KR20190069089A - Door Apparatus, Opening and closing Method of Container - Google Patents

Abstract

The present invention relates to a door apparatus for opening and closing an opening part of a container. The door apparatus comprises: a door spaced from the container, and opening and closing at least a portion of a space in which the container is located; and a cover installed in the door to open and close the opening part of the container. Moreover, the opening part of the container can be easily blocked to suppress or prevent the inside temperature of the container from being lowered.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a door device,

The present invention relates to a door device and a method for opening and closing an opening of a container, and more particularly, to a door device and a method for opening and closing an opening of a container that can easily prevent an opening of the container from being lowered.

Generally, the steelmaking process proceeds in the order of iron pre-treatment, converter refining, secondary refining, and continuous casting. In converter refining, pure oxygen is removed and removed to oxidize and refine impurities. In the second refining, oxygen and oxygen oxides are removed by oxygen blowing during the refining of the converter.

During refinement of refinement, refinement is carried out by refilling the furnace by charging the furnace with scrap iron and scrap iron, and then supplying the gas only through the scrap nozzle installed on the bottom of the converter. In the scouring, the gas is supplied to the upper part of the furnace to refine the charcoal. In refinement of refinement, refining of the charcoal is performed by supplying gas through the upper and lower portions of the charcoal. Through this process, the molten steel in which impurities are removed is called molten steel.

Conversion refining may be stopped due to shortage of charcoal and scrap iron inside the converter, abnormal operation of the equipment, and operational factors of the post-process. At this time, if the temperature of the refractory provided in the converter rapidly drops because the heat inside the converter is discharged through the furnace, the life span of the refractory may be lowered due to the spoiling phenomenon due to the temperature change.

Further, in order to raise the temperature of the molten iron (or molten steel) inside the converter in order to carry out the refining of the converter again, the manufacturing cost of the molten steel may increase because the heat part must be supplied with ferro silicon (Fe-Si) or graphite. On the other hand, slag and molten steel are attached to the nogh part of the converter by cooling and solidifying, which may result in a low running rate or a poor quality due to a delay in dissolving the submaterials charged during the refining of the converter.

Conventionally, when the refining of the converter is stopped, a cover is provided on the nose of the converter by using an overhead crane to suppress or prevent the heat inside the converter from being released to the outside. However, there was no space to store the cover near the converter, and the cover was kept in a separate storage room 30 to 50m away from the converter. Therefore, when the overhead crane performs another operation, there is a problem that it is not possible to perform the operation of installing the cover on the nose of the converter.

Further, even if the overhead crane is used, it takes a long time to move and install the cover, so there is a problem that the refractory of the converter is cooled until the cover is installed. Since it takes a long time to separate the cover from the converter, the cover is detached from the converter to perform the next operation. However, much time may be delayed to reduce the efficiency of the operation and the productivity.

KR 1997-0033314 U KR 2002-0000338 A

The present invention provides a door device capable of easily opening and closing an opening of a container having an inner space in which molten metal is processed, and a method of opening and closing an opening of the container.

The present invention provides a door device and a method of opening and closing an opening of a container that can suppress or prevent the temperature of the internal space of the container from being lowered.

A door device capable of opening and closing an opening of a container, comprising: a door which is spaced from the container and can open and close at least a part of a space in which the container is located; And a cover provided on the door so as to open and close the opening of the container.

The door includes a plurality of bodies movably installed, and the cover is installed on at least one of the plurality of bodies.

The cover includes a plurality of bodies mounted on each body, movable with each body, and detachably connected to each other.

The body includes: a driver supported by the body; A support plate having one surface connected to the driver so as to move back and forth toward the opening of the container; And a refractory member provided on the other surface of the support plate so as to be in contact with the opening of the container.

The body further includes a plurality of protrusions provided on the other surface of the support plate to fix the refractory member.

At least one of the protruding portion and the inserting portion may be formed on the body, and the protruding portion of another body may be inserted into the inserting portion of the one body.

The size of the area of the portion of the bodies connected to each other facing the container is equal to or larger than the size of the opening area of the container.

