3D-printing of metallic honeycomb monoliths as a doorway to a new generation of catalytic devices: the Ni-based catalysts in methane dry reforming showcase

3D-printing of metallic honeycomb monoliths as a doorway to a new generation of catalytic devices: the Ni-based catalysts in methane dry reforming showcase

Stainless-steel honeycomb monoliths (square cell-shape/230 cpsi cylinders) were 3D-printed and used as support of a Ni/CeO2-ZrO2 powder deposited by washcoating. The resulting catalysts were characterized by XRF, SEM-EDX and H2-TPR, and tested in the dry reforming of methane reaction. In the 750–900...

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Bibliographic Details
Published in:Catalysis communications Vol. 148; p. 106181
Main Authors: Agueniou, Fazia, Vidal, Hilario, de Dios López, Juan, Hernández-Garrido, Juan C., Cauqui, Miguel A., Botana, Francisco J., Calvino, José J., Galvita, Vladimir V., Gatica, José M.
Format: Journal Article
Language:English
Published: Elsevier B.V 05-01-2021
Elsevier
Subjects:
3D-printing
Ceria-Zirconia
Dry reforming of methane
Nickel
Stainless-steel honeycomb
Nickel
3D-printing
Ceria-Zirconia
Stainless-steel honeycomb
Dry reforming of methane
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Summary:Stainless-steel honeycomb monoliths (square cell-shape/230 cpsi cylinders) were 3D-printed and used as support of a Ni/CeO2-ZrO2 powder deposited by washcoating. The resulting catalysts were characterized by XRF, SEM-EDX and H2-TPR, and tested in the dry reforming of methane reaction. In the 750–900 °C range, they showed competitive conversions (45–95%) and H2/CO ratio (0.84–0.94) compared to cordierite honeycombs with same catalyst loading and geometric characteristics, but did not require activation time thanks to better heat transfer. Both structured catalysts were stable in prolonged TOS experiments. The bare metallic monoliths exhibited significant activity at 900 °C due to their intrinsic nickel content. [Display omitted] •Nickel catalyst onto 3D-printed stainless-steel honeycomb for methane dry reforming•3D-printed metal honeycomb overcomes cordierite for similar washcoat loading•Bare 3D-printed metal honeycomb is active at 900 °C due to its intrinsic Ni content•Surface roughness inherent in 3D-printing sums to the heat transfer assistance•Room for improvement via channel geometry control and adequate raw powder selection
ISSN:1566-7367
1873-3905
DOI:10.1016/j.catcom.2020.106181