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Solar energy runs the engines of the earth. It heats its atmosphere and its lands, generates its winds, drives the water cycle, warms its oceans, grows its plants, feeds its animals, and even (over the long haul) produces its fossil fuels. This energy can be converted into heat and cold, driving force and electricity. |
SOLAR RADIATION
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Solar radiation is electromagnetic radiation in the 0.28...3.0 µm
wavelength range. The solar spectrum includes a small share of ultraviolet
radiation (0.28...0.38 µm) which is invisible to our eyes and comprises
about 2% of the solar spectrum, the visible light which range from 0.38
to 0.78 µm and accounts for around 49% of the spectrum and finally
of infrared radiation with long wavelength (0.78...3.0 µm), which
makes up most of the remaining 49% of the solar spectrum.
 The
Sun |
HOW MUCH SOLAR ENERGY STRIKES
THE EARTH?
The sun generates an enormous amount of energy - approximately 1.1
x 10 E20 kilowatt-hours every second. (A kilowatt-hour is the amount of
energy needed to power a 100 watt light bulb for ten hours.) The earth’s
outer atmosphere intercepts about one two-billionth of the energy generated
by the sun, or about 1500 quadrillion (1.5 x 10 E18 ) kilowatt-hours per
year. Because of reflection, scattering, and absorption by gases and aerosols
in the atmosphere, however, only 47% of this, or approximately 700 quadrillion
(7 x 10 E17 ) kilowatt-hours, reaches the surface of the earth.
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In the earth’s atmosphere, solar radiation is received directly (direct radiation) and by diffusion in air, dust, water, etc., contained in the atmosphere (diffuse radiation). The sum of the two is referred to as global radiation. |
latitude
local climate
season of the year
inclination of the collecting surface in the direction of the sun.
TIME AND SITE
The solar energy varies because of the relative motion of the sun.
This variations depend on the time of day and the season. In general,
more solar radiation is present during midday than during either the early
morning or late afternoon. At midday, the sun is positioned high in the
sky and the path of the sun’s rays through the earth’s atmosphere is shortened.
Consequently, less solar radiation is scattered or absorbed, and more solar
radiation reaches the earth’s surface.
Variations of solar irradiation (tilt angle South 30Deg.) in Europe and Caribbean region in kWh/m2.day.
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CLOUDS
The amount of solar radiation reaching the earth’s surface varies
greatly because of changing atmospheric conditions and the changing position
of the sun, both during the day and throughout the year. Clouds are the
predominant atmospheric condition that determines the amount of solar radiation
that reaches the earth. Consequently, regions of the nation with cloudy
climates receive less solar radiation than the cloud-free desert climates.
For any given location, the solar radiation reaching the earth’s surface
decreases with increasing cloud cover. Local geographical features, such
as mountains, oceans, and large lakes, influence the formation of clouds;
therefore, the amount of solar radiation received for these areas may be
different from that received by adjacent land areas. For example, mountains
may receive less solar radiation than adjacent foothills and plains located
a short distance away. Winds blowing against mountains force some of the
air to rise, and clouds form from the moisture in the air as it cools.
Coastlines may also receive a different amount of solar radiation than
areas further inland.
The solar energy which is available during the day varies and depends
strongly on the local sky conditions. At noon in clear sky conditions,
the global solar irradiation can in e.g. Central Europe reach 1000 W/m2
on a horizontal surface (under very favourable conditions, even higher
levels can occur) whilst in very cloudy weather, it may fall to less than
100 W/m2 even at midday.
POTENTIALS
Solar radiation provides us at zero cost with 10,000 times more
energy than is actually used worldwide. All people of the world buy, trade,
and sell a little less than 85 trillion (8.5 x 1013 ) kilowatt-hours of
energy per year. But that’s just the commercial market. Because we have
no way to keep track of it, we are not sure how much non-commercial energy
people consume: how much wood and manure people may gather and burn, for
example; or how much water individuals, small groups, or businesses may
use to provide mechanical or electrical energy. Some think that such non-commercial
energy may constitute as much as a fifth of all energy consumed. But even
if this were the case, the total energy consumed by the people of the world
would still be only about one seven-thousandth of the solar energy striking
the earth’s surface per year.
In some developed countries like in the United States people consume roughly 25 trillion (2.5 x 10E13 ) kilowatt-hours per year. This translates to more than 260 kilowatt-hours per person per day - this is the equivalent of running more than one hundred 100 watt bulbs all day, every day. U.S. citizen consumes 33 times as much energy as the average person from India, 13 times as much as the average Chinese, two and a half times as much as the average Japanese, and twice as much as the average Sweden.
Even in such heavy energy consuming countries like USA solar energy
falling on the land mass can many times surplus the energy consumed
there. If only 1% of land would be set aside and covered by solar systems
(such as solar cells or solar thermal troughs) that were only 10% efficient,
the sunshine falling on these systems could supply this nation with all
the energy it needed. The same is true for all other developed countries.
In a certain sense, it is impractical - besides being extremely expensive,
it is not possible to cover such large areas with solar systems.
The damage to ecosystems might be dramatic. But the principle remains.
It is possible to cover the same total area in a dispersed manner - on
buildings, on houses, along roadsides, on dedicated plots of land, etc.
In another sense, it is practical. In many countries already more than
1% of land is dedicated to the mining, drilling, converting, generating,
and transporting of energy. And the great majority of this energy is not
renewable on a human scale and is far more harmful to the environment than
solar systems would prove to be.
SOLAR ENERGY UTILISATION
In most places of the world much more solar energy hits a home’s
roof and walls as is used by its occupants over a year’s time. Harnessing
this sun’s light and heat is a clean, simple, and natural way to provide
all forms of energy we need. It can be absorbed in solar collectors to
provide hot water or space heating in households and commercial buildings.
It can be concentrated by parabolic mirrors to provide heat at up to several
thousands degrees Celsius. This heat can be used either for heating purposes
or to generate electricity. There exist also another way to produce power
from the sun - through photovoltaics. Photovoltaic cells are devices
which convert solar radiation directly into electricity.
Solar radiation can be converted into useful energy using active systems and passive solar design. Active systems are generally those that are very visible like solar collectors or photovoltaic cells. Passive systems are defined as those where the heat moves by natural means due to house design which entails the arrangement of basic building materials to maximize the sun’s energy.
Solar energy can be converted to useful energy also indirectly, through other energy forms like biomass, wind or hydro power. Solar energy drives the earth´s weather. A large fraction of the incident radiation is absorbed by the oceans and the seas, which are warmed than evaporate and give the power to the rains which feed hydro power plants. Winds which are harnessed by wind turbines are getting its power due to uneven heating of the air. Another category of solar-derived renewable energy sources is biomass. Green plants absorb sunlight and convert it through photosynthesis into organic matter which can be used to produce heat and electricity as well. Thus wind, hydro power and biomass are all indirect forms of solar energy.
Passive solar buildings in the United States were in such demand by 1947, as a result of scarce energy during the prolonged World War 2, that Libbey-Owens-Ford Glass Company published a book entitled Your Solar House, which profiled forty-nine of the nations greatest solar architects.
In the mid-1950’s, architect Frank Bridgers designed the world’s
first commercial office building using solar water heating and passive
design. This solar system has been continuously operating since that time
and the Bridgers-Paxton Building is now in the National Historic Register
as the world’s first solar heated office building.
Low oil prices following World War 2 helped keep attention away
from solar designs and efficiency. Beginning in the mid-1990’s, market
pressures are driving a movement to redesign our building systems to more
in line with nature.
Passive Solar Space Heating
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There are few basic architectural modes for the utilisation of passive
solar utilisation in architecture. But these modes, as presented below,
can be developed into many different scheme, and enrich the design.
The essential elements of a passive solar home are: good siting of the house, many south-facing windows (in Northern Hemisphere) to admit solar energy in winter (and, conversely, few east or west facing windows, to limit the collection of unwanted summer sunshine), sufficient interior mass (thermal mass) to smooth out undesirable temperature swings and to store heat for night time and a well-insulated building envelope. Siting, insulation, windows orientation and mass must be used together. For least variation of indoor temperature the insulation should be placed on the outside of the mass. However where rapid indoor heating is required some insulation or low heat capacity material should be placed at the inside surface. There will be an optimum design for each micro-climate and indications are that a careful balance between mass and insulation in a structure will result not only in energy savings but in initial material cost saving as well. |
Site
Landscaping and Trees
According to the U.S. Department of Energy report, “Landscaping
for Energy Efficiency” (DOE/GO-10095-046), careful landscaping can save
up to 25% of a household’s energy consumption for heating and cooling.
Trees are very effective means of shading in the summer months as well
as providing breaks for the cool winter winds. In addition to contributing
shade, landscape features combined with a lawn or other ground cover can
reduce air temperatures as much as 5 degrees Celsius in the surrounding
area when water evaporates from vegetation and cools the surrounding air.
Trees are wonderful for natural shading and cooling, but they must be located
appropriately so as to provide shade in summer and not block the winter
sun. Even deciduous trees that lose their leaves during cold weather block
some winter sunlight - a few bare trees can block over 50 percent of the
available solar energy.
Windows
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All effective passive systems depend on windows. Glass or other translucent materials allow short-wave, solar radiation to enter a building and prohibit the long-wave, heat radiation, from escaping. Windows control the energy flow in two principle ways: they admit solar energy in winter, so warming the house above the otherwise cool to cold internal conditions; and by excluding sun from the windows (by orientation and shading) there exist the opportunity to use ventilation to cool the otherwise warm hot house in summer. If use is to be made of the sun’s heat, then it has to reach buildings when it is useful. Generally, the sun should be able to reach the collection area between 9 a.m. and 3 p.m. in winter with as little obstruction and interference as possible.Trees on the site or the neighbours’ site might shade the vital areas of the building. This need to be checked and the building located to minimise any such interference. It is possible to plan a house to have its main outlook in any direction and still be an efficient low energy building. The building envelope, i.e. the walls, floor and roof are the important elements in design, rather than the location of internal spaces. If a window needs to face west it requires correct shading and its size restricted. |
There are three ways that heat moves through a glazing material.
The first is conduction. Conductive heat is transferred through the glazing
by direct contact. Heat can be felt by touching the glazing material. The
second form of heat transfer is radiation; electromagnetic waves carry
heat through a glazing. This produces the feeling of heat radiating from
the surface of the glazing. The third method of heat transfer is convection.
Convection transfers heat by motion, in this case, air flow. The natural
flow of warm air toward colder air allows heat to be lost or gained.
The R-value of a glazing - its insulating capabilities or resistance
to the flow of heat - is determined by the degree of conduction, radiation,
and convection through the glazing material. However, air infiltration
will also determine the overall R-value of a glazing system. The amount
of heat that travels around a glazing is as important as the heat transfer
through a glazing. Air can leak in or out of a building around the glazing
via the framing. The quality, workmanship, and the installation of the
entire glazing system, including the framing, affects air infiltration.
Advances in glass technology have perhaps been the single largest
contributor to building efficiency since the 1970s and they play an important
roll in solar design. Some window advances include:
Double
and triple pane windows with much higher insulating values.
Low emissivity or Low-E glass employing a coating which lets heat in but
not out.
Argon (and other) gas filled windows that increase insulating values above
windows with just air.
Phase-change technologies that can switch from opaque to translucent when
a voltage is applied to them.
Basic Glass Types
Glazing materials include glass, acrylics, fibreglass, and other
materials. Although different glazing materials have very specific applications,
the use of glass has proven the most diverse. The various types of glass
allow the passive solar designer to fine-tune a structure to meet client
needs. The single pane is the simplest of glass types, and the building
block for higher performance glass. Single panes have a high solar transmission,
but have poor insulation - the R-value is about 1,0. Single pane glass
can be effective when used as storm windows, in warm climate construction
(unless air conditioning is being used), for certain solar collectors,
and in seasonal greenhouses. Structures using single pane glass will typically
experience large temperature swings, drafts, increased condensation, and
provide a minimal buffer from the outdoors.
Perhaps the most common glass product used today is the double pane
unit. Double pane glass is just that: two panes manufactured into one unit.
Isolated glass (thermopane) incorporate a spacer bar (filled with a moisture
absorbing material called a desiccant) between the panes and are typically
sealed with silicone. The spacer creates a dead air space between the panes.
This air space increases the resistance to heat transfer; the R-value for
double pane is about 1,8-2,1. Huge air spaces will not drastically increase
R-value. In fact, a large air space can actually encourage convective heat
transfer within the unit and produce a heat loss. A rule of thumb for air
space is between 1 and 2 centimetres. It is also possible to go as large
as 10-12 centimetres without creating convective flow, but at that point
you are dealing with a very large and awkward unit. The demand for greater
energy efficiency in building and retrofitting homes has made insulated
glass units the standard. With good solar transmission and fair insulation,
such unit is a large improvement over the single pane. Windows, doors,
skylights, sunrooms, and many other areas utilize double pane glass.
HIGH PERFORMANCE GLASS
High performance or enhanced glass offers even better R-value and
solar energy control. By further improving the insulating capability of
glass, it is possible dramatically increase also design options.
What were once insulated walls may become sunrooms. Solid roofs and ceilings
become windows to the sky. Dark rooms can “wake up” to natural light, solar
heat gain, and wonderful views. For a relatively small increase in cost
it is possible to improve efficiency, provide better moisture and UV protection,
and gain design flexibility. A variety of high performance glass is now
available.
What are the advantages of this glass? Low emissivity (Low-E) glass is succeeding double pane glass in energy efficient buildings. Emissivity is the measure of infrared (heat) transfer through a material. The higher the emissivity, the more heat is radiated through the material. Conversely, the lower the emissivity, the more heat is reflected by the material. Low-E coatings will reflect, or re-radiate, the infrared heat back into a room, making the space warmer. This translates into R-values from 2.6 to 3.2. In warmer climates it is possible to reverse the unit and re-radiate infrared heat back to the outside, keeping the space cooler. Low-E glass improves the R-value, UV protection, and moisture control.Gas-filled windows increase R-value. Properly done, gas-filling will increase the overall R-value of a glass unit by about 1,0. The air within an insulated glass unit is displaced with an inert, harmless gas with better insulation properties. Typical gases used are Krypton and Argon.
