KR102242499B1 - Keep warming furnice of exact quantity - Google Patents

Abstract

The present invention relates to an aluminum quantitative warmth-keeping furnace and, more specifically, to an aluminum quantitative warmth-keeping furnace formed to enable one single person to easily and safely open an upper cover of a molten metal warmth-keeping furnace for injecting aluminum molten metal into a mold by receiving the same from a smelting furnace, and prevent the molten metal from containing foreign substances while stabilizing the injection of the molten metal. According to an advisable embodiment of the present invention, when molten metal melted in a smelting furnace is injected into a molten metal storage body, an inlet is formed to be inclined, and an inlet partition is formed to prevent molten metal having a different temperature from being suddenly injected into the molten metal storage body, oxidized molten metal can be blocked to make the molten metal have a good quality, and, when the inside of the molten metal storage body is confirmed, repaired or cleaned, working efficiency can be high because a user can perform simple work by safely opening a cover on his or her own, and, as molten metal having a different temperature is stably injected into the molten metal storage body, the internal temperature of the molten metal can be prevented from sharply fluctuating, and moreover, the molten metal can be stably supplied into a mold, which can lead to an effect of increasing the quality of a product.

Description

Aluminum fixed heat insulation furnace {KEEP WARMING FURNICE OF EXACT QUANTITY}

The present invention relates to an aluminum quantitative heating furnace, and more specifically, the upper cover of the molten metal heating furnace for receiving the aluminum molten metal from the melting furnace and injecting it into the mold apparatus is formed so that one person can easily and safely open the molten metal. It relates to an aluminum quantitative heating furnace that is stable and does not contain foreign substances in the molten metal.

In general, a die-casting device is used to dissolve the metal into a predetermined product. The die-casting device is divided into a dosing furnace for dissolving the metal at a predetermined temperature, a nozzle device for injecting molten metal dissolved in the dosing furnace, and It consists of a mold device or the like that injects the molten metal injected from the nozzle device and manufactures it in a predetermined shape.

In particular, it is known that aluminum die casting transfers molten metal to a die casting machine in two ways.

In the first method, there is a method of pumping aluminum molten in the open melting furnace 1 into the ladle 2 and putting it into the sleeve of the die casting machine 3 as shown in FIG. 1.

In this case, impurities are picked up from the surface of the molten metal and are dirty, which causes quality problems, and there is a problem that low molten metal is pumped up due to the temperature difference between the surface and the inside of the molten metal. There is a problem such as poor quality of the molten metal due to the action.

In addition to the first method, the second method is a method in which pressure is applied to the molten metal with pneumatic pressure in a closed melting furnace 1 ′ as shown in FIG. 2 and transferred through the transfer ladle 5.

In this case, all the problems of the above open type are solved, but since it is a closed type, the melting furnace and the transfer ladle must be replaced with a cylinder body, so maintenance is difficult, and expensive, ceramic materials are used, and frequent cleaning is required. There were problems such as.

In recent years, the first method is used more than the second method in the case of aluminum die casting due to the difficulty of maintenance and rising prices.

However, the conventional aluminum quantitative heating furnace or dosing furnace for die casting has the following problems.

(1) When receiving the molten metal from the melting furnace, the quality of the molten metal is degraded because foreign substances are injected or the oxidized part of the upper part is mixed and put into the molten metal storage unit.

(2) Since the cover cannot be opened by itself, several people have to work at once for maintenance or cleaning, resulting in poor work efficiency.

(3) When the molten metal is injected into the mold device, the quality of the molded product is degraded because the molten metal of a very suitable temperature cannot be safely supplied.

In order to solve the above problems, the present invention includes a molten metal storage body having an inlet port and a tapping port formed therein, and the upper end thereof being opened; A cover capable of covering the open upper end of the molten metal storage body; In a general aluminum quantitative heating furnace consisting of a transfer means capable of transferring the molten metal storage body up, down, before and after,

The inlet port of the molten metal storage body is formed to be inclined to one side and protrudes, and an inlet partition wall protruding to the lower end is formed at the upper end of the inlet port, and a tapping port partition wall protruding downward so as to be spaced apart from the spout port is formed,

The cover is characterized in that it is formed to be opened by sliding back while the cover body is lifted to the top by a spring and a guide.

According to the aluminum quantitative heating furnace formed in a preferred embodiment of the present invention, the following effects occur.

(1) When the molten metal dissolved in the melting furnace is injected into the molten metal storage body, the inlet port is formed inclined and the inlet partition wall is formed so that the molten metal with different temperatures is not urgently administered to the inside of the molten metal storage body. The quality of the molten metal is good because it can be used.

