KR20190027184A - Apparatus for preventing the scattering of molten steel from submerged nozzle - Google Patents

Abstract

The present invention relates to an apparatus for preventing scattering of molten steel from a submerged nozzle to prevent scattering of molten steel discharged through a submerged nozzle, which comprises: a first prevention unit disposed to be spaced apart from any one of discharge ports of the submerged nozzle at a predetermined interval to prevent scattering of the molten steel; and a second prevention unit spaced apart from the other one of the discharge ports of the submerged nozzle at a predetermined interval to prevent scattering of the molten steel. One of the first prevention unit and the second prevention unit is movably installed in the other one to adjust a separation distance. Therefore, scattering molten steel is prevented from being fixated to an internal wall surface of a case or a sensor.

Description

TECHNICAL FIELD [0001] The present invention relates to an apparatus for preventing scattering of molten steel for a submerged nozzle,

The present invention relates to a molten steel scattering prevention device for an immersion nozzle. And more particularly, to a molten steel scattering prevention device for an immersion nozzle that prevents scattering of molten steel discharged from an immersion nozzle.

In general, the continuous casting machine is composed of a facility for receiving molten steel transferred from a furnace to a ladle to a tundish, and supplying the molten steel to a mold to continuously produce a cast steel having a predetermined size.

Referring to FIGS. 1 and 2, in the continuous casting operation of the stopper casting type, the turn dish saw 20, on which the turn disc 10 is mounted, moves upward to a casting position, can do. Accordingly, the immersion nozzle 11 disposed at the bottom of the turn-dish 10 is inserted into the mold 30 and stopped at a constant height.

Then, when the long nozzle 51 is connected to the ladle 40 by operating the shroud mann plate 50 and a sliding gate (not shown) is closed to seal the injection port of the ladle 40, Along the inside diameter, molten steel is injected into the bath of the turn-dish 10. At this time, as a certain amount of molten steel is filled in the turn-dish 10, the inclusion contained in the molten steel is separated.

When the inclusion is separated, the stop cylinder 13, which hermetically closes the injection port of the immersion nozzle 11, is raised to a certain height by operating the suck cylinder 12. A space is formed between the upper injection port of the immersion nozzle 11 and the stopper 13 so that the molten steel is injected into the mold 30 through the discharge port 11a of the immersion nozzle 11. [

Thus, the molten steel supplied to the mold 30 is cooled while being retained for a predetermined time to form a solidified cell, and solidification proceeds progressively to the inner surface, and the molten steel is drawn out into a rectangular shaped cast strip.

On the other hand, when the molten steel is injected into the mold 30, a floor is required to prevent the molten steel from being exposed, and the dummy bar head 60 performs its role. At this time, the initial molten steel is solidified and joined with the dummy bar head 60.

However, when the molten steel is fused to the upper surface of the dummy bar head 60, it becomes difficult to separate the solidified casting and the dummy bar head 60 from each other. To prevent this, a nail chip and a grinder chip (not shown) are mounted on the upper portion of the dummy bar head 60 to perform a sealing operation to fill a gap between the dummy bar head 60 and the mold 30, a metal chip 70 such as a grinder chip is disposed.

However, when molten steel is discharged from the immersion nozzle 11, molten steel collides with the metal chip 70 stacked on the upper surface of the dummy bar head 60 to scatter the metal chip 70 in various directions.

Further, some of the molten steel to be scattered may be fixed to the inner wall surface of the mold 30 and another portion may be fixed to the sensor 80.

In particular, the molten steel fixed to the inner wall surface of the mold 30 interferes with the heat transfer between the solidified shell and the molten steel during the cooling process of the cast steel, resulting in non-uniformity of the solidified shell formation. This may lead to defects on the surface of the cast steel, or to confine the solidified shell to the casting mold 30, which may cause a facility accident such as break-out at the casting of the cast steel.

Further, the molten steel welded to the sensor 80 causes a malfunction of the sensor 80. As a result, the molten steel in the non-solidified state can cause the molten steel to be drawn, resulting in a molten steel leakage accident or the like. Here, the sensor 80 can sense molten steel filled in the mold 30.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide a molten steel scattering prevention device for an immersion nozzle, which prevents scattering of molten steel discharged from an immersion nozzle.

At this time, the distance between the short side portions of the mold and the shape of the groove portion of the dummy bar head are adjusted in accordance with the type (steel type, size, etc.) of the casting die to be drawn, A scattering prevention device is provided.

