KR101303918B1 - Scrubbing apparatus for exhaust gas - Google Patents

Abstract

The present invention relates to an exhaust gas treating apparatus.
An exhaust gas treating apparatus according to an embodiment of the present invention includes an exhaust gas treating apparatus for treating the exhaust gas by collecting dust contained in the exhaust gas, wherein the exhaust gas cooling unit includes an exhaust gas introduced therein; Coolant flows, and the plurality of coolant injection nozzles are formed so that the flowing coolant is injected in the cooling unit, wherein the coolant injection nozzles adjacent to the inner wall of the exhaust gas cooling unit of the coolant injection nozzles Cooling water supply passage characterized in that it is formed to be directed downward toward the center; A washing water injection unit into which the exhaust gas passing through the exhaust gas cooling unit is introduced into the inside, and the washing water is injected to contact the dust included in the exhaust gas to collect the dust; A washing water supply passage including washing water spray nozzles for flowing the washing water and spraying the washing water; And a neck portion through which the exhaust gas passing through the washing water injection unit is formed to have a flow passage area smaller than the flow passage area of the washing water injection unit, so that the pressure of the introduced exhaust gas is reduced. A dust separation unit formed to have a flow passage area larger than the flow passage area of the neck portion, and through which the exhaust gas passing through the neck portion flows, in which the dust contacted with the washing water is separated from the exhaust gas; And an exhaust gas discharge part communicating with the dust separation part to discharge the exhaust gas from which the dust is separated to the outside.

Description

Scrubbing apparatus for exhaust gas

The present invention relates to an exhaust gas treating apparatus for treating dust contained in exhaust gas.

Exhaust gas according to the product production process in the plant contains a large number of dust, and if the exhaust gas containing the dust is discharged to the atmosphere without a separate treatment process causes serious air pollution.

Therefore, the exhaust gas is generally discharged to the atmosphere through a process of collecting dust, and the exhaust gas treatment apparatus for performing the exhaust gas treatment process may be formed in various forms such as wet, filtered, or electrostatic precipitating. Can be.

On the other hand, when the dust of the exhaust gas is explosive, highly corrosive or high temperature dust, a wet exhaust gas treatment apparatus is used, and the wet exhaust gas treatment apparatus sprays a cleaning liquid for collecting dust to the exhaust gas. Thus, the exhaust gas is treated.

An object of the present invention is to provide an exhaust gas treatment apparatus that effectively treats dust contained in exhaust gas and increases durability.

An exhaust gas treating apparatus according to the present invention for achieving the above object is an exhaust gas treating apparatus for treating the exhaust gas by collecting dust contained in the introduced exhaust gas, and exhaust gas into which the exhaust gas is introduced. Cooling unit; Coolant flows, and the plurality of coolant injection nozzles are formed so that the flowing coolant is injected in the cooling unit, wherein the coolant injection nozzles adjacent to the inner wall of the exhaust gas cooling unit of the coolant injection nozzles Cooling water supply passage characterized in that it is formed to be directed downward toward the center; A washing water injection unit into which the exhaust gas passing through the exhaust gas cooling unit is introduced into the inside, and the washing water is injected to contact the dust included in the exhaust gas to collect the dust; A washing water supply passage including washing water spray nozzles for flowing the washing water and spraying the washing water; And a neck portion through which the exhaust gas passing through the washing water injection unit is formed to have a flow passage area smaller than the flow passage area of the washing water injection unit, so that the pressure of the introduced exhaust gas is reduced. A dust separation unit formed to have a flow passage area larger than the flow passage area of the neck portion, and through which the exhaust gas passing through the neck portion flows, in which the dust contacted with the washing water is separated from the exhaust gas; And an exhaust gas discharge part communicating with the dust separation part to discharge the exhaust gas from which the dust is separated to the outside.

In addition, the cooling water supply passage, at least one main pipe; And a plurality of auxiliary pipes branched from the main pipe.

The main pipe may be arranged to cross the exhaust gas cooling unit, and the cooling water injection nozzles disposed at both ends of the cooling water injection nozzles disposed in the main pipe may be disposed with downward injection holes, and at the same time, the exhaust gas cooling unit may be directed toward the center of the exhaust gas cooling unit. And the auxiliary pipes branched from the main pipe in the direction of the inner wall of the exhaust gas cooling part to extend in a direction crossing the extending direction of the main pipe, and among the cooling water injection nozzles formed in the auxiliary pipes. The coolant injection nozzle located closest to the distal end of the auxiliary pipe extending toward the inner wall of the exhaust gas cooling unit with respect to the main pipe may be disposed so that the injection hole is downward and deflected toward the center of the exhaust gas cooling unit. have.

