Thermodynamics-Acoustics Coupling Studies on Self-Excited Combustion Oscillations Maximum Growth Rate

Zhao, Dan

doi:10.1007/s11630-020-1361-8

Cited by 20 publications

(5 citation statements)

References 51 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Equation (15) shows that the expression of displacement contains an exponential growth term. It means that smallamplitude acoustic disturbances at any frequency will be exponentially amplified.…”

Section: Divergent Analysis Of the Complex Damped Systemmentioning

confidence: 99%

See 1 more Smart Citation

A time-domain method for free vibration responses of an equivalent viscous damped system based on a complex damping model

Wang

Fan

et al. 2023

Journal of Low Frequency Noise, Vibration and Active Control

View full text Add to dashboard Cite

The free vibration responses are divergent based on a complex time-domain damping model. The traditional step by step integration method cannot be used to calculate the time-domain responses. Based on the theoretic solution that eliminates the divergent term for the complex damping model, the equivalent viscous damping model is proposed and the corresponding average acceleration method is realized in this paper. The numerical cases show that the calculated results of the equivalent viscous damped system are convergent, which are equal to the ones of the deleted divergent term based on the complex damping model. The correctness of the proposed method is verified, and the computational efficiency is high.

show abstract

Section: Divergent Analysis Of the Complex Damped Systemmentioning

confidence: 99%

“…It means that small-amplitude acoustic disturbances at any frequency will be exponentially amplified. 15 The growth rate of vibration responses is the important factor. 16 The growth item of free vibration responses is normaleαt.…”

Section: Free Vibration Responses Of the Equivalent Viscous Damped Sy...mentioning

confidence: 99%

A time-domain method for free vibration responses of an equivalent viscous damped system based on a complex damping model

Wang

Fan

et al. 2023

Journal of Low Frequency Noise, Vibration and Active Control

View full text Add to dashboard Cite

show abstract

“…Hence, the deflection angle of the extended neck significantly changes the resonance frequency. The modified Helmholtz resonators with extended necks with an optimum design could be applied to attenuate self-excited combustion oscillations, [46][47][48] thus enabling propulsion systems being operated stably.…”

Section: Effect Of the Extended Neck Implementation Configurationsmentioning

confidence: 99%

Numerical investigation on low-frequency noise damping performances of Helmholtz resonators with an extended neck in presence of a grazing flow

Guan

2021

Journal of Low Frequency Noise, Vibration and Active Control

View full text Add to dashboard Cite

In this work, modified designs of Helmholtz resonators with extended deflected neck are proposed, numerically evaluated and optimized aiming to achieve a better transmission loss performance over a broader frequency range. For this, 10 Helmholtz resonators with different extended neck configurations (e.g. the angle between extended neck and the y-axis) in the presence of a grazing flow are assessed. Comparison is then made between the proposed resonators and the conventional one, i.e. in the absence of an extended neck (i.e. Design A). For this, a two-dimensional linearized Navier Stokes equations-based model of a duct with the modified Helmholtz resonator implemented was developed in frequency domain. The model was first validated by comparing its numerical predictions with the experimental results available in the literature and the theoretical results. The model was then applied to evaluate the noise damping performance of the Helmholtz resonator with (1) an extended neck on the upstream side (Design B); (2) on the downstream side (Design C), (3) both upstream and downstream sides (Design D), (4) the angle between the extended neck and the y-axis, i.e. (a) 0°, (b) 30°, and (c) 45°, (d) 48.321°. In addition, the effects of the grazing flow Mach number (Ma) were evaluated. It was found that the transmission loss peaks of the Helmholtz resonator with the extended neck was maximized at Ma = 0.03 than at the other Mach numbers. Conventional resonator, i.e. Design A was observed to be associated with a lower transmission loss performance at a lower resonant frequency than those as observed on Designs B–D. Moreover, the optimum design of the proposed resonators with the extended neck is shown to be able to shift the resonant frequency by approximately 90 Hz, and maximum transmission loss could be increased by 28–30 dB. In addition, the resonators with extended necks are found to be associated with two or three transmission loss peaks, indicating that these designs have a broader effective frequency range. Finally, the neck deflection angles of 30° and 45° are shown to be involved with better transmission loss peaks than that with a deflection angle of 0°. In summary, the present study sheds light on maximizing the resonator’s noise damping performances by applying and optimizing an extended neck.

show abstract

“…Two important parameters to evaluate the growth of thermoacoustic instability are the growth rate of the acoustic disturbances α and G. The definition and detail derivation of α and G can be found in the reference [44]. The time evolution of the pressure and heat release of the flame from 0 s to 0.4 s are illustrated in Figures 8 and 9.…”

Section: Self-excited Pressure Oscillation-the Exponential Growth Of Thermoacoustic Instabilitymentioning

confidence: 99%

Numerical Study on the Route of Flame-Induced Thermoacoustic Instability in a Rijke Burner

2021

View full text Add to dashboard Cite

The self-excited thermoacoustic instability in a two-dimensional Rijke-type burner with a center-stabilized premixed methane–air flame is numerically studied. The simulation considers the reacting flow, flame dynamics, and radiation model to investigate the important physical processes. A finite volume-based approach is used to simulate reacting flows under both laminar and turbulent flow conditions. Chemical reaction modeling is conducted via the finite-rate/eddy dissipation model with one-step reaction mechanisms, and the radiation heat flux and turbulent flow characteristics are determined by using the P-1 model and the standard k-ε model, respectively. The steady-state reacting flow is first simulated for model verification. Then, the dynamic pressure, velocity, and reaction heat evolutions are determined to show the onset and growth rate of self-excited instability in the burner. Using the fast Fourier transform (FFT) method, the frequency of the limit cycle oscillation is obtained, which agrees well with the theoretical prediction. The dynamic pressure and velocity along the tube axis provide the acoustic oscillation mode and amplitude, also agreeing well with the prediction. Finally, the unsteady flow field at different times in a limit cycle shows that flame-induced vortices occur inside the combustor, and the temperature distribution indicates that the back-and-forth velocity changes in the tube vary the distance between the flame and honeycomb in turn, forming a forward feedback loop in the tube. The results reveal the route of flame-induced thermoacoustic instability in the Rijke-type burner and indicate periodical vortex formation and breakdown in the Rijke burner, which should be considered turbulent flow under thermoacoustic instability.

show abstract

Thermodynamics-Acoustics Coupling Studies on Self-Excited Combustion Oscillations Maximum Growth Rate

Cited by 20 publications

References 51 publications

A time-domain method for free vibration responses of an equivalent viscous damped system based on a complex damping model

A time-domain method for free vibration responses of an equivalent viscous damped system based on a complex damping model

Numerical investigation on low-frequency noise damping performances of Helmholtz resonators with an extended neck in presence of a grazing flow

Numerical Study on the Route of Flame-Induced Thermoacoustic Instability in a Rijke Burner

Contact Info

Product

Resources

About