KR101997731B1 - Apparatus for treating submerged nozzle and Tundish having the same - Google Patents

Abstract

The present invention relates to a display device, A left arm rotatably disposed on the main body; A left supporter disposed on one side of the left arm; A right arm rotatably disposed on the main body; A right supporter disposed on one side of the right arm; And a first cylinder that rotates the right arm and the left arm, and as the right arm and the left arm in a deployed state with respect to the main body are rotated downward by the first cylinder, The present invention relates to an immersion nozzle processing apparatus for holding an outer circumferential surface of an immersion nozzle inserted into a mold, and a tundish including the supporter and the left supporter. Thereby, the immersion nozzle can be taken out to the outside without bumping into the mold.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a submerged nozzle processing apparatus and a tundish having the same,

The present invention relates to an immersion nozzle processing apparatus and a tundish including the same. More particularly, the present invention relates to an immersion nozzle processing apparatus that fixes an immersion nozzle at the time of cutting an immersion nozzle disposed in a tundish and removes the immersion nozzle cut, and a tundish including the same.

In general, the continuous casting operation by the stopper casting type continuous casting machine is performed by moving the turn dish machine 20, on which the turn main body 10 is mounted, to a casting position After a certain height can be lowered. Accordingly, the immersion nozzle 11 disposed at the bottom of the turn-around body 10 is inserted into the mold 30 and stopped at a constant height.

The immersion nozzle 11 may be arranged such that a part of the immersion nozzle 11 is inserted into the mold 30, as shown in Fig.

The ladle 40 is then connected to the injection port of the long nozzle 51 by operating the shroud mann plate 50 which connects the long nozzle 51 to the ladle 40 containing molten steel, When a sliding gate (not shown) that hermetically closes the injection port is opened, molten steel is injected into the bath of the turn-around body 10 along the inner diameter of the long nozzle 51. At this time, as a certain amount of molten steel is filled, the inclusion contained in the molten steel is separated.

When the inclusion is separated, the stop cylinder 13, which seals the injection port of the immersion nozzle 11, is raised to a certain height by operating the suck cylinder 12, as shown in Fig. As a result, a space is formed between the stopper 13 and the injection port at the upper end of the immersion nozzle 11, and molten steel is injected into the mold 30.

Thus, the molten steel supplied to the mold 30 is cooled while being retained for a predetermined time to form a solidified cell, and solidification progresses gradually to the inner surface, and the molten steel is drawn into a rectangular slab (S, Slab).

When the molten steel is injected through the ladle 40 containing molten steel, the continuous casting operation is performed by exchanging molten steel with other ladle 40 containing molten steel, and continuously injecting the molten steel into the turn-based main body 10.

At this time, the amount of molten steel injected into the mold 30 can be correlated with the amount of molten steel injected into the turn-key body 10, so that the molten steel can be stably injected into the mold 30 by controlling the suet cylinder 12 . For example, the amount of molten steel injected into the mold 30 can be controlled by repeatedly raising and lowering the stopper 13 at a predetermined height.

However, when the molten steel is not injected into the turn-key body 10 as in the case of exchanging the ladle 40, the molten steel may be deteriorated.

For example, if molten steel is continuously injected into the tundish main body 10 and the mold 30 as described above, and there is no ladle 40 containing more molten steel, only the molten steel contained in the tundish main body 10 Continuous casting end work can be done by injecting into the mold 30.

At the end of the continuous casting, the injection port of the immersion nozzle 11 inserted in the corresponding mold 30 may be closed at the same time to end the operation. However, if the length of the drawn slab S is not satisfied, the molten steel may be injected into the other molds 30 to seal and block the molten steel.

On the other hand, as molten steel is injected into the mold 30, the bath surface of the turn-around body 10 is lowered to maintain a constant height. At this time, in order to prevent the slag layer formed on the upper surface of the molten steel from being mixed into the mold 30, the stopper 13 may be lowered to close the injection port of the immersion nozzle 11.

However, even if the supply of molten steel is cut off by the stopper 13, molten steel may leak out. The molten steel that is discharged may delay the formation of the solidification cell of the slab S. In addition, the molten steel that has spilled out may contaminate the slab S.

Further, the molten steel that flows out may melt and grow on the bearing portion disposed on the roller or the roller, and may interfere with the rotation of the bearing.

Further, the molten steel that has been spouted can be fused and grown on the short sides and the cover of the mold 30 and can be made now. Accordingly, the molten steel that is now made can act as a resistor when changing the width, and can form a clearance to induce the molten steel to be injected at the beginning of the continuous casting operation. Therefore, the possibility of accident risk is improved.

When the molten steel flows out, the coolant is supplied to accelerate the solidification by lowering the temperature of the molten steel. Otherwise, the immersion nozzle 11 is cut by providing the cutting device 60 at the lower position of the turn- So that the cutter 61 is located on the lower side of the cut immersion nozzle 11 to prevent the molten steel from leaking.

