KR20050006882A - Ladle turret with molten iron heat insulation function - Google Patents

Abstract

PURPOSE: To provide a ladle turret with molten steel heat reserving function that prevents temperature drop of molten steel by covering ladle pockets on a ladle that waits casting or performs casting and automatically connects a hydraulic line to a cassette for molten steel discharge by hydraulic line fittings. CONSTITUTION: In a ladle turret for supporting two or more ladles to perform continuous casting, the ladle turret with molten steel heat reserving function comprises ladle pockets(10A,10b) which are formed in such a way that a lower portion and a side portion of the ladle is covered by an outer wall(11a) and inner wall(11b), the outer wall and the inner wall being spaced apart from each other in a certain distance, and which are fixed to a swing tower rotationally driven; a ladle pocket side hydraulic line fitting(66) mounted on the ladle pockets in such a way that the ladle pocket side hydraulic line fitting is positioned at the inner side of the ladle pockets to receive hydraulic pressure through a hydraulic line(50); and a ladle side hydraulic line fitting(47) which is mounted on an outer portion of the ladle(40), to which a cassette side hydraulic line(46) for supplying hydraulic pressure to a cassette for molten steel discharge is connected, and which is connected to the ladle pocket side hydraulic line fitting when the ladle is rested on the ladle pockets.

Description

Ladle turret with molten steel heat insulation function

The present invention relates to a ladle turret having a molten steel thermal insulation function, and more particularly, to a ladle turret having a molten steel thermal insulation function, which enables the molten steel of a ladle that is waiting to be cast.

In general, the ladle turret is a device that enables continuous casting to connect two ladles alternately to the tundish, and the conventional ladle turret 100 is a rotational drive of the swing tower 110 as shown schematically in FIG. Ladle pedestals 120A and 120B are provided to allow the ladles to be seated on both sides, respectively, so that the ladle pedestals 120A and 120B are alternately positioned on the top of the tundish 130 to tumble the molten steel of the ladle. By the operation of discharging), it has a configuration to maintain the continuity of the casting.

At this time, the cassette (not shown) installed in the lower portion of the ladle 140 is responsible for the discharge of the molten steel is operated hydraulically, the hydraulic line 150 for providing the hydraulic pressure to the cassette is the worker (W) directly ladle To the cassette at 140. This is because the worker W directly performs the hydraulic line connection work adjacent to the high temperature ladle 140, and thus is exposed to the risk of burn due to the high temperature, and the ladle pedestal 120A and 120B rotated and mounted thereon. The risk of a safety accident, such as damage to the body by the ladle 140 has a very high problem.

In addition, in the conventional ladle turret 100 when the ladle 140 is seated on the ladle pedestal (120A) (120B), because the periphery of the ladle 140 is maintained in a state directly exposed to the outside air, the tundish 130 When the ladle 140 is seated on the ladle pedestal 120A in a position deviated from), the molten steel of the ladle 140 seated on the ladle pedestal 120A is deprived of heat from the surroundings and cooled. Has Conventionally, this problem was to heat molten steel to have a higher temperature than the casting temperature in the molten steel refining process, which is not desirable because it takes a lot of energy to raise the temperature of the molten steel, The temperature rise of molten steel takes a long time, and the problem which causes productivity fall was also generated.

The present invention is to solve the above-mentioned conventional problems, ladle having a molten steel insulation function to wrap the ladle in the casting atmosphere or casting to prevent the temperature drop of the molten steel and to automatically connect the hydraulic line to the molten steel discharge cassette The purpose is to provide a turret.

1 is a schematic structural diagram showing a ladle turret according to the prior art;

Figure 2 is a perspective view of the ladle turret having a molten steel thermal insulation function according to the invention as a whole;

3 is a perspective view showing a partial cutaway ladle pocket of the present invention;

4 is a detailed cross-sectional view showing a hydraulic line connecting portion of the present invention;

5 is a detailed cross-sectional view showing an inert gas supply unit of the present invention.

※ Explanation of symbols about main part of drawing ※

10A, 10B: Ladle Pocket 11b: Inner Wall

11 body 11a outer wall

16: insulation 40: ladle

46, 50: hydraulic line 47, 66: hydraulic line connector

70, 72: connector 80, 82: inert gas supply pipe

110: swing tower

As a technical configuration for achieving the above object, the present invention, in the ladle turret configured to support two or more ladles for continuous casting, the shape surrounding the bottom and side of the ladle by the outer wall and the inner wall spaced a predetermined interval Ladle pocket formed to be fixed to the swing tower to be rotated, the ladle pocket side hydraulic line connector mounted to be located inside the ladle pocket and supplied with hydraulic pressure through the hydraulic line, and mounted outside the ladle and discharged molten steel Ladle having a molten steel insulation function characterized in that it comprises a ladle-side hydraulic line connector is connected to the hydraulic line connector when the cassette-side hydraulic line for supplying the hydraulic pressure to the cassette for seating the ladle pocket By providing a turret.

