KR101712830B1 - Object Processing Facilites and Recovery Method for Refractories of the same - Google Patents

Abstract

The present invention relates to a vacuum processing apparatus comprising: a chamber in which an internal space in which an object to be processed is accommodated is formed; And a refractory block including a refractory block that is movable toward the inner space in a region narrower than the other region of the chamber, so that the abraded refractory can be quickly recovered.

Description

FIELD OF THE INVENTION [0001] The present invention relates to an object treatment facility,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an object treatment facility and a refractory restoration method thereof, and more particularly, to a to-be-treated treatment facility capable of quickly recovering worn refractories and a refractory restoration method thereof.

Coke fire extinguishing systems used in coke plants in steel mills can be classified as wet and dry depending on how the cryogenic coke supplied from the coke oven is cooled. The method of cooling the red gypsum coke using Coke Dry Quenching (CDQ) is as follows.

First, the coke in the coke oven is placed in a bucket and the coke is charged into the pre-chamber through the top inlet of the CDQ body using a crane. Then, the inert gas introduced into the lower portion of the cooling chamber by the blowing force of the circulating fan moves to the pre-chamber provided at the upper portion by the upward flow, and performs heat exchange with the high-temperature coke (above 1000 캜). The coke can be cooled gradually to about 180 ° C when it is finally discharged.

The boiler water can be heated by using the heat generated during the dry digestion of the red gypsum coke. That is, the heat exchange tube of the boiler forming the movement path of the water passes through the inside of the chamber, so that the water moving through the heat exchange tube can be heated by the heat inside the chamber. Generally, the steam generated is converted to electric energy from a steam turbine generator.

At this time, a refractory is installed on the neck where the prechamber and the cooling chamber are connected. It prevents the heat exchange tube of the boiler from directly coming into contact with the coke coming down from the upper side and prevents the high temperature coke heat from being transmitted to the outside of the chamber .

However, if the refractory material on the neck region is over-abraded due to collision with the coke, the refractory will not protect the heat exchange tube and the heat exchange tube will be in direct contact with the coke. Therefore, the heat exchange tube can be broken or pierced, and a large facility accident can be caused.

KR 2012-0130587 A

The object of the present invention is to provide an object-treatment equipment capable of quickly recovering a worn-out refractory and a refractory restoring method thereof

The present invention provides an object treatment facility capable of facilitating maintenance of equipment and a refractory restoration method thereof.

The present invention relates to a vacuum processing apparatus comprising: a chamber in which an internal space in which an object to be processed is accommodated is formed; And a refractory block capable of moving toward the inner space in an area narrower than the other area of the chamber.

The chamber includes a first body having a smaller width toward the lower side and a second body connected to a lower portion of the first body and having a width larger than that of the lower portion of the first body, And is installed at a portion where the first body and the second body are connected.

The refractory recovery apparatus further includes a driver connected to the refractory block to move the refractory block.

The refractory recovery apparatus further includes a temperature meter for measuring the temperature of the refractory block.

The refractory recovery apparatus further includes a controller for controlling the operation of the driver in accordance with the temperature of the refractory block.

A heat insulating material is provided between the walls of the first body and the second body and the refractory block, and the heat insulating material is capable of sliding contact with the refractory block.

The refractory recovery apparatus further includes a sealing unit installed between the refractory block and the actuator to block the interior space and the exterior of the chamber.

A path through which gas is supplied to the sealing unit is formed and a path through which the gas is supplied is communicated with a space between the walls of the first body and the second body and the refractory block.

The sealing unit includes a sealing member that surrounds the periphery of the refractory and is capable of sliding contact with the heat insulating material.

The object to be treated includes a coke, and the chamber further includes a digestion chamber for extinguishing the coke, and further includes a heat exchange tube located below the refractory recovery device.

The present invention provides a method of manufacturing a semiconductor device, the method comprising: preparing a refractory block movable toward an inner space of a chamber to be processed; Measuring a degree of wear of the refractory block; And moving the refractory block as much as worn when the refractory block is worn; .

The step of providing the movable refractory block may include the step of providing the refractory block at a portion where the width of the chamber is narrowed.

The step of measuring the degree of wear of the refractory block may include: measuring a temperature of the refractory block; And determining whether the temperature of the measured fire block is equal to or greater than a predetermined set value; .

