KR101321046B1 - Method and apparatus for preventing melting steel scattering - Google Patents

Abstract

The present invention relates to a device and a method for preventing scattering of molten steel that occurs initially when injecting molten steel into a mold through an immersion nozzle, and in particular, a molten steel guide integrally formed at one side of a connection portion inserted into an outlet of the immersion nozzle. The molten steel scattering prevention method and apparatus for preventing the scattering of the molten steel by supplying the molten steel to the mold through the molten steel guide including another molten steel guide installed on the other side of the connecting portion.

Description

Method and apparatus for preventing molten steel scattering

The present invention relates to an apparatus and a method for preventing scattering of molten steel generated at the beginning of a process of injecting molten steel into a mold through an immersion nozzle, and in particular, a molten steel guide integrally formed at one side of a connection portion inserted into an outlet of the immersion nozzle. The molten steel scattering prevention method and apparatus for preventing the scattering of the molten steel by supplying the molten steel to the mold through the molten steel guide including another molten steel guide installed on the other side of the connecting portion.

In general, continuous casting equipment is for manufacturing molten steel into semi-finished products such as slabs, and consists of a tundish, a mold, and a plurality of rolls of the machine, and after the molten steel passes through the mold to form a solidified layer, It has a manufacturing process for cooling the surface of the cast piece by spraying the cooling water as it passes between the rolls of players arranged on both sides of the dog.

In more detail, the molten steel that has been blown in the steelmaking process is put into a ladle for the next step of refining.

The ladle is moved for the process of the next step with the molten steel contained therein to perform a continuous casting process and the like.

1, the molten steel contained in the ladle 10 is charged into the tundish 20 through the shroud nozzle and the mold 30 through the immersion nozzle SEN in the tundish 20. Continuous molten steel is supplied to the molten steel and cooled by the coolant spray device 45 while transferring the solidified cast steel through the mold 30 to the roll roller 42.

In such continuous casting facility, the molten steel in the tundish 20 is charged into the mold 30 through the immersion nozzle SEN.

At this time, the molten steel stays in the tundish 20 for a predetermined time in the process of charging the mold 30 through the immersion nozzle (SEN) to perform the process of supplying into the mold 30 after the impurities in the molten steel are satisfactorily removed. do.

On the other hand, the molten steel outflow timing in the tundish 20 detects the weight including the load of the tundish 20 and the molten steel therein with a load cell, and tilts the gate (not shown) when the weight is greater than or equal to the set weight to immerse the nozzle (SEN). ) To inject molten steel into the mold 30.

The immersion nozzle SEN is used between the tundish 20 and the mold 30 during continuous casting of the steel to prevent slag mixing by preventing oxidation of molten steel and vortex prevention of molten steel to improve the quality of the cast steel. Will play an important role.

As illustrated in FIG. 2, the immersion nozzle SEN has a structure in which discharge holes SENa for injecting molten steel S into the mold 30 are formed at both sides, and molten steel S forms the discharge holes SENa. In the process of being injected into the mold 30 through the mold to a certain height within the mold initially has a high flow rate, and thus the initial direction of the molten steel (S) hits the bottom surface of the discharge port (SeNa) while the arrow direction shown in the drawing It is scattered to form an irregular now attached to the inner peripheral surface of the mold (30).

Such a configuration is well known and is described in detail in Korean Patent Laid-Open Publication No. 2009-0050659, which will not be repeated.

On the other hand, as the irregular irregularities as described above are fixed to the inner circumferential surface of the mold 30, not only the casting operation becomes unstable during the initial solidification of the molten steel (S), but also causes defects in the cast slab to increase the defective rate.

In order to solve this problem, a molten steel scattering prevention device 50 as shown in FIG. 3 is proposed.

As shown, the molten steel scattering prevention device 50 arranges the frames 51, 52, 53, and 54 of the plurality of plate bodies to have a triangular cross section as a whole, and alternately supports the support members 55 and 56 that are alternately arranged therein. It is included.

The molten steel scattering prevention device 50 having such a configuration is installed inside the immersion nozzle SEN to guide the flow of molten steel to both sides at an inclined angle during the initial injection of molten steel, thereby suppressing the scattering of molten steel and casting the mold. It is prevented from adhering to the inner wall surface of the splashing or splashing to the outside and the molten steel injected into the mold is filled up to suppress the scattering of the molten steel until the discharge port of the immersion nozzle (SEN) is immersed.