(2) When checking the inside of the molten metal storage body, maintaining or cleaning the inside of the body, the cover can be opened safely by yourself and can be easily operated, so the work efficiency is high.

(3) When molten metal with different temperatures is introduced into the interior of the molten metal storage body, it stably flows in and the temperature inside the molten metal does not change rapidly, and the quality of the product is improved because the molten metal can be stably supplied to the mold apparatus.

1 is a conceptual diagram of injecting a conventional molten aluminum metal into a mold apparatus.
2 is a conceptual diagram of a warming furnace (dosing furnace) used to inject a conventional molten aluminum metal into a mold apparatus.
Figure 3 is a front conceptual view of an aluminum quantitative heating furnace formed in a preferred embodiment of the present invention.
Figure 4 is a plan cross-sectional view of the molten metal storage body of the aluminum quantitative heating furnace formed in a preferred embodiment of the present invention.
Figure 5 is an AA cross-sectional view of the molten metal storage body of the aluminum quantitative heating furnace formed in a preferred embodiment of the present invention.
Figure 6 is a perspective conceptual view of the guide of the aluminum quantitative heating furnace formed in a preferred embodiment of the present invention.
7 is a side view and an operation side view of a cover part of an aluminum quantitative heating furnace formed according to a preferred embodiment of the present invention.

The present invention includes a molten metal storage body 100 in which the inlet 110 and the tapping port 120 are formed and the upper end is opened; A cover 200 capable of covering the open upper end of the molten metal storage body 100; In a general aluminum quantitative heating furnace consisting of a transfer means 300 capable of transferring the molten metal storage body 100 up, down, before and after,

The inlet 110 of the molten metal storage body 100 is formed to be inclined to protrude to one side, and an inlet partition wall 130 protruding to the lower end is formed at the upper end of the inlet 110, and the tapping port 120 and The tapping port partition wall 140 protruding to the bottom so as to be spaced apart is formed,

The cover 200 is formed to be opened by sliding back while the cover body 210 is lifted to the top by the spring 220 and the guide 230.

The molten metal storage body 100 is formed so that heat does not leak to the outside through a plurality of insulating means at the periphery, and includes a plurality of temperature sensors so that the temperature of the molten metal can be checked at any time.

The molten metal storage body 100 may include a heater injected from the top, and a heater is formed to maintain the temperature of the molten metal.

The inlet 110 of the molten metal storage body 100 is formed to protrude outward from one side, and the inlet 110 has an upper end open, and an inclined lower wall 102 inclined to the inside of the molten metal storage body is formed.

An inlet partition wall 130 protruding from the top to the bottom so as to be spaced apart from the top is formed in the middle of the inclined lower wall 102.

The inlet partition wall 130 is formed by being deeply embedded in the lower than the water surface of the molten metal.

The inlet partition wall 130 is such that the molten metal injected into the open portion of the inlet 110 is not directly injected into the existing molten metal contained in the molten metal storage body 100, but flows into the lower portion of the existing molten metal. The inclined lower wall 102 is formed.

The tapping port 120 is located diagonally from the inlet port 110 and protrudes in the opposite direction, so that a mechanism for sucking the molten metal is introduced or a tapping guide or the like is inserted.

The tapping port partition wall 140 is formed to be spaced apart from the tapping port 120 so that the oxidized molten metal on the surface of the molten metal is not injected into the tapping port 120.

A dosing device may be formed in the spout 120 so that the molten metal can be discharged from the molten metal storage body 100 by pressure when necessary.

The cover 200 is spaced apart by a plurality of separation bars 231, at least two guide grooves 232 are formed, a fixing plate 234 is formed vertically at the rear, and an upper stone protruding to the top. A pair of guides 230 on which the publication 236 is formed;

A pair of springs 220 having one end fixed to the upper protruding plate 236 of the guide 230 and one end fixed to the upper end of the cover body 210;

Protrusions that can be transported along the guide groove 232 are formed on both sides, and the upper end is composed of a cover body 210 fixed to the other end of the spring 220, respectively.

The cover body 210 includes a plurality of insulating materials and is formed to block the temperature while blocking the open top of the molten metal storage body 100.

The guide 230 is spaced apart by a plurality of separation bars 231, at least two guide grooves 232 are formed, a fixing plate 234 is formed vertically at the rear, and an upper stone protruding to the top. A publication 236 is formed.

The fixing plate 234 is fixed to the outer wall of the molten metal storage body 100 and formed to support the entire cover 200.