The step of moving the refractory block includes moving the refractory block when the measured temperature of the refractory block is equal to or higher than the preset value.

Further comprising the step of blocking the inner space of the chamber from the outside before measuring the degree of wear of the refractory block.

The process of interrupting the inner space of the chamber from the outside includes the step of supplying an inert gas between the wall of the chamber and the refractory block.

According to the embodiments of the present invention, it is possible to quickly recover even if the refractory provided in a predetermined area of the object to be treated has collided with the objects to be treated and is worn.

For example, refractories that protect the heat exchange tubes of coke dry fire extinguishing systems can be repaired if they wear out. Therefore, it is possible to suppress or prevent the direct contact of the heat exchange tube with the coke, thereby prolonging the life of the heat exchange tube and facilitating the maintenance of the facility.

In addition, the degree of wear of the refractory material can be monitored to determine the time for restoration or replacement of the refractory material. Therefore, it is possible to prevent the safety accident caused by the breakage of the refractory or the heat exchange tube, thereby securing the safety of the operator.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view showing an object to be treated according to an embodiment of the present invention. Fig.
2 is a view showing a structure of a refractory recovery apparatus according to an embodiment of the present invention;
3 is a view showing a refractory recovery apparatus according to another embodiment of the present invention.
4 is a view showing a refractory recovery method according to an embodiment of the present invention.
5 is a view showing the operation of the refractory recovery apparatus according to the 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.

Although embodiments of the present invention are illustratively described for a coke dry fire extinguishing facility, the scope of application is not so limited and may be used in a variety of installations having refractory materials and treating the material to be treated.

2 is a view showing a structure of a refractory recovery apparatus according to an embodiment of the present invention, and FIG. 3 is a sectional view of a refractory recovery apparatus according to another embodiment of the present invention. FIG. 4 is a view showing a refractory recovery method according to an embodiment of the present invention, and FIG. 5 is a view showing the operation of the refractory recovery apparatus according to an embodiment of the present invention.

Referring to FIG. 1, the object treatment apparatus 100 according to an embodiment of the present invention includes a chamber 110 in which an internal space capable of receiving an object to be processed is formed, And a refractory block (130) having a refractory block (131) movable toward the inner space in a narrow area. The object treatment facility 100 may further include a boiler 120 having a heat exchange tube 121 passing through an internal space of the chamber 110. In this case, the object to be treated is coke, the chamber 110 is a fire extinguishing chamber for extinguishing the coke, and the to-be-treated water treatment facility 100 may be a coke dry fire extinguishing facility.

The chamber 110 includes a first body 111 having a smaller width toward the lower side and a second body 111 connected to a lower portion of the first body 111 and having a width larger than a width of a lower portion of the first body 111 2 body 112. As shown in FIG. The first body 111 and the second body 112 may be integrally formed or separately manufactured and assembled. The inner walls of the first body 111 and the second body 112 may be made of refractory to withstand the high temperature of the coke.

The first body 111 is installed on the upper side of the second body 112. The upper and lower portions of the first body 111 are opened to form an inlet port 111a into which the coke can be charged and the lower portion communicates with the second body 112. Thus, the coke introduced into the first body 111 through the entry port 111a can be moved to the second body 112.

Also, the first body 111 is formed to have a narrower width toward the lower side. For example, the first body 111 may have a trapezoidal cross-sectional shape. Accordingly, the coke supplied from the first body 111 to the second body 112 can be accumulated from the center of the second body 112, and the coke is not accumulated to the upper edge of the second body 112, A space may be formed in an upper corner portion of the body 112. [ Therefore, the heat exchange tube 121 of the boiler 120 can be installed in the space where the second body 112 does not accumulate coke.

The second body 112 is connected to the lower portion of the first body 111. The upper portion of the second body 112 is formed to be wider than the lower portion of the first body 111. Even if the coke is supplied from the first body 111 to the second body 112, the coke is not accumulated in the upper edge of the second body 112, so that a space is formed in the upper corner of the second body 112 .

