LAPSE:2025.0161v1
Published Article
LAPSE:2025.0161v1
A 2D Axisymmetric Transient State CFD Modelling of a Fixed-bed Reactor for Ammonia Synthesis
June 27, 2025
Abstract
Power-to-Ammonia technology offers sustainable pathways for energy storage and chemical production, with fixed-bed reactors being critical components for efficient synthesis. Understanding reactor dynamics under varying conditions is essential for optimizing these systems, particularly when integrated with intermittent renewable energy sources. This study aims to develop and validate a 2D axisymmetric CFD model for analysing the dynamic response of a ruthenium-catalysed ammonia synthesis reactor to thermal perturbations. The model incorporates detailed reaction kinetics, multicomponent mass transport, and heat transfer mechanisms to predict system behaviour under transient conditions. Results reveal that a step increase in wall temperature from 400°C to 430°C enhances NH3 concentration by 136% (from 2.2 to 5.1 vol.%), with rapid system stabilization achieved within 0.5 seconds. The thermals response maintains consistent heat transfer patterns, exhibiting ~400K differentials between inlet and maximum temperature zones
Power-to-Ammonia technology offers sustainable pathways for energy storage and chemical production, with fixed-bed reactors being critical components for efficient synthesis. Understanding reactor dynamics under varying conditions is essential for optimizing these systems, particularly when integrated with intermittent renewable energy sources. This study aims to develop and validate a 2D axisymmetric CFD model for analysing the dynamic response of a ruthenium-catalysed ammonia synthesis reactor to thermal perturbations. The model incorporates detailed reaction kinetics, multicomponent mass transport, and heat transfer mechanisms to predict system behaviour under transient conditions. Results reveal that a step increase in wall temperature from 400°C to 430°C enhances NH3 concentration by 136% (from 2.2 to 5.1 vol.%), with rapid system stabilization achieved within 0.5 seconds. The thermals response maintains consistent heat transfer patterns, exhibiting ~400K differentials between inlet and maximum temperature zones
Record ID
Keywords
Alternative Fuels, Ammonia Synthesis, Computational Fluid Dynamics, Dynamic Modelling, Process Intensification
Subject
Suggested Citation
Bravo L, Rengifo C, Cobo M, Figueredo M. A 2D Axisymmetric Transient State CFD Modelling of a Fixed-bed Reactor for Ammonia Synthesis. Systems and Control Transactions 4:67-72 (2025) https://doi.org/10.69997/sct.158817
Author Affiliations
Bravo L: Energy, Materials and Environment Laboratory, Faculty of Engineering, Universidad de La Sabana, Campus Universitario Puente del Común, Km. 7 Autopista Norte, Bogotá, Colombia
Rengifo C: Department of Mathematics, Physics and Statistics, Universidad de La Sabana, Campus Universitario Puente del Común, Km. 7 Autopista Norte, Bogotá, Colombia
Cobo M: Energy, Materials and Environment Laboratory, Faculty of Engineering, Universidad de La Sabana, Campus Universitario Puente del Común, Km. 7 Autopista Norte, Bogotá, Colombia
Figueredo M: Energy, Materials and Environment Laboratory, Faculty of Engineering, Universidad de La Sabana, Campus Universitario Puente del Común, Km. 7 Autopista Norte, Bogotá, Colombia
Rengifo C: Department of Mathematics, Physics and Statistics, Universidad de La Sabana, Campus Universitario Puente del Común, Km. 7 Autopista Norte, Bogotá, Colombia
Cobo M: Energy, Materials and Environment Laboratory, Faculty of Engineering, Universidad de La Sabana, Campus Universitario Puente del Común, Km. 7 Autopista Norte, Bogotá, Colombia
Figueredo M: Energy, Materials and Environment Laboratory, Faculty of Engineering, Universidad de La Sabana, Campus Universitario Puente del Común, Km. 7 Autopista Norte, Bogotá, Colombia
Journal Name
Systems and Control Transactions
Volume
4
First Page
67
Last Page
72
Year
2025
Publication Date
2025-07-01
Version Comments
Original Submission
Other Meta
PII: 0067-0072-1222-SCT-4-2025, Publication Type: Journal Article
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LAPSE:2025.0161v1
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https://doi.org/10.69997/sct.158817
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Jun 27, 2025
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References Cited
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