KR101403503B1 - Apparatus for feeding molten steel - Google Patents

Abstract

Disclosed herein is a molten metal supply device for preventing external air from flowing into a molten metal during molten metal supply to prevent oxidation of molten metal, thereby improving the quality of the molten metal product.
The molten metal supplying apparatus according to an embodiment of the present invention includes a warming furnace 200 that is supplied with a molten metal S as a molten metal and is configured to be hermetically sealed with the molten metal S; And a molten metal supply unit 300 configured to pressurize the molten metal S to supply the molten metal S to the mold M and to prevent the inflow of external air during the supply of the molten metal S; The molten metal supplying unit 300 includes a molten metal supplying pump 310 provided in the heating furnace 200 such that a part of the molten metal supplying unit 300 is located inside the heating furnace 200, Wherein the molten metal supply pipe 320 is connected to the molten metal supply pump 310 and the other end of the molten metal supply pipe 320 is located on an upper portion of the mold M, And one side of which is pivotally connected to the fixing part 321 through the heat insulating furnace 200 and the other side of which is located on the upper side of the mold M, Closing valve 324 which is opened and closed in accordance with the turning of the swinging part 322 is provided on the other side of the swinging part 322. The swinging part 322 is provided at the swinging part 322, May be provided.

Description

[0001] APPARATUS FOR FEEDING MOLTEN STEEL [0002]

The present invention relates to a molten metal supplying device for supplying a molten metal as a molten metal to a mold for producing a molten metal, and more particularly, to a molten metal supplying device for molten metal, Thereby improving the quality of the cast product.

In order to produce casting products, raw materials containing metal are first added to the melting furnace. Then, the raw material containing the metal contained in the melting furnace is heated by the heating unit provided in the melting furnace.

As a result, the raw material containing the metal contained in the melting furnace is melted and becomes a molten metal. Then, the molten metal in the melting furnace is supplied to the mold from the melting furnace by the molten metal supplying device and is contained in the mold. Thus, the molten metal contained in the mold is cooled to form a shape corresponding to the shape of the mold. Thereafter, the cooled and shaped metal is separated from the mold, and the cast product is completed through further processing such as grinding.

In the conventional molten metal supplying apparatus for supplying the molten metal to the mold, molten metal of the molten metal is supplied to the mold by its own weight.

For this purpose, a molten metal supply pump is provided in the melting furnace in order to raise the molten metal contained in the melting furnace to the upper part of the melting furnace. One side of the molten metal supply pipe is connected to the molten metal supply pump, and the other side of the molten metal supply pipe is located on the upper side of the mold. Further, one side of the molten metal supply pipe is positioned higher than the other side. That is, the molten metal supply pipe is positioned between the molten metal supply pump and the mold so that one side is higher than the other side.

With this configuration, the molten metal drawn up to the upper portion of the melting furnace by the molten metal supply pump flows into one side of the molten metal supply pipe as described above. Then, the molten metal flowing into one side of the molten metal supply pipe flows to the other side of the molten metal supply pipe by its own weight. Thereafter, the molten metal is discharged through the other side of the molten metal supply pipe and supplied to the mold.

As described above, since the molten metal is supplied to the mold by the weight of the molten metal, the molten metal introduced into one side of the molten metal supply pipe by the molten metal supply pump is accelerated while flowing through the molten metal supply pipe. Therefore, the flow rate of the molten metal discharged to the other side of the molten metal supply pipe becomes larger than the flow rate of the molten metal flowing into one side of the molten metal supply pipe.

Therefore, when one side and the other side of the molten metal supply pipe have the same cross-sectional area, the flow rate of the molten metal discharged to the other side of the molten metal supply pipe becomes larger than the molten metal flow flowing into one side of the molten metal supply pipe. Thereby, a region in which the molten metal does not exist exists in the molten metal supply pipe. And, the region where the molten metal is not present in the molten metal supply pipe is lower than the atmospheric pressure of the outside.

Accordingly, there is a problem that outside air flows into the molten metal supply pipe through a gap formed in the molten metal supply pipe. The outside air introduced into the molten metal supply pipe reacts with the molten metal flowing through the molten metal supply pipe. That is, the molten metal flowing through the molten metal supply pipe, that is, the molten metal, is oxidized by reacting with oxygen contained in the air. As described above, when the melted metal is oxidized, there is a problem that the quality of the cast product produced by the molten metal is deteriorated as described above.