3, the conventional cutting apparatus 60 is configured so that the space for inserting the immersion nozzle 11 is opened, and the cutter 61 built in the cutting apparatus 60 is operated to operate the cylinder 62 So as to cut the immersion nozzle 11 located in the open space.

It may be necessary to cut off the supply of molten steel from the turn-key body 10 to the mold 30 by cutting the end of the stopper 13, cutting the stopper, or some other abnormality during the casting operation.

In this case, the cylinder 62 is operated to push the cutter 61, and the cutter 61 is moved by a certain distance by the operation of the cylinder 62 rod to cut the immersion nozzle 11.

However, since the conventional cutting apparatus 60 does not have any means for holding or collecting the cut portion of the immersion nozzle 11, the cut portion of the immersion nozzle 11 falls into the molten steel. In this case, the molten steel may be scattered and the worker may be exposed to a safety accident.

Further, the molten steel that is scattered may cause malfunction or damage of the peripheral equipment, and the work environment may be contaminated.

In addition, the cut portion of the immersion nozzle 11 immersed in the molten steel must be removed. In this case, not only the operator is exposed to a safety accident, but also the quality of the product is lowered or the rate of water loss is lowered.

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art, and an object of the present invention is to provide an immersion nozzle processing apparatus and a tundish including the immersion nozzle processing apparatus which can safely cut and remove the immersion nozzle when the immersion nozzle occurs.

The problems to be solved by the embodiments are not limited to the above-mentioned problems, and other problems not mentioned here can be clearly understood by those skilled in the art from the following description.

According to an embodiment of the present invention, A plurality of arm means rotatably disposed on the main body; A plurality of supporters associated with the arm means; And a driving means for rotating the arm means, wherein the arm means in a deployed state with respect to the main body are rotated downward, so that the supporters are moved to a submerged nozzle processing apparatus for holding an outer peripheral surface of the immersion nozzle inserted in the mold Lt; / RTI >

Here, the arm means includes a left arm and a right arm rotatably disposed on the main body, respectively, and the supporter includes a left supporter and a right supporter which are respectively disposed on one side of the left arm and the right arm, Means is provided in a first cylinder for rotating the right arm and the left arm such that as the right arm and the left arm are pivoted downwardly by the first cylinder, the right supporter and the left supporter are brought into contact with the mold And the outer circumferential surface of the inserted immersion nozzle can be held.

Preferably, the immersion nozzle treatment apparatus includes a main body; A left arm rotatably disposed on the main body; A left supporter disposed on one side of the left arm; A right arm rotatably disposed on the main body; A right supporter disposed on one side of the right arm; And a first cylinder that rotates the right arm and the left arm, and as the right arm and the left arm in a deployed state with respect to the main body are rotated downward by the first cylinder, The supporter and the left supporter can hold the outer peripheral surface of the immersion nozzle inserted into the mold.

The immersion nozzle processing apparatus may further include a stopper portion for controlling whether the right arm and the left arm can be rotated.

Here, the stopper portion includes a pin and a second cylinder for moving the pin, and the pin has a pivoting stop position for supporting the end portions of the right arm and the left arm, and an end portion of each of the right arm and the left arm The second cylinder can be moved between the pivotal application positions releasing the support.

A guide groove for fitting the rail may be formed on the pin so as to be guided by the rail of the main body when the pin is moved.

The immersion nozzle processing apparatus may further include a third cylinder for rotating the left supporter and a fourth cylinder for rotating the right supporter.

Here, the left supporter may include a left gripper supporting one side of the outer circumferential surface of the immersion nozzle; A first left coupling part protruding from the left gripper and rotatably disposed on the left arm; And a second left engaging portion protruding from the first left engaging portion and hinged to the third cylinder, wherein the right supporter includes a right gripper supporting one side of the outer circumferential surface of the immersion nozzle; A first right side coupling portion protruding from the right side gripper and rotatably disposed on the right side arm; And a second right side coupling portion protruding from the first right side coupling portion and hinged to the fourth cylinder.

Then, as the third cylinder pushes the second left coupling portion, and the fourth cylinder pulls the second right coupling portion, the immersion nozzle can be rotated 90 degrees.

At this time, the size of the left gripper may be larger than the size of the right gripper.

In addition, a plurality of protrusions may be formed on the inner surfaces of the left gripper and the right gripper, respectively.

According to an embodiment of the present invention, there is provided a tundish comprising: a tundish main body in which an immersion nozzle is disposed at a lower portion; A cutting device disposed at a lower portion of the tundish main body to cut the immersion nozzle; An immersion nozzle processing device disposed at a lower portion of the tundish main body; And a moving unit for moving the immersion nozzle processing apparatus, wherein the immersion nozzle processing apparatus includes: a main body that moves by the moving unit; A right arm rotatably disposed on the main body; A right supporter disposed on one side of the right arm; A left arm rotatably disposed on the main body; A left supporter disposed on one side of the left arm; And a first cylinder that rotates the right arm and the left arm, wherein the main body is moved toward the immersion nozzle by the moving unit in a state in which the right arm and the left arm are deployed with respect to the main body, And a tundish in which the right supporter and the left supporter hold the outer peripheral surface of the immersion nozzle inserted in the mold as the right arm and the left arm are rotated downward by the first cylinder.