At least a part of the cover is provided so as to adjust the inclination.

The cover further includes a support bar having one end connected to the cover and the other end rotatably connected to the actuator.

The door has an inclined surface at least partially, and the cover is supported on the inclined surface of the door in a downward inclined direction toward the container.

The present invention provides a method of opening and closing an opening of a container, comprising the steps of: providing a door provided with a cover; Closing at least a part of the space in which the container is located by moving the door; And moving the cover in a direction intersecting with the moving direction of the door to make the cover closely contact with the opening of the container.

The process of moving the door includes moving the cover provided in the door together with the door in the moving direction of the door.

The door includes a plurality of bodies movably installed, and the cover includes a plurality of bodies that are installed on each body, moveable together with the bodies, and detachably connected to each other,

The step of moving the cover installed in the door together with the door in the direction of movement of the door includes a step of coupling the plurality of bodies.

Before moving the cover in a direction intersecting the moving direction of the door,

And adjusting the inclined angle of the cover and the opening of the container.

The container includes a converter, and the space in which the container is located includes the interior space of the clean house.

According to the embodiments of the present invention, a cover capable of blocking the opening of the container is provided in a door capable of opening and closing at least a part of the space where the container is located. Thus, since the cover is disposed at a position close to the container, the opening of the container can be quickly blocked by the cover, so that the temperature of the internal space of the container can be prevented from being lowered or prevented.

In addition, even if there is no separate crane, at least a part of the cover can move and block or open the opening of the container. Thus, since the opening of the container can be easily opened and closed, the time required for the entire process can be prevented from being delayed due to the opening and closing time of the container. Thus, the productivity and efficiency of the overall process can be improved.

For example, when the refractory is provided in the container, the opening of the container can be blocked by the cover before the refractory is suddenly cooled by releasing heat to the opening of the container. Therefore, it is possible to suppress or prevent the lifetime of the refractory material from deteriorating due to a rapid temperature change. Thus, the service life of the equipment can be improved and the maintenance of the equipment can be facilitated.

1 is a perspective view showing a door apparatus according to an embodiment of the present invention;
2 is a view showing a structure of a door apparatus according to an embodiment of the present invention;
3 is a view showing an operating structure of a cover according to an embodiment of the present invention.
4 is a view showing the structure of a door apparatus according to another embodiment of the present invention.
5 is a view showing an operating structure of a cover according to another embodiment of the present invention.
6 is a view showing an operating structure of a cover according to another embodiment of the present invention.
7 is a flowchart showing a method for opening and closing an opening of a container according to an embodiment of the present invention.
8 is a plan view showing an operation in which a cover according to an embodiment of the present invention closes an opening of a container.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It will be apparent to those skilled in the art that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to let you know. To illustrate the invention in detail, the drawings may be exaggerated and the same reference numbers refer to the same elements in the figures.

FIG. 1 is a perspective view showing a door device according to an embodiment of the present invention, and FIG. 2 is a view showing a structure of a door device according to an embodiment of the present invention.

1 and 2, a door device 100 according to an embodiment of the present invention includes a door device 100 capable of opening and closing an opening 55 of a container 50, A door 120 capable of opening and closing at least a part of the space, and a cover 130 installed on the door 120. At this time, the container 50 may be a converter, and the space where the container 50 is located may be the inner space of the clean house.

The container 50 has an inner space in which the molten metal is stored. For example, a bottom portion and side wall portions may be provided to form an inner space. The bottom part and the side wall part may be composed of a metal foil forming an outer shape and a refractory material formed inside the metal foil.

An outlet for discharging the molten metal stored in the inner space is formed in the side wall portion. If the container 50 is tilted so that the outlet faces downward after the molten metal is treated in the container 50, the molten metal contained in the inner space can be discharged to the outside through the outlet.

The bottom portion may be provided with a low-noise nozzle capable of supplying a process gas. Oxygen gas can be used as the process gas. Therefore, the molten metal in the vessel 50 can be refined by the process gas supplied to the bottom of the vessel 50.

