KR101921936B1 - Door Apparatus, and Mounting and Unmounting Method thereof - Google Patents

Abstract

The present invention relates to a door device for opening and closing an opening part of a facility for processing a material to be treated at a temperature higher than an external temperature. To this end, the door device comprises: a body formed to cover the opening; a refractory disposed on one side of the body; and a regulator installed on the body for regulating the width of the refractory. The object attached to the door device can be easily removed, and the door device can be stably detached from the opening of the facility.

Description

[0001] The present invention relates to a door device and a mounting and demounting method thereof,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a door device and a detaching method thereof, and more particularly, to a door device which can be easily removed and can be stably detached from an opening of a facility, and a detaching method thereof.

Generally, a coke oven is composed of a combustion chamber for generating heat and a carbonization chamber for charging coal therein. At this time, the coke making process can be carried out in the following order. First, both open sides of the carbonization chamber are blocked by a door, and coal is charged into the carbonization chamber. The coal in the carbonization chamber is dried using the heat generated in the combustion chamber. Then, the door is separated from the carbonization chamber, and the coke produced in the carbonization chamber is extruded outside.

At this time, the temperature inside the carbonization chamber can be raised to about 1300 ° C in order to carry the coal. The inside of the carbonaceous chamber is built with refractories to withstand the heat of coal. Further, since the temperature of the carbonization chamber can be transmitted to the door side, the inside portion in contact with the coke of the door is formed of refractory bricks. The outside of the door can be made of steel castings.

However, if coal is loaded into the carbonization chamber while the door is mounted on the carbonization chamber, coal may partially flow into the door. When the coal introduced into the door is dry, tar and carbon can be attached to the door. Therefore, there is a problem that the door is not normally separated from the carbonization chamber.

Conventionally, when the door is not separated from the carbonization chamber, the operator directly intervenes in the unmanned moving vehicle to separate the door. Therefore, there is a problem that a lot of manpower and time are wasted in the operation of separating the door. In addition, there is a problem that the refractory brick of the door is easily damaged in the process of detaching the door, and the life of the door is lowered.

KR 10-1189519 B

The present invention provides a door device in which an attachment can be easily removed, and a detachment method thereof.

The present invention provides a door device that can be stably installed and removed in an opening of a facility, and a detaching method thereof.

The present invention provides a door device whose lifetime can be prolonged and a method for attaching and detaching the same.

The present invention relates to a door device for opening and closing an opening of a facility for processing a material to be treated at a temperature higher than an external temperature, the door device comprising: a body formed to cover the opening; A refractory disposed on one side of the body; And a regulator installed on the body to adjust the length in the width direction of the refractory.

The refractory includes a plurality of refractory members, and the regulator is connected to the refractory member to move the plurality of refractory members in different directions.

The refractory includes: a first refractory member; And a second refractory member at least a part of which can be releasably fitted to the first refractory member in the width direction.

Wherein the first refractory member is provided with a first groove through which at least a part of the second refractory member can be inserted in a surface of the first refractory member which faces the second refractory member, And a second groove is provided on the side surface of the housing, on which at least a part of the adjuster can be housed.

The first refractory member and the second refractory member may include a plurality of blocks formed in a height direction; And a connection member connected to the plurality of blocks through a height direction.

The regulator includes: a support member having one side penetrating at least a part of the first refractory member and the second refractory member and the other side connected to the body; A first adjusting member having one end connected to the first refractory member and the other end connected to the support member so as to move the first refractory member in the width direction; And a second adjusting member having one end connected to the second refractory member and the other end connected to the supporting member so as to move the second refractory member in the width direction.

Wherein the first adjusting member and the second adjusting member comprise: a housing having an inner space; A movable body movably installed in an inner space of the housing in a width direction; And

And a rod, one end of which is connected to the moving body, and the other end of which is connected to the refractory member.

Wherein the support member has an inner space communicating with an inner space of the housing,

And a pressure supply member detachably connected to the support member so as to apply a pressure capable of moving the moving body to the inner space of the housing.

And a through hole is formed in the first refractory member and the second refractory member so as to extend in the width direction and through which the support member can pass.

The body includes: a frame; And a roller positioned between the frame and the refractory member.

The present invention relates to a door detachment method for opening and closing an opening of a facility for treating an object to be treated at a temperature higher than an external temperature, comprising a body and a door A process of preparing a device; A step of bringing the door device into close contact with the opening; And adjusting the length of the refractory in the width direction.