However, the above-described technology has the following problems.

First, when there are four discharge ports of the immersion nozzle, the conventional molten steel scattering prevention device may not be used.

Second, when the scattering direction of the molten steel is in the upper direction, the above-described scattering preventing device may not prevent the scattering of the molten steel and may not protect the sensor measuring the level of molten steel injected into the mold.

Third, when the discharge port of the immersion nozzle is small in size, there is a problem in that the above-mentioned scatter prevention apparatus cannot be mounted on the immersion nozzle.

Fourth, when the discharge amount of the initial molten steel is excessive, there is a problem that the scattering prevention device is moved or dropped by the kinetic energy of the molten steel.

In order to solve this problem, a molten steel scattering prevention device 60 as shown in FIG. 4 may be proposed (for details, see Korean Utility Model Registration No. 20-0309110).

The scattering prevention device 60 includes a connecting portion 61 inserted into the discharge port of the immersion nozzle and a hollow molten steel guide 62 installed at both sides of the connecting portion 61.

At this time, the molten steel is injected into the mold side through the molten steel guide 62 to prevent the molten steel from scattering.

However, the above-described scattering prevention device 60 has the following problems.

First, in the above-described prior art, the molten steel guide and the connecting portion are fixed by welding, which makes it difficult to install the molten steel guide and makes it difficult to closely adhere the molten steel guide and the immersion nozzle.

Second, even in the case of the prior art, when the initial molten steel is excessively injected, the scattering prevention device may not be prevented from moving or falling off.

The present invention is to solve the above-mentioned problems, one of the above-mentioned molten steel guide is formed integrally with the connecting portion while the other molten steel guide is formed as an assembly and includes a pressing means capable of pressing the molten steel guide toward the immersion nozzle side To prevent the molten steel from scattering, as well as a molten steel scattering prevention method and apparatus capable of keeping the molten steel guide tightly attached to the immersion nozzle and holding the scattering preventing device firmly, including a grip part capable of fixing the connection part and the immersion nozzle to each other. The purpose is to provide.

The present invention for achieving the above object is a connecting portion 120 is inserted into the discharge port (SeNa) of the immersion nozzle (SEN), and the hollow insertion guide of the molten steel 110 is provided on both sides of the connecting portion 120 and coupled As a method (S100) of preventing molten steel from scattering by using the molten steel scattering prevention device 100 including the molten steel guide 130, the molten steel guide 110 integrally formed on one side of the connection part 120 is provided. A second step (S110) of preparing and inserting the connection part 120 into the discharge port SENa, and attaching the combined molten steel guide 130 to the connection part 120 exposed to the opposite side of the discharge port SENa. There is a feature of the molten steel scattering prevention method comprising the step (S120).

At this time, after performing the second step (S120), formed on one end of the connecting portion 120 is in close contact with the end surface of the coupling molten steel guide 130 and the pressure plate 140 and the pressure plate 140 It is provided with a pressing means 150 for pressing the coupling molten steel guide 130 toward the immersion nozzle (SEN) side by the pressing means 150 to the coupling molten steel guide 130 to the immersion nozzle (SEN) It may further include a third step (S130) to be in close contact.

In addition, the present invention is the connection portion 120 is inserted into the discharge port (SeNa) of the immersion nozzle (SEN), the hollow-shaped insertion molten steel guide 110 and the coupling molten steel guide 130 are respectively provided on both sides of the connection portion 120 The molten steel scattering prevention device 100 including a), it is attached to the insertion molten steel guide 110 is formed integrally on one side of the connecting portion 120 and the connecting portion 120 exposed to the opposite side of the discharge port SENa. Is formed on one side end of the coupling molten steel guide 130, the connection portion 120 is in contact with the end surface of the coupling molten steel guide 130 and the pressing plate 140 is provided in the Another feature of the molten steel scattering prevention device including a pressing means 150 for pressing the combined molten steel guide 130 to the immersion nozzle (SEN) side.

At this time, as the coupling molten steel guide 130 is formed in a portion of the connecting portion 120 is provided with a moving slit 120a having a shape open in the longitudinal direction of the connecting portion 120, and the moving slit 120a After penetrating, it is also possible to further include a fixing means 180 fixed to the coupling molten steel guide 130.

In addition, the pressing plate 140 may have the same shape as the end surfaces of the molten steel guides 110 and 130.

In addition, the connection part 120 may further include a grip part 160 formed on one side and fixed to one side of the immersion nozzle SEN.