In addition, the upper portion of the container 50 may be at least partially opened to form the opening 55. [ The opening 55 may be located at a portion opposed to the bottom portion. At this time, the opening 55 may be a bow inlet. Therefore, a charge such as charcoal or scrap iron can be charged into the interior of the container 50 through the opening 55. The molten iron can be refined in the inner space of the container 50, and the impurities can be removed to become molten steel.

The container 50 can be adjusted in its inclination. That is, the container 50 is tiltably supported. Therefore, the opening 55 and the outlet position of the container 50 can be changed. When the container 50 is tilted so that the opening 55 faces upward, it is possible to carry out a process of charging the contents into the container 50 to treat the molten metal therein. When the container is tilted so that the outlet faces downward, the molten metal inside the container 50 can be discharged to the outside through the outlet. When the container 50 is tilted such that the opening 55 faces forward and the outlet faces upward, the slag floating on the molten metal in the container 50 can be discharged to the outside through the opening 55. [

The clean house, though not shown, has an internal space in which the container 50 is received, is open on the upper side, and can be installed on the floor and on a separate support. The clean house can cover the periphery of the container 50 so that the container 50 is not exposed to the outside. Thus, the clean house serves to prevent the heat and the arsenic generated when the molten metal is treated in the vessel 50 from flowing out or diffusing to the outside. The clean house can be opened in the direction in which the cover 130 is located. That is, at least a portion of the side of the clean house can be opened. The door 120 is installed in correspondence with the open portion of the clean house to open or close the clean house.

The door 120 can open and close at least a part of the space where the container is located (or the inner space of the clean house). The door 120 opens the side surface of the clean house so that a transportation device (not shown) can charge the inside of the container 50 through the open side of the clean house So that it can be charged smoothly. When the molten metal is processed into the container 50, the door 120 may block the side surface of the clean house to prevent the heat or the arsenic from diffusing or diffusing to the outside to contaminate the surrounding workplace.

Further, the door 120 may be located apart from the container 50. Accordingly, a space in which the cover 130 can be positioned between the door 120 and the container 50 can be formed. The door 120 may include a plurality of bodies movably installed. For example, the bodies are arranged in pairs and are arranged in the width direction (or the left-right direction) of the container 50. A clean house is opened by a pair of bodies moving away from each other, and a clean house can be closed by a pair of bodies approaching each other.

The body of the door 120 may have an inclined surface at least partially and the cover 130 may be supported on the inclined surface of the body of the door 120 in a downward inclined direction toward the container 50. For example, the body may include a first plate 121, a second plate 122, a third plate 123, a structure 125, a drive wheel 124, and a locking member (not shown) .

The first plate 121 is formed in a rectangular plate shape and can extend in the vertical direction. The first plate 121 may cover a part of the open side of the clean house.

The second plate 122 may have a rectangular plate shape and may extend in a direction intersecting the extending direction of the first plate 121. For example, the second plate 122 may extend diagonally. That is, the second plate 122 may be provided with an inclined surface on the body. One end (or the lower end) of the second plate 122 may be connected to the upper portion of the first plate 121 and the other end (or the upper end) may be disposed to face the vessel 50. The second plate 122 may cover a portion of the open side of the clean house.

The third plate 123 is formed in a rectangular plate shape and can extend in the vertical direction. The lower portion of the third plate 123 may be connected to the upper end of the second plate 122. Accordingly, the first plate 121 and the third plate 123 may be spaced from each other in the longitudinal direction as well as the vertical direction. The third plate 123 can cover a part of the open side of the clean house. Accordingly, the first plate 121, the second plate 122, and the third plate 123 can be coupled to each other to form one door 120, and cover the open side of the clean house .

At this time, the distance between the first plate 121 and the container 50 may be larger than the distance between the third plate 123 and the container 50. A larger space may be formed between the first plate 121 and the container 50 so that the cover 130 is supported by the second plate 122 so that the first plate 121 and the container 50 ), And can be stored.

