JPH0731083B2 - Gas turbine combustor flame detection method - Google Patents

Description

Description: FIELD OF THE INVENTION The present invention relates to a flame detection method in a gas turbine combustor,
Particularly, the present invention relates to a method for selectively detecting only one flame when a diffusion flame and a premixed flame are present at the same time in a combustor, or when a bright flame and a non-flaming flame are simultaneously present. .

[Background of the Invention]

A flame radiates wave energy that produces heat rays and rays. About 90% of the total radiant energy in the case of oil combustion, about 95% in gas combustion
Belongs to the infrared region of invisible light and is used as heat. Energy in the ultraviolet region of short wavelength is 1% or less.
It should be noted that visible rays and infrared rays are also emitted from an object that is red-heated by the heat rays. A flame detector that detects a flame in a gas turbine combustor needs to distinguish between light emitted from this red-heated object (for example, a combustor inner cylinder) and light emitted from the combustion flame. Therefore,
The use of gas turbine flame detectors in the visible and infrared range results in loss of operational safety of the gas turbine. The detection methods of the flame detector according to the prior art are roughly classified into the following 6 methods.

(1) Bimetal method: Presence of combustion flame is detected by gas temperature.

(2) CdS cell method: The presence of flame is detected as a resistance change due to light.

(3) PbS cell method: The presence of flame is detected as a change in resistance value due to infrared rays.

(4) Photoelectric tube method: The presence of flame is detected as the amount of photoelectron emission of an object caused by light.

(5) Flame rod method: The existence of flame is detected as a current value even by utilizing its property as a conductor.

(6) Ultravision method: The presence of flame is detected as the amount of energy in the ultraviolet region only.

FIG. 1 shows the relative sensitivities by wavelength for these systems.
As the flame detection method in the gas turbine combustor, the ultravision method of the above item (6) is generally used (wavelength: 1900 to 2000Å). Fig. 2 shows the flame detection circuit in the gas turbine combustor conventionally used in this method. The flame existing in the combustor is directly sampled by the ultraviolet photoelectric tube 1 to become an electric signal, and then the flip-flop circuit 2 emits a rectangular wave. Then, it is converted into a DC signal by the wave conditioning circuit 3, integrated by the next integrating circuit 4, and guided to the flame presence / absence determination circuit 5, where the presence of flame is detected.

By the way, in recent years, the world's interest in environmental problems has been increasing, and the regulation value for NO _X in the exhaust gas discharged from the gas turbine to the atmosphere is becoming strict rather than the exception. In order along the bandwagon, companies have Kezutsu the surpassing the low NO _X reduction of the gas turbine combustor. As a result, the conventional single combustion system is replaced with the multiple combustion system. A typical example is
In combination with diffusion combustion and premixed combustion is a low NO _X combustor.
Therefore, a diffusion flame and a premixed flame (or a bright flame and a non-flaming flame) simultaneously exist in the combustor, but the ignition timing of the flame is different due to the optimization of NO _X control. In this case, one of the two flames is present, and it is necessary to confirm the establishment of the other flame in this state.
The gas turbine combustor is made compact due to the constraints of high heat capacity and miniaturization, and since both flames are mixed, the prior art is affected by one flame and the recognition of the establishment of the other flame is recognized. Can not.

[Object of the Invention]

The present invention eliminates the above-mentioned drawbacks and also has the same function as that of the conventional flame detection circuit. Therefore, a gas turbine combustor in which a diffusion flame and a premixed flame, or a bright flame and a non-flame flame simultaneously exist , Either one of the flames (for example,
It is to provide a flame detection method capable of selectively detecting only premixed flames.

[Outline of Invention]

The gist of the present invention is that when two types of flames having different combustion characteristics (diffusion flame and premixed flame, or bright flame and non-flaming flame) are present in the gas turbine combustor at the same time, Emission wavelength (3000 Å ~ 6000 Å) of single or multiple chemical species (for example, OH, CN, CH, C ₂ etc.) that has characteristic
Focusing only on this, we devised a method that can selectively detect one of the flames by monitoring the change over time of the integrated value of the emission intensity, the emission intensity value for each wavelength, or both. That is what I did.

