1 / 19

Developments in renewable technology

Developments in renewable technology. Michael G Boyce July 4 th 2012 Melksham Climate Friendly Group. Solar Cement.

stu
Download Presentation

Developments in renewable technology

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Developments in renewable technology Michael G Boyce July 4th 2012 Melksham Climate Friendly Group

  2. Solar Cement • The global cement industry is currently one of the largest single emitter of carbon dioxide, generating on average about 830 kg of this greenhouse gas for each 1000 kg of cement produced (source: International Energy Agency 2007, Tracking Industrial Energy Efficiency and CO2 Emissions; pdf). Considering that the worldwide annual production of cement is a whopping 3.8 trillion kg (source), the cement industry alone accounts for approximately 5-6% of man-made CO2 emissions.Read more: http://www.nanowerk.com/spotlight/spotid=24883.php#ixzz1yWXrqvSo • "In cement production, the majority of CO2 emissions occurs during the decarbonation of limestone (CaCO3) to lime (CaO) and the remainder (30 to 40%) from burning fossil fuels, such as coal, to heat the kiln reactors to ∼900°C," Licht explains to Nanowerk. " Our study presents a low-energy, entirely new synthetic route to form CaO without any carbon dioxide emission, and is based on unexpected solubility behavior in molten salts. This synthesis can be accomplished without solar energy, and without our new STEP process, but is particularly attractive when combined with this new solar process." "Alternatively" he adds, "the new synthesis could be used by industry to produce cement using any non-solar, renewable or nuclear energy without any CO2 release, or greatly decrease CO2 if fossil fuels were used to drive the new cement production – in the latter, worst case scenario, the products are lime, graphite and oxygen; there is still no CO2 product, but CO2 would be used in the energy to drive the process." In STEP cement limestone undergoes low energy electrolysis to produce lime, O2 and reduced carbonate without carbon dioxide emission. • Read more: http://www.nanowerk.com/spotlight/spotid=24883.php#ixzz1yWYDFXaJ

  3. Thin Film Solar • Organic Cell is Lean and Limber • Adhering to the adage that one can never be too thin, Austrian and Japanese researchers developed a 1.9 μm-thick solar cell. The polymer-based ultrathin device features electrodes on plastic foil and the flexibility required for inclusion in textiles and conformable electronics. The organic PV cells, 10x lighter and thinner than others available, post a power conversion efficiency of 4.2%.

  4. No Reflectance Solar Cell • Silicon in Basic Black • The virtual absence of reflectance from silicon cells fabricated by Natcore Technology, NJ, and U.S. National Renewable Energy Lab translates into 99.7% incident light absorption. Anti-reflection black cell technology increases energy conversion efficiency at reduced manufacturing costs. Production entails liquid phase deposition to coat and passivatenanoporous Si wafers, reports Solar Novus Today.

  5. Technical Challenges: Solar- Inverter • DC LV to AC 20V • Power loses • Reliability

  6. Tech Challenges- Wind Power • Wind availability. Velocity > 6m/s for smaller WTGs • Gearbox (power losses, noise, reliability. Lubrication) • Long blades >45M- transport issues • Long towers: 30-40 same issues • Road access and surfaces • Environmental Impact

  7. Thinking big: The 2.5xl turbine has a rotor diameter of 100 meters — or about the length of a football field. By comparison, its widely used 1.5-megawatt cousin has a rotor diameter of 70 to 77 meters. The 2.5xl turbine isn’t currently sold in the U.S., but GE will begin offering it to North American customers next year — with those units to be assembled in Pensacola, Fla

  8. How Wind Power Works • http://www.youtube.com/watch?feature=player_detailpage&v=g0WSqqLRsQE • http://www.youtube.com/watch?feature=player_detailpage&v=ny04UDEnJ6Q • http://www.youtube.com/watch?v=LNXTm7aHvWc&feature=player_detailpage • http://www.youtube.com/watch?v=PyehD1j0kUU&feature=results_main&playnext=1&list=PLA1D1EBDE1CDC833A • http://www.youtube.com/watch?v=wHVG-ZhuwzM&feature=player_detailpage • http://www.youtube.com/watch?v=ELXSceFpS_w&feature=player_detailpage • http://www.youtube.com/watch?v=r0DZUDQyw_0&feature=player_detailpage • http://www.youtube.com/watch?v=06D4LvU-CG8&feature=player_detailpage

  9. Storing Wind Power Wind Energy is in the Bag Video documents progress in the maturation of inflatable energy bags developed at University of Nottingham, UK, to provide wind energy storage. Tethered to the sea floor, these compressed air energy storage balloons offer a means to address the intermittent nature of wind power systems. Watch preliminary field tests off Orkney, Scotland, and assembly of steel ballast structures. http://www.youtube.com/watch?v=ktup6CAvfGo&feature=player_embedded

  10. High Altitude Wind • Turbine Meets Blimp • More height equals more wind, so it was just a matter of time before someone married a turbine to a blimp. A Massachusetts company recently completed testing of a 35 ftairborne wind turbine (AWT) at an altitude of 350 ft. Constructed in a sail-making loft, the donut-shaped blimp surrounds a Southwest Skystream turbine, using fins and guy wires to adjust direction and output. The ultimate goal is harnessing strong and steady winds found above 1,000 ft.

  11. Wave/Tidal

  12. Geothermal • Hot Water from Old Mines • Heat collects in abandoned underground mines, presenting a geothermal resource already tapped in some areas of Europe and Canada. A general model developed at McGill University, Canada, could help predict how much energy can be produced from mine sites. Heat extracted from hot water pumped to the surface could yield 150 kW heat/km of a typical underground flooded mine.

  13. Conclusions • Economy of scale has size implications • Investment is critical • ROC or FIT is essential • Offshore is not the ‘’gold rush’’ we thought it would be • Nothing beats saving energy. Population issues have to be considered (not popular) • Payback of energy used in manufacture of wind equip is about 1-2 months • Wind turbines are not toys: 2.5 MW may cost 1-2 million GBP installed. Best is isolated rural areas. Need wind. Taller= more wind capture, but need grid connections.. • Tidal/wave not new, just not scaled up • Geothermal unexploited in UK

More Related