Dynamics of entropy wave generation in a simplified model of gas turbine combustor: a theoretical investigation
Dynamics of entropy wave generation in a simplified model of gas turbine combustor: a theoretical investigation
Entropy noise remains as a largely unexplored mechanism of combustion generated noise. Currently, little is known about the production sources of entropy waves in flames. To address this issue, the present work puts forward a theoretical investigation of the generation of entropy waves in a one-dimensional, ducted flow. A linear theory is developed for the dynamic responses of different sources of unsteady entropy generation including thermal, hydrodynamic, pressure, and chemical irreversibility. For the first time in the literature, dynamics of chemical sources of unsteady entropy generation are investigated extensively. It is found that the mixture fraction fluctuations are responsible for the production of almost all unsteady chemical entropy and the effect of chemical potential is negligibly small. For the Strouhal numbers less than unity, fluctuations in pressure are the most significant source of the overall generation of unsteady entropy. However, at higher frequencies, mixture fraction fluctuations dominate the generation of entropy wave. The cut-off frequency for the generation of entropy wave is shown to depend not only on the thermal and hydrodynamic characteristics of the flame but also on the chemical properties of the downstream gases. It is further argued that the transfer function of entropy generation for a thin flame may feature an unrealistically high amplitude. This study shows that neglecting the chemical sources of an entropy wave can result in wrong predictions of the combustor acoustics and impede the suppression of combustion instabilities and noise.
Fattahi, Abolfazl
5748d630-bb73-4abe-90e2-f5234dc5fb18
Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
Hajialigol, Najmeh
025d6490-d714-4df6-b82f-fc9f9459c213
1 October 2020
Fattahi, Abolfazl
5748d630-bb73-4abe-90e2-f5234dc5fb18
Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
Hajialigol, Najmeh
025d6490-d714-4df6-b82f-fc9f9459c213
Fattahi, Abolfazl, Karimi, Nader and Hajialigol, Najmeh
(2020)
Dynamics of entropy wave generation in a simplified model of gas turbine combustor: a theoretical investigation.
Physics of Fluids, 32 (10).
(doi:10.1063/5.0021729).
Abstract
Entropy noise remains as a largely unexplored mechanism of combustion generated noise. Currently, little is known about the production sources of entropy waves in flames. To address this issue, the present work puts forward a theoretical investigation of the generation of entropy waves in a one-dimensional, ducted flow. A linear theory is developed for the dynamic responses of different sources of unsteady entropy generation including thermal, hydrodynamic, pressure, and chemical irreversibility. For the first time in the literature, dynamics of chemical sources of unsteady entropy generation are investigated extensively. It is found that the mixture fraction fluctuations are responsible for the production of almost all unsteady chemical entropy and the effect of chemical potential is negligibly small. For the Strouhal numbers less than unity, fluctuations in pressure are the most significant source of the overall generation of unsteady entropy. However, at higher frequencies, mixture fraction fluctuations dominate the generation of entropy wave. The cut-off frequency for the generation of entropy wave is shown to depend not only on the thermal and hydrodynamic characteristics of the flame but also on the chemical properties of the downstream gases. It is further argued that the transfer function of entropy generation for a thin flame may feature an unrealistically high amplitude. This study shows that neglecting the chemical sources of an entropy wave can result in wrong predictions of the combustor acoustics and impede the suppression of combustion instabilities and noise.
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Published date: 1 October 2020
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Local EPrints ID: 509120
URI: http://eprints.soton.ac.uk/id/eprint/509120
ISSN: 1070-6631
PURE UUID: 839e2b56-726a-4ea4-9b4e-b8d6cceb37ec
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Date deposited: 11 Feb 2026 17:51
Last modified: 12 Feb 2026 03:31
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Author:
Abolfazl Fattahi
Author:
Nader Karimi
Author:
Najmeh Hajialigol
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