KR102550734B1 - Active nitrogen oxide and sulfur oxide reduction system to reduce combustion emission materials and nitrogen oxide and sulfur oxide reduction method using the same - Google Patents

Abstract

An embodiment of the present invention provides an active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions, and an active nitrogen oxide and sulfur oxide reduction method using the same. The active nitrogen oxide precursor reduction system for reducing fine dust includes an SCR catalytic reaction unit, a sulfur oxide and fine dust processing unit, a water storage tank unit, a water filter unit, and a neutral water storage tank unit, and foreign substances are generated in the water filter. When the hole of the filter is blocked, an organic light emitting diode (LED) mounted on the water filter emits light to inform the replacement time of the water filter.

Description

Active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions and method for reducing nitrogen oxide and sulfur oxide using the same

The present invention relates to an active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions, and more particularly, to an active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions and a method for reducing nitrogen oxides and sulfur oxides using the same it's about

In the existing solid phase, liquid phase and gas phase combustion processes, sulfur oxides and nitric oxides are generated in the exhaust gas according to the content of sulfur (S) and nitrogen (N) contained in the fuel.

The sulfur oxides are generally treated using water (water) as flue gas desulfurization technology, but this technology has problems in application due to equipment cost, equipment space, and wastewater treatment.

Recently, the use of biomass for thermal power generation has increased (the nitrogen content is higher than that of coal) in accordance with the eco-friendly energy policy and the increase in the use of new and renewable energy (REC acquisition), and the generation of NOx (nitrogen oxide) according to the nitrogen content in biomass has increased. is increasing

The NOx is a precursor material that causes secondary generation of fine dust, and there is a method of treating it with a catalyst or the like in the post-treatment stage, but NO, which accounts for 80% to 90% of the components of the NOx, urea or ammonia used in the catalytic reaction Excessive dosage causes another environmental problem, or there is a problem in that reduction materials are wasted or efficiency is lowered because there is no active treatment method.

In addition, in the case of power plant combustion, it is “mixed coal” that is used by dynamically mixing fuel every day in consideration of fuel supply and demand and combustion efficiency. As the generation of combustion gas varies according to output load, a method that can actively replace it is needed. .

According to the above necessity, as a method for controlling the emission of nitrogen oxides generated in the combustion process, ammonia is injected into the exhaust gas or combustion convection area at a molar concentration ratio at a reaction temperature of 850 ° C to 1,100 ° C through a combustion chamber without using a catalyst. There is a non-selective catalytic reduction method (SNCR) that reduces NOx by reducing NOx.

In addition, there are two methods of selective catalytic reduction (SCR) in which a reducing agent is sprayed on nitrogen oxide to pass through a catalyst layer to effectively proceed with a reduction reaction at a relatively low temperature of 250° C. to 400° C. while converting nitrogen oxide into N ₂ .

Since the reduction reaction proceeds at a low temperature, the selective catalytic reduction (SCR) method has low installation and operating costs compared to the non-selective catalytic reduction method, and has a high removal efficiency, establishing itself as a representative nitrogen oxide treatment technology in domestic thermal power plants.

However, the selective catalytic reduction method (SCR) requires a control device such as a storage space for a reducing agent and an analyzer, and has problems such as high maintenance costs and a decrease in nitrogen oxide removal efficiency due to damage to the catalyst at a temperature higher than the catalyst reaction temperature. there is.

In addition, exhaust gas generated after a combustion process is generally removed by a wet or dry method, and when the exhaust gas is treated by a wet method, water generated after the exhaust gas treatment has high acidity.

In general, in order to treat the water as wastewater, a method of storing the water in a tank and transporting and disposing of the water is often used, but this requires a lot of transportation and treatment costs, and in a small-scale device, water treatment and purification are used, but in this case, foreign substances, etc. This is generated and there is a problem that is difficult to recycle.

In addition, since the small-scale treatment device is a passive treatment device, it is impossible to actively cope with water whose acidity concentration changes according to the combustion process.

Japanese Laid-open Patent No. 2015-0015520

A technical problem to be achieved by the present invention is to provide an active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions and a method for reducing nitrogen oxide and sulfur oxides using the same.

The technical problem to be achieved by the present invention is not limited to the above-mentioned technical problem, and other technical problems not mentioned can be clearly understood by those skilled in the art from the description below. There will be.

In order to achieve the above technical problem, an embodiment of the present invention provides an active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions.

