Abstract
The results of carbon dioxide reforming of CH4 (model biogas) on catalysts prepared by solution combustion synthesis (SCS) and impregnation of moisture capacity methods are presented. Investigation of the activity of catalysts synthesized from initial mixtures of Co(NO3)2-Al(NO3)3-urea of different compositions was carried out for the production of synthesis-gas, and SCS and traditional incipient wetness impregnation catalyst preparation methods were compared. The methane conversion reached 100%, and the conversion of CO2 increased to 86.2%, while the yield of H2 and CO was 99.2% and 85.4%, respectively, at 900 °C. It was found that CoAl2O4 spinel formation was due to substitution of Al3+ with Co2+ cations. Consequently, CoAl2O4 lattice parameters increased, since the ionic radius of Al3+ (0.51 Å) less than Cο2+ (0.72 Å). Advantages of SCS catalysts in comparison with catalysts prepared by the traditional incipient wetness impregnation method in dry reforming of methane were shown. The aim of this work is to develop a new catalyst for the conversion of model biogas into synthesis gas, which will contribute to the organization of a new environmentally friendly, energy-saving production in the future.
Highlights
In recent years, an intensive study of the processes involving biogas as an alternative source for energy, and as a raw material for the production of petrochemicals, started throughout the world due to the inevitable exhaustion of non-renewable resources for energy generation and petrochemical production
The aim of this work is to develop new catalysts for the conversion of model biogas into synthesis gas, which will contribute to the organization of new environmentally friendly, energy-saving production in the future
This could only be explained by the reaction of carbon with metal oxides
Summary
An intensive study of the processes involving biogas as an alternative source for energy, and as a raw material for the production of petrochemicals, started throughout the world due to the inevitable exhaustion of non-renewable resources for energy generation and petrochemical production. Biogas resulting from the anaerobic fermentation of biomass and from any organic waste is a practically inexhaustible renewable resource for obtaining valuable products such as synthesis gas, hydrogen, and hydrocarbons. Even biogas of “low” quality is suitable for processing into valuable raw materials for power engineering and petrochemistry, making it possible to avoid expensive methods of production. Development of the scientific foundations of its use as a raw material for the production of liquid motor fuels and a number of other products seems to be an urgent task, since biogas is a renewable raw material [1,2,3,4]. Biogas is a very convenient component for its synthesis, since it contains both CH4 and CO2 reaction components
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