Further, the groove portion and the metal chip are protected by the molten steel falling on the inclined surface of the groove portion formed on the head of the dummy bar, corresponding to damage to the groove portion, adhesion of a part of the molten steel to the groove portion, irregularity of the metal chip disposed on the inclined surface, The present invention provides a molten steel scattering prevention device for an immersion nozzle.

The problems to be solved by the embodiments are not limited to the above-mentioned problems, and other problems not mentioned here can be clearly understood by those skilled in the art from the following description.

According to an embodiment of the present invention, there is provided a molten steel scattering prevention device for an immersion nozzle for preventing scattering of molten steel discharged through an immersion nozzle, the molten steel scattering prevention device comprising: A first prevention part disposed so as to be spaced apart from the first protection part; And a second prevention part spaced apart from the other one of the discharge ports of the immersion nozzle by a predetermined distance so as to prevent scattering of the molten steel, wherein one of the first prevention part and the second prevention part And the movable gap is adjustable so that the spacing distance can be adjusted.

Here, the first prevention portion may include a first base disposed on an upper portion of the dummy bar head; And a first prevention plate projecting from the first base to prevent scattering of the molten steel; And a protrusion formed on the first base, wherein the second prevention portion includes a second base disposed on an upper portion of the dummy bar head; And a second prevention plate projecting from the second base to prevent scattering of the molten steel; And a slot formed in the second base, and the second base can be moved along the longitudinal direction of the slot by the protrusion when the second prevention part is moved.

A first hole may be formed in a lower portion of each of the first prevention plate and the second prevention plate.

A plurality of second holes may be formed along the width direction of the first and second prevention plates.

The first base and the second base may further include a protection plate rotatably disposed on one side of each of the first base and the second base, and the protection plate may be disposed on an inclined surface of the groove formed in the dummy bar head.

And a support member movably disposed on one side of each of the first base and the second base to support a lower surface of the protection plate, and as the support member moves, the rotation angle of the protection plate is adjusted .

The core further includes a coil-shaped core disposed on the groove. One side of the core is supported by the first base, and the other side is supported by the second base.

According to an embodiment of the present invention, there is provided a molten steel scattering prevention device for an immersion nozzle for preventing scattering of molten steel discharged through an immersion nozzle, comprising: a third base disposed on an upper surface of a dummy bar head along a longitudinal direction of the mold; A base having two fourth bases protruding from the third base at a predetermined interval in the short side direction of the mold; A first prevention plate and a second prevention plate protruding upward from each of the fourth bases; And a protection plate rotatably disposed on one side of each of the fourth bases, wherein the protection plate is disposed on an inclined surface of the groove formed in the dummy bar head.

The support base may further include a support member movably disposed on each of the fourth bases to support a lower surface of the protection plate. The rotation angle of the protection plate may be adjusted as the support member moves.

Further, it may further comprise a coil-shaped core disposed on the groove portion, and the core may be disposed between the fourth base.

A plurality of second holes may be formed along the width direction of the first and second prevention plates.

According to an embodiment of the present invention, there is provided a molten steel scattering prevention device for an immersion nozzle which prevents scattering of molten steel discharged through an immersion nozzle, the molten steel scattering prevention device comprising: a coil-shaped core disposed at an upper portion of a groove portion formed in a dummy bar head; And two barrier plates spaced apart from the discharge port of the immersion nozzle at a predetermined spacing, wherein one region of each of the barrier plates is bent with respect to a plurality of third holes formed along the vertical direction And a molten steel scattering prevention device for an immersion nozzle.

The apparatus for preventing splashing of molten steel for an immersion nozzle according to an embodiment of the present invention having the above-described structure can prevent scattering of molten steel discharged from the immersion nozzle.

At this time, the distance between the discharge port and the molten steel scattering prevention device for the immersion nozzle can be adjusted within the mold considering the distance between the short side portions of the mold and the shape of the groove portion of the dummy bar head.

Thereby, it is possible to prevent the molten steel to be scattered from sticking to the inner wall surface or the sensor of the mold.

In addition, it is possible to protect the groove portion of the dummy bar head by using the shield plate and to prevent the damage caused by the molten steel falling by guiding the molten steel to the groove portion.

