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Module code: EE1606 |
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4V (4 hours per week) |
5 |
Semester: 6 |
Mandatory course: yes |
Language of instruction:
German |
Assessment:
Written exam, duration: 90 minutes
[updated 26.01.2023]
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EE1606 (P212-0083) Energy system technology / Renewable energies, Bachelor, ASPO 01.10.2022
, semester 6, mandatory course
UI-T-WPV (P212-0083) Environmental Technologies, Bachelor, ASPO 01.10.2023
, semester 6, mandatory course
UI-T-WPV (P212-0083) Environmental Technologies, Bachelor, ASPO 01.10.2025
, semester 6, mandatory course
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60 class hours (= 45 clock hours) over a 15-week period. The total student study time is 150 hours (equivalent to 5 ECTS credits). There are therefore 105 hours available for class preparation and follow-up work and exam preparation.
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Recommended prerequisites (modules):
None.
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Recommended as prerequisite for:
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Module coordinator:
Prof. Dr. Marc Deissenroth-Uhrig |
Lecturer: Prof. Dr. Marc Deissenroth-Uhrig
[updated 08.03.2024]
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Learning outcomes:
After successfully completing this course, students will: - be able to explain the formation of wind, taking into account local characteristics - have mastered simple analytical methods and procedures for dimensioning wind turbines - have mastered the blade element method for the design of rotor blades based on experiments - be able to explain the use and procedure of flow simulation in rotor design - be able to explain the structural design of current drivetrains and developing trends - be able to explain current tower concepts - be able to explain the most important loads and structural stresses for pre-dimensioning - be able to name and explain the main electrical concepts used in the wind industry - be familiar with the control and regulation of wind turbines with regard to operational management - have mastered simple methods for the economic evaluation of wind turbines and possible locations - be able to name and explain the most important special features for the planning, construction and operation of offshore plants - be able to describe the structure and function of a solar cell - be able to explain the factors that influence efficiency with the help of semiconductor physics - be able to assess the degree of efficiency improvement in new cell developments - be able to analyze the electrical performance data of a PV system, identify the factors influencing its performance losses and propose solutions for improvement - be able to use simple analytical methods and procedures to design PV systems according to various system concepts and calculate the expected energy yield.
[updated 26.01.2023]
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Module content:
Wind energy - Wind formation and distribution - Physical principles of wind energy conversion ( Impulse Theory according to Betz) - Design structure of wind turbines - Rotor aerodynamics ( blade element method, CFD) - Mechanical drivetrain (structure, components) - Tower and foundation - Loads and structural stresses - Electrical system of a wind turbine - Control, regulation and operation management - Planning, construction and operation - Costs of wind turbines and economic efficiency - Offshore wind power Photovoltaics - The annual and daily cycle of solar irradiance - Introduction to the semiconductor physics of solar cells, - Design and mode of operation of solar cells, parameters that influence efficiency - Types of solar cells and development trends - Solar curves of modules and generators with - Influences of temperature, mismatching and partial shading on the system efficiency - Wiring concepts
[updated 26.01.2023]
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Teaching methods/Media:
Seminar-style teaching with integrated tutorials
[updated 26.01.2023]
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Recommended or required reading:
Gasch, Robert (Hrsg.): Windkraftanlagen, Springer Vieweg, (akt. Aufl.) Kaltschmitt, Martin (Hrsg.): Erneuerbare Energien, Springer, (akt. Aufl.) Mertens, Konrad: Photovoltaik, Hanser, (akt. Aufl.) Quaschning, Volker: Regenerative Energiesysteme, Hanser, (akt. Aufl.) Wagemann, Hans-Günther; Eschrich, Heinz: Photovoltaik, Vieweg + Teubner, 2010, 2. Aufl.
[updated 26.01.2023]
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