A numerical and comparative study of the laminar combustion characteristics and kinetics of dimethyl ether and ethanol flames at elevated temperature

Ethanol and DME are the most promising gasoline and diesel alternative fuels among biofuels. In the present study, we conducted a numerical and comparative study of the laminar burning velocity, chemical kinetics and flame instability of DME and ethanol premixed flames at P = 1 bar, T = 408 K and equivalence ratio of 0.8-1.4. The laminar burning velocity and adiabatic flame temperature of DME are higher than ethanol at all equivalence ratios. In addition, acetaldehyde and formaldehyde are the dominant intermediate product of ethanol and DME, respectively. The peak mole fraction of H + OH + CH3 radicals correlates nearly linearly with the laminar burning velocity. The rate-of-production of DME and ethanol suggests that CH3 + O = CH2O + H is the main reaction of CH3 consumption in both DME and ethanol flames. In addition, the reverse reaction of CH3 + O = CH2O + H is enhanced to inhibit the consumption of CH3 due to the high mole fraction of CH2O in DME, which is one of the reasons that the mole fraction of CH3 in DME flame is higher than in ethanol flame. Furthermore, the hydrodynamic and diffusional-thermal instability of DME are both stronger than ethanol because of thinner flame thickness, higher thermal expansion ratio and smaller effective Lewis number.

Automated summary

The study conducted numerical and comparative analysis of the laminar burning velocity, chemical kinetics, and flame instability of DME and ethanol premixed flames. The results showed that DME has higher burning velocity and adiabatic flame temperature compared to ethanol, with acetaldehyde and formaldehyde being the dominant intermediate products. The rate-of-production of DME and ethanol indicated that the main reaction of CH3 consumption is CH3 + O = CH2O + H in both flames. Additionally, the hydrodynamic and diffusional-thermal instability of DME were found to be stronger than ethanol due to various factors like flame thickness and thermal expansion ratio.