The gas turbine combustor internal flame detection method of the present invention is a premixing generated by premixing and burning air and fuel after a diffusion flame generated by diffusing combustion of air and combustion is formed. It detects the presence of a flame in a gas turbine combustor in which a flame is formed, monitors the flame in the gas turbine combustor, and measures the emission intensity of a specific chemical species with respect to wavelength over time to obtain diffusion. The measurement results are filtered by an interference filter that transmits a wavelength characteristic of the flame and an interference filter that transmits a wavelength characteristic of the premixed flame, and the establishment of the premixed flame is detected.

Example of Invention

In a gas turbine low NO _X combustor that achieves low NO _X by distributing diffusion flame and pre-mixed flame, chemical species (OH, CN, CH, CH, C
Typical characteristic example of wavelength and emission intensity of ₂₎ in Figure 3, also illustrates the chemical species diffusion flame (OH, CH, representative characteristic of the wavelength and the emission intensity of C ₂₎ in Figure 4. Comparing FIG. 3 and FIG. 4, it can be seen that the premixed flame has the characteristics in the CN having the wavelength of 3880Å, and the diffusion flame has the characteristics in the C ₂ having the wavelength of 5160Å. Therefore, the presence of the flame can be detected by monitoring the emission intensity of the chemical species. 5th against the above premixed flame
By filtering with an interference filter having the transmittance as shown in the figure, the emission characteristics shown in FIG. 6 can be obtained.
On the contrary, when the diffusion flame is filtered by the interference filter as shown in FIG. 7, the emission characteristic shown in FIG. 8 is obtained.
When comparing bright flames and non-flaming flames, the most distinguishing feature is that bright flames have luminescent properties emitted from C ₂ species with a wavelength of 5160Å, which is close to visible light. That's what it means. Figure 9 shows the typical emission characteristics of a bright flame, and Figure 10 shows the typical emission characteristics of a nonflaming flame. Therefore, 51 against the bright flame
The use of an interference filter with maximum transmittance near 60Å makes it possible to detect the presence of bright flames. By applying this method, it is possible to detect one of the flames having different emission characteristics. Fig. 11 shows a typical structural diagram of a low NO _X combustor for natural gas firing. Combustor inner cylinder 16
Is disposed inside the combustor caging 20, the outer cylinder 21, and the front cover 22, and the head combustion chamber 17, the rear combustion chamber 18, and the cone 23 are disposed.
And has a primary fuel nozzle 24 and a secondary fuel nozzle 25 as combustion nozzles, and has a flame characteristic that the primary flame is a diffusion flame,
The secondary flame becomes a premixed flame. As a flame detector, a frame sampling head (an optical lens and an optical fiber, and if necessary, a cooling mechanism) is provided at the rear of the outer cylinder 21.
6 is installed and the optical fiber 13 is connected. The installation location of the flame detector is an example, and is not limited to this position. Combustor for optimization of the NO _X control, 12
The fuel control shown in the figure is performed. The primary fuel F ₁ is injected at a gas turbine speed of 20%, ignited by a spark plug, and operated up to a gas turbine load of 25%. The length of this primary flame differs depending on the combustion state, and the flame exists up to the wake side. When the gas turbine load is 25%, the secondary fuel F ₂ is charged, heated by the primary flame to a temperature higher than the self-ignition temperature, and ignited. The establishment of this secondary flame (premixed flame) is detected by the present invention. First
A typical example of the flame detection circuit in the gas turbine combustor according to the present invention is shown in FIGS. 13, 14 and 15. In FIG. 13, the light beam is sampled by the flame flame sampling head 6, and the relevant light beam is introduced into the interference filter 7 through the optical fiber 13. The interference filter 7 has a wavelength 3880 of the chemical species CN characteristically possessed by the secondary flame (premixed flame).
It has the function of transmitting only the light ray of Å, and transmits only the light ray necessary for selective flame detection to the wake. The filtered light beam passes through the optical fiber 13 (note that it is not always necessary to pass through the optical fiber), is guided to the light receiver 8, and is converted into an electric signal 14. This signal 14 is applied to the amplifier 9
And the integrated amount is integrated by the integrator circuit 10, and then the integrated amount is monitored by the elapsed time judgment circuit 11 over time and compared with the set value. The monitoring function of the judgment circuit 11 over time is shown in FIG. This embodiment has a function of detecting the secondary flame f ₂ (premixed flame) generated by the secondary fuel F ₂ , and has a wavelength of 3880Å generated by the establishment of the secondary flame after ignition time t ₀ seconds. The light emission intensity integrated amount of is compared with the set value, and a flame detection signal is emitted at time t ₁ when the set value is exceeded. This electric signal 14 is transmitted to the flame presence / absence determination circuit 12, and the presence / absence of flame is determined.

