KR20120010853A - Apparatus for preventing reoxidation of molten steel - Google Patents

Abstract

PURPOSE: An apparatus for preventing the reoxidation of molten steel is provided to prevent molten steel from touching with the air when the molten steel is drawn out of a ladle. CONSTITUTION: An apparatus for preventing the reoxidation of molten steel comprises position control units(700), a first jetting unit(800a) for sealing the outer side of a ladle, and a second jetting unit(800b) for sealing the inner side of a ladle. The position control units are installed in both sides of a bogie(600) and lifts a ladle(200) to the outlet of a furnace. The first jetting unit is fixed to the position control units and jets inert gas to the outside the ladle. The second jetting unit is fixed to the position control units and jets inert gas to the inside the ladle.

Description

Apparatus for preventing reoxidation of molten steel}

The present invention relates to an apparatus for preventing reoxidation of molten steel, and more particularly, to an apparatus for preventing reoxidation of molten steel capable of minimizing exposure to molten steel in the atmosphere.

In general, a trolley installed in a stainless steel mill is installed to move a predetermined rail upper portion, and a molten steel casting ladle is mounted on the upper portion of the trolley. These molten steel casting ladle is pulled out of the molten steel is completed in the refining furnace.

At this time, in the process of tapping by the interval between the bogie and the ladle, the molten steel is in contact with the air in the atmosphere is mixed oxygen and nitrogen into the molten steel. These oxygen and nitrogen are present as steel inclusions in combination with elements having affinity in molten steel. This adversely affects the most important surface state in stainless steel, thereby providing a cause of poor quality.

In addition, since the molten steel is dropped on the ladle at a high position, a large amount of molten steel is accompanied by scattering and agitation at the beginning of the tapping. By such strong molten steel stirring, the slag in the molten steel and the slag on the upper ladle are mixed into the molten steel to generate molten steel reproducible inclusions. This causes a problem that adversely affects the quality of the molten steel.

Accordingly, an object of the present invention is to suppress the exposure of molten steel to the atmosphere during molten steel tapping operation from the refining furnace to the molten steel casting ladle. Accordingly, the molten steel is in contact with the air in the atmosphere to provide a reoxidation prevention device for molten steel that can eliminate the phenomenon that oxygen and nitrogen are introduced into the molten steel and combined with a strong affinity element.

In addition, another object of the present invention is to provide an apparatus for preventing reoxidation of molten steel that can shorten the falling position of the molten steel and reduce the scattering of strong molten steel and agitation to minimize the mixing of slag in the molten steel.

In the refining furnace 100 tapping operation according to the present invention, in the re-oxidation prevention device of the molten steel that is installed on the trolley 600 on which the ladle 200 is seated, is installed on both sides of the trolley 600, the ladle 200 A) position control unit 700 for elevating to the exit of the refining furnace 100; One area is fixed to the position control unit 700, the ladle external sealing injector unit 800a for injecting an inert gas to the outside of the ladle 200; And a ladle inside sealing injector part 800b for injecting an inert gas into the ladle 200 and having a region fixed to the position control part 700.

The position controller 700 may include a fixed frame 10, a hydraulic cylinder 30 installed below the fixed frame 10, and a lifting frame 20 whose height is adjusted by the operation of the hydraulic cylinder 30. Can be.

The ladle outer sealing injector unit 800a and the ladle inner sealing injector unit 800b have a region fixed to the elevating frame 20 of the position control unit 700, and thus, the hydraulic cylinder 30 The height can be adjusted by operation.

The ladle outer sealing injector unit 800a and the ladle inner sealing injector unit 800b each include an inert gas supply unit 59 and 59 '; A rotating member (68, 54) connected by the inert gas supply part (59, 59 ') and the first gas supply pipe (70, 56) and rotatably installed in the position control part (700); It may be connected to the rotary member (68, 54) and the second gas supply pipe (60, 50), the injection nozzle unit 61, 53 formed on the ladle 200;

The injection nozzle part 61 of the ladle outer sealing injector part 800a has injection nozzles 65, 66, 67 formed along the upper circumference of the ladle 200, and the injection nozzles 65, 66, 67 is an upper injection nozzle 66 facing the upper portion of the ladle 200, a spray nozzle 65 facing the upper surface of the ladle 200 and a lower injection nozzle 67 facing the lower portion of the ladle 200. It may include.

The injection nozzles 65, 66, 67 may be formed in a horizontally long slot shape.

