KR101907929B1 - Apparatus for charging raw material and Inspection method thereof - Google Patents

Abstract

The present invention relates to a device for supplying a raw material a facility to treat the raw material. To this end, the device comprises: a storage part having an inner space to store the raw material, and releasing the raw material to one side; a transfer part connected to one side of the storage part to guide the raw material toward the facility; and a blocking part installed to block a path where the raw material moves to the transfer part in the storage part. According to the present invention, it is possible to easily inspect internal state.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a raw material supply apparatus,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a raw material supply apparatus and a method of inspecting the raw material supply apparatus, and more particularly, to a raw material supply apparatus and a method of inspecting the raw material supply apparatus.

Generally, the coking coal used to produce the coke is stored for each type of coal, then crushed to a uniform size by a crusher, and then stored. The raw coke is blended according to a predetermined blending ratio when the coke making process is carried out, and then supplied to the coke oven to produce coke.

At the top of the coke oven there is a hopper for storing the coke, and a screw feeder is located between the hopper and the coke oven. The coke is transported to the hopper and is temporarily stored in the hopper, and the coke oven stored in the hopper is charged into the carbonization chamber of the coke oven by the operation of the screw feeder.

At this time, the temporarily stored cullet may be adhered to the inside of the screw feeder, or the screw feeder may be broken due to the tar component contained in the cullet. Alternatively, the screws or bearings provided in the screw feeder may be deformed or broken due to long-term use, so that the screw feeder may not operate normally.

Conventionally, when a trouble occurs in the screw feeder, the state of the screw feeder is checked after discharging the raw material. However, when discharging the coke within the screw feeder, the coke stored in the storage portion is continuously supplied to the screw feeder, which makes it difficult to discharge the coke within the screw feeder.

That is, when discharging the coke within the screw feeder, the coke stored in the hopper is supplied to the screw feeder. Therefore, the coke can not be removed from the screw feeder until the coke stored in the hopper is supplied to the screw feeder. Therefore, it takes much time to discharge the coke from the screw feeder, and the time for checking and repairing the screw feeder may be delayed.

KR 2015-0024612 A KR 2013-0140240 A

The present invention provides a raw material supply apparatus and a checking method thereof that can easily check the state without discharging all the raw materials stored therein.

The present invention provides a raw material supply apparatus and a checking method thereof that can improve the efficiency of inspection and repair work.

The present invention relates to an apparatus for supplying a raw material to an apparatus for processing a raw material, the apparatus comprising: a storage unit having an internal space in which a raw material can be stored; A transfer unit connected to one side of the storage unit to guide the raw material to the facility side; And a blocking unit installed in the storage unit to block a path through which the raw material moves to the feeding unit.

And a dispersion unit installed in the storage unit to disperse the raw material moving to the transfer unit, wherein the dispersion unit includes a first dispersion plate and a second dispersion plate, the first dispersion plate and the second dispersion plate being disposed opposite to each other, Plate.

Wherein the shielding portion comprises a plurality of shielding plates rotatably installed to open and close paths through which the raw material moves between the dispersing portion and the storage portion; A driver for generating a driving force for rotating the blocking plate; And a power transmitting member for transmitting driving force generated in the driver to the blocking plate.

Wherein the drive unit includes a motor, the power transmitting member includes: a plurality of cylindrical gears connected to the plurality of shield plates and meshed with each other; And a worm gear connected to the driver and engageable with at least one of the plurality of cylindrical gears.

At least a portion of the blocking plate is disposed in a spaced-apart space between the first and second dispersion plates.

The driver includes a plurality of cylinders, and the power transmitting member includes a hinge rotatably connecting the plurality of cylinders and the plurality of shield plates.

The control unit controls the degree to which the blocking unit blocks the path of the raw material moving to the conveyance unit in the storage unit, depending on the type of operation.

The control unit may open a path through which the raw material moves to the transfer unit when discharging the raw material in the storage unit and may block a path through which the raw material moves to the transfer unit when inspecting or repairing the storage unit and the transfer unit .

An observation window is provided in the storage section so that the inside of the storage section can be observed, and the observation window is positioned between one side of the storage section and the blocking section.

Wherein the transfer unit includes a transfer pipe connected to the storage unit and having a supply port for discharging the raw material to the facility side; A transfer member for moving the material from the transfer tube to the supply port; And a switch installed to open and close at least a part of the conveyance pipe.

