Self-excited oscillations of a confined flame, burning in the wake of a bluff-body flameholder, are considered. These oscillations occur due to interaction between unsteady combustion and acoustic waves. According to linear theory, flow disturbances grow exponentially with time. A theory for nonlinear oscillations is developed, exploiting the fact that the main nonlinearity is in the heat release rate, which essentially 'saturates'. The amplitudes of the pressure fluctuations are sufficiently small that the acoustic waves remain linear. The time evolution of the oscillations is determined by numerical integration and inclusion of nonlinear effects is found to lead to limit cycles of finite amplitude. The predicted limit cycles are compared with results from experiments and from linear theory. The amplitudes and spectra of the limit-cycle oscillations are in reasonable agreement with experiment. Linear theory is found to predict the frequency and mode shape of the nonlinear oscillations remarkably well. Moreover, we find that, for this type of nonlinearity, describing function analysis enables a good estimate of the limit-cycle amplitude to be obtained from linear theory.Active control has been successfully applied to eliminate these oscillations. We demonstrate the same effect by adding a feedback control system to our nonlinear model. This theory is used to explain why any linear controller capable of stabilizing the linear flow disturbances is also able to stabilize finite-amplitude oscillations in the nonlinear limit cycles.
▪ Abstract Early work and recent advances in feedback control of combustion oscillations are described. The physics of combustion oscillations, most commonly caused by a coupling between acoustic waves and unsteady heat release, are discussed, and the concept of using feedback control to interrupt these interactions is introduced. Factors affecting practical implementation of feedback control, including sensors, actuators, and controller design are described, and the historical development of control strategy for combustion oscillations is reviewed. Finally, demonstrations of feedback control on full-scale combustion systems are described, and it is concluded that there is potential to apply more systematic controller designs at full scale.
A premixed ducted flame, burning in the wake of a bluff-body flame-holder, is
considered. For such a flame, interaction between acoustic waves and unsteady
combustion can lead to self-excited oscillations. The concept of a time-invariant
turbulent flame speed is used to develop a kinematic model of the response of the flame
to flow disturbances. Variations in the oncoming flow velocity at the flame-holder
drive perturbations in the flame initiation surface and hence in the instantaneous rate
of heat release. For linear fluctuations, the transfer function between heat release and
velocity can be determined analytically from the model and is in good agreement
with experiment across a wide frequency range. For nonlinear fluctuations, the model
reproduces the flame surface distortions seen in schlieren films.Coupling this kinematic flame model with an analysis of the acoustic waves generated
in the duct by the unsteady combustion enables the time evolution of disturbances
to be calculated. Self-excited oscillations occur above a critical fuel–air ratio.
The frequency and amplitude of the resulting limit cycles are in satisfactory agreement
with experiment. Flow reversal is predicted to occur during part of the limit-cycle
oscillation and the flame then moves upstream of the flame-holder, just as in experimental
visualizations. The main nonlinearity is identified in the rate of heat release,
which essentially ‘saturates’ once the amplitude of the velocity fluctuation exceeds
its mean. We show that, for this type of nonlinearity, describing function analysis can
be used to give a good estimate of the limit-cycle frequency and amplitude from a
quasi-nonlinear theory.
The effectiveness of a cylindrical perforated liner with mean bias flow in its absorption of planar acoustic waves in a duct is investigated. The liner converts acoustic energy into flow energy through the excitation of vorticity fluctuations at the rims of the liner apertures. A one-dimensional model that embodies this absorption mechanism is developed. It utilizes a homogeneous liner compliance adapted from the Rayleigh conductivity of a single aperture with mean flow. The model is evaluated by comparing with experimental results, with excellent agreement. We show that such a system can absorb a large fraction of incoming energy, and can prevent all of the energy produced by an upstream source in certain frequency ranges from reflecting back. Moreover, the bandwidth of this strong absorption can be increased by appropriate placement of the liner system in the duct. An analysis of the acoustic energy flux is performed, revealing that local differences in fluctuating stagnation enthalpy, distributed over a finite length of duct, are responsible for absorption, and that both liners in a double-liner system are absorbant. A reduction of the model equations in the limit of long wavelength compared to liner length reveals an important parameter grouping, enabling the optimal design of liner systems.
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