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Conventional Energy

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Title: Conventional Energy


1
Conventional Energy
2
Outline
  • Energy History
  • How Energy Is Used
  • Coal
  • Oil
  • Natural Gas
  • Nuclear Power
  • Fission
  • Reactors
  • Waste Management
  • Fusion

3
WHAT IS ENERGY
  • Work - Application of force through a distance.
  • Energy - The capacity to do work.
  • Power - Rate at which work is done.
  • Calorie - Amount of energy necessary to heat 1
    gram of water 1o C.
  • Joule - Amount of work done when a force of 1
    newton is exerted over 1 meter.

4
Energy History
  • Muscle power provided by domestic animals has
    been important since dawn of agriculture 10,000
    years ago.
  • World oil use peaked in 1979.
  • Oil prices rose ten-fold in 1970s.
  • Early 1980s saw increased interest in
    conservation and renewable energy.
  • Oil glut in mid 1980s caused prices to fall.
  • U.S. now imports over half annual oil supply.

5
Current Energy Sources
  • Fossil fuels currently provide about 86 of all
    commercial energy in the world.
  • Hydroelectric dams supply about 7 of commercial
    power.
  • Nuclear power makes up about 6.5 of commercial
    power, but about 20 of electric power in
    more-developed countries.

6
Worldwide Commercial Energy Production
7
Per Capita Consumption
  • Richest 20 countries consume nearly 80 of
    natural gas, 65 of oil, and 50 of coal
    production annually.
  • On average, each person in the U.S. and Canada
    uses more than 300 GJ (equivalent to 60 barrels
    of oil) of energy annually.
  • In poorest countries of the world, each person
    generally consumes less than one GJ annually.

8
Per Capita Energy Use and GDP
9
HOW ENERGY IS USED
  • Largest share of energy used in the U.S. is
    consumed by industry (33).
  • Residential and Commercial buildings use 20 of
    primary energy consumed in U.S..
  • Transportation consumes about 27 of all energy
    used in the U.S..
  • Three trillion passenger miles and 600 billion
    ton miles of freight carried annually by motor
    vehicles in the U.S..

10
How Energy Is Used
  • About half of all energy in primary fuels is lost
    during conversion to more useful forms while
    being shipped, or during use.
  • Nearly two-thirds of energy in coal being burned
    to generate electricity is lost during thermal
    conversion in the power plant.
  • Another 10 is lost during transmission and
    stepping down to household voltages.

11
U.S. Energy Flow
12
COAL
  • Fossilized plant material preserved by burial in
    sediments and compacted and condensed by
    geological forces into carbon-rich fuel.
  • Most laid down during Carboniferous period (286
    million to 360 million years ago).

13
Coal
  • Resources and Reserves
  • World coal deposits are ten times greater than
    conventional oil and gas resources combined.
  • Under current consumption rates, this could last
    several thousand years.

14
Proven-In-Place Coal Reserves
15
Coal
  • Mining
  • Between 1870 and 1950, more than 30,000 coal
    miners died of accidents and injuries in
    Pennsylvania alone.
  • Several thousands have died of respiratory
    diseases.
  • Black Lung Disease - Inflammation and fibrosis
    caused by accumulation of coal dust in the lungs
    or airways.

16
Coal
  • Air Pollution
  • Coal burning releases radioactivity and toxic
    metals into the atmosphere.
  • Coal combustion is responsible for 25 of all
    atmospheric mercury pollution in the U.S..
  • Coal contains up to 10 sulfur by weight.
  • Unless removed by washing or flue-gas scrubbing,
    sulfur is released and oxidizes to sulfur dioxide
    or sulfate.

17
OIL
  • Petroleum is formed very similar to oil - Organic
    material buried in sediment and subjected to high
    pressure and temperature.
  • Oil pool usually composed of individual droplets
    or thin film permeating spaces in porous
    sandstone or limestone.
  • At least half of total deposit is usually
    uneconomical to pump out.
  • Secondary oil recovery techniques.