In addition, the plurality of main pipes may be arranged to cross the exhaust gas cooling unit, and the cooling water injection nozzles disposed at both ends of the plurality of cooling water injection nozzles disposed in the main pipe may have downward injection holes, and at the same time, the exhaust gas. The auxiliary pipe is branched from the main pipe in the direction of the central portion or the inner wall of the exhaust gas cooling unit, and extends in a direction intersecting with an extension direction of the main pipe, from the main pipe. Among the auxiliary pipes extending in the direction of the inner wall of the exhaust gas cooling unit, the cooling water injection nozzle located closest to the distal end of the auxiliary pipe adjacent to the inner wall of the exhaust gas cooling unit is disposed with a spray hole downward, and simultaneously deflects toward the center of the exhaust gas cooling unit. To be arranged .

The apparatus may further include a flow passage area adjusting unit for adjusting a flow passage area of the neck portion by opening or closing a portion of the neck portion.

In addition, the flow passage area control unit, the drive motor is provided in a fixed state on the outside of the neck portion, generating a rotational force; A rotation shaft connected to the drive motor and rotated by the rotational force, and having a spiral groove formed on an outer circumferential surface thereof; Is partially provided through the inner wall of the neck portion is inserted into the neck portion in a linear motion, the rotation shaft fixing groove is formed on one side to be rotatably engaged with the rotary shaft, is generated in the drive motor It may include; an area control unit for adjusting the flow passage area of the neck portion in accordance with the movement in one direction or the other direction by the rotational force.

In addition, the area adjusting unit may be disposed to be inclined so that the other side of the area adjusting unit is directed downward.

In addition, the drive motor, the rotation shaft, the area control unit may be provided in a pair symmetrical to each other.

The dust separator may further include a dust collecting part which is opened downward and is installed below the dust separating part and accommodates the collecting water for collecting the dust separated from the exhaust gas.

In addition, extending from the lower side of the dust separation portion is formed to extend downward so as to be immersed in the collection water, the extension pipe for providing a flow path for the dust flow from the dust separation portion to the collection water; may further include.

According to the proposed embodiment, in the exhaust gas treatment process for treating the exhaust gas by collecting the dust contained in the exhaust gas, there is an advantage that can minimize the damage of the exhaust gas treatment device and increase the exhaust gas treatment efficiency.

1 is a view showing an exhaust gas treating apparatus according to an embodiment of the present invention.
2 is a cross-sectional view of the exhaust gas treating apparatus of FIG. 1.
3 is a cross-sectional view taken along line III-III of FIG. 2;
4 is a cross-sectional view taken along line IV-IV of FIG.
5 is a cross-sectional view taken along the V-V diagram of FIG. 3.
6 and 7 is a view showing the operating state of the flow passage area adjustment unit of FIG.

Hereinafter, with reference to the accompanying drawings, it will be described in detail a preferred embodiment according to the present invention.

1 is a view showing an exhaust gas treatment apparatus according to an embodiment of the present invention, Figure 2 is a view showing a cross section of the exhaust gas treatment apparatus of FIG. 3 is a cross-sectional view taken along the III-III diagram of FIG. 2, and FIG. 4 is a cross-sectional view taken along the IV-IV diagram of FIG. 2. In addition, Figure 5 is a cross-sectional view taken along the V-V diagram of Figure 3, Figure 6 and Figure 7 is a view showing the operating state of the flow passage area adjusting portion of FIG.

The exhaust gas E1 may be generated during the production of raw materials such as quicklime or coke or fuel combustion for the production process, and the exhaust gas E1 includes fine particles of dust.

The dust is, for example, 0.01 μm to 100 μm in size, and when discharged into the atmosphere without a separate treatment, it causes environmental pollution such as smog.

1 to 6, the exhaust gas treating apparatus 1 according to the embodiment of the present invention is to treat the exhaust gas E1 by collecting dust contained in the exhaust gas E1. It may be provided as a wet exhaust gas treatment apparatus for collecting dust using the washing water (W2).

The exhaust gas treatment device 1 includes an exhaust gas cooling unit 11, a washing water injection unit 12, a neck unit 13, a dust separation unit 14, a dust collection unit 18, And an extension tube 19, a cooling water supply passage 16, a washing water supply passage 17, a flow passage area adjusting unit 15, and a cooling water / clean water supply unit 20, and a fluid flow The cross-sectional area, that is, the magnitude of the flow passage area may vary depending on the direction.

