KR20200009527A - Container apparatus and method for removing adherent materials - Google Patents

Abstract

The present invention relates to a container apparatus capable of removing attachment, comprising: a container unit having an inner space; a cover unit disposed to cover at least a part of the circumference of the container unit; and a connection unit connecting the container unit and the cover unit, wherein at least a part of the connection unit is able to cause a collision by interlocking with an inclination of the container unit so as to remove the attachment attached to the container unit and the cover unit. Accordingly, the attachment can be easily removed.

Description

CONTAINER APPARATUS AND METHOD FOR REMOVING ADHERENT MATERIALS}

The present invention relates to a container apparatus and a deposit removing method, and more particularly, to a container apparatus and a deposit removing method that can remove the deposit.

In general, the ladle holds molten steel until it receives molten steel from the converter and supplies it to the tundish of the casting facility. The ladle is supported above the tundish by a ladle turret. When all the molten steel in the ladle has been injected into the tundish, the ladle turret moves the other ladle containing the molten steel above the tundish. Thus, molten steel may be continuously supplied to the tundish.

At this time, in the course of carrying out the operation of refining the molten steel into the ladle in the converter, or refining the molten steel in the ladle, the molten steel may be generated by fusion to the upper end of the ladle or the shell. When the ladle is moved by crane or the like, or the ladle turret is operated, the fused ladle now can fall off the ladle and fall. Accordingly, there is a problem that peripheral equipment such as tundish or the like occurs due to the falling time.

Conventionally, the worker has removed the now attached to the ladle by hand with a separate tool. However, because the removal of the hand by hand, now is not smoothly removed, there is a problem that takes a lot of time. In addition, the now separated from the ladle fall to the worker may cause a safety accident.

On the other hand, after hanging the removal port in the hook of the crane now, the operation of the crane was controlled to remove the now welded to the ladle. However, since the now-outlet is rocked from side to side by the operation of the crane, it can be very difficult to correctly place the now-outlet on top of the ladle to remove now. Therefore, the removal operation takes a long time, and may cause an accident that the removal port is moved to the wrong position and damages the ladle.

KR 2002-0084950 A

The present invention provides a container device and a method for removing a deposit that can easily remove the deposit.

The present invention provides a container apparatus and a method for removing a deposit that can prevent or prevent the deposit from falling and damaging the surrounding equipment or causing a safety accident.

The present invention relates to a container device capable of removing deposits, the container portion having an internal space; A cover part disposed to cover at least a portion of the circumference of the container part; And a connecting portion connecting at least a portion of the container portion and the cover portion to generate a collision in association with the inclination of the container portion so as to remove an attachment attached to the container portion and the cover portion.

The connection part may include: a first connector provided between the container part and the cover part, the first connector including a first crashing member and a second crashing member, which may at least partially collide with each other due to a difference in inclination of the container part and the cover part; And a second connector spaced apart from the first connector and installed between the container portion and the cover portion and configured to adjust the inclination of the cover portion.

The first collision member is installed in the container portion,

The second collision member is installed in the cover part, at least a portion of which may move toward the first collision member.

One side of the first collision member and the second collision member are spaced apart from each other, and the other side is rotatably connected to each other.

One of the first collision member and the second collision member is provided with a protruding member protruding toward the other.

The second connector, the body member is installed in the container; A first connection member installed on the body member to be movable in an extension direction of the container part; And a second connecting member having one end rotatably connected to the first connecting member and the other end rotatably connected to the cover part.

The body member extends in the extension direction of the container portion inside the body member, and includes a first space through which the first connection member is inserted, and the first connection member can penetrate the body member. And a through hole connected to the first space and extending in an extension direction of the first space.

The second connector further includes a vibration member installed on the body member to generate vibration.

A second space extending in the extending direction of the container portion is provided in the body member,

The vibrating member may include: a colliding body arranged to be movable in an extension direction of the container part in the second space; And an elastic body installed in the second space and disposed to be in contact with the colliding body.

The second connector further includes a driver capable of moving the first connection member in the extending direction of the container portion.

The driver may include a driving member capable of generating a driving force capable of moving the first connection member; And a power transmission member having one end connected to the first connection member and the other end connected to the drive member so as to transfer the driving force.

