KR20210031302A - Aluminum Lost foam pattern casting method - Google Patents

Abstract

The present invention relates to a first foaming step in which a foamed resin made of polystyrene material is injected into a molding device and foamed, a second foaming step in which the foamed resin foamed by the molding device is introduced into a mold to produce a loss model, and the disappearance Applying a coating agent composed of a combination of silica flower, chamotte, and adhesive on the outer surface of the model to form a coating film on the disappearing model during casting, and placing the disappearing model inside the casting box, and the casting A loss model burying step in which casting sand is put into the empty space of the box to bury the loss model in the inside of the casting box, and a casting box cover is installed on the upper side of the casting box, and a vacuum device is connected to the casting box cover. The vacuum depressurization step of decompressing the inside of the casting box, and the molten aluminum is injected through the molten metal inlet formed in the casting box cover to burn the vanishing model, and the area where the vanishing model is burned is filled with aluminum molten metal. It proceeds including a molten metal injection step of forming a casting product, and a casting discharge step of discharging to the outside of the casting box after the casting product is cured to remove the casting sand attached to the outside of the casting product, and the molten metal The aluminum melting model casting method is provided, characterized in that the aluminum molten metal used in the injection step is injected into the inside of the casting box while heated to a temperature in the range of 800°C to 950°C, which is higher than the melting point temperature of the aluminum molten metal. As a result, when the molten aluminum is injected, the vacuum pressure is lowered than that of the existing vacuum pressure to improve the flowability of the molten metal, and the loss model is completely burned by the molten metal, thereby producing excellent aluminum casting products and minimizing the occurrence of defects. I made it so.

Description

Aluminum lost foam pattern casting method

The present invention relates to an aluminum vanishing model casting method, which is higher than the existing aluminum pouring temperature during aluminum vanishing model casting, and when the molten metal is injected, the vacuum pressure is lower than the existing vacuum pressure to improve the flowability of the molten metal, and the vanishing model. The present invention relates to an aluminum loss model casting method capable of minimizing the problem of defects in the casting due to not being completely burned in the process of being destroyed by this molten metal.

In general, the vanishing model casting method is attracting attention as a casting method that can replace the existing sand casting in that it is eco-friendly, economical, and can obtain a high-quality cast surface similar to the surface of an actual product.

The vanishing model casting method has the characteristic of being injected while the temperature of the molten metal tip is lowered preferentially because the molten metal tip is introduced and the model is decomposed and discharged with the molten metal heat energy, and the molten metal proceeds while replacing its position.

The above-described vanishing model casting method mainly produces various products using cast iron.

The vanishing model casting method uses expanded polystyrene (EPS: Expandable Polystyrene) or polymethacryl (PMMA), which is a raw material such as styrofoam, as a raw material, to make a model molded in the same shape as the casting product to be manufactured, and then on the surface of the model. After applying a water-soluble coating agent, embedding it in non-caking sand (general silica-based sand) and then injecting the molten metal, the embedded model is vaporized under the heat of the molten metal and is discharged into the sand and injected into the space. This is a method of obtaining the desired casting by cooling the molten metal.

The loss-of-casting method as described above is disclosed in Korean Laid-Open Patent Publication No. 10-2007-0089744.

Such a conventional vanishing model casting method is a vanishing model casting method that mainly produces high-quality casting products, and the temperature of the molten metal is approximately 1250℃ to 1330℃, and the molten metal is injected into the model to vaporize the model, and This is injected and the cast product is molded.

However, unlike cast iron, the vanishing model casting method using aluminum mostly consists of a melting point of about 600℃~700°C, so that the vanishing model made of foam resin cannot be completely burned, resulting in defects in the aluminum casting product. have.

In addition, the general vanishing model casting method is to install a model made of foam resin inside the casting box, fill the casting sand inside the casting box, and inject the molten metal into the model. In this process, the model is completely burned. It is replaced by molten metal.

In the process of injecting the molten metal, a vacuum device is generally connected to inject the molten metal in a state where vacuum pressure is applied to the inside of the casting box, and in the general vanishing model casting method, a vacuum pressure of 50 to 60 bar is applied to the casting sand.

This conventional vacuum pressure is the vacuum pressure used in cast iron, and when it is applied to the aluminum vanishing model casting method, the gas generated in the combustion process of the vanishing model cannot be discharged to the casting sand side due to high vacuum pressure. There is a problem in that this is a cause of defects in the casting as it falls, and the combustion gas remains in the formation part of the casting.

