KR102329499B1 - Immersion nozzle for Casting - Google Patents

Abstract

An immersion nozzle device for casting according to the present invention comprises: an immersion nozzle body immersed in a casting mold for accommodating molten steel; and a detection means provided in the immersion nozzle body to detect a change in the thickness of a wall of the immersion nozzle body; and a moving means connected to the submerged nozzle body to move the submerged nozzle body with respect to the mold, wherein the moving means includes a region of the wall of the submerged nozzle body with the thinnest thickness. It may be provided to move the immersion nozzle body so that the region is separated from the slag of the molten steel.

Description

Immersion nozzle for Casting

The present invention relates to an immersion nozzle device for casting.

In the continuous casting operation, the continuous casting operation performed by exchanging the ladle improves the error rate of the product and improves the productivity of the product.

1 shows a conventional immersion nozzle device for casting.

In the immersion nozzle 20 , the nozzle wall 21 is immersed in the mold 10 , and discharge ports 22 , which are passages through which the molten steel is discharged, are provided on both sides of the nozzle wall 21 .

The immersion nozzle 20 is moved in a direction in which the Y-axis decreases to descend into the mold 10 , and molten steel M is supplied to the inside of the mold 10 to perform the casting operation.

When the casting operation is in progress, a slag (S) layer is formed on the upper portion of the molten steel M in the mold 10, and the slag layer S has a predetermined thickness in the Y-axis direction.

When the slag layer (S) and the nozzle wall 21 are in continuous contact, the dissolution part 30 is generated in the nozzle wall 21, and as a result, the nozzle wall 21 is damaged.

When the nozzle wall 21 is damaged, the submerged nozzle 20 must be maintained or replaced, but during the maintenance or replacement of the submerged nozzle, the operation must be stopped, so there is a problem that the productivity of the product is reduced.

In addition, while the immersion nozzle 20 is immersed in the molten steel (M), there is a problem that the operator cannot confirm the dissolution loss 30 generated in the immersion nozzle 20.

US 10-1734738 B1 (2017.05.02)

An object of the present invention is to quickly detect the state of dissolution loss of an immersion nozzle, and to enable continuous casting operation.

In addition, an object of the present invention is to improve the productivity of the product and reduce the time and cost consumed in the maintenance work of the casting equipment.

The present invention relates to an immersion nozzle device for casting.

An immersion nozzle device for casting according to the present invention includes: an immersion nozzle body immersed in a casting mold accommodating molten steel; and a detection means provided in the immersion nozzle body to detect a change in the thickness of the wall of the immersion nozzle body; a moving means connected to the immersion nozzle body to move the immersion nozzle body with respect to the mold; and a control means connected to the detecting means and the moving means and provided to control the moving means according to the value of the wall thickness of the submerged nozzle body detected by the detecting means, wherein the control means is the moving means It may be provided to control the moving means to move the immersion nozzle body so that a dissolution loss region including a region with the thinnest thickness among the walls of the immersion nozzle body is separated from the slag of the molten steel.

In addition, a display means connected to the detection means to transmit visual or auditory information when the thickness value of the wall of the immersion nozzle body detected by the detection means is less than or equal to a predetermined value; may further include.

In addition, the control means may be provided to be connected to the display means to control the display means by the thickness value of the wall of the immersion nozzle body detected by the detection means.

In addition, a plurality of the detection means may be provided inside the wall of the immersion nozzle body to detect a change in the thickness of the wall of the immersion nozzle body.

In addition, the detection means may include: a first detection sensor provided inside the wall of the immersion nozzle body to be spaced apart by a first distance from the outer periphery of the immersion nozzle body; and a second detection sensor provided inside the wall of the submersion nozzle body and provided inside the wall of the submersion nozzle body to be spaced apart from the outer periphery of the submersion nozzle body by a second distance. may be shorter than the second distance.

According to the present invention, the operator can quickly sense the state of dissolution loss of the immersion nozzle, and can perform continuous casting operation.

In addition, the productivity of the product is improved, and the time and cost consumed in the maintenance work of the casting equipment are reduced.

1 schematically shows a conventional immersion nozzle device for casting.
Figure 2 schematically shows an immersion nozzle device for casting according to an embodiment of the present invention.
Figure 3 schematically shows an immersion nozzle device for casting according to another embodiment of the present invention.
4 is an enlarged view of A of FIG. 3 .
5 is a conceptual diagram of a detection means according to another embodiment of the present invention.

In order to help the understanding of the description of the embodiment of the present invention, elements indicated by the same reference numerals in the accompanying drawings are the same elements, and related elements among the elements that perform the same operation in each embodiment are the same or extended numbers. marked.

In addition, in order to clarify the gist of the present invention, descriptions of elements and techniques well known by the prior art will be omitted, and below, the present invention will be described in detail with reference to the accompanying drawings.

