phy648 - Wind Resources and their Applications (Vollständige Modulbeschreibung)
Modulbezeichnung | Wind Resources and their Applications |
Modulkürzel | phy648 |
Kreditpunkte | 6.0 KP |
Workload | 180 h
( Attendance: 56 hrs, Self study: 124 hrs )
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Einrichtungsverzeichnis | Institut für Physik |
Verwendbarkeit des Moduls |
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Zuständige Personen |
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Teilnahmevoraussetzungen | Energy Meteorology |
Kompetenzziele | assess different aspects of wind energy farms by modelling, comparison, explanation of wind energy potential, wind energy farm’s output, power curves, wind energy project development, assess in detail influences of meteorological/ climatological aspects on the performance of wind power systems, summarize physical processes governing atmospheric wind flows, value atmospheric boundary layer flow relevant for wind power conversion, argue methods for wind resource assessment and forecasting |
Modulinhalte | Advanced Wind Energy Meteorology (Lecture – 90 h workload) Atmospheric Boundary Layer (turbulence, vertical structure, special BL effects) Atmospheric Flow Modelling: Linear models, RANS and LES models Wind farm modelling Offshore-Specific Conditions Resource Assessment and Wind Power Forecasting Wind Measurements and Statistics Wind Energy Applications - from Wind Resource to Wind Farm Operations (Lecture – 90 h workload) Evaluation of Wind Resources Weibull Distribution Wind velocity measurements to determine energy yield Basics of Wind Atlas Analysis and Application Program (WAsP) Method, Partial models using WAsP Measure-Correlate-Predict (MCP) Method of long term corrections of wind measurement data in correlation to long term reference data Conditions for stable, neutral and instable atmospheric conditions Wind yield from wind distribution and the power curve Basics in appraising the yearly wind yield from a wind turbine. Wake Effect and Wind Farm Recovery of original wind fields in the downstream of wind turbines Basics of Risø Models Spacing and efficiency in wind farms Positive and Negative Effects of Wind Farms Wind Farm Business Income from the energy yield from wind farms Profit optimization by increase of energy production Wind farm project development Wind farm operation and Surveillance of power production vs. wind climate, power curves, and turbine availability |
Literaturempfehlungen | Advanced Wind Energy Meteorology Holton, J.R. and G. J. Hakim, 2013: An Introduction to Dynamic Meteorology, 5th Edition, Academic Press, New York Stull, R.B., 1988: An Introduction to Boundary Layer Meteorology. Kluwer Academic Pub. Wind Energy Applications - from Wind Resource to Wind Farm Operations Burton, T., N. Jenkins, D. Sharpe and E. Bossanyi, 2011: Wind Energy Handbook, Second Edition, John Wiley. Gasch, R. and J. Twele, 2012: Wind Power Plants: Fundamentals, Design, Construction and Operation; Second Edition, Springer http://www.av8n.com/how/htm/airfoils.html, Last access: 4/2016 http://www.windpower.org/en/, Last access: 4/2016 |
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Unterrichtssprache | Englisch |
Dauer in Semestern | 1 Semester |
Angebotsrhythmus Modul | jährlich |
Aufnahmekapazität Modul | unbegrenzt |
Modulart | Wahlpflicht / Elective |
Modullevel | MM (Mastermodul / Master module) |
Lehr-/Lernform | Vorlesung: 4 SWS |
Vorkenntnisse | Knowledge in Basics Wind Energy, Fluid Dynamics I, Matlab |
Prüfung | Prüfungszeiten | Prüfungsform |
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Gesamtmodul | 1 Written examination: 120 minutes or Oral examination: Between 30 and 45 minutes or Internship report: Between 15 and 20 pages in one lecture and regular active participation in the other lecture |
Lehrveranstaltungsform | Vorlesung |
SWS | 4 |
Angebotsrhythmus | SoSe oder WiSe |
Workload Präsenzzeit | 56 h |