phy643 - Renewable Energy Technologies II for Engineering Physics (Vollständige Modulbeschreibung)
Modulbezeichnung | Renewable Energy Technologies II for Engineering Physics |
Modulkürzel | phy643 |
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 | |
Kompetenzziele | After successful completion of the module students should be able to: - critically evaluate and compare major Renewable Energy conversion processes and technologies in solar thermal energy and biomass energy, - analyze various system components and their interconnections within a complex Renewable Energy supply system, - evaluate the Renewable Energy supply systems' operational size and efficiency, - critically evaluate non-technical impact and side eects when implementing renewable energy supply systems. |
Modulinhalte | Solar Thermal Energy (Seminar and Exercises - 90 h workload) - Assessment of solar thermal ambient parameters: regional global, diffuse, reflected solar radiation on horizontal and on tilted plane, ambient temperature, - Solar thermal collectors, - Solar thermal heat exchangers, - Solar thermal storages, - Solar thermal systems and their operation, - Characterization of solar thermal systems. Biomass Energy (Lecture - 90 h workload) - Energy mix overview; gas, heat, electricity, Pros and Cons of biomass, - Chemical composition of biomass: sugar, cellulose, starch, fats. Oils, proteins, lignin, - Natural photosynthesis in plants: chemical storage of solar energy; general mechanisms, - Chemistry and Biology (microorganism) of Biogas Technology, - Conversion processes of biomass: classification, main pathways, - Introduction to catalysis used in biomass conversion, - Chemical fuels (chemical energy storage) from biomass, routes to platform chemicals and separation processes, - Technology concepts for bioenergy usage, - Introduction into economical and legal constraints. |
Literaturempfehlungen | Biomass Energy - R. Schlögl (Ed.), Chemical Energy Storage, De Gruyter, 2013, ISBN: 978-3-11-026407-4, Chapter 2, Pages 59-133, - D.L. Klass. Biomass for renewable energy, fuels, and chemicals, Chapter 4 Virgin Biomass Production, p. 91ff, - Food and Agriculture Organization of the UN (FAO) http://www.fao.org, - IEA Energy Technology Essentials - Biomass for Power Generation and CHP. http://www.iea.org/techno/essentials3.pdf, - R.A. Houghton, Forest Hall, and Scott J. Goetz. Importance of biomass in the global carbon cycle J. Geophys.Res., 114, 2009, - Schlögl, Robert (2013). Chemical energy storage (Elektronische Ressource] ed.). Berlin [u.a.]: De Gruyter., - Twidell and Weir. Renewable Energy Resources, Chapter 10, http://www.4shared.com/document/HpYwRDPy/Renewable_Energy_Resources_2nd.html,- Wheildon`s 2013, http://www.wheildons.co.uk/ wp-content/uploads/2013/07/carbon-neutral.jpg, - Waste-to-Energy Research and Technology Council(WtERT), 2009, http://www.wtert.eu/default.asp? Menue=13&ShowDok=12#Hydrolysis,Solar Thermal - DGS, (2010) Planning and installing solar thermal systems, a guide for installers, architects and engineers, 2nd ed., - Duffie JA, Beckman WA (2013) Solar engineering of thermal processes: Wiley, - Kasper, B., and Antony, F. (2004). Solarthermische Anlagen |
Links | |
Unterrichtssprache | Englisch |
Dauer in Semestern | 1 Semester |
Angebotsrhythmus Modul | Wintersemester |
Aufnahmekapazität Modul | unbegrenzt |
Modulart | Wahlpflicht / Elective |
Modullevel | MM (Mastermodul / Master module) |
Lehr-/Lernform | Lecture: 2 hrs/week and Seminar: 2 hrs/week |
Lehrveranstaltungsform | Kommentar | SWS | Angebotsrhythmus | Workload Präsenz |
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Vorlesung | 2 | SoSe oder WiSe | 28 | |
Seminar | 2 | SoSe oder WiSe | 28 | |
Übung | 2 | SoSe oder WiSe | 28 | |
Praktikum | 2 | SoSe oder WiSe | 28 | |
Präsenzzeit Modul insgesamt | 112 h |
Prüfung | Prüfungszeiten | Prüfungsform |
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Gesamtmodul | Referat |