The present invention relates to a method for removing deposits that can remove deposits, comprising: a container part having a container part, a cover part disposed to surround the container part, and a connection part connecting the container part and the cover part. process; Tilting the container; Generating a collision at the connection unit; And separating the attachment by causing an impact or vibration to the container part and the cover part due to the collision generated in the connection part.

The connection part includes a first collision member installed on the container portion, and a second collision member installed on the cover portion, the at least a portion of which is movable toward the first collision member,

The process of generating a collision in the connection portion, the process of adjusting the inclination of the container portion and the cover portion differently; And colliding the first collision member and the second collision member due to the difference in inclination of the container portion and the cover portion.

The process of generating a collision at the connection unit includes a process of generating a collision at a plurality of positions of the connection unit.

The container portion includes a ladle capable of receiving molten steel therein, and the attachment now includes.

According to embodiments of the present invention, the deposit attached to the container device can be easily removed. As a result, deposits may not grow on the container device, and the container device may be kept in a clean state. Thus, maintenance of the container device can be facilitated.

In addition, since the deposit attached to the container device has been removed, it is possible to prevent the deposit attached to the container device from falling around the container device when carrying or moving the container device. Thus, the attachment may prevent damage to the surrounding equipment or the occurrence of a safety accident.

1 is a view showing the structure of a container apparatus according to an embodiment of the present invention.
2 is a view showing a structure of a cover unit according to an embodiment of the present invention.
3 is a view showing a structure of a connecting unit according to an embodiment of the present invention.
4 is a view showing the structure of a second connector according to an embodiment of the present invention.
5 is a view showing the structure of a second connector according to another embodiment of the present invention.
6 is a flow chart showing a method for removing deposits according to an embodiment of the present invention.
7 is a view showing the operation of the container device according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention in more detail. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various forms, and only the embodiments are intended to complete the disclosure of the present invention and to those skilled in the art to fully understand the scope of the invention. It is provided to inform you. BRIEF DESCRIPTION OF THE DRAWINGS The drawings may be exaggerated in order to describe the invention in detail, in which like reference numerals refer to like elements.

1 is a view showing the structure of a container apparatus according to an embodiment of the present invention, Figure 2 is a view showing the structure of a cover unit according to an embodiment of the present invention. Hereinafter, a container apparatus according to an embodiment of the present invention will be described.

Referring to FIG. 1, a container apparatus 1000 according to an embodiment of the present invention relates to a container apparatus capable of removing deposits. The container device 1000 includes a container part 100, a cover part 200, and a connection part 300.

The container portion 100 extends in the vertical direction to have a cylindrical shape, and the upper portion thereof may be opened. The container part 100 may have an inner space. For example, the container portion 100 may be a ladle. The outside of the container portion 100 is formed of a steel shell, the refractory may be built inside. Therefore, hot molten steel may be accommodated in the container part 100.

In addition, the side surface of the container portion 100 may be provided with a sovereign locking member 110. The sovereign locking member 110 may protrude outward from the surface of the container part 100. The sovereignty locking member 110 may be provided with a pair. A pair of sovereign hooks provided in the crane may be caught in each of the sovereign locking members 110. Thus, the container portion 100 can be supported by the crane.

On the other hand, the back side of the container portion 100 may be provided with a holding lock member 120. The holding member 120 may be located lower than the holding member 110. The winding hook provided on the crane may be caught by the holding hook member 120. Depending on the degree of crane lifting the hook hook, the inclination of the container 100 may be adjusted.

At this time, in the process of carrying out the operation of refining the molten steel into the container portion 100 in the converter, or refining the molten steel in the container portion 100, the molten steel is the top or the shell of the container portion 100, or the cover portion 200 The bond can then be produced as it is squeezed into it. Therefore, the attachments attached to the container part 100 and the cover part 200 may be removed by the vibration generated by the connection part 300.

The cover part 200 may be disposed to cover at least a portion of the circumference of the container part 100. In detail, the cover part 200 may be provided in plural and disposed along the circumference of the container part 100. Therefore, the cover part 200 may protect at least one of the front, side, and rear surfaces of the cover part 200 from the molten steel protruding from the container part 100. Therefore, it is possible to suppress or prevent the formation of deposits in the container part 100.

Also, referring to FIGS. 1 and 2, the cover part 200 may include a first cover member 210 and a second cover member 220. The first cover member 210 and the second cover member 220 may be manufactured in one piece, or may be manufactured separately and combined with each other by welding or the like.