Window curtains
In addition to decorative functions, curtains can be used to reduce
the heat losses that occur during the cold months as well as the heat gains
during the warmer months. The plywood box over the curtain top prevents
warm ceiling air from moving between the glass and curtain. The curtain
should drop at least 30 cm below the window for it to be effective. The
optimum condition would be for it to drop to the floor.
Thermal mass can be incorporated into a passive solar room in many ways, from tile-covered floors to water-filled drums. Thermal mass materials, which include slab floors, masonry walls, and other heavy building materials, absorb and store heat. They are a key element in passive solar homes. Homes with substantial south-facing glass areas and no thermal storage mass do not perform well.
It is important to know that dark surfaces reflect less, therefore, absorb more heat. In case of a dark tiled floor, the floor will be able to absorb heat all day and radiate heat into the room at night. The rate of heat flow is based on the temperature difference between heat source and the object to which the heat flows. As described above heat flows in three ways - conduction (heat transfer through solid materials), convection (heat transfer through the movement of liquids or gasses), and radiation. All surfaces of a building lose heat via these three modes. Good solar design works to minimize heat loss and maximize efficient heat distribution. The need for thermal mass (heat-storage materials) inside a building is very climate-dependent. Heavy buildings of high thermal mass are consistently more comfortable during hot weather in hot-arid and cool-temperate climates, while in hot-humid climates there is little benefit. In cool-temperature climates the thermal mass acts as a cold-weather heat store thus improving overall comfort and reducing the need for auxiliary heating, except on overcast or very cold days. In intermittently heated buildings, however, it tends to increase the heat needed to maintain the chosen conditions.
Providing adequate thermal mass is usually the greatest challenge
to the passive solar designer. The amount of mass needed is determined
by the area of south-facing glazing and the location of the mass. In order
to ensure an effective design it is important to follow these guidelines:
Locate the thermal
mass in direct sunlight. Thermal mass installed where the sun can reach
it directly is more effective than indirect mass placed where the sun’s
rays do not penetrate. Houses that rely on indirect storage need three
to four times more thermal mass than those using direct storage.
Distribute the
thermal mass. Passive solar homes work better if the thermal mass is relatively
thin and spread over a wide area. The surface area of the thermal mass
should be at least 3 times, and preferably 6 times, greater than the area
of the south windows. Slab floors that are 8 to 10 centimetres thick are
more cost effective and work better than floors 16 to 20 inches thick.
Do not cover
the thermal mass. Carpeting virtually eliminates savings from the passive
solar elements. Masonry walls can have drywall finishes, but should not
be covered by large wall hangings or lightweight panelling. The drywall
should be attached directly to the mass wall, not to covers fastened to
the wall that create an undesirable insulating airspace between the drywall
and the mass.
Select an appropriate
mass colour. For best performance, finish mass floors with a dark colour.
A medium colour can store 70 percent as much solar heat as a dark colour,
and may be appropriate in some designs. A matte finish for the floor reduces
reflected sunlight, thus increasing the amount of heat captured by the
mass and having the additional advantage of reducing glare. The colour
of interior mass walls does not significantly affect passive solar performance.
Insulate the
thermal mass surfaces. There are several techniques for insulating slab
floors and masonry exterior walls. These measures should introduced to
achieve the energy savings. Unfortunately, problems in some case
can arise like with termite infestations in foam insulation for perimeter
slabs. This can complicate the issue of whether and how to insulate slab-on-grade
floors.
Make thermal
mass multipurpose. For maximum cost effectiveness, thermal mass elements
should serve other purposes as well. Masonry thermal storage walls are
one example of a passive solar design that is often cost prohibitive because
the mass wall is only needed as thermal mass. On the other hand, tile-covered
slab floors store heat, serve as structural elements, and provide a finished
floor surface. Masonry interior walls provide structural support, divide
rooms, and store heat.
When developing a thermal storage system or simply comparing materials it is useful to look at the storage capacity of the proposed building materials which is referred to as the volumetric heat capacity (J/m3. Deg. Celsius) or more commonly the specific heat and the rate at which the material can take up and store heat. Some examples of common storage materials are given in the following table:
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Thermal insulation
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Materials generally available for building purposes can be classified into two generic groups - bulk materials and reflective foil laminates (RFL). The first of these relies on the resistance of air trapped in pockets between the fibres of the blanket type materials (mineral fibre materials) or the cells formed in the foamed structure of board or slab type materials (usually made from plastics such as polystyrene and polyurethane foams). The second reflects radiant energy away from the object or surface being protected. Thermal insulation in the outer fabric of a building is a vital component of an energy-efficient design strategy. The key to successful energy-efficient design is the control of heat flow through the external fabric. All the solar energy gained could be easily lost from an inadequately insulated building before it is able to be of benefit. It will have been noted that some materials have a very much higher thermal resistance per unit thickness than others irrespective of their density. The fact that air is a good insulator especially if it is bounded by a bright foil surface to limit radiation transfer can be very useful as well. |
Cooling
In many parts of the world a passive solar building needs cooling
as much as heating. One of the best, time proven methods of cooling is
thermal coupling with the earth’s constant temperature. Dropping the ground
floor at least one meter into the earth provides a more even exterior temperature
which aids cooling as well as heating. Adequate structural engineering,
drainage, and damp proofing are essential in below ground areas. Thermal
isolation is the best and most economical way to temper the building’s
environment. Using the earth’s thermal mass keeps the house at a reasonable
temperature, and so does good insulation. Shades located outside and inside
the windows, ventilation and reflective films on the windows are also very
important in order to control temperature inside the building.
External Shades and Shutters
Exterior window shading treatments are effective cooling measures
because they block both direct and indirect sunlight outside of the home.
Solar shade screens are an excellent exterior shading product with a thick
weave that blocks up to 70 percent of all incoming sunlight. The screens
absorb sunlight so they should be used on the exterior of the windows.
From outside, they look slightly darker than regular screening, but from
the inside many people do not detect a difference. Most products also serve
as insect screening. They should be removed in winter to allow full sunlight
through the windows. A more expensive alternative to the fibreglass product
is a thin, metal screen that blocks sunlight, but still allows a view from
inside to outside. Hinged decorative exterior shutters which close over
the windows are also excellent shading options. However, they obscure the
view, block daylight completely, may be expensive and may be difficult
for many households to operate on a daily basis.
Interior Shades and Shutters
Shutters and shades located inside the house include curtains, roll-down
shades, and Venetian blinds. Interior shutters and shades are generally
the least effective shading measures because they try to block sunlight
that has already entered the room. However, if passive solar windows do
not have exterior shading, interior measures are needed. The most effective
interior treatments are solid shades with a reflective surface facing outside.
In fact, simple white roller blinds keep the house cooler than more expensive
louvered blinds, which do not provide a solid surface and allow trapped
heat to migrate between the blinds into the house.
Reflective Films and Tints
Reflective film, which adheres to glass and is found often in commercial
buildings, can block up to 85% of incoming sunlight. The film blocks sunlight
all year, so it is inappropriate on south windows in passive solar homes.
However, it may be practical for unshaded east and west windows. These
films are not recommended for windows that experience partial shading because
they absorb sunlight and heat the glass unevenly. The uneven heating of
windows may break the glass or ruin the seal between double-glazed units.
Ventilation
Ventilation is the changing of air in buildings to control oxygen,
heat and contaminants. Ventilation may occur in few forms. Building orientation,
form, plan and user actions also alter air flow paths. Natural ventilation
consumes no energy and has few if any running costs, but depends on weather
conditions and can be difficult to control. Mechanical and air-conditioned
ventilation are energy-driven alternatives to natural ventilation, normally
dictated by building type, site and function. They can be particularly
efficient as supplements to natural ventilation. Mechanical ventilation
uses fans and ducts to supply and extract air in localised areas such as
a kitchen. Air conditioning both treats and supplies air. It is particularly
useful to cool air below ambient temperatures.
SOLAR ARCHITECTURE & ACTIVE
SYSTEMS
It is important to design the house with the aim to incorporate
active solar systems (see below) like collectors or photovoltaic modules
as well. The building should orient these appliances due south. Tilt
of the solar collectors should be in Europe and North America more than
50° (from horizontal) to maximize winter heat collection. Solar collectors
should be thermally locked with the roof. Non-tracking photovoltaics receive
the most yearly insolation (exposure to the sun’s rays) when tilted at
an angle, from horizontal, equal to the building’s latitude. Design of
the building’s roof should be done to such angles and southern orientation
as integral aspects of the building. Hot water collectors and photovoltaic
panels should be located as close as possible to their main areas of use.
It is important to concentrate these areas of use. For example, putting
the bathrooms and kitchen close together economizes on their installation
and minimizes energy loss. All appliances should be selected with efficiency
as the prime criterion.
SUMMARY
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Passive use of sunlight contributes around 15% of space heating needs in typical building. It is important source of energy savings which can be utilised everywhere and almost at no extra cost. There are some principles which can help a designer to harness solar energy through thermally efficient buildings. |
SITE
It is important to become familiar with the energy flows of house
surroundings. The nature and relationship of the lay of the land, water
courses, vegetation, soil types, wind directions, and exposure to the sun
should be investigated. A site suitable for solar design should balance
and complement these elements. It must have unobstructed exposure to the
sun from 9 am to 3 pm during the heating season.
HEATING
In Northern hemisphere orientation due south of the main solar insolating
spaces, i.e. greenhouse, and/or main daytime activity areas is important.
Glass should be open to the sun patterns during the winter. By facing of
the windows to the south, and virtually none to the north maximaze solar
gain. Multiple pane glass in all windows is recommended.
NATURAL HEAT FLOW
It is useful to design the house with the natural heat flow in mind.
Hot air rises, so placing some activity areas on a second floor to
draw heat up from a lower collector area and across other areas can save
a lot of energy. Buffer areas of the building (unheated rooms, or partially
heated spaces such as utility rooms, vestibules and storage areas) should
be oriented due to the north to lessen the impact of the winter’s cold.
Using a vestibule on doors to the exterior can lead to energy savings.
Vestibules cut heat loss and provide a buffer zone between the exterior
and the interior.
SOLAR COLLECTOR MARKET
Solar domestic
hot-water systems are technically mature and available practically all
over the world. The market for flat-type collectors has been reported as
substantial in Israel, China, Cyprus, Japan, Australia, Austria, Germany,
Greece Turkey and USA. Sales in Europe are mainly for domestic water heating,
which may also include space heating and heating swimming pools. World
production of solar collectors in 1995 was 1,3 million m2 where market
in Europe and Mediterranean countries is reported to be about 40% of the
world market. Total amount of installed solar collectors exceeded 30 million
m2 and the development of sales was very rapid since 1980. Since 1989 there
is steady increase with around 20 % per year.
Among countries in Europe, Greece has become the leader in production
of solar systems and exports 40% of all collectors produced and comprises
30% of the market in Germany. The industry‘s goal for the year 2005
represents 1,3 million systems and 5 million m2 of collectors. A
project on Crete will need 20,000 collectors over two years. The
Greek market installs 70,000 solar systems a year, reducing CO2 emissions
by 1,5 million tonnes.
Sales in the EU in 1996 were reported to be over 0,7 million m2
of glazed collectors and about 0,15 million m2 of unglazed collectors (Renewable
energy world, Sept. 1998). All the indications are that this trend will
continue at a rapid pace since measures are being taken all over the EU
for the promotion of solar systems.
Glazed solar collector production in 1994 (Source : Sun in action.
The solar thermal market, a strategic plan for action in Europe. European
Solar Industry Federation. Altener Program).
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Installed solar collector area in the world (Source: Sun in action. The solar thermal market, a strategic plan for action in Europe. European Solar Industry Federation. Altener Program).
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POTENTIALS
In Europe the total rapidly exploitable potential for solar collectors
production is estimated to be 360 million m2 , representing a market volume
of 50 billion USD at an annual average growth rate of 23%. In 2005 the
area occupied by glazed solar collector installations in the EU is expected
to rise to 28 million m2. Moreover, unglazed solar collectors for heating
swimming pools are expected to reach 20 million m2.
SOLAR COLLECTORS TYPES
Typical solar collectors collect the sun’s energy usually with rooftop
arrays of piping and net metal sheets, painted black to absorb as much
radiation as possible. They are encased in glass or plastic and angled
towards south to catch maximum sunshine. The collectors act as miniature
greenhouses, trapping heat under their glass plates. Because solar radiation
is so diffuse, the collectors must have a large area.
Solar collectors can be made in various sizes and constructions depending
on requirements. They give enough hot water for washing, showers and cooking.
They can be used also as pre-heaters for existing water heaters. Today
there are several collectors on the market. They can be divided into several
categories. One of them is division according temperature they produce:
Low-temperature
collectors provide low grade heat, less than 50 degrees Celsius, through
either metallic or non-metallic absorbers for applications such as swimming
pool heating and low-grade water.
Medium-temperature
collectors provide medium to high-grade heat (greater than 50 degrees Celsius,
usually 60 to 80 degrees), either through glazed flat-plate collectors
using air or liquid as the heat transfer medium or through concentrator
collectors that concentrate the heat to levels greater than “one sun.”
These include evacuated tube collectors, and are most commonly used for
residential hot water heating.
High-temperature
collectors are parabolic dish or trough collectors primarily used by independent
power producers to generate electricity for the electric grid.
Batch Solar Water Collectors
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The simplest type of solar water collector is a “batch” collector, so called because the collector is the storage tank - water is heated and stored a batch at a time. Batch collectors are used as pre-heaters for conventional or instantaneous water heaters. When hot water is used in the household, solar-preheated water is drawn into the conventional water collector. Since the water has already been heated by the sun, this reduces energy consumption. A batch solar water collector is a low cost alternative to an active solar hot water system, offering no moving parts, low maintenance, and zero operational cost. The acronym for a batch type solar water collector is ICS, meaning Integrated Collector and Storage. Batch collectors, also known as “breadbox” , use one or more black tanks filled with water and placed in an insulated, glazed box. Some boxes include reflectors to increase the solar radiation. Solar energy passes through the glazing and heats the water in the tanks. These devices are inexpensive solar water collectors but must be drained or protected from freezing when temperatures drop below freezing. |
Flat-Plate Collectors
Flat-plate
collectors are the most common collectors for residential water heating
and space-heating installations. A typical flat-plate collector is an insulated
metal box with a glass or plastic cover called the glazing and a dark-coloured
absorber plate. The glazing can be transparent or translucent. Translucent
(transmitting light only) low-iron glass is a common glazing material for
flat-plate collectors because low-iron glass transmits a high percentage
of the total available solar energy. The glazing allows the light to strike
the absorber plate but reduces the amount of heat that can escape. The
sides and bottom of the collector are usually insulated, further minimising
heat loss.