This phenomenon can occur if the cross-sectional area of the other side of the molten metal supply pipe through which the molten metal is discharged is smaller than the cross-sectional area of one side of the molten metal supply pipe, provided that the nozzle is provided on the other side of the molten metal supply pipe and the flow rate of the molten metal discharged through the nozzle is sufficiently large .

When the flow rate of the molten metal discharged to the other side of the molten metal supply pipe is large, there is a problem that the molten metal discharged to the other side of the molten metal supply pipe is scattered when supplied to the mold. Thus, when the molten metal is scattered, there is a problem that the molten metal can not be properly supplied to the mold. Further, there is a problem that the scattered molten metal adheres to the casting apparatuses other than the casting mold to damage the casting apparatus. Thereby, there is a problem that the productivity is lowered.

The present invention is realized by recognizing at least any one of the requirements or problems occurring in the conventional melt supply apparatus.

One aspect of the object of the present invention is to prevent external air from flowing into the molten metal when the molten metal is supplied.

Another aspect of the object of the present invention is to prevent oxidation of molten metal, i.e., molten metal.

Another aspect of the object of the present invention is to ensure the quality of the cast product.

Another aspect of the object of the present invention is to prevent scattering of the molten metal when the molten metal is supplied to the mold.

A melt supply apparatus according to an embodiment for realizing at least one of the above problems may include the following features.

The present invention is basically based on a configuration in which a molten metal as a molten metal is pressurized and supplied to a mold, while preventing the inflow of outside air when molten metal is supplied.

A molten metal supply device according to an embodiment of the present invention includes a heating furnace that is supplied with molten metal as a molten metal and is configured to be hermetically sealed with the molten metal; And a molten metal supply unit configured to pressurize the molten metal to supply the molten metal to the mold and prevent external air from flowing into the molten metal when the molten metal is supplied; And the molten metal supply part is connected to the molten metal supply pump through one side of the molten metal supply pump and the other side is connected to the upper part of the mold The molten metal supply pipe is connected to the molten metal supply pump. The molten metal supply pipe is connected to the molten metal supply pump. The molten metal supply pipe is connected to the molten metal supply pump. And an open / close valve that is opened or closed in accordance with the turning of the swivel portion may be provided on the other side of the swivel portion.

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In this case, the molten metal supply pump may include a motor provided in the heating furnace; A rotary shaft rotatably connected to the motor and passing through one side of the heat insulating furnace and positioned inside the heat insulating furnace; A pump casing which is rotatably connected to the rotary shaft and is located inside the heat insulating furnace so as to allow the molten metal to flow therein and to which one side of the molten metal supply pipe is connected; And an impeller connected to the rotating shaft; . ≪ / RTI >

One side of the molten metal supply pipe can penetrate the upper surface of the heat insulating furnace.

In addition, a nozzle may be provided on the other side of the molten metal supply pipe.

The other end of the molten metal supply unit is connected to the molten metal supply pipe. The other end of the molten metal supply unit is located inside the insulated furnace, so that the molten metal is partially or completely returned to the insulated furnace when the molten metal is supplied. As shown in FIG.

Further, the bypass pipe may have a smaller cross-sectional area in the flow direction of the molten metal.

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The inert gas inlet may include an inert gas inlet to which the inert gas is introduced.

In addition, the molten metal may include magnesium.

As described above, according to the embodiment of the present invention, it is possible to prevent the outside air from flowing into the molten metal when the molten metal is supplied.

Further, according to the embodiment of the present invention, oxidation of molten metal, that is, molten metal, can be prevented.

Further, according to the embodiment of the present invention, the quality of the cast product can be improved.

Furthermore, according to the embodiment of the present invention, it is possible to prevent the molten metal from scattering when the molten metal is supplied to the mold.