The tundish may further include a guide unit disposed at a lower portion of the tundish to guide movement of the immersion nozzle treatment apparatus.

The immersion nozzle processing apparatus may further include a stopper portion for controlling whether the right arm and the left arm can be rotated.

The immersion nozzle processing apparatus further includes a third cylinder for rotating the left supporter and a fourth cylinder for rotating the right supporter, and the immersion nozzle is driven by driving the third cylinder and the fourth cylinder, 90 degrees.

The immersion nozzle processing apparatus and the tundish including the tundish nozzle according to the present invention having the above-described structure can safely cut and remove the immersion nozzle when the immersion nozzle is pierced by the discharge port of the immersion nozzle.

That is, when the immersion nozzle is cut by using the cutting apparatus, the immersion nozzle processing apparatus can hold the immersion nozzle by rotating the left arm and the right arm downward.

Further, after the immersion nozzle is cut, the immersion nozzle treatment apparatus can rotate the cut immersion nozzle 90 degrees and easily remove it without bumping into the immersion nozzle mold.

1 is a view showing a continuous casting process in a stopper casting method,
2 is a partial cross-sectional view of a conventional implement equipped with an immersion nozzle cutting device,
Fig. 3 is an exploded perspective view showing the cutting apparatus shown in Fig. 2,
4 is a view showing a tundish according to an embodiment,
5 is a perspective view showing the immersion nozzle processing apparatus according to the embodiment,
6 is an exploded perspective view showing the immersion nozzle processing apparatus according to the embodiment,
7 is a bottom perspective view showing a main body of the immersion nozzle processing apparatus according to the embodiment,
FIG. 8 is a view showing the operation of the fin provided in the immersion nozzle processing apparatus according to the embodiment,
9 is a view showing that the left supporter and the right supporter hold the immersion nozzle as the first cylinder of the immersion nozzle processing apparatus according to the embodiment is driven,
10 is a view showing a state in which the immersion nozzle rotates 90 degrees as the third cylinder and the fourth cylinder of the immersion nozzle processing apparatus according to the embodiment are driven.

The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated and described in the drawings. It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

The terms including ordinal, such as second, first, etc., may be used to describe various elements, but the elements are not limited to these terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the second component may be referred to as a first component, and similarly, the first component may also be referred to as a second component. And / or < / RTI > includes any combination of a plurality of related listed items or any of a plurality of related listed items.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, . On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings, wherein like or corresponding elements are denoted by the same reference numerals, and redundant description thereof will be omitted.

Referring to FIG. 4, the tundish 1 according to the embodiment of the present invention includes the immersion nozzle processing apparatus 2 according to the embodiment, the tundish main body 10 having the immersion nozzle 11 disposed thereon, A moving unit 70 and a guide unit 80 disposed at a lower portion of the immersion nozzle 10 for cutting the immersion nozzle 11.

The moving unit 70 can move the immersion nozzle treatment apparatus 2.

The moving part 70 may be disposed below the tundish main body 10. As the moving part 70, a cylinder such as a hydraulic cylinder, a pneumatic cylinder or the like may be used. Accordingly, as the rod of the cylinder is moved, the immersion nozzle treatment apparatus 2 can be moved toward or away from the immersion nozzle 11.

That is, when a problem such as leakage occurs in the immersion nozzle 11, the moving part 70 can move the immersion nozzle treatment device 2 toward the immersion nozzle 11. [

At this time, the guide section 80 can guide the movement of the immersion nozzle treatment apparatus 2. For example, when the immersion nozzle treatment apparatus 2 approaches or separates toward the immersion nozzle 11, the guide section 80 guides the movement of the immersion nozzle treatment apparatus 2.

Further, the guide portion 80 can support the immersion nozzle treatment apparatus 2 disposed at the lower portion of the tundish main body 10. [ Accordingly, the guide portion 80 can disperse the load of the immersion nozzle treatment apparatus 2. [

Here, as shown in Figs. 4 and 5, a member having a T-shaped groove may be used for the guide portion 80. Fig.

Accordingly, when a problem such as leakage occurs in the immersion nozzle 11, the immersion nozzle treatment apparatus 2 is guided by the guide portion 80 to move toward the immersion nozzle 11, and then the immersion nozzle 11 is fixed . Then, the cutting device 60 cuts the immersion nozzle 11.

Then, the immersion nozzle treatment apparatus 2 rotates the cut immersion nozzle 11 by 90 degrees. The moving unit 70 moves the immersion nozzle treatment apparatus 2 so that the immersion nozzle 11 cut off can be removed.