The present invention provides a method of checking a raw material supply device for supplying a raw material to an equipment for processing a raw material, the process comprising: providing a shutoff part inside a storage part connected to a transfer part for guiding the raw material to the facility side; Closing the path through which the raw material moves from the storage unit to the transfer unit with the blocking unit and discharging the raw material inside the transfer unit; And observing the interior of at least one of the storage unit and the transfer unit.

The process of discharging the raw material in the transfer unit includes discharging the raw material inside the transfer unit together with the raw material in the transfer unit.

The process of discharging the raw material in the transfer unit includes discharging the process of discharging the raw material into the car.

And observing the inside of at least one of the storage unit and the transfer unit, and then removing the attached raw material when the raw material attached to the inside is found.

According to the embodiments of the present invention, it is possible to easily check the internal state of the transfer part connected to the storage part without discharging all the raw materials stored in the storage part. That is, the moving path of the raw material moving from the storage unit to the conveyance unit is cut off, and the raw materials inside the conveyance unit can be discharged in a state in which supply of the raw material to the conveyance unit is blocked. Therefore, the raw materials stored in the transfer part can be quickly removed, and the time for checking or repairing the transfer part can be shortened. Therefore, it is possible to improve the efficiency of inspection and repair work on the conveyance portion.

1 is a perspective view showing a raw material supply apparatus according to an embodiment of the present invention;
2 is a side sectional view showing a structure of a raw material supply apparatus according to an embodiment of the present invention.
3 is a front sectional view showing a structure of a raw material supply apparatus according to an embodiment of the present invention.
4 is a front cross-sectional view illustrating a structure of a blocking portion according to an embodiment of the present invention;
5 is a front cross-sectional view illustrating a structure of a blocking portion according to another embodiment of the present invention.
6 is a flowchart showing a method of checking a raw material supply apparatus according to an embodiment of the present invention.
7 is a view showing a sequence of shutting the inside of the storage part according to the embodiment of the present invention and discharging the raw material from the transfer part.

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

FIG. 1 is a perspective view showing a raw material supplying apparatus according to an embodiment of the present invention, FIG. 2 is a side sectional view showing the structure of a raw material supplying apparatus according to an embodiment of the present invention, Sectional view showing the structure of the feeding device.

1 to 3, a raw material supply apparatus 100 according to an embodiment of the present invention is an apparatus for supplying a raw material to a raw material processing apparatus and includes a storage unit 110, a transfer unit 120, (130). The raw material supplying apparatus 100 may further include a balancer for collecting the raw materials discharged from the distributing unit 140, the control unit (not shown) and the transferring unit 120.

At this time, the equipment for treating the raw material may be a coke oven, and the raw material may be coking coal. Therefore, the raw material supply device 100 may be a device for supplying coking coal to the coke oven 50. Although the embodiment of the present invention exemplifies the raw material supply device used in the coke process, the scope of application is not limited to this, but may be applied to other equipment for processing the raw material.

The storage unit 110 has an internal space in which the raw material can be stored, and the raw material can be discharged to one side. For example, the storage unit 110 may be a hopper and may have a narrower width from the upper side to the lower side. The upper portion of the storage portion 110 may be opened, and the lower portion may have a discharge port. Accordingly, the raw material can be supplied to the inside through the open upper part of the storage part 110, and the raw material inside can be discharged to the outside through the lower outlet. That is, a path through which the raw material moves from the upper side to the lower side may be formed in the storage unit 110.

In addition, an observation window 111 may be provided in the storage unit 110 so that the inside of the storage unit 110 can be observed. The observation window 111 may be formed on at least one of the side walls of the storage unit 110. The observation window 111 is made of a transparent material and can observe the interior of the storage unit 110 through the observation window 111 from outside the storage unit 110. [

Alternatively, a part of the side surface of the storage part 110 may be opened and the observation window 111 may cover the open part of the side surface of the storage part 110. The observation window 111 is slidably installed to open and close the open part of the side surface of the storage part 110. [ When the raw material is stored in the storage unit 110, the observation window 111 is closed and when the inside of the storage unit 110 is observed, the observation window 111 is opened to observe the inside of the storage unit 110 .

At this time, the observation window 111 may be positioned between one side (or an outlet) of the storage unit 110 and the blocking unit 130. The state of the outlet of the storage unit 110 and the state of a part of the interior of the transfer unit 120 connected to the discharge port can be controlled through the observation window 111, Can be confirmed.