The active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions is installed at the rear end of the solid combustion furnace, and the SCR catalyst is located inside so that the nitrogen oxide reduction reaction proceeds, and the nitrogen oxides of the exhaust gas discharged from the solid combustion furnace SCR catalytic reaction unit for controlling the reduction reaction of nitrogen oxides to increase by increasing the amount of ammonia when the concentration exceeds the preset concentration;

a sulfur oxide and fine dust treatment unit installed at a rear end of the SCR catalytic reaction unit and configured to react with water to purify nitrogen oxides remaining after being purified in the SCR catalytic reaction unit and sulfur oxides and fine dust in exhaust gas;

a water storage tank unit installed at a rear end of the sulfur oxides and fine dust treatment unit, neutralized by neutralized water and stored when the water discharged from the sulfur oxides and fine dust treatment unit is acidic;

A water filter unit installed at the rear end of the water storage tank unit and controlling the acidity of the water by a filter when the water discharged from the water storage tank unit is acidic; and

It may include a neutral water storage tank unit installed below the water filter unit and storing water purified by the water filter unit.

In one embodiment of the present invention, the SCR catalytic reaction unit,

The reaction region is divided into a plurality, the SCR catalyst is located inside the reaction region, an empty space is formed between the plurality of reaction regions, and the SCR catalyst in which a reduction reaction of nitrogen oxide discharged from the solid combustion furnace proceeds reactor;

A plurality of nitrogen oxide concentration meters located above and below the SCR catalyst reactor and measuring the concentration of nitrogen oxide in the exhaust gas discharged from the primary heat exchanger or the concentration of nitrogen oxide after the reduction reaction by the SCR catalyst;

A plurality of exhaust gas temperature measuring devices located in an empty space between the upper part of the SCR catalytic reactor and the reaction region and measuring the temperature of the exhaust gas discharged from the solid combustion furnace or the temperature while the reaction is in progress; and

It is located in the empty space between the upper part of the SCR catalytic reactor and the reaction region inside the plural number so that ammonia is injected into the SCR catalytic reactor when the concentration of nitrogen oxides measured by the nitrogen oxide concentration meter exceeds a preset value. of ammonia dosing grids.

In one embodiment of the present invention, the SCR catalytic reactor may have three reaction regions divided into the plurality.

In one embodiment of the present invention, the sulfur oxide and fine dust processing unit,

A desulfurization processor installed at the rear end of the SCR catalytic reaction unit and purifying the sulfur oxides and fine dust by reacting sulfur oxides and fine dust in the exhaust gas discharged from the SCR catalytic reaction unit with water; and

A scrubbing water input device installed on a side of the desulfurization processor and injecting water into the desulfurization processor may be included.

In one embodiment of the present invention, the water storage tank unit is installed at the rear end of the sulfur oxides and fine dust treatment unit, and stores the water in which sulfuric acid and nitric acid remain after the sulfur oxides and fine dust are purified. Tank;

A plurality of pH sensors installed inside the water discharge pipe and measuring the pH of the water in which the sulfuric acid and nitric acid are dissolved;

A neutralized water input device installed on a side of the water storage tank and allowing the neutralized water to be injected into the water storage tank; and

A water pump installed on the water discharge pipe to transfer the water of the sulfur oxides and fine dust treatment unit to the water storage tank or to transfer the water inside the water storage tank to the purification filter unit.

In one embodiment of the present invention, the purification filter unit,

an ion filter installed at a rear end of the water storage tank, mounted on the water discharge pipe, and composed of an ion exchange resin to adjust the acidity of the water;

A carbon filter installed at the rear end of the ion filter and mounted on the water discharge pipe and made of carbon resin to adjust the acidity of the water; and

It may include a sediment filter installed at a rear end of the carbon filter, mounted on the water discharge pipe, and made of a corrosion-resistant material to adjust the acidity of the water.

In one embodiment of the present invention, a differential pressure sensor may be installed on the side of the sediment filter.

In one embodiment of the present invention, an organic light emitting diode (LED) may be installed on one side of the ion filter, the carbon filter, and the precipitate filter of the purification filter unit.

In one embodiment of the present invention, the neutral water storage tank portion is composed of a neutral water storage tank, and the water stored in the neutral water storage tank portion is transported to a scrubbing water input device and can be reused in the desulfurization processor.

In order to achieve the above technical problem, another embodiment of the present invention provides a method for reducing active nitrogen oxides and sulfur oxides for reducing combustion emissions.