The structure 125 may be installed on a surface of the first plate 121, the second plate 122, and the third plate 123 facing the outside of the converter. For example, the structure 125 may be an aggregate of bar-shaped structures extending vertically and horizontally. The structure 125 can be stably supported and operated by adding weight to the plates.

The driving wheel 124 may be installed under the first plate 121. Therefore, the entire open side of the clean house can be opened or shut while the entire door 120 is slid to the left and right.

At this time, a rail 160 may be installed on the lower side of the door 120. The rails 160 may extend in the width direction of the container 50. The drive wheel 124 can move on the rails 160 while rotating along the rails 160.

The locking member (not shown) serves to limit the rotation of the driving wheel 124. For example, the locking member may be a brake. Thus, when the door 120 is operated with the open side of the clean house blocked, the door 120 can be prevented from opening the side surface of the clean house. Also, it is possible to stably maintain the state where the bodies provided on the cover 130 are connected to each other by the locking member.

However, the structure and shape of the body are not limited to this and may vary. That is, the body may be formed in the form of a plate extending in the up-and-down direction without having an inclined surface. Also, the number of the bodies and the structure in which the bodies are moved is not limited to this, and may vary.

FIG. 3 is a view showing an operating structure of a cover according to an embodiment of the present invention, and FIG. 4 is a view showing a structure of a door device according to another embodiment of the present invention.

2 and 3, the cover 130 is installed on the door 120 so as to open and close the opening 55 of the container 50. As shown in FIG. The cover 130 may be supported by the second plate 122 and disposed in a downward inclined direction toward the container 50. For example, the cover 130 may be inclined at 85-89 degrees with respect to a vertical line. When the tilting angle of the cover is out of the range of 85 to 89 degrees, the cover 130 and the opening 55 of the container 50 may not be centered. As a result, the cover 130 can not cover the entire opening 55, and heat can be released to the open portion of the opening 55. The inclined angle of the cover 130 may be 85 degrees or more and 89 degrees or less so that the cover 130 covers the entire opening 55 by aligning the center of the cover 130 and the opening 55. [ However, the inclination angle of the cover 130 is not limited to this, and may vary.

The cover 130 may be installed on at least one of the plurality of bodies. When a plurality of the bodies of the door 120 are provided, the cover 130 may include a plurality of bodies fixed to the respective bodies of the door 120 and detachably connected to each other. For example, when a pair of bodies is provided, a pair of bodies may be provided. When a pair of bodies move away from each other, the bodies can also be separated from one another. When a pair of bodies move closer together, the bodies can be connected to each other as they approach each other.

Since the bodies of the cover 130 are moved by the body as shown in FIG. 3, when the bodies are separated from each other, the bodies are separated from each other. When the bodies are closer to each other, the bodies can be connected to each other. Accordingly, in order for the bodies of the cover 130 to be connected to cover the opening 55 of the container 50, the door 120 must be kept closed. Therefore, since the cover 130 covers the opening 55 of the container 50 in the closed state of the door 120, the heat inside the container 50 can be prevented from being discharged to the outside.

At this time, the shape of the portion of the bodies connected to each other facing the container 50 may be formed along the shape of the opening 55 of the container 50. The size of the area of the portion of the bodies connected to each other facing the container 50 may be larger than the size of the area of the opening 55 of the container 50. [ Therefore, the portions of the bodies connected to each other facing the container 50 can be brought into close contact with the opening 55 of the container 50 to completely block the opening 55. [

The body includes a driver 131, a support plate 132, and a refractory member 133. In addition, the body may further include a plurality of protrusions 134 and a case 135. The driver 131, the support plate 132, the refractory member 133, the protrusion 134, and the case 135, which are provided in any one of the pair of doors 120, will be described do.

The actuator 131 serves to generate a driving force for moving the support plate 132 and the refractory member 133. For example, the actuator 131 may be a cylinder, and the support plate 132 and the refractory member 133 may be pushed toward the container 50 side or toward the door 120 side. That is, the support plate 132 and the refractory member 133 can be moved back and forth by the operation in which the rod portion of the driver 131 is moved back and forth.