When the coke is charged into the chamber 110, the coke is sequentially stacked from the second body 112 to the first body 111. When the loading of the coke is completed, an inert gas is injected into the chamber 110 through a gas supply duct (not shown) connected to one side of the second body 112. The inert gas rises along the gap of the coke stacked in the second body 112 and moves toward the first body 111 side to cool the coke. Then, the cooled coke is discharged through the discharge port 112a provided in the lower portion of the second body 112. However, the structure of the chamber 110 and the shapes of the first body 111 and the second body 112 are not limited to these and may vary.

The boiler 120 is disposed outside the chamber 110. The boiler 120 includes a heat exchange tube 121 that forms a path for the passage of the cooling water. At least a portion of the heat exchange tube 121 passes through the interior of the chamber 110. The portion of the heat exchange tube 121 passing through the chamber 110 is located inside the second body 112. That is, the heat exchange tube 121 may be located at an upper corner portion of the second body 112 where the coke is not accumulated. Accordingly, the cooling water moving inside the heat exchange tube 121 can absorb heat energy from the high-temperature coke inside the second body 112 and change into steam. The steam thus generated can be used by switching from a steam turbine generator (not shown) to electric energy.

At this time, the portion where the first body 111 and the second body 112 are connected is a region where the inner diameter (horizontal direction) or the width of the chamber 110 is narrowed. Accordingly, the portion where the first body 111 and the second body 112 are connected is protruded toward the center of the chamber 110 as compared with other regions. Accordingly, the heat exchange tube 121 in which the connection portion of the first body 111 and the second body 112, that is, the protruded portion is disposed on the lower side, can be protected from the coke.

However, since the connecting portion between the first body 111 and the second body 112 protrudes, it can be easily worn by collision with the coke. Therefore, when the refractory of the connecting portion is excessively abraded due to the collision with the coke, the refractory does not cover the upper portion of the heat exchange tube 121 and the coke, which moves from the first body 111 to the second body 112, And the heat exchange tube may be broken or pierced by collision with the coke. Therefore, the refractory recovery apparatus 130 according to the embodiment of the present invention can restrain the refractory even if the refractory is worn out, thereby suppressing or preventing direct contact of the heat exchange tube 121 with the coke.

Referring to FIGS. 1 and 2, the refractory recovery apparatus 130 is installed in a region where the first body 111 and the second body 112 are connected to each other, or in a region where the width of the chamber 110 is narrow. That is, the refractory recovery apparatus 130 is provided with only a predetermined region in the chamber 110 to recover the refractory.

 The refractory recovery apparatus 130 includes a refractory block 131 having a predetermined area to cover the upper portion of the heat exchange tube 121 and movable toward the center of the chamber 110, A controller 132 connected to the fire block 131, a temperature meter 133 measuring the temperature of the fire block 131, a controller 134 controlling the operation of the driver 132 according to the temperature of the fire block, And a sealing unit 135 installed between the refractory block 131 and the driver 132 to block the inside space and the outside of the chamber 110. [

At this time, the heat exchange tube 121 may be positioned below the refractory recovery apparatus 130. Therefore, the refractory restoration device 130 can protect the heat exchange tube 121 inside the chamber 110.

The refractory block 131 has a predetermined area to cover the heat exchange tube 121 from above the heat exchange tube 121 and the front end portion may be introduced into the inner space of the chamber 110. For example, the refractory block 131 may be formed in the shape of a rectangular plate to protect the heat exchange tube 121 from the coke moving from the upper side to the lower side. The refractory block 131 may be provided as much as the number of portions penetrating the inside of the chamber 110 of the heat exchange tube 121 to protect the heat exchange tubes 121. At this time, the refractory block 131 can move forward from the rear, that is, toward the inside of the chamber 110.

A movement path is formed in a portion where the first body 111 and the second body 112 are connected to each other so that the refractory block 131 can move in the lateral direction toward the inner space of the chamber 110. The cross-sectional shape of the movement path is formed corresponding to the shape of the refractory block 131, and the cross-sectional area is formed to be equal to or larger than the cross-sectional area of the refractory block 131. Therefore, the refractory block 131 can be easily moved in the movement path. However, the structure, shape, and the number of the refractory block 131 are not limited to the above, and may vary.

