KR101606009B1 - Method for controlling clinker - Google Patents

Abstract

Provided is a method for controlling a clinker. The method for controlling a clinker of the present invention is a method for controlling a clinker generated during the combustion of coal by using a clinker control device in a thermal power generation system which conveys coal by using a conveyor belt and supplies the coal to a boiler. The clinker control device comprises: a supply unit placed on the conveyor belt to supply a clinker control agent to the coal, which comprises two or more nozzles for spraying different clinker control agents; a control unit for controlling the supply unit according to the substances of the coal to control the supply of the clinker control agent; and a storage unit connected to the supply unit to store the clinker control agent, which comprises two or more tanks storing different clinker control agents. The method for controlling a clinker of the present invention comprises the steps of: preparing substance data of the coal; controlling the supply condition of the clinker control agent according to the substance data; and supplying the clinker control agent according to the supply condition. The present invention analyzes the substances of the coal and when the substances of the coal are changed, the types of the clinker control agents supplied to the coal are also changed.

Description

{METHOD FOR CONTROLLING CLINKER}

The present invention relates to a method of inhibiting clinker.

The thermal power plant burns coal to generate energy and produces about 40% of domestic power. The coal-fired power plant burns coal and heavy fuel oil mixed with an appropriate amount of air in a huge boiler. At this time, deposits such as clinker and slag, which are coal ashes remaining in the boiler, are generated. These clinkers can accumulate in the boiler and damage the boiler. Also, if the boiler is shut down due to the clinker, it may cause a great loss in the power generation efficiency of the entire thermal power plant.

One of the most common causes of clinker is the change of coal ash. In Korea, since coal is mainly imported from abroad, the quality of coal and the type of coal often change. Particularly, anthracite, semi-anthracite, bituminous coal, and heavy oil (Bunker-C oil) are burned together. Combustion characteristics of these fuels are not compatible with existing boilers, and the amount of generated clinker is increased.

Conventionally, the clinker inside the boiler has been physically removed to remove the clinker. However, this method is very dangerous and safety accidents can occur because people have to apply physical force directly. In addition, there is a problem that when the boiler is stopped to remove the clinker, loss of electric power is generated, and the overall cost efficiency of the electric power generation is reduced. There is a method of using an inhibitor to suppress the clinker, but there is a problem that it is very difficult to change the supply condition of the inhibitor every time the composition of the coal coal or coal is changed.

In order to solve the above problems, a clinker suppression method for suppressing the generation of clinker by supplying a clinker inhibitor to the thermal power generation system of the present invention is provided.

The present invention provides a method of inhibiting clinker that controls the supply of a clinker inhibitor depending on the composition of coal.

Other objects of the present invention will become apparent from the following detailed description and the accompanying drawings.

The clinker suppression method according to embodiments of the present invention is a method for suppressing clinker generated by combustion of coal by using a clinker suppression device in a thermal power generation system for conveying coal to a boiler by using a conveyor belt Wherein the clinker suppression device comprises a supply portion disposed on the conveyor belt and including at least two nozzles for supplying a clinker inhibitor to the coal and for spraying different clinker inhibitors, And a reservoir connected to the supply unit and including at least two tanks for storing the clinker inhibitor and storing different clinker inhibitors, wherein the clinker suppression method comprises: A step of preparing a large amount of Controlling the supply condition of the linker inhibitor, and supplying the clinker inhibitor according to the supply condition, wherein when the component of the coal is changed in real time, The type of clinker inhibitor is also changed.

The component data may be generated using a nuclear magnetic resonance (NMR) apparatus.

The clinker suppression method may further comprise preparing weight data of the coal, and in the adjustment step, the supply of the clinker inhibitor may be adjusted according to the weight data of the coal.

The clinker suppression method may further comprise preparing data on the amount of generated clinker, and the supply of the clinker inhibitor may be adjusted according to the clinker amount data.

In the adjustment step, at least one selected from among the kind of the clinker inhibitor, the supply amount of the clinker inhibitor, and the supply time of the clinker inhibitor may be adjusted.

The thermal power generation system may include an overburden sensor disposed below the conveyor belt for detecting the degree of overburden of the coal, and when the overburden sensor generates the overburden signal, the clinker inhibitor may be supplied to the coal have.

