Burner stabilized flames: Towards reliable experiments and modelling of transient combustion

In this work the diffusive-thermal pulsations of the burner stabilized methane-air flames are investigated experimentally, by analysing the OH* chemiluminescence signal, and numerically within the model with various detailed reaction mechanisms. The employment of the nitrogen co-flow configuration to isolate the flame from the surrounding air allows us to obtain the experimental data of high fidelity such that the difference between the numerical data calculated with different reaction mechanisms is greater then the experimental uncertainty, demonstrating that the proposed technique can be used to verify the reaction mechanisms. Sensitivity analyses are carried out and it is shown that the steady and pulsating regimes of combustion has different although partly overlapping subsets of most important elementary reactions, especially for the case of relaxational oscillations in which the combustion front exhibits stages close to quenching and re-ignition. The suggested configuration can thus be used to access transient combustionand to gain an additional information to verify mechanisms.

Automated summary

In this study, the diffusive-thermal pulsations of the burner stabilized methane-air flames were investigated through experimental and numerical analysis. The use of the nitrogen co-flow configuration isolated the flame and provided high-fidelity experimental data, allowing for the verification of reaction mechanisms. Sensitivity analysis revealed that steady and pulsating combustion have different important elementary reaction subsets, providing additional information for mechanism verification.