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When a commodity
becomes increasingly expensive, market forces will seek or
develop alternatives to that product or service. In the case of
“energy,” which has taken on the characteristics of a commodity,
alternative fuels have yet to receive the price signal needed to
flourish.
As
a result of high oil prices, declining global supply, and a
strong global economy, alternative energy is gaining momentum as
a commercially viable ‘alternative’ to traditional means of
energy production and consumption. Moreover, from a security
and independence standpoint, it is vital for the U.S. to reduce
its dependence on foreign firms and countries for energy
sources. For example, OPEC controls an estimated 40% of global
oil production whereas the U.S. is estimated to hold less than
3% of proven global oil reserves. Finally, concerns over the
impact on global warming from the consumption of conventional
fuels not only from the production of electric but from auto
emissions and industrial production are forcing the exploration
and development of the vast array of alternative fuels. The
impact of current energy use on the environment has taken on
global importance, resulting in numerous investment
opportunities outside the United States.
What is an Alternative Fuel Company?
Conventional fuels,
especially for the production of electricity still remain
economically dominant. For the purposes of discussion we believe
it is critical to define what conventional and alternative fuels
are, and, are not. Conventional fuels include:
-
Coal & Lignite
-
Oil & Natural
Gas
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Nuclear
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Hydroelectric
Alternatives fuels
are essentially any source of electricity production which is
not from the above mention resources.
Alternative energy options are many and varied. Below is a list
of the major alternative energy options.
Ethanol
Wheat
Vegtable
Oil
Animal
Slurry Digestion & Litter
Food Waste
Municipal &
Industrial Waste
Straw
Wood & Wood
Waste
Biopolymers
The term “alternative
fuel” can be broadly defined and, accordingly, investment
opportunities can encompass highly specialized span areas within
the universe. The sector is polarized, consisting of large well
capitalized companies, having a “conglomerate”-like” profile
which are not focused solely on developing pure green energy or
alternative energy resources, such as General Electric (total
capitalization $739 billion), Chevron Corp. ($140.0 billion),
Archer-Daniels Midland ($25 billion).
At the other end
other end of the spectrum are companies with a main emphasis on
a particular form of alternative energy. These companies tend to
be elemental, and not broadly capitalized, for example, Beacon
Power Corp. ($ 11.6 million total capitalization), Plug Power
($289.5 million), and Pacific Ethanol Inc. ($545.6 million).
These companies tend to be extremely speculative, having a
substantial mortality rate and volatile trading pattern than
conventional energy — namely those readily characterized as
coal, oil & gas, nuclear and hydro companies.
ALTERNATIVE ENERGY DESCRIPTIONS & TECHNOLOGIES DESCRIPTIONS:
Advanced Nuclear Technologies (specially, Nuclear Fusion)
The process of joining the nuclei of two atoms together. Energy
is equal to mass times the speed of light squared. It is easy to
see that a small amount of mass can be converted into an
enormous amount of energy. Research into controlled fusion, with
the aim of producing
fusion
power for the production of electricity, has been
conducted for over 50 years. It has been accompanied by extreme
scientific and technological difficulties, and as of yet has not
been successful in producing workable designs. the only
self-sustaining fusion reactions produced by humans have been
produced in hydrogen bombs, where the extreme power of a fission
bomb is necessary to begin the process.
Some plans have been put forth to attempt to use the explosions
of hydrogen bombs to generate electricity (notably, the
PACER
Project), yet none of these have moved past the design stage.
The PACER project would absorb the energy of the explosion in
a molten salt, which would then be used in a
heat
exchanger to heat water for use in a
steam
turbine. In the original fusion-bomb proposal, a huge
cavity would be emptied in a
salt dome,
but further developments used engineered cavities instead. As an
energy source, the system is the only one that could be
demonstrated to work using existing technology. However it would
also require a large, continuous supply of nuclear bombs, making
the economics of such a system rather questionable.
Air
Pollution Control Devices
One of the primary pollution control devices are Scrubbers.
Scrubber
systems are a diverse group of
air pollution control devices that can be used to remove
particulates and/or gases from industrial exhaust streams.
Traditionally, the term "scrubber" has referred to pollution
control devices that used liquid to "scrub" unwanted pollutants
from a gas stream. Recently, the term is also used to describe
systems that inject a dry reagent or
slurry into a dirty exhaust stream to "scrub out" acid
gases. Scrubbers are one of the primary devices that control
gaseous emissions, especially acid gases. The exhaust gases of
combustion may at times contain substances considered
harmful to the environment, and it is the job of the scrubber to
either remove those substances from the exhaust gas stream, or
to neutralize those substances so that they cannot do any harm
once emitted into the environment as part of the exhaust gas
stream.