The active nitrogen oxide and sulfur oxide reduction method for reducing combustion emissions may be performed by the above-described active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions, and the exhaust gas discharged from the solid combustion furnace is SCR An SCR catalytic reaction step in which a nitrogen oxide reduction reaction is performed by the SCR catalyst after being introduced into the catalytic reaction unit;

Sulfur oxides and fine dust remaining after being purified in the SCR catalytic reaction step are input to the sulfur oxide and fine dust treatment unit and react with water to generate sulfuric acid or nitric acid-containing water. Fine dust treatment step;

A first water neutralization step in which the acidity of the water is adjusted by the neutralization water input device after the water containing sulfuric acid or nitric acid generated in the sulfur oxide and fine dust treatment step is moved to a water storage tank by a water pump;

If the pH of the water discharged from the water storage tank after the acidity is adjusted in the first water neutralization step is greater than 5, the water is moved to the neutral water storage tank, and if the pH of the water is 5 or less, the water is A second water neutralization step in which acidity is adjusted by moving to the ion filter of the water filter unit;

If the pH of the water discharged from the water storage tank after the acidity is adjusted in the second water neutralization step is greater than 5, the water is moved to the neutral water storage tank, and if the pH of the water is 5 or less, the water is A third water neutralization step in which the acidity is adjusted by moving to the carbon filter of the water filter unit; and

If the pH of the water discharged from the water storage tank after the acidity is adjusted in the third water neutralization step is greater than 5, the water is moved to the neutral water storage tank, and if the pH of the water is 5 or less, the water is A fourth water neutralization step in which acidity is adjusted by moving to a precipitate filter of a water filter unit may be included.

In one embodiment of the present invention, in the second water neutralization step and the third water neutralization step, when the pH of the water is within a predetermined range, organic light emitting attached to the side surfaces of the ion filter and the carbon filter The diode (LED) may emit blue light.

In one embodiment of the present invention, in the fourth water neutralization step,

When particulate matter is deposited on the precipitate filter of the water and the differential pressure sensor attached to the side of the precipitate filter detects a signal and the turbidity falls within a preset section, an organic light emitting diode (LED) may emit blue light.

In one embodiment of the present invention, when the organic light emitting diode (LED) emits yellow light, a hole in the precipitate filter may be automatically changed to a second hole by a control device.

In one embodiment of the present invention, when all holes present in the precipitate filter are blocked by the precipitate, the organic light emitting diode (LED) may emit red light.

According to an embodiment of the present invention, the exhaust gas can be actively treated according to the amount of exhaust gas by the active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions, and the generated after processing the exhaust gas The high acidity of water is lowered and neutralized, and the neutralized water can be reused in the desulfurization system.

In addition, when a hole in the filter is clogged due to a foreign substance being formed in the water filter, an organic light emitting diode (LED) mounted on the water filter emits light to notify the replacement time of the water filter, enabling a continuous process. The trouble of washing the filter during the combustion process can be solved.

The effects of the present invention are not limited to the above effects, and should be understood to include all effects that can be inferred from the detailed description of the present invention or the configuration of the invention described in the claims.

1 is a block diagram of an active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions according to an embodiment of the present invention.
2 is a configuration diagram of an SCR catalytic reaction unit according to an embodiment of the present invention.

Hereinafter, the present invention will be described with reference to the accompanying drawings. However, the present invention may be embodied in many different forms and, therefore, is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Throughout the specification, when a part is said to be "connected (connected, contacted, combined)" with another part, this is not only "directly connected", but also "indirectly connected" with another member in between. "Including cases where In addition, when a part "includes" a certain component, it means that it may further include other components without excluding other components unless otherwise stated.

Terms used in this specification are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this specification, terms such as "include" or "have" are intended to indicate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, but one or more other features It should be understood that the presence or addition of numbers, steps, operations, components, parts, or combinations thereof is not precluded.

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

1 is a block diagram of an active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions according to an embodiment of the present invention.

Referring to FIG. 1 , an active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions according to an embodiment of the present invention includes an SCR catalytic reaction unit; Sulfur oxide and fine dust processing unit; Water storage tank unit; It may include a water filter unit; and a neutral water storage tank unit.

An active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions according to an embodiment of the present invention may include an SCR catalytic reaction unit.

The SCR catalytic reaction unit is installed at the rear end of the solid combustion furnace (1), the SCR catalyst is located therein, and the nitrogen oxide reduction reaction proceeds, and the nitrogen oxide concentration of the exhaust gas discharged from the solid combustion furnace (1) is a preset concentration. If it exceeds , the reduction reaction of nitrogen oxide can be controlled to increase by increasing the input amount of ammonia.

