Alternative Energy Sources
World Wide Energy Production 15.2% alternative 84.8% fossil fuels
U.S. Energy Consumption The four primary consumers of energy in the U.S. in 2007 were Industrial32% Transportation28% Residential22% Commercial18% 93% of the energy generated and used in the U.S. are from nonrenewable resources
Energy & Society Without energy, Life would not be possible Energy not only powers modern technologies including transportation, etc., but is also necessary to power living organisms (people, animals, plants, etc.)
Sources of Energy Nonrenewable Renewable Inexhaustible
Nonrenewable Energy This is a source of energy that once used, cannot be replenished Examples: Coal, Natural gas, Nuclear, etc.
Renewable Energy This is a source of energy that can be replenished if it is used. Examples: wood, ethanol, food, etc.
Inexhaustible Energy This is a source of energy that can be considered permanent (at least for a few million more years). Examples: Sun, Wind, Waves, Geothermal
Renewable & Inexhaustible Energy To combat the ill effects, and high costs of nonrenewable energy sources, new technology must be developed. These new energy technologies must heavily rely on renewable and inexhaustible resources in order to be sustainable
Energy vs. Power Energy is defined as “the ability to do work” Power is a term used to describe the measure of work being done (rate)
World-wide, with the exception of coal, which has known reserves that will last a couple of centuries, the known reserves of oil are expected to be exhausted in your lifetime... Clearly, alternative energy sources are needed for the future Alternative Energy Sources
We will look at: Solar energy Geothermal power Hydropower Tidal Power Ocean thermal energy conversion Wind energy Biomass Alternative Energy Sources
Solar Energy The Sun is free (nobody owns or controls it) In principle, the amount of solar energy that reaches the Earth’s surface could provide for all human energy needs forever
Solar Energy The distribution of solar energy over the continental U.S. in watts per square meter The desert regions of the southwest U.S. receive the most sunlight
Clean Solar Energy Solar energy is clean energy It produces no hazardous solid, liquid or gas wastes It does not create water or air pollution
Solar Energy The two areas in which solar energy can make the greatest contribution are in space heating and in the generation of electricity These are uses that account for two-thirds of U.S. energy consumption
Solar Heating The simplest approach to solar heating is passive-solar heating The building design should allow the maximum amount of sunlight to stream in through south and west windows during the cooler months This heats the house and materials inside
Solar Heating Trees can be positioned to shade the house in summer Wide eaves can shade windows in summer, but allow winter sunlight to enter Drapes and shutters can insulate window areas in winter
Solar Heating It has been estimated that 40 to 90% of most homes’ heating requirements could be supplied by passive-solar heating systems 100% solar homes have been built, but such homes usually cost many tens of thousands of dollars more to build Retrofitting older homes to be solar efficient can be too costly Over insulation can aggravate indoor pollution
Solar Electricity Direct production of electricity using sunlight is accomplished using photovoltaic cells, also called solar cells They have no moving parts and are “clean” energy They are used to power the space station and to provide electricity in remote areas on Earth
Solar Electricity A major limitation is cost, which greatly exceeds the cost of producing electricity using fossil fuels or nuclear power The best solar cells are only 20% efficient and only provide 50 watts of electricity per square meter of cell size
Solar Electricity A 100 watt light bulb would require 2 square meters of solar cells And a 100-megawatt power plant would require 2 square kilometers (0.78 square miles) of solar cells This represents a major use of land and resource, which would use far more steel and concrete than a fossil fuel power plant
Storing Solar Electricity In a solar energy home, extra electricity is stored in batteries for later use This work well for one house Unfortunately, no wholly practical technology has been developed to store large amounts of electricity, despite advances in batteries
Storing Solar Energy Some possible schemes for storing the energy of solar generated electricity include breaking up water into oxygen and hydrogen to burn later as fuels Also pumping water to an elevated reservoir for later use as hydroelectric power generation
Solar Energy Currently, solar energy provide less that 0.5% of the U.S. power needs, but even with existing technology, it could provide up to 15%
Solar Electricity In summation, to make solar energy truly useful for large-scale power generation: We need more efficient solar cells We need a means of better storing electricity
Geothermal Power
Magma rising from the mantles brings unusually hot material near the surface Heat from the magma, in turn, heats any groundwater This is the basis for generating geothermal energy
Geothermal Power The steam and/or hot water is used to create electricity or for heating
Geothermal Power Plants Worldwide, there are now about 40 geothermal power plants, especially in Japan, Mexico and the Philippines Note that most geothermal power plants are built along plate tectonic boundaries
Geothermal Power Plants How the geothermal energy is used depends on the temperature of the water Three types of power plants are used to generate power from geothermal energy: Dry steam Flash Binary
Types of Geothermal Power Dry steam plants take steam out of the ground and uses the steam to turn a turbine that spins a generator This was first done in Italy in 1904 Iceland, a volcanic island, has many geothermal areas that produce steam and are tapped to generate electricity
Types of Geothermal Power Flash plants take super heated water, usually at temperatures over 200°C, out of the ground, allowing it to boil as it rises to the surface, then separates the steam from the water and uses the steam to turn a turbine generator A flash power plant in Japan
Types of Geothermal Power In binary plants, the hot water flows through heat exchangers, boiling an organic fluid that spins the turbine For all three types of power plants, the condensed steam and remaining geothermal fluid are injected back into the hot rock to pick up more heat This is why geothermal energy is viewed as sustainable It is also very “clean” Only produces steam
The Geysers, California The largest U.S. geothermal power plant is The Geysers in California (it uses dry steam) By 1989, a total of 10 billion watts of electricity was being produced by The Geysers and six other plants in the U.S.
