KR102025146B1 - System for monitoring a state of catalytic reaction in power plant DeNOx facilities, and method thereof - Google Patents

Abstract

The present invention provides a catalytic reaction condition monitoring system for an installation comprising: a catalyst module having a plurality of lattices through which exhaust gases pass; An ammonia supply unit supplying ammonia gas to the catalyst module; An image acquisition unit for acquiring a temperature change resulting from a catalytic reaction between the exhaust gas and the ammonia gas as an image; And a controller configured to control the ammonia supply unit by determining a degree of the catalytic reaction of each of the grids based on the obtained image.

Description

System for monitoring a state of catalytic reaction in power plant DeNOx facilities, and method

The present invention relates to a catalytic reaction state monitoring system and method of a denitrification plant in power plant. By automatically controlling the ammonia input amount of each valve for the optimum reaction based on the data, the ammonia overload and the ammonia gas in each subdivision zone of the power plant denitrification plant are passed through the catalyst module without being involved in the reduction of nitrogen oxides. The present invention relates to a catalytic reaction state monitoring system and method of a power plant denitrification plant, which can minimize slip occurrence.

In general, combustion gases such as boilers, gas turbines, gas engines, diesel engines, and exhaust gases from internal combustion engines contain nitrogen oxides (NO, NO ₂ ). These pollutants are regulated before they are released into the atmosphere. It should be treated below concentration.

NO, NO ₂ , NO ₃ , N ₂ O, N ₂ O ₃ , N ₂ O _5, etc. are known to be present in the nitrogen oxides. However, N ₂ O (nitrous oxide) and NO (nitric oxide) are detected in the atmosphere. NO ₂ (nitrogen dioxide). Although NO and NO ₂ are toxic and cause photochemical reactions in the atmosphere, N ₂ O is not considered to be an air pollutant, although N ₂ O is present in a large amount because it is not toxic and independent of photochemical reactions. Therefore, when referred to as nitrogen oxides means NO and NO ₂ and is usually written as NOx.

Typical NOx configurations in the exhaust are 95% NO and 5% NO ₂ . NO is a colorless, odorless gas that easily converts into tan brown NO ₂ in the atmosphere. It may also cause acid rain, produce various oxidants such as O ₃ , HCHO, PAN, and cause secondary pollution, and cause photochemical smog.

The NOx control method can be divided into three areas: pre-combustion denitrification, improved combustion conditions, and post-combustion denitrification.

Post combustion treatments include catalytic decomposition, adsorption, radiation, selective non-catalytic reduction (SNCR), non-selective catalytic reduction (NSCR), Selective catalytic reduction (SCR). The most effective of these is the selective catalytic reduction (SCR) has been studied a lot until now. At present, SCR is the only technology that can remove more than 90% of NOx from fixed sources.

SCR is cheaper in fixed asset investment and operation cost than other dry methods described above, and is a simple process requiring only ammonia (NH ₃ ) feeder and reactor, and can achieve high NOx treatment rate of more than 90%, and there are no by-products such as waste water. .

SCR is a method of reducing NOx to nitrogen (N ₂ ) on a catalyst by injecting a reducing agent such as ammonia into the exhaust gas containing NOx, as shown in FIG. 1, and is generally expressed by a chemical reaction formula according to Equation 1 below. . 1 is a view showing the ammonia and NOx reaction process in the catalyst bed in a general power plant denitrification facility.

Here, the side effect formula may be represented by a chemical reaction according to Equation 2 below.

SCR is similar to SNCR in that it uses a reducing agent, but differs in that it uses a catalyst, and thus the reaction temperature is lower than that of SNCR, and also shows a very high NOx treatment rate at an appropriate temperature.

However, in most power plants, NOx measuring sensors are installed at one or two points for the denitrification facility, and the amount of ammonia input is controlled using only the NOx measurement value through this, and the control of each valve is fixed stably regardless of the state change in each subregion. I'm in control.