That is, since the immersion nozzle 11 is partly inserted into the mold 30, the immersion nozzle treatment apparatus 2 rotates the immersion nozzle 11 cut by 90 degrees so that the immersion nozzle 11 is moved to the mold 30 so that they can be easily peeled off.

Hereinafter, the immersion nozzle processing apparatus 2 will be described with reference to FIGS. 3 to 7. FIG.

The immersion nozzle treatment apparatus 2 includes a main body 100, a plurality of arm means rotatably disposed on the main body 100, a plurality of supporters associated with the arm means, and driving means for rotating the arm means .

5, the arm means may include a left arm 200 and a right arm 400 that are rotatably disposed on the main body 100, respectively. The supporter may include a left supporter 300 and a right supporter 500. The driving unit may be provided as a first cylinder 600 that rotates the left arm 200 and the right arm 400.

The supporters 300 and 500 may be fixed to the immersion nozzle 11 inserted in the mold 30 as the arm means 200 and 400 in a deployed state with respect to the main body 100 are rotated downward, As shown in Fig.

In detail, the immersion nozzle treatment apparatus 2 includes a main body 100, a left arm 200, a left supporter 300, a right arm 400, a right supporter 500, a first cylinder 600, A third cylinder 800 that rotates the left supporter 300, and a fourth cylinder 900 that rotates the right supporter 500.

Here, the stopper portion 700 may include the pin 710 and the second cylinder 720.

The main body 100 of the immersion nozzle treatment apparatus 2 may be disposed below the tundish main body 10 as shown in Fig.

When the main body 100 is moved from the lower portion of the tundish main body 10, the main body 100 can be guided by the guide portion 80. At this time, the main body 100 can be moved by the moving part 70 disposed at the lower portion of the tundish main body 10.

4 to 6, the main body 100 includes a body 110 having a space formed therein, a guide member 120, a cutout 130 formed on a side surface of the body 110, A rail 140 and a support 150.

The body 110 may form an outer shape of the body 100. Further, as shown in FIG. 6, the opening may be formed in a rectangular shape and downward.

The guide member 120 may be disposed on the upper surface 111 of the body 110. Then, the guide member 120 can be guided by the guide portion 80 during the movement.

As shown in FIGS. 4 and 5, the guide portion 80 has a T-shaped groove, and the guide member 120 may have a T-shaped cross section to match the groove.

Accordingly, the body 110 can be engaged with the guide portion 80 through the guide member 120. When the body 110 is moved, the body 110 can move along the groove of the guide portion 80. At this time, the rod of the moving part 70 may be fixed to one side of the guide member 120 by bolts, nuts, or the like.

The incision 130 may be formed by cutting the side surface of the body 110. The left arm 200 and the right arm 400 may be rotatably disposed in the cutout 130. [ For example, each of the left arm 200 and the right arm 400 may be rotatably disposed by a fixing member 90 such as a bolt. Accordingly, the left arm 200 and the right arm 400 can rotate with the fixing member 90 as a rotation axis.

The rail 140 may protrude from the inside of the body 110, as shown in FIG.

The rail 140 can guide the movement of the pin 710. For example, the rail 140 can be engaged with the rail groove 711 formed on the side surface of the pin 710. As a result, the pin 710 moved by the second cylinder 720 moves along the rail 140.

Here, as the second cylinder 720, a hydraulic cylinder, an air cylinder, or the like may be used. Accordingly, when the rod of the second cylinder 720 pushes or pulls the pin 710, the pin 710 moves along the rail 140. Here, a mounting hole 160 may be formed on one side of the body 110 for inserting the pin 710.

As shown in FIG. 5, the second cylinder 720 may be detachably installed on one side of the body 110. Accordingly, the rod of the second cylinder 720 can be arranged to pass through the mounting hole 160.

The support 150 may be disposed on the other side of the body 110. More specifically, the support 150 may be disposed on the outer surface of the opposite body 110 of the mounting hole 160.

The support base 150 may be formed in a plate shape. Further, a support member 151 may be further disposed on the support base 150 to support the support base 150. Here, the support member 151 may be disposed to be inclined with respect to the support base 150.

The first cylinder 600 can be detachably disposed on the support 150 by a fixing member 91 such as a bolt. Accordingly, during the maintenance of the first cylinder 600, the first cylinder 600 can be easily replaced.

The left arm 200 may be rotatably disposed on the cutout 130 of the main body 100.

As shown in Figs. 5 and 6, one end of the left arm 200 can be rotatably disposed on the main body 100. As shown in Fig. The left supporter 300 may be rotatably disposed at the other end of the left arm 200. [

The left arm 200 may be formed in a shaft shape that is bent several times in consideration of the turning radius and the position of the immersion nozzle 11.