1 is a front view showing an embodiment of a molten metal supplying apparatus according to the present invention.
2 is a plan view showing an embodiment of a molten metal supplying apparatus according to the present invention.
Fig. 3 is an enlarged view of a portion A in Fig. 1, showing a pivotal portion of a molten metal supply pipe of an embodiment of the molten metal supply device according to the present invention pivotably connected to a fixed portion of the molten metal supply pipe.
Fig. 4 is an enlarged view of a portion B in Fig. 3, wherein Fig. 4 (a) is a view showing that the molten metal having flowed through the swivel portion is supplied to the mold by opening the other side of the swivel portion, And the other side of the swivel portion is closed so that the molten metal flowing through the swivel portion is not supplied to the mold.
5 is a front view showing the operation of one embodiment of the molten metal supply apparatus according to the present invention, in which the molten metal produced in the melting furnace is supplied to the heating furnace.
Fig. 6 is a front view showing the operation of one embodiment of the molten metal supplying apparatus according to the present invention, in which molten metal contained in the insulated furnace is supplied to the mold.
Fig. 7 is a plan view of Fig. 6, which is not shown, for ease of explanation.
8 is a view showing the operation of one embodiment of the molten metal supply apparatus according to the present invention, showing the completion of the supply of the molten metal to the mold.
Fig. 9 is a plan view of Fig. 8, which is not shown, for ease of explanation.

In order to facilitate understanding of the features of the present invention as described above, the melt supply device according to the embodiment of the present invention will be described in detail.

Hereinafter, exemplary embodiments will be described based on embodiments best suited for understanding the technical characteristics of the present invention, and the technical features of the present invention are not limited by the illustrated embodiments, It is to be understood that the present invention may be implemented as illustrated embodiments. Therefore, it is intended that the present invention covers the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents. In order to facilitate understanding of the embodiments to be described below, in the reference numerals shown in the accompanying drawings, among the constituent elements which perform the same function in each embodiment, the related constituent elements are indicated by the same or an extension line number.

Embodiments related to the present invention are basically based on a configuration in which molten metal as a molten metal is pressurized to supply molten metal to a mold, while preventing the inflow of outside air when molten metal is supplied.

1 and 2, the molten metal supplying apparatus 100 according to the present invention may be configured to include a warming furnace 200 and a molten metal supplying unit 300.

As shown in FIG. 5, the warming furnace 200 may be configured such that a molten metal S, which is a molten metal, is supplied and sealed and hermetically sealed to the outside. For this purpose, the furnace 200 may be provided with a crucible 210, which is made of refractory material and contains the molten metal S, as shown in FIGS. 1 and 2, and is hermetically sealed with the outside. And, although this crucible 210 is not shown, it can be covered with one or more heat insulating materials.

Therefore, even if the molten metal S having a very high temperature is supplied and stored in the crucible 210 of the warming furnace 200, that is, the warming furnace 200, the heat transfer from the molten metal S contained in the crucible 210 to the outside Can be minimized. As a result, the molten metal S contained in the crucible 210 is cooled and can be immersed in the crucible 210 in a molten state. Thus, the molten metal S contained in the crucible 210 of the warming furnace 200, that is, the warming furnace 200 can be supplied to the mold M as shown in Figs. 6 and 7.

In order to supply the molten metal S to the crucible 210 of the warming furnace 200, that is, the warming furnace 200, a heating unit (not shown) is used as in the embodiment shown in Figs. 1 and 2, The other side of the molten metal supply pipe 220 connected to the melting furnace F which is melted by the molten metal S and connected to the melting furnace F may be connected to the crucible 210 of the warming furnace 200, 5, the molten metal S produced in the melting furnace F may be supplied to the crucible 210 of the heat insulating furnace 200, that is, the crucible 210 of the heat insulating furnace 200 through the molten metal supplying pipe 220 .

As shown in FIGS. 1 and 2, the inert gas inlet 230 may be provided in the warming furnace 200. One side of the inert gas inlet 230 may be connected to an inert gas supply source (not shown). The other side of the inert gas inlet 230 may be connected to the crucible 210 of the warming furnace 200 as shown in the illustrated embodiment.

5, an inert gas such as fluorine fluoride (SF ₆ ) stored in an inert gas supply source is supplied to the warming furnace 200 through the inert gas inlet 230, that is, the crucible of the warming furnace 200 210). The supply of the inert gas to the crucible 210 of the warming furnace 200 through the inert gas inlet 230 is performed from the melting furnace F to the warming furnace 200, The molten metal S may be supplied to the crucible 210 or after the supply of the molten metal S is completed. Thus, the crucible 210 of the heat insulating furnace 200, that is, the heat insulating furnace 200 can contain not only the above-mentioned molten metal S but also an inert gas.