The clinker suppression method according to the embodiments of the present invention can suppress the generation of clinker generated in the thermal power generation system by supplying the clinker inhibitor to the thermal power generation system. In addition, the clinker suppression method can control the supply of the clinker inhibitor in accordance with the component and / or the seed of the coal used in the thermal power generation system. Since the clinker inhibiting method supplies the clinker inhibitor differently according to the components of the coal, it is possible to use coal of various qualities, so that low-cost coal can be used without worrying about the clinker. Also, since the clinker suppression method reduces the amount of generated clinker, the management cost of the thermal power generation system can be reduced, and the overall cost of power generation can be reduced. The clinker suppression method can reduce the loss caused by an increase in differential pressure due to clogging of the air heater of the thermal power generation system. The clinker suppression method can prevent a phenomenon that the clinker falls and the water pipe of the boiler furnace wall is broken. The clinker suppression method can reduce a shutdown phenomenon of the thermal power generation system by forming bridges due to over-generation of the clinker.

1 shows a clinker suppression device according to embodiments of the present invention.
2 shows a clinker suppression device according to embodiments of the present invention.
3 illustrates a process of processing coal component data of a clinker suppression apparatus according to embodiments of the present invention.
4 shows a clinker suppression apparatus including a component measurement unit according to embodiments of the present invention.
5 shows a clinker suppression apparatus including a weight measuring unit according to embodiments of the present invention.
Figure 6 shows a clinker suppression device comprising a topsensor sensor according to embodiments of the present invention.
7A and 7B illustrate the operation method of the control unit 200 according to the embodiments of the present invention.
8 shows a clinker suppression apparatus including a clinker measurement unit according to embodiments of the present invention.
9 shows a clinker measuring unit according to embodiments of the present invention.
10 shows a thermal power generation system including a clinker suppression device according to embodiments of the present invention.
11 and 12 illustrate a clinker suppression method according to embodiments of the present invention.

Hereinafter, the present invention will be described in detail with reference to examples. The objects, features and advantages of the present invention will be easily understood by the following embodiments. The present invention is not limited to the embodiments described herein, but may be embodied in other forms. The embodiments disclosed herein are provided so that the disclosure may be thorough and complete, and that those skilled in the art will be able to convey the spirit of the invention to those skilled in the art. Therefore, the present invention should not be limited by the following examples.

Although the terms first, second, etc. are used herein to describe various elements, the elements should not be limited by such terms. These terms are only used to distinguish the elements from each other. In addition, when an element is referred to as being on another element, it may be directly formed on the other element, or a third element may be interposed therebetween.

The sizes of the elements in the figures, or the relative sizes between the elements, may be exaggerated somewhat for a clearer understanding of the present invention. In addition, the shape of the elements shown in the drawings may be somewhat modified by variations in the manufacturing process or the like. Accordingly, the embodiments disclosed herein should not be construed as limited to the shapes shown in the drawings unless specifically stated, and should be understood to include some modifications.

[ Clinker  Suppression device]

1 and 2 show a clinker suppression device 10 according to embodiments of the present invention.

Referring to FIGS. 1 and 2, the clinker suppression apparatus 10 may include a supply unit 100, a control unit 200, and a storage unit 300.

The supply unit 100 supplies a clinker inhibitor capable of suppressing the clinker generated in the thermal power generation system 1. The supply unit 100 is controlled by the control unit 200 and can supply a clinker inhibitor stored in the storage unit 300 to the thermal power generation system 1. [

The supply portion 100 may include components for transporting and supplying the liquid clinker inhibitor stored in the storage portion 300 to the thermal power generation system 1, for example, pipes, pumps, valves, and nozzles. The pipe may provide a passage for moving the clinker inhibitor by connecting the storage unit 300 and the nozzle. The pump can transfer the clinker inhibitor of the storage unit 300 to a higher position. The valve may be disposed in the pipe to control the flow rate of the clinker inhibitor delivered through the pipe. The nozzle may be disposed on a conveyor belt 20 that carries coal and may spray a clinker inhibitor to the coal carried by the conveyor belt. Different pipes, nozzles, and valves may be used depending on the number of pipes and the number of nozzles, and the kind of the clinker inhibitor.

The control unit 200 controls the supply unit 100 to regulate the supply of the clinker inhibitor. The control unit 200 can control at least one selected from a type of a clinker inhibitor, a supply amount of a clinker inhibitor, and a supply time of a clinker inhibitor.

The control unit 200 may analyze data including at least one selected from the coal component data, the operating conditions of the thermal power generation system 1, the weight data of the coal, and the amount of clinker generated to control the supply of the clinker inhibitor . The data can be received and stored in the control unit 200 and used. For example, the user can confirm a clinker inhibitor supply setting value suitable for the stored data.

