KR100934801B1 - Molten steel - Google Patents

Abstract

The present invention relates to an apparatus for preventing scattering of molten steel having an improved structure to suppress molten steel from scattering when the molten steel is initially injected into the mold from the immersion nozzle of the tundish for continuous casting equipment.

The present invention is provided in the lower part of the tundish and the immersion nozzle having a discharge hole formed in the injection hole on both sides to inject the molten steel into the mold, and enters through the injection holes on both sides of the immersion nozzle is installed on the bottom surface of the discharge hole and the A guide for guiding the flow in a direction inclined to both sides.

According to the present invention, the present invention guides the flow of molten steel to branch to both sides at an inclined angle during the initial injection of molten steel, thereby suppressing the scattering of molten steel and preventing it from sticking to the inner wall surface of the mold or splashing outside. Has

Description

Splash intercepting apparatus for molten steel}

The present invention relates to an apparatus for preventing scattering of molten steel, and more particularly, to an apparatus for preventing scattering of molten steel having an improved structure to prevent molten steel from scattering when the molten steel is initially injected into the mold from the immersion nozzle of a tundish for continuous casting equipment. will be.

In general, continuous casting equipment is for manufacturing molten steel into semi-finished products such as slabs, and consists of a tundish, a mold, and a plurality of rolls of the machine, and after the molten steel passes through the mold to form a solidified layer, It has a manufacturing process for cooling the surface of the cast piece by spraying the cooling water as it passes between the rolls of players arranged on both sides of the dog.

In detail, the molten steel that has been electrically blown in the steelmaking process is put into a ladle for the next step of refining.

The ladle is transported for the next process with molten steel to perform a continuous casting process.

1, the molten steel contained in the ladle 10 is charged into the tundish 20 through the shroud nozzle and in the tundish 20 through the immersion nozzle 25, the mold 30 is shown in FIG. Continuous molten steel production is performed by supplying molten steel and cooling the molten steel through the mold 30 to the soft cycle roll 42 while transferring the solidified roll 42.

In such continuous casting facility, the molten steel in the tundish 20 is charged into the mold 30 through the immersion nozzle 25, and the molten steel is tundished for a predetermined time in the process of charging the molten steel into the mold 30 through the immersion nozzle 25. After being stored in the molten steel, the impurities in the molten steel are well removed and then supplied into the mold 30.

At this time, the molten steel outflow time in the tundish detects the weight including the load of the tundish and the molten steel therein with a load cell, and when the weight exceeds the set weight, the gate (not shown) is tilted to open the immersion nozzle 25 to mold the molten steel. Injected into (30).

When the molten steel in the existing tundish is discharged, the temperature is about 1500 ° C. or more, and solidifies in a semi-finished state while passing through the mold 30.

The immersion nozzle 25 is used between tundish and mold during continuous casting of steel to prevent slag mixing due to prevention of oxidation of molten steel and vortex prevention of molten steel to improve the quality of the cast slab. It will play an important role.

As illustrated in FIG. 2, the immersion nozzle 25 has a structure in which injection holes 25b for injecting molten steel S into the mold 30 are formed at both sides of the lower discharge port, and the molten steel S is formed in the injection hole ( In the process of being injected into the mold 30 through the 25b) it has a high flow rate, so that during the initial injection of the molten steel (S) it hits the bottom surface of the discharge port (25a) and the injection hole in the direction of the arrow shown in the drawing ( 25b) is scattered and irregularly attached to the inner circumferential surface of the mold 30 to form a now.

As such irregularities are fixed to the inner circumferential surface of the mold 30, the casting operation becomes unstable at the time of initial solidification of the molten steel S, and also causes defects in the cast slab, thereby increasing the defective rate.

The present invention has been proposed to solve the above problems in view of the above problems, the object of which is to improve the molten steel to prevent the splashing and hitting the bottom surface of the discharge port when the molten steel is initially injected through the immersion nozzle of the tundish It relates to a scattering prevention device of.

The present invention for achieving the above object is an immersion nozzle having an ejection opening is formed in the lower portion to inject molten steel in the tundish into the mold;

It is installed on the bottom surface of the discharge port of the immersion nozzle, characterized in that it comprises a guide for inducing the flow of the molten steel to prevent the molten steel from scattering.