At this time, a heat insulating material 140 may be provided between the walls of the first body 111 and the second body 112 and the refractory block 131. The heat insulating material 140 disposed between the lower part of the first body 111 and the upper part of the refractory block 131 is attached to the lower surface of the first body 111 and the upper part of the second body 112 and the upper part of the refractory block 131 131 may be attached to the upper surface of the second body 112. That is, the heat insulating material 140 may be formed to surround the refractory block 131. The heat generated in the chamber 110 flows into the space between the walls of the first body 111 and the second body 112 and the refractory block 131 so that the first body 111 or the second body 111 So that it can be prevented from being transmitted to the body 112.

The inner walls of the first body 111 and the second body 112 may be formed of a refractory material to withstand the high temperature inside the chamber 110. In other parts of the first body 111 and the second body 112, So that it is vulnerable to heat. The heat insulating material 140 is used to protect the first body 111 and the second body 112 from the heat flowing between the walls of the first body 111 and the second body 112 and the refractory block 131. [ .

Further, the heat insulating material 140 can make sliding contact with the refractory block 131. Therefore, when the refractory block 131 moves toward the inner space of the chamber 110, it is possible to reduce the friction with the heat insulating material 140, and the refractory block 131 can be easily moved. However, the structure and shape of the heat insulating material 140 are not limited to these, and may vary.

The driver 132 may be disposed outside the chamber 110 and may be connected to the refractory block 131 to move the refractory block 131. For example, the driver 132 may be a hydraulic cylinder, and one pair may be connected to both sides of the rear end of the refractory block 131 to move the refractory block 131 back and forth toward the inside of the chamber 110. By controlling the operation of the driver 132, the position of the refractory block 131 can be controlled. However, the method of moving the refractory block 131 of the driver 132, the installation structure, and the number of the refractory blocks 131 are not limited to this, and may vary.

The temperature measuring unit 133 is installed in the refractory block 131 to measure the temperature of the refractory block 131. For example, the temperature measuring device 133 may be installed at the rear end of the refractory block 131, and the degree of wear of the refractory block 131 may be confirmed based on the measured temperature value. That is, as the length from the front end portion to the rear end portion of the refractory block 131 is shortened due to abrasion, the amount of heat energy transmitted to the temperature measuring device 133 through the refractory block 131 becomes large. Accordingly, it can be seen that the degree of wear of the refractory block 131 increases as the temperature measured by the temperature meter 133 increases.

If the degree of wear of the refractory block 131 is calculated in correspondence with the temperature value measured by the temperature meter 133, the temperature of the refractory block 131 is measured using the driver 132 according to the measured value of the temperature measurer 133 Can be calculated. That is, the refractory block 131 can move the refractory block 131 toward the inside of the chamber 110 by the worn length.

The controller 134 is connected to the temperature meter 133 and the driver 132 to control the operation of the driver 132 according to the temperature of the fire block 131. The controller 134 includes a transceiver 134a connected to the temperature meter 133, a determiner 134b for determining whether the measured temperature value is equal to or greater than a preset value, And a control unit 134c for controlling the operation of the driver 132 according to the control signal.

The transmission and reception unit 134a is connected to the temperature measuring unit 133 and transmits and receives temperature information of the refractory block 131. [ Thus, the transceiver 134a can collect temperature information of the refractory block 131 in real time.

The determination unit 134b is connected to the transmission / reception unit 134a and determines whether the temperature value of the refractory block 131 transmitted from the transmission / reception unit 134a is greater than a preset value. The set value may be plural. For example, when the length of the refractory block 131 in the longitudinal direction is 600 mm and the temperature of the refractory block 131 measured by the temperature measuring device 133 is 700 degrees centigrade and the refractory block 131 is worn by 100 mm The temperature detected by the temperature measuring device 133 can rise by 100 degrees centigrade. At this time, a plurality of set values may be set. For example, three set values may be set. The first set value may be 800 degrees Celsius, the second set value 900 degrees Celsius, and the third set value 1000 degrees Celsius.

Therefore, if the temperature measured by the temperature measuring unit 133 is equal to or higher than the first set value but less than the second set value, it is determined that the front end portion of the refractory block 131 is worn less than 100 mm and less than 200 mm, It is judged that it should be moved to the center of the chamber 110 by 100 mm or more and less than 200 mm.