One end (for example, the body portion) of the driver 131 is connected to the door 120 and the other end (for example, the rod portion) is connected to the support plate 132. Thus, the driver 131 can move the support plate 132 while supporting the support plate 132.

At this time, a plurality of drivers 131 may be provided. As the number of the driving units 131 increases, the supporting plate 132 can be stably supported and the driving unit 131 can move the supporting plate 132 stably. For example, they may be arranged in a 2 x 2 array of four drivers and connected to the support plate 132. However, the structure in which the actuator 131 moves the support plate 132, the manner in which the actuator 131 is arranged, and the number of the actuators 131 provided are not limited to the above, and may vary.

The case 135 serves to receive at least a part of the driver 131. [ The case 135 may be a box having an internal space. The case 135 may be installed in the door 120. The main body portion of the driver 131 may be located in the inner space of the case 135 and the rod portion of the driver 131 may be connected to the support plate 132 through the case 135. Thus, at least a portion of the driver 131 can be protected from heat or arsenic generated in the vessel 50.

The support plate 132 may be formed in a shape that is divided in the shape of the opening 55 of the container 50. For example, when the opening 55 of the container 50 is formed in a circular shape and two bodies are provided, the support plate 132 may be formed in a semicircular shape. When the supporting plate 132 of the one body 130a and the supporting plate 132 of the other body 130b are connected to each other on the door 120, ) Shape.

The surface of the support plate 132 facing the door 120 is connected to the driver 131 and the refractory member 133 may be installed on the surface facing the container 50. The support plate 132 can support the refractory member 133 while moving back and forth toward the opening 55 of the container 50 by the driver 131. [ However, the structure and shape of the support plate 132 are not limited to the above, and may vary.

A plurality of protrusions 134 may be provided on a surface of the support plate 132 facing the container 50. The protrusion 134 may be formed in an 'I' or 'Y' shape. For example, the protrusion 134 may be a stud pin. Thus, the state in which the refractory member 133 is fixed to the support plate 132 by the protrusion 134 can be more stably maintained. Therefore, the refractory member 133 can stably move forward and backward along the support plate 132 while maintaining the state of being fixed to the support plate 132. [ However, the shape of the projection 134 is not limited to this, and may be various.

The refractory member 133 can contact the opening 55 of the container 50 and can block or open the opening 55 of the container 50 while moving back and forth. The refractory member 133 may be provided on the surface of the support plate 132 facing the container 50. The refractory member 133 may be formed along the shape of the support plate 132. For example, when the support plate 132 is formed in a semicircular shape, the refractory member 133 may be provided on the support plate 132 in a semicircular shape. When the refractory member 133 of the body 130a and the refractory member 133 of the body 130b are connected to each other, the shape of the opening may be the same as the shape of the opening 55 of the container 50 . Therefore, the refractory member 133 can cover the opening 55 of the container 50.

For example, when the refractory member 133 advances toward the opening 55 side of the container 50 by the driver 131, the refractory member 133 can be blocked against the opening 55 while being close to the opening 55 . Thus, the heat inside the container 50 can be suppressed or prevented from being released to the outside through the opening 55. [ The refractory member 133 and the opening 55 of the container 50 can be spaced apart from each other and the opening of the opening 50 of the container 50 55 may be opened.

At this time, the size of the area of the portion of the refractory members 133 connected to each other facing the container 50 may be larger than the size of the area of the opening 55 of the container 50. Therefore, the portions of the bodies connected to each other facing the container 50 can be brought into close contact with the opening 55 of the container 50 to completely block the opening 55. [

Further, the refractory member 133 may be made of castellation, which is an atypical refractory. This makes it easier to mount the refractory member 133 on the support plate 132. [ Since the refractory member 133 is formed of a refractory, the refractory member 133 can withstand the heat generated inside the container 50 and can stably cover the opening 55 of the container 50. However, the structure and the shape of the refractory member 133 are not limited to these, and may vary.