In addition, there is a limit to installing the NOx measurement sensor at every measurement point, and it is difficult to estimate the catalyst state by the NOx measurement value.

In addition, since it depends on the measured value by the NOx measurement sensor, there is a problem that it is difficult to diagnose the status of each subdivision in the catalyst bed which is the core of the power plant denitrification facility.

In addition, catalyst performance decreases and failures frequently occur due to an increase in slip of ammonia during the catalyst reaction, and accordingly, there is a problem in that costs are generated because the catalyst is visually diagnosed and replaced during several maintenance periods each year. .

Korean Patent Publication No. 10-0601054 (Registration Date: July 07, 2006)

An object of the present invention for solving the above-mentioned problems, photographing the reaction state of the ammonia catalyst in the power plant denitrification equipment through the camera, and processes the photographed image as data on the state of each subdivision, and optimal based on the data By automatically controlling the ammonia input amount of each valve for the reaction, it is possible to minimize the ammonia overload of each subdivision zone in the power plant denitrification facility and slip generation through the catalyst module without ammonia gas being involved in the reduction of nitrogen oxides. The present invention provides a system and method for monitoring a catalytic reaction state of a power plant denitrification plant.

According to an aspect of the present invention, there is provided a catalytic reaction state monitoring system for a power plant denitrification system, including: a catalyst module having a plurality of lattices through which exhaust gas passes; An ammonia supply unit supplying ammonia gas to the catalyst module; An image acquisition unit for acquiring a temperature change resulting from a catalytic reaction between the exhaust gas and the ammonia gas as an image; And a controller configured to control the ammonia supply unit by determining a degree of the catalytic reaction of each of the grids based on the obtained image.

The apparatus may further include a storage unit configured to store a mapping table in which pixel region positions of the grids of the catalyst module and positions of the supply valves of the ammonia supply unit corresponding thereto are mapped.

The image acquisition unit may acquire the image having a different color according to the reactivity of the catalytic reaction in each of the gratings.

The controller may further include an image analyzer configured to analyze the degree of reactivity of the catalytic reaction by comparing brightness values according to color differences of the grids with respect to the obtained image; And a valve control unit controlling opening and closing of the corresponding supply valve of the ammonia supply unit corresponding to the pixel region position of each lattice according to the degree of reactivity of the catalytic reaction for each lattice.

The image analyzer may determine that the reactivity of the catalytic reaction is low when the brightness of the lattice is high, and that the catalytic reaction is high when the brightness of the lattice is low.

In addition, the ammonia supply unit, a specific number of supply valves per grid unit of the catalyst module may be installed.

The ammonia supply unit may be configured such that a supply line for supplying ammonia gas to the plurality of grids is provided via the grids, and injects the ammonia gas supplied through the supply line for each grid. Feed valves may be arranged respectively.

The controller may analyze the image in a lattice unit to determine that the lattice having high brightness according to the color difference is low in reactivity of the catalytic reaction, and that the ammonia supply unit corresponding to the pixel area of the lattice having high brightness The supply valve may be recognized to generate a message indicating that maintenance of the supply valve of the recognized ammonia supply unit is required.

On the other hand, the catalytic reaction state monitoring method of the power plant denitrification facility according to an embodiment of the present invention for achieving the above object, the catalyst module having a plurality of grids through which the exhaust gas, and supplying ammonia gas to the catalyst module A method of monitoring a catalytic reaction state of a power plant denitrification facility of a system comprising an ammonia supply unit, the method comprising: supplying ammonia gas to the catalyst module through which the exhaust gas passes through the plurality of grids; Acquiring, by an image acquisition unit, a temperature change resulting from a catalytic reaction between the exhaust gas and the ammonia gas as an image; Analyzing, by the controller, the image in grid units; And controlling, by the control unit, the ammonia supply unit by determining the degree of the catalytic reaction of each of the grids based on the obtained image.