1 is a view showing a continuous casting apparatus in a stopper casting system,
2 is a view showing a molten steel injected into a mold by an immersion nozzle,
3 is a view showing a molten steel scattering preventing device for immersion nozzle according to the first embodiment disposed in a mold,
4 is a perspective view showing a molten steel scattering prevention device for an immersion nozzle according to the first embodiment,
5 is an exploded perspective view showing a molten steel prevention device for an immersion nozzle according to the first embodiment,
6 is a view showing the movement of the support member of the molten steel prevention device for immersion nozzle according to the first embodiment,
7 is a view showing molten steel discharged to the molten steel prevention device for an immersion nozzle according to the first embodiment,
8 is a view showing a shape in which a molten steel scattering prevention device for an immersion nozzle according to the first embodiment is bent along a second hole,
9 is a view showing a molten steel scattering prevention device for an immersion nozzle according to a second embodiment of the present invention,
10 is a view showing a shape in which a molten steel scattering preventing device for immersion nozzle according to the second embodiment is bent along a second hole,
11 is a view showing a molten steel scattering prevention device for an immersion nozzle according to a third embodiment of the present invention,
12 is a view showing a shape in which a molten steel scattering preventing device for an immersion nozzle according to a third embodiment is bent along a third hole;

The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated and described in the drawings. It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

The terms including ordinal, such as second, first, etc., may be used to describe various elements, but the elements are not limited to these terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the second component may be referred to as a first component, and similarly, the first component may also be referred to as a second component. And / or < / RTI > includes any combination of a plurality of related listed items or any of a plurality of related listed items.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, . On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings, wherein like or corresponding elements are denoted by the same reference numerals, and redundant description thereof will be omitted.

The molten steel scattering preventing apparatuses 1, 1a and 1b for immersion nozzle according to the embodiment are disposed inside a mold 30 having a dummy bar head 60 disposed thereunder. At this time, the molten steel prevention device (1, 1a, 1b) for immersion nozzle prevents scattering of molten steel discharged from the discharge port (11a) of the immersion nozzle (11).

Here, the molds 30 may include a long side 31 and a short side 32 which are spaced apart from each other. The dummy bar head 60 may be provided with a groove 61 and an inclined surface 62.

At this time, the short side 32 of the mold 30 can move along one side of the long side 31 in consideration of the size of the casting. The dummy bar head 60 having various grooves 61 corresponding to the size of the mold 30 can be disposed below the mold 30. [

The molten steel scattering prevention device 1, 1a, 1b for the immersion nozzle may be disposed on the upper surface 63 of the dummy bar head 60 to prevent the molten steel discharged from being scattered. Accordingly, the molten steel may be filled in the mold 30 and then solidified to form a uniform solidified shell.

1st Example

Fig. 3 is a view showing a molten steel scattering preventing device for immersion nozzle according to the first embodiment arranged in the mold, Fig. 4 is a perspective view showing a molten steel scattering preventing device for immersion nozzle according to the first embodiment, 6 is a view showing movement of a support member of a molten steel prevention device for an immersion nozzle according to the first embodiment, and Fig. 7 is a sectional view of the first embodiment FIG. 8 is a view showing molten steel discharged to a molten steel prevention device for an immersion nozzle according to the first embodiment. FIG. 8 is a view showing a shape in which a molten steel scattering prevention device for an immersion nozzle according to an example is bent along a second hole.

3 to 8, a molten steel scattering prevention device 1 for immersion nozzle according to the first embodiment includes a first prevention part 100, a second prevention part 200, a first prevention part 100, And a protection plate 300 and a support member 400 provided to each of the second prevention parts 200. [ The molten steel scattering prevention device for immersion nozzle 1 may further include a core 500.

Each of the first prevention part (100) and the second prevention part (200) can prevent scattering of molten steel discharged through the immersion nozzle (11).

As shown in FIG. 3, any one of the first prevention part 100 and the second prevention part 200 of the molten steel scattering prevention device for immersion nozzle 1 may be movably installed on the other. The distance D between each of the first prevention part 100 and the second prevention part 200 and the discharge port 11a of the immersion nozzle 11 can be adjusted. At this time, each of the first prevention part 100 and the second prevention part 200 may be movably disposed on the upper surface 63 of the dummy bar head 60. Here, the movement of the first prevention part 100 and the second prevention part 200 can be performed by a separate device (not shown) such as a cylinder or a crane.

Referring to FIG. 4, the first prevention part 100 may include a first prevention plate 120 for preventing scattering of molten steel discharged through the first base 110 and the immersion nozzle 11.

The first base 110 may be formed in a plate shape. The first base 110 may be disposed on the upper surface 63 of the dummy bar head 60. Accordingly, when the molten steel is discharged from the immersion nozzle 11 toward the first prevention plate 120, the first base 110 can prevent the first prevention plate 120 from being rolled over.

