KR200189490Y1 - Device for opening of nozzle hole in ladle - Google Patents

Abstract

The present invention relates to a nozzle opening device for ladle for penetrating a hardened molten steel of ladle when injecting molten steel into a tundish, and a burnout part which is burned out by a flame while injecting oxygen during the coagulation layer destruction work on the top of the ladle bottom nozzle port. And an ignition part installed at the tip of the burnout part to induce rapid ignition of the burnout part, and a fixed part connected to the burnout part and the oxygen holder at both ends, thereby preventing work delay and safety accident caused by ignition of the oxygen pipe. The occurrence can be prevented, and the stability of the performance casting work and the convenience of the work can be improved by shortening the opening time due to the increase in the thermal power.

Description

Nozzle Hole Opening Device for Ladle {Device for Opening of Nozzle Hole in Ladle}

The present invention relates to an opening device for ladle for continuous casting, and more particularly to a nozzle opening device for ladle for drilling the hardened molten steel of the ladle when molten steel is injected into the tundish.

The molten steel processed in the steelmaking process is transferred to the cast column to perform continuous casting.

In this continuous casting operation, the casting ladle in which the molten steel is received is opened by the cassette device attached to the lower portion, whereby the molten steel in the ladle is injected into the tundish to perform the casting operation.

However, even when the cassette device attached to the casting ladle is opened, when the molten steel solidification layer in the ladle is generated and is not naturally injected into the tundish, the casting operation is made possible by opening the solidification layer using a forced opening device.

This forced opening is closely related to the amount of molten steel in the tundish and the temperature and quality, so that continuous casting is impossible when it is not accurate and quick, which greatly affects productivity and quality, and causes casting and safety accidents. The opening work of the initial nozzle port is very important.

Figure 4 is a cross-sectional view showing a nozzle opening of the ladle according to the prior art.

Then, the nozzle hole forced opening operation of the casting ladle with reference to the drawings as follows.

As shown in FIG. 4, the top nozzle 54 and the collect nozzle 56 for injecting the molten steel 52 into a tundish (not shown) are mounted on the bottom of the ladle 51 in which the molten steel 52 is contained. The cassette 55 is installed.

When the ladle 51 arrives at the playing column, the cassette 55 is opened to inject the molten steel 52 into the tundish, the oxygen pipe 57 is ignited, and then the oxygen pipe through the collect nozzle 56. Insert 57 to break the coagulation layer 53 in the ladle.

Since the oxygen pipe 57 is now used by the operator to fold the pipe arbitrarily by 90 ° and to ignite using a torch at the distal end, it is not possible to work alone, and the operator during the ignition operation of the oxygen pipe 57. There is a risk of burns, and in order to shorten the working time due to the ignition work of the oxide pipe 57, the work is rushing, and there is a risk of various equipment and safety accidents.

In addition, the oxygen pipe 57 is difficult to handle. When the coagulation layer 53 is destroyed after being inserted into the collect nozzle 56, oxygen is not blown into the center of the coagulation layer 53, and the top nozzle 54 is surrounded by the top nozzle 54. In many cases, oxygen is blown, which causes a problem of premature burnout of ladle refractory and accident risk of molten steel outflow.

In addition, the coagulation layer 53 breaking operation using the existing oxygen pipe 57 takes a long time, and the coagulation layer being broken is locally performed to perform the second and third breaking operations, so that continuous casting is difficult. This has the problem of poor speed.

The present invention is to solve the problems as described above, the object is to provide a nozzle hole forced opening device of the ladle that can accurately and quickly destroy the solidification layer in the ladle during the performance casting operation.

1 is a cross-sectional view of the oxygen pipe which is the nozzle hole opening device of the ladle according to the present invention,

2 is a cross-sectional view taken along line A-A of FIG. 1 of the present invention;

3 is a detailed view of the ignition device of the present invention,

Figure 4 is a cross-sectional view showing a nozzle opening of the ladle according to the prior art.

Explanation of symbols on the main parts of the drawings

10: burned out portion 11: inner tube

12: internal iron core 13: internal oxygen pipe

14: external iron core 15: external oxygen pipe

20: wear part 21: drill

22: rotary pen 23: ignition plate

24: ignition stone 30: fixed part

35: fixed stopper

The present invention for achieving the object as described above,

The burned out portion which is burned out by the flame while injecting oxygen during the coagulation layer destruction work on the top of the ladle bottom nozzle port, the ignition portion which is installed at the tip of the burned portion to induce rapid ignition of the burned out portion, The oxygen holder is characterized by consisting of a fixed portion connected to both ends.

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

1 is a cross-sectional view of an oxygen pipe which is a nozzle opening device for a ladle according to the present invention, FIG. 2 is a cross-sectional view taken along line A-A of FIG. 1 of the present invention, and FIG. 3 is a detailed view of the ignition device of the present invention.

According to the drawings, the subject innovation is the burnout portion 10 which is burned out by the flame while injecting oxygen, the ignition portion 20 for inducing rapid ignition of the burnout portion 10, and the burnout portion ( 10) and an oxygen holder are composed of fixed parts 30 connected at both ends.