In more detail, the exhaust gas cooling unit 11 may be formed, for example, in a cylindrical shape in which a flow path through which the exhaust gas E1 may flow is formed. In the exhaust gas cooling unit 11, the coolant W1 is injected while the high temperature exhaust gas E1 flows into the washing water injection unit 12 while the coolant W1 is injected and the exhaust gas E1 is cooled. Flows towards.

In the cooling water supply passage 16, the cooling water W1 flows from the cooling water / clean water supply unit 20 to allow the cooling water W1 to be supplied into the exhaust gas cooling unit 11. At this time, the cooling water supply flow path 16 allows the cooling water W1 to be injected in a state where a part thereof passes through the exhaust gas cooling unit 11 and is located inside the exhaust gas cooling unit 11.

The cooling water supply passage 16 may be formed of a plurality of pipes arranged in a vertical direction and a horizontal direction with respect to the exhaust gas cooling unit 11. In this embodiment, the cooling water supply passage 16 may be vertically vertical. In three rows in the direction and two rows in the horizontal direction.

In addition, the cooling water supply passage 16 may include a main pipe 165 penetrating the wall surface of the exhaust gas cooling unit 11 in a horizontal direction, and a plurality of auxiliary pipes 166 branched from one main pipe 165. Include. At this time, the auxiliary pipes 166 are formed to extend in a direction crossing the main pipe 165 extending direction, the direction in which the main pipe 165 and the auxiliary pipe 166 extend is the exhaust gas cooling unit 11 Is formed in a direction crossing with respect to the direction in which the exhaust gas (E) flows. This is to increase the cooling efficiency of the exhaust gas E1 by efficiently contacting the cooling water W1 injected from the cooling water supply passage 16 and the flowing exhaust gas E1.

In addition, the cooling water supply passage 16 includes a plurality of cooling water injection nozzles 161 and 163 in which the injection holes 162 and 164 are formed to spray the flowing cooling water W1.

On the other hand, in the cooling water injection nozzles 161 and 163, the high pressure cooling water W1 is injected toward the inside of the exhaust gas cooling unit 11, and the high pressure sprayed cooling water W1 is the inner wall 111 of the exhaust gas cooling unit 11. ), The inner wall 111 is worn, and the exhaust gas cooling unit 11 may be damaged. In addition, when the acidic water or the slurry is supplied as the cooling water W1, the wear of the inner wall 111 and the possibility of damage of the exhaust gas cooling unit 11 are further increased.

Therefore, of the coolant injection nozzles 161 and 163 of the exhaust gas treating apparatus 1 according to the embodiment of the present invention, the first coolant injection nozzle 161 most adjacent to the inner wall 111 of the exhaust gas cooling unit 11 is provided. They are formed to be inclined by a predetermined angle θ so as to be directed downward toward the center axis L, that is, the center of the exhaust gas cooling unit 11.

Meanwhile, other cooling water injection nozzles 163 other than the first cooling water injection nozzles 161, that is, the second coolant injection nozzles 163 which are not adjacent to the inner wall 111 of the exhaust gas cooling unit 11, are directed downward. It is formed to be oriented.

Accordingly, the first coolant injection nozzles 161 adjacent to the inner wall 111 may be cooled in a direction inclined toward the center of the exhaust gas cooling unit 11 such that the coolant W1 injected does not directly contact the inner wall 111. By spraying (W1), damage to the exhaust gas cooling unit 11 due to wear of the inner wall 111 can be minimized.

In addition, by allowing the cooling water W1 to be injected toward the center portion of the exhaust gas cooling unit 11 where the flow amount of the exhaust gas E1 is relatively higher, the cooling efficiency of the exhaust gas E1 can be increased.

Although the first coolant jetting nozzle 161 and the second coolant jetting nozzle 163 according to the present exemplary embodiment are described in an exemplary embodiment in the main pipe 165 according to the distance from the inner wall 111, The configuration in which the first coolant jet nozzle 161 and the second coolant jet nozzle 163 are formed in the auxiliary pipe 166 will also be included in the embodiment of the present invention.

