Course Manual FEM
Finite element method in electrical engineering
PDF Course Catalog Deutsche Version: FEM
Version: 2 | Last Change: 29.04.2022 18:23 | Draft: 0 | Status: vom verantwortlichen Dozent freigegeben
| Long name | Finite element method in electrical engineering |
|---|---|
| Approving CModule | SIM_MaET |
| Responsible |
Prof. Dr. Wolfgang Evers
Professor Fakultät IME |
| Valid from | summer semester 2021 |
| Level | Master |
| Semester in the year | summer semester |
| Duration | Semester |
| Hours in self-study | 78 |
| ECTS | 5 |
| Professors |
Prof. Dr. Wolfgang Evers
Professor Fakultät IME |
| Requirements | - Electrostatic: field strength, flux density, dielectrics - Electromagnetism: field strength, flux density, flux, magnetic circuits, induced voltage |
| Language | German |
| Separate final exam | No |
Literature
| Thomas Westermann, Modellbildung und Simulation |
| Thomas Westermann: Mathematik für Ingenieure |
Learning goals
| Goal type | Description |
|---|---|
| Skills | Discretisation of physical problems using the example of an electrostatic arrangement - One-dimensional model - Two-dimensional model - Replacement of partial derivatives by finite differences - Boundary conditions - Setting up the linear system of equations - Different methods for solving the system of equations - Result representation with interpolation - Use of boundary-fitted grids - Solving a two-dimensional electrostatic problem with FEM software - Exploiting symmetries in the simulation - Solving a two-dimensional magnetic problem with FEM software - Extending the magnetic problem to include non-linear material properties - Extension of the simulation by program-controlled variation of parameters and automatic output of characteristic diagrams with Python |
| Skills | Carry out and critically evaluate FEM simulations on various physical effects |
Expenditure classroom teaching
| Type | Attendance (h/Wk.) |
|---|---|
| Lecture | 2 |
| Exercises (whole course) | 2 |
| Exercises (shared course) | 0 |
| Tutorial (voluntary) | 0 |
Special requirements
| none |
| Accompanying material |
- electronic lecture slides for the lecture - electronic exercise task collection |
|---|---|
| Separate exam | Yes |
Separate exam
| Exam Type | EN andere studienbegleitende Prüfungsform |
|---|---|
| Details | The students independently solve tasks in which given physical arrangements are to be calculated with an FEM programme. Subsequently, a report is written in the form of a conference paper. The examinations during the course consist of three tasks with different scope and correspondingly different influence on the grade: 1. Simulation of two electrostatic arrangements. Exploitation of model symmetries. (20 %) 2. Simulation and optimisation of a magnetic arrangement with materials with linear and non-linear magnetisation characteristic. (20 %) 3. Automation of a simulation of a magnetic arrangement with Python and calculation of characteristics by parameter variation and output to a diagram. (60 %) Translated with www.DeepL.com/Translator (free version) |
| Minimum standard | - Functional simulation with physically meaningful results. - Comprehensible presentation of the results in the respective report. - Achievement of 50% of the total points to be awarded. |
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