La Jolla High School / Overview

Chapter 17: Energy: Some Basics
Energy Crisis in Ancient Greece
and Rome
• Greeks and Romans used wood to heat their
homes.
– As local supplies ran out had to bring it in from farther
away.
• Eventually both societies learned to build houses
south facing
– Allows sun to heat house in winter
– Sustainable
• In Rome laws pasted to protect a person’s right to
solar energy.
Energy Today and Tomorrow
• Energy situation facing the US today is
similar to that faced by Greeks and Romans.
• The decisions we make today will affect
energy use for generations.
Energy Basics
• In physicists’ terms
– Exerting force over a distance moved is work
• Work is the product of a force times a distance
– Energy is the ability to do work
• When the car is higher on the hill the potential
energy of the car has increased
• Energy can be converted from one kind to another
– The total energy conserved
– First law of thermodynamics
Energy Basics
• To illustrate the conservation and conversion of
energy think of a tire swing
– At highest position all energy is stored potential energy
– At lowest position all energy is kinetic energy
• Energy of motion
– With each swing friction slows the swing generating
heat energy
• Eventually all the energy is converted to heat and the swing
stops - that heat has NO ability to to WORK (it is not useful)
Energy Basics
• Energy quality
– The ability of the energy to do work
– The higher quality of the energy, the more easily it can
be converted to work.
– The lower the energy quality, the more difficult it is to
convert to work.
• Second law of thermodynamics
– Energy always tends to go from a more usable (higherquality) form to a less usable (lower-quality) form.
– When you use energy, you lower its quality.
Energy Efficiency
• The percentage difference between what is
available and what is actually translated into
usable energy
Energy used – Energy converted X 100%
Energy consumed
It may take 1000 KJ of energy rich coal to get
300 KJ of electrical energy (30%
Efficiency)
Energy Efficiencies
• Electricity generating plants have nearly the
same first-law and second-law efficiencies.
– Generating plants are examples of heat engines.
– Produces work from heat.
– Most of the electricity generated in the world
today comes from heat engines
• Use nuclear fuel, coal, gas, or other solid fuels.
Energy Source and Consumption
• Industrialized countries contain only a small
percentage of the world’s population, but
consume a disproportionate share of the
total energy produced in the world.
– E.g. US with only 5% of the world’s
population, uses approximately 25% of the total
energy consumed.
Fossil Fuels and Alternative
Energy Sources
• 90% of the energy consumed in the US comes
from fossil fuels
– Petroleum, natural gas, and coal.
– They are essentially nonrenewable.
• Other sources of energy
– Include geothermal, nuclear, hydropower, and solar
– Referred to as alternative energy sources.
– Solar and wind, are not depleted by consumption and
are known as renewable energy - they are
SUSTAINABLE.
Energy Consumption in the US
Today
• US is dependent on three major fossil fuels
– coal; natural gas; and petroleum.
• From 1950 to late-1970s, energy consumption
increased tremendously
– From 30 exajoules to 80 exajoules.
• Since about 1980, energy consumption has
increased by roughly 20 exajoules.
– Suggests that policies to improve energy conservation
through efficiency improvements have been at least
partially successful.
Energy Consumption in the US
Today
• Energy losses are associated with
– the production of electricity and it’s transit
– Most energy losses occur because of the use of heat
engines
• Looking at the generalized energy flow of the US
for a particular year
– We imported considerably more oil than we produced
– Consumption distributed in three sectors: residential/
commercial, industrial, and transportation.
• We remain at risk to the politics of oil production
Energy Conservation, Increased
Efficiency and Cogeneration
• Conservation of energy
– Simply getting by with less demand for energy.
• Increased energy efficiency
– Involves designing equipment to yield more
energy output from a given amount of input
energy (first-law efficiency)
– Better matches between energy source and end
use (second-law efficiency).
Energy Conservation, Increased
Efficiency and Cogeneration
• Cogeneration
– Processes designed to capture and use waste
heat rather than release it as a thermal pollution.
– Using that waste heat, can increase the overall
efficiency of a typical power plant from 33% to
as much as 75%
– Could provided an estimated 10% of the power
capacity of the US
Building Design
• A spectrum of possibilities exists for increasing
energy efficiency and conservation in residential
buildings.
– Design and construct homes that minimize the energy
consumption
– Design buildings to take advantage of passive solar
potential
– For older homes:insulation, caulking, weather stripping,
installation of window coverings, storm windows, and
regular maintenance.
Industrial Energy
• Industrial production of goods continues to
grow significantly.
– U.S. industry consumes about one-third of the
energy produced.
– More industries are using co-generation and
more energy-efficient machinery.
Automobile design
• Early 1970s, the average US automobile got 14
mpg.
• By 1996, the average was 28 mpg for highway
driving.
– Fuel consumption rates did not improve much from
1996 to 1999.
• In 2004 many vehicles sold were SUVs and light
trucks with fuel consumption of 10–20 mpg.
– A loophole in regulations permits poorer fuel
consumption
– SUVs declined in 2006.