In the obtaining of the image, the image obtaining unit may obtain the image having a different color according to the reactivity of the catalytic reaction in each of the gratings.

In the analyzing, the image analysis unit of the controller may analyze the degree of reactivity of the catalytic reaction by comparing the brightness values according to the color difference of each grid with respect to the obtained image.

The analyzing may include determining that the reactivity of the catalytic reaction is low when the brightness of the gratings is high, and that the catalytic reaction is high when the brightness of the gratings is low. can do.

In the controlling step, the valve control unit may control the opening and closing of the corresponding supply valve of the ammonia supply unit corresponding to the pixel region position of each lattice according to the degree of reactivity of the catalytic reaction for each lattice.

In the analyzing, the controller analyzes the image in a lattice unit, and determines that the lattice having high brightness according to the color difference is low in reactivity of the catalytic reaction. The corresponding supply valve of the ammonia supply unit corresponding to the position of the pixel region of the grid may be recognized to generate a message indicating that maintenance of the corresponding supply valve of the recognized ammonia supply unit is required.

Other aspects, advantages and features of the present invention will become more apparent on the basis of the following sections: Contents set forth in the entire application specification, including the following brief description, detailed description and claims.

According to the present invention, a special camera measuring method for checking the catalyst state in a power plant denitrification facility is used, and the reaction state for each subdivision of the catalyst layer is data-processed through real-time image image processing technology. The input amount of ammonia gas in each valve can be controlled automatically.

Therefore, by automatically controlling the ammonia supply valve according to the reaction state of each subdivision of the catalyst, it is possible to minimize the excessive input, the occurrence of slip, reduce the operating cost of the power plant, and prevent the failure.

And, as it is possible to confirm the catalytic reaction state for each subdivision, it is possible to predict when the catalyst needs to be replaced, thereby reducing maintenance costs.

1 is a view showing the ammonia and NOx reaction process in the catalyst bed in a general power plant denitrification facility.
Figure 2 is a block diagram schematically showing the configuration of a catalytic reaction state monitoring system of a power plant denitrification apparatus according to an embodiment of the present invention.
3 is a view showing an example of photographing the reaction state of the ammonia catalyst according to an embodiment of the present invention with a camera.
4 is a plan view of a catalyst module showing an example in which each supply valve of the ammonia supply unit according to the embodiment of the present invention is disposed.
5 is a flowchart illustrating an operation of a method for monitoring a catalytic reaction state of a power plant denitrification facility according to an exemplary embodiment of the present invention.
FIG. 6 is a diagram illustrating a lattice unit catalytic reaction rate of a catalyst module according to an exemplary embodiment of the present invention. FIG.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention.

In order to clearly describe the present invention, parts irrelevant to the description are omitted, and like reference numerals designate like elements throughout the specification.

Throughout the specification, when a part is "connected" to another part, this includes not only "directly connected" but also "electrically connected" with another element in between. . In addition, when a part is said to "include" a certain component, which means that it may further include other components, except to exclude other components unless otherwise stated.

When a portion is referred to as being "above" another portion, it may be just above the other portion or may be accompanied by another portion in between. In contrast, when a part is mentioned as "directly above" another part, no other part is involved between them.

Terms such as first, second, and third are used to describe various parts, components, regions, layers, and / or sections, but are not limited to these. These terms are only used to distinguish one part, component, region, layer or section from another part, component, region, layer or section. Accordingly, the first portion, component, region, layer or section described below may be referred to as the second portion, component, region, layer or section without departing from the scope of the invention.

The terminology used herein is for reference only to specific embodiments and is not intended to limit the invention. As used herein, the singular forms “a,” “an,” and “the” include plural forms as well, unless the phrases clearly indicate the opposite. As used herein, the meaning of "comprising" embodies a particular characteristic, region, integer, step, operation, element and / or component, and the presence of other characteristics, region, integer, step, operation, element and / or component It does not exclude the addition.