Also, in the SCR catalytic reaction unit, nitrogen oxides of the exhaust gas discharged from the solid combustion furnace are mixed with ammonia (NH ₃ ), and a reaction of reducing the nitrogen oxides (NOx) to nitrogen (N ₂ ) may proceed.

At this time, it is necessary to adjust the amount of ammonia input in order to increase the efficiency of the nitrogen oxide reduction reaction.

Therefore, the SCR catalytic reaction unit includes an SCR catalytic reactor 10; A plurality of nitrogen oxide concentration meters; A plurality of exhaust gas temperature meters; and a plurality of ammonia injection grids.

At this time, when the concentration of nitrogen oxide measured by the nitrogen oxide concentration meter is compared with the preset concentration, the measured concentration of nitrogen oxide is greater than the preset concentration.

Ammonia is additionally injected into the SCR catalyst reactor from the ammonia injection grid, so that the efficiency of the nitrogen oxide reduction reaction may be increased.

An active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions according to an embodiment of the present invention may include a sulfur oxide and fine dust processing unit.

A desulfurization processor 20 installed at a rear end of the SCR catalytic reaction unit and reacting sulfur oxides and fine dust in the exhaust gas discharged from the SCR catalytic reaction unit with water to purify the sulfur oxides and fine dust; and

A scrubbing water input device 30 installed on a side of the desulfurization processor and injecting water into the desulfurization processor may be included.

At this time, the desulfurization processor 20 is installed at the rear end of the SCR catalytic reaction unit, and nitrogen oxides remaining after being purified in the SCR catalytic reaction unit, sulfur oxides of exhaust gas and fine dust react with water to produce sulfuric acid or nitric acid. and can be processed.

That is, water 40 in which sulfuric acid or nitric acid is dissolved may be generated by treating the nitrogen oxides, sulfur oxides of the exhaust gas, and fine dust.

In addition, the scrubbing water input device 30 may continuously inject water into the desulfurization processor, and the water injected by the scrubbing water input device 30 is an active nitrogen oxide for reducing combustion emissions according to the present invention. It can be recycled water from persulphur oxide abatement systems.

At this time, since sulfuric acid or nitric acid is dissolved in the water 40 generated by the action of the sulfur oxide and fine dust treatment unit, the acidity may be lowered to pH 5 or less. At this time, the water having an acidity of pH 5 or less is not discharged as it is and can be treated as neutral water and reused.

An active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions according to an embodiment of the present invention may include a water storage tank.

The water storage tank unit water storage tank 60; pH sensor 71; A neutralized water input device 80; and water pumps 50 and 90 may be included.

At this time, the water storage tank 60 is installed at the rear end of the sulfur oxide and fine dust treatment unit, and can store water in which sulfuric acid and nitric acid remain after the sulfur oxide and fine dust are purified.

In addition, the pH sensor 71 is installed inside the water discharge pipe and can measure the pH of the water in which the sulfuric acid and nitric acid are dissolved.

In addition, the neutralized water input device 80 is installed on the side of the water storage tank, and the neutralized water can be injected into the water storage tank.

In addition, the water pump is installed on the water discharge pipe and transported by the water pump 50 for transferring the water of the sulfur oxide and fine dust treatment unit to the water storage tank, or the water inside the water storage tank to the purification filter unit. Water may be transported by the water pump 90 for transporting.

Therefore, the water storage tank unit is installed at the rear end of the sulfur oxide and fine dust treatment unit, and when the water discharged from the sulfur oxide and fine dust treatment unit is acidic, it can be neutralized by neutralized water and stored.

In this case, the neutralized water may use a substance having a basic property, and may include, for example, sodium hydroxide (NaOH).

Due to the basic nature of the neutralized water, the acidic water can be neutralized.

An active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions according to an embodiment of the present invention may include a purification filter unit.

The purification filter unit ion filter 110; A carbon filter 120; and a sediment filter 130 may be included.

The ion filter 110 is installed at the rear end of the water storage tank and mounted on the water discharge pipe, and is composed of an ion exchange resin to adjust the acidity of the water.

In addition, the carbon filter 120 is installed at the rear end of the ion filter and mounted on the water discharge pipe, and is made of carbon resin to adjust the acidity of the water.

In addition, the sediment filter 130 is installed at the rear end of the carbon filter and mounted on the water discharge pipe, and is made of a corrosion-resistant material to adjust the acidity of the water.

In addition, a differential pressure sensor may be installed on a side surface of the sediment filter, and the differential pressure sensor may measure a pressure difference between spaces to detect a phenomenon in which foreign matter is deposited on the sediment filter and the sediment filter is clogged.

