KR100773833B1 - Molten mold flux for submerged nozzl - Google Patents

Abstract

A submerged nozzle for a molten mold flux is provided to prevent the molten mold flux from losing heat by forming an insulating board which is spread corresponding to a level of the molten mold flux. A submerged nozzle(100) for a molten mold flux comprises a nozzle body(110) and an insulating board(140). The nozzle body is provided in a mold and has a tube structure including a flow path. The nozzle body has a closed inner bottom surface and a side surface including an outlet(120). The insulating board is prepared at a direct upper side of the outlet and is hinged to the nozzle body. The insulating board has a shape and a size corresponding to those of an inner major side and a minor side of the mold.

Description

Immersion nozzle for melt mold flux {MOLTEN MOLD FLUX FOR SUBMERGED NOZZL}

1 is a cross-sectional view showing a conventional immersion nozzle for melt mold flux.

Figure 2 is a perspective view showing the immersion nozzle for melt mold flux according to the present invention.

3 is a cross-sectional view showing the operation of the immersion nozzle for the molten mold flux in the initial supply state of the molten mold flux.

It is sectional drawing which shows operation | movement of the immersion nozzle for molten mold flux in the medium-term supply state of molten mold flux.

5 is a cross-sectional view showing the operation of the immersion nozzle for molten mold flux in the terminal supply state of the molten mold flux.

<Description of Symbols for Main Parts of Drawing>

10, 100: immersion nozzle 12, 120: discharge port

20: mold 30: molten steel

40 melt mold flux layer 110 nozzle body

130: fastening portion 140: insulation board

The present invention relates to an immersion nozzle for molten mold flux, and more particularly, to an immersion nozzle for molten mold flux that can prevent the temperature drop of the molten mold flux when the molten mold flux is supplied to the mold through the immersion nozzle. .

Generally, cast steel produced in a continuous casting apparatus is manufactured by receiving molten steel from a ladle and temporarily storing the molten steel in a tundish and then feeding the mold. Cooling water flows inside the wall of the mold to take away the heat of the molten steel in contact with the inner wall of the mold to form a solidified shell, and the molten steel is completely drawn to the cooling water sprayed through the spray nozzle by drawing the solidified shell under the solidified shell. While solidified, a cast is produced that matches the size and shape of the mold.

Thus, when molten steel is supplied to the mold, not only molten steel but also an auxiliary mold flux is supplied to the mold, and the mold flux may be easily lubricated so that the molten steel can easily escape from the mold when the molten steel is drawn out of the mold. It insulates the heat from being released above the mold and solidifies.

As described above, the mold flux supplied for lubrication in the mold may be supplied to the mold in a molten state in some cases. To this end, a solid mold flux, such as powder or granules, is charged to the crucible, heated to a predetermined temperature, melted into a liquid phase, and then supplied to a mold.

1 is a cross-sectional view showing a conventional immersion nozzle for melt mold flux. Referring to the drawings, the mold flux of the powder to granules is melted in a mold flux melting furnace (not shown) equipped with a heating means, and the mold flux melting furnace to supply the molten mold flux into the mold 20. An immersion nozzle 10 is provided that is connected and drawn into the mold.

The conventional molten mold flux immersion nozzle 10 has a substantially upright tube shape and a flow path through which the molten mold flux flows is formed, and an inner bottom surface of the immersion nozzle 10 is located below a mold. The molten mold flux discharge port 12 is formed on the side (circumference of the outer diameter of the immersion nozzle) and opened at right angles to the direction of the flow path to block the flow of the furnace molten mold flux directly.

Referring to the conventional melt mold flux immersion nozzle 10 as described above, the molten mold flux is supplied to the mold 20 through the immersion nozzle 10 when the mold flux is melted in the mold flux melting furnace, The immersion nozzle 10 is positioned above the molten surface (the uppermost layer of the molten steel supplied into the mold), and a part of the immersion nozzle 10 is positioned at a height that can be immersed in the molten mold flux layer 40.

In this state, when the molten mold flux is first supplied to the mold 20, the molten mold flux moves along the flow path formed inside the immersion nozzle 10 to supply the molten steel 30 to the mold 20 through the discharge port 12. Is fed to the top of the.

At this time, the molten mold flux supplied to the molten surface through the discharge port 12 of the immersion nozzle 10 generates heat loss while contacting the outside air at the same time as the discharge. In other words, the temperature drop due to the heat loss of the molten mold flux adversely affects the cast quality during continuous casting.