Terms indicating relative space such as "below" and "above" may be used to more easily explain the relationship of one part to another part shown in the drawings. These terms are intended to include other meanings or operations of the device in use with the meanings intended in the figures. For example, if the device in the figure is reversed, any parts described as being "below" of the other parts are described as being "above" the other parts. Thus, the exemplary term "below" encompasses both up and down directions. The device can be rotated 90 degrees or at other angles, the terms representing relative space being interpreted accordingly.

Unless defined otherwise, all terms including technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art. Commonly defined terms used are additionally interpreted to have a meaning consistent with the related technical literature and the presently disclosed contents, and are not interpreted in an ideal or very formal sense unless defined.

Figure 2 is a block diagram schematically showing the overall configuration of the catalytic reaction state monitoring system of the power plant denitrification apparatus according to an embodiment of the present invention, Figure 3 is a camera for photographing the reaction state of the ammonia catalyst according to an embodiment of the present invention An example is shown.

2 and 3, the catalytic reaction state monitoring system 200 of a power plant denitrification facility according to an embodiment of the present invention includes a catalyst module 110, an ammonia supply unit 120, an image acquisition unit 130, and storage. The unit 140 and the controller 150 may be included.

The catalyst module 110 may include a plurality of grids 112 through which the exhaust gas passes. Catalyst module 110 may have a honeycomb structure in which the lattice 112 is continuous. Here, the exhaust gas may mean a combustion exhaust gas discharged from the combustion device of the turbine, and may contain nitrogen oxides (NOx).

The ammonia supply unit 120 may supply ammonia gas to the catalyst module 110. That is, the ammonia supply unit 120 may supply ammonia gas for removing nitrogen oxide (NOx) contained in the exhaust gas to the catalyst module 110 through which the exhaust gas passes as a catalyst. In this case, the ammonia supply unit 120 may include a supply valve installed in a specific number per grid unit of the catalyst module 110.

Therefore, in the embodiment of the present invention, the ammonia supply unit 120 injects ammonia gas as a catalyst in the ammonia supply unit 120 with respect to the exhaust gas containing nitrogen oxides (NOx) passing through the catalyst module 110 to the chemical reaction according to equation (1). This may be detected through the image acquisition unit 130. At this time, in the catalyst module 110, a process of removing nitrogen oxide (NOx) in exhaust gas may be performed by ammonia gas used as a catalyst to reduce NOx to nitrogen (N ₂ ). In this process, it is an object of the present invention to diagnose the reaction state of the ammonia catalyst by photographing the camera.

The ammonia supply part 120 is arranged such that a supply line for supplying ammonia gas to each of the gratings 112 formed of the plurality of catalyst modules 110 passes through the gratings 112. Each grating 112 may be provided with a supply valve for injecting ammonia gas supplied through the supply line, respectively.

The image acquisition unit 130 may acquire a temperature change resulting from the catalytic reaction between the exhaust gas and the ammonia gas as an image. That is, the image acquisition unit 120 may include a camera photographing a temperature change according to heat, and may acquire an image having a different color through the camera according to the reactivity of the catalytic reaction in each of the gratings 112. Here, the camera may include, for example, a thermal imaging camera that tracks and detects heat to generate an image according to the temperature data of the heat. The thermal imaging camera detects thermal energy radiated from a heat source. The thermal imager detects thermal energy as an infrared wavelength, which is a kind of electromagnetic waves, and displays each color according to the intensity of radiant heat on the surface of a subject. However, the type of camera is not particularly limited, and the image acquisition unit 130 may include a camera capable of detecting a temperature change due to a difference in reactivity between the gratings 112.

In the catalyst module 110, the nitrogen oxide (NOx) of the exhaust gas and the ammonia gas as the catalyst may react with each other as in Equation 1 to generate a temperature change due to an endothermic reaction. At this time, the temperature according to the chemical reaction is increased, and accordingly, in the image acquired through the camera, a high temperature portion may appear as a red system, and a low temperature portion may appear as a blue system.