The first cover member 210 serves to cover the upper region of the side of the container portion 100. The first cover member 210 may be a plate. The first cover member 210 may be spaced apart from the container part 100 to be formed along a portion of the circumference of the container part 100. One side of the first cover member 210 is disposed to face the container part 100, and the other side thereof is connected to the second cover member 220. The upper surface of the first cover member 210 may have an inclination. For example, one side of the first cover member 210 may be located above the other side. Thus, even if the molten steel bounces from the container part 100 to the first cover member 210, the molten steel may move outward of the cover part 200 along the inclination. However, the structure and shape of the first cover member 210 may vary without being limited thereto.

The second cover member 220 serves to cover the middle region of the side of the container portion 100. The second cover member 220 may be a plate. The second cover member 220 may be spaced apart from the container part 100 to form a part of the circumference of the container part 100 along a shape. The second cover member 220 may extend in the vertical direction. An upper end of the second cover member 220 may be connected to the first cover member 210. Accordingly, the second cover member 220 may protect the intermediate region of the side of the container 100. However, the structure and shape of the second cover member 220 may vary without being limited thereto.

In this case, since the first cover member 210 and the second cover member 220 extend in different directions, the cover part 200 may be bent and formed. Therefore, a space may be formed between the cover part 200 and the container part 100 (or inside the cover part 200). The connection part 300 may be installed in a space between the cover part 200 and the container part 100.

3 is a view showing the structure of the connecting unit according to an embodiment of the present invention, Figure 4 is a view showing the structure of a second connector according to an embodiment of the present invention, Figure 5 is a view according to another embodiment of the present invention It is a figure which shows the structure of 2 connector. Hereinafter, the structure of the connection part 300 in the embodiment of the present invention will be described.

1 and 3, the connection part 300 may connect the container part 100 and the cover part 200.

 At least a part of the connection part 300 may generate a collision in conjunction with the inclination of the container part 100. A collision generated in the connection part 300 may be transmitted to the container part 100 and the cover part 200, and an attachment attached to the container part 100 or the cover part 200 by shock or vibration caused by the collision may be transmitted. It may be separated and removed from the container part 100 or the cover part 200. The connector 300 includes a first connector 310 and a second connector 320.

The first connector 310 is installed between the container part 100 and the cover part 200. One side of the first connector 310 is connected to the upper outer wall of the container portion 100, the other side is connected to the upper inner wall of the cover portion 200. The first connector 310 may support the upper portion of the cover part 200.

In addition, the first connector 310 may have a first collision member 311 and a second collision member 312 provided in the first connector 310 due to the difference in inclination between the container part 100 and the cover part 200. Can collide with each other. Thus, shock or vibration may occur in the first connector 310, and attachments attached to the container part 100 or the cover part 200 may be removed by the shock and vibration generated in the first connector 310.

The first collision member 311 is installed in the container portion 100. The first collision member 311 protrudes outward from the surface of the container portion 100.

In addition, the first collision member 311 may include a collision surface that may collide with the protruding member 313, and a connecting body that protrudes outward from the container portion 100 more than the collision surface. The collision surface is disposed to face the second collision member 312. The collision surface may be located above the connecting body. The connector may be provided with a pair and spaced apart from each other in a direction crossing the extension direction. Thus, the lower end of the second collision member 312 may be located between the connecting bodies. However, the structure and shape of the first collision member 311 may be various but not limited thereto.

The second collision member 312 is installed in the cover part 200. At least a portion of the second collision member 312 may move toward the first collision member 311. Accordingly, at least a portion of the second collision member 312 may be spaced apart from the first collision member 311 and move toward the first collision member 311 to collide with the first collision member 311. have. Therefore, shock or vibration may occur due to the collision between the first collision member 311 and the second collision member 312.

For example, the first collision member 311 and the second collision member 312 may be spaced apart from each other, and the lower portion may be rotatably connected to each other. That is, the first collision member 311 and the second collision member 312 may be hinged. The lower end of the second collision member 312 may be located between the connectors provided in the first collision member 311, and a rotation shaft may penetrate the lower ends of the connectors and the second collision member 312. . Therefore, the upper end of the second collision member 312 may rotate about the lower end. By the hinge, the second collision member 312 can move only toward one position of the first collision member 311. However, the structure in which the first collision member 311 and the second collision member 312 are rotatably connected to each other may be various but not limited thereto.