Republic of Korea Patent Publication No. 10-2007-0089744

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, and the object of the present invention is to make the aluminum pouring temperature higher than the aluminum pouring temperature during aluminum vanishing model casting, and to reduce the vacuum pressure when injecting the aluminum molten metal to the existing vacuum pressure. It is intended to provide a method for casting an aluminum vanishing model that can improve flowability of the molten metal by lowering it, and produce an excellent aluminum casting product by completely burning the vanishing model by the molten metal, and minimize the occurrence of defects.

According to a feature of the present invention for achieving the above object, the aluminum vanishing model casting method according to the present invention includes a first foaming step of introducing and foaming a foamed resin made of a polystyrene material into a molding apparatus, and the molding apparatus. The second foaming step of producing a vanishing model by putting the foamed resin foamed by the mold, and applying a coating agent composed of a combination of silica flower, chamotte, and adhesive to the outer surface of the vanishing model to the vanishing model when casting. A painting agent coating step of forming a painting film, and a vanishing model embedding step of placing the vanishing model in the inside of the casting box and inserting the casting sand into the empty space of the casting box to bury the vanishing model inside the casting box; and , A casting box cover is installed on the upper side of the casting box, a vacuum device is connected to the casting box cover to depressurize the inside of the casting box, and molten aluminum through the molten metal injection port formed in the casting box cover. A molten metal injection step in which molten aluminum is filled in the area where the vanishing model is burned to form a casting product, and discharged to the outside of the casting box after the casting product is cured. Including a casting discharge step of removing the casting sand attached to the outside of the casting product, the use temperature of the aluminum molten metal used in the molten metal injection step is in the range of 800 ℃ ~ 950 ℃ that is a temperature higher than the melting point temperature of the aluminum molten metal It is characterized in that it is injected into the inside of the casting box in a heated state.

Here, in the vacuum depressurization step, the vacuum pressure applied to the inside of the casting box is vacuum depressurized in a range of 10 bar to 20 bar.

In addition, the coating agent used in the coating agent application step is made of silica flower, chamotte, and adhesive, and the mixing ratio of each component is 1:0.4:0.05.

In addition, a drying step is further performed between the molten metal injection step and the casting discharge step, and in the drying step, after the molten aluminum is injected into the casting box, it is naturally dried for a certain period of time, and the inside of the casting box , It is characterized in that the internal heat of the casting box is discharged through a plurality of through-holes formed to communicate with the outside and naturally dried.

In addition, a gate installation step is further performed between the second foaming step and the coating agent coating step, and in the gate installation step, a gate made of styrofoam is attached to the molten metal input side of the vanishing model and burned when the molten metal is injected, It is characterized in that it forms an input path of the molten metal inside the casting sand.

The aluminum loss model casting method of the present invention as described above, while molten aluminum is injected into the loss model foamed with polystyrene, the loss model is completely burned without remaining in the casting, and excellent aluminum casting products of the same shape as the loss model are produced. There is an effect that can be produced.

In addition, the foaming resin used in the aluminum vanishing model casting method of the present invention can produce a vanishing model of a thin thickness without rough surface by producing a vanishing model using a polystyrene raw material having a small particle size. There is an effect that an excellent casting product can be produced that is produced in a thin thickness without having a rough surface in the same shape.

In addition, the aluminum vanishing model casting method of the present invention, when the molten metal is injected into the vanishing model seated inside the casting box filled with the casting sand, the molten metal is transferred to the outside of the vanishing model by the coating film applied to the outer surface of the vanishing model. While preventing discharge, the gas generated while the burnout model is burned can be provided so as to be discharged to the outside of the burnout model. It has the effect of having both strength and breathability.

In addition, the aluminum dissipation model casting method of the present invention occurs when the dissipation model is burned by using the aluminum molten metal heated to a temperature in the range of 800°C to 950°C, which is higher than the temperature of the aluminum molten metal used in general aluminum casting. In addition to reducing the amount of gas, there is an effect of having high flowability of the molten metal.

1 is a block diagram showing a manufacturing process of an aluminum vanishing model casting method according to a preferred embodiment of the present invention
Figure 2 is a cross-sectional view showing a state in which the vanishing model is seated in the casting box constituting a preferred embodiment of the present invention, and the casting sand is filled.
3 is a cross-sectional view illustrating another embodiment according to the present invention showing a through hole of a casting box in FIG. 2 and a state in which an outer case is coupled to the casting box

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the aluminum vanishing model casting method according to the present invention will be described in detail.