Since the observation window 111 is located below or at the same height as the blocking unit 130, the state of the lower part of the blocking unit 130 can be confirmed inside the storage unit 110 through the observation window 111. [ Therefore, the lower part of the storage part 110, from which the raw material is discharged, can be easily observed while the upper part of the raw material is prevented from moving downward by the blocking part 130. However, the structure and shape of the storage unit 110 are not limited to the above, and may vary.

The dispersion unit 140 is installed to disperse the raw material moving from the storage unit 110 to the transfer unit 120. The dispersion unit 140 may be positioned at the center of the storage unit 110 in a plan view. The dispersion unit 140 is installed inside the storage unit 110 and is formed so as to have a wider width from the upper side to the lower side. Accordingly, the raw material supplied to the inside of the storage unit 110 drops downward, contacts with the dispersing unit 140 to reduce the speed, can be discharged in the dropping direction, and can be discharged to the transfer unit 120. Therefore, the raw material can be stably supplied to the transfer unit 120.

For example, the dispersing unit 140 may include a first dispersing plate 141 and a second dispersing plate 142, which are disposed opposite to each other and connected at one end (or upper end) to each other and at the other end (or lower end) ).

The first dispersion plate 141 may have a rectangular plate shape and may be installed inside the storage unit 110. For example, the first dispersion plate 141 may extend in the front-rear direction and be connected to the inner wall of the storage unit 110 and may be spaced apart from the inner wall of the storage unit 110 in the left-right direction. The first dispersion plate 141 may be inclined with respect to the vertical direction so that the surface of the first dispersion plate 141 facing the opened top of the storage portion 110 may form an inclined surface.

The second dispersion plate 142 may have a rectangular plate shape and may be installed inside the storage unit 110. For example, the second dispersion plate 142 may extend in the front-rear direction and be connected to the inner wall of the storage unit 110 and may be spaced apart from the wall of the storage unit 110 in the horizontal direction. The second dispersion plate 142 may be arranged to be symmetrical with the first dispersion plate 141 in the vertical direction. Accordingly, the surface of the first dispersion plate 141 facing the opened upper portion of the storage unit 110 can form an inclined surface.

The upper end of the second dispersion plate 142 is connected to the upper end of the first dispersion plate 141 and the distance between the first dispersion plate 141 and the second dispersion plate 142, Can be increased. That is, the first dispersion plate 141 and the second dispersion plate 142 may be arranged to form two sides of a triangle. The upper end of the dispersing portion 140 (or the portion facing the open upper portion of the storage portion 110) is sharpened and a space is formed between the first dispersing plate 141 and the second dispersing plate 142 .

At this time, the left end of the dispersion unit 140 is spaced apart from the inner wall of the storage unit 110, and the right end thereof is separated from the inner wall of the storage unit 110. Therefore, the movement path of the raw material in the storage section 110 can be divided into a left path formed on the left side of the dispersing section 140 and a right path formed on the right side of the dispersing section 140. However, the structure of the dispersion unit 140 and the number of paths divided by the dispersion unit 140 are not limited to this, and the structures and shapes of the first dispersion plate 141 and the second dispersion plate 142 It can be varied.

The transfer unit 120 is connected to one side (or the lower side) of the storage unit 110 to guide the raw material discharged from the storage unit 110 to the coke oven side. The transfer unit 120 may include a transfer tube 121, a transfer member 123, a drive motor 124, and a switch 122.

The transfer tube 121 may be a tube that forms a transfer path for the raw material therein. The transfer tube 121 is connected to the first body 121a and the first body 121a extending in a direction intersecting the movement path of the raw material formed in the storage unit 110, And a second body 121b extending in a direction intersecting with the first body 121a.

The first body 121a is connected to a lower portion (or an outlet) of the storage unit 110. [ Therefore, the raw material can move into the transfer pipe 121 from inside the storage unit 110. For example, the first body 121a may extend in the front-rear direction, and a rear end of the first body 121a may be connected to a lower portion of the storage unit 110. [ Accordingly, the first body 121a and the inner space of the storage unit 110 can communicate with each other.

The second body 121b is connected to the front end of the first body 121a. Accordingly, the raw material can move from the first body 121a to the second body 121b. For example, the second body 121b may extend vertically and the upper end of the second body 121b may be connected to the lower end of the first body 121a. Accordingly, the inner spaces of the first body 121a and the second body 121b can communicate with each other.

In addition, a feed port for discharging the raw material to the coke oven side is formed at the lower end of the second body 121b. Accordingly, the raw material moving from the first body 121a to the second body 121b can be charged into the coke oven through the supply port formed in the second body 121b while falling downward. However, the structure and the shape of the transfer tube 121 are not limited to this and may vary.