However, if one continues to wear the refractory block 131, it can be secondarily abraded by subsequent collisions with the coke. In this case, since the refractory block 131 is worn, the temperature value measured by the temperature measuring device 133 is always equal to or higher than the first set value. Accordingly, it is determined that the refractory block 131 should be moved by 100 mm for a while compared with the first set value, so that the refractory block 131 may excessively protrude into the chamber 110. Thus, after the firstly worn refractory material is moved, the temperature value measured by the temperature measuring device 133 can be compared with the second set value and not be compared with the first set value.

Then, if the measured value is equal to or greater than the second set value, it is determined that the refractory block 131 has been worn by a distance of 100 mm in the first worn state, and it is determined that the refractory block 131 should be moved by 100 mm. After the temperature of the refractory block 131 is determined to be equal to or higher than the second set value and the refractory block 131 is moved, the temperature value measured by the temperature measurer 133 is compared with the third set value without comparing with the second set value . Accordingly, it is possible to prevent the refractory block 131 from excessively protruding into the chamber 110, and to move the refractory block 131 only as much as it is worn.

In addition, when the measured temperature of the refractory block 131 is equal to or more than a final set value, the refractory block 131 can be replaced. That is, since the degree of wear of the refractory block 131 can not be determined after the final set value, the new refractory block 131 can be replaced without using the refractory block 131 as it is. However, the number of set values and numerical values that are actually set may be various and may be varied, and the replacement timing of the refractory block 131 is not limited to this, and may vary according to the judgment of the operator.

The control unit 134c is connected to the determination unit 134b and the driver 132. [ The control unit 134c may control the operation of the driver 132 to move the fire block 131 according to the determination of the determination unit 134b. For example, if the determination unit 134b measures the temperature of the refractory block 131 and determines that the refractory block 131 has been worn by 100 mm, the controller 134c controls the driver 132 to refract the refractory block 131, May be moved forward by a worn 100 mm or towards the center of the chamber 110. Therefore, even if the refractory block 131 is worn, the control section 134c can recover the same, so that the refractory block 131 can continue to protect the heat exchange tube 121 and the life of the heat exchange tube 121 can be extended.

The sealing unit 135 functions to block the inside space and the outside of the chamber 110. This prevents or prevents the dust or the like generated in the chamber 110 from flowing out of the chamber 110 through the gap between the walls of the first body 111 and the second body 112 and the refractory block 131 can do.

For example, as shown in Fig. 2, the sealing unit 135 may include a blocking plate 135b covering the rear side of the refractory block 131. As shown in Fig. The blocking plate 135b has a predetermined area and can seal the inside of the chamber 110. Accordingly, it is possible to prevent the harmful gas, dust, and the like in the chamber 110 from flowing out of the chamber 110 through the movement path of the refractory block 131.

The blocking plate 135b may be connected to the gas supply pipe 135a and the gas supplied from the gas supply pipe may be separated by a gap between the walls of the first body 111 and the second body 112 and the refractory block 131 A through hole may be formed in the blocking plate 135b. Thus, the path through which the gas is supplied can be communicated with the space between the walls of the first body 111 and the second body 112 and the refractory block 131.

The gas supply pipe 135a forms a path through which the inert gas moves, and may be formed in the shape of a square pipe. The gas supply pipe 135a may extend vertically and one side may be connected to the rear surface of the blocking plate 135b. The gas supply pipe 135a may be formed with a corresponding supply hole corresponding to the through hole formed in the shutoff plate 135b. When the inert gas is supplied to the gas supply pipe 135a, the inert gas moves from the upper side to the lower side, and the walls of the first body 111 and the second body 112 and the refractory block 131, As shown in Fig. The gas introduced into the gap can fill in the gap, so that the harmful gas or dust generated in the chamber 110 can suppress or prevent the inert gas from flowing into the gap. Accordingly, it is possible to prevent the liquid from flowing out of the chamber 110.

The gas supply pipe 135a may include a driver 132 and may be installed in front of the driver 132. At this time, the rod of the driver 132 may be connected to the refractory block 131 through the gas supply pipe 135a and the shutoff plate 135b. That is, the rod of the driver 132 may pass through a path through which the inert gas moves. Thus, an inert gas can be filled in the path through which the rod of the driver 132 moves. However, the installation structure, shape, and the number of the gas supply pipes 135a are not limited to these, and may vary.