1 is a block diagram showing the manufacturing process of the aluminum vanishing model casting method according to a preferred embodiment of the present invention, and Figure 2 is a vanishing model is seated inside a casting box constituting a preferred embodiment of the present invention. , A cross-sectional view showing a state in which the casting sand is filled is shown, and FIG. 3 is a cross-sectional view showing another embodiment according to the present invention showing a state in which the through hole of the casting box and the outer case are coupled to the casting box in FIG. 2 Is shown.

As shown in these drawings, the aluminum vanishing model casting method according to the present invention includes a first foaming step (S10) of introducing a foamed resin made of polystyrene material into a molding apparatus and foaming, and foaming foamed by the molding apparatus. In the second foaming step (S20) of injecting a resin into the mold to produce the vanishing model 100, and casting a coating agent composed of a combination of silica flower, chamotte, and adhesive on the outer surface of the vanishing model 100 A coating agent coating step (S40) of forming a coating film 200 on the casting sand, and the vanishing model 100 is placed inside the casting box 300, and the casting sand 10 is placed in the empty space of the casting box 300. ) To bury the vanishing model 100 inside the casting box 300 (S50), and the casting box cover 400 is installed on the upper side of the casting box 300, and the A vacuum device 421 is connected to the casting box cover 400 to depressurize the inside of the casting box 400 (S60), and the molten metal injection port 410 formed in the casting box cover 400 is provided. A molten metal injection step (S70) in which molten aluminum is injected to burn the vanishing model 100 by burning the vanishing model 100, and the molten aluminum is filled in the area where the vanishing model 100 is burned to form a casting product, and the casting product is After curing, it includes a casting discharge step (S90) of discharging to the outside of the casting box 300 to remove the casting sand 10 attached to the outside of the casting product, and used in the molten metal injection step (S70) The use temperature of the aluminum molten metal is characterized in that it is injected into the casting box 300 in a heated state in the range of 800°C to 950°C, which is a temperature higher than the melting point temperature of the aluminum molten metal.

Looking at the aluminum vanishing model casting method as described above step by step in the manufacturing process, as follows.

First, the first foaming step (S10) and the second foaming step (S20) will be described.

The first foaming step (S10) is a process in which a foaming resin containing expanded polystyrene (EPS) or polymethacryl (PMMA) as a raw material is introduced into a molding apparatus (not shown) and foamed.

Such a foaming resin is a foam molding material for manufacturing the vanishing model 100, and the vanishing model 100 is a material that can be burned or vaporized from the heat of the molten metal and lose its shape, and the particle size is 1.0 It is preferable to use a foam resin consisting of mm ~ 1.8mm.

This is generally smaller than the average particle size of the foamed resin used in the vanishing model casting, which is 2.6mm, so that the surface is not rough and it is possible to manufacture the vanishing model 100 having a thin thickness.

Thereafter, in the second foaming step (S20), the foaming resin foamed by the molding apparatus is put into a mold (not shown) having the shape of the disappearance model 100, so that the disappearance model 100 is manufactured. It's a process.

The foaming resin injected into the mold is dried for a certain period of time, and the vanishing model 100 is produced, and the vanishing model 100 has a substantially the same shape as the final cast product.

Here, since the first foaming step (S10) and the second foaming step (S20) are general processes of foaming a foaming resin to form the disappearance model 100, a detailed description of the foaming process will be omitted.

In addition, a gate installation step (S30) in which the gate 110 is attached to any one portion of the vanishing model 100 manufactured through the second foaming step (S20) is further performed.

The gate 110 is an input path for injecting molten metal into the vanishing model 100 seated in the casting box 300, and the casting box of the gate 110 from any one portion of the vanishing model 100 It is formed extending to the cover 400. This is as shown in FIG. 2 attached.

It is preferable that the gate 110 is made of a styrofoam material that can be burned when molten metal is injected, or is made of the above-described foaming resin.

Next, the coating agent application step (S40) will be described.

The coating agent application step (S40) is a step of forming the coating film 200 on the vanishing model 100 and the gate 110 manufactured through the above-described steps (S10, S20, S30).

The coating layer 200 is formed by applying a coating agent to all outer surfaces of the vanishing model 100 and the gate 110 and drying the coating material.

When the vanishing model 100 and the gate 110 are lost by the drawing layer 200, the shape of the vanishing model 100 can be maintained.