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Anatomy of an Air Scrubber |
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One side effect of scrubbing is that the process only moves the
unwanted substance from the exhaust gases into a solid paste or
powder form. If there is no useful purpose for this solid waste,
it must be either contained or buried to prevent environmental
contamination. Limestone-based scrubbers can produce a synthetic
gypsum of sufficient quality that can be used to manufacture
drywall and other industrial products.
Wet Scrubbing
A
wet scrubber
is used to clean air or other gases of various pollutants and
dust particles. Wet scrubbing works via the contact of target
compounds or particulate matter with the scrubbing solution.
Solutions may simply be water (for dust) or complex solutions of
reagents that specifically target certain compounds. Wet
scrubbers are only effective for mercury removal under certain
conditions. Mercury removal results in a waste product that
either needs further processing to extract the raw mercury, or
must be buried in a special hazardous wastes landfill that
prevents the mercury from seeping out into the environment.
Wet Scrubber methodologies and approaches can also be referred
to as:
Removal efficiency of pollutants is improved by increasing
residence time in the scrubber or by the increase of surface
area of the scrubber solution by the use of a
spray nozzle,
packed towers or an
aspirator.
Wet scrubbers will often significantly increase the
proportion of water in waste gases of industrial processes which
can be seen in a stack plume
Dry Scrubbing
A
dry or
semi-dry scrubbing system,
unlike the
wet scrubber, does not saturate with moisture the flue gas
stream that is being treated. In some cases no moisture is
added; while in other designs only the amount of moisture that
can be evaporated in the flue gas without condensing is added.
Therefore, dry scrubbers do not have a stack steam plume or
wastewater handling/disposal requirements. Dry scrubbing
systems are used to remove
acid gases (such as SO2 and HCl) primarily from
combustion sources.
Scrubbers can be referred to beyond just “wet” and “dry,” for
example, other common names for scrubber technology are:
Flue gas
desulphurization, oil desulphurization, Electrostatic
Precipitator:
Flue gas desulfurization
(FGD) is the current state-of-the art technology used for
removing
sulfur dioxide (SO2) from the exhaust
flue gases in
power plants that burn coal or oil to produce steam for the
steam turbines that drive their electricity
generators. Sulfur dioxide is responsible for
acid rain formation. Tall
flue gas stacks disperse the emissions by diluting the
pollutants in ambient air and transporting them to other
regions.
Oil
desulphurization,
also known as
Hydrodesulfurization
(HDS) is a
catalytic chemical process widely used to remove
sulfur (S) from
natural gas and from
refined petroleum products such as
gasoline or petrol,
jet fuel,
kerosene,
diesel fuel, and
fuel oils.
The purpose of removing the sulfur is to reduce the sulfur
dioxide (SO2) emissions that result from using those
fuels in automotive
vehicles,
aircraft, railroad
locomotives,
ships, gas or oil burning
power plants, residential and industrial
furnaces, and other forms of fuel
combustion. An
electrostatic precipitator
(ESP), or electrostatic air cleaner is a
particulate collection device that removes particles from a
flowing gas (such as air) using the force of an induced
electrostatic charge. Electrostatic precipitators are highly
efficient
filtration devices that minimally impede the flow of gases
through the device, and can easily remove fine particulate
matter such as dust and smoke from the air stream.
Biofuels & Biodiesel (i.e. Energy Crops),
Biomass & Agricultural Waste (Waste-to-Energy)
Biofuel
can be broadly defined as solid, liquid, or gas
fuel consisting of, or derived from
biomass. The definition used here is narrower: biofuel is
defined as liquid or gas transportation fuel derived from
biomass.
Biomass can also be used directly for heating or power: this
is commonly called
biomass fuel: Biomass is material
derived from recently living
organisms. It includes plants, animals and their
by-products. For example, manure, garden waste and crop residues
are all sources of biomass, including manure, garden waste and
crop residues.
Agricultural products specifically grown for biofuel
production include
corn and
soybeans, primarily in the United States;
rapeseed,
wheat and
sugar beet primarily in Europe;
sugar cane in Brazil; and
palm oil in South-East Asia;
Biodegradable outputs from industry, agriculture, forestry
and households can be used for biofuel production, either using
anaerobic digestion to produce
biogas.
Examples
Second Generation Biofuel processes
consist of
straw,
timber,
manure,
rice husks,
sewage
and
food waste.
The use of biomass fuels can therefore contribute to waste
management as well as fuel security and climate change
Biofuel is considered an important means of reducing
greenhouse gas emissions and increasing
energy security by providing a viable alternative to
fossil fuels. Biofuels are used globally: biofuel industries
are expanding in Europe, Asia and the Americas. The most common
use for biofuels is in automotive transport (for example
E10 fuel). Biofuel can be produced from any carbon source
that can be replenished rapidly e.g. plants. Many different
plants and plant-derived materials are used for biofuel
manufactured.
