TY - GEN
T1 - A numerical analysis of the temperature field evolution during an optimization of the catalyst distribution in a steam reforming reactor
AU - Pajak, Marcin
AU - Kimijima, Shinji
AU - Szmyd, Janusz S.
N1 - Funding Information:
The present study was financially supported by AGH University of Science and Technology (Grant AGH No. 16.16.210.476). The numerical results were obtained by computational power provided by the PL-Grid infrastructure.
Publisher Copyright:
© ECOS 2021 - 34th International Conference on Efficency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems.
PY - 2021
Y1 - 2021
N2 - The steam reforming reaction is the most widespread method used for the hydrogen production. Both, for the industrial and small-scale applications. The reforming reaction has a strong endothermic character, meaning that it requires a constant heat supply to proceed. Due to the process’ character, a non-uniform temperature field is forming inside the reactor. The temperature gradients have an adverse influence on the reactor’s lifetime. The catalytic material is degrading rapidly as a consequence of occurring thermal stresses. The presented study addresses the given problem and proposes an optimization of the catalyst distribution as a solution. The catalytic material’s density and morphology are altered. Secondly, the catalyst is locally substituted with a non-reactive metallic foam to suppress the reaction and allow for reheating of the gaseous reactants. For the needs of the presented research an in-house numerical code simulating the reforming reaction is developed. The kinetics included in the code are derived basing on experimental analyses conducted by our team. The optimization procedure is prepared to limit the occurring temperature gradients, with no significant reduction in the overall process’ effectiveness.
AB - The steam reforming reaction is the most widespread method used for the hydrogen production. Both, for the industrial and small-scale applications. The reforming reaction has a strong endothermic character, meaning that it requires a constant heat supply to proceed. Due to the process’ character, a non-uniform temperature field is forming inside the reactor. The temperature gradients have an adverse influence on the reactor’s lifetime. The catalytic material is degrading rapidly as a consequence of occurring thermal stresses. The presented study addresses the given problem and proposes an optimization of the catalyst distribution as a solution. The catalytic material’s density and morphology are altered. Secondly, the catalyst is locally substituted with a non-reactive metallic foam to suppress the reaction and allow for reheating of the gaseous reactants. For the needs of the presented research an in-house numerical code simulating the reforming reaction is developed. The kinetics included in the code are derived basing on experimental analyses conducted by our team. The optimization procedure is prepared to limit the occurring temperature gradients, with no significant reduction in the overall process’ effectiveness.
KW - Hydrogen
KW - Kinetics
KW - Numerical analysis
KW - Optimization
KW - Reforming
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M3 - Conference contribution
AN - SCOPUS:85134418253
T3 - ECOS 2021 - 34th International Conference on Efficency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems
SP - 2078
EP - 2088
BT - ECOS 2021 - 34th International Conference on Efficency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems
PB - ECOS 2021 Program Organizer
T2 - 34th International Conference on Efficency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems, ECOS 2021
Y2 - 28 June 2021 through 2 July 2021
ER -