The absorber plate is usually black because dark colours absorb
more solar energy than light colours. Sunlight passes through the glazing
and strikes the absorber plate, which heats up, changing solar radiation
into heat energy. The heat is transferred to the air or liquid passing
through the flow tubes. Because most black paints still reflect approximately
10% of the incident radiation some absorber plates are covered with “selective
coatings,” which retain the absorbed sunlight better and are more durable
than ordinary black paint. The selective coating used in the collector
consists of a very precise thin layer of an amorphous semiconductor plated
on to a metal substratum. Selective coatings has both high absorptivity
in the visible region and low emissivity in the long-wave infrared region.
Absorber plates are often made of metal usually copper or aluminium
because they are both good heat conductors. Copper is more expensive, but
is a better conductor and is less prone to corrosion than aluminium. An
absorber plate must have high thermal conductivity, to transfer the collected
energy to the water with minimum temperature loss. Flat-plate collectors
fall into two basic categories: liquid and air. And both types can be either
glazed or unglazed.
Liquid Collectors
In a liquid
collector, solar energy heats a liquid as it flows through tubes in the
absorber plate. For this type of collector, the flow tubes are attached
to the absorber plate so the heat absorbed by the absorber plate is readily
conducted to the liquid.
The flow tubes can be routed in parallel, using inlet and outlet
headers, or in a serpentine pattern. A serpentine pattern eliminates the
possibility of header leaks and ensures uniform flow. A serpentine pattern
can pose some problems for systems that must drain for freeze protection
because the curved flow passages will not drain completely.
The simplest liquid systems use potable household water, which is
heated as it passes directly through the collector and then flows to the
house to be used for bathing, laundry, etc. This design is known as an
“open-loop” (or “direct”) system. In areas where freezing temperatures
are common, however, liquid collectors must either drain the water when
the temperature drops or use an antifreeze type of heat-transfer fluid.
In systems with heat-transfer fluids, the transfer fluid absorbs
heat from the collector and then passes through a heat exchanger. The heat
exchanger, which generally is in the water storage tank inside the house,
transfers heat to the water. Such designs are called “closed-loop” (or
“indirect”) systems.
Glazed liquid collectors are used for heating household water and
sometimes for space heating. Unglazed liquid collectors are commonly used
to heat water for swimming pools. Because these collectors need not withstand
high temperatures, they can use less expensive materials such as plastic
or rubber. They also do not require freeze-proofing because swimming pools
are generally used only in warm weather.
Air Collectors
Air collectors have the advantage of eliminating the freezing and
boiling problems associated with liquid systems. Although leaks are harder
to detect and plug in an air system, they are also less troublesome than
leaks in a liquid system. Air systems can often use less expensive materials,
such as plastic glazing, because their operating temperatures are usually
lower than those of liquid collectors.
Air collectors are simple, flat-plate collectors used primarily
for space heating and drying crops. The absorber plates in air collectors
can be metal sheets, layers of screen, or non-metallic materials. The air
flows through the absorber by natural convection or when forced by a fan.
Because air conducts heat much less readily than liquid does, less heat
is transferred between the air and the absorber than in a liquid collector.
In some solar air-heating systems, fans on the absorber are used to increase
air turbulence and improve heat transfer. The disadvantage of this strategy
is that it can also increase the amount of power needed for fans and, thus,
increase the costs of operating the system. In colder climates, the air
is routed between the absorber plate and the back insulation to reduce
heat loss through the glazing. However, if the air will not be heated more
than 17°C above the outdoor temperature, the air can flow on both sides
of the absorber plate without sacrificing efficiency.
The best features of air collector systems are simplicity and reliability.
The collectors are relatively simple devices. A well-made blower can be
expected to have a 10 to 20 year life span if properly maintained, and
the controls are extremely reliable. Since air will not freeze, no heat
exchanger is required.
However, the use of solar air heating collectors is still limited
to supply hot air for space heating and for drying of agricultural products
mainly in developing countries. The major limitations for the wide adoption
of solar air heaters are the high cost for commercially produced solar
air heaters, the large collector area required due to the low density and
the low specific heat capacity of the air compared to liquid heat transfer
fluids, the extended air duct system required, the high power requirement
for forcing the air through the collector, and the difficulty of heat storage.
In countries with comparatively low insolation and extended periods of
adverse weather, supplementary heat is required which increases investment
costs to a level which limits its competitiveness to conventional heating
systems. Promising ways to reduce the collector cost are the integration
of the collector into the walls or roofs of buildings and the development
of collectors which can be constructed using prefabricated components.
Heating with the solar wall .
Evacuated-Tube Collectors
Conventional
simple flat-plate solar collectors were developed for use in sunny and
warm climates. Their benefits are greatly reduced when conditions become
unfavourable during cold, cloudy and windy days. Furthermore, weathering
influences such as condensation and moisture will cause early deterioration
of internal materials resulting in reduced performance and system failure.
These shortcomings are reduced in evacuated-tube collectors.
Evacuated-tube collectors heat water in residential applications
that require higher temperatures. In an evacuated-tube collector, sunlight
enters through the outer glass tube, strikes the absorber tube, and changes
to heat. The heat is transferred to the liquid flowing through the absorber
tube. The collector consists of rows of parallel transparent glass tubes,
each of which contains an absorber tube (in place of the absorber plate
in a flat-plate collector) covered with a selective coating. The heated
liquid circulates through heat exchanger and gives off its heat to water
that is stored in a solar storage tank.
Evacuated tube collectors are modular tubes which can be added or
removed as hot-water needs change. When evacuated tubes are manufactured,
air is evacuated from the space between the two tubes, forming a vacuum.
Conductive and convective heat losses are eliminated because there is no
air to conduct heat or to circulate and cause convective losses. There
can still be some radiant heat loss (heat energy will move through space
from a warmer to a cooler surface, even across a vacuum). However, this
loss is small and of little importance compared with the amount of heat
transferred to the liquid in the absorber tube. The vacuum in the glass
tube, being the best possible insulation for a solar collector, suppresses
heat losses and also protects the absorber plate and the “heat-pipe” from
external adverse conditions. This results in exceptional performance far
superior to any other type of solar collector.
SOLAR COOKERS AND STILLS
There exists also some other inexpensive, “low-tech” solar collectors
with specific functions like solar box cookers (used for cooking) and solar
stills producing inexpensive distilled water from virtually any water source.
Solar box cookers (see chapter on Solar cooking) are inexpensive
to buy and easy to build and use. They consist of a roomy, insulated box
lined with reflective material, covered with glazing, and fitted with an
external reflector. Black cooking pots serve as absorbers, heating up more
quickly than aluminium or stainless steel cookware. Box cookers can also
be used to kill bacteria in water if the temperature can reach the boiling
point.
Solar stills (see chapter on Solar water distillation) provide inexpensive
distilled water from even salty or badly contaminated water. They work
on the principle that water in an open container will evaporate. A solar
still uses solar energy to speed up the evaporation process. The stills
consist of an insulated, dark-coloured container covered with glazing that
is tilted so the condensing fresh water can trickle into a collection trough.
A small solar still, which is about the size of kitchen stove, can produce
up to ten litres of distilled water on a sunny day.
Technology Examples
Solar energy has a variety of practical and cost-effective applications
in today’s homes and buildings. The main applications of solar collectors
are as follows :
hot water preparation
in households, commercial buildings and industry,
water heating
in swimming pools,
space heating
in buildings,
drying crops
and houses,
space cooling
and refrigeration,
water distillation,
solar cooking.
The technologies for all applications are considered to be mature
and for the first two, under the appropriate conditions, economically viable.
Separate chapter is devoted to concentrating collectors which are cost
effectively used for power production especially in regions with high insolation
(see chapter on Solar Thermal Power).
Solar Thermal Residential Water Heating
Hot water production is the most widely distributed utilisation of direct solar heating. An installation consists of one or more collectors in which a fluid is heated by the sun, plus a hot-water tank where the water is heated by the hot liquid. Even in the areas of low insolation like in Northern Europe a solar heating system can provide 50-70% of the hot water demand. It is not possible to obtain more, unless there is a seasonal storage (see chapter below). In Southern Europe a solar collector is able to cover 70-90% of the hot-water consumption. Heating water with the sun is very practical and cost effective. While photovoltaics (see chapter on photovoltaics) range from 10-15% efficiency, thermal water panels range from 50-90% efficiency. In combination with a wood stove coil/loop, virtually year round domestic hot water can be obtained without the use of fossil fuels.
HOW IS A SOLAR WATER COLLECTOR
COMPETITIVE WITH CONVENTIONAL HEATERS ?
Costs of complete solar water heating systems differs considerably
from country to country (in Europe and the USA e.g. between 2000 - 4000
USD). They also depend on hot water requirements and the climate conditions
in the area. This is usually a higher initial investment than required
for an electric or gas heater but when adding all of the costs involved
with heating water in home, the life-cycle cost of a solar water heating
system is usually lower than traditional heating system. It must be noted
that simple pay-back time for investment into solar heating system depends
on prices of fossil fuels substituted by solar energy. In EU countries
pay-back times are generally less than 10 years. The expected life span
of the solar heating system is 20-30 years.
Important feature of solar installation is energy pay-back time
- time needed to produce as much energy by solar system as it was needed
to produce this system. In Northern Europe with less solar radiation than
in other parts of the world a solar heating system for hot-water preparation
has an energy pay back period of 3-4 years.
HOW MUCH ENERGY CAN WE GET ?
The amount of energy we can get from solar heating system depends
on available insolation and efficiency of the solar system. Insolation
differs widely in the world and is crucial for solar system. The amount
of solar radiation available in some regions of the world is given in chapter
Solar Radiation. The efficiency of solar system depends on efficiency of
solar collector and losses in the hot water circulation system. As the
later depends on various specific parameters we will focus only on solar
collector efficiency. Efficiency is defined as the ration between the amount
of energy produced and solar energy falling down on collector. Efficiencies
are different for different collector types and depends on solar intensity,
thermal and optical losses - higher losses means lower efficiencies. Thermal
losses are minimal if the temperature of water used for application is
the same as ambient air temperature. Thus simple absorber without glazing
used for pool heating achieve the highest efficiencies up to 90%. But when
these collectors are used for warm domestic hot water preparation (water
temperature 40 degrees Celsius higher than ambient air temperature) their
efficiencies are usually lower than 20%. In this case the best results
are achieved by flat-plate collectors (with selective coatings) and evacuated
tube collectors which are best suited for this application. When
higher water temperatures are needed (e.g. for space heating) evacuated
-tube collectors are the best but also the most expensive.
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pool heating |
domestic hot water |
space heating |
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Low efficiency of evacuated tube collector in low temperature region
is caused by high optical losses on curved surface of the glass.
Bearing in mind that there are huge differences between prices of
collectors it is obvious that the crucial criteria for collector type selection
is purpose of its utilisation. A comparison of different collector types
and their economy features are given in the table below.
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Evacuated-tube |
20-100 |
350-450 |
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Guidelines on Solar Water Heating
System Sizing
A solar water heating system can be used as the sole source for
hot water or may include a back-up conventional system to meet heavy or
unusual hot water requirements throughout the year. Systems are usually
sized according to the number of rooms, people and household water needs.
There are several different configurations of solar water heating systems.
In general, however, there are two main types: active systems which have
pumps and controls to deliver solar heat to the storage tank, and
passive systems like thermosiphons which utilise natural circulation of
hot water.
When designing a solar water heating system, it is important to
decide first how much hot water will be used per average day. If the amount
of hot water is known, the size of system (collectors, storage tank) have
to be calculated. Here are some general remarks on what should be taken
into consideration when designing solar heating system.
Solar Collector
The main
part of the solar heating system are the solar collectors. Most frequently
used are flat-plate collectors consisting of an absorber where the solar
radiation is transferred to heat in the solar collector fluid, insulation
along the edge and under the absorber a case that holds everything together,
and allows the necessary ventilation and a glass or plastic cover.
When glass is used as cover, it is important that the iron content
is low or zero, so at least 95% of the solar radiation pass through the
glass. In practice no more than single layer of glass is used. If a plastic
cover is used, it is important that the plastic can stand up to the UV-rays
from the sun. It has been found that polycarbonate plates are very satisfactory.
The absorber
can be made of a plate with tubes where the collector fluid flows. Usually
the absorber is made of copper or stainless steel. Experience have shown,
that best absorber tubes are those made from copper. Ordinary steel tubes
cause big problems with corrosion. It is essential that the absorber can
stand up to the UV-light from the sun, and the stagnation temperature (dry-boiling
temperature), which is 100-140 deg.C for solar collectors without selective
coating, and 150-200 deg.C with selective coating.
Construction of a flat plate collector requires soldering and brazing
of tubes and physically bonding the tubes to sheet. The more physical contact
between the sheet and the tubes, the more heat transfer to the fluid moving
through the tubes. The absorber is often covered by a selective black coating,
which absorbs the sun rays, but holds back the heat radiation. The problem
with normal black paint is that it will outgas, or boil off the metal under
the extreme heat. Also, under normal cases, black paint will radiate heat,
rather than absorb it for transfer to the fluid.
Many choices for the framework of solar collectors are reasonably
available. Wood, plastic, steel or aluminium have all been used with varying
degrees of success, but nothing is as good as aluminium. Aluminium weathers
the elements with very low maintenance, and has colour choices baked on,
so there is no need to paint the exterior of solar panel. Over the years,
plastics have proven to be a poor choice for the major parts of a solar
panel. For the exterior, plastic has a nasty habit of degrading from the
sun’s ultraviolet rays. Plastic discolours and eventually becomes brittle
and cracks. Plastic also has a high coefficient of expansion. This means
it expands and contracts so much that making the joints weather tight is
difficult. Using steel for framework means also some problems. One is that
the panels need painting regularly and two, they react chemically with
the copper interior.