Automobile design
• Today, some hybrid (gasoline-electric) vehicles
exceeds 90 mpg on the highway and 60 mpg in the
city.
• Improvement has several causes:
– Increased efficiency and resulting conservation of fuel
– Cars that are smaller, w/ engines constructed of lighter
materials
– Combination of a fuel-burning engine with an electric
motor
Values, Choices, and Energy
Conservation
• Ways of modifying behavior to conserve energy
include the following:
– Ride a bike, walk, or take a bus or train to work.
– Using carpools to travel to and from work or
school
– Purchasing a hybrid car (gasoline-electric)
– Turning off lights when leaving rooms
– Taking shorter showers (conserves hot water)
– Putting on a sweater and turning down the
thermostat
Values, Choices, and Energy
Conservation
– Using energy-efficient compact florescent lightbulbs
– Purchasing energy-efficient appliances
– Sealing drafts in buildings with weather stripping
and caulk
– Better insulating your home
– Washing clothes in cold water whenever possible
– Purchasing local foods to reduce energy in transport
– Using powerstrips and turning them off when not in
use
Energy Policy
• U.S. energy policy during the past
half-century has not moved us
closer to energy self-sufficiency.
– We import more oil than ever.
– In the late 1990s, the US spent $2
billion per year on R and D for energy.
– By comparison, $45 billion per year
went to R and D for the military.
Energy Policy Act of 2005
• Some of the provisions are as
follows.
– 1. Promotes conventional energy
sources
– 2. Promotes nuclear power
– 3. Encourages alternative energy
– 4. Promotes conservation measures
– 5. Promotes research
– 6. Provides for energy infrastructure
Hard Path vs. Soft Path
• Hard path involves finding greater amounts
of fossil fuels and building larger power
plants.
– Continuing the past emphasis on quantity of
energy used.
– Requires no new thinking; no realignment of
political, economic, or social conditions; and
little anticipation of coming reductions of oil
supply.
Hard Path vs. Soft Path
• According to hard-path proponents, we
should
– 1. Let the energy industry develop the available
energy resources
– 2. Let industry, free from government
regulations, provide a steady supply of energy
with less total environmental damage (it
assumes that corporations will “do the right
thing” ….. Like AIG? Like Enron? Like Bears
and Stearns?).
Hard Path vs. Soft Path
• The second road of energy policy is called
the soft path.
• It involves energy alternatives that
emphasize
– energy quality, are renewable, are flexible, and
are environmentally more benign than those of
the hard path.
Hard Path vs. Soft Path
• These alternatives for “soft path energy”
have several characteristics:
– They rely heavily on renewable energy
resources, such as sunlight, wind, and
biomass.
– They are diverse and are tailored for
maximum effectiveness under specific
circumstances.
– They are flexible, accessible, and
understandable to many people.
– They are matched in energy quality,
geographic distribution, and scale to end-use
Energy for Tomorrow
• Future changes in population densities as
well as intensive conservation measures will
probably change existing patterns of energy
use.
• To stabilize the climate in terms of global
warming, use of energy from fossil fuels
would need to be cut by about 50%.
– Reductions in energy use need not be
associated w/ lower quality of life – who would
have an interest in us thinking it would?.
Energy for Tomorrow
• What is needed is increased conservation and
more efficient use of energy:
– More energy-efficient land-use planning that
maximizes the accessibility of services and minimizes
the need for transportation.
– Agricultural practices and personal choices that
emphasize
• 1. Eating more locally grown foods
• 2. Community Sponsored Agriculture (CSA’s)
• 3. Eating more vegetables, beans, and grains.
– Industrial guidelines for factories that promote energy
conservation and minimize production of waste.
Integrated, Sustainable Energy
Management
• Integrated energy management recognizes
that no single energy source can provide all
the energy required.
– Range of options that vary from region to
region will have to be employed.
– The mix of technologies and sources of energy
will involve both fossil fuels and alternative,
renewable sources.
Integrated, Sustainable Energy
Management
• A basic goal is to move toward sustainable energy
development, implemented at the local level.
• Would have the following characteristics:
– It would provide reliable sources of energy.
– It would not cause destruction or serious harm to our
global, regional, or local environments.
– It would help ensure that future generations inherit a
quality environment with a fair share of the Earth’s
resources.
Integrated, Sustainable Energy
Management
• A good energy plan is part of an aggressive
environmental policy with the goal of
producing a quality environment for future
generations.
• A good plan should do the following:
– Provide for sustainable energy development.
– Provide for aggressive energy efficiency and
conservation.
Integrated, Sustainable Energy
Management
– Provide for the diversity and integration of
energy sources.
– Provide for a balance between economic health
and environmental quality.
Integrated, Sustainable Energy
Management
• The global pattern of everincreasing energy consumption led
by the US cannot be sustained w/o a
new energy paradigm
– Includes changes in human values rather than a
breakthrough in technology.
– Choosing to own fuel-efficient automobiles and living in
more energy-efficient homes are consistent with a
sustainable energy system.
– Eating locally grown foods