In addition, an organic light emitting diode (LED) may be installed on one side of the ion filter 110, the carbon filter 120, and the precipitate filter 130 of the purification filter unit.

At this time, when foreign matter is formed in the ion filter 110 and the carbon filter 120 and the efficiency of the filter is lowered, the pH measured by the pH sensor can be measured.

In addition, the organic light emitting diode (LED) may emit blue light when the detected pH value is compared with the measured value before the formation of the foreign material and falls within a predetermined range.

In addition, when foreign substances are formed in the sediment filter 130 and the efficiency of the filter is lowered, a pressure difference between spaces can be measured by a differential pressure sensor.

The organic light emitting diode (LED) may emit blue light when the pressure difference between the measured spaces is compared with the measured value before foreign matter is formed and falls within a preset section.

An active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions according to another embodiment of the present invention is provided.

The active nitrogen oxide and sulfur oxide reduction method for reducing combustion emissions may be performed by an active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions.

In addition, the method for reducing active nitrogen oxides and sulfur oxides includes an SCR catalytic reaction step; Sulfur oxide and fine dust treatment step; a first water neutralization step; a second water neutralization step; A third water neutralization step; and a fourth water neutralization step.

First, the method for reducing active nitrogen oxides and sulfur oxides for reducing combustion emissions may include an SCR catalytic reaction step.

Referring to FIG. 2, the SCR catalytic reaction step will be described.

In the SCR catalytic reaction step, the exhaust gas discharged from the solid combustion furnace is introduced into the SCR catalytic reaction unit, and a nitrogen oxide reduction reaction may be performed by the SCR catalyst.

In addition, in the SCR catalytic reaction unit, a reaction region is divided into a plurality of reaction regions, an SCR catalyst is located inside the reaction region, an empty space is formed between the plurality of divided reaction regions, and nitrogen oxides discharged from the solid combustion furnace An SCR catalyst reactor 200 in which a reduction reaction proceeds;

A plurality of nitrogen oxide concentration meters (31, 32);

A plurality of exhaust gas temperature measuring devices (41, 42, 43) located in the empty space between the upper part of the SCR catalytic reactor and the reaction region and measuring the temperature of the exhaust gas discharged from the solid combustion furnace or the temperature during the reaction. );and

It is located in the empty space between the upper part of the SCR catalytic reactor and the reaction region inside, and a plurality of so that ammonia is injected into the SCR catalytic reactor when the concentration of nitrogen oxides measured by the nitrogen oxide concentration meter exceeds a preset value. of ammonia injection grids 21, 22, 23 and 24.

In this case, the SCR catalyst reactor may have three reaction regions, and each reaction region may include SCR catalysts 201, 202, and 203.

At this time, the nitrogen oxide reduction reaction means a reaction in which nitrogen oxides (NOx) of the exhaust gas discharged from the solid combustion furnace is mixed with ammonia (NH ₃ ) to reduce the nitrogen oxides (NOx) to nitrogen (N ₂ ). can do.

At this time, it is necessary to adjust the amount of ammonia input in order to increase the efficiency of the nitrogen oxide reduction reaction.

In addition, in order to inject an appropriate amount of ammonia according to the amount of nitrogen oxide, nitrogen oxide concentration meters 31 and 32, exhaust gas temperature meters 41, 42, and 43 and ammonia injection grids 21, 22, and 23 ,24) is required.

At this time, the nitrogen oxide concentration meter is located at the upper part 31 and the lower part 32 of the SCR catalyst reactor, and the concentration of nitrogen oxide in the exhaust gas discharged from the solid combustion furnace or the nitrogen oxide concentration after the reduction reaction by the SCR catalyst concentration can be measured.

That is, the concentration of nitrogen oxide in a state in which the reduction reaction of nitrogen oxide has not proceeded before the exhaust gas is introduced into the SCR catalyst reactor is measured by the nitrogen oxide concentration meter 31 located above the SCR catalyst reactor. When the measured concentration of nitrogen oxide exceeds a preset concentration, ammonia may be injected from the first ammonia injection grid 21 .

In addition, the nitrogen oxide concentration measured after the exhaust gas of the SCR catalyst reactor is introduced and the reduction reaction of nitrogen oxide is progressed by the nitrogen oxide concentration measuring device 32 located at the lower part of the SCR catalyst reactor, When the concentration exceeds the preset concentration, ammonia may be injected from the second ammonia injection grid 22 , the third ammonia injection grid 23 , and the fourth ammonia injection grid 24 .

