KR101900161B1 - Dust coal leak prevention system of filter cloth - Google Patents

Abstract

The present invention relates to a system for preventing fine particulate leakage of a filter fabric, comprising a fine-particle collector for collecting fine-powders through a filter provided in a row, a filter for detecting a gas emitted from the filter, A leakage position detection unit for detecting a leakage position of the pulverized coal in the filter cloth; and a seal member for sealing the position where the pulverized coal is grasped by the leakage position grasping unit, .

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

The present invention relates to a system for preventing fine particle leakage of a filter fabric.

Generally, in the blast furnace, iron ore and coke used as raw materials are charged into the blast furnace and the coal is crushed and blown into the blast furnace by pulverized coal, and coke and pulverized coal are burned by the hot hot wind to generate reducing gas The iron ore is reduced and melted.

During the above process, the coal is compacted in a crusher, dried with a high temperature gas, and crushed into pulverized coal, which moves together with the hot gas to enter the collection facility.

Here, most of the pulverized coal is dropped by its own weight, and the high-temperature gas is discharged to the atmosphere through the filter cloth.

In order to smooth out the pulverized coal adhering to the surface of the filter cloth and smooth discharge of gas at a high temperature, pulsation of the nitrogen spraying method is periodically performed inside the filter cloth.

In addition, several filter cloths made of special cloth are installed in the collection facility, but filter cloth breaks at the time of pulsation of nitrogen due to deterioration of the material of the filter cloth, poor sewing, and aging due to use of the filter cloth for a long time, .

Conventionally, as a countermeasure against the above-mentioned phenomenon, the entire pulverized coal production facility is stopped, the collection facility cover is opened, and then the toxic gas is replaced.

Then, the operator enters the collecting facility to check the filter cloth and performs only replacement of the filter cloth.

However, the conventional method has the following problems.

First, if the pulverized coal is leaked to the atmosphere due to the bleb breakage phenomenon during operation of the pulverized coal production facility, it is necessary to stop the pulverized coal production facility immediately after the naked eyes, and to allow enough cooling and gas replacement for the workers to enter the collection facility, Thereby causing a decrease in productivity.

Secondly, it is possible only when stopping the pulverized coal production facility when checking the filtration site. All the work is done by hand, which causes problems of workload and safety accidents.

Korean Patent Publication No. 1997-0002053 (Publication date: Mar. 17, 1997, entitled: Korean Utility Model Application No. 1997-017947 (Publication date: May 23, 1997, entitled: Bump Damage Detection in a Backfill Filter of a Pulverized Coal Collection System and a Prevention Device for Preventing Leaky Coal Leakage)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a system for preventing fine particle leakage of a filtering cloth that remotely checks the breakage of a pulverized coal filter bag to check whether the filter bag is blown.

It is also an object of the present invention to provide a system for preventing fine particle leakage of a filter fabric which prevents banding leakage by banding the filter breaking site.

The technical objects to be achieved by the present invention are not limited to the above-mentioned technical problems.

According to an aspect of the present invention, there is provided a pulverized coal leakage preventing system for a filter fabric, comprising: a pulverized coal collecting unit for collecting pulverized coal through a filter bag provided in a row; A fine particle leakage detecting unit for detecting a gas emitted from the arranged filter cloth and detecting damage of the filter cloth based on the concentration of the fine particle; A leakage position grasping unit for grasping a position where the fine coal is leaked from the filter cloth; And a hermetically sealed portion for hermetically sealing the leakage position of the pulverized coal in the filter fabric grasped by the leakage position grasping portion.

Specifically, the pulverized coal collecting unit includes a nitrogen pulsation pipe connected to each of the filter sheets; A nitrogen pump for collectively delivering nitrogen to the nitrogen pulsation pipe; And a pulsating valve for controlling the amount of nitrogen introduced into the nitrogen pulsation pipe by the nitrogen pump. The pulsating unit periodically and collectively injects nitrogen into the nitrogen purging pipe And the pulsation is performed.

In addition, the pulverized coal leakage detector may include a pulverized coal concentration meter for measuring the concentration of pulverized coal conveyed through the piping connected to the arranged filter cloths, and the controller may compare the pulverized coal pulverized coal with a pre- And a leakage state is detected.