The gas supply unit 138 is installed outside the chamber 110 and connected to the gas supply pipe 135a. Thus, the gas supplier 138 serves to supply an inert gas. For example, nitrogen may be used as the inert gas. When the inert gas is supplied to the gas supply pipe 135a, the space between the walls of the first body 111 and the second body 112 and the refractory block 131 may be filled with the inert gas. Accordingly, it is possible to suppress or prevent the harmful gas, dust, and the like in the chamber 110 to be introduced into the space from flowing out of the chamber 110 due to the inert gas.

Alternatively, the sealing unit 135 may have other embodiments. 3, the sealing unit 135 may have one or a plurality of sealing members 135c surrounding the shield plate 135b and the refractory block 131. [ The sealing member 135c may wrap around the rear end of the refractory block 131 to serve as an O-ring. Further, the sealing member 135c can make sliding contact with the surface of the heat insulating material 140 or the movement path. Accordingly, the sealing member 135c can move together with the refractory block 131 when the refractory block 131 moves while sealing the space between the heat insulating materials 140. [ At this time, the refractory block 131 is formed with a groove into which the sealing member 135c can be inserted, so that the sealing member 135c can be fixed to the refractory block 131.

The sealing member 135c may be exposed to the inside of the chamber 110 by the refractory block 131 moving toward the inside of the chamber 110 when the sealing member 135c is installed at the front end of the refractory block 131 have. Therefore, the sealing member 135c may collide with the coke and be damaged, and the rear end of the refractory block 131 may not be sealed. The sealing member 135c may be installed at the rear end of the refractory block 131 to seal the inside of the chamber 110 even if the front end of the refractory block 131 is worn. However, the structure, the installation position, and the number of the sealing members 135c are not limited to these, and may vary.

Alternatively, the sealing unit 135 may include both the blocking plate 135b, the gas supply pipe 135a, and the sealing member 135c. The inside of the chamber 110 is firstly blocked by the sealing member 135c and the blocking plate 135b is used to block the inside of the chamber 110 by using the inert gas supplied to the gas supply pipe 135a The inside of the chamber 110 can be blocked by the third order. Accordingly, it is possible to more effectively suppress or prevent the harmful gas or dust in the chamber 110 from flowing out of the chamber 110. However, the method of sealing the inside of the chamber 110 is not limited to this and may be various.

As described above, even if the refractory provided in the predetermined area of the object treatment facility 100 collides with the objects to be treated and is worn, it can be quickly recovered. That is, even if the front end of the refractory block 131 is worn, the refractory block 131 can be moved and restored. Therefore, even if the refractory block 131 is worn, the heat exchange tube can be protected, and the direct contact of the heat exchange tube 121 with the coke can be suppressed or prevented to prolong the life of the heat exchange tube 121, It can be facilitated.

Also, the degree of wear of the refractory block 131 may be monitored to determine the time for repairing or replacing the refractory block 131. Therefore, it is possible to prevent a safety accident caused by damage to the refractory block 131 or the heat exchange tube 121, thereby securing the safety of the operator.

Hereinafter, a refractory recovery method according to an embodiment of the present invention will be described.

A refractory restoration method according to an exemplary embodiment of the present invention includes the steps of providing a refractory block capable of moving toward an internal space of a chamber to be processed, measuring a degree of wear of the refractory block, And moving the refractory block as much as it is worn. This process will be described in more detail below with reference to FIG.

A refractory block 131 which can be moved toward the inside of the chamber 110 may be installed at a narrowed portion of the chamber 110. (S100) A portion where the width of the chamber 110 is narrowed is a chamber 110 So that it can be easily broken by collision with the object to be processed as compared with other parts. Accordingly, the worn portion can be quickly recovered by providing the movable block 131 in the region where the width or the inner diameter of the chamber 110 is narrowed.

Then, the inside of the chamber 110 must be blocked from the outside before the object to be processed is charged into the chamber 110 and the object to be processed is processed. That is, since the harmful gas or dust generated while the object to be treated is processed can flow out of the chamber 110 through the gap between the wall of the chamber 110 and the refractory block 131, It is necessary to seal the gap between the wall and the refractory block 131.

