Litcius/Paper detail

On the adequacy of OH* as heat release marker for hydrogen–air flames

Francesco G. Schiavone, Andrea Aniello, Éléonore Riber, Thierry Schuller, Davide Laera

2024Proceedings of the Combustion Institute22 citationsDOIOpen Access PDF

Abstract

The correlation between the distributions of OH* and heat release rate (HRR) is numerically investigated for laminar and turbulent hydrogen–air flames. First, laminar premixed one-dimensional flames are considered, observing a peak shift between OH* and HRR regardless of the equivalence ratio or OH* sub-mechanism. Nevertheless, OH* and HRR well correlate for methane-hydrogen fuel mixtures, suggesting that the reasons for such peak shift are to be searched in the hydrogen flame intrinsic properties. In particular, the H-radical is pivotal, given its different role in the main OH* formation and HRR reaction pathways. The chain-branching nature of hydrogen oxidation enhances the formation of H-radical pool, leading to higher OH* production in the post-flame region, while HRR peaks upstream, being linked to the consumption of HO2 generated by the recombination reactions of back-diffused H-radicals. Methane oxidation, instead, is chain-terminating, hence H-consuming, releasing heat and preventing the radical pool formation in the post-flame zone. Similar analyses are then performed for strained counterflow diffusion hydrogen–air flames, where the OH* distribution shows to be, at least for strain levels not close to extinction, an adequate HRR marker. Indeed, differently from premixed flames, HRR is here found to be dominated by H direct consumption on the fuel side. The observations made for laminar one-dimensional flames are confirmed by Large Eddy Simulations (LES) of three-dimensional turbulent hydrogen–air diffusion and partially premixed flames, stabilized in the HYLON injector at IMFT laboratory. When compared with the experimental OH* field, LES-computed HRR correctly retrieves OH* position in the diffusion flame, while a mismatch in the axial direction is observed between the two distributions for the lifted partially premixed flame. An overall good match, instead, is observed between measured and LES-computed OH* fields, emphasizing the importance of including OH* kinetics to accurately compare simulations and experiments of multi-regime hydrogen–air flames.

Topics & Concepts

Laminar flowHydrogenDiffusion flameChemistryAnalytical Chemistry (journal)ThermodynamicsCombustionOrganic chemistryCombustorPhysicsCombustion and flame dynamicsAdvanced Combustion Engine TechnologiesFire dynamics and safety research