The composition of the coal may not be constant. The lower the cost of the coal, the more often the composition of the coal may change. Preferably, in order to effectively suppress the clinker, the clinker inhibitor may be supplied differently depending on the change in the composition of the coal.

The control unit 200 may control the supply unit 100 to supply the other clinker inhibitor depending on the coal component. The control unit 200 can receive the coal component data and select the clinker inhibitor suitable for the coal component data. For example, for the first coal and the second coal having different components, the first clinker inhibitor may be supplied to the first coal, and the second clinker inhibitor may be supplied to the second coal . The constituent data of the coal can be obtained by various methods.

The control unit 200 can adjust the supply of the clinker inhibitor according to the operating conditions of the thermal power generation system 1. [ The operating conditions may include at least one selected from data such as the scale, performance, and system temperature of the thermal power generation system 1, but the present invention is not limited thereto and may vary depending on the type of the thermal power generation system 1.

The control unit 200 may adjust the supply of the clinker inhibitor according to the weight data of the coal. The control unit 200 may adjust the supply amount of the clinker inhibitor according to the weight data. For example, as the weight increases, the amount of supply may also increase. When the weight is detected, the controller 200 can operate the supplying unit 100. [

The control unit 200 can adjust the supply of the clinker inhibitor according to the amount of clinker generated. For example, if the controller 200 determines that the clinker needs to be further suppressed after checking the clinker generation amount, the controller 200 may increase the supply amount of the clinker inhibitor.

The storage unit 300 stores the clinker inhibitor. The storage 300 may include one or more clinker inhibitor storage tanks. For example, the storage unit 300 may include a first tank 301, a second tank 302, a third tank 303, and a fourth tank 304. The first to fourth tanks may store different clinker inhibitors, respectively. For example, the first tank may contain a first clinker inhibitor 301, the second tank 302 may include a second clinker inhibitor, the third tank 303 may include a third clinker inhibitor, May store a fourth clinker inhibitor. The clinker inhibitor stored in the storage unit 300 may be supplied through the supply unit 100 connected to the pipe.

In embodiments, the controller 200 may be wirelessly and / or wirelessly connected to the storage 300 to monitor the storage state of the clinker inhibitor, the remaining amount of the clinker inhibitor, and the like.

FIG. 3 shows a process of processing the coal component data of the clinker suppression apparatus 10 according to the embodiments of the present invention, and FIG. 4 shows a clinker suppression apparatus including the coal analysis unit 400 according to the embodiments of the present invention .

3 and 4, the coal component data may include at least one selected from first component data (a) and second component data (b).

The first component data (a) may be data obtained by analyzing the components of the coal extracted at random. For example, the first component data (a) may be analyzed by random extraction of the coal. The specific analysis method or means of the first component data (a) is not limited.

The second component data (b) may be data obtained by analyzing the coal with the coal analysis unit (400). The coal analysis unit 400 may analyze the components of the coal being conveyed through the conveyor belt 20 to generate the second component data b. The second component data (b) may be generated in real time and transmitted to the control unit (200). The controller 200 can increase the accuracy of the coal component data through the second component data b and select the optimum clinker inhibitor suitable for the coal to be supplied. When the second component data (b) is used, the controller 200 can adjust the supply of the clinker inhibitor in accordance with the change of the component of the coal.

The clinker suppression apparatus 10 may further include a coal analysis unit 400. The coal analysis unit 400 may be disposed on the conveyor belt 20. Preferably, the coal analysis section 400 may be disposed before the feed section 100. This is because it is preferable that the analysis of the coal is performed before the clinker inhibitor is supplied to the coal.

In embodiments, the coal analysis section 400 may be a nuclear magnetic resonance (NMR) device. The NMR apparatus may be an apparatus using a phenomenon in which external energy specific to the magnetic moment of the nucleus in a magnetic field acts to absorb the energy and transfer to another energy level. The NMR apparatus can accurately analyze the coal component. The coal analysis unit 400 is not limited to the above NMR apparatus, and it is only required to be able to measure the components of the coal.

5 shows a clinker suppression apparatus 10 including a weighing unit 500 according to embodiments of the present invention.

Referring to FIG. 5, the clinker suppression apparatus 10 may further include a weight measuring unit 500 disposed under the conveyor belt 20 to generate weight data of the coal. When the weight data is transmitted to the controller 200, the controller 200 may control the supplier 100 to adjust the supply amount of the clinker inhibitor by analyzing the weight data. For example, when the weight data is increased, the control unit 200 may control the supply unit 100 to increase the supply amount of the clinker inhibitor. In another example, the controller 200 may adjust the supply amount of the clinker inhibitor per hour of the supply nozzle according to the weight data. The control unit 200 can operate the supplying unit 100 by sensing the weight.