The leaking position determination unit may further include: a heat resistant hose connected to the carbon monoxide concentration meter; A nozzle for detecting the powdered coal connected to the end of the heat resistant hose; And a length adjuster for adjusting the length of the heat resistant hose.

The detecting nozzle connected to the end of the heat-resistant hose controlled by the length adjuster transmits information of the pulverized coal sucked in accordance with the position of the filter cloth to the pulverized coal densitometer to determine the presence of pulverized coal.

The controller may further include a controller for controlling operations of the pulverized coal leakage detector, the leakage positioner, and the closure, wherein the controller transmits the numerical value of pulverized coal detected according to the internal position of the filter cloth to the control unit When the detected value of the pulverized coal is equal to or greater than a predetermined value, the operation of the length adjuster is stopped to determine the pulverized coal leaking part of the filter fabric.

In addition, the closed part further includes first and second cylinder parts for adjusting the length in the horizontal direction.

The sealing portion may include a vertical moving portion that moves the first and second cylinder portions in a vertical direction; A first electromagnet and a second electromagnet provided at respective ends of the first and second cylinders; And first and second lid parts respectively coupled to the electromagnet, each of the first and second lid parts having silicon inside and hollow inside when coupled to each other.

The first and second lids are coupled to each other by a first permanent magnet and a second permanent magnet having different polarities on a contact surface.

In addition, the first and second lids provided with the silicone seal each other at a position where the pulverized coal fines are combined with each other at a position where the pulverized coal is leaked.

In addition, a partition wall is provided inside the pulverized coal collecting unit so as to be separated from the closed part, and the partition wall is moved up and down.

As described above,

The apparatus for preventing leaking of blast furnace dust collecting filter according to the present invention has the effect of reducing bad influence on the operation and remarkably raising the productivity by preventing the filtering cloth breaking area in a short time without stopping the pulverized coal manufacturing facility.

In addition, the present invention can detect leakage of the pulverized coal to the atmosphere by detecting the filter bleeder region at an early stage, and it is possible to prevent safety accidents in the conventional method There is a practical effect.

1 is a perspective view illustrating a system for preventing fine particle leakage of a filter fabric according to an embodiment of the present invention.
2 is a view showing a combination of a pulsating portion and a pulverized coal leakage detecting portion of the pulverized coal fines preventing system of the filter fabric according to the embodiment of the present invention.
3 is a view showing a leakage position determination unit of a system for preventing fine particle leakage of a filter fabric according to an embodiment of the present invention.
FIG. 4 is a view showing a banding process performed by the sealing unit of the fine particle leakage preventing system of the filter fabric according to the embodiment of the present invention.
FIG. 5 is a view showing a state in which the banding process is completed by the sealing part of the system for preventing fine particle leakage of the filter fabric according to the embodiment of the present invention.
FIG. 6 is a view showing a part of a closed part of a system for preventing fine particle leakage of a filter fabric according to an embodiment of the present invention.
FIG. 7 is a block diagram showing a configuration of a control system of a system for preventing fine particle leakage of a filter fabric according to an embodiment of the present invention. Referring to FIG.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventive concept. Other embodiments falling within the scope of the inventive concept may readily be suggested, but are also considered to be within the scope of the present invention.

FIG. 1 illustrates a system for preventing fine particle leakage of a filter fabric according to an embodiment of the present invention. The system includes a fine particle collector 100, a fine particle leakage detector 200, a leakage position detector 300, An enclosure 400, and a control unit 500. [

The pulverized coal collecting unit 100 collects the pulverized coal inside the reactor and collects the pulverized coal by the filter cloth 110 and discharges the gas through the filter fabric 110 to the atmosphere. And a filter cloth 110 arranged in a plurality of rows and columns for filtering the gas.

Generally, the filter cloth 110 provided in the pulverized coal collecting unit 100 is arranged in 12 x 20.

At this time, the pulverized coal collecting unit 100 further includes a pulsating unit 120 periodically and cyclically injecting nitrogen into the filter cloths 110 to perform pulsation.

As shown in Fig. 2, the pulsation section 120 includes a nitrogen pumping pipe 121, a nitrogen discharge pump 122, and a pulsation valve 123. As shown in Fig.

The nitrogen pumping pipe 121 is connected to each of the filter cloths 110 in parallel and the nitrogen pumping pipe 121 connected to the filter cloth 110 is connected to the nitrogen pump 122. The nitrogen-dosing pump 122 can collectively transfer nitrogen to the nitrogen pulsation pipe 121.

