Effects of turbulence on variations in early development of hydrogen and iso-octane flame kernels under engine conditions
Effects of turbulence on variations in early development of hydrogen and iso-octane flame kernels under engine conditions
The understanding and prediction of the early development of flame kernels are of high practical importance for the robust relight of aviation gas turbines and the control of cycle-to-cycle variations (CCV) of spark-ignition engines. CCV are known to correlate strongly with early flame kernel development and complicate the optimization of such engines in terms of safety, thermal efficiency, and engine emissions. The flame kernel initiated by a spark is initially small, in the very early combustion phase typically smaller than the size of the turbulent integral length scales. Therefore, the development of the flame kernel is dominated by local, intermittent flow fluctuations and can vary under the same nominal conditions. In this study, the effects of turbulence on the early development of premixed iso-octane and hydrogen turbulent flame kernels under realistic engine conditions are investigated through direct numerical simulations. Multiple realizations were simulated under the same nominal conditions for both fuels. Significant variations in flame kernel interactions with turbulence can be identified among different realizations. The fuel consumption rate varies by a factor of two, which is remarkable considering that only statistical differences in the local flow field are present between different realizations. Effects of different flow features of the initial flow fields on the flame kernel development were analyzed. It was found that the flow motion on the scale of the ignition radius, specifically the fluid deformation, which is characterized by the invariants of the strain rate tensor, determines the global shape of the kernel, while the variations of the kernel growth rate are mostly driven by the variations of the smallest turbulent scales. In particular, turbulence influences the flame surface area growth mainly through the tangential strain rate at the flame surface, which is shown to result from the small-scale turbulent motion. Due to differential diffusion effects, hydrogen and iso-octane exhibit significantly different flame responses to curvature, which is comprehensively studied for both fuels. The findings in this study will guide the development of combustion models that are capable to capture variations of the early flame kernels based on the local turbulence dissipation rate.
Cycle-to-cycle variation, DNS, Flame kernel, Hydrogen, Premixed flame, Turbulence
Chu, Hongchao
10bf0051-928b-4829-b069-f364ce0cc134
Berger, Lukas
d7eee085-2362-42c0-ba19-85d799b67367
Grenga, Temistocle
be0eba30-74b5-4134-87e7-3a2d6dd3836f
Gauding, Michael
1d43ad6b-4de3-416e-addb-8090abc52e46
Cai, Liming
a26ace37-15e2-4c9a-b917-57d753690d62
Pitsch, Heinz
3dc0eb6e-deca-4742-98a1-f0cdd62ff8b8
6 July 2023
Chu, Hongchao
10bf0051-928b-4829-b069-f364ce0cc134
Berger, Lukas
d7eee085-2362-42c0-ba19-85d799b67367
Grenga, Temistocle
be0eba30-74b5-4134-87e7-3a2d6dd3836f
Gauding, Michael
1d43ad6b-4de3-416e-addb-8090abc52e46
Cai, Liming
a26ace37-15e2-4c9a-b917-57d753690d62
Pitsch, Heinz
3dc0eb6e-deca-4742-98a1-f0cdd62ff8b8
Chu, Hongchao, Berger, Lukas, Grenga, Temistocle, Gauding, Michael, Cai, Liming and Pitsch, Heinz
(2023)
Effects of turbulence on variations in early development of hydrogen and iso-octane flame kernels under engine conditions.
Combustion and Flame, 255, [112914].
(doi:10.1016/j.combustflame.2023.112914).
Abstract
The understanding and prediction of the early development of flame kernels are of high practical importance for the robust relight of aviation gas turbines and the control of cycle-to-cycle variations (CCV) of spark-ignition engines. CCV are known to correlate strongly with early flame kernel development and complicate the optimization of such engines in terms of safety, thermal efficiency, and engine emissions. The flame kernel initiated by a spark is initially small, in the very early combustion phase typically smaller than the size of the turbulent integral length scales. Therefore, the development of the flame kernel is dominated by local, intermittent flow fluctuations and can vary under the same nominal conditions. In this study, the effects of turbulence on the early development of premixed iso-octane and hydrogen turbulent flame kernels under realistic engine conditions are investigated through direct numerical simulations. Multiple realizations were simulated under the same nominal conditions for both fuels. Significant variations in flame kernel interactions with turbulence can be identified among different realizations. The fuel consumption rate varies by a factor of two, which is remarkable considering that only statistical differences in the local flow field are present between different realizations. Effects of different flow features of the initial flow fields on the flame kernel development were analyzed. It was found that the flow motion on the scale of the ignition radius, specifically the fluid deformation, which is characterized by the invariants of the strain rate tensor, determines the global shape of the kernel, while the variations of the kernel growth rate are mostly driven by the variations of the smallest turbulent scales. In particular, turbulence influences the flame surface area growth mainly through the tangential strain rate at the flame surface, which is shown to result from the small-scale turbulent motion. Due to differential diffusion effects, hydrogen and iso-octane exhibit significantly different flame responses to curvature, which is comprehensively studied for both fuels. The findings in this study will guide the development of combustion models that are capable to capture variations of the early flame kernels based on the local turbulence dissipation rate.
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More information
Accepted/In Press date: 19 June 2023
e-pub ahead of print date: 6 July 2023
Published date: 6 July 2023
Additional Information:
Funding Information:
H.C. and H.P. acknowledge the funding by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) under Research Unit FOR2687 . L.B., T.G., and H.P. acknowledge the European Union’s Horizon 2020 research and innovation program under the Center of Excellence in Combustion (CoEC) project, grant agreement no. 952181 . The authors gratefully acknowledge the Gauss Centre for Supercomputing e.V. ( www.gauss-centre.eu ) for funding this project by providing computing time on the GCS Supercomputer Super-MUC at Leibniz Supercomputing Centre (LRZ, www.lrz.de ).
Funding Information:
H.C. and H.P. acknowledge the funding by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) under Research Unit FOR2687. L.B. T.G. and H.P. acknowledge the European Union's Horizon 2020 research and innovation program under the Center of Excellence in Combustion (CoEC) project, grant agreement no. 952181. The authors gratefully acknowledge the Gauss Centre for Supercomputing e.V. (www.gauss-centre.eu) for funding this project by providing computing time on the GCS Supercomputer Super-MUC at Leibniz Supercomputing Centre (LRZ, www.lrz.de).
Keywords:
Cycle-to-cycle variation, DNS, Flame kernel, Hydrogen, Premixed flame, Turbulence
Identifiers
Local EPrints ID: 483880
URI: http://eprints.soton.ac.uk/id/eprint/483880
ISSN: 0010-2180
PURE UUID: 16cb5254-ae97-4288-bbd7-4843e471ca55
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Date deposited: 07 Nov 2023 18:03
Last modified: 06 Jun 2024 02:16
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Contributors
Author:
Hongchao Chu
Author:
Lukas Berger
Author:
Temistocle Grenga
Author:
Michael Gauding
Author:
Liming Cai
Author:
Heinz Pitsch
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