And the feed member 123 serves to move the raw material in the first body 121a toward the feed port. The transfer member 123 may be installed inside the first body 121a. The conveying member 123 may extend in the extending direction of the first body 121a, and a screw may be formed on the outer peripheral surface of the conveying member 123. The central axis of the conveying member 123 can be rotatably supported on the wall of the first body 121a. Accordingly, when the conveying member 123 rotates in one direction, the raw material supplied into the first body 121a from the storage unit 110 can be conveyed to the second body 121b side by the screw.

The driving motor 124 may be installed outside the first body 121a. The driving motor 124 can be connected to the central axis of the conveying member 123 and generate a rotational force for operating the conveying member 123. [ When the driving motor 124 rotates the feeding member 123, the raw material in the first body 121a is transferred into the second body 121b, and the driving motor 124 stops the feeding member 123 The raw material supplied from the storage unit 110 can be stored in the first body 121a. However, the method of driving the conveying member 123 is not limited to this and may be various.

The switch 122 may be installed in the transfer tube 121 to open or close at least a part of the transfer tube 121. For example, at least a portion of a portion of the first body 121a opposite to the outlet of the storage portion 110 may be opened, and the switch 122 may be installed in an open portion of the first body 121a . The switch 122 may include a cover member 122a and a drive cylinder 122b.

The cover member 122a may be a plate formed along the shape of the open portion of the first body 121a. One or a plurality of cover members 122a may be provided, and the cover member 122a may be rotatably installed on the first body 121a. If the cover member 122a completely covers the opened portion of the first body 121a, the raw material can be stored in the first body 121a or the raw material can be stably transported to the second body 121b side . When the cover member 122a opens the opened portion of the first body 121a, the raw material in the first body 121a can be discharged to the outside through the opened portion.

The driving cylinder 122b is connected to the cover member 122a to generate a driving force for rotating the cover member 122a. One or more driving cylinders 122b may be provided and may be supported on the outer wall of the first body 121a. When the rod of the driving cylinder 122b advances to one side, the cover member 122a can open the open part of the first body 121a and when the rod of the driving cylinder 122b moves back to the other side, Can close the open portion of the first body 121a. However, the method of driving the cover member 122a is not limited to this, and may vary.

At this time, since the switch 122 is installed to open and close the opened portion of the first body 121a, the raw material stored in the first body 121a can be discharged without operating the transfer member 123. [ That is, when a problem occurs in the conveying member 123 and the conveying member 123 can not be rotated, a part of the conveying member 123 may be opened to open the first body 121a using the switch 122 to discharge the raw material in the first body 121a And the other part is pushed into the second body 121b to be discharged and then the inside of the first body 121a and the state of the transfer member 123 can be checked easily.

4 is a cross-sectional front view illustrating a structure of a blocking portion according to an embodiment of the present invention. Hereinafter, the blocking unit 130 according to the embodiment of the present invention will be described.

Referring to FIG. 4, the blocking unit 130 is installed to block the path of the raw material moving to the transfer unit 120 in the storage unit 110. The blocking portion 130 includes a blocking plate 131, a driver 132, and a power transmitting member 133. In addition, the blocking portion 130 may further include a case 134.

The blocking plate 131 may include a plurality of the blocking plates 131 as many as the number of the paths of the raw materials divided by the dispersing unit 140. For example, when the distribution unit 140 divides the path of the raw material into two, two shutoff plates 131 may be provided to open and close each path.

The blocking plate 131 may be a plate extending along the extending direction of the dispersion unit 140 and may be formed along the plane shape of the path between the dispersion unit 140 and the inner wall of the storage unit 110 . The blocking plate 131 may be installed to be rotatable to open and close the paths through which the raw material moves between the dispersion unit 140 and the storage unit 110.

For example, the blocking plate 131 may have a shaft 131a connected to the main body. The front end of the shaft 131a is rotatably connected to the inner wall of the storage part 110 and the rear end of the shaft 131a passes through the inner wall of the storage part 110 and is positioned outside the storage part 110 can do. The main body of the blocking plate 131 can be supported on the shaft 131a while rotating around the shaft 131a and the main body of the blocking plate 131 can be supported by the path between the dispersion unit 140 and the storage unit 110 Can be opened and closed.

