KR102556686B1 - The SNCR denitrification facility system using ammonium carbonate - Google Patents

Abstract

The present invention relates to a SNCR denitrification facility system using ammonium carbonate. To achieve the above object, the SNCR denitration facility system using ammonium carbonate according to the present invention stores urea water and supplies it to the set section. A storage unit, an ammonium carbonate storage unit for storing and supplying ammonium carbonate to a set section, controlling the urea water stored in the urea water storage unit to be sprayed in the set section according to operating conditions of the boiler, and detecting the temperature through the sensor unit. According to the detection result, a control unit that selectively controls the ammonium carbonate stored in the ammonium carbonate storage unit to be sprayed to a set section, and is located between the urea water storage unit and the boiler. Receiving urea water from the urea water storage unit A urea dilution unit for generating a diluted urea solution having a reduced concentration and supplying it to the boiler, and an ammonium carbonate having a reduced concentration by receiving ammonium carbonate from the ammonium carbonate storage unit while being located between the ammonium carbonate storage unit and the boiler. An ammonium carbonate dilution unit generating a dilution solution and supplying it to the boiler, a first nozzle unit installed in the boiler and spraying urea water that has passed through the urea water dilution unit into the boiler, and the ammonium carbonate unit installed in the boiler A second nozzle unit for spraying ammonium carbonate that has passed through the dilution unit into the boiler, and the first nozzle unit and the second nozzle unit located at one side of the boiler so that the urea water and the ammonium carbonate are sprayed into the boiler. It is characterized in that it is configured to include an air compressor for supplying compressed air to.
According to the present invention, in the SNCR denitrification facility system to which Selective Non-Catalytic Reduction (SNCR) is applied to reduce nitrogen oxide (NOx), an air pollutant generated in process facilities such as boilers, Reduce the amount of urea water used due to supply and demand instability as much as possible, and use ammonium carbonate to increase nitrogen oxide removal by designing hybrid operation according to the supply and demand of raw materials and temperature changes in the boiler. It has the effect of improving the performance and increasing the efficiency of the process by reducing impurities.

Description

The SNCR denitrification facility system using ammonium carbonate}

The present invention relates to a SNCR denitrification facility system using ammonium carbonate, and more particularly, to a selective non-catalytic reduction method for reducing nitrogen oxides (NOx), an air pollutant generated from process facilities such as boilers. In the SNCR denitrification facility system to which Reduction; SNCR) is applied, the amount of urea water used due to unstable supply of raw materials is reduced as much as possible, and ammonium carbonate is used to increase nitrogen oxide removal and reduce impurities to improve process performance and efficiency. It relates to a SNCR denitrification facility system using ammonium carbonate with increased

In general, in boilers operated in power plants, factories, incinerators, etc., as fossil fuels are burned, nitrogen oxides (NOx), which are harmful gases, are generated and discharged. Such nitrogen oxides are treated as one of the major air pollutants because they generate secondary pollutants by photochemical reactions.

As a system for treating such nitrogen oxides, the SCR system to which Selective Catalytic Reduction (SCR) is applied and the SNCR system to which Selective Non-Catalytic Reduction (SNCR) is applied are most commonly applied, respectively. processes have different strengths and weaknesses.

The SCR system has the advantage of increasing the treatment efficiency up to 90% by using a catalyst during the process and being able to operate at a temperature as low as 300 ° C. There is a downside to being In addition, when operating at 300 ° C or lower, sulfur oxides (SOx) in the exhaust gas and ammonia injected form ammonium sulfate, which poisons the catalyst or causes clogging of the catalyst or air preheater, making it difficult to operate the denitration facility. There are downsides.

On the other hand, the SNCR system is widely applied to existing incinerators in Korea or facilities emitting relatively low concentrations of nitrogen oxides (NOx), and has a removal efficiency of about 40 to 80%. Since this SNCR system is a relatively simple facility requiring only a reducing agent injection device and a reducing agent storage container, it has the advantage of being easily installed in an existing boiler. In such a SNCR system, treatment efficiency varies depending on the reaction temperature, the location and residence time of the injection nozzle, and the type of reducing agent. The main reaction of the SNCR system occurs in a narrow temperature range of 900 ~ 1200 ℃, and generally shows the maximum removal efficiency at 950 ~ 1,100 ℃. As the reducing agent, ammonia and urea solution are mainly used. In general, ammonia shows higher efficiency than urea solution, but urea solution, which is easy to store and handle, is often used.