As described above, when the molten metal S and the inert gas are contained in the crucible 210 of the warming furnace 200, that is, the warming furnace 200, the furnace 210 of the warming furnace 200, The molten metal S contained therein may not react with impurities such as oxygen contained in the air or the like. Therefore, the quality of the molten metal S can be excellent.

On the other hand, a heating unit (not shown) may be provided in the warming furnace 200. By this heating unit, the molten metal S contained in the heat insulating furnace 200 can be heated. The molten metal S contained in the crucible 210 of the warming furnace 200, that is, the crucible 210 of the warming furnace 200 is cooled and can be stored in the warming furnace 200 in a melted state. The heating unit provided in the heating furnace 200 is not particularly limited and the heating furnace 200 may be heated by electric energy to heat the molten metal S contained in the crucible 210 of the heating furnace 200, Any known structure is applicable as long as it is capable of heating the molten metal S or heating the molten metal S.

On the other hand, the molten metal S supplied to the crucible 210 of the warming furnace 200, that is, the warming furnace 200 may contain magnesium. Since magnesium reacts well with oxygen in particular, when the molten metal S containing magnesium is supplied to the mold M, the use of the molten metal supplying apparatus 100 according to the present invention can prevent the magnesium from being oxidized.

However, the components contained in the molten metal S are not limited to the magnesium described above, and any metal may be included in the molten metal S.

The molten metal supply unit 300 may be configured to pressurize the molten metal S to supply the molten metal S to the mold M as shown in FIGS. 6 and 7 and to prevent the inflow of external air when the molten metal S is supplied.

As described above, since the inflow of outside air during the supply of the molten metal S is prevented, the molten metal S, that is, the molten metal, may not react with oxygen contained in the air. Therefore, the molten metal S, that is, the molten metal may not be oxidized, so that the quality of the cast product produced by supplying the molten metal S to the mold M may be excellent.

For this purpose, the molten metal supplying unit 300 may include a molten metal supplying pump 310 and a molten metal supplying pipe 320 as in the embodiment shown in FIGS. 1 and 2.

The molten metal supply pump 310 may be provided in the heat insulating furnace 200 such that one side thereof is positioned inside the crucible 210 of the heat insulating furnace 200, . The molten metal supplying pump 310 may include a motor 311, a rotating shaft 312, a pump casing 313, and an impeller 314 as shown in the illustrated embodiment.

The motor 311 may be provided in the warming-up furnace 200 as in the embodiment shown in FIG. Further, the motor 311 may be provided on the upper side of the warming-up furnace 200 as shown in the illustrated embodiment. The motor 311 is not particularly limited, and any well-known motor 311 can be used.

One side of the rotary shaft 312 may be rotatably connected to the motor 311 as in the embodiment shown in FIG. Therefore, when the motor 311 is driven, the rotation shaft 312 can be rotated. The other side of the rotary shaft 312 may be located inside the heat insulating furnace 200, that is, inside the crucible 210 of the heat insulating furnace 200, through one side of the heat insulating furnace 200. The other side of the rotary shaft 312 passes through the upper surface of the crucible 210 of the heat insulating furnace 200 and flows into the inside of the heat insulating furnace 200, (Not shown).

The rotating shaft 312 is not particularly limited and may be any type of rotating shaft that is rotatably connected to the motor 311 and can be positioned inside the heat insulating furnace 200 through one side of the heat insulating furnace 200 The rotating shaft 312 may be used.

1, the other side of the rotary shaft 312 may be rotatably connected to the pump casing 313. As shown in FIGS. 6 and 7, the molten metal S may be located inside the heat insulating furnace 200, that is, inside the crucible 210 of the heat insulating furnace 200. For this purpose, the pump casing 313 may be provided with a melt inlet (not shown). Also, one side of the molten metal supply pipe 320 may be connected to the pump casing 313 as shown in the illustrated embodiment.

The impeller 314 may be connected to the other side of the rotary shaft 312 as in the embodiment shown in FIG. Accordingly, when the rotation shaft 312 is rotated by the driving of the motor 311 as described above, the impeller 314 is also rotated. 5, the molten metal S contained in the heat insulating furnace 200, that is, the crucible 210 of the heat insulating furnace 200 flows into the pump casing 313 by the rotation of the impeller 314 . As described above, the molten metal S introduced into the pump casing 313 can be pressed by the rotation of the impeller 314. The pressurized molten metal S may be introduced into the molten metal supply pipe 320 connected to the pump casing 313 as shown in FIG.

