KR20000048581A - Method, device and closure member for casting on liquid casts - Google Patents

Abstract

PURPOSE: A method for discharging a solidified molten mass and a switching device for use in the method are provided to prevent an inductor for melting the solidified molten mass from being damage due to heat generated when the solidified molten mass is discharged out of a passage of a vessel. CONSTITUTION: In a method for discharging a molten mass through a discharging tube(3) of a vessel which, before discharging a molten steel(S), the molten mass is solidified at an inlet(4) of the discharging tube(3) to shut, the discharging process is carried out by using electromagnetic energy generated by an inductor(6). The electromagnetic energy is induced in a region(H) of an outlet(5) located at a low portion of the discharging tube(3) to melt the solidified molten mass. Accordingly, it is possible to discharging the solidified molten mass.

Description

METHOD, DEVICE AND CLOSURE MEMBER FOR CASTING ON LIQUID CASTS}

Containers, especially pans, containing molten steel, in particular molten steel, are used to receive the melt from the conversion furnace and send it to the continuous casting apparatus, which closes the outlet until the molten metal is received from the conversion furnace to the continuous casting apparatus. The closing of the outlet may be made by opening and closing control device or may be made by solidified metal.

While the molten metal flows into the continuous casting apparatus, the molten metal does not solidify because the outlet is not cooled by the molten metal. Conventionally, an inductor is installed on the bottom of a container close to the molten metal inside the container in order to allow molten metal to flow inside the discharge pipe. While molten metal is not solidified while the molten metal is discharged through the outlet, it is important to maintain the temperature of the inductor so that the inductor installed around the discharge passage is damaged when overheated, so that the molten metal is not damaged even at a high temperature due to the thermal conduction of the molten metal.

German Patent No. 195 15 230 discloses a method of heating and firing a primary electromagnetic field and a secondary electromagnetic field generated by an inductor outside of a ceramic molded body. In this method, the inductor coil is provided outside the molded body and in the cooling part. This patent document does not explain the injection method of a melt.

Summary of the Invention

It is an object of the present invention to provide a method of preventing the breakage of an inductor due to overheating and dissolving the melt solidified into the inductor when the melt discharge passage is discharged from a closed container by the solidified melt.

The object of the invention described above is achieved by the invention of claim 1.

According to the present invention, the solidified melt closing the discharge passage of the container is melted by an electromagnetic field induced from the inductor. The inductor is operated when discharging the solution from the continuous casting machine without being connected to the power source while moving the melt container to the continuous casting machine. When discharging the melt, connect the inductor to a power source and allow it to cool. Since the temperature at the outlet pipe inlet side rises when the melt is injected into the inlet, there is a risk that the inductor is damaged by overheating while moving the container when the inductor is installed around the outlet pipe.

Therefore, in order to minimize the damage of the inductor caused by the overheating of the melt, it is necessary to use a hollow inductor. In some cases, it may be more effective to use water-cooled inductors to minimize damage from overheating.

According to the present invention, the conductor surrounding the discharge passage of the discharge pipe is installed to be electrically inductively coupled to the electromagnetic field of the inductor so that the outlet portion of the discharge pipe is heated by the electromagnetic field of the inductor and at the same time, the secondary portion of the discharge pipe is discharged by the aforementioned conductor. An electromagnetic field was generated that caused the inlet portion of the discharge line to be inductively heated by the secondary electromagnetic field from this conductor. The generation of this secondary electromagnetic field has been described in detail in the aforementioned German Patent No. 195 15 230.

The above-described conductor may be installed in the discharge passage of the discharge pipe or may be formed on the main wall of the discharge pipe. If the conductor is formed in the main wall of the discharge pipe, the conductor remains in the main wall and can be used many times. The conductor described above is connected to a barrier that closes the inlet of the discharge pipe.

The discharge process is initiated by dissolving the solidified melt in the barrier material having an outer diameter that matches the inner diameter of the discharge pipe and opening the discharge passage of the open / close control valve as in the known open / close control valve. The blocking material is used to close the inlet of the discharge pipe. Such barriers may be achieved by known sand injection. In either case, the conductors connected to the shield shall extend to the part where the inductor is installed if the inductor is installed at the lower outlet part of the discharge pipe.