The pulsation valve 123 may be installed in the nitrogen pulsation pipe 121 to adjust the amount of nitrogen introduced into the nitrogen pulsation pipe 121 by the nitrogen pump 122. Accordingly, the pulverized coal adhering to the outer surface of the filter cloth 110 is removed to prevent clogging of the filter cloth 110 to smooth out the gas.

As shown in FIG. 2, the pulverized coal leakage detecting unit 200 is constructed such that individual pipes 210 are connected to the arranged filter cloths 110, and the main pipe 220, which collects the individual pipes 210, 240).

At this time, it is not meant that each of the individual pipes 210 is connected to the main pipe 220 but the gas detected by each of the individual pipes 210 is mixed in the main pipe 220.

The individual piping 210 and the main piping 220 enable the pulverized coal concentration of each filter cloth 110 to be measured by the pulverizer 240 through the valve 230.

 That is, the gas detected by the individual pipe 210 is transmitted to the carbon monoxide concentration meter 240 through the main pipe 220.

Although the illustration of the valve 230 is depicted analogously in the embodiment of the present invention, it is preferable that the valve 230 be configured to be fully openable and closable by the control unit 500. [ The pulsation valve 123 and the valve 230 according to the embodiment of the present invention are preferably constituted by a solenoid valve.

That is, the pulverized coal concentration of the filter cloth 110 is measured sequentially or regularly with respect to the filter cloth 110 arranged.

At this time, the pulverized coal concentration meter 240 transmits information on the pulverized coal concentration of each filter fabric 110 individually measured to the controller 500, and determines whether the pulverized coal concentration is equal to or greater than a predetermined concentration value.

If the measured pulverized coal concentration is not less than a preset concentration value, the controller 500 determines that the filter fabric 110 is damaged. If the measured pulverized coal concentration is less than the predetermined concentration value, the controller 500 can determine that the filter fabric 110 is normal.

In the case of the damaged filter cloth 110, since the pulverized coal is not collected and discharged together with the gas, the concentration of the pulverized coal is included in the measured gas, so that the concentration of pulverized coal can be measured through the discharged gas.

Here, the open state of the valve 230 of the controller 500 and the pulverized coal leakage detector 200 is synchronized, and the position of the filter fabric 110 that is currently measured can be grasped.

More specifically, the control unit 500 operates the check nitrogen pumping pump 122 to check whether the filter cloth 110 is damaged, opens the pulsation valve 123 of the nitrogen pumping pipe 121, 200 also opens the valve 230 of the individual piping 210 of the main pipe 200 to prevent the discharged fine coal from being sucked into the nitrogen pump 122 and discharged to the atmosphere.

The control unit 500 closes all the valves 230 installed in the individual pipe 210 connected to the filter cloth 110 and controls the individual pipe 210 of the filter cloth 110 in the first row and the first column in the control unit 500 Only the installed valve 230 is opened and the nitrogen pumping pipe 121 and the pulsation valve 123 of the filter cloth 110 in the first row and column are closed so as not to be sucked toward the nitrogen pumping pipe 121, The damaged state of the filter cloth 110 in the first row and column is detected by the fine particle concentration meter 240 with the concentration of the pulverized coal in the flowing gas through the control of the pulsation valve 123 and the valve 230.

In this manner, the concentration of the pulverized coal in the remaining filter cloth 110 can be measured sequentially or regularly to determine whether the filter is damaged.

3, the leakage position detecting unit 300 is configured to detect the position where the fine coal is leaked from the damaged filter fabric 110. The leakage position detecting unit 300 includes a heat-resisting hose 310, And a length adjuster 330 for moving the heat resistant hose 310, the pulverized coal detecting nozzle 320 and the length adjuster 330 to the position of the filter cloth 110 (340), a horizontal moving part (350), and a cylinder part (360).

One end of the heat resisting hose 310 is connected to the pulmonary carbon concentration meter 240 so that the gas can be delivered to the pulverizer 240.

In this case, in the embodiment of the present invention, the pulverized coal concentration meter 240 of the pulverized coal leakage detector 200 is applied, but it is preferable that the pulverized coal concentration meter 240 has a separate pulverized coal concentration meter for detecting the leaked position.

