KR20140058767A - Apparatus for molten metal treatment and the method thereof - Google Patents

Abstract

The present invention relates to an apparatus and a method for treating molten metal. The apparatus for treating molten metal comprises a container for containing molten metal and a refractory ring included in the container to move vertically while floating by the molten metal. Therefore, the present invention can increase the life span of a refractory material by inhibiting base metal from adhering to the inside of the container in the process of treating the molten metal.

Description

[0001] DESCRIPTION [0002] Apparatus for molten steel treatment and the method thereof [

The present invention relates to a molten steel treatment apparatus and a treatment method thereof, and more particularly to a molten steel treatment apparatus and a treatment method therefor which can improve the life of refractory by suppressing the adhesion of the present in the vessel during the treatment of molten steel .

A vessel is a device used to uniformize and improve the quality of molten steel by removing the gas and impurities in the molten steel by receiving the molten steel. Generally, the vessel used for the degassing operation and the impurity removing operation of the molten steel removes impurities and gas from the molten steel while refluxing the molten steel through the reflux pipe provided in the lower tank. At this time, the reflux pipe uses the vacuum pump to reflux the molten steel in the ladle.

The structure of the vessel used for improving the quality of molten steel is shown in Fig.

Referring to FIG. 1, a structure of a vessel 100 is provided with a vessel lower vessel 150 at a lower portion thereof, and a return pipe 160 is provided at both sides of a lower end of a vessel lower vessel 150. The reflux pipe 160 is paired with an uprising pipe 160b for sucking the molten steel M of the ladle 110 and a downfalling pipe 160a for feeding down the sucked molten steel M to the ladle 110 again. A bottom wall of the reflux pipe 160 divided into the uprising pipe 160b and the downfalling pipe 160a is provided with a dip pipe 1170 contained in the molten steel M of the ladle 110. [

The upper part of the vessel lower tank 150 is provided with a device for evacuating the inside of the vessel 100 to remove impurities and gas generated during the processing of the molten steel and for inputting alloy iron into the molten steel in the vessel 100 A vessel upper tank 130 connected to the upper portion of the vessel. The bezel 100 is installed in the vertical direction of the vessel lower tank 150 and the vessel upper tank 130 in order to facilitate the operation of replacing the refractory of the vessel lower tank 150. The flange 140 ). At this time, in order to facilitate the refractory replacement work, cooling water is circulated in the flange 140 to prevent the flange 140 from overheating.

However, if the temperature of the flange 140 is lowered by using the cooling water, the temperature of the connecting portion (a) between the vessel lower tank 150 and the vessel upper tank 130 is relatively lower than the other portions. The splash S generated in the process of treating the molten steel is adhered to and solidified at the connection site a between the vessel lower tank 150 and the vessel upper tank 130 where the temperature is relatively low, A phenomenon occurs. Further, when molten steel is treated for a long time, the splash S is continuously attached to (B) and the size of (B) is increased to form a lump. In this case, when the auxiliary raw material P such as alloy steel or gadolinic material is supplied to the molten steel, the added raw material P may be dropped on the upper side of the present B, (B) is melted and fused to the deposition pipe 170 or the like. Further, there is a problem that it is difficult to separate the vessel lower tank 150 and the vessel upper tank 130 to replace the refractory of the vessel lower tank 150.

KR 0812142 B KR 0270108 B

The present invention provides a molten steel treatment apparatus and a treatment method thereof capable of suppressing or preventing formation of a present in a container for containing molten steel.

The present invention provides a molten steel treatment apparatus and a method of treating the same, which can reduce the processing time by causing the present in the vessel to be spontaneously dissolved.

The present invention provides a molten steel treatment apparatus and a treatment method thereof capable of improving process efficiency and productivity.

A molten steel treatment apparatus according to an embodiment of the present invention includes: a container in which molten steel is accommodated; And a refractory ring provided in the container and lifted by the molten steel to move in a vertical direction.

The container includes: a lower container having an upper portion opened; an upper container having a lower portion opened and provided at an upper portion of the lower container; And a flange connecting the lower container and the upper container.

The refractory ring may be floated by the molten steel and disposed at a connection portion between the lower vessel and the upper vessel.

The refractory ring may be formed to have a height of 30 to 60% of the height of the lower vessel.

The refractory ring may be made using a monolithic refractory.

The outer diameter of the refractory ring may be smaller than the inner diameter of the lower vessel.