The vertical width of the injection nozzles 65, 66, 67 may range from 2 mm to 2.5 mm.

The second gas supply pipe 60 is connected to the rotating members 68 and 54 by connecting the gear 42 to which the power transmission unit 41 is connected and the gears 43, 44, and 45 coupled to the gear 42. 50) can be rotated.

The injection nozzle unit 61 of the ladle outer sealing injector unit 800a has a shape in which a plurality of circular arcs are coupled, and may be separated and coupled by rotation of the rotation members 68 and 54.

The injection nozzle part 53 of the ladle inner sealing injector part 800b may be formed to face the inside of the ladle 200.

The inert gas supply units 59 and 59 ′ may supply argon (Ar) gas.

Opening and closing means (62, 63, 64, 52) for controlling the supply of the inert gas may be further provided between the second gas supply pipe (60, 50) and each of the injection nozzles (61, 53).

As described above, according to the present invention, when tapping the molten steel completed in the refining furnace in the ladle, by minimizing the exposure of the molten steel in the atmosphere and preventing the molten steel contact with air in the atmosphere, reoxidation of the molten steel by oxygen mixing Can be prevented.

In addition, by minimizing the mixing of slag in the molten steel, it is possible to suppress the occurrence of inclusions in the steel in advance.

1 is a front view showing a general refining work tapping operation.
2 is a front view showing the molten steel reoxidation prevention device according to the present invention.
Figure 3 is a side view showing a position control unit and a rotating member of the molten steel anti-oxidation device according to the present invention.
4 is a cross-sectional view taken along line BB ′ of FIG. 3, illustrating a power transmission gear of the rotating member according to the present invention.
5 is a cross-sectional view taken along the line A-A 'of FIG. 3, and is a side view showing the injector portion of the molten steel anti-oxidation device according to the present invention.
6 is a cross-sectional view taken along the line C-C 'of FIG. 5, showing the injection nozzle of the sealing gas according to the present invention.
7 is a cross-sectional view showing a portion D of FIG. 5, showing an external sealing gas injection device according to the present invention.
8 is a plan view showing an open state of the injector unit for ladle seating of the molten steel anti-oxidation device according to the present invention.
9 is a plan view showing a state in which the ladle is seated on the injector unit of the molten steel reoxidation prevention device according to the present invention.
10 is a plan view showing the injector portion of the molten steel reoxidation prevention device according to the present invention.
11 is a side view showing a state of taking the molten steel anti-oxidation device according to the present invention.
12 is a side view showing a sealing state of the molten steel anti-oxidation device according to the present invention.
Figure 13 is a side view showing a state of tapping the molten steel in the ladle in the sealing state of the molten steel reoxidation prevention device according to the present invention.

Hereinafter, an apparatus for preventing reoxidation of molten steel according to the present invention will be described in detail with reference to the drawings showing an embodiment of the present invention.

1 is a front view showing a general refining work tapping operation.

Referring to FIG. 1, generally, the bogie 600 installed in a stainless steel mill is a rigid welding structure. And, the trolley 600 moves the predetermined rail 610, the tapping steel molten steel 300 is completed in the refining furnace 100 to the molten steel casting ladle 200 seated on the trolley 600.

Such equipment is installed in a state in which a sufficient distance is secured between the refining furnace 100 and the ladle 200 in order to prevent a collision due to the rotation radius of the refining furnace 100. Therefore, when the molten steel 300 is pulled out from the trolley 600 to the ladle 200, the molten steel 300 comes into contact with air in the atmosphere, and oxygen and nitrogen are mixed into the molten steel 300 to exist as inclusions in the steel.

Then, the slag in the molten steel 300 and the slag on the upper ladle 200 is mixed into the molten steel by the strong molten steel 300 stirring to generate the molten steel reproducible inclusions. This adversely affects the surface state of the stainless steel, resulting in poor quality.

In order to improve this, the present invention prevents the reoxidation of molten steel to prevent the cause of poor quality of molten steel. In addition, the fall of the tap between the refining furnace and the ladle is minimized to prevent the incorporation of impurities in the molten steel. The present invention also provides an apparatus for preventing reoxidation of molten steel having a structure in which atmospheric exposure of molten steel is suppressed during tapping for a stable operation.

2 is a front view showing the molten steel reoxidation prevention device according to the present invention.

