KR20210091617A - Automatic Calculation System and Method for Combustion reaction gas Distribution Diagram Plot of Fluidized Bed Boiler - Google Patents

Abstract

The present invention relates to an automatic calculation system for an air distribution chart of a fluidized bed boiler which provides a graph showing an air volume ratio in accordance with a boiler load, and a driving method thereof. The automatic calculation system for an air distribution chart of a fluidized bed boiler comprises: a ratio determination unit determining the ratio of primary air and secondary air in a combustion chamber in accordance with a fuel type; an air volume calculation unit calculating a minimum required air volume required for fuel injection in accordance with a fuel injection method; and a graph generation unit using the minimum required air volume calculated by the air volume calculation unit to generate a boiler air distribution curve graph displaying an air injection amount for each boiler load. The automatic calculation system for an air distribution chart of a fluidized bed boiler can suggest a guide for stable combustion and load operation in comparison to a conventional operation method of determination and operation by an operator based on operation data collected from a pressure gauge and a thermometer when changing fuel.

Description

Automatic Calculation System and Method for Combustion reaction gas Distribution Diagram Plot of Fluidized Bed Boiler

The present invention relates to a system for automatically calculating the air distribution of a fluidized bed boiler and a driving method thereof, and more particularly, to a system for automatically calculating the air distribution of a fluidized bed boiler and a driving method thereof, which provides a graph showing a ratio of an air amount according to a boiler load. .

A fluidized bed boiler is an eco-friendly power generation technology that has the advantage of significantly reducing the generation of sulfur oxides and nitrogen oxides compared to conventional thermal power boilers and can apply various fuels such as low-quality coal, biomass, and waste.

In particular, biomass fuels can reduce the impact of global warming _{caused by CO 2} emissions generated by the combustion of fossil fuels such as coal and natural gas. In addition, because of the advantage of being able to recover energy, waste fuel is gradually being applied to fluidized bed boilers.

In the case of domestic and foreign circulating fluidized bed boiler power plants, other types of coal other than the existing design coal are burned, and the application of biomass co-firing and its ratio are increasing.

On the other hand, in the case of a fluidized bed boiler, when the fuel is changed, the ratio of air (primary air, secondary air) and injection amount according to the fuel properties are changed. In addition, the minimum required amount of air that must always be supplied during boiler operation must be recalculated.

That is, the circulating fluidized bed boiler preferably controls the direction of the operating conditions according to the result calculated by calculating the air distribution when the fuel is changed.

If the air distribution and injection amount are not properly changed according to the fuel change, the local temperature inside the combustion furnace will rise due to the occurrence of combustion non-uniformity. This results in lowering the overall combustion efficiency of the boiler.

Also, conventionally, when changing fuel, an experienced operator sets items based on temperature and pressure meter data acquired from the boiler and controls the boiler operation in such a way that the input value is changed.

Conventional techniques are limited to the physical boiler structure change and control method, such as changing the position of the open distribution nozzle for a specific fuel, changing the shape of the device, and precise control of air injection. Therefore, it is difficult to respond flexibly and quickly according to fuel changes.

In the case of a circulating fluidized bed boiler that can use various fuels, it is desirable to apply different air distribution rates according to fuels, injection, combustion and bottom ash treatment equipment, and minimum required air for stable operation.

There is a need for a guideline for stable boiler operation that can be flexibly and quickly respond to fuel changes by automatically calculating when fuel information is input and presenting an air distribution curve according to the boiler load.

US 10-1273311 B1 US 10-1273312 B1 US 10-1932458 B1 US 10-1580085 B1

The present invention is derived from such a technical background, and by automatically calculating the required air amount when fuel information is input and presenting an air distribution curve according to the boiler load, for stable boiler operation that can respond flexibly and quickly according to fuel changes. An object of the present invention is to provide a system and method for automatically calculating the air distribution of a fluidized bed boiler that can provide guidelines.

In addition, it is an object of the present invention to provide a system and method for automatically calculating the air distribution of a fluidized bed boiler, which can prevent the local temperature rise in the furnace from occurring due to the occurrence of combustion non-uniformity and further increase the overall combustion efficiency of the boiler.