According to the present invention described above, the molten steel guide through which the molten steel is discharged is brought into close contact with the immersion nozzle, thereby effectively preventing scattering of the molten steel.

In addition, even when the molten steel is excessively injected, the molten steel does not move from the immersion nozzle or the molten steel scattering prevention device does not drop, thereby preventing the scattering of molten steel injected into the initial mold more stably.

1 to 4 is a conceptual diagram showing a conventional molten steel scattering prevention device.
5 is an exploded perspective view showing an embodiment of the molten steel scattering prevention apparatus of the present invention.
6 is an exploded perspective view showing that the molten steel scattering prevention device of the present invention is mounted to an immersion nozzle.
7 is a cross-sectional view showing a cross section of the molten steel scattering apparatus including the pressing means of the present invention.
8 and 9 are perspective views showing various embodiments of the pressing means.
10 is an exploded perspective view showing the grip portion of the present invention.
11 is an exploded perspective view showing another embodiment of the present invention.

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

Example 1

5 and 6, the connection part 120 inserted into the discharge port SENa of the immersion nozzle SEN and the hollow insertion guide of the hollow shape are respectively provided on both sides of the connection part 120. It is a method (S100) for preventing the scattering of molten steel using the molten steel scattering prevention device 100 including a 110 and the combined molten steel guide 130.

The method (S100) performs a first step (S110) of inserting the connection part 120 into the discharge port SENa by providing an insertion molten steel guide 110 integrally formed on one side of the connection part 120. do.

That is, in the case of the present invention, the insertion molten steel guide 110 is integrally formed with the connecting portion 120 and the coupling molten steel guide 130 is capable of mutual coupling.

At this time, the insertion molten steel guide 110 is in close contact with the immersion nozzle (SEN) by the first step (S110) and the connection portion 120 is exposed to the opposite discharge port (SENa).

Thereafter, a second step S120 of attaching the coupling molten steel guide 130 to the connection part 120 is performed on the connection part 120 exposed to the opposite side of the discharge port SENa.

At this time, the connecting portion 120 and the coupling molten steel guide 130 may be coupled to each other by a fastener (F), for example, bolts, etc. penetrating the connecting portion 120 as shown.

On the other hand, as shown in Figure 7 is formed on one side end of the connecting portion 120 is in close contact with the end surface of the coupling molten steel guide 130 and the pressure plate 140 is installed on the pressure plate 140 It may include a pressing means 150 for pressing the combined molten steel guide 130 to the immersion nozzle (SEN) side.

The pressing step 150 performs a third step S130 of bringing the combined molten steel guide 130 into close contact with the immersion nozzle SEN.

By the present invention, the combined molten steel guide 130 can be brought into close contact with the immersion nozzle SEN.

Conventionally, as described above, the molten steel guide has a problem in that it is difficult to install in the immersion nozzle, because the configuration is coupled to the connecting portion by welding.

In addition, in the case of the conventional molten steel guide described above, the shape is already determined, there is a problem that it is difficult to adhere to the immersion nozzle.

However, according to the method (S100) of the present invention, the insertion molten steel guide 110 is integrally formed by inserting the connection portion 120 into the discharge port SENa, and then the remaining coupling molten steel guide 130 to the connection portion 120. Since it is not necessary to insert the molten steel guide itself unlike the conventional, it is easy to install the molten steel scattering prevention device of the present invention.

In addition, the pressurizing means 150 may be in close contact with the coupling molten steel guide 130 toward the immersion nozzle SEN, whereby the insertion molten steel guide 110 may also be in close contact with the immersion nozzle SEN.

Hereinafter, the molten steel scattering prevention device 100 will be described in more detail in the following embodiments.

Example 2

As described above, the molten steel scattering prevention device 100 includes a connection part 120 inserted into the discharge port SENa of the immersion nozzle SEN and a hollow insertion molten steel provided on both sides of the connection part 120, respectively. A guide 110 and a combined molten steel guide 130 (see FIGS. 5 to 7).

In this case, the insertion molten steel guide 110 is integrally formed on one side of the connection part 120.

In addition, the combined molten steel guide 130 is attached to the connection portion 120 exposed to the opposite side of the discharge port SENa.

That is, the insertion molten steel guide 110 is integrally formed on one side of the connection portion 120, and the coupling molten steel guide 130 is detachably attached to the other side.

