KR100954934B1 - Submerged nozzle centering apparatus - Google Patents

Abstract

The present invention relates to an immersion nozzle centering device. The present invention is attached to one side of the inner surface of the mold (3), one passes through the molten steel discharge port 11 of the immersion nozzle (5) charged in the mold 3 and the other is spaced apart from the molten steel discharge port (11) A laser generator 20 for irradiating a laser beam L passing through an outer circumferential outer side of the immersion nozzle 5; And a display member 27 attached to the other side of the laser generator 20 to detect the position of the laser beam L to display the centering position of the molten steel discharge port 11. According to the present invention, the immersion nozzle 5 can be accurately and quickly centered, and the centering error of the immersion nozzle can be minimized, thereby reducing the drift of molten steel. Therefore, there is an advantage that can be expected to improve the quality of the slab.

Immersion nozzle, centering

Description

Submerged nozzle centering apparatus

The present invention relates to an immersion nozzle centering device, and more particularly, to an immersion nozzle centering device capable of accurately measuring and managing the centering position of an immersion nozzle which is lowered into the mold to supply molten steel from the tundish into the mold. will be.

In the continuous casting process of manufacturing molten steel into slabs, molten steel contained in the ladle is continuously supplied to the mold in a state of temporarily storing the molten steel in the tundish of the continuous casting machine, and the mold is cooled to produce the slabs.

1 is a cross-sectional view showing an incorrect centering position of an immersion nozzle descending into a mold, and FIG. 2 is a graph showing numerical results of normal or abnormal drift of molten steel according to the centering position of the immersion nozzle. .

As shown in the figure, an immersion nozzle 5 for supplying molten steel of the tundish 1 into the mold 3 is mounted below the tundish 1. The immersion nozzle 5 is mounted to be exposed to the bottom surface of the tundish 1 through the well block 7 inserted through the bottom surface of the tundish 1 and the nozzle connecting portion 9 provided at the bottom thereof. The nozzle connecting portion 9 serves to hold the upper part of the immersion nozzle 5 to maintain the nozzle uprightness of the immersion nozzle 5.

The lower part of the immersion nozzle 5 is formed with a molten steel discharge port 11 penetrating to both sides, and the stopper 13 for supplying an appropriate amount of molten steel to the mold 3 by opening and closing the immersion nozzle 5. Is located.

The tundish (1) having such a configuration molds the lower end of the immersion nozzle (5) after entering the immersion nozzle (5) down into the mold (3) to supply the molten steel received therein into the mold (3) (3) The installation is completed by being located inside. In this process, the centering operation of the immersion nozzle 5 is performed.

Centering work of the immersion nozzle 5 is performed by moving the tundish 1 by using a cylinder, in which the design factors such as the shape, size of the molten steel discharge port and the position (immersion depth) of the discharge hole, and the initial installation before the start of casting are performed. Operation factors such as position and position change during casting have a great influence on product quality.

That is, in the state in which the immersion nozzle 5 is correctly centered, as shown in FIG. 2A, the flow pattern symmetrically flows left and right in the long side (long side) and short side (short side) directions of the mold 3. It is possible to ensure the stability of the initial solidification by forming a healthy cast or a defect-free cast.

However, the tundish 1 is prone to thermal deformation in the longitudinal direction of the mold 3 by long use, and such thermal deformation causes the tundish 1 to be eccentric to one side in the longitudinal direction. The eccentricity of the tundish 1 reduces the accuracy of the centering position in the mold 3 even when the immersion nozzle 5 is installed upright in the lower part of the tundish 1.

As such, when the casting operation is performed while the stopper 13 is opened while the immersion nozzle 5 is not accurately centered, as shown in (b) and (c) of FIG. It is biased to either side, and the molten steel drifts.

The drift of molten steel has a close correlation with the installation position error of the immersion nozzle 5, and this installation position error of the immersion nozzle 5 is mainly caused by off-centering generated during continuous casting operation. do. An example of off centering is as follows.

First, when the center of the immersion nozzle (5) in the center of the long side or short side width of the mold (3) is off to the left in the horizontal direction in the drawing (Fig. 1 (a)), second is the same aspect but off to the right in the drawing (Fig. 1 (B)), Third, when the immersion nozzle 5 is inclined to one side or the immersion nozzle 5 rotates in the axial direction due to incompatibility of the nozzle connecting portion 9 when the immersion nozzle 5 is replaced. (C) of FIG.