The present invention for achieving the above object includes the following configuration.

That is, the automatic air distribution diagram calculation system of a fluidized bed boiler according to an embodiment of the present invention includes a ratio determining unit that determines the ratio of primary air and secondary air in the combustion chamber according to the type of fuel, and the minimum required for fuel injection according to the fuel injection method. and a graph generator for generating a boiler air distribution curve graph indicating an air injection amount for each boiler load by using an air amount calculator for calculating the air amount and the minimum required air amount calculated by the air amount calculator.

On the other hand, the automatic air distribution calculation method of a fluidized bed boiler performed in the automatic air distribution calculation system of a fluidized bed boiler includes the steps of determining the ratio of primary air to secondary air in the combustion chamber according to the type of fuel, and the method required for fuel injection according to the fuel injection method. Calculating a minimum required air amount, and generating a boiler air distribution curve graph indicating an air injection amount for each boiler load by using the calculated minimum required air amount.

According to the present invention, it is an automatic calculation algorithm that presents to the user (driver) a curve representing the air injection ratio for each fuel for each load of a fluidized bed boiler utilizing various fuels, based on the operation data collected from the pressure and thermometer when changing fuel. The effect of providing a system and method for automatically calculating the air distribution of a fluidized bed boiler that can provide a guide for stable combustion and load operation is derived compared to the existing operation method in which the driver judges and operates the operation.

In addition, by adjusting the air ratio essential for the creation of a stable combustion environment according to the characteristics of the fuel, the local temperature rise due to the agglomeration of the materials in the furnace is prevented, thereby increasing the efficiency through a uniform combustion temperature gradient throughout the furnace and the fluidized bed. It has the effect of contributing to securing the utilization rate of the boiler power plant.

1 is a block diagram showing the configuration of an automatic air distribution diagram calculation system of a fluidized bed boiler according to an embodiment of the present invention;
2 is an exemplary view of a boiler air distribution curve graph generated by a graph generating unit of an automatic air distribution diagram calculation system of a fluidized bed boiler according to an embodiment;
3 is a flowchart illustrating a method for automatically calculating an air distribution diagram of a fluidized bed boiler according to an embodiment of the present invention.

It should be noted that the technical terms used in the present invention are only used to describe specific embodiments, and are not intended to limit the present invention. In addition, the technical terms used in the present invention should be interpreted as meanings generally understood by those of ordinary skill in the art to which the present invention belongs, unless otherwise defined in particular in the present invention, and excessively comprehensive It should not be construed in the meaning of a human being or in an excessively reduced meaning.

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

1 is a block diagram illustrating the configuration of an automatic air distribution diagram calculation system of a fluidized bed boiler according to an embodiment of the present invention.

1 , the automatic air distribution diagram calculation system of a fluidized bed boiler according to an embodiment includes an information input unit 100, a ratio determination unit 110, an air quantity calculation unit 120, a graph generation unit 130, and an information providing unit ( 140).

The automatic air distribution diagram calculation system of the fluidized bed boiler according to an embodiment automatically calculates the air distribution rate according to the fuel, the amount of injected air for each injection, combustion and bottom ash processing device, and the minimum required air amount by inputting only fuel information for stable operation of the circulating fluidized bed boiler. calculated and provided. Specifically, it is possible to suggest guidelines for stable boiler operation by providing an air distribution curve according to the boiler load.

In one embodiment, the information input unit 100 receives the fuel type and properties for convenience of driving when changing fuel.

The ratio determining unit 110 determines the type of fuel using industrial analysis (fixed carbon content, volatile content), elemental analysis (oxygen), and high calorific value information of the fuel based on the information input to the information input unit 100 . And accordingly, the ratio of primary air and secondary air in the total combustion air to be supplied to the boiler is determined.

For the purpose of stabilizing the flame, promoting the mixing of fuel and air, and protecting the inner wall of the fuel chamber, the combustor often supplies air from multiple positions, but in this case, it is supplied from the position closest to the fuel outlet or The air that is mixed and led to the combustion chamber is called primary air. It is called secondary and tertiary air depending on the distance from the fuel outlet.