When the weight data is transferred to the controller 200, the controller 200 may adjust the supply time of the clinker inhibitor. The supply time may vary depending on the type of the clinker inhibitor. For example, in the clinker suppression apparatus 10 for supplying the first clinker inhibitor, the control unit 200 may control the supply unit 100 according to the weight data to adjust the supply time of the first clinker inhibitor . In another example, the control unit 200 may control the supply unit 100 to adjust the interval of the supply time.

Figure 6 shows a clinker suppression device 10 comprising a carburst sensor 600 in accordance with embodiments of the present invention.

Referring to FIG. 6, the clinker suppression apparatus 10 may further include a carburizing sensor 600 for detecting whether or not the coal is burnt on the conveyor belt 20. The carburizing sensor 600 can automatically generate a carburst signal when the coal is loaded on the conveyor belt 20. [ The controller 200 may receive the satellite signal. The control unit 200 can operate the supplying unit 100 by the supercharging signal. In the embodiments, when the control unit 200 is stopped, the control unit 200 may be automatically operated when the overcurrent signal is generated.

7A and 7B show a control method of the supplying unit 100 of the control unit 200 according to the embodiments of the present invention.

7A, when at least one of the weight data and the car signals is transmitted to the control unit 200, when the control unit 200 is in operation, the control unit 200 starts to control the supply unit 100 . The signal may be variously set according to the operating condition of the thermal power generation system 1, stability, and the intention of the user. For example, the user can set the control unit 200 to control the supply unit 100 upon receiving both the weight data and the top signal.

In another example, when at least one of the weight data and the top signal is transmitted to the control unit, the control unit 200 may be operated when the control unit 200 is stopped.

Referring to FIG. 7B, the control unit 200 may stop the control of the supply unit 100 if at least one of the weight data and the car signals is not received.

7A and 7B, the control unit 200 can determine whether coal is present on the conveyor belt 20 and automatically start or stop the control of the supply unit 100. [

8 shows a clinker suppression apparatus 10 including a clinker measurement unit 700 according to embodiments of the present invention.

Referring to FIG. 8, the clinker suppression apparatus 10 may further include a clinker measurement unit 700. The clinker measuring unit 700 can measure the amount of clinker generated in the boiler 30 where the coal is burnt. The clinker measuring unit 700 may transmit the clinker amount data to the controller 200. [ The control unit 200 may control the supply unit 100 to adjust the supply of the clinker inhibitor by analyzing the clinker amount data.

9 shows a clinker measuring unit 700 according to embodiments of the present invention.

Referring to FIG. 9, the clinker measuring unit 700 according to the embodiments may include an insertion portion 701 and a body portion 702.

The inserting portion 701 can be inserted into the boiler 30. The insertion portion 701 may include a temperature sensor. For example, when the inserting portion 701 is inserted into the boiler 30, the clinker can be accumulated in the inserting portion 701. The temperature sensor can measure the temperature of the inserting portion 701. The temperature may vary depending on the amount of the clinker generated.

The main body 702 may include an operation unit for calculating the amount of the clinker generated therein. For example, the body portion 702 may analyze the temperature measured at the inserting portion 701 to generate the clinker amount data.

[Thermal power generation system]

10 shows a thermal power generation system 1 including a clinker suppression device 10 according to embodiments of the present invention.

10, the thermal power generation system 1 includes a clinker suppression device 10, a boiler 30, a denitration device 40, a heat exchanger 50, a dust collector 60, and a desulfurizer 70 can do. The clinker suppressing device 10 can suppress the amount of the clinker generated inside the boiler 30. The boiler 30 can be stopped by the clinker, and the shutdown phenomenon of the boiler 30 can be reduced due to the operation of the clinker suppression device 10. [

When the boiler 30 burns the coal, exhaust gas is generated. The exhaust gas includes atmospheric pollutants such as nitric acid gas, dust, and sulfuric acid gas. If the clinker is suppressed by the clinker suppression device 10, the quality of the exhaust gas may be improved. Therefore, the content of nitric acid gas, dust, and sulfuric acid gas contained in the exhaust gas can be reduced. If the content of the nitric acid gas contained in the exhaust gas is reduced, the life of the denitration unit 40 may increase. If the content of the dust contained in the exhaust gas is reduced, the life of the dust collector 60 may increase. If the content of the sulfuric acid gas contained in the exhaust gas is reduced, the life of the desulfurizer 70 may increase. The clinker suppression device 10 suppresses the amount of clinker generated, thereby improving the quality of the exhaust gas, thereby increasing the lifetime and efficiency of the entire thermal power generation system 1. [

[Clinker suppression method]

A method for suppressing clinker occurring in a thermal power generation system (1) using coal is disclosed. Preferably, the clinker inhibitor may be administered differently depending on the composition of the coal, in order to effectively inhibit the clinker.