The drift of the molten steel (S) in the mold (3) generated by the above-described off-centering causes an increase in the fluctuation of the water surface or the vortex phenomenon, so that the mold powder is entrained into the molten steel (S). Coagulation nonuniformity will occur. This solidification non-uniformity forms a non-uniform coagulation shell, which degrades the quality of the slab, and in severe cases, the cast pieces burst during casting, causing a break out phenomenon in which molten steel flows out.

This break out phenomenon increases the risk of a worker's safety accident and damages the facility. In addition, the damage of the equipment has a problem that the production efficiency is reduced because the entire operation must be stopped and the work equipment must be reset.

The present invention is to solve the conventional problems as described above, an object of the present invention is an immersion nozzle centering device to enable accurate centering by accurately measuring the installation position of the immersion nozzle entered into the mold using a laser device To provide.

According to a feature of the present invention for achieving the object as described above, the present invention is attached to one side of the inner surface of the mold, one passes through the molten steel discharge port of the immersion nozzle charged in the mold and the other is spaced apart from the molten steel discharge port A laser generator for irradiating a laser beam passing through an outer circumferential outer side of the immersion nozzle; And a display member attached to the other side of the laser generator to detect the position of the laser beam and display the centering position of the molten steel discharge port.

The laser generator and the display member are located at both sides in the short side direction of the mold.

The laser generator comprises a laser beam generating housing for generating a laser beam and detachable by a magnet to the inner surface of the short side of the mold; And a laser beam generating unit provided at the front end of the laser beam generating housing and irradiating at least two laser beams passing through the outer circumferential outer side of the molten steel discharge port and the immersion nozzle.

The spaced interval of the laser beam irradiated from the laser beam generator is more than half of the thickness of the immersion furnace.

The display member is a ruler made of a rubber magnet material that is detachable to an inner surface of the mold.

At least one of the long sides of both sides of the mold is formed with a projection to be the centering reference position of the immersion nozzle.

According to the present invention, the immersion nozzle centering apparatus is provided in the mold to measure and manage the installation position of the immersion nozzle. This makes it possible to accurately and quickly install the immersion nozzle in the centering position.

In addition, when the immersion nozzle centering apparatus of the present invention is used, the centering position error of the immersion nozzle can be minimized, thereby reducing the drift of molten steel. As a result, the solidification cell in the mold is uniformly formed, so that the quality improvement of the slab can be expected.

In addition, the reduction of the drift of the molten steel reduces the level fluctuations of the molten steel, so that the maximum casting operation is possible while ensuring operational stability, thereby improving production efficiency.

Hereinafter, exemplary embodiments of an immersion nozzle centering apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

3 is a perspective view showing the configuration of a preferred embodiment of the immersion nozzle centering apparatus according to the present invention. The same configuration as the conventional configuration will be described with reference to FIG. 1.

Prior to the description, the immersion nozzle 5 is installed at the lower portion of the tundish 1 by the nozzle connection unit 9, and the immersion nozzle 5 injects molten steel of the tundish 1 into the mold 3. In order to enter the mold 3 provided in the lower portion of the tundish (1). In addition, the lower part of the immersion nozzle 5 is provided with a molten steel discharge port 11 which is open to both sides to supply the molten steel of the tundish (1) into the mold (3), in this case to prevent the drift of the molten steel The centering operation of the nozzle 5 is performed.

Referring to FIG. 1, an immersion nozzle centering device is provided as a means for centering the immersion nozzle 5 entering the mold 3. The immersion nozzle centering apparatus has a laser generator 20 installed so that the laser beam L is irradiated perpendicularly to the direction in which the immersion nozzle 5 is charged, and a position where the laser beam L has passed through the molten steel discharge port ( And a display member 27 for indicating the centering position of 11).

The immersion nozzle centering apparatus measures the degree to which the immersion nozzle 5 deviates from the centering position by using the laser beam L when the immersion nozzle 5 is inserted into the mold 3 and uses the measured result. It is to be possible to calibrate the installation position in (5).