Solar collectors are usually mounted directly on top of the roof,
or at a frame placed on a flat roof or the ground. Solar collectors can
also be integrated in the roofing. In some cases problems with sealing
between the solar collector and the rest of the roof can arise.
The size of solar collectors depends on the daily hot water requirements.
In general one person may require approx. up to 50 litres of hot water
at approx. 55° to 60° degrees Celsius per day (for domestic bathing
only, without laundry). It has been shown that in average 1-1,5 m2 solar
collector area is needed per 50 litres daily consumption of hot water.
Selection of size would also depend on availability of standard products.
Prizes vary with the collector size and with the installation charges.
Installation is simplest when the system is incorporated in the initial
planning of the construction of a new house. This allows the architect
to incorporate the collectors into the plan, both esthetically and economically.
SOLAR COLLECTOR ORIENTATION
The orientation of solar collectors (which way they face and how
they are tilted) optimizes their collection ability. The earth’s atmosphere
absorbs and reflects a significant portion of solar radiation. Thus, the
most energy that can be gathered on any given sunny day is at solar noon,
when the direct beam radiation is least affected by the atmosphere. Solar
noon is true south in the northern hemisphere. Although orienting the collectors
to true south will normally maximize performance, a variation within 20°
east or west is acceptable without additional collector surface area.
A solar collector that traces the sun, will usually receive about
20% more solar radiation than a south facing optimum placed collector.
This
additional output do not compensate the costs related to a construction,
which has to trace the sun. Usually it will be cheaper to install a 20%
larger solar collector.
Local weather patterns (i.e., morning haze or prevailing afternoon
cloudiness) should also be considered in collector orientation. If local
weather is not a factor and collectors cannot be faced true south, orienting
them to the west is generally preferable due to higher afternoon temperatures
(collectors have less heat loss with higher outside temperatures).
Since elevation of the sun varies throughout the year depending
on local latitude, collectors should be tilted towards the sun depending
upon application. In general, seasonal differences in irradiation are considerable
and must be taken into account for all solar energy applications. Tilting
the collecting surface some 30...50 degrees to the South in the Northern
Hemisphere or to the North in the Southern Hemisphere yields somewhat better
wintertime results for the region in question, but also some losses in
summer. Space heating systems are tilted more to the position of the winter
sun. In the tropics, a nearly horizontal receiving surface is generally
most advantageous because of the sun’s high altitude. The most desired
angle of inclination to mount the solar collector is the local latitude.
Positive difference between latitude and roof angle results better system
performance in winter. Lower solar collector mounting angle than the local
latitude will result in greater system performance in summer. Variations
of solar collector tilt angle for architectural reasons can be compensated
with additional collector size.
Storage Tank
The storage tank shall store the solar heat. This is done by storing
hot water until it is needed. There are several different sizes of tanks
available. All tanks must have connections for cold water inlet and hot
water outlet as well as two connections for circulation pipes. Hot water
storage tanks can easily be fitted to a stand. The most efficient is a
vertical tank with good temperature stratification, so the cold inlet water
aren’t mixed with the warmer water at the top of the tank. A horizontal
tank reduces the output by 10-20%.
The heat from the solar collectors is delivered to the water in
a heat exchanger. As heat exchanger is mostly used a coil in the bottom
of the tank, or a cap around the tank with collector fluid. In low-flow
and self-circulating systems a cap are always used. In low-flow systems
the solar collector fluid flows slowly down through the cap of the storage
tank, which gives a stratification of collector fluid in the cap corresponding
to the stratification in the tank. This gives more ideal heat transfer,
and thereby a higher efficiency than in traditional systems.
All hot water storage tanks must be well insulated to keep the water
hot during the night. Heat loss depends on many factors (ambient temperature,
wind, season, etc.) and will be approximately 0,5 to 1 degree Celsius per
hour during the night. The insulation of the tank must be so good, that
hot water from a sunny day still is hot two days later. Especially the
top must be well insulated, and without thermal bridges. Experience shows
that a minimum thickness of insulation of 100 mm should be maintained.
It must be ensured that piping from the storage tank do not lead
to self-circulation, which can drain the tank for hot water during periods
without hot water consumption. If there is a flow tube pipe for the hot
water, this must not be connected to the cold water; but has to enter at
the upper part of the tank. Usually the outlet of the storage tank is equipped
with a scalding protection, so the water delivered for use never gets warmer
than e.g. 60 deg.C, regardless of the temperature in the tank.
The solar water collector storage tank should have a size of 80
litres of hot water storage volume per person with a hot water consumption
of 50 litres per day. These are the average values. If the home have a
dishwasher, washing machine, several children taking daily showers or baths
during the day, so all of this water usage must be figured into the total
water needs.
Solar Collector Circuit
The solar collector circuit connects the solar collector to the
storage tank. The components of the circuit are:
a pump that ensures circulation
(not needed in self-circulating systems). The pump is usually controlled
by a difference thermostat, so it starts running, when the solar collector
is a bit warmer than the storage tank. If the storage tank has a heat exchanger
coil at the bottom, a more simple control system can be used; e.g. a light
sensor, or a timer that starts the pump during day time.
pipelines connecting hot
water storage tank and collectors. Layout of pipelines should secure to
be of shortest possible distance. Pipes should not be exposed to the weather
if possible. Best is to keep them inside the house where possible. It is
important to have several separate pipes from the collector to the taps
to reduce heat losses (smaller pipes) and to give a fast supply of hot
water to the user, with a maximum delay of about 10 to 20 seconds. Pipelines
must be produced of a non-corroding material. Systems with open expansion
are most risky to get corrosion problems.
a one-way valve which
prevents that the solar collector fluid runs backwards at night, and empties
the storage tank for heat (not necessary in all kinds of installations).
an expansion tank; either
an open container at the top of the installation, or a pressurised expansion
tank that contains minimum 5% of the solar collector fluid.
overpressure protection
(only in connection with pressurized expansion tank); must be a type that
manage to let out the solar collector fluid, if the system is boiling.
There must always be an accumulation tank to the fluid in case of boiling.
This is normally a safety valve and a non-return valve (check), or a non-return
valve and a vent pipe which will release over-pressure due to the
increase of volume by heating.
air outlets, automatic
or simply screws; must be used at all height points in the system, as air
pockets always will appear.
filling valve.
dirt filter for the pump,
to remove dirt, e.g. from the installation (can be spared in some installations).
manometers and thermometers
according to need.
the solar collector fluid
must be able to stand frost, and must not be toxic.
Usually is used an approved liquid, consisting of water with 40% propylene glycol (can stand minus 20 deg.C), and a substance that can be seen and tasted, if solar collector fluid leak to the tap water. Oil can also be used as collector fluid, but it is difficult to make a collector circuit with oil tight.
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MAINTENANCE
The simplicity of solar water heating systems means that maintenance
is minimal. Required maintenance will depend on type of system. Experience
shows that once or twice a year it must be controlled, that there are enough
fluid and pressure on the system. Once a year it should be checked that
the solar collector fluid hasn’t become acid. Acid indicator paper can
be used. Acid fluid should be changed. In case the system is boiling, it
is simply needed to fill new fluid on the system; as the old fluid may
be damaged by the boiling.
An important consideration when designing a system is the freeze-protection
requirements. Some storage tanks must be softened, and the anti-corrosion
zinc block shall be changed after approximately 10 years, it prolongs
the life span significantly.
in
average 50 litres of hot water per person and day is needed.
1-1,5 m2 solar collector area is needed per 50 litres daily consumption
of hot water.
the storage tank shall be 40-70 litres per m2 solar collector or 80 litres
per head.
the heat exchanger in the storage tank shall be able to transfer 40-60
W/deg.C per m2 solar collector at 50 deg.C.
If these guidelines are followed, a typical solar water collector
installed in Northern Europe will cover 60-70% of the annual hot water
consumption, and be able to produce 350-500 kWh/m2 per year. For larger
buildings (e.g. hotels, hospitals, apartment blocks), the collector areas
and storage volumes required per head are smaller, but good dimensioning
needs detailed analysis of demand and local climate conditions. The experience
shows that solar systems for hot water preparation should be designed to
be as simple as possible and not oversized.
Example
For a family with 4 persons which uses 200 litre of hot water each
day solar collector with 6 m2 area are needed. During the year they
can produce up to 3000 kWh of clean energy. When solar collectors substitute
the oil boiler than net saving can achieve at least 300 litres of oil annually.
THERMOSIPHON
Thermosiphons are solar water heating systems with natural circulation
(i.e. by convection) which can be used in non-freezing areas. These systems
are not the highest in overall efficiency but they do offer many advantages
to the home builder. They are simple to make and most of these devices
operate without the assistance of an electric pump. This thermosiphon circulation
occurs because of the variation of water density with its temperature.
With the heating of the water in the collector (usually flat-plate), the
warm water rises, and since it is connected in a riser pipe to the hot
water storage tank and a down-comer pipe again to the collector, it is
replaced by the cooler, heavier cold water from the bottom of the hot water
storage tank. It is therefore necessary to place the collectors below the
hot water storage tank and to insulate both connecting circulation pipes.
Thermosiphon systems have serious problems with their collectors
freezing and bursting, even in areas with only one or two mild freezes
a year. It only takes one frozen night to ruin an unprotected collector.
Some systems are designed to avoid freeze damage by using 10 centimetres
or larger copper tubing in a double glazed, insulated enclosure. Quite
simply, the volume of water in system is too large to freeze and burst
in a mild freeze. This type of installations is popular in sub-tropical
and tropical areas.
The flat plate
collector (absorber).
The circulation
piping.
The hot water
storage tank (boiler).
Usually solar collector is located on a lower story, porch, or shed roof so that the top of the panel is at least 50 centimetres below the bottom of the storage tank. Tank location is usually in a second story, an attic, sometimes a cupola - somewhere that ensures an 50 cm vertical height difference between panel and the tank.
Solar Pool Heating
Solar pool heating system is a wise investment. In the USA the Department
of Energy has identified swimming pools as a huge consumer of energy across
the country, and has recognized pool heating as one of the most cost-effective
means of reducing energy consumption. Solar pool heating systems are being
used in virtually every area of the United States or Europe. Over 200 000
pools are heated by solar in the United States alone. The oldest systems
have been in use for more than 25 years, and are cost-effective, highly
reliable and require minimal maintenance. Important fact is that they function
well and are cost-effective for the swimming season even in northern climates.
Systems can also be designed for indoor pools as well as for larger municipal
and commercial pools.
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Adequate swimming pool heating can be achieved by having low temperature collectors directly connected to the filter circulation. In a few cases an additional “booster pump” or a slightly larger filtration pump may be needed. Today’s most efficient systems employ the use of an automatically controlled diverting valve. The pool’s filtration system is set to run during the period of most intense sunshine. During this period, when the solar control senses that adequate heat is present in the solar collectors, it causes a motorized diverting valve to turn, forcing the flow of pool water through the solar collectors, where water is heated. The heated water then returns to the pool. When heat is no longer present, the water bypasses the solar collector. Thus, most systems have very few moving parts which minimizes operation and maintenance requirements. Additional precautions are required against corrosion in collectors, since the water is quite aggressive (use of low temperature collectors, possibly made of plastics). |
PLACING THE SYSTEMS
Systems can quite easily be placed out of sight in a remote places,
for example upon a suitable roof; however some basic design rules should
be observed. The chosen site should be level or slightly sloping (less
than 30 deg. to horizontal) with the return manifolds higher than the infeed
manifolds and all hoses rising steadily from one to the other to ensure
all air is expelled during operation.
Both a non-return valve and a vacuum release valve should be fitted
to systems placed at more than 1 meter above pool level to prevent the
reverse flow of water into the pool and the flattening of hoses when the
collector drains at the end of each operating cycle. All connections into
the pool filtration circuit must be made after the filter unit and, if
applicable, before any existing conventional heater to avoid pressurising
the solar system.
OPERATION AND MAINTENANCE
The simplicity of solar pool heating systems means that operation
and maintenance requirements are minimal. In fact, in most cases no additional
maintenance beyond normal filter cleaning and winter close-up is necessary.
The system should be drained in the winter months; however, in some cases
even this may not be necessary because the system drains itself. In addition,
solar pool heating equipment is so reliable that many solar pool collector
manufacturers provide warranty coverage for their products which far exceeds
that of automobiles and household appliances.
SOLAR SPACE HEATING
So far only systems for warm water preparation have been described.
An active solar heating plant can provide hot water, and additional heating
via the central heating system at the same time. To get a reasonable output,
the central heating temperature must be as low as possible (preferably
around 50 deg.C), and there must be a storage for the space heating. A
smart solution is to combine the solar heating installation with under-floor
heating, where the floor function as heat storage.
Solar heating installations for space heating usually give less
profit than hot-water installations, both according economy and energy,
as heating is seldom needed during summer. But if heat is needed during
summer (like in some mountain areas), then space heating installations
is a good idea. In central Europe, some 20% of the total heat load of a
traditional house, and close to 50% low energy house, could be supplied
by an advanced active solar heating system employing water storage only.
The remaining heat need to be drawn from auxiliary energy systems. To increase
the solar fraction, would in practice require larger storage capacities.
For single houses, systems with well-insulated water tanks between
5-30 m³ have been constructed especially in Switzerland (so-called
Jenni system) but the costs are too high and the storage is often unpractical.
The solar fraction of a Jenni-system is >50% and may reach even 100%.
If all of the load in the above example were supplied by an up-to-date
active solar heating system, a 25 m² collector area and 85 m³
storage water tank with 100 cm insulation around would be needed. Improving
the energy storage capacity of the storage unit, would dramatically improve
the practical possibilities for storage.
Although individual solar space heating is technically feasible,
it is likely that it would be far more cost effective to invest in insulation
to cut space heating demands.
SEASONAL STORAGE
If a far larger collector together with a much larger storage tank
were fitted, solar energy should be able to supply energy for several houses.
