Modelling and Optimisation of Fuel Cell Systems
2022/2023
Recommended prerequisite for participation in the module
The module is based on knowledge achieved when studying the 1st semester on the Master of Science in Energy Engineering on one of the Thermal Energy Engineering specialisations or similar.Content, progress and pedagogy of the module
Learning objectives
Knowledge
- Have knowledge about the design, modelling and optimisation of energy systems used in various energy production applications involving fuel cell technology
- Have knowledge about and comprehension of the detailed operation, functionality and interaction between the various components used in fuel cell- and hydrogen production systems
- Have knowledge needed to construct and operate fuel cell based technologies in the laboratory and in real applications
Skills
- Be able to have analytical skills in system integration with respect to system efficiency and control aspects of fuel cell energy systems
- Be able to judge the usefulness of the used different scientific methods for analysis and modelling of fuel cell and hydrogen systems
- Be able to verify the analytical and numerical approaches by means of laboratory experiments
- Be able to evaluate the optimisation procedures used for fuel cell and hydrogen systems
Competences
- Be able to control the working and development process within the project theme, and be able to develop new solutions within fuel cell and hydrogen systems
- Be able to independently define and analyse scientific problems in the area of fuel cells and hydrogen systems
Type of instruction
Problem based project oriented project work in groups. The semester focuses on modelling and optimisation of a physical fuel cell or hydrogen based system. The semester project serves to give the students an advanced comprehension of systems based upon fuel cells and hydrogen technology. The fundamental competence within thermodynamics and control engineering within these systems are established. The students must develop a non-linear dynamical model of a system – for instance using block diagrams as in Simulink. Simultaneously, a data acquisition and control system is developed in for instance the Labview real time system through which basic analogical data acquisition and control is interconnected.
Extent and expected workload
Since it is a 15 ECTS project module, the work load is expected to be 450 hours for the student
Exam
Exams
| Name of exam | Modelling and Optimisation of Fuel Cell Systems |
| Type of exam | Oral exam based on a project |
| ECTS | 15 |
| Assessment | 7-point grading scale |
| Type of grading | External examination |
| Criteria of assessment | The criteria of assessment are stated in the Examination Policies and Procedures |
Additional information
Project on 2nd semester Fuel Cells and Hydrogen Technology.
Facts about the module
| Danish title | Modellering og optimering af brændselscellesystemer |
| Module code | N-EE-K2-2 |
| Module type | Project |
| Duration | 1 semester |
| Semester | Spring
|
| ECTS | 15 |
| Language of instruction | English |
| Empty-place Scheme | Yes |
| Location of the lecture | Campus Aalborg |
| Responsible for the module | |
| Time allocation for external examiners | B |
Organisation
| Study Board | Study Board of Energy |
| Department | Department of Energy |
| Faculty | The Faculty of Engineering and Science |