As shown in FIGS. 1 and 2, the burnout part 10 is burned out when the solidification layer is broken, and 12 inner cores 12 of 2π are installed around an inner pipe 11 of 7 mm, and an inner iron core is installed. (12) The outer oxygen pipe 13 of 17mm is installed on the outside. In addition, 23 external iron cores 14 of 2π are installed around the internal oxygen pipe 13, and an external oxygen pipe 15 having a diameter of 27 mm is provided outside the external iron core 14.

The swelling portion 10 is divided into a first distribution portion 16 through the inner core 12 and a second distribution portion 17 through the outer core 14 for uniform distribution of oxygen.

On the other hand, the external oxygen pipe 15 is attached to the eight fixed stoppers 35 at a 30 ° angle to the vertical direction to protect the top nozzle and prevent the eccentricity when the solidification layer breaks, the external oxygen pipe 15 of By installing the first 15mm at the rear end and the second 65mm at the front end, the burnout part 10 is naturally burned and dropped when the solidification layer is destroyed. The fixed stopper 35 can also prevent the fall by the weight of the oxygen pipe to facilitate the handling of the operator.

The ignition unit 20 is attached to the tip of the burnout section 10, as shown in Figure 3, is provided with a rotary pen 22 is rotated by the pressure of oxygen introduced, the tip of the rotary pen 22 of the solidified layer A drill 21 for destruction is attached to rotate by the rotational force of the rotary pen 22. In addition, an ignition stone 24 is attached to the rear end of the rotary pen 22 so as to be rotated by the rotational force of the rotary pen 22, and a ignition plate 23 is installed at the tip of the ignition stone 24 to rotate the rotary pen ( The ignition stone 24 is rotated by the rotational force generated when the 22 is rotated, and the ignition stone 24 is configured to generate sparks by generating friction with the ignition plate 23.

The fixed portion 30 is bent by 90 ° with an oxygen pipe having an outer diameter of 21 mm to give convenience and safety to the operator. A holder connecting portion 31 connects a small swelling portion 10 to one end and an oxygen holder to the other end thereof. Is installed.

Hereinafter, the operation of the present invention will be described.

In the continuous casting operation using the oxygen pipe of the present invention, the forced opening of the ladle is performed by the oxygen blown through the holder connecting portion 31 to be uniformly distributed in the first distribution portion 16 and the second distribution portion 17. It is introduced into the iron core 12 and the outer iron core 14, and after a predetermined pressure is formed is discharged to the outside through the inner tube (11).

At this time, the high pressure oxygen introduced into the inner tube 11 rotates the rotary pen 22 while passing through the ignition unit 20, and the drill 21 of the tip end rotates as the rotary pen 22 rotates the casting ray. The oxygen washing position of the oxygen pipe is set while destroying the coagulation layer in the field.

At the same time, the ignition stone 24 attached to the rear end of the rotary pen 22 is rotated to rub against the ignition plate 23, and the embers generated by the friction are naturally ignited by the introduced oxygen, thereby causing the burnout of the oxygen pipe. The part is ignited to allow oxygen cleaning.

In this way, the auto-ignited burnout part 10 increases the fire power as the inner iron core 12 is burned at the same time as the ignition, and then the outer iron core 14 is ignited to increase the fire power by double.

At this time, the fixed stopper 35 is located on the top nozzle so that the ignition unit 20 is directed toward the central portion of the solidification layer, thereby preventing eccentricity and protecting the surrounding ladle refractory.

As described above, the oxygen pipe of the present invention opens the nozzle hole of the ladle while the burnout portion 10 and the fixed stopper 35 are burned, and the external oxygen pipe 15 is 27 mm so that the coagulated layer destroyed is 50 mm. The molten steel in the ladle can be sufficiently injected into the tundish without the secondary and tertiary oxygen washing operations performed in the conventional working method, and since the thermal power reaches several times of the conventional method, it is possible to smoothly follow the opening time. Casting can be performed and the quality of molten steel can be prevented by reducing the time that molten steel is in contact with the outside air.

As described above, according to the nozzle opening device of the ladle according to the present invention, since the natural ignition, it is possible to prevent the operation delay and the occurrence of the safety accident caused by the ignition of the oxygen pipe, and by shortening the opening time by increasing the thermal power It is possible to increase the stability of the casting performance and the convenience of the work, and to prevent the leakage of molten steel due to the protection of the ladle refractory.

Claims (3)

In a forced ladle oxygen pipe, It consists of an inner tube installed in the center, an inner iron core installed around the inner tube, an inner oxygen pipe installed outside the inner iron core, an outer iron core installed around the inner oxygen pipe, and an outer oxygen pipe installed outside the outer iron core. Sosonbuwa; An ignition part installed at the tip of the burnout part to induce rapid ignition; The ladle nozzle opening device, characterized in that the burn-out portion and the oxygen holder is made of a fixed portion connected to both ends. The rotary pen which rotates by the pressure of oxygen which the said ignition part penetrates, The drill which is provided in the front end of the said rotary pen, and destroys the coagulation layer, The ignition stone provided and rotated in the rear end of the said rotary pen, The ladle nozzle opening device, characterized in that made of a ignition plate fixed to the bottom of the ignition stone to generate a spark by friction with the ignition stone. The apparatus of claim 1 or 2, further comprising a fixed stopper installed in the external oxygen pipe to protect the top nozzle and prevent eccentricity when the solidification layer is broken.