The impeller 314 is not particularly limited and may be connected to the other side of the rotary shaft 312 and may be rotated by the rotation of the rotary shaft 312 to rotate the rotary shaft 312 in a state where the molten metal 200 contained in the crucible 210 of the heat insulating furnace 200, (S) flows into the pump casing 313 and then flows into the molten metal supply pipe 320, any known method can be used.

1, one side of the molten metal supply pipe 320 is connected to a molten metal supply pump (not shown) disposed in the crucible 210 of the warming furnace 200 through the one side of the warming furnace 200 310, in the illustrated embodiment, to the pump casing 313 of the melt supply pump 310. Therefore, the molten metal S pressed by the rotation of the impeller 314 flows into the molten metal supply pipe 320 and flows through the molten metal supply pipe 320 as described above.

One side of the molten metal supply pipe 320 penetrates the upper surface of the heat insulating furnace 200, that is, the upper surface of the heat insulating furnace 200, that is, the upper surface of the crucible 210 of the heat insulating furnace 200 like the embodiment shown in FIG. And may be connected to a pump 310. Therefore, the molten metal S flowing into the molten metal supply pipe 320 can flow upward along the molten metal supply pipe 320 by the pressure applied by the molten metal supply pump 310, as shown in FIG.

6 and 7, the other side of the molten metal supply pipe 320 may be located on the upper side of the mold M as shown in FIGS. 6 and 7, the molten metal S flowing into the molten metal supply pipe 320 by the pressure applied by the molten metal supply pump 310 is discharged to the other side of the molten metal supply pipe 320 as described above, And can be supplied to the mold M.

The molten metal S does not flow along the molten metal supply pipe 320 due to the weight of the molten metal S as in the prior art and flows along the molten metal supply pipe 320 by the pressure applied by the molten metal supply pump 310 The flow rate of the molten metal S flowing into one side of the molten metal supply pipe 320 and the flow rate of the molten metal S discharged to the other side of the molten metal supply pipe 320 can be substantially the same. The flow rate of the molten metal S flowing into one side of the molten metal supply pipe 320 and the flow rate of the molten metal S discharged to the other side of the molten metal supply pipe 320 Is almost the same.

Thereby, the molten metal S does not exist in the molten metal supply pipe 320, so that there is no region where the pressure is lower than the external atmospheric pressure. Therefore, when the molten metal S flows into the molten metal supply pipe 320, external air is prevented from flowing into the molten metal pipe 320 through the gap formed in the molten metal supply pipe 320 or the like. Then, the molten metal S as the molten metal does not react with the oxygen contained in the air, and oxidation of the molten metal S as the molten metal can be prevented. Therefore, the quality of the cast product can be improved.

1 and 4, a nozzle 323 may be provided on the other side of the molten metal supply pipe 320. The discharge from the other side of the molten metal supply pipe 320 of the molten metal S can be guided by the nozzle 323 since the nozzle 323 has a configuration in which the sectional area becomes smaller toward the discharge direction of the molten metal S,

The flow rate of the molten metal S in the nozzle 323 is lowered by the arrangement of Bernoulli and the discharge of the molten metal S in the direction of the discharge of the molten metal S as described above As you go towards the direction, it gets faster. The flow rate of the molten metal S discharged to the other side of the molten metal supply pipe 320 when the nozzle 323 is not provided and the flow rate of the molten metal S discharged from the nozzle 323 when the nozzle 323 is provided, The flow rate of the gas is almost the same.

Therefore, even if the nozzle 323 is provided on the other side of the molten metal supply pipe 320, the molten metal S does not exist in the molten metal supply pipe 320, so that there is no region where the pressure is lower than the external atmospheric pressure. Thus, even when the nozzle 323 is provided on the other side of the molten metal supply pipe 320, when the molten metal S flows through the molten metal supply pipe 320, the external air flows through the gap formed in the molten metal supply pipe 320, And is not introduced into the supply pipe 320.

1, the molten metal supply pipe 320 may include a fixed portion 321 and a swivel portion 322. In this embodiment,

The fixing portion 321 may be connected to one side of the melt supply pump 310 located inside the warming furnace 200, that is, inside the crucible 210 of the heat insulating furnace 200, as in the embodiment shown in FIG. have. The fixing portion 321 may be connected to the pump casing 313 of the melt supply pump 310 as shown in the illustrated embodiment.