In the combustion of heavy oil, primary air may be used for atomization of fuel, or secondary air may be used for the purpose of accelerating mixing with fuel by vortexing.

In one aspect, the ratio determining unit 110 determines the ratio of primary air and secondary air in the total combustion air according to the fuel type, and further determines the upper and lower ratios of the secondary air.

The ratio determining unit 110 may determine the air ratio of the upper and lower portions of the secondary air (multi-stage combustion) based on the type of fuel and the volatile content in the fuel determined according to the first determined ratio of the primary air and the secondary air.

When the user selects a fuel injection method, the number of injection holes, and an injection hole diameter, the air amount calculation unit 120 automatically calculates the amount of air required for fuel injection at the rated output of the boiler.

In addition, the information providing unit 140 determines whether fuel injection air should be supplied from either the hot air passing through the air preheater, the cold air coming directly to the blower, or the primary and secondary air according to the calculation result in the air amount calculating unit 120 . You can provide information about the results.

In addition, the air amount calculation unit 120 is based on at least one of the initial start-up burner, the bottom ash processing facility, the number of limestone injectors, and the limestone supply amount input from the user to the information input unit 100. The cooling required at the rated output of each device. (Cooling), exhaust (Purging), exhaust (Drain), injection (Feeding) air volume is calculated.

The information providing unit 140 calculates the amount of cooling, purging, drain, and feeding air required for the rated output of the boiler calculated by the air quantity calculation unit 120 as secondary air, high-pressure air , and other results are provided by classifying them by air.

In addition, the air amount calculating unit 120 receives the input from the user to the information input unit 100 the total amount of combustion air to be injected at the rated output load of the boiler changed according to the change of fuel and the amount of high pressure air injected into the bubble heat exchanger. And based on the received air amount information, it is possible to calculate the ratio of primary air, secondary air, high-pressure air, fuel injection air, and other air in the total air at the rated output.

The air amount calculator 120 may determine whether the fuel injection air ratio is properly calculated based on the calculation result.

The air amount calculation unit 120 further calculates the minimum amount of air that must always be supplied when the boiler is operating regardless of the boiler load.

In one aspect, the air amount calculating unit 120 calculates the minimum amount of air that must always be supplied when the boiler is operating by reflecting the boiler lower grid value and the number of primary air nozzles.

When the user inputs the numerical value (Width × Depth) of the grid, the number of partition walls of the windbox and the number of installed primary air nozzles through the information input unit 100 Calculate the pressure drop across the grid, which is the distribution plate.

Conversely, it is also possible to calculate the number of primary air nozzles required in a specific pressure drop section. Therefore, the number of nozzles can be adjusted when operation is to be performed in a specific input section due to the constraint of operation or blower. The number of nozzles can be adjusted by blocking the nozzle's outlet or installing additional nozzles.

In addition, when the structural design value and number of secondary air nozzles are input, the air amount calculating unit 120 may determine whether air is injected at an appropriate injection rate and calculate the minimum required amount of air.

The graph generating unit 130 generates a boiler air distribution curve graph indicating the air injection amount for each boiler load by using the minimum required air amount calculated by the air amount calculating unit 120 . And the generated boiler air distribution curve graph is provided as visible data to the user through the information providing unit 140 .

2 is an exemplary diagram of a boiler air distribution curve graph generated by a graph generating unit of an automatic air distribution diagram calculation system of a fluidized bed boiler according to an embodiment.

As shown in FIG. 2 , the graph generating unit 130 shows the total amount of combustion air (%) for each boiler load (%). You can create an air distribution curve graph showing the total combustion air versus boiler load by air for primary air, secondary air bottom, secondary air top, high pressure air, and other air.

The information providing unit 140 is implemented as a display device and directly converts the boiler air distribution curve graph into visible data and outputs it, or is configured as a separate communication module and is a physically separated user terminal from the graph generating unit 130 . It is interpreted to cover all technical constructs that provide the generated boiler air distribution curve graph.

3 is a flowchart illustrating a method for automatically calculating an air distribution diagram of a fluidized bed boiler according to an embodiment of the present invention.