Geothermal Power Plants By the end of 2005 worldwide use of geothermal energy for electricity had reached 9.3 billion watts, with an additional 28 billion watts used directly for heating In 1999, it was estimated that the U.S. could produce 100 billion watts of geothermal energy by 2050
Geothermal Heat Even if the geothermal water is not as hot as steam, the warm water can be used to heat buildings, home and even greenhouses This is routinely done in Russia and Iceland In fact, using geothermal energy to heat is about 2-3 times as common as using it to create electricity
Limitations Each geothermal field can only be used for a period of time, a few decades, before heat extraction is seriously reduced Simply put, you can take hot water out of the ground faster than it can be renewed (even if you pump the water back into the ground) For example, steam pressure at The Geysers has declined rapidly over recent years It peaked at over 2 billion watts by 1991, but now in 2011 produces about 0.7 billion watts
Hydropower One-third (33%) of all power plants in the U.S. are hydroelectric, but they only generate 6% of U.S. electricity needs
Hydropower A cross-section of a typical hydroelectric dam Water flows down the penstock, turns the turbine blades which power the generators
Hydropower Water use for generating hydroelectric power is totally dependent on the available water (duh!!) The Glen Canyon Dam in Utah is the classic example of building too big of dam for not enough water
Hydropower Hydropower is a very clean, pollution-free, renewable energy source The water is not consumed, but rather simply passes thru the generating equipment, and since several dams may occur along the same river, the water can be reused and reused
Hydropower If every stream and river in America was dammed to generate power, you still only provide 20% of current U.S. power needs There are about 1000 dams in the U.S. and there is very little prospect of building any new ones In fact, some older dams have been removed, such as the 162 years old Edwards Dam in Maine
Three Gorges Dam The Three Gorges Dam is now the largest hydroelectric dam in the world
Three Gorges Dam As a size comparison, it is 5 times larger than the Hoover Dam on the Colorado River
Three Gorges Dam The dam is 185 meters (600 feet) high and 2.3 kilometers (1.4 miles) wide It has 26 hydroelectric power generators with a collective generating capacity of about 18,000 megawatts (the average nuclear power plant generates about 1000 megawatts)
Three Gorges Dam The Chinese began filling the reservoir in 2003 When filled to capacity, the reservoir will hold 22 cubic kilometers of water
Three Gorges Dam As with any engineering project of great magnitude, there are serious problems The reservoir will eventually stretch over 600 kilometers (375 miles) in length It will submerge 125,000 acres of prime farmland
Three Gorges Dam 1,900,000 people were forced to relocate, many against their will Entire cities have been abandoned Over 1200 historic areas are being flooded
Three Gorges Dam Three spectacular river gorges called Qutang, Wuxia and Xiling, all worthy of being national parks, have been flooded
Three Gorges Dam Officials report that the cost is within its US$25 billion budget and insisted early on that the project would pay for itself through electricity generation However, the project is thought to have cost more than any other single construction project in modern China, with unofficial estimates of US$100 billion or more
Tidal Power All large bodies of water, including the oceans and large lakes, have tides Tidal power captures the energy contained in moving water mass due to tides
Tidal Power Two types of tidal energy can be extracted: Kinetic energy of currents between ebbing and surging tides Potential energy from the difference in height (or head) between high and low tides
Tidal Power You can use the flowing water between low and high tides to generate electricity, similar to hydropower
Tidal Power Turbines can be place on the ocean floor, for example at the entrance of a bay, where the flowing water can turn the fan to generate electricity
Tidal Power Another option is to use under water turbines, which is like an underwater wind farm This is currently being tested offshore of Scotland’s Orkney Islands The ebbing and surging tidal flows turn 100 foot propellers, which each produce 1 megawatts of electricity
Ocean energy thermal conversion (OTEC) is a new, clean technology that is still in the developmental stage It exploits the temperature difference between warm surface water and the cold water at depth to run a “heat engine” A heat engine is a device placed between a high temperature reservoir and a low temperature reservoir that produces energy OTEC