As shown in FIGS. 4 and 5, the first base 110 may be formed in a T shape.

Referring to FIGS. 4 and 5, the first base 110 may include a first support portion 111, a first extension portion 112, a first rollover prevention portion 113, and a projection 114.

Hereinafter, the longitudinal direction with respect to the long side 31 of the mold 30 is referred to as a long side direction (x direction), the longitudinal direction with respect to the short side 32 is referred to as a short side direction (y direction) The vertical direction is the vertical direction (z direction) and the description will be made clear.

The first support portion 111 may be formed in a plate shape elongated in the short side direction. The first protection plate 120 may be disposed above the first support portion 111.

The first extending portion 112 may extend from the first supporting portion 111 in the longitudinal direction. 3 and 5, the first extension 112 may be disposed on the first support 111 in a direction opposite to the direction in which molten steel is discharged.

The first rollover prevention portion 113 may extend from the first support portion 111 in the longitudinal direction. 3 and 5, the first rollover prevention portion 113 may be disposed on the first support portion 111 in a direction opposite to the first extension portion 112. [ Accordingly, when molten steel is discharged from the immersion nozzle 11, the first rollover prevention portion 113 can support the first support portion 111 to prevent the first prevention plate 120 from being rolled over.

The protrusion 114 may protrude upward from the first extending portion 112. The protrusion 114 can engage with the elongated hole 214 of the second base 210. The movement of the second base 210 in the longitudinal direction of the elongated hole 214 can be guided by the protrusion 114 when the second preventing portion 200 is moved. The first prevention part 100 moves in the longitudinal direction of the elongated hole 214 by the elongated holes 214 of the protrusions 114 and the second base 210 when the first prevention part 100 moves. Can be informed.

The first prevention plate 120 can prevent scattering of molten steel discharged through the discharge port 11a. For this, the first prevention plate 120 may be moved and spaced apart from the discharge port 11a by a predetermined distance D. At this time, the first prevention plate 120 may be arranged to protrude upward from the first base 110.

Referring to FIG. 5, the first prevention plate 120 may include a first body 121, a first hole 122, and a second hole 123.

The first body 121 may be formed in a plate shape. The first body 121 may be disposed in the short side direction (y direction).

At this time, the first main body 121 may be formed at a predetermined height h2 higher than the height h1 of the discharge port 11a. Accordingly, the first main body 121 can prevent the molten steel discharged through the immersion nozzle 11 from scattering. A part of the molten steel struck against the first main body 121 can be guided by the first main body 121 and moved to the first base 110.

In addition, the first body 121 may have a predetermined thickness. Here, the thickness may be formed in consideration of the melting rate of the first body 121 with respect to molten steel.

As shown in FIG. 5, the first body 121 may be formed in a rectangular plate shape, but is not limited thereto. For example, the first body 121 may be formed in a shape in which three sides such as an arc shape and a trapezoid are formed, or a shape in which one area is bent.

The first hole 122 may be disposed under the first prevention plate 120. 4 and 5, the first hole 122 formed in the lower portion of the first body 121 may have a rectangular shape. Accordingly, molten steel moved toward the first base 110 can move along the first base 110 in a horizontal plane through the first holes 122.

On the other hand, the melting rate of the first body 121 can be increased through the first hole 122. For example, as the molten steel is filled into the mold 30, the first prevention plate 120 is immersed in the molten steel. At this time, the surface area at which the molten steel and the first body 121 are in contact with each other is improved by the first hole 122, so that the first body 121 can be rapidly melted in the molten steel.

Here, the first hole 122 is formed in a rectangular shape, but the present invention is not limited to this, and it is needless to say that the first hole 122 may be formed in various shapes such as a semicircle and a triangle in consideration of the flow rate and the melting rate of the molten steel.

In addition, one end of the core 500 may be disposed on one side of the first hole 122. Accordingly, the flow of the core 500 to molten steel to be dropped can be prevented.

A plurality of second holes 123 may be disposed in the first body 121 along the width direction (y direction) of the first prevention plate 120. As shown in FIGS. 4 and 5, a plurality of second holes 123 may be horizontally disposed in the first body 121. At this time, the second hole 123 may be formed by drilling a region of the first body 121.

As the molten steel is filled into the mold 30, the molten steel can move in the horizontal direction through the second holes 123.

