KR100883162B1 - System for preventing generation of environmental contaminants in coal-fired power station - Google Patents

Abstract

A system for preventing generation of environmental contaminants in a coal-fired power station is provided to prevent generation of two kinds of environmental contaminants by removing carbon dioxide using cinder, and then neutralizing the cinder. A system for preventing generation of environmental contaminants in a coal-fired power station comprises a first water tank(120-1) generating strong alkaline water by reacting bottom ash with water; a removal reaction tank(170) accommodating the strong alkaline water and removing carbon dioxide contained within exhaust gas; a sludge reservoir(190) storing sludge generated by the removal reaction; a first stone reservoir(140-1) storing bottom ash stone neutralized staying in the first water tank; and a second water tank(120-2) feeding strong alkaline water generated by reacting fly ash with water into the removal reservoir.

Description

Environmental pollutant prevention system of thermal power plant {SYSTEM FOR PREVENTING GENERATION OF ENVIRONMENTAL CONTAMINANTS IN COAL-FIRED POWER STATION}

The present invention relates to a system for preventing environmental pollutants in a thermal power plant, and more particularly, using bottom ash and fly ash, which are coal ashes generated by coal combustion in a combustion furnace of a thermal power plant. System to prevent environmental pollutants from thermal power plants that can remove and clean carbon such as carbon dioxide contained in exhaust gas discharged from the combustion furnace, and at the same time neutralize bottom ash and fly ash to be harmless. It is about.

In general, coal ash (i.e. ash) generated as a by-product from coal-fired power plants is an inorganic residual material remaining after the combustion of coal as fuel in a combustion furnace. It is divided into a bottom ash (fly ash) discharged through the upper flue (煙道) along with the bottom ash (bottom ash) and the exhaust gas.

The fly ash is discharged through the flue with the exhaust gas in the state of being scattered into particles of fine size, and is collected by a dust collector provided on the flue during the discharge.

The bottom ash is formed to form a rather large particle by the sintering action in the combustion furnace. The bottom ash is accumulated by falling down in the combustion furnace, and is usually collected and crushed into a size of about 1 to 10 mm through a grinder.

In the past, these coal ashes were mainly buried in landfills additionally installed in power plants, but landfilling became difficult due to the recent difficulty in securing landfills due to a sharp rise in land prices.

In addition, recently, coal ash has been actively recycled.

That is, fly ash is mainly recycled to cement admixtures, landfills, land improvement materials, lightweight aggregates, and bottom ash is recycled to subgrade soils, pavement base materials, and concrete mix aggregates.

However, the recycling rate is still low, and much of the situation is simply landfilled.

Therefore, at this point, there is a need to further expand the field of recycling coal ash.

On the other hand, coal ash is different in its composition depending on the type of combustion coal and the type of combustion furnace, but basically contains about 2 to 45% of quicklime (CaO) component.

Therefore, when landfilled or recycled coal ash, CaO contained reacts with water to produce calcium hydroxide (Ca (OH) ₂ ), resulting in strong alkalinity of pH 12 or above. It causes damage to the structure and sometimes causes partial ridges. On the other hand, when it is landfilled or recycled as a civil component, the strong alkaline leachate is released into the river or seawater by contact with groundwater or rainwater to produce strong alkaline leachate. There is a problem that can cause serious water pollution.

Therefore, the coal ash is required to enhance the possibility that it can be recycled for other purposes as well as not to cause environmental pollution or damage to the structure when being buried or recycled by being neutralized in advance.

However, the neutralization and detoxification of coal ash should not be excessively costly or cause further environmental pollution during the treatment.

In other words, a satisfactory treatment method in terms of economics and eco-friendliness should be taken.

On the other hand, in the above-described thermal power plant, carbon dioxide (CO ₂ ) is generated in a large amount by the following mechanism in accordance with the combustion of coal fuel and contained in the exhaust gas.

"C + O _2- > CO ₂ ↑ (mass carbon dioxide generation)"

In relation to this, carbon dioxide accounts for about 60% of all greenhouse gases, which is the main culprit of global warming, and efforts to reduce its emissions have been made early through international agreements on climate change. With this introduction, if companies cannot reduce their emissions by their allotted targets, they will have to purchase their allowances, thus losing their competitiveness due to higher costs. Conversely, companies that have reduced their emissions more than their allotted targets will be able to reduce their emissions. It can be sold to other companies to generate additional profits while also giving you the image of a green company.

