KR20210124817A - Flue gas control system for incinerator - Google Patents

Abstract

The present invention provides a hazardous gas concentration control system in a waste incineration facility, which includes a reducing agent input control unit to control the input of reducing agent in the incineration facility. The reducing agent input control unit includes a measurement module disposed between a back filter and an SCR, a reducing agent input module for removing SOx and HCl by introducing the reducing agent, and a control module for controlling the operation of the reducing agent input module on the basis of data on harmful gas concentration measured by the measurement module. The maintenance cost of the waste incineration facility can be reduced, and the concentration of harmful gas reaching the SCR can be kept constant, thereby preventing the life span of the SCR from being reduced due to a change in the concentration of the harmful gas. The reference concentration of harmful gas is set, so that the SOx and HCl removal process of a dry reaction tower and an incinerator desulfurization process can be performed, thereby enabling a more efficient and economical operation of the waste incineration facility.

Description

Hazardous gas concentration control system in waste incineration facility {FLUE GAS CONTROL SYSTEM FOR INCINERATOR}

The present invention relates to a system for controlling the concentration of harmful gases in a waste incineration facility, and more particularly, the concentration of harmful gases reaching the SCR by measuring the concentration of the harmful gas at the rear end of the bag filter or the front end of the SCR (Selective Catalytic Reactor) It relates to a hazardous gas concentration control system in a waste incineration facility that enables real-time control of the

The gases emitted from waste incinerators, power plants and other industrial facilities contain hazardous substances such as sulfur oxides (SOx), hydrogen chloride (HCl), nitrogen oxides (NO _x ), hydrogen fluoride (HF), and dust. In order to prevent this, it is required to remove these harmful components contained in the exhaust gas and then discharge the exhaust gas to the atmosphere.

As a method for treating such harmful gases, a semi-dry method in which a powder containing an alkaline absorbent such as limestone, slaked lime, quicklime, and sodium bicarbonate and water or slurry are directly contacted with exhaust gas to neutralize it, and an aqueous absorbent solution is exhausted A wet method of removing the gas by spraying it, and a dry method of removing the absorbent powder by directly spraying it on the exhaust gas are known.

However, while the above wet method has a high removal rate of harmful gases, it requires a treatment facility for wastewater containing reaction product salts or heavy metals generated by the neutralization reaction, and white smoke generated because the temperature of the exhaust gas is low. ), it must be reheated to prevent it, and there is a problem that equipment and operation costs are high. For this reason, recently, a semi-dry method is mainly used instead of a wet method. A conventional exhaust gas treatment apparatus having a semi-dry reactor has a structure in which an alkali material is constantly sprayed from the top to the bottom of the reactor by a spray nozzle.

However, since the components of waste incinerated in an incinerator are not uniform and can change frequently, in conventional hazardous gas removal facilities, harmful gases exceeding the standard value are introduced into the SCR to reduce the performance of the SCR, or excessive alkali substances are sprayed in the semi-dry reactor. There was a problem that reduced the efficiency.

Republic of Korea Patent No. 10-0606438 Republic of Korea Patent Registration No. 10-1992290

The present invention is to solve the above problems, and the concentration of harmful gases such as SOx , HCl and NOx is measured at the rear end of the bag filter or at the front end of the SCR (Selective Catalytic Reactor) to reach the SCR. An object of the present invention is to provide a system for controlling the concentration of harmful gases in a waste incineration facility that allows the concentration to be controlled in real time.

The present invention includes a reducing agent input control unit for controlling the input of a reducing agent (medicine) in the incineration facility, wherein the reducing agent input control unit includes a measuring module disposed between the bag filter and the SCR, and a reducing agent input to remove SOx and HCl by introducing a reducing agent It provides a harmful gas concentration control system in a waste incineration facility comprising a module and a control module for controlling the operation of the reducing agent input module based on the harmful gas concentration data measured by the measurement module.

