KR20130099331A - Collrctor nozzle for ladle - Google Patents

Abstract

PURPOSE: A collector nozzle for a ladle is provided to prevent the formation of an inclusion generated by molten steel scattered on a molten steel injection unit of the shroud nozzle, thereby improving a lifetime of the shroud nozzle. CONSTITUTION: A collector nozzle (130) for a ladle (100) includes a body unit (132). The body unit guides molten steel inside the ladle to a shroud nozzle (150) and includes a ring-shaped transfer guide unit (134). The transfer guide is formed on the lower part of the body unit to be integrated and extended to the lower outer side.

Description

Collector Nozzle for Ladles {COLLRCTOR NOZZLE FOR LADLE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a nozzle for use in steel ladle, and more particularly, to a collector nozzle for a ladle mounted at the bottom of a ladle to guide molten steel from a ladle to a shroud nozzle.

In general, a continuous casting machine is a facility for producing a slab of a predetermined size by receiving molten steel produced in a steelmaking furnace and transferred to a ladle in a turndish and supplying it as a mold for a continuous casting machine.

The continuous casting machine includes a ladle for storing molten steel, a continuous casting machine mold for cooling the tundish and the molten steel discharged from the tundish to form a casting having a predetermined shape, and a casting formed in the mold connected to the mold. It includes a plurality of pinch roller to move.

For the flow of molten steel from the ladle to the tundish, collector nozzles and shroud nozzles are used. The collector nozzle is coupled to the ladle and the shroud nozzle is coupled to the collector nozzle.

A related prior art is Korean Utility Model Publication No. 2000-13981 (published date; July 15, 2000, name; Ladle collector nozzle).

The present invention provides a ladle collector nozzle for preventing molten steel from scattering in the molten steel injection portion of the shroud nozzle during transfer of the molten steel from the ladle to the shroud nozzle.

The technical problems to be achieved by the present invention are not limited to the technical problems mentioned above.

Ladle collector nozzle of the present invention for realizing the above object is formed in the body portion for guiding the molten steel in the ladle to the shroud nozzle side, and the body portion, the molten steel toward the wall surface of the molten steel injection portion of the shroud nozzle It may include a ring-shaped transfer guide to prevent scattering.

In detail, the transfer guide part may be integrally formed at the lower part of the body part and may extend outward from the lower part of the body part.

The conveying guide part may be coupled to the inner circumferential surface of the body part and extend outward from the lower part of the body part.

The transfer guide portion and the body portion may be attached by a bonding material applied between the outer circumferential surface of the transfer guide portion and the inner circumferential surface of the body portion.

According to the ladle collector nozzle described above, it is possible to prevent molten steel from scattering in the molten steel injection portion of the shroud nozzle during transfer of the molten steel from the ladle to the shroud nozzle.

In addition, the formation of inclusions is prevented, thereby reducing the frequency of cleaning by the oxygen lance of the molten steel injection portion of the shroud nozzle, thereby improving the life of the shroud nozzle.

1 is a conceptual diagram showing a continuous casting machine according to an embodiment of the present invention mainly on the flow of molten steel.
2 is a partial cross-sectional view conceptually showing the configuration of the tapping portion of the ladle of FIG.
3 is a detailed view of a collector nozzle according to an embodiment of the present invention.
4 is a detailed view of a collector nozzle according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like elements in the figures are denoted by the same reference numerals wherever possible. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

1 is a conceptual diagram showing a continuous casting machine according to an embodiment of the present invention mainly on the flow of molten steel.

Continuous casting is a casting method in which molten metal is solidified in a mold having no bottom (Mold, 300) and continuously drawn out of a cast or steel ingot. Continuous casting is used to make long products of simple cross-section, such as square, rectangular or round, and mainly slabs, blooms or billets, which are materials for rolling.

As shown, the continuous casting machine may include a ladle 100, a tundish 200, a mold 300, a support roll 60, and a cutter (not shown).

Ladle (Ladle) 100 is a molten steel containing a steel content is formed through a refining process.

The tundish 200 is a container that receives the molten metal from the ladle 100 and supplies the molten metal to the mold 300. Ladle 100 is provided in a pair, alternately receives molten steel to supply to the tundish 200. In the tundish 200, the supply rate of molten metal flowing into the mold 300 is adjusted, the molten metal is distributed to each mold 300, the molten metal is stored, and the slag and the non-metallic inclusions are separated.