The pulverized coal detection nozzle 320 is connected to the end of the heat resisting hose 310 and is inserted into the damaged filter fabric 110 sensed by the pulverized coal leakage sensing unit 200 to suck gas corresponding to the position of the filter fabric 110, 310 to the pulverized coal concentration meter 240.

The length adjuster 330 adjusts the length of the heat resistant hose 310 so that the heat resistant hose 310 extends to the inside of the filter cloth 110 so that the pulverized coal detecting nozzle 320 can be positioned below the filter cloth 110 .

The length adjuster 330 can be adjusted in length by rotating the heat resistant hose 310 in the form of a reel 331 by a motor 332 and winding or releasing the heat resistant hose 310 .

The method of winding or releasing the heat resistant hose 310 by the reel 331 is possible by forward rotation or reverse rotation of the motor 332. [

In the embodiment of the present invention, an encoder (not shown) is coupled to the reel 331 to grasp the length of the filter 310. The heat resisting hose 310 is released by the length of the filter cloth 110, The lower portion of the filter cloth 110 is lowered and then the reel 331 is gradually wound up to raise the pulverizer detection nozzle 320 while sucking the gas passing through the filter cloth 110 according to the height of the filter cloth, To the concentration meter 240.

The pulverized coal concentration meter 240 transmits the concentration of the pulverized coal that is sucked according to the position of the filter cloth 110 to the control unit 500 and determines the concentration based on the concentration criterion. It is judged whether or not it is equal to or higher than a predetermined concentration value.

At this time, it is preferable that the height of the nozzle 310 for detecting the powdered coal in the filter cloth 110 is synchronized with the judgment of the controller 500.

In addition, it is preferable that the length adjuster 330 raises the pulverizing coal detecting nozzle 320 by the height set by the user. In other words, it is preferable that the pulverizing coal detecting nozzle 320 is not moved continuously but is elevated to a certain height at regular time intervals.

In order to insert the pulverized coal detection nozzle 320 into the damaged filter cloth 110, the position of the heat resistant tub 310 including the pulverized coal detection nozzle 320 and the length adjuster 330 is changed to the damaged filter cloth 110, The position should be adjusted to the top.

To this end, the first guide unit 340, the horizontal movement unit 350, and the cylinder unit 360 are further included.

The first guide portion 340 is spaced apart from the pulverized coal collecting portion 100 so that the first guide portion 340 can be moved in one direction without being separated in the other direction toward the upper end of the pulverized coal collecting portion 100.

The horizontal moving part 350 is coupled to the first guide part 340 and horizontally moves the upper end of the pulverized coal collecting part 100 along the first guide part 340. That is, the first guide part 340 is moved along the X axis.

The cylinder unit 360 is positioned at the upper end of the horizontal moving unit 350 and moves to the row where the corresponding filter cloth 110 is damaged by the horizontal moving unit 320, So that the pulverized coal detection nozzle 320 connected to the end of the heat resisting hose 310 can be inserted into the filter cloth 110. [

That is, the length adjusting part 330 is coupled to the cylinder part 360, and the length adjusting part 330 can be moved to the corresponding row by adjusting the length of the cylinder part 360.

Accordingly, when the length adjuster 330 coupled to the cylinder 360 is moved along the X axis by the first guide unit 340, it is moved in the Y axis by the cylinder 360.

The sealing part 400 may be provided on the inner side of the pulverized coal collecting part 100 as a separation wall 130 or on the side of the pulverized coal collecting part 100, The position where the pulverized coal of the pulverizer 110 is leaked is sealed to prevent the pulverized coal from leaking to the damaged region.

That is, the damaged portion is sealed by the banding treatment so that the pulverized coal is not introduced through the damaged portion.

The separating wall 130 can be opened and closed by being moved up and down by the separating wall moving part 140 and closed when the sealing part 400 is not used.

4 to 6, the sealing part 400 includes a second guide part 410, a vertical moving part 420, a second horizontal moving part 430, a first cylinder 441, a second The second electromagnet 451, the first lid 461, the second lid 462, the first permanent magnet 481, and the second permanent magnet 482 ).

The second guide part 410 is formed on one side surface so as to be spaced apart from the pulverized coal collecting part 100 and to be moved in one direction without being separated. If the first guide part 340 of the leakage position detecting part 300 is installed on the X axis with respect to the pulverized coal collecting part 100, the second guide part 410 of the sealing part 400 is installed in the Y axis desirable.