 Biodiesel
typically
refers to a
diesel-equivalent processed fuel derived from biological
sources (such as
vegetable oils) which can be used in unmodified
diesel-engine vehicles. It is thus distinguished from the
straight vegetable oils (SVO)
or
waste vegetable oils (WVO)
or
animal fats
used as fuels in some diesel vehicles. Biodiesel
is
biodegradable and non-toxic,
and typically produces about 60% less net
carbon dioxide emissions than
petroleum-based diesel, since Biodiesel fuels are
produced from atmospheric
carbon dioxide via
photosynthesis in plants.
Biopolymers
are a class of polymers produced by
living organisms,
such as
starch,
proteins
and
peptides,
DNA,
and
RNA
are all examples of biopolymers. A major but defining
difference between
polymers
and
biopolymers
can be found in their structures – specifically,
Biopolymers
inherently have a well defined structure and chemical sequence.
Carbon Sequestration
Carbon Sequestration,
also know as
Carbon Capture and Storage (CCS),
is an approach to
mitigating global warming by capturing
carbon dioxide (CO2) from large point sources
such as
power plants and subsequently storing it instead of
releasing it into the atmosphere. The merit of CCS systems is
the reduction of CO2 emissions by up to 90%,
depending on plant type. Technology for capturing of CO2
is already commercially available for large CO2
emitters, such as power plants; Storage of CO2, on
the other hand, is a relatively untried concept and as yet
(2007) no power plant operates with a full carbon capture and
storage system.
In theory,
CCS applied to a modern conventional power plant could reduce CO2
emissions to the atmosphere by approximately 80-90% compared to
a plant without CCS. CCS, however, is a costly and energy
intensive process, recently studies indicates that Capturing and
compressing CO2 requires much energy and would
increase the fuel needs of a plant with CCS by about 10-40%. In
those current estimates place the total cost of energy from a
power plant with CCS would be higher by 30-60%.
Various
forms have been conceived for permanent storage of CO2.
These forms include gaseous storage in various deep geological
formations (including saline formations and exhausted gas
fields), liquid storage in the ocean, and solid storage by
reaction of CO2 with metal
oxides to produce stable
carbonates. Storage of the CO2 is envisaged
either in deep geological formations or deep ocean geological
formations. Further, surface storage capacity is limited and
some studies place the potential geological formations able to
accommodate CCS emissions at between 10% and 55% of the total
carbon mitigation effort until year 2100.
The
environmental effects of ocean storage are poorly understood but
it is generally believed that the environmental effects are
negative and would require more exhaustive study.
As of 2005, three industrial-scale storage projects are in
operation.
Sleipner
is the oldest
project (1996). Located in the North Sea where Norway's,
Statoil, the largest petroleum company in the
Nordic countries, strips carbon dioxide from natural gas
with amine solvents and disposes of this carbon dioxide in a
saline formation. The carbon dioxide is a waste product of the
field's natural gas production and the gas contains more (9% CO2)
than is allowed into the natural gas distribution network.
Storing it underground avoids this problem and saves Statoil
hundreds of millions of dollars in avoided
carbon taxes. Sleipner stores about one million
tonnes CO2 a year.
Coal
Gasification
Coal
Gasification is a process that converts carbonaceous materials,
such as
coal, into
carbon monoxide and
hydrogen by reacting the raw material at high temperatures
with a controlled amount of
oxygen. The resulting gas mixture is called
synthesis gas or
syngas and is itself a fuel. Gasification is a very
efficient method for extracting
energy from many different types of organic materials, and
also has applications as a clean
waste disposal technique. The advantage of gasification is
that using the
syngas is more efficient than direct combustion of the
original fuel; more of the energy contained in the fuel is
extracted.
Syngas may be burned directly in internal combustion
engines. Gasification can also begin with materials that are not
otherwise useful fuels, such as
biomass or
organic waste.
Almost any
type of
organic material can be used as the raw material for
gasification, such as wood,
biomass, or even
plastic waste. Thus, gasification may be an important
technology for
renewable energy. In particular
biomass gasification is
carbon neutral.
Conservation (a.k.a. Demand Side Management)
Conservation
and the term
Demand Side Management (DSM)
was phrases coined in the 1970s particular just following the
1973 energy crisis (i.e. Arab oil embargo) and became a
permanent part of the vernacular in 1979 after the Three Mile
Island nuclear accident. This disruption in these 2 fuel
supplies, resulted in a focus on alternating the “demand” side
of the energy Supply/Demand equitation. By 1979, it became
apparent that fossil fuels (coal, oil & natural gas, and
nuclear) were in a more finite supply than had been anticipated
at the beginning of the decade and, as a result, supervision the
Demand side of the energy equation had could play vital role in
the managing the supply and cost of energy. Hence, conservation
and DSM have become essential alternatives to the green energy
initiative. Energy conservation is an important part of
lessening climate change by the demand for electricity and thus
reducing carbon emissions.