Therefore, the carbon dioxide generated in the thermal power plant should be actively reduced, but the groundbreaking reduction technology has not been developed enough to satisfy efficiency, economics, and field applicability.

The present invention was devised to solve the above problems, and can remove carbons such as carbon dioxide contained in the exhaust gas by using coal ash generated by itself, and at the same time neutralize coal ash. The aim is to provide a pollution prevention system for thermal power plants.

The above objects and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention by those skilled in the art.

Environmental pollution generation prevention system of the thermal power plant of the present invention for achieving the above object, the bottom ash is generated to be integrated on the lower side of the furnace, the fly ash with the exhaust gas through the flue extending from the furnace The fly ash is a system for preventing the generation of environmental contaminants in the thermal power plant system collected in the dust collector on the flue, and receives the bottom ash from the combustion furnace and reacts with the water contained therein to generate strong alkaline water. A first water immersion tank; A removal reaction tank provided on the flue behind the dust collector and accommodating the strong alkaline water supplied from the first water immersion tank and removing the carbon dioxide contained in the exhaust gas passed therethrough; A sludge storage tank for receiving and storing sludge produced by the removal reaction in the removal reaction tank; And a first aggregate storage tank configured to receive and store a bottom ash aggregate remaining in the first water immersion tank after being neutralized according to the generation of the strong alkaline water. It includes.

Preferably, the environmental pollution generation prevention system of the thermal power plant of the present invention, the second water immersion tank receiving the fly ash taken out from the dust collector and reacted with the water contained therein to generate a strong alkaline water to supply to the removal reaction tank; And a second aggregate storage tank for receiving and storing the fly ash aggregate remaining in the second water immersion tank after being neutralized according to the generation of the strong alkaline water. It may further include.

Also preferably, the environmental pollutant generation system of the thermal power plant of the present invention, the strong alkali water generated in the first and second water immersion tank is supplied to the removal reaction tank through a supply pipe, provided on the supply pipe Valve means for selectively opening and closing the supply of the strong alkaline water from the first water immersion tank or the second water immersion tank to the removal reaction tank; It may further include.

Also preferably, in the environmental pollutant generation prevention system of the thermal power plant of the present invention, the first water immersion tank and the second water immersion tank are repeatedly applied to the bottom ash and the fly ash injected into the generation of the strong alkaline water. Impact imparting means for extracting quicklime components for; It may be provided.

Also preferably, in the environmental pollutant generation prevention system of the thermal power plant of the present invention, the removal reaction tank, the contact rate improving means for improving the contact rate between the strong alkaline water and the exhaust gas; Wherein, the contact rate improving means, the rotating means for rotating the strong alkaline water, the stirring means for stirring the strong alkaline water, gas subdivision means for subdividing and injecting the exhaust gas, aeration means for aeration to inject the exhaust gas It may be any one of.

Also preferably, in the environmental pollutant generation prevention system of the thermal power plant of the present invention, the first aggregate storage tank and the second aggregate storage tank, an aggregate outlet for taking out the internally stored aggregate; It may be provided.

Also preferably, in the environmental pollution generation prevention system of the thermal power plant of the present invention, the sludge storage tank, the sludge outlet for taking out the sludge of the internally stored sludge state or dried state; It may be provided.

According to the present invention, by using a large amount of coal ash generated in a coal-fired power plant, the carbonaceous material such as carbon dioxide contained in the exhaust gas can be removed and purified, and in the process, the coal ash can also be neutralized and detoxified. In addition, the effect of detoxifying both kinds of environmental pollutants generated during operation can be achieved.

As a result, it is possible to prevent the pollution of the air environment by carbon dioxide and to secure corporate competitiveness by actively coping with the stricter regulations on carbon dioxide emission.

In addition, since the coal ash can be neutralized, it is possible to expand the recycling field and prevent water pollution or damage to the structure when it is buried or recycled.

In addition, since carbon dioxide is removed using self-generated coal ash, it is very economical and has excellent field applicability, and thus does not cause any other environmental pollution in the process, thereby having an environmentally friendly advantage.

Furthermore, since calcium carbonate that can be usefully recycled is also provided as a by-product, it is also excellent in economy and utility in this respect.