Basic problem with solar energy is related to the fact that most of the
energy is needed during the winter when solar insolation is the lowest
and on the other side much of summer potential output can not be used because
the demand is mostly not there. So capital investment into larger collectors
with larger gains would be wasted.
Despite this fact there are several installations using summer heat
produced by solar collectors and saved through to the winter. These installations
are using large storage tanks (seasonal storage). Problem is that the volume
of hot water storage needed to supply a house is almost the same size as
the house itself. In addition, the tank would need to be better insulated.
A normal domestic hot water cylinder would require insulation of 4 metres
thick to retain most of its heat from summer to winter. It therefore pays
to make storage volume really enormous. This reduces the ratio
of surface area to volume.
Large solar heating plants for district heating are now in use,
e.g. in Denmark, Sweden, Switzerland, France or USA. Solar modules are
mostly installed directly at the ground in larger fields. Without a storage
such solar heating installation would cover approximately 5% of the annual
heat demand, as the plant never must produce more than the minimum heat
consumption, including loss in the district heating system (by 20% transmission
loss). If there is a day-to-night storage, then the solar heating installation
can cover 10-12% of the heat demand including transmission loss, and with
a seasonal storage up to 100%. There is also a possibility to combine district
heating with individual solar water collectors. Then the district heating
system can be closed during summer, when the sun provides hot water, and
there is no need for space heating.
PRESENT SOLAR STORAGE SYSTEMS
Large-size seasonal storage systems for communities have been demonstrated
in several countries but are still too expensive. The size of a central
storage system may range from a few thousand m³ up to a few 100 000
m³. The largest storage project in Europe is in Oulu, Finland where
a large rock cavern heat storage of 200 000 m³ will be connected to
a combined heat and power plant burning biomass. This district heating
plant was built under the EU-Thermie programme.
Another successful project with seasonal storage of hot water has
been constructed in Lyckebo, Sweden. This project is using a rock cavern
filled with water (volume of 105 000 m3) and flat plate solar collectors
with area of 28 800 m2 which supply 100% energy (8500 MWh/a) for space
and water heating of 550 dwellings. All houses are connected to communal
district heating system. The temperature of supply water is 70 degrees
Celsius and the temperature of return water is 55 degrees.
The pay-back times of such installations are very long. The important
lesson from space heating systems has been that it is essential to invest
in energy conservation and passive solar design first and then to use solar
energy to help supply the remaining reduced load.
COMBINING SOLAR WITH OTHER RENEWABLE
SOURCES
Combining renewable energy sources such as solar heat with solar
storage in form of biomass may be a good solution. Or, if the remaining
load of a low energy house is very low, some liquid or gaseous biofuels
with advanced burners together with solar heating may be used.
Solar heating together with solid biomass boilers may provide interesting
synergy and also solution to the seasonal storage of solar energy. Using
biomass in the summer may be non-optimal, as the boiler efficiencies at
partial loads are low and also relative piping losses may be high - in
smaller systems using wood in the summer may even be uncomfortable. Solar
heating may well provide 100% of the summertime loads in such cases. In
the winter, when the solar yield is negligible, the biomass options provides
almost all of the heat needed.
Experiences notably from central Europe with solar heating and biomass
together are positive. Some 20-30% of the total load is typically provided
by solar heating and the main load, i.e. 70-80% of the total load, by biomass.
Combined solar heat and biomass may be used for both single-family houses
and for district heating. For central European conditions, around 10 m³
of biomass (e.g. wood) would be enough for a single-family house with solar
heating system replacing well up to 3 m³ per year in a household.
Solar Thermal Commercial Water
Heating
Many businesses
use solar water heating to preheat the water before using another method
to heat it to boiling or for steam. Being less dependent on fluctuating
fuel prices is another factor that makes solar system a wise investment.
In many cases installation of solar water heating will derive an immediate
and significant savings in energy costs. Depending on the volume of hot
water needed and the local climate a business can realize savings of 40
- 80% on electric or fuel bills. For example the 24-story Kook Jae office
building in Seoul, South Korea meets over 85% of its daily hot water needs
with a solar hot water heating system. The system has been in operation
since 1984 and is so efficient that it has exceeded it’s design specifications
and even provides 10 to 20 percent of the annual space heating requirement.
SOLAR COOLING
The world demand of energy for air-conditioning and cooling is still
increasing. This is not only due to an increasing wish for comfort in highly
industrialized countries but also follows the necessity of e.g. food storage
and medical applications in hot climates especially third world countries.
Today there are mainly three techniques available for active cooling.
First of all the compression machine driven by electricity which is today
the standard cooling device in Europe. On the other hand there is the absorption
cooling machine using heat as driving force. Both compression and absorption
machines are able to provide air conditioning, i.e. chilled water at about
5°C, and refrigeration, i.e. temperatures below 0°C. There is a
third possibility which is desiccant and evaporative cooling used for air
conditioning. All systems can be driven by solar energy and in addition
have the advantage of using absolute harmless working fluids like simple
water, solutions of certain salts in water or ammonia. Possible applications
of this technology are not only air-conditioning but also refrigeration
(food storage etc.).
The vast use of present compression cooling machines is also responsible
for an increasing peak demand of electrical power in summer which reaches
already the capacity limit in some southern countries. Because most of
the electrical power stems from fossil fired power plants this also increases
the production of CO2 which is no longer acceptable. A more innovative
approach is to use solar energy from thermal collectors as driving force
for air-conditioning systems. This idea is very promising in the sense
that to some extent the demanded cooling power is correlated with the incident
solar radiation intensity which also delivers the driving force.
In principle compression cooling machine can be driven by solar
energy i.e. by electricity from photovoltaic panels but we will restrict
to sorption cooling machines using heat from a thermal solar collector
due to the advantage of using environmental harmless refrigerants and the
higher market penetration of thermal solar collectors. A higher market
penetration is also found for absorption cooling machines compared to desiccant
cooling systems. Moreover absorption machines can also be used as retrofit
in standard air conditioning systems using chilled water. Solar collectors
are used for vaporization heat in absorption machine.
In Kuwait, where air conditioning is essential for summer cooling
in residential, commercial and public buildings, the use of solar for air
conditioning has received serious attention during the seventies and eighties.
Development has primarily focused on modifying conventional steam-fired
cooling systems for use with solar-heated water at temperatures below 100°C.
Some attention has also been paid to using photovoltaic systems to generate
the electricity needed to operate a conventional vapour compression air
conditioning unit.
SOLAR DRYING
A solar collector that heats air, can be used as a cheap heat source
for drying crops like corn, fruit or vegetable. Since solar air collectors
can efficiently increase the ambient air temperature by 5 to 10 degrees
Celsius (some sophisticated devices by even more), it can also be used
effectively for air conditioning in warehouses.
The use of simple and low cost solar air collectors for heating
the drying air of crop dryers offers a promising alternative to reduce
the tremendous post harvest losses in developing countries. The lack of
adequate storage and preservation facilities in the developing countries
result in considerable food losses. Although reliable estimate of the magnitude
of the post harvest losses in these countries is not possible, some references
indicates estimates of about 50 to 60%. To avoid such losses, growers usually
sell of their produce immediately after harvest at low prices. Reduction
in these losses through the processing of fresh products into dried products
would be of great significant to growers and consumers alike. In several
developing countries, open air sun drying is the widely practiced method
of food preservation. This involves spreading the fresh material on the
ground, on rocks, along the roadside, or on the roofs. The advantage of
this method lies in its simplicity and cheapness. However, the quality
of the final product is low due to long drying time, contamination by dirt
and dust, infestation by insects and degradation by overheating. Furthermore,
drying to a low moisture content is difficult resulting in spoilage during
subsequent storage. The introduction of solar dryers is an appropriate
technology that can help to improve the quality of the dried products and
to reduce the wastage.
Various types of small scale solar dryers were developed for drying
small amounts of agricultural products in developing countries. In the
natural convection dryers, the solar air heater is either incorporated
into the dryer, or the air heater is connected to a cabinet or chamber
dryer. The solar air-collector may consist of a black mat covered by a
plastic plate. The air is drawn through the mat, where it is heated, and
thereafter blown through the crops. These dryers can be used both in arid
and humid regions for drying fruits, vegetables and spices. Due to their
enlarged capacity they are mainly used on larger farms or by cooperatives
for producing high quality products. Integrating the solar air heater into
the south oriented roof of the barn is common system used in industrialized
countries for drying hay.
Solar dryers are usually classified according to the mode of air
flow into natural convection and forced convection dryers. Natural convection
dryers do not require a fan to pump the air through the dryer. The low
air flow rate and the long drying time, however, result in low capacity
and product quality. Thus, this system is restricted to the processing
of small quantities agricultural surplus for family consumption. Where
large quantities of fresh produce are to be processed for the commercial
market, forced convection dryers should be used. One fundamental disadvantage
of forced convection dryers lies in their requirement of electrical power
to run the fan. Since the rural or remote areas of many developing countries
are not connected to the national electric grid, the use of these dryers
is limited to electrified urban areas. Even in the urban locales with grid-connected
electricity, the service is unreliable. In view of the prevailing economic
difficulties in most of these countries, this situation is not expected
to change in the foreseenable future. The application of photovoltaic to
generate the electricity required by the fan could boost the dissemination
of solar dryers in the developing countries.
In developed countries the solar air heater usually consists of
a black absorber foil, a transparent plastic foil where the air is forced
by a fan between the space. To enlarge the collector area, the roof is
extended southward to the ground and the whole roof is used as collector.
The solar greenhouse dryer is used for drying medicinal and aromatic plants
on large farms. By using a photovoltaic driven blower, it can be secured
that only when the sun shines, air is blown in. Such installations are
commonly used in summer cottages in Denmark and Sweden, where they keep
the houses dry most of the year.
While solar drying has many advantages over sun drying, lack of
control over the weather is the main problem with both methods. In many
regions weather is not suitable for sun or solar drying because there are
few consecutive days of high temperatures and low humidity. It is likely
that the food will sour or mold before drying is completed.
SOLAR
COOKING
Successful solar cookers were first reported in Europe and India
as early as the 18th century. Solar cookers and ovens, absorb solar energy
and convert it to heat, which is captured inside an enclosed area.
This absorbed heat is used for cooking or baking various kinds of food.
In solar cookers temperatures as high as 200 degrees Celsius can be achieved.
Solar cookers come in may shapes and sizes. For example there are:
box ovens, concentrating-type or reflector cookers, solar steam cookers
etc. This list could go on forever. Designs vary, but all cookers trap
heat in some form of insulated compartment. In most of these designs the
sun actually strikes the food.
BOX-TYPE SOLAR COOKERS
Box-type solar cookers consist of a well-insulated box with a black
interior, into which black pots containing food are placed. The cover of
the box usually comprises a two-pane “window” that lets solar radiation
enter the box but keeps the heat from escaping. This in addition to a lid
with a mirror on the inside that can be adjusted to intensify the incident
radiation when it is open and improve the box’s insulation when it is closed.
They make use
of both direct and diffuse solar radiation.
Several vessels
can be heated at once.
They are light
and portable.
They are easy
to handle and operate.
They needn’t
track the sun.
The moderate
temperatures make stirring unnecessary.
The food can
be kept warm until evening.
The boxes are
easy to make and repair using locally available materials.
They are relatively
inexpensive (compared to other types of solar cookers).
There are some disadvantages too:
Cooking must
be limited to the daylight hours.
The moderate
temperatures make for long cooking times.
The glass cover
causes considerable heat losses.
Such cookers
cannot be used for frying or grilling.
Thanks to their simple construction, relatively low cost, uncomplicated handling and easy operation, solar cooking boxes are the most widely used type of solar cooker. There are all sorts of box-type solar cookers: mass-produced, hand-crafted, do-it-yourself types etc. with shapes resembling a suitcase or a wide, low box, and stationary types made of clay, with a horizontal lid for tropical and subtropical areas or an inclined lid for more temperate regions. Standard models with aperture areas of about 0,25 m2 are the rule for a family of five, and larger versions measuring 1 m2 and more are available on the market.
GUIDELINES FOR CONSTRUCTION
Since the heat absorbed by the inner box needs to be conducted to
the area beneath the cooking pots, the best choice of material is aluminium,
because it is a very good heat conductor. Additionally, aluminium is good
for reasons of corrosion prevention, i.e. iron sheet boxes, even galvanized
ones, could not stand up indefinitely to the hot, humid conditions that
are created inside during the cooking process. Sheet copper is prohibitively
expensive.
No metal parts should placed to the outside around the top rim of
the inner box: thermal bridges must be avoided. The insulation may consist
of glass, rock wool or some natural material like residue from the processing
of peanuts, coconuts, rice, corn, etc. Whatever kind of material is used,
it must be kept dry.
The cover could consist of one or two panes of glass with a layer
of air between them. The pane-to-pane clearance usually amounts to 10...20
mm. Recent experiments have shown that a honeycomb structure of transparent
material that divides the inner space into small vertical compartments
can substantially reduce the cooker’s heat losses, thus increasing its
efficiency accordingly. The inside cover pane is exposed to substantial
amounts of thermal stress, for which reason tempered (safety) glass is
frequently used; otherwise, both panes may consist of normal window glass
with a thickness of about 3 mm.
The outer cover, or lid, of the solar cooking box always serves as
a reflector to amplify the incident radiation. The reflecting surface may
consist of an ordinary glass mirror (heavy, expensive, fragile, but easily
obtainable anywhere), plastic sheet with a reflecting coating (Mylar, Tedlar,
etc.; cheap, but not very durable and hard to find), or a metal mirror
(unbreakable). In an emergency, even foil from empty cigarette packs will
do the job.
The outer box of the solar cooker may be made of wood, glass-reinforced
plastic (GRP) or metal. GRP is light, inexpensive and fairly weather-resistant,
but not necessarily stable enough for continuous use. Wood is more stable,
but also heavier and less weather-resistant. A metal case aluminium with
wooden bracing offers the best finish and is adequately stable with regard
to mechanical impact and the effects of weather. An aluminium-clad wooden
box is the most stable of all, but it is expensive and time-consuming to
make, in addition to being heavy.