6 and 7, the impeller 314 is rotated by driving the motor 311 of the molten metal supply pump 310, and the molten metal S introduced into the pump casing 313 flows through the impeller 314, The molten metal can be pressurized by the rotation of the molten metal supply pipe 314 and flow into the fixed portion 321 of the molten metal supply pipe 320.

1, one side of the swivel part 322 passes through the warming furnace 200 and passes through the upper surface of the crucible 210 of the warming furnace 200 in the illustrated embodiment, As shown in Fig. The other side of the swivel portion 322 may be located on the top of the mold M as shown in FIGS.

6 to 9, the swivel unit 322 may be pivoted by the swivel drive unit 340 provided in the warming furnace 200. 3, a first connecting curved surface portion 321a having a convex curved surface may be formed at the end of the fixing portion 321 to which one side of the swivel portion 322 is pivotally connected. In addition, a second connection curved surface portion 322a having a concave curved surface corresponding to the first connection curved surface portion 321a may be formed at one end of the swivel portion 322 as shown in the illustrated embodiment. 3, the molten metal S flowing through the fixed portion 321 is supplied to the swivel portion 322 even when the swivel portion 322 is pivoted by the swivel drive unit 340. [ Can be introduced. However, even if the swivel unit 322 is pivoted by the swivel drive unit 340, the configuration in which the molten metal S flowing through the fixed unit 321 flows into the swivel unit 322 is not limited to this, Configuration is possible.

2 and 3, the swivel part 322 is slidably provided on a guide member 325 provided on the upper part of the heat insulating furnace 200, And can penetrate the hole formed by the first sliding member 326 and the second sliding member 327.

The first sliding member 326 and the second sliding member 327 may be connected by a connecting member 328 as in the embodiment shown in FIG. The connecting member 328 may be connected to the first sliding member 326 and the second sliding member 327 by bolts or the like as shown in the illustrated embodiment. The connection member 328 on the side of the second sliding member 327 may have a long hole as shown in the illustrated embodiment. In addition, the first sliding member 326 and the second sliding member 327 may be connected to an elastic member 329.

6, when the swivel unit 322 is turned obliquely by the swivel drive unit 340, a part of the first sliding member 326 is guided by the guide member (not shown) 325 in the direction from the second sliding member 327. As a result, the first sliding member 326 is separated from the second sliding member 327 as shown in Fig.

7, the shape of the hole formed by the first sliding member 326 and the second sliding member 327 through which the swivel portion 322 passes is changed from circular to elliptical. Then, the elastic member 329 is stretched. Thus, the swivel portion 322 can be pivoted to be easily inclined.

The first sliding member 326 and the second sliding member 327 that pass through the space between the first sliding member 326 and the second sliding member 327 or the swinging unit 322 and the swing unit 322, Since the inert gas supplied to the crucible 210 of the heat insulating furnace 200 can be discharged to the outside through the sealing member such as a ceramic wool, May not flow into the molten metal S contained in the crucible 210 of the heat insulating furnace 200.

In this state, when the swivel unit 322 is pivoted vertically by the swivel drive unit 340 as shown in Fig. 8, the first sliding member 326 is moved to the second sliding member 327). The first sliding member 326 is slid with the second sliding member 327 so that a part of the first sliding member 326 coming out of the guide member 325 is inserted into the guide member 325. [ At this time, the elastic member 329 is contracted by the elastic force so that the first sliding member 326 and the second sliding member 327 can be easily joined. Accordingly, the shape of the hole formed by the first sliding member 326 and the second sliding member 327 changes from an elliptical shape to a circular shape as shown in the figure.

The swing drive unit 340 may include a support frame 341, a plurality of links 342, and a drive cylinder 343, as in the embodiment shown in Fig.

The support frame 341 may be provided in the warming furnace 200 as in the embodiment shown in FIG. The plurality of links 342 may be connected to each other and pivotally connected to the support frame 341 as shown in the illustrated embodiment. In addition, the drive cylinder 343 may be coupled to one of the plurality of links 342, as shown in the illustrated embodiment.

6 to 9, when the driving cylinder 343 is driven, the other side of the turn portion 322 of the molten metal supply pipe 320 is positioned inside the mold M, So that the swivel portion 322 can be pivoted.

