KR102510235B1 - Pore free apparatus for diecasting and operating method thereof - Google Patents

Abstract

The present invention supplies a high-capacity gas to the inside of the injection sleeve before injecting the molten metal into the injection sleeve 110, and when the molten metal is injected into the injection sleeve, the capacity is lower than that of the high-capacity gas into the injection sleeve. Disclosed is a non-porous device for die casting including a gas supply pipe 210 for supplying a low-volume gas and an operation method thereof.

Description

Non-porous apparatus for die casting and its operation method {PORE FREE APPARATUS FOR DIECASTING AND OPERATING METHOD THEREOF}

The present invention relates to a non-porous die casting technique in which air in a sleeve is substituted with oxygen, combined with molten metal by high-pressure injection, and solidified to eliminate pores.

The die casting method is a casting method in which molten metal (molten metal) is injected into a mold having a complex and precise cavity to produce castings with high precision and beautiful surfaces in large quantities in a short period of time.

The pore-free die-casting method was jointly developed by ILZRO (International Lead Zine Research Organization Inc) of the United States and Nippon Light Metal Co., Ltd. in 1968. The air in the sleeve is replaced with gas and then melted by high-pressure injection. It is a method of combining with metal and solidifying to eliminate pores. Since the gas used here is oxygen as described in patent literature, the pore-free die-casting method is called a PF method or an oxygen atmosphere die-casting method.

The non-porous die casting method was developed in 1968, but has been applied and used in Japan since the early and mid-2010s, and there is no case applied to the field in Korea yet. Recently, it is known that companies that mass-produce some domestic auto parts are experimenting to apply the non-porous die casting method to the field.

Conventionally, by supplying oxygen into the injection sleeve through a nozzle formed in the injection sleeve, mechanical or physical properties such as stiffness and elongation of the injection product are improved. However, in the prior art, there is a problem in that it is difficult to precisely control the amount of oxygen supplied or to produce an injection molding product of constant quality due to clogging of the nozzle during the process.

Korea Patent Registration No. 10-0187989

In order to solve the above problems, the present invention supplies a high-capacity gas to the inside of the injection sleeve before injecting the molten metal into the injection sleeve, and when injecting the molten metal into the injection sleeve, the high-capacity gas is supplied to the inside of the injection sleeve. Provided is a non-porous device for die casting that supplies a low volume gas and an operation method thereof.

A non-porous device for die casting according to an embodiment of the present invention for the above object to be solved is a first gas for supplying a high-capacity gas into the injection sleeve 110 before injecting molten metal into the injection sleeve 110. The supply pipe 211 includes a gas supply pipe 210 composed of a second gas supply pipe 212 for supplying a low volume gas having a lower capacity than a high volume gas to the inside of the injection sleeve when molten metal is injected into the injection sleeve, It is characterized in that the pressure of the high-capacity gas and the low-capacity gas can be adjusted, and a set amount of gas is supplied.

In the non-porous apparatus for die casting according to an embodiment of the present invention, gas and air are supplied through the nozzle 140 formed in the injection sleeve, and air is supplied before supplying the high-capacity gas to remain in the cavity connected to the injection sleeve. It can be characterized by removing gas.

According to an embodiment of the present invention, a method of operating a non-porous device for die casting for supplying gas to the inside of an injection sleeve through a gas supply pipe is the inside of the injection sleeve in a state where the spout 120 formed in the injection sleeve is closed. supplying a high-capacity gas to the inside of the injection sleeve and supplying a low-capacity gas having a lower capacity than the high-capacity gas to the inside of the ejection sleeve in a state in which the pouring spout is open, the pressure of the high-capacity gas and the low-capacity gas It is characterized in that it is controllable and supplies a set amount of gas.

The gas supply pipe may be characterized in that it supplies a low-volume gas until the injection process in consideration of gas flow fluctuation due to movement of the plunger or gas leakage due to heat loss of convection.

The present invention can control the pressure of the high-capacity gas and the low-capacity gas by using a gas supply pipe divided into a first gas supply pipe and a second gas supply pipe, thereby providing an appropriate amount of gas injection to prevent overreaction of the oxidation reaction. , there is a remarkable effect of producing high-quality injection molding products with a constant quality level.