The capacity of a normal box-type solar cooker with a 0.25 m2 area
of incidence (aperture) amounts about 4 kg ready-to-eat food, or enough
to feed a family of five.
The inside of a solar cooking box can reach a peak temperature of
over 150 deg.C on a sunny day in the tropics; that amounts to a thermal
head of 120 deg.C, referred to the ambient temperature. Since the water
content of food does not heat up beyond 100 deg. C, a loaded solar cooker
will always show an accordingly lower inside temperature. The temperature
inside of the solar cooker drops off sharply when the vessels are placed
inside it. Also important is the fact that the temperature remains well
below 100 deg.C for the greater part of the cooking time. Nevertheless
the boiling temperature of 100 deg. C is not necessary for most vegetables
and cereals.
The average achievable cooking times in box-type solar cookers amount
to somewhere between 1 and 3 hours for good insolation and a reasonable
fill volume. Thin-walled aluminium vessels yield much shorter cooking times
than stainless steel pots.
The time taken for cooking is also influenced by the following factors:
The cooking
time is shortened by strong insolation and viceversa
High ambient
temperatures shorten the cooking time, and viceversa
Small volumes
(shallow fill) in the pot make for shorter cooking times, and vice versa.
REFLECTOR COOKERS
The most elementary kind of reflector cooker is one that consists
of (more or less) parabolic reflectors and a holder for the cooking pot
situated at the cooker’s focal spot. If the cooker is properly aligned
with the sun, the solar energy bounces off of the reflectors such that
it all meets at the focal spot, thus heating the pot. The reflector can
be a rigid axial paraboloid, made for example from sheet metal or from
a reflecting foil. The reflecting surface is usually made of treated aluminium
or a mirror-finish metal or plastic sheet, but it may also consist of numerous
little flat mirrors cemented onto the inside of the paraboloid. Depending
on the desired focal length, the reflector may have the shape of a deep
bowl that completely “swallows” the pot (short focal length, pot shielded
from the wind) or that of a shallow plate with the cooking pot mounted
in the focal point a certain distance above or in front of it.
All reflector cookers exploit only direct insolation and must track
the sun at all times. The tracking requirement makes them somewhat complicated
to handle, depending on the nature and stability of the stand and adjusting
mechanism.
The advantages
of reflector cookers include: The ability to
achieve high temperatures and accordingly short cooking times.
Relatively
inexpensive versions are possible.
Some of them
can also be used for baking.
The above mentioned merits stand in contrast to the following drawbacks,
some of which are quite serious:
Depending on
its focal length, the cooker must be realigned with the sun every 15 minutes
or so.
Only direct
insolation is exploited, i.e. diffuse radiation goes unused.
Even scattered
clouds can cause high heat losses.
The handling
and operation of such cookers is not easy; it requires practice, a good
grasp of the working principle.
The reflected
radiation is blinding, and there is danger of injury by burning when manipulating
the pot in the cooker’s focal spot.
Cooking is
restricted to the daylight hours.
The cook must
stand out in the hot sun (single exception: fixed-focus cookers).
The efficiency
is heavily dependent on the momentary wind conditions.
Any food cooked
around noon or in the afternoon gets cold by evening.
Particularly the cooker’s complicated handling, in combination with the fact that the cook has to stand out in the sun, is a major impediment with regard to the acceptance of reflector cookers. But in China, where the food demands high cooking power and temperature, eccentric axis reflector cookers have been disseminated and accepted in a large number.
THERMAL OUTPUT
The thermal output of a solar cooker is determined by the insolation
level, the cooker’s effective collecting area (usually between 0.25 m2
and 2 m2), and its thermal efficiency (usually between 20% and 50%). Table
below compares some typical area, efficiency and cooking-power values for
a box-type solar cooker and a reflector.
Standard values for area, efficiency and power output of reflector cookers and cooking boxes
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SOLAR RADIATION
The first and foremost prerequisite for success in a solar cooker
application is adequate insolation, with only infrequent interruptions
during the day and/or the year. The duration and intensity of solar radiation
must suffice to allow the use of a solar cooker for prolonged, worthwhile
regular periods. While cooking with solar energy is possible in Central
Europe on a sunny summer day, a minimum irradiation of 1500 kWh/m2 per
year (corresponding to a mean daily insolation of 4 kWh/m2 per day) should
be available for any solar cooker. But these annual data can sometimes
be misleading. The essential condition for solar cooking is a reliable
“summer weather”, i.e. essentially predictable sequences of regular cloudless
days.
Supply of solar energy varies substantially from country to country,
even within the Third World’s tropical belt. Thus, local data must be referred
to - and they are not always available. Some examples: In India solar radiation
in most regions is good to very good for purposes of solar energy exploitation.
The yearly averages of daily annual global radiation range from 5 to 7
kWh/m2 per day, depending on the region. In most places, the insolation
reaches its minimum during the monsoon season and is nearly as weak again
during the months of December and January.
In Kenya’s climate and insolation potential are favourable to the
use of solar cookers. Kenya is close to the equator and therefore has a
purely tropical climate. In Nairobi, the daily irradiation alternates between
3.5 kWh/m2 per day in July and 6.5 kWh/m2 per day in February, but
it remains practically uniform (6.0...6.5 kWh/m2 per day) in other regions
of Kenya like Lodwar. Solar irradiation in Nairobi is adequate for cooking
with solar energy nine months a year (excluding June through August). On
the other hand, conventional cooking facilities must be relied on for cloudy
or hazy days. In the Lodwar area, though, solar cookers can be used year-round.
SOLAR COOKERS FOR DEVELOPING
COUNTRIES
The purpose of solar cookers, of course, is to save energy in the
face of a double energy crisis: the poor people’s energy crisis is the
increasing scarcity of firewood, and the nation’s energy crisis is the
growing pressure on its balance of payments. Solar cooker should be judged
with that in mind.
Compared to other nations, developing countries consume very little
energy. For example, India’s 1982 per capita energy consumption rate, at
7325 GJ, was one of the world’s lowest. But the country’s energy consumption
rate is increasing nearly twice as fast as its gross national product.
The same is true for the most developing countries.
The poor majority of the people in developing countries cover most
of their energy requirement in a non-commercial way, using traditional,
locally available sources of energy and their own physical labour. They
simply cannot afford to buy any appreciable amounts of commercial energy.
The logical consequence is a relative shortage of fuel for use by
the poor, whose living conditions deteriorate even more as a result. Solar
cookers could at least try to compensate.
If the “poor” majority of the Third World’s people is the target
group, then solar cookers must be first and foremost to the benefit of
the rural population.
SOLAR
WATER DISTILLATION
Many people throughout the world do not have access to clean water.
Of the 2.4 billion people in developing countries, less than 500 million
have access to safe drinking water, let alone distilled water. The answer
to these problems is a solar still. A solar still is a simple device that
can convert saline, brackish, or polluted water into distilled water. The
principles of solar distillation have been around for centuries. In the
fourth century B.C., Aristotle suggested a method of evaporating sea water
to produce potable water. However, the first solar still was not produced
until 1874, when J. Harding and C. Wilson built a still in Chile to provide
fresh water to a nitrate mining community. This 4700 m2 still produced
24000 litres of water per day. Currently there are large still installations
in Australia, Greece, Spain and Tunisia, and on Petit St. Vincent Island
in the Caribbean. Smaller stills are commonly used in other countries.
Practically any seacoast and many desert areas can be made inhabitable
by using sunshine to pump and purify water. Solar energy does the pumping
(see chapter on photovoltaics), purification, and controls seawater
feed to the stills.
SOLAR STILL BASICS
The most common still in use is the single basin solar still. The
still consists of an air tight basin that holds the polluted or salt water,
covered by a sloped sheet of glass or plastic. The bottom of the basin
is black to help absorb the solar radiation. The cover allows the radiation
to enter the still and evaporate the water. The water then condenses on
the under side of the cover (which is cooled by the outside air), and runs
down the sloped cover into a trough or tube. The tube is also inclined
so that the collected water flows out of the still.
The process is exactly Mother Nature’s method of getting fresh water
into the clouds from oceans, lakes, swamps, etc. All the water we have
ever consumed has already been solar distilled a several thousand times
around the hydrologic cycle.
SOLAR STILL PERFORMANCE
Operation of the still requires no routine maintenance and has no
routine operating costs. The rated production of the still is an estimated
annual average and is not exact, as the amount of sunshine can vary widely.
Stills produce more in hot climates than in cold ones, more at low latitudes
than high, and more in summer than in winter. At the 23° North latitude
of the central Bahamas, the estimated average production of the installation
was 12 times higher in June than in mid-winter. In higher latitudes, addition
of a mirror to the rear of each still increases winter production. Some
stills also functions in freezing climates. In general solar still can
produce 1 litre of distilled of water a day per square meter of still.
On very sunny days over one litre of water can be gained. The still is
usually filled once daily, at night or in the morning.
STILL COSTS
The cost of a solar distillation system will vary widely, due to
size and site-specific circumstances. The stills are usually inexpensive
to build. Some small models designed in the USA cost 25 USD with glass
or 18 USD with plastic (the amount of water produced is smaller). If the
stills are used for one year, they will produce water at approximately
10 cents per litre.
WATER QUALITY
The distilled water produced is of very high quality, normally better
than that sold in bottles as distilled water. It routinely tests lower
than one part per million total dissolved solids. It is also aerated, as
it condenses in the presence of air inside the still. The water may taste
a little strange at first because distilled water does not have any of
the minerals which most people are accustomed to drinking. Tests have shown
that the stills eliminated all bacteria, and that the incidence of pesticides,
fertilizers and solvents is reduced by 75–99,5%. This is of great importance
for many countries where cholera and other water borne diseases are killing
people daily.
DESIGNING SOLAR STILL
There are a few things to keep in mind when designing the solar
still:
The tank can
be made of cement, adobe, plastic, tile, or any other water resistant material.
If plastic
is used to line the bottom of the still or for the condensate trough, make
sure the tank never remains dry. This could melt the plastic.
Insulation
should be used if possible. Even a small amount will greatly increase the
efficiency of the still.
The container
holding the distilled water should be protected from solar radiation to
avoid re-evaporation.
SOLAR
THERMAL POWER PRODUCTION
In addition to using the warmth of the sun directly, it is possible
(in areas with high level of solar radiation) to use the heat to make steam
to drive a turbine and produce electricity. If undertaken on a large scale,
solar thermal electricity is very cost-competitive. The first commercial
applications of this technology appeared in the early 1980’s, and the industry
grew very rapidly. Today, utilities in the U.S. have installed more than
400 megawatts of solar thermal generating capacity, providing electricity
to 350,000 people and displace the equivalent of 2,3 million barrels of
oil annually. Nine plants in California’s Mojave Desert are generating
354 MWe of solar electric capacity, and have accumulated 100 plant-years
of commercial operating experience. The technology is maturing to
the point where officials say it can compete directly with conventional
power technologies in many regions of USA. A number of opportunities for
solar thermal projects may open soon in other regions of the world. India,
Egypt, Morocco, and Mexico have active programs that will receive grants
from the Global Environment Facility, and independent power producers are
designing power projects in Greece, Spain, and the US.
According to the way how the heat is produced solar thermal power
plants can be divided between solar concentrators (mirrors) and solar ponds.
SOLAR CONCENTRATORS
Solar thermal electric power plants generate heat by using lenses
and reflectors to concentrate the sun’s energy. Because the heat can be
stored, these plants can generate power when it is needed, day or night,
rain or shine.
Large mirrors - of the point focusing type or the line focusing
variety - can concentrate solar beams to such an extent that water can
be converted to steam with enough power to drive a generating turbine.
Enormous fields of such mirrors have been constructed by Luz Corp. in the
Californian desert, for the production of 354 MW of electric power. Such
systems can convert solar to electric power with an efficiency of about
15%.
All solar thermal technologies except solar ponds achieve high temperatures
by utilizing solar concentrators to reflect sunlight from a large area
to a smaller receiver area. A typical system consists of the concentrator,
receiver, heat transfer, storage system and a delivery system.
The sun’s heat can be collected in a variety of different ways.
Today‘s technology includes solar parabolic troughs, solar parabolic dish
and power towers. Because these technologies involve a thermal intermediary,
they can be readily hybridized with fossil fuel and in some cases adapted
to utilize thermal storage. The primary advantage of hybridization and
thermal storage is that the technologies can provide dispatchable power
(dispatchability means that power production can be shifted to the period
when it is needed) and operate during periods when solar energy is not
available. Hybridization and thermal storage can enhance the economic value
of the electricity produced and reduce its average cost.
Solar Parabolic Troughs
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These systems use parabolic trough-shaped mirrors to focus sunlight on thermally efficient receiver tubes that contain a heat transfer fluid. Fluid is heated to almost 400 deg.C and pumped through a series of heat exchangers to produce superheated steam which powers a conventional turbine generator to produce electricity. A transparent glass tube placed in focal line of the trough may envelop the receiver tube to reduce heat loss. Parabolic troughs usually employ single-axis or dual-axis tracking. In rare instances, they may be stationary. |
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Cost projections for trough technology are higher than those for power towers and dish/engine systems (see bellow) due in large part to the lower solar concentration and hence lower temperatures and efficiency. However, with long operating experience, continued technology improvements, and operating and maintenance cost reductions, troughs are the least expensive, most reliable solar thermal power production technology for near-term applications. |
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These systems use an array of parabolic dish-shaped mirrors (similar in shape to a satellite dish) to focus solar energy onto a receiver located at the focal point of the dish. Fluid in the receiver is heated up to 1000°C and is utilized directly to generate electricity in a small engine attached to the receiver.Engines currently under consideration include Stirling and Brayton cycle engines. Several prototype dish/engine systems, ranging in size from 7 to 25 kW have been deployed in various locations in the USA. High optical efficiency and low start up losses make dish/engine systems the most efficient of all solar technologies. A Stirling engine/parabolic dish system holds the world’s record for converting sunlight into electricity. In 1984, a 29% net efficiency was measured at Rancho Mirage, California. |
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In addition, the modular design of dish/engine systems make them
a good match for both remote power needs in the kilowatt range as well
as hybrid end-of-the-line grid-connected utility applications in the megawatt
range.