Here, the disappearance model 100 and the gate 110 are lost, and in order to maintain the shape of the disappearance model 100, the painting film 200 is applied to the pressure applied from the inside or from the outside by the disappearance model 100. It is preferable that the coating film 200 has high strength so that the shape of) is not easily deformed.

In addition, as the high-temperature molten metal is injected into the vanishing model 100, the drawing film 200 preferably has high strength and fire resistance as described above.

Here, the coating agent is made of silica flour, chamotte, and adhesive, and the mixing ratio of each component is preferably prepared by mixing 1:0.4:0.05.

The silica flower is a silica powder having a small particle size and is used to improve high temperature strength with excellent fire resistance, and the chamotte has a particle size larger than that of the silica flower, and is a high calcined powder of alumina clay by firing the clay once. The furnace has a high degree of fire resistance and has the effect of reducing hot deformation and shrinkage even at firing temperature, so that high fire resistance against high temperature molten metal can be achieved.

Such a coating agent is mixed with the adhesive at a higher ratio than the chamotte, so that the silica flower having a small particle size can form the coating film 200 with a small gap, thereby having high strength. Even if the molten metal is injected into (100), it is not discharged to the outside of the vanishing model (100).

In addition, gas generated when the vanishing model 100 is burned has air permeability capable of being discharged to the outside of the vanishing model 100 through the painting film 200.

As such, the coating agent can form the coating film 200 having high strength, fire resistance, and breathability even with a simple combination of components.

Next, the vanishing model embedding step (S50) will be described.

The vanishing model burying step (S50) is a step of embedding the vanishing model 100 to which the drawing film 200 is applied in the casting box 300.

That is, the vanishing model 100 on which the drawing film 200 manufactured in the above-described process is formed and the gate 110 attached thereto are seated in the casting box 300.

At this time, the end of the gate 110 is positioned above the casting box 300 to communicate with the molten metal injection port 410 formed in the casting box cover 400. This is as shown in FIG. 2 attached.

Thereafter, while the casting sand 10 is poured into the casting box 300, the vanishing model 100 and the gate 110 are buried in the casting sand 10.

Here, the vanishing model 100 is completely buried by the casting sand 10, but the end of the gate 110 is not completely buried in the casting sand 10 so as to communicate with each other with the molten metal injection port 410 as described above. Do not.

At this time, it is important that the casting sand 10 is completely filled around the vanishing model 100 inside the casting box 300, and the casting sand 10 is densely filled around the vanishing model 100. This is because defects such as collapse of the vanishing model 100 and the coating film 200 between castings, sintering of the casting sand, deformation of the casting, or defects in dimensionality occur.

Therefore, by vibrating the casting box 300 with a vibration device (not shown) so that the casting sand 10 is uniformly and densely filled in the casting box 300, the casting sand 10 When injected into 300), it is preferable that the casting sand 10 fills the periphery of the loss model (!00) tightly and is flattened.

In other words, the casting sand 10 injected into the casting box 300 is uniformly and densely filled in the casting box 300 by the vibration of the casting box 300, and the casting box ( The vibration device for the vibration of 300) is a vertical one-axis vibration, a horizontal vibration, or a vertical and horizontal multi-axis vibration, and a circular vibration that makes a two-dimensional circular motion on the receiving surface.

Next, the vacuum pressure reduction step (S60) will be described.

The vacuum depressurization step (S60) is a step of forming a vacuum decompression in the casting box 300 to harden the casting sand 10 filled in the casting box 300.

In the vacuum depressurization step (S60), the vanishing model 100 is seated, and the casting box cover 400 is installed on the upper side of the casting box 300 completely buried with the casting sand 10, while the casting box 300 The inside of) blocks it from the outside.

At this time, the molten metal injection port 410 formed in the casting box cover 400 is aligned with the position of the end of the gate 110.

Thereafter, as shown in FIG. 2, the vacuum device 421 is connected from the pressure reducing port 420 formed in the casting box cover 400, and then the vacuum device 421 is operated to the casting box 300. The inside is decompressed, and the casting sands 10 filled therein are in close contact with each other and are hardened.

In this process, when the inside of the casting box 400 is depressurized, even if the burnout model 100 is burned and burned, it is necessary to maintain the casting shape by the above-described painting film 200, but the casting sand ( If 10) is not tightly compacted in the casting box 300, it is difficult to maintain the above-described casting shape. This is a process in which the casting sand 10 fills the periphery of the loss model 100 more densely.