1 is a block diagram showing a non-porous die casting system according to an embodiment of the present invention.
Figure 2 is a cross-sectional view showing a non-porous die casting system according to an embodiment of the present invention.
Figure 3 is an enlarged cross-sectional view of the mold apparatus of Figure 2;
4 is an enlarged cross-sectional view of the imperforate device of FIG. 2;
5 is a flowchart illustrating a non-porous die casting method according to an embodiment of the present invention.
6 is a flowchart showing the method of gas supply in 5 in detail.
Figure 7 is a flow chart showing the non-porous die casting method of Figure 5 in more detail.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings and the contents described in the accompanying drawings, but the present invention is not limited or limited by the embodiments.

1 is a block diagram showing a non-porous die-casting system according to an embodiment of the present invention, the non-porous die-casting system 10 includes a mold device 100, a non-porous device 200 and a control means 300 .

The mold device 100 is a device for producing an injection product in the same shape as the mold by using molten metal in the mold, and the non-porous device 200 supplies gas or air to the mold device 100 to improve the quality of the injection product. The control means 300 controls the operation of the mold device 100 and the non-porous device 200.

The control means 300 may be installed in the mold device 100 or the non-porous device 200 and may be installed in an independent space, but is not limited thereto. The control means 300 may control the operation of the mold device 100 and the non-porous device 200 using wired or wireless communication.

Figure 2 is a cross-sectional view showing a non-porous die-casting system according to an embodiment of the present invention, the control means 300 can be installed in the mold device 100 or non-porous device 200, to be installed in an independent space may, but is not limited thereto. The control means 300 may control the operation of the mold device 100 and the non-porous device 200 using wired or wireless communication. 2, the control means 300 is installed in the non-porous device 200.

FIG. 3 is an enlarged cross-sectional view of the mold device of FIG. 2 . The mold device 100 includes an injection sleeve 110 , a pouring hole 120 , a plunger 130 and a nozzle 140 . The injection sleeve 110 is a cylindrical part for injection. The injection sleeve 110 has a pouring spout 120 for injection of molten metal at one end of the upper part, and a plunger 130 for opening and closing the pouring spout 120 is formed on one end, and the pouring spout 120 and Nozzles 140 are formed at positions spaced apart at predetermined intervals. The other end of the injection sleeve 110 is formed with a mold part 150 including a cavity.

FIG. 4 is an enlarged cross-sectional view of the non-porous device of FIG. 2 . The non-porous device 200 includes a gas supply pipe 210 , an air supply pipe 220 and a connection pipe 230 . One end of the gas supply pipe 210 is connected to the gas supply device 400 and the other end is connected to the connection pipe 230 . The gas is an oxygen gas, a gas for eliminating pores in an injection product, or a gas used to improve the quality of an injection product.

One end of the air supply pipe 220 is connected to the air supply device 500, and the other end is connected to the connection pipe 230. One end of the connection pipe 230 is connected to the gas supply pipe 210 and the air supply pipe 220, and the other end is connected to the nozzle 140. The connection pipe 230 may be a 'Y' shaped pipe. Gas and air flow from the non-porous device 200 to the mold device 100. That is, the flow directions of gas and air are the same.

The control means 300 controls supply timing of gas and air supplied into the injection sleeve 110 through the nozzle 140 . More specifically, the control means 300 can control the supply of gas during the process of manufacturing the injection-molded product, and can control the supply of air when the production of the injection-molded product is completed.

The non-porous die casting system 10 can clean the nozzle 140 using air, at the same time determine whether or not the nozzle 140 is clogged, and produce a high-quality injection molding product with a constant quality level.

The gas supply pipe 210 supplies a high-capacity gas to the inside of the injection sleeve 110 before injecting molten metal into the injection sleeve 110 to supply an appropriate amount of gas, and melts into the injection sleeve 110. When the metal is injected, a low-capacity gas having a lower capacity than the high-capacity gas is supplied into the injection sleeve 110 .

The gas supply pipe 210 supplies high-capacity gas into the injection sleeve 110 when the pouring spout 120 formed in the ejection sleeve 110 is closed, and the pouring spout 120 into the injection sleeve 110. In an open state, a low-capacity gas having a lower capacity than the high-capacity gas is supplied into the injection sleeve 110 . When the plunger 130 is retracted, gas such as oxygen leaks through the chill vent or gas vent due to the internal temperature and convection of the mold part 150, so a low-capacity gas is supplied to fill it.