In addition, the second collision member 312 may be formed along a portion of the cover portion 200. For example, the second collision member 312 may be formed by refraction of the portion along the shape of the cover part 200. The upper portion of the second collision member 312 is coupled to the inner side of the first cover member 210 and the lower portion is connected to the first collision member 311. Thus, the upper portion of the second collision member 312 may rotate toward the inside and outside of the container portion 100 with respect to the lower portion. As the second collision member 312 rotates, the upper portion of the second collision member 312 and the first collision member 311 may be closer or further away from each other. However, the structure and shape of the second collision member 312 may vary, without being limited thereto.

Meanwhile, one of the first collision member 311 and the second collision member 312 may be provided with a protruding member 313 protruding toward the other. The protruding member 313 may be provided at the first collision member 311 and the second collision member 312, and may be disposed to collide with one another. For example, the protruding member 313 may be provided in the second collision member 312 and disposed to face the first collision member 311. The protruding member 313 is positioned between the upper and lower portions of the second collision member 312. The protruding member 313 may protrude toward the first collision member 311 from the surface of the second collision member 312. The protruding member 313 may be spaced apart or in contact with the first collision member 311.

When the second collision member 312 rotates toward the first collision member 311, the distance between the protruding member 313 and the first collision member 311 may be closer. Thus, the protruding member 313 may collide with the first collision member 311 to generate shock and vibration. When the second collision member 312 rotates to the outside of the container portion 100, the distance between the protruding member 313 and the first collision member 311 may be increased. Therefore, the protruding member 313 and the first collision member 311 may be spaced apart from each other.

The impact may be concentrated by reducing the area of the portion where the first collision member 311 and the second collision member 312 collide by the protruding member 313. Therefore, the impact and vibration may be effectively generated by the collision between the first collision member 311 and the second collision member 312. However, the protruding member 313 may be provided in the first collision member 311 to collide with the second collision member 312.

1 and 4, the second connector 320 is installed between the container part 100 and the cover part 200. One side of the second connector 320 is connected to the outer wall of the middle portion of the container portion 100, and the other side is connected to the inner wall of the middle portion of the cover portion 200. The second connector 320 may support an intermediate portion of the cover part 200. Thus, the second connector 320 may be spaced apart from the first connector in the vertical direction.

In addition, the second connector 320 may adjust the inclination of the cover part 200. Thus, the cover portion 200 may be adjusted differently from the container portion 100 inclination. Accordingly, while the inclinations of the cover part 200 and the container part 100 are changed, the second collision member 312 may rotate, and the protrusion member 313 and the first may be rotated by the rotation of the second collision member 312. The collision members 311 may be spaced apart or collide with each other. The second connector 320 includes a body member 321, a first connection member 322, and a second connection member 323.

Body member 321 is installed in the container portion (100). Body member 321 is formed in a cylindrical shape, it may extend up and down. The body member 321 may be spaced apart from the cover part 200 to face the cover part 200. The body member 321 has a first space 321a and a through hole 321c.

The first space 321a extends in the extending direction (or up and down direction) of the container portion 100 inside the body member 321. Thus, one side of the first connection member 322 is inserted into the first space 321a to move along the extension direction of the first space 321a. Therefore, the first space 321a may serve as a guide of the first connection member 322.

In addition, the first space 321a may extend to an upper surface of the body member 321. Thus, a hole communicating with the first space 321a may be formed in the upper surface of the body member 321. The lower surface of the body member 321 may not be opened. Therefore, one side of the first connection member 322 may be inserted into the first space 321a through a hole formed in the upper surface of the body member 321.

The through hole 321c allows the first connection member 322 to penetrate the body member 321. The through hole 321c may be formed on a surface of the first connection member 322 that faces the cover part 200. The through hole 321c may be dug toward the first space 321a from one surface of the first connection member 322. Thus, the through hole 321c is connected to the first space 321a. The width of the through hole 321c may be smaller than the width of the first space 321a. Accordingly, the first connection member 322 may be inserted into the first space 321a to prevent it from being separated.

In addition, the through hole 321c may extend along an extension direction (or up and down direction) of the first space 321a. Thus, the first connection member 322 may move along the direction in which the through hole 321c and the first space 321a extend.