According to an embodiment of the present invention, the reducing agent input module includes a first reducing agent input module for controlling the amount of slaked lime powder input to the dry reaction tower.

According to an embodiment of the present invention, the reducing agent input module includes a second reducing agent input module for controlling the amount of _{CaCO 3 input to the incinerator.}

According to an embodiment of the present invention, the control module drives the first reducing agent input module when the SOx and HCl values measured by the measuring module exceed the first reference value, and when the second reducing agent exceeds the second reference value Start the input module.

According to an embodiment of the present invention, it is installed in the incinerator further includes an image acquisition module for understanding the properties of the incoming waste.

According to an embodiment of the present invention, when the amount of sulfur or chlorine contained in the waste is predicted to be higher than the reference value by predicting the properties of the waste flowing into the waste incineration facility, before receiving the data of the measurement module, the second reducing agent Start the input module.

According to an embodiment of the present invention, the control module operates the second reducing agent input module when the concentration of the pollutant measured by the measurement module exceeds the second reference value, and as a result of the analysis of the waste properties, the emission of the pollutant increases. When it is predicted that the second reference value exceeds the third reference value lower than the second reference value, the second reducing agent input module is operated.

According to an embodiment of the present invention, when the control module increases the SOx and HCl concentration values measured by the measurement module and exceeds the first reference value, the increase rate of the measured SOx and HCl concentration values is higher than a preset value. If the first reducing agent input module is directly driven, and the increase rate of the measured SOx and HCl concentration values is smaller than the preset value, the second reducing agent input module is first driven and then the increase rate of the SOx and HCl concentration values is maintained or increased. 1 Run the reducing agent input module.

According to the present invention, it is possible to control the reducing agent injected from the dry reaction tower by monitoring the concentration of the harmful gas in real time. This can reduce the maintenance cost of the waste incineration facility.

In addition, since it is possible to maintain a constant concentration of harmful gas reaching the SCR, it is possible to prevent the life span of the SCR from being reduced due to a change in the concentration of harmful gas.

In addition, it is possible to operate the waste incineration facility more efficiently and economically by setting the standard concentration of harmful gas so that the SOx and HCl removal process of the dry reaction tower and the desulfurization process in the incinerator can be performed in parallel.

1 is a conceptual diagram of a system for controlling the concentration of harmful gases in a waste incineration facility according to an embodiment of the present invention.
Figure 2 is a conceptual diagram for explaining the driving procedure of the harmful gas removal reducing agent (chemical) input module according to the concentration of SOx and HCl detected by the measurement module.
3 is a flowchart illustrating a method for controlling the concentration of harmful gases in a waste incineration facility according to an embodiment of the present invention.
4 is a flowchart illustrating a method for controlling the concentration of harmful gases in a waste incineration facility according to another embodiment of the present invention.
5 is a conceptual diagram for explaining a driving procedure of a harmful gas removal reducing agent (drug) input module according to the concentration of SOx and HCl detected by the measurement module according to another embodiment of the present invention.

Since the present invention can have various changes and can have various embodiments, specific embodiments are illustrated in the drawings and will be described in detail in the detailed description. However, this is not intended to limit the present invention to a specific embodiment, it should be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings. In the present specification, the same and similar reference numerals are assigned to the same and similar components in different embodiments, and the description is replaced with the first description. As used herein, the singular expression includes the plural expression unless the context clearly dictates otherwise.

In addition, the suffix "module" or "part" for the components used in the following description is given or mixed in consideration of only the ease of writing the specification, and does not have a meaning or role distinct from each other by itself.

1 is a conceptual diagram of a system for controlling the concentration of harmful gases in a waste incineration facility according to an embodiment of the present invention.

Referring to Figure 1, the harmful gas concentration control system in the waste incineration facility is an incinerator, a boiler, a semi-dry reaction tower (SDR), a dry reaction tower (DR), a bag filter, a selective catalytic reduction facility (SCR) and , and may include a stack and a reducing agent input control unit.

