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Sustainable Energy Technology. Sustainable energy and our society. Global warming Depletion of fossil fuels Very large time scales We have to take our responsibility for our future now!. Simulation with climate model. Fossil fuel reserves. Proven reserves Coal: 250 year Oil: 50 year
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Sustainable energy and our society • Global warming • Depletion of fossil fuels • Very large time scales We have to take our responsibility for our future now!
Fossil fuel reserves • Proven reserves • Coal: 250 year • Oil: 50 year • Natural gas: 60 year Possible reserves: 500 year (based on the present consumption )
Fossil fuels • Global warming • Rise of the sea level Kyoto protocol 1997: • Industrialised countries • Reduction of green house gases 2008-2012 with 5% (1990) Sustainable energy
Sustainable energy in the Netherlands • The Dutch targets for the year 2020 • 2% reduction in energy consumption per year • 30 % reduction of CO2 emission • 20 % sustainable energy • Policy • Stimulate technological developments • Give subsidies for: Energy savings Green investments • Forcing: Force the electricity suppliers to deliver green electricity
Inzet wind • ca. 1500 wind turbines in the Netherlands (1% of total) • Wind energy about 3x more expensive as conventional supply
Solar energy • Incoming radiation is about 50 times our energy demand. • Direct energy saving • Relatively expensive
Solar Storage of solar energy Biomass!
Organic material from plant and trees created by photosynthesis Biomass Closed cycle Biomass for energy is CO2 neutral
Master Sustainable Energy Technology TU Eindhoven officially started in June 2005 with an approved master program. In April 2006 upgraded to a national master program (TUE/TUDelft/UT) Combination between technical (75%) and social sciences (25%), contrary to Utrecht (25 % technical, 75% social) Comparable programs in Oldenburg, Stockholm, Leeds en Reading
program objectives Domain-specific requirements Broad: Have disciplinary theoretical and technical knowledge (broad) able to evaluate conventional and sustainable energy systems in integrated electrical system context able to evaluate sustainable energy systems in the societal context able to design energy systems able to analyze and understand the socio- technical nature of system innovations Deep: expert in at least one sub-area
The core courses Energy from biomass Solar energy Wind energy Electrical power engineering and system integration Hydrogen technology System innovation and stategic nich management 24 EC
introductory course: Technology for sustainable development courses to reach adequate basic levels in mathematics, physics, chemistry and design engineering: Transport phenomena Energy systems Chemical reactor engineering Design methodology courses to reach adequate basic levels in social sciences: Energy and economy Technology for sustainable development
system integration projects (6+9 EC): ‘System integration projects 1 and 2’ (Can be replaced by an Internship) elective courses (15 EC): Courses in preparation of the graduation project graduation project (45 EC): In one of the following topics: Solar Energy, Wind energy, Biomass, Hydrogen, Intelligent electricity networks and Transition policy
System integration projects: Formulated in cooperation with ECN TNO EDON ENECO Energie Delfland ENW EnergieNed EPON GASTEC KEMA Shell Stork First integration project: Project-led education (as in the CTW bachelor education). Second integration project: individual hands-on experience in the design, analysis or application of an energy system or in the exploration of new research questions. problem oriented in the form of a research assignment. Or an internship: ‘Energy related’, at one of these companies, or at Essent, Nuon, BTG, etc.
Research groups on: • Thermal conversion of biomass (v.d. Meer, v Swaaij, Lefferts) • Bio-refinery (De Haan, Van Swaaij......) • Membrane-based energy production (Wessling) • Integrated reactor technology (Kuipers) • Use of sustainable energy in consumer products and in buildings (Brouwers, Van Houten) • Water Power Generation (Hulscher) • Design and production with light weight and smart materials (Akkerman) • Gas technology (Wolters) • Engineering fluid dynamics (Hoeijmakers)
Elective courses 110201 Life-cycle strategy 110203 Product design 114142 Transp. in turbulente stromingen m. chem.reacties 114143 Gastechnologie 114150 Thermische werktuigbouwkunde - Capita Selecta 114171 Therm.conversie v brandstoffen,afval en biomassa 114531 Levenscyclusgericht ontwerpen 115472 Fluid mechanics of turbomachines 1 115475 Technische stromingsleer - Capita Selecta 115771 Numerical methods in mechanical engineering 134506 Kinetiek en katalyse 137004 Chemische Reactorkunde 137508 Flowsheeting 138501 Process Equipment Design 147017 Voortgezette fysische stromingsleer 1 147020 Meetmethoden in de stromingsleer 155010 Partiele diff.verg. uit de math.fysica 544090 Duurzaam bouwen
Program supervision of the M.Sc. program dr. ir. A.M.C. Lemmens (TU/e), prof.dr.ir. Th.H, van der Meer (UT) and prof.dr. F. Mulder (TUDelft). The program director will be dr.ir. A.M.C. Lemmens Program administration in Twente at CTW, C.T.A. Ruijter
There are three target groups for the program: • Bachelor students from technical and related science programs at Dutch universities • Bachelor students from polytechnic colleges for higher education (in particular energy technology); • Bachelor students from technical and related science programs at foreign universities.
Admission • Advanced Technology (SET-track) • Applied Physics • Chemical Engineering • Electrical Engineering • Mechanical Engineering • Technology Management of TU/e, TUD and UT (with restrictions) • B.Sc. in Physics/Chemistry: check on level of science and maths • Other technical B.Sc.-programs of Dutch universities: individual judgment, possibly a pre-master program is demanded • B-Sc programs from polytechnic colleges: Pre-master • Foreign students: check on level of Maths, Science and English (similar to other Masters)