The guide is installed in an inclined direction to have an inclined surface with respect to the bottom surface of the discharge port to guide the flow of the molten steel to both sides,

It is to have a first and second guide body is divided into the upper end is opposed to the structure in contact with each other.

The first and second guide bodies may further include a supporting member having one end portion formed on an inner surface facing each other and the other end contacting the bottom surface of the discharge port to support the first and second guide bodies, respectively.

The guide is formed to have an inclined surface in the form of a triangular pyramid with respect to the bottom surface of the discharge port so as to guide the flow of the molten steel to both sides.

The guide is bent to induce the flow of the molten steel is bent to have at least one or more inclination angles of different angles.

The present invention relates to an apparatus for preventing scattering of molten steel having an improved structure so that molten steel is prevented from scattering when the molten steel is initially injected into the mold from the immersion nozzle of the tundish for continuous casting equipment. By inducing the molten steel to branch to both sides at an inclined angle during the initial injection of the molten steel, it has a useful effect of preventing the molten steel from scattering and sticking to the inner wall surface of the mold or splashing to the outside.

In addition, this has the advantage of maintaining the stability of the casting during the initial solidification of the molten steel, and also to improve the quality by preventing the defects of the cast.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in detail, the same reference numerals for the same components as those of the prior art described above, duplicate description will be omitted.

3 to 5, the apparatus for preventing scattering of molten steel according to the present invention is installed at a lower portion of the tundish and injected holes 25b at both sides of the lower portion to inject molten steel S into the mold 30. Is formed through the immersion nozzle 25 having the discharge port 25a formed therein and through both injection holes 25b of the immersion nozzle 25 to be installed on the bottom surface of the discharge port 25a to direct the flow of molten steel S to both sides. It is composed of a guide 100 for guiding in an inclined direction.

In more detail, the guide 100 is made of a steel material so as to dissolve by the molten steel (S) and change the properties of the molten steel over time after the initial injection of the molten steel (S), both sides are divided and opposed to each other The first and second guide bodies 110 and 120 are formed in a shape and have an inclined surface.

This allows the first and second guide bodies 110 and 120 to enter through the injection holes 25b formed at both sides to facilitate installation, and to allow the upper ends to contact each other to have a substantially triangular horn shape. This is to guide the molten steel (S) coming down from the inclined direction.

In addition, the first and second guide bodies 110 and 120 extend from the contact surfaces 112 and 122 and the contact surfaces 112 and 122 where the molten steel S comes into contact with the inside of the immersion nozzle 25. It is bent to have a gentle inclination angle different from the contact surface 112,122 relative to the () and the end is composed of the bending surface (114,124) in contact with the bottom surface of the discharge port (25a), respectively.

An angle of the contact surfaces 112 and 122 is preferably about 120 ° with respect to the bottom surface of the discharge port 25a so as not to disturb the flow during the initial injection of molten steel, but is not limited thereto.

The first and second guide bodies 110 and 120 further include support members 132 and 134 which are integrally formed such that one end portion is formed on one side of the inner surface facing each other and the other end is in contact with the bottom surface of the discharge port 25a. It is preferable to provide.

Referring to the operation of the present invention having such a structure is as follows.

The apparatus for preventing scattering of molten steel according to the present invention includes the first guide main body 110 and the second guide from both sides through the injection holes 25b of both sides of the immersion nozzle 25 before injection of the molten steel S into the mold 30. When the main body 120 enters the inside of the discharge port 25a in the horizontal direction, respectively, and is seated on the bottom surface of the discharge port 25a, the upper ends of the first and second guide bodies 110 and 120 are centered on the discharge port 25a. In contact with each other in the form of a rough triangular horn.

Subsequently, when the immersion nozzle 25 is opened, when the molten steel S in the tundish flows down to the discharge port 25a side along the inside of the immersion nozzle 25, the first and second guide bodies 110 and 120 are formed. Branched to both sides with respect to the upper end portion is guided and discharged at an inclined angle toward both injection holes 25b.

In this case, the molten steel (S) is branched to both sides at an inclined angle along the contact surfaces 112 and 122 of the first and second guide bodies 110 and 120, and the bent surfaces 114 and 124 having a gentler angle than the contact surfaces 112 and 122. As a result, external scattering is suppressed.