In other words, when the temperature of the molten mold flux in the mold 20 is lowered, the uppermost layer of the molten mold flux layer 40 positioned on the molten surface in contact with the outside air is solidified, thereby lowering the fluidity of the molten mold flux. This has a problem of directly affecting the consumption of mold flux per unit area due to slab drawing, thereby reducing the lubrication between the slab and the mold, thereby increasing the frequency of breakout.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is to provide an immersion nozzle for molten mold flux, which can prevent a temperature drop of the molten mold flux supplied to a mold.

Another object is to provide an immersion nozzle for molten mold flux which can prevent the molten mold flux from scattering and stabilize the water surface when the molten mold flux is discharged from the immersion nozzle into the mold.

Technical concept of the present invention for achieving the above object, the nozzle body having a shape of a tube located in the mold and the flow path formed therein, the inner bottom is closed and the molten mold flux discharge port is formed on the side, and the discharge port It is achieved by an immersion nozzle for molten mold flux that includes a heat insulating board hingedly fastened to the nozzle body.

Here, it is preferable that the heat insulation board has a shape and size corresponding to the long and short sides in the mold in which the nozzle body is located.

In addition, the insulation board is preferably installed detachably with the nozzle body.

In addition, the insulation board is preferably made of a material lighter than the specific gravity of the molten mold flux supplied to the mold.

Hereinafter, embodiments according to the present invention will be described in more detail with reference to the accompanying drawings.

Figure 2 is a perspective view showing the immersion nozzle for melt mold flux according to the present invention. Referring to the drawings, the immersion nozzle 100 for the molten mold flux according to the present invention, the nozzle body 110 is introduced into the mold in the mold flux melting furnace (not shown), and provided in the nozzle body 110 It is composed of a thermal insulation board 140 to expand the valve according to the level of the molten mold flux supplied to the mold.

The nozzle body 110 has a substantially tubular shape and a flow path through which the molten mold flux flows is formed therein, and an inner bottom surface is formed at a position where the flow path ends so that the molten mold flux flows directly under the mold. Will be blocked.

In some cases, the structure may be formed to form a plurality of irregularities on the inner bottom surface or to have a gentle arc shape to prevent the molten mold flux flowing along the flow path of the nozzle body 110 from colliding with the inner bottom surface and scattering. It may be made of.

In addition, the molten mold flux discharge port opened to intersect the flow direction of the molten mold flux flowing through the flow path around the inner bottom surface of the nozzle body 110, that is, the outer diameter of the nozzle body 110 in which the inner bottom surface is located ( 120) is formed. The discharge port 120 is preferably formed in at least two places so as to be branched in various directions to be supplied to the mold.

Above the outlet 120 formed in the nozzle body 110 as described above is provided with a heat insulating board 140 to expand the opening according to the level of the molten mold flux supplied to the mold, the heat insulating board 140 is in the mold It has a shape and a length corresponding to the long side and the short side, and is hinged to the nozzle body.

In other words, the insulation board 140 is made of a substantially rectangular plate, but may block heat loss in the molten mold flux layer supplied to the mold, and may be sufficiently refractory to heat emitted from the molten surface and the molten mold flux layer. It is preferable that it consists of.

In addition, one end of the insulation board 140 has a bent shape surrounding the radius of the nozzle body 110 or has a recessed shape having a diameter larger than the radius of the nozzle body 110, and protrusions opposed to the inside thereof. Is formed. On the other hand, a fastening portion 130 having a groove into which a protrusion formed in the heat insulation board 140 is inserted is provided directly above the discharge hole 120 formed in the nozzle body 110, and the heat insulation board 140 is connected to the nozzle body ( 110) and hinged.

That is, the insulation board 140 is fastened so that the projections hinged to the nozzle body 110 and the hinge body can be rotated in the longitudinal direction of the nozzle body 110, and the insulation board 140 has a specific gravity of the molten mold flux. It is preferably made of a material that is lighter and can float in the molten mold flux.

Here, the hinge fastening of the insulation board 140 and the nozzle body 110 is not limited to the above-described structure can be changed. For example, grooves may be formed at both ends of one end of the heat insulation board 140, and protrusions may be formed at the fastening part 130 of the nozzle body 110 to hinge the fastening, and in some cases, the nozzle body ( The heat insulation board 140 may be hinged directly to the nozzle body 110 without the fastening part 130 being formed in the 110.

The operation of the immersion nozzle for melt mold flux having the above configuration will be described based on FIGS. 3 to 5.

