Swirler effects on combustion instabilities analyzed with measured FDFs, injector impedances and damping rates
Swirler effects on combustion instabilities analyzed with measured FDFs, injector impedances and damping rates
The influence of the injection system on combustion instabilities is investigated on a laboratory-scale combustor equipped with a single injector that is weakly-transparent to acoustic waves. The combustor is fed with liquid heptane delivered as a spray by a hollow cone atomizer. Experiments are carried out with three swirlers having similar geometries but different pressure losses and swirl numbers. Self-sustained oscillations (SSOs) corresponding to these swirlers feature differences in oscillation frequency and amplitude for a given chamber length. These observations do not match with standard modeling predictions. Therefore, a low-order analytical model is derived, representing the effect of the acoustically weakly-transparent injection system using an impedance at the injector outlet. This quantity and the flame describing function (FDF), both determined experimentally, are used together with damping rate estimates as model inputs. It is shown that the FDF can only be determined by suitably selecting the position for the measurement of incident velocity disturbances at the injector outlet and that plenum-based velocity measurements cannot be used for this purpose. It is also assumed that the OH*-chemiluminescence intensity can be used as a proxy for the heat release rate. This admittedly strong assumption for spray flames is discussed in detail and justified by showing that the equivalence ratio modulations are relatively weak for the particular spray flames considered in this study. Results from the model indicate that the injector impedance (that depends on the swirler characteristics) shifts the classical bands of instability and modifies the growth rate magnitude compared to a generic combustor with an acoustically transparent injector. Using the proposed model, the stability of the system can be rated along with a prediction for growth rate and frequency of oscillation. Predictions generally agree with experimental observations with some limitations. The model combined with damping rate estimates is finally used to predict limit cycle oscillation amplitudes with the aid of the FDF framework.
Rajendram Soundararajan, Preethi
27962fcb-d8a8-405a-b137-086815ec8e29
Durox, Daniel
5abd6445-57f2-41a0-b831-983ef4239273
Renaud, Antoine
aedb2589-2a4a-4614-b9fa-1da56f9c7b0d
Vignat, Guillaume
f808aa32-377e-48a7-bc60-2db7e1767e09
Candel, Sebastien
c8f272d5-74e9-4fdf-9052-30122eb3a372
10 January 2022
Rajendram Soundararajan, Preethi
27962fcb-d8a8-405a-b137-086815ec8e29
Durox, Daniel
5abd6445-57f2-41a0-b831-983ef4239273
Renaud, Antoine
aedb2589-2a4a-4614-b9fa-1da56f9c7b0d
Vignat, Guillaume
f808aa32-377e-48a7-bc60-2db7e1767e09
Candel, Sebastien
c8f272d5-74e9-4fdf-9052-30122eb3a372
Rajendram Soundararajan, Preethi, Durox, Daniel, Renaud, Antoine, Vignat, Guillaume and Candel, Sebastien
(2022)
Swirler effects on combustion instabilities analyzed with measured FDFs, injector impedances and damping rates.
Combustion and Flame, 238.
(doi:10.1016/j.combustflame.2021.111947).
Abstract
The influence of the injection system on combustion instabilities is investigated on a laboratory-scale combustor equipped with a single injector that is weakly-transparent to acoustic waves. The combustor is fed with liquid heptane delivered as a spray by a hollow cone atomizer. Experiments are carried out with three swirlers having similar geometries but different pressure losses and swirl numbers. Self-sustained oscillations (SSOs) corresponding to these swirlers feature differences in oscillation frequency and amplitude for a given chamber length. These observations do not match with standard modeling predictions. Therefore, a low-order analytical model is derived, representing the effect of the acoustically weakly-transparent injection system using an impedance at the injector outlet. This quantity and the flame describing function (FDF), both determined experimentally, are used together with damping rate estimates as model inputs. It is shown that the FDF can only be determined by suitably selecting the position for the measurement of incident velocity disturbances at the injector outlet and that plenum-based velocity measurements cannot be used for this purpose. It is also assumed that the OH*-chemiluminescence intensity can be used as a proxy for the heat release rate. This admittedly strong assumption for spray flames is discussed in detail and justified by showing that the equivalence ratio modulations are relatively weak for the particular spray flames considered in this study. Results from the model indicate that the injector impedance (that depends on the swirler characteristics) shifts the classical bands of instability and modifies the growth rate magnitude compared to a generic combustor with an acoustically transparent injector. Using the proposed model, the stability of the system can be rated along with a prediction for growth rate and frequency of oscillation. Predictions generally agree with experimental observations with some limitations. The model combined with damping rate estimates is finally used to predict limit cycle oscillation amplitudes with the aid of the FDF framework.
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Accepted/In Press date: 15 December 2021
e-pub ahead of print date: 10 January 2022
Published date: 10 January 2022
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Local EPrints ID: 505788
URI: http://eprints.soton.ac.uk/id/eprint/505788
ISSN: 0010-2180
PURE UUID: df10f036-20ab-47a3-8edc-8425efa74280
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Date deposited: 20 Oct 2025 16:32
Last modified: 21 Oct 2025 02:12
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Author:
Preethi Rajendram Soundararajan
Author:
Daniel Durox
Author:
Antoine Renaud
Author:
Guillaume Vignat
Author:
Sebastien Candel
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