According to the present invention the melt, in particular molten steel, is injected into the vessel with the on-off control valve closed. The inductor is then connected to the power supply while operating the cooling system, especially the air-cooled system, when the vessel is brought into casting. Then, the barrier material is melted. At this time, the opening and closing control valve is opened to start discharging the melt. The closing valve may be opened just before the melt is discharged. The inlet of the discharge line is closed with a barrier before pouring the melt into the vessel. The conductors connected to the barrier material may be formed as extensions extending from the barrier material or may be formed as separate separate parts. The vessel closed with the on / off regulating valve is moved to a continuous casting machine and the inductor is connected to the power source to melt the blocking material and then open the on / off regulating valve, which may be opened before or after melting of the blocking material. .

The apparatus embodying the present invention has a blocking material for the melt solidified at the inlet of the discharge pipe, the opening and closing member is extended to the outlet portion in which the inductor is installed to be inductively coupled to the electromagnetic field of the inductor, so that the solidified melt on the blocking material through the extension portion It is melted by the secondary electromagnetic field generated by the heat conduction or the inlet side of the extension.

The extension may be formed in various forms. The extension part may be installed outside the inlet of the discharge passage so that the secondary electromagnetic field is generated by the inductor, and thus the inlet part may be inductively heated. This configuration has been described in detail in the aforementioned German Patent No. 195 15 230. In addition, the extension may be installed in the nozzle brick or may be configured as the discharge pipe itself, it may be formed to be inserted into the discharge passage of the discharge pipe. In the first case, the extension is formed of a heat-resistant electrically conductive ceramic material with magnetic field guide slits so that they do not melt during discharge of the melt and remain in the wall of the nozzle brick. In the second case the extension consists of part of the discharge tube, and in the third case the extension is inserted into the discharge tube, in which case the extension disappears during the discharge of the melt.

In another embodiment of the present invention, the inductor is connected to the bottom of the vessel, in particular the metal shell, so that it is radiated by heat conduction. According to this configuration, since the metal shell functions to radiate heat, the inductor heated by the heat of the melt during the movement of the container is cooled.

The shielding material used in the practice of the present invention includes a shielding portion adapted to the inner cross section of the discharge pipe, which is connected to the tubular extension extending to the inductor installed in the discharge port of the discharge pipe. The blocking member is formed of a metal and the extension is formed of a ceramic material which can be inductively coupled.

Hereinafter, the present invention will be described in detail with reference to the drawings.

The present invention relates to a discharge method for discharging a liquid melt through a discharge pipe of a receiving container, and more particularly to a method for discharging a liquid melt, in particular molten steel, from a discharge pipe closed by a solidified melt before discharge.

1 is a cross-sectional view of an apparatus used to practice the method of the present invention.

A nozzle brick 2 is formed on the bottom face 1 of the melt container, and a discharge pipe 3 made of a refractory material is provided in the nozzle brick 2. The discharge pipe 3 was formed with a discharge passage in the longitudinal direction having an inlet 4 at the upper end and an outlet 5 at the lower end. An inductor 6 is provided around the outlet 5 of the discharge pipe 3 so as to surround the lower end of the discharge pipe 3, which has a space in which a cooling medium, for example air, flows. . The inductor 6 is installed inside the lower end of the nozzle brick 2 away from the molten metal so as not to contact the molten metal S inside the container, and an insulating layer 7 is provided between the inductor 6 and the nozzle brick 2. Was formed.

The inductor 6 was installed in the lower end outlet portion H of the discharge pipe 3 away from the molten metal S inside the vessel. The bottom face 1 of the container has a metal shell 8, and the metal shell 8 is provided with a frame 9 of the opening / closing control valve 10. As shown in FIG. This frame 9 was supported by a movable valve valve 11 for opening and closing. The discharge passage 13 connected to the discharge port 5 is opened and closed by the valve plate 11. The inductor 6 is installed in the frame 9 or the bottom metal shell 8 so as to allow heat conduction. On the outer circumferential surface of the inductor 6, an electrical insulation layer formed of a ferrite material electromagnetically blocking the metal frame 9 from the inductor 6 was formed. And a heat conduction tube 14 for transferring heat from the inductor 6 to the frame 9 or the metal shell 8 is provided on the outer periphery of the inductor 6.

