KR101144770B1 - Vaccum melting apparatus for light metal using electro-magnetic stirring and vacuum melting method using the same - Google Patents

Abstract

The present invention relates to a light metal vacuum melting apparatus and a vacuum melting method thereof, and more particularly, to melt the light metal raw materials by a heating unit in a high vacuum state and to stir the composition of the molten metal by an electronic stirring unit. The present invention relates to a light metal vacuum melting apparatus using electron stirring, which improves melting efficiency, gas (bubble) removing efficiency, and the like, thereby producing high quality molten metal, and a vacuum melting method using the same.

Vacuum melting apparatus of the present invention, the vacuum melting chamber is provided with an air discharge pipe on the upper side; A first material input pipe connected to one side of the vacuum melting chamber and communicatively connected to one side of the vacuum melting chamber; A second material introduction tube connected between the first material introduction tube and the vacuum melting chamber; A heating unit for melting installed on an outer side of the vacuum melting chamber; An electronic stirring unit installed outside the heating unit for melting and having a spiral coil embedded therein; First and second vacuum valves installed at both ends of the first material input pipe; A first molten metal heat insulating tube communicating with the other side of the vacuum melting chamber; And a second molten metal heat insulating tube communicating with the first molten metal heat insulating tube.

Light metal, vacuum, melting, molten metal, stirring, heating unit

Description

Light metal vacuum melting apparatus using electronic stirring and vacuum melting method using the same {VACCUM MELTING APPARATUS FOR LIGHT METAL USING ELECTRO-MAGNETIC STIRRING AND VACUUM MELTING METHOD USING THE SAME}

The present invention relates to a vacuum melting apparatus using electron stirring and a vacuum melting method thereof. More particularly, the composition of the molten metal is melted by melting the light metal raw material by a heating unit in a high vacuum state, and by stirring it by an electron stirring unit. The present invention relates to a light metal vacuum melting apparatus using electron stirring and a vacuum melting method using the same, which improves uniformity, improves melting efficiency, gas (bubble) removing efficiency, and the like, thereby producing high quality molten metal.

In general, light metals are lighter in weight than titanium (specific gravity 4.5), and typically beryllium (specific gravity 1.85), magnesium (1.74), aluminum (2.7), titanium (4.5), and the like. The earliest practical use is aluminum and titanium is widely used in aircraft materials. From the viewpoint of low specific gravity, alkaline earth metals such as silicon (2.3), yttrium (4.3), sodium, potassium, lithium, and the like, and alkaline earth metals such as calcium (1.5) also enter light metals, but in general, light metals Refer to the four metals listed above as the material.

The earliest practical use was aluminum, and a strong alloy called duralumin was invented in the early twentieth century, which contributed significantly to the development of aircraft, which began to develop when the strength per weight was nearly three times that of general steel. Later, light weight structural materials were needed, and magnesium was industrially produced, resulting in a number of strong magnesium alloys.

In addition, since the mid-1940s, titanium was produced industrially and various titanium alloys were used, making it possible to produce supersonic aircraft today. Beryllium took time to process and improve it to a thin plate, or to improve the viscosity of the finished plate so that it would not crack, but in the mid-1960s, it was used for aerospace development. Also used. In addition, beryllium does not absorb thermal neutrons, and thus is excellent as a structural material for nuclear reactors.

In particular, magnesium is the eighth most abundant element, accounting for about 2.7% of the planet. Magnesium alloy has a specific gravity of 1.79 ~ 1.81, which is light and has a weight reduction effect of about 70% compared to steel. Its usage is increasing rapidly.

As a representative example of such a light metal casting method, a die casting method is mainly used, and the die casting method includes a hot chamber, a cold chamber, thixomolding, and the like.

In the cold chamber system, the mold casting machine and the light metal melting furnace are separately configured, and the molten molten metal is poured into the injection sleeve of the mold casting machine, and the molten metal is pressed by an injection plunger and injected into the mold. The hot chamber method is a method in which an injection cylinder is installed in a melting furnace and pressurized so that a high temperature molten metal flows into a mold. The thixomolding method is a combination of the conventional injection molding method and the metal die casting method, and uses light metal raw materials in the form of chips such as resin injection.