As shown, the waste incinerated through the incinerator and the boiler is discharged through a semi-dry reaction tower (SDR), a dry reaction tower (DR), a bag filter, a selective catalytic reduction facility (SCR), and a stack.

Hereinafter, for convenience of explanation, the concentration of SOx and HCl in the harmful gas will be described. However, the concept of the present invention is not limited to the SOx and HCl concentration, it can be applied with regard to different concentrations of harmful gases such as NO _x.

In the present invention, since the concentrations of SOx and HCl increase and decrease together with the input of the reducing agent, it is preferable to set the reference concentration of the harmful gas by adding the concentrations of SOx and HCl, but according to another embodiment of the present invention, the concentration of SOx or HCl It is also possible to set the reference concentration with only the concentration (ie, the concentration of either contaminant).

Hereinafter, the contents of the present invention will be described with the concentrations of 'SOx and HCl' for convenience of description, but the concept of the present invention may be equally applied to the case of changing them to the concentrations of 'SOx or HCl'. The semi-dry reactor used in the desulfurization process of air pollutants is generally called by several different names depending on the field to which it is applied. For example, in the incinerator field, a semi-dry reactor (SDR) or absorber In the glass manufacturing process, it is called a stabilizer, and in the field of power plants, it is called a flue gas desulfurizer (FGD). In the present invention, for convenience of description, the semi-dry reactor is referred to as a semi-dry reactor (SDR).

In the semi-dry reaction tower, the slaked lime slurry is sprayed to neutralize the acid gas, and the slaked lime slurry is sprayed by the control module (the first reducing agent module) described below.

In a dry reactor (DR), slaked lime powder or activated carbon is added to neutralize acidic gas.

The neutralization reaction in the dry reaction tower is carried out in connection with the neutralization reaction in the semi-dry reaction tower. For example, depending on the amount of harmful gas (SOx or HCl) measured in the measurement module, the first reducing agent input module or the third reducing agent input module is the amount of slaked lime slurry injected from the semi-dry reaction tower and the slaked lime powder (or The amount of activated carbon) can be individually adjusted.

The reducing agent input control unit may include a control module, a measurement module, and a reducing agent input module.

The control module controls the reducing agent input module based on the harmful gas concentration data measured by the measurement module.

For example, when the concentration of the harmful gas measured by the measurement module exceeds a certain value, the control module drives the reducing agent input module to determine whether to input the slaked lime powder in the dry reaction tower or to adjust the amount of the slaked lime powder to be input.

The measurement module is disposed between the bag filter and the SCR to measure the concentration of harmful gas flowing into the SCR.

According to the related law, since the concentration, flow rate, temperature, etc. of harmful gas emitted into the atmosphere are measured and reported, in the prior art, such information was measured and feedback controlled by the TMS installed at the rear end of the stack. There is a problem in that it is difficult to give immediate feedback depending on the state of the incinerator, SDR, DR, etc. due to the distance between (or the front end of the SCR) and the TMS. In particular, ancillary equipment may be disposed between the SCR and the stack, and in this case, real-time feedback control becomes more difficult, and harmful gas exceeding the capacity may flow into the SCR and damage the SCR.

The present invention solves this problem by measuring the concentration of noxious gas flowing into the SCR and performing a noxious gas reduction process in real time based on the measured data.

The reducing agent input module may include a first reducing agent input module for adjusting the amount of slaked lime powder (or activated carbon) input to the dry reaction tower. If necessary, the first reducing agent input module can also adjust the amount of slaked lime (slurry) input to the semi-dry reaction tower.

In addition, according to another embodiment of the present invention, the reducing agent input module may further include a second reducing agent input module for controlling the amount of _{CaCO 3 input in the incinerator.}

The first reducing agent input module to the third reducing agent input module may be driven complementary to each other. For example, when the concentration of harmful gas measured in the measurement module exceeds the reference value, the first reducing agent input module is operated first, and the harmful gas concentration continues to increase despite the operation of the first reducing agent input module because the amount of harmful gas generated is excessive The second reducing agent input module may also be driven together.

