Experimental and Numerical Investigations of Soot Formation in the Laminar to Turbulent Transition of an Acetylene Diffusion Flame.

Abstract

Soot formation from incomplete hydrocarbon combustion poses significant challenges for emission control in propulsion systems. This study employed experimental and numerical methods to investigate the transition process of the acetylene diffusion flame from laminar to turbulent flows, with particular focus on the evolutions of the soot formation rate (<i>ṁ</i> _soot), flame temperature (<i>T</i>), and sound pressure level (SPL). Results from different regimes indicate the following: (1) In the laminar state, <i>ṁ</i> _soot increased linearly with <i>Re</i>, with a growth rate positively correlated with the tube diameter. (2) After entering the transitional state, <i>ṁ</i> _soot decreased exponentially by over 95%; <i>T</i> gradually increased by 150 K; and both SPL and the standard deviation of <i>T</i> (σ _<i>T</i> ) initially rose and then declined. (3) After entering the fully turbulent state, SPL increased again whereas σ _<i>T</i> stabilized at 14. When <i>Re</i> was decreased from the critical value at the occurrence of lift-off, the lifted flame could be maintained within the fully turbulent region (named as the reverse lifted flame) and ended upon entering the transitional region. <i>ṁ</i> _soot of the reverse lifted flame was about 2 to 3 times that of the attached flame, which was due to the enhanced O₂ entrainment from the bottom of the flame.