KR20230082360A - Filter regenerating apparatus of denitrification facility - Google Patents

Abstract

The present invention relates to a catalyst regeneration device for a denitrification facility that automatically cleans a filter mounted on the denitrification facility without separating the filter and regenerates the filter. The catalyst regeneration device comprises: a main body module disposed on top of a filter mounted on a denitrification facility and transported in a first direction; a nozzle support module supported by the main body module and reciprocated in a second direction crossing the first direction; a spray nozzle detachable from the nozzle support module and allowing dry ice to be sprayed toward the filter disposed below; and a power control module controlling the operation of the body module and the nozzle support module so that the spray nozzle is transported in the first and second directions along the filter. The purpose of the present invention is to automatically clean and regenerate the filter mounted on the denitrification facility without removing the filter.

Description

Filter regeneration device of denitrification facility {FILTER REGENERATING APPARATUS OF DENITRIFICATION FACILITY}

The present invention relates to a filter regeneration device for a denitrification facility, and more particularly, to a filter regeneration device for a denitration facility for regenerating a denitration catalyst of a power generation facility.

In general, thermal power plants are operated on the basis of coal or oil. In recent years, regulations on environmental pollution have been strengthened, and research, development, and distribution of environmental facilities that can reduce the emission of pollutants are increasing.

The prior art for these environmental facilities is disclosed by "Korean Registered Patent Publication No. 10-1918663 (Power Generation System, 2018.11.08.)". The registered invention is characterized in that it includes a denitrification facility for denitrifying the exhaust gas by injecting a reducing agent into the exhaust gas exhausted from the power plant.

The denitrification facility is provided to include a denitrification catalyst, that is, a filter, and performs denitrification of the exhaust gas. As the denitrification catalyst is poisoned by ammonium sulfate salt, dust, and metal salt during repeated denitrification processes, replacement or regeneration is required. However, since most of the denitrification catalysts are manually cleaned, there is a problem in that the denitration catalysts are not uniformly cleaned. In addition, when the denitration catalyst is poisoned by sodium, potassium, phosphorus pentoxide, etc., it is difficult to regenerate the denitration catalyst, so there are problems such as environmental problems and increased landfill costs due to disposal.

Republic of Korea Patent Registration No. 10-1918663 (Power Generation System, 2018.11.08.)

An object of the present invention is to provide a catalyst regeneration device of a denitration facility that regenerates the filter while automatically cleaning the filter installed in the denitration facility without separating the filter.

A filter regeneration device for a denitrification facility according to the present invention includes a main body module disposed on top of a filter installed in the denitrification facility and transported in a first direction, and a body module supported by the main body module and transported reciprocally in a second direction crossing the first direction. a nozzle support module and a spray nozzle detachable from the nozzle support module and configured to spray dry ice toward the filter disposed below, and the spray nozzle to be transported along the filter in the first and second directions. A main body module and a power control module for controlling the operation of the nozzle support module are included.

The filter regeneration device of the denitrification facility may further include a rail module that can be installed above the filter and forms a path through which the body module is transported in the first direction.

The body module includes a body frame, a transport roller disposed between the body frame and the rail module to allow the body frame to be transported along the rail module, and supported by the body frame and the nozzle support module including the second A support frame forming a path transported in a direction, a first power source providing power to the transfer roller so that the main body module is transported in the first direction, and a nozzle support module providing power to the nozzle support module It may include a second power source to be transported in the second direction along the support frame.

The rail module may include first and second rail frames installed along the frame of the denitration facility in the first direction at a predetermined interval, and a connection frame connecting the first and second rail frames. there is.

The filter regeneration device of the denitrification facility may further include a regeneration material supply module supplying dry ice and compressed air to the injection nozzle.

The regeneration material supply module may adjust the injection pressure of the dry ice pellets and the compressed air to 4 to 8 bar.

The power control module may allow the injection nozzle to be moved in the first and second directions according to a preset rule.

The power control module may control the operation of the body module and the nozzle support module so that the spray nozzle is moved over the entire upper area of the filter.

The particulates of the dry ice injected toward the filter penetrate into the pores of the filter and then sublimate so that the poisonous substances of the filter can be discharged from the pores of the filter to the outside.

The dry ice sprayed towards the filter may instantaneously form a vacuum between the inner walls of the filter so that the poisonous substance may be discharged from the filter.

The catalyst regeneration device of a denitration facility according to the present invention has an effect of improving regeneration efficiency and shortening regeneration time by performing regeneration of a filter by automatically transferring a spray nozzle.

