%0 Journal Article %1 Huang2004239 %A Huang, Y. %A Sung, Chih-Jen %A Eng, J. A. %D 2004 %J Combustion and Flame %K Laminar Premixed combustion flame speed %N 3 %P 239 - 251 %R http://dx.doi.org/10.1016/j.combustflame.2004.08.011 %T Laminar flame speeds of primary reference fuels and reformer gas mixtures %U http://www.sciencedirect.com/science/article/pii/S0010218004001750 %V 139 %X The laminar flame speeds of neat primary reference fuels (PRFs), n-heptane and iso-octane, \PRF\ blends, reformer gas, and reformer gas/iso-octane/air mixtures are measured over a range of equivalence ratios at atmospheric pressure, using counterflow configuration and digital particle image velocimetry (DPIV). \PRF\ blends with various octane numbers are studied. The synthetic reformer gas mixture employed herein has a composition that would be produced from the partial oxidation of rich iso-octane/air mixture into \CO\ and H2, namely, 28% H2, 25% CO, and 47% N2. Computationally, the experimentally determined laminar flame speeds are simulated using the detailed kinetic models available in the literature. Both experimental and computational results demonstrate that the flame speeds of hydrocarbon/air mixtures increase with addition of a small amount of reformer gas, and the flame speeds of reformer gas/air mixtures are dramatically reduced with addition of a small amount of hydrocarbon fuel. Furthermore, the number density effect of seeding particles on flame speed measurement is assessed, and the experimental uncertainties associated with the present \DPIV\ setup as well as the linear extrapolation method employed herein are discussed.

@article{Huang2004239, abstract = {The laminar flame speeds of neat primary reference fuels (PRFs), n-heptane and iso-octane, \{PRF\} blends, reformer gas, and reformer gas/iso-octane/air mixtures are measured over a range of equivalence ratios at atmospheric pressure, using counterflow configuration and digital particle image velocimetry (DPIV). \{PRF\} blends with various octane numbers are studied. The synthetic reformer gas mixture employed herein has a composition that would be produced from the partial oxidation of rich iso-octane/air mixture into \{CO\} and H2, namely, 28% H2, 25% CO, and 47% N2. Computationally, the experimentally determined laminar flame speeds are simulated using the detailed kinetic models available in the literature. Both experimental and computational results demonstrate that the flame speeds of hydrocarbon/air mixtures increase with addition of a small amount of reformer gas, and the flame speeds of reformer gas/air mixtures are dramatically reduced with addition of a small amount of hydrocarbon fuel. Furthermore, the number density effect of seeding particles on flame speed measurement is assessed, and the experimental uncertainties associated with the present \{DPIV\} setup as well as the linear extrapolation method employed herein are discussed. }, added-at = {2014-01-06T13:11:51.000+0100}, author = {Huang, Y. and Sung, Chih-Jen and Eng, J. A.}, biburl = {https://www.bibsonomy.org/bibtex/208817f4a65e56f6f13913fb694a46241/rlanger}, doi = {http://dx.doi.org/10.1016/j.combustflame.2004.08.011}, interhash = {ac41d50eae0d0bc39243c25c28d5e8a3}, intrahash = {08817f4a65e56f6f13913fb694a46241}, issn = {0010-2180}, journal = {Combustion and Flame }, keywords = {Laminar Premixed combustion flame speed}, number = 3, pages = {239 - 251}, timestamp = {2014-01-09T18:27:12.000+0100}, title = {Laminar flame speeds of primary reference fuels and reformer gas mixtures }, url = {http://www.sciencedirect.com/science/article/pii/S0010218004001750}, volume = 139, year = 2004 }