EP1429002A2 - Method and device for affecting thermoacoustic oscillations in combustion systems - Google Patents

Abstract

A flow of gas (FOG) near a burner (6) is subjected to acoustic stimulation. This modulates the injection of fuel. The acoustic stimulation of the FOG and the modulated fuel injection are tuned to the affects from the same interference frequency. A measured signal is subjected to a first phase shift to generate a first driver signal that triggers an acoustic source (3) to stimulate the FOG. An Independent claim is also included for a device for affecting thermoacoustic vibrations in a combustion system.

Description

Technical field

The invention relates to a method and a device for influencing thermoacoustic vibrations in a combustion system with at least a burner and at least one combustion chamber with the features of Preamble of claim 1 and with the features of the preamble of Claim 7.

State of the art

It is known that undesired thermoacoustic vibrations often occur in the combustion chambers of gas turbines. The term "thermoacoustic vibrations" denotes mutually rocking thermal and acoustic disturbances. High vibration amplitudes can occur, which can lead to undesirable effects, such as a high mechanical load on the combustion chamber, an increased NO _x emission due to inhomogeneous combustion and even an extinguishing of the flame. This is especially true for combustion systems with low acoustic damping. In order to ensure high performance in terms of pulsations and emissions over a wide operating range, active control of the combustion vibrations may be necessary.

In order to achieve particularly low NO _x emissions, an increasing proportion of the air is passed through the burners themselves in modern gas turbines and the cooling air flow is reduced. Since, in conventional combustion chambers, the cooling air flowing into the combustion chamber has a sound-absorbing effect and thus contributes to damping thermoacoustic vibrations, the abovementioned measures to reduce the NO _x emissions reduce the sound damping.

From EP 0 918 152 A1 it is known thermoacoustic vibrations by influencing that the developing in the area of the burner Shear layer is acoustically excited.

From EP 0 985 810 A1 it is known thermoacoustic vibrations to influence that a liquid or gaseous injection Fuel modulated.

The known devices and methods are each for influencing one specific interference frequency of the thermoacoustic vibrations. at However, certain applications can also use vibration systems several interference frequencies occur, it being possible in particular that the Reduction of the disruptive effect of a main interference frequency the disruptive effect a secondary interference frequency amplified.

Presentation of the invention

This is where the invention comes in. The present invention is concerned with Problem, a way to improve the influence of thermoacoustic To show vibrations in a combustion system, in particular influencing thermoacoustic vibrations with two or more Interference frequencies should be made possible.

This problem is solved by the subject matter of the invention independent claims solved. Advantageous embodiments are Subject of the dependent claims.

The invention is based on the general idea of multiple interference frequencies to influence the thermoacoustic vibrations separately. hereby can have adverse interactions in fighting one Interference frequency can cause an amplification of the other interference frequency, be reduced or eliminated. It has been shown that through the Procedure according to the invention at least the attenuation of the main interference frequency can be significantly strengthened.

According to an advantageous embodiment, two interference frequencies exclusively through acoustic excitation of the gas flow with vibrations different phases and / or amplitudes can be influenced. At this Embodiment can influence two interference frequencies on one modulated injection can be dispensed with. Influencing the Thereby, thermal-acoustic vibrations are mainly acoustic Path.

In an alternative development, two interference frequencies can only through modulated injection of the fuel with injection modulations different injection times and / or injection quantities are influenced. in the Difference to the variant mentioned above can in this one acoustic excitation of the gas flow can be dispensed with. Accordingly the thermoacoustic vibrations are influenced here mainly through fuel injection.

Furthermore, a solution is conceivable in which an interference frequency occurs acoustic excitation of the gas flow is influenced while another Interference frequency is influenced by modulated injection of the fuel. at This variant uses the two different influencing methods combined with each other to have different interference frequencies to influence different methods. With such a structure can in particular the known systems mentioned at the outset become.

Further important features and advantages of the invention result from the Subclaims, from the drawings and from the associated Description of the figures using the drawings.

Brief description of the drawings

Fig. 1 bis 3

jeweils eine stark vereinfachte Prinzipdarstellung einer erfindungsgemäßen Vorrichtung bei unterschiedlichen Ausführungsformen.

Preferred exemplary embodiments of the invention are illustrated in the drawings and are explained in more detail in the following description, the same reference symbols referring to the same or similar or functionally identical components. Each shows schematically

1 to 3

each a greatly simplified schematic diagram of a device according to the invention in different embodiments.

Ways of Carrying Out the Invention

1 to 3, a device 1 according to the invention comprises a controller 2, which is here only by a broken line symbolized frame is symbolized. The device 1 also has at least one acoustic source 3 and / or at least one control valve 4 a fuel supply device, not otherwise shown. The Device 1 is assigned to a combustion system 5, which is usually has at least one burner 6 and at least one combustion chamber 7. to Simplification are burner 6 and combustion chamber 7 by a common one Rectangle symbolizes.