At this time, at least a part of the blocking plate 131 may be disposed in the space between the first dispersion plate 141 and the second dispersion plate 142. For example, the shaft 131a of the blocking plate 131 may be located in a space between the first dispersion plate 141 and the second dispersion plate 142. [ Therefore, it is possible to prevent the shaft 131a from being damaged by being protected from the raw material moving in the storage part 110. [

Also, when the blocking plate 131 is rotated downward to open the path through which the raw material moves, the blocking plate 131 may not protrude outward from the dispersing unit 140 in plan view. Accordingly, the blocking plate 131 is disposed so as not to interfere with the movement of the raw material, and the raw material can smoothly move along the path. However, the structure and shape of the blocking plate 131 are not limited to the above, and may vary.

The driver 132 may be located outside the storage unit 110 and may generate a driving force for rotating the blocking plate 131. For example, the driver 132 may be a motor that generates rotational force. The shutoff plate 131 is rotated upward or downward according to the rotational direction of the driver 132 to open and close the path through which the raw material moves between the storage unit 110 and the dispersion unit 140. However, the type of driver 132 is not limited to this and may vary.

The power transmitting member 133 serves to transmit the driving force generated in the driver 132 to the blocking plate 131. For example, the power transmitting member 133 may include a cylindrical gear 133a and a worm gear 133b.

The cylindrical gear 133a may be formed in a cylindrical shape and teeth may be formed on the outer circumferential surface. A plurality of cylindrical gears 133a may be provided as many as the number of the blocking plates 131 is provided. The cylindrical gears 133a may be connected to the plurality of blocking plates 131, respectively. The cylindrical gear 133a is connected to the shaft 131a of the blocking plate 131 and the cylindrical gear 133a and the shaft 131a can rotate together. For example, the cylindrical gear 133a may be connected to the rear end of the shaft 131a and may be located outside the storage part 110. [

In addition, the cylindrical gears 133a connected to the different shielding plates 131 may be installed to interlock with each other. Thus, when one of the cylindrical gears 133a rotates in the clockwise direction, the other cylindrical gear 133a can rotate in the counterclockwise direction in association with this. Therefore, the rotation of the cylindrical gear 133a causes the blocking plate 131 to rotate upward or downward, thereby opening and closing the path through which the raw material moves.

The worm gear 133b may be formed in a bar shape, and a screw thread may be formed on the outer peripheral surface of the end. The worm gear 133b may be positioned above or below the cylindrical gear 133a and may extend in a direction intersecting the extending direction of the shaft 131a of the blocking plate 131. [ One side of the worm gear 133b is connected to the driver 132 and a screw thread formed on the worm gear 133b can be engaged with at least one of the plurality of cylindrical gears 133a. Thus, the worm gear 133b can be rotated by the driver 132 and can transmit the rotational force of the driver 132 to the meshed cylindrical gear 133a. The cylindrical gear 133a is rotated by the worm gear 133b and transmits the rotational force to the blocking plate 131 to rotate the blocking plate 131. [

At this time, since the cylindrical gears 133a are engaged with each other, even if any one of the plurality of cylindrical gears 133a is rotated by the worm gear 133b, the other cylindrical gear 133a can rotate together. Therefore, the rotational force of the driver 132 can cause the blocking plate 131 to rotate by the worm gear 133b and the cylindrical gear 133a. However, the structure of the power transmitting member 133 is not limited to this and may vary.

The case 134 has an inner space and may be installed on the outer surface of the storage unit 110. [ At least a part of the cylindrical gear 133a and the worm gear 133b may be accommodated in the case 134. [ Thus, the cylindrical gear 133a and the worm gear 133b can be protected from the outside by the case 134. [

The control unit (not shown) controls the operation of the blocking unit 130. The control unit can control the degree to which the cutoff unit 130 cuts off the path through which the raw material moves to the transfer unit 120 in the storage unit 110, depending on the type of work. That is, the control unit may be connected to a driver provided in the blocking unit 130, and may control the operation of the driving unit so that the blocking plate provided in the blocking unit 130 blocks the path through which the raw material moves.

For example, as shown in FIG. 4 (a), when the control unit inspects or repairs the inside of the storage unit 110 and the transfer unit 120, the path through which the raw material moves to the transfer unit 120 may be blocked. When the raw material stored in the transfer unit 120 is removed to inspect or repair the inside of the storage unit 110 or the transfer unit 120, it is possible to prevent the raw material stored in the storage unit 110 from being supplied to the transfer unit 120 can do. Therefore, the raw material in the transfer unit 120 can be quickly removed.