However, the conventional SNCR system using ammonia and urea water has low denitrification efficiency and requires twice as much operating cost as the SCR system in terms of reducing agent consumption. In particular, a large amount of unreacted ammonia due to an excessive amount of reducing agent damages the boiler tube and generates ammonium sulfate in the air preheater, so that corrosion and clogging of the thermal element frequently occur.

Therefore, it is necessary to develop a SNCR denitrification system with improved performance and efficiency of the process using ammonium carbonate in order to minimize the amount of urea water used due to unstable supply and demand of raw materials.

KR 10-2452927 B1(2022. 10. 05.)

The present invention has been made to solve the problems of the prior art, and the problem to be solved in the present invention is to reduce nitrogen oxides, an air pollutant generated in process facilities such as boilers. SNCR with a selective non-catalytic reduction method applied In the denitrification facility system, the purpose is to minimize the amount of urea water used due to unstable supply and demand of raw materials and to utilize ammonium carbonate.

Another purpose is to enable real-time response to the temperature change in the boiler according to the detection result by using a thermal infrared ray sensor capable of adjusting the vertical and horizontal angles.

In order to achieve the above object, the SNCR denitrification facility system using ammonium carbonate according to the present invention includes a urea water storage unit for supplying urea water to the storage and setting section, and ammonium carbonate for supplying ammonium carbonate to the storage and setting section According to the operating conditions of the storage unit and the boiler, the urea water stored in the urea water storage unit is controlled to be sprayed in a set section, and the temperature is detected through the sensor unit, and the ammonium carbonate stored in the ammonium carbonate storage unit is selectively stored according to the detection result. A control unit for controlling spraying in the setting section, and an element that is located between the urea water storage unit and the boiler and receives urea water from the urea water storage unit to generate a diluted urea solution having a reduced concentration and supply it to the boiler. An ammonium carbonate dilution unit positioned between a water dilution unit and the ammonium carbonate storage unit and the boiler and receiving ammonium carbonate from the ammonium carbonate storage unit to generate a diluted ammonium carbonate solution having a reduced concentration and supplying it to the boiler; A first nozzle unit installed in the boiler and spraying urea water that has passed through the urea water dilution unit into the boiler, and a second nozzle unit installed in the boiler and spraying ammonium carbonate that has passed through the ammonium carbonate dilution unit into the boiler And an air compressor located at one side of the boiler and supplying compressed air to the first nozzle part and the second nozzle part so that the urea water and the ammonium carbonate are injected into the boiler. do.

In addition, inside the boiler, a first nozzle part and a second nozzle part are sequentially installed from the direction in which exhaust gas moves by burning fossil fuel, and the second nozzle part is installed in a relatively low temperature region than the first nozzle part. characterized by being

In addition, a plurality of nozzles are installed in the first nozzle unit 40 and the second nozzle unit 50 according to the size of the boiler, and the plurality of nozzles are configured in a form in which the angle is adjusted vertically or vertically. to be characterized

In addition, the sensor unit (S) is a thermal infrared sensor, and is located between the first nozzle unit 40 and the second nozzle unit 50 to sense the temperature inside the boiler 1 in real time, and the first It is characterized in that the position is adjusted vertically between the nozzle unit 40 and the second nozzle unit 50.

According to the present invention, in the SNCR denitrification facility system to which Selective Non-Catalytic Reduction (SNCR) is applied to reduce nitrogen oxide (NOx), an air pollutant generated in process facilities such as boilers, Reduce the amount of urea water used due to supply and demand instability as much as possible, and use ammonium carbonate to increase nitrogen oxide removal by designing hybrid operation according to the supply and demand of raw materials and temperature changes in the boiler. It has the effect of improving the performance and increasing the efficiency of the process by reducing impurities.

1 is a schematic configuration diagram of a SNCR denitrification facility system using ammonium carbonate according to the present invention.
2 is a schematic configuration diagram of a SNCR denitration facility system using ammonium carbonate according to another embodiment of the present invention.
3 is a schematic configuration diagram of a SNCR denitration facility system using ammonium carbonate according to another embodiment of the present invention.

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

The present invention is a SNCR denitrification facility system to which Selective Non-Catalytic Reduction (SNCR) is applied to reduce nitrogen oxides (NOx), an air pollutant generated from process facilities such as boilers, Reduce the amount of urea water that exists and use ammonium carbonate to increase nitrogen oxide removal by designing hybrid operation according to the supply and demand situation of raw materials and temperature changes in the boiler by using ammonium carbonate. It relates to a SNCR denitrification facility system using ammonium carbonate, which improves process performance and efficiency by reducing impurities.

1 is a schematic configuration diagram of a SNCR denitrification facility system using ammonium carbonate according to the present invention.