However, the spirit of the present invention is not limited to the presented embodiment, and specific elements may be proposed in other forms with addition, change, or deletion by those skilled in the art, but this is also included within the scope of the same spirit as the present invention. make it clear

Hereinafter, the X-axis direction shown in the accompanying drawings is a direction perpendicular to the direction of gravity, and the Y-axis direction is the direction of gravity.

As shown in Figure 2, the immersion nozzle device for casting according to an embodiment of the present invention is provided in the immersion nozzle body 110, the immersion nozzle body immersed in the casting mold 101 for accommodating the molten steel (M). A detection means 120 for detecting a change in the thickness of the wall 111 of the submerged nozzle body 110 and a moving means connected to the submerged nozzle body 110 to move the submerged nozzle body 110 with respect to the mold ( 130).

The moving means is provided to move the submerged nozzle body 110 so that a dissolution loss region including a region with the thinnest thickness among the walls 111 of the submerging nozzle body 110 is separated from the slag of the molten steel. can be

Specifically, the moving means may be provided as a cylinder means (not shown) connected to the submerged nozzle body 110 to move the submerged nozzle body 110 in the Y-axis direction, but this is necessarily by the present invention. It is not limited and may be appropriately changed and applied by those skilled in the art.

In the X-Y plane, the immersion nozzle body 110 has a pair of walls 111 . The pair of walls 111 are provided with outlets 112 through which molten steel is discharged, respectively, so that the molten steel can move to the mold 101 .

A slag layer 102 is formed on the molten steel M of the mold 101, and the slag layer is in contact with a pair of walls 111 of the submerged nozzle body 110, The wall 111 is gradually damaged, and the thickness of the wall 111 is gradually reduced.

As such, the portions in which the thickness of the pair of walls 111 of the immersion nozzle body 110 are thinner than the initial thickness is referred to as a dissolution area, and the dissolution area is the thickness of the pair of walls 111 in the X-axis direction. , including the region with the thinnest thickness.

Among the thicknesses of the pair of walls 111 in the X-axis direction, the region with the thinnest thickness is the region with the greatest dissolution loss.

Therefore, by causing the moving means to move the immersion nozzle body 110 in the direction in which the Y-axis increases or the Y-axis decreases, the dissolution loss region does not come into contact with the slag layer 102, thereby reducing the lifespan of the immersion nozzle body 110. This is to prevent interruption of continuous casting operation.

In an embodiment of the present invention, a plurality of detecting means 120 may be provided inside the wall of the submerged nozzle body 110 to detect a change in the thickness of the wall of the submerged nozzle body 110 .

A plurality of the detection means 120 are spaced apart from each other by different distances from the outer periphery of the submerged nozzle body 110 inside the wall 111 of one side of the submerged nozzle body 110, and the submerged nozzle body ( The thickness of the wall 111 of 110 may be detected stepwise or sequentially.

In addition, the plurality of detection means 120 may be provided on another wall 111 of the immersion nozzle body 110 .

The immersion nozzle device for casting according to an embodiment of the present invention is connected to the detection means 120 and the thickness value of the wall of the immersion nozzle body 110 detected by the detection means 120 is initially set to a predetermined value. In the following cases, the display unit 140 for transmitting visual or auditory information to the outside may be further included.

The display means 140 notifies the operator of the thickness of the wall 111 of the submerged nozzle body 110 in real time, so that the operator can recognize the thickness of the wall 111 of the submerged nozzle body 110 .

In addition, as shown in FIG. 3 , the immersion nozzle device for casting according to another embodiment of the present invention is connected to the detection means 120 , the moving means and the display means 140 and in the detection means 120 . It may further include a control means 150 provided to control the moving means and the display means according to the detected thickness value of the wall of the immersion nozzle body (110).

The control means 150 receives the thickness value of the wall 111 of the submerged nozzle body 110 from the detection means 120 and the moving means 130 according to the change in the thickness value of the wall of the submerged nozzle body 110 . Through the immersion nozzle body 110 can be moved.

Specifically, the immersion nozzle body 110 may be moved so that the dissolution loss region 114 generated on the wall 111 of the immersion nozzle body 110 does not contact the slag layer 102 inside the mold 101 .

The dissolution loss region 114 includes a region 113 having the thinnest thickness in the X-axis direction on the wall 111 of the immersion nozzle body 110 .

According to such a control means 150, it is possible to improve the speed of the operation by automating the continuous casting operation, and it is possible to prevent the occurrence of a safety accident of the operator in advance.

On the other hand, as shown in FIG. 4 , the plurality of detection means 120 are provided inside the wall of the submerged nozzle body 110 so as to be spaced apart _{by a first distance D 1 from the outer periphery of the submerged nozzle body 110 .} The first detection sensor 121 and the submerged nozzle body 110 are provided inside the wall of the submerged nozzle body 110, and are spaced apart _{from the outer periphery of the submerged nozzle body 110 by a second distance D 2 .} It may include a second detection sensor 122 provided on the inside of the wall.

