KR101596255B1 - Brush type soot removing module for selective catalytic reduction system - Google Patents

Abstract

According to the present invention, a brush apparatus for removing a particulate material for a selective catalytic reduction system comprises: a brush unit which is arranged on a front of a catalyst carrier for processing exhaust gas, and brushes off a particulate material attached to a front surface of the catalyst carrier by a movement; and a drive unit to move the brush unit. The drive unit comprises: a screw which is extended in a vertical direction, and lifts and lowers the brush unit by rotation; a cover frame which is mounted on a reactor housing fixing the catalyst carrier on the front of the catalyst carrier, and rotatably supports the screw; and a motor unit to provide the screw with driving power from the outside of the cover frame.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a particulate matter removal apparatus for a brush type selective catalytic reduction system,

The present invention relates to an apparatus for removing particulate matter that can be applied to a selective catalytic reduction system such as a ship using a brush.

Emissions regulation of ships has been relatively recent, and IMO (International Maritime Organization) and advanced countries are actively taking measures to deal with them. In the field of NOx reduction in green ship exhaust gas treatment technology to respond to environmental regulations related to shipbuilding and marine industry of International Maritime Organization, selective catalytic reduction (SCR) system with proven performance, safety and economical efficiency Is getting popular.

The SCR system includes a honeycomb-structured catalytic reactor. The catalytic converter is a catalytic reactor in which the exhaust gas, which is a mixture of nitrogen compound (NOx) and ammonia (NH ₃ ), is reduced to produce nitrogen (N ₂ ) . As a material for supporting the catalyst, a ceramic extruded material which is low in cost and easy to mass-produce has been proposed, but a metal carrier having excellent workability and mechanical properties can be manufactured with a thin thickness.

In ships internal combustion engines, large-scale incinerators, energy plants, etc., many low-grade fuels such as unique sulfur oil and bunker oil are often used, resulting in generation of soot and other solid particulate matter and poor combustion conditions. The size of the generated particulate matter is also large and the composition is also various. Such solid particulate matter tends to block the narrow channels of the reactor containing the catalyst, thereby greatly reducing the throughput by reduction. Therefore, it is necessary to periodically remove the particulate matter contained in the reactor to keep the efficiency constant.

A soot blower, which has been conventionally used for the removal of particulate matter, is constructed so as to blow off compressed air or the like in front of the inside of a connection or a carrier to collect soot or remove it. However, in a large-capacity SCR system, the volume and the area of the reactor also increase sharply. Therefore, there is a possibility that the particulate matter is not completely removed by the compressed air injection method, and the possibility of blocking the narrow channel of the carrier is also increased.

SUMMARY OF THE INVENTION The present invention has been made in consideration of the above-mentioned problems, and it is an object of the present invention to provide a particulate selective catalytic reduction apparatus capable of being installed in a selective catalytic reduction reactor having a large capacity, The object of the present invention is to propose a material removing apparatus.

It is another object of the present invention to combine the use of a compressed gas while using an efficient physical removal method to minimize durability degradation and improve removal characteristics.

In order to solve the above problems, an apparatus for removing particulate matter of a brush-type selective catalytic reduction system according to the present invention is disposed in front of a catalyst carrier for treating an exhaust gas, A brush unit formed to be able to remove particulate matter; And a driving unit configured to move the brush unit, wherein the driving unit includes: a screw formed to extend vertically and capable of lifting and lowering the brush unit by rotation; A cover frame coupled to a reactor housing for fixing the catalyst carrier in front of the catalyst carrier, the cover frame being formed to rotatably support the screw; And a motor portion for providing a driving force to the screw from the outside of the cover frame.

As an example related to the present invention, the brush unit may be formed in a bar shape extending in the transverse direction in front of the catalyst carrier.

According to an embodiment of the present invention, the brush unit includes: a brush formed in a shape protruding toward the catalyst carrier; A holder for fixing the brush; And an inner screw which supports the holder and which is lifted and lowered by the rotation of the screw.

As an example related to the present invention, the holder portion may further include an exhaust channel formed such that the exhaust gas can pass therethrough.

As an example related to the present invention, the exhaust channel may be formed in a slot shape.

