Experimental investigation of the hydrodynamic effects upon convecting entropy waves in nozzle flows
Experimental investigation of the hydrodynamic effects upon convecting entropy waves in nozzle flows
Entropy noise induced by hot spots (entropy waves) is the least explored mechanism of combustion generated sound. Emission of entropy noise is subject to convection of entropy wave throughout the combustor exit nozzle. Nonetheless, the highly diffusive flows in combustors can dissipate entropy waves partially and even totally and hence, suppress the noise generation. Yet, the annihilation of entropy waves in this process is still poorly understood. In particular, no investigation exists on the evolution of entropy waves in nozzle flows. To address this issue, two low-speed, nozzle configurations supplied with fully developed flows at the inlet are examined experimentally. Entropy waves are generated by a controllable electric heater embedded inside the flow. A set of fast-response thermocouples are arranged at the entrance and exit sections of the nozzle to record the spatio-temporal evolution of the entropy wave during its passage thought the nozzle. The acoustic wave, generated by the conversion of entropy waves to sound, is further measured by differential pressure sensors. The results show that hydrodynamic characteristics of the flow such as Reynolds number and turbulence intensity as well as nozzle geometry dominate the survival of entropy wave. Analysis of the spatio-temporal coherence of the wave reveals that there is a predictable frequency threshold above that the wave is spatially distorted. This frequency limit determines the validity range of the commonly used, one-dimensional theoretical models of entropy wave that are currently applied to the whole spectral domain.
Hosseinalipour, S. Mostafa
c86bc780-c932-48a6-9be5-1d435d786ce3
Rahmani, Ebrahim
c37e5b12-bf17-4424-b1e3-2815b19142da
Fattahi, Abolfazl
ba9b2b28-8499-42ab-9178-c391585b8c75
Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
1 December 2020
Hosseinalipour, S. Mostafa
c86bc780-c932-48a6-9be5-1d435d786ce3
Rahmani, Ebrahim
c37e5b12-bf17-4424-b1e3-2815b19142da
Fattahi, Abolfazl
ba9b2b28-8499-42ab-9178-c391585b8c75
Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
Hosseinalipour, S. Mostafa, Rahmani, Ebrahim, Fattahi, Abolfazl and Karimi, Nader
(2020)
Experimental investigation of the hydrodynamic effects upon convecting entropy waves in nozzle flows.
Aerospace Science and Technology, 107, [106301].
(doi:10.1016/j.ast.2020.106301).
Abstract
Entropy noise induced by hot spots (entropy waves) is the least explored mechanism of combustion generated sound. Emission of entropy noise is subject to convection of entropy wave throughout the combustor exit nozzle. Nonetheless, the highly diffusive flows in combustors can dissipate entropy waves partially and even totally and hence, suppress the noise generation. Yet, the annihilation of entropy waves in this process is still poorly understood. In particular, no investigation exists on the evolution of entropy waves in nozzle flows. To address this issue, two low-speed, nozzle configurations supplied with fully developed flows at the inlet are examined experimentally. Entropy waves are generated by a controllable electric heater embedded inside the flow. A set of fast-response thermocouples are arranged at the entrance and exit sections of the nozzle to record the spatio-temporal evolution of the entropy wave during its passage thought the nozzle. The acoustic wave, generated by the conversion of entropy waves to sound, is further measured by differential pressure sensors. The results show that hydrodynamic characteristics of the flow such as Reynolds number and turbulence intensity as well as nozzle geometry dominate the survival of entropy wave. Analysis of the spatio-temporal coherence of the wave reveals that there is a predictable frequency threshold above that the wave is spatially distorted. This frequency limit determines the validity range of the commonly used, one-dimensional theoretical models of entropy wave that are currently applied to the whole spectral domain.
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Published date: 1 December 2020
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Local EPrints ID: 509077
URI: http://eprints.soton.ac.uk/id/eprint/509077
ISSN: 1270-9638
PURE UUID: ed953178-0d30-4e8b-b513-4efaa45a97d7
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Date deposited: 10 Feb 2026 18:11
Last modified: 11 Feb 2026 03:18
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Author:
S. Mostafa Hosseinalipour
Author:
Ebrahim Rahmani
Author:
Abolfazl Fattahi
Author:
Nader Karimi
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