The outer circumferential surface of the refractory ring may be inclined such that the outer diameter increases from the upper portion toward the lower portion.

A molten steel treatment method according to an embodiment of the present invention includes the steps of: providing a refractory ring inside a vessel; And reflowing the molten steel to the inside of the vessel, wherein at least a part of the refractory ring is floated to the upper part of the molten steel by a molten steel flow generated by refluxing the molten steel in the process of refluxing the molten steel So that now is formed in the refractory ring.

The container may include a lower container and an upper container provided on the lower container, and the upper portion of the refractory ring may float up to a position higher than a connecting portion between the lower container and the upper container.

Some of the refractory rings formed in the refractory ring may be dissolved and removed in the molten steel during the process of refluxing the molten steel.

And immersing the refractory ring in the molten steel introduced into the container before refining and treating the molten steel to dissolve the refractory ring attached to the refractory ring.

According to the molten steel treating apparatus and the treating method therefor according to the embodiment of the present invention, it is possible to suppress or prevent the molten steel from being attached to the vessel to be treated. Particularly, it is possible to effectively suppress the attachment of the present to the connection portion (a) of the lower tank and the upper tank in a container to which the lower tank and the upper tank are connected, such as a vessel.

And now attached to the ring, the molten steel can be spontaneously dissolved in the molten steel during processing. Therefore, it is possible to shorten the time required for removing the present, and to suppress the deterioration of the service life due to the melting of the refractory due to the use of the burner. In addition, production delay due to unnecessary maintenance can be prevented, and long-time operation is also possible. In addition, it is possible to suppress the contamination of facilities and the occurrence of safety accidents due to the melts generated in the process of removing the present.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic view of a degassing apparatus to which a molten steel treatment apparatus according to the prior art is applied. Fig.
2 is a view showing a schematic configuration of a degassing apparatus to which a molten steel treating apparatus according to an embodiment of the present invention is applied;
3 is a view showing the structure of a refractory ring;
4 is a view showing a state in which molten steel is processed using the molten steel treatment apparatus according to the embodiment of the present invention.
Fig. 5 is a view showing a state of removing the now attached to the refractory ring; Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be embodied in various different forms, and it is to be understood that these embodiments are merely illustrative of the principles of the invention and are not intended to limit the scope of the invention to those skilled in the art. It is provided to let you know completely.

FIG. 2 is a schematic view of a degassing apparatus to which a molten steel treating apparatus according to an embodiment of the present invention is applied, and FIG. 3 is a view showing a structure of a refractory ring.

2, the degassing operation is performed by a ladle 210 in which the molten steel M is stored and a vessel 200 provided in the upper part of the ladle 210, .

A schematic configuration of the vessel 200 will be described. The vessel 200 is an apparatus for removing impurities and gas contained in the molten steel M in the ladle 210. The vessel 200 includes a vessel upper tank 230 and a vessel lower tank 250, A reflux pipe 260 is provided on both sides of the lower end of the pipe. One of the reflux pipes 260 is provided with an uprising pipe 260b for sucking the molten steel of the ladle 210 and the other is for returning the molten steel sucked by the uprising pipe 260b to the ladle 110 again Down pipe 260a. At this time, if a vacuum is formed inside the vessel upper and lower tanks 230 and 250, the molten steel M rises from the uprising pipe 260b and the molten steel M descends through the downfalling pipe 260a, Oxygen is blown into the upper and lower tanks 230 and 250 using a lance nozzle or the like to remove impurities in the molten steel M. [ The bezel 200 is a known component, and a detailed description thereof will be omitted.

The vessel lower tank 250 generally has a hollow shape with an open top, and an uprising pipe 260b and a downfalling pipe 260a are provided at a lower portion thereof as described above.

The vessel lower tank 250 is formed with a cylindrical steel pipe 253 and a refractory to prevent the pipe 253 from being damaged by the high temperature molten steel and has a heat insulating material 252, And a built-in tread 251 are formed. As the refractory, various refractory bricks can be used. For example, dolomite, magnesia refractory brick, or the like can be used. The permanent field 254 may be configured in a cylindrical or polygonal shape with an interior hollow and an open end. The built-in tread 251 is made of a material having sufficient heat resistance to accommodate molten steel, and can be constructed by building bricks of high heat resistance.

The vessel upper tank 230 is disposed above the vessel lower tank 250 and the vessel upper tank 230 and the vessel lower tank 250 are connected to each other by using the flange 240 at the outer peripheral surface of the vessel 200. Here, the flange 240 is supplied with cooling water to prevent or prevent overheating. The position where the flange 240 is installed, that is, the connecting portion a between the upper vessel vessel 230 and the lower vessel vessel 250, has a relatively lower temperature than the other portion.