The vertical movement unit 420 moves the second guide unit 410 vertically by forming the second guide unit 410 in one direction. That is, the second guide unit 410 is moved in the Z-axis direction.

The second horizontal moving part 430 is coupled to the second guide part 410 and moves in the Y axis direction along the second guide part 410.

The first cylinder 441 and the second cylinder 442 are coupled to the second horizontal movement unit 430 and the first cylinder 441 and the second cylinder 442 are spaced apart from each other by a predetermined distance.

The first cylinder 441 and the second cylinder 442 are moved in the Y axis by the second horizontal moving part 430 while the lengths of the first cylinder 441 and the second cylinder 442 are adjusted in the X axis It is possible. That is, the sealing part 400 can move in the X-axis, the Y-axis, and the Z-axis by the vertical moving part 420, the second horizontal moving part 430 and the cylinders 441 and 442.

The first electromagnet 451 and the second electromagnet 452 are provided at the ends of the first cylinder 441 and the second cylinder 442 respectively and are operated through control through the control unit 500.

The first lid 461 and the second lid 462 are coupled to the first electromagnet 451 and the second electromagnet 452 respectively and have a silicon 470 inside.

A hollow is formed on the inner side even when the first lid part 461 and the second lid part 462 provided with the silicon 470 are coupled to each other.

The first lid part 461 and the second lid part 462 correspond to each other in a semi-donut form and the silicon lid 470 provided inside the first lid part 461 and the second lid part 462, It is also desirable to have a semi-donut form.

In such a configuration, the damaged filter fabric 110 is positioned between the grooves and the grooves inside the first and second cover parts 461 and 462, and the first and second cover parts 461 and 462 So that the bending process can be performed.

At this time, the sealing force of the filter fabric 110 damaged by the silicon 470 provided inside the first and second cover parts 461 and 462 is increased.

The first permanent magnet 481 and the second permanent magnet 482 may have different polarities on the contacting surfaces when the first lid 461 and the second lid 462 are engaged so that the first lid 461 And the second cover portion 462 can be engaged with each other.

That is, if the first permanent magnet 481 coupled to the first lid 461 has the N polarity, the second permanent magnet 482 coupled to the second lid 462 has the S polarity.

The position where the sealing unit 400 bends includes information on the position of the filter cloth 110 detected through the pulverized coal leakage detector 200 and the position of the filter cloth 110 detected by the leak position detector 300 The upper end of the leakage position of the filter cloth 110 received from the control unit 500 can be banded.

7, the control unit 500 controls the configurations of the pulverized coal leakage detection unit 200, the leakage position determination unit 300, and the closure unit 400, and more specifically, the pulverized coal leakage detection unit 200 detects the pulverized coal concentration of the gas detected by each of the filter cloths 110 by the pulverized coal concentration meter 240 and judges whether the filter cloth 110 is damaged by the detected concentration of the filter cloths 110.

That is, if the detected pulverized coal concentration is equal to or greater than a preset reference concentration, the control unit 500 determines that the filter fabric 110 is damaged.

The control unit 500 stores the position of the damaged filter cloth 110 and detects the damaged area of the filter cloth 110 through the leak position determination unit 300. In the case where it is determined that the filter cloth 110 is damaged by the control unit 500, .

When the pulverized coal concentration of the gas is detected by the pulverized coal concentration meter 240 according to the height of the filter cloth 110, the controller 500 determines whether the concentration reference of each height is normal according to the pulverized coal concentration standard, Locate the leak location.

Here, the controller 500 determines a portion of the pulverized coal 110 having a predetermined reference concentration or higher, which is differently detected depending on the height of the filter fabric 110.

The control unit 500 activates the sealing unit 400 to detect the damaged portion of the filter fabric 110 so that the first lid unit 461 and the second lid unit 462 of the closing unit 400 Bending is performed on the upper part of the damaged area by adjusting control so that it can be positioned.

Therefore, the leakage preventing device by blasting the blast furnace dust collecting filter of the present invention has the effect of reducing bad influence on the operation and remarkably raising the productivity by preventing the filtering cloth breaking portion in a short time without stopping the pulverized coal manufacturing facility.