This technology has been successfully demonstrated in a number of applications. |
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These systems use a circular field array of heliostats (large individually-tracking mirrors) to focus sunlight onto a central receiver mounted on top of a tower which absorbs the heat energy that is then utilized in driving a turbine electric generator. A computer-controlled, dual-axis tracking system keeps the heliostats properly aligned, so that the reflected rays of the sun are always aimed at the receiver. Fluid circulating through the receiver transports heat to a thermal storage system, which can turn a turbine to generate electricity or provide heat directly for industrial applications. Temperatures achieved at the receiver range from 538°C to 1482°C. |
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“Solar Two”, a power tower electricity generating plant in California, is a 10-megawatt prototype for large-scale commercial power plants. This facility first generated power in April 1996, and is scheduled to run for a 3-year test, evaluation, and power production phase to prove the molten-salt technology. It stores the sun’s energy in molten salt at 550 deg.C, which allows the plant to generate power day and night, rain or shine. The successful completion of Solar Two should facilitate the early commercial deployment of power towers in the 30 to 200 MW range (source: Southern California Edison). |
Technology Comparison
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Table below highlights the key features of the three solar technologies. Towers and troughs are best suited for large, grid-connected power projects in the 30-200 MW size, whereas, dish/engine systems are modular and can be used in single dish applications or grouped in dish farms to create larger multi-megawatt projects. Parabolic trough plants are the most mature solar power technology available today and the technology most likely to be used for near-term deployments. Power towers, with low cost and efficient thermal storage, promise to offer dispatchable, high capacity factor, solar-only power plants in the near future. The modular nature of dishes will allow them to be used in smaller, high-value applications. Towers and dishes offer the opportunity to achieve higher solar-to-electric efficiencies and lower cost than parabolic trough plants, but uncertainty remains as to whether these technologies can achieve the necessary capital cost reductions and availability improvements. Parabolic troughs are currently a proven technology primarily waiting for an opportunity to be developed. Power towers require the operability and maintainability of the molten-salt technology to be demonstrated and the development of low cost heliostats. Dish/engine systems require the development of at least one commercial engine and the development of a low cost concentrator. |
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Comparison of Major Solar Thermal Technologies.
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BENEFITS
Solar thermal power plants create two and one-half times as many
skilled, high paying jobs as do conventional power plants that use fossil
fuels.
California Energy Commission study shows that even with existing
tax credits, a solar thermal electric plant pays about 1,7 times more in
federal, state, and local taxes than an equivalent natural gas combined
cycle plant. If the plants paid the same level of taxes, their cost of
electricity would be roughly the same.
POTENTIAL
Utilizing only 1% of the earth’s deserts to produce clean solar
thermal electric energy would provide more electricity than is currently
being produced on the entire planet by fossil fuels.
FUTURE
Over 700 megawatts of solar thermal electric systems should be deployed
by the year 2003 in the U.S. and internationally. The market for these
systems should exceed 5,000 megawatts by 2010, enough to serve the residential
needs of 7 million people which will save the energy equivalent of 46 million
barrels of oil per year.
SUMMARY
Solar thermal power technologies based on concentrating technologies
are in different stages of development. Trough technology is commercially
available today, with 354 MW currently operating in the Mojave Desert in
California. Power towers are in the demonstration phase, with the 10 MW
Solar Two pilot plant located in Barstow (USA), currently undergoing testing
and power production. Dish/engine technology has been demonstrated. Several
system designs are under engineering development, a 25 kW prototype unit
is on display in Golden (USA), and five to eight second-generation
systems have been scheduled for field validation in 1998. Solar thermal
power technologies have distinct features that make them attractive energy
options in the expanding renewable energy market world-wide.
Solar thermal electricity generating systems have come a long way
over the past few decades. Increased research and development of solar
thermal technology will make these systems more cost competitive with fossil
fuels, increase their reliability, and become a serious alternative for
meeting or supplying increased electricity demand.
Solar Ponds
Neither focusing mirrors nor solar cells can generate electricity
at night. For this purpose the daytime solar energy must be stored in storage
tanks, a process which occurs naturally in a solar pond.
Salt-gradient solar ponds have a high concentration of salt near
the bottom, a non-convecting salt gradient middle layer (with salt concentration
increasing with depth), and a surface convecting layer with low salt concentration.
Sunlight strikes the pond surface and is trapped in the bottom layer because
of its high salt concentration. The highly saline water, heated by the
solar energy absorbed in the pond floor, can not rise owing to its great
density. It simply sits at the pond bottom heating up until it almost boils
(while the surface layers of water stay relatively cool)! This hot brine
can then be used as a day or night heat source from which a special organic-fluid
turbine can generate electricity. The middle gradient layer in solar pond
acts as an insulator, preventing convection and heat loss to the surface.
Temperature differences between the bottom an surface layers are sufficient
to drive a generator. A transfer fluid piped through the bottom layer carries
heat away for direct end-use application. The heat may also be part of
a closed-loop Rankine cycle system that turns a turbine to generate electricity.
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1. High salt concentration
2. Middle layer. 3. Low salt concentration. 4. Cold water in and hot water out. |
In 1839 Edmund
Becquerel, a French physicist observed the photovoltaic effect.
In 1883 Selenium
PV cells were built by Charles Edgar Fritts, a New York electrician. Cells
converted light in the visible spectrum into electricity and were 1% to
2% efficient. (light sensors for cameras are still made from selenium today).
In the early
1950’s the Czochralski meter was developed for producing highly purecrystalline
silicon.
In 1954 Bell
Telephone Laboratories produced a silicon PV cell with a 4% efficiency
and later achieved 11% efficiency.
In 1958 the
US Vanguard space satellite used a small (less than one watt) array to
power its radio. The space program has played an important role in the
development of PV’s ever since.
During the
1973-74 oil price shock several countries launched photovoltaic utilization
programmes, resulting in the installation and testing of over 3,100 PV
systems in USA alone, many of which are in operation today.
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The present PV market is characterised by a fairly high and stable increase of over 20 % per year, however on a still fairly low level of production volume. The world-wide module production for 1998 amounted to about 125 MW while prices have dropped from $50/W in 1976 to $5/W in 1999. Nevertheless kWh prices of electricity produced by PV systems are still too expensive by a factor 3 to 10 (depending on the site and system design) as compared to conventional electric energy. The PV market is thus a small niche market, however with steadily increasing market segments where PV is already cost competitive as e.g. in many stand alone system applications. |
Progress is visible in many parts of the world. The Japanese government
is investing $250 million a year to increase manufacturing capacity from
40 MW (1997) to 190 MW (2000) and national programs are being launched
in Europe, driven by energy independence and environment. These programs,
combined with environmental pressures such as climate change, can
accelerate growth of the PV industry. Shell Solar has built the world’s
largest PV manufacturing facility in Germany, with current annual production
of 10 MW and future growth to 25 MW. The cost was 50 million Mark.
PV UTILISATION
For a range
of applications solar cells are technically feasible and economically viable
alternative to fossil fuels. A solar cell can directly convert the sun’s
irradiation to electricity and this process requires no moving parts.
This results in a relatively long service life of solar generators. PV
systems have been the best choice for many jobs since the first commercial
PV cells were developed. For example, PV cells have been the exclusive
power source for satellites orbiting the earth since the 1960s. PV systems
have been used for remote stand-alone systems throughout the world since
the 1970s. In the 1980s, commercial and consumer product manufacturers
began incorporating PV into everything from watches and calculators to
music boxes. And in the 1990s, many utilities are finding PV to be the
best choice for thousands of small power needs.
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PV modules supplied electricity also to the Breitling Orbiter 3 balloon during its non-stop trip around the world. For three weeks in March 1999, the balloon’s on-board equipment was powered by 20 modules suspended under the nacelle. Each module was tilted to ensure even power output during rotation, and recharged five lead batteries for navigation instruments, satellite communications systems, lighting and water heating. The modules functioned perfectly throughout epic voyage. |
PV is successfully utilised also in village electrification. Today
two billion people in the world are without electricity. A large portion
live in the developing world, where 75% of the population lives without
electricity. There is rarely a utility grid in these remote, rural or suburban
villages. Experience shows that PV delivers cost-effective electricity
for basic services, such as:
light
water pumping
communications
health facilities
businesses
People not served by a power grid often rely on fossil fuels like
kerosene and diesel. There are a number of problems associated with the
use of fossil fuels.
Imported fossil fuels drain
foreign currency.
Transporting is difficult
because of infrastructure.
Maintenance of fossil fuel
generators is difficult because of lack of spare parts.
Generators pollute the
environment by loud noises and exhaust.
Electric lights powered by PV are more effective than kerosene lights
in developing countries, and installing a PV system is usually less expensive
than extending the power lines. Moreover, many developing countries are
located in areas with high insolation levels, providing them with a free
abundant source of energy year round. Using photovoltaics to generate electricity
from sunlight is simple and has proven reliable in tens of thousands of
applications world-wide.
During the next decades, a large part of the world’s population
will be introduced to electricity produced by PV systems. These PV systems
will make the traditional requirements of building large, expensive power
plants and distribution systems unnecessary. As the costs of PV continue
to decline and as PV technology continues to improve, several potentially
huge markets for PV will open up. For example, building materials that
incorporate PV cells will be designed right into homes, helping to ventilate
and light the buildings. Consumer products ranging from battery-powered
hand tools to automobiles will take advantage of electricity - producing
components containing PV materials. Meanwhile, electric utilities will
find more and more ways to use PV to supply the needs of their customers.
The EU wants to double the share of renewables by 2010, and key
actions include one million PV systems (500,000 roof and the export of
500,000 village systems) with total installed capacity of 1 GW. BP Amoco
(one of the world’s leading marketers of petroleum products) will incorporate
solar energy into 200 of its new service stations in Britain, Australia,
Germany, Austria, Switzerland, the Netherlands, Japan, Portugal and Spain,
France and the US. The $50 million program will involve 400 panels, generating
3.5 MW and saving 3,500 tonnes of CO2 emissions every year. The project
will make BP Amoco one of the world’s largest users of solar power, as
well as one of the largest manufacturers of cells and modules. The solar
panels will generate more power than consumed for lighting and pump power,
and will be grid-connected to allow excess electricity to be exported during
the day and the shortfall imported at night. The world market for photovoltaics
will reach 1,000 MW by 2010 and 5 million MW by 2050, according to the
president of BP Solar.
Today’s solar
cell production is almost exclusively based on silicon. About 80% of all
modules are fabricated using crystalline silicon cells (multicrystalline
and single crystalline) and about 20% are based on amorphous silicon thin
film cells. The crystalline cells are the more common, generally
blue-coloured frosty looking ones. Amorphous means noncrystalline, and
these look smooth and change color depending on the way you hold them.
Monocrystalline silicon has the best efficiency - about 14% of the
sunlight can be utilized - but it is more expensive than multicrystalline
silicon, which typically has 11% efficiency. Amorphous
silicon is widely used in small appliances such as watches and calculators,
but its efficiency and long-term stability are significantly lower;
consequently, it is rarely used in power applications.
amorphous silicon (a-Si:
H) cells,
cadmium telluride/cadmium
sulfide (CTS) cells,
copper indium diselenide
or copper indium/gallium diselenide (CIS or CIGS) cells, crystalline silicon
thin film (c-Si film) cells and
nanocrystalline dye sensitised
electrochemical (nc-dye) cells.
PV
cells are “sandwiches” of silicon, the second most abundant material in
the world. Ninety-nine percent of today’s solar cells are made of silicon
(Si), and other solar cells are governed by basically the same physics
as Si solar cells. One layer of silicon is treated with a substance to
create an excess of electrons. This becomes the negative or “N” layer.
The other layer is treated to create a deficiency of electrons, and becomes
the positive or “P” layer. Assembled together with conductors, the arrangement
becomes a light-sensitive NP junction semiconductor. It’s called a semiconductor,
because, unlike a wire, the unit conducts in only one direction; from negative
to positive. When exposed to sunlight (or other intense light source),
the voltage is about 0,5 Volts DC, and the potential current flow (amps)
is proportional to the light energy (photons). In any PV, the voltage is
nearly constant, and the current is proportional to the size of the PV
and the intensity of the light.
Photovoltaic cells are made from hyper pure silicon that is precisely
doped with other materials. The hyper pure silicon substrates used to make
PV cells are very expensive. After all, the same amount of hyper pure silicon
used in a single 50 Watt PV module could have been made into enough integrated
circuits for about two thousand computers. The remainder of the materials
used by PV cells are aluminum, glass, and plastic - all inexpensive and
easily recyclable materials.
Solar
modules are an array of solar cells which are interconnected and
encapsulated behind a glass cover. The stronger the light falling
down on the cells and the larger the cell surface, the more electricity
is generated and the higher the current. Modules are rated in peak
watts (Wp). A watt is the unit used to express the power of a generator
or the demand of a consumer. One peak watt is a specification which
indicates the amount of power generated under rated conditions, i.e.
when solar irradiance of 1 kW/m2 is incident on the cell at a temperature
of 25 deg. C. This level of intensity is achieved when weather conditions
are good and the sun is at its zenith. No more than a cell of
10 x 10 cm is necessary to generate a peak watt. Larger modules,
1 m x 40 cm in size, have an output of about 40-50 Wp. Most of the
time, however, the irradiation is below 1 kW/m2. Furthermore, in
sunlight the module will warm up beyond the rated temperature. Both
effects will reduce the module’s performance. For typical conditions an
average output of about 6 Wh per day and 2000 Wh per year per
peak watt can be expected. To have the idea of how much that is,
5 Wh is the energy consumed by a 50 W lamp in 6 minutes (50W x 0,1h = 5Wh)
or by a small radio in one hour (5W x 1h = 5Wh).
PV ADVANTAGES
High Reliability
PV cells were originally developed for use in space, where repair
is extremely expensive, if not impossible. PV still powers nearly
every satellite circling the earth because it operates reliably for long
periods of time with virtually no maintenance.
Low Operating Costs
PV cells use the energy from sunlight to produce electricity - the
fuel is free. With no moving parts, the cells require low-maintenance.