On the other hand, when the molten steel is refluxed in the vessel 200 during the processing of the molten steel, a splash S occurs in which molten steel bounces up to the upper part of the molten steel. The splash S generated in this way causes the inner wall of the vessel 200, (251) to form now. Particularly, the splash S is easily fused to the connection portion (a) between the vessel upper tank 250 having a relatively low temperature and the vessel lower tank 230, and is now formed. During the process, the splash S is continuously fused so that the size of the splash S is increased, and the splash S is most greatly formed at the connecting portion (a) between the vessel upper vessel 230 and the vessel lower vessel 250. Therefore, in the case of the feedstock P such as alloy steel and gadolinite in the vessel 200 for processing the molten steel, there is a problem that the feedstock P is presently falling and the slip rate is lowered.

In the embodiment of the present invention, the splash S is fused to the connecting portion a of the vessel top tank 230 and the vessel bottom tank 250 to prevent the formation of the present, 300 are inserted.

The refractory ring 300 floats on the upper part of the molten steel by the molten steel generated in the process of refluxing the molten steel in the vessel 200 and attaches the splash S generated during the molten steel treatment to the inner wall of the vessel 200, Thereby suppressing the formation of the present in the connecting portion (a) between the bath 230 and the vessel lower bath 250.

The refractory ring 300 may be formed by a method such as casting using a monolithic refractory. At this time, castable, dry ramming mass, spray mass, or the like may be used as the unshaped refractory.

The outer diameter W of the refractory ring 300 may be smaller than the inner diameter of the vessel upper tank 230 and the vessel lower tank 250. Therefore, the refractory ring 300 can move up and down inside the vessel 200 while being floated by the molten steel during the processing of the molten steel, and can prevent collision with the inner wall of the vessel 200. Further, the refractory ring 300 may be formed such that the outer circumferential surface thereof is inclined, for example, the outer diameter W increases from the upper portion to the lower portion. When the refractory ring 300 floats above the molten steel and moves in the vertical direction through the above structure, friction or collision with the inner wall of the vessel 200 can be minimized, and the flow of the molten steel flows to the inner wall of the vessel 200 It can also relieve friction or impact. When the outer diameter W of the refractory ring 300 is decreased from the upper portion to the lower portion, the lower thickness T of the refractory ring 300 is decreased, and the buoyancy generated by the molten steel flow is decreased, There is a difficulty that the molten metal 300 floats on the molten steel.

Further, the refractory ring 300 may be formed to have a height H lower than the height of the molten steel accommodated in the vessel lower tank 250. This is to initially dissolve and remove the present B attached to the refractory ring 300 by contacting the refractory ring 300 with the molten steel at the initial stage of refluxing the molten steel in the vessel 200. That is, The refractory ring 300 sinks on the bottom of the vessel 200, that is, on the bottom of the vessel lower tank 250, and when the molten steel is fully refluxed, the refractory ring 300 floats up the molten steel by the molten steel . The surface of the refractory ring 300 is brought into contact with the molten steel at the initial stage of reflowing molten steel, in other words, before the refractory ring 300 floats above the molten steel, thereby dissolving the present B attached to the surface of the refractory ring 300 in the previous step . Therefore, the process waiting time can be shortened in order to remove the present (B) attached to the refractory ring 300, and the melting loss of the refractory due to the use of the burner can be suppressed.

The height H of the refractory ring 300 is lower than the height L of the vessel lower tank 250 which is lower than the height L of the vessel lower tank 250 Of the total thickness of the substrate. The refractory ring 300 may have a thickness T of about 2 to 5% of the inner diameter of the lower vessel 250 so that buoyant force may be generated by reflux of the molten steel. The refractory ring 300 has an outer diameter W of 2500 mm and a height H of 1000 mm and a height H of 100 mm when the lower vessel 250 is formed to have an inner diameter of 2740 mm and a height L of 2400 mm. Mm < / RTI >

As described above, the refractory ring 300 is provided in the vessel 200 so that the inner wall of the vessel 200, especially the connection portion a between the vessel upper tank 230 and the vessel lower tank 250 having a relatively lower temperature, It is possible to prevent the splash S from being attached and suppress or prevent the occurrence of the present (B).