The gas supply pipe 210 is divided into a first gas supply pipe 211 for supplying high-capacity gas and a second gas supply pipe 212 for supplying low-capacity gas, so that the pressure of the high-capacity gas and the low-capacity gas can be adjusted. In the present invention, when gas is supplied through a single pipe, it may be difficult to control both the flow rate and pressure, the number of control parts to control may increase, and the unit cost of parts may increase, and unnecessary oxygen waste may occur to maintain pressure. It is supplied through the first gas supply pipe 211 and the second gas supply pipe 212 .

More specifically, in the present invention, if one tube is used, the capacity can be adjusted from a high capacity to a low capacity gas. Therefore, it is supplied to the first gas supply pipe 211 and the second gas supply pipe 212 for efficient pressure control.

The non-porous device 200 includes a control means 240 for adjusting the flow rate or pressure of the fluid and a measurement for measuring the flow rate or pressure of the fluid in order to accurately supply fluids such as gas and air and determine whether or not the nozzle 140 is clogged. A means 250 may be further included.

The control unit 240 may include a flow control valve, a solenoid valve, a check valve, and a regulator. The flow control valve and the solenoid valve may be installed in each of the first gas supply pipe 211 and the second gas supply pipe 212, and may also be installed in the air supply pipe 220. The check valve may be installed at ends of the gas supply pipe 210 and the air supply pipe 220, and may prevent the inflow of reverse pressure when a mixture of gas and air is used. The regulator may be installed at one end of the gas supply pipe 210 and the air supply pipe 220, and may adjust the pressure of the supplied gas or air.

The measuring means 250 may include a pressure gauge and a flowmeter. The pressure gauge and the flowmeter may be installed at one end of the gas supply pipe 210 and the air supply pipe 220, and may measure the pressure or flow rate of the supplied gas or air. The pressure gauge and the flowmeter may be installed at ends of the gas supply pipe 210 and the air supply pipe 220, and may measure the pressure or flow rate of gas or air on the output side. In addition, a pressure gauge may be installed at the end of the air supply pipe 220 and used to determine whether or not the nozzle 140 is clogged.

The control means 300 controls the operation of the adjusting means 240 using the measured value received from the measuring means 250 or a preset setting value. The measured value may include a flow rate value indicating the flow rate of the fluid or a pressure value indicating the pressure of the fluid. The set value may be a reference value for comparison with the measured value, and may be a control value for controlling the control unit 240 .

Porous device 200 may include a filter 260 to purify gas or air. The filter 260 may be formed between the gas supply device 400 and the gas supply pipe 210 or between the air supply device 500 and the air supply pipe 220 . The non-porous device 200 may further include a backfire prevention means 270 for preventing backfire of gas.

5 is a flow chart showing a non-porous die-casting method according to an embodiment of the present invention, in which the non-porous die-casting system 10 supplies gas to the inside of the injection sleeve 110 through a nozzle 140, and melts the gas An injection product is completed by reacting the metal, and by supplying air to the inside of the injection sleeve through the nozzle 140, supply timing of gas and air supplied to the inside of the injection sleeve 110 is controlled.

Figure 6 is a flow chart showing the gas supply method of 5 in detail, the non-porous device 200 is a high-capacity gas to the inside of the injection sleeve 110 in a state in which the spout 120 formed in the injection sleeve 110 is closed is supplied, and a low-volume gas having a lower capacity than the high-capacity gas is supplied to the inside of the ejection sleeve 110 in a state in which the pouring spout 120 is open, and the low-volume gas is supplied until the injection process. .

In the present invention, gas flow fluctuations may occur when the plunger 130 retreats, such as movement of the plunger 130 during the injection process, and gas leakage may occur due to heat loss of convection, resulting in a decrease in the quality of the injection product. Since this may occur, the low-volume gas is supplemented until the injection process. According to the present invention, by supplying gas until the injection process, it is possible to prevent quality deterioration of an injection product that may occur during the injection process.