Referring to FIG. 2, the reoxidation prevention apparatus of molten steel according to the present invention may be installed at both sides of the trolley 600 on which the ladle 200 is seated when the refining furnace 100 is pulled out. More specifically, the reoxidation prevention device for molten steel of the present invention includes a position control unit 700, a ladle outer sealing injector unit 800a and a ladle inner sealing injector unit 800b.

The position control unit 700 may elevate the ladle 200 to the exit of the refining furnace 100. In addition, one area of the ladle external sealing injector unit 800a is fixed to the position control unit 700, and inert gas is injected to the outside of the ladle 200. In addition, one area is fixed to the position control unit 700 and the ladle inner sealing injector unit 800b, and inert gas is injected into the ladle 200.

Here, the position control unit 700 includes a fixed frame 10, a hydraulic cylinder 30 installed below the fixed frame 10 and a lifting frame 20 whose height is adjusted by the operation of the hydraulic cylinder 30. That is, the fixed frame 10 of the position control unit 700 is fixed to both sides of the trolley 600, and the lifting frame 20 is fixed to the upper end of the fixed frame 10 so that the lifting and lowering is possible via the hydraulic cylinder 30. do.

In addition, in one region of the lifting frame 20, the second gas supply pipes 50 and 60 of the ladle inner sealing injector unit 800b and the ladle outer sealing injector unit 800a may be rotatably fixed. have. Accordingly, the height of the ladle inner sealing injector 800b and the ladle outer sealing injector 800a may be adjusted by the operation of the hydraulic cylinder 30 of the position controller 700.

The ladle outer sealing injector portion 800a and the ladle inner sealing injector portion 800b are each an inert gas supply portion 59, 59 ′, a rotating member 68, 54, and an injection nozzle portion 61, 53. It may include.

Here, the injection nozzle portion 61 of the ladle outer sealing injector portion 800a is formed with injection nozzles 65, 66, 67 along the upper circumference of the ladle 200, and injection nozzles 65, 66, 67. ) May include an upper injection nozzle 66 facing upwards of the ladle 200, an injection nozzle 65 facing upwards of the ladle 200, and a lower injection nozzle 67 facing downwards of the outside of the ladle 200. have.

In addition, the second gas supply pipes 60 and 50 may rotate on the rotation members 68 and 54 by the power transmission unit 41. In addition, the injection nozzle unit 53 of the ladle inner sealing injector unit 800b may be formed to face the inside of the ladle 200. The inert gas supply units 59 and 59 ′ may supply argon (Ar) gas.

In FIG. 2, a schematic component of the apparatus for preventing reoxidation of molten steel according to the present invention has been described, and a description of each component in detail will be described with reference to the accompanying drawings.

Figure 3 is a side view showing a position control unit and a rotating member of the molten steel reoxidation prevention apparatus according to the present invention, Figure 4 is a cross-sectional view showing B-B 'of Figure 3, showing a power transmission gear of the rotating member according to the present invention. Drawing.

Referring to FIGS. 3 and 4, the position control unit 700 has a lifting frame whose height is adjusted by the operation of the fixed frame 10, the hydraulic cylinder 30 installed below the fixed frame 10, and the hydraulic cylinder 30. And 20.

Among these, the second gas supply pipes 50 and 60 of the ladle inner sealing injector unit 800b and the ladle outer sealing injector unit 800a are rotatably fixed to the lifting frame 20. Gears 43, 44, and 45 may be fixed to lower ends of the second gas supply pipes 50 and 60. These gears 43, 44, 45 are meshed with the gear 42 fixed on the top of the power transmission portion 41, such as a motor fixed to the side. In addition, the motor 41 may be connected to a controller (not shown) that controls the operation.

That is, the rotating members 68 and 54 of the ladle outer sealing injector unit 800a and the ladle inner sealing injector unit 800b are connected to the gear 42 and the gear 42 to which the power transmission unit 41 is connected. The second gas supply pipes 60 and 50 may rotate by connecting the gears 43, 44 and 45 that are engaged with each other.

The hydraulic cylinder 30 of the position control unit 700 is connected to a hydraulic pump (not shown) via a supply pipe (not shown), the hydraulic pump is configured to be operated by the controller 31.

FIG. 5 is a cross-sectional view taken along line AA ′ of FIG. 3, and is a side view showing an injector part of the molten steel anti-oxidation device according to the present invention. FIG. 6 is a cross-sectional view taken along line C-C ′ of FIG. 5. It is a figure which shows the injection nozzle of sealing gas.