In addition, the catalyst regeneration device of the denitration facility according to the present invention not only removes clogging of the filter based on dry ice, but also regenerates the filter to solve environmental problems caused by waste landfill by prolonging the lifespan of the filter and reducing landfill cost increase. has a resolving effect.

The technical effects of the present invention as described above are not limited to the effects mentioned above, and other technical effects not mentioned will be clearly understood by those skilled in the art from the description below.

1 is a perspective view showing a filter regeneration device and a denitrification facility of a denitration facility according to the present embodiment;
2 is a perspective view showing a filter regeneration device and a denitrification facility of a denitration facility according to the present embodiment;
3 is a conceptual diagram showing a filter regeneration device of a denitrification facility according to the present embodiment;
4 is a flowchart showing the operation of the filter regeneration device of the denitrification facility according to the present embodiment;
5 is a conceptual diagram showing the filter regeneration principle of the filter regeneration device of the denitrification facility according to the present embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, this embodiment is not limited to the embodiments disclosed below and may be implemented in various forms, but this embodiment only makes the disclosure of the present invention complete, and the scope of the invention to those skilled in the art. It is provided for complete information. The shapes of elements in the drawings may be exaggeratedly expressed for more clear description, and elements indicated by the same reference numerals in the drawings mean the same elements.

1 is a perspective view showing a filter regeneration device and a denitrification facility of a denitration facility according to this embodiment, and FIG. 2 is a perspective view showing a filter regeneration device and a denitration facility of the denitration facility according to this embodiment. 3 is a conceptual diagram showing a filter regeneration device of a denitrification facility according to the present embodiment.

As shown in FIGS. 1 to 3, the filter regeneration device (1000, hereinafter referred to as the filter regeneration device) of the denitrification facility according to the present embodiment includes a regeneration unit 100 and a control unit 200, The filter 30 installed in the denitrification facility 10 is regenerated.

Here, the cross section of the filter 30 in the height direction may have a honeycomb structure, but this is for explanation of the present embodiment, and the cross section of the filter 30 in which regeneration is performed by the filter regeneration device 1000 It may have various shapes such as a plate structure and a corrugated structure.

The regeneration unit 100 may include a rail module 110, a body module 120, a nozzle support module 130, a spray nozzle 140, and a regeneration material supply module 150.

The rail module 110 is disposed on the upper side of the filter 30 to form a path through which the spray nozzle 140 is transported on the upper side of the filter 30 . For example, the rail module 110 may be disposed on a frame of the denitration facility 10 supporting the filter 30 .

The rail module 110 may include a first rail frame 111 , a second rail frame 112 , a first connection frame 113 and a second connection frame 114 .

Here, the first rail frame 111 and the second rail frame 112 may be spaced apart from each other so as to have a predetermined distance and fixed to the frame of the denitration facility 10.

In addition, the first connecting frame 113 connects one end of the first rail frame 111 and the second rail frame 112, and the second connecting frame 114 connects the first rail frame 111 and the second rail frame. Connect the other end of (112).

In addition, the body module 120 is connected to the rail module 110 and can be transported along the rail module 110 . The body module 120 can be reciprocally transported in a first direction along the first rail frame 111 and the second rail frame 112, and the nozzle support module 130 supported in one area is interlocked in the first direction. To enable reciprocating transfer in the second direction.

For example, the body module 120 may include a body frame 121 , a transfer roller 122 , a support frame 123 , a first power source 124 and a second power source 125 .

The body frame 121 may be provided in plurality to configure the body module 120 .

And the conveying roller 122 is disposed under the body frame 121 . A plurality of transfer rollers 122 are provided so that the body module 120 reciprocally slides in the first direction along the first rail frame 111 and the second rail frame 112 .

And the support frame 123 is supported by the body frame 121 and is disposed elongated along the second direction. The support frame 123 forms a path along which the nozzle support module 130 is transported along the second direction.

And, the first power source 124 is supported by the body frame 121 and provides power to the plurality of transfer rollers 122 . The first power source 124 provides power to the transfer rollers 122 according to a signal provided from the outside so that the plurality of transfer rollers 122 are driven along the first rail frame 111 and the second rail frame 112. Reciprocating transfer in one direction is possible. Here, the first power source 124 may include a motor, but is not limited thereto.

The second power source 125 is supported by the body frame 121 and provides power to the nozzle support module 130 . The second power source 125 provides power to the nozzle support module 130 according to a signal provided from the outside so that the nozzle support module 130 can move back and forth along the support frame 123 in the second direction. Here, the second power source 125 may provide power to the nozzle support module 130 based on a motor, a rack and pinion structure, a conveyor structure, and an actuator, but the type of the second power source 125 is not limited.

