KR100847778B1 - bubbling plug for a ladle - Google Patents

Abstract

The present invention relates to a ladle bubbling plug which is mounted on the bottom or side of the ladle in the steelmaking process and used to blow gas for stirring molten steel, and induces the oxygen blown at a high temperature during oxygen cleaning to flow only into the gas vent. To improve the porosity and protect the steel bar from melting.

The bubbling plug for ladle according to the present invention is formed with an intake opening through which gas is blown, and forms an outer shell; A refractory body provided inside the iron shell and having a plurality of gas vents penetrating therein; A sealing refractory filling and sealing between the iron shell and the refractory body; And a sealing tube surrounding the bottom edge of the refractory body to seal between the shell and the refractory body.

Ladle, Bubbling, Plug, Gas Blow

Description

Bubbling plug for a ladle

1 is a cross-sectional view showing a bubbling plug for a conventional ladle,

2 is a perspective view showing a bubbling plug for a ladle according to the present invention,

3 is a cross-sectional view showing a bubbling plug for a ladle according to the present invention,

Figure 4 is a state diagram used during the cleaning operation of the bubbling plug for ladle according to the present invention.

<Explanation of symbols for the main parts of the drawings>

1: bubbling plug for ladle 10: shell

11: inlet 20: refractory body

21: gas vent 23: space

30: sealing refractory 40: sealing tube

The present invention relates to a ladle bubbling plug used to blow gas for stirring molten steel by attaching it to the bottom or side of the ladle in a steelmaking process, and more specifically, the oxygen blown at a high temperature during oxygen cleaning to a gas vent only. It relates to a buckle plug for ladle that can be guided to flow to improve the porosity, and can protect the steel shell with a risk of melting.

Generally in the steelmaking and refining technology, bubbling plugs are installed on the bottom or side of ladles, and an inert gas such as argon or nitrogen is blown into the molten metal through the bubbling device to stir the molten metal or to form impurities in the molten metal. Floating non-metallic inclusions present produce high quality clean steel.

The bubbling plug is a mechanism that is mounted on the bottom or side of the ladle in order to blow inert gas into the ladle. The bubbling plug should be well ventilated to ensure flow rate and ensure porosity during oxygen cleaning.

Therefore, conventionally, a bubbling plug (Japanese Patent Application Laid-Open No. 05-222434) made of porous refractory material has been proposed and used, but there is a problem in that the melt loss of the porous refractory material is remarkable and its life is extremely short.

Recently, a bubbling plug of the type as shown in FIG. 1 has been used.

1 is a cross-sectional view showing a conventional bubbling plug for ladle, the conventional ladle bubbling plug 100 is a cone-shaped body 110 is made of a compact refractory rather than a porous refractory, and up and down to secure breathability A plurality of gas vents 111 communicated with each other are formed, and the shell 120 surrounds the body 110 for protection of the body 110, and the iron shell 120 is connected to the gas vent 111. The inlet 121 is formed, and a bracket 130 is provided between the bottom of the main body 110 and the shell 120 to secure a space for supplying gas.

Since the bubbling plug is a device that is opened to blow gas, it is impossible to prevent intrusion of molten steel through the hole through which gas passes, for example, the gas vent of FIG. 1, in the state of receiving molten steel in the ladle. In particular, since the bubbling plug does not continuously blow gas, molten steel naturally invades into the gas vent and hardens due to the static pressure of the molten steel at the time of not blowing gas.

In addition, immediately after the gas is blown into the molten steel, since the temperature of the bubbling plug portion is low, molten steel solidifies on the bubbling plug, and now is formed. After casting is completed, molten steel and slag remain on the bottom of the ladle. Is rapidly dropped, causing additional molten steel and slag to solidify on top of the bubbling plug.

In this state, when the molten steel of the next charge is taken, even if gas is supplied for bubbling, normal bubbling does not occur, causing operation disturbances.

Thus, the ladle that is waiting for the next charge will dissolve the current by supplying high pressure oxygen for the current cleaning in the bubbling plug, which injects a separate oxygen supply pipe into the ladle and then bubbles Dissolved by supplying oxygen to the top of the ring plug. This should be done when the ladle is hot, and the depth of the ladle increases the length of the oxygen supply pipe, which is why it takes a long time to make accurate aiming at the top of the bubbling plug difficult. There was a problem.

In addition, it is difficult to check the degree of cleaning progress because it is difficult to check the current dissolved due to the direction in which oxygen is blown. Accordingly, the porosity of the gas vent is low due to excessive cleaning, resulting in melting of the bubbling plug or insufficient cleaning. There was a problem such as losing.