7 is a flow chart showing the non-porous die casting method of FIG. 5 in more detail, the mold device 100 and the non-porous device 200 are controlled by the control means 300, and the order of operation is as follows.

In the mold apparatus 100, when the pouring hole 120 is closed, the non-porous apparatus 200 opens the first gas supply pipe 210. Thereafter, the non-porous device 200 closes the first gas supply pipe 211 and opens the second gas supply pipe 212 when the set atmosphere time is reached. The atmosphere time means the time required to fill the inside of the injection sleeve 110 with a gas atmosphere. The mold apparatus 100 opens the pouring hole 120 to inject molten metal into the injection sleeve 110 when the second gas supply pipe 212 is opened.

Since the gas remaining inside the cavity causes the generation of bubbles in die casting, the non-porous device 200 supplies air to the inside through the air supply pipe 200 before opening the first gas supply pipe 211, The gas remaining inside can be discharged.

The mold apparatus 100 starts supplying and injecting molten metal, and closes the pouring port 120. The non-porous device 200 stops the supply of oxygen by closing the second gas supply pipe when the pouring spout 120 is closed.

When injection is completed, the mold apparatus 100 performs molding, mold opening, and extraction processes. When the take-out process is completed, the mold apparatus 100 sprays the mold release agent, opens the pouring spout 120, and applies the lubricant. When the application of the lubricant is completed, the non-porous device 200 opens the air supply pipe 220, cleans the nozzle 140, and determines whether the nozzle 140 is clogged.

The present invention can clean the nozzle 140 using air, at the same time determine whether or not the nozzle 140 is clogged, and has a remarkable effect of producing a high-quality injection molding having a constant quality level.

In the present invention, by using the gas supply pipe 210 divided into the first gas supply pipe 211 and the second gas supply pipe 212, it is possible to control the pressure of the high-capacity gas and the low-capacity gas, thereby providing an appropriate amount of gas injection and reacting with oxidation. There is a remarkable effect of preventing overreaction to and producing high-quality injection moldings with a constant quality level.

The non-porous device 200) supplies gas and air through the nozzle 140) formed in the injection sleeve 110), and supplies air before supplying the high-capacity gas to remove residual gas in the cavity connected to the injection sleeve 110). The non-porous device 200) supplies air while the injection sleeve 110) is closed before supplying the high-capacity gas, so that remaining gas or harmful substances in the cavity can be forcibly discharged through a chill vent or gas vent.

Burning may occur due to the ignition of plunger oil when the injection molding is supplied to the pouring hole 120, and abnormal fluidity of the injection molding material or sloshing about the injection speed may occur during the injection process. Burning or an abnormal injection process can cause nozzle clogging, and it can be difficult to supply oxygen quantitatively due to the above reasons, and the cycle time of the process can be increased, which can reduce the reliability or productivity of the product and increase the defective rate of the product. It can be. Gas or moisture may remain after spraying the release agent, and if the residual gas is not removed, bubbles may occur in the product.

Therefore, the present invention can supply air to remove residual gas inside, clean the inside of the nozzle 140, and improve product production efficiency by checking whether or not the nozzle 140 is clogged.

The die casting method may include a vacuum die casting method. The vacuum die casting method is a device that forcibly exhausts air and gas generated during pouring by vacuuming the cavity inside the mold.

The present invention can apply a vacuum die casting method. For example, in the present invention, the gas supply device 400 and the air injection device 500 can be installed to be connected to the passage at the top of the mold, and the inside of the cavity can be made into a vacuum condition using the air injection device 500, Oxygen can be supplied after securing a vacuum.

However, when the present invention is applied to the vacuum die-casting method, the following problems occur, so the non-porous die-casting method is applied.

Since the air injection device 500 creates a vacuum state in the vacuum die-casting method, it is difficult to remove the residual gas inside the vacuum die-casting method in the process of creating a vacuum state, which is why the plunger 130 when injecting a gas such as oxygen There is a problem in that it is difficult to inject a fixed amount of oxygen due to the back pressure for oxygen input due to the closing or internal closing pressure. On the other hand, the non-porous die-casting method has the advantage of being able to easily discharge the residual gas in the cavity, as well as cleaning the nozzle 140 and checking whether or not it is clogged.