The laser generator 20 includes a laser beam generating housing 21 and a laser beam generator 25, and the laser beam L is formed on the outer circumferential surface of the molten steel discharge port 11 and the immersion nozzle 5 of the immersion nozzle 5. By passing through the outside, the centering position of the immersion nozzle 5 is measured.

The laser beam generating housing 21 is a portion constituting the body of the laser generator 20 and is attached to the inside of the short side of the mold 3 by a magnet. To this end, one side of the laser beam generating housing 21 is provided with an on-off switch 23 for selectively generating a magnet. For reference, the short side of the mold 3 is referred to as a short side (X axis), the long side is a long side (Y axis), and the longitudinal axis into which the immersion nozzle 5 is inserted is referred to as an immersion depth (Z axis).

The laser beam generator 25 is provided at the tip of the laser beam generating housing 21. The laser beam generator 25 irradiates at least one laser beam L, and the laser beam L irradiated from the laser beam generator 25 goes straight to the molten steel discharge port 11 of the immersion nozzle 5. The immersion nozzle 5 passes through a position spaced apart from the outer circumference.

The laser beam generator 25 is formed to extend in one direction such that a virtual extension line passes through the outer periphery of the molten steel discharge port 11 and the immersion nozzle 5. To this end, the laser beam L irradiated from the laser beam generator 25 should be spaced apart by a distance greater than or equal to the interval between the center of the molten steel discharge port 11 and the outer periphery of the immersion nozzle 5.

In the mold 3, the display member 27 on which the laser beam L passed through the immersion nozzle 5 is displayed is disposed on the opposite surface of the laser beam generating housing 21. The display member 27 is a rubber ruler 27 ′, which can be attached to and detached from the inner surface of the mold 3. The ruler 27 ′ shows the laser beam L as a small dot, and the laser beam L is irradiated to correct the installation position of the immersion nozzle 5.

More specifically, the presence of the laser beam L formed in the ruler 27 'passing through the molten steel discharge port 11 and the outer periphery of the immersion nozzle 5 or in the shape of the laser beam L 5) Check the installation position is out of the correct position, and centering the installation position of the immersion nozzle (5) using this.

In this embodiment, the installation position of the immersion nozzle 5 is measured by two laser beams L passing through the molten steel discharge port 11 of the immersion nozzle 5 and the outer circumference, but is not necessarily limited thereto. When only the above laser beam L passes the immersion nozzle 5, the installation position of the immersion nozzle 5 can be measured. However, it is preferable to use at least two laser beams L for accurate measurement.

On the other hand, a separate screen (not shown) for displaying the installation position of the laser beam L displayed on the ruler 27 'to the outside is provided. The screen may be provided with a calculation unit (not shown) for irradiating the laser beam (L). Of course, the calculation unit measures the exact installation position of the immersion nozzle 5 from the position of the laser beam (L) displayed on the ruler, and using this measurement result to display the degree of immersion nozzle (5) out of the centering position on the screen You may.

In the center of the long side of the mold 3 is provided with a protrusion 29 protruding upward. The protrusion 29 serves as a reference for accurately centering the installation position of the immersion nozzle 5 when the immersion nozzle 5 is initially charged into the mold 3. One protrusion 29 is provided in this embodiment, but is not necessarily so.

Next, a mode switch (not shown) for controlling the operation on / off of the laser generator 20 is provided. The mode switch controls to generate the laser beam L in the laser beam generating housing 21.

Although not shown, correction means for correcting the deviation from the correct position by spatially synthesizing the position of the laser beam L displayed on the ruler 27 'may be provided. The correction means may be a separate control having a function of calculating the degree of deviation from the correct position of the immersion nozzle 5 and automatically centering the correction amount at that time.

Hereinafter, the operation of the immersion nozzle centering apparatus according to the present invention having the configuration as described above will be described in detail.

In the process of setting the tundish 1 on the upper part of the mold 3, in order to accurately center the immersion nozzle 5 loaded in the mold 3, it is necessary to measure whether the installation position of the immersion nozzle 5 is correct. do. To this end, the laser generator 20 is attached to the short side of the mold 3 in the state in which the immersion nozzle 5 is charged.