5 and 6, the ladle outer sealing injector portion 800a and the ladle inner sealing injector portion 800b are inert gas supply portions 59 and 59 ', rotating members 68 and 54, respectively. It may include the injection nozzle unit 61, 53.

The rotating members 68 and 54 are connected by the inert gas supply parts 59 and 59 'and the first gas supply pipes 70 and 56, and are rotatably installed in the position control part 700. In addition, the injection nozzle parts 61 and 53 are connected by the rotation members 68 and 54 and the second gas supply pipes 60 and 50, and may be formed on the ladle 200.

Here, the upper end of the second gas supply pipe 60 of the ladle outer sealing injector unit 800a forms a structure having an arc (see FIGS. 8 to 10). The injection nozzle unit 61 may be configured in a circular state to wrap the ladle 200 located in the center with an inert gas. In addition, the injection nozzle part 61 is formed with a horizontally long slot-shaped injection nozzle (65, 66, 67), it is fixed via the opening and closing means 62, 63, 64 such as a valve. Here, the opening and closing means (62, 63, 64) may be connected to a separate controller (not shown).

In addition, injection nozzles 65, 66, and 67 are formed along the upper circumference of the ladle 200 in the injection nozzle part 61 of the ladle outer sealing injector part 800a. In this case, the injection nozzles 65, 66, 67 may face the upper injection nozzle 66 facing the upper portion of the ladle 200, the injection nozzle 65 facing the upper surface of the ladle 200, and the lower portion of the ladle 200. It may include a lower injection nozzle (67).

Here, the vertical widths of the injection nozzles 65, 66, 67 formed in the injection nozzle part 61 are formed with a continuous groove having a width of 2 mm to 2.5 mm to prevent mixing of air when the inert gas is injected. It may be configured in a slot shape. When the vertical widths of the injection nozzles 65, 66, and 67 are less than 2 mm, the size of the injection nozzles may be so small that the desired amount of inert gas may not be injected. In addition, when the vertical width of the injection nozzles 65, 66, 67 exceeds 2.5 mm, the size of the injection nozzles is large, and thus the meaning of forming the slots is lost.

In this case, the inert gas supply units 59 and 59 ′ may supply argon (Ar) gas. In addition, the opening and closing means 52 for controlling the supply of the inert gas may be installed between the second gas supply pipe 50 and the injection nozzle unit 53 of the injector unit 800b for sealing the ladle.

Slot-shaped lower injection nozzle 67 The ladle 200 has a structure injecting downward to shield the lower portion of the outside. To this end, a slot-shaped lower injection nozzle 67 may be formed at a portion inclined by 30 ° in the axial direction of the circumference. In addition, the middle injection nozzle 65 of the central portion may be formed with a slot-shaped intermediate injection nozzle 65 in the horizontal direction to shield the upper surface of the ladle (200). In addition, the upper injection nozzle 66 has a structure injecting upward 60 ° to shield the upper portion of the ladle 200. The ladle inner sealing injector part 800b may cover the exit of the refinery 100 of the upper portion.

FIG. 7 is a cross-sectional view showing part D of FIG. 5 and showing an external sealing gas injection device according to the present invention.

Referring to Figure 7, the lower end of the supply pipe (50, 60) is a rotary member 54, 68 such as a rotary joint is configured to prevent rotation and leakage through the O-rings (55, 69). The rotating members 54 and 68 are connected to the inert gas supply units 59 ′ and 59 through the first gas supply pipes 56 and 70, respectively.

8 is a plan view showing an open state of the injector unit for ladle seating of the molten steel anti-oxidation device according to the present invention.

Referring to FIG. 8, the injection nozzle unit 61 of the ladle outer sealing injector unit 800a has a shape in which a plurality of circular arcs are combined, and may be separated and coupled by rotation of the rotating members 68 and 54. have.

In addition, the injection nozzle part 53 of the ladle inner sealing injector part 800b may be formed to face the inside of the ladle 200. The injection nozzle part 53 of the ladle inner sealing injector part 800b may be moved according to the operation of the injection nozzle part 61 of the ladle outer sealing injector part 800a.

That is, when the injection nozzle portion 61 of the ladle outer sealing injector portion 800a is separated, the injection nozzle portion 53 of the ladle inner sealing injector portion 800b is not positioned above the ladle 200. Do not. When the injection nozzle part 61 of the ladle outer sealing injector part 800a is coupled, the injection nozzle part 53 of the ladle inner sealing injector part 800b may be positioned above the ladle 200. Can be.

