1. Energy Efficiency and Renewable Energy Brian Kaestner Thanks to Miller and Clements

2. The Importance of Improving Energy Efficiency  Net useful energy  Life cycle cost Least Efficient  Incandescent lights  Internal combustion engine  Nuclear power plants Energy Inputs SystemOutputs U.S. economy and lifestyles 84% 7% 5% 4% 9% 7% 41% 43% Nonrenewable fossil fuels Nonrenewable nuclear Hydropower, geothermal, wind, solar Biomass Useful energy Petrochemicals Unavoidable energy waste Unnecessary energy waste

3. Ways to Improve Energy Efficiency  Insulation  Elimination of air leaks  Air to air heat exchangers  Cogeneration  Efficient electric motors  High-efficiency lighting  Increasing fuel economy

4. Uranium 100% 95%54% 17%14% Waste heat Waste heat Waste heat Waste heat Electricity from Nuclear Power Plant Uranium mining (95%) Uranium processing and transportation (57%) Power plant (31%) Transmission of electricity (85%) Resistance heating (100%)

5. Passive Solar Waste heat Sunlight 100% 90% Window transmission (90%)

6. Prolongs fossil fuel supplies Reduces oil imports Very high net energy Low cost Reduces pollution and environmental degradation Buys time to phase in renewable energy Less need for military protection of Middle East oil resources Improves local economy by reducing flow of money out to pay for energy Creates local jobs

7. Hybrid Vehicles  Rechargeable battery systems  Hybrid electric-internal combustion engine Electricity Fuel Combustion engine A Fuel tank B Electric motorC Battery bank D RegulatorE TransmissionF A B C D E F

8. Using Solar Energy to Provide Heat and Electricity  Passive solar heating  Active solar heating PASSIVE Stone floor and wall for heat storage Superwindow Winter sun Summer sun Heavy insulation Superwindow Hot Water tank Pump Heat exchanger Super- window Heat to house (radiators or forced air duct) ACTIVE Heavy insulation

9. Direct Gain Ceiling and north wall heavily insulated Hot air Super insulated windows Cool air Warm air Summer sun Winter sun Earth tubes

10. Greenhouse, Sunspace, or Attached Solarium Summer cooling vent Warm air Cool air Insulated windows

12. Earth Sheltered Earth Triple-paned or superwindows Flagstone floor for heat storage Reinforced concrete, carefully waterproofed walls and roof

14. Using Solar Energy to Provide High- Temperature Heat and Electricity  Photovoltaic (PV) cells Single Solar Cell Boron-enriched silicon Junction Sunlight Cell Phosphorus- enriched silicon DC electricity

15. Solar Power Tower

17. Solar Thermal Plant

20. AdvantagesDisadvantages Moderate net energy Moderate environmental impact No CO 2 emissions Fast construction (1–2 years) Costs reduced with natural gas turbine backup Low efficiency High costs Needs backup or storage system Need access to sun most of the time High land use May disturb desert areas

21. Producing Electricity from Moving Water  Large-scale hydropower  Small-scale hydropower  Tidal power plant  Wave power plant Basin side Bulb unit impeller Sea side Tide out twice a day Tide in twice a day Tidal Power Plant Wave Power Plant Floating turbogenerator Vane Pump

26. Producing Electricity from Wind Wind Turbine Power cable Electrical generator Gearbox Fig. 15.29, p. 381 Existing projects Planned projects Normal winds Moderate winds Good winds Excellent winds

29. AdvantagesDisadvantages Moderate to high net energy High efficiency Moderate capital cost Low electricity cost (and falling) Very low environ- mental impact No CO 2 emissions Quick construction Easily expanded Steady winds needed Backup systems when needed winds are low High land use for wind farm Visual pollution Noise when located near populated areas May interfere in flights of migratory birds and kill birds of prey

30. Producing Energy from Biomass  Biofuels  Crop residues  Animal manure  Ethanol Solid Biomass Fuels Wood logs and pellets Charcoal Agricultural waste (stalks and other plant debris) Timbering wastes (branches, treetops, and wood chips) Animal wastes (dung) Aquatic plants (kelp and water hyacinths) Urban wastes (paper, cardboard, and other combustible materials) Direct burning Conversion to gaseous and liquid biofuels Gaseous Biofuels Synthetic natural gas(biogas) Wood gas Liquid Biofuels Ethanol Methanol Gasohol

33. Geothermal Energy Electric power Generator Condenser Cooling tower Steam Separator Turbine Warm brine Steam and hot water Cooled water Pump Impermeablerock Injectionwell Permeablerock Cooled brine Productionwell Hot brine

34. Geothermal Reservoirs

36. Entering the Age of Decentralized Micropower  Centralized power systems  Decentralized power systems  Micropower systems Central power plants Residential Industrial Commercial Transmission and distribution system Bioenergy power plants Wind farm Small solar cell power plants Fuel cells Solar cell rooftop systems Commercial Microturbines Industrial Transmission and distribution system Residential Small wind turbine Fuel cells Rooftop solar cell arrays Fig. 15.39, p. 389Fig. 15.40, p. 390

37. Solutions: A Sustainable Energy Strategy Improve Energy Efficiency Increase fuel-efficiency standards for vehicles, buildings, and appliances Mandate government purchases of efficient vehicles and other devices Provide tax credits for buying efficient cars, houses, and appliances Offer tax credits for investments in efficiency Reward utilities for reducing demand Encourage independent power producers Increase efficiency research and development More Renewable Energy Increase renewable energy to 40% by 2020 Provide subsidies and tax credits for renewable energy Use full-cost accounting and least-cost analysis for com- paring all energy alternatives Encourage government purchase of renewable energy devices Increase renewable energy research and development Reduce Pollution and Health Risk Cut coal use 50% by 2020 Phase out coal subsidies Levy taxes on coal and oil use Phase out nuclear power or put it on hold until 2020 Phase out nuclear power subsidies