Smart grids
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| Module title: | Seminar Intelligent Power Grids |
| Module level, if applicable | Master's degree |
| If applicable Abbreviation | |
| Subtitle, if applicable | |
| Courses, if applicable |
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| Semester of study: | Winter semester |
Module coordinator(s): | Prof. Dr.-Ing. Martin Braun |
Lecturer(s): | Prof. Dr.-Ing. Martin Braun and Paul Kaufmann |
| Language: German | German |
Assignment to the curriculum | Compulsory module: Specialization module: Elective module: Yes |
Teaching form/SWS: | 2 SWS: Seminar |
| Workload: | 90 h: 30 h attendance time 0 60 h self-study |
| Credit points: | 3 |
Recommended prerequisites: | Fundamentals of electrical engineering |
Intended learning outcomes | The student can independently - Conduct a literature research on a current topic from the field of intelligent power grids - Understand and evaluate models and simulation methods - Prepare scientific investigations and findings and present them in their own words - Document in scientific form and - Present Learning outcomes in relation to the course objectives: - Acquire in-depth knowledge in mathematical and scientific areas - Acquire in-depth knowledge of electrical engineering-specific fundamentals - Acquire extended and applied subject-specific fundamentals - Recognize and classify complex electrical engineering and interdisciplinary tasks - Confidently apply and evaluate analytical methods - Independently develop and evaluate solution methods - Familiarize yourself with new areas of knowledge, Conducting research and evaluating the results - In-depth and important experience in practical technical and engineering activities - Working and researching in national and international contexts |
Content: | Experiment 1: - Recording the characteristic curve of a solar module - Recording the characteristic curve of a solar module at different irradiance levels Experiment 2: - Temperature influence on the characteristic curve of a solar module - Influence of the tilt angle on the power output of a solar module - Recording a daily curve for summer and winter Experiment 3: - Series connection of solar modules - Parallel connection of solar modules - Shading of solar modules without bypass diode - Shading of solar modules with bypass diode Experiment 4: - Photovoltaic system in parallel grid operation - Measurement of inverter efficiency - Photovoltaic system in stand-alone grid operation Experiment 5: - PV grid integration using the example of a backup and hybrid system - Design of a PV system with a simulation program |
Study/examination achievements: | Form and duration: Literature research and preparation of a scientific topic, seminar paper, seminar presentation (approx. 45 minutes incl. discussion) |
Media forms: | Beamer, blackboard |
| Literature: | Current literature will be named in the lecture. |