2018
DOI: 10.1115/1.4041007
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Effects of Asymmetry on Thermoacoustic Modes in Annular Combustors: A Higher-Order Perturbation Study

Abstract: Gas-turbine combustion chambers typically consist of nominally identical sectors arranged in a rotationally symmetric pattern. However, in practice, the geometry is not perfectly symmetric. This may be due to design decisions, such as placing dampers in an azimuthally nonuniform fashion, or to uncertainties in the design parameters, which break the rotational symmetry of the combustion chamber. The question is whether these deviations from symmetry have impact on the thermoacoustic-stability calculation. The p… Show more

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Cited by 37 publications
(30 citation statements)
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“…Such predictions can be achieved using reduced-order thermoacoustic network models which include modelled or measured flame transfer functions and acoustic propagation in 3D complex geometries -e.g. [18,19,20,21] for linear description of the annular thermoacoustics, with stability analysis and investigation of symmetry breaking, [22] for computationally efficient numerical methods to solve the associated nonlinear eigenvalue problem and [23] to perform sensitivity analysis to perturbations in the heat release rate distribution , [24,25] for frequency domain description of the thermoacoustics in annular combustors with measured and modelled nonlinear flame feedback, [15,26] for state-space description allowing for time and frequency domain analysis. Coming back to the 1D description adopted in this work, previous 1D studies from Ghirardo et al [27,28] use a general formulation with flame describing function for both static and dynamic nonlinearities.…”
Section: Introductionmentioning
confidence: 99%
“…Such predictions can be achieved using reduced-order thermoacoustic network models which include modelled or measured flame transfer functions and acoustic propagation in 3D complex geometries -e.g. [18,19,20,21] for linear description of the annular thermoacoustics, with stability analysis and investigation of symmetry breaking, [22] for computationally efficient numerical methods to solve the associated nonlinear eigenvalue problem and [23] to perform sensitivity analysis to perturbations in the heat release rate distribution , [24,25] for frequency domain description of the thermoacoustics in annular combustors with measured and modelled nonlinear flame feedback, [15,26] for state-space description allowing for time and frequency domain analysis. Coming back to the 1D description adopted in this work, previous 1D studies from Ghirardo et al [27,28] use a general formulation with flame describing function for both static and dynamic nonlinearities.…”
Section: Introductionmentioning
confidence: 99%
“…They extended their analysis to flame describing functions for the calculation of limit cycles [170]. Different symmetry-breaking perturbations to the burners were studied with higher-order perturbation adjoint theory in [171]. In eigenvalue optimization, Mensah and Moeck [172] calculated the optimal placement and tuning of acoustic dampers in an annular combustor; while Aguilar and Juniper [173,174] eliminated thermoacoustic oscillations by shape optimization.…”
Section: Thermoacousticsmentioning
confidence: 99%
“…• there is no flame-to-flame interaction from one sector to another; [202,[217][218][219] as modelled in [171].…”
Section: Helmholtz Equationmentioning
confidence: 99%
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