Wind Power Systems (4 cr)
Code: TE00BX17-3003
General information
Enrollment
01.06.2024 - 29.08.2024
Timing
02.09.2024 - 13.12.2024
Number of ECTS credits allocated
4 op
Mode of delivery
Contact teaching
Unit
Engineering and Business
Teaching languages
- Finnish
Degree programmes
- Degree Programme in Energy and Environmental Technology
Teachers
- Dominique Roggo
- Ossi Koskinen
Groups
-
PEYTES22
-
PEYTES21
- 16.09.2024 10:00 - 12:00, Wind Power Systems TE00BX17-3003
- 19.09.2024 10:00 - 12:00, Wind Power Systems TE00BX17-3003
- 23.09.2024 10:00 - 12:00, Wind Power Systems TE00BX17-3003
- 26.09.2024 10:00 - 12:00, Wind Power Systems TE00BX17-3003
- 30.09.2024 12:00 - 14:00, Wind Power Systems TE00BX17-3003
- 03.10.2024 10:00 - 12:00, Wind Power Systems TE00BX17-3003
- 07.10.2024 10:00 - 12:00, Wind Power Systems TE00BX17-3003
- 10.10.2024 14:00 - 16:00, Wind Power Systems TE00BX17-3003
- 28.10.2024 12:00 - 14:00, Wind Power Systems TE00BX17-3003
- 11.11.2024 12:00 - 14:00, Wind Power Systems TE00BX17-3003
- 14.11.2024 14:00 - 16:00, Wind Power Systems TE00BX17-3003
- 18.11.2024 12:00 - 14:00, Wind Power Systems TE00BX17-3003
- 21.11.2024 14:00 - 16:00, Wind Power Systems TE00BX17-3003
Objective
After completing the course, student will
- be able to calculate the maximal peak power and yearly energy available for a wind turbine in function of wind conditions
- Understand the principles for the transition from wind’s kinetic energy to rotor’s mechanic energy and to electrical grid
- know how a modern wind turbine is built and what is the role of the main components and specifications
- Understand the key techniques and factors for optimization of energy yields in function of wind speed, turbine rotating speed and blades angle
- Get a technical and economic overview of modern wind turbines topologies
Content
1. Introduction to modern wind energy conversion and markets
2. Power, force and yearly energy available in the wind for production of RE
3. Principle of conversion from wind’s kinetic energy to mechanical rotative energy (rotor)
4. Impact of rotating speed and blade angle control on energy yield
5. Description and evaluation of main wind turbine topologies
6. Noise assessment of wind power plant
7. Guiding rules for wind farm projects
8. Design and optimization of a wind turbine rotor (Simulation exercises)
9. Implementation and optimization of a wind energy farm (Simulation exercises)
Evaluation scale
H-5
Qualifications
Pre-requisities: Renewable energy production, Introduction to power electronics, Sähkövoimatekniikka ja sähköverkot