Combustion of Iron Particles Suspension in Laminar Premixed and Diffusion Flames

In the work, the combustion regimes of iron particles (d(10) = 4.7 mu m) in a laminar pre-mixed flame (LPF) and in an axisymmetric laminar diffusion flame (LDF) are studied. For (LPF), we studied the effect of variations in gas suspension of the concentrations of fuel C-f = 0.4 divided by 0.6 kg/m(3) and oxygenC(O2) = 21 divided by 40%, and for (LDF), pure oxygen blowing and variation in the iron concentrationC(f) = 0.4 divided by 1.5 kg/m(3). The results of particle temperature measurements in the combustion zone of LPF and LDF, the dispersed and phase composition of the combustion products (depending on the concentration of fuel and oxidizer) are presented. It is shown that, under certain conditions, iron particles in LPF switch to a high-temperature diffusion mode of combustion. This mode is accompanied by intensification of gas-phase reactions and leads to a two-mode particle size distribution of combustion products. In this mode of combustion of a gas suspension (at temperatures much lower than the boiling point of iron), the mass yield of a nanoscale fraction of combustion products reaches tens of percent and increases with increasing oxygen concentration in LPF. This mode of iron particles combustion was not observed in LDF. The features of the thermal structure of the diffusion dust flame are analyzed. It is shown that in LDF the burning time of metal particles in the diffusion mode is proportional to the particle radius r(p) (root r(p) in the kinetic mode), and should depend on the concentration of fuel and the size of the burner.

Automated summary

This study investigates the combustion regimes of iron particles in a premixed flame and a diffusion flame. It is found that under certain conditions, the iron particles in the premixed flame can switch to a high-temperature diffusion mode of combustion, while this mode is not observed in the diffusion flame. In addition, gas-phase reactions are intensified, leading to an increase in the mass yield of nanoscale particles in the combustion products.