In addition, although a certain amount of reducing agent is basically input in the SDR, it is possible to adjust the amount of the reducing agent input to the SDR through the third reducing agent input module according to the harmful gas concentration measured in the measurement module.

In addition, according to an embodiment of the present invention, the control module is possible to selectively operate the first to third reducing agent input modules according to the combustion characteristics of the incineration facility. For example, when the harmful gas increase rate is high, the first reducing agent input module is operated first, and when the harmful gas increase rate is low, it is possible to operate the first reducing agent input module after first operating the second reducing agent input module.

Hereinafter, embodiments of the present invention will be described in detail with reference to FIGS. 2 to 4 .

In addition, according to another embodiment of the present invention, the system may adjust the input of the reducing agent according to the type of waste introduced into the incinerator. To this end, the incinerator may be provided with an image acquisition module for understanding the properties of the incoming waste.

The image acquisition module may include a visible light camera, an infrared camera, or a hyperspectral camera.

If the waste is expected to contain a lot of sulfur or chlorine by analyzing the data collected through the image acquisition module, the control module can pre-spray the reducing agent by driving the reducing agent input module before receiving the data from the measurement module.

That is, in this embodiment, the control module can control the input of the reducing agent more precisely by synthesizing the data collected from the image acquisition module and the measurement module.

2 is a conceptual diagram for explaining the operation procedure of the harmful gas removal reducing agent input module according to the concentration of SOx and HCl detected by the measurement module.

Referring to FIG. 2 , the control module operates the first reducing agent input module when the harmful gas concentration measured by the measurement module reaches the first reference value, and operates the second reducing agent input module when the second reference value is reached.

When the first reducing agent input module is operated, since the concentration of harmful gas generated in the facility is reduced, the rate of increase in the concentration of harmful gas on the graph of FIG. 2 is gradually reduced to be reduced below the first reference value.

When the concentration of the harmful gas is reduced below the first reference value, the control module may stop the first reducing agent input module or allow only the set minimum amount of reducing agent to be input. . That is, the control module blocks the slaked lime powder input to the dry reaction tower to prevent unnecessary waste of the reducing agent.

Then, when the sulfur and chlorine components contained in the waste increase and the SOx and HCl concentrations again reach the first reference value, the control module operates the first reducing agent input module again to increase the reducing agent input amount in the DR. .

When the concentration of SOx and HCl reaches the second reference value despite the operation of the first reducing agent input module because the sulfur component contained in the waste is excessive, the control module operates the second reducing agent input module.

When the second reducing agent input module is operated, CaCO ₃ is injected into the incinerator to reduce the increase in the concentration of SOx and HCl generated in the facility. When the concentration of SOx and HCl decreases below the second reference value, the control module stops the second reducing agent input module.

Even if the second reducing agent input module is stopped, if the concentration of SOx and HCl exceeds the first reference value, the second reducing agent input module continues to operate. When the first reducing agent input module is operated and the concentration of SOx and HCl generated in the facility is reduced below the first reference value, the control module also stops the first reducing agent input module or allows only the set minimum amount of reducing agent to be input.

According to the complex harmful gas removal process driven in response to changes in the concentration of SOx and HCl, the concentration of SOx and HCl introduced into the SCR can be maintained at a certain level.

3 is a flowchart illustrating a method for controlling the concentration of harmful gases in a waste incineration facility according to an embodiment of the present invention, and FIG. 4 is a method for controlling the concentration of harmful gases in a waste incineration facility according to another embodiment of the present invention. It is a flowchart.

Referring to FIG. 3, in the system, after spraying slaked lime slurry or slaked lime powder and water in the semi-dry reaction tower, the measuring module measures the SOx and HCl concentrations at the rear end of the bag filter (or the front end of the SCR), and the SOx and HCl concentrations are the first If it falls below the standard, stop spraying the slaked lime slurry or slaked lime powder and water, and if the concentration is above the standard, keep spraying.

