KR100798023B1 - Apparatus for controlling multistaged combustion system - Google Patents

Abstract

The present invention relates to a control device for a multi-stage air supply combustion system that can maintain the optimum operating state by adjusting the flow rate of the air supply system to grasp the state of the flame and reduce the emissions of carbon monoxide and nitrogen oxides. The control system according to the present invention comprises: a plurality of air flow rate and fuel flow control solenoid valves for respectively regulating the flow rate of air and fuel at a constant pressure supplied to the combustor at each stage by a burner; An air and fuel flow measurement unit having an air flow meter and a fuel flow meter for measuring and converting the air flow rate adjusted by the flow control solenoid valves into an electrical signal; Concentrates the chemiluminescence energy of OH and CH C ₂ , which are intermediate products of carbon monoxide and nitrogen oxide, generated in the flame of each burner of the burner, and selects only the luminescence energy in the wavelength band of OH and CH C ₂ among the emission energy emitted from the flame. After passing through the optical measuring unit for measuring and converting it to an electrical signal; From the strength of the electrical signals, the current state of the flame is grasped and displayed in real time, the state of carbon monoxide and nitrogen oxides in the exhaust gas is determined, and the air flow rate is controlled to adjust the air flow rate supplied to the combustion apparatus of each stage from the determination. And a control unit for controlling the opening degree of the solenoid.

Multistage Combustion Device, Burner, Air Flow Control, Condenser, Spectroscope

Description

Apparatus for controlling multistaged combustion system

1 is a schematic block diagram of a control device of a multistage air supply combustion system according to the present invention;

2 is a view showing a control process of the control device of the multi-stage air supply combustion system according to the present invention.

3 is a plan view of a multi-stage air supply combustion device used in the control device of the multi-stage air supply combustion system according to the present invention.

4 is a rear view of the multistage air supply combustion device shown in FIG.

5a schematically shows a light collecting device for use in a control device of a multistage air supply combustion system according to the present invention;

5b schematically illustrates another type of light collecting device for use in a control device of a multistage air supply combustion system according to the present invention;

6 schematically shows a spectroscopic device for use in a control device of a multistage air feed combustion system according to the present invention.

7 is a graph showing the relationship between chemiluminescence intensity according to the equivalent ratio of OH, CH, and C ₂ in exhaust gas.

(Explanation of symbols for the main parts of the drawing)

1: burner 2: air and fuel flow measurement unit

3: optical measuring unit 4: control unit

5: nozzle 6: air supply

7: fuel supply source 8a, 8b, 8c: air flow control solenoid valve

9: fuel flow control solenoid valve

10a, 10b, 10c: air flow meter 11: data collector

12: fuel flow meter 13, 13a, 13b: light collecting device

14 spectrometer 15 air flow control unit

16: ultraviolet lens 17, 22: band pass filter

18, 23: photomultiplier tube 19: collimator lens

20: optical fiber 21: dichroic mirror

24: control logic

The present invention relates to a control device of a multi-stage air supply combustion system, and more particularly, to measure the chemiluminescence energy (radiation energy) of OH, CH, and C ₂ , which are intermediate products of carbon monoxide and nitrogen oxides generated from a flame, A control device for a multistage air supply combustion system for minimizing pollutants in exhaust gases by predicting nitrogen oxides.

In general, a multi-stage air-supply combustion system is divided into several combustion stages, in which fuel and air are supplied at each stage, and oxygen in the combustion gas in a combustion facility equipped with a Proportional Integrate Derivative (PID) controller to control the oxygen concentration at each stage. When controlling the concentration, each PID controller is provided with an air ratio regulator to feed back the oxygen concentration measured by the oxygen concentration measuring device installed in the year so that the PID controller can be reduced to reduce the error between the oxygen concentration setting value and the measured value. By operating the air ratio controller to adjust the air fuel ratio set value, by adjusting the air flow rate to extract the oxygen concentration.

Korean Patent Registration No. 10-0328951 proposes a method for optimal combustion by measuring oxygen concentration in combustion gas, and US Patent No. 5,480,298 uses OH radiation energy of flame to reduce nitrogen oxides in exhaust gas. The method of measuring and measuring temperature is used.

In addition, as a control mentioned in the conventional multi-stage air supply combustion system, there is a method in which the operator directly controls the flame by visually checking the visible shape or color of the flame or changes the operating conditions by measuring the exhaust gas directly by the operator. .

