State prediction of an entropy wave advecting through a turbulent channel flow
State prediction of an entropy wave advecting through a turbulent channel flow
Survival of entropy waves during their advection throughout a combustor is central to the generation of entropic sound and the subsequent effects upon thermoacoustic stability of the system. However, the decay and spatial non-uniformity of entropy waves are largely ignored by the existing models used for the calculation of entropy noise generation. Recent investigations have demonstrated the complex spatio-temporal dynamics of entropy waves and cast doubts on the sufficiency of the one-dimensional approach, conventionally used for the analysis of these waves. Hence, this paper proposes a novel approach to the low-order modelling of entropy wave evolution wherein the wave is described by the two states of position and amplitude in the streamwise direction. A high-order model is first developed through direct numerical simulation of the advection of entropy waves in a fully developed, heat transferring, compressible, turbulent channel flow. The data are then utilised to build and validate a series of nonlinear, low-order models that provide an unsteady two-dimensional representation of the decaying and partially annihilating entropy waves. It is shown that these models need, at most, approximately 12.5% of the total trace of entropy wave advection to predict the wave dynamics accurately. The results further reveal that the existing linear low-order models are truly predictive only for the entropy waves with less than 2% increase in the gas temperature compared to that of the surrounding flow. Yet, in agreement with the assumption of existing models, it is shown that entropy waves travel with the mean flow speed.
Christodoulou, Loizos
de7c82a5-af71-4087-aaa6-38c22740b4b9
Karimi, Nader
7c0d67c7-7aa4-40db-9a05-5cde85933fdc
Cammarano, Andrea
c0c85f55-3dfc-4b97-9b79-e2554406a12b
Paul, Manosh
fbb523c5-ff1d-4609-8327-0175d3c9e5b3
Navarro-Martinez, Salvador
9ea4b95c-0c53-43a4-99e8-4cbfa6a53b7d
10 January 2020
Christodoulou, Loizos
de7c82a5-af71-4087-aaa6-38c22740b4b9
Karimi, Nader
7c0d67c7-7aa4-40db-9a05-5cde85933fdc
Cammarano, Andrea
c0c85f55-3dfc-4b97-9b79-e2554406a12b
Paul, Manosh
fbb523c5-ff1d-4609-8327-0175d3c9e5b3
Navarro-Martinez, Salvador
9ea4b95c-0c53-43a4-99e8-4cbfa6a53b7d
Christodoulou, Loizos, Karimi, Nader, Cammarano, Andrea, Paul, Manosh and Navarro-Martinez, Salvador
(2020)
State prediction of an entropy wave advecting through a turbulent channel flow.
Journal of Fluid Mechanics, 882, [A8].
(doi:10.1017/jfm.2019.799).
Abstract
Survival of entropy waves during their advection throughout a combustor is central to the generation of entropic sound and the subsequent effects upon thermoacoustic stability of the system. However, the decay and spatial non-uniformity of entropy waves are largely ignored by the existing models used for the calculation of entropy noise generation. Recent investigations have demonstrated the complex spatio-temporal dynamics of entropy waves and cast doubts on the sufficiency of the one-dimensional approach, conventionally used for the analysis of these waves. Hence, this paper proposes a novel approach to the low-order modelling of entropy wave evolution wherein the wave is described by the two states of position and amplitude in the streamwise direction. A high-order model is first developed through direct numerical simulation of the advection of entropy waves in a fully developed, heat transferring, compressible, turbulent channel flow. The data are then utilised to build and validate a series of nonlinear, low-order models that provide an unsteady two-dimensional representation of the decaying and partially annihilating entropy waves. It is shown that these models need, at most, approximately 12.5% of the total trace of entropy wave advection to predict the wave dynamics accurately. The results further reveal that the existing linear low-order models are truly predictive only for the entropy waves with less than 2% increase in the gas temperature compared to that of the surrounding flow. Yet, in agreement with the assumption of existing models, it is shown that entropy waves travel with the mean flow speed.
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Accepted/In Press date: 30 September 2019
e-pub ahead of print date: 6 November 2019
Published date: 10 January 2020
Identifiers
Local EPrints ID: 490832
URI: http://eprints.soton.ac.uk/id/eprint/490832
ISSN: 0022-1120
PURE UUID: f7cafebf-4c6c-4c6d-a138-56697e9df093
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Date deposited: 06 Jun 2024 17:11
Last modified: 07 Jun 2024 02:08
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Contributors
Author:
Loizos Christodoulou
Author:
Nader Karimi
Author:
Andrea Cammarano
Author:
Manosh Paul
Author:
Salvador Navarro-Martinez
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