4 (a), the cover 130 further includes a support bar 136 having one end connected to the cover 130, the other end connected to the driver 131, and at least part of which is refracted You may. That is, the support bar 136 may be formed in a partially bent shape to support the actuator 131. Thus, even if the door 120 is not provided with the inclined surface, the support bar 136 can support the actuator 131 in an inclined direction. Therefore, the cover 130 and the opening 55 of the container 50 can be arranged so as to face each other even if the container 50 is slightly tilted at right angles to the vertical line. However, the structure and the shape of the cover 130 are not limited thereto and may vary.

Alternatively, as shown in FIG. 4B, at least a part of the cover 130 may be installed so as to adjust the tilt. The cover 130 may further include a support bar 136 having one end connected to the cover 130 and the other end rotatably connected to the driver 131. Accordingly, the angle of the support plate 132 and the refractory member 133 can be adjusted by adjusting the tilting angle of the actuator 131 by the support bar 136. The operation of the support bar 136 can be controlled to adjust the tilted angle of the refractory member 133 to match the angle of the container 50. [

Hereinafter, a cover according to another embodiment of the present invention will be described. FIG. 5 is a view showing an operation structure of a cover according to another embodiment of the present invention, and FIG. 6 is a view showing an operation structure of a cover according to another embodiment of the present invention.

At least one of the protruding portion and the inserting portion may be formed in the supporting plate 132 and the refractory member 133 of the body. The protruding portion B of the other body 130b can be inserted into the insertion portion A of the one body 130a installed in the different door 120. [

For example, as shown in FIG. 5, a groove-shaped insertion portion A may be formed at the center of a portion of the body 130a facing the other body 130b. A protrusion B projecting toward the one body 130a may be formed at a central portion of the other body 130b facing the one body 130a. The protrusion B of the other body 130b can be inserted into the insertion portion A of the body 130a when the body 130a and the body 130b are closely contacted with each other. Therefore, the one body 130a and the other body 130b connected to each other can be stably connected without covering each other in the vertical direction, so that the opening 55 of the container 50 can be covered.

Alternatively, as shown in FIG. 6, an insertion portion A may be formed at an upper portion of a portion of the body 130a facing the other body 130b, and a protrusion B may be formed at a lower portion. The protrusion B may be formed on the upper portion of the body 130a facing the body 130a of the other body 130b and the insertion portion A may be formed on the lower portion. When the one body 130a and the other body 130b come close to each other and come into close contact with each other, the protrusion B of the other body 130b can be inserted into the insertion portion A of the one body 130a, The protruding portion B of the one body 130a can be inserted into the insertion portion A of the main body 130a. Therefore, the one body 130a and the other body 130b connected to each other can be stably connected without covering each other in the vertical direction, so that the opening 55 of the container 50 can be covered. However, the structure and shape of the insertion portion A and the projection portion B are not limited to this, and may vary.

A cover 130 is provided on the door 120 capable of opening and closing at least a part of the space where the container 50 is located and capable of blocking the opening 55 of the container 50. [ Therefore, since the cover 130 is disposed at a position close to the container 50, the opening portion 55 of the container 50 is quickly cut off by the cover 130 to lower the internal space temperature of the container 50 Or inhibit.

Also, at least a portion of the cover 130 can move and block or open the opening 55 of the container 50 without the need for a separate crane. Therefore, the opening 55 of the container 50 can be easily opened and closed, so that the time required for the entire process can be prevented from being delayed due to the opening and closing time of the container 50. Thus, the productivity and efficiency of the overall process can be improved.

In particular, when the refractory is provided in the container, the opening (55) of the container (50) can be blocked by the cover (130) before the refractory is suddenly cooled by releasing heat to the opening of the container (50). Therefore, it is possible to suppress or prevent the lifetime of the refractory material from deteriorating due to a rapid temperature change. Thus, the service life of the equipment can be improved and the maintenance of the equipment can be facilitated.

Hereinafter, a method for opening and closing an opening of a container according to an embodiment of the present invention will be described. FIG. 7 is a flow chart showing a method for opening and closing an opening of a container according to an embodiment of the present invention, and FIG. 8 is a plan view showing an operation for closing an opening of the container according to the embodiment of the present invention.