Alternatively, when the raw material in the storage unit 110 is discharged to the transfer unit 120 as shown in FIG. 4 (b), the control unit may open the path of the raw material moving to the transfer unit 120. Accordingly, since the blocking portion 130 does not interfere with the movement of the raw material, the raw material can be smoothly supplied to the transfer portion 120.

In addition, as shown in FIG. 4C, the controller can adjust the amount of the raw material supplied to the transfer unit 120 by controlling the degree of blocking the movement path of the raw material by the shutoff plate 131. Accordingly, it is possible to control the amount of the raw material supplied according to the situation inside the coke oven.

In this way, the internal state of at least one of the storage unit 110 and the transfer unit 120 connected to the storage unit 110 can be easily checked without discharging all the raw materials stored in the storage unit 110. That is, the moving path of the raw material moving from the storage unit 110 to the transfer unit 120 may be cut off, and the raw materials in the transfer unit 120 may be discharged in a state where the supply of raw materials to the transfer unit 120 is blocked. Accordingly, the raw materials stored in the transfer unit 120 can be quickly removed, and the time for checking or repairing the state of the transfer unit 120 or the part connected to the transfer unit 120 of the storage unit 110 can be shortened . Therefore, it is possible to improve the efficiency of the inspection and repair work on the raw material supply apparatus 100.

5 is a cross-sectional front view illustrating a structure of a blocking portion according to another embodiment of the present invention. Hereinafter, the blocking unit 130 according to another embodiment of the present invention will be described.

Referring to FIG. 5, the blocking unit according to another embodiment of the present invention includes a blocking plate 131 ', a driver 132', and a power transmitting member 133 '.

The blocking plate 131 'may include a plurality of the blocking plates 131' as many as the number of the paths of the raw materials are divided by the dispersing unit 140. The blocking plate 131 'may be a plate extending along the extending direction of the dispersing unit 140 and may be formed along the plane shape of the path between the dispersing unit 140 and the inner wall of the storing unit 110. The blocking plate 131 'may be installed to be rotatable to open and close the paths through which the raw material moves between the dispersion unit 140 and the storage unit 110.

For example, the upper end of the blocking plate 131 'may be rotatably connected to the inner wall of the storage unit 110. Accordingly, the lower end of the blocking plate 131 'can vertically pivot about the upper end, and the blocking plate 131' can open / close the path through which the raw material moves. However, the structure and shape of the blocking plate 131 'are not limited to these, and may vary.

The actuator 132 'serves to generate a driving force for moving the blocking plate 131'. For example, the actuator 132 'may be a cylinder, and a plurality of actuator 131' may be provided. Thus, each of the actuators 132 'can move the respective blocking plates 131'.

Particularly, the driver 132 'is installed on the outer side of the storage unit 110 and the other part of the driver 132' penetrates the wall of the storage unit 110 and is connected to the blocking plate 131 'through the power transmitting member 133' Lt; / RTI > Thus, when the rod of the actuator 132 'advances, the lower end of the blocking plate 131' is rotated upward, blocking the path of movement of the blocking plate 131 'by the raw material. The rod of the actuator 132' The lower end of the blocking plate 131 'is rotated downward to open the path through which the blocking plate 131' moves the raw material. However, the type of driver 132 'is not limited to this and may vary.

The power transmitting member 133 'may be a hinge that rotatably connects the plurality of cylinders and the plurality of blocking plates 131' to each other. Thus, when the cylinder generates the driving force, the blocking plate 131 'can be rotated by the power transmitting member 133'. Accordingly, the blocking plate 131 'can be connected to the cylinder having a different direction of motion, and the blocking plate 131' can be rotated by the operation of the cylinder. However, the structure of the power transmitting member 133 'is not limited thereto and may vary.

FIG. 6 is a flow chart showing a method of checking a raw material supply apparatus according to an embodiment of the present invention, and FIG. 7 is a view showing a procedure of cutting off the inside of a storage unit and discharging a raw material from a transfer unit according to an embodiment of the present invention. Hereinafter, a method of checking a raw material supply apparatus according to an embodiment of the present invention will be described.

Referring to FIG. 6, a method of inspecting a raw material supplying apparatus according to an embodiment of the present invention is a method of inspecting a raw material supplying apparatus for supplying a raw material to an apparatus for treating a raw material, (S120) of inserting the raw material in the transfer unit, and observing the inside of at least one of the storage unit and the transfer unit (S130) do.

 At this time, the equipment for treating the raw material may be a coke oven, and the raw material may be coking coal. Therefore, the raw material supply device may be a device for supplying coking oven with coke oven. Although the embodiment of the present invention exemplifies the raw material supply device used in the coke process, the scope of application is not limited to this, but may be applied to other equipment for processing the raw material.