18
Oil Recovery Process
19
OIL
  • Resources and Reserves
  • Total amount of oil in the world is estimated at
    4 trillion barrels. (Half is thought to be
    ultimately recoverable)
  • In 2003, proven reserves were estimated at 1
    trillion barrels.
  • As oil becomes depleted and prices rise, it will
    likely become more economical to find and bring
    other deposits to market.

20
Proven Oil Reserves
21
Oil
  • Imports and Domestic Supplies
  • The U.S. has used about 40 of its original
    recoverable petroleum resource.
  • Of the 120 billion barrels thought to remain, 58
    billion are proven-in-place.
  • Until 1947, the U.S. was the worlds leading oil
    export country.
  • By 1998, the U.S. was importing 10 million
    barrels per day - Half of total consumption.

22
Oil
  • Oil Shales and Tar Sands
  • Estimates of total oil supply usually do not
    reflect large potential from unconventional oil
    sources such as shale oil and tar sand.
  • Could potentially double total reserve.

23
NATURAL GAS
  • Worlds third largest commercial fuel.
  • 23 of global energy consumption.
  • Produces half as much CO2 as equivalent amount of
    coal.
  • Most rapidly growing energy source.
  • Difficult to ship long distances, and to store in
    large quantities.

24
Natural Gas
  • Resources and Reserves
  • Proven world reserves of natural gas are 5,500
    trillion ft3.
  • Current reserves represent roughly 60 year supply
    at present usage rates.
  • Proven reserves in North America are about 250
    trillion ft3.

25
Proven Natural Gas Reserves
26
Unconventional Gas Sources
  • Methane hydrate - Small individual molecules of
    natural gas trapped in a crystalline matrix of
    frozen water.
  • Thought to hold 10,000 gigatons of carbon, or
    twice as much as combined amount of all
    traditional fossil fuels combined.
  • Difficult to extract, store, and ship.

27
NUCLEAR POWER
  • President Dwight Eisenhower, 1953, Atoms for
    Peace speech.
  • Nuclear-powered electrical generators would
    provide power too cheap to meter.
  • Between 1970 and 1974, American utilities ordered
    140 new reactors for power plants.

28
Nuclear Power
  • After 1975, only 13 orders were placed for new
    nuclear reactors, and all of those were
    subsequently cancelled.
  • In all, 100 of 140 reactors on order in 1975 were
    cancelled.
  • Electricity from nuclear power plants was about
    half the price of coal in 1970, but twice as much
    in 1990.

29
Nuclear Power Plant History
30
How Do Nuclear Reactors Work ?
  • Most commonly used fuel is U235, a naturally
    occurring radioactive isotope of uranium.
  • Occurs naturally at 0.7 of uranium, but must be
    enriched to about of 3.
  • Formed in cylindrical pellets (1.5 cm long) and
    stacked in hollow metal rods (4 m long).
  • About 100 rods are bundled together to make a
    fuel assembly.
  • Thousands of fuel assemblies bundled in reactor
    core.

31
How Do Nuclear Reactors Work
  • When struck by neutrons, radioactive uranium
    atoms undergo nuclear fission, releasing energy
    and more neutrons.
  • Triggers nuclear chain reaction.

32
Nuclear Fission
33
How Do Nuclear Reactors Work
  • Reaction is moderated in a power plant by
    neutron-absorbing solution (Moderator).
  • In addition, Control Rods composed of
    neutron-absorbing material are inserted into
    spaces between fuel assemblies to control
    reaction rate.
  • Water or other coolant is circulated between the
    fuel rods to remove excess heat.

34
Kinds of Reactors
  • Seventy percent of nuclear power plants are
    pressurized water reactors.
  • Water circulated through core to absorb heat from
    fuel rods.
  • Pumped to steam generator where it heats a
    secondary loop.
  • Steam from secondary loop drives high-speed
    turbine producing electricity.