As an example related to the present invention, the particulate matter removal apparatus of the brush-type selective catalytic reduction system may further include a blower disposed in front of the screw and removing particulate matter accumulated on the screw by compressed air.

As an example related to the present invention, the blower may be formed in a rod shape parallel to the screw, and may have a plurality of injection holes facing the screw.

As an example related to the present invention, the particulate matter removal device of the brush type selective catalytic reduction system may further include a dust collection cartridge disposed below the cover frame so that the particulate matter removed by the brush unit may fall and gather can do.

As an example related to the present invention, the brush may be formed of a metal material.

As an example of the present invention, the motor unit may further include a sealing reinforcing portion disposed on the cover frame and capable of enhancing the hermeticity of the connection portion between the screw and the motor portion. In this case, the sealing reinforcing portion may include a plurality of discs arranged on an extension of the screw and arranged to have a smaller diameter as the distance from the cover frame increases; And a disc housing formed to surround the plurality of discs.

As an example related to the present invention, the particulate matter removal device of the brush type selective catalytic reduction system may further include a dust collection cartridge disposed below the cover frame so that the particulate matter removed by the brush unit may fall and gather can do.

In an embodiment of the present invention, the dust collecting cartridge is formed in a hopper shape so that the particulate matter can be collected, and a connection portion can be installed at a lower portion of the dust collecting cartridge so that suction equipment can be connected thereto.

According to the particulate matter removal apparatus of the brush-type selective catalytic reduction system according to the present invention, the particulate matter removal device is provided with a brush unit for transferring the entire surface of the catalyst carrier, and is capable of forcibly removing particulate matter and accumulating particulate matter The entire surface of the catalyst carrier can be cleaned at a time. Particularly, it is possible to minimize the presence of an incomplete removal region that can occur as the catalyst carrier is enlarged and the deterioration of the processing efficiency of the exhaust gas accordingly.

According to one embodiment of the present invention, the brush unit is conveyed by a screw in the reactor housing and an external motor unit, which facilitates maintenance in terms of maintenance of the exhaust gas and solid particles in the reactor, Can be reduced.

According to another embodiment of the present invention, the blower that blows the compressed air together with the brush unit to be conveyed is provided to reliably remove the particulate matter accumulated on the screw.

FIG. 1 is a schematic side cross-sectional view of a large-capacity catalyst carrier reactor 100 to which a particulate matter removal apparatus according to the present invention is applied
2 is a perspective view of an apparatus 200 for removing particulate matter according to the present invention.
3 is a conceptual perspective view of a drive unit 230 that moves the brush unit 220 associated with the present invention
4 is an operational state diagram of the brush unit 220 related to the present invention.
FIG. 5 is a perspective view of another blower 250 and an operating state,
6 is a conceptual cross-sectional view showing the flow of exhaust gas through the exhaust channel 224 of the brush unit 220
7 is a schematic cross-sectional view showing the structure of the tightening reinforcement 260 related to the present invention
8 is a perspective view of the dust-collecting cartridge 340 according to another example of the present invention.
9 is a perspective view of a brush unit 420 according to another example related to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an apparatus for removing particulate matter in a brush-type selective catalytic reduction system according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic cross-sectional side view of a large-capacity catalyst carrier reactor 100 to which a particulate matter removal apparatus according to the present invention is applied.

The reactor 100 is installed at the rear end of an engine or furnace such as a ship, a power plant, or a large-scale plant such as an incinerator and exhaust gas containing nitrogen oxide (NOx) and ammonia (NH ₃ ) Is generated. The reactor 100 is disposed between the exhaust pipes 101 and includes a reactor housing 110 in which a large-capacity catalyst carrier 120 for supporting a catalyst is disposed in a multi-stage or single-stage configuration. The guide structure 102 may be installed between the exhaust pipe 101 and the reactor housing 110 so that the flow path is evenly extended from the exhaust pipe 101 to the front surface of the large-capacity catalyst carrier 120 having a large area.