In order to solve the problems caused by the conventional bubbling plug cleaning method, the present applicant switches the blowing method of oxygen during oxygen cleaning to directly blow the high pressure oxygen into the bubbling plug to clean the now, thereby improving the opening ratio of the gas vent and It was confirmed that the process time can be shortened.

However, when the high pressure oxygen is blown into the conventional bubbling plug to clean the now, the high pressure oxygen blown in the hot air is not concentrated in the gas vent, but is blown between the gaps formed between the main body and the bark to melt the bark, The problem of falling porosity appeared.

The present invention has been made to solve the above problems, the present invention is the iron shell and the main body even if the high-pressure oxygen directly blows into the bubbling plug during the cleaning of the bubbling plug used to be mounted on the bottom or side of the ladle It is an object of the present invention to provide a bubbling plug for a ladle that can prevent damage to and improve the porosity of the gas vent by concentrating the flow of oxygen to be blown.

Bubbling plug for ladle according to the present invention for achieving the above object is formed in the inlet to the gas blown, and the iron shell forming an appearance; A refractory body provided inside the iron shell and having a plurality of gas vents penetrating therein; A sealing refractory filling and sealing between the iron shell and the refractory body; And a sealing tube surrounding the bottom edge of the refractory body to seal between the shell and the refractory body.

And, the bottom surface of the refractory body is characterized in that a space portion for accommodating the sealing tube, so that the air inlet and the gas vent communicate with the inner circumference of the sealing tube is formed.

In this case, the sealing tube is preferably formed of a refractory material, the sealing refractory is preferably formed of a castable refractory.

Hereinafter, a preferred embodiment of a bubbling plug for ladle according to the present invention will be described in detail with reference to the drawings.

2 is a perspective view illustrating a bubbling plug for a ladle according to the present invention, Figure 3 is a cross-sectional view showing a bubbling plug for a ladle according to the present invention.

As shown in the drawings, the bubbling plug 1 for ladle according to the present invention includes a steel shell 10 having a large appearance, a refractory body 20 provided inside the steel shell 10, and a gas passing therethrough, and Sealing refractories 30 for sealing between the shell 10 and the refractory body 20, and sealing tube 40 for sealing between the shell 10 and the refractory body 20 at the bottom of the refractory body 20 Include.

The iron shell 10 is formed in a cone shape, and the inlet 11 through which gas is blown is formed at one side (lower side in the embodiment of the present invention), and the other side (upper side in the embodiment of the present invention). Is open.

In the embodiment of the present invention, the iron shell 10 is implemented in the shape of a cone for preferable discharge and easy installation of the gas to be blown, but may be implemented in any shape such as a column shape or a column shape in which the bottom surface is formed into a polygon.

In addition, the refractory body 20 is made of a dense refractory material, and penetrates up and down therein to blow gas into the inlet 11 of the shell 10 to an upper portion, that is, an opening portion of the shell 10. A plurality of gas vents 21 are formed that communicate with each other so as to eject.

The number, shape, and size of the gaps of the gas vents 21 are not limited, and may be variously changed, but in the present invention, the gas vents 21 are radially based on the center of the refractory body 20. Each gas vent 21, which is distributed, has a slender oval shape and has a length of about 0.2 mm to facilitate the injection of gas, while preventing the inflow of molten steel.

At this time, the bottom surface of the refractory body 20 is formed with a concave groove-shaped space portion 23 in the position including the gas vent (21).

The space 23 is also connected to the inlet 11 of the iron shell 10 so that the gas blown into the inlet 11 is introduced into the gas vent 21 through the space 23.

The sealing refractory 30 serves to seal a gap (gab) generated between the shell 10 and the refractory body 20, preferably a space portion formed on the bottom surface of the refractory body 20 ( All parts except 23) may be filled at the point of contact with the steel bar 10.

Therefore, the gas blown into the blowing holes 11 is minimized in contact with the steel bar 10 to prevent the iron shells 10 from being dissolved by the oxygen blown through the blowing holes 11 in the hot.

In this case, the sealing refractories 30 may be made of castable refractory materials.

The castable refractory material is stable at high temperatures and is composed of alumina (Al ₂ O ₃ ) clinker as a main component and magnesia (MgO) clinker as a secondary component to provide high corrosion resistance to molten steel and slag. It has a structure on spinel.

However, the sealing refractory 30 is not limited to the castable refractory material, and may be manufactured by changing to various other refractory materials having high corrosion resistance to molten steel and slag other than the castable refractory material.

In addition, the sealing tube 40 is a hollow heat-resistant tube, which is provided to surround the bottom edge of the refractory body 20, preferably accommodated in the space 23 of the refractory body 20 The inside of the sealing tube 40, the inner periphery of the inlet 11 and the gas vent 21 may be located so as to communicate with each other.