On the other hand, the melting rate of the first body 121 can be increased through the second holes 123. For example, as the molten steel is filled into the mold 30, the first prevention plate 120 is immersed in the molten steel. At this time, the surface area at which the molten steel and the first body 121 are in contact with each other is improved by the second hole 123, so that the first body 121 can be rapidly melted in the molten steel.

Referring to FIG. 4, the second prevention part 200 may include a second prevention plate 220 for preventing scattering of molten steel discharged through the second base 210 and the immersion nozzle 11.

The second base 210 may be formed in a plate shape. The second base 210 may be disposed on the upper surface 63 of the dummy bar head 60. Accordingly, when molten steel is discharged from the immersion nozzle 11 toward the second prevention plate 220, the second base 210 can prevent the second prevention plate 220 from being rolled over.

As shown in FIG. 4, the second base 210 may be formed in a T shape.

Referring to FIG. 5, the second base 210 may include a second support portion 211, a second extension portion 212, a second rollover prevention portion 213, and a long hole 214.

The second support portion 211 may be formed in a plate shape elongated in the short side direction. The second support plate 211 may be provided with a second prevention plate 220 upwardly.

The second extending portion 212 may extend from the second supporting portion 211 in the longitudinal direction. 3 and 5, the second extension portion 212 may be disposed on the second support portion 211 in a direction opposite to the direction in which molten steel is discharged.

The second rollover prevention portion 213 may extend from the second support portion 211 in the longitudinal direction. 3 and 5, the second rollover prevention portion 213 may be disposed on the second support portion 211 in a direction opposite to the second extension portion 212. [ Accordingly, when molten steel is discharged from the immersion nozzle 11, the second rollover prevention portion 213 can support the second support portion 211 to prevent the second prevention plate 220 from being rolled over.

The elongated hole 214 may be formed in the second extension portion 212. As shown in FIG. 4, the long hole 214 may be formed long in the long-side direction.

The long hole 214 can engage with the projection 114 of the first base 110. The movement of the second base 210 in the longitudinal direction of the elongated hole 214 can be guided by the protrusion 114 when the second preventing portion 200 is moved.

The second prevention plate 220 can prevent scattering of molten steel discharged through the discharge port 11a. For this, the second prevention plate 220 may be moved so that the second prevention plate 220 is spaced apart from the discharge port 11a by a predetermined distance D. At this time, the second prevention plate 220 may be disposed so as to protrude upward from the second base 210.

Referring to FIG. 5, the second prevention plate 220 may include a second body 221, a first hole 222, and a second hole 223.

The second body 221 may be formed in a plate shape. The second body 221 may be disposed in the short side direction (y direction).

At this time, the second body 221 may be formed at a predetermined height h2 higher than the height h1 of the discharge port 11a. Accordingly, the second main body 221 can prevent the molten steel discharged through the immersion nozzle 11 from scattering. A part of the molten steel hit by the second main body 221 can be guided by the second main body 221 and can be moved to the second base 210.

In addition, the second body 221 may have a predetermined thickness. Here, the thickness may be formed considering the melting rate of the second body 221 with respect to molten steel.

As shown in FIG. 5, the second body 221 may be formed in a rectangular plate shape, but is not limited thereto. For example, when viewed from above, the second body 221 may be formed in a shape formed by three sides of an arc shape or a trapezoid, or a shape in which one area is bent.

The first hole 222 may be disposed below the second plate 220. 4 and 5, the first hole 222 formed in the lower portion of the second body 221 may have a rectangular shape. Accordingly, molten steel moved toward the second base 210 can move along the upper surface of the second base 210 in a horizontal plane through the first holes 222.

Meanwhile, the melting rate of the second body 221 can be increased through the first hole 222. For example, as the molten steel is filled into the mold 30, the second prevention plate 220 is immersed in the molten steel. At this time, the surface area at which the molten steel and the second body 221 are in contact with each other is improved by the first hole 222, so that the second body 221 can be rapidly melted in the molten steel.

Here, the first hole 222 is formed in a rectangular shape, but the present invention is not limited thereto, and it is needless to say that the first hole 222 may be formed in various shapes such as a semicircle or a triangle in consideration of the flow rate and the melting rate of the molten steel.

In addition, one end of the core 500 may be disposed on one side of the first hole 222. Accordingly, the flow of the core 500 to molten steel to be dropped can be prevented.

A plurality of second holes 223 may be disposed in the second body 221 along the width direction (y direction) of the second prevention plate 220. As shown in FIGS. 4 and 5, a plurality of second holes 223 may be horizontally disposed in the second body 221. At this time, the second hole 223 may be formed by drilling a region of the second body 221.

