KR20110000834A - Complex denitrification system - Google Patents

Abstract

PURPOSE: An integrated complex denitrification system is provided to obtain the space velocity for removing nitrogen oxide, by preventing the differential pressure when inflowing exhaust gas. CONSTITUTION: An integrated complex denitrification system including a boiler comprises the following; an exhaust gas inlet on one lower side of the system; a filtering precipitator with an exhaust gas outlet on the other upper side of the system; a filtering cloth(200) included inside the filtering precipitator; and a single SCR catalyst(1000) included inside the filtering cloth, for removing nitric oxides from the exhaust gas. The SCR catalyst is integrated with the inside of the filtering cloth.

Description

Integrated Complex Denitrification System {COMPLEX DENITRIFICATION SYSTEM}

In the present invention, in order to remove the nitrogen oxides remaining in the flue gas between the boiler and the chimney, in order to exhibit excellent denitrification efficiency even in a low temperature region, the SCR catalyst is mounted inside the filter cloth of the bag filter as a single long catalyst bag. Integrate this, but the flow of the exhaust gas in the filter cloth smoothly, and the lower 25% to 35% of the filter cloth to the integrated composite denitrification system provided with a space so as not to take the differential pressure as much as possible when the flue gas inflow.

In general, electricity generation uses nuclear, coal, LNG, oil and renewable raw materials. In Korea, coal accounts for about 33%, which is increasing every year. In addition, the government is also planning to maintain more than 40% of heavy oil and coal-fired power generation facilities in consideration of the global supply and demand of energy resources. However, as regulations on air pollutants are expected to be tightened in the future, it is necessary to develop related technologies for treating air pollutants emitted from boilers.

The conventional treatment of existing boiler exhaust gas is applied to the system of unique unit technology such as denitrification unit, electrostatic precipitator, deactivation unit, and other harmful substance treatment technology. Currently, the Selective Catalytic Reduction (SCR) method, which is a dry method in terms of technical reliability and economic efficiency, is adopted by various countries around the world, especially in Japan. I use it.

In particular, the treatment of nitrogen compounds in boilers is mainly the selective catalytic reduction method using ammonia as a reducing agent. Catalysts mainly used for the treatment of nitrogen oxides in boilers disperse oxides such as V, W and Mo and mixtures thereof in a finely dispersed form (TiO ₂ / V ₂ O ₂ ) in Ti-based oxides. Depending on the shape, it is used in the shape of honeycomb, plate, etc. However, in domestic boilers, the catalyst activity was reduced due to the thermal fatigue of the catalyst due to frequent operation changes such as the temperature of the flue gas increased instantaneously, and the catalyst life was lowered, thereby increasing the operating cost due to frequent catalyst exchange.

To solve this problem, a method of installing a denitrification facility at the rear end of the Flue-Gas Desulfurization (FGD) field has been developed. Brought about economic losses.

In order to satisfy the recently strengthened standards, even if low sulfur fuel is used, SO2 generation of about 100 to 200 ppm is inevitable, and 5 to 20% of water is contained in the exhaust gas, which is inevitable when ammonia is used as a reducing agent of the denitrification equipment. As a result, catalyst poisoning may occur due to the production of ammonium sulfate and the like. In addition, the outflow of ammonia contained in the flue-gas causes corrosion of the downstream equipment, and the regulation of ammonia itself is tightened.

Commercial ammonia catalysts are operated with a molar ratio of NH ₃ / NOx of 0.8 to 0.9 in order to avoid ammonia slip, but in this case the NOx removal rate can be obtained only up to 80 to 90%. There is a disadvantage in that the amount of the catalyst used is sharply increased.

And because the enumerated system takes up a lot of installation space, it is difficult to secure the site and the installation cost is increased when the existing facility is repaired. In addition, there is a problem that the performance fluctuation range of the electrostatic precipitator is large due to the change of coal type.

To solve the above problems, the applicant filed with the Patent Office on March 17, 2009 as an integrated complex denitrification system (Application No. 10-2009-22540), the claims, that is, claim 1, the boiler In the integrated composite denitrification system provided, the inside is formed in the form of an empty box, the exhaust gas inlet through which the exhaust gas after combustion discharged from the boiler is formed in the lower portion of one side, the exhaust gas outlet for exhaust gas is discharged to the upper portion of the other side Filter dust collector is provided; A filter cloth provided inside the bag filter; And a plate-shaped SCR catalyst layer provided inside the filter cloth to remove nitrogen oxides contained in the exhaust gas. According to claim 2, Claim 2, wherein the one side of the exhaust gas inlet port of the filter precipitator, the control damper is provided that can be added to the flue gas inflow amount containing nitrogen oxide to the filter dust collector, Claim 3 The device of claim 1, wherein the SCR catalyst layer comprises: a support provided in the bag filter; And a disc shaped SCR catalyst installed on the support and provided in multiple stages at regular intervals so as not to take a differential pressure. 4, wherein the cross section of the SCR catalyst is formed in one of a honeycomb type and a corrugated type.