On the other hand, when magnesium is used as the raw material for the die casting method, it is ignited when it is melted in the air, so measures to prevent oxidation of the molten metal are necessary. Therefore, when melting magnesium alloy, a large amount of flame retardant flux (SF ₆ + CO ₂ mixed gas) or an inert gas is injected into the melting furnace. Such flux (Flux) is a greenhouse gas, which adversely affects the atmospheric environment. It is regulated. In addition, since the price is also rising, the melting of magnesium alloy by the die casting method has a relatively high production cost in terms of production cost and causes air pollution.

In addition, thixomolding stores raw materials in the form of chips in a hopper, feeds magnesium alloy chips into cylinders, moves them forward by the rotation of the screw, and simultaneously heats them, makes them into a slurry phase having a predetermined solid phase rate, and then The slurry is filled in the molding part of the mold by the fast forward motion of the screw. However, raw materials in the form of chips are quite expensive, and scraps (molding defects, runners, gates) generated during metal forming are also impossible to reuse, which has a disadvantage of high raw material values.

The present invention has been made in view of the above, and the composition of the molten metal is made uniform by melting the light metal raw materials by the heating unit in a high vacuum state and by stirring the electrons by the electron stirring unit, and melting efficiency and gas ( It is an object of the present invention to provide a light metal vacuum melting apparatus using an electron stirring and a vacuum melting method using the same, which can improve bubble removal efficiency and generate high quality molten metal.

Vacuum melting apparatus of the present invention for achieving the above object,

Vacuum melting chamber provided with an air discharge pipe on the upper side;

A first material input pipe connected to one side of the vacuum melting chamber and communicatively connected to one side of the vacuum melting chamber;

A second material introduction tube connected between the first material introduction tube and the vacuum melting chamber;

A heating unit for melting installed on an outer side of the vacuum melting chamber;

An electronic stirring unit installed outside the heating unit for melting and having a spiral coil embedded therein;

First and second vacuum valves installed at both ends of the first material input pipe;

A first molten metal heat insulating tube communicating with the other side of the vacuum melting chamber; And

And a second molten metal heat insulating tube communicating with the first molten metal heat insulating tube.

The heating unit for melting is disposed on the lower outer peripheral surface of the vacuum melting chamber, the heating unit for thermal insulation is disposed on the outer peripheral surfaces of the first and second molten metal insulation tube.

A material input support is disposed at the rear of the second vacuum valve, and a charge plunger is installed at the rear of the material input support so as to move forward and backward.

The first and second vacuum valves are provided with a valve housing, a drive cylinder installed at an upper end of the valve housing, an operating rod vertically operated by the drive cylinder, and a valve body provided at an end of the operating rod, respectively.

The valve element of the second vacuum valve has a plug hole at one side thereof, and is configured such that a charging plunger is inserted into the plug hole.

A molten metal valve cylinder is installed at an upper end of the second molten metal heat insulating tube, and an operating rod vertically operated by the molten metal valve cylinder and a molten valve body installed at an end of the operating rod are installed inside the second molten metal heat insulating tube.

On the other hand, the vacuum melting method according to the present invention,

By closing the first vacuum valve and the molten valve body and opening the upper air discharge pipe of the vacuum melting chamber, the inside of the vacuum melting chamber, the first and second molten metal heat insulating tubes are vacuumed, and the second vacuum valve is A step (S1) of preparing a light metal raw material for advancing the charging plunger and opening the light metal raw material into the first material input pipe after opening;

After the charging plunger is reversed and the second vacuum valve is closed, the charging plunger is advanced again to close the plug hole of the second vacuum valve, and then open the air discharge pipe on one side of the first material input pipe to open the inside of the first material input pipe. The space is formed in a vacuum state, and the vacuum degree of the material introduction pipe is the same as that of the vacuum melting chamber, the first and second molten metal insulation tubes, the first vacuum valve is opened, and the charging plunger is advanced to light metal. A step of charging light metal raw materials to charge the raw materials into the vacuum melting chamber (S2);

Melting the light metal raw material in the vacuum melting chamber by operating a heating unit for melting, and melting the light metal raw material by stirring the molten metal by operating an electronic stirring unit;

Temporarily storing the molten metal in the first and second molten metal heat insulating tubes through the vacuum melting chamber, and insulating the molten metal in the first and second molten metal heat insulating tubes by the heating operation of the heat insulating heating unit. It includes; the thermal insulation step (S4) of the molten metal.