A particulate matter removal device 200 configured to remove particulate matter accumulated on the entire surface of the catalyst carrier 120 is installed in front of the catalyst carrier 120 during operation of the reactor 100. The particulate matter removal apparatus 200 generally includes a cover frame 210, a brush unit 220, a drive unit 230, and a dust collection cartridge 240. The brush unit 220 is formed to be capable of forcibly blowing particulate matter (solid matter, soot, etc.) accumulated on the entire surface of the catalyst carrier 120 while being vertically transported by the driving unit 230. The particulate matter dropped downward is collected in the dust collecting cartridge 240, and is extracted and processed to the outside. Since the particulate matter removal device 200 can form the brush unit 220, which is a moving element in the reactor, in a slender shape, it is easy to manufacture the particulate matter removal device 200 in a slim form, and the brush unit 220 is driven The exhaust gas leaking in the reactor 100 can be operated.

3 is a conceptual perspective view of a drive unit 230 for moving the brush unit 220 associated with the present invention, and Fig. 4 is a perspective view of the particulate matter removal apparatus 200 according to the present invention. 5 is a perspective view showing another blower 250 and an operating state according to an embodiment of the present invention, and Fig. 6 is a perspective view showing the state of the brush unit 220 passing through the exhaust channel 224 of the brush unit 220 Sectional view showing the flow of the exhaust gas.

The cover frame 210 is formed to be able to be coupled to the reactor housing 110 at the front of the catalyst carrier 120 and guides the brush unit 220 so that the brush unit 220 can be moved therein. As the size of the catalyst carrier 120 increases, a rectangular catalyst carrier 120 may be used, which is easily modularized and assembled. Accordingly, the reactor housing 110 may have a rectangular shape. Thus, the cover frame 210 may also be formed in the form of a rectangular cabinet that abuts against the reactor housing 110 to conform thereto. A drive unit 230 is disposed at an upper portion of the cover frame 210 and a closed space 211 is formed in the drive unit 230 so that the components constituting the drive unit 230 can be hermetically sealed to the outside. The cover frame 210 has a motor portion 236 for transmitting power from the outside and a connection structure 232, 234 and 260 for connecting the motor portion 236 to one side of the cover frame 210.

The brush unit 220 is formed so that the particulate matter attached to the front surface of the catalyst carrier 120 can be forcibly blown off. Specifically, the brush unit 220 is in the form of a bar extending in the transverse direction in front of the catalyst carrier 120. The brush unit 220 has a brush 221 formed in a shape protruding toward the catalyst carrier 120 and a holder 222 for fixing the brush 221. [ The brushes 221 may be formed of a metal material so as to reduce denaturation and wear due to exhaust gas. The length of the brush unit 220 may correspond to the length of one side of the catalyst carrier 120 so that the entire surface of the catalyst carrier 120 can be cleaned by vertically conveying the brush unit 220. [

As shown in FIG. 6, the brush unit 220 may include an exhaust channel 224 to minimize its own blocking of the flow of exhaust gas. The exhaust channel 224 is formed in a substantially slot shape and may include an inlet portion 225 of a sectional shape of the holder portion 222 and an outlet portion 226 formed on one side of the brush 221. Accordingly, the exhaust gas is supplied to the catalyst carrier 120 through the exhaust channel 220 formed in the brush unit 220, so that the exhaust resistance can be minimized.

The driving unit 230 is connected to the brush unit 220 so as to vertically transfer the brush unit 220. The driving unit 230 includes a screw 231 extending upward and downward and formed to extend vertically and capable of lifting and lowering the brush unit 220 by rotation and a screw 231 extending from the outside of the cover frame 210 And a motor portion 236 for providing a driving force to the screw 231. The screw 231 may be provided with a pair of left and right pairs 231A and 231B so as to raise and lower the brush unit 220 horizontally and stably. The brush unit 220 may also include inner screws 223, 223A, and 223B that are in contact with the screw 231 to raise and lower the holder portion 222. [

The cover frame 210 is coupled to the reactor housing 120 that fixes the catalyst carrier 120 in front of the catalyst carrier 120 and rotatably supports the screw 231.