11 and 12 illustrate a clinker suppression method according to embodiments of the present invention.

Referring to FIGS. 11 and 12, the clinker suppression method includes preparing data for controlling supply of a clinker inhibitor (S10), adjusting supply conditions of a clinker inhibitor according to the data (S20) (S30) < / RTI >

Data for controlling the supply of the clinker inhibitor is prepared (S10). The data may include at least one selected from coal component data, coal weight data, clinker generation data, operating condition data of the thermal power generation system, and clinker type data. For example, the component data may be prepared by NMR analysis or the like. The component data may include at least one selected from first component data obtained by randomly extracting and analyzing the coal and second component data obtained by analyzing the coal in real time.

The supply condition of the clinker inhibitor is adjusted according to the data (S20). Depending on the data, one or more conditions selected from the type of clinker inhibitor, the feed rate, and the feed time may be adjusted.

For example, other clinker inhibitors may be supplied depending on the composition of the coal. For the first coal and the second coal having different components, the first clinker inhibitor may be adjusted to be supplied to the first coal, and the second clinker inhibitor may be adjusted to be supplied to the second coal . The constituent data of the coal can be obtained by various methods.

In another example, the supply condition of the clinker inhibitor may be adjusted according to the operating condition data. The operating condition may include at least one selected from data such as the scale, performance, and system temperature of the thermal power generation system, and may vary depending on the type of the thermal power generation system.

In another example, the supply amount condition of the clinker inhibitor may be adjusted according to the weight data of the coal. When the weight increases, the supply amount may also increase.

In another example, the supply condition of the clinker inhibitor may be adjusted according to the clinker amount data. As a result of checking the amount of clinker generated, if it is determined that the clinker needs to be further suppressed, the supply amount of the clinker inhibitor can be increased.

The clinker inhibitor is supplied according to the supply condition (S30). For example, a liquid clinker inhibitor may be supplied to the coal through a pipe, pump, nozzle, or the like.

In embodiments, the clinker suppression method may further comprise the step of ascertaining the amount of clinker generated. The amount of clinker generated can be measured by the clinker measuring unit 700. The control unit 200 checks the clinker generation amount, and if it is necessary to further suppress the clinker, the control unit 200 can regulate the supply of the clinker suppression agent again (S20).

[ Example  One]

When the clinker suppression device 10 according to the embodiments of the present invention was used, the operation period of the boiler 30 was measured to confirm the clinker suppression effect. If a large amount of the clinker is formed in the boiler 30, the operation time is reduced and the power generation efficiency is reduced. Therefore, the longer the operating time of the boiler 30, the better the effect of the clinker suppression device 10 can be.

Conventional coal-fired boilers can cause slagging and fouling due to the occurrence of clinker, which can cause frequent problems. In order to solve such a problem, when the boiler is stopped and cleaned, energy loss may occur.

In the boiler in which the clinker suppression device 10 according to the present embodiment was not applied, the generation stoppage period for the cleaning was three weeks. The power generation stop period is an example corresponding to the present embodiment, and does not limit the present invention.

The amount and composition of the coal supplied to the boiler are not uniform and it is difficult to supply the clinker inhibitor suitable for the coal. In one example, when unexpectedly large amounts of bituminous coal were introduced into the boiler, more slagging and clinker were formed than usual.

In order to solve the above problems, the clinker suppression apparatus 10 according to the embodiment of the present invention is applied. In this embodiment, the clinker suppression device 10 was able to adjust the supply of the clinker inhibitor in real time in response to a change in the composition of the coal.

As a result of applying the clinker suppression device 10, the power generation stop period could be extended from 3 weeks to 5 weeks. The power generation stop period may vary depending on conditions such as the quality of the coal and the quality of the clinker inhibitor.