The mold 300 is typically made of water-cooled copper and allows the molten steel to be primary cooled. The mold 300 forms a hollow portion in which molten steel is accommodated as a pair of structurally facing surfaces are opened. In manufacturing the slab, the mold 300 includes a pair of barriers and a pair of end walls connecting the barriers. Here, the end wall has a smaller area than the barrier. The walls of the mold 300, mainly short walls, may be rotated to move away from or close to each other to have a certain level of taper.

Mold 300 has a solid cast angle or solidified shell (Solidified Shell, 80) is formed so that the cast piece drawn out from the mold 300 maintains a certain shape, and the molten metal which is still less solidified does not flow out Play a role. The water-cooling structure includes a method using a copper tube, a method of water-cooling the copper block, and a method of assembling a copper tube having a water-cooling groove.

The mold 300 is oscillated to prevent the molten steel from sticking to the wall surface of the mold 300, and reduces friction between the mold 300 and the solidification shell 80 and prevents burning during oscillation. Lubricating agents such as powders are used for this purpose. The powder is added to the molten metal in the mold 300 to become slag, as well as the lubrication of the mold 300 and the solidification shell 80, as well as to prevent oxidation and nitriding of the molten metal in the mold 300, and to keep the surface of the molten metal. It also performs the function of absorption of emerging nonmetallic inclusions.

The secondary cooling stand further cools the molten steel that is primarily cooled in the mold 300. The primary cooled molten steel is directly cooled by the spraying means 65 for spraying water while being maintained by the support roll 60 so that the coagulation angle is not deformed. The solidification of the cast steel is mostly made by the secondary cooling.

The pulling device employs a multi-drive type or the like that uses several pairs of pinch rolls (not shown) so as to pull out the casting slides without slipping. A pinch roll (not shown) pulls the solidified tip 83 of the molten steel in the casting direction, thereby allowing the molten steel passing through the mold 300 to continuously move in the casting direction.

Continuously produced cast pieces are cut to a certain size by a predetermined cutter (not shown).

That is, the molten steel M flows to the tundish 200 in the state accommodated in the ladle 100. For this flow, the ladle 100 is provided with a shroud nozzle 150 extending toward the tundish 200. The shroud nozzle 150 extends to be immersed in the molten steel in the tundish 200 so that the molten steel M is not exposed to air and oxidized / nitrided.

The molten steel M in the tundish 200 flows into the mold 300 by a submerged entry nozzle 250 extending into the mold 300. The immersion nozzle 250 is disposed in the center of the mold 300 so that the flow of molten steel M discharged from both discharge ports of the immersion nozzle 250 can be symmetrical. The start, discharge speed, and stop of the discharge of the molten steel M through the immersion nozzle 250 are determined by the stopper 210 installed in the tundish 200 in response to the immersion nozzle 250.

The molten steel M in the mold 300 starts to solidify from the portion in contact with the wall surface forming the mold 300. This is because heat is more likely to be lost by the mold 300 in which the periphery is cooled rather than the center of the molten steel M. By the way that the periphery is first solidified, the back portion along the casting direction of the cast slab forms a form in which the non-solidified molten steel is wrapped in the solidified shell 80.

As the pinch roll (not shown) pulls the tip portion 83 of the completely cast piece, the unsolidified molten steel moves together with the solidified shell 80 in the casting direction. The uncondensed molten steel is cooled by the spray means 65 for spraying the coolant during the movement of the stomach. This causes the thickness of the unsolidified molten steel to gradually decrease in the cast cast. When the cast steel reaches a point, the cast steel is filled with the solidification shell 80 of the entire thickness. The finished casting cast piece is cut to a certain size at the cutting point 91 and divided into slabs P such as slabs.

2 is a partial cross-sectional view conceptually showing the configuration of a part for tapping the molten metal of the ladle 100 of FIG.

Referring to this figure, a tap hole for tapping the molten steel is opened at the bottom of the ladle 100. The upper nozzle 120 is inserted into the exit port.

Upper and lower sliding gates 140 are installed below the upper nozzle 120. The collector nozzle 130 is installed as a lower nozzle below the lower sliding gate 140. The shroud nozzle 150 is fastened to the collector nozzle 130.

The upper and lower sliding gates 140 open and close the moving passage of the molten steel from the upper nozzle 120 to the shroud nozzle 150 while slidingly moving in the horizontal direction.