As the molten steel is filled into the mold 30, the molten steel can move in the horizontal direction through the second holes 223.

Meanwhile, the melting rate of the second body 221 can be increased through the second hole 223. For example, as the molten steel is filled into the mold 30, the second prevention plate 220 is immersed in the molten steel. At this time, the surface area at which the molten steel and the second body 221 are in contact with each other is improved by the second hole 223, so that the second body 221 can be rapidly melted in the molten steel.

The protection plate 300 may be rotatably disposed on one side of the first base 110. As shown in FIG. 4, the protection plate 300 may be rotatably coupled to one side of the first support portion 111 in a hinged manner.

The protection plate 300 may be rotatably disposed on one side of the second base 210. As shown in FIG. 4, the protection plate 300 may be rotatably coupled to one side of the second support portion 211 in a hinged manner.

The protective plate 300 of the molten steel is disposed on the inclined surface 62 of the groove portion 61 formed in the dummy bar head 60 to protect the inclined surface 62 of the dummy bar head 60, So that the damage caused by the falling molten steel can be prevented.

The support member 400 may be movably disposed on one side of each of the first base 110 and the second base 210.

4 and 5, the support member 400 may be movably disposed in the sliding groove 115 formed in the first support portion 111. [ For example, the support member 400 can be moved along the sliding groove 115 by forming a protrusion on the side surface of the support member 400 and forming a groove in the sliding groove 115 to engage with the protrusion.

In addition, the support member 400 may be movably disposed in the sliding groove 215 formed in the second support portion 211. The supporting member 400 can move along the sliding groove 215 by forming a protrusion on the side surface of the supporting member 400 and forming a groove in the sliding groove 215 to engage with the protrusion.

At this time, the support member 400 can support the lower surface of the protection plate 300.

6 (a), the support member 400 supports the lower surface of the protection plate 300 to restrain the rotation of the protection plate 300. As shown in FIG.

However, depending on the type of casting slab to be pulled out, the size of the groove 61 of the dummy bar head 60 and the degree of inclination of the slope 62 may be changed.

Therefore, as shown in FIG. 6 (b), the rotation angle of the protection plate 300 can be adjusted by moving the support member 400. At this time, the protection plate 300 may be disposed in parallel with the inclined surface 62 of the dummy bar head 60. Accordingly, even if the metal chip 70 is disposed on the inclined surface 62, the protection plate 300 is prevented from colliding with the metal chip 70 by the support member 400.

In addition, since the protective plate 300 is disposed in parallel to the inclined surface 62, the falling molten steel is guided to the protection plate 300 and filled in the groove 61. Therefore, the protective plate 300 can prevent some of the falling molten steel from damaging the inclined plane 62. [

The core 500 may be disposed on the upper portion of the groove 61. At this time, one side of the core 500 may be supported by the first base 110 and the other side may be supported by the second base 210. Thereby, the core 500 can prevent molten steel falling directly from falling to the groove 61 side.

The core 500 can improve the cooling rate of the molten steel filled in the mold 30. [ Accordingly, the core 500 may be formed in a coil shape, as shown in Fig.

Meanwhile, the upper portions of the first body 121 and the second body 221 may be bent. At this time, since the regions of the first and second main bodies 121 and 221 having the second holes 123 along the width direction (y direction) are lower in rigidity than other regions, they can be easily bent.

The upper portion of the first main body 121 and the second main body 221 may be bent at a predetermined angle? Toward the discharge port 11a with reference to the second hole 123 . Accordingly, it is possible to more effectively prevent the molten steel discharged from the discharge port 11a from being scattered to the upper side.

Second Example

Fig. 9 is a view showing a molten steel scattering prevention device for an immersion nozzle according to a second embodiment, which is disposed in a mold, and Fig. 10 is a sectional view of a molten steel scattering prevention device for immersion nozzle according to the second embodiment, Fig.

9 and 10, the same components as the molten steel prevention device 1 for immersion nozzle according to the first embodiment will be described with reference to the molten steel scattering prevention device 1a for immersion nozzle according to the second embodiment They are denoted by the same reference numerals, and a detailed description thereof will be omitted.

The molten steel scattering prevention device 1a for immersion nozzle according to the second embodiment is different from the molten steel scattering prevention device 1 for immersion nozzle according to the first embodiment in that the first and second prevention plates 120, There is a difference in the base 600 supporting the base 220.