Hereinafter will be described the operation and effect of the present invention.

When the molten liquid S is not filled in the container, the valve plate 11 of the opening / closing control valve 10 is moved to block the discharge hole 13 of the discharge pipe 3 and the blocking material 16 is connected to the inlet port of the discharge pipe 3. Insert (4) to close the inlet (4). For this purpose, the outer diameter of the barrier material 16 should be sized to be inserted into the discharge passage of the discharge pipe 3. In this open position the barrier 16 protrudes above the nozzle brick 2 at the inlet 4. The extension part 15 in the discharge pipe 3 extended from the blocking material 16 to the inductor 6 provided in the discharge port 5 portion H of the discharge pipe 3. The barrier material 16 is formed of metal and the extension 15 is formed of an electrically conductive ceramic material which is electromagnetically inductively coupled. The blocking material 16 and the extension part 15 may be formed integrally. The drawing shows a state where the extension part 15 is located in the discharge passage of the discharge pipe 3.

In the closed state in which the barrier material 16 and the extension part 15 are inserted into the discharge pipe 3, when the melt is injected into the container, the melt solidifies on the barrier material 16 to serve as a stopper 18. In this state, the vessel is transferred to a continuous casting machine. This transfer process cuts power to the inductor 6 but does not cool the inductor. In this state, the inductor 6 is heated by the heat of the melt, but the inductor 6 is not in direct contact with the melt but is radiated by the frame 9 and the metal shell 8 which are connected in thermal conduction, so that the temperature of the inductor 6 Does not overheat enough to be damaged during transfer. In a continuous casting machine, the inductor 6 is connected to a power source and the cooling system of the inductor 6 is activated. Then, the extension part 15 is connected to the electromagnetic field of the inductor 6 and heated, and the heat of the extension part 15 is transferred to the barrier material 16 at its upper end to melt the melt solidified on the upper surface of the barrier material 16. At this time, the valve plate 11 is moved to the open position to start the injection operation.

The extension 15 was formed of a tubular conductor 17 inserted into the discharge tube 3 and formed of a ceramic material which can be inductively connected containing carbon.

The thermally conducting function of the electrically conductive extension 15 described above is as follows: The electrically conductive extension 15 extends downwardly from the blocking material 16 to the inductor 6 so as to be inductively coupled to the inductor 6 so that the inductor The lower end of the extension 15 extending to the inductor 6 is heated by the primary electromagnetic field of. The inductor 6 has a slit for generating a secondary electromagnetic field F at the inlet 4 portion N when the inductor is connected to a power source, and at the inlet portion N the secondary electromagnetic field F is generated. This caused the portion of the inlet 4 to be heated. As described above, the heat of the lower end of the extension portion 15 heated by the primary electromagnetic field is transferred to the inlet portion N through the heat conduction of the extension tube, and the inlet portion N of the extension tube is heated again by the secondary electromagnetic field. This heat causes the barrier material 16 to melt and the discharge of the melt is started. Substantial induction heating does not occur in the intermediate region between the primary and secondary electromagnetic fields of the inductor 6.

In another form of the invention, the electrical conductor 17 or extension 15 may be integrally formed in the wall of the discharge pipe.

In addition, the above-described electrical conductor 17 or extension 15 may be installed to be detachable in the nozzle brick 2 surrounding the discharge pipe.

The blocking material 16 may be a stopper 18 connected to the tubular extension 15. The stopper 18 is formed to fit the inner diameter of the discharge pipe 18 and can be inserted into or withdrawn from the discharge pipe 3. These stoppers are made of metal.

The plug 18 described above may be inserted into the discharge passage of the discharge pipe 3 and fixed to be connected to the tubular extension 15 or may be detachably inserted. And the stopper 18 and the extension portion 15 may be formed integrally or may be formed of a separate component.

