230 likes | 246 Views
A comprehensive overview of the renewable energy potential of ocean winds, detailing the environmental benefits and economic considerations. Explore the power of wind energy over oceans and its implications for sustainable energy solutions. Learn about the efficiency, costs, and impact of harnessing ocean breeze for clean energy generation. Discover how ocean wind energy can reduce reliance on fossil fuels and mitigate environmental impacts, paving the way for a greener future.
E N D
An Introduction to Ocean and Sea Breeze Wind Energy Renewable Energy from Ocean Winds Frank R. Leslie, BSEE, MS Space Technology 5/25/2002, Rev. 1.7 f.leslie@ieee.org; (321) 768-6629
Overview of Ocean Energy • Ocean energy is replenished by the sun and through tidal influences of the moon and sun gravitational forces • Near-surface winds induce wave action and cause wind-blown currents at about 3% of the wind speed • Tides cause strong currents into and out of coastal basins and rivers • Ocean surface heating by some 70% of the incoming sunlight adds to the surface water thermal energy, causing expansion and flow • Wind energy is stronger over the ocean due to less drag, although technically, only seabreezes are from ocean energy 1.0 020402
What’s renewable energy? • Renewable energy systems transform incoming solar energy and its alternate forms (wind and river flow, etc.), usually without pollution-causing combustion • This energy is “renewed” by the sun and is “sustainable” • Renewable energy is sustainable indefinitely, unlike long-stored, depleting energy from fossil fuels • Renewable energy from wind, solar, and water power emits no pollution or carbon dioxide • Renewable energy is “nonpolluting” since no combustion occurs (although the building of the components does in making steel, etc., for conversion machines does pollute during manufacture) 1.1 020302
Renewable Energy (Continued) • Fuel combustion produces “greenhouse gases” that are believed to lead to climate change (global warming), thus combustion of biomass is not as desirable as other forms • Biomass combustion is also renewable, but emits CO2 and pollutants • Biomass can be heated with water under pressure to create synthetic fuel gas; but burning biomass creates pollution and CO2 • Nonrenewable energy comes from fossil fuels and nuclear radioactivity (process of fossilization still occurring but trivial) • Nuclear energy is not renewable, but sometimes is treated as though it were because of the long depletion period 1.1 020402
The eventual declineof fossil fuels • Millions of years of incoming solar energy were captured in the form of coal, oil, and natural gas; current usage thus exceeds the rate of original production • Coal may last 250 to 400 years; estimates vary greatly; not as useful for transportation due to losses in converting to liquid “synfuel” • We can conserve energy by reducing loads and through increased efficiency in generating, transmitting, and using energy • Efficiency and conservation will delay an energy crisis, but will not prevent it 1.1 020402
Available Energy • Potential Energy: PE = mh • Kinetic Energy: KE = ½ mv2 or ½ mu2 1.2 020412
Economics • Cost of installation, operation, removal and restoration • Compare cost/watt & cost/watt-hour vs. other sources • Relative total costs compared to other sources • Externality costs aren’t included in most assessments • Cost of money (inflation) must be included (2 to 5%/year) • Life of energy plant varies and treated as linear depreciation to zero • Tax incentives or credits offset the hidden subsidies to fossil fuel and nuclear industry • Environmental Impact Statements (EIS) require early funding to justify permitting 1.3 020402
Ocean Wind Energy • Over or in proximity to the ocean surface, the wind moves at higher speeds over water than over land roughness 2.0 020525
Ocean Wind Energy • Wind energy results from uneven heating of the atmosphere • Wind resources vary greatly worldwide; strong over oceans • Power is proportional to the cube of the wind speed Ref.: www.freefoto.com/pictures/general/ windfarm/index.asp?i=2 6.0 020121