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

1 shows an environmental pollutant generation system of a thermal power plant according to a preferred embodiment of the present invention.

In a coal-fired power plant, the coal fuel is combusted in the combustion chamber 10 to obtain high heat energy. In the process, a bottom ash is accumulated in the lower portion of the combustion furnace 10 and accumulated. Fly ash is discharged together with the exhaust gas through the flue 20 extending from the top, the fly ash discharged through the flue 20 is collected in the dust collector 30 provided on the flue (20).

Environmental pollution generation prevention system of the thermal power plant according to the present invention, the first water immersion tank is integrated in the lower side of the combustion furnace 10 and receives the bottom ash discharged to the outside and reacts with the internally received water to generate a strong alkaline water And a second water immersion tank 120 which is collected by the dust collector 30 provided on the flue 20 and is supplied with a fly ash which is taken out to the outside to react with water contained therein to generate strong alkaline water 120. -2) and exhaust gas provided on the flue 20 behind the dust collector 30 to internally receive the strong alkaline water supplied from the first water immersion tank 120-1 and the second water immersion tank 120-2 The first reactor for receiving and storing the bottom ash aggregate remaining after neutralization in accordance with the generation of strong alkaline water in the removal reaction tank 170 and the first water immersion tank 120-1 to remove carbons such as carbon dioxide contained in the gas Strong alkali water in the aggregate storage tank 140-1 and the second immersion tank 120-2. Second aggregate storage tank (140-2) for receiving and storing the bottom ash aggregate remaining after being neutralized according to the production, and sludge storage tank 190 for receiving and storing the sludge produced by the removal reaction in the removal reaction tank (170) It includes.

The bottom ash integrated on the lower side of the combustion furnace 10 is transferred through the first transfer pipe 110-1 and introduced into the first water immersion tank 120-1, wherein the transfer is performed by pneumatic conveying, hydraulic conveying, It may be carried out through conveyor conveyance, natural drop conveyance, and the like.

The first water immersion tank 120-1 receives the bottom ash supplied through the first transfer pipe 110-1 in a state where water is received therein, and generates strong alkaline water according to the reaction between the water and the bottom ash.

That is, since the bottom ash contains about 2% to 45% of the CaO component, the CaO component reacts with water according to the following reaction formula to produce calcium hydroxide (Ca (OH) ₂ ), which is a strong alkali having a pH of 12 or higher. Indicates.

"CaO + H ₂ O → Ca (OH) ₂ "

Meanwhile, the fly ash collected in the dust collector 30 provided on the flue 20 extending from the combustion furnace 10 is transferred through the second transfer pipe 110-2 to the second water immersion tank 120-2. It is fed into, in which case the conveying can be carried out through pneumatic conveying, hydraulic conveying, conveyor conveying, natural drop conveying and the like.

The second water immersion tank 120-2 receives the fly ash supplied through the second transfer pipe 110-2 in a state where water is received therein, and generates strong alkaline water according to the reaction between the water and the fly ash.

That is, since the fly ash contains a CaO component, the CaO component reacts with water to produce calcium hydroxide (Ca (OH) ₂ ), which has a strong alkalinity of pH 12 or higher.

Of course, the first water immersion tank 120-1 and the second water immersion tank 120-2 are provided with water inlets 120a and 120b for receiving new water from the outside.

The strong alkali water of Ca (OH) ₂ component produced by the reaction in the first immersion tank 120-1 and the second immersion tank 120-2 is then transferred to a conveying force supply unit (not shown) such as a water pump. In accordance with the operation of the feed pipe 150 is transferred to the removal reaction tank 170 is supplied.

In this case, the supply pipes 150 extending from the first water immersion tank 120-1 and the second water immersion tank 120-2 may be joined to each other and then connected to the removal reaction tank 170 in the form of one tube, and joined. The valve means 160 is provided at the point to selectively open and close the supply of the strong alkaline water from the first water immersion tank 120-1 and the second water immersion tank 120-2.

Of course, the valve means 160 opens both the communication with the first immersion tank 120-1 and the second immersion tank 120-2 to supply strong alkaline water from both of the immersion tanks 120-1 and 120-2 at the same time. You can also

Furthermore, the impact imparting means for applying the repetitive impact on the coal ash injected into the first water immersion tank 120-1 and the second water immersion tank 120-2 to extract the CaO component contained in the coal ash more effectively and maximally (Not shown) may be provided.