In this case, the first distance (D ₁ ) may be shorter than the second distance (D ₂ ), and the first detection sensor is higher than the second detection sensor. can be placed close to

According to this, the change in the thickness of the wall 111 of the immersion nozzle body 110 can be detected step by step or sequentially, so that the dissolution area of the wall 111 of the immersion nozzle body 110 can be quickly and accurately determined.

Meanwhile, FIG. 5 shows the concept of the detection means 120 according to an embodiment of the present invention. FIG. 5 is an enlarged view of an area corresponding to A of FIG. 3 .

As shown in FIG. 5 , in an embodiment of the present invention, the first detection sensor 121 may be connected to two points of the control means 150 through separate paths. Specifically, the first detection sensor 121 may be connected to a point on one side of the control unit 150 through a first path, and the first detection sensor 121 may be connected to the control unit 150 through a second path. It can be connected to the other side point of Here, the first detection sensor may be connected to the control means 150 by a wire.

And the second detection sensor 122 may be connected to a wire connected to the + pole of the power source and a wire connected to the - pole of the power source, and the wire connected to the + pole and the - pole of the power source may be connected to the control means 150 . have. In this circuit, the second detection sensor 122 becomes a resistor.

Therefore, the first detection sensor 121 and the second detection sensor 122 may be resistance sensors, and the control unit 150 detects a change in resistance and causes the display unit 140 to display the result visually or aurally. to be indicated as

Therefore, when the wall 111 of the immersion nozzle body 110 is melted by the molten steel M and the second detection sensor 122 is damaged or damaged, the control means 150 is connected to the second detection sensor 122 Detects a change in resistance in the circuit, and the display unit 140 notifies the operator by visually or audibly indicating it.

Then, the operator can know that the second detection sensor 122 is damaged and the thickness of the wall 111 of the immersion nozzle body 110 has decreased to the position where the second detection sensor 122 is located.

If the thickness of the wall 111 of the immersion nozzle body 110 is continuously reduced by the molten steel M and the first detection sensor 121 is damaged or damaged by the molten steel M, the 2 connected to the control means 150 The resistance between points is changed.

Then, the control means 150 displays it on the display means 140 , and the operator breaks the first detection sensor 121 through the display means 140 , so that the thickness of the wall 111 of the immersion nozzle body 110 is It can be seen that the first detection sensor 121 is reduced to the position.

Therefore, the operator can safely and quickly grasp the dissolution area of the wall 111 of the immersion nozzle body 110 through the display means 140 .

The above has been described with respect to one embodiment of the present invention, the scope of the present invention is not limited thereto, and various modifications and variations are possible within the scope without departing from the technical spirit of the present invention described in the claims. It will be apparent to one of ordinary skill in the art.

101: mold 102: slag layer
110: immersion nozzle body 111: wall
112: outlet 120: detection means
121: first detection sensor 122: second detection sensor
130: moving means 140: display means
150: control means

Claims (5)

an immersion nozzle body immersed in a casting mold for accommodating molten steel;
detection means provided in the submerged nozzle body to detect a change in the thickness of the wall of the submerged nozzle body;
a moving means connected to the immersion nozzle body to move the immersion nozzle body with respect to the mold; and
a control means connected to the detecting means and the moving means and provided to control the moving means by the value of the wall thickness of the submerged nozzle body detected by the detecting means;
including,
The control means controls the moving means to move the immersion nozzle body so that the dissolution loss region including the thinnest region among the walls of the immersion nozzle body is separated from the slag of the molten steel. An immersion nozzle device for casting, characterized in that provided.
According to claim 1,
a display means connected to the detection means to transmit visual or auditory information when the thickness value of the wall of the immersion nozzle body detected by the detection means is less than or equal to a predetermined value;
An immersion nozzle device for casting further comprising a.
3. The method of claim 2,
The control means,
An immersion nozzle device for casting which is connected to the display means and is provided to control the display means by the value of the wall thickness of the immersion nozzle body detected by the detection means.
4. The method according to any one of claims 1 to 3,
The detection means,
An immersion nozzle apparatus for casting, characterized in that a plurality of immersion nozzles are provided inside the wall of the immersion nozzle body and are provided to detect a change in the thickness of the wall of the immersion nozzle body.
4. The method according to any one of claims 1 to 3,
The detection means,
a first detection sensor provided inside the wall of the submerged nozzle body to be spaced apart by a first distance from the outer periphery of the submerged nozzle body; and
A second detection sensor provided on the inside of the wall of the immersion nozzle body and provided inside the wall of the immersion nozzle body so as to be spaced apart by a second distance from the outer periphery of the immersion nozzle body;
The immersion nozzle device for casting, characterized in that the first distance is shorter than the second distance.

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