[ Example  2]

In order to confirm the reduction effect of SOx emissions according to the clinker suppression device 10 in the thermal power generation system 1 including the clinker suppression device 10 according to the embodiment of the present invention, ) The SO ₃ emissions before and after the operation were compared.

The SO ₃ emission amount was measured at the desulfurizer 70. If the amount of SO ₃ discharged after the operation of the clinker suppression device 10 is lower than the previous one, it can be judged that the effect of the clinker suppression device 10 is excellent.

SOx emissions before desulfurization (ppm) SOx emissions after desulfurization (ppm) Minimum 316 31 Average 371 44 Highest 424 65

Number of measurements Clinker suppression device Inoperative SO ₃ (ppm) Clinker inhibitor Operating SO ₃ (ppm) One 10.93 6.73 2 10.09 2.04 3 19.34 12.61

Table 1 shows the SOx emissions measured at the front end and the rear end of the desulfurizer 70 according to the embodiment of the present invention. Table 2 shows the SO ₃ emission amounts generated in the thermal power generation system 1 according to the embodiment of the present invention. . The SO ₃ emission amount was expressed by averaging the data measured in each hour (minute), and the number of measurements was three.

Referring to Table 1, SOx emissions before and after desulfurization are shown in the state where the clinker suppression device 10 is not applied. Thus, the effect of the desulfurizer 70 can be confirmed.

Referring to Table 2, it is possible to confirm the SO ₃ emission amount when the clinker suppressing apparatus 10 is not operated and when it is operating. When the clinker suppression device 10 was not operating, the amount of SO ₃ generated at the rear end of the desulfurizer 70 was measured to be 10.93, 10.09, and 19.34 ppm, respectively. When the clinker suppression device 10 was operated, the amount of SO ₃ generated at the rear end of the desulfurizer 70 was measured to be 6.73, 2.04, and 12.61 ppm, respectively. It can be confirmed that the amount of generated SO ₃ is remarkably reduced due to the operation of the clinker suppression device 10.

Due to the clinker suppression device 10, the amount of SOx and SO ₃ emissions can be reduced, thereby increasing the lifetime of the desulfurizer 70. In addition, if the SOx emission amount is reduced, corrosion of parts affected by the exhaust gas can be suppressed, and the overall stability and power generation efficiency of the thermal power generation system 1 can be improved.

Hereinafter, specific embodiments of the present invention have been described. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the disclosed embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is defined by the appended claims rather than by the foregoing description, and all differences within the scope of equivalents thereof should be construed as being included in the present invention.

1: Thermal power generation system 10: Clinker suppression device
20: Conveyor belt 30: Boiler
40: denitration unit 50: heat exchanger
60: dust collector 70: desulfurizer
100: supply unit 200:
300: storage unit 301: first tank
302: second tank 303: third tank
304: fourth tank 400: coal analysis section
500: Weight measuring part 600:
700: Clinker measuring unit 701:
702: main body portion a: first component data
b: second component data

Claims (6)

A method for controlling a clinker generated by combustion of coal by using a clinker suppressing device in a thermal power generation system for conveying coal to a boiler by using a conveyor belt,
Wherein the clinker suppression device comprises a supply portion disposed on the conveyor belt and comprising at least two nozzles for supplying a clinker inhibitor to the coal and for spraying different clinker inhibitors, And a reservoir coupled to the supply and including at least two tanks for storing the clinker inhibitor and for storing different clinker inhibitors,
Preparing component data of the coal;
Adjusting a supply condition of the clinker inhibitor according to the component data; And
Supplying the clinker inhibitor in accordance with the feeding condition,
Wherein the composition of the coal is analyzed in real time to change the type of the clinker inhibitor supplied to the coal when the composition of the coal is changed. The method according to claim 1,
Wherein the component data is generated using a nuclear magnetic resonance (NMR) apparatus. The method according to claim 1,
Further comprising preparing weight data of the coal,
Wherein the control of the supply of the clinker inhibitor is controlled according to the weight data of the coal. The method according to claim 1,
Further comprising the step of preparing data on the amount of generated clinker,
Wherein the supply of the clinker inhibitor is controlled according to the clinker generation amount data. The method according to claim 1,
Wherein at least one selected from among the type of the clinker inhibitor, the amount of the clinker inhibitor supplied, and the time of supplying the clinker inhibitor is regulated in the regulating step. The method according to claim 1,
In the thermal power generation system,
And a supercharged sensor disposed below the conveyor belt for detecting whether the coal is recharged,
And the clinker inhibitor is supplied to the coal when the supercharged sensor generates a supercharged signal.

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