Ocean Wind Energy (continued) • Long fetch (distance) of unhindered wind increases speed and available energy beyond land installations • Offshore wind turbines diminish public outcry against wind turbines (low visibility, monopod supports) • Turbines are typically placed on concrete supports in groups; rotors are often 80 m in diameter • Turbines are also placed along a coast on the foreshore area to intercept the prevailing wind from over the ocean • Must avoid bird migration routes; turbine ~20 to 30 rpm 6.0 020402
Ocean Wind Energy (continued) • Present and planned offshore wind energy plants will supply significant consumer demand and reduce need for coal- and oil-fired plants and resultant pollution • Middlegrunden near Denmark • Oil-drilling platforms • Small auxiliary turbine • Platform design can be modified to support large wind turbine 6.0 020402
Wind Energy Equations(also applies to water turbines) • Assume a “tube” of air the diameter, D, of the rotor • A = π D2/4 • A length, L, of air moves through the turbine in t seconds • L = u·t, where u is the wind speed • The tube volume is V = A·L = A·u·t • Air density, ρ, is 1.225 kg/m3 (water density ~1000 kg/m3) • Mass, m = ρ·V = ρ·A·u·t, where V is volume • Kinetic energy = KE = ½ mu2 6.1 020402
Wind Energy Equations (continued) • Substituting ρ·A·u·t for mass, and A = π D2/4 , KE = ½·π/4·ρ·D2·u3·t • Theoretical power, Pt = ½·π/4·ρ·D2·u3·t/t = 0.3927·ρa·D2·u3, ρ (rho) is the density, D is the diameter swept by the rotor blades, and u is the speed parallel to the rotor axis • Betz Law shows 59.3% of power can be extracted • Pe = Pt·59.3%·ήr·ήt·ήg, where Pe is the extracted power, ήr is rotor efficiency, ήt is transmission efficiency, and ήg is generator efficiency • For example, 59.3%·90%·98%·80% = 42% extraction of theoretical power 6.1 020402
Generic Trades in Energy • Energy trade-offs required to make rational decisions • PV is expensive ($4 to 5 per watt for hardware + $5 per watt for shipping and installation = $10 per watt) compared to wind energy ($1.5 per watt for hardware + $5 per watt for installation = $6 per watt total) • Are Compact Fluorescent Lamps (CFLs) always better to use than incandescent? Ref.: www.freefoto.com/pictures/general/ windfarm/index.asp?i=2 Ref.: http://www.energy.ca.gov/education/story/story-images/solar.jpeg Photo of FPL’s Cape Canaveral Plant by F. Leslie, 2001 7.1 020315
Energy Storage • Renewable energy is often intermittent, and storage allows alignment with time of use. • Compressed air, flywheels, weight-shifting (pumped water storage at Niagara Falls) • Batteries are traditional for small systems and electric vehicles; first cars (1908) were electric • Hydrogen can be made by electrolysis • Energy is best stored as a financial credit through “net metering” • Net metering requires a utility to bill at the same rate for buying or selling energy www.strawbilt.org/systems/ details.solar_electric.html 7.2 020402
EnergyTransmission • Electricity and hydrogen are energy carriers, not natural fuels • Electric transmission lines lose energy in heat (~2% to 5%); trades loss vs. cost • Line flow directional analysis can show where new energy plants are required to reduce energy transmission • Hydrogen is made by electrolysis of water, cracking of natural gas, or from bacterial action (lab experiment level) • Oil and gas pipelines carry storable energy • Pipelines (36” or larger) can transport hydrogen without appreciable energy loss due to low density and viscosity • More efficient than 500 kV transmission line and is out of view 7.3 020402
Legal aspects and other complications • PURPA: Public Utility Regulatory Policy Act of 1978. Utility purchase from and sale of power to qualified facilities; avoided costs offsetting basis of purchases • Energy Policy Act of 1992 leads to deregulation • “NIMBYs” rally to shrilly insist “Not In My Backyard”! • Investment taxes and subsidies favor fossil and nuclear power • High initial cost dissuades potential users; future is uncertain • Lack of uniform state-level net metering hinders offsetting costs • Environmental Impact Statements (EIS) require extensive and expensive research and trade studies • Numerous “public interest” advocacy groups are well-funded and ready to sue to stop projects 7.4 020402
Conclusion • Renewable energy offers a long-term approach to the World’s energy needs • Economics drives the energy selection process and short-term (first cost) thinking leads to disregard of long-term, overall cost • Increasing oil, gas, and coal prices will ensure that the transition to renewable energy occurs • Offshore and shoreline wind energy plants offer a logical approach to part of future energy supplies 8.0 0201402