를 달성할 수 없어 시스템 효율이 저하(하단부는 가스유입이 작아서 점선으로 표시)되는 문제점이 있었다.However, in the integrated composite denitrification system of the above-mentioned patent application No. 10-2009-22540, as shown in Figure 1, the SCR catalyst 320 is located on the upper side of the support 310 installed at a predetermined interval inside the filter cloth 200 As shown in FIG. 2, when the catalyst is installed in multiple stages, as shown in FIG. 2, since about 80% of the flue gas flows only to the upper catalyst layer, a space velocity, in which nitrogen oxide contained in the flue gas is removed, SV)

There was a problem in that the system efficiency is lowered (the lower part is indicated by a dashed line due to a small gas inflow) because it cannot be achieved.

In order to solve the above problems, the present invention is to mount the SCR catalyst as a single long catalyst as a single catalyst inside the filter cloth of the bag filter in order to exhibit an excellent denitrification efficiency even in a low temperature region, to integrate it, the exhaust gas in the filter cloth The lower 25% to 35% of the filter cloth is provided with a space so as to smooth the flow of the gas and prevent the differential pressure from being applied as much as possible when the exhaust gas is introduced.

In order to achieve the above object, the present invention

In an integrated composite denitrification system having a boiler,

An inner bag formed in an empty box shape, and an exhaust gas inlet through which exhaust gas after combustion discharged from the boiler flows in a lower part of one side, and an exhaust gas outlet having an exhaust gas outlet in an upper part of the other side;

A filter cloth provided inside the bag filter; And

A single SCR catalyst (1000) provided inside the filter cloth and formed to have a bag shape to remove nitrogen oxides contained in the exhaust gas; Including but not limited to,

Here, the SCR catalyst 1000 is integrated into the filter cloth 200 of the bag filter 100, to facilitate the flow of the exhaust gas in the filter cloth 200, so that the differential pressure is not taken as much as possible when the exhaust gas inlet ( And spaced at 25% to 35% of the lower portion of 200).

를 달성할 수 있는 효과가 있다.When the present invention generated by the above-described configuration is installed with a single catalyst, the flue gas flows smoothly, and the differential pressure is not taken as much as possible when the flue gas is introduced.

There is an effect that can be achieved.

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

3 is a view schematically showing an integrated composite denitrification system according to the present invention, and FIG. 4 is a view schematically showing the filter cloth of FIG. 3 and schematically showing the air flow.

The present invention is an integrated composite denitrification system relates to a technique for removing nitrogen oxides by selective catalytic reduction, as shown in Figure 3, the inside is formed in the form of an empty box, the exhaust gas after combustion discharged from the boiler 20 on one side A filter dust collector 100 having an inlet exhaust gas inlet 150 formed therein; A filter cloth provided in the bag filter 200; And a single SCR catalyst 1000 that is provided inside the filter cloth and has a long bag shape for removing nitrogen oxides contained in the exhaust gas.

Filter dust collector (filtration dust collector, 100) serves to filter various harmful particles, such as dust contained in the exhaust gas discharged from the boiler (20). In this embodiment, the filter medium of the glass fiber or cotton fiber attached to the filter material as shown in Figure 4 to form a filter 200 to adopt the internal filtration method to collect the dust inside the filter cloth.

As described above, the filter cloth 200 is a function of filtering out dust from inside the bag filter 100 and may also be called a follicle or a filter cloth. That is, when the dust and the like contained in the exhaust gas flows into the inside of the bag filter 100, it serves to filter them. At this time, the material of the filter cloth 200 may be composed of natural fibers such as cotton wool, wool, asbestos, silk and hemp, or may be implemented by artificial fibers such as glass fiber, synthetic fiber and metal wool.

In the embodiment, the filter cloth 200 was formed in a bag shape. However, it should be noted that in the construction of the filter cloth 200, the gap between the tissues of the filter cloth 200 should be dense enough to filter out particulate matter of about 0.1 to 0.5.