Here, the vacuum pressure applied to the inside of the casting box 300 by the vacuum device 421 is preferably reduced to a vacuum in the range of 10 bar to 20 bar, and 50 bar, which is the vacuum pressure in the depressurization step made in the conventional vanishing model casting. If the vacuum pressure is reduced in the range of ~60 bar, the coating film 200 may be decomposed by the reduced pressure, or gas generated when the vanishing model 100 is burned may not be discharged.

Therefore, in the aluminum vanishing model casting method according to the present invention, even if the vacuum pressure applied to the inside of the casting box 300 is vacuum-depressed in the range of 10 bar to 20 bar, the above-described painting film 200 has sufficient rigidity and gas discharge. Ventilation can be secured.

In addition, in the case of vacuum decompression with too strong vacuum pressure, when the molten metal is injected into the vanishing model 100, the flow of the injected molten metal is disturbed due to the strong pressure to the vanishing model 100, and soot is generated in the casting product. Defective products may be produced, but when the vacuum pressure is reduced in the range of 10 bar to 20 bar described above, the molten metal injected into the vanishing model 100 may be smoothly flowed.

Of course, the pressure reducing port 420 to which the vacuum device 421 is connected is not limited to that formed in the casting box cover 400, and if the inside of the casting box 300 can be depressurized, the casting box cover (400) Alternatively, any portion of the casting box 300 may be formed.

Next, the molten metal injection step (S70) will be described.

The molten metal injection step (S70) is a process of injecting molten aluminum into the vanishing model 100 to form an aluminum casting product.

In this molten metal injection step (S70), the aluminum molten metal is injected through the molten metal injection port 410.

Accordingly, the aluminum molten metal is injected into the vanishing model 100 along the gate 110, and at this time, the gate 110 and the vanishing model 100 are burned by the high temperature of the molten metal. The molten aluminum is filled to form a casting product.

That is, a casting product having the same shape as the vanishing model 100 and the gate 110 is formed.

On the other hand, the aluminum molten metal is not discharged by the drawing film 200 and is filled along the inner shape of the vanishing model 100 and the gate 110, but as the vanishing model 100 and the gate 110 are burned, The generated gas escapes through the coating layer 200.

Here, the use temperature of the aluminum molten metal is preferably heated to a temperature in the range of 800°C to 950°C, which is higher than the melting point temperature of the aluminum molten metal (600°C to 700°C).

The use temperature of the aluminum molten metal used in the molten metal injection step (S70) is higher than 700°C to 720°C, which is an appropriate use temperature of the aluminum molten metal used in the conventional vanishing model casting.

This is because the high-temperature aluminum molten metal raised to a temperature at which the coating layer 200 is not decomposed can reduce the amount of gas generated when the burnout model 100 is burned than the molten metal having a lower temperature.

The amount of gas generated while the burnout model 100 is burned has a great influence on forming a casting product, and a casting product in which a large amount of such gas is generated has a high defect rate.

Meanwhile, in the molten metal injection step (S70), it may be performed together with the vacuum depressurization step (S60). This means that the vacuum device 421 continues while the molten aluminum is injected and filled into the vanishing model 100 and the gate 110, and until the injected molten aluminum is completely solidified after filling is completed. This is because it is helpful in discharging the gas generated while the burnout model 100 and the gate 110 are burned through the painting film 200 by activating the ignition model 100 and the gate 110.

Accordingly, in the molten metal injection step (S70), the aluminum molten metal filled in the same shape at the location where the vanishing model 100 and the gate 110 are lost is hardened to form a cast aluminum product.

Meanwhile, a drying step (S80) is further performed to dry the molten aluminum to form a casting product.

This drying step (S80) is a process of cooling the molten aluminum filled in the vanishing model 100 and the gate 110, and curing the cast product formed while naturally drying the casting box 300 for a predetermined period of time.

Here, in the drying step (S80), depending on the environment, wind such as hot air or cold air may be applied to the casting box 300 and dried.

In addition, as shown in the accompanying Figure 3, by discharging the internal heat of the casting box 300 through a plurality of through-holes 310 formed to communicate with the inside and outside of the casting box 300, quick drying is achieved. I can.

Of course, in the case of the embodiment in which the through hole 310 is formed in the casting box 300, it is preferable that an outer case 500 surrounding the outside of the casting box 300 is further provided, and the drying step (S80) ), the outer case 500 is configured to be detachable from the casting box 300 for natural drying.

Finally, the casting discharge step (S90) will be described.

In the casting discharge step (S90), the hardened casting product is discharged from the casting box 300 and the attached casting sand 10 is removed to complete the aluminum casting product.

