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An overview of modelling techniques is presented, emphasising the different scales for modelling: from molecular level to the whole plant/process scale. Multidisciplinary approach is underlined, as fuel cell modelling require a pure science background (material science, physics and chemistry) as well as an engineering one (transport phenomena, thermal and fluid dynamics). Last update: Paidar Martin (01.11.2022)
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From following this course students should be able to: • Discuss the mathematical tools that are required to simulate the operation and performances of a fuel cell system, including an overview on the equations to model the fundamental physical phenomena occurring inside the active layers (electrodes and electrolyte) of the electrochemical cell. • Explain methodological approaches that are required to design and simulate the performance of fuel cell or electrolyser systems. • Understand the modes of operation of a fuel cell and the operating principle(s) of single components comprised in a fuel cell system. • Display knowledge on how to perform energy systems analysis of fuel cell systems with a focus on stationary applications. Last update: Paidar Martin (01.11.2022)
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ISBN 0-471-49926-9 ff.) Last update: Paidar Martin (01.11.2022)
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1. Introduction on modelling of fuel cell systems 2. Thermodynamics and electrochemistry basic principles 3. Transport phenomena 4. Electrochemical modelling 5. PEMFC modelling 6. SOFCs modelling: multidimensional approach 7. SOFC stack and system modelling 8. Exercises on SOFC 9. Seminar on biogas-fed SOFC-based systems Last update: Paidar Martin (01.11.2022)
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Completing a course is an oral exam. The requirement for an oral exam is a graduation project calculation. Last update: Paidar Martin (01.11.2022)
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