Wherein the refractory includes a first refractory member and a second refractory member at least a portion of which can be releasably fitted to the first refractory member,

The step of adjusting the length of the refractory may include moving at least one of the first refractory and the second refractory to increase the length of the refractory in the width direction.

The process of increasing the length of the refractory in the width direction includes a step of hitting and removing the deposit adhering to the opening.

And reducing the length of the refractory in the width direction of the body after the object to be treated is treated in the facility with the door device mounted on the opening.

The step of reducing the length of the refractory in the width direction includes a step of removing deposits adhered to the refractory while the object to be processed is processed.

And reducing the length of the refractory and then separating the door device from the opening.

The installation includes a coke oven.

According to the embodiments of the present invention, it is possible to easily remove the attachment from the door device even if the attachment is attached to the door device mounted to the opening of the device. Thus, while the door device is forcibly separated from the opening, it is possible to suppress or prevent damage to the door device or the equipment. Therefore, the service life of the door device or equipment can be prolonged.

Further, the attachment attached to the door device can be easily removed, so that the door device can be stably separated from the opening. Accordingly, it is possible to prevent an accident that the operation of opening and closing the opening of the facility is delayed by the deposit, or that the door apparatus is not separated from the opening by the deposit.

1 shows a coke oven according to an embodiment of the invention.
2 is a perspective view showing a door apparatus according to an embodiment of the present invention;
3 is a view showing a connection structure of refractory members according to an embodiment of the present invention.
4 is a view showing a coupling structure of a door device according to an embodiment of the present invention;
5 illustrates a structure of a regulator according to an embodiment of the present invention.
6 is a view showing a mounting structure of a door apparatus according to an embodiment of the present invention;
7 illustrates a structure for removing an attachment attached to a door device according to an embodiment of the present invention;
8 is a flowchart illustrating a method for attaching and detaching a door device according to an embodiment of the present invention.

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.

1 is a view showing a coke oven according to an embodiment of the present invention.

Referring to FIG. 1, a door device 100 according to an embodiment of the present invention is a door device that opens and closes an opening of a facility for processing an object to be processed at a temperature higher than an external temperature. At this time, the equipment may be the coke oven 50.

First, a process for producing coke in the coke oven 50 will be described. The charging car 52 loaded with the coking coal moves to the upper side of the carbonization chamber 51 and the coking chamber 51 is charged into the carbonization chamber 51 through the inlet port provided at the upper portion of the carbonization chamber 51. At this time, the door device 100 is mounted on both sides of the carbonization chamber 51. When the coke is charged, the coke in the carbonization chamber 51 is carbonized at a high temperature of 1000 to 3000 degrees Celsius using heat generated in the combustion chamber. The door device 100 mounted on both sides of the carbonization chamber 51 is detached and the coke in the carbonization chamber 51 is taken out.

The withdrawal of the coke is carried out by the extruder 53. The extruding rod of the extruder 53 is introduced into the carbonization chamber 51 through the opening in one side of the carbonization chamber 51 to push out the coke. The coke pushed out by the extruder 53 is drawn out of the carbonization chamber 51 through the opening on the other side of the carbonization chamber 51 and loaded on the bucket 54 and transported to the next processing site by the train.

When the door device 100 is installed in the carburizing chamber 51 and the coking chamber 51 is filled with the coking material, part of the raw carburden may be introduced into the door device 100. When the coke introduced into the door device 100 is dry, tar and carbon can be attached to the door device 100. Therefore, a problem may occur that the door device 100 is not normally separated from the carbonization chamber 51. Therefore, the door device 100 according to the embodiment of the present invention can be easily removed, and the door device 100 can be stably detached from the opening of the carbonization chamber 51.

FIG. 2 is a perspective view showing a door device according to an embodiment of the present invention, FIG. 3 is a view showing a connection structure of refractory members according to an embodiment of the present invention, FIG. 4 is a perspective view of a door device according to an embodiment of the present invention, Fig. Hereinafter, a door device according to an embodiment of the present invention will be described. At this time, the Z direction may be the height direction (or the vertical direction), the X direction may be the width direction (or the left and right direction), and the Y direction may be the thickness direction (or the back and forth direction).

2 to 4, the door device 100 includes a body 110, a refractory 120, and a regulator 130. At this time, the door device 100 can open and close the opening formed in the carbonization chamber of the coke oven.

