High hydrogen content syngas fuel burning in lean premixed spherical flames at elevated pressures: effects of preferential diffusion
High hydrogen content syngas fuel burning in lean premixed spherical flames at elevated pressures: effects of preferential diffusion
This study addresses the effects of preferential diffusion on flame structure and propagation of high hydrogen content (HHC) turbulent lean premixed hydrogen-carbon monoxide syngas flames at elevated pressures. The direct numerical simulations with detailed chemistry were performed in three-dimensional domain for expanding spherical flame configuration in a constant pressure combustion chamber. To identify the role of preferential diffusion on flame structure and propagation under low and high turbulence levels at elevated pressure, simulations were performed at an initial turbulent Reynolds number of 15 and 150 at a pressure value of 4bar. The results demonstrate that the thermo-diffusive instability greatly influences the lean premixed syngas cellular flame structure due to strong preferential diffusion effects under low turbulence level at elevated pressure. In contrast, the results reveal that the thermo-diffusive effects are destabilising and preferential diffusion is overwhelmed by turbulent mixing under high turbulence level at elevated pressure. This finding suggests that the development of cellular flame structure is dominated by turbulence with little or no contribution from the thermo-diffusive instability for the lean premixed syngas flame which operates under conditions of high turbulence and elevated pressures. However, results demonstrate that the flame acceleration and species diffusive flux are still influenced by the preferential diffusion for the lean premixed syngas flame which operates under conditions of high turbulence and elevated pressures.
18231-18249
Ranga Dinesh, K.K.J.
6454b22c-f505-40f9-8ad4-a1168e8f87cd
Shalaby, H.
aaa2a247-5995-4292-88ed-772b026dd369
Luo, K.H.
1c9be6c6-e956-4b12-af13-32ea855c69f3
van Oijen, J.A.
e6566136-6e12-416a-838f-2089a7ad8151
Thevenin, D.
7f50fca8-49b0-4182-9275-9e02255a1792
26 October 2016
Ranga Dinesh, K.K.J.
6454b22c-f505-40f9-8ad4-a1168e8f87cd
Shalaby, H.
aaa2a247-5995-4292-88ed-772b026dd369
Luo, K.H.
1c9be6c6-e956-4b12-af13-32ea855c69f3
van Oijen, J.A.
e6566136-6e12-416a-838f-2089a7ad8151
Thevenin, D.
7f50fca8-49b0-4182-9275-9e02255a1792
Ranga Dinesh, K.K.J., Shalaby, H., Luo, K.H., van Oijen, J.A. and Thevenin, D.
(2016)
High hydrogen content syngas fuel burning in lean premixed spherical flames at elevated pressures: effects of preferential diffusion.
International Journal of Hydrogen Energy, 41 (40), .
(doi:10.1016/j.ijhydene.2016.07.086).
Abstract
This study addresses the effects of preferential diffusion on flame structure and propagation of high hydrogen content (HHC) turbulent lean premixed hydrogen-carbon monoxide syngas flames at elevated pressures. The direct numerical simulations with detailed chemistry were performed in three-dimensional domain for expanding spherical flame configuration in a constant pressure combustion chamber. To identify the role of preferential diffusion on flame structure and propagation under low and high turbulence levels at elevated pressure, simulations were performed at an initial turbulent Reynolds number of 15 and 150 at a pressure value of 4bar. The results demonstrate that the thermo-diffusive instability greatly influences the lean premixed syngas cellular flame structure due to strong preferential diffusion effects under low turbulence level at elevated pressure. In contrast, the results reveal that the thermo-diffusive effects are destabilising and preferential diffusion is overwhelmed by turbulent mixing under high turbulence level at elevated pressure. This finding suggests that the development of cellular flame structure is dominated by turbulence with little or no contribution from the thermo-diffusive instability for the lean premixed syngas flame which operates under conditions of high turbulence and elevated pressures. However, results demonstrate that the flame acceleration and species diffusive flux are still influenced by the preferential diffusion for the lean premixed syngas flame which operates under conditions of high turbulence and elevated pressures.
Text
__soton.ac.uk_ude_PersonalFiles_Users_jkk1d12_mydocuments_RANGADINESH_SOTON2013TO2017_JournalPapersforEprints_2016_HE1_2016.doc
- Accepted Manuscript
More information
Accepted/In Press date: 12 July 2016
e-pub ahead of print date: 30 July 2016
Published date: 26 October 2016
Organisations:
Energy & Climate Change Group
Identifiers
Local EPrints ID: 400575
URI: http://eprints.soton.ac.uk/id/eprint/400575
ISSN: 0360-3199
PURE UUID: 11df6165-c527-4bf9-9c31-8806ea218ad1
Catalogue record
Date deposited: 19 Sep 2016 13:17
Last modified: 15 Mar 2024 05:54
Export record
Altmetrics
Contributors
Author:
H. Shalaby
Author:
K.H. Luo
Author:
J.A. van Oijen
Author:
D. Thevenin
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
