RENEWABLE SOURCES OF MECHANICAL ENERGY SC 208 Our Energy Future April 14, 2005 John Bush

1. RENEWABLE SOURCES OF MECHANICAL ENERGYSC 208 Our Energy FutureApril 14, 2005 John Bush

2. WIND, WATER, THERMAL GRADIENTS • Hydroelectric • Tidal and Ocean/River Currents • Wave • Wind • Geothermal • Ocean thermal

3. COMMON FEATURES • With minor exceptions they all provide electricity exclusively • They have very specific site requirements • They all have environmental or aesthetic negatives • Until recently only hydroelectric and geothermal were commercially useful

4. THE CASE OF HAWAII • Now almost totally dependent (90%) on imported oil for its energy • Has an increasing need for fresh water • Has access to ample renewable resources • Intense sunlight • Fast growing crops, particularly sugarcane • Strong, steady winds • Fast flowing streams • Ocean currents • Warm and cold ocean waters • Renewables represent a great opportunity for Hawaii but what about for the rest of the United States?

6. HYDROELECTRIC POWER • Electricity generated by using gravitational potential energy to power a turbine-generator • Two utility applications • Conventional hydroelectric generation • Energy storage by pumping water to upper reservoir during electric surplus and releasing it through a turbine-generator when needed • Two approaches for conventional hydro • Dams create a reservoir • Run of river depends on diverting river flow

8. LARGE SCALE CONVENTIONAL HYDROELECTRIC GENERATION • Output depends on time of year and precipitation • Future sites in the US are limited to none because of strong public resistance • Impacts • Water resources: stream flows, water temp. • Effects on fish migrations • Damage to archaeological/historic sites • Loss of scenic/wilderness resources • Upstream deposition (silting) & downstream erosion • Increased landslide potential • Gain in recreation resources • DOE forecast a net decline in hydro generation (see chart following)

10. FUTURE OF MINIHYDRO? • Small, low impact units: 1-2 MWe • Advanced controls permit integration into a distributed network • May reactivate some sites abandoned in the 1960s • Active in Japan and the Phillipines • Net impact in the US probably low

11. HYDROELECTRICITY IN CALIFORNIA • About 15% of California’s in-state generation is from hydroelectric (vs. 7% nationally) • Substantial imports of hydropower from the Pacific Northwest sensitive to precipitation and salmon migrations • Total of 386 hydroplants with 14,116 MWe capacity • Future large installations in California are unlikely

12. POWER FROM TIDES AND CURRENTS • Technical approaches • Tidal dams (barrages) • Tidal fences • Turbine fields • Common features • Depend on water driven fans/turbines • Low operating costs if can avoid biofouling and storm damage • High construction costs • Known or suspected negative impacts on marine environment

13. TIDAL BARRAGES • Dams across estuaries with gates and turbines • Tidal differences must be more than 16 feet—there are about 40 such sites in the world • Gates are opened when tide is high enough allowing water to flow through hydroturbines • La Rance a 240 MWe facility in France has operated reliably for many years • No facilities in the US—possibilities in the Pacific Northwest and the Atlantic Northeast • Cause silting, destroy wetlands and interfere with fish migrations • Probably limited potential for the US

17. TIDAL FENCES • Look like giant turnstiles • Span channels and spin in tidal currents • Current must be at least 5 to 8 knots • Density of sea water permits extracting much more energy from these than from corresponding wind mills

18. AXIAL FLOW TIDAL TURBINES • Arrayed in rows like wind farms • Look like wind turbines • Ideally close to shore in water depths of 60-100 ft. • Estimated costs of 5 MWe free-flow turbine installation (2005 dollars) • Capital cost $4300/KWe • Operating cost $.07-.09/KWH • Deployable 2010-2012

20. CROSS FLOW TURBINES • Like those for tidal gates • Use conduits to concentrate the tidal flow • Raised during incoming tide • Lowered to generate power during tidal ebb

21. CROSS FLOW TURBINECONDUIT PLUS RESERVOIRTIDAL OR WAVE ENERGY

22. POTENTIAL FOR TIDAL TURBINES IN US • Tidal locations (120): 1200 MWe • Riverine locations: 12,500-170,000 MWe • Gulf Stream: 685,000 MWe • Fragmented industry with no major industrial firms • Demonstration in 2006: Manhattan’s East River, 6 turbines, 35 rpm, 200 KWe by Verdant Power • For discussion see: Proceedings of the Hydrokinetic and Wave Energy Technologies Technical and Environmental Issues Workshop Oct. 26-28, 2005 http://hydropower.inl.gov/

23. WAVE ENERGYTECHNICAL APPROACHES • Floats or pitching devices: wave action moves two or more bodies relative to one another—various devices generate power; energy storage in supercapacitors since voltage/current are wildly erratic • Oscillating water columns: wave action drives air in and out of column—power is generated by an air turbine in the column • Wave surge or focusing devices: wave action drives water up a channel into a reservoir—power is generated by hydro turbines during outflow from reservoir

24. EUROPEAN DESIGN WAVE ENERGY CONVERTER

26. AQUABUOY DESIGN (US)OSCILLATING COLUMN

27. OSCILLATING COLUMN (SCOTLAND)

28. WAVE ENERGY POTENTIAL • Designs range from distributed generation to large scale power plants • Susceptibility to storm damage and biofouling are issues • Power conditioning and grid connection are also issues • EPRI estimate: at 60 m off US coast the average wave power is 2100TWH/Year • Could generate 7% of current US electricity demand by capturing 20% of the total wave energy at 50% efficiency.