In addition, the present invention can detect leakage of the pulverized coal to the atmosphere by detecting the filter bleeder region at an early stage, and it is possible to prevent safety accidents in the conventional method There is a practical effect.

The above-described system for preventing fine particle leakage of the filter fabric is not limited to the construction and the operation of the embodiments described above. The embodiments may be configured so that all or some of the embodiments may be selectively combined so that various modifications may be made.

100: pulverized coal collecting part 110: filter cloth
120: pulsating section 121: nitrogen pulse tube
122: Nitrogen pump 123: Pulsating valve
130: separating wall 140: separating wall moving part
200: an internal combustion engine leakage detection unit 210: individual piping
220: main piping 230: valve
240: Pulverized coal concentration meter 300:
310: Heat-resistant hose 320: Pulverized coal detection nozzle
330: length adjusting portion 331: reel
332: motor 340: first guide portion
350: first horizontally moving part 360:
400: sealing part 410: second guide part
420: vertical moving part 430: second horizontal moving part
441: first cylinder 442: second cylinder
451: first electromagnet 452: second electromagnet
461: first lid part 462: second lid part
470: Silicon 481: First permanent magnet
482: second permanent magnet 500: control part

Claims (11)

A pulverized coal collector for collecting pulverized coal through a filter cloth provided in a row inside;
A fine particle leakage detecting unit for detecting a gas emitted from the arranged filter cloth and detecting damage of the filter cloth based on the concentration of the fine particle;
A leakage position grasping unit for grasping a position where the fine coal is leaked from the filter cloth; And
And a sealing part for sealing the leakage position of the pulverized coal in the filter fabric grasped by the leakage position grasping part,
The sealing portion
First and second cylinder portions for adjusting the length in the horizontal direction,
A vertical moving part for vertically moving the first and second cylinder parts;
A first electromagnet and a second electromagnet provided at respective ends of the first and second cylinders; And
And first and second lid parts respectively coupled to the electromagnets, each of the first and second lid parts being provided with silicon on the inside thereof and hollow inside when coupled to each other.
The method according to claim 1,
The pulverized coal collecting unit includes a nitrogen pulsation pipe connected to each of the filter sheets;
A nitrogen pump for collectively delivering nitrogen to the nitrogen pulsation pipe; And
And a pulsation valve for controlling the amount of nitrogen introduced into the nitrogen pulsation pipe by the nitrogen pump,
Wherein the pulsating section periodically and collectively injects nitrogen into the filter cloth to perform pulsation.
The method according to claim 1,
Wherein the pulverized coal leakage detecting unit includes a pulverized coal concentration meter for measuring the concentration of pulverized coal conveyed through the piping unit connected to the arranged filter fabric,
And a control unit for detecting a pulverized coal leaking state by comparing the measured value with a predetermined value through a numerical value measured in the pulverized coal concentration meter.
The method according to claim 3,
The leaking position determination unit includes a heat resistant hose connected to the CO concentration meter;
A nozzle for detecting the powdered coal connected to the end of the heat resistant hose; And
And a length adjuster for adjusting the length of the heat-resistant hose.
The method of claim 4,
Wherein the detection nozzle connected to the end of the heat-resistant hose controlled by the length adjuster transmits the information of the pulverized coal sucked in accordance with the position of the filter cloth to the pulverized coal concentration meter to determine whether the pulverized coal is pulverized. .
The method of claim 5,
The control unit controls the operations of the pulverized coal leakage detecting unit, the leak position locating unit and the closing unit, and transmits the numerical value of the pulverized coal that is detected according to the internal position of the filter cloth to the control unit, ,
Wherein when the detected value of the pulverized coal is not less than a predetermined value, the operation of the length adjuster is stopped to determine the pulverized coal leakage area of the filter fabric.
delete delete The method according to claim 1,
Wherein the first and second lid parts are coupled to each other by a first permanent magnet and a second permanent magnet having different polarities on a contact surface when the first and second lid parts are engaged.
The method according to claim 1 or 9,
Wherein the first and second lid portions with the silicone seal each other at a position where the pulverized coal fines are combined with each other at a position where the pulverized coal is leaked to seal the leaked position of the pulverized coal.
The method according to claim 1,
Wherein a separation wall is provided on the inner side of the pulverized coal collecting part so as to be separated from the closed part, and the separation wall is moved up and down.

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