In addition, the allowable temperature of the filter cloth 200 is different in the temperature that can be treated according to the fiber, but except for asbestos, generally not suitable for high temperature high temperature gas, care must be taken in selecting the material of the filter cloth 200 according to the implementation conditions. do.

In particular, the SCR catalyst 1000 is provided inside the filter cloth 200 to serve to remove nitrogen oxides contained in the exhaust gas. In the present invention, unlike the existing technology, the SCR catalyst 1000 is mounted inside the filter cloth 200 of the bag filter 100 so as to be integrated with each other, to facilitate the flow of the exhaust gas in the filter cloth 200, and the inlet gas inflow. It is preferable that a space is provided in the lower 25% to 35% of the filter cloth 200 so that the differential pressure is not applied as much as possible.

And in the practice of the present invention, the control damper 155 for controlling the influx of the inflow amount of the exhaust gas containing nitrogen oxide to the filter dust collector 100 in the exhaust gas inlet 150 formed on one side lower portion of the filter dust collector 100 It can be carried out further including.

That is, by controlling the inflow amount of the exhaust gas flowing into the bag filter 100, it is possible to determine the demassation of nitrogen oxides and the operation of the denitrification system. And when the filter cloth 200 or the SCR catalyst 1000 is replaced, there is an advantage that can block the inflow of the exhaust gas through the control damper 155 and replace them. In addition, by integrating the bag filter 100 and the SCR catalyst 1000, there is an advantage in that it is possible to save space for securing the space and operating the system.

Hereinafter will be described the operating principle of the present invention.

3, the exhaust gas discharged after the combustion of coal in the boiler 20 is discharged along the pipe. The discharged exhaust gas is mixed with ammonia, a reducing agent injected by an ammonia injector.

The discharged exhaust gas is regulated by the control damper 155 along the pipe and is introduced into the bag filter 100. Since the exhaust gas introduced into the filter dust collector 100 is relatively higher in temperature than the inside of the filter dust collector 100, the exhaust gas rises upward due to a density difference, and passes dust through the filter cloth 200 installed inside the filter dust collector 100. Etc. are removed.

And the exhaust gas from which dust is removed is passed through the SCR catalyst 1000, which is formed in a bag shape installed in the filter cloth 200 through the lower portion of the filter cloth 200, as shown in FIG. ) and the reaction taking place is the oxidation reaction in which hydrogen is exit, nitrogen compounds causing a reduction loss of oxygen (for example:. 4NO + 4NH3 + O2 4N2 + 6H2) and consequently the ammonia and the exhaust gas is nitrogen (N ₂₎ and water (H ₂ O) to remove nitrogen oxides (NOx).

이다.At this time, the reaction temperature is 200 to 350, and the space velocity (SV) is

to be.

After the exhaust gas exited through the exhaust gas outlet 160 of the bag filter is the temperature is reduced to a certain temperature while going through the reduction reaction, the temperature is reduced to 90 while passing through the heat exchanger (30) chimney 40 It is discharged to the outside via.

1 is a view schematically showing a filter cloth according to the prior art,

2 is an enlarged view illustrating main parts schematically showing air flow of the filter cloth of FIG. 1;

3 is a view schematically showing an integrated complex denitrification system according to the present invention;

FIG. 4 schematically shows the filter cloth of FIG. 3 and schematically shows the air flow.

<Description of the symbols for the main parts of the drawings>

20; Boiler 30; heat transmitter

40; Chimney 100; Bag filter

150; Exhaust gas inlet 155; Adjustable damper

160; Exhaust gas outlet 200; Filter cloth

1000; SCR Catalyst

Claims (1)

In an integrated composite denitrification system having a boiler, An inner bag formed in an empty box shape, and an exhaust gas inlet through which exhaust gas after combustion discharged from the boiler flows in a lower part of one side, and an exhaust gas outlet having an exhaust gas outlet in an upper part of the other side; A filter cloth provided inside the bag filter; And A single SCR catalyst (1000) provided inside the filter cloth and formed to have a bag shape to remove nitrogen oxides contained in the exhaust gas; Including but not limited to, Here, the SCR catalyst 1000 is integrated into the filter cloth 200 of the bag filter 100, to facilitate the flow of the exhaust gas in the filter cloth 200, so that the differential pressure is not taken as much as possible when the exhaust gas inlet ( An integrated composite denitrification system, characterized in that a space is provided at a lower portion of 25% to 35% of 200).

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