1 to 7, the blocking unit 130 may be provided inside the storage unit 110 connected to the transfer unit 120 for guiding the raw material to the coke oven 50 side. The dispersion unit 140 is disposed inside the storage unit 110 to disperse the material moving to the transfer unit 120. The separation unit 130 can be installed below the dispersion unit 140. [

The blocking unit 130 may open or close the movement path of the raw material formed between the inner wall of the storage unit 110 and the dispersing unit 140. 7 (a), when the shutoff part 130 opens the movement path, the raw material in the storage part 110 can smoothly move downward. When the blocking unit 130 blocks the movement path, the material on the upper side of the blocking unit 130 can be prevented from moving downward.

The feedstock stored in the feeder 120 may adhere to the feeder 120, or a failure may occur in the feeder 120 due to the tar component contained in the feeder. Or, the components such as the conveying member 123 and the bearings provided in the conveying unit 120 may be deformed or damaged due to long-term use, so that the conveying unit 120 may not operate normally. Therefore, it is possible to perform an operation of checking the inside of the transfer unit 120 and the storage unit 110. [

First, as shown in FIG. 7 (b), the shutoff part 130 cuts off the path through which the raw material moves from the storage part 110 to the transfer part 120, and the raw material in the transfer part 120 can be discharged. When the raw material is discharged from the transfer unit 120 without shutting the inside of the storage unit 110, the raw material is supplied from the storage unit 110 to the transfer unit 120 as much as the raw material is discharged from the transfer unit 120, The raw materials in the transfer unit 120 do not decrease until all of the raw materials stored in the transfer unit 110 are supplied to the transfer unit 120. Accordingly, the raw material can perform the operation of discharging the raw material from the transfer unit 120 after cutting off the path through which the raw material moves in the storage unit 110 with the blocking unit 130.

When the blocking unit 130 blocks the inside of the storage unit 110, the opening / closing unit 122 of the transfer unit 120 may be operated to open a part of the transfer pipe 121 as shown in FIG. 7C. Accordingly, the raw material stored in the transfer tube 121 can be discharged. The raw material that has not been discharged to the switch 122 inside the transfer pipe 121 can be pushed into the supply port formed in the transfer pipe 121 and discharged.

At this time, along with the raw material in the transfer pipe 121, only the raw material below the blocking unit 130 can be discharged from the storage unit 110. That is, the raw material on the upper side of the blocking part 130 in the storage part 110 is restricted by the blocking part 130 and the raw material on the lower side of the blocking part 130 can be supplied to the transfer part 120. Therefore, when discharging the raw material in the transfer unit 120, the raw material below the cut-off unit 130 can be supplied to the transfer unit 120 and discharged together. Therefore, even if a part of the feed pipe 121 is opened, the entire raw material in the storage unit 110 may not be supplied to the feed unit 120, and the raw material in the feed pipe 121 may be quickly removed.

On the other hand, before the part of the transfer pipe 121 is opened by the switch 122, the transfer pipe 121 can be positioned on the upper side of the car 150. The carriage 150 has an inner space, and the upper portion can be opened. A part of the transfer pipe 121 can be opened by the switch 122 while the switch 122 and the bogie 150 are arranged to face each other. Accordingly, the raw material discharged to the open portion of the transfer pipe 121 can be discharged into the car 150 for collecting the raw material. Therefore, the raw material can be collected easily.

In this case, since the amount of the raw material discharged to the open part of the conveyance pipe 121 can be reduced by the blocking part 130, too much raw material is supplied to the carriage 150, It is possible to prevent overflow to the outside of the space. Therefore, the raw material can be collected and reused in the bogie 150 in a stable manner.

Then, the inside of at least one of the storage unit 110 and the transfer unit 120 can be observed. For example, the state of the lower part of the blocking part 130 and a part of the state of the transfer part 120 can be confirmed in the storage part 110 through the observation window 111 provided in the storage part 110. Alternatively, the inside of the transfer unit 120 may be checked through a portion of the transfer pipe 121 that is opened by the switch 122. Therefore, it is possible to check whether the raw material is adhered to the inside of the storage unit 110 or the transfer unit 120, or to confirm the damaged part.

After observing the inside of at least one of the storage unit 110 and the transfer unit 120, it is possible to perform an operation of removing the adhered raw material when the attached raw material is found. Alternatively, it is possible to perform an operation of repairing a damaged portion of at least one of the storage unit 110 and the transfer unit 120.