The transfer structure of the brush unit 220 by the screw 231 is excellent in maintenance from the viewpoint of minimizing the failure and deterioration of the member or parts in the state of being exposed to the exhaust gas in the reactor 100 . The driving unit 230 may include a vibration module for vibrating the brush unit 220 in the longitudinal direction so as to more reliably remove the particulate matter. The vibration module may be implemented by a guide for applying vibration to the transport chain 233 fixing the brush unit 220, or a vibration striking element for the transport chain.

The rotation axis of the screw 231 is extended and connected to the motor section 236. [ A sealing reinforcing portion 260 may be formed between the rotation shaft of the screw 231 and the motor portion 236 so as to increase the hermeticity of the connection portion. 7 is a sectional view showing the structure of the sealing reinforcing portion 260. As shown in FIG. The sealing reinforcing portion 260 includes a plurality of disks 261, 262 and 263 which are arranged on the rotating shaft of the screw 231 and are arranged so as to be smaller in diameter as they move away from the cover frame 210 and a plurality of disks 261, 262, 263 And a disc housing 265 which is provided with a disc housing. When the disks 261, 262, 263 are rotated, the disk 261 having a larger diameter has a lower edge velocity than the disk 263 having a smaller diameter, so that the pressure is relatively low. Therefore, the exhaust gas in the reactor 100 does not cause leakage on the connection portion due to such a pressure difference.

The dust collecting cartridge 240 is formed so that the particulate matter removed by the brush unit 220 can fall and gather. Specifically, the dust collecting cartridge 240 may be formed in a hopper shape so as to collect particulate matter, and a connection portion 241 may be provided at a lower portion of the dust collecting cartridge 240 to connect the suction device.

The particulate matter removal apparatus 200 may further include a blower 250 disposed in parallel to the screw 231 and formed to spray compressed air to the screw 231. The blower 250 may be formed in a pipe shape in which a plurality of nozzles 251 for ejecting compressed air are formed. This blower 250 is useful for removing particulate matter accumulated in the screw 231 that is placed in the flow of the exhaust gas. The brushes 221 may include discontinuous gaps so that the blower 250 may pass therethrough to provide an installation space for the blower 250 and to prevent an increase in thickness.

4, the screw 231 receives the driving force from the motor unit 236 and rotates while transferring the brush unit 220 connected to the brush unit 220 from the upper part to the lower part, The particulate matter accumulated on the front is swept downward. The particulate matter collected in the lower dust collection cartridge 240 is discharged to the outside through the suction device connected to the connection portion 241. [ The control of the driving unit 230 and the motor unit 236 is performed periodically and the lowered brush unit 220 is automatically returned to the upper position and then the operation of the reactor 100 is performed.

8 is a perspective view of a dust collecting cartridge 340 according to another example related to the present invention. The dust collecting cartridge 340 in this example is formed in a drawer shape, unlike in Fig. Specifically, the dust collecting cartridge 340 includes a cartridge cylinder 343 coupled to the lower end of the cover frame 210, a drawer body 344 formed to be able to be drawn and received through the side opening of the cartridge cylinder 343, And a flange cover 345 provided at an end of the drawer body 344 and configured to seal the side opening. The structure of the drawer-type dust collecting cartridge 340 can reliably remove the particulate matter collected by the operator periodically, and it is possible to easily adjust the design according to the size of the reactor in a narrow engine installation condition in the ship.

9 is a perspective view of a brush unit 420 according to another example related to the present invention.

The brush unit 420 of this embodiment includes a first brush 421 protruding toward the catalyst carrier 120 and a second brush 427 protruding toward the screw 431. A first holder 422 may be provided to fix the first brush 421 and a second holder 428 may be provided to fix the second brush 427. [ The inner screw 423 can be provided so that the first brush 421 can be moved up and down according to the rotation of the screw 423. The second brush 427 and the second holder 428 may be fixed to one side of the first holder 422 or the inner screw 423. [ The end of the second brush 427 may be formed so as to surround the screw 431 so that the solid particles attached to the screw 431 can be blown off. With this configuration, even if the inner screw 423 is in the flow of the exhaust gas, the attachment of the solid particles or the soot by the second brush 427 can be minimized, and the failure or the like can be reduced.