However, although the conventional technique is measured through a measuring device, since it is an open loop control rather than a feedback control, a lot of time, labor, fuel and the like are consumed. And the operator's direct determination of the operating conditions of the combustion system by visualizing the state of the flame cannot ignore the operator's visible errors and cannot adapt to sudden changes in the external environment. However, the biggest problem than this disadvantage is that it is difficult to control in real time.

Accordingly, an object of the present invention is to provide a control device of a multi-stage air supply combustion system that can maintain the optimum operating state by adjusting the flow rate of the air supply system to determine the current flame condition and reduce the emissions of carbon monoxide and nitrogen oxides. have.

The object as described above comprises: a plurality of air flow rate and fuel flow control solenoid valves each regulating the flow rate of air and fuel at a constant pressure supplied to the combustor at each stage to a burner; An air and fuel flow rate measurement unit having an air flow rate meter and a fuel flow rate meter for measuring and converting the air flow rate adjusted by the flow rate control solenoid valves into electric signals; Concentrates the chemiluminescence energy of OH and CH C ₂ , which are intermediate products of carbon monoxide and nitrogen oxide, generated in the flame of each burner of the burner, and selects only the luminescence energy in the wavelength band of OH and CH C ₂ among the emission energy emitted from the flame. An optical measuring unit including a spectroscope for measuring the spectrum of the emitted light and a light concentrating device for measuring the light emission energy and converting the light signal into electrical signals after passing through the light; From the intensity of the electrical signals, the current state of the flame is identified and displayed in real time, the state of carbon monoxide and nitrogen oxides in the exhaust gas is determined, and the air is adjusted to adjust the air flow rate supplied to the combustion apparatus of each stage from the determination. A control unit for controlling the opening degree of the flow control solenoid; It can be achieved by the control device of the multistage air supply combustion system according to the invention, characterized in that it is carried out repeatedly through continuous feedback control to select the optimum flame state and drive the combustion device in this state.

In the above, the optical measuring unit includes three light collecting devices arranged to focus on the axial center position of the turbulent flame in front of the outlet of the burner.

Each of the light collecting devices directly directs the light of the flame at the burner, and has a lens for focusing, a band pass filter having a wavelength band corresponding to the wavelength band of OH, CH, and C _{2 in} the flame, and emitting energy as an electrical signal. A photodiode or photomultiplier tube is provided.

The light collecting device has an ultraviolet lens which is focused on the optical fiber by directing the light of the flame in the burner.

The spectrometer includes three dichroic mirrors for spectroscopically reflecting light of a specified wavelength band, and only the emission energy of a wavelength band corresponding to the wavelength band of OH, CH, C ₂ from the light spectroscopy by each dichroic mirror. Three band pass filters passing through, and a plurality of photodiodes or photomultipliers for converting the emission energy of the OH, CH, C ₂ wavelength bands into electrical energy by the band pass filter.

The control unit is a data collector for inputting the electrical signal transmitted from the air and fuel flow rate measuring unit and the optical measuring unit, a program for processing the electrical signal transmitted from the data collection unit to determine the current state of the flame and cope with Stored control logic, and an air flow rate control for controlling the air flow rate control solenoid valves to vary the air flow rate supplied to each combustor stage of a burner.

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

1 is a schematic block diagram of an apparatus for performing a control apparatus of a multistage air supply combustion system according to the present invention.

As shown in Figure 1, the control unit for performing the control device of the multi-stage air supply combustion system according to the present invention is an air and fuel flow rate measuring unit (2) for measuring the flow rate of air and fuel supplied to the burner (1) Input from the optical measuring unit 3 for measuring the chemiluminescence energy of OH and CH C ₂ generated in the flame generated from the burner 1, and the air and fuel flow rate measuring unit 2 and the optical measuring unit 3. And a control section 4 for controlling the flame of the burner 1 in accordance with the electrical signal.

The burner 1 has a three stage multistage combustor, as shown in FIGS. 3 and 4, in which fuel supplied from the fuel supply 7 is injected from a centrally arranged nozzle 5, while combustion of each stage is performed. Air is supplied from the air supply device 6, such as a blower, to a furnace, respectively. The air supplied from the air supply device 6 is supplied to the burner 1 by adjusting the flow rate by the respective air flow control solenoid valves 8a, 8b, 8c, and the fuel is also supplied to the fuel flow control valve 9 Thereby, it is supplied to the burner 1 in the state in which the flow volume was adjusted.