The predetermined amount of molten metal is stored and stored in the vacuum melting chamber, the first and second molten metal insulation tubes by repeating the preparing of the light metal raw material (S1), the filling of the light metal raw material (S2), and the melting of the light metal raw material (S3). Characterized in that.

In the warming step of the molten metal, the molten metal is characterized in that it is kept at a temperature of about 10 ~ 200 ℃ lower than the melting point of the light metal raw materials.

According to the present invention as described above, the first and second material injection pipes can be fed into the light metal raw material in a high vacuum state by a plurality of vacuum valves on the outside of the vacuum melting chamber, and vacuum melting operation in the vacuum melting chamber is very high. There is an advantage that is made smoothly.

In addition, the present invention by disposing a heating unit on the outside of the vacuum melting chamber, an electronic stirring unit on the outside of the heating unit to significantly improve the dissolution efficiency of light metal raw materials and to significantly improve the degassing effect and light metal alloy There is an advantage that the composition of the molten metal becomes uniform.

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

1 is a partial cutaway perspective view showing a light metal vacuum melting apparatus according to an embodiment of the present invention.

As shown, the light metal vacuum melting apparatus according to the present invention is a vacuum melting chamber 10, the first material input pipe 40, the first material input pipe (40) which is communicatively connected to one side of the vacuum melting chamber 10 ( 40 and the first and second vacuum valves 30 and 50 respectively installed at both ends of the first material introduction pipe 40 and the first material introduction pipe 40 connected between the vacuum melting chamber 10 and the vacuum melting. The first molten metal heat insulating tube 70 communicated with the other side of the chamber 10, and the second molten metal heat insulating tube 80 communicating with the first molten metal heat insulating tube 70.

In the vacuum melting chamber 10, a molten metal is accommodated therein, and an air discharge pipe 11 is provided on an upper side thereof, and an air discharge valve is installed in the air discharge pipe 11. Through the air discharge valve and the air discharge pipe 11, the interior of the vacuum melting chamber 10 is in a vacuum state.

The heating unit 15 for melting is disposed on the outer circumferential surface of the vacuum melting chamber 10, in particular, the lower outer circumferential surface, and the melting heating unit 15 is a kind of electric heating device and a light metal that is introduced into the vacuum melting chamber 10. It is configured to apply a predetermined heat to melt the raw material 1.

The electromagnetic stirring unit 16 is disposed outside the heating unit 15 for melting, and is provided with a spiral coil 16a therein to generate an electromagnetic field as electricity is applied to the coil 16a side. It is composed. By stirring the molten metal 2 by the electromagnetic field of the electromagnetic stirring unit 16, there is an advantage that the degassing effect in the molten metal 2 can be enhanced.

One side of the vacuum melting chamber 10 is connected to the first material input pipe 40 in communication with each other, the second material input pipe 42 between the first material input pipe 40 and the vacuum melting chamber 10 is Connected.

One end of the second material introduction pipe 42 is directly connected to one side of the vacuum melting chamber 10, and the other end of the second material introduction pipe 42 is connected to the first material introduction pipe 40. . A flange 42a is formed at the other end of the second material introduction pipe 42, and the flange 42a is sealingly coupled to one side of the valve housing 33 of the first vacuum valve 30.

The light metal raw material 1 is introduced into the inner space of the first material input pipe 40 and the second material input pipe 42, and an air discharge pipe 41 is installed at one side of the first material input pipe 40. The air discharge valve 41 is provided with an air discharge valve. First and second vacuum valves 30 and 50 are installed at both ends of the first material input pipe 40, respectively, and the air discharge pipe 41 and the first and second vacuum valves 30 and 50 may be operated together. As a result, the internal space of the material introduction pipe 40 is in a vacuum state. Flanges 40a and 40b are formed at both ends of the first material input pipe 40, respectively, and the first and second vacuum valves 30 and 50 are individually sealed to the flange of the first material input pipe 40. do.