The particulate matter removal apparatus of the brush-type selective catalytic reduction system as described above is not limited to the configuration and operation of the embodiments described above. The above embodiments may be configured so that all or some of the embodiments may be selectively combined to make various modifications.

100: Reactor 101: Exhaust pipe
102: guide structure 110: reactor housing
120: catalyst carrier 200: particulate matter removal device
210: cover frame 220, 420: brush unit
221: Brush 222: Holder
223: Inner screw 224: Exhaust channel
225: inlet part 226: outlet part
230: drive unit 231, 231A, 231B: screw
240: dust collecting cartridge 241:
250: blower 251: injection hole
260: sealing reinforcing portions 261, 262, 263:
S: solid particles or soot

Claims (13)

A brush unit disposed in the form of a bar extending in the transverse direction in front of the catalyst carrier for treating the exhaust gas and capable of removing particulate matter attached to the front surface of the catalyst carrier by movement; And
And a drive unit configured to move the brush unit, wherein the drive unit includes:
A screw formed to extend vertically and capable of lifting and lowering the brush unit by rotation;
A cover frame coupled to a reactor housing for fixing the catalyst carrier in front of the catalyst carrier, the cover frame being formed to rotatably support the screw; And
And a motor portion for providing a driving force to the screw from the outside of the cover frame,
Wherein the brush unit comprises:
A brush formed in a shape protruding toward the catalyst carrier;
A holder for fixing the brush; And
And an inner screw supporting the holder portion and being lifted and lowered by rotation of the screw,
Wherein the holder portion includes an exhaust channel through which the exhaust gas is allowed to pass.
delete delete delete The method according to claim 1,
Wherein the exhaust channel is formed in a slot shape.
The method according to claim 1,
Further comprising a blower disposed in front of the screw to remove particulate matter accumulated on the screw by compressed air.
A brush unit disposed in front of the catalyst carrier for treating the exhaust gas and configured to remove particulate matter attached to the front surface of the catalyst carrier by movement; And
And a drive unit configured to move the brush unit, wherein the drive unit includes:
A screw formed to extend vertically and capable of lifting and lowering the brush unit by rotation;
A cover frame coupled to a reactor housing for fixing the catalyst carrier in front of the catalyst carrier, the cover frame being formed to rotatably support the screw;
A motor portion for providing a driving force to the screw from the outside of the cover frame; And
And a blower disposed in front of the screw to remove particulate matter accumulated on the screw by compressed air,
Wherein the blower is formed in a rod shape parallel to the screw and has a plurality of injection holes directed toward the screw.
The method according to claim 1,
Wherein the brush is formed of a metal material.
The method according to claim 1,
The motor unit is disposed on the upper side of the cover frame,
Further comprising a sealing reinforcing portion capable of increasing airtightness at a connection portion between the screw and the motor portion.
A brush unit disposed in front of the catalyst carrier for treating the exhaust gas and configured to remove particulate matter attached to the front surface of the catalyst carrier by movement; And
And a drive unit configured to move the brush unit, wherein the drive unit includes:
A screw formed to extend vertically and capable of lifting and lowering the brush unit by rotation;
A cover frame coupled to a reactor housing for fixing the catalyst carrier in front of the catalyst carrier, the cover frame being formed to rotatably support the screw;
A motor unit for providing a driving force to the screw from above the cover frame; And
And a sealing reinforcing portion capable of increasing the hermeticity of a connection portion between the screw and the motor portion,
The sealing reinforcing portion
A plurality of discs arranged on the extensions of the screws and arranged to be smaller in diameter away from the cover frame; And
And a disc housing formed to enclose the plurality of discs.
The method according to claim 1,
Further comprising a dust collecting cartridge disposed at a lower portion of the cover frame so that the particulate matter removed by the brush unit can be dropped and gathered.
12. The method of claim 11,
Wherein the dust collection cartridge is formed in a hopper shape so as to collect the particulate matter,
And a connecting portion is provided at a lower portion of the dust collecting cartridge so that suction equipment can be connected thereto.
The method according to claim 1,
Wherein the brush unit comprises:
A first brush formed in a shape protruding toward the catalyst carrier; And
And a second brush formed in a shape protruding toward the screw.

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