The left arm 200 includes a left base 210 and a first left end 220 protruding toward the main body 100 from one side of the left base 210. The first left end 220 and the second left end 220, The first left fixing part 240 and the second left fixing part 250 formed to protrude in a direction opposite to the first left fixing part 220 and the second left fixing part 230. [

The left base 210 may be formed in a long rod shape. The left base 210 may be spaced apart from the side surface of the body 110. However, when the left arm 200 is rotated downward by the first cylinder 600, the left base 210 may be pivoted to the lower side of the body 110 and may be disposed at a lower portion of the body 110.

5, when the left arm 200 and the right arm 400 are deployed with respect to the main body 100, the left base 210 is spaced apart from the side of the main body 110. As shown in FIG. When the left arm 200 and the right arm 400 are rotated downward by the first cylinder 600, the left base 210 is spaced apart from the lower side of the body 110.

That is, as the first cylinder 600 is driven, the left base 210 rotates downward. Accordingly, the left supporter 300 is brought into close contact with the outer peripheral surface of the immersion nozzle 11.

The first left end 220 may protrude from one side of the left base 210 toward the main body 100. The first left end 220 may be rotatably disposed on the cutout 130 of the main body 100.

A through hole 221 may be formed in the first left end 220 and a fixing member 90 such as a bolt may be coupled to the through hole 221 through the body 110. Accordingly, the left arm 200 can be rotated by using the fixing member 90 as a rotation axis.

The second left end 230 may protrude from the other side of the left base 210 toward a direction opposite to the first left end 220.

The left supporter 300 may be rotatably disposed at the second left end 230. For example, a through hole 231 may be formed in the second left end portion 230, and a fixing member 92 such as a bolt may be coupled to the through hole 231. Accordingly, the left supporter 300 can be rotatably disposed at the second left end portion 230 with the fixing member 92 as a rotation axis.

The first left fixing part 240 may protrude from the left base 210 in the same direction as the first left end 220. The first left fixing part 240 may be spaced apart from the first left end 220.

On the other hand, the rod 610 of the first cylinder 600 can be hinged to the first left fixing part 240. For example, when the rod 610 is pulled by driving the first cylinder 600, the first left fixing part 240 is also pulled. Accordingly, the left base 210 can be rotated downward with the fixing member 90 as a rotation axis. The left supporter 300 is brought into close contact with the outer peripheral surface of the immersion nozzle 11.

Here, the first left fixing part 240 can be hinged to the rod 610 of the first cylinder 600 by a fixing member 93 such as a bolt, and the rotation of the left base 210 can be facilitated An arc-shaped through hole 241 may be formed in the first left fixing part 240. [

The second left fixing part 250 may protrude from the second left end part 230. One side of the third cylinder 800 may be rotatably disposed on the second left fixing part 250 using a hinge coupling method or the like. A fixing member 94 such as a bolt may be used for such hinge coupling.

The left supporter 300 can be rotated by the first cylinder 600 to support one side of the outer circumferential surface of the immersion nozzle 11 inserted into the mold 30.

The left supporter 300 may be rotatably disposed at the second left end portion 230. Accordingly, when the third cylinder 800 is driven, the left supporter 300 can rotate the immersion nozzle 11 by 90 degrees while supporting one side of the outer circumferential surface of the immersion nozzle 11.

When the immersion nozzle 11 is rotated by 90 degrees, the left supporter 300 supports the lower portion of the immersion nozzle 11. Therefore, the size of the left supporter 300 may be larger than the size of the right supporter 500. [ Accordingly, the left supporter 300 can stably support the lower portion of the immersion nozzle 11. [

6, the left supporter 300 protrudes from the inner surface 312 of the left gripper 310, the first left coupling portion 320, the second left coupling portion 330, and the left gripper 310 And may include a plurality of protrusions 340 formed therein.

The left gripper 310 can support one side of the outer peripheral surface of the immersion nozzle 11. Thus, the left gripper 310 and the right gripper 510 hold the outer circumferential surface of the immersion nozzle 11.

The left gripper 310 may be formed in a shape corresponding to the shape of the outer circumferential surface of the immersion nozzle 11. As shown in FIG. 6, the left gripper 310 may be formed in a semi-cylindrical shape.

An observer 311 may be formed on one side of the left gripper 310. The operator can confirm whether the immersion nozzle 11 is supported by the left gripper 310 through the observation hole 311. [

The first left coupling part 320 may protrude from one side of the left gripper 310. That is, one side of the first left coupling part 320 may be coupled to the left gripper 310, and the other side may be rotatably disposed on the second left side end 230 using a hinge coupling method or the like. A fixing member 92 such as a bolt may be used for such hinge coupling.

The second left coupling portion 330 may protrude from the first left coupling portion 320. One end portion of the second left coupling portion 330 may be rotatably disposed on the rod of the third cylinder 800 using a hinge coupling method or the like. A fixing member 95 such as a bolt may be used for this hinge coupling.