That is, the plurality of main pipes 165 are disposed to cross the exhaust gas cooling unit 11, and the coolant injection nozzles 161 disposed at both ends of the plurality of coolant injection nozzles 161 and 163 disposed on the main pipe 165. The injection hole 162 is disposed downward, and at the same time, the injection hole 162 is disposed to be deflected toward the center portion of the exhaust gas cooling unit 11. In addition, the auxiliary pipe 166 branches from the main pipe 165 in the direction of the central portion or the inner wall of the exhaust gas cooling unit 11 and extends in the direction crossing the extension direction of the main pipe 165, and the main pipe 165. Coolant injection nozzle 161 located closest to the distal end of the auxiliary pipe 166 adjacent to the inner wall of the exhaust gas cooling unit 11 among the auxiliary pipes 166 extending in the inner wall direction of the exhaust gas cooling unit 11). The injection port 162 is disposed downward, and at the same time, the injection port 162 is disposed to be deflected toward the center portion of the exhaust gas cooling unit 11.

In addition, the exhaust gas treating apparatus 1 according to the present embodiment is described as having a plurality of main pipes 165 installed, but only one main pipe 165 is also included in the embodiment of the present invention. something to do.

When one main pipe 165 is installed in the exhaust gas cooling unit 11, the main pipe 165 is arranged to cross the central portion of the exhaust gas cooling unit 11, and is arranged in the main pipe 165. The cooling water injection nozzles 161 disposed at both ends of the plurality of cooling water injection nozzles 161 and 163 are disposed with the injection holes 162 downward, and at the same time, the injection holes 162 are directed toward the center of the exhaust gas cooling unit 11. It is arranged to be deflected. In addition, the auxiliary pipes 166 branch from the main pipe 165 in the direction of the inner wall of the exhaust gas cooling unit 11 and extend in a direction intersecting with an extension direction of the main pipe 165. Among the coolant spray nozzles 161 and 163 formed therein, the coolant spray nozzle 161 located closest to the distal end of the auxiliary pipe 166 extending toward the inner wall of the exhaust gas cooling unit 11 with respect to the main pipe 165 is The injection port is disposed below, and at the same time, the injection port is arranged to be deflected toward the center portion of the exhaust gas cooling unit 11.

On the other hand, the washing water injection unit 12 is in communication with the exhaust gas cooling unit 11 so that the exhaust gas E1 cooled through the exhaust gas cooling unit 11 flows into the inside, and the washing water injection unit 12 The washing water W2 is sprayed into the dust by contacting the dust contained in the exhaust gas E1 to collect the dust.

The washing water supply passage 17 is for injecting the washing water W2 into the washing water injection unit 12, and the washing water supply passage 17 is cleaned from the cooling water / cleaning water supply unit 20 inside the washing water supply passage 17. The water W2 flows and the washing water W1 is supplied into the exhaust gas cooling unit 11.

The washing water supply passage 17 includes a plurality of washing water spray nozzles 171 to which the washing water W2 is sprayed. In this case, the plurality of washing water injection nozzles 171 are included in the exhaust gas E1 by causing the washing water W2 to be sprayed to be sprayed in one direction, for example, counterclockwise, inside the washing water injection unit 12. The dust is disposed to give a moment capable of collecting by a cyclone dust collecting method.

On the other hand, the cooling water / clean water supply unit 20 supplies the cooling water W1 and the washing water W2 to the cooling water supply passage 16 and the washing water supply passage 17, respectively. At this time, the cooling water (W1) and the washing water (W2) may be formed of the same material or different materials according to the cooling requirements or the type of dust collected.

The neck portion 13 is formed to have a flow passage area smaller than the flow passage area of the washing water injection unit 12, and the exhaust portion E1 passing through the washing water injection unit 12 flows into the neck portion 13. . In this case, the flow passage area means substantially the cross-sectional area of the internal flow path of the washing water injection unit 12 through which the exhaust gas E1 passes and the cross-sectional area of the internal flow path of the neck portion 13.

The exhaust gas E1 flowing into the neck portion 13 contains the dust, the cooling water W1 and the washing water W2, and the exhaust gas passing through the neck portion 13 as the flow passage area is reduced. The pressure of the gas E1 is reduced and the speed is increased. At this time, the pressure and speed of the exhaust gas E1 in the neck portion 13 are referred to as the neck portion passage pressure and the neck portion passage speed, respectively.

Therefore, atomization of the cooling water W1 and the washing water W2 flowing together with the exhaust gas E1 is accelerated, and the particles of the atomized cooling water W1 and the washing water W2 and the dust are accelerated. Contact and collision are increased, and dust collection can be performed efficiently.