Therefore, there is an effect of injecting an appropriate amount of ammonia by measuring the nitrogen oxide concentration and the exhaust gas temperature in real time by the SCR catalytic reactor.

Next, the method for reducing active nitrogen oxides and sulfur oxides may include a step of treating sulfur oxides and fine dust.

In the sulfur oxide and fine dust treatment step, nitrogen oxides remaining after being purified in the SCR catalytic reaction step and sulfur oxides and fine dust in exhaust gas are introduced into the sulfur oxide and fine dust treatment unit and react with water to contain sulfuric acid or nitric acid. It is possible to make the water to be generated.

A reaction in which the nitrogen oxides and sulfur oxides and fine dust in the exhaust gas are introduced into the sulfur oxide and fine dust treatment unit and react with water to generate water containing sulfuric acid or nitric acid may be performed in a desulfurization processor, and scrubbing water may be introduced. Water may be introduced into the desulfurization treatment unit by means of a device.

At this time, since the water containing sulfuric acid or nitric acid is acidic, a reaction to neutralize the acidic water may proceed.

Next, the method for reducing active nitrogen oxides and sulfur oxides may include a first water neutralization step.

In the first water neutralization step, after the water containing sulfuric acid or nitric acid generated in the sulfur oxide and fine dust treatment step is moved to a water storage tank by a water pump, the acidity of the water is controlled by the neutralized water input device. It can be.

At this time, the neutralized water injected into the water storage tank may include a basic material, for example, sodium hydroxide (NaOH).

Therefore, in the first water neutralization step, acidic water can be neutralized, and when the pH of the water measured by the pH measuring device 72 exceeds 5, the water can be moved to the neutral water storage tank.

On the other hand, when the neutralization of water is not sufficiently performed in the first water neutralization step, the second water neutralization step may proceed.

The method for reducing active nitrogen oxides and sulfur oxides may include a second water neutralization step.

In the second water neutralization step, when the pH of the water measured by the pH measuring device 72 is 5 or less, the water moves to the ion filter of the water filter unit, and the acidity can be adjusted.

In this case, the ion filter may be installed at a rear end of the water storage tank, mounted to the water discharge pipe, and made of an ion exchange resin.

If the pH of the water measured by the pH measuring device 73 after being neutralized in the second water neutralization step in the ion filter is greater than 5, the water may be moved to the neutral water storage tank.

At this time, when neutralization of water is not sufficiently performed in the second water neutralization step, a third water neutralization step may proceed.

In the third water neutralization step, when the pH of the water measured by the pH measuring device 73 is 5 or less, the water moves to the carbon filter of the water filter unit, and the acidity can be adjusted.

At this time, the carbon filter is installed at the rear end of the ion filter and mounted on the water discharge pipe, and is made of carbon resin to adjust the acidity of the water.

When the pH of the water measured by the pH measuring device 74 after being neutralized in the third water neutralization step in the ion filter is greater than 5, the water may be moved to the neutral water storage tank.

In this case, when neutralization of water is not sufficiently performed in the third water neutralization step, a fourth water neutralization step may proceed.

In the fourth water neutralization step, when the pH of the water measured by the pH measuring device 74 is 5 or less, the water moves to the sediment filter of the water filter unit, and the acidity can be adjusted.

At this time, the sediment filter is installed at the rear end of the ion filter and mounted on the water discharge pipe, and is made of a corrosion-resistant material to adjust the acidity of the water.

Next, after being neutralized in the fourth water neutralization step in the sediment filter, the water may move to the neutral water storage tank.

At this time, the neutral water may be transferred to a scrubbing water input device and reused in order to be injected into the desulfurization treatment unit.

A method for measuring the automatic exchange cycle of the ion filter, carbon filter and sediment filter will be described.

An organic light emitting diode (LED) may be installed on one side of the ion filter, the carbon filter, and the sediment filter, and the organic light emitting diode (LED) may be connected to the pH sensor and the differential pressure sensor.

At this time, when the pH of the water measured by the pH sensor is within a predetermined range, organic light emitting diodes (LEDs) attached to the side surfaces of the ion filter and the carbon filter may emit blue light.

In addition, a differential pressure sensor located on one side of the sediment filter may detect a pressure difference between spaces of the sediment filter.

At this time, when particulate matter is stacked on the precipitate filter of the water and the differential pressure sensor attached to the side of the precipitate filter detects a signal and the turbidity falls within a preset section, the organic light emitting diode (LED) can emit blue light. .

In addition, when the organic light emitting diode (LED) emits yellow light, a hole in the precipitate filter may be automatically changed to a second hole by a control device.