As such, when the molten steel is blown off in the refining furnace 100, the motor 41 of the rotating members 54 and 68, which are maintained in a circular state, is operated as shown in FIG. As a result, the power transmission unit 41 and the gear 42 interlock the gears 43, 44, and 45 which are tooth-coupled. Thereafter, the second gas supply pipes 50 and 60 connected to the ladle inner sealing injector part 800b and the ladle outer sealing injector 800a and the injection nozzle part 53 connected to the second gas supply pipes 50 and 60. , 61) is rotated. When the rotation is completed and the completion point is reached, the operation is stopped.

9 is a plan view showing a state in which the ladle seated on the injector unit of the molten steel anti-oxidation device according to the present invention, Figure 10 is a plan view showing the injector unit of the molten steel anti-oxidation device according to the present invention.

9 and 10, when the injection nozzles 53 and 61 are completely opened, the ladle 200 is mounted on the trolley 600 by using a crane (not shown). Then, the power transmission part 41 of the rotating members 54 and 68 is operated. As a result, the gear 42 connected to the power transmission unit 41 is geared to the gears 43, 44, 45 and the ladle inner sealing injector part 800b connected to the gears 43, 44, 45 and the ladle outside. The second gas supply pipes 50 and 60 and the injection nozzle parts 53 and 61 connected to the sealing injector 800a rotate. When the injection nozzles 53 and 61 are rotated to reach the completion point, the operation stops.

1 to 13, the operation of the molten steel anti-oxidation device according to the present invention will be described.

11 is a side view showing a state of taking the molten steel anti-oxidation device according to the present invention.

Referring to FIG. 11, when the injection nozzle is completely closed as shown in FIG. 10, the bogie 600 is moved to the lower portion of the refining furnace 100 at the completion of molten steel refining in the cab of the bogie 600.

When the bogie 600 is moved to the lower portion of the refining furnace 100 and stopped, the hydraulic pump (not shown) of the position controller 700 is operated to supply hydraulic pressure to the hydraulic cylinder 30. As a result, the hydraulic cylinder 30 is raised to raise the lifting frame 20 connected to the hydraulic cylinder 30. Then, the injectors 53 and 61 connected to the lifting frame 20 are lifted up to the smelting furnace 100 side as much as possible.

In addition, when the opening and closing means 52 supplied to the injector unit 800b for sealing the ladle is opened, an inert gas is injected toward the lower center of the ladle 200 from the top. Then, a predetermined time elapses and air inside the ladle 200 is excluded. Subsequently, the opening and closing means 64 of the injection nozzle part 53 and the opening and closing means 62 for shielding the outer lower end of the ladle 200 to shield the plane of the injection nozzle part 53, that is, the upper end of the ladle 200. ) Is open at the same time. As a result, the supply of the inert gas proceeds to shield the inside and the bottom of the ladle 200.

It is a side view which shows the sealing state of the molten steel reoxidation prevention apparatus which concerns on this invention.

Referring to FIG. 12, when the inside and the bottom of the ladle 200 are shielded, the opening / closing means 63 for supplying the inert gas is opened and the inert gas is ejected to the outside of the ladle 200. This is to shield the upper ladle 200. When the upper shielding of the ladle 200 is made, the opening and closing means 64 for supplying the inert gas to the upper surface of the ladle 200 is closed, so that the inert gas is supplied to the upper and lower portions of the ladle 200.

Fig. 13 is a side view showing a state in which molten steel is pulled out in a ladle in a sealing state of the molten steel reoxidation prevention device according to the present invention.

Referring to FIG. 13, when the injection nozzles 53 and 61 are raised to completely shield the upper and lower portions of the ladle 200, the tapping of the refinery 100 where the blowing is completed is rotated at an angle of 90 ° to start tapping. do. As a result, the tapping hole of the refining furnace 100 and the inner and outer parts of the ladle 200 are tapped in a state of being shielded by an inert gas.

Then, the steel reeling operation is performed by tilting the refining furnace 100, and at this time, the height of the injection nozzle parts 53 and 61 should be adjusted according to the height of the refining furnace 100 while checking the molten steel state during the steel reeling work. When the tilting angle of the refining furnace 100 is greatly changed, the hydraulic cylinder 30 of the position control unit 700 is operated to lower the heights of the injection nozzle parts 53 and 61. Adjusting the descent height of the descent and position control unit 700, the descent operation is completed.

