KR102531024B1 - Filter processing method of denitrification facility - Google Patents

Abstract

The present invention is a filter treatment method of a denitration facility for converting a new filter into a low-temperature filter in order to provide a filter treatment method of a denitration facility that improves the denitration efficiency of the new filter by cleaning and coating the new filter installed in the denitration facility. , spraying a cleaning material toward the new filter to perform cleaning on the new filter, and converting the new filter into the low-temperature filter by spraying a catalytically active material on the cleaned new filter. And, the catalytically active material may include vanadium pentoxide.

Description

Filter processing method of denitrification facility {FILTER PROCESSING METHOD OF DENITRIFICATION FACILITY}

The present invention relates to a filter treatment method of a denitration facility, and more particularly, to a filter treatment method of a denitration facility for treating a new filter installed in a denitration facility to treat exhaust gas discharged from a power plant.

In general, thermal power plants are operated based on 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. A filter is an important component for denitrification of exhaust gas, and the performance of the filter is a major technology to improve denitrification efficiency. Accordingly, various researches and developments are being made to improve the efficiency of filters installed in denitrification facilities. However, most of the research is limited to technology for improving the material and shape of the filter, and research on the processing method of the manufactured filter is insufficient.

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

An object of the present invention is to provide a filter treatment method of a denitration facility for improving the denitration efficiency of a new filter by cleaning and coating a new filter installed in the denitration facility.

A filter treatment method according to the present invention is a filter treatment method of a denitrification facility that converts a new filter into a low-temperature filter, wherein the steps of cleaning the new filter by spraying a cleaning material toward the new filter, and the cleaning and converting the new filter into the low-temperature filter by spraying a catalytically active material on the completed new filter, wherein the catalytically active material may include vanadium pentoxide.

The low-temperature filter may be applied to a denitrification process of 200° C. or less.

The cleaning material may include dry ice pellets.

In the spraying of the cleaning material, the dry ice pellets and compressed air may be sprayed toward the filter.

In the injection of the cleaning material, the injection pressure may be adjusted to 4 to 8 bar.

In the cleaning step, dry ice pellets are sprayed toward the new filter, and the dry ice pellets permeate into the pores of the new filter and then sublimate to form manufacturing residues including a binder added during the manufacturing of the new filter. It can be discharged to the outside through the pores of the filter.

The injection of the dry ice pellets may instantaneously form a vacuum between the inner walls of the new filter so that the manufacturing residue is discharged from the new filter.

In the converting step, a catalytically active material may be sprayed onto the new filter and the new filter may be heated so that the catalytically active material is coated on the new filter.

In the heating of the new filter, the new filter into which the catalytically active material is sprayed may be installed in a denitrification facility and a boiler connected to the denitration facility may be operated to coat the catalytically active material.

On the other hand, in the method of manufacturing a low-temperature filter according to the present invention, in the manufacturing method of a low-temperature filter, the step of cleaning the filter by spraying a cleaning material toward the filter and applying a catalytically active material to the cleaned filter and converting the filter into the low-temperature filter by spraying, wherein the catalytically active material includes vanadium pentoxide.

The filter treatment method of the denitrification facility according to the present invention has the effect of greatly improving the denitration efficiency by cleaning and coating the new filter before or after the installation of the new filter.

In addition, the filter treatment method of the denitration facility according to the present invention has an effect of converting a general filter into a low-temperature filter suitable for a denitration process of 200 ° C or less by cleaning and coating operations.

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 schematically showing a filter applied to a filter treatment method of a denitrification facility according to this embodiment;
2 is a flowchart schematically showing a filter treatment method of a denitrification facility according to the present embodiment;
3 is a flow chart showing the filter cleaning process of the denitrification facility according to the present embodiment;
4 and 5 are conceptual views showing the filter cleaning process of the denitrification facility according to this embodiment,
6 is a flow chart showing a filter cleaning process of a denitrification facility according to the present embodiment;
7 is a conceptual diagram showing a filter cleaning process of a denitrification facility according to this embodiment;
8 is a conceptual diagram showing a catalyst performance test of a low-temperature filter generated by the filter treatment method of a denitration 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 schematically showing a filter applied to a filter treatment method of a denitration facility according to this embodiment, and FIG. 2 is a flowchart schematically showing a filter treatment method of a denitration facility according to this embodiment.

As shown in FIGS. 1 and 2 , in the filter treatment method (S100) of the denitrification facility according to the present embodiment, the filter 10 installed in the denitration facility provided in the power generation environment is processed. For example, in the processing of the filter 10, the new filter 11 can be converted into a low-temperature filter 12. Here, the new filter 11 may be a general filter, and through the treatment of the new filter 11, it is possible to produce a low-temperature filter 12 suitable for denitrification at a low temperature of 200 ° C or less.