That is, since the yellow diode is stacked on the No. 1 hole in the filter to indicate that it has reached a dangerous level, it can be confirmed that it is time to replace the measurement hole.

In addition, when all holes present in the precipitate filter are blocked by the precipitate, the organic light emitting diode (LED) may emit red light.

That is, the red organic light emitting diode (LED) means that all holes present in the precipitate filter are blocked, so it can be confirmed that it is time to replace the precipitate filter.

Therefore, the active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions and the active nitrogen oxide and sulfur oxide reduction method for reducing combustion emissions increase the efficiency of reducing nitrogen oxides by adjusting the amount of ammonia input according to the concentration of nitrogen oxides. In the desulfurization processor, sulfur oxides and fine dust can be reduced by using acid-neutralized water, and the acidic water containing sulfuric acid or nitric acid goes through a water neutralization step and finally becomes neutral water. It has a neutralizing effect.

In addition, in the water neutralization step, an organic light emitting diode (LED) can be used to check the replacement time of the ion filter, the carbon filter, and the sediment filter of the water filter unit in a simple way.

The above description of the present invention is for illustrative purposes, and those skilled in the art can understand that it can be easily modified into other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, the embodiments described above should be understood as illustrative in all respects and not limiting. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as distributed may be implemented in a combined form.

The scope of the present invention is indicated by the following claims, and all changes or modifications derived from the meaning and scope of the claims and equivalent concepts should be interpreted as being included in the scope of the present invention.

1: solid combustion furnace
10: SCR catalytic reactor
20: desulfurization processor
30: scrubbing water input device
40: water
50: water pump
60: water storage tank
71,72,73,74: pH sensor
80: neutralized water input device
90: water pump
110: ion filter
120: carbon filter
130: sediment filter
140: neutral water storage tank

Claims (14)