Therefore, it is preferable to inject the gas supply device 400 and the air injection device 500 from the nozzle 140 formed on the injection sleeve 110 rather than from the upper part of the mold part 150 .

More specifically, the reason for applying the non-porous die-casting method rather than the vacuum die-casting method in the present invention is as follows. The vacuum die-casting method does not directly inject air from the outside into the mold, but uses air to suction and discharge the gas in the cavity by the Venturi effect (reverse flow and suction), so the gas remaining inside the cavity is discharged. Hard to do. In addition, since the vacuum die-casting method makes a vacuum state by sucking and discharging gas in the cavity, in this case, when oxygen is injected when the plunger 130 is closed, back pressure for oxygen input may be applied, making it difficult to inject a fixed amount of oxygen. In addition, in the vacuum die-casting method, when the plunger 130 is retracted, the surrounding environment of the pouring spout 120 is poor, and flow and suction due to contact with external air occur in the injection sleeve 110, completely discharging the remaining gas. It can be difficult to do. For example, when the plunger 130 is retracted, soot or dirty substances may exist, and the surrounding environment of the pouring spout 120 may be very poor. Can be difficult to remove.

The non-porous die casting method of the present invention is an injection sleeve ?? gate ?? Because it has flow in the order of cavity - overflow (chill vent/gas vent), the flow of gas and air injection is made in one forward direction, so it can generate the optimal effect. In addition, the non-porous die casting method of the present invention can remove dirty substances formed around the pouring spout 120 through air injection. In addition, the non-porous die-casting method of the present invention has a simple structure, there is no restriction according to the surrounding environment, and if the sleeve gas inlet is also jigized, it can be used interchangeably with any other equipment.

10: non-porous die casting system 100: mold device
110: injection sleeve 120: pouring hole
130: plunger 140: nozzle
150: mold part 200: non-porous device
210: gas supply pipe 211: first gas supply pipe
212: second gas supply pipe 220: air supply pipe
230: connector 240: adjusting means
250 measuring means 260 filter
270: backfire prevention means 300: control means
400: gas supply device 500: air supply device

Claims (4)

A first gas supply pipe 211 for supplying high-capacity gas to the inside of the injection sleeve before injecting molten metal into the injection sleeve 110 and high-capacity gas to the inside of the injection sleeve when injecting molten metal into the injection sleeve Including a gas supply pipe 210 composed of a second gas supply pipe 212 for supplying a low-capacity gas having a lower capacity, the pressure of the high-capacity gas and the low-capacity gas can be adjusted, and a set amount of gas is supplied,
An air supply pipe 220 connected to the air supply device 500;
A connection pipe 230 having one end connected to the gas supply pipe and the air supply pipe, and the other end connected to the nozzle 140 formed in the injection sleeve, and
Further comprising a measuring means 250 for measuring the flow rate or pressure of a fluid such as gas and air,
Adjust the flow rate or pressure of the fluid through the measuring means, determine whether or not the nozzle is clogged,
By supplying air while the injection sleeve is closed, the remaining gas in the cavity is discharged through a gas vent,
The non-porous device for die casting, characterized in that the gas and air have a forward flow from the injection sleeve to the gas vent. delete In the method of operating a non-porous device for die casting for supplying gas to the inside of an injection sleeve through a gas supply pipe,
supplying a high-capacity gas into the injection sleeve in a state where the pouring hole 120 formed in the injection sleeve is closed; and
A step of supplying a low-volume gas having a lower capacity than the high-capacity gas to the inside of the ejection sleeve in a state in which the pouring hole is opened into the ejection sleeve, wherein the pressure of the high-capacity gas and the low-capacity gas can be adjusted, and the set amount supply gas,
The non-porous device,
An air supply pipe connected to the air supply device;
One end is connected to the gas supply pipe and the air supply pipe, and the other end is connected to the nozzle formed on the injection sleeve, and
Including a measuring means for measuring the flow rate or pressure of a fluid such as gas and air,
Adjust the flow rate or pressure of the fluid through the measuring means, determine whether or not the nozzle is clogged,
By supplying air while the injection sleeve is closed, the remaining gas in the cavity is discharged through a gas vent,
The method of operating a non-porous device for die casting, characterized in that the gas and air have a forward flow from the injection sleeve to the gas vent. delete

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