Conservation and DSM are term
which can used synonymously, however, DSM is frequently used to
describe entails actions that influence patterns and quality of
energy used, notably such usage patterns targeted at the
reduction of peak demand load when energy-supply systems are
constrained to the maximum. Peak demand management does not
necessarily decrease total energy consumption. It is hoped that
used systematically, Conservation and DSM but could be expected
to reduce the need for investments in new power plants and,
even, infrastructure networks (notably, Transmission &
Distribution lines). Demand side management is also, today,
alternative referred to as demand
response.
Technologies and Approaches for
Demand Reduction & Conservation:
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Smart metering
has been implemented in some
jurisdictions to provide real-time pricing for all types of
users, as opposed to fixed-rate pricing throughout the
demand period. In this application, users have a direct
incentive to reduce their use at high-demand, high-price
periods.
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Shedding load
or as it is commonly know, turning
down or off certain appliances or sinks (and, when demand is
unexpectedly low, potentially increasing usage).
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Time of Day Pricing
would set the price of
electric a different intervals during the day to match the
cost of producing (and, thus, the “real time” cost of
consumption) electricity at vary times of the day. The
concept involves turning down or off certain appliances when
demand is expectedly low, thereby shifting demand to periods
when demand would be potentially higher, effectively
flattening cost the demand curve in order to reduce the need
(i.e. Supply) of electricity. For example,
air conditioning,
heating
or
refrigeration may be turned
down, delaying slightly the draw until a peak in usage has
passed.
Electricity use can vary
dramatically on short and medium time frames. Proponents of
Conservation & DSM feel that flexible pricing plans aimed at
various points on the demand curve, properly and instantaneously
reflect the cost as additional higher-cost ("peaking") electric
capacity and by reflecting the substantially higher incremental
cost of energy at the demand of “peak demand,” consumers will
adjust (ideally, reduce energy usage) based on the significant
higher cost of the service at the time of peak. This encourages
users to flatten their demand for energy. It is hoped that by
producing a “real” price signal, the result will be a reduction
in demand at the time of “peak” and a shifting of load to less
expensive (i.e. from a production perspective) points on the
Supply curve. By altering demand to reflect its real elasticity
(and therefore “cost” to the consumer), which can vary widely
during a day or given time frame, the need for new power plants
can be deferred many years, even decades.
Governments of many countries
mandated performance of various programs for demand management
after the 1973 energy crisis – the United States passed the
National Energy Conservation Policy Act of 1978. The success of
such programs depends on the development of appropriate
technology, a suitable pricing system for electricity, and the
cost of the underlying technology. In a 2004 report to Congress,
it was estimated that by 2007 the potential demand response
capability equaled about 20,500 megawatts (MW), 3% of total
U.S. peak demand. In 2007, the actual delivered peak demand
reduction was about 9,000 MW (1.3% of peak), leaving ample
margin for improvement
Fuel Cells & High Capacity Energy Storage
A
fuel cell is an
electrochemical energy conversion device. It produces
electricity from external supplies of fuel (on the anode side)
and oxidant (on the cathode side). These react in the presence
of an electrolyte. Generally, the reactants flow in and reaction
products flow out while the electrolyte remains in the cell.
Fuel cells can operate virtually continuously as long as the
necessary flows are maintained. Fuel cells differ from batteries
in that they consume a reactant (which must be replenished),
while batteries store electrical energy chemically in a closed
system. Many combinations of fuel and oxidant are possible. A
hydrogen cell uses hydrogen as fuel and oxygen as oxidant. Other
fuels include hydrocarbons and alcohols. Other oxidants include
air, chlorine and chlorine dioxide
The most common discussed Fuel Cell is the
Hydrogen-Fuel Cell.
Hydrogen is the lightest, and among the most abundant elements
in the universe. To use hydrogen as a fuel, it must be extracted
from another substance, such as water or natural gas. For this
reason, hydrogen is considered an energy carrier as opposed to
an energy source. In order to harness the energy in hydrogen, a
fuel cell is required. A fuel cell is similar to a battery that
never needs recharging as long as hydrogen is fed into the fuel
cell.
The cost of output from fuel cells in 2002, was
approximately $1000 per kilowatt of electric power production.
The goal is to reduce the cost in order to compete with current
market technologies including gasoline internal combustion
engines. Many companies are working on techniques to reduce cost
in a variety of ways including reducing the amount of platinum
needed in each individual cell.
Ballard Power Systems
have experiments with a catalyst enhanced with carbon silk which
allows a 30% reduction in platinum usage without reduction in
performance.
Storage systems are seen to provide by far the
broadest range of power quality protection. While storage
provides comprehensive protection, it may not be the economic
choice for each many customer - accordingly, Industrial
consumers may find it to be the best application for reliability
purposes. Storage systems have the ability to detect and respond
to the energy variability in energy supply delivery on a rapid
basis. Given the relatively high cost of installing large scale
energy storage facilities, Industrial consumers will find these
systems the preferred solution for voltage reduction,
under voltages, and power interruptions. At the current stage of
development, Residential and small Commercial users will find
available storage technologies prohibitively expensive.