2 and 4 , the system may be configured to control the injection module by dividing the harmful gas reference concentration into two stages.

The system predicts the properties of the waste flowing into the incinerator, and when the amount of sulfur or chlorine contained in the waste is expected to be higher than the reference value, the second reducing agent input module may be operated in advance before receiving the data of the measurement module. The reference value may be a first reference value, a second reference value, or a separately selected reference value.

In addition, even after spraying 'slaked lime slurry' or 'slaked lime powder and water' in the semi-dry reaction tower, if the concentration of SOx and HCl is higher than the second reference value, the second reducing agent input module is operated to spray _{CaCO 3 from the incinerator.}

When the second reducing agent input module is operated and the concentration of SOx and HCl falls below the second reference value, the system stops the second reducing agent input module, and when the concentration of SOx and HCl falls below the first reference value, the first reducing agent input module is also stopped to stop the reducing agent to prevent wastage of

When the concentration of SOx and HCl falls below the second reference value but is higher than the first reference value, the first reducing agent input module is continuously operated to further reduce the concentration of SOx and HCl.

Also, referring to FIG. 5 , the control module may further set a third reference value between the first reference value and the second reference value.

As shown, the system predicts the properties of the waste at the time when the waste starts to flow, and the reducing agent (CaCO ₃ ) injected into the incinerator can be adjusted in advance. At this time, any one of the first reference value, the second reference value, or the third reference value may be selected as the reference value for determining whether to inject the reducing agent.

According to an embodiment of the present invention, the reducing agent input may be differentially applied according to the amount of change in the concentration of the pollutant. For example, when the concentration of a pollutant increases rapidly, the reducing agent may be injected from the DR immediately, and when the concentration of the pollutant increases slowly, the reducing agent may be injected from the DR after the reducing agent is input from the incinerator. At this time, the control module directly drives the first reducing agent input module when the increase rate of the measured SOx and HCl values is higher than the preset value when the SOx and HCl values measured in the measurement module increase and exceed the first reference value, and the measurement is performed. When the increase rate of the SOx and HCl values is smaller than the preset value, the second reducing agent input module is first driven, and then, when the increase rate of the SOx and HCl values is maintained or increased, the first reducing agent input module may be driven.

In addition, according to another embodiment of the present invention, when the concentration of the contaminant measured by the measurement module exceeds the second reference value, the second reducing agent input module is operated, but when the third reference value is exceeded in the case of waste property analysis The second reducing agent input module may be operated.

That is, if the concentration of the pollutant is expected to correspond to a specific value between the maximum reference value (second reference value) and the minimum reference value (first reference value), the system arbitrarily operates the second reducing agent input module to initially enter the SCR. You can control the amount of pollutants. After that, precise control can be started according to the measurement value of the measurement module. The system may adjust the operation of the first reducing agent module according to whether the harmful gas concentration falls below the third reference value.

For example, when the harmful gas concentration is higher than the second reference value, both the first reducing agent input module and the second reducing agent module are operated, and when the concentration is between the second reference value and the third reference value, the second reducing agent input module is stopped, but the first reducing agent input module is stopped The input module is activated.

When the harmful gas concentration becomes lower and becomes between the third reference value and the first reference value, the system stops the first reducing agent input module. That is, the system stops the input of the reducing agent in the DR when the concentration of the harmful gas is lower than the third reference value, thereby lowering the rate of decreasing the concentration of the harmful gas, thereby reducing the wastage of the reducing agent due to the time difference between the input of the reducing agent and the measurement of the harmful gas. In this case, the control module maintains the reducing agent injected from the SDR.

When the harmful gas concentration is lower than the first reference value, the system reduces the reducing agent injection amount in the SDR to a minimum to prevent the reducing agent from being wasted.