Meanwhile, the hole formed in the upper surface of the body member 321 by the first space 321a may be blocked by the opening and closing member 329 to be described later. Accordingly, the opening / closing member 329 may prevent the first connection member 322 from leaving the outer side of the body member 321.

The first connection member 322 may extend in a direction crossing the vertical direction (for example, front and rear or left and right directions). One side of the first connection member 322 may be inserted into the first space 321a in the body member 321, and the other side may protrude out of the body member 321 through the through hole 321c. The first connection member 322 is installed on the body member 321 so as to be movable in an extension direction (or up and down direction) of the container part 100.

In addition, the driving wheel 322a may be provided at one side of the first connection member 322. The driving wheel 322a may be disposed in the first space 321a and move while rotating in the first space 321a. Accordingly, the first connection member 322 can be easily moved along the extension direction of the first space 321a by the driving wheel 322a.

The second connection member 323 may extend in the longitudinal direction. The second connection member 323 may be connected to the first connection member 322 to move together with the first connection member 322.

In addition, one end of the second connection member 323 is rotatably connected to the first connection member 322. That is, the first connection member 322 and the second connection member 323 may be hinged. For example, a pair of protrusions on the other side of the first connection member 322 may be provided. One end of the second connection member 323 may be located between the protrusions of the first connection member 322, and a rotation shaft may penetrate the protrusions and one end of the second connection member 323. Therefore, the other end of the second connection member 323 may rotate about one end. However, the structure in which the first connection member 322 and the second connection member 323 are rotatably connected to each other may be various but not limited thereto.

On the other hand, the other end of the second connecting member 323 is rotatably connected to the cover 200. That is, the second connection member 323 and the cover 200 may be hinged. For example, the cover 200 may be provided with a pair of combinations 225. The combination 225 may protrude toward the second connection member 323 from the inner wall of the cover 200. The other end of the second connection member 323 may be located between the coupling bodies 225, and a rotation shaft may penetrate the protrusions and one end of the second connection member 323. However, the structure in which the second connection member 323 and the cover part 200 are rotatably connected to each other may be various but not limited thereto.

The second connector 320 may further include a vibration member 330. Accordingly, the second connector 320 may also generate vibrations to remove the attachments at different positions together with the first connector 310. The vibration member 330 is installed on the body member 321. The vibration member 330 may generate vibration in the body member 321. Thus, vibration generated in the body member 321 may be transmitted to the container part 100 and the cover part 200, and the attachment may be removed by vibration. Since the first connector 310 and the vibrating member 330 generate vibrations at different positions, strong vibrations can be easily transmitted to the entire container part 100 and the cover part 200, and the attachment is effectively removed. Can be.

In addition, the vibrating member 330 may include a collider 331 and an elastic body 332. In this case, the colliding body 331 and the elastic body 332 may be installed in the second space 321b provided in the body member 321.

The second space 321b may further include a second space 321b extending in the extending direction (or up and down direction) of the container part 100 in the body member 321. The second space 321b is spaced apart from the first space 321a. For example, the second space 321b may be disposed closer to the container portion 100 than the first space 321a. Therefore, the first connection member 322 inserted into the first space 321a may be connected to the second connection member 323 on the outside through the through hole 321c.

In addition, the second space 321b may extend to an upper surface of the body member 321. Thus, a hole communicating with the second space 321b may be formed in the upper surface of the body member 321. The lower surface of the body member 321 may not be opened. Therefore, the impact body 331 and the elastic body 332 can be inserted into the second space 321b through the hole formed in the upper surface of the body member 321.

The collider 331 may be formed of a sphere. The collider 331 is arranged to be movable in the extension direction of the container part 100 in the second space 321b. Accordingly, the collision body 331 may collide with the inner wall of the body member 321 while moving in the second space 321b. Therefore, the impact and vibration may occur in the body member 321 due to the collision with the impact body 331. The impact body 331 may move in the second space 321b according to the inclination of the container part 100.

The elastic body 332 is installed in the second space 321b. The elastic body 332 may be a spring. The elastic body 332 may be fixed to the bottom bottom of the second space 321b. As a result, the collision between the collider 331 and the bottom of the second space 321b can be prevented, and the shock applied to the bottom of the second space 321b can be absorbed. That is, the elastic body 332 is disposed in contact with the colliding body 331, and can absorb shock while being contracted.