In addition, the sealing tube 40 serves to seal the gas compressed and blown between the bottom surface of the refractory body 20 and the bottom surface of the shell 10.

The sealing tube 40 is preferably formed of a refractory material to withstand high temperatures, and is formed of a refractory material having elasticity to improve the sealing effect of the bottom surface of the refractory body 20 and the bottom surface of the steel shell 10. will be good.

Hereinafter, the cleaning operation of the bubbling plug for ladle according to the present invention will be described with reference to the accompanying drawings.

Figure 4 is a state diagram used during the cleaning operation of the bubbling plug for ladle according to the present invention.

As shown in FIG. 4, the bubbling plug 1 for ladle according to the present invention is mounted on a seating block 3 provided on the bottom or side of the ladle 2. At this time, the inlet 11 is installed so as to face the outside of the ladle (2).

In this way, when the ladle bubbling plug 1 is mounted on the ladle 2, the molten steel is taken on the ladle 2, and then, when the temperature and components of the molten steel are to be uniform, and the non-metallic inclusions are removed, an inert gas is blown in (11). Through the ladle (2).

If it is now attached to the ladle bubbling plug 1 of the ladle 2 which finished the series of processes in this way, oxygen washing is performed for the next charge process.

When oxygen washing is performed, a supply line 4 for supplying high pressure oxygen to the inlet 11 is connected, and high pressure oxygen is supplied into the bubbling plug 1 for ladle.

Then, the oxygen supplied through the inlet 11 is blown into the gas vent 21 through the space 23, and the gas vent 21 and the refractory body by the high-temperature atmosphere of the ladle 2 with this high-pressure oxygen. The solidified portion of the upper portion 20 is melted, and the molten liquid is discharged into the ladle 2 through the gas vent 21 to improve the porosity of the gas vent 21.

At this time, the high-pressure oxygen blown into the intake opening 11 is sealed by the sealing tube 40 and the sealing refractory 30 to be prevented from being blown through other paths except the gas vent 21.

Therefore, it is possible to minimize the high-pressure oxygen is in contact with the shell (10).

A test was carried out to confirm the opening efficiency and the shielding damage efficiency of the bubbling plug for ladle according to the present invention.

After the casting was completed, the ladle bubbling plug according to the present invention was installed in ten units for 20 empty ladles carried out to the ladle preparation site, and the remaining ten units were shown in FIG. A conventional bubbling plug (comparative example) for ladle was installed.

Then, 5Kg / cm ² pressure of oxygen was blown in through the inlet, and the time required for oxygen cleaning and the state of the bark after the test were investigated.

In this test, the oxygen cleaning time was defined as the time until the internal current is no longer discharged to the gas vent, and the results are shown in Table 1 below.

division Example Comparative example Travel time average 1.5 min 10.6 min Standard Deviation 1.7 minutes 3.8 minutes

As can be seen in Table 1, it was confirmed that using the bubbling plug for ladle according to the present invention can significantly reduce the oxygen cleaning time, the reason is that the high-pressure oxygen is blown into the gas vent to improve the opening efficiency It seems to improve.

And, in the embodiment equipped with a bubbling plug for the ladle according to the present invention was not found that the iron shell was dissolved, in the comparative example equipped with a conventional ladle bubbling plug was found to be partially dissolved, The reason for this is judged to be that the portion of the high-pressure oxygen blown in direct contact with the shell by the sealing refractory and the sealing tube is minimized.

As described above, when the bubbling plug for ladle according to the present invention is used, even if the high pressure oxygen is directly injected into the bubbling plug even in the hot state during the cleaning of the bubbling plug, it is sealed by the sealing tube and the sealing refractory, Since the gas of the gas is guided only to the gas vent, the flow of gas is concentrated to improve the opening rate of the gas vent and at the same time, it is possible to prevent damage to the shell.

Claims (4)

An intake port through which gas is blown is formed and forms an outer appearance thereof; A refractory body provided inside the iron shell and having a plurality of gas vents penetrating therein; A sealing refractory filling and sealing between the iron shell and the refractory body; A buckle plug for ladle formed of a refractory material and including a sealing tube surrounding the bottom edge of the refractory body to seal between the shell and the refractory body. The method of claim 1, The bottom surface of the refractory body is a bubbling plug for ladle, characterized in that the space receiving the sealing tube, the inner periphery of the sealing tube is formed so that the air inlet and the gas vent communicate with each other. delete The method of claim 1, The sealing refractory is bubbling plug for ladle, characterized in that formed of a castable refractory.

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