The first vacuum valve 30 is the valve housing 33, the drive cylinder 35 installed on the upper end of the valve housing 33, the operation rod 34 which is operated up and down by the drive cylinder 35, the operation rod 34 The valve body 31 provided in the edge part is provided.

Both sides of the valve housing 33 are sealingly coupled to the other end flange 42a of the second material input pipe 42 and one end flange 40a of the first material input pipe 40, respectively.

As the hydraulic cylinder or the pneumatic pressure is applied to the driving cylinder 35, the operation rod 34 is operated up and down, and the valve body 31 is operated by the operation of the operation rod 34 up and down by the other material input pipe 42. The stage and one end of the first material input pipe 40 are opened and closed.

The second vacuum valve 50 includes a valve housing 53, a driving cylinder 55 installed at an upper end of the valve housing 53, an operation rod 54 operating up and down by the driving cylinder 55, and an operation rod 54. The valve body 51 provided in the edge part is provided.

The other end flange 40b of the first material input pipe 40 is sealingly coupled to the valve housing 53.

As the hydraulic cylinder or pneumatic pressure is applied to the driving cylinder 55, the operation rod 54 is operated up and down, and the valve body 51 is connected to the other end of the first material input pipe 40 by the operation of the operation rod 54 up and down. Open and close The valve body 51 has a plug hole 51a on one side thereof, and is configured such that the charging plunger 60 is inserted into the plug hole 51a. Accordingly, even when the valve body 51 of the second vacuum valve 50 closes the other end of the first material injection pipe 40, the charging plunger 60 can move forward while penetrating the plug hole 51a. By the forward operation of the charging plunger 60, the light metal raw material 1 can be charged into the vacuum melting chamber 10.

A material input support 66 is disposed behind the second vacuum valve 50, and the material input support 66 has an arc-shaped cross section. A charging plunger 60 is installed at the rear of the material input support 66 so as to be able to move back and forth. In the material input support 66, a light metal raw material 1 in a solid state is located, and the light metal raw material 1 is connected to the first material input pipe 40 and the second material input pipe 42 by the charging plunger 60. You can move inside.

The other side of the vacuum melting chamber 10 is inclinedly communicated with the first molten metal insulation tube 70 at a predetermined angle, and the second molten metal insulation tube 80 is obliquely communicated with the first molten metal insulation tube 70 at a predetermined angle.

A molten valve cylinder 90 is installed at an upper end of the second molten metal heat insulating tube 80, and an operating rod 91 and an upper and lower operation operated by the molten valve cylinder 90 are operated inside the second molten metal heat insulating tube 80. The molten valve body 85 provided in the edge part of the rod 91 is provided. Thus, the hydraulic rod or the pneumatic pressure is applied to the molten valve cylinder 90, the operation rod 91 is operated up and down, and the molten valve body 85 is configured to open and close the injection hole of the second molten metal insulation tube 80. .

In addition, an insulating heating unit 75 may be disposed on the outer circumferential surfaces of the first and second molten metal insulating tubes 70 and 80, and the insulating heating unit 75 is a kind of electrical heating device. 2 It is configured to prevent the solidification of the molten metal and to keep warm by applying a predetermined heat to the molten heat insulating tube (70, 80) side.

The mold casting machine of various structures is connected to the injection hole of the second molten metal heat insulating tube 80, and the die casting machine of the present invention is a die casting machine (patent registration No. 10-0578257) and a vertical vacuum squeeze casting machine (patent of the present invention). 10-0572583), vertical vacuum forging machine (Patent Registration No. 10-0572589), vacuum gravity mold casting machine (Patent Registration No. 10-0572581) and the like may be referred to.

2 to 14 will be described in detail the operating relationship of the vacuum melting apparatus of the present invention and the vacuum melting method of the present invention with reference to the same.