6 and 7, when the molten metal S is supplied to the mold M, the swivel portion 322 is rotated so that the other side of the swivel portion 322 is located inside the mold M And is turned by the swing drive unit 340.

When the supply of the molten metal S to the mold M is completed, the swivel portion 322 is rotated so that the other side of the swivel portion 322 is located outside the mold M as shown in Figs. 8 and 9. [ Is turned by the swing drive unit (340). 9, the mold M having been supplied with the molten metal S is moved to the other side and the mold M to be supplied with the molten metal S is positioned below the other side of the turn portion 322 can do.

On the other hand, on the other side of the swivel part 322, an on-off valve 324 may be provided as in the embodiment shown in FIG. The opening / closing valve 324 can be opened or closed in accordance with the turning of the swivel portion 322.

That is, as shown in Figs. 4 (a) and 6 and 7, the swivel part 322 is lowered so that the other side of the swivel part 322 is located inside the mold M, 324 are brought into contact with the mold M, the open / close valve 324 is raised. 7 and 8, the molten metal S flowing through the swivel portion 322 flows into the other side of the swivel portion 322, that is, the nozzle 323 And the like. The molten metal (S) discharged to the outside can be supplied to the mold (M).

When the supply of the molten metal S to the mold M is completed and the other side of the turn portion 322 is moved to the outside of the mold M as shown in Figs. 4 (b), 8 The on-off valve 324 is lowered when the swivel portion 322 is raised. The other side of the swivel part 322 is thus closed so that the molten metal S flowing through the swivel part 322 as shown in Figs. 9 and 10 can not be discharged to the outside through the other side of the swivel part 322 do. Therefore, the molten metal S can not be supplied to the mold M.

The molten metal supply unit 300 may further include a bypass pipe 330 as in the embodiment shown in FIGS. One side of the bypass pipe 330 may be connected to the other side of the molten metal supply pipe 320, that is, the other side of the pouring portion 322 of the molten metal supply pipe 320 in the illustrated embodiment. The other side of the bypass pipe 330 may be located inside the heat insulating furnace 200, that is, inside the crucible 210 of the heat insulating furnace 200, as shown in the illustrated embodiment. Accordingly, part or all of the molten metal S can be returned to the heating furnace 200, that is, the crucible 210 of the heat insulating furnace 200 upon the supply of the molten metal S described above.

6 and 7, when the swivel portion 322 of the molten metal supply pipe 320 is pivoted downward and the opening / closing valve 324 is opened to supply the molten metal S to the mold M A part of the molten metal S which is pressurized by the molten metal supply pump 310 and flows through the molten metal supply pipe 320 is supplied to the mold M. [ 7, the remaining molten metal S is returned to the crucible 210 of the warming furnace 200, that is, the crucible 210, through the bypass pipe 330.

Accordingly, when the molten metal S is supplied to the mold M, a large amount of the molten metal S is not discharged through the other side of the turn portion 322 of the molten metal supply pipe 320. Thereby, the flow rate of the molten metal S can be relatively small when the molten metal S is supplied to the mold M, and scattering of the molten metal S can be prevented.

8 and 9, the swirl portion 322 of the molten metal supply pipe 320 is pivoted upward, the opening / closing valve 324 is closed, and the molten metal S is not supplied to the mold M The entire molten metal S flowing through the molten metal supply pipe 320 by the molten metal supply pump 310 flows through the bypass pipe 330 into the warming furnace 200, 210 < / RTI >

Even when the molten metal S is not supplied to the mold M for the movement of the mold M in this manner, the molten metal S flowing through the molten metal supply pipe 320 flows into the warming furnace 200, Can continue to flow to the crucible 210 of the furnace 200. Therefore, the molten metal S flowing through the molten metal supply pipe 320 may be cooled by heat exchange with the outside and not be solidified.

The bypass pipe 330 may have a smaller cross-sectional area in the flow direction of the molten metal S. The static pressure of the molten metal S flowing through the bypass pipe 330 can be reduced along the bypass pipe 330 and the flow rate of the molten metal S flowing through the bypass pipe 330 can be reduced Lt; RTI ID = 0.0 > 330 < / RTI > Therefore, part or all of the molten metal S flowing through the molten metal supply pipe 320 can be smoothly returned to the warming furnace 200, that is, the crucible 210 of the heat insulating furnace 200 through the bypass pipe 330 have.