For example, an inert gas may be supplied between the wall of the chamber 110 and the refractory block 131. Accordingly, the space between the wall of the chamber 110 and the refractory block 131 is filled with the inert gas, and the space in which the harmful gas or dust can be introduced into the chamber 110 can be reduced or eliminated. Accordingly, it is possible to prevent or prevent the harmful gas, dust, and the like in the chamber 110 from flowing out of the chamber 110, thereby preventing air pollution and contamination of the workplace. The supply of the inert gas can be continuously performed while the treatment operation for the object to be treated is performed.

At this time, the narrowed portion of the chamber 110 protrudes toward the center of the chamber 110. Therefore, the heat exchange tube 121 having the protruded portion disposed on the lower side can be protected from the object to be processed moving in the chamber 110. However, when the refractory provided on the protruded portion is excessively worn out due to collision with the object to be treated, the refractory does not cover the heat exchange tube 121, so that the heat exchange tube 121 is broken or pierced .

Therefore, the degree of wear of the refractory block 131 is measured, and the refractory block 131 is moved as much as the refractory block 131 is worn to recover the worn portion. For example, the degree of wear of the refractory block 131 can be measured by measuring the temperature of the refractory block 131.

The temperature of the refractory block 131 that protects the heat exchange tube 121 can be measured using the temperature meter 133 to measure the degree of wear of the refractory block 131. S200 Next, It is possible to determine whether the temperature of the refractory block 131 is equal to or higher than a predetermined set value. (S300)

For example, when the length of the refractory block 131 in the longitudinal direction is 600 mm and the temperature of the refractory block 131 measured by the temperature measuring device 133 is 700 degrees centigrade and the refractory block 131 is worn by 100 mm Assuming that the temperature detected by the temperature meter 133 rises by 100 degrees Celsius, the set value can be set to 800 degrees Celsius. Therefore, if the measured temperature value of the refractory block 131 is equal to or greater than the predetermined value, it can be known that the front end portion of the refractory block 131 is worn by 100 mm or more.

Meanwhile, a plurality of set values may be set. For example, three set values may be set. The first set value may be 800 degrees Celsius, the second set value 900 degrees Celsius, and the third set value 1000 degrees Celsius. Therefore, if the temperature measured by the temperature measuring unit 133 is equal to or greater than the first set value but less than the second set value, it can be determined that the front end portion of the refractory block 131 is worn less than 100 mm and less than 200 mm.

However, if one continues to wear the refractory block 131, it can be secondarily abraded by subsequent collisions with the coke. In this case, since the refractory block 131 is worn, the temperature value measured by the temperature measuring device 133 is always equal to or higher than the first set value. Therefore, after determining that the refractory has been worn by a distance of 100 mm, the temperature measured by the temperature measuring unit 133 may be compared with the second set value and compared with the first set value.

Next, if the measured value is equal to or greater than the second set value, it can be determined that the refractory block 131 has been worn by 100 mm in the secondary state in the primary worn state. After determining that the refractory block 131 is worn secondarily, the temperature value measured by the temperature measuring unit 133 can be compared with the third set value without comparing with the second set value.

In addition, when the measured temperature of the refractory block 131 is equal to or more than a final set value, the refractory block 131 can be replaced. That is, since the degree of wear of the refractory block 131 can not be determined after the final set value, the new refractory block 131 can be replaced without using the refractory block 131 as it is.

If the temperature of the refractory block 131 is equal to or higher than the preset value, the refractory block 131 may be moved. (S400) For example, as shown in FIG. 5A, Assuming that the temperature of the refractory block 131 rises by 100 degrees centigrade every time the refractory block 131 is worn by 100 mm, the temperature of the refractory block 131 is 700 degrees centigrade before being worn when the direction length is 600 mm. You can set the setting at 800 degrees Celsius. If the measured temperature value of the refractory block 131 is equal to or greater than the predetermined value, it can be seen that the front end portion of the refractory block 131 is worn by 100 mm or more as shown in FIG. 5 (b).

The driver 132 is controlled to move the refractory block 131 forward by 100 mm or as much as the worn portion of the refractory block 131 or to the center portion of the chamber 110 by 100 mm as shown in FIG. Lt; / RTI > Therefore, even if the refractory block 131 is worn out, it can be restored, the refractory block 131 can continue to protect the heat exchange tube 121, and the life of the heat exchange tube 121 can be extended. However, the number of set values and numerical values that are actually set may be various and may be varied, and the replacement timing of the refractory block 131 is not limited to this, and may vary according to the judgment of the operator.

