecting molten metal into an injection sleeve; Advancing the plunger to perform slow injection of the molten metal; Discharging the air inside the injection sleeve through the exhaust port formed at the upper end of the injection sleeve before the molten metal is filled 100% inside the injection sleeve; And discharging the air and then injecting the molten metal at a high speed.

The method may further include the step of air blowing the exhaust port and the injection sleeve through an exhaust port formed on the upper end of the injection sleeve before injecting the molten metal, thereby cleaning the exhaust port and the injection sleeve.

Advantages of the injection sleeve air vent apparatus and method for a die casting apparatus according to the present invention will be described as follows.

The amount of air introduced into the die casting mold is reduced by discharging the air at the upper end of the injection sleeve through the exhaust port formed at the upper end of the injection sleeve in the process of injecting the molten metal into the injection sleeve and advancing the plunger to inject the molten metal into the mold It is possible not only to minimize the inclusion of air in the casting but also to secure the internal quality such as rigidity and pressure resistance.

1 is a schematic view showing a die casting injection structure according to the prior art;
2 is a schematic view for explaining a configuration of a die casting injection part according to the present invention;
Figure 3 is a perspective view of the flange bushing and the injection sleeve in Figure 3;
Figure 4 is a perspective view and an incision view of the injection sleeve in Figure 3;
Fig. 5 is a perspective view showing the exhaust port of the injection sleeve in Fig. 3 and a rear view
Fig. 6 is a perspective view, an incision oblique view and a rear view of the flange bushing in Fig.
7 is a cross-sectional view for explaining an air blowing method and an air venting method according to the present invention
8 is a schematic view for explaining a method of operating an injection sleeve air vent apparatus for a die casting apparatus according to the present invention
Fig. 9 is an operation flow chart for explaining an injection sleeve air vent method for a die casting apparatus according to the present invention. Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention.

FIG. 3 is a perspective view of a flange bushing and an injection sleeve in FIG. 3, FIG. 4 is a perspective view and a cutaway perspective view of the injection sleeve in FIG. 3, FIG. 5 is a perspective view and a rear view showing the exhaust port of the injection sleeve in FIG. 3, and FIG. 6 is a perspective view, an incision perspective view, and a rear view of the flange bushing in FIG.

The present invention relates to an injection sleeve air vent apparatus for a die casting apparatus capable of improving the internal quality of a casting by discharging air incorporated in the casting die casting die casting.

The injection sleeve air vent apparatus for a die casting apparatus according to the present invention is an apparatus that can be applied to produce an aluminum casting die casting product such as a timing chain cover or the like.

The injection part 10 includes a flange bushing 12 connected to a mold sleeve 11 and an injection sleeve 13 having a molten metal injection port 13a at an upper end thereof. (13), and a plunger (26) for injecting the molten metal injected into the injection sleeve (13) into the mold, all of which are arranged horizontally.

The mold sleeve 11 is mounted inside the mold as a part for connecting the flange bushing 12 and the mold (stationary mold base).

The flange bushing 12 has a cylindrical tube structure in which a hollow portion is formed, and an injection sleeve 13 is inserted into the flange bushing 12.

A molten metal injection port 13a is formed in the rear of the upper end of the injection sleeve 13 to inject molten metal into the injection sleeve 13 through the molten metal injection port 13a.

The plunger 26 is constituted by a plunger tip 14, a fitting portion 15 and a plunger rod 16, which can be moved forward and backward by a separate driving means, .

Here, the present invention provides an air vent device in which an exhaust port 18 is formed at the upper end of an injection sleeve 13 to exhaust air inside the injection sleeve 13 before injection.

The exhaust port 18 includes a vertical movement hole 18a formed to communicate with the inside of the injection sleeve 13 in a direction perpendicular to the upper end of the injection sleeve 13 and a vertical movement hole 18b formed in the upper end of the injection sleeve 13 in the vertical movement hole 18a. And a horizontally moving groove 18b having a semi-circular cross-sectional shape formed up to the molten metal inlet 13a on the outer circumferential surface.

The flange bushing 12 includes a horizontally moving groove 12a having a semicircular cross-sectional shape that is elongated in the axial direction and an end groove 12b formed at the rear end of the horizontal moving groove 12a.

The horizontal movement groove 12a of the flange bushing 12 is arranged to cover the upper portion of the horizontal movement groove 18b of the injection sleeve 13 and the horizontal movement groove 12b of the flange bushing 12 12a and the horizontal movement groove 18b of the injection sleeve 13 are formed into a circular shape in the upper part and the lower part.

A pipe 17 made of copper is inserted into the exhaust port 18 of the injection sleeve 13 and the horizontal movement groove 12a and the end groove 12b of the flange bushing 12, Air can be injected into the injection sleeve 13 or the air inside the injection sleeve 13 can be discharged to the outside.

At this time, both ends of the pipe 17 may be formed in an elbow shape.

The piping 17 is connected to the air supply unit 19 and the air vent unit 20 through a fluid transfer line 21.