On the other hand, when the general collector nozzle 130 is used, the molten steel is scattered toward the molten steel injection part wall side of the shroud nozzle 150 by the inner diameter difference between the collector nozzle 130 and the shroud nozzle 150 while the molten steel is moved. Thus, inclusions are formed in the “A” portion (FIG. 2). These inclusions not only act as a factor to hinder the flow of molten steel, but also prevent the close connection with the collector nozzle 130 when reconnecting to use the shroud nozzle 150 repeatedly.

Therefore, after using the shroud nozzle 150, such inclusions are removed by washing the molten steel inlet with an oxygen lance for subsequent reuse. At this time, by decarburizing the shroud nozzle 150 that is oxygenated carbonaceous refractory, the shroud nozzle 150 is fragile, and the service life of the shroud nozzle 150 is reduced.

However, when the collector nozzle 130 of the present invention is used, molten steel is guided to the shroud nozzle 150 without being scattered from the molten steel injection portion at the top of the shroud nozzle 150, thereby preventing inclusions from being formed. .

Specifically, the collector nozzle 130 of the present invention may include a body portion 132 and the transfer guide portion 134, as shown in Figs.

The body 132 guides the molten steel inside the ladle 100 to the shroud nozzle 150. In general, the body 132 is connected to the bottom of the sliding gate 140 at the bottom of the ladle 100 as shown in Figure 2, but may be directly connected to the ladle 100 when the sliding gate 140 is not configured. . On the other hand, the shroud nozzle 150 is connected to the lower side of the body portion 132 to transfer the molten steel passing through the body portion 132 to the tundish 200.

The body portion 132 is formed with a ring-shaped conveying guide portion 134, to prevent molten steel from scattering toward the wall surface of the molten steel injection portion of the shroud nozzle 150. To this end, the transfer guide part 134 is preferably formed to have a length extending to the lower portion of the molten steel injection portion of the shroud nozzle 150.

As shown in FIG. 3, the transfer guide part 134 may be integrally formed at the lower part of the body part 132 and may extend outward from the lower part of the body part 132. Alternatively, the transfer guide part 134 may be coupled to the inner circumferential surface of the body part 132 as shown in FIG. 4 and may extend outward from the bottom of the body part 132. In this case, the transfer guide part 134 is formed of a material having high resistance to high heat of molten steel. Specifically, the transfer guide part 134 is preferably made of alumina, which is the same material as the body part 132, and is easily attached to the body part 132 without a sense of heterogeneity.

Here, the transfer guide portion 134 and the body portion 132 is attached by an adhesive material 136 applied between the outer circumferential surface of the transfer guide portion 134 and the inner circumferential surface of the body portion 132. For example, a mortar adhesive material 136 may be used as the adhesive material 136.

The collector nozzle for the ladle as described above is not limited to the configuration and operation of the embodiments described above. The embodiments may be configured so that all or some of the embodiments may be selectively combined so that various modifications may be made.

According to the ladle collector nozzle described above, it is possible to prevent molten steel from scattering in the molten steel injection portion of the shroud nozzle during transfer of the molten steel from the ladle to the shroud nozzle.

In addition, the formation of inclusions is prevented, thereby reducing the frequency of cleaning by the oxygen lance of the molten steel injection portion of the shroud nozzle, thereby improving the life of the shroud nozzle.

100: ladle 120: upper nozzle
130: collector nozzle 132: body
134: transfer guide portion 136: adhesive material
140: sliding gate 150: shroud nozzle
200: tundish 210: stopper
250: immersion nozzle 300: mold
60: support roll 65: spray means
80: solidified shell 83: distal end
91: cutting point

Claims (4)

A body portion for guiding molten steel inside the ladle toward the shroud nozzle; And
And a ring-shaped conveying guide part formed on the body part to prevent molten steel from being scattered toward the wall surface of the molten steel injection part of the shroud nozzle.
The method according to claim 1,
The conveyance guide portion
The collector nozzle for the ladle is formed integrally with the lower portion of the body portion and extends to the lower outer side of the body portion.
The method according to claim 1,
The conveyance guide portion
Coupled through the inner circumferential surface of the body portion and the collector nozzle for ladle extending to the outer side of the lower portion.
The method according to claim 3,
The transfer guide portion and the body portion,
Ladle collector nozzles are attached by a bonding material applied between the outer peripheral surface of the transfer guide portion and the inner peripheral surface of the body portion.

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