In this way, the internal state of at least one of the storage unit 110 and the transfer unit 120 connected to the storage unit 110 can be easily checked without discharging all the raw materials stored in the storage unit 110. That is, the moving path of the raw material moving from the storage unit 110 to the transfer unit 120 may be cut off, and the raw materials in the transfer unit 120 may be discharged in a state where the supply of raw materials to the transfer unit 120 is blocked. Accordingly, the raw materials stored in the transfer unit 120 can be quickly removed, and the time for checking or repairing the state of the transfer unit 120 or the part connected to the transfer unit 120 of the storage unit 110 can be shortened . Therefore, it is possible to improve the efficiency of the inspection and repair work on the raw material supply apparatus 100.

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.

100: raw material supply device 110:
111: Observation window 120:
121: Transport pipe 122: Actuator
130: blocking portion 131: blocking plate
132: driver 133: power transmission member
140: dispersion part 141: first dispersion plate
142: second dispersion plate 150:

Claims (14)

An apparatus for supplying a raw material to an apparatus for treating a raw material,
A storage unit having an inner space through which a raw material can be stored and from which raw material can be discharged;
A transfer unit connected to one side of the storage unit to guide the raw material to the facility side;
A dispersion unit installed in the storage unit to disperse a raw material moving to the transfer unit; And
And a blocking unit installed in the storage unit to block a path of moving the raw material to the feeding unit,
Wherein the dispersing portion includes a first dispersing plate and a second dispersing plate which are disposed opposite to each other and whose ends are connected to each other and whose other ends are spaced apart from each other. delete The method according to claim 1,
The cut-
A plurality of shielding plates rotatably installed to open and close paths through which the raw material moves between the dispersing unit and the storage unit;
A driver for generating a driving force for rotating the blocking plate; And
And a power transmitting member for transmitting a driving force generated by the driver to the blocking plate. The method of claim 3,
Wherein the actuator comprises a motor,
The power transmitting member includes:
A plurality of cylindrical gears connected to the plurality of shield plates and meshed with each other; And
And a worm gear connected to the driver and engageable with at least one of the plurality of cylindrical gears. The method of claim 4,
And at least a part of the blocking plate is disposed in a spacing space between the first dispersion plate and the second dispersion plate. The method of claim 3,
Wherein the actuator includes a plurality of cylinders,
Wherein the power transmitting member includes a hinge for rotatably connecting the plurality of cylinders and the plurality of blocking plates. The method according to any one of claims 1 and 3 to 6,
Further comprising a control unit for controlling the degree to which the blocking unit blocks a path through which the raw material moves to the transfer unit in the storage unit depending on the type of operation. The method of claim 7,
The control unit may open a path through which the raw material moves to the transfer unit when discharging the raw material in the storage unit and may block a path through which the raw material moves to the transfer unit when inspecting or repairing the storage unit and the transfer unit. Raw material supply device. An apparatus for supplying a raw material to an apparatus for treating a raw material,
A storage unit having an inner space through which a raw material can be stored and from which raw material can be discharged;
A transfer unit connected to one side of the storage unit to guide the raw material to the facility side; And
And a blocking unit installed in the storage unit to block a path of moving the raw material to the feeding unit,
Wherein an observation window is provided in the storage part so as to observe the inside of the storage part, and the observation window is located between one side of the storage part and the blocking part. The method according to any one of claims 1 and 3 to 6,
The transfer unit
A transfer pipe connected to the storage unit and having a supply port for discharging the raw material to the facility side;
A transfer member for moving the material from the transfer tube to the supply port; And
And an opening / closing device installed to open / close at least a part of the conveyance pipe. A method for checking a raw material supply device for supplying a raw material to an equipment for processing a raw material,
A step of providing a shielding part in a storage part connected to a conveying part for guiding the raw material to the facility side;
Closing the path through which the raw material moves from the storage unit to the transfer unit with the blocking unit and discharging the raw material inside the transfer unit; And
And observing the interior of at least one of the storage unit and the transfer unit. The method of claim 11,
In the process of discharging the raw material in the transfer unit,
And discharging the raw material in the lower part of the blocking part in the storage part together with the raw material in the transfer part. The method of claim 11,
In the process of discharging the raw material in the transfer unit,
And discharging the raw material to a bogie for collecting the raw material. The method according to claim 11 or 12,
After observing the inside of at least one of the storage unit and the transfer unit,
And removing the attached raw material when the raw material attached to the inside is found.

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