The impact imparting means is not particularly limited as long as the impact imparting means can be repeatedly applied to the coal ash therein, but is preferably provided in each of the water immersion tanks 120-1 and 120-2 to perform reciprocating lateral movement or rotational movement. It can be implemented as.

When the CaO component contained in the coal ash is removed as the strong alkali water is generated in the first water immersion tank 120-1 and the second water immersion tank 120-2, the coal ash remains in the form of aggregate in a neutralized state.

And, the remaining coal aggregate is transferred through the corresponding aggregate transfer pipe (130-1, 130-2), respectively, and stored in each aggregate storage tank (140-1, 140-2), the transfer is conveyed conveyor, screw It can be carried out through the transfer of the rotary type.

That is, the bottom ash aggregate remaining in the first water immersion tank 120-1 is transferred through the first aggregate transport pipe 130-1 and stored in the first aggregate storage tank 140-1, and the second water immersion tank ( The fly ash aggregate remaining in the 120-2) is transferred through the second aggregate transfer pipe 130-2 and stored in the second aggregate storage tank 140-2.

And, aggregates stored in each aggregate storage tank (140-1, 140-2) can be withdrawn after the outside and recycled, aggregate aggregate outlet 140a in each aggregate storage tank (140-1, 140-2) for the external withdrawal , 140b).

The removal reaction tank 170 is provided on the flue 20 at the rear position of the dust collector 30 so that the exhaust gas discharged after the fly ash is removed is passed, and the first water immersion tank 120-1 and the second water immersion tank ( 120-2) is used to remove the carbons such as carbon dioxide contained in the exhaust gas passed by using a strong alkaline water of Ca (OH) ₂ component contained inside.

That is, the exhaust gas is passed through the strong alkaline water of the Ca (OH) ₂ component contained therein, so that the strong alkali water and the exhaust gas are contacted to remove carbon dioxide in the exhaust gas according to the following reaction formula.

"Ca (OH) ₂ + CO ₂ → CaCO ₃ + H ₂ O"

Specifically, the exhaust gas is introduced through the lower portion of the removal reaction tank 170, and the exhaust gas purified therein is discharged through the upper portion of the removal reaction tank 170, thereby increasing the strong alkaline water in which the exhaust gas is received. After passing it can be discharged through the top.

At this time, in order to block backflow of the strong alkali water contained in the flue 20 on the side from which the exhaust gas flows from the removal reaction tank 170, an inflow point may be appropriately provided with a backflow prevention means (not shown).

The removal reaction tank 170 may be provided with a contact rate improving means (not shown) for improving the contact rate between the strong alkaline water and the exhaust gas so that the removal reaction is quick and more effective.

Such contact rate improvement means includes a rotating means for rotating the received strong alkaline water, a stirring means for stirring the strong alkaline water, a gas subdivision means for subdividing and injecting the exhaust gas, and an aeration for injecting the inflowing exhaust gas. (Iii) means or the like may be used.

Furthermore, according to the removal reaction in the removal reaction tank 170, calcium carbonate (CaCO ₃ ) sludge is generated as a reaction by-product therein and deposited at the lower portion, and the deposited CaCO ₃ sludge is transferred through the sludge transfer pipe 180. The sludge storage tank 190 is stored in this case, and the transfer may be carried out through conveyor conveyance, screw rotary conveyance, or the like.

The sludge storage tank 190 stores CaCO ₃ sludge supplied from the removal reaction tank 170, and basically stores calcium carbonate as it is, but alternatively, calcium carbonate sludge may be dried and stored in a solid state.

Then, the calcium carbonate stored in the sludge storage tank 190 may be withdrawn afterwards to be appropriately recycled as raw materials for construction of steel, cement, and fertilizer or aggregate for construction, and the sludge outlet in the sludge storage tank 190 for external extraction. 190a is provided.

On the other hand, the exhaust gas purified by removing carbons such as carbon dioxide contained while passing through the elimination reaction tank 170 is continuously transferred through the flue 20 behind the elimination reaction tank 170 and finally discharged to the atmosphere.