At this time, the pressure plate 140 and the pressure plate 140 is formed on one side end of the connection portion 120 to be in close contact with the end surface of the coupling molten steel guide 130 to the coupling molten steel guide 130 And pressurizing means 150 for pressurizing to the immersion nozzle SEN side.

According to the present invention as described above, the molten steel guide can be brought into close contact with the immersion nozzle.

Meanwhile, the combined molten steel guide 130 and the inserted molten steel guide 110 may provide a path through which initial molten steel may flow to prevent scattering of the molten steel.

In this case, the coupling molten steel guide 130 and the insertion molten steel guide 110 may have a pentagonal cross section as a hollow shape as shown.

However, the combined molten steel guide 130 and the inserted molten steel guide 110 is intended to provide a space for the initial molten steel flowing through the immersion nozzle (SEN) as described above, bar, such a purpose As long as to achieve the above, even if the combined molten steel guide 130 and the inserted molten steel guide 110 has a cross-section of a different shape, it is obvious that all belong to the scope of the present invention.

Meanwhile, the connection part 120 may have a bar shape having a narrow width and a long length.

However, the connection part 120 is intended to allow the coupling molten steel guide 130 to be attached after passing through the discharge port SENa in a state where the insertion molten steel guide 110 is formed. Of course, even if the connecting portion 120 has a different shape, all belong to the scope of the present invention.

On the other hand, the coupling molten steel guide 130 may be attached to the connection portion 120 by a fastener (F), such as a bolt as shown.

However, this is only an example of a configuration in which the coupling molten steel guide 130 and the connecting portion 120 are detachable, and the present invention is not limited by the above example.

On the other hand, the pressing plate 140 is installed in the left end portion in the drawing of the connection portion 120 as shown in Figure 7 may be installed orthogonal to the connection portion 120.

In this case, the pressing plate 140 may have the same cross section as the molten steel guides 110 and 130 as shown in FIG. 8, and may have a rectangular cross section as shown in FIG. 9.

That is, the pressing plate 140 is provided with a pressing means 150 as described above, the pressing means 150 is intended to press the coupling molten steel guide 130, so as to achieve this purpose Of course, even if the installation position of the pressing plate 140 is changed or its shape is different belong to the scope of the present invention.

In addition, the pressing means 150 has a shape of a bolt as shown in the drawing, while pressing the rotating molten steel guide 130 toward the immersion nozzle SEN while the bolt rotates, the coupling molten steel guide 130 and the immersion nozzle ( SEN) can be in close contact with each other.

At this time, the pressing means 150 may be disposed on the upper and lower portions of the pressing plate 140 as shown.

When the upper portion of the coupling molten steel guide 130 is opened with the immersion nozzle (SEN) by placing a pressing means 150 on the upper side of the pressing plate 140 to press the upper portion of the coupling molten steel guide 130 The combined molten steel guide 130 and the immersion nozzle SEN may be in close contact with each other.

On the contrary, when the lower portion of the coupling molten steel guide 130 is separated from the immersion nozzle SEN, the pressing means 150 is disposed on the lower side of the pressing plate 140 to lower the coupling molten steel guide 130. By pressing the portion, the coupling molten steel guide 130 and the immersion nozzle SEN may be in close contact with each other.

Meanwhile, as illustrated in FIGS. 7 to 9, the movable slit 120a is formed in a portion of the connection part 120 on which the coupling molten steel guide 130 is installed, and is open in the longitudinal direction of the connection part 120. And a fixing means 180 fixed to the coupling molten steel guide 130 after passing through the moving slit 120a.

That is, when the molten steel scattering prevention device 100 of the present invention is mounted to the immersion nozzle SEN, the combined molten steel guide 130 is immersed in the state where the insertion molten steel guide 110 is in close contact with the immersion nozzle SEN. It may be in a state spaced apart from the nozzle SEN.

In this case, the coupling molten steel guide 130 may be moved to the immersion nozzle SEN and then fixed by the fixing means 180 to closely adhere the coupling molten steel guide 130 to the immersion nozzle SEN.

That is, as shown in FIG. 8 and FIG. 9, the bolt F1 and the nut F2 are provided as the fixing means 180 to move while the bolt F1 is coupled to the coupling molten steel guide 130. .

In this case, the bolt F1 is movable along the moving slit 120a and positioned at an optimal position, thereby fixing the bolt F1 by the nut F2.