In addition, the nozzle support module 130 may have a spray nozzle 140 that sprays dry ice pellets toward the filter 30 . The nozzle support module 130 allows the injection nozzle 140 to be reciprocally transported in the second direction along the support frame 123 by the second power source 125 .

In addition, the spray nozzle 140 causes the dry ice pellets to be sprayed toward the filter 30 . The injection nozzle 140 is connected to the regeneration material supply module 150 through a connection tube. The spray nozzle 140 may spray the dry ice pellets provided from the regeneration material supply module 150 toward the filter 30 so that the filter 30 can be regenerated.

In addition, the regeneration material supply module 150 supplies dry ice pellets to the spray nozzle 140 based on compressed air. For example, the regeneration material supply module 150 may provide dry ice pellets and compressed air to the injection nozzle 140 through a connection tube so that the filter 30 is cleaned.

Meanwhile, the control unit 200 may control the overall operation of the reproducing unit 100 . For example, the control unit 200 may include a power control module 210 and a supply control module 220 .

The power control module 210 may be supported by the body module 120 . The power control module 210 may control the first power source 124 so that the injection nozzle 140 is reciprocally transported in the first direction, and controls the second power source 125 so that the injection nozzle 140 moves in the second direction. It can be reciprocally transported in the direction.

Also, the supply control module 220 may be provided in the regeneration material supply module 150 . The supply control module 220 may control the regeneration material supply module 150 to supply compressed air and dry ice pellets to the spray nozzle 140 .

Meanwhile, hereinafter, the operation of the filter regeneration device of the denitration facility according to the present embodiment will be described with reference to the accompanying drawings. However, detailed descriptions of the above-described components will be omitted and the same reference numerals will be given for description.

4 is a flow chart showing the operation of the filter regeneration device of the denitration facility according to the present embodiment, and FIG. 5 is a conceptual diagram showing the filter regeneration principle of the filter regeneration device of the denitration facility according to the present embodiment.

As shown in FIGS. 4 and 5, the filter regeneration device 1000 according to the present embodiment is transported by a worker to the environment where the denitration facility 10 is located to regenerate the filter 30 of the denitration facility 10. It can be. Then, the worker dismantles the denitrification facility 10 so that the upper part of the filter 30 is exposed.

Thereafter, the operator may install the rail module 110 on the frame of the denitrification facility 10 (S100). Here, the first rail frame 111 and the second rail frame 112 may be installed to correspond to the frame interval of the denitrification facility 10, but may be installed at intervals of 80 to 120 cm, for example. And the worker connects one end of the first rail frame 111 and the second rail frame 112 to the first connecting frame 113, and the other ends of the first rail frame 111 and the second rail frame 112 By connecting with the second connection frame 114, the rail module 110 maintains a solid state.

Meanwhile, when the installation of the rail module 110 is completed, the operator installs the body module 120 to the rail module 110 . At this time, the operator installs the body module 120 so that the transfer roller 122 can be transferred along the first rail frame 111 and the second rail frame 112 . Then, the operator fastens the injection nozzle 140 to the nozzle support module 130 so that the injection nozzle 140 is fixed to the nozzle support module 130 .

Thereafter, when the installation of the filter regeneration device 1000 is completed, the operator controls the supply control module 220 so that the dry ice pellets and compressed air are discharged from the regeneration material supply module 150 through the connecting tube to the spray nozzle 140. To be provided as (S200). Then, the operator controls the power control module 210 so that the regeneration unit 100 transfers the injection nozzle 140 in the first and second directions and performs a regeneration process on the filter 30 (S300).

For example, the regeneration unit 100 causes the injection nozzle 140 to be moved in a first direction according to a signal provided from the outside. Here, the transfer interval of the spray nozzle 140 may be transferred by a preset distance, but it is also possible to adjust the transfer interval of the spray nozzle 140 according to the operator's operation.

At this time, as the spray nozzle 140 is moved by a set distance in the first direction, the dry ice pellets and compressed air sprayed from the spray nozzle 140 are sprayed toward the honeycomb of the filter 30, and the honeycomb is cleaned. can be made Here, the injection pressure of the dry ice pellets and compressed air may be 4 to 8 bar, but is not limited thereto. However, when the compressed air is injected at a pressure below the set range, poisoning substances may not be smoothly removed, and when the compressed air is injected at a pressure above the set range, the filter 30 may be damaged. there is.