A plurality of protrusions 340 may be formed on the inner surface 312 of the left gripper 310. Here, the protrusion 340 may be formed in a conical shape.

As a result, the plurality of protrusions 340 can effectively hold the immersion nozzle 11.

The right arm 400 may be rotatably disposed on the cutout 130 of the main body 100.

As shown in Figs. 5 and 6, one end of the right arm 400 may be rotatably disposed on the main body 100. Fig. The right supporter 500 can be rotatably disposed at the other end of the right arm 400.

The right arm 400 may be formed in a shaft shape that is bent several times in consideration of the turning radius and the position of the immersion nozzle 11. [

The right arm 400 includes a right base 410, a first right end 420 formed to protrude from one side of the right base 410 toward the main body 100, a first right end 420 extending from the other side of the right base 410 The first right fixing part 440 and the second right fixing part 450, which are formed to protrude in a direction opposite to the first right fixing part 420 and the second right fixing part 430, respectively.

The right base 410 may be formed in a long rod shape. The right base 410 may be spaced apart from the side surface of the body 110. However, when the right arm 400 is rotated downward by the first cylinder 600, the right base 410 may be spaced apart from the lower portion of the body 110.

5, when the left arm 200 and the right arm 400 are deployed with respect to the main body 100, the right base 410 is positioned apart from the side of the main body 110. When the left arm 200 and the right arm 400 are rotated downward by the first cylinder 600, the right base 410 is spaced apart from the lower side of the body 110.

That is, as the first cylinder 600 is driven, the right base 410 rotates downward. Accordingly, the right supporter 500 is brought into close contact with the outer peripheral surface of the immersion nozzle 11.

The first right end 420 may protrude from one side of the right base 410 toward the main body 100. The first right end 420 may be rotatably disposed on the cutout 130 of the main body 100.

A through hole 421 may be formed in the first right end 420 and a fixing member 90 such as a bolt may be coupled to the through hole 421 through the body 110. Accordingly, the right arm 400 can be pivoted with the fixing member 90 as a rotation axis, like the left arm 200.

The second right end 430 may protrude from the other side of the right base 410 toward a direction opposite to the first right end 420.

The right side supporter 500 can be rotatably disposed on the second right side end 430. For example, a through hole 431 may be formed in the second right end portion 430, and a fixing member 92 such as a bolt may be coupled to the through hole 431. Accordingly, the right supporter 500 can be rotatably disposed at the second right end portion 430 with the fixing member 92 as a rotation axis.

The first right fixing portion 440 may be disposed to protrude from the right base 410 in the same direction as the first right end 420. The first right fixing part 440 may be disposed apart from the first right end 420.

On the other hand, the rod 610 of the first cylinder 600 can be hinged to the first right fixing part 440. For example, when the rod 610 is pulled by driving the first cylinder 600, the first right fixing part 440 is also pulled. Accordingly, the right base 410 can be pivoted downward with the fixing member 90 as a rotation axis. The right supporter 500 is in close contact with the outer circumferential surface of the immersion nozzle 11.

Here, the first right fixing part 440 can be hinged to the rod 610 of the first cylinder 600 by a fixing member 93 such as a bolt, and can easily rotate the right base 410 An arc-shaped through hole 441 may be formed in the first right fixing part 440. [

The second right fixing portion 450 may be formed to protrude from the second right end portion 430. One side of the third cylinder 800 may be rotatably disposed on the second right fixing part 450 using a hinge coupling method or the like. A fixing member 94 such as a bolt may be used for such hinge coupling.

The right supporter 500 can be rotated by the first cylinder 600 to support one side of the outer circumferential surface of the immersion nozzle 11 inserted into the mold 30.

Then, the right supporter 500 can be rotatably disposed at the second right end 430. Accordingly, when the fourth cylinder 900 is driven, the right supporter 500 can rotate the immersion nozzle 11 by 90 degrees while supporting one side of the outer circumferential surface of the immersion nozzle 11.

6, the right supporter 500 is provided on the inner surface 512 of the right gripper 510, the first right coupling portion 520, the second right coupling portion 530, and the right gripper 510, And may include a plurality of protrusions 540 formed therein.

The right gripper 510 can support one side of the outer peripheral surface of the immersion nozzle 11. The right gripper 510 catches the outer peripheral surface of the immersion nozzle 11 together with the left gripper 310. [

The right gripper 510 may be formed in a shape corresponding to the shape of the outer circumferential surface of the immersion nozzle 11. As shown in FIG. 6, the right gripper 510 may be formed in a semi-cylindrical shape.

The first right side engaging portion 520 may be formed to protrude from the right gripper 510. That is, one side of the first right coupling part 520 may be coupled to the right gripper 510, and the other side may be rotatably disposed on the second right side end 430 using a hinge coupling method or the like. A fixing member 92 such as a bolt may be used for such hinge coupling.

