Transcript Slide 1
Costs of generating electricity (http://www.iea.org/Textbase/npsum/ElecCostSUM.pdf $US quoted) • Coal (Avg of 27 plants) $1K-$1.5K/kWe capital – $45-60/MW.h (Inv. 50%, O&M 15%, Fuel 35%) • Gas (23) $0.6-0.8K/kWe – $40-63/MWh (Inv. 20%, O&M 7%, Fuel 73%) • Nuclear (13) $1-$2K/kWe – $30-50/MWh (Inv. 70%, O&M 13%, Fuel 10%) • Wind (19) $1-2K/kWe – $45-140/MWh (O&M 12-40%) – Load factor variability is a major factor in setting the costs of running a wind plant • Solar (6) approaches $300/MWh • Cogeneration (24) estimated $30-70/MWh Types of Windmills/turbines 7% efficiency, but work at low wind speeds Altogether, there are 150,000 windmills operating in the US alone (mainly for water extraction/distribution) According to wikipedia, as of 2006 installed world-wide capacity is 74 GW (same capacity as only 3.5 dams the size of the three-Gorges project in China). Up to 56 % efficiency with 3 blades, do very little at low wind speeds Wind Energy According the article from the IEA (previous slide), the typical availability of a wind farm is 17-38% for landbased plants and 40-45% for offshore plants. http://www.windpower.org/en/tour/wres/euromap.htm An extensive site for Wind Information!! Worldwide Wind Capacity http://en.wikipedia.org/wiki/Wind_power US Wind Distribution http://en.wikipedia.org/wiki/Wind_power Types of Windmills (cont.) Altamont Pass (CA) http://www.ilr.tu-berlin.de/WKA/windfarm/altcal.html 6000 turbines, built 1980’s San Gorgonio Pass (CA) http://www.ilr.tu-berlin.de/WKA/windfarm/sgpcal.html 3500 turbines, built 1980’s Basics of a Wind Turbine http://www.nrel.gov/wind/animation.html Blade diameter: 100m Wind range: 3.5m/s to 25m/s Rated wind speed: 11.5 m/s GE 2.5MW generator http://www.gepower.com/prod_serv/products/wind_turbines/en/downloads/ge_25mw_brochure.pdf GE 3.5 MW Blade diameter: 111m Wind range: 3.5m/s to 27 m/s Rated wind speed: 14 m/s Specifically designed for off-shore deployment Web site for movie on wind turbine construction http://www.gepower.com/businesses/ge_wind_energy/en/image_gallery/index.htm Wind Turbines http://www.afm.dtu.dk/wind/turbines/img0003.jpg Water wheels through the ages ITAIPU (Brazil/Paraguay) http://www.solar.coppe.ufrj.br/itaipu.html ITAIPU (Brazil/Paraguay) http://www.solar.coppe.ufrj.br/itaipu.html Essentials of PV design Basics of Photo-Voltaics A useful link demonstrating the design of a basic solar cell may be found at: http://jas.eng.buffalo.edu/education/pnapp/solarcell/index.html • There are several different types of solar cells: – Single crystal Si (NASA): most efficient (up to 30%) and most expensive (have been $100’s/W, now much lower) – Amorphous Si: not so efficient (5-10% or so) degrade with use (but improvements have been made), cheap ($2.5/W) – Recycled/polycrystalline Si (may be important in the future) Engineering work-around # 2: Martin Green’s record cell. The grid deflects light into a light trapping structure Power characteristics (Si) 100 cm2 silicon Cell under different Illumination conidtions Material Level of efficiency in % Lab Level of efficiency in % Production Monocrystalline Silicon approx. 24 14 to17 Polycrystalline Silicon Amorphous Silicon approx. 18 approx. 