35
Kinds of Reactors
  • Both reactor vessel and steam generator are
    housed in a special containment building
    preventing radiation from escaping, and providing
    extra security in case of accidents.
  • Under normal operating conditions, a PWR releases
    very little radioactivity.

36
PWR
37
Kinds of Reactors
  • Simpler, but more dangerous design is a boiling
    water reactor.
  • Water from core boils to make steam, directly
    driving turbine generators.
  • Highly radioactive water and steam leave
    containment structure.
  • Canadian deuterium reactors - Operate with
    natural, un-concentrated uranium.
  • Graphite moderator reactors - Operate with a
    solid moderator instead of a liquid.

38
Alternative Reactor Designs
  • High-Temperature, Gas-Cooled Reactors
  • Uranium encased in tiny ceramic-coated pellets.
  • Process-Inherent Ultimate Safety Reactors
  • Reactor core submerged in large pool of
    boron-containing water within a massive pressure
    vessel.

39
Breeder Reactors
  • Breeder reactors create fissionable plutonium and
    thorium isotopes from stable forms of uranium.
  • Uses plutonium reclaimed from spent fuel from
    conventional fission reactors as starting
    material.

40
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41
Breeder Reactor Drawbacks
  • Reactor core must be at very high density, thus
    liquid sodium used as a coolant.
  • Corrosive and difficult to handle.
  • Core will self-destruct within a few seconds if
    primary coolant is lost.
  • Produces weapons-grade plutonium.

42
RADIOACTIVE WASTE MANAGEMENT
  • Until 1970, the U.S., Britain, France, and Japan
    disposed of radioactive waste in the ocean.
  • Production of 1,000 tons of uranium fuel
    typically generates 100,000 tons of tailings and
    3.5 million liters of liquid waste.
  • Now approximately 200 million tons of radioactive
    waste in piles around mines and processing plants
    in the U.S..

43
Radioactive Waste Management
  • About 100,000 tons of low-level waste (clothing)
    and about 15,000 tons of high-level (spent-fuel)
    waste in the U.S..
  • For past 20 years, spent fuel assemblies have
    been stored in deep water-filled pools at the
    power plants. (Designed to be temporary)
  • Many internal pools are now filled and a number
    plants are storing nuclear waste in metal dry
    casks outside.

44
Radioactive Waste Management
  • U.S. Department of Energy announced plans to
    build a high-level waste repository near Yucca
    Mountain Nevada in 1987.
  • Facility may cost between 10 and 35 billion, and
    will not open until at least 2010.

45
Decommissioning Old Nuclear Plants
  • Most plants are designed for a 30 year operating
    life.
  • Only a few plants have thus far been
    decommissioned.
  • General estimates are costs will be 2-10 times
    more than original construction costs.

46
CHANGING FORTUNES OF NUCLEAR POWER
  • Public opinion has fluctuated over the years.
  • When Chernobyl exploded in 1985, less than
    one-third of Americans favored nuclear power.
  • Now, half of all Americans support
    nuclear-energy.
  • Currently, 103 nuclear reactors produce about 20
    of all electricity consumed in the U.S..

47
Changing Fortunes
  • With natural gas prices soaring, and electrical
    shortages looming, many sectors are once again
    promoting nuclear reactors.
  • Over the past 50 years, the U.S. government has
    provided 150 billion in nuclear subsidies, but
    less than 5 billion to renewable energy research.

48
NUCLEAR FUSION
  • Nuclear Fusion - Energy released when two smaller
    atomic nuclei fuse into one large nucleus. (Sun)
  • Temperatures must be raised to 100,000,000o C and
    pressure must reach several billion atmospheres.
  • Magnetic Confinement
  • Inertial Confinement
  • Despite 50 years and 25 billion, fusion reactors
    have never produced more energy than they consume.

49
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50
Summary
  • Energy History
  • How Energy Is Used
  • Coal
  • Oil
  • Natural Gas
  • Nuclear Power
  • Fission
  • Reactors
  • Waste Management
  • Fusion

51
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