The body 110 is formed so as to cover the opening of the carbonization chamber. Thus, the body 110 can open and close the opening of the carbonization chamber. The body 110 includes a frame 111 and a roller 113. The body 110 may further include a power member (not shown).

The frame 111 may be formed along the shape of the opening of the carbonization chamber. For example, it may be formed in the form of a rectangular plate along the shape of the opening, and the frame 111 may be formed extending vertically along the extending direction of the opening. The area of the frame 111 may be equal to or larger than the area of the opening. Thus, if the frame 111 covers the opening, the opening can be blocked.

A spring box 117 and a latching bar 115 may be installed on one side of the frame 111. The frame 111 can be locked or unlocked in the opening by the latching bar 115. However, the structure and the shape of the frame 111 are not limited thereto and may vary.

The roller 113 may be positioned between the frame 111 and the refractory member provided in the refractory 120. That is, a plurality of rollers 113 may be provided on the other surface of the frame 111 (or the surface facing the refractory 120). The plurality of rollers 113 may be arranged in a line spaced apart from each other in the width direction of the frame 111. The roller 113 may extend vertically and contact the refractory 120 provided in the refractory 120 while rotating in the width direction of the frame 111.

For example, a groove may be formed on the other surface of the frame 111 to allow the roller 113 to be rotatably inserted therein, and at least a part of the roller 113 may be exposed to the outside of the groove to contact the refractory . Thus, when the refractory member moves, the refractory member can be easily moved while the roller 113 in contact with the refractory member rotates. However, the structure and shape of the roller 113 are not limited to this, and may vary.

The power member (not shown) serves to provide a rotational force for rotating at least one of the plurality of rollers 113. The power member may be a motor and may be connected to at least one of the plurality of rollers 113.

For example, a pair of power members may be provided, one for providing a rotational force to the rollers 113 in contact with the first refractory member 121, and the other for providing a rotational force to the rollers 113 in contact with the second refractory member 122 (Not shown). The pair of power members can generate rotational force in different directions and the first refractory member 121 and the second refractory member 122 can move in different directions. However, the manner in which the power member provides the rotational force and the number thereof are not limited thereto and may vary.

The refractory 120 is disposed on one side of the body 110. And is made of a material that can withstand the heat inside the carbonization chamber. The refractory 120 can suppress or block the heat inside the carbonization chamber from being released to the outside and protect the body 110 from heat inside the carbonization chamber. The refractory 120 can be adjusted in width. That is, the length of the refractory 120 in the width direction can be adjusted. At this time, since the refractory 120 and the body 110 are arranged in a line along the thickness direction, the distance between the refractory 120 and the body 110 does not change even when the width of the refractory 120 is changed.

Further, the refractory 120 may include a plurality of refractory members. The plurality of refractory members can move in different directions, and the width of the refractory 120 can be adjusted by movement of the refractory members. For example, the refractory 120 may include a first refractory member 121 and a second refractory member 122. The first refractory member 121 and the second refractory member 122 are provided so as to be movable in a direction (width direction) intersecting with the direction (thickness direction) in which the door apparatus 100 is brought into close contact with the opening.

The first refractory member 121 may form one refractory 120 together with the second refractory member 122. The first refractory member 121 may be installed to be movable in the width direction of the body 110. For example, the surface of the first refractory member 121 facing the body 110 can contact the roller 113 and can be easily moved by the roller 113. [ The first refractory member 121 may include a first block 121a, a first connector 121b, and a first fixing cap 121c.

A plurality of first blocks 121a may be provided and may be constructed in a height direction. The first block 121a may be formed as a castable. The first blocks 121a can be constructed like a brick, and only the damaged part can be separated and replaced. At least a portion of the first block 121a may be formed in a planar shape in a 'C' shape. However, the structure and the shape of the first block 121a are not limited thereto and may vary.

The first connector 121b serves to connect the plurality of first blocks 121a. The first connector 121b may be formed in a rod shape extending in the height direction and may be connected by penetrating the plurality of first blocks 121a in the height direction. Accordingly, the first connector 121b can combine the first blocks 121a into one. For example, the first block 121a may have a first connection hole 121e, and the first connection member 121b may penetrate the first connection hole 121e. Accordingly, the first blocks 121a can be maintained in a state where the first blocks 121a are coupled by the first link members 121b, and even if any one of the plurality of first blocks 121a is moved, the entire first blocks 121a move together .