In one embodiment, the automatic air distribution diagram calculation system of the fluidized bed boiler includes a service platform for driving an application providing a user interface designed for convenience of operation when changing fuel of a circulating induction bed boiler.

As shown in FIG. 3 , the method for automatically calculating the air distribution of the fluidized bed boiler according to an embodiment determines the ratio of primary air to secondary air in the combustion chamber according to the type of fuel ( S300 ).

The type of fuel is determined using industrial analysis (fixed carbon content, volatile content), elemental analysis (oxygen), and high calorific value information of the fuel by receiving input from the user on the properties and type of fuel newly applied. It then determines the ratio of primary air to secondary air in the total combustion air that must be supplied to the boiler.

That is, the ratio of primary air and secondary air in the total combustion air is determined according to the fuel type, and the air ratio of the upper and lower portions of the secondary air (in the case of multi-stage combustion) is further determined ( S310 ).

In this case, the calculating of the amount of air includes receiving at least one of a fuel injection method, the number of injection holes, and an injection hole diameter from the user and automatically calculating the amount of air required for fuel injection at the rated output of the boiler.

And it gives the user the result whether the fuel injection air should be supplied: hot air past the air preheater or cold air coming directly to the blower, primary air or secondary air.

Cooling, Purging, Drain, and Injection required by the rated output of each device by receiving at least one of the number and limestone supply amount of the initial start-up burner, bottom ash treatment facility, and limestone injection device. (Feeding) It is possible to provide information by calculating the amount of air and classifying it by secondary air, high-pressure air, and other air.

That is, it is possible to calculate the fuel injection air amount, calculate the air amount of the initial start-up burner, calculate the air amount of our treatment facility, and calculate the limestone injection air amount to calculate the additional air ratio (S320).

After that, when the user inputs the total amount of combustion air to be injected at the rated output load of the boiler changed according to the change of fuel and the required high-pressure air to be injected into the bubble heat exchanger, etc., the primary and secondary air, high-pressure air, and fuel at the rated output It calculates and shows the proportion of the injected air and other air in the total air, and informs the user whether the fuel injection air ratio is properly calculated. Through this, it is possible to check the air ratio at the rated output (S330).

After that, the minimum amount of air supplied at all times during boiler operation is calculated by reflecting the number of the boiler lower grid and the number of primary air nozzles.

That is, the minimum amount of air required for fuel injection is calculated according to the fuel injection method ( S340 ).

This is the step of calculating the minimum amount of air that must always be supplied when the boiler is started regardless of the boiler load. To do this, input the number (Width × Depth) of the grid below the boiler, the number of bulkheads in the windbox, and the number of installed primary air nozzles to calculate the pressure drop across the grid, the boiler air distribution plate.

Conversely, since it is possible to calculate the number of primary air nozzles required in a specific pressure drop section, adjust the number of nozzles (mainly by blocking the nozzle outlet) when operation is required in a specific pressure section due to limitations of the operation or blower. or to install additional nozzles).

In addition, by inputting the structural design value and number of secondary air nozzles, it is possible to determine whether air is injected at an appropriate injection rate and calculate the minimum amount of air required.

A boiler air distribution curve graph indicating the air injection amount for each boiler load is generated using the calculated minimum required air amount (S350).

That is, it is possible to automatically plot the ratio of each air amount according to the boiler load as a curve as shown in FIG. 2 . Through this, the operator is provided with a guideline for the ratio of the injected air type for each boiler load and can perform stable boiler load fluctuation operation to improve the power plant utilization rate.

The above-described method may be implemented as an application or implemented in the form of program instructions that may be executed through various computer components and recorded in a computer-readable recording medium. The computer-readable recording medium may include program instructions, data files, data structures, etc. alone or in combination.

The program instructions recorded on the computer-readable recording medium are specially designed and configured for the present invention, and may be known and available to those skilled in the computer software field.

Examples of the computer-readable recording medium include a hard disk, a magnetic medium such as a floppy disk and a magnetic tape, an optical recording medium such as a CD-ROM and DVD, and a magneto-optical medium such as a floppy disk. media), and hardware devices specially configured to store and execute program instructions, such as ROM, RAM, flash memory, and the like.