Hereinafter, a process for treating molten steel using the molten steel treatment apparatus will be described.

FIG. 4 is a view showing a state in which molten steel is treated using a molten steel treatment apparatus according to an embodiment of the present invention, and FIG. 5 is a view showing a state where the molten steel is attached to a refractory ring.

First, the refractory ring 300 is inserted and disposed in the vessel 200. The refractory ring 300 is disposed at the bottom of the vessel 200, that is, at the bottom of the vessel bottom tank 250, before molten steel flows into the vessel 200.

When a vacuum is formed in the vessel 200, the molten steel stored in the ladle 210 flows into the vessel 200 through the uprising pipe 260b and is discharged to the ladle 210 through the downfalling pipe 260a. The molten steel is refluxed. At this time, the molten steel is raised to a predetermined height, for example, about 50% of the height of the lower vessel 250 in the vessel 200.

Since the molten steel flow is relatively weak at the initial stage of refluxing the molten steel, the refractory ring 300 inside the bezel 200 sinks on the bottom of the vessel 200, and when the molten steel is refracted due to full reflux of the molten steel, (300) floats above the molten steel. Since the surface of the refractory ring 300 is in direct contact with the molten steel at the initial stage of the reflux, which is relatively weak in the molten steel flow, the present B formed on the surface of the refractory ring 300 in the previous step is dissolved and removed in the molten steel at high temperature. Therefore, it is not necessary to separately remove the present B attached to the refractory ring 300 after the molten steel treatment.

Thereafter, the refractory ring 300 floats on the molten steel while the molten steel is being refluxed, and moves upward and downward in the vessel 200 according to the molten steel flow. At this time, the refractory ring 300 is disposed between the upper vessel vessel 230 and the lower vessel vessel 250, preferably between the vessel upper vessel 230 and the lower vessel vessel 250.

The splash S generated by the molten steel during the processing of the molten steel is attached to the surface of the refractory ring 300 and forms the present B so that the inner wall of the vessel 200, It is possible to minimize the formation of the present (B) at the connecting portion (a) of the vessel 230 and the vessel lower tank 250.

Here, the vessel has been described as being separated into the upper and lower parts to perform the degassing treatment of the molten steel, but the present invention is not limited thereto, and may be applied to various types of vessels that receive molten steel or process molten steel.

Although the present invention has been described in connection with certain exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Therefore, the scope of the present invention should not be limited by the described embodiments, but should be defined by the appended claims and equivalents thereof.

100, 200: vessel 110, 210: ladle
130, 230: Bessel top jaw 140, 240: Flange
150, 250: vessel bottom vessel 160: reflux tube
170, 270: deposition pipe 300: refractory ring

Claims (11)

A container for containing molten steel; And
A refractory ring provided in the container and lifted by the molten steel to move in a vertical direction;
And the molten steel treatment apparatus. The method according to claim 1,
The container may include:
A lower container in which an upper portion is opened,
An upper container having a lower portion opened and provided at an upper portion of the lower container; And
And a flange connecting the lower vessel and the upper vessel. The method of claim 2,
Wherein the refractory ring is floated by the molten steel and is disposed at a connecting portion between the lower vessel and the upper vessel. The method of claim 2,
And the refractory ring is formed to have a height of 30 to 60% of the height of the lower vessel. The method according to claim 1 or 2,
Wherein the refractory ring is manufactured using a monolithic refractory. The method according to claim 1 or 2,
And the outer diameter of the refractory ring is smaller than the inner diameter of the lower vessel. The method of claim 6,
Wherein the outer circumferential surface of the refractory ring is formed so as to be inclined so that its outer diameter increases from the upper portion to the lower portion. Providing a refractory ring within the vessel;
And refluxing and processing the molten steel into the vessel,
In the process of refluxing the molten steel
Wherein at least a part of the refractory ring is floated above the molten steel by a molten steel flow generated by refluxing the molten steel so that the refractory ring is now formed in the refractory ring. The method of claim 8,
Wherein the container includes a lower container and an upper container provided on the upper portion of the lower container, and the upper portion of the refractory ring is lifted to a position higher than a connecting portion between the lower container and the upper container. The method of claim 8,
Wherein a portion of the refractory ring formed in the refractory ring is dissolved in and removed from the molten steel during a reflux process of the molten steel. The method according to any one of claims 8 to 10,
Before the process of refluxing the molten steel
And immersing the refractory ring in the molten steel flowing into the inside of the vessel to dissolve the now attached to the refractory ring.

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