Stud.IP Uni Oldenburg
Universität Oldenburg
04.12.2021 00:01:59
phy669 - Aeroelastic Simulation of Wind Turbines / Wind Physics Measurement Project (Vollständige Modulbeschreibung)
Originalfassung Englisch PDF Download
Modulbezeichnung Aeroelastic Simulation of Wind Turbines / Wind Physics Measurement Project
Modulkürzel phy669
Kreditpunkte 6.0 KP
Workload 180 h
Einrichtungsverzeichnis Institut für Physik
Verwendbarkeit des Moduls
  • Master Engineering Physics (Master) > European Wind Energy Master
Zuständige Personen
Kühn, Martin (Modulberatung)
Teilnahmevoraussetzungen
Wind Energy Utilization (Bachelor) or Wind Energy (Master), Design of Wind Energy Systems (parallel
Kompetenzziele
A student who has met the objectives of the course will be able to:
o understand the basic concept of an aero-servo-elastic computer code to determine the unsteady aerodynamic loads,
o derive and validate the required parameters to model the aero-hydro-elastic response of a wind turbine,
o identify and interpret the required empirical parameters to correct the blade element momentum (BEM) method with respect to dynamic inflow, unsteady airfoil aerodynamics (dynamic stall), yawed flow, dynamic wake modeling,
o explain the effects of the different models on the resulting time series and validate the code,
o interpret design standards for on- and offshore wind tur- bines, select the required load cases according to site-specific environmental data,
o identify the dimensioning load cases and calculate design loads for different main components of a wind turbine.
Modulinhalte
The course focuses on the practical implications and hands-on experience of the aero-hydro-servo-elastic modelling and simulation of wind turbines. The subjects are similar but the treatment is complementary to the parallel course ‘Design of Wind Energy Systems’, which deals with the underlying theoretical background:
o advanced wind field modelling for fatigue and extreme event loading,
o modelling of wind farm flow and wake effects,
o rotor aerodynamics (e.g. stationary or dynamic effects, comparison of Blade Element Momentum theory and more advanced methods like free vortex methods or CFD),
o structural dynamics and dynamic modelling of wind tur- bine structures (modelling by ordinary or partial differential equations, stochastics, multi body system modelling),
o advanced control of wind turbines,
o design standards, design loads and design aspects of offshore and onshore wind turbines.
The students analyse in pairs a model of an entire wind tur- bine with the aid of a typical wind turbine design tool like GH Bladed, Flex5 or Aerodyn/FAST.
Literaturempfehlungen
o T. Burton et. al.: Wind Energy Handbook. John Wiley, New York, 2nd ed., 2011
o R. Gasch, J. Twele: Wind Power Plants. Springer, Berlin, 2nd ed., 2011.
o Garrad Hassan, Bladed, Wind Turbine Design Software, Theory Manual
o Selected papers from e.g. Wind Energy Journal, Wiley Interscience
Links
Unterrichtssprache Englisch
Dauer in Semestern 1 Semester
Angebotsrhythmus Modul
Aufnahmekapazität Modul unbegrenzt
Modullevel / module level MM (Mastermodul / Master module)
Modulart / typ of module Pflicht / Mandatory
Lehr-/Lernform / Teaching/Learning method SE / Ü: 2 SWS
Vorkenntnisse / Previous knowledge
Prüfung Prüfungszeiten Prüfungsform
Gesamtmodul
1 Klausur oder
1 Referat oder
1 mündliche Prüfung oder
1 Hausarbeit oder
1 fachpraktische Übung
Lehrveranstaltungsform Vorlesung
SWS 4
Angebotsrhythmus SoSe oder WiSe
Workload Präsenzzeit 56 h