In addition, when the container part 100 is inclined, when the collider 331 moves in a direction opposite to the bottom surface of the second space 321b, the elastic body 332 contracted by the load of the collider 331 is extended. The collider 331 can be pushed out. Thus, the collision body 331 may collide with the inner wall of the body member 321 while moving at a higher speed by the elastic body 332. Thus, stronger vibrations occur, so that deposits can be removed more effectively.

Meanwhile, a plurality of second spaces 321b may be provided. The vibrating member 330 may also be provided as many as the second space 321b is provided. Accordingly, the plurality of colliders 331 may generate shock and vibration to the body member 321. Thus, stronger shocks and vibrations occur, so that deposits can be removed more effectively. However, the structure and shape of the vibrating member 330 and the method of generating the vibration may be various but not limited thereto.

The body member 321 may further include an opening and closing member 329. The opening and closing member 329 may be installed at an upper portion of the body member 321. A hole formed in the upper surface of the body member 321 of the opening and closing member 329 may be covered. Therefore, the first connecting member 322 moving along the first space 321a can be prevented from leaving the body member 321, and the collider 331 moving in the second space 321b can be prevented. Leaving away the member 321 can be prevented. The collider 331 may collide with the opening and closing member 329 to generate vibration.

In addition, it may be formed in a plate shape along the upper surface shape of the body member 321. The bolt penetrates through the body member 321 and the opening and closing member 329, so that the body member 321 and the opening and closing member 329 may be coupled to each other. When the bolt is released, the body member 321 and the opening and closing member 329 may be separated, and holes of the upper surface of the body member 321 may be opened. Accordingly, when the components in the first space 321a or the second space 321b are damaged, the opening / closing member 329 may be separated from the body member 321, and then repair or replacement may be easily performed.

1 and 5, the second connector 320 may further include a driver 340. The driver 340 may adjust the inclination of the cover 200 to be different from the inclination of the container 100. The driver 340 may move the first connection member 322 in the extending direction of the container part 100. The driver 340 includes a driving member 341 and a power transmission member 342.

The driving member 341 may generate a driving force capable of moving the first connection member 322. For example, the drive member 341 may be a hydraulic cylinder. The driving member 341 may be spaced apart from the lower side of the body member 321. However, the method of generating the driving force of the driving member 341 may be various.

The power transmission member 342 may have one end connected to the first connection member 322 and the other end connected to the driving member 341 so as to transmit the driving force. For example, the power transmission member 342 may be a cylinder rod. The upper end of the power transmission member 342 may be connected to the first connection member 322 in the first space 321a through the lower portion of the body member 321, and the lower end may be connected to the driving member 341. The power transmission member 342 may move up and down by the driving member 341. Accordingly, the first transmission member 322 may be moved up and down while the power transmission member 342 moves.

When the first connection member 322 moves upward by the driver 340, the lower portion of the cover part 200 may move upward. Thus, the upper portion of the cover part 200 may move toward the container part 100, and the protruding member 313 may move toward the first collision member 311 and collide with each other. Therefore, without adjusting the inclination of the container part 100, the inclination of the cover part 200 is adjusted by the driver 340 to collide the first collision member 311 and the protruding member 313 to generate vibration. Can be.

When hydraulic pressure is supplied to the driving member 341, the driving member 341 may move the power transmission member 342 upward. Thus, the first collision member 311 and the protruding member 313 may collide with each other while the inclination of the cover 200 is adjusted differently from that of the container 100. When the driving member 341 moves the power transmission member 342 downward, the inclination of the cover 200 is equal to the inclination of the container 100, and the first collision member 311 and the protruding member 313 are provided. Can be spaced apart. Therefore, by controlling the operation of the driver 340 may generate a vibration in the first connector 310 to remove the deposit.

6 is a flowchart illustrating a deposit removing method according to an embodiment of the present invention, Figure 7 is a view showing the operation of the container apparatus according to an embodiment of the present invention. Hereinafter, a method for removing deposits of the container device according to an embodiment of the present invention will be described.

The deposit removal method of a container apparatus relates to the deposit removal method which can remove a deposit. Referring to FIG. 6, the removal method includes providing a container device including a container part, a cover part disposed to surround the container part, and a connection part connecting the container part and the cover part (S110), and tilting the container part. It includes a step (S120), the step of generating a collision in the connection (S130), and the process of separating the attachment by causing a shock or vibration to the container portion and the cover to the collision generated in the connection (S140).