Here, the cross section of the filter 10 in the height direction may have a honeycomb structure. However, this is for explanation of the present embodiment, and the cross section of the filter 10 may have various shapes such as a plate structure or a corrugated structure.

Accordingly, in the treatment of the filter 10, a cleaning operation (S200) and a coating process (S300) of the new filter 11 may be performed to produce a low-temperature filter 12 suitable for low-temperature denitrification.

Hereinafter, a cleaning process (S200) and a coating process (S300) for producing a low-temperature filter 12 suitable for low-temperature denitrification from the new filter 11 will be described in detail based on the accompanying drawings.

3 is a flow chart showing a filter cleaning process of the denitration facility according to this embodiment, and FIGS. 4 and 5 are conceptual diagrams showing a filter cleaning process of the denitration facility according to this embodiment.

As shown in FIGS. 3 to 5, in the cleaning process (S200) of the new filter 11 according to the present embodiment, dry ice pellets are sprayed on the new filter 11 to clean the new filter 11. do.

First, in the cleaning of the new filter 11, the new filter 11 is transported to a work environment (S210). For example, the working environment may be a predetermined work place where cleaning of the new filter 11 is to be performed, and if necessary, the new filter 11 may be installed in a denitrification facility, that is, in a power generation environment.

Thereafter, in the cleaning of the new filter 11, the new filter 11 is cleaned based on a cleaning material such as dry ice pellets (S220). For example, in cleaning the new filter 11 using dry ice pellets, the cleaning material spraying device 100 may be used.

The cleaning material spraying device 100 sprays dry ice pellets toward the new filter 11 based on compressed air. Here, the injection pressure of the dry ice pellets may be 4 to 8 bar, but is not limited thereto. However, cleaning of the new filter 11 may not be performed smoothly when the compressed air is injected at a pressure below the set range, and when the compressed air is injected at a pressure above the set range, the new filter 11 is damaged. this may occur.

On the other hand, as the dry ice pellets and compressed air are injected toward the honeycomb of the new filter 11, manufacturing residues remaining in the pores of the new filter 11 will be crushed and removed according to the collision kinetic energy with the dry ice pellets. can Here, the manufacturing residue remaining in the pores of the new filter 11 may be a contaminant remaining in the production process of the new filter 11, for example, a binder, but is not limited thereto.

On the other hand, as the dry ice pellets are sprayed, the dry ice particles in the honeycomb of the new filter 11 permeate and sublimate (volume expands 500 to 800 times), and manufacturing residues are discharged from the pores to the outside. That is, manufacturing residues 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 new filter 11 can be regenerated.

Here, the dry ice pellets may be sprayed from the top of the new filter 11, and the cleaning material spray device 100 moves in a plane direction from the top of the new filter 11 and sprays the dry ice pellets to the new filter ( In 11), cleaning can be performed for each honeycomb.

Meanwhile, when the cleaning operation (S200) of the new filter 11 is completed, the new filter 11 is coated with a catalytically active material and heated to produce the low-temperature filter 12.

6 is a flow chart showing a filter cleaning process of the denitration facility according to this embodiment, and FIG. 7 is a conceptual diagram showing a filter cleaning process of the denitration facility according to this embodiment.

6 and 7, in the coating process of the new filter 11 according to this embodiment, the new filter 11 is coated with a catalytically active material (S300). For example, the catalytically active material may include an aqueous vanadium oxide (Vanadium pentoxide) solution, and the catalytically active material coating device 200 may be used in spraying the catalytically active material.

First, in the coating of the new filter 11, the cleaned new filter 11 is transferred to a working environment (S310). However, the coating operation of the new filter 11 may be performed in the same environment as the cleaning environment, and if necessary, the new filter 11 may be performed in a state in which the new filter 11 is installed in the denitrification facility, that is, in a power generation environment.

Thereafter, the catalytically active material coating device 200 causes the previously stored catalytically active material to be sprayed toward the new filter 11 (S320). Here, the spraying of the catalytically active material coating device 200 may be performed from the top of the new filter 11, and the catalytically active material coating device 200 moves in the planar direction from the top of the new filter 11, and the new filter ( 11) may be coated for each honeycomb.

Thereafter, the new filter 11 coated with the catalytically active material may be subjected to a drying and firing process through heating (S330).

For example, if the new filter 11 is not installed in the denitrification device, that is, if the coating is performed in a separate working environment, a separate heating device is used or the new filter 11 is moved to a heating environment and heated and dried. and a firing process.

As another example, if the new filter 11 is installed in the denitrification device, drying and firing of the new filter 11 may be achieved by operating a boiler connected to the denitrification facility without requiring a separate drying and firing process. there is. That is, drying and firing of the new filter 11 may be performed based on waste heat of exhaust gas discharged from the boiler.