As described above, the present invention can control the reducing agent sprayed from the dry reaction tower by monitoring the concentration of the harmful gas in real time, thereby reducing the maintenance cost of the waste incineration facility and reducing the harmful gas concentration reaching the SCR. It can be kept constant so that the lifespan of the SCR due to changes in the concentration of harmful gases can be prevented from being reduced. Thus, it is possible to expect different effects from the prior art, such as enabling more efficient and economical operation of waste incineration facilities.

The present invention described above is not limited to the configuration and method of the above-described embodiments, but all or some of the embodiments may be selectively combined so that various modifications may be made.

Claims (10)

Waste incineration facilities including semi-dry reaction tower (SDR), dry reaction tower (DR), bag filter and selective catalytic reduction facility (SCR); and
Including a reducing agent input control unit for controlling the input of the reducing agent in the waste incineration facility,
The reducing agent input control unit,
a measurement module disposed between the bag filter and the selective catalytic reduction facility (SCR);
a reducing agent input module for removing SOx and HCl by introducing a reducing agent; and
Harmful gas concentration control system in a waste incineration facility, characterized in that it comprises a control module for controlling the operation of the reducing agent input module based on the harmful gas concentration data measured by the measurement module. According to claim 1,
The reducing agent input module,
Noxious gas concentration control system in a waste incineration facility, characterized in that it comprises a first reducing agent input module for controlling the amount of slaked lime powder input to the dry reaction tower (DR). 3. The method of claim 2,
The reducing agent input module,
Noxious gas concentration control system in a waste incineration facility, characterized in that it comprises a second reducing agent input module for controlling the amount of _{CaCO 3} input to the incinerator. 4. The method of claim 3,
The reducing agent input module,
Harmful gas concentration control system in a waste incineration facility, characterized in that it comprises a third reducing agent input module for controlling the amount of slaked lime slurry input to the semi-dry reaction tower (SDR). 5. The method of claim 4,
The control module is
In a waste incineration facility, characterized in that the first reducing agent input module is driven when the SOx and HCl values measured by the measurement module exceed the first reference value, and the second reducing agent input module is driven when the second reference value is exceeded Harmful gas concentration control system. 5. The method of claim 4,
The control module is
When the SOx and HCl values measured in the measurement module increase and exceed the first reference value, if the increase rate of the measured SOx and HCl values is higher than a preset value, the first reducing agent input module is directly driven, and the measured SOx and HCl When the increase rate of the value is smaller than the preset value, the second reducing agent input module is first driven, and then, when the increase rate of SOx and HCl values is maintained or increased, the first reducing agent input module is driven. Concentration control system. 5. The method of claim 4,
Toxic gas concentration control system in the waste incineration facility that is installed in the incinerator and further includes an image acquisition module to determine the properties of the incoming waste. 8. The method of claim 7,
When the amount of sulfur or chlorine contained in the waste is predicted to be higher than the standard value by predicting the properties of the waste flowing into the waste incineration facility, the second reducing agent input module is operated in advance before receiving the data of the measurement module Hazardous gas concentration control system in waste incineration facility. 9. The method of claim 8,
The control module is
When the concentration of the pollutant measured by the measurement module exceeds the second reference value, the second reducing agent input module is operated, but as a result of the analysis of the waste properties, when the emission of pollutants is predicted to increase, a third lower than the second reference value A system for controlling the concentration of harmful gases in a waste incineration facility, characterized in that the second reducing agent input module is operated when the standard value is exceeded. 10. The method of claim 9,
The control module is
When the SOx and HCl concentration values measured in the measurement module increase and exceed the first reference value, if the increase rate of the measured SOx and HCl concentration values is higher than a preset value, the first reducing agent input module is directly driven, and the measured SOx and when the increase rate of the HCl concentration value is smaller than the preset value, the second reducing agent input module is first driven, and then the first reducing agent input module is driven when the increase rate of the SOx and HCl concentration values is maintained or increased. Waste incineration Harmful gas concentration control system in the facility.

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