In addition, the ladle pocket of the present invention is characterized in that the heat insulating material is filled between the outer wall and the inner wall.

In addition, the present invention is fixed to the inside of the ladle pocket is connected to the inert gas supply pipe is connected to the ladle pocket side receiving the inert gas is fixed, the outside of the ladle to supply the inert gas to the inner molten steel of the ladle at the bottom of the ladle. It is connected to the inert gas supply pipe to be installed is coupled to the ladle pocket side connector is characterized in that the ladle-side connector receiving the inert gas is fixedly installed.

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

Figure 2 is a perspective view of the ladle turret having a molten steel thermal insulation function according to the invention as a whole, the ladle pockets 10A (10B) 10B is fixed to each side of the swing tower 110 that is rotationally driven fixed Is installed. The ladle pockets 10A and 10B have the same structure, and have an approximate container shape in which the upper end is opened and the lower end is closed so that the ladle 40 can be inserted and seated from the upper part.

Lug grooves 12 are formed at both upper ends of the ladle pockets 10A and 10B so that the lugs 42 formed on the upper left and right sides of the ladle 40 can be placed thereon, and the sides far from the swing tower 110. The spout groove 14 for accommodating the spout portion 44 of the ladle 40 is formed at the upper end.

Figure 3 is a perspective view showing a part of the ladle pocket of the present invention, the ladle pocket (10A) (10B) is composed of a body 11 consisting of an outer wall (11a) and the inner wall (11b), and the outer wall (11a) Between the inner wall (11b) may be filled with a heat insulating material 16 for suppressing heat transfer. Of course, only the air layer may be formed between the outer wall 11a and the inner wall 11b at a predetermined distance, thereby suppressing heat transfer and generating a heat insulating effect.

In addition, the bottom surface of the ladle pocket (10A) (10B) is formed through the cassette insertion port (18a) into which the molten steel discharge cassette is inserted, and the leg insertion port (18b) into which the legs of the ladle are inserted.

4 is a detailed cross-sectional view showing the hydraulic line connecting portion of the present invention, wherein the hydraulic line connecting portion is connected to the cassette of the ladle 40 when the ladle 40 is seated in the ladle pockets 10A and 10B. It is configured to be automatically connected to the cassette-side hydraulic line 46 connected.

That is, as shown in Figs. 2 and 4, the rod 60 extends up and down on the outer side of the ladle pockets 10A and 10B so as to be movable upward and downward, and the rod 60 is a ladle pocket ( It is positioned to be lowered by the lug 42 of the ladle 40 seated on 10A) 10B.

The lower end of the rod 60 is hinged to one side of the rotary link 62 rotatably mounted to the outer wall 11a of the ladle pockets 10A and 10B, and the other end of the rotary link 62. The side is hinged to the female hydraulic line connector 66, the female hydraulic line connector 66 passes through the outer wall (11a) and the inner wall (11b) of the ladle pocket (10A) (10B) ladle pocket (10A) (10B). ) Has a structure that is moved forward and backward inside. In this case, when the rod 60 is lowered by the ladle 40, the female hydraulic line connector 66 is advanced into the ladle pockets 10A and 10B, and when the rod 60 is raised, the female hydraulic line is raised. The connector 66 is configured to be retracted in a direction away from the inside of the ladle pockets 10A and 10B.

More specifically, a cone-shaped connector receiving groove 11c is formed to penetrate the outer wall 11a and the inner wall 11b toward the outer wall 11a, and the female hydraulic line connector 66 is the connector. It has a cone-shaped shape to be seated in the receiving groove (11c), the extension portion 66a integrally formed in the female hydraulic line connector 66 is extended to the outside of the ladle pocket (10A) (10B) to the It is hinged to the rotary link 62, the hydraulic line 50 is connected to the female hydraulic line connector 66. In addition, the female hydraulic line connector 66 is formed with a cone-shaped groove 67 of a shape gradually expanding toward the ladle 40 toward the ladle 40 side.

In addition, a male hydraulic line connector 47 having a cone shape is fixedly installed outside the ladle 40 so as to be coupled to the female hydraulic line connector 66, and a cassette-side hydraulic pressure is provided at the male hydraulic line connector 47. Line 46 is connected.