Referring to FIG. 7, a method of opening and closing an opening of a container according to an embodiment of the present invention includes opening and closing a door of a container (S110) (S120) closing at least a part of the door (S120), and moving the cover in a direction intersecting with the moving direction of the door (S130) and bringing the cover close to the opening of the container (S130). At this time, the container 50 may be a converter, and the space where the container 50 is located may be the inner space of the clean house.

1 to 3 and 8, a door 120 provided with a cover 130 may be provided. At this time, the door 120 includes a plurality of bodies that are movably installed, and the cover 130 may include a plurality of bodies installed in the respective bodies, movable along with the respective bodies, and detachably connected to each other. have.

The refining operation for the molten metal may be stopped due to a shortage of raw materials in the container 50, an abnormality in the equipment, and operational factors of the back-and-forth process. At this time, if the heat inside the container 50 is released through the opening, the temperature of the refractory provided in the container 50 is rapidly lowered, and the lifetime of the refractory may be lowered due to a spoiling phenomenon caused by a temperature change. Therefore, it is possible to suppress or prevent the heat inside the container 50 from being released to the outside by performing an operation of cutting off the opening 55 of the container 50. [

First, the door 120, which opens and closes a part of the space where the container 50 is located, is moved to close the side surface of the space where the container 50 is located. That is, the open side of the clean house accommodating the container 50 in the internal space can be closed by the door 120.

When the bodies of the door 120 come close to each other and come into contact with each other, the bodies of the cover 130 installed in each body can also be coupled to each other. That is, the bodies of the cover 130 installed on each body of the door 120 may move together with the body in the direction of movement of the body and be coupled to each other. The shape of the portion of the body of the cover 130 that faces the container 50 may be formed along the shape of the opening 55 of the container 50.

Then, the cover can be moved in the direction (or in the front-back direction) intersecting with the movement direction (or the left-right direction) of the door 120 and brought into close contact with the opening of the container. For example, the support plate 132 and the refractory member 133 can be moved toward the opening 55 of the container 50 by the driver 131 of the cover 130. The opening 55 of the container 50 can be shut off while the refractory member 133 is in close contact with the opening 55 of the container 50. [ Since the cover 130 blocks the opening 55 of the container 50 in a state where the door 120 is closed, the heat inside the container 50 can be blocked from being discharged to the outside. Thus, it is possible to effectively suppress or prevent the temperature of the internal space of the container 50 from being lowered.

On the other hand, it is possible to perform an operation of aligning the inclined angle of the opening portion 55 of the container 50 with the cover 130 before the cover 130 is moved and brought into close contact with the opening portion 55. The container 50 can be tilted such that the opening of the container 50 faces the cover 130. [ The container 50 may be tilted to match the inclined angle of the cover 130. Alternatively, the cover 130 may tilt the cover 130 so as to face the opening 55 of the container 50. The center line of the opening 55 of the container 50 and the center line of the cover 130 can be located on the same line and the opening 55 of the container 50 and the cover 130 can be disposed facing each other .

The method of opening the opening 55 of the container 50 can be performed in the reverse order of the above procedure. That is, the cover 130 can be moved backward toward the door 120, so that the cover 130 and the container 50 can be separated from each other. Then, the container 50 can be tilted in the home position, and the door 120 can be opened according to the operation.

A cover 130 is provided on the door 120 capable of opening and closing at least a part of the space where the container 50 is located and capable of blocking the opening 55 of the container 50. [ Therefore, since the cover 130 is disposed at a position close to the container 50, the opening portion 55 of the container 50 is quickly cut off by the cover 130 to lower the internal space temperature of the container 50 Or inhibit.

Conventional example Example Cover installation time 20 minutes 1 minute Cover disassembly time 20 minutes 1 minute Refractory temperature of container before cover installation 1176 ° C 1142 DEG C Refractory temperature of container after cover installation 683 ° C 802 ℃ Temperature drop amount of refractory before and after cover installation 493 DEG C 340 ° C

In the conventional example, the opening 55 of the container 50 is closed by moving the nog cover by using a ceiling crane. In the embodiment, the opening 55 of the container 50 is closed by the cover 130 provided on the door 120, .

