Experimental measurements of n-heptane flame speeds behind reflected shock waves with variable extents of pre-flame auto-ignition chemistry

The flame speeds of premixed stoichiometric n-heptane/21% O2-79% Ar (so-called “airgon”) flames with different extents of pre-flame auto-ignition chemistry were experimentally investigated using an extended test-time, side-wall-imaging shock tube. n-Heptane/airgon mixtures were impulsively heated by...

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Bibliographic Details
Published in:Combustion and flame 2024-08, Vol.266, p.113539, Article 113539
Main Authors: Zheng, Lingzhi, Figueroa-Labastida, Miguel, Streicher, Jesse W., Ferris, Alison M., Hanson, Ronald K.
Format: Article
Language:English
Subjects:
Auto-ignition assisted flame
Laminar flame speed
Low-temperature chemistry
n-heptane
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Summary:The flame speeds of premixed stoichiometric n-heptane/21% O2-79% Ar (so-called “airgon”) flames with different extents of pre-flame auto-ignition chemistry were experimentally investigated using an extended test-time, side-wall-imaging shock tube. n-Heptane/airgon mixtures were impulsively heated by reflected shock waves to a temperature of 703 ± 8 K and pressure of 1.55 ± 0.05 atm, exhibiting first-stage auto-ignition at 20.1 ± 0.6 ms. Flames were spark-ignited using a laser from 0.45 ms to 39 ms after reflected-shock heating, thus probing the augmentation of flame speeds with variable extents of pre-flame auto-ignition chemistry. The fixed-initial-temperature experiments displayed multiple distinctive flame speed regimes across first-stage auto-ignition. A burned-gas flame speed (Sb0) increase of 6% was first observed with spark-ignition at ∼7 ms after reflected-shock heating. At spark-ignition timing very close to the first-stage auto-ignition, Sb0 displayed a sharp 24% rise, which then gradually declined to ∼10% above the reference value where pre-flame chemistry is negligible. Experiments were additionally performed at 1.55 ± 0.05 atm using two fixed spark-ignition timings (0.45 ms and 25 ms after reflected-shock heating) for initial temperatures between 641 K and 771 K. In the experiments with variable initial temperatures, a non-monotonic Sb0 dependence on initial temperature was observed for the 25-ms experiments, which showed a maximum Sb0 increase of 14% relative to the 0.45-ms experiments. To provide modeling comparisons, the thermochemical time history of the reacting gas was first simulated; the species profiles and the temperature at a given residence time were then used to obtain the flame speed from 1D steady-state simulations. The multi-regime flame speed behavior was not observed in fixed-initial-temperature simulations, which predicted a single rise in flame speed only near the first-stage auto-ignition time. The simulations with variable initial temperatures qualitatively recovered the non-monotonic flame speed trend, but generally showed underprediction of flame speeds relative to experimental results. These new experiments provide insight into the effect of pre-flame chemistry on flame propagation and offer targets for improving flame modeling, potentially aiding the development of next-generation engine concepts.
ISSN:0010-2180
DOI:10.1016/j.combustflame.2024.113539