Effect of ammonia addition on combustion characteristics of hydrogen/air using passive turbulent jet ignition

Hydrogen (H₂) and ammonia (NH₃) are ideal carbon-free fuels, and the application of NH₃/H₂ in internal combustion engines offers the potential to reduce carbon emissions. And turbulent jet ignition (TJI) is an advanced ignition strategy that can effectively enhance the combustion. This work aims to experimentally investigate the effect of NH₃ addition on the combustion characteristics of H₂/air mixtures under passive TJI conditions. Combustion images and instantaneous pressure were collected for processing and analysis. The effect of NH₃ substitution and equivalence ratio were investigated. The results indicate that the peak combustion pressure decreases with the addition of NH₃, accompanied by longer combustion duration and ignition delay, as well as lower jet velocity and flame area growth rate. The hot jet will be quenched by the strong heat transfer, causing the change in the ignition mechanism as the NH₃ substitution ratio increases. In addition, compared to lean conditions, the combustion appears to be less sensitive to the equivalence ratio on the rich side and always shows high jet velocity and flame propagation speed. However, a relatively small amount of NH₃ addition changes the ignition mechanism on the rich combustion side compared with lean conditions, resulting in a longer ignition delay.