9 and 10, the molten steel scattering prevention device for the immersion nozzle 1a includes a first prevention plate 120, a second prevention plate 220, a protection plate 300, a support member 400, 600). The molten steel scattering prevention device for the immersion nozzle (1a) may further include a core (500).

The base 600 may include a third base 610 and a fourth base 620.

The third base 610 may be disposed on the upper surface 63 of the dummy bar head 60 along the long side direction.

The two fourth bases 620 may be formed to protrude at a predetermined interval in the short side direction.

The first and second protection plates 120 and 220 protrude upward from the fourth base 620, respectively.

A protection plate 300 may be rotatably disposed on one side of each of the fourth bases 620. Accordingly, the shield plate 300 can be coupled to each of the fourth bases 620 in a hinged manner and pivotable.

The shield plate 300 is disposed on the inclined surface 62 of the groove 61 formed in the dummy bar head 60 to protect the inclined surface 62 of the dummy bar head 60 and to guide the molten steel to the groove 61 So that the damage caused by falling molten steel can be prevented.

The support member 400 may be movably disposed on one side of each of the fourth bases 620.

9 and 10, the support member 400 may be movably disposed in the sliding groove 115 formed in the fourth base 620. [ The support member 400 can support the lower surface of the protection plate 300.

Accordingly, depending on the degree of inclination of the inclined surface 62 of the dummy bar head 60, the support member 400 can adjust the rotation angle of the protection plate 300. [

On the other hand, the core 500 may be disposed between the fourth bases 620. Accordingly, the core 500 can be disposed on the upper portion of the groove 61.

A plurality of second holes 123 and 223 may be formed along the width direction of the first prevention plate 120 and the second prevention plate 220, respectively.

10, the upper portions of the first body 121 and the second body 221 are bent toward the discharge port 11a at a predetermined angle? With respect to the second holes 123 and 223 . Accordingly, it is possible to more effectively prevent the molten steel discharged from the discharge port 11a from being scattered to the upper side.

Third Example

Fig. 11 is a view showing a molten steel scattering prevention device for an immersion nozzle according to a third embodiment of the present invention, and Fig. 12 is a sectional view of the molten steel scattering prevention device for immersion nozzle according to the third embodiment, Fig.

11 and 12, a description will be given of a molten steel scattering prevention device 1b for an immersion nozzle according to a third embodiment. In the molten steel scattering prevention device 1, 1a for immersion nozzle according to the first and second embodiments, Can be described by the same reference numerals or the same names, and a detailed description thereof will be omitted.

The molten steel scattering prevention device 1b for immersion nozzle according to the third embodiment is different from the molten steel scattering prevention device 1 or 1a for immersion nozzle according to the first and second embodiments in that the shape of the prevention plate 700 And the two protection plates 700 are disposed apart from the core 500.

11 and 12, the molten steel scattering prevention device 1b for immersion nozzle may include two anti-scattering plates 700 spaced apart from the core 500 and the core 500. Here, the core 500 may be provided in a coil shape.

The prevention plate 700 prevents the molten steel discharged from the discharge port 11a of the immersion nozzle 11 from scattering.

When the prevention plate 700 is disposed on the core 500, the prevention plate 700 can be disposed by adjusting the spacing D from the discharge port 11a. The molten steel scattered by the immersion nozzle 1b is prevented from being adhered to the inner wall surface of the mold 30 or the sensor because the molten steel is prevented from being fixed to the inner wall surface or the sensor of the mold 30. [ can do.

Referring to FIG. 12, the prevention plate 700 may include a body 710, a first hole 720, and a third hole 730.

The main body 710 may be formed in a plate shape. The main body 710 may be disposed in the short side direction (y direction).

At this time, the main body 710 may be formed at a predetermined height h2 higher than the height h1 of the discharge port 11a. Accordingly, the main body 710 can prevent the molten steel discharged through the immersion nozzle 11 from scattering. The molten steel hitting the main body 710 can be guided by the main body 710 and moved to the core 500.

The first hole 720 may be disposed at a lower portion of the main body 710.

The first hole 720 may be disposed in one region of the core 500. Accordingly, the main body 710 can be seated in one region of the core 500.

A plurality of third holes 730 may be formed along the vertical direction (z direction) of the main body 710. As shown in FIGS. 11 and 12, a plurality of third holes 730 may be arranged vertically in the body 710.

As the molten steel is filled into the mold 30, the molten steel can move in the horizontal direction through the third holes 730. The melting rate of the main body 710 can be increased through the third hole 730.

12 (a), the third hole 730 may be formed by perforating one region of the body 710. As shown in FIG.