1, the SNCR denitrification facility system using ammonium carbonate according to the present invention includes a urea water storage unit 10, an ammonium carbonate storage unit 10', a control unit 20, and a urea water dilution unit 30 ), an ammonium carbonate dilution unit 30 ', a first nozzle unit 40, a second nozzle unit 50 and an air compressor 60.

More specifically, the operation of the urea water storage unit 10 for storing urea water and supplying it to the setting section, the ammonium carbonate storage unit 10 'for supplying ammonium carbonate to the storage and setting section, and the boiler 1 Depending on the condition, the urea water stored in the urea water storage unit 10 is controlled to be sprayed in a set section, and the temperature is detected through the sensor unit S, and the ammonium carbonate storage unit 10 'selectively according to the detection result. The control unit 20 controls the ammonium carbonate stored in the spraying in the set section, and the urea water storage unit 10 is positioned between the boiler 1 and receives the urea water from the urea water storage unit 10 The urea dilution unit 30 for generating a diluted urea solution having a reduced concentration and supplying it to the boiler 1, and the ammonium carbonate storage unit 30 positioned between the ammonium carbonate storage unit 10' and the boiler 1 An ammonium carbonate dilution unit 30 'for receiving ammonium carbonate from the unit 10' and generating a dilute ammonium carbonate solution having a reduced concentration and supplying it to the boiler 1, and the urea solution being installed in the boiler 1 A first nozzle unit 40 for spraying urea water that has passed through the dilution unit 30 into the boiler 1, and ammonium carbonate that has passed through the ammonium carbonate dilution unit 30' while installed in the boiler 1 a second nozzle unit 50 for spraying into the boiler 1; And while being located on one side of the boiler 1, compressed air is supplied to the first nozzle part 40 and the second nozzle part 50 so that the urea water and the ammonium carbonate are injected into the boiler 1. It is configured to include an air compressor 60 to do.

Here, the sensor unit (S) may be composed of a thermal infrared sensor and may be located at the lower end of the second nozzle unit 50, and the temperature inside the boiler 1 is measured in real time through the sensor unit (S). It detects and determines in real time whether to input ammonium carbonate according to the detection result.

In the present invention, in addition to the urea water supply nozzle of the general SNCR denitration system, an ammonium carbonate supply nozzle is additionally installed, so that urea water and ammonium carbonate are designed to enable hybrid operation according to the supply and demand situation of raw materials and temperature changes in the boiler. It is possible to respond optimally to real-time nitrogen oxide generation, thereby increasing the amount of nitrogen oxide removal and reducing impurities to improve process performance and increase efficiency.

Here, inside the boiler 1, a first nozzle unit 40 and a second nozzle unit 50 are sequentially installed from the direction in which exhaust gas moves by burning fossil fuel, and the second nozzle unit 50 ) is installed in a relatively low temperature region than the first nozzle unit 40.

This is because the reaction temperature inside the boiler 1 generally starts at a high temperature from the direction in which the exhaust gas moves by burning the fuel and the temperature is lowered to some extent at the point where it is discharged, so the element reacting at the reaction temperature of 1,050 ~ 1,200 ℃ The first nozzle unit 40 for spraying water and the second nozzle unit 50 for spraying ammonium carbonate reacting at a reaction temperature of 800 to 1,000 ° C. are sequentially installed, but the second nozzle unit 50 is installed in a relatively low-temperature region than the first nozzle unit 40.

In other words, in general, in the SNCR denitration system, the nozzle for spraying the reducing agent is installed so that the reducing agent reacts at a reaction temperature of 1,100 ~ 1,300 ℃, which is a section where the combustion heat rises in the boiler. When used, its performance efficiency is equal to or slightly higher than that of existing reducing agents (ammonia or urea).

On the other hand, when configured to react at a reaction temperature of 800 ~ 1,000 ℃ due to the nature of ammonium carbonate, it is possible to increase the performance and efficiency of the process by increasing the amount of nitrogen oxide removal and reducing nozzle protection and impurities.

In addition, since the reaction temperature of urea water is 1,050 to 1,200 ° C, and the reaction temperature of ammonium carbonate is 800 to 1,000 ° C, urea water is sprayed to the first nozzle unit 40 from the direction in which the exhaust gas moves by burning fossil fuel. And, the second nozzle unit 50 is configured to spray ammonium carbonate.

A plurality of nozzles may be installed in the first nozzle unit 40 and the second nozzle unit 50 according to the scale of the boiler, and the plurality of nozzles are configured in a form in which the angle is adjusted vertically or vertically, It is possible to quickly respond to real-time changing flames in the boiler (1).