Of course, the hydraulic line 46, 50 is composed of a pair of two for the hydraulic supply and hydraulic discharge, the hydraulic supply of the hydraulic line 46, 50 when the connector 47, 66 is coupled to each other Lines and hydraulic discharge lines are to be connected to each other.

The female hydraulic line connector 66 is elastically supported in a direction away from the ladle 40 by the spring 68.

Figure 5 is a cross-sectional view showing in detail the inert gas supply of the present invention, the male connector 70 is fixed to the inner wall (11b) of the ladle pocket (10A) (10B), the male connector 70 is the upper end A convex circular cross section is formed, and the inlet gas supply pipe 80 is connected to the male connector 70. At this time, the inert gas supply pipe 80 is connected through the ladle pocket (10A) (10B), the tip of the inert gas supply pipe 80 extends to the upper end of the male connector 70 is inert gas through the portion It is configured to supply.

And, the outer side of the ladle 40 is fixed to the female connector 72 is connected to be mounted on the upper portion of the male connector 70, the lower end of the female connector 72 of the male connector 70 An inert gas supply pipe 82 is connected to the upper end of the ladle 40 so as to supply an inert gas to the inner molten steel of the ladle 40 at a lower portion of the ladle 40. . At this time, the front end of the inert gas supply pipe 82 is extended to the lower end of the female connector 72 is configured to receive an inert gas through the portion.

The operation of the present invention having the above configuration will be described.

First, the ladle pockets 10A and 10B of the present invention are formed in a shape surrounding the ladle 40, and made of an outer wall 11a and an inner wall 11b to keep the molten steel of the ladle 40 warmed, thereby reducing the temperature of the molten steel. Suppress as much as possible.

In particular, the ladle 40 by allowing the air layer or the heat insulator 16 formed between the outer wall 11a and the inner wall 11b to block the heat radiated from the ladle 40 so as to stay inside the ladle pockets 10A and 10B. The molten steel is insulated.

Next, when the ladle 40 is seated in the ladle pockets 10A and 10B, the female hydraulic line connector 66 and the male hydraulic line connector 47 which make the hydraulic line connection are connected to each other, and also supply the inert gas. By connecting the male connector 70 and the female connector 72 to each other, a pipeline for automatically supplying hydraulic pressure to the ladle cassette and supplying an inert gas to the molten steel of the ladle is automatically formed.

When the inert gas is supplied to the molten steel in the ladle, while the molten steel is stirred, the non-metallic inclusions are separated and floated to improve the cleanliness of the molten steel.

Of course, when the ladle 40 is separated from the ladle pockets 10A and 10B, the female hydraulic line connector 66 and the male hydraulic line connector 47 which form the hydraulic line connection part are separated from each other, and also form an inert gas supply part. The male connector 70 and the female connector 72 are separated from each other.

According to the ladle turret having a molten steel insulation function according to the present invention as described above, the ladle pocket of the shape surrounding the ladle is installed to have an excellent effect of insulating the molten steel of the ladle.

In addition, the hydraulic lines for supplying hydraulic pressure to the cassette are automatically connected when the ladle is seated, so that a separate operator does not need to manually connect the hydraulic lines.

Claims (3)

A ladle turret configured to support two or more ladles for continuous casting, Ladle pocket is formed to have a shape surrounding the lower portion and the side of the ladle by the outer wall (11a) and the inner wall (11b) spaced apart by a predetermined distance and fixed to the swing tower 110 is rotationally driven, A ladle pocket-side hydraulic line connector 66 mounted to be positioned inside the ladle pocket and receiving hydraulic pressure through the hydraulic line 50; A cassette-side hydraulic line 46 is mounted on the outside of the ladle 40 to supply hydraulic pressure to the molten steel discharge cassette and is connected to the hydraulic line connector 66 when the ladle 40 is seated in a ladle pocket. Ladle turret having a molten steel insulation function, characterized in that it comprises a ladle-side hydraulic line connector 47 is coupled. The ladle turret of claim 1, wherein the ladle pocket is filled with a heat insulating material (16) for thermal insulation between the outer wall (11a) and the inner wall (11b). According to claim 1, Ladle pocket side connector 70 is connected to the inert gas supply pipe 80 to receive the inert gas is fixed to the inside of the ladle pocket, the ladle 40 to the outside of the ladle 40 Connected to the inert gas supply pipe 82 is connected to be installed to supply the inert gas to the inner molten steel of the ladle 40 at the bottom of the ladle-side connector 72 is coupled to the ladle pocket-side connector 70 receives the inert gas Ladle turret having a molten steel insulation function characterized in that the fixed).