In addition, as the dry ice pellets and compressed air are injected toward the honeycomb, the poisonous substances in the pores of the filter 30 can be crushed and removed according to the kinetic energy of the collision with the dry ice pellets. At this time, the dry ice particles in the honeycomb permeate and sublimate (volume expands 500 to 800 times), and the poisonous substances are discharged from the pores to the outside. That is, poisonous substances in the pores are discharged to the outside by instant vacuum formation of dry ice particles passing quickly between the inner walls of the honeycomb, and the honeycomb can be regenerated.

Thereafter, when the injection nozzle 140 completes regeneration of the corresponding honeycomb, the regeneration unit 100 may cause the injection nozzle 140 to be moved by a set distance in the second direction. That is, the regeneration unit 100 may allow the injection nozzle 140 to be transferred to the upper portion of the honeycomb adjacent to the second direction, and the injection nozzle 140 may inject dry ice pellets and compressed air into the transferred honeycomb. to perform regeneration for the honeycomb.

Then, when the regeneration of the row of honeycombs in which the injection nozzles 140 are arranged in the second direction is completed, the regeneration unit 100 transports the injection nozzles 140 by a set distance in the first direction, and moves the injection nozzles 140 in the second direction. It is possible to perform regeneration for honeycombs in other rows arranged in .

When the regeneration of the filter 30 is finally completed, the operator can end the operation of the regeneration unit 100 .

As described above, the catalyst regeneration device of the denitration facility according to the present invention has an effect of improving regeneration efficiency and shortening regeneration time by performing regeneration of the filter by automatically transferring the injection nozzle.

In addition, the catalyst regeneration device of the denitration facility according to the present invention not only removes clogging of the filter based on dry ice, but also regenerates the filter to solve environmental problems caused by waste landfill by prolonging the lifespan of the filter and reducing landfill cost increase. has a resolving effect.

One embodiment of the present invention described above and shown in the drawings should not be construed as limiting the technical idea of the present invention. The protection scope of the present invention is limited only by the matters described in the claims, and those skilled in the art can improve and change the technical spirit of the present invention in various forms. Therefore, such improvements and changes will fall within the protection scope of the present invention as long as they are obvious to those skilled in the art.

Claims (10)

a main body module disposed on top of a filter installed in a denitrification facility and transported in a first direction;
a nozzle support module supported by the body module and reciprocally transported in a second direction crossing the first direction;
a spray nozzle detachable from the nozzle support module and spraying dry ice toward the filter disposed below; and
and a power control module for controlling operations of the body module and the nozzle support module so that the spray nozzle is transported along the filter in the first and second directions.
According to claim 1,
The filter regeneration device of the denitration facility further comprising a rail module that can be installed on the upper side of the filter and forms a path through which the body module is transported in the first direction.
According to claim 2,
The body module
body frame,
a transfer roller disposed between the body frame and the rail module to allow the body frame to be transported along the rail module;
a support frame supported by the body frame and forming a path along which the nozzle support module is transported in the second direction;
A first power source for providing power to the conveying roller so that the body module is conveyed in the first direction;
and a second power source supplying power to the nozzle support module so that the nozzle support module is transported in the second direction along the support frame.
According to claim 2,
The rail module
First and second rail frames installed along the frame of the denitrification facility in the first direction at a predetermined interval;
Filter regeneration device of a denitration facility, characterized in that it comprises a connecting frame connecting between the first and second rail frames.
According to claim 1,
Filter regeneration device of a denitration facility, characterized in that it further comprises a regeneration material supply module for supplying dry ice and compressed air to the injection nozzle.
According to claim 5,
The regeneration material supply module
Filter regeneration device of a denitration facility, characterized in that for adjusting the injection pressure of the dry ice pellets and the compressed air to 4 to 8 bar.
According to claim 1,
The power control module
A filter regeneration device of a denitration facility that allows the injection nozzle to be transported in the first and second directions according to a pre-set rule.
According to claim 7,
The power control module
The filter regeneration device of the denitration facility, characterized in that the operation of the body module and the nozzle support module is controlled so that the injection nozzle is moved over the entire upper area of the filter.
According to claim 1,
The fine particles of the dry ice sprayed toward the filter
The filter regeneration device of the denitrification facility, characterized in that the poisonous substances of the filter are discharged to the outside from the pores of the filter by penetrating into the pores of the filter and then sublimating.
According to claim 9,
The dry ice sprayed toward the filter
A filter regeneration device of a denitration facility, characterized in that a vacuum is instantaneously formed between the inner walls of the filter so that the poisonous substance is discharged from the filter.

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