Pilot scale study of elevated pressure autothermal dry reforming of methane over Ni-UGSO pellets

Pilot scale study of elevated pressure autothermal dry reforming of methane over Ni-UGSO pellets

This work investigates syngas production via the auto-thermal dry reforming (ATDR) of methane under a pressures range of 1–10 bar over Nickle supported upgraded slag oxide pellets (Ni-UGSO) prepared from metallurgical residues. The effects of process parameters (i.e., reaction pressure, temperature,...

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Bibliographic Details
Main Authors: Muhammad Irfan Malik, Nicolas Abatzoglou, Jasmin Blanchard, Inès Esma Achouri
Format: Article
Language:English
Published: Elsevier 2025-07-01
Series:Journal of CO2 Utilization
Subjects:
Mining residue
Ni-UGSO pellet
Autothermal dry reforming of methane
Elevated pressure
Thermodynamic data
Online Access:http://www.sciencedirect.com/science/article/pii/S2212982025001052
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Summary:This work investigates syngas production via the auto-thermal dry reforming (ATDR) of methane under a pressures range of 1–10 bar over Nickle supported upgraded slag oxide pellets (Ni-UGSO) prepared from metallurgical residues. The effects of process parameters (i.e., reaction pressure, temperature, feed ratio, gas hourly space velocity, and O2 feed distribution) on methane conversion and syngas selectivity are also determined. The Ni-UGSO pellets consistently show resistance to coke formation owing to the excellent Ni dispersion in Al- and Fe-based spinels and Mg-rich silicates. The catalysts did not deactivate at pressures between 1–8 bar, and close to the equilibrium CH4 conversion (80 %) was achieved at 8 bar, CH4/O2 = 2, CH4/CO2 = 3, 850°C, and 800 GHSV (L/h.kg). The pellets exhibited high activity and stability by providing a nearly constant H2/CO ratio (∼1) for 8 h at 8 bar under autothermal conditions. However, further operation was unfeasible because the O2 feed line oxidized midway through the experiment at 850°C and 8 bar, highlighting challenges in maintaining material stability for elevated-pressure ATDR. The scanning electron microscope (SEM) and Transmission electron microscopy (TEM) analyses confirmed that, at 10 bar, a higher reactant concentration resulted in significant sintering, impacting both the active metal and support structure. This can be attributed to the higher extent of complete methane combustion, which generated excessive hotspots, decreased CO2 conversion to 15 %, and led to the thermal degradation of the catalyst. Thus, the oxygen and methane distribution should be set carefully to avoid uncontrolled total methane combustion during the elevated-pressure ATDR of methane.
ISSN:2212-9839

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