Study on the Mechanism of Soot Inhibition in Methanol-Ethylene Mixed Combustion Under High-Pressure Conditions

Soot particle emitted during the combustion of hydrocarbon fuels in power equipment is one of the major causes of urban smog, which brings serious harm to human health, so reducing soot emission is a hot topic in the field of combustion research. This study employs the Laser-Induced Incandescence (LII) flame diagnostics to measure soot volume fraction (SVF) and investigates the effects of methanol addition on flame morphology and SVF in a co-flow diffusion flame of ethylene under high-pressure conditions. Kinetic simulations are used to study the mechanisms by which methanol inhibits soot formation and the effects of reaction pressure on soot formation. The results show that as the methanol blending ratio increases, the blue region of the flame becomes more pronounced, and the flame brightness decreases. As pressure increases, the flame becomes taller and narrower, the bright yellow region expands, and the flame becomes brighter. At the same pressure, the SVF in the flame decreases linearly with increasing methanol blending ratio. At the same methanol blending ratio, the SVF increases quadratically with increasing pressure, the soot distribution area expands, and soot appears earlier. Numerical analysis reveals that adding methanol to the ethylene flame reduces the mole fractions of radicals such as H and OH during the reaction, lowers the reaction rates of elementary reactions in the pathway converting ethylene to benzene (A1), which reduces the mole fractions of key soot-forming substances such as C2H2, C3H3, and A1, and hinders the dehydrogenation of A1. This suppresses the formation of large molecular soot precursors from A1, leading to a reduction in soot formation. Reaction pressure has a minor effect on the primary reaction pathways for soot formation during ethylene combustion, but increasing the reaction pressure raises the concentration of reactants, significantly enhancing the reaction rates of key elementary reactions. This increases the mole fractions of key soot-forming substances, ultimately resulting in an increase in soot formation.

Keywords: ethylene, Methanol, Soot Particles, High Pressure, Co-flow Diffusion Combustion

Suggested Citation: Suggested Citation

Shi, Jun and Yang, Pan and Ren, Xuemei and Yang, Xudong and YAN, HUI and Tan, Yu and Lei, Zhenzhen, Study on the Mechanism of Soot Inhibition in Methanol-Ethylene Mixed Combustion Under High-Pressure Conditions. Available at SSRN: https://ssrn.com/abstract=4994507 or http://dx.doi.org/10.2139/ssrn.4994507