Referring to Table 1, it can be seen that the embodiment has a shorter time to install or disassemble the cover than the conventional example. That is, the opening of the container 50 can be quickly opened and closed by the cover 130 provided on the door 120 as compared with the case where the cover is installed or dismantled by using the overhead crane, The time required for opening and closing the door was shortened.

Further, in the conventional example, it takes a long time to install the nog cover, so that it can be confirmed that the refractory temperature before and after the nog cover is lowered by 493 deg. On the other hand, in the embodiment, since the opening portion 55 of the container 50 is quickly cut off by the cover 130, the temperature of the refractory before and after the cover is lowered by only 340 占 폚. That is, since the amount of heat released from the inner space of the container 50 is smaller in the embodiment than in the conventional example, the temperature variation width of the refractory is reduced.

As described above, in the embodiment of the present invention, the opening portion 55 of the container 50 can be blocked by the cover 130 before the heat is released to the opening portion of the container 50 and the refractory material is suddenly cooled. Therefore, it is possible to suppress or prevent the lifetime of the refractory material from deteriorating due to a rapid temperature change. Thus, the service life of the equipment can be improved and the maintenance of the equipment can be facilitated.

Although the present invention has been described in detail with reference to the specific embodiments thereof, it will be apparent to those skilled in the art that various modifications and variations can be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited by the described embodiments, but should be defined by the appended claims, as well as the appended claims.

50: container 55: opening
100: door device 120: door
130: Cover 131: Actuator
132: support plate 133: refractory member
134: protrusion 135: case

Claims (15)

A door device capable of opening and closing an opening of a container,
A door spaced from the container and capable of opening and closing at least a portion of the space in which the container is located; And
And a cover provided on the door so as to open and close the opening of the container. The method according to claim 1,
Wherein the door includes a plurality of bodies movably installed,
Wherein the cover is installed on at least one of the plurality of bodies. The method of claim 2,
Wherein the cover comprises a plurality of bodies mounted on each body and movable with each body and detachably connected to each other. The method of claim 3,
The body,
A driver supported on the body;
A support plate having one surface connected to the driver so as to move back and forth toward the opening of the container; And
And a refractory member provided on the other surface of the support plate so as to be in contact with the opening of the container. The method of claim 4,
Wherein the body further comprises a plurality of protrusions provided on the other surface of the support plate to fix the refractory member. The method of claim 3,
Wherein at least one of a protruding portion and an inserting portion is formed on the body,
Wherein a projection of another body can be fitted to an insertion portion of a body. The method of claim 3,
Wherein the size of the area of the portion of the bodies connected to each other facing the container is equal to or larger than the size of the opening area of the container. The method according to any one of claims 4 to 7,
Wherein at least a part of the cover is installed so as to be adjustable in inclination. The method of claim 8,
Wherein the cover further comprises a support bar having one end connected to the cover and the other end rotatably connected to the actuator. The method according to any one of claims 1 to 7,
Wherein the door has an inclined surface at least in part,
Wherein the cover is supported on an inclined surface of the door in a downward inclined direction toward the container. A method for opening and closing an opening of a container,
A door provided with a cover;
Closing at least a part of the space in which the container is located by moving the door; And
And moving the cover in a direction intersecting the moving direction of the door to bring the cover into close contact with the opening of the container. The method of claim 11,
The process of moving the door includes:
And moving the cover installed in the door together in the moving direction of the door. The method of claim 12,
The door includes a plurality of bodies movably installed, and the cover includes a plurality of bodies that are installed on each body, moveable together with the bodies, and detachably connected to each other,
Wherein the step of moving the cover installed in the door together with the moving direction of the door includes the step of coupling the plurality of bodies. The method of claim 11,
Before moving the cover in a direction intersecting the moving direction of the door,
And aligning the inclined angle of the cover with the opening of the container. The method according to any one of claims 11 to 14,
Wherein the container includes a converter, and the space in which the container is located includes the inner space of the clean house.

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