The side portion of the main body 710 may be bent toward the discharge port 11a at a predetermined angle? 1 with respect to the third hole 730 as shown in FIG. 12 (b). In view of the above, the body 710 can be formed in a shape in which three sides of a trapezoid are formed.

Accordingly, the bent main body 710 allows the molten steel discharged from the discharge port 11a to be easily filled in the groove portion 61 through the core 500. [

Although the third hole 730 is shown as an example of the molten steel scattering prevention device 1b for an immersion nozzle according to the third embodiment, the third hole 730 is not necessarily limited to this, and the immersion nozzle according to the first and second embodiments It is needless to say that it can also be formed in the molten steel scattering prevention device 1, 1a. Accordingly, the first prevention plate 120 and the second prevention plate 220 of the wet steel pipe splash preventing device for immersion nozzle according to the first and second embodiments may also be bent and provided as the shape of FIG. 12 (b) have.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the present invention as defined by the following claims It can be understood that

1: Dissipation prevention device for immersion nozzle
11: immersion nozzle 30: mold
60: Dummy bar head 61: Groove
62:
100: first prevention part 110: first base
111: first support portion 114:
120: first prevention plate 122, 222: first hole
123, 223: second hole
200: second prevention part 210: second base
211: second support part 214: long hole
300: Shield plate
400: support member
500: Core
600: Base 610: Third base
620: fourth base
700: Protective plate

Claims (12)

A molten steel scattering prevention device for an immersion nozzle for preventing scattering of molten steel discharged through an immersion nozzle,
A first prevention part spaced apart from a discharge port of the immersion nozzle at a predetermined interval; And
And a second prevention part spaced apart from the other one of the discharge ports of the immersion nozzle at a predetermined interval,
Wherein one of the first prevention portion and the second prevention portion is movably installed in the other one of the first and second prevention portions so that the spacing can be adjusted. The method according to claim 1,
The first prevention part
A first base disposed at an upper portion of the dummy bar head; And
A first prevention plate projecting from the first base to prevent scattering of the molten steel; And
And a projection formed on the first base,
The second prevention portion
A second base disposed on top of the dummy bar head; And
A second prevention plate protruding from the second base to prevent scattering of the molten steel; And
And a slot formed in the second base,
And the second base is moved along the longitudinal direction of the elongated hole by the protrusion when the second preventing portion is moved. 3. The method of claim 2,
And a first hole is formed in a lower portion of each of the first prevention plate and the second prevention plate. The method of claim 3,
Wherein the first prevention plate and the second prevention plate each have a plurality of second holes formed along the width direction thereof. 3. The method of claim 2,
Further comprising a protection plate rotatably disposed on one side of each of the first base and the second base,
Wherein the protection plate is disposed on an inclined surface of the groove formed in the dummy bar head. 6. The method of claim 5,
And a support member movably disposed on one side of each of the first base and the second base to support a lower surface of the protection plate,
Wherein the rotation angle of the protection plate is adjusted as the support member moves. The method according to claim 6,
And a coil-shaped core disposed above the groove,
Wherein one side of the core is supported by the first base and the other side is supported by the second base. A molten steel scattering prevention device for an immersion nozzle for preventing scattering of molten steel discharged through an immersion nozzle,
A base having a third base disposed on an upper surface of the dummy bar head along a long side direction of the mold and two fourth bases protruding from the third base in a direction of a short side of the mold at a predetermined interval;
A first prevention plate and a second prevention plate protruding upward from each of the fourth bases; And
And a protection plate rotatably disposed on one side of each of the fourth bases,
Wherein the protection plate is disposed on an inclined surface of the groove formed in the dummy bar head. 9. The method of claim 8,
And a support member movably disposed on each of the fourth bases to support a lower surface of the protection plate,
Wherein the rotation angle of the protection plate is adjusted as the support member moves. 10. The method of claim 9,
And a coil-shaped core disposed above the groove,
And the core is disposed between the fourth base and the molten steel. 11. The method of claim 10,
Wherein the first prevention plate and the second prevention plate each have a plurality of second holes formed along the width direction thereof. A molten steel scattering prevention device for an immersion nozzle for preventing scattering of molten steel discharged through an immersion nozzle,
A coil-shaped core disposed on an upper portion of the groove portion formed in the head of the dummy bar; And
And two prevention plates arranged on the core so as to be spaced apart from the discharge port of the immersion nozzle by a predetermined gap,
And one region of each of the prevention plates is bent with reference to a plurality of third holes formed along the vertical direction.

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