On the other hand, as in the embodiment shown in FIG. 5, the bath surface measurement sensor C can be pivotally provided for measuring the bath surface of the molten metal S in the mold M. Such a bath surface measuring sensor C can be pivoted completely away from the mold M when the molten metal is not supplied to the mold M as shown in Fig.

6 and 7, when the molten metal is supplied to the mold M, the molten metal is supplied to the mold M in such a manner that one end of the molten metal is supplied to the mold M M). ≪ / RTI >

8 and 9, when the molten metal is supplied to the mold M, the melt surface measuring sensor C may be turned completely away from the mold M.

As described above, when the molten metal supplying apparatus of the present invention is used, external air may not flow into the molten metal during the supply of the molten metal, and the molten metal may not be oxidized, and the quality of the molten metal may be excellent When the molten metal is supplied to the mold, the molten metal may not be scattered.

The above-described molten metal supply apparatus can be applied to a limited number of configurations of the above-described embodiments, but the above embodiments may be configured by selectively combining all or a part of each of the embodiments so that various modifications can be made .

100: molten metal supplying device 200: insulated furnace
210: crucible 220, 320: molten metal supply pipe
230: inert gas inlet 300: molten metal supply part
310: molten metal supply pump 311: motor
312: rotating shaft 313: pump casing
314: Impeller 321:
321a: first connection curved surface portion 322:
322a: second connection curved surface portion 323: nozzle
324: opening / closing valve 325: guide member
326: first sliding member 327: second sliding member
328: connecting member 329: elastic member
330: Bypass tube 340: Swiveling drive unit
341: Support frame 342: Link
343: drive cylinder S: molten metal
M: mold F: melting furnace
C: Bake surface measurement sensor

Claims (11)

A warming furnace 200 which is supplied with a molten metal S as a molten metal and is configured to be hermetically sealed to the outside; And
A molten metal supply unit 300 configured to pressurize the molten metal S to supply the molten metal S to the mold M and prevent the inflow of external air when the molten metal S is supplied; And,
The molten metal supplying unit 300 includes a molten metal supply pump 310 provided in the heat insulating furnace 200 so that a part of the molten metal supplying unit 300 is located inside the heat insulating furnace 200 and one side of the heat insulating furnace 200 And a molten metal supply pipe (320) connected to the molten metal supply pump (310) and positioned on the other side of the mold (M)
The molten metal supply pipe 320 is connected to the molten metal supply pump 310 and has a fixing part 321 which is pivotally connected to the fixing part 321 through one side of the heat insulating furnace 200, And a swivel part (322) located at an upper portion of the mold (M) and pivoted by a swiveling drive unit (340) provided in the warming furnace (200)
And an open / close valve (324) is provided on the other side of the swivel part (322) for opening / closing the swivel part (322). delete The method of claim 1, wherein the melt supply pump (310)
A motor 311 provided in the heat insulating furnace 200;
A rotary shaft 312 rotatably connected to the motor 311 and passing through one side of the thermal insulation furnace 200 and located inside the thermal insulation furnace 200;
A pump casing 313 which is rotatably connected to the rotary shaft 312 and is located inside the heat insulating furnace 200 to allow the molten metal S to flow therein and to which one side of the molten metal supply pipe 320 is connected; And
An impeller 314 connected to the rotating shaft 312;
Wherein the molten metal supply device comprises: 2. The molten metal supplying apparatus according to claim 1, wherein one side of the molten metal supply pipe (320) penetrates the upper surface of the heat insulating furnace (200). The molten metal supplying apparatus according to claim 1, wherein a nozzle (323) is provided on the other side of the molten metal supply pipe (320). The method according to claim 1, wherein the molten metal supply unit (300)
The other side is connected to the molten metal supply pipe 320 and the other side is located inside the heating furnace 200 so that a part or all of the molten metal S is returned to the heating furnace 200 when the molten metal S is supplied. ); The molten metal supplying device further comprising: 7. The molten metal supplying apparatus according to claim 6, wherein the bypass pipe (330) has a smaller sectional area in the direction of flow of the molten metal (S). delete delete The apparatus for supplying molten metal according to claim 1, wherein the inert gas inlet (230) for introducing an inert gas into the heat insulating furnace (200) is provided. The molten metal supplying apparatus according to claim 1, wherein the molten metal (S) comprises magnesium.

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