On the other hand, the above-described fixing means 180 is intended to fix the connecting portion 120 while allowing the coupling molten steel guide 130 to move along the moving slit 120a. It is obvious that all of the means 180 belong to the scope of the present invention even if they have different configurations.

Meanwhile, as illustrated in FIG. 10, the grip part 160 may be further formed on the bottom surface of the connection part 120 and fixed to one side of the immersion nozzle SEN.

The immersion nozzle SEN of FIG. 10 shows only the lower part after cutting based on the discharge port SENa, and the connection part 120 omits the illustration of the molten steel guide disposed at both sides.

As illustrated, when the grip part 160 is formed on one side of the connection part 120 and fixed to one side of the immersion nozzle SEN, even when the amount of molten steel introduced through the immersion nozzle SEN is excessive, the grip part The connection part 120 and the molten steel guides 110 and 130 may be stably supported by the 160.

Meanwhile, the grip part 160 may have a pair of bar shapes protruding downward in the drawing on left and right sides of the bottom surface of the connection part 120 as shown.

In this case, the grip unit 160 may be fixed to the discharge port SENa of the immersion nozzle SEN.

However, the grip part 160 is installed in the immersion nozzle SEN as described above, and aims to fix the connection part 120. The shape of the grip part 160 is different or immersed as long as the object is achieved. Naturally, even if the part fitted to the nozzle SEN is different, it belongs to the scope of the present invention.

On the other hand, the molten steel scattering prevention device 100 of the present invention can be applied to the case of four discharge ports SENa (see FIG. 10) as shown in FIG.

That is, the molten steel scattering prevention device 100 of the present invention as described above can be installed in a pair of discharge ports and another molten steel scattering prevention device 200 having the same configuration can be installed in the remaining pair of discharge ports.

In this case, the reference numerals 210, 220, 230 are the same as the above-described inserted molten steel guide 110, the connecting portion 120, and the combined molten steel guide 130.

100: molten steel scattering prevention device 110: insertion molten steel guide
120: connection 130: a combined molten steel guide
140 pressurizing plate 150 pressurizing means
160 grip part

Claims (6)

A molten steel including a connecting portion 120 inserted into the discharge port SENa of the immersion nozzle SEN, and a hollow inserting molten steel guide 110 and a combined molten steel guide 130 respectively provided at both sides of the connecting portion 120. As a method (S100) of preventing scattering of molten steel using the scattering prevention device 100,
A first step S110 of providing an insertion molten steel guide 110 integrally formed at one side of the connection part 120 and inserting the connection part 120 into the discharge port SENa;
And a second step (S120) of attaching the combined molten steel guide 130 to the connection portion 120 exposed to the opposite side of the discharge port SENa. The method of claim 1,
After performing the second step (S120),
Is formed on one side end of the connecting portion 120 is in close contact with the end surface of the coupling molten steel guide 130 and the pressure plate 140 is installed on the pressure plate 140 to immerse the coupling molten steel guide 130 Providing the pressurizing means 150 for pressurizing to the nozzle (SEN) side
The molten steel scattering prevention method further comprises a third step (S130) to contact the immersion nozzle (130) to the immersion nozzle (SEN) by the pressing means (150). A molten steel including a connecting portion 120 inserted into the discharge port SENa of the immersion nozzle SEN, and a hollow inserting molten steel guide 110 and a combined molten steel guide 130 respectively provided at both sides of the connecting portion 120. As the scattering prevention device 100,
Inserting molten steel guide 110 is formed integrally with one side of the connecting portion 120,
Coupling molten steel guide 130 attached to the connection portion 120 exposed to the opposite side of the discharge port SENa,
Is formed on one side end of the connecting portion 120 is in close contact with the end surface of the coupling molten steel guide 130 and the pressure plate 140 is installed on the pressure plate 140 to immerse the coupling molten steel guide 130 It comprises a pressurizing means 150 for pressurizing to the nozzle (SEN) side,
A moving slit 120a which is formed in a portion of the connection part 120 where the coupling molten steel guide 130 is installed, and is open in the longitudinal direction of the connection part 120;
The molten steel scattering prevention device further comprises a fixing means (180) which is fixed to the combined molten steel guide 130 after passing through the moving slit (120a). delete The method of claim 3,
The pressing plate 140 has a molten steel scattering prevention device having the same shape as the end surface of the molten steel guide (110,130). The method of claim 3,
The connection part 120 is formed on one side of the molten steel shatterproof device further comprises a grip portion (160) fixed to one side of the immersion nozzle (SEN).

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