Either the warm water is used directly to run a turbine, or the heat is used to vaporize a working fluid (ammonia) which runs the turbine OTEC The cold water is used to chill down the water or vapor Drinkable, distilled fresh water is a by- product
The temperature difference must be at least 40 o F (22 o C) year round, which is only found near the equator So this emerging technology is best for tropic islands OTEC
A test plant is currently being constructed at Keahole Pointe on the Kona coast of Hawaii and should become operational in 2013 OTEC
Wind energy has been utilized for thousands of years Wind Energy
The wind is free, commonly available and can provide clean, pollution-free energy Today’s wind-turbines are very high tech Wind Energy
In most places, the cost of commercial wind power on a large scale is not now economically competitive with conventionally generated electricity One important factor is that with a doubling of wind speed, power output increases by a factor of 8 Wind Energy
The numbers indicate the percentage of 1990 regional electricity demand that full utilization of wind energy could meet Clearly, the great plains have significant wind energy potential Wind Energy
U.S. wind power capacity from 1981 to 2002 Wind Energy
U.S. wind power capacity from 1996 to 2008 Wind Energy
The U.S. remains the world leader in wind energy, but Europe has embarked on an very ambitious wind-power development program Wind Energy It is predicted that by 2030, wind energy will supply at least twice the electricity it does now
It would take about 1000 one-million watt windmills to equal the energy output of one sizable fossil fuel power plant Wind Energy Limitations The windmills can be noisy And they are hard on migrating birds
Biomass energy is derived from organic matter Stoves that burn wood are the classic example In fact, there had been a 20-25% increase in the use of wood stoves over the past several decades Biomass Energy
Biofuels differ from other renewable energy sources, such as wind, hydroelectric, geothermal and solar, as they are primarily used in the transportation sector and are derived from recently living matter, both plant and animal Biomass Fuels or Biofuels
Ethanol fuel is a biofuel alternative to gasoline, which is gaining popularity world-wide Car engines can be designed to run on 10%, 50% even 100% pure ethanol Ethanol Fuel It is cleaner burning than gasoline Worldwide, the use of ethanol is rapidly increasing
Ethanol fuel mixtures have "E" numbers which describe the percentage of ethanol in the mixture by volume, for example, E85 is 85% ethanol and 15% gasoline “E” Numbers Low ethanol blends, from E5 to E25, are also known as gasohol, though internationally the most common use of the term gasohol refers to the E10 blend
E10 gasohol is becoming more commonly found at gas stations in the U.S. (Tennessee is way behind) As the “10” indicates it is made from a mixture of gasoline (90%) and ethanol (10%) Gasohol Gasohol has higher octane, or antiknock, properties than gasoline and burns more slowly, more cooler, and more completely, resulting in reduced emissions of some pollutants
Ethanol Fuel Automotive ethanol capabilities vary widely country to country, but most spark-ignited gasoline style engines will operate well with mixtures of up to 10% ethanol Brazil is the world leader in ethanol fuels In Brazil, ethanol-powered and flexible-fuel vehicles are manufactured to be capable of operation by burning hydrated ethanol, an azeotrope of 93% ethanol and 7% water
Ethanol Fuel Ethanol fuel is produced from sugar cane in Brazil, which is a more efficient source of fermentable carbohydrates than corn as well as much easier to grow and process in the tropical climate
UT & Switchgrass The UT Biofuels Initiative has started testing the use of switchgrass, which is believed to offer a greater ethanol yield than corn in a temperate climate, such as in Tennessee
UT & Switchgrass The project represents the culmination of years of corporate research and development and a highly touted $40.7 million investment from the state of Tennessee to build a plant for demonstrating technology developed by DuPont Danisco Cellulosic Ethanol
Most of the world still relies very heavily on fossil fuels, but slowly but surely, attention is being diverted to alternative energy Energy use in the future will not be dominated by a single source Alternative Energy Sources
The most important aspects of most alternative energy sources is that they promise clean, pollution-free energy Alternative Energy Sources