Thus, the image acquisition unit 130 is a catalyst reaction between the ammonia gas supplied from the ammonia supply unit 120 and the nitrogen oxide (NOx) of the exhaust gas when the exhaust gas passes through the grids 112 of the catalyst module 110. An image may be acquired by photographing the temperature change that appears according to the camera. Here, the installation of the camera can be installed in the following positions. In plan view, one camera may be installed in the center of the catalyst module 110. In addition, the catalyst module 110 may be installed one by one on the rim.

The storage unit 140 may store a mapping table in which pixel region positions of the grids 112 of the catalyst module 110 and positions of respective supply valves of the ammonia supply unit 120 corresponding to the pixel region positions are mapped. Can be.

The controller 150 may control the ammonia supply unit 120 by determining the degree of catalytic reaction of each of the gratings 112 based on the obtained image. The controller 150 supplies ammonia to each of the gratings 112 based on the position of the supply valve stored in the storage 140 and the reactivity difference of the catalytic reaction between the gratings 112 obtained by the image obtaining unit 120. The amount of gas can be controlled.

The controller 150 may include an image analyzer 152 and a valve controller 154.

The image analyzer 152 may analyze the degree of reactivity of the catalytic reaction by comparing the brightness values according to the color difference of each grid 112 with respect to the obtained image. For example, the image analyzer 152 may divide the grid pixel area corresponding to a blue color according to the temperature change and the grid pixel area corresponding to a red color according to the temperature change.

The image analyzer 152 may determine that the reactivity of the catalytic reaction is low when the brightness of the gratings 112 is high, and may determine that the reactivity of the catalytic reaction is high when the brightness of the gratings 112 is low.

The valve control unit 154 may supply a corresponding supply valve of the ammonia supply unit 120 corresponding to the pixel region position of each of the grids 112 according to the degree of reactivity of each of the grids 112 analyzed by the image analyzer 152. Can control the opening and closing of the

In addition, the controller 150 analyzes the image in a lattice unit to determine that the grating 112 having high brightness according to the color difference is low in reactivity of the catalytic reaction, and corresponds to the pixel region position of the grating 112 having high brightness. Recognizing the corresponding supply valve of the ammonia supply unit 120, and generates a message that the maintenance of the corresponding supply valve of the recognized ammonia supply unit 120 may be generated and transmitted to the person in charge terminal or management device.

Although not shown in FIG. 2, the catalytic reaction state monitoring system 200 of a power plant denitrification facility may include a nitrogen oxide (NOx) measurement sensor (not shown) that detects an emission of nitrogen oxides (NOx). The nitrogen oxide (NOx) measurement sensor (not shown) may measure the concentration of nitrogen oxide (NOx) in real time or detect the emission of nitrogen oxide (NOx), and may transmit the detected nitrogen oxide detection signal to the controller 150. .

4 is a plan view of a catalyst module showing an example in which each supply valve of the ammonia supply unit according to the embodiment of the present invention is disposed.

Referring to FIG. 4, the ammonia supply unit 120 according to an embodiment of the present invention may include a supply line for supplying ammonia gas on the surface of the catalyst module 110 including a plurality of lattice-shaped lattice 112. 122 may be arranged to pass through each of the gratings 112.

In addition, a plurality of supply valves 124 may be provided in the supply line 122. Feed valve 124 may be disposed for each of the gratings 112 of the catalyst module 110, respectively. The supply valve 124 may adjust the amount of ammonia gas supplied to each of the gratings 112 through separate control.

In this case, as illustrated in FIG. 4, the supply valve 124 is illustrated as being disposed one by one on all the gratings 112 having a grid shape. However, the supply valve 124 is not limited thereto and may be disposed every two gratings 112 or more. One per grid 112 may be disposed. That is, the supply line 122 is disposed in the catalyst module 110 via all the grids 112 in the lattice unit, and the supply valve 124 is disposed in the one or more lattice units on the supply line 122, respectively. Can be.