In FIG. 14, the electric signal 14 processed in the same manner as in FIG.
Enters the determination circuit 15 for each wavelength from the amplifier 9 and monitors the emission intensity (emission intensity of wavelength 3880Å in this embodiment) for each wavelength and compares it with the set value. The monitoring function of the wavelength-specific judgment circuit 15 is shown in FIG. In the present embodiment has a function for detecting the secondary flame f _2, it is compared with a set value the emission intensity values that occur in the secondary flame f ₂ after establishment, when it exceeds the set value, the flame detection Emit a signal. This electric signal 14 is transmitted to the flame presence / absence determination circuit 12, and the presence / absence of flame is determined.

FIG. 15 shows a flame detection circuit in which the reliability of flame detection is improved by using both circuits described in FIGS. 13 and 14. It is also possible to selectively detect only the primary flame (diffusion flame) by the same method and circuit (monitor the ray of wavelength 5160Å of the chemical species C ₂ ).
Also, in a gas turbine combustor in which a bright flame and a non-flaming flame are present at the same time, the method and circuit for selectively detecting only one of them are also the same.

〔The invention's effect〕

Low NO _X reduction can be achieved by the allocation of the diffusion flame and the premixed flame. Not gas turbine low NO _X combustor only, in the gas turbine combustor luminous flame and non luminous flame is present at the same time, it is possible to detect only one of the flame which require selective, gas It has the effect of dramatically improving the safety of turbine operation.

[Brief description of drawings]

FIG. 1 is a characteristic diagram showing the relative sensitivity of various flame detectors of the prior art to each wavelength, FIG. 2 is a conventional flame detection circuit diagram of a gas turbine combustor flame, and FIG. 3 is a diagram of a premixed flame. Typical characteristics chart of each wavelength and luminescence intensity of the chemical species possessed, Fig. 4 is a typical characteristics chart of each wavelength and luminescence intensity of the chemical species possessed by the diffusion flame, and Fig. 5 is an interference filter used for premixed flame detection FIG. 6 is a characteristic diagram showing the relationship between the wavelength of light rays filtered by the interference filter and the emission intensity. FIG. 7 is a transmittance characteristic diagram of the interference filter used for the diffusion flame. The figure is a characteristic diagram showing the relationship between the wavelength and the emission intensity of the light rays filtered by the interference filter.
FIG. 9 is a typical characteristic diagram of wavelengths and luminescence intensities of the chemical species possessed by the luminous flame, FIG. 10 is a typical characteristic diagram of respective wavelengths and luminescence intensity of the chemical species possessed by the flame retardant, and FIG. 11 is a representative. Fig. 12 is a cross-sectional view showing the structure of a typical low NO _X combustor, Fig. 12 is a fuel control schedule diagram of a typical low NO _X combustor, and Figs. 13, 14, and 15 are gases according to the present invention. FIG. 16 is a block diagram of the flame detection circuit in the turbine combustor, FIG. 16 is an operation explanatory diagram of the temporal determination circuit according to the present invention, and FIG. 17 is an operation explanatory diagram of the wavelength-based determination circuit according to the present invention. 6 ... Frame sampling head, 7 ... Interference filter, 8 ... Photoreceiver, 9 ... Amplifier, 10 ... Integration circuit, 11
…… Judgment circuit, 16 …… Inner cylinder, 17 …… Head combustion chamber, 18 ……
Rear combustion chamber, 24 …… Primary fuel nozzle, 25 …… Secondary combustion nozzle.

Claims (1)

[Claims] Claim: What is claimed is: 1. A gas turbine combustion system in which a diffusion flame generated by diffusing combustion of air and combustion is formed, and then a premixed flame generated by premixing and burning air and fuel is formed. A method for detecting flame in a gas turbine combustor for detecting the presence of a flame in a furnace, wherein the flame in the gas turbine combustor is monitored and the emission intensity of a specific chemical species with respect to wavelength is measured over time, and An interference filter that transmits a wavelength characteristic of a diffusion flame and an interference filter that transmits a wavelength characteristic of the premixed flame are used to filter the measurement result, and the establishment of the premixed flame is detected. Gas turbine combustor flame detection method.