In addition, if the first connector 121b is removed from the first blocks 121a, the first blocks 121a can be separated from each other. Accordingly, if any one of the first blocks 121a is damaged, the first blocks 121a can be separated and the damaged part can be replaced and repaired.

The first fixing cap 121c prevents the first connector 121b from being separated from the first blocks 121a. Two first fixed caps 121c may be provided, one detachably connected to the upper end of the first connector 121b and the other detachably connected to the lower end of the first connector 121b . The first fixing cap 121c may have a larger diameter than the first connection hole 121e formed in the first block 121a. The first fixing cap 121c may be detachably fixed to the first block 121a by a bolt.

When the first fixing cap 121c is connected to the first connection body 121b and the first block 121a, the first connection body 121b is prevented from escaping from the first connection hole 121e, The connecting body 121b can stably combine the first blocks 121a. When the first fixing cap 121c is separated from the first connection body 121b, the first connection body 121b can be removed from the first connection hole 121e and the first blocks 121a can be separated from each other .

At this time, a first groove 121f through which at least a part of the second refractory member 122 can be inserted may be provided on a surface of the first refractory member 121 facing the second refractory member 122. For example, at least a part of the first refractory member 121 may be formed in a 'C' shape and extend in a vertical direction. That is, the first refractory member 121 may be formed with a first groove 121f that is waved in the width direction on a surface facing the second refractory member 122.

Therefore, the first groove 121f may be formed at the center of the first refractory member 121. [ A part of the second refractory member 122 may be inserted into the first groove 121f to move in the width direction of the body 110. [ If the second refractory member 122 moves relative to the first refractory member 121 and the portion inserted into the first groove 121f increases, the width of the refractory 120 decreases and the second refractory member The width of the refractory 120 may increase as the portion of the first groove 121f exposed to the outside of the first groove 121f increases. However, the structure and shape of the first refractory member 121 are not limited to the above, and may vary.

The second refractory member 122 may be removably fitted to the first refractory member 121 at least partially in the width direction of the body 110. The second refractory member 122 may be installed to be movable in the width direction of the body 110. If the first refractory member 121 and the second refractory member 122 move in directions opposite to each other, the length of the refractory 120 may be reduced in the width direction of the body 110, 121 and the second refractory member 122 move in directions opposite to each other, the length of the refractory 120 in the width direction of the body 110 may increase. The second refractory member 122 may include a second block 122a, a second connector 122b, and a second fixed cap 122c.

A plurality of second blocks 122a may be provided and may be constructed in the height direction. The second block 122a may be formed as a castable. The second blocks 122a can be constructed like a brick, and only the damaged part can be separated and replaced. The second block 122a may be formed in a 'C' shape at least partially on a plane. However, the structure and shape of the second block 122a are not limited thereto and may vary.

The second connector 122b serves to connect the plurality of second blocks 122a. The second connector 122b may be formed in a rod shape extending in the height direction and may be connected through the plurality of second blocks 122a in the height direction. Accordingly, the second connector 122b can couple the second blocks 122a into one. For example, a connection hole may be formed in the second blocks 122a, and a second connection member 122b may penetrate the connection holes. Accordingly, the second blocks 122a can be maintained in a state in which the second blocks 122a are coupled by the second link member 122b, and even if any one of the plurality of second blocks 122a is moved, the entire second blocks 122a move together .

In addition, if the second link member 122b is removed from the second blocks 122a, the second blocks 122a can be separated from each other. Accordingly, if any one of the second blocks 122a is damaged, the second blocks 122a can be separated and the damaged part can be replaced and repaired.

The second fixing cap 122c serves to prevent the second connector 122b from being separated from the second blocks 122a. Two second fixed caps 122c may be provided, one detachably connected to the upper end of the second connector 122b and the other detachably connected to the lower end of the second connector 122b . The second fixing cap 122c may be formed to have a larger diameter than the second connection hole 122e formed in the second block 122a. And the second fixed cap 122c may be detachably fixed to the second block 122a by a bolt.

When the second fixing cap 122c is connected to the second connecting body 122b and the second block 122a, the second connecting body 122b is prevented from escaping from the second connecting hole 122e, The connector 122b can stably couple the second blocks 122a. When the second fixing cap 122c is separated from the second connection body 122b, the second connection body 122b can be removed from the second connection hole 122e and the second blocks 122a can be separated from each other .