5 is a flowchart illustrating an operation of a method for monitoring a catalytic reaction state of a power plant denitrification facility according to an exemplary embodiment of the present invention.

2 to 5, in the catalytic reaction state monitoring system 200 of a power plant denitrification facility according to an embodiment of the present invention, the ammonia supply unit 120 includes a catalyst through which exhaust gas passes through a plurality of grids 112. Ammonia gas may be supplied to the module 110 (S510).

That is, the ammonia supply unit 120 supplies ammonia gas through each supply valve 124 installed on the supply line 122 passing through each of the gratings 112 of the catalyst module 110 as shown in FIG. 4. Each spray may be supplied to the gratings 112.

Subsequently, the image acquisition unit 130 may acquire a temperature change, which is indicated by the catalytic reaction between the exhaust gas and the ammonia gas, as the catalytic reaction image (S520).

That is, the image acquisition unit 130 is a catalytic reaction between the ammonia gas supplied from the ammonia supply unit 120 and the nitrogen oxide (NOx) of the exhaust gas when the exhaust gas passes through the grids 112 of the catalyst module 110. The change in temperature that appears according to the camera can be obtained by the catalytic reaction image.

In this case, the image acquisition unit 130 may obtain a catalytic reaction image having a different color according to the reactivity of the catalytic reaction in each of the gratings 112.

The catalytic reaction image acquired according to the catalytic reaction of ammonia gas is displayed in each of the grids 112 of the catalyst module 110, for example, the color of the high temperature part is represented by a red color system, and the color of the low temperature part is May appear blue. That is, the catalytic reaction image obtained by photographing the catalyst module 110 through the thermal imaging camera may be a red system due to the high temperature because the catalytic reaction occurs actively in the portion of the grating 112 which is sufficiently supplied with ammonia gas. In addition, since the catalytic reaction does not occur actively in the portion of the grating 112 that is not sufficiently supplied with ammonia gas, the temperature may be low and may appear as a blue system.

Subsequently, the controller 150 may analyze the obtained catalytic reaction image in units of grids (S530).

That is, the image analyzer 152 in the controller 150 may analyze the degree of reactivity of the catalytic reaction by comparing the brightness values according to the color difference of each grid 112 with respect to the obtained image. For example, since the temperature change caused by the catalytic reaction is different for each lattice unit, the color appearing in the image may be different for each lattice 112. In this case, the pixel region may be divided into a low brightness region and a high brightness region.

In addition, the controller 150 may calculate the catalytic reaction rate in units of lattice as shown in FIG. 6 with respect to the catalytic reaction image of the catalyst module 110. FIG. 6 is a diagram illustrating a lattice unit catalytic reaction rate of a catalyst module according to an exemplary embodiment of the present invention. FIG. That is, the controller 150 may analyze the brightness value for each of the grids 112 and calculate the catalytic reaction rate for each grid according to the brightness value. The controller 150 may control the amount of ammonia gas provided to each of the gratings 112 based on the catalytic reaction rate between the gratings 112.

In addition, the controller 150 may detect the amount of ammonia gas supplied to the catalytic reaction through a nitrogen oxide (NOx) measuring sensor installed in each of the grids 112 of the catalyst module 110 to calculate the catalytic reaction rate in units of grids. Can be.

Subsequently, the controller 150 may determine the degree of reactivity of the catalytic reaction for each lattice according to the analysis result of the catalytic reaction image (S540).

That is, the image analyzer 152 may determine that the lattice having high brightness among the gratings 112 has low reactivity of the catalytic reaction, and that the image having low brightness among the gratings 112 may have high reactivity of the catalytic reaction. Can be.