The fluid transfer line 21 may be either split into an air supply line 21a and an air vent line 21b or may be unified into a single line.

A manifold 22 may be installed in the fluid transfer line 21. [

The front end of the manifold 22 is connected to the fluid movement line 21 and the rear end of the manifold 22 is connected to the air vent 20 through a separate air vent line 21b. The middle portion of the fold 22 is connected to the air supply portion 19 through a separate air supply line 21a.

Solenoid valves 23 and 24 are provided at the front end and the rear end of the manifold 22 to open and close the fluid communication path between the fluid movement line 21 and the air vent line 21b, A solenoid valve 25 is provided at the outlet of the air supply line 21a to open and close the fluid connection path with the air supply line 21a.

The air supply unit 19 may be an air storage tank.

A vacuum device is employed in place of the air vent portion 20 so that the air inside the injection sleeve 13 can be smoothly discharged by sucking air by a vacuum pressure.

The present invention provides an air vent control 27 for controlling the flow of fluid between the injection sleeve 13 and the air supply and discharge.

The air vent control section 27 controls the operation of the solenoid valve and the plunger 26 and the time and time of the air blow and the air vent in accordance with the forward and backward movement of the plunger 26.

An interface is established between the die casting device 28 and the air vent control part 27 to enable timing control of the air vent and air blowing.

The air vent method in the injection sleeve 13 according to the present invention will now be described.

8 is a schematic view for explaining a method of operating an injection sleeve air vent apparatus for a die casting apparatus according to the present invention, and FIG. 9 is a schematic view for explaining the operation of the injection sleeve air vent apparatus for a die casting apparatus according to the present invention. Fig. 6 is an operational flowchart for explaining an injection sleeve air vent method for a die casting apparatus according to the present invention.

Before the molten metal is injected, air is blown into the injection sleeve (13) through the pipe (17) to prevent clogging of the inlet of the pipe (17) and clean the interior of the injection sleeve (13).

At this time, the aluminum (aluminum) coating at the inlet of the pipe 17 due to the forward and backward movement of the plunger 26 is removed.

After the plunger 26 is retracted to the original position in the injection sleeve 13, the solenoid valve 23 causes the air to flow from the air supply line 19 to the air supply line 21a, the manifold 22, Is supplied to the inside of the sleeve via the line 21 and the pipe 17 to clean the inside of the pipe 17 and the injection sleeve 13 and then to blow the air through the air vent line, the manifold 22 and the air vent portion 20 to the outside.

The air blow may be continued for a predetermined time by a timer.

Then, the molten metal is injected into the injection sleeve 13 through the molten metal injection port 13a.

Then, after the plunger 26 is advanced, that is, after low-speed injection, the air at the top of the injection sleeve 13 is discharged through the pipe 17 before the molten metal is filled in the sleeve 100%, that is, before high-speed injection.

Here, a vacuum device may be connected to the end of the pipe 17 or instead of the air vent 20 to increase the air discharge effect.

The molten metal is injected into the injection sleeve 13 and then the plunger 26 is advanced to inject the molten metal into the mold so that the molten metal is injected through the exhaust port 18 formed at the upper end of the injection sleeve 13, By discharging the air at the upper end of the die 13, it is possible to reduce the amount of air mixed into the die casting mold and to minimize the inclusion of air in the casting, and to secure the internal quality such as rigidity and pressure resistance.

10:
11: Molded sleeve
12: Flange bushing
12a: Horizontal moving groove
12b: end groove
13: Injection sleeve
13a:
14: Plunger tip
15: Fitting portion
16: plunger rod
17: Piping
18: Exhaust
18a: vertical moving hole
18b: Horizontal moving groove
19:
20: Air vent section
21: Fluid transfer line
21a: air supply line
21b: Air vent line
22: Manifold
23, 24, 25: Solenoid valve
26: Plunger
27: Air vent control part
28: Die casting device

Claims (8)

delete delete delete delete delete delete An injection sleeve air vent method for a die casting apparatus for discharging air from an injection sleeve of a die casting apparatus,
Injecting molten metal into the injection sleeve;
Advancing the plunger to perform slow injection of the molten metal;
Discharging the air inside the injection sleeve through the pipe inserted into the exhaust port formed at the top of the injection sleeve before the melt is filled 100% inside the injection sleeve after the low speed injection;
Discharging the air, and then injecting the molten metal at a high speed;
/ RTI >
The injection sleeve is air-blown through a pipe inserted in an exhaust port of the injection sleeve before the injection of the molten metal to prevent clogging of the pipe inlet, and the inside of the injection sleeve is cleanly cleaned,
After the plunger has retracted from the interior of the injection sleeve and the plunger has retreated from its original position due to the forward and backward movement of the plunger, air is drawn from the air supply line by the actuation of the solenoid valve into the air feed line, manifold, And discharging the air through the air vent line, the manifold, and the air vent after the inside of the injection sleeve is cleaned by cleaning the inside of the pipe and the injection sleeve. Of an injection sleeve air vent for a die casting device.
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