S1: preparation of light metal raw materials

First, as shown in FIG. 2, after the molten valve body 85 and the first and second vacuum valves 30 and 50 are closed, the vacuum melting chamber 10 is opened by opening the air discharge valve of the air discharge pipe 11. ), The second material injection tube 42, the first and the second molten metal insulation tube (70, 80) inside to form a vacuum. Then, the light metal raw material 1 is placed in the material input support 66.

Subsequently, the second vacuum valve 50 is opened as shown in FIG. 3, and the charging plunger 60 is advanced as shown in FIG. 4 to push the light metal raw material 1 into the first material input pipe 40.

S2: Loading stage of light metal raw materials

After the charging plunger 60 is reversed as shown in FIG. 5, the second vacuum valve 50 is closed and operated as shown in FIG. 6, and then the charging plunger 60 is advanced again to the plug hole 51a of the valve body 51. Insert it. Thus, the charging plunger 60 closes the plug hole 51a of the valve body 51. In such a state, the air discharge valve of the air discharge pipe 41 is opened to form the internal space of the first material input pipe 40 in a vacuum state.

Then, when the degree of vacuum in the first material input pipe 40 is equal to the degree of vacuum of the vacuum melting chamber 10, the second material input pipe 42, and the first and second molten metal heat insulating pipes 70 and 80. As shown in FIG. 7, the air discharge valve of the air discharge pipe 41 is closed, and the first vacuum valve 30 is opened.

Subsequently, the charging plunger 60 is advanced as shown in FIG. 8 to charge the light metal raw material 1 into the vacuum melting chamber 10, and the charging plunger 60 is reversed as shown in FIG. 9 and the first vacuum valve ( 30) close. At this time, the charging plunger 60 moves backward to maintain the plug hole 51a of the second vacuum valve 50 in a closed state.

Thereafter, as shown in FIG. 10, the charging plunger 60 is reversed so as to be separated from the plug hole 51a of the second vacuum valve 50, thereby destroying the internal vacuum of the first material injection pipe 40.

S3: melting of light metal raw materials

As shown in FIG. 11, the light metal raw material 1 charged in the vacuum melting chamber 10 is melted by operating the heating unit 15 for melting. Then, the electromagnetic stirring unit 16 is operated to generate an electromagnetic field by the coil 16a of the electromagnetic stirring unit 16, and the light metal raw material 1 is stirred while the electromagnetic field is melted. As it is stirred by the electromagnetic field as described above, the gas inside the molten metal 2 is effectively separated, and furthermore, since the inside of the vacuum melting chamber 10 is in a vacuum state, the degassing effect is further maximized, and the composition of the molten metal alloy The molten metal 2 stored in the vacuum melting chamber 10 by being uniform has an advantage in that its quality is very high.

S4: Insulating step of molten metal

Then, by repeatedly performing the operations of FIGS. 2 to 11, as shown in FIG. 12, a predetermined amount of the molten metal 2 can be kept warm in the vacuum melting chamber 10 and the first and second molten thermal insulation tubes 70 and 80. have.

At this time, the molten metal 2 in the first and second molten metal heat insulating tubes 70 and 80 by the heating operation of the heating unit 75 for warming is kept warm in a state where the solidification is prevented and is kept constant. At this time, the molten metal 2 is kept at a temperature about 10 to 200 ° C. lower than the melting point of light metal raw materials.

S5: tapping stage of molten metal

Then, as shown in FIG. 13, the molten metal valve 85 is opened to tap the molten metal 2 to a mold casting machine (not shown), and the molten metal valve body 85 is closed as shown in FIG. It can be temporarily stored in the first and second molten metal insulation tube (70, 80).

1 is a partial cutaway perspective view showing a vacuum melting apparatus of a light metal according to an embodiment of the present invention.

2 to 4 is a view showing a step of preparing a light metal raw material according to the present invention.

5 to 10 is a view showing a charging step of the light metal raw material according to the present invention.

11 is a view showing a melting step of light metal raw materials according to the present invention.

12 is a view showing a step of keeping the molten metal according to the present invention.

13 and 14 are views showing the tapping step of the molten metal according to the present invention.