One of the storage technologies holding consider
promise is that of Flywheels
-- a.k.a. Flywheel Energy Storage
Systems (FES) or "Flywheels".
A flywheel, in essence is a mechanical battery -
simply a mass rotating about an axis. Flywheels store energy
mechanically in the form of kinetic energy. They take an
electrical input to accelerate the rotor up to speed by using
the built-in motor, and return the electrical energy by using
this same motor as a generator. Certain companies believe that
Flywheels will serve as an important component for automobiles
and future energy needs. Flywheels are one of the most promising
technologies for replacing conventional lead acid batteries as
energy storage systems for a variety of applications, including
automobiles, economical rural electrification systems, and
stand-alone, remote power units commonly used in the
telecommunications industry.
Recent advances in the mechanical properties of
composites has rekindled interest in developing Flywheel
technologies for small-scale users, on an economically
competitive basis.
Illustrated below is an example of a
FES:
 
Flywheel energy storage systems (FES) also offer
several important advantages over forms of chemical energy
storage. The rate at which energy can be exchanged into or out
of the battery is limited only by the generator design. Thereby
making it is possible to withdraw large amounts of energy in a
far shorter time than with traditional chemical batteries.
Feasibility studies are underway assess the ability to quickly
charge FES batteries making them desirable for application in
electric cars, where the charge time could be dropped from hours
to minutes.
Geothermal (a.k.a. "Hot Rocks")
Geothermal,
sometimes know as "hot rocks"
refers to heat sources within the planet. Strictly speaking,
geo-thermal necessarily refers to the Earth and uses the
planet's internal heat – or what may be called the earth’s
“natural radioactive decay.” The approach was originally
generated during its accretion, due to gravitational binding
energy, and since then additional heat has continued to be
generated by the radioactive decay of elements such as uranium,
thorium, and potassium. Temperature within the Earth increases
with increasing depth and Heat flows constantly from its sources
within the Earth to the surface.
Geothermal heat at the surface is highly concentrated where
magma is close to the surface. This primarily occurs in volcanic
and hotspot areas and at spreading ridge areas.
Geothermal systems are some of the most environmentally benign
sources of energy. There is 50,000 times more energy in the
upper six miles of the earth's crust than in all of the global
oil and natural gas reserves combined.
Geothermal
heating has been used since Roman times as a way
of heating buildings and spas by utilizing
sources of hot water and hot steam that exist
near the earth's surface. Where such geothermal
resources are available, it is possible to
distribute hot water or steam to multiple
buildings. This technique, long practiced
throughout the world in Europe, especially those
areas having high volcanic activity, for
example, Italy and has also been successfully in
Reykjavik, Iceland and Boise, Idaho, USA
(primarily California and Hawaii), is known as
Geothermal District heating.
 Geothermal heating has frequently been used in
recent to refer to the heating and cooling that can be achieved
in combination with a Geothermal heat pump. Illustrated above is
a complete illustration of a geothermal electric generating
system. If heat recovered by ground source heat pumps is
included, the generating capacity of geothermal energy is
estimated at more than 100 GW (gigawatts of thermal power) and
the technology is used commercially in over 70 countries.
Prospectively, geothermal offers a very promising option in
future environmentally-friendly energy supply and one which has
under utilized.
Heat Pumps
Heat pumps
are very efficient heating and cooling systems and can
significantly reduce energy costs.
A heat pump can provide year-round climate control for a
home by supplying heat to it in the winter and cooling it in the
summer, and some heat pumps can also heat water. Using a
heat pump to exclusively satisfy meet all heating needs may not
be economical. When used in conjunction with a
supplementary, conventional form of heating, for example. an
oil, gas or electric furnace, a heat pump can provide reliable
and economic heating in winter and cooling in the summer --
consumers can experience cost savings especially on a long-term
basis.
Homes having a
conventional oil or electric heating system, can accrue energy
cost savings by installing a heat pump. Heat pumps may
have lower fuel costs than conventional heating and cooling
systems, yet the up-front cost of purchasing and installing a
heat-pump will increase the initial, net economic benefit to
homeowners. Consumers need to carefully weigh your the trade-off
between anticipated fuel savings against the initial cost. In
addition, the maximum heat pumps will be most economical when
used year round and is, thus, are ideal for consumers interested
in both summer cooling and winter applications.
A heat pump is an electrical device that
extracts heat from one place and transfers it to another.
The heat pump is not a new technology; it has been used
world-wide for several for decades. Refrigerators and air
conditioners are both common examples of heat pump technologies.
A
simple diagram of a heat pump's vapor-compression refrigeration
cycle is detailed below:
1.