As shown in FIG. 4, each combustor is provided with a turbulence, and the turbulence flame is generated in each combustor by the turbulence. For example, the vortex angle in the first stage combustor may be set to 60 degrees, 45 degrees in the second stage, and 30 degrees in the third stage. The vortex angle in each of these combustors can vary depending on the air flow rate supplied. Therefore, when the flow rate supplied changes, since the total vortex of the burner 1 changes, the flame state of the burner 1 will change.

The air generated from the air supply device 6 is regulated to a constant pressure by a regulator (not shown), and the flow rate is controlled by the air flow control solenoid valves 8a, 8b, and 8c installed in each air supply line. The air flow rate supplied to the combustor of each stage of the burner 1 in the adjusted state, and the air flow rate supplied to the combustor of each stage of the burner 1 are the air which comprises the air and fuel flow measurement part 2 so that an air flow rate may be measured. It is measured by the flow meters 10a, 10b, and 10c. The flow rate of air initially measured by the flow meters 10a, 10b, and 10c is transmitted to the data collection unit 11 provided in the control unit 4 as an electric signal of 4-20 kV.

On the other hand, the flow rate of the fuel supplied from the fuel supply source 7 to the burner 1 is also adjusted by the regulator like the air, and the flow rate of the fuel supplied to the burner 1 is controlled by the fuel flow meter 12. Is measured. This fuel flow control is made by the fuel flow control solenoid valve 9. Similar to the air measurement, the flow rate measured by the fuel flow meter 12 is also converted into an electric signal of 4 to 20 kV and transmitted to the data collection unit 11 of the control unit 4. The flow rate of the fuel supplied to the burner 1 may be initially set according to the load of the burner 1, so that a constant flow rate of fuel can be continuously supplied to the burner 1.

The optical measuring unit 3 measures the light emission energy from the flame of the burner 1 and measures the light concentrating device 13 and / or the spectrum of the collected light energy for measuring the light emission energy using a 300 mm lens. The spectrometer 14 is included. The optical measuring unit 3 is provided such that the light collecting device 13 focuses on the axial center position of the turbulent flame at the front end of the outlet of the burner 1. The light collecting device 13 may use a light collecting device 13a using a photodiode or a photo multiplier tube (PMT) or a light collecting device 13b using an optical fiber as shown in FIGS. 5A and 5B. .

Three light collecting devices 13a are used, and the ultraviolet light 16, which is focused on the flame and the photodiode or the photomultiplier tube (PMT) or the optical fiber by directing the light of the flame in the burner 1, And a band pass filter 17 having a wavelength band corresponding to the wavelength band of OH, CH, and C ₂ , and a photodiode or photomultiplier tube 18 for converting light emission energy into an electrical signal. In the light collecting device 13a, the light emission energy of OH, CH, and C ₂ generated in the flame is collected by the ultraviolet lens 16, and light of different wavelengths is removed by the band pass filter 17, so that the OH in the flame Only light corresponding to each of the wavelength bands CH, C, and C ₂ passes through the band pass filter 17.

In the case of the light collecting device 13a, the light energy passing through the band pass filter 17 is converted into direct light through the collimator lens 19 in front of the photodiode or photomultiplier tube 18 so as to fit the measurement area plane, and the direct light The light is converted into electrical energy through a photodiode or photomultiplier tube 18. The electrical signals converted from the luminous energy by the photodiode or photomultiplier tube 18 of the respective light collecting devices 13 are transmitted to the data collection unit 11 of the control unit 4.

In the case of the light collecting device 13b shown in FIG. 5B, one light collecting device is used in the present invention, and the ultraviolet lens 16 focused on the optical fiber 20 by directing the light of the flame in the burner 1 is used. Equipped. The luminous energy focused on the optical fiber 20 is sent to the spectrometer 14 shown in FIG. On the other hand, the use of the optical fiber in the light converging device 13b shown in FIG. 5B is to remove the limitation depending on the position.

The spectrometer 14 has three dichroic mirrors 21 (DM) for spectroscopically reflecting light of a specified wavelength band and OH, CH, C from the light spectroscopy by each dichroic mirror 21. Three band pass filters 22 which pass only the emission energy of the wavelength band corresponding to the wavelength band of ₂ and the band pass filter 22 convert the emission energy of the OH, CH, and C ₂ wavelength bands into electrical energy. And a plurality of photodiodes or photomultiplier tubes 23 for the purpose of the present invention. These dichroic mirrors 21, band pass filters 22 and photodiodes or photomultipliers 23 are configured to be housed in one box for miniaturization.