It is installed at the rear of the solid combustion furnace, and the nitrogen oxide reduction reaction proceeds with the SCR catalyst located inside. When the nitrogen oxide concentration of the exhaust gas discharged from the solid combustion furnace exceeds the preset concentration, the input amount of ammonia is increased to nitrogen SCR catalytic reaction unit for controlling the reduction reaction of oxides to increase;
a sulfur oxide and fine dust treatment unit installed at a rear end of the SCR catalytic reaction unit and configured to react with water to form sulfuric acid or nitric acid between nitrogen oxides remaining after being purified in the SCR catalytic reaction unit and sulfur oxides and fine dust in the exhaust gas;
a water storage tank unit installed at a rear end of the sulfur oxides and fine dust treatment unit, neutralized by neutralized water and stored when the water discharged from the sulfur oxides and fine dust treatment unit is acidic;
A water filter unit installed at the rear end of the water storage tank unit and controlling the acidity of the water by a filter when the water discharged from the water storage tank unit is acidic; and
A neutral water storage tank unit installed below the water filter unit and storing water purified by the water filter unit;
The SCR catalytic reaction unit,
The reaction region is divided into a plurality, the SCR catalyst is located inside the reaction region, an empty space is formed between the plurality of reaction regions, and the SCR catalyst in which a reduction reaction of nitrogen oxide discharged from the solid combustion furnace proceeds reactor;
a plurality of nitrogen oxide concentration meters located above and below the SCR catalyst reactor and measuring the concentration of nitrogen oxide in the exhaust gas discharged from the solid combustion furnace or the concentration of nitrogen oxide after a reduction reaction by the SCR catalyst;
A plurality of exhaust gas temperature measuring devices located in an empty space between the upper part of the SCR catalytic reactor and the reaction region and measuring the temperature of the exhaust gas discharged from the solid combustion furnace or the temperature while the reaction is in progress; and
It is located in the empty space between the upper part of the SCR catalytic reactor and the reaction region inside, and a plurality of so that ammonia is injected into the SCR catalytic reactor when the concentration of nitrogen oxides measured by the nitrogen oxide concentration meter exceeds a preset value. Including an ammonia injection grid of,
The SCR catalytic reactor has three reaction regions divided into the plurality,
Sulfur oxide and fine dust processing unit,
A desulfurization processor installed at the rear end of the SCR catalytic reaction unit and reacting sulfur oxides and fine dust in the exhaust gas discharged from the SCR catalytic reaction unit with water to purify the sulfur oxides and fine dust; And
An active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions, characterized in that it comprises a scrubbing water input device installed on the side of the desulfurization processor and injecting water into the desulfurization processor. delete delete delete The method of claim 1, wherein the water storage tank unit,
a water storage tank installed at a rear end of the sulfur oxides and fine dust treatment unit and storing water in which sulfuric acid and nitric acid remain after the sulfur oxides and fine dust are purified;
A plurality of pH sensors installed inside the water discharge pipe and measuring the pH of the water in which the sulfuric acid and nitric acid are dissolved;
A neutralized water input device installed on a side of the water storage tank and allowing the neutralized water to be injected into the water storage tank; and
A water pump installed on the water discharge pipe to transfer the water of the sulfur oxides and fine dust treatment unit to the water storage tank or to transfer the water inside the water storage tank to the purification filter unit. Active nitrogen oxide and sulfur oxide abatement systems for abatement. The method of claim 5, wherein the water filter unit,
an ion filter installed at a rear end of the water storage tank, mounted on the water discharge pipe, and composed of an ion exchange resin to adjust the acidity of the water;
A carbon filter installed at the rear end of the ion filter and mounted on the water discharge pipe and made of carbon resin to adjust the acidity of the water; and
An active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions including a sediment filter installed at the rear end of the carbon filter and mounted on the water discharge pipe and made of a corrosion-resistant material to control the acidity of the water. According to claim 6,
An active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions, characterized in that a differential pressure sensor is installed on the side of the sediment filter. According to claim 1,
An active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions, characterized in that an organic light emitting diode (LED) is installed on one side of the ion filter, carbon filter and sediment filter of the water filter unit. According to claim 1,
The neutral water storage tank unit is composed of a neutral water storage tank, and the water stored in the neutral water storage tank unit is transferred to a scrubbing water input device and reused in a desulfurization processor. Cargo Reduction System. In the active nitrogen oxide and sulfur oxide reduction method performed by the active nitrogen oxide and sulfur oxide reduction system for reducing combustion emissions of claim 1,
an SCR catalytic reaction step in which the exhaust gas discharged from the solid combustion furnace is introduced into an SCR catalytic reaction unit and a nitrogen oxide reduction reaction is performed by the SCR catalyst;
Sulfur oxides and fine dust remaining after being purified in the SCR catalytic reaction step are input to the sulfur oxide and fine dust treatment unit and react with water to generate sulfuric acid or nitric acid-containing water. Fine dust treatment step;
A first water neutralization step in which the acidity of the water is adjusted by a neutralization water input device after the water containing sulfuric acid or nitric acid generated in the sulfur oxide and fine dust treatment step is moved to a water storage tank by a water pump;
If the pH of the water discharged from the water storage tank after the acidity is adjusted in the first water neutralization step is greater than 5, the water is moved to the neutral water storage tank, and if the pH of the water is 5 or less, the water is A second water neutralization step in which acidity is adjusted by moving to the ion filter of the water filter unit;
If the pH of the water discharged from the water storage tank after the acidity is adjusted in the second water neutralization step is greater than 5, the water is moved to the neutral water storage tank, and if the pH of the water is 5 or less, the water is A third water neutralization step in which the acidity is adjusted by moving to the carbon filter of the water filter unit; and
If the pH of the water discharged from the water storage tank after the acidity is adjusted in the third water neutralization step is greater than 5, the water is moved to the neutral water storage tank, and if the pH of the water is 5 or less, the water is An active nitrogen oxide and sulfur oxide reduction method for reducing combustion emissions, characterized in that it comprises a fourth water neutralization step in which acidity is adjusted by moving to the sediment filter of the water filter unit. The method of claim 10, wherein in the second water neutralization step and the third water neutralization step,
Active nitrogen oxide for reducing combustion emissions, characterized in that organic light emitting diodes (LEDs) attached to the side surfaces of the ion filter and the carbon filter emit blue light when the pH of the water is within a predetermined range; and Sulfur oxide abatement methods. The method of claim 10, wherein in the fourth water neutralization step,
When the particulate matter is stacked on the precipitate filter of the water and the differential pressure sensor attached to the side of the precipitate filter detects a signal and the turbidity falls within the preset section, the organic light emitting diode (LED) emits blue light. Characterized in that Active Nitrogen Oxide and Sulfur Oxide Reduction Method for Reduction of Combustion Emissions. According to claim 12,
When the organic light emitting diode (LED) emits yellow light, the hole in the precipitate filter is automatically changed to the second hole by the control device. Active nitrogen oxides and sulfuric acid for reducing combustion emissions Cargo reduction method. According to claim 12,
When all holes present in the sediment filter are blocked by sediment, the organic light emitting diode (LED) emits red light, characterized in that active nitrogen oxides and sulfur oxides reduction method for reducing combustion emissions.

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