At this time, the flow passage area adjusting part 15 opens or closes a part of the neck portion 13, thereby adjusting the flow passage area of the neck portion 13 to adjust the passage pressure and the passage speed of the exhaust gas E1. do. That is, according to the pressure and the speed of the exhaust gas E1 flowing into the exhaust gas treating apparatus 1 according to the embodiment of the present invention, the neck portion passage pressure and the neck portion of the exhaust gas E1 in the neck portion 13 By adjusting the passing speed, the dust collecting efficiency of the dust can be increased.

The flow passage area adjusting part 15 is provided in a fixed state on the outside of the neck portion 13 and is connected to the driving motor 153 for generating the rotational force and the driving motor 153 and rotated by the rotational force and the outer circumferential surface thereof. The rotating shaft 155 is formed in the spiral groove, and the area adjusting unit 152 is provided to be slidably movable in accordance with the rotation of the rotary shaft 155.

The drive motor 153, the rotation shaft 155, and the area control unit of the exhaust gas treating apparatus 1 according to the present embodiment may be provided in a pair symmetrical with each other.

The area adjusting unit 152 is provided to be linearly movable in a state in which a portion of the area adjusting unit 152 is inserted into the neck portion 13 through the inner wall of the neck portion 13. And, one side of the area control unit 152 is formed with a rotary shaft fixing groove 154 is rotatably engaged with the rotary shaft 155. Therefore, the area control unit 152 is moved in one direction or the other direction toward the central axis L by the rotational force generated by the driving motor 153, thereby adjusting the flow passage area of the neck portion 13.

In this case, the area adjusting unit 152 may be disposed in a direction crossing at an angle with respect to the flow direction of the exhaust gas E1 passing through the neck portion 13. That is, the other side of the area control unit 152 is inclined so as to be directed downward, so as to be in contact with the exhaust gas (E1) obliquely, it is possible to further increase the scrubbing effect of the exhaust gas (E1).

In addition, as the area control unit 152 slides obliquely with respect to the flow direction of the exhaust gas E1, the interference of the movement of the area control unit 152 by the flow of the exhaust gas E1 may be minimized. There is an advantage to that.

On the other hand, the dust separation unit 14 is formed to have a flow passage area larger than the flow passage area of the neck portion 13, and the exhaust gas (E1) having passed through the neck portion 13 to the dust separation portion 14 is As it is introduced, the dust in contact with the washing water (W2) can be separated from the exhaust gas (E1).

The exhaust gas E2 from which the dust is separated is discharged to the outside of the exhaust gas treatment device 1 through the exhaust gas discharge unit 141 communicating with the dust separator 14 from the side, and is discharged from the exhaust gas E2. The dust (d) to be separated flows downward.

The lower side of the dust separation unit 14 is opened downward, and the dust d flowing downward is collected in the dust collection unit 18 provided below the dust separation unit 14. At this time, the dust collecting unit 18 is accommodated in the collecting water (W3) for collecting the dust (d).

In addition, the extension pipe 19 extends downward from the lower side of the dust separation unit 14 to be submerged in the collection water W3, and the dust d is collected from the dust separation unit 14 (W3). It provides a flow path to the flow.

On the other hand, although not shown in the drawings, the cooling water W1 and the washing water W2 for cooling the exhaust gas E1 and scrubbing the dust d from the exhaust gas E1 are dust in the dust separation unit 14. It may flow downward with (d) and be collected in the collection water W3.

That is, even if fine particles such as dust (d), cooling water (W1), and washing water (W2) move downward at a high flow rate, the fine particles do not wear the inner wall of the exhaust gas treatment device 1, It may be collected in the dust collector 18.

At this time, the cooling water W1 and the washing water W2 collected in the collection water W3 may be supplied to the cooling water / clean water supply unit 20 after reprocessing.

According to the proposed embodiment, in the exhaust gas treatment process for treating the exhaust gas by collecting the dust contained in the exhaust gas, there is an advantage that can minimize the damage of the exhaust gas treatment device and increase the exhaust gas treatment efficiency.

Although the above has been illustrated and described with respect to the preferred invention of the present invention, the invention is not limited to the specific embodiments described above, it is common in the art to which the invention belongs without departing from the spirit of the invention claimed in the claims. Various modifications may be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or the scope of the present invention.

