Plasma assisted conversion of biogas at atmospheric pressure supported by a DBD and the influence of additives on the product distribution

This thesis deals with the development and the improvement of an apparatus to convert methane and carbon dioxide in a plug flow reactor supported by a dielectric barrier discharge (DBD) at atmospheric pressure. Main criteria for assessing the process characteristic are the product composition, the conversion efficiency, and the total consumed energy defined in kJ/mol. Different concentrations of the simulated biogas components are used. The mixtures are diluted with helium as a buffered gas to 2.5%. The synthesis gas components (hydrogen and carbon dioxide), C2 hydrocarbons (ethane, ethene and acetylene) and oxygenates (methanol and formaldehyde) are the main products. The first part of this thesis deals with C2 hydrocarbons with ethane being the main product. The other two components are generated in lower concentrations. For all of these products, methane rich inlet flow, high plasma power (60 W), and low velocity of the gas stream (200 sccm) are favorable for the production of these products. An ethane product fraction between 2% and 6% is obtained with this setup. In the second part of this research work, the influence of additives as water and oxy-gen on the product distribution is analyzed. Two different kinds of experiments were performed. Firstly, the amount of the additives was fixed to 0.5% while the concentrations of the starting material methane and carbon dioxide as well as the plasma power are altered at a constant velocity of the gas flow. Secondly, the power and the composition of the inlet flow were fixed while the amount of the additives was changed. Extra amount of oxygen and water influences strongly the yield of oxygenates. After adding 0.6% water, the concentration of methanol increases by a factor of 3.8 and the formaldehyde yield rises by a factor of 2.8. Because water is an additional source of hydrogen the concentration of hydrogen increases as a result. In addition, methane is able to react with oxygen to carbon monoxide as shown in the increase of the CO yield. The ratio of the hydrogen yield to the carbon monoxide yield (H2:CO) is adjustable by adding water (H2:CO decreases) and oxygen (H2:CO increases).