Highly efficient reforming of toluene to syngas in a gliding arc plasma reactor

Plasma reforming is a promising technology to transform tars from biomass gasification into valuable fuels and chemicals. However, the key performance (tar conversion, gas yield and energy, efficiency) of the plasma tar reforming process can be significantly influenced by operating conditions such as the gas composition. In this study, the effect of CO2, steam and O-2 on the plasma reforming of toluene, a model tar compound, was investigated in a gliding arc (GA) reactor. Compared to the plasma reforming of toluene with N-2 the presence of oxidative gases (CO2, H2O and O-2) can generate a highly reactive plasma environment, thus creating new reaction pathways in the plasma conversion of toluene. The optimal content of CO2, H2O and O-2 to balance the toluene conversion, syngas yield and energy efficiency in the plasma reforming was 2 vol%, 4 vol% and 2 vol%, respectively, suggesting that the presence of an appropriate amount of oxidative gas (CO2, H2O and O-2) is important to maximize the key performance of the plasma reforming process. The highest toluene conversion of 78.3%, syngas yield of 73.9% and energy efficiency of 69.5 g/kWh were achieved simultaneously in the plasma reforming of toluene containing 4 vol% steam. The reaction pathways in the plasma reforming of toluene have been proposed through the analysis of gas and liquid products coupled with optical emission spectroscopic diagnostics.

Automated summary

The composition of gases has a significant impact on the key performance of plasma tar reforming process. The presence of oxidative gases can enhance the reactivity of plasma environment and create new reaction pathways. Optimal content of CO2, H2O, and O-2 can balance the conversion of toluene, syngas yield, and energy efficiency in plasma reforming.