1: exhaust gas treatment device 11: exhaust gas cooling unit
12: washing water injection portion 13: neck portion
14: dust separation unit 15: flow passage area control unit
16: cooling water supply passage 17: washing water supply passage
18: dust collection unit 19: extension tube
20: cooling water / clean water supply unit

Claims (10)

An exhaust gas treatment apparatus for treating the exhaust gas by collecting dust contained in the exhaust gas,
An exhaust gas cooling unit into which exhaust gas is introduced;
Coolant flows, and the plurality of coolant injection nozzles are formed so that the flowing coolant is injected in the cooling unit, wherein the coolant injection nozzles adjacent to the inner wall of the exhaust gas cooling unit of the coolant injection nozzles Cooling water supply passage characterized in that it is formed to be directed downward toward the center;
A washing water injection unit into which the exhaust gas passing through the exhaust gas cooling unit is introduced into the inside, and the washing water is injected to contact the dust included in the exhaust gas to collect the dust;
A washing water supply passage including washing water spray nozzles for flowing the washing water and spraying the washing water; And
A neck portion through which the exhaust gas passing through the washing water spraying unit is introduced, and having a flow rate passing area smaller than that of the washing water spraying unit, to reduce the pressure of the introduced exhaust gas;
A dust separation unit formed to have a flow passage area larger than the flow passage area of the neck portion, and through which the exhaust gas passing through the neck portion flows, in which the dust contacted with the washing water is separated from the exhaust gas; And
And an exhaust gas discharge part communicating with the dust separation part so that the exhaust gas from which the dust is separated is discharged to the outside.
The cooling water supply flow path,
At least one main pipe; And
And a plurality of auxiliary pipes branched from the main pipe.
The main pipe is arranged to cross the exhaust gas cooling unit,
The cooling water injection nozzles disposed at both ends of the cooling water injection nozzles disposed in the main pipe are disposed such that the injection holes are disposed downward and are deflected toward the center of the exhaust gas cooling unit at the same time.
The auxiliary pipes branch from the main pipe in the direction of the inner wall of the exhaust gas cooling part and extend in a direction crossing the extension direction of the main pipe,
Among the coolant injection nozzles formed in the auxiliary pipes, the coolant injection nozzles located closest to the distal end of the auxiliary pipe extending toward the inner wall of the exhaust gas cooling unit with respect to the main pipe are disposed with a spray hole downward, and simultaneously An exhaust gas treating apparatus, characterized in that arranged to be deflected toward the center portion of the exhaust gas cooling unit. delete delete The method of claim 1,
The plurality of main pipes are arranged to cross the exhaust gas cooler,
The cooling water injection nozzles disposed at both ends of the plurality of cooling water injection nozzles arranged in the main pipe are disposed such that the injection holes are disposed downward and are deflected toward the center of the exhaust gas cooling unit at the same time.
The auxiliary pipe branches from the main pipe in the direction of the central portion or the inner wall of the exhaust gas cooling unit and extends in a direction crossing the extending direction of the main pipe,
Among the auxiliary pipes extending from the main pipe in the direction of the inner wall of the exhaust gas cooling unit, the cooling water injection nozzle located closest to the distal end of the auxiliary pipe adjacent to the inner wall of the exhaust gas cooling unit is disposed with a spray hole downward, and at the same time, the exhaust gas cooling is performed. An exhaust gas treating device, characterized in that it is arranged to be deflected toward the central portion of the part. The method of claim 1,
And a flow passage area adjusting portion for adjusting a flow passage area of the neck portion by opening or closing a portion of the neck portion. The method of claim 5, wherein
The flow passage area control unit,
A driving motor provided in a fixed state on the outside of the neck portion and generating a rotational force;
A rotation shaft connected to the drive motor and rotated by the rotational force, and having a spiral groove formed on an outer circumferential surface thereof;
Is partially provided through the inner wall of the neck portion is inserted into the neck portion in a linear motion, the rotation shaft fixing groove is formed on one side to be rotatably engaged with the rotary shaft, is generated in the drive motor And an area adjusting unit configured to adjust the flow passage area of the neck portion as it is moved in one direction or the other direction by a rotational force. The method according to claim 6,
The area control unit, the exhaust gas treatment device is disposed to be inclined so that the other side of the area control unit is directed downward. The method according to claim 6,
The driving motor, the rotation shaft, the area control unit is provided with a pair of symmetrical exhaust gas treatment device. The method of claim 1,
The lower side of the dust separation unit is opened downwards,
And a dust collecting unit disposed below the dust separating unit and configured to accommodate the collecting water for collecting the dust separated from the exhaust gas. The method of claim 9,
And an extension tube extending downward from the lower side of the dust separator so as to be immersed in the collected water and providing a flow path through which the dust flows from the dust separator to the collected water.

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