Prediction of combustion instability limit cycle oscillations by combining flame describing function simulations with a thermoacoustic network model

Han, Xingsi; Li, Jingxuan; Morgans, Aimee S.

doi:10.1016/j.combustflame.2015.06.020

Cited by 185 publications

(80 citation statements)

References 95 publications

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“…Based on the PaSR model, the filtered chemical reaction rate of the i -th species, , can be scaled by κ and modelled as [23, 40]: where denotes the mean concentration of species i exiting the mesh cell, and is the initial mean concentration of species i inside the same cell. Δ t is the computational time step, and denotes the density-weighted (Favre) filtering, defined as for an arbitrary variable ψ .…”

Section: Large Eddy Simulation Of a Turbulent Reacting Flow-fieldmentioning

confidence: 99%

“…Previous large eddy simulations (LES) [21–23] and experiments [24] of combustor reacting flow-fields have shown that the main large-scale flow features, such as flow separation and recirculation zones, are the same whether the flame is fully-premixed [22], partially-premixed [23], or non-premixed [21, 24]. The mean and fluctuating velocity fields are both qualitatively and quantitatively very similar in all cases.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Dispersion of Entropy Perturbations Transporting through an Industrial Gas Turbine Combustor

Xia

Durán

Morgans

et al. 2017

Flow Turbulence Combust

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In the context of combustion noise and combustion instabilities, the transport of entropy perturbations through highly simplified turbulent flows has received much recent attention. This work performs the first systematic study into the transport of entropy perturbations through a realistic gas turbine combustor flow-field, exhibiting large-scale hydrodynamic flow features in the form of swirl, separation, recirculation zones and vortex cores, these being ubiquitous in real combustor flows. The reacting flow-field is simulated using low Mach number large eddy simulations, with simulations validated by comparison to available experimental data. A generic artificial entropy source, impulsive in time and spatially localized at the flame-front location, is injected. The conservation equation describing entropy transport is simulated, superimposed on the underlying flow-field simulation. It is found that the transport of entropy perturbations is dominated by advection, with both thermal diffusion and viscous production being negligible. It is furthermore found that both the mean flow-field and the large-scale unsteady flow features contribute significantly to advective dispersion — neither can be neglected. The time-variation of entropy perturbation amplitude at combustor exit is well-modelled by a Gaussian profile, whose dispersion exceeds that corresponding to a fully-developed pipe mean flow profile roughly by a factor of three. Finally, despite the attenuation in entropy perturbation amplitude caused by advective dispersion, sufficient entropy perturbation strength is likely to remain at combustor exit for entropy noise to make a meaningful contribution at low frequencies.

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Section: Large Eddy Simulation Of a Turbulent Reacting Flow-fieldmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Dispersion of Entropy Perturbations Transporting through an Industrial Gas Turbine Combustor

Xia

Durán

Morgans

et al. 2017

Flow Turbulence Combust

Self Cite

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“…This shows that a large number of calculations is required to accurately estimate the FDIDF. This makes it currently non-affordable f or, say, compressible LES studies, in which many CPU hours are already required to calculate the FDF only [57] .…”

Section: Discussion On Cost and Practical Implementationmentioning

confidence: 99%

Flame Double Input Describing Function analysis

Orchini

Juniper

2016

Combustion and Flame

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a b s t r a c tThe Flame Describing Function (FDF) is a useful and relatively cheap approximation of a flame's nonlinearity with respect to harmonic velocity fluctuations. When embedded into a linear acoustic network, it is able to predict the amplitude and stability of harmonic thermoacoustic oscillations through the harmonic balance procedure. However, situations exist in which these oscillations are not periodic, but their spectrum contains peaks at several incommensurate frequencies. If one assumes that two frequencies dominate the spectrum, these oscillations are quasiperiodic, and the FDF concept can be extended by forcing the flame with two amplitudes and two frequencies. The nonlinearity is then approximated by a Flame Double Input Describing Function (FDIDF), which is a more expensive object to calculate than the FDF, but contains more information about the nonlinear response.In this study, we present the calculation of a non-static flame's FDIDF. We use a G -equation-based laminar conical flame model. We embed the FDIDF into a thermoacoustic network and we predict the nature and amplitude of thermoacoustic oscillations through the harmonic balance method. A criterion for the stability of these oscillations is outlined. We compare our results with a classical FDF analysis and self-excited time domain simulations of the same system. We show how the FDIDF improves the stability prediction provided by the FDF. At a numerical cost roughly equivalent to that of two FDFs, the FDIDF is capable to predict the onset of Neimark-Sacker bifurcations and to identify the frequency of oscillations around unstable limit cycles. At a higher cost, it can also saturate in amplitude these oscillations and predict the amplitude and stability of quasiperiodic oscillations.

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“…In order to study the thermoacoustic modes, we use a low order thermoacoustic network modelling tool -in this case the open source OSCILOS [15,25] which has been validated against experiments [26]. As shown in Fig.…”

Section: The Effect On Thermoacoustic Modesmentioning

confidence: 99%