The exemplary embodiments shown here differ essentially in that the controller 2 two in the variant according to FIG. 1 controls separate acoustic sources 3, while according to the variant FIG. 2 controls two separate control valves 4 and in the variant according to FIG. 3 controls an acoustic source 3 and a control valve 4. Provided two acoustic Sources 3 are present, one of them is designated 3 '. In corresponding One of the control valves 4 is designated 4 ′ when two control valves 4 are provided.

The controller 2 contains two control paths 8 and 9 for this purpose contain a frequency band pass filter 10 on the input side. Since the two Frequency band pass filter 10 tuned to different interference frequencies are, a frequency band pass filter is designated 10 '. In the Control paths 8, 9 is the frequency band pass filter 10, 10 'each Time delay element 11 or 11 'connected, which in turn a Amplifier element 12 is connected downstream. The two are on the output side Control paths 8, 9 either with one of the acoustic sources 3 or with one the control valves 4 connected.

Furthermore, each controller 2 contains a control algorithm 13 which is shown in FIG Depending on incoming signals, corresponding signals to the input sides the control paths 8, 9 delivers. The control algorithm 13 receives its Input signals from a sensor system, not shown here, for measurement thermoacoustic vibrations in the combustion system 5 is formed. The Signals determined by the sensor system correlate with the thermoacoustic Vibrations in the combustion system 5. The measured signals can thereby be pressure signals. The sensors then include pressure sensors, preferably microphones, in particular water-cooled microphones and / or Microphones with piezoelectric pressure transducers. It is also possible that the signals measured by the sensors using chemical luminescence signals are formed, preferably by chemiluminescent signals from the emission one of the radicals OH or CH. The sensor system can then expediently be optical Sensors for visible or infrared radiation, especially optical ones Have fiber probes.

The pressure or measured in the combustion chamber 7, for example Luminescence signal is filtered in the frequency band pass filters 10, 10 '. By the different pass frequencies of the frequency band pass filter 10, 10 'becomes the desired separate influencing of two different ones Interference frequencies, for example a main interference frequency and a secondary interference frequency, the thermoacoustic vibrations in the combustion system 5 allows. The respective control path 8, 9 then takes place in the respective Time delay element 11, 11 'a phase shift, the Phase shifts in the control paths 8, 9 can be different. Signal amplification then takes place in amplifier 12, and here too to generate different amplitudes the gain in the Control paths 8, 9 can be different. The control paths 8, 9 outgoing signals then drive the respective acoustic source 3, 3 'or that respective control valve 4, 4 '. This results in the desired influence thermoacoustic vibrations.

The controller 2, in particular its control algorithm 13, can be in Dependence of the current pressure or luminescent signals Actuate time delay elements 11 or 11 'and / or the amplifiers 12. As a result, the influence of the respective control path 8, 9 on the respective assigned interference frequency can be varied or tracked. So far closed control loops for both control paths 8, 9.

For the functioning of influencing the thermoacoustic vibrations by means of acoustic excitation of the gas flow, EP 0 918 152 A1 referenced, the content of which is hereby expressly referred to in the Disclosure content of the present invention is incorporated. In is accordingly for the functioning of influencing the thermoacoustic vibrations by means of modulated fuel injection EP 0 985 810 A1, the content of which is hereby expressly referred to Reference to the disclosure content of the present invention is incorporated.

The fluid mechanical stability of a gas turbine burner is of crucial for the occurrence of thermoacoustic vibrations.

The fluid-mechanical instability waves in the burner lead for the formation of vertebrae. These are also referred to as coherent structures Eddies play an important role in mixing processes between air and fuel. The spatial and temporal dynamics of this coherent Structures affect combustion and heat release. Through the Acoustic excitation of the gas flow can make this coherent Structures are counteracted. Will the emergence of vortex structures reduced or prevented at the burner outlet, this also periodic heat release fluctuation reduced. This periodic Fluctuations in heat release form the basis for the occurrence thermoacoustic vibrations, so that the acoustic excitation Amplitude of the thermoacoustic fluctuations can be reduced.

It is particularly advantageous here if the thermoacoustic vibrations occur in the area of the burner forming shear layer is acoustically excited. With shear layer is here Mixture layer refers to that between two fluid flows forms different speeds. Influencing the shear layer has the advantage that the excitation introduced in the shear layer increases become. So there is little to cancel an existing sound field Excitation energy needed. In contrast, with a pure Anti-sound principle an existing sound field by a phase-shifted Sound field of equal energy extinguished.

The shear layer can be excited both downstream and upstream of the burner become. Downstream of the burner, the shear layer can be excited directly. With an excitation upstream of the burner, the acoustic excitation first introduced into a working gas, for example air, the Then excitation after passage of the working gas through the burner into the Shear layer transmits. Since only a small amount of stimulation is required, can the acoustic sources 3 by acoustic drivers, such as Loudspeakers, be formed, which are aligned with the gas flow. alternative can one or more chamber walls mechanically cause vibrations in the desired frequency can be excited.