Ammonium carbonate used in the present invention reacts ammonia with carbon dioxide, a waste gas of a hydrogen plant, to use ammonium carbonate at a concentration of 30 to 35% with almost no foreign substances. ~1,000℃), it is easy to generate ammonia and has excellent nitrogen oxide removal efficiency, so it is effective in securing the efficiency and stability of the subsequent process.

Ammonium carbonate ((NH ₄ ) ₂ CO ₃ ) is produced from ammonia (NH ₃ ) through the following reaction equation using boiler exhaust gas as a heat source.

(NH ₄ ) ₂ CO ₃ ↔ 2NH ₃ + CO ₂ + H ₂ O

In addition, the following chemical reaction is caused by ammonia (NH ₃ ) generated by the above reaction.

4NO + 4NH ₃ + O ₂ -> 4N ₂ + 6H ₂ O

2NO ₂ + 4NH ₃ + O ₂ -> 3N ₂ + 6H ₂ O

NO + NO ₂ + 2NH ₃ -> 2N ₂ + 3H ₂ O

Ammonium carbonate ((NH ₄ ) ₂ CO ₃ ) has almost no foreign substances and has good reactivity by using Gas Base raw material, and can solve the problem of scaling generated when using urea water. Not only is there no clogging of the outlet, but there is no generation of insoluble components (biuret, triuret, aldehydes, coal tar and metal ions, etc.) compared to the number of urea.

In addition, ammonium carbonate ((NH ₄ ) ₂ CO ₃ ) has the advantage of excellent NOx removal performance due to low temperature decomposition due to its low evaporation temperature compared to urea solution, and the NOx removal efficiency is relatively higher when ammonium carbonate is used compared to the same amount of urea , There is less generation of ammonium sulfate (Ammonium Sulfate) due to the NH ₃ Slip phenomenon (unreacted ammonia), which is a problem with the number of urea, and the price is low according to the amount used compared to the number of urea.

Therefore, the urea water and ammonium carbonate of the present invention are optimized for real-time nitrogen oxide generation through hybrid operation according to the supply and demand situation of raw materials and the temperature change in the boiler, thereby increasing the amount of nitrogen oxide removal and reducing impurities in the process. can improve performance and increase efficiency.

In addition, by driving the pumps P1 and P2, the urea water and ammonium carbonate stored in the urea water storage unit 10 and the ammonium carbonate storage unit 10 are supplied to the boiler 1 through a supply pipe (reference numeral not shown). transported inside.

Since the SNCR denitrification facility system using ammonium carbonate of the present invention is operated 365 days a year, ammonium carbonate must be continuously injected and nitrogen oxides must be steadily removed. (10') may be composed of two or more.

Accordingly, even when the consumed reducing agent is charged during operation or a problem occurs in one of the ammonium carbonate storage units 10', smooth operation is possible without interruption.

2 is a schematic configuration diagram of a SNCR denitration facility system using ammonium carbonate according to another embodiment of the present invention.

Referring to FIG. 2 attached, in the present invention, a third nozzle unit 50' is further installed on the boiler 1.

After detecting the temperature through sensing in the sensor unit (S), when the reaction temperature is higher than the range of 800 to 1,000 ° C., spraying of the second nozzle unit 50 is stopped through the control unit 20, and the exhaust gas is discharged through the outlet. This is to control the spraying of ammonium carbonate at the position of the third nozzle part 50 'where the temperature is relatively lower after being moved to the side (reference numeral not shown).

Through this, not only can the use of unnecessary ammonium carbonate be reduced, but also it is possible to improve the performance and increase the efficiency of the process due to the excellent removal efficiency of nitrogen oxides.

3 is a schematic configuration diagram of a SNCR denitration facility system using ammonium carbonate according to another embodiment of the present invention.

Referring to the accompanying FIG. 3 , the sensor unit S may be configured in a form in which the position can be adjusted vertically.

More specifically, the sensor unit (S) is located between the first nozzle unit 40 and the second nozzle unit 50 to sense the temperature inside the boiler 1 in real time, and the first nozzle unit The position is adjusted up and down between (40) and the second nozzle unit (50).

This is to detect a more accurate reaction temperature by changing the temperature sensing position according to operating conditions such as incineration raw material, combustion amount, operating time, etc. of the boiler 1, and control so that ammonium carbonate is sprayed in an appropriate section according to the detection result . In this case, after the position of the sensor unit S is adjusted up and down, the injection angle of the second nozzle unit 50 may be controlled up and down according to the detected temperature.

In addition, in the present invention, an auxiliary sensor unit (S') may be further installed at the top of the inside of the boiler (1).