At this time, the second refractory member 122 may be provided with a second groove 122f in which at least a part of the regulator 130 can be housed, on a surface facing the first refractory member 121. [ For example, at least a part of the second refractory member 122 may be formed in a 'C' shape and extend in the vertical direction. And a second groove 122f may be formed at the center of the second refractory member 122. [ That is, the second groove 122f may be formed by being inserted into the first groove 121f in the second refractory member 122 and being cut in the width direction on the surface facing the first refractory member 121. [

The second refractory member 122 may include an insertion portion that can be inserted into the first refractory member 121 and a protruding portion that protrudes toward the body 110 side in the insertion portion. The insertion portion may be formed in a 'C' shape, and a portion of the regulator 130 may be positioned in the second groove 122f. A part of the regulator 130 is connected to the second refractory member 122 and the other part is connected to the first refractory member 121 through a portion opened by the second groove 122f in the second refractory member 122 ). Accordingly, the regulator 130 can move the first refractory member 121 and the second refractory member 122 in the second groove 122f.

The projecting portion may be connected to a portion of the insertion portion exposed to the outside of the first groove 121f. The protruding portion protrudes toward the body 110 and can contact the roller 113 provided on the body 110. Therefore, when the second refractory member 122 moves, the second refractory member 122 can be easily moved while the protruding portion is stably moved by the roller 113. [ However, the structure and the shape of the second refractory member 122 are not limited to this and may vary.

5 is a view showing the structure of a regulator according to an embodiment of the present invention. Hereinafter, a controller according to an embodiment of the present invention will be described.

4 and 5, the regulator 130 is installed in the body 110 to adjust the length of the refractory 120 in the width direction. The regulator 130 may move each of the plurality of refractory members in different directions. One side of the regulator 130 may be connected to the refractory 120, and the other side thereof may be installed on the body 110. The adjuster 130 includes a support member 131, a first adjustable member 132, and a second adjustable member 133. The regulator 130 may further include a pressure supply member 135.

The support member 131 may be formed in a pipe shape. The support member 131 can extend in the thickness direction of the body 110 and has one side penetrating at least a part of the first refractory member 121 and the second refractory member 122 in the thickness direction, 110). An empty space may be formed in the support member 131. Accordingly, hydraulic pressure or air pressure can be transmitted to the inside of the support member 131.

The other end of the support member 131 may protrude outwardly of the latching bar 115 through the body 110. Accordingly, the pressure supplying member 135 can be connected to or separated from the protruding end of the supporting member 131. However, the structure and shape of the support member 131 are not limited to this and may vary.

At this time, the first refractory member 121 and the second refractory member 122 may be provided with through-holes 123 through which the support member 131 can pass. One end of the support member 131 may be positioned in the second groove 122f formed in the second refractory member 122 through the through hole 123. [ The through-hole 123 may extend in the width direction of the body 110. Therefore, when the first refractory member 121 and the second refractory member 122 move, it is possible to prevent the first refractory member 121 and the second refractory member 122 from being hung on the support member 131. Accordingly, the first and second refractory members 121 and 122 can move in the width direction of the body 110 within the length of the through hole 123.

The first regulating member 132 extends in the width direction of the body 110 and is connected to the first refractory member 121 at one end so as to move the first refractory member 121 in the width direction, 131). For example, the first adjustment member 132 may be a cylinder. At least a portion of the first adjustment member 132 may be located in the second groove 122f. The first regulating member 132 may include a housing 132c, a moving body 132d, an elastic body 132e, a rod 132a, and a plate 132b.

The housing 132c has an inner space and can be connected to the support member 131. [ The inside of the housing 132c can communicate with the inside of the support member 131. [ A hole through which the rod 132a can pass can be formed at one side of the housing 132c and a jaw for engaging with the protrusion formed at the moving body 132d can be formed therein.

The moving body 132d is installed so as to be movable in the width direction inside the housing 132c. Projections may be formed on the left end and the right end of the housing 132c, respectively. The jaws of the housing 132c may be positioned between the projections. When the moving body 132d moves to the left, the protrusion of the right end is caught by the jaw and movement is limited. When the moving body 132d moves to the right, the protrusion of the left end is caught by the jaw, Thus, the moving body 132d can move within a limited distance.

The elastic body 132e is installed in the housing 132c. The elastic member 132e can be a spring and can be stretched and contracted. The elastic body 132e is positioned between the moving body 132d and the inner wall of the housing 132c. In detail, the elastic body 132e can be positioned between the hole formed in the housing 132c and the right end of the moving body 132d. Thus, the spring 132e can move the moving body 132d by applying an elastic force to the moving body 132d.

