KR101952021B1 - NOx Removing System Using Urea as Reduction Catalyst - Google Patents

Abstract

The present invention relates to a urea tank for storing urea; A urea supply pump for supplying urea from the urea tank to high-frequency induction heating; High frequency induction heating for rapidly heating the urea supplied from the urea supply pump; A spray nozzle for spraying the product pyrolyzed by the high frequency induction heating in a reaction space; A compressed air supply for supplying compressed air to the reaction space; A blocking damper for blocking supply of the combustion gas; And a reaction space in which a combustion gas and a pyrolyzed product of urea react with each other to reduce nitrogen oxides, and a method for removing nitrogen oxides using the same.

Description

TECHNICAL FIELD [0001] The present invention relates to a NOx removal system and a NOx removal system using urea as a reduction catalyst,

The present invention relates to a nitrogen oxide removal system and a removal method using urea as a reduction catalyst. More particularly, the present invention relates to a nitrogen oxide removal system and a removal method using urea as a reduction catalyst, To a nitrogen oxide removal system and a removal method using urea as a reduction catalyst.

Ammonia (NH ₃ ) and urea ((NH ₂ ) ₂ CO) are used as reduction catalysts for reducing NOx contained in the combustion gas. Of these, ammonia is a substance that can cause explosion and requires a handling and licensing.

Unlike ammonia, urea ((NH ₂ ) ₂ CO) is easily handled as a liquid phase, but it is decomposed into ammonia (NH ₃ ) and water vapor (H ₂ O) to improve the mixing with the combustion gas and the reduction reaction in the catalyst Is required.

As a condition for decomposing urea into ammonia (NH ₃ ) and water vapor (H ₂ O), it is required to heat the urea to a pyrolysis temperature of 150 ° C. or higher when injecting the urea into the combustion gas.

_{(NH 2) 2 CO → NH} 3 + H 2 O

A method of decomposing urea into ammonia (NH ₃ ) and water vapor (H ₂ O) using a chemical reaction (thermal decomposition) as in the following chemical reaction equation is used in the prior art by injecting urea into a high temperature exhaust gas have.

(NH ₂ ) ₂ CO + 2NO + 1 / 2O ₂ ? 2N ₂ + CO ₂ + 2H ₂ O

However, when the temperature of the exhaust gas is low, the reduction reaction of NOx as described above can not be further promoted, and countermeasures are demanded.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a urea catalyst capable of promoting the reduction reaction of NOx using urea as a reducing catalyst even when the exhaust gas temperature is low. And to provide a nitrogen oxide removal system and a removal method using the same as a reduction catalyst.

The technical problem of the present invention as described above is achieved by the following means.

(1) a urea tank for storing urea; A urea supply pump for supplying urea from the urea tank to high-frequency induction heating; High frequency induction heating for rapidly heating the urea supplied from the urea supply pump; A spray nozzle for spraying the product pyrolyzed by the high frequency induction heating in a reaction space; A compressed air supply for supplying compressed air to the reaction space; A blocking damper for blocking supply of the combustion gas; And a reaction space in which the combustion gas and the pyrolyzed product of urea react with each other to reduce the nitrogen oxide, wherein the urea is a reduction catalyst.

(2) In the above-mentioned (1), it is preferable that,

A first solenoid valve connected in parallel between the urea supply pump and the high frequency induction heater to form a recovery circuit to the urea tank; A third solenoid valve connected in series between the high frequency induction heater and the injection nozzle; A second solenoid valve connected in parallel between the high frequency induction heater and the third solenoid valve to form a recovery circuit to the urea tank; And a fourth solenoid valve (4) connected in parallel between the third solenoid valve and the injection nozzle for controlling the flow of compressed air from the compressed air supply.

(3) In the above (1)

And a recovery line temperature sensor for measuring the temperature of the fluid discharged from the high frequency induction heating furnace on the pipe between the high frequency induction heating furnace and the second solenoid valve. system.

(4) A method for removing nitrogen oxides using a nitrogen oxide removal system using urea according to (2) above as a reduction catalyst,

Operating an electronic circuit portion for driving the high frequency induction heater;

Driving a urea supply pump to supply urea;

Opening the first solenoid valve and the second solenoid valve with the third solenoid valve (3) and the fourth solenoid valve (4) in a cut-off state;

Opening the third solenoid valve (3) when the urea is heated above the set temperature, and blocking the first solenoid valve and the second solenoid valve together therewith; And

And a step of injecting the combustion gas into the reaction space by opening the blocking damper and injecting urea into the reaction space through the injection nozzle to perform the nitrogen oxide reduction reaction. Way.

