Investigation of the Effect of Hydrogen and Methane on Combustion of Multicomponent Syngas Mixtures using a Constructed Reduced Chemical Kinetics Mechanism

Resumen

This study investigated the effects of H₂ and CH₄ concentrations on the ignition delay time and laminar flame speed during the combustion of CH₄/H₂ and multicomponent syngas mixtures using a novel constructed reduced syngas chemical kinetics mechanism. The results were compared with experiments and GRI Mech 3.0 mechanism. It was found that mixture reactivity decreases and increases when higher concentrations of CH₄ and H₂ were used, respectively. With higher H₂ concentration in the mixture, the formation of OH is faster, leading to higher laminar flame speed and shorter ignition delay time. CH₄ and H₂ concentrations were calculated at different pressures and equivalence ratios, showing that at high pressures CH₄ is consumed slower, and, at different equivalence ratios CH₄ reacts at different temperatures. In the presence of H₂, CH₄ was consumed faster. In the conducted two-stage sensitivity analysis, the first analysis showed that H₂/CH₄/CO mixture combustion is driven by H₂-based reactions related to the consumption/formation of OH and CH₄ recombination reactions are responsible for CH₄ oxidation. The second analysis showed that similar CH₄-based and H₂ -based reactions were sensitive in both, methane- and hydrogen-rich H₂/CH₄ mixtures. The difference was observed for reactions CH₂O + OH = HCO + H₂O and CH₄ + HO₂ = CH₃ + H₂O₂, which were found to be important for CH₄-rich mixtures, while reactions OH + HO₂ = H₂O + O₂ and HO₂ + H = OH + OH were found to be important for H₂-rich mixtures.