Experimental investigation of entropy waves’ evolution for understanding of indirect combustion noise in gas turbine combustors
Experimental investigation of entropy waves’ evolution for understanding of indirect combustion noise in gas turbine combustors
Achieving clean and quiet combustion in gas turbines is essential for improving many low-carbon energy and propulsion technologies. This often requires suppression of combustion instabilities and combustion generated noise in gas turbine combustors. Entropy noise is the less explored mechanism of combustion generated sound. Central to the emission of entropic sound is the survival of entropy wave during convection by the mean flow and reaching the combustor exit nozzle. Yet, the annihilation of entropy waves in this process is still poorly understood. To address this issue, the evolution of convected entropy waves in a fully-developed, cold flow inside a circular duct is investigated experimentally. Entropy waves are produced by a well-controlled electrical heater. Fast-response, miniaturized thermocouples arranged over a moveable cross-section of the duct are employed to record the state of entropy waves at different axial locations along the duct. Hydrodynamic parameters including Reynolds number and turbulence intensity are varied to investigate their effects upon the wave decay. The results show that the decay process is strongly wavelength dependent. It is found that the wave components with wavelengths larger than the duct diameter are almost unaffected by the flow and therefore remain essentially one-dimensional. However, other spectral components of the wave are subject to varying degrees of dissipation and loss of spatial correlation. Overall, the results support the recent numerical findings about the likelihood of wave survival in adiabatic flows. They further clarify the validity range of the one-dimensional assumption commonly made in the literature.
Hosseinalipour, S.M.
d31a978d-35c1-4594-b89b-cfff6465d209
Fattahi, A.
d7ed8e10-a89c-4654-a446-7f4aef5df35a
Tootoonchian, F.
99de9c8f-3890-4486-a073-3d5e38ea0895
Khalil, H.
6ad1e2cd-6bb3-4993-9c9a-0421bf817bf9
Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
7 February 2020
Hosseinalipour, S.M.
d31a978d-35c1-4594-b89b-cfff6465d209
Fattahi, A.
d7ed8e10-a89c-4654-a446-7f4aef5df35a
Tootoonchian, F.
99de9c8f-3890-4486-a073-3d5e38ea0895
Khalil, H.
6ad1e2cd-6bb3-4993-9c9a-0421bf817bf9
Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
Hosseinalipour, S.M., Fattahi, A., Tootoonchian, F., Khalil, H. and Karimi, Nader
(2020)
Experimental investigation of entropy waves’ evolution for understanding of indirect combustion noise in gas turbine combustors.
Energy.
(doi:10.1016/j.energy.2020.116978).
Abstract
Achieving clean and quiet combustion in gas turbines is essential for improving many low-carbon energy and propulsion technologies. This often requires suppression of combustion instabilities and combustion generated noise in gas turbine combustors. Entropy noise is the less explored mechanism of combustion generated sound. Central to the emission of entropic sound is the survival of entropy wave during convection by the mean flow and reaching the combustor exit nozzle. Yet, the annihilation of entropy waves in this process is still poorly understood. To address this issue, the evolution of convected entropy waves in a fully-developed, cold flow inside a circular duct is investigated experimentally. Entropy waves are produced by a well-controlled electrical heater. Fast-response, miniaturized thermocouples arranged over a moveable cross-section of the duct are employed to record the state of entropy waves at different axial locations along the duct. Hydrodynamic parameters including Reynolds number and turbulence intensity are varied to investigate their effects upon the wave decay. The results show that the decay process is strongly wavelength dependent. It is found that the wave components with wavelengths larger than the duct diameter are almost unaffected by the flow and therefore remain essentially one-dimensional. However, other spectral components of the wave are subject to varying degrees of dissipation and loss of spatial correlation. Overall, the results support the recent numerical findings about the likelihood of wave survival in adiabatic flows. They further clarify the validity range of the one-dimensional assumption commonly made in the literature.
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Accepted/In Press date: 20 January 2020
Published date: 7 February 2020
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Local EPrints ID: 508905
URI: http://eprints.soton.ac.uk/id/eprint/508905
ISSN: 0360-5442
PURE UUID: c7eb73b7-15d6-4325-8c91-f878c0e8a45a
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Date deposited: 05 Feb 2026 17:55
Last modified: 07 Mar 2026 04:28
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Author:
S.M. Hosseinalipour
Author:
A. Fattahi
Author:
F. Tootoonchian
Author:
H. Khalil
Author:
Nader Karimi
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