That is, after the casting product is completely cured inside the casting box 300, the casting sand 10 and the cured casting product are discharged from the casting box 300, and the casting sand attached to the outside of the casting product Separate (10).

At this time, the separated casting sand 10 can be recycled again.

And, after removing the drawing film 200 attached to the casting product, the shape of the gate 110 is removed, leaving the shape of the vanishing model 100 in the final finished product state of the product, and smoothing the surface of the casting product. Processing to complete the production of the final aluminum casting product.

Eventually, the aluminum loss model casting method of the present invention is the same as the loss model 100, while the aluminum molten metal is injected into the loss model 100 foamed with polystyrene, the loss model 100 is completely burned without remaining in the casting. It can produce aluminum casting products of excellent shape.

In addition, the foaming resin used in the aluminum vanishing model casting method of the present invention can produce the vanishing model 100 having a thin thickness without having a rough surface by producing the vanishing model 100 using a polystyrene raw material having a small particle size. Accordingly, it is possible to produce an excellent casting product that is produced in the same shape as the vanishing model 100 and not having a rough surface and having a thin thickness.

The scope of the present invention is not limited to the embodiments illustrated above, and many other modifications based on the present invention will be possible for those skilled in the art within the above technical scope.

S10. 1st foaming step S20. 2nd foaming step
S30. Gate installation step S40. Coating agent application step
S50. Vanishing model burial step S60. Vacuum decompression step
S70. Molten metal injection step S80. Drying step
S90. Casting discharge step 10. Foundry sand
100. Vanishing model 110. Gate
200. Shape film 300. Casting box
310. Through hole 400. Casting box
410. Molten metal injection port 420. Pressure reducing port
421. Vacuum device 500. Outer case

Claims (5)

A first foaming step (S10) of foaming by introducing a foamed resin made of polystyrene material into a molding apparatus;
A second foaming step (S20) of producing a loss model 100 by injecting the foamed resin foamed by the molding apparatus into a mold;
A coating agent coating step (S40) of forming a coating film 200 on the vanishing model 100 by applying a coating agent composed of a combination of silica flower, chamotte, and adhesive to the outer surface of the vanishing model 100 and forming a coating layer 200 on the vanishing model 100 when casting. ;
The vanishing model 100 is seated inside the casting box 300, and the casting sand 10 is put into the empty space of the casting box 300, and the vanishing model 100 is placed inside the casting box 300. A vanishing model burying step (S50) of burying;
The casting box cover 400 is installed on the upper side of the casting box 300, and a vacuum device 421 is connected to the casting box cover 400 to decompress the inside of the casting box 400 ( S60) and;
The molten aluminum is injected through the molten metal inlet 410 formed in the casting box cover 400 to burn the dissipation model 100, and the molten aluminum is filled in the area where the dissipation model 100 is burned. Injecting a molten metal to form a product (S70);
And a casting discharge step (S90) of discharging to the outside of the casting box 300 after the casting product is cured to remove the casting sand 10 attached to the outside of the casting product;
The use temperature of the molten aluminum used in the molten metal injection step (S70) is characterized in that the molten metal is injected into the casting box 300 while heated to a temperature in the range of 800°C to 950°C, which is higher than the melting point temperature of the aluminum molten metal. Aluminum loss model casting method. The method of claim 1, wherein in the vacuum depressurization step (S60),
Aluminum vanishing model casting method, characterized in that the vacuum pressure applied to the inside of the casting box 300 is vacuum reduced to a range of 10 bar to 20 bar. The aluminum vanishing model according to claim 1, wherein the coating agent used in the coating agent application step (S40) is made of silica flower, chamotte, and adhesive, and the mixing ratio of each component is 1:0.4:0.05. Casting method. The method of claim 1, wherein a drying step (S80) is further performed between the molten metal injection step (S70) and the casting discharge step (S90);
In the drying step (S80),
After the molten aluminum is injected into the casting box 300, the casting box 300 is naturally dried for a certain period of time, and then the casting box 300 is formed with a plurality of through holes 310 formed so that the inside and the outside of the casting box 300 communicate with each other. 300) as the internal heat is discharged, and the aluminum vanishing model casting method characterized in that it is dried naturally. The method of claim 1, wherein a gate installation step (S30) is further performed between the second foaming step (S20) and the coating agent coating step (S40);
The gate installation step (S30),
A styrofoam material gate 110 is attached to the molten metal input side of the burnout model 100 to burn when the molten metal is introduced, and to form an input path for the molten metal inside the casting sand.

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