For example, when a pressure for moving the moving body 132d to the inside of the housing 132c is applied, the moving body 132d can move to the right while the elastic body 132e is pushed by the moving body 132d and compressed. When the pressure for moving the moving body 132d is weakened, the elastic body 132e is stretched and the moving body 132d can be pushed to the left.

One end of the rod 132a penetrates through the hole of the housing 132c and is connected to the moving body 132d and the other end of the rod 132a penetrates through the first block 121a and is coupled to the first connector 121b. For example, the other end of the rod 132a may be formed in the form of a bolt, and a hole through which the bolt can be fastened may be formed in the first link member 121b. Thus, the other end of the rod 132a may pass through the first block 121a and be coupled to the hole formed in the first linking member 121b. That is, the rod 132a may be rotated and coupled to the first link member 121b. Accordingly, when the moving body 132d moves, the first refractory member 121 can be moved while the rod 132a moves.

In addition, the rod 132a may include a main body, a part of which is housed in the housing 132c, and a plurality of bars connected to the main body. The bar may be formed smaller in diameter than the main body. Accordingly, the rod 132a and the first link member 121b can be stably coupled while reducing the size of the region through which the rod 132a passes through the first block 121a.

The plate 132b may be provided on the rod 132a and may be in contact with or connected to the first block 121a. The plate 132b can be moved back and forth with the rod 132a. The first block 121a and the first link 121b of the first refractory member 121 can be moved while being stably supported by the rod 132a and the plate 132b. However, the structure of the first regulating member 132 is not limited to this and may vary.

The second adjusting member 133 extends in the width direction of the body 110 and is connected to the second refractory member 122 at one end so as to move the second refractory member 122 in the width direction, 131). For example, the second adjusting member 133 may be a cylinder. At least a portion of the second refractory member 122 may be located in the second groove 122f. The second adjustable member 133 may have the same structure as the first adjustable member 132 and may be disposed symmetrically with the first adjustable member 132 with respect to the planar support member 131.

The direction in which the second regulating member 133 moves the second refractory member 122 may be opposite to the direction in which the first regulating member 132 moves the second refractory member 122. [ Therefore, the width of the refractory 120 can be increased or decreased. The second adjusting member 133 may be connected to the second block 122a and the second connecting member of the second refractory member 122 unlike the first adjusting member 132. [

The pressure supply member 135 serves to provide a pressure capable of moving the moving body 132d to the inner space of the housing 132c. The pressure supply member 135 may be a line for supplying pressure. Accordingly, the first refractory member 121 and the second refractory member 122 can move. For example, the pressure supply member 135 may apply hydraulic pressure or pneumatic pressure to the inside of the housing 132c through the support member 131. [ Accordingly, the first refractory member 121 and the second refractory member 122 can move because hydraulic pressure or pneumatic pressure moves the moving body 132d.

Further, the pressure supply member 135 may be detachably connected to the other end of the support member 131. The pressure supply member 135 can be connected to the support member 131 only when the first refractory member 121 and the second refractory member 122 are moved and the door device 100 can be opened / The pressure supplying member 135 may be separated from the supporting member 131 and may not interfere with the movement of the door device 100. [ However, the method of controlling the operation of the first adjusting member 132 and the second adjusting member 133 is not limited to this and may be various.

At this time, one controller 130 may be provided to move the entire first and second refractory members 121 and 122, and a plurality of the refractory members 121 and the second refractory members 122 122 may be pushed or pulled at a plurality of locations. When a plurality of regulators 130 are provided, the lines supplied to the regulator 130 can be connected to one another, and the pressure supply member 135 can control the operation of the plurality of regulators 130 by providing the pressure to the one line. . However, the number or connection structure of the regulator 130 is not limited to this, and may vary.

Thus, even if the attachment is attached to the door device 100 mounted to the opening of the carbonization chamber of the coke oven, the attachment can be easily removed from the door device 100. Thus, while the door device 100 is forcibly separated from the opening, damage to the door device 100 and the coke oven can be suppressed or prevented. Therefore, the service life of the door device 100 or the coke oven can be extended.

Further, the attachment attached to the door apparatus 100 can be easily removed, so that the door apparatus 100 can be stably separated from the opening. Accordingly, it is possible to prevent an accident that the operation of opening and closing the opening of the carbonization chamber of the coke oven is delayed by the deposit, or that the door device 100 is not separated from the opening by the deposit.