In addition, even if the coating is performed in a state where the new filter 11 is not installed in the denitrification device, the new filter 11 with the coating is installed in the denitrification facility and the boiler connected to the denitration facility is operated. ) can be made to dry and sinter.

Thus, the new filter 11 can be converted into a low-temperature filter 12 suitable for low-temperature denitrification at 200° C. or less by completing drying and firing after washing and coating.

8 is a conceptual diagram showing a catalyst performance test of a low-temperature filter generated by the filter treatment method of a denitration facility according to the present embodiment.

As shown in FIG. 8, a performance test was performed on the new filter 11 according to this embodiment and the low-temperature filter 12 that had undergone a filter treatment process from the new filter 11.

In the performance test, the denitrification temperature of the new filter (11) and the low-temperature filter (12) was set to 170 ° C, and nitrogen oxide (NOx, nitrogen oxide) at the inlet side flowing into the new filter (11) and the low-temperature filter (12) The concentration of 70ppm, the concentration of sulfur oxides (SOx) was 0ppm, and the conditions of 0% water (H2O) were applied.

At this time, it was found that the denitrification efficiency of the new filter 11 not subjected to the filter treatment process was 67.7%. On the other hand, the low-temperature filter 12 to which the filter treatment method according to the present embodiment was applied under the same conditions was found to have a denitrification efficiency of 90.9%. That is, the low-temperature filter 12 subjected to the filter treatment process according to the present embodiment showed an improved denitrification efficiency of about 23% or more compared to the new filter 11.

As described above, the filter treatment method of the denitration facility according to the present invention has an effect of greatly improving the denitration efficiency by cleaning and coating the new filter before or after the installation of the new filter.

In addition, the filter treatment method of the denitrification facility according to the present invention has an effect of converting a general filter into a suitable temperature filter suitable for a denitration process of 200 ° C or less by cleaning and coating operations.

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)

In the filter treatment method of a denitration facility for converting a new filter having a honeycomb structure in the cross section in the height direction into a low-temperature filter applied to a denitration process of 200 ° C or less,
A cleaning material spraying device disposed above the new filter transfers the cleaning material in a planar direction from above the new filter, and sprays the cleaning material toward the honeycomb of the new filter so that cleaning is performed for each honeycomb of the new filter step;
a step of transferring the catalytically active material coating device disposed above the new filter in a planar direction from above the new filter and spraying the catalytically active material toward the honeycomb of the new filter; and
Heating the new filter coated with the catalytically active material to convert it into the low-temperature filter,
In the step of making the cleaning
The cleaning material spraying device injects cleaning materials including dry ice pellets together with compressed air toward the honeycomb of the new filter;
In the conversion step
The new filter coated with the catalytically active material is installed in a denitrification facility and a boiler connected to the denitration facility is operated to dry and sinter the new filter based on the waste heat of the exhaust gas discharged from the boiler,
The catalytically active material includes vanadium pentoxide,
The dry ice pellets permeate into the pores of the new filter and then sublimate so that manufacturing residues including the binder added during the manufacturing of the new filter are discharged from the pores of the filter to the outside. method.
delete delete delete According to claim 1,
In the injection of the cleaning material
A filter treatment method of a denitrification facility, characterized in that the injection pressure is adjusted to 4 to 8 bar.
delete According to claim 1,
The spraying of the dry ice pellets
A filter treatment method of a denitration facility, characterized in that by instantaneously forming a vacuum between the inner walls of the new filter so that the manufacturing residue is discharged from the new filter.

delete delete In the manufacturing method of a low-temperature filter for manufacturing a low-temperature filter applied to a denitrification process of 200 ° C or less based on a new filter having a honeycomb structure in the cross section in the height direction,
A cleaning material spraying device disposed above the new filter transfers the cleaning material in a planar direction from above the new filter, and sprays the cleaning material toward the honeycomb of the new filter so that cleaning is performed for each honeycomb of the new filter step;
a step of transferring the catalytically active material coating device disposed above the new filter in a planar direction from above the new filter and spraying the catalytically active material toward the honeycomb of the new filter; and
Heating the new filter coated with the catalytically active material to convert it into the low-temperature filter,
In the step of making the cleaning
The cleaning material spraying device injects cleaning materials including dry ice pellets together with compressed air toward the honeycomb of the new filter;
In the conversion step
The new filter coated with the catalytically active material is installed in a denitrification facility and a boiler connected to the denitration facility is operated to dry and sinter the new filter based on the waste heat of the exhaust gas discharged from the boiler,
The catalytically active material includes vanadium pentoxide,
The dry ice pellets are sublimated after penetrating into the pores of the new filter so that manufacturing residues including the binder added during the manufacturing of the new filter are discharged from the pores of the filter to the outside. method.

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