For example, the image analyzer 152 may determine the grating 112 having a higher brightness value than the other gratings 112 as a region having low reactivity of the catalytic reaction. That is, the image analyzing unit 152 is in a state in which the ammonia of the gratings 112 of the image is not sufficiently supplied with the catalyst and thus the catalytic reaction is not active or the ammonia gas is not completely consumed and is released into the atmosphere so that the catalytic reaction is not active. The lattice 112 represented by the blue color having a high brightness of the obtained image may be determined to have low reactivity of the catalytic reaction. At this time, the release of ammonia gas into the atmosphere without being completely consumed in the ammonia catalyst reaction is referred to as "ammonia slip".

In addition, the image analyzer 152 may determine the grating 112 having a lower brightness than the other gratings 112 as a region having high reactivity of the catalytic reaction. That is, the image analyzer 152 catalyzes the grating 112 represented by a dark red system having a low brightness as the color of the obtained image is sufficiently supplied with ammonia gas among the gratings 112 of the image. It can be judged that the reaction is highly reactive.

At this time, the controller 150 recognizes the corresponding supply valve of the ammonia supply unit 120 corresponding to the pixel area having a high brightness value based on the table stored in the storage unit 140, and supplies the corresponding supply of the recognized ammonia supply unit 120. A message indicating that the valve is in need of maintenance can be generated and sent to the operator's terminal or management device.

Subsequently, the controller 150 may control the opening and closing of the corresponding supply valve of the ammonia supply unit 120 according to the determined degree of reactivity of the catalytic reaction for each of the gratings 112 (S550).

That is, the controller 150 opens the supply valve corresponding to the grating 112 having low reactivity of the catalytic reaction, and maintains or supplies the open state of the supply valve corresponding to the grating 112 having the high reactivity of the catalytic reaction. The valve can be controlled to reduce the supply of ammonia gas.

For example, the controller 150 determines that the lattice 112 having high brightness is low in the catalytic reaction in the catalytic reaction image, and the ammonia supply unit 120 corresponding to the pixel region position of the lattice 112 having high brightness is determined. By opening the corresponding supply valve of, it can be controlled to supply more ammonia gas to the grating 112.

In addition, the control unit 1500 recognizes the corresponding supply valve of the ammonia supply unit 120 corresponding to the pixel area position of the high-lattice grating 112, and thus maintenance of the corresponding supply valve of the recognized ammonia supply unit 120 is necessary. A message may be generated and controlled to be transmitted to the management device or the person in charge.

As described above, according to the present invention, the reaction state of the ammonia catalyst in the power plant denitrification facility is photographed through a camera, the photographed image is processed as data on the state of each subdivision, and the angle for the optimum reaction based on the data Automatic control of the ammonia input of the valve allows the plant to minimize the ammonia overload of each subdivision within the power plant denitrification facility and to minimize the occurrence of slip through the catalyst module without the ammonia gas being involved in the reduction of nitrogen oxides. The system and method for diagnosing the catalytic reaction state of the denitrification plant can be realized.

As those skilled in the art to which the present invention pertains may implement the present invention in other specific forms without changing the technical spirit or essential features, the embodiments described above should be understood as illustrative and not restrictive in all aspects. Should be. The scope of the present invention is shown by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. .

200: catalytic reaction status monitoring system of power plant denitrification equipment
110: catalyst module
112: grid
120: ammonia supply unit
130: image acquisition unit
140: storage unit
150: control unit
152: image analysis unit
154: valve control unit

Claims (14)