29. PROBLEMS PREVENTING REALIZATION OF POTENTIAL • Both wave and tide technologies are largely unproven • DOE has no R&D capacity for them • The firms involved are small and undercapitalized • The regulatory structure is poorly defined • There are no tax credits for wave/tide power

30. WIND POWER • The most promising near term renewable resource • Issue: what will happen when the subsidies vanish? • US installed capacity growing at about 25% per year • Intermittent, irregular supply: • Value depends on installed capacity, site specific capacity factor, and timing of generation (e.g. summer generation is usually more valuable than winter generation) • At greater than 20% of a grid’s supply, managing the grid becomes difficult and expensive

31. SOME GENERAL ATTRIBUTES • Best sited where there is a reliable strong wind: the US midwest and southwest • Adaptable to either centralized (wind farm) or decentralized siting • Used by utilities to save fuel—not reliable baseload generation • Siting issues: Long Island, Nantucket/Martha’s Vineyard • Aesthetics/visibility: NIMBY • Noise • Electromagnetic interference • Banned within 1.5 miles of shipping or ferry lanes • Wild life fatalities: California, West Virginia • Low flying, migratory song birds (Altamount Pass) • Bats

33. TECHNOLOGIES • Horizontal axis fans are the best proven technologies • Windmills have been in use in the West since the Middle Ages • New designs are proliferating • Technical issues • Mechanisms are complex and expensive to maintain • Large blades for efficient units are expensive to make and transport • Power conditioning and grid connection issues seem to be resolved

36. MECHANISMS OF TURBINES ARE COMPLEX

37. LARGER MACHINES ARE MORE EFFICIENT

39. VERTICAL SHAFT TURBINES • Compared to horizontal axis turbines • Greater efficiency: 45% vs. 25-40% • Operate in higher winds: 70 mph vs. 50 mph maximum • Quieter and less visibly intrusive • More readily scaled up in size: to 10 MWe vs. 5MWe maximum • Unproven technology at large scale

40. VERTICAL SHAFT WIND TURBINES

42. WIND POWER: EXAMPLES • Upstate New York: Maple Ridge • Leeward of Lake Ontario • Largest project east of the Mississippi: 195 turbines, 320 ft high, 320 MWe (peak) • Generate lease payments to landowners: $5000-$10,000 per turbine annually • Cost ~$1700 per KWe (peak) [2005 dollars] • Financed by Goldman Sachs • Subsidized by surcharge on utility bills • US installed capacity (2004) 6740 MWe (peak)

43. WINDPOWER POTENTIAL FOR THE UNITED STATES • Battelle estimated that with constraints wind can provide 20% of US electricity demand • DOE goal 6% of US demand by 2020 • Unconstrained estimate is that the US potential is equivalent to operating ~1500 1000 MWe nuclear or coal plants • Of the 50 states North Dakota has the greatest potential followed by Texas, Kansas, South Dakota, Montana and Nebraska—California is 17th • North Dakota could supply 25% of the current US electricity demand but would require a major growth of electricity transmission capacity.

44. WINDPOWER PROSPECTS • A big potential market: worldwide capacity is growing at 30% per year • Annual equipment sales ~ $2Billion in 2005 • Project financing for renewables in 2005 • Windpower $3.5 Billion • Solar Photovoltaic $2.2 Billion • All Other $1.25 Billion • Growing at 25% per year • Major companies are involved • General Electric • British Petroleum • Goldman Sachs • J P Morgan Chase • Siemens AG

45. GEOTHERMAL POWER • Employs geothermal heat directly (buildings, greenhouses, etc.) or to generate electricity • Electricity generation requires source temperatures > 300º F • Three basic plant designs • Dry steam: uses steam directly from reservoir w/o recycling: cost $.04-.06 per KWH • Flash steam: partially flashes superheated water (> 360º F) to steam and recycles the rest • Binary cycle: Reservoir fluid and working fluid kept separate—able to use lower temperature fluids (225-260º F): cost $.05-.08 per KWH

48. SOME SITE SPECIFIC RESERVOIR CHARACERISTICS • Fluid temperature and production rate • Corrosive nature of fluids • Co-production of noxious gases • Difficulty of drilling reservoir rock • Rate of replenishment of fluids and heat • Reservoir plugging due to mineralization or rock deformation • Access to maintenance and electric transmission

49. RESOURCES: ACTUAL AND POTENTIAL • Geothermal wells/springs (> 130º F) are widely distributed in the Western US (see map) • US currently generates 3000 MWe and uses 570 MWt from geothermal sources • Research efforts • Resource characterization • Plant efficiencies • Geothermal field development