Condenser, 2.
Expansion Valve
3.
Evaporator, 4.
Compressor
Heat pumps transfer heat by circulating a
substance called a refrigerant through a cycle of evaporation
and condensation. A compressor pumps the refrigerant
between two heat exchanger coils. In one coil, the refrigerant
is evaporated at low pressure and absorbs heat from its
surroundings. The refrigerant is then compressed as it travels to
the other coil, where it is condensed at high pressure. At this
point, it releases heat (which it absorbed earlier in the
cycle).
Cooling With Heat
Pumps
Refrigerators and air conditioners are both
examples of heat pumps operating only in the cooling mode. A
refrigerator is essentially an insulated box with a heat pump
system connection. The evaporator coil is located inside
the box, usually in the freezer compartment. Heat is absorbed
from this location and transferred outside, usually behind or
underneath the unit where the condenser coil is located. An air
conditioner operates in a similar fashion by transferring heat
from inside a house to the outdoors.
Heating With Heat
Pumps
The heat pump cycle is fully reversible, and
heat pumps can provide year-round home climate control – heating
in winter and cooling and dehumidifying in summer. Since the
ground and air outside always contain some heat, a heat pump can
supply heat to a house even during cold winter days. An
air-source heat pump absorbs heat from the outdoor air in the
winter and rejects heat into outdoor air in summer. In addition,
ground-source heat pumps withdraw heat from the ground or ground
water, are gaining consumer acceptance.
Photovoltaics
Photovoltaics
(PV)
is a
solar power technology using solar
cells or solar photovoltaic arrays
to convert sun light directly into
electricity. Photovoltaics remains
in its elemental stage and is under
study and development by various
Universities and private
corporations. The manufacture
of photovoltaic cells has expanded
dramatically in recent years, with
the total peak power demand
power provided by solar PV arrays
was around 3,700 MW as of the end of
2005. PV installations may be
ground-mounted (and sometimes
integrated with farming and grazing)
or building integrated -- with
attempts to integrate the panels
with building design (Illustrated
below Photovoltaic Cell).
In
order to stimulate the growth and
development of PV, financial
incentives in the form of
preferential tariffs for
solar-generated electricity and net
metering. Germany, Japan, and
the United States have supported PV
installations. The first practical
application of photovoltaics was to
power orbiting satellites and other
spacecraft and pocket calculators.
Grid Connected Applications
The majority of photovoltaic modules
are used for
grid connected
power generation. In this
case an inverter is required to
convert the DC to AC. The initial
capital cost, installation and
materials, has stalled the
development of on grid PV. In
addition, should on-grid and
off-grid applications of PV expand,
its cost will be heavily influenced
by the price of silicon which
is the most important critical
component of the PV technology. The
price of silicon has risen in recent
years due its use with
computer-related equipment and
shortages occurred in 2005 and 2006.
An major expansion in the commercial
use of PV to produce electricity
will be the availability and cost of
its single greatest component,
silicon.
Off Grid
Applications
Building-integrated
photovoltaics (BIPV)
or
Off Grid
applications are
increasingly
incorporated into
new domestic and
industrial
buildings. PV
is frequently being
used as the
principal or a key
ancillary source of
electrical power, and
are one of the
fastest growing
segments of the
photovoltaic
industry. Typically,
an array is
incorporated into
the roof or walls of
a building, and roof
tiles with
integrated PV cells.
Arrays can also be
retrofitted into
existing buildings;
in this case they
are usually fitted
on top of the
existing roof
structure.
An
array can be located
separately from the
building but
connected by cable
to supply power for
the building. Panels
are usually mounted
at an angle based on
latitude, and often
they are adjusted
seasonally to meet
the changing solar
declination. Solar
tracking can also be
utilized to access
even more
perpendicular
sunlight, thereby
raising the total
energy output.
Solar Energy
Solar Energy Solar energy is captured
by solar panels through two main which uses complete different
technologies to make use of
the energy
from the sun. Solar power is a
source of energy that uses radiation emitted by the Sun.
These are:
-
Solar Water Heating collectors:
These panels absorbs the energy from the sun and transfer it
to heat water.
-
Photovoltaic or solar electric
panels: These panels transform the solar radiation directly
into electricity.
Solar Water Heating
Solar hot water systems use sunlight to heat water. Solar Power
Solar water heating systems are the most popular form of solar
energy. The system is connected to the hot water system and
Solar water heating systems can provide over half of a
household's hot annual water requirements. Solar water heating
is particularly appropriate for low temperature (75-150F)
applications such as domestic hot water and swimming pools.
Two types of solar water heating collector are available, these
consist of: (1) flat plate and (2)
evacuated tubes.