In addition, the guide 100 is dissolved by the molten steel (S) when the molten steel (S) is continuously injected after the initial injection of the molten steel (S), and in the mold 30 at the time when the guide 100 is dissolved Since the molten steel (S) is contained state, the molten steel (S) is not scattered.

On the other hand, Figure 6 is a view showing another embodiment of the guide of the present invention, the guide 100 is a structure formed integrally, not divided into the first and second guide body 110, 120, the line described above As in the example, the contact surfaces 112 and 122 and the bent surfaces 114 and 124 are formed at both sides to guide the flow of the molten steel S to both sides.

In this case, the supporting members 132 and 134 may be omitted because both ends of the bent surfaces 114 and 124 contact the bottom surface of the discharge port 25a to support the guide 100.

Another embodiment of the present invention having such a configuration. The installation process of the guide 100 in the above-described embodiment will have a slightly different installation process, in which case the operator enters the guide 100 at an oblique angle through one of the injection holes 25b on both sides. The ends of 114 and 124 are in contact with the bottom surface of the discharge port 25a and the position is adjusted so that the upper end is located at the center.

Thereafter, the process of inducing the flow of molten steel (S) and the process of melting have the same process and function as those of the above-described embodiment, and thus redundant description will be omitted.

The present invention described above is provided on the discharge port 25a side of the immersion nozzle 25 to guide the flow of molten steel S in the direction inclined to both sides during the initial injection of molten steel S, Since it has a technical idea of suppressing external scattering, modifications can be made to any extent without departing from the spirit and concept of the present invention. For example, one end of the supporting members 132 and 134 is not formed to extend from the inner surface of the guide 100, but is formed to extend from the ends of the bent surfaces 114 and 124 to have a plate shape in surface contact with the bottom surface of the discharge port 25a. It may be.

1 is a block diagram showing a typical continuous casting equipment.

Figure 2 is an illustration showing that molten steel is scattered through the discharge port of the conventional immersion nozzle.

Figure 3 is a front view showing an embodiment of the apparatus for preventing scattering of molten steel according to the present invention.

4 is a perspective view of FIG.

5 is a state diagram used in one embodiment of the present invention.

Figure 6 is a front view showing another embodiment of the apparatus for preventing scattering of molten steel according to the present invention.

Explanation of symbols on the main parts of the drawings

20: tundish 25: immersion nozzle

25a: discharge port 25b: injection hole

30: mold 100: guide

110, 120: the first and second guide body

112,122: contact surface

114,124: Bending surface

115,125: Bends

S: molten steel

Claims (5)

An immersion nozzle 25 having a discharge port 25a in which an injection hole 25b is formed at a lower portion so as to inject molten steel S in the tundish into the mold 30; It is installed on the bottom surface of the discharge port 25a of the immersion nozzle 25 to induce the flow of the molten steel (S) to prevent the molten steel (S) from scattering and as the time passes after the initial injection of the molten steel (S) An apparatus for preventing scattering of molten steel, comprising: a guide 100 made of a material dissolved by (S). The method according to claim 1, The guide 100 is installed in an inclined direction to have an inclined surface with respect to the bottom surface of the discharge port 25a to guide the flow of the molten steel (S) to both sides, An apparatus for preventing scattering of molten steel, characterized in that the first and second guide bodies (110, 120) are divided so that their upper ends are opposed to each other in a structure capable of contacting each other. The method according to claim 2, The first and second guide bodies 110 and 120 have one end portion formed on the inner surface facing each other, and the other end is in contact with the bottom surface of the discharge port 25a so that the first and second guide bodies 110 and 120 ( The apparatus for preventing scattering of molten steel, characterized in that it further comprises a support member (132, 134) for supporting 120, respectively. The method according to claim 1, The guide 100 is scattering prevention device of the molten steel, characterized in that the upper end is formed to have a slope in the form of a triangular pyramid with respect to the bottom surface of the discharge port (25a) to guide the flow of the molten steel (S) to both sides. The method according to any one of claims 1 to 4, The guide 100 is formed by bending the inclined surface to induce the flow of the molten steel (S) is characterized in that the scattering prevention device of the molten steel, characterized in that it has at least one or more inclination angles.

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