Vietnam Journal of Catalysis and Adsorption

Coated monolith/foam catalysts are promising materials for chemistry applications due to structured reactor configuratiions providing low expansion coefficient, good thermal stability and low pressure loss. In this study, powedered Ni(⁰)/La₂O₃ catalysts in perovskite structures, were deposited on cordierite monolith substrates (2MgO-2Al₂O₃-5SiO₂) by dip-coating method. The catalysts were characterized by N₂ adsorption, XRD, TPR-H₂ analysis. The activity of structured catalysts with various powder loadings (4, 8, 12, 20 and 30 wt %) were evaluated in combined Steam-CO₂ reforming reaction (CH₄/CO₂/H₂O = 2/1/2 vol%) at  GHSV = 60.000 h^-1. XRD and TPR results showed that the active phase LaNiO₃ were mainly Ni and La₂O₃distributed on the surface of cordierite channels after air calcination of 850^oC, 3 hours and  hydrogen reduction of 600^oC, 2 hours . The conversion of methane and CO₂ on monolith catalysts, with proper active sites loadings of 12 – 20 wt%, were close to 80 vol% at 800^oC. At the same reaction amount of active sites, the feedstock conversion on LaNiO₃/monolith (12 %wt LaNiO₃/monolith) was significantly higher than on corresponding powdered type, respectively 1.6 times of CH₄, 1.8 times of CO₂ conversion.

Perovskite/Monolith; CO2 Reforming; Steam Reforming; Methane; Syngas production

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