Flat Plate Collectors:
Solar water heating panels in their simplest form are made from
a sheet of metal painted black, making it a good absorber of
solar energy. Solar water heating
systems are composed of solar thermal collectors, a storage tank
and a circulation loop. Water
is fed through the panel in pipes attached to the metal sheet
and picks up the heat in the metal. The pipes are often made of
copper for better conduction. The metal sheet is embedded in an
insulated box and covered with glass or clear plastic on the
front and the system is typically installed on the roof.
Evacuated Tubes: The
evacuated tube system consists of a series of glass heat tubes
grouped together. The tubes are highly insulated, due to a
vacuum inside the glass.
The three basic classifications
of solar water heaters are:
- Batch systems which
consist of a tank that is directly heated by
sunlight. These are the oldest and simplest
solar water heater designs, however; the
exposed tank can be vulnerable to cool down.
- Active systems which use
pumps to circulate water or a heat transfer
fluid.
- Passive systems which
circulate water or a heat transfer fluid by
natural circulation. These are also called
thermo- siphon systems. A
Trombe Wall is a passive solar
heating and ventilation system consisting of
an air channel sandwiched between a window
and a sun-facing wall. Sunlight heats the
air space during the day causing natural
circulation through vents at the top and
bottom of the wall and storing heat in the
thermal mass.
Solar Electricity
Solar Cells, is also referred to as
photovoltaic cells (PV), are
devices or banks of devices that use the photovoltaic effect of
semiconductors to generate electricity directly from sunlight.
Until recently, their use has been limited because of high
manufacturing costs. One cost effective has been use in very
low-power devices, such as calculators
with LCD's. Another use has been in remote applications
such as roadside emergency telephones,
remote sensing,
cathodes protection of pipe
lines, and
limited "off grid" home power applications.
An
energy tower
(illustrated to the left) is an alternative
proposal to the solar updraft tower. It is
driven by spraying water at the top of the
tower, evaporation of water causes a downdraft
by cooling the air thereby increasing its
density, driving wind turbines at the bottom of
the tower. It requires a hot arid climate and
large quantities of water (seawater may be used)
but does not require the large glass house of
the solar updraft tower.
Finally, PV
has been used to powering orbiting
satellites and spacecraft.
To take advantage of the incoming electromagnetic radiation from
the sun, solar panels can be attached to each house or building
-- creating an integral part of the PV technology known as an
"array." The panels should be mounted perpendicular to the arc
of the sun. Total peak power of installed PV is around 6,000 MW
as of the end of 2006 (978,020 MWs Summer Peak Demand in
the United States, shaving roughly 0.6% off peak demand) .
Installed PV is projected to increase to over 9,000 MW in 2007.
One the the
drawbacks of Solar Power electric generation is the extended
pay-back period -- which may take over 10 years to recover
depending on: (1) the cost of grid
electricity, (2) availability and
cost of silicon (a necessary ingredient to the PV) and
(3) tax rebates or other
Governmental financial incentives.
Grid-connected systems - those systems that use an
inverter to connect to the utility grid instead of relying on
batteries - which currently make up the largest segment of the
market. Economies of scale and Federal and State tax incentives
will serve as a critical impetus growth to the PV market.
In 2003, worldwide production of solar cells increased by
32%. Between 2000 and 2004, the increase in
worldwide solar energy capacity was an annualized 60%. Reliance
on PV in 2005 was expected to see large growth again, but
shortages of refined silicon have been hampering production
worldwide since late 2004.
Solar Ponds
are simply a pools of water which collect and stores solar
energy. It contains layers of salt solutions with increasing
concentration (and therefore density) to a certain depth, below
which the solution has a uniform high salt concentration. It is
a relatively low-tech, low-cost approach to harvesting solar
energy. The principle is to fill a pond with 3 layers of water:
(1) A top layer with a low salt
content, (2) An intermediate
insulating layer with a salt gradient, which sets up a density
gradient that prevents heat exchange by natural convection in
the water (3)A bottom layer with a
high salt content which reaches a temperature approaching 90
degrees Celsius.
The layers
have different densities due to their different
salt content, and this prevents the development
of convection currents which would otherwise
transfer the heat to the surface and then to the
air above. The heat trapped in the salty bottom
layer can be used for heating of buildings,
industrial processes, generating electricity or
other purposes.
 Parabolic
Troughs (illustrated on the left) consists of
a long row of parabolic mirrors
concentrates sunlight on a tube filled with a heat transfer
fluid -- usually oil. As with the power tower, this heated oil
is used to power a conventional steam turbine, or stored for
nighttime use. The largest operating solar power plant, as of
2007, is one of the SEGS parabolic trough systems in the Mojave
Desert in California.
Wind Power
Wind Power people
have used the power wind of the wind for many
years to produce mechanical power for milling grain and
pumping water. Wind turbine technology harness wind to
generate electricity. The electricity is then exported
either to the grid for use locally or may be used
to power a stand alone application. Wind Power
energy has the potential for both on shore and off shore
applications. Wind power is one of the cleanest and
safest of all the renewable commercial methods of
generating electricity.