(5) In the above (4), when the reaction is terminated,

Stopping the operation of the electronic circuit section to stop the driving of the high frequency induction heater;

Closing the third solenoid valve to shut off the inflow of the urea and opening the second solenoid valve;

Dropping the speed of the urea feed pump and stopping the pump when the recovered temperature measured by the recovered temperature sensor is lower than the set temperature;

Shutting off the second solenoid valve when the urea supply pump is stopped to shut off the internal circulation of the fluid;

Closing the blocking damper in a state where the second solenoid valve is shut off to block the inflow of the combustion gas;

Opening a fourth solenoid valve to clean the reaction space and the injection nozzle; And

And purging and cleaning the inside of the reaction space and the injection nozzle by injecting compressed air at a high pressure through a compressed air supply, wherein the urea is a reduction catalyst.

As described above, according to the nitrogen oxide removal system and the removal method using the urea reduction catalyst according to the present invention, even when the temperature of the exhaust gas is low, the reduction reaction of NOx can be further promoted by using urea as the reduction catalyst It gives effect.

FIG. 1 is a configuration diagram of a nitrogen oxide removal system using urea as a reduction catalyst according to the present invention,
2 is a flow chart showing the initiation and subsequent progress of NOx removal reaction using a nitrogen oxide removal system using urea as a reduction catalyst according to the present invention,
FIG. 3 is a flow chart showing the termination process of the NOx removal reaction using the nitrogen oxide removal system using urea as a reduction catalyst according to the present invention.

Hereinafter, the nitrogen oxide removal system and the removal method using the urea reduction catalyst according to the present invention will be described in detail.

1 is a configuration diagram of a nitrogen oxide removal system using urea as a reduction catalyst according to the present invention.

The system of the present invention includes a high frequency induction heater 40 having a urea tank 10, a urea feed pump 20, a flow meter 30, and an electronic circuit 41 equipped with an agitator 11, A feeder 50, an injection nozzle 60, a blocking damper 70, and a reaction space 80.

The urea tank 10 is a tank in which a urea to be involved in the reaction is stored, and an agitator 11 is mounted for stirring the urea.

A urea supply pump 20 is installed at the rear end of the urea tank for supplying the urea stored in the urea tank 10. Therefore, the urea stored in the tank 10 by the urea feed pump 20 is supplied to the circulation or injection nozzle, and a flow meter 30 is provided for checking to have a constant flow rate.

The high frequency induction furnace 40 is required to rapidly heat the introduced urea to the pyrolysis temperature of the urea. The urea is rapidly heated to a pyrolysis temperature of 150 캜 or higher by the high-frequency induction furnace 40 and decomposed into ammonia and water vapor. For this purpose, an electronic circuit unit 41 is provided.

It is needless to say that the high-frequency induction heater 40 used in the present invention may be a series pipe coil type or a parallel multi-pipe type.

The ammonia produced by pyrolysis in the high frequency induction furnace 40 is supplied to the injection nozzle 60 and the injection nozzle 60 injects ammonia into the reaction space 80.

At the same time, a blocking damper 70 is provided for supplying and blocking the combustion gas requiring treatment into the reaction space 80, and ammonia and combustion gas react in the reaction space 80 to reduce and remove NOx .

Four valves on the pipeline of the system of the present invention are mounted to form a fluid circuit, specifically the fluid circuit is connected in parallel between the urea supply pump and the high frequency induction heater to provide a recovery circuit to the urea tank A first solenoid valve for forming the first solenoid valve; A third solenoid valve connected in series between the high frequency induction heater and the injection nozzle; A second solenoid valve connected in parallel between the high frequency induction heater and the third solenoid valve to form a recovery circuit to the urea tank; And a fourth solenoid valve (4) connected in parallel between the third solenoid valve and the injection nozzle for controlling the flow of compressed air from the compressed air supply.

Hereinafter, the operation of the urea fluid circuit of the present invention will be described in more detail.

The first solenoid valve 1 and the second solenoid valve 2 are opened and the third solenoid valve 3 and the fourth solenoid valve 3 are opened during the initiation and progress of the reaction. The valve 4 is shut off. As a result, the urea heated in the high frequency induction heater 40 is not discharged to the outside through the third solenoid valve 3 but is circulated inside, and gradually reaches a pyrolysis temperature (for example, 150 캜) .

The recovery line temperature sensor 5 is mounted on the pipe between the high frequency induction heater 40 and the second solenoid valve 2 to measure the temperature of the fluid discharged from the high frequency induction heater 40, The first solenoid valve 1 and the second solenoid valve 2 are closed while the third solenoid valve 3 is opened.