The luminescence energy transmitted to the optical fiber through the light collecting device 13b is spectroscopically in three directions as shown in FIG. 6 by three dichroic mirrors 21 accommodated in the spectrometer 14. By means of the three dichroic mirrors 21, the light passes through the band pass filter 22, where only energy corresponding to the respective wavelength bands of OH, CH and C ₂ passes through the band pass filter 22. do. Light passing through the band pass filter 22 is converted into an electrical signal while passing through three photodiodes or photomultiplier tubes 23, and the electrical signal is sent to the data collection unit 11 of the control unit 4.

As described above, the optical measuring section 3 used in the apparatus for performing the control device of the multistage air supply combustion system according to the present invention has been described in two forms. That is, the first is to send an electrical signal converted from the luminous energy directly to the data collection unit 11 of the control unit 4 by using three light collecting devices 13a using a port diode or a photomultiplier tube, and the other one. The luminous energy is transmitted to the spectrometer 14 through the optical fiber 20 by using one light collecting device 13b that uses an optical fiber, and then the light is decomposed by the spectroscope 14 to decompose the photodiode or the photomultiplier tube. By using the 23, the light emission energy is converted into an electrical signal and transferred to the data collection unit 11 of the controller 4.

As shown in FIG. 1, the control unit 4 processes an electrical signal, a data collection unit 11 to which an electrical signal transmitted from the air and fuel flow rate measuring unit 2 and the optical measuring unit 4 is input, Controlling the air flow control solenoid valves 8a, 8b, 8c to change the flow of air supplied to each combustor stage of the burner 1, and the control logic 24 having stored therein a program capable of identifying and coping with the current state. It includes an air flow control unit 15 for.

The data collection unit 11 into which the electrical signals are input processes the electrical signals input from the air and fuel flow rate measuring unit 2 and the optical measuring unit 3 and transmits them to the control logic 24. The control logic 24 displays the input electrical signal in real time, and determines the emissions of carbon monoxide and nitrogen oxide using the stored data and the input electrical signal.

The control logic 24 determines the amounts of carbon monoxide and nitrogen oxides in the exhaust gas by using the strengths of the electrical signals of OH, CH, and C ₂ transmitted from the data collection unit 11. The control logic 24 grasps the state of the current flame by the determined value, and in order to optimize the flame state, the air flow control solenoid valve 8a based on the air flow rate supplied to each combustor stage of the current burner 1. By controlling the opening degree of 8b and 8c, the air flow rate supplied to the combustor of each stage of the burner 1 is controlled. This control measures the flow rate of air supplied to each combustor stage of the burner 1 and the emission energy of the flame through the closed loop control (feedback control) as shown in FIG. Change the operating conditions of 1) to make the optimum flame state.

[Table 1] shows the wavelengths of OH, CH, and C _{2. In} the apparatus for performing the control device of the multistage air supply combustion system according to the present invention, each of the OH, CH, C ₂ Only measure the light intensity. This light intensity has a characteristic according to the change in the equivalent ratio as can be seen in the graph of FIG. From this, it shows that the light intensity of each OH, CH, C ₂ increases as the equivalent ratio increases.

OH CH C ₂ Wavelength (λ) 282.9 nm 387.1 nm 516.5 nm 308.9 nm 431.4 nm

That is, the equivalent ratio of OH, CH, and C ₂ of the flame can be calculated using FIG. 7. In addition, by detecting the nitrogen oxide and carbon monoxide emission concentration for each air in the combustor of each stage for each equivalence ratio, the data to determine the increase and decrease state of nitrogen oxide and carbon monoxide according to the increase in the light intensity of each OH, CH, C ₂ . Through this result, the flame state by the optical measuring unit 3 can be grasped. This makes it possible to obtain information immediately after combustion, so that faster and more accurate information can be obtained than the flame information obtained only through the conventional exhaust gas after combustion.

The amount of carbon monoxide and nitrogen oxides predicted above gives the electric signal to the electric valve of the air supply unit through the air supply controller to control the air flow at each stage through the air supply controller to determine the current flame state and to make the optimum flame state. To change the state.

Through the process as described above, the burner 1 maintains an optimum flame and, in response to the change of the flame of the burner 1 due to a sudden change in the external environment, in response to this change, the burner ( The optimum operating condition of 1) is detected and the optimum operating state of the burner 1 is maintained even in a new condition.