<Brief description of symbols for the main parts of the drawings>

10: vacuum melting chamber 11: air exhaust pipe

30, 50: first and second vacuum valve 40: first material input pipe

41: air discharge pipe 42: second material input pipe

60: charging plunger 66: material input support

70: first molten metal heat insulating tube 80: second molten metal heat insulating tube

Claims (8)

Vacuum melting chamber provided with an air discharge pipe on the upper side; A first material input pipe connected to one side of the vacuum melting chamber and communicatively connected to one side of the vacuum melting chamber; A second material introduction tube connected between the first material introduction tube and the vacuum melting chamber; A heating unit for melting installed on an outer side of the vacuum melting chamber; An electronic stirring unit installed outside the heating unit for melting and having a spiral coil embedded therein; First and second vacuum valves installed at both ends of the first material input pipe; A first molten metal heat insulating tube communicating with the other side of the vacuum melting chamber; And And a second molten metal heat insulating tube communicating with the first molten metal heat insulating tube. And the heating unit for melting is disposed on the lower outer peripheral surface of the vacuum melting chamber, and the heating unit for thermal insulation is disposed on the outer peripheral surfaces of the first and second molten metal heat insulating tubes. delete The method of claim 1, A light metal vacuum melting apparatus using an electronic stirrer, wherein a material input support is disposed at the rear of the second vacuum valve, and a charging plunger is installed at the rear of the material input support to enable forward and backward movement. The method of claim 1, The first and second vacuum valves are provided with a valve housing, a drive cylinder installed at an upper end of the valve housing, an operating rod vertically operated by the drive cylinder, and a valve body provided at an end of the operating rod, respectively. The valve body of the second vacuum valve has a plug hole on one side thereof, the light metal vacuum melting apparatus using electromagnetic stirring characterized in that the plug plunger is configured to be inserted into the plug hole. The method of claim 1, A molten metal valve cylinder is installed at an upper end of the second molten metal heat insulating tube, and an operating rod vertically operated by the molten metal valve cylinder and a molten valve body installed at an end of the operating rod are installed inside the second molten metal heat insulating tube. Light metal vacuum melting apparatus using an electronic stirring. A vacuum melting method using the vacuum melting apparatus according to any one of claims 1 and 3 to 5, By closing the first vacuum valve and the molten valve body and opening the upper air discharge pipe of the vacuum melting chamber, the inside of the vacuum melting chamber, the first and second molten metal heat insulating tubes are vacuumed, and the second vacuum valve is A step (S1) of preparing a light metal raw material for advancing the charging plunger and opening the light metal raw material into the first material input pipe after opening; After the charging plunger is reversed and the second vacuum valve is closed, the charging plunger is advanced again to close the plug hole of the second vacuum valve, and then open the air discharge pipe on one side of the first material input pipe to open the inside of the first material input pipe. The space is formed in a vacuum state, and the vacuum degree of the material introduction pipe is the same as that of the vacuum melting chamber, the first and second molten metal insulation tubes, the first vacuum valve is opened, and the charging plunger is advanced to light metal. A step of charging light metal raw materials to charge the raw materials into the vacuum melting chamber (S2); Melting the light metal raw material in the vacuum melting chamber by operating a heating unit for melting, and melting the light metal raw material by stirring the molten metal by operating an electronic stirring unit; The molten metal is temporarily stored in the first and second molten metal heat insulating tubes through the vacuum melting chamber, and is heated to prevent solidification of the molten metal in the first and second molten metal heat insulating tubes by the heating operation of the heat insulating heating unit. Insulation step (S4) of the light metal vacuum melting method using an electronic stirring comprising a. The method of claim 6, The predetermined amount of molten metal is stored and stored in the vacuum melting chamber, the first and second molten metal insulation tubes by repeating the preparing of the light metal raw material (S1), the filling of the light metal raw material (S2), and the melting of the light metal raw material (S3). Light metal vacuum melting method using an electronic stirring, characterized in that. The method of claim 6, In the warming step of the molten metal, the molten metal is a light metal vacuum melting method using an electronic stirring, characterized in that to be kept at a temperature 10 ~ 200 ℃ lower than the melting point of the light metal raw materials.

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