Examples of program instructions include not only machine language codes such as those generated by a compiler, but also high-level language codes that can be executed by a computer using an interpreter or the like. The hardware device may be configured to operate as one or more software modules to perform processing according to the present invention, and vice versa.

Although the above has been described with reference to the embodiments, those skilled in the art will understand that various modifications and changes can be made to the present invention without departing from the spirit and scope of the present invention as set forth in the following claims. will be able

100: information input unit 110: ratio determining unit
120: air quantity calculating unit 130: graph generating unit
140: information providing unit

Claims (12)

a ratio determining unit for determining a ratio of primary air and secondary air in the combustion chamber according to the type of fuel;
an air amount calculation unit for calculating a minimum required air amount for fuel injection according to a fuel injection method; and
Automatic calculation system for air distribution of a fluidized bed boiler comprising a; a graph generating unit for generating a boiler air distribution curve graph indicating the air injection amount for each boiler load by using the minimum required air quantity calculated by the air quantity calculating unit. The method of claim 1,
The ratio determining unit,
Determines the ratio of primary air to secondary air in the total combustion air according to the type of fuel,
Automatic calculation system for air distribution of a fluidized bed boiler, characterized in that further determining the upper and lower proportions of the secondary air. The method of claim 1,
The air volume calculation unit,
An automatic calculation system for air distribution of a fluidized bed boiler, characterized in that it receives at least one of a fuel injection method, the number of injection holes, and an injection hole diameter, and calculates the amount of air required for fuel injection at the rated output of the boiler. 4. The method of claim 3,
The air volume calculation unit,
An automatic calculation system for air distribution of a fluidized bed boiler, characterized in that it calculates the amount of cooling, purging, drain, and feeding air required at the rated output of the boiler. 4. The method of claim 3,
The air volume calculation unit,
An automatic calculation system for air distribution of a fluidized bed boiler, characterized in that it receives at least one of the initial start-up burner, the bottom ash treatment facility, the number of limestone injection devices, and the limestone supply amount and calculates the amount of air required at the rated output of the boiler. The method of claim 1,
The air volume calculation unit,
An automatic calculation system for air distribution in a fluidized bed boiler, characterized in that it calculates the minimum amount of air supplied at all times during boiler operation by reflecting the boiler lower grid value and number of primary air nozzles In the automatic calculation method of the air distribution of the fluidized bed boiler performed in the automatic calculation system of the air distribution of the fluidized bed boiler,
determining a ratio of primary air to secondary air in the combustion chamber according to a fuel type;
calculating a minimum amount of air required for fuel injection according to a fuel injection method;
generating a boiler air distribution curve graph indicating an air injection amount for each boiler load using the calculated minimum required air amount; Automatic calculation method of air distribution diagram of a fluidized bed boiler comprising 8. The method of claim 7,
The step of determining the ratio is
Determines the ratio of primary air to secondary air in the total combustion air according to the type of fuel,
Automatic calculation method of air distribution of a fluidized bed boiler, characterized in that further determining the upper and lower proportions of the secondary air. 8. The method of claim 7,
The step of calculating the amount of air,
An automatic calculation method for air distribution in a fluidized bed boiler, characterized in that receiving at least one of a fuel injection method, the number of injection holes, and an injection hole diameter, and calculating the amount of air required for fuel injection at the rated output of the boiler. 10. The method of claim 9,
The step of calculating the amount of air,
An automatic calculation method for air distribution in a fluidized bed boiler, characterized in that the amount of cooling, purging, drain, and feeding air required at the rated output of the boiler is calculated. 10. The method of claim 9,
The step of calculating the amount of air,
An automatic calculation method for air distribution in a fluidized bed boiler, characterized in that the initial start burner, the bottom ash treatment facility, the number of limestone injection devices, and the limestone supply amount are input and the required air amount is calculated at the rated output of the boiler. 8. The method of claim 7,
The step of calculating the amount of air,
An automatic calculation method for air distribution in a fluidized bed boiler, characterized in that the minimum amount of air supplied at all times during boiler operation is calculated by reflecting the number of the lower grid of the boiler and the number of primary air nozzles.

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