On the response of a lean-premixed hydrogen combustor to acoustic and dissipative-dispersive entropy waves
On the response of a lean-premixed hydrogen combustor to acoustic and dissipative-dispersive entropy waves
Combustion of hydrogen or hydrogen containing blends in gas turbines and industrial combustors can activate thermoacoustic combustion instabilities. Convective instabilities are an important and yet less investigated class of combustion instability that are caused by the so called “entropy waves”. As a major shortcoming, the partial decay of these convective-diffusive waves in the post-flame region of combustors is still largely unexplored. This paper, therefore, presents an investigation of the annihilating effects, due to hydrodynamics, heat transfer and flow stretch upon the nozzle response. The classical compact analysis is first extended to include the decay of entropy waves and heat transfer from the nozzle. Amplitudes and phase shifts of the responding acoustical waves are then calculated for subcritical and supercritical nozzles subject to acoustic and entropic forcing. A relation for the stretch of entropy wave in the nozzle is subsequently developed. It is shown that heat transfer and hydrodynamic decay can impart considerable effects on the entropic response of the nozzle. It is further shown that the flow stretching effects are strongly frequency dependent. The results indicate that dissipation and dispersion of entropy waves can significantly influence their conversion to sound and therefore should be included in the entropy wave models.
272-291
Fattahi, A.
fe8f6b2a-4e95-49f9-aa6c-e7024a0c72e8
Hosseinalipour, S.M.
7f9178cb-86d7-4c65-bfc6-6500e5a49de0
Karimi, N.
620646d6-27c9-4e1e-948f-f23e4a1e773a
Saboohi, Z.
9b18752d-cc15-406f-8825-fe158a7e53b3
Ommi, F.
6d86522f-15c0-4558-9b46-6528d3545bd2
1 August 2019
Fattahi, A.
fe8f6b2a-4e95-49f9-aa6c-e7024a0c72e8
Hosseinalipour, S.M.
7f9178cb-86d7-4c65-bfc6-6500e5a49de0
Karimi, N.
620646d6-27c9-4e1e-948f-f23e4a1e773a
Saboohi, Z.
9b18752d-cc15-406f-8825-fe158a7e53b3
Ommi, F.
6d86522f-15c0-4558-9b46-6528d3545bd2
Fattahi, A., Hosseinalipour, S.M., Karimi, N., Saboohi, Z. and Ommi, F.
(2019)
On the response of a lean-premixed hydrogen combustor to acoustic and dissipative-dispersive entropy waves.
Energy, 180, .
(doi:10.1016/j.energy.2019.04.202).
Abstract
Combustion of hydrogen or hydrogen containing blends in gas turbines and industrial combustors can activate thermoacoustic combustion instabilities. Convective instabilities are an important and yet less investigated class of combustion instability that are caused by the so called “entropy waves”. As a major shortcoming, the partial decay of these convective-diffusive waves in the post-flame region of combustors is still largely unexplored. This paper, therefore, presents an investigation of the annihilating effects, due to hydrodynamics, heat transfer and flow stretch upon the nozzle response. The classical compact analysis is first extended to include the decay of entropy waves and heat transfer from the nozzle. Amplitudes and phase shifts of the responding acoustical waves are then calculated for subcritical and supercritical nozzles subject to acoustic and entropic forcing. A relation for the stretch of entropy wave in the nozzle is subsequently developed. It is shown that heat transfer and hydrodynamic decay can impart considerable effects on the entropic response of the nozzle. It is further shown that the flow stretching effects are strongly frequency dependent. The results indicate that dissipation and dispersion of entropy waves can significantly influence their conversion to sound and therefore should be included in the entropy wave models.
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Published date: 1 August 2019
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Local EPrints ID: 509070
URI: http://eprints.soton.ac.uk/id/eprint/509070
ISSN: 0360-5442
PURE UUID: 9d6d95e9-8da2-48cc-b6eb-00e46e236516
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Date deposited: 10 Feb 2026 18:10
Last modified: 11 Feb 2026 03:18
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Author:
A. Fattahi
Author:
S.M. Hosseinalipour
Author:
N. Karimi
Author:
Z. Saboohi
Author:
F. Ommi
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