3 is a cross-sectional view showing the operation of the immersion nozzle for the molten mold flux in the initial supply state of the molten mold flux. Referring to the drawings, the molten steel received in the tundish (not shown) is supplied to the mold 20 through a molten steel immersion nozzle (not shown) installed in the lower portion of the tundish, and is supplied to the mold 20 According to the casting state of the molten steel, the molten mold flux flows downward along the flow path formed in the immersion nozzle 100 for the molten mold flux.

The molten mold flux flowing downward along the flow path formed in the immersion nozzle 100 for the molten mold flux is branched from the inner bottom surface at which the flow path ends and is discharged to the upper portion of the molten steel 30 through the discharge port 120. That is, the immersion nozzle 100 for the molten mold flux is positioned above the molten surface, and the molten mold flux is positioned at a height at which a portion of the molten mold flux may be immersed in the molten mold flux layer 40. Movement along the flow path of the () is discharged to the upper portion of the molten steel 30 through the discharge port 120.

Since the molten mold flux discharged through the discharge port 120 is discharged to the upper portion of the molten steel with a predetermined flow rate, the other end of the insulation board 140 located in front of the discharge port 120 is pushed in the molten mold flux discharge direction. Thus, the insulation board 140 is rotated in the molten mold flux discharge direction with the axis of the nozzle body 110 hinged to the axis. In this case, the insulation board 140 may block the scattering of the molten mold flux generated when the ejection opening 120 is discharged to the upper portion of the molten steel to stabilize the ejection of the molten mold flux.

It is sectional drawing which shows operation | movement of the immersion nozzle for molten mold flux in the medium-term supply state of molten mold flux. Referring to the drawings, when the molten mold flux is supplied to the upper portion of the molten steel 30 through the discharge port 120, the heat insulation board 140 is lighter than the specific gravity of the molten mold flux, the nozzle body 110 and The floating in the molten mold flux about the hinged axis minimizes the contact of the molten mold flux with the outside in the mold 20.

5 is a cross-sectional view showing the operation of the immersion nozzle for molten mold flux in the terminal supply state of the molten mold flux. Referring to the drawings, when the molten mold flux supplied through the immersion nozzle 100 for the molten mold flux is supplied to the mold 20 to a predetermined height, the supply of the molten mold flux is stopped or the supply amount is continuously maintained. Will be reduced.

At this time, the height of the molten mold flux layer supplied to the mold, as shown in the figure, the water insulation board 140 and the heat insulation board 140 of the molten mold flux so as to reach the position hinged to the nozzle body 110. Becomes horizontal, and the insulation board 140 may cover the entire areas of the long side and the short side in the mold 20 to completely block contact between the outside air and the molten mold flux in the mold 20. The temperature loss can be prevented by reducing the heat loss of the molten mold flux supplied to 20).

On the other hand, the present invention is not limited only to the above-described embodiment, but can be modified and modified within the scope not departing from the gist of the present invention, it should be seen that such modifications and variations are included in the technical idea of the present invention. do.

For example, the immersion nozzle for the molten mold flux may be provided with a sliding gate for controlling the discharge amount of the molten mold flux. In addition, the insulation board may be made of a transparent material or may form an observation window on the insulation board to observe the state of the molten surface from the outside of the mold.

In addition, the immersion nozzle for the molten mold flux may be installed to penetrate through the tundish into the mold and may be supplied to the mold while the molten mold flux passing through the tundish is preheated.

The immersion nozzle for the molten mold flux according to the present invention is provided with an insulating board that actively expands in accordance with the level of the molten mold flux supplied to the mold, thereby blocking contact between the outside air and the molten mold flux to supply the molten melt. It is possible to reduce the heat loss of the mold flux to prevent the temperature drop.

In addition, when the molten mold flux is discharged into the mold, there is an effect of preventing the molten mold flux from scattering and stabilizing the water surface.

Claims (4)

A nozzle body having a shape of a tube located in the mold and having a flow path formed therein, the inner bottom of which is closed and a molten mold flux discharge port formed on a side thereof; An immersion nozzle for molten mold flux including a heat insulating board hingedly coupled to the nozzle body and positioned directly above the discharge port. The method according to claim 1, The insulating board has a shape and size corresponding to a long side and a short side in a mold in which the nozzle body is located. The method according to claim 1, The heat insulation board, the immersion nozzle for the molten mold flux, characterized in that the detachable installation with the nozzle body. The method according to claim 1, The insulating board, the immersion nozzle for molten mold flux, characterized in that made of a material lighter than the specific gravity of the molten mold flux supplied to the mold.

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