1 and 7, the container device 1000 includes a container part 100 having an inner space, a cover part 200 disposed to cover at least a portion of the container part circumference, and the container part and the cover part. In order to remove the adhered to the container portion 100 and the cover portion 200, at least a portion includes a connection portion 300 that can generate an impact in conjunction with the inclination of the container portion 100. Accordingly, vibration may occur due to the shock generated by the connection part 300 interlocking with the inclination of the container part 100, and the shock and vibration may be transmitted to the container part 100 and the cover part 200 to remove the deposit. have.

At this time, the container portion 100 may be a ladle capable of receiving molten steel therein, the attachment may now be. In the course of carrying out the operation of refining molten steel into the container portion 100 or refining the molten steel in the container portion 100 in the converter, the molten steel springs to the top or the shell of the container portion 100, or cover portion 200 The fusion can produce the same attachment as now. Therefore, the attachments attached to the container part 100 and the cover part 200 may be removed by the vibration generated by the connection part 300.

First, the hook hook 11 may be hooked to the hook hook member 110 provided in the container part 100, and the hook hook 12 may be hooked to the hook hook member 120 provided in the container part 100. In the state in which the position of the sovereign hook 11 is fixed, when the borehole hook 12 is lifted upward, the inclination of the container portion 100 can be adjusted while the bouncing member 120 of the container portion 100 moves upward. Can be. That is, the container 100 may be tilted so that the upper portion of the container 100 may be inclined toward the front.

In this case, the operation of tilting the container part 100 may be performed while supplying all the molten steel in the container part 100 to the tundish, and then discharging the molten steel remaining in the container part 100. Therefore, in order to remove the deposit attached to the container device 1000, a separate place or working time may not be secured. Accordingly, the molten steel may be discharged and at the same time, a work for removing the deposit may be performed.

When the container part 100 is tilted and tilted, the container part 100 may be adjusted like the container part 100 of the second connector 320 in a horizontal state. Accordingly, the first connection member 322 may move along the inclination of the first space 321a toward the upper portion (or the opening portion) of the container portion 100 by its own weight. The second connection member 323 is interlocked by the movement of the first connection member 322 to push the lower portion of the cover part 200 outward of the container part 100. Therefore, while the inclination of the container part 100 and the cover part 200 is changed, the upper part of the cover part 200 moves to the container part 100 side, so that the first collision member 311 and the protruding member 313 are moved. May crash.

That is, while the connection part 300 is operating, the inclination of the cover part 200 may be adjusted differently from the inclination of the container part 100. Thus, the upper portion of the cover portion 200 may move to the container portion 100 side, and the lower portion of the cover portion 200 may move to the outside of the container portion 100. Therefore, the first collision member 311 installed at the upper portion of the container portion 100 and the protrusion member 313 of the second collision member 312 provided at the upper portion of the cover portion 200 may collide with each other as they approach each other. . Due to the difference between the inclination of the container part and the cover part, the collision between the first collision member 311 and the protruding member 313 causes shock or vibration to the container part 100 and the cover part 200, and thus the attachment part is attached to the container part 100. And the cover 200 may be separated.

In addition, the cover part 200 may be inclined at a larger angle than the angle at which the container part 100 is inclined by the connection part 300. Thus, before the molten steel is fixed, the molten steel may move along the inclination of the cover part 200 to be separated from the cover part 200. The interior of the container part 100 is still separated from the inner wall of the container part 100 by the shock and vibration transmitted from the connection part 300. It may be discharged to the outside by the inclined container 100.

On the other hand, the impact body 331 in the second space 321b provided in the body member 321 may also generate shock or vibration. That is, when the container portion 100 is tilted, the upper portion of the body member 321 may also be tilted downward. Accordingly, the collider 331 may move to the upper side of the second space 321b along the slope by the own weight at the lower portion of the second space 321b. The collider 331 may collide with the upper portion of the body member 321 to generate shock and vibration. Therefore, the impact or vibration generated by the collision between the impact body 331 and the inner wall of the body member 321 (or the opening / closing member 329) is transmitted to the container part 100 and the cover part 200 to be the container part 100. ) And the attachment attached to the cover 200 may be separated.