At this time, since the exhaust gas can be significantly reduced as the passing force passes through the removal reaction tank 170 in the middle, the feed pressure imparting means (not shown) for adding the conveying force in the middle for the smooth discharge of the flue ( 20) may be suitably provided, and a blowing fan may be used as the conveying pressure applying means.

In addition, the environmental pollution generation prevention system of the thermal power plant according to the present invention may further include a control panel (not shown) for performing overall operation control to enable automatic operation, and also on the transfer pipe or supply pipe for transferring each object. Opening and closing means (not shown) for controlling the supply amount by opening and closing the transfer of the object to control the transfer time, and a flow meter (not shown) and a hydraulic system (not shown) for measuring the transfer flow rate and the transfer pressure of the object may be provided In addition, the first and second water immersion tanks 120-1 and 120-2 and the removal reaction tank 170 may be provided with a pH measurement means (not shown) for measuring hydrogen ion concentration.

The operation of the environmental pollutant generation prevention system of the thermal power plant according to the present invention having the above configuration will be described below.

When coal raw material is combusted according to the operation of the combustion furnace 10, the bottom ash generated by the combustion falls down to the lower side of the combustion furnace 10 and is accumulated, and the fly ash extends from the combustion furnace 10 together with the exhaust gas. Being discharged through the flue 20 is collected in the dust collector 30 provided on the flue (20).

In addition, the bottom ash accumulated on the lower side of the combustion furnace 10 is taken out, transferred through the first transfer pipe 110-1, and then introduced into the first water immersion tank 120-1, and in the dust collector 30, The collected fly ash is taken out, transferred through the second transfer pipe 110-2, and then injected into the second water immersion tank 120-2.

Then, the water previously contained in the first water immersion tank 120-1 and the second water immersion tank 120-2 and the CaO component contained in the injected coal ash react with each other to generate a strong alkali water of Ca (OH) ₂ component. Create

At this time, the impact imparting means provided in the first water immersion tank 120-1 and the second water immersion tank 120-2 is operated to effectively remove the CaO component from the coal ash by repeatedly applying the impact to the coal ash.

Subsequently, the strong alkaline water generated in the first water immersion tank 120-1 and the second water immersion tank 120-2 is transferred through the supply pipe 150 according to the operation of the water pump provided on the supply pipe 150. Supplied to the removal reaction tank 170, the supply of the strong alkaline water from both the water immersion tank (120-1, 120-2) by the valve means 160 provided on the supply pipe 150 can be adjusted appropriately.

As such, the bottom ash aggregate and the fly ash aggregate which are neutralized by removing the quicklime component as the strong alkali water is generated in the first submerged tank 120-1 and the second submerged tank 120-2 are then required at a later time. Each aggregate transport pipe (130-1, 130-2) is transferred through and stored in the corresponding aggregate storage tank (140-1, 140-2).

In addition, the bottom ash aggregate and the fly ash aggregate stored in this way may be externally drawn out when necessary and recycled appropriately.

Subsequently, the strong alkaline water transferred and supplied from the first water immersion tank 120-1 and the second water immersion tank 120-2 is accommodated in the removal reaction tank 170.

Meanwhile, the exhaust gas discharged after the fly ash is removed from the dust collector 30 while being discharged through the flue 20 according to the operation of the combustion furnace 10 is introduced into the removal reaction tank 170. By contact reaction with strong alkaline water of Ca (OH) ₂ component contained therein, carbons such as carbon dioxide contained are removed.

At this time, the exhaust gas is introduced through the lower portion of the removal reaction tank 170 and then moved upwardly to pass through the strong alkaline water contained therein and then discharged through the upper portion, and the exhaust gas passing through the removal reaction tank 170 is carbon such as carbon dioxide. Is removed and purged and continues to be transported through the rear flue 20 and finally released to the atmosphere.

In addition, CaCO ₃ sludge is generated and deposited therein according to the removal reaction in the removal reaction tank 170, and the deposited CaCO ₃ sludge is transferred through the sludge transfer pipe 180 at the required time and is in the sludge storage tank 190. The calcium carbonate thus stored can then be externally extracted at the required time and recycled appropriately.

As a result, according to the present invention, since carbon materials such as carbon dioxide and carbon monoxide contained in the atmospheric gas can be effectively removed using coal ash generated in a large amount of thermal power plant, it is possible to prevent pollution of the air environment and to gradually tighten carbon dioxide emission regulations. You can actively cope.