FIG. 6 is a view showing a mounting structure of a door device according to an embodiment of the present invention, FIG. 7 is a view showing a structure for removing an attachment attached to a door device according to an embodiment of the present invention, Fig. 7 is a flowchart illustrating a method for attaching and detaching a door device according to an embodiment of the present invention. Hereinafter, a method for attaching and detaching a door device according to an embodiment of the present invention will be described.

A method for attaching and detaching a door device according to an embodiment of the present invention is a method for attaching and detaching a door device that opens and closes an opening of a facility for processing an object to be processed at a temperature higher than an external temperature. At this time, the equipment may be a coke oven.

Referring to FIGS. 2 to 7, a door device having a body and a refractory whose length can be adjusted in a width direction at one side of the body may be provided (S110). The refractory 120 may include a first refractory member 121 and a second refractory member 122 at least a portion of which may be releasably fit with the first refractory member 121. [

The first refractory member 121 and the second refractory member 122 can move in the width direction of the body 110. The length of the refractory 120 can be reduced in the width direction of the body 110 when the first refractory member 121 and the second refractory member 122 are moved in directions opposite to each other, 121 and the second refractory member 122 move in directions opposite to each other, the length of the refractory 120 in the width direction of the body 110 may increase.

Then, the door device can be brought into close contact with the opening (S120). That is, the body 110 of the door device 100 can be brought into contact with the carbonization chamber frame 51a by advancing the door device 100. [ Thus, the body 110 can cover and block the carbonation chamber opening, and at least a portion of the refractory can be located in the opening.

Meanwhile, the first and second refractory members 121 and 122 may be in a state in which they are moved in directions opposite to each other before the door device 100 is brought into close contact with the opening. That is, the width of the refractory 120 can be reduced to the maximum. Thus, the width of the refractory 120 can be smaller than the width of the opening. Therefore, collision between the refractory 120 and the carbonization chamber frame 51a can be prevented, and the door device 100 can be easily brought into close contact with the opening.

Then, the width direction length of the refractory can be adjusted (S130). For example, as shown in FIG. 6, the operation of the regulator 130 may be controlled to move at least one of the first refractory member 121 and the second refractory member 122. That is, at least any one of the first refractory member 121 and the second refractory member 122 may be moved in directions opposite to each other to increase the length of the refractory 120 in the width direction.

The width of the refractory 120 may increase to the width of the opening of the carbonization chamber. That is, the first refractory member 121 moves and is brought into close contact with one side of the carbonization chamber frame 51a, and the second refractory member 122 can move and be brought into close contact with the other side of the carbonization chamber frame 51a. Thus, at least a part of the gap between the refractory 120 and the opening can be blocked. Accordingly, the carbonization chamber opening is doubly blocked by the refractory 120 and the body 110, so that the inside of the carbonization chamber can be effectively sealed, and the gap between the refractory 120 and the carbonization chamber frame 51a can be effectively prevented Can be prevented.

At this time, as the width of the refractory 120 is adjusted, it is possible to strike the deposit attached to the carbonization chamber frame. Therefore, the deposit attached to the carbonization chamber frame 51a can be crushed or impacted by the refractory 120 and removed.

Then, the object to be treated can be treated with the equipment in a state in which the door device 100 is mounted on the opening. That is, the coke can be produced by charging the coke as the object to be treated into the carbonization chamber and carrying out the carbonization of the carbonitrided material while keeping the inside of the carbonization chamber closed. However, when the raw coke is dry, deposits such as tar and carbon can be attached to the door device 100. Therefore, a problem may occur that the door device 100 is not normally separated from the carbonization chamber 51. Therefore, after the attachment attached to the door apparatus 100 is removed, the door apparatus 100 can be separated from the opening of the carbonization chamber.

First, the width of the refractory 120 can be reduced as shown in FIG. For example, the operation of the regulator 130 may be controlled to move at least one of the first refractory member 121 and the second refractory member 122 in directions opposite to each other. Therefore, the length in the width direction of the refractory 120 can be reduced.

At this time, deposits generated while processing the object to be treated can be removed from the refractory 120. That is, the first refractory member 121 moves toward the second refractory member 122 and is spaced apart from the carbonization chamber frame 51a. When the second refractory member 122 moves toward the first refractory member 121, And can be separated from the frame 51a. Therefore, the deposit attached between the first refractory member 121 and the carbonization chamber frame 51a can be pulled and pulled by the movement of the first refractory member 121, And the carbonization chamber frame 51a can be pulled by the movement of the second refractory member 122 and pulled off and broken. Thus, the deposit can be removed from the refractory 120.