In general, charging of the immersion nozzle 5 is performed by moving the tundish 1 using the hydraulic pressure of the cylinder, wherein the immersion nozzle 5 is formed by the projection 29 formed at the center of the long side of the mold 3. Is charged with some centering. However, when the tundish 1 is thermally deformed by a long time of use, the immersion nozzle 5 may be biased toward either side, so that the centering operation using the laser beam L is additionally performed for accurate centering.

To this end, in the state where the laser generator 20 is attached to the short side of the mold 3, the ruler 27 ′ is also attached to the inner surface of the mold 3 opposite to the laser generator 20. At this time, the laser generator 20 is attached so that the extended direction of the laser beam generator 25 passes through the molten steel discharge port 11 of the immersion nozzle 5 and the outside of the outer periphery on a virtual extension line.

In this way, the mode switch is turned on while the laser beam generating means 20 and the ruler 27 'are attached to the mold 3 to irradiate the laser beam L. FIG. The irradiated laser beam L passes through the outer periphery of the molten steel discharge port 11 and the immersion nozzle 5, and is displayed on the ruler 27 ′, and the operator of the laser beam L is displayed on the ruler 27 ′. The shape of the molten steel discharge port 11 is measured to determine whether the position of the molten steel discharge port 11 is precisely disposed toward the width center of both short sides of the mold 3.

That is, when the molten steel discharge port 11 is biased toward any one side, since the shape of the laser beam L formed on the ruler does not form an accurate circle, the tundish 1 is moved to form the correct circle so as to form the immersion nozzle ( Correct the installation position of 5).

More specifically, the presence of the laser beam L formed in the ruler 27 'through the molten steel discharge port 11 and the outer periphery of the immersion nozzle 5, or the immersion nozzle 5 in the shape of the laser beam L. ) Will be calibrated by checking the degree of deviation from the correct position.

When the centering operation of the immersion nozzle 5 through the above-described process is completed, the mode switch and the on-off switch 23 are sequentially turned off to form the laser generator 20 and the ruler 27 'in the mold 3. The mold 3 may be removed in the reverse order to attaching to the mold.

Within the scope of the basic technical idea of the present invention, many modifications are possible to those skilled in the art, and the scope of the present invention should be interpreted based on the appended claims. will be.

1 is a cross-sectional view showing an example of the installation position of the immersion nozzle is lowered into the mold.

Figure 2 is a graph showing the numerical analysis results of the drift phenomenon of the normal or abnormal molten steel according to the installation position of the immersion nozzle.

Figure 3 is a perspective view showing the configuration of a preferred embodiment of the immersion nozzle centering apparatus according to the present invention.

Explanation of symbols on the main parts of the drawings

20: laser beam generating means 21: laser beam generating housing

23: On-off switch 25: Laser beam generator

27: display member 27 ': ruler

29: protrusion L: laser beam

S: molten steel

Claims (6)

A laser generator attached to one side of an inner surface of the mold, one laser beam passing through the molten steel discharge port of the immersion nozzle inserted into the mold and the other passing through the outer circumference of the immersion nozzle spaced apart from the molten steel discharge port; And a display member attached to the other side of the laser generator and configured to identify a position of the laser beam and display a centering position of the molten steel discharge port. The method of claim 1, And the laser generator and the display member are located at both sides of the mold in the short side direction. The method according to claim 1 or 2, The laser generator A laser beam generating housing generating a laser beam and detachable by a magnet to an inner surface of the short side of the mold; Immersion nozzle centering, comprising: a laser beam generating unit provided at the front end of the laser beam generating housing, irradiating at least two laser beams passing through the outer periphery outer side of the molten steel discharge port and the immersion nozzle; Device. The method of claim 3, Immersion nozzle centering apparatus, characterized in that the spaced interval of the laser beam irradiated from the laser beam generating unit is more than half the thickness of the immersion nozzle. The method of claim 4, wherein The display member is an immersion nozzle centering apparatus, characterized in that the ruler made of a rubber (Rubber) magnet material that can be attached to the inner surface of the mold. The method of claim 5, Immersion nozzle centering apparatus, characterized in that the projection is formed at the center of at least one of the long sides of the mold to be the centering reference position of the immersion nozzle.

Images