In addition, since the coal ash can be neutralized and neutralized, the coal ash can be prevented from causing environmental pollution or damage to the structure when the ash is buried or recycled, and the coal ash can be recycled for various uses.

In summary, it is possible to remove both the carbon content in the exhaust gas and the quicklime component in the coal ash, which are environmental pollutants generated by thermal power plants.

In addition, since it does not generate any other environmental pollution at all during the treatment process, it is very eco-friendly, and since the raw material is self-supporting using only water generated in addition to water, it may be very economical and excellent in field application.

In addition, since calcium carbonate, which can be usefully recycled as industrial raw materials or aggregates for construction, is also provided as a by-product, economical efficiency and utility may be excellent in this respect.

In the foregoing description, it should be understood that those skilled in the art can make modifications and changes to the present invention without changing the gist of the present invention as merely illustrative of a preferred embodiment of the present invention.

1 is a block diagram showing a system for preventing environmental pollutants of a thermal power plant according to a preferred embodiment of the present invention.

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

10: combustion furnace 20: year

30: dust collector 110-1, 110-2: transfer pipe

120-1, 120-2: Water immersion tank 120a, 120b: Water inlet

130-1, 130-2: aggregate transport pipe 140-1, 140-2: aggregate storage tank

140a, 140b: aggregate outlet 150: supply pipe

160: valve means 170: removal reaction tank

180: sludge feed pipe 190: sludge storage tank

190a: sludge outlet

Claims (7)

A bottom ash is generated to accumulate on the lower side of the furnace, and fly ash is discharged with the exhaust gas through the flue extending from the furnace, the fly ash being polluted by environmental pollutants in a thermal power plant system which is collected in the dust collector in the flue. System to prevent the occurrence of A first water immersion tank receiving the bottom ash taken out from the combustion furnace and reacting with water contained therein to generate strong alkaline water; A removal reaction tank provided on the flue behind the dust collector and accommodating the strong alkaline water supplied from the first water immersion tank and removing the carbon dioxide contained in the exhaust gas passed therethrough; A sludge storage tank for receiving and storing sludge produced by the removal reaction in the removal reaction tank; A first aggregate storage tank configured to receive and store a bottom ash aggregate remaining in the first water immersion tank after being neutralized according to generation of the strong alkaline water; And A second water immersion tank receiving the fly ash taken out from the dust collector and reacting with the water contained therein to generate strong alkaline water and supply it to the removal reaction tank. Environmental pollution generation prevention system of the thermal power plant comprising a. The method of claim 1, And a second aggregate storage tank for supplying and storing fly ash aggregate remaining in the second water immersion tank after being neutralized according to the generation of the strong alkaline water. The method according to claim 1 or 2, The strong alkaline water generated in the first and second immersion tank is supplied to the removal reaction tank through a supply pipe, Valve means provided on the supply pipe to selectively open and close the supply of the strong alkaline water from the first water immersion tank or the second water immersion tank to the removal reaction tank; Environmental pollutant generation prevention system of the thermal power plant further comprising a. The method according to claim 1 or 2, The first immersion tank and the second immersion tank, Impact imparting means for repeatedly applying the internally charged bottom ash and the fly ash to extract the quicklime component for producing the strong alkaline water; Environmental pollutant generation prevention system of the thermal power plant characterized in that it comprises a. The method according to claim 1 or 2, The removal reaction tank, Contact rate improving means for improving a contact rate between the strong alkaline water and the exhaust gas; Provided with The contact rate improving means, A thermal power plant, characterized in that any one of the rotating means for rotating the strong alkaline water, the stirring means for stirring the strong alkaline water, the gas dividing means for subdividing and injecting the exhaust gas, and the aeration means for aeration to inject the exhaust gas. Environmental pollution prevention system. The method of claim 2, The first aggregate storage tank and the second aggregate storage tank, Aggregate outlet for taking out the internally stored aggregate; Environmental pollutant generation prevention system of the thermal power plant comprising a. The method according to claim 1 or 2, The sludge storage tank, A sludge outlet for taking out sludge in an internally stored sludge state or a dried state; Environmental pollutant generation prevention system of the thermal power plant comprising a.

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