Effects of the Equivalence Ratio and Reynolds Number on Turbulence and Flame Front Interactions by Direct Numerical Simulation

Abstract: Direct numerical simulation (DNS) of a two-dimensional premixed turbulent syngas flame (50% H 2 and 50% CO) was performed to investigate turbulence−flame interactions. An in-house DNS code, based on the low-Mach-number version of Navier−Stokes equations, was used to predict the influences of the equivalence ratio and Reynolds number on the turbulence−flame interactions using the constant volume enclosure method. The reaction between syngas and air was modeled with the Davis mechanism, which includes 14 species… Show more

“…This influence is mainly linked to the change of both the local properties of the reaction zone and the global behaviour of the combustion system associated with the flame propagation within spatial variations of the equivalence ratio [5]. Therefore, quantifications of this ratio are essential to sustain the higher stability of the combustion process and to minimize the soot emissions [6].…”

Lean partially premixed turbulent flame equivalence ratio measurements using laser-induced breakdown spectroscopy

“…This influence is mainly linked to the change of both the local properties of the reaction zone and the global behaviour of the combustion system associated with the flame propagation within spatial variations of the equivalence ratio [5]. Therefore, quantifications of this ratio are essential to sustain the higher stability of the combustion process and to minimize the soot emissions [6].…”

Lean partially premixed turbulent flame equivalence ratio measurements using laser-induced breakdown spectroscopy

Thermal analysis of high viscosity deicing fluid in the heating system

A DNS study on turbulence-chemistry interaction in lean premixed syngas flames