On the other hand, when the reaction is terminated, the fluid circuit interrupts the third solenoid valve 3 and opens the second solenoid valve 2 to internally circulate the in-pipe fluid through the recovery line, The second solenoid valve 2 is shut off and the fourth solenoid valve 4 is opened to purge and clean the reaction space 80 when the temperature falls below a set temperature (for example, 100 ° C).

Hereinafter, the process of reducing NOx contained in the combustion gas using the urea fluid circuit according to the present invention for performing the above-described configuration and operation will be described in detail with reference to the preferred embodiments of the present invention.

To this end, as shown in FIG. 2, the start and follow-up processes of the NOx reduction reaction according to the embodiment of the present invention are as follows.

First, in Step 201, the agitator 11 of the urea tank 10 is driven. In step 202, the electronic circuit section 41 for driving the high frequency induction heater 40 is operated. At this time, the heating temperature is set to a maximum value which is a pyrolysis temperature.

At step 203, the flow rate is checked using the flow meter 30 to drive the pump 20 to accelerate the urea, preferably at a constant flow rate.

In step 204, the first solenoid valve 1 and the second solenoid valve 2 are opened. At this time, the third solenoid valve 3 and the fourth solenoid valve 4 should be shut off. When the first solenoid valve 1 and the second solenoid valve 2 are opened and the third solenoid valve 3 and the fourth solenoid valve 4 are in the cut-off state, the urea is returned to the urea tank 10), and the circulation is performed until the temperature rises and reaches the set temperature.

When the urea reaches the set temperature or more in step 205, the third solenoid valve 3 is opened and at the same time, the first solenoid valve 1 and the second solenoid valve 2 are shut off.

In step 206, the combustion gas flows into the reaction space 80 through the opening of the blocking damper 70, and the urea is injected into the reaction space 80 through the injection nozzle 60 to cause the reaction.

The process of purging or cleaning the reaction space 80 after the removal of nitrogen oxide (NOx) due to the reaction as described above will be described in detail through a reaction termination process according to a preferred embodiment of the present invention.

As shown in FIG. 3, when the reduction reaction of nitrogen oxides (NOx) using the system according to the present invention is completed, the operation of the electronic circuit unit 41 is first performed in step 301 to cut off the driving of the high frequency induction heater 40 Stop.

In step 302, the third solenoid valve 3 is shut off to block the inflow of urea, and in step 303, the second solenoid valve 2 is opened.

In step 304, the speed of the urea feed pump 20 is lowered to the lowest level, and when the recovered temperature measured in the recovered temperature sensor 5 is lower than 100 캜, the urea feed pump 20 is stopped.

When the urea feed pump 20 is stopped, the second solenoid valve 2 is shut off at step 305 or thereafter to shut off the internal circulation of the fluid. At this time, the first solenoid valve 1 is in a cut-off state.

In a state where the second solenoid valve 2 is shut off, the blocking damper 70 is shut off in step 306 to block the inflow of the combustion gas.

At the same time, the fourth solenoid valve 4 is opened in step 307 to clean the reaction space 80 and the injection nozzle 60.

In step 308, high pressure compressed air is injected through the compressed air supply 50 to purge and clean the interior of the reaction space 80 and the injection nozzle 60.

Then, in step 309, the fourth solenoid valve 4 is shut off, and the operation of the compressed air supply 50 is stopped.

With the above arrangement, even when the temperature of the exhaust gas is low, the reduction reaction of nitrogen oxides (NOx) can be further promoted by using urea as a reduction catalyst.

10: Urea tank
11: Stirrer
20: Urea supply pump
30: Flow meter
40: High frequency induction heating
41: Electronic circuit part
50: Compressed air supply
60: injection nozzle
70: Blocking damper
80: reaction space

Claims (5)

A nitrogen oxide removal system comprising urea as a reduction catalyst,
A urea tank for storing urea; A urea supply pump for supplying urea from the urea tank to high-frequency induction heating; High frequency induction heating for rapidly heating the urea supplied from the urea supply pump; A spray nozzle for spraying the product pyrolyzed by the high frequency induction heating in a reaction space; A compressed air supply for supplying compressed air to the reaction space; A blocking damper for blocking supply of the combustion gas; A reaction space in which a combustion gas and a pyrolyzed product of urea react with each other to reduce nitrogen oxides; And
A first solenoid valve installed on the pipeline of the system and connected in parallel between the urea supply pump and the high frequency induction heater to form a recovery circuit to the urea tank, a first solenoid valve connected in series between the high- A second solenoid valve connected in parallel between the third solenoid valve and the third solenoid valve to form a recovery circuit to the urea tank and a second solenoid valve connected in parallel between the third solenoid valve and the injection nozzle, And a fourth solenoid valve for controlling the flow of compressed air from the feeder, wherein the urea is a reduction catalyst.
delete delete delete delete

Images