Maximization of hydrogen production via methane steam reforming in a wavy microreactor by optimization of catalyst coating: a combined computational and data analytics approach
Maximization of hydrogen production via methane steam reforming in a wavy microreactor by optimization of catalyst coating: a combined computational and data analytics approach
This study introduces an advanced methodology for optimizing catalytic coatings on microreactor walls used in the steam reforming of methane. By integrating computational fluid dynamics, data analytics, and multiobjective optimization, this approach significantly intensifies the process, reduces catalyst usage, and improves the economic and environmental aspects of hydrogen production. The challenge of identifying ideal catalytic coatings is addressed by employing surrogate functions created by extensive data sets from computational fluid dynamics and machine learning. These surrogate functions are rigorously validated, achieving 99.9% accuracy for both the total H2 production rate and the H2 production rate per coated surface area. The optimal catalyst coating demonstrates a 65.8% increase in the H2 production rate per coated surface area, yet a 9% increase in total entropy generation compared to a fully coated channel. These findings underscore significant opportunities to enhance the cost-effectiveness and sustainability of future microreactors through the optimization of discrete catalytic coatings.
18599-18614
Esfandiary, Mohsen
e59ddc54-2386-4f2e-bdc5-b0708d973134
Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
Saedodin, Seyfolah
7dfdfd79-4ead-424b-b9f7-4077a4f77eb9
30 October 2024
Esfandiary, Mohsen
e59ddc54-2386-4f2e-bdc5-b0708d973134
Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
Saedodin, Seyfolah
7dfdfd79-4ead-424b-b9f7-4077a4f77eb9
Esfandiary, Mohsen, Karimi, Nader and Saedodin, Seyfolah
(2024)
Maximization of hydrogen production via methane steam reforming in a wavy microreactor by optimization of catalyst coating: a combined computational and data analytics approach.
Industrial & Engineering Chemistry Research, 63 (43), .
(doi:10.1021/acs.iecr.4c02467).
Abstract
This study introduces an advanced methodology for optimizing catalytic coatings on microreactor walls used in the steam reforming of methane. By integrating computational fluid dynamics, data analytics, and multiobjective optimization, this approach significantly intensifies the process, reduces catalyst usage, and improves the economic and environmental aspects of hydrogen production. The challenge of identifying ideal catalytic coatings is addressed by employing surrogate functions created by extensive data sets from computational fluid dynamics and machine learning. These surrogate functions are rigorously validated, achieving 99.9% accuracy for both the total H2 production rate and the H2 production rate per coated surface area. The optimal catalyst coating demonstrates a 65.8% increase in the H2 production rate per coated surface area, yet a 9% increase in total entropy generation compared to a fully coated channel. These findings underscore significant opportunities to enhance the cost-effectiveness and sustainability of future microreactors through the optimization of discrete catalytic coatings.
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Accepted/In Press date: 8 October 2024
e-pub ahead of print date: 21 October 2024
Published date: 30 October 2024
Identifiers
Local EPrints ID: 509413
URI: http://eprints.soton.ac.uk/id/eprint/509413
ISSN: 0888-5885
PURE UUID: 411b9258-c182-47c2-891d-c47194195058
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Date deposited: 20 Feb 2026 17:47
Last modified: 21 Feb 2026 03:25
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Contributors
Author:
Mohsen Esfandiary
Author:
Nader Karimi
Author:
Seyfolah Saedodin
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