Then, in a state in which the length of the refractory 120 is reduced, the door device 100 can be moved to the outside of the carbonization chamber to separate the door from the door device 100. [ Thus, the width of the refractory 120 becomes smaller than the width of the opening, so that the refractory 120 can easily move outside the opening. Therefore, the opening of the carbonization chamber can be opened, and the coke inside the carbonization chamber can be drawn out to the outside.

The first refractory member 121 and the second refractory member 122 may be moved plural times in the width direction of the body 110 after the door apparatus 100 is separated from the carbonization chamber. That is, the first refractory member 121 and the second refractory member 122 may be moved a plurality of times in a direction opposite to each other and then moved in a direction opposite to each other. Thus, vibration generated in the refractory 120 can remove the deposit that has not been removed from the refractory 120.

Although the present invention has been described in detail with reference to the specific embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may 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: Coke oven 100: Door device
110: body 113: roller
120: refractory 121: first refractory member
122: second refractory member 130: regulator
132: first adjusting member 133: second adjusting member

Claims (17)

1. A door device for opening and closing an opening of a facility for processing an object to be processed at a temperature higher than an external temperature,
A body formed to cover the opening;
A refractory disposed on one side of the body; And
And a regulator installed on the body to adjust the length of the refractory in the width direction,
Wherein the refractory includes a plurality of refractory members,
Wherein the regulator is connected to the refractory member so as to move the plurality of refractory members in different directions. delete The method according to claim 1,
The refractory,
A first refractory member; And
And a second refractory member at least a part of which can be releasably fitted to the first refractory member in the width direction. The method of claim 3,
Wherein a first groove is formed in a surface of the first refractory member facing the second refractory member so that at least a part of the second refractory member can be inserted,
And a second groove on the surface of the second refractory member facing the first refractory member, the second groove being capable of accommodating at least a part of the regulator. The method of claim 3,
Wherein the first refractory member and the second refractory member,
A plurality of blocks constructed in a height direction; And
And a connecting body connected to the plurality of blocks through a height direction. The method according to any one of claims 3 to 5,
The regulator,
A support member having one side penetrating at least a part of the first refractory and the second refractory and the other side connected to the body;
A first adjusting member having one end connected to the first refractory member and the other end connected to the support member so as to move the first refractory member in the width direction; And
And a second adjusting member having one end connected to the second refractory member and the other end connected to the supporting member so as to move the second refractory member in the width direction. The method of claim 6,
Wherein the first adjusting member and the second adjusting member,
A housing having an inner space;
A movable body movably installed in an inner space of the housing in a width direction; And
And a rod having one end connected to the moving body and the other end connected to the refractory member. The method of claim 7,
Wherein the support member has an inner space communicating with an inner space of the housing,
Further comprising a pressure supply member detachably connected to the support member so as to apply a pressure to move the movable body to the inner space of the housing. The method of claim 6,
The first refractory member and the second refractory member,
And a through hole through which the support member can pass. The method according to any one of claims 3 to 5,
The body,
frame; And
And a roller positioned between the frame and the refractory member. A door detachment method for opening and closing an opening of a facility for processing an object to be treated at a temperature higher than an external temperature,
Providing a door device having a body and a refractory whose length can be adjusted in a width direction at one side of the body;
A step of bringing the door device into close contact with the opening; And
And adjusting a width direction length of the refractory. The method of claim 11,
Wherein the refractory includes a first refractory member and a second refractory member at least a portion of which can be releasably fitted to the first refractory member,
Wherein the step of adjusting the length of the refractory includes moving at least one of the first refractory member and the second refractory member to increase the length of the refractory in the width direction. The method of claim 12,
In the process of increasing the width direction length of the refractory,
And removing the attachment attached to the opening part by hitting the attachment part. The method of claim 12,
Treating the object to be treated with the equipment in a state where the door device is mounted on the opening,
And reducing the width of the refractory in the width direction of the body. 15. The method of claim 14,
The process of reducing the widthwise length of the refractory comprises:
And removing the deposit adhering to the refractory while processing the object to be treated. 16. The method of claim 15,
After reducing the length of the refractory,
And separating the door device from the opening. The method according to any one of claims 11 to 16,
Wherein the installation comprises a coke oven.

Images