References: Books, etc. • General: • Sørensen, Bent. Renewable Energy, Second Edition. San Diego: Academic Press, 2000, 911 pp. ISBN 0-12-656152-4. • Henry, J. Glenn and Gary W. Heinke. Environmental Science and Engineering. Englewood Cliffs: Prentice-Hall, 728pp., 1989. 0-13-283177-5, TD146.H45, 620.8-dc19 • Brower, Michael. Cool Energy. Cambridge MA: The MIT Press, 1992. 0-262-02349-0, TJ807.9.U6B76, 333.79’4’0973. • Di Lavore, Philip. Energy: Insights from Physics. NY: John Wiley & Sons, 414pp., 1984. 0-471-89683-7l, TJ163.2.D54, 621.042. • Bowditch, Nathaniel. American Practical Navigator. Washington:USGPO, H.O. Pub. No. 9. • Harder, Edwin L. Fundamentals of Energy Production. NY: John Wiley & Sons, 368pp., 1982. 0-471-08356-9, TJ163.9.H37, 333.79. Tidal Energy, pp. 111-129. • Wind: • Patel, Mukund R. Wind and Solar Power Systems. Boca Raton: CRC Press, 1999, 351 pp. ISBN 0-8493-1605-7, TK1541.P38 1999, 621.31’2136 • Gipe, Paul. Wind Energy for Home & Business. White River Junction, VT: Chelsea Green Pub. Co., 1993. 0-930031-64-4, TJ820.G57, 621.4’5 • Johnson, Gary L, Wind Energy Systems. Englewood Cliffs NJ: Prentice-Hall, Inc. TK 1541.J64 1985. 621.4’5; 0-13-957754-8. • Waves: • Smith, Douglas J. “Big Plans for Ocean Power Hinges on Funding and Additional R&D”. Power Engineering, Nov. 2001, p. 91. • Kotch, William J., Rear Admiral, USN, Retired. Weather for the Mariner. Annapolis: Naval Institute Press, 1983. 551.5, QC994.K64, Chap. 11, Wind, Waves, and Swell. • Solar: • Duffie, John and William A. Beckman. Solar Engineering of Thermal Processes. NY: John Wiley & Sons, Inc., 920 pp., 1991. 9.1 020402
References: Internet • General: • http://www.google.com/search?q=%22renewable+energy+course%22 • http://www.ferc.gov/ Federal Energy Regulatory Commission • http://solstice.crest.org/ • http://dataweb.usbr.gov/html/powerplant_selection.html • http://mailto:energyresources@egroups.com • http://www.dieoff.org. Site devoted to the decline of energy and effects upon population • Tidal: • http://www.unep.or.kr/energy/ocean/oc_intro.htm • http://www.bluenergy.com/technology/prototypes.html • http://www.iclei.org/efacts/tidal.htm • http://zebu.uoregon.edu/1996/ph162/l17b.html • Waves: • http://www.env.qld.gov.au/sustainable_energy/publicat/ocean.htm • http://www.bfi.org/Trimtab/summer01/oceanWave.htm • http://www.oceanpd.com/ • http://www.newenergy.org.cn/english/ocean/overview/status.htm • http://www.energy.org.uk/EFWave.htm • http://www.earthsci.org/esa/energy/wavpwr/wavepwr.html 9.2 020329
References: Internet • Thermal: • http://www.nrel.gov/otec/what.html • http://www.hawaii.gov/dbedt/ert/otec_hi.html#anchor349152 on OTEC systems • Wind: • http://awea-windnet@yahoogroups.com. Wind Energy elist • http://awea-wind-home@yahoogroups.com. Wind energy home powersite elist • http://telosnet.com/wind/20th.html 9.2 020329
Units and Constants • Units: • Power in watts (joules/second) • Energy (power x time) in watt-hours • Constants: • 1 m = 0.3048 ft exactly by definition • 1 mile = 1.609 km; 1m/s = 2.204 mi/h (mph) • 1 mile2 = 27878400 ft2 = 2589988.11 m2 • 1 ft2 = 0.09290304 m2; 1 m2 = 10.76391042 ft2 • 1 ft3 = 28.32 L = 7.34 gallon = 0.02832 m3; 1 m3 = 264.17 US gallons • 1 m3/s = 15850.32 US gallons/minute • g = 32.2 ft/s2 = 9.81 m/s2; 1 kg = 2.2 pounds • Air density, ρ (rho), is 1.225 kg/m3 or 0.0158 pounds/ft3 at 20ºC at sea level • Solar Constant: 1368 W/m2 exoatmospheric or 342 W/m2 surface (80 to 240 W/m2) • 1 HP = 550 ft-lbs/s = 42.42 BTU/min = = 746 W (J/s) • 1 BTU = 252 cal = 0.293 Wh = 1.055 kJ • 1 atmosphere = 14.696 psi = 33.9 ft water = 101.325 kPa = 76 cm Hg =1013.25 mbar • 1 boe (42- gallon barrel of oil equivalent) = 1700 kWh 9.3 020402
Energy Equations • Electricity: • E=IR; P=I2 R; P=E2/R, where R is resistance in ohms, E is volts, I is current in amperes, and P is power in watts • Energy = P t, where t is time in hours • Turbines: • Pa = ½ ρ A2 u3, where ρ (rho) is the fluid density, A = rotor area in m2, and u is wind speed in m/s • P = R ρ T, where P = pressure (Nm-2 = Pascal) • Torque, T = P/ω, in Nm/rad, where P = mechanical power in watts, ω is angular velocity in rad/sec • Pumps: • Pm = gQmh/ήp W, where g=9.81 N/kg, Qm is mass capacity in kg/s, h is head in m, and ήp is pump mechanical efficiency 9.4 020402