As described above, the control device of the multi-stage air supply combustion system according to the present invention passes the sensor by sucking the exhaust gas of the conventional mechanical proportional control or the combustion chamber rear, to determine the current burner state by measuring the oxygen concentration, Compared to a device that controls the air-fuel ratio of the combustion system, the self-luminescence of the flame is measured. Therefore, the response speed is faster and real-time control is possible. In addition to controlling the air-fuel ratio, the combustion reaction state of the flame to be controlled is directly measured and diagnosed to reduce carbon monoxide and nitrogen oxide simultaneously, and the flame state is controlled to optimize the system efficiency through the air-fuel ratio control. high. In addition, even if the surrounding conditions change, it immediately reacts to the optimum operating state again.

As can be seen from the above, the present invention can be applied to various types of combustion systems such as boilers and gas turbines as well as multi-stage air supply combustion systems, and it is possible to improve the energy efficiency of combustion systems and at the same time nitrogen oxides and carbon monoxide, etc. Will greatly contribute to the reduction of pollutants. In addition, the energy efficiency of the combustion system can be improved to reduce energy costs and reduce costs, and furthermore, automation of the combustion system performance measurement system can be achieved, thereby reducing manpower and time.

Claims (9)

A plurality of air flow rate and fuel flow control solenoid valves each having a combustor having a plurality of stages in the burner and regulating a flow rate of air and fuel at a predetermined pressure supplied to the combustors of each stage; An air and fuel flow rate measuring unit having an air flow rate meter measuring the air flow rate adjusted by the flow control solenoid valves and converting the air flow rate into an electrical signal and a fuel flow rate meter measuring and converting the fuel flow rate into an electrical signal; Concentrates the chemiluminescence energy of OH and CH C ₂ , which are intermediate products of carbon monoxide and nitrogen oxide, generated in the flame of each burner of the burner, and selects only the luminescence energy in the wavelength band of OH and CH C ₂ among the emission energy emitted from the flame. An optical measuring unit including a light collecting device for measuring the light emission energy and a spectroscope for measuring the spectrum of the light emission energy collected after the light beam is passed through the light source and measured and converted into an electric signal; From the intensity of the electrical signals, the current state of the flame is grasped and displayed in real time, the state of carbon monoxide and nitrogen oxides in the exhaust gas is determined, and the air flow rate is adjusted to adjust the air flow rate supplied to the combustor of each stage from the determination. A control unit for controlling the opening degree of the control solenoid; Through continuous feedback control, it continuously measures the flow rate of air supplied to the combustor of each stage of the burner and the emission energy of flame, and selects the optimum flame state according to the measurement result and operates the combustor in this state. Control device of a multi-stage air supply combustion system. The control apparatus of claim 1, wherein the optical measuring unit comprises three light collecting devices arranged to focus on an axial center position of the turbulent flame in front of the outlet of the burner. 3. The light collecting device of claim 2, wherein the light collecting device includes any one of a band pass filter having a wavelength band corresponding to a wavelength band of OH, CH, and C ₂ in a flame, and a photodiode or a photomultiplier tube for converting light emission energy into an electrical signal. Control device for a multi-stage air supply combustion system characterized in that it comprises a. delete delete 4. The control device of a multistage air supply combustion system as recited in claim 3, wherein said light collecting device includes an ultraviolet lens which is focused on an optical fiber by directing the light of flame in a burner. 2. The spectrometer according to claim 1, wherein the spectroscope corresponds to three dichroic mirrors for spectroscopically reflecting light of a specified wavelength band and corresponding to a wavelength band of OH, CH, C ₂ from light spectroscopy by each dichroic mirror. Three band pass filters for passing only the emission energy of the wavelength band, and a plurality of photodiodes for converting the emission energy of the wavelength band of OH, CH, C ₂ into electrical energy by the band pass filter Control device of a multi-stage air supply combustion system. 2. The spectrometer according to claim 1, wherein the spectroscope corresponds to three dichroic mirrors for spectroscopically reflecting light of a specified wavelength band and corresponding to a wavelength band of OH, CH, C ₂ from light spectroscopy by each dichroic mirror. Three band pass filters for passing only the emission energy of the wavelength band, and a plurality of photomultipliers for converting the emission energy of the wavelength band of OH, CH, C ₂ into electrical energy by the band pass filter. Control device of a multistage air supply combustion system. delete

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