The momentary acoustic excitation of the gas flow or whose shear layer with a signal measured in the combustion system phase-coupled, which is correlated with the thermoacoustic fluctuations. This signal can be in the combustion chamber or in a downstream of the burner Calming chamber arranged upstream of the burner can be measured. The current acoustic excitation is then dependent on this Measurement signal controlled.

By choosing a suitable one, depending on the type of signal measured different phase difference between the measurement signal and the current one acoustic excitation signal affects the acoustic excitation of the training coherent structures, so that the amplitude of the pressure pulsation is reduced. The phase difference is determined by the respective Time delay element 11, 11 'is set and takes into account that as a rule by the arrangement of the measuring sensors and acoustic drivers or sources 3, 3 'or control valves 4, 4' and by the measuring devices and lines themselves Phase shifts occur. If the set relative phase is like this chosen to result in the greatest possible reduction in the pressure amplitude, all these phase shifting effects are implicitly taken into account. Since the cheapest relative phase can change over time, the relative phase remains advantageously variable and can be controlled via pressure fluctuations be adjusted in such a way that great suppression is always guaranteed.

The training can also be done with the help of the modulated fuel injection influence thermoacoustic vibrations. Under a modulated Fuel injection is every time varying injection of understood liquid or gaseous fuel. This modulation can for example with any frequency. The injection can phase-independent of the pressure fluctuations in the combustion system respectively; however, an embodiment is preferred in which the injection is carried out with is phase-coupled to a signal measured in the combustion system 5, the is correlated with the thermoacoustic vibrations. The modulation of the The fuel is injected by opening and closing the Control valves 4, 4 ', whereby the injection times (start and end of injection) and / or the injection quantity can be varied. Thanks to the modulated fuel supply can the amount of fuel converted in large eddies to be controlled. This can result in the formation of coherent heat releases and thus the emergence of thermoacoustic instabilities to be influenced.

In the embodiment according to FIG. 1 there are two separate acoustic sources 3 and 3 ', which are controlled separately via the parallel control paths 8, 9 become. In principle, however, an embodiment is conceivable in which both Control paths 8, 9 are connected to a common acoustic source, then the output signals of the control paths 8, 9 in a corresponding manner be overlaid. The same applies to the embodiment according to FIG. 2, in which two separate control valves 4 and 4 'from the two control paths 8, 9 can be controlled. Here, too, it is basically conceivable to have a common one Control valve by superimposing the output signals of the two Control paths 8, 9 to influence the two interference frequencies.

LIST OF REFERENCE NUMBERS

1

contraption

2

control

3

acoustic source

4

control valve

5

combustion system

6

burner

7

combustion chamber

8th

control path

9

control path

10

Frequency band-pass filter

11

Time delay element

12

amplifier

13

control algorithm

Claims (8)

Method for influencing thermoacoustic vibrations in a combustion system (5) with at least one burner (6) and at least one combustion chamber (7), in which a gas flow developing in the area of the burner (6) is acoustically stimulated and / or in which an injection of Fuel modulated,
characterized in that the acoustic excitations of the gas flow and / or the modulated injections of the fuel are coordinated to influence at least two different interference frequencies of the thermoacoustic vibrations. Method according to claim 1,
characterized in that two interference frequencies are influenced exclusively by acoustic excitations of the gas flow with different phases and / or amplitudes. Method according to claim 2,
characterized in that the acoustic excitations of the gas flow are generated with at least one acoustic source (3), the acoustic excitations of different phases and / or amplitudes being generated either via a common acoustic source or via at least two separate acoustic sources (3, 3 ') he follows. Method according to claim 1,
characterized in that two interference frequencies are influenced exclusively by modulated injection of the fuel with different injection times and / or injection quantities. Method according to claim 4,
characterized in that the modulated injections of the fuel are generated with at least one control valve (4), the generation of modulated injections of different injection times and / or injection quantities either using a common control valve or at least two separate control valves (4, 4 '). Method according to claim 1,
characterized in that an interference frequency is influenced by acoustic excitation of the gas flow and another interference frequency is influenced by modulated injection of the fuel. Device for influencing thermoacoustic vibrations in a combustion system (5) with at least one burner (6) and a combustion chamber (7), in which in the area of the burner (6) at least one acoustic source (3, 3 ') for generating an acoustic excitation of a a gas flow forming in the area of the burner (6) is arranged and / or in which the burner (6) has at least one fuel supply device with at least one control valve (4, 4 ') for producing a modulated injection of a fuel,
characterized in that a controller (2) is provided which controls the at least one acoustic source (3, 3 ') and / or the at least one control valve (4, 4') for influencing at least two different interference frequencies of the thermoacoustic vibrations. Device according to claim 7,
characterized in that the controller (2) has a control path (8, 9) for each interference frequency to be influenced, which contains on the input side a frequency band pass filter (10, 10 ') matched to the respective interference frequency and on the output side to the respective acoustic source (3, 3 ') or to the respective control valve (4, 4'), each control path (8, 9) containing a time delay element (11, 11 ').

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