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Data set for "Fluid Age-based Analysis of a Lifted Turbulent DME Jet Flame DNS"

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dc.contributor EPSRC - Engineering and Physical Sciences Research Council
dc.contributor Shin, Dong-hyuk
dc.creator Shin, Dong-hyuk
dc.creator Richardson, Edward
dc.creator Chen, Jacqueline
dc.date 2018-06-27T08:18:01Z
dc.date 2018-06-27T08:18:01Z
dc.date.accessioned 2023-02-17T20:53:48Z
dc.date.available 2023-02-17T20:53:48Z
dc.identifier Shin, Dong-hyuk; Richardson, Edward; Chen, Jacqueline. (2018). Data set for "Fluid Age-based Analysis of a Lifted Turbulent DME Jet Flame DNS", [dataset]. https://doi.org/10.7488/ds/2368.
dc.identifier https://hdl.handle.net/10283/3108
dc.identifier https://doi.org/10.7488/ds/2368
dc.identifier.uri http://localhost:8080/xmlui/handle/CUHPOERS/244149
dc.description The link between the distribution of fluid residence time and the distribution of reactive scalars is analysed using Direct Numerical Simulation data. Information about the reactive scalar distribution is needed in order to model the reaction terms that appear in Large Eddy and Reynolds-Averaged simulations of turbulent reacting flows. The lifted flame is simulated taking account of multi-step chemistry for dimethyl-ether fuel. Due to autoignition and flame propagation, the reaction progress increases with residence time. The variation of fluid residence time is evaluated by solving an Eulerian transport equation for the fluid age. The fluid age is a passive scalar with a spatially-uniform source term, meaning that its moments and dissipation rates in turbulent flows can be modelled using closures already established for conserved scalars such as mixture fraction. In combination with the mixture fraction, the fluid age serves as a useful mapping variable to distinguish younger less-reacted fluid near the inlet from older more-reacted fluid downstream. The local fluctuations of mixture fraction and fluid age have strong negative correlation and, building upon established presumed-pdf models for mixture fraction, this feature can be used to construct an accurate presumed-pdf model for the joint mixture fraction/fluid age pdf. It is demonstrated that the double-conditional first-order moment closure combined with the proposed presumed model for the joint pdf of mixture fraction and fluid age gives accurate predictions for unconditional reaction rates – both for pre-ignition radical species produced by low-temperature processes upstream of the flame base, and for major species that are produced at the flame front.
dc.format application/zip
dc.format text/plain
dc.language eng
dc.relation Dong-Hyuk Shin, Edward S. Richardson, Vlad Aparace-Scutariu, Yuki Minamoto, and Jacqueline H. Chen, "Fluid Age-based Analysis of a Lifted Turbulent DME Jet Flame DNS", Proceedings of the Combustion Institute, 2019.
dc.rights Creative Commons Attribution 4.0 International Public License
dc.subject turbulence
dc.subject autoignition
dc.subject presumed pdf
dc.subject residence time
dc.subject Engineering::Automotive Engineering
dc.title Data set for "Fluid Age-based Analysis of a Lifted Turbulent DME Jet Flame DNS"
dc.type dataset


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