In this case, since shock and vibration occur at a plurality of different positions (that is, both the first connector 310 and the second connector 320), the shock and vibration are counted, and the shock and vibration may be generated and transmitted. The range can be widened. Therefore, the shock and vibration are easily transmitted to the cover 200 and the container 100 as a whole, and the attachment may be removed while being effectively separated.

In this way, the deposit attached to the container device 1000 can be easily removed. As a result, deposits may not grow on the container device 1000, and the container device 1000 may be kept in a clean state. Thus, maintenance of the container apparatus 1000 can be facilitated.

In addition, since the deposit attached to the container apparatus 1000 has been removed, the attachment attached to the container apparatus 1000 may be prevented from falling around the container apparatus 1000 when the container apparatus 1000 is transported or moved. Can be. Thus, the attachment may prevent damage to the surrounding equipment or the occurrence of a safety accident.

As described above, in the detailed description of the present invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the claims described below, but also by those equivalent to the claims.

100: container 200: cover
300: connector 310: first connector
311: first collision member 312: second collision member
313: protrusion member 320: second connector
321: body member 322: first connecting member
323: second connection member 330: vibration member
340: driver 1000: container device

Claims (15)

Regarding the container device that can remove the deposit,
A container part having an inner space;
A cover part disposed to cover at least a portion of the circumference of the container part; And
And a connecting portion connecting at least a portion of the container portion to the cover portion and causing a collision in association with the inclination of the container portion so as to remove an attachment attached to the container portion and the cover portion. . The method according to claim 1,
The connecting portion,
A first connector disposed between the container portion and the cover portion, the first connector including a first collision member and a second collision member, at least a portion of which may collide with each other due to a difference in inclination of the vessel portion and the cover portion; And
And a second connector spaced apart from the first connector and installed between the container portion and the cover portion and configured to adjust an inclination of the cover portion. The method according to claim 2,
The first collision member is installed in the container portion,
The second collision member is installed in the cover portion, at least a portion of the container device capable of moving toward the first collision member. The method according to claim 3,
One side of the first collision member and the second collision member is spaced from each other, the other side is a container device that is rotatably connected to each other. The method according to claim 4,
Any one of the first collision member and the second collision member, the container device which is provided with a protruding member protruding toward the other. The method according to claim 2,
The second connector,
A body member installed in the container portion;
A first connection member installed on the body member to be movable in an extension direction of the container part; And
And a second connecting member having one end rotatably connected to the first connecting member and the other end rotatably connected to the cover part. The method according to claim 6,
The body member,
A first space extending in the extension direction of the container portion in the body member, the first connecting member being inserted and moving; and
And a through hole connected to the first space and extending along the extending direction of the first space so that the first connecting member can pass through the body member. The method according to claim 7,
The second connector further comprises a vibrating member installed on the body member to generate vibration. The method according to claim 8,
A second space extending in the extending direction of the container portion is provided in the body member,
The vibration member,
A collider arranged to be movable in an extension direction of the container portion in the second space; And
And an elastic body installed in the second space and disposed to be in contact with the colliding body. The method according to claim 6,
The second connector further comprises a driver capable of moving the first connecting member in the extending direction of the container portion. The method according to claim 10,
The driver,
A driving member capable of generating a driving force capable of moving the first connection member; And
And a power transmission member having one end connected to the first connection member and the other end connected to the driving member so as to transmit the driving force. The present invention relates to a method of removing a deposit that can remove a deposit.
Providing a container device having a container part, a cover part disposed to surround the container part, and a connection part connecting the container part and the cover part;
Tilting the container;
Generating a collision at the connection unit; And
And removing the deposit by causing an impact or vibration to the container part and the cover part due to a collision occurring in the connection part. The method according to claim 12,
The connection part includes a first collision member installed on the container portion, and a second collision member installed on the cover portion, the at least a portion of which is movable toward the first collision member,
The process of generating a collision in the connection unit,
Adjusting the inclination of the container portion and the cover portion differently; And
And colliding the first colliding member and the second colliding member due to a difference in inclination of the container portion and the cover portion. The method according to claim 12,
The process of generating a collision in the connection unit,
Attachment removal method comprising the step of generating a collision at a plurality of locations of the connecting portion. The method according to any one of claims 12 to 14,
And the container portion includes a ladle capable of receiving molten steel therein, wherein the attachment comprises now.

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