13 http://www.solarserver.de/wissen/photovoltaik-e.html 13 to15 5 to7 Solar Cell Costs http://www.nrel.gov/pv/pv_manufacturing/cost_capacity.html Costs have dropeed from about $5.89/pk Watt output in 1992 to $2.73/pW in 2005 Solar House This house in Oxford produces more electricity than it uses (but only about 4kWh/yr!! According to the NREL, hardly worth selling) http://www.nrel.gov/pv/pv_manufacturing/cost_capacity.html Advanced designs-multilayers http://www.nrel.gov/highperformancepv/ Typical products Flood light system for $390 (LED’s plus xtal. cells) 15W systems for $150 Battery charges (flexible Amorphous cells) http://www.siliconsolar.com/ Example of a retrofit Dick Swanson Martin Green Fuel Cells- sample schematics http://www.iit.edu/~smart/garrear/fuelcells.htm For more details on these and other types, see also: http://www.eere.energy.gov/hydrogenandfuelcells/fuelcells/fc_types.html Ballard Power Systems (PEM) •85kW basic module power (scalable from 10 to 300kW They say) for passenger cars. •212 lb (97 kg) •284 V 300 A •Volume 75 liters •Operates at 80oC •H2 as the fuel (needs a reformer to make use of Methanol etc.) •300kW used for buses Fuel Cell Energy (“Direct Fuel Cell”) •Appears to be a molten carbonate systme based on their description •Standard line includes units of 0.3,1.5 and 3 MW •Fuel is CH4 (no need for external reformer) can also use “coal gas”, biogas and methanol •Marketed for high-quality power applications (fixed location) This is a nominal 300kW unit (typically delivers 250kW according to their press releases). Most of the units installed to date are of this size. http://www.netl.doe.gov/publications/proceedings/03/dcfcw/dcfcw03.html http://www.netl.doe.gov/publications/proceedings/03/dcfcw/Cooper%202.pdf The Hydrogen Hype •H2 burns with 02 to make water •H2 comes from the oceans (lots of it) •Fuel cells can “burn” it efficiently The Realities •Can’t mine it, it is NOT an energy source –Why not just use electricity directly? •Even as a liquid, energy density is low –Storage and transport are difficult issues •More dangerous (explosive) than CH4 • No existing infrastructure Hydrogen Economy •Hydrogen seems to be an attractive alternative to fossil fuels, but it cannot be mined. You need to treat it more like electricity than gasoline (i.e. as a carrier of energy, not as a primary source). •Need lots of research in areas such as: –Production –Transmission/storage –Distribution/end use http://www.eere.energy.gov/hydrogenandfuelcells/pdfs/review04/4_science_stevens_04.pdf http://www.eere.energy.gov/hydrogenandfuelcells/pdfs/review04/4_science_stevens_04.pdf http://www.eere.energy.gov/hydrogenandfuelcells/pdfs/review04/4_science_stevens_04.pdf Storage Possabilities Physisorbtion Chemical Reaction Chemisorbtion Encapsulation Weak binding energy -> Low T required Carbon nanotubes Porous materials Zeolites Reversible Hydrides PdH, LiH, … Large energy input to release H2 Slow Dynamics H Al Very large energy input to release H2 Not technologically feasible H2 trapped in cages or pores Variation of physical properties (T or P) to trap/release H2 4 H molecules in 51264 cage http://www.eere.energy.gov/hydrogenandfuelcells/pdfs/review04/4_science_stevens_04.pdf DOE report from 2004 is available at: http://www.eere.energy.gov/hydrogenandfuelcells/pdfs/review04/4_science_stevens_04.pdf Nature and Physics Today articles: Nature Vol. 414, p353-358 (2001) Physics Today, vol 57(12) p39-44 (2004) MIT web site on photo-production: http://web.mit.edu/chemistry/dgn/www/research/e_conversion.html http://www.eere.energy.gov/hydrogenandfuelcells/pdfs/review04/4_science_stevens_04.pdf Three Gorges Dam (China) http://www.physicstoday.org/vol-59/iss-12/p38.html