The second right side engaging portion 530 may be formed to protrude from the first right side engaging portion 520. One end of the second right side engaging portion 530 may be rotatably disposed on the rod of the fourth cylinder 900 using a hinge coupling method or the like. A fixing member 95 such as a bolt may be used for this hinge coupling.

A plurality of protrusions 540 may be formed on the inner surface 512 of the right gripper 510. Here, the protrusion 540 may be formed in a conical shape.

The plurality of protrusions 540 can effectively catch the immersion nozzle 11 together with the protrusion 340 of the left supporter 300. [

The first cylinder 600 is hinged to the first left fixing part 240 and the first right fixing part 440. As the first cylinder 600 is driven, the first cylinder 600 can rotate the left arm 200 and the right arm 400 downward.

5, the rod 610 of the first cylinder 600 is in an expanded state when the left arm 200 and the right arm 400 are deployed with respect to the main body 100. As the rod 610 of the first cylinder 600 is contracted, each of the left arm 200 and the right arm 400 can be pivoted downwardly of the main body 100.

As shown in FIG. 6, a double acting cylinder may be used as the first cylinder 600, but it is not necessarily limited to this, and two single acting cylinders may be used.

Meanwhile, the first cylinder 600 may be detachably disposed on the support 150. The upper housing 620 and the lower housing 630 may be disposed on the upper and lower portions of the first cylinder 600 to effectively implement the same. The upper housing 620 may be detachably disposed on the support 150.

The stopper unit 700 can control whether the left arm 200 and the right arm 400 can be rotated.

The stopper portion 700 may include a pin 710 and a second cylinder 720 for moving the pin 710, as shown in Figs. 5 and 6.

Referring to FIG. 8, the pin 710 can move between the pivotal stop position and the pivotal application position. Here, the rotation stop position refers to a position where the pin 710 supports the ends of the left arm 200 and the right arm 400, as shown in FIG. 8 (a). The bottom surface of the pin 710 supports the first left end 220 of the left arm 200 and the first right end 420 of the right arm 400. [

Accordingly, the left arm 200 and the right arm 400 can not be rotated even when the first cylinder 600 is driven by the pin 710 that is pivotally stopped. Even if the main body 100 moves while the left arm 200 and the right arm 400 are deployed, since the pin 710 is positioned at the rotation stop position, the left arm 200 and the right arm 400 Can be prevented.

8 (b), the pin 710 is moved to disengage the ends of the left arm 200 and the right arm 400. As shown in FIG. The bottom surface of the pin 710 disengages from supporting the first left end 220 of the left arm 200 and the first right end 420 of the right arm 400. [

Accordingly, when the immersion nozzle treating apparatus 2 approaches the immersion nozzle 11, the pin 710 moves to the rotation applying position. The left arm 200 and the right arm 400 are rotated downward by driving the first cylinder 600 so that the left supporter 300 and the right supporter 500 catch the immersion nozzle 11 .

8, a rail groove 711 may be formed on a side surface of the pin 710. The pin 710 may be moved by a rail 140 which cooperates with the rail groove 711, Can be informed.

The third cylinder 800 can rotate the left supporter 300. Then, the fourth cylinder 900 can rotate the right supporter 500. Here, as the third cylinder 800 and the fourth cylinder 900, a cylinder such as a hydraulic cylinder, a pneumatic cylinder, or the like may be used.

One side of the third cylinder 800 is hinged to the second left fixing part 250 and the other side is hinged to the second left coupling part 330. One side of the fourth cylinder 900 is hinged to the second right fixing part 450 and the other side is hinged to the second right side engaging part 530.

Therefore, when the first cylinder 600 is driven, the left supporter 300 and the right supporter 500 catch the immersion nozzle 11 as shown in FIG.

When the third cylinder 800 is driven to push the second left coupling part 330 and the fourth cylinder 900 pulls the second right coupling part 530, (11) is rotated 90 degrees.

Then, the immersion nozzle 11 can be easily removed from the mold 30 without colliding with the mold 30 by using the moving part 70.

The immersion nozzle treatment apparatus 2 disposed in the tundish 1 approaches the immersion nozzle 11 by the moving unit 70 and then is driven by the first cylinder 600, The left arm 200 and the right arm 400 are rotated downward. At this time, the pin 710 is moved to the rotation applying position.

Accordingly, as shown in FIG. 9, the left supporter 300 and the right supporter 500 hold the immersion nozzle 11.

Then, the cutting apparatus 60 can cut the immersion nozzle 11.

10, after the immersion nozzle 11 is cut, the third cylinder 800 and the fourth cylinder 900 are driven to rotate the immersion nozzle 11 by 90 degrees to facilitate the removal from the mold 30 .

