Litcius/Paper detail

Performance analysis of hybrid catalytic conversion of CO2 to DiMethyl ether

Hamid Reza Godini, Sanjay Ramesh Kumar, Nithin Tadikamalla, Fausto Gallucci

2021International Journal of Hydrogen Energy19 citationsDOIOpen Access PDF

Abstract

The performance of the single-step and sequential-steps catalytic CO2-hydrogenation to DiMethyl Ether (DME) was systematically analyzed. CuO–ZnO model-catalysts for CO2-hydrogenation to methanol were synthesized via different methods namely co-precipitation, sequential precipitation and precipitation-impregnation of the precursors. Moreover, co-precipitation and co-impregnation methods were applied to establish bifunctional catalytic structures composed of CuO–ZnO over HZSM-5 for direct CO2-hydrogenation to DME in a single-step. In addition, the performance of the catalytic bed made of sequential layered-arrangements of the CuO–ZnO and ZSM-5 catalysts as well as random mixture of these catalysts were also analyzed both experimentally as well as through the performed model-based study. It was observed that a faster conversion of the generated methanol to DME, secured by establishing a closer distance between the catalytic materials responsible for CO2-hydrogenation to methanol and methanol-dehydration to DME, will improve the overall selective CO2-conversion. This was demonstrated by obtaining the highest combined yield of methanol and DME products at the reactor outlet in those cases. Similarly, a bifunctional catalyst, for instance synthesized by co-impregnation method (made of 1:2 CuO–ZnO:ZSM-5), showed one of the most promising DME selectivity of 65% and DME yield of 12.5% under the highest reaction temperature of 260 °C, lowest tested GHSV of 200 h−1, and maximum operating pressure 20 bar for the lowest H2/CO2 ratio of 3.

Topics & Concepts

Dimethyl etherMethanolCatalysisBifunctionalSpace velocitySelectivityYield (engineering)Bifunctional catalystPrecipitationMaterials scienceChemical engineeringChemistryInorganic chemistryOrganic chemistryComposite materialEngineeringMeteorologyPhysicsCarbon dioxide utilization in catalysisCatalysts for Methane ReformingCarbon Dioxide Capture Technologies