The internal temperature of the boiler 1 does not remain constant for each section depending on the incineration raw material, combustion amount, operating time, etc., but changes every moment in the range of 300 ~ 1,350 ℃, The exhaust gas generated at a high temperature in the lower introduction part from the direction becomes lower in temperature in the upper discharge part, which is the direction in which the exhaust gas is finally discharged.

Therefore, there is no significant change in the temperature range, and ammonium carbonate is sprayed from the third nozzle unit 50' through the auxiliary sensor unit S' installed on the upper discharge side, which is the direction in which the exhaust gas is finally discharged. It detects in real time whether it is a temperature that can be reached, and according to the detected temperature, ammonium carbonate is sprayed instead of the second nozzle unit 50 or ammonium carbonate is sprayed in addition to the second nozzle unit 50 to produce nitrogen oxide ( NOx) can be reduced reliably.

According to the present invention, in the SNCR denitrification facility system to which Selective Non-Catalytic Reduction (SNCR) is applied to reduce nitrogen oxide (NOx), an air pollutant generated in process facilities such as boilers, Reduce the amount of urea water used due to supply and demand instability as much as possible, and use ammonium carbonate to increase nitrogen oxide removal by designing hybrid operation according to the supply and demand of raw materials and temperature changes in the boiler. It has the effect of improving the performance and increasing the efficiency of the process by reducing impurities.

In the above, reference numerals and names have been given to the drawings showing preferred embodiments and components shown in the drawings for convenience of description, but this is an embodiment according to the present invention, and the shapes shown on the drawings and the names given have been described. The scope of the right should not be construed as being limited, and the change to various shapes predictable from the description of the invention and the simple substitution with a configuration that has the same action are within the range of change for easy implementation by those skilled in the art. You will see it as self-evident.

1: boiler 10: urea water storage unit
10 ': ammonium carbonate storage unit 20: control unit
30: urea dilution unit 30': ammonium carbonate dilution unit
40: first nozzle part 50: second nozzle part
50 ': third nozzle part 60: air compressor
P1, P2: Pump S: Sensor part
S': auxiliary sensor unit

Claims (4)

A number of urea storage unit 10 for storing and supplying the number of urea to a setting section;
An ammonium carbonate storage unit 10 'for supplying ammonium carbonate to a storage and setting section;
According to the operating conditions of the boiler 1, the urea water stored in the urea water storage unit 10 is controlled to be sprayed in a set section, and the temperature is detected through the sensor unit S, and the ammonium carbonate is selectively detected according to the detection result. A control unit 20 for controlling the ammonium carbonate stored in the storage unit 10 'to be sprayed to a set section;
Being located between the urea water storage unit 10 and the boiler 1, receiving urea water from the urea water storage unit 10 to generate a diluted urea solution having a reduced concentration and supplying it to the boiler 1 Urea dilution unit 30;
Being positioned between the ammonium carbonate storage unit 10' and the boiler 1, ammonium carbonate is received from the ammonium carbonate storage unit 10' to generate a dilute ammonium carbonate solution having a reduced concentration toward the boiler 1. Ammonium carbonate dilution unit to supply (30 ');
A first nozzle unit 40 installed in the boiler 1 and spraying urea water that has passed through the urea water dilution unit 30 into the boiler 1;
A second nozzle unit 50 installed in the boiler 1 and spraying ammonium carbonate passed through the ammonium carbonate dilution unit 30' into the boiler 1; and
Being located on one side of the boiler 1, supplying compressed air to the first nozzle part 40 and the second nozzle part 50 so that the urea water and the ammonium carbonate are injected into the boiler 1 Air compressor (60);
A SNCR denitrification facility system using ammonium carbonate, characterized in that it comprises a.
According to claim 1,
Inside the boiler 1,
The first nozzle unit 40 and the second nozzle unit 50 are sequentially installed from the direction in which exhaust gas moves by burning fossil fuel,
The second nozzle unit 50 is a SNCR denitration facility system using ammonium carbonate, characterized in that it is installed in a relatively low temperature region than the first nozzle unit 40.
According to claim 1,
A plurality of nozzles are installed in the first nozzle part 40 and the second nozzle part 50 according to the scale of the boiler, and the plurality of nozzles are configured in a form in which the angle is adjusted vertically or vertically, SNCR denitrification facility system using ammonium carbonate.
According to claim 1,
The sensor unit (S) is a thermal infrared sensor,
It is located between the first nozzle part 40 and the second nozzle part 50 to sense the temperature inside the boiler 1 in real time,
SNCR denitration facility system using ammonium carbonate, characterized in that the position is adjusted up and down between the first nozzle part 40 and the second nozzle part 50.

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