Then, when the coke is discharged to the outside of the chamber 110 after completion of the processing operation for the coke in the chamber 110, the supply of the inert gas can be stopped. Accordingly, it is possible to prevent the harmful gas, dust, and the like generated during the processing of the coke in the chamber 110 from being discharged to the outside of the chamber 110 through the movement path formed in the chamber 110.

As described above, even if the refractory provided in the predetermined area of the object treatment facility 100 collides with the objects to be treated and is worn, it can be quickly recovered. That is, even if the front end of the refractory block 131 is worn, the refractory block 131 can be moved and restored. Therefore, even if the refractory block 131 is worn, the heat exchange tube can be protected, and the direct contact of the heat exchange tube 121 with the coke can be suppressed or prevented to prolong the life of the heat exchange tube 121, It can be facilitated.

Also, the degree of wear of the refractory block 131 may be monitored to determine the time for repairing or replacing the refractory block 131. Therefore, it is possible to prevent a safety accident caused by damage to the refractory block 131 or the heat exchange tube 121, thereby securing the safety of the operator.

Although refinement of the refractory of the coke dry fire extinguishing system has been exemplarily described above, the scope of application is not limited to this and can be used in various facilities for treating the object to be treated.

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.

100: object treatment facility 110: chamber
120: boiler 121: heat exchange tube
130: Refractory recovery device 131: Refractory block
132: driver 133: temperature measuring instrument
134: Controller 135: Sealing unit

Claims (16)

A chamber in which an internal space for accommodating the object to be processed is formed; And
A refractory block capable of moving toward the inner space in a region narrower than the other region of the chamber and a driver connected to the refractory block for moving the refractory block, equipment. The method according to claim 1,
The chamber includes a first body having a smaller width toward the lower side and a second body connected to a lower portion of the first body and having a width larger than that of the lower portion of the first body, Wherein the first body and the second body are connected to each other. delete The method according to claim 1,
Wherein the refractory recovery apparatus further comprises a temperature measuring unit for measuring a temperature of the refractory block. The method of claim 4,
Wherein the refractory recovery device further comprises a controller for controlling the operation of the driver in accordance with the temperature of the refractory block. The method of claim 2,
A heat insulating material is provided between the walls of the first body and the second body and the refractory block,
And the heat insulating material is capable of sliding contact with the refractory block. The method of claim 6,
Wherein the refractory recovery apparatus further comprises a sealing unit installed between the refractory block and the actuator to block the interior space and the exterior of the chamber. The method of claim 7,
A path through which gas is supplied to the sealing unit is formed,
Wherein the path through which the gas is supplied is communicated with a space between the walls of the first body and the second body and the refractory block. The method of claim 7,
Wherein the sealing unit includes a sealing member that surrounds the periphery of the refractory and is capable of sliding contact with the heat insulating material. The method according to claim 1 or 2,
Wherein the object to be treated comprises a coke, the chamber comprising a digestion chamber for digesting the coke,
Further comprising a heat exchange tube located below the refractory recovery device. Providing a refractory block capable of moving toward the inner space of the chamber in which the object to be processed is processed;
Measuring a degree of wear of the refractory block; And
And moving the refractory block as much as the abraded block if the refractory block is worn; Containing refractory material. The method of claim 11,
The step of providing the movable refractory block includes:
And providing the refractory block at a portion where the width of the chamber is narrowed. The method according to claim 11 or 12,
Wherein the step of measuring the degree of wear of the refractory block comprises:
Measuring a temperature of the refractory block; And
Determining whether a temperature of the measured fire block is equal to or greater than a predetermined set value; Containing refractory material. 14. The method of claim 13,
The step of moving the refractory block includes:
And moving the refractory block when the measured temperature of the refractory block is equal to or higher than the preset value. The method according to any one of claims 11 to 12,
Before measuring the degree of wear of the refractory block,
Further comprising the step of blocking the inner space of the chamber from the outside. 16. The method of claim 15,
The process of cutting off the inner space of the chamber from the outside may include:
And supplying an inert gas between the wall of the chamber and the refractory block.

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