A catalyst module having a plurality of gratings through which exhaust gas passes;
An ammonia supply unit supplying ammonia gas to the catalyst module;
An image acquisition unit for acquiring a temperature change resulting from a catalytic reaction between the exhaust gas and the ammonia gas as an image; And
A controller for controlling the ammonia supply unit by determining a degree of the catalytic reaction of each of the grids based on the obtained image;
Catalytic reaction state monitoring system of the power plant denitrification plant comprising a. The method of claim 1,
A storage unit which stores a mapping table in which pixel region positions of the grids of the catalyst module and positions of respective supply valves of the ammonia supply unit corresponding to the pixel region positions are mapped;
Catalytic reaction state monitoring system of the power plant denitrification plant further comprising. The method of claim 1,
The image acquisition unit, the catalyst reaction state monitoring system of a power plant denitrification facility to obtain the image having a different color according to the reactivity of the catalytic reaction in each of the grids. The method of claim 1,
The control unit,
An image analyzer for analyzing the degree of reactivity of the catalytic reaction by comparing brightness values according to color differences of the grids with respect to the obtained image; And
A valve control unit controlling opening and closing of the corresponding supply valve of the ammonia supply unit corresponding to the pixel region position of each lattice according to the degree of reactivity of the catalyzed reaction for each lattice analyzed;
Catalytic reaction state monitoring system of the power plant denitrification plant comprising a. The method of claim 4, wherein
The degree of reactivity of the catalytic reaction analyzed by the image analyzer is inversely proportional to the brightness value of the grid, catalytic reaction state monitoring system of a power plant denitrification facility. The method of claim 1,
The ammonia supply unit is a catalytic reaction state monitoring system of a power plant denitrification facility, a specific number of supply valves are installed per grid unit of the catalyst module. The method of claim 1,
The ammonia supply unit is arranged such that a supply line for supplying ammonia gas to each of the plurality of gratings passes through the gratings,
And each of the grids has a supply valve for injecting ammonia gas supplied through the supply line, respectively. The method of claim 1,
The controller recognizes a corresponding supply valve of the ammonia supply unit corresponding to the pixel region position of each of the grids according to the determination result of the degree of reactivity of the catalytic reaction with respect to each of the grids, and recognizes the corresponding supply valve of the recognized ammonia supply unit. A catalytic reaction status monitoring system at a power plant denitrification plant that generates a message that maintenance is required. A method for monitoring the catalytic reaction state of a power plant denitrification system of a system comprising a catalyst module having a plurality of lattices through which exhaust gas passes, and an ammonia supply unit for supplying ammonia gas to the catalyst module,
The ammonia supply unit supplying ammonia gas to the catalyst module through which exhaust gas passes through the plurality of grids;
Acquiring, by an image acquisition unit, a temperature change resulting from a catalytic reaction between the exhaust gas and the ammonia gas as an image;
Analyzing, by the controller, the image in grid units; And
Controlling, by the controller, the ammonia supply unit by determining a degree of the catalytic reaction of each of the lattice based on the obtained image;
Catalytic reaction state monitoring method of the power plant denitrification plant comprising a. The method of claim 9,
Acquiring the image,
And the image acquisition unit acquires the image having a different color according to the reactivity of the catalytic reaction in each of the grids. The method of claim 9,
The analyzing step,
The image analysis unit of the control unit compares the brightness values according to the color difference of each grid with respect to the obtained image, to analyze the degree of reactivity of the catalytic reaction, the catalytic reaction state monitoring method of the power plant denitrification equipment. The method of claim 11,
The analyzing step,
The degree of reactivity of the catalytic reaction analyzed by the image analyzer is inversely proportional to the brightness value of the grid, the catalytic reaction state monitoring method of the power plant denitrification equipment. The method of claim 11,
The controlling step,
And a valve control unit controls the opening and closing of the corresponding supply valve of the ammonia supply unit corresponding to the pixel region position of each lattice according to the degree of reactivity of the catalytic reaction for each lattice. The method of claim 9,
The controlling may include the control unit recognizing a corresponding supply valve of the ammonia supply unit corresponding to the pixel region position of each of the grids according to a determination result of the degree of reactivity of the catalytic reaction with respect to each of the grids. A method of monitoring the catalytic reaction status of a power plant denitrification plant, generating a message that maintenance of the corresponding feed valve is required.

Images