In this case, the inert gas injected from the injection nozzles 53 and 61 forms an inert gas atmosphere inside the exit hole of the ladle 200 and the refining furnace 100. Therefore, the molten steel tapping out of the tapping hole of the refining furnace 100 does not come into contact with air, and tapping is performed in an inert gas.

Although the technical spirit of the present invention has been described in detail according to the above-described preferred embodiment, it should be noted that the above-described embodiment is for the purpose of description and not of limitation. In addition, those skilled in the art will understand that various embodiments are possible within the scope of the technical idea of the present invention.

10: fixed frame 20: lifting frame
30: hydraulic cylinder 31: controller
41: power transmission unit 50, 60: second gas supply pipe
52, 63, 62, 64: opening and closing means 53, 61: injection nozzle unit
54, 68: rotation member 56, 70: first gas supply pipe
59, 59 ': inert gas supply part 100: refining furnace
200: ladle 300: molten steel
400: upper sealing portion outside the ladle 500: lower sealing portion outside the ladle
600: bogie 610: rail

Claims (12)

In the refining furnace 100, when the lifting operation, in the re-oxidation prevention device of the molten steel that is installed on the trolley 600 on which the ladle 200 is seated,
A position control unit 700 installed at both sides of the trolley 600 to elevate the ladle 200 to the exit of the refining furnace 100;
One area is fixed to the position control unit 700, the ladle external sealing injector unit 800a for injecting an inert gas to the outside of the ladle 200; And
A region is fixed to the position control unit 700, the ladle inner sealing injector unit 800b for injecting an inert gas into the ladle 200; apparatus for preventing reoxidation of molten steel. The method of claim 1,
The position control unit 700 includes a fixed frame 10, a hydraulic cylinder 30 installed below the fixed frame 10, and a lifting frame 20 whose height is adjusted by the operation of the hydraulic cylinder 30. Anti-oxidation device of molten steel. The method of claim 2,
The ladle outer sealing injector unit 800a and the ladle inner sealing injector unit 800b have a region fixed to the elevating frame 20 of the position control unit 700, and thus, the hydraulic cylinder 30 Anti-oxidation device of molten steel whose height is adjusted by operation. The method of claim 1,
The ladle outer sealing injector unit 800a and the ladle inner sealing injector unit 800b each include an inert gas supply unit 59 and 59 '; A rotating member (68, 54) connected by the inert gas supply part (59, 59 ') and the first gas supply pipe (70, 56) and rotatably installed in the position control part (700); Preventing reoxidation of molten steel, including; spray nozzles 61 and 53 connected to the rotary members 68 and 54 and second gas supply pipes 60 and 50 and formed on the ladle 200. Device. The method of claim 4, wherein
The injection nozzle part 61 of the ladle outer sealing injector part 800a has injection nozzles 65, 66, 67 formed along the upper circumference of the ladle 200, and the injection nozzles 65, 66, 67 is an upper injection nozzle 66 facing the upper portion of the ladle 200, a spray nozzle 65 facing the upper surface of the ladle 200 and a lower injection nozzle 67 facing the lower portion of the ladle 200. Anti-oxidation device of molten steel comprising a. The method of claim 5,
The injection nozzle (65, 66, 67) is characterized in that the reoxidation of molten steel is formed in a slot shape that is horizontally long. The method of claim 5,
Device for preventing reoxidation of molten steel in the vertical width of the injection nozzle (65, 66, 67) is in the range of 2mm to 2.5mm. The method of claim 4, wherein
The second gas supply pipe 60 is connected to the rotating members 68 and 54 by connecting the gear 42 to which the power transmission unit 41 is connected and the gears 43, 44, and 45 coupled to the gear 42. 50) Anti-oxidation device of this rotating molten steel. The method of claim 8,
The injection nozzle part 61 of the ladle outer sealing injector part 800a has a shape in which a plurality of circular arcs are combined, and prevents reoxidation of molten steel that is separated and coupled by the rotation of the rotating members 68 and 54. Device. The method of claim 4, wherein
The injection nozzle unit (53) of the injector unit (800b) for sealing the inner ladle is formed to prevent reoxidation of molten steel is formed to face the inside of the ladle (200). The method of claim 4, wherein
The inert gas supply unit 59, 59 'is a reoxidation prevention device of molten steel for supplying argon (Ar) gas. The method of claim 4, wherein
Refining molten steel between the second gas supply pipe (60, 50) and each of the injection nozzles (61, 53) is further provided with opening and closing means (62, 63, 64, 52) for controlling the supply of inert gas Prevention device.

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