At least two of the guide grooves 232 are formed in the longitudinal direction, the front portion is formed to be fixed to the lower end at the same height, and the rear of the guide groove 232 formed in the front is at the top, and the guide groove 232 formed at the rear. ) Is formed to face the bottom.

Two protrusions of the cover body 210 included in the guide groove 232 are formed on both sides.

Protective caps 238 for protecting the guide groove 232 may be formed on both sides of the guide 230, respectively.

The transfer means 300 is formed to be transferred before, after, up and down, and the cable is also configured to follow the transfer well.

The transfer means 300 is formed to receive the molten metal at a spaced apart position of the mold apparatus and at a spaced apart position such as when the molten metal is injected from the melting furnace, so that it can be easily moved as a whole.

Hereinafter, looking at the operation of the aluminum quantitative heating furnace formed in a preferred embodiment of the present invention as follows.

The molten metal dissolved in the melting furnace is put into the inlet 110 of the molten metal storage body 100.

At this time, the temperature of the injected molten metal may drop slightly during the transfer, but it is safely and naturally inputted by the previously stored molten metal and the inclined lower wall 102.

In addition, since the upper end of the molten metal is blocked by the inlet partition wall 130, it is naturally introduced into the molten metal.

Thereafter, when the molten metal is required, the molten metal is extracted from the tapping port 120 and injected or used.

If the inside of the molten metal storage body 100 is examined, or when cleaning is performed, the cover body 210 of the cover 200 is opened and examined. When the cover body 210 is slightly lifted to the top as shown in FIG. 7, the spring 220 transports it to the top, and when pushing it to the rear, the cover body 210 moves along the guide groove 232.

The cover body 210 moved as described above may be fixed in a form in which the front side is lifted and the rear side is lowered.

That is, the cover body 210 is very heavy because it includes an insulating material, etc., and one person can lift it and open it easily.

According to the aluminum quantitative heating furnace formed in a preferred embodiment of the present invention, when the molten metal dissolved in the melting furnace is injected into the molten metal storage body, the inlet port is formed inclined and the inlet partition wall is formed, so that the temperature is different inside the molten metal storage body. It is not administered in a hurry, and the oxidized molten metal can be blocked, so the quality of the molten metal is good, and when checking the inside of the molten metal storage body, opening the cover safely by yourself and cleaning, the work efficiency is high. When a molten metal with a different temperature is introduced into the storage body, it is stably introduced and the temperature inside the molten metal does not change rapidly, and the molten metal can be stably supplied to the mold device, resulting in an effect of increasing the quality of the product.

Although the present invention has been described based on a preferred embodiment with reference to the accompanying drawings, it is apparent that a person skilled in the art can make various modifications without departing from the scope of the present invention covered by the claims to be described later from this description.

100: molten metal storage body 102: inclined lower wall
110: input port 120: tap port
130: inlet bulkhead 140: outlet bulkhead
200: cover 210: cover body
220: spring 230: guide
231: separation bar 232: guide groove
234: fixed plate 236: upper protruding plate
238: protective cap 300: means of movement

Claims (4)

delete delete A molten metal storage body 100 in which the inlet 110 and the tapping port 120 are formed and the upper end is opened; A cover 200 capable of covering the open upper end of the molten metal storage body 100; In a general aluminum quantitative heating furnace consisting of a transfer means 300 capable of transferring the molten metal storage body 100 up, down, before and after,
The inlet 110 of the molten metal storage body 100 is formed to be inclined to protrude to one side, and an inlet partition wall 130 protruding to the lower end is formed at the upper end of the inlet 110, and the tapping port 120 and The tapping port partition wall 140 protruding to the bottom so as to be spaced apart is formed,
The cover 200 is formed to be opened by sliding rearward while the cover body 210 is lifted to the top by the spring 220 and the guide 230,
The cover 200 is spaced apart by a plurality of separation bars 231, at least two guide grooves 232 are formed, a fixing plate 234 is formed vertically at the rear, and an upper stone protruding to the top. A pair of guides 230 on which the publication 236 is formed;
A pair of springs 220 having one end fixed to the upper protruding plate 236 of the guide 230 and one end fixed to the upper end of the cover body 210;
Aluminum fixed-quantity warming furnace, characterized in that the protrusions that can be transported along the guide groove 232 are formed on both sides, and the upper end is composed of a cover body 210 fixed to the other end of the spring 220, respectively. The method of claim 3,
At least two of the guide grooves 232 are formed in the longitudinal direction, the front portion is formed to be fixed to the lower end at the same height, and the rear of the guide groove 232 formed in the front is at the top, and the guide groove 232 formed at the rear. ) The rear of the aluminum quantitative heating furnace, characterized in that formed to face the bottom.

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