Wind power is the conversion
of wind into more useful forms, usually electricity,
using wind turbines. At the end of 2006, worldwide
capacity of wind-powered generators was 74,223 megawatts
-- nevertheless Wind currently produces just over
1% of world-wide electricity use. In wind friendly
regions such as approximately Denmark it accounts for
20% of the electricity produced, 9% in Spain, and
7% in Germany. Globally, wind power has more than
quadrupled the production of electricity between 2000
and 2006.
 Wind
power produces electricity by converting the rotation of
turbine blades into electrical current by means of an
electrical generator - illustration Wind Tower.
On Grid -
and Off-Grid Generation of Electricity
Wind power is used in
large scale wind
farms (the
consolidation of numerous Wind Towers) for
On Grid
production of electricity and,
Off Grid
for small turbines for providing electricity
to rural residences or
Grid-Isolated
locations.Wind energy is
plentiful,
renewable,
widely distributed,
clean,
and reduces
toxic atmospheric
and greenhouse gas
emissions in lieu of the conventional
generation of electricity. One of the major
downfalls of Wind
Energy is that certain region
in the world are Wind deficient, therefore,
these regions have to explore other Green Energy
alternatives.
TIDAL POWER (ALSO KNOWN AS
"OCEAN POWER" and "WAVE POWER")
Tidal power,
sometimes called
Tidal Energy
or Ocean
Energy, is a form of
hydropower that exploits the rise and
fall in sea levels due to the tides,
essentially taking advantage of the
movement of water caused by the tidal
flow. The know-how and equipment
are currently available to produce
electricity from Tidal movements.
Moreover, source familiar with the
technology, argue that its reliable
exceeds that on environmentally friends
sources of producing electricity --
especially, wind and solar power.
The basic physics of
Tidal Power
Systems
make use of the kinetic energy
from the moving water currents to drive
turbines, in a similar way to underwater
wind turbines. The attraction of
Tidal Power
Systems
is based on its relative
low and competitive costs relative to
other form of generating electricity and
its minimal ecological impact.
 Advances
in turbine technology hold considerable
promise - but development of the
technology lacks the requisite financial
backing - for example, recently Ocean
Power Inc. (PWREQ.PK) was forced to file
for Bankruptcy due to a thin market for
its product, causing a inability to
raise sufficient capital to market and
provide rate of return during the
products the evolutionary stages.
Deriving energy from the ocean holds
considerable potential and if the
industry can survive the infancy stage,
tidal energy may eventually become
a significant percentage of the electric
power generating market. Such
flows occur almost anywhere where there
are entrances to bays and rivers, or
between land masses where water currents
are concentrated. High velocity
areas where natural tidal flows are
concentrated and ideal for the
application of tidal power are, for
instance, the west coast of Canada, the
Strait of Gibraltar, the Bosporus, and
south east Asia and Australia.
However, tidal flows occur almost
anywhere where there are entrances to
bays and rivers, or between land masses
where water currents are concentrated.
Tidal
barrage power schemes have a high costs
of entry but, as with other forms of
alternative fuels, very low running
cost. As a result, a tidal power scheme
may not produce acceptable rates of
return for investors for many years.
There are two primary methods of
harnessing tidal power,
Barrage Tidal
Power and
Ebb Generation:
The barrage method
of extracting tidal energy involves building a barrage
and creating a tidal lagoon. The barrage traps a water level
inside a basin. When the height of water pressure created
outside the basin or lagoon changes relative to the water level
inside, the "head" pressure is used to move turbines.
Ebb
generation fills a basin on
water channels until high tide, after
which the water channels gates are closed. At
this stage the water is "Pumped" or raised one
level further. Turbine gates are kept closed
until the sea level falls to create sufficient
water pressure across the barrage, and then are
opened so that the turbines generate until the
water pressure is again low. The process is then
repeated: the channels are opened,
turbines disconnected and the basin is filled
again. Hence, Ebb generation occurs as the tide
ebbs and flows.
Wave Power
is another form of utilizing power from the
ocean. Wave Power
refers to the "energy" created by the surface
ocean waves and captures that "energy" to do
useful work (i.e. production or energy
transferred by force) - including electricity
generation, desalination, and the pumping of
water (into reservoirs). Though often
co-mingled, wave power is distinct from tidal
power and the steady movement of ocean currents.
Ocean surface
waves are mechanical waves that propagate along
the interface between water and air; the
restoring force is provided by gravity, and so
they are often referred to as surface gravity
waves. As the wind blows, pressure and friction
forces perturb the equilibrium of the ocean
surface, thereby forcing an energy transfer from
the air to the water, forming waves -- this
energy can be harnessed into a power source. No
commercial wave facility in presently in
operation. Wave power generation is not a widely
employed technology, and no commercial wave farm
has yet been established.
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