The tundish 1 can drive the moving part 70 to remove the cut immersion nozzle 11 from the mold 30.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the present invention as defined by the following claims It can be understood that

1: tundish 2: immersion nozzle treatment device
11: immersion nozzle 13: stopper
30: mold 70: moving part
80: guide portion
100: main body 120: guide member
130: incision section 140: rail
150: Support
200: left arm 210: left base
300: Left supporter 310: Left gripper
340: protrusion
400: Right arm 410: Right base
500: Right supporter 510: Right gripper
600: first cylinder
700: stopper portion 710: pin
720: second cylinder
800: Third cylinder
900: Fourth cylinder

Claims (14)

main body;
Arm means including a left arm and a right arm rotatably disposed on the main body, respectively;
A left supporter rotatably disposed at an end of the left arm and closely attached to an outer peripheral surface of the immersion nozzle;
A right supporter rotatably disposed at an end of the right arm and closely attached to an outer peripheral surface of the immersion nozzle;
A first cylinder for rotating the right arm and the left arm;
A stopper portion for controlling whether the right arm and the left arm can be rotated;
A third cylinder rotatably disposed at one side of the left arm to rotate the left supporter; And
And a fourth cylinder rotatably disposed on one side of the right arm to rotate the right supporter,
The left supporter
A left gripper for supporting one side of the outer peripheral surface of the immersion nozzle;
A first left coupling part protruding from the left gripper and rotatably disposed on the left arm; And
And a second left coupling part protruding from the first left coupling part and hinged to the rod of the third cylinder,
The right supporter
A right gripper for supporting one side of the outer peripheral surface of the immersion nozzle;
A first right side coupling portion protruding from the right side gripper and rotatably disposed on the right side arm; And
And a second right engaging portion protruding from the first right engaging portion and hinged to the rod of the fourth cylinder,
Wherein the stopper portion includes a pin and a second cylinder for moving the pin,
The pin is moved by the second cylinder between a pivoting stop position for supporting the end of each of the right arm and the left arm and a pivoting application position for releasing the right arm and the end of each of the left arms,
When the pin is positioned at the rotation applying position,
In a state in which the right arm and the left arm are rotated downward by the first cylinder so that the right supporter and the left supporter hold the outer circumferential surface of the immersion nozzle inserted in the mold,
Wherein the third cylinder pushes the second left engaging portion and the fourth cylinder pulls the second right engaging portion, the immersion nozzle rotates 90 degrees. delete delete delete The method according to claim 1,
Wherein guide grooves are formed on the rails so as to be guided by the rails of the main body when the pins are moved. delete delete delete The method according to claim 1,
Wherein a size of the left gripper is larger than a size of the right gripper. The method according to claim 1,
Wherein a plurality of protrusions are formed on inner surfaces of the left gripper and the right gripper, respectively. A tundish main body having an immersion nozzle disposed at a lower portion thereof;
A cutting device disposed at a lower portion of the tundish main body to cut the immersion nozzle;
An immersion nozzle processing device disposed at a lower portion of the tundish main body;
A moving unit for moving the immersion nozzle treatment apparatus; And
And a guide portion disposed at a lower portion of the tundish main body for guiding movement of the immersion nozzle processing apparatus,
The immersion nozzle processing apparatus includes:
A body moving by the moving unit;
A right arm rotatably disposed on the main body;
A right supporter rotatably disposed on one side of the right arm and disposed in close contact with an outer peripheral surface of the immersion nozzle;
A left arm rotatably disposed on the main body;
A left supporter rotatably disposed on one side of the left arm and disposed closely to an outer circumferential surface of the immersion nozzle;
A first cylinder for rotating the right arm and the left arm;
A stopper portion for controlling whether the right arm and the left arm can be rotated;
A third cylinder rotatably disposed at one side of the left arm to rotate the left supporter;
And a fourth cylinder rotatably disposed on one side of the right arm to rotate the right supporter,
The left supporter includes a left gripper for supporting one side of the outer peripheral surface of the immersion nozzle; A first left coupling part protruding from the left gripper and rotatably disposed on the left arm; And a second left coupling portion protruding from the first left coupling portion and hinged to the rod of the third cylinder,
The right supporter includes a right gripper for supporting one side of the outer peripheral surface of the immersion nozzle; A first right side coupling portion protruding from the right side gripper and rotatably disposed on the right side arm; And a second right engaging portion protruding from the first right engaging portion and hinged to the rod of the fourth cylinder,
Wherein the stopper portion includes a pin and a second cylinder for moving the pin,
The pin is moved by the second cylinder between a pivoting stop position for supporting the end of each of the right arm and the left arm and a pivoting application position for releasing the right arm and the end of each of the left arms,
When the pin is positioned at the rotation applying position,
In a state in which the right arm and the left arm are rotated downward by the first cylinder so that the right supporter and the left supporter hold the outer circumferential surface of the immersion nozzle inserted in the mold,
Wherein the immersion nozzle is rotated by 90 degrees as the third cylinder pushes the second left engagement portion and the fourth cylinder pulls the second right engagement portion. delete delete delete

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