Claims (18)

In the device for discharging the molten liquid in the container through the discharge pipe (3), in particular the molten liquid solidified at the inlet (4) of the discharge pipe so that the inlet is closed before discharge of the molten steel (S), the discharge port of the lower end of the discharge pipe (3) (5) A method of discharging the melt, wherein electromagnetic energy is introduced into the portion (H) so that the inlet (4) portion of the discharge pipe (3) is heated by the electromagnetic field. 2. The electrical conductor 17 is inductively coupled to the electromagnetic field of the inductor 6 at the outlet 5 portion H of the discharge tube 3 and to the inlet 4 portion N of the discharge tube 3. The secondary electromagnetic field is generated in the conductor 17, and the induced magnetic field is induced by the induced magnetic field in the outlet portion H of the discharge pipe 3 and the inlet portion N of the discharge pipe 3 by the induced electromagnetic field. Heated by an electromagnetic field. 3. Method according to claim 2, characterized in that the electrical conductor (17) is formed in the discharge passage of the discharge pipe (3) or in the side wall of the discharge pipe (3). In one of the preceding claims, the discharge hole (5) of the discharge pipe (3) is opened and closed by the opening and closing control valve (10), the blocking material (16) is inserted into the inlet (4) of the discharge pipe (3) discharge passage The closing material 16 is connected to the blocking member 16, the extension part 15 extending to the outlet portion (H) of the discharge pipe (3) in which the inductor (6) is installed on the bottom of the container is connected, opening and closing the discharge pipe (3) Close with valve 10 and barrier 16 and inject melt into container to move to injection position, connect inductor 6 to cooling system and power source to melt barrier 16 and open valve 10 to melt Discharging method of the melt, characterized in that to discharge the. Method according to one of the preceding claims, characterized in that the open / close control valve (10) is a known gate valve or nozzle transducer. Method according to one of the preceding claims, characterized in that the inductor (6) is air cooled. In the device for discharging the molten liquid, in particular molten steel from the molten liquid container through a discharge pipe that is opened and closed by a known opening and closing control valve, the shielding material in which the molten liquid S solidifies at the inlet portion 4 of the qonf tube 3 (N) ( 16 is fixed and the barrier member 16 has an extension extending downward to the outlet portion H of the discharge tube 3 so as to be inductively coupled to the inductor 6 installed in the outlet 5 portion of the discharge tube 3. Extensions 15, 17 are inductively heated by electromagnetic fields at the inlet portion N of the inductor 6 and heated by thermal conduction so that the barrier material 16 melts Characterized in that the melt, in particular molten steel discharge device. 8. The extension (15) of the inlet portion (N) is inductively heated by the secondary electromagnetic field (F) during activation of the inductor (6) and the extension (15) consists of an electric conductor (17). Characterized in that the device. Device according to claim 7 or 8, characterized in that the extension (16, 17) is fixed in the discharge pipe (3) or consists of the discharge pipe (3) itself. Device according to claim 7 and 8, characterized in that the extension (15, 17) consists of a ceramic material comprising inductively coupled thermal conductors, in particular carbon, inserted in the discharge pipe (3). Apparatus according to one of the preceding claims, characterized in that the barrier material (16) is metal or sand. Apparatus according to one of the preceding claims, characterized in that the inductor (6) is thermally coupled to the bottom of the vessel, in particular the metal shell. Apparatus according to one of the preceding claims, characterized in that the mounting frame (9) attached to the metal shell (8) is shielded from electromagnetic fields by ferrite cores (14). In the barrier material used to close the inlet port 4 of the outlet tube 3 for carrying out the method according to claims 1 to 6, the barrier material is formed to fit the inner diameter of the outlet tube 3 and the portion of the outlet port 5 H Blocking material, characterized in that consisting of a plug (18) connected to the extension (15, 17) extending to the inductor (6) installed in the). 15. The barrier material according to claim 14, wherein the stopper (18) is formed of a metal and the tubular extension (15, 17) is formed of a ceramic material which can be inductively coupled. 17. The eddy current induced in the tubular extension 15, 17 is divided into a discontinuous portion in the middle portion z to act on the portion H to the upper portion N adjacent to the stopper 18. A barrier material characterized in that it is intended to be refracted. 17. The stopper 18 is characterized in that the stopper 18 is inserted or covered in the inlet 4 of the discharge pipe 3 and connected to the extensions 15 and 17 formed in the discharge passage of the discharge pipe 3. Blocking material. A stopper (18) is inserted or covered in the inlet (4) of the discharge pipe (3), the extensions (15, 17) surrounding the discharge passage of the discharge pipe (3) or integrally in the discharge pipe (20). Blocking material characterized in that formed.