Cost-effective PV systems are ideal for supplying power to communication
stations on mountain tops, navigational buoys at sea, or homes far from
utility power lines.
Non-polluting
Because they burn no fuel and have no moving parts, PV systems are
clean and silent. This is especially important where the main alternatives
for obtaining power and light are from diesel generators and kerosene lanterns.
Modular
A PV system can be constructed to any size. Furthermore, the
owner of a PV system can enlarge or move it if his or her energy needs
change. For instance, homeowners can add modules every few years
as their energy usage and financial resources grow. Ranchers can
use mobile trailer-mounted pumping systems to water cattle as they are
rotated between fields.
Low Construction Costs
PV systems are usually placed close to where the electricity is
used, meaning much shorter wire runs than if power is brought in from the
utility grid. In addition, using PV eliminates the need for a step-down
transformer from the utility line. Fewer wires mean lower costs and shorter
construction time.
HOW MUCH SPACE DOES PV TAKE?
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The most common modules (using cells made from crystalline silicon) generate 100-120 watts per square meter (W/m2). Thus, one square meter module generates enough electricity to power a 100 W light bulb. At the upper end of the range, a PV power plant laid out on a square piece of land measuring approximately 160km on a side could supply all the electricity consumed annually be the entire United States. Better alternative than to use open land area is to place PV modules on the roofs of buildings or integrate them into facades of the walls. This option is usually cheaper because it can replace traditional building materials which have to be used anyway. |
Simple PV Systems
The sunlight
that creates the need for water pumping and ventilation can be harnessed
using the most basic PV systems to meet those same needs. Photovoltaic
modules produce the most electricity on clear, sunny days. Simple PV systems
use the DC electricity as soon as it is generated to run water pumps or
fans. These basic PV systems have several advantages for the special jobs
they do. The energy is produced where and when it is needed, so complex
wiring, storage, and control systems are unnecessary. Small systems, under
500 W, weigh less than 70 kilograms making them easy to transport and install.
Most installations take only a few hours. And, although pumps and fans
require regular maintenance, the PV modules require only an occasional
inspection and cleaning.
Solar Water Pumping
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Photovoltaic pumping systems provide a welcome alternative to fuel burning generators or hand pumps. They provide the most water precisely when it is needed the most - when the sun shines the brightest! Solar pumps are simple to install and maintain. The smallest systems can be installed by one person in a couple hours, with no experience or special equipment required. |
low maintenance
ease of installation
reliability
scalability
Solar power differs fundamentally from conventional electric or engine-powered
systems, so solar pumps often depart from the conventional. PV arrays produce
DC power, rather than the AC from conventional sources. And, the power
available varies with the sun’s intensity. Since it costs less to store
water (in tanks) than energy (in batteries) solar pumps tend to be low
in power, pumping slowly through the duration of the solar day.
Simple, efficient systems are the key to economical solar pumping.
Special, low-power DC pumps are used without batteries or AC conversion.
Modern DC motors work well at varying voltage and speed. The better DC
motors require maintenance (brush replacement) only after periods of 5
years or more. Most solar pumps used for small scale application (homes,
small irrigation, livestock) are “positive displacement” pumps which seal
water in cavities and force it upward. This differs from faster, conventional
centrifugal type pumps (including jet and submersible pumps) which spin
and “blow” the water up.
Positive displacement pumps include piston, diaphragm, rotary vane,
and pump jacks. They work best for low volumes, particularly where variable
running speeds occur. Centrifugal, jet and turbine pumps are used for higher
volume systems. Electronic matching devices known as Power Trackers and
Linear Current Boosters allow solar pumps to start and run under low-light
conditions. This permits direct use of the sun’s power without bothersome
storage batteries. Solar trackers may be used to aim the panels at the
sun from morning to sunset, extending the useable period of sunlight. Storage
tanks usually hold a 3-10 day supply of water, to meet demands during cloudy
periods. Solar pumps use surprisingly little power. They utilize high efficiency
design and the long duration of the solar day, rather than power and speed,
to lift the volume of water required.
In areas where photovoltaic pumps have entered into competition
with diesel-driven pumps, their comparatively high initial cost is offset
by the achieved savings on fuel and reduced maintenance expenditures. Studies
concerning the economic efficiency of photovoltaic pumping systems confirm
that they are often able to yield cost advantages over diesel-driven pumps,
depending on the country-specific situation.
PV SYSTEMS WITH BATTERIES
The most simple solutions have certain drawbacks - the most obvious
one being that in case of PV powered pump or fan could only be
used during the daytime, when the sun is shining. To compensate for
these limitations, a battery is added to the system. The battery is charged
by the solar generator, stores the energy and makes it available at the
times and in the amounts needed. In the most remote and hostile environments,
PV-generated electrical energy stored in batteries can power a wide variety
of equipment. Storing electrical energy makes PV systems a reliable source
of electric power day and night, rain or shine. PV systems with battery
storage are being used all over the world to power lights, sensors, recording
equipment, switches, appliances, telephones, televisions, and even power
tools.
A solar module generates a direct current (DC), generally at a voltage
of 12 V. Many appliances, such as lights, TV’s, refrigerators,
fans, tools etc., are now available for 12V DC operation. Nevertheless
the majority of common electrical household appliances are designed
to operate on 110 V or 220 V alternating current (AC). PV systems with
batteries can be designed to power DC or AC equipment. People who want
to run conventional AC equipment add a power conditioning device called
an inverter between the batteries and the load. Although a small amount
of energy is lost in converting DC to AC, an inverter makes PV-generated
electricity behave like utility power to operate everyday AC appliances,
lights, or computers.
PV systems with batteries operate by connecting the PV modules to
a battery, and the battery, in turn, to the load. During daylight hours,
the PV modules charge the battery. The battery supplies power to the load
whenever needed. A simple electrical device called a charge controller
keeps the batteries charged properly and helps prolong their life by protecting
them from overcharging or from being completely drained. Batteries make
PV systems useful in more situations, but also require some maintenance.
The batteries used in PV systems are often similar to car batteries, but
are built somewhat differently to allow more of their stored energy to
be used each day. They are said to be deep cycling. Batteries designed
for PV projects pose the same risks and demand the same caution in handling
and storage as automotive batteries. The fluid in unsealed batteries should
be checked periodically, and batteries should be protected from extremely
cold weather.
A solar generating system with batteries supplies electricity when
it is needed. How much electricity can be used after sunset or on cloudy
days is determined by the output of the PV modules and the nature of the
battery bank. Including more modules and batteries increases system cost,
so energy usage must be carefully studied to determine optimum system size.
A well-designed system balances cost and convenience to meet the user’s
needs, and can be expanded if those needs change.
DESIGNING PV HOME SYSTEM WITH BATTERIES
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A solar-powered system with batteries can run quite a lot of consumer devices, but only, of course, if the energy demand does not exceed the generator output. The right sizing of the system is thus necessary. The first step towards having such a system that will provide energy needs is specification of the system. |
CALCULATION OF ENERGY DEMAND
In case of
designing PV powered home system the first step to make is to create a
list of all electrical appliances in the household. Check the power input
required for the operation of these appliances and put this on the list.
As an example average data on power consumption for some devices
are in the table below, but it is important to bear in mind that these
are only rough estimations. To calculate power consumption (E) of the system
with inverter (using AC devices) it is needed to make correction (multiply
average consumption by C to calculate the total power demand Ptot).
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| Radio/Cas.tape,6V |
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| Small b/w TV |
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Second step is to estimate the amount of time per day that the specific appliances are in operation. This maybe as much as 10 hours for a lamp in the living room, but perhaps only 10 minutes for one in the store. Add these data to your list in a second column in table bellow. Finally, you should make a third column where you list the daily energy requirement. Calculate this figure by multiplying the power by the operating period, e.g. 27 W x 4 h = 108 Wh. When you have added up all the figures in this column, you will have your overall energy demand (E).
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Using the first figure, PV system can be adjusted to the average
insolation per year, which means there are some months with more energy
than required or calculated and some months with less. If you use the second
(low case) figure, you will always have at least enough energy to meet
your requirements, except in unusually bad weather periods. However, the
PV module will have to be larger and it will also be more costly.
Now you can calculate the rated power of the PV module. Use your
energy demand figure (in Wh/d), multiply it by 1,7 to allow for energy
losses in the system and divide it by the solar insolation figure (in Wh/d),
e.g. 280 (Wh/d) x 1,7/ 5 (kWh/d) = 96,2 W. Unfortunately, PV modules
are only available with a few power ratings. Using a 50 W module, for example,
you can build generators of 50 W, 100 W, 150 W, etc.. With a power demand
of 95 W, a two-module system would be the best match. Choose the number
of modules whose total power rating corresponds approximately to the value
you have calculated. If the two figures differ significantly, you have
to undersize or oversize the generator. In the first case, the PV system
will not be able to meet overall energy demand. Decide whether this partial
supply option would be acceptable to you. In the second case, you will
have surplus energy.
Designing the battery size depends on energy demand and the number
of PV modules. For above mentioned example battery capacity of 60 Ah per
module as a minimum should be used and 100 Ah as an optimum. Such a battery
can store 1200 Wh at 12 V. This capacity can cover 4 days of energy needs
for above mentioned example with daily energy consumption of 280 Wh.
It covers peak loads which
the PV modules cannot meet on its own (buffer).
It provides energy during
the night (short-term storage).
It compensates for periods
of bad weather or of unusually high energy demand (medium-term
storage).
Automotive
batteries, which are available all over the world at reasonable prices,
are the most commonly employed type of battery. However, they
are designed to deliver high currents over short periods. They cannot
withstand the continuos cycles of charging and discharging that are
typical for solar systems. The industry has developed batteries,
sometimes called solar batteries, which meet these conditions. Their
main feature is low sensitivity to cyclic operation.
The capacity of a battery is indicated in ampere-hours (Ah).
A 100 Ah, 12 V battery, for instance, can store 1,200 Wh (12 V x
100 Ah). However, the capacity will vary, depending on the
duration of the charging or discharging process. In other words,
a battery will deliver more energy during a 100 h discharging
period than during a 10 h period. The charging period is indicated
by an index to the capacity c, e.g. C100 for 100 hours. Note
that suppliers may use different reference periods.
When storing energy in batteries, a certain amount of energy
is lost in the process. Automotive batteries have efficiencies of
about 75%, while solar batteries may perform slightly better.
Some of the battery capacity is lost in each charging-discharging cycle
and eventually drops to a level at which the battery has to be
replaced. Solar batteries have a longer lifetime than heavy-duty
automotive batteries, which last about 2 or 3 years.
SIZING THE PV SYSTEM’S BATTERY
It is important to size the PV systems battery with a minimum of
four days of storage. Consider the system that consumes 2,480 watt-hours
daily. If we divide this figure by system voltage of 12 V DC, we arrive
at a daily consumption of 206 Ampere-hours from the battery. So four days
of storage would be 4 days X 206 Ampere-hours per day or 826 Ampere-hours.
If the battery is a lead-acid type, then we should add 20% to this amount
to ensure that the battery is never fully discharged. This brings our ideal
lead-acid battery up to a capacity of 991 Ampere-hours. If the battery
is nickel-cadmium or nickel-iron, then this extra 20% capacity is not required
because alkaline batteries don’t mind being fully discharged on a regular
basis.
THE CHARGE REGULATOR
A
battery can only be expected to last several years if a good charge
regulator is employed. It protects the battery against overcharging
and deep-discharging, both of which are harmful to the battery. If
a battery is fully charged, the regulator reduces the current delivered
by the solar generator to a level which equalizes the natural losses. On
the other hand, the regulator interrupts the amount of energy supplied
to the load appliances when the battery has discharged to a
critical level. Thus, in most cases a sudden interruption in supply
is not a system failure, but rather an effect of this safeguard mechanism.
Charge regulators are electronic components and, as such, may be
affected by malfunctions and improper handling of the systems.
Improved designs are equipped with safeguards to prevent damages
to the regulator and other components. These include safeguards against
short circuit and battery reverse polarity (mixing up of the
batteries’ +/- poles) as well as a blocking diode to prevent overnight
battery discharge. Many models indicate certain states of operation
and malfunctions by means of LEDs (light emitting diodes = small lamps).
A few even indicate the state of charge. Nevertheless the state of
charge is difficult to determine and can only be roughly estimated.
THE INVERTER
The
inverter converts low voltage DC power (stored in the battery and produced
by the PVs) into standard alternating current, house power (120 or 240
V AC, 50 or 60 Hz). Inverters come in sizes from 250 watts (about 300 USD)
to over 8,000 watts (about 6,000 USD). The electric power produced by modern
sine wave inverters is far purer than the power delivered to your wall
sockets by your local electric utility. There are also “modified sine wave”
inverters that are less expensive yet still up to most household tasks.
This type of inverter may create a buzz in some electronic equipment and
telephones which can be a minor problem. The better sine wave inverters
have made great improvements in performance and price in recent years.
Inverters can also provide a “utility buffer” between your system and the
utility grid, allowing you to sell your excess power generated back to
the utility for distribution by their grid.
TRACKERS
PV modules work best when their cells are perpendicular to the Sun’s
incoming rays. Adjustment of static mounted PV modules can result in from
10% (in winter) to 40% (in summer) more power output yearly. Tracking means
mounting the array on a movable platform which follows the sun’s daily
motion. A tracker is a special PV mounting rack that follows the path of
the sun. In general the extra energy captured by following the sun must
be weighed against the costs of installing and maintaining the tracking
system.
Trackers cost money just like PV modules. In many countries it is
not cost effective to track less than eight modules (e.g. in the USA).
Under eight modules, we will get more power output for money if we spend
the money on more panels rather than a tracker. At eight panels in the
system, the tracker starts to pay off. There are exceptions to this rule,
for example array direct water pumps. If PVs are directly driving a water
pump, without a battery in the system, then it is cost effective to track
two or more PV modules. This has to do with technical details like the
peak voltage required to drive the pumps electric motor.
THE LAMPS
Due to their excellent efficiency and long lifetime, energy
saving lamps should always be used in PV operated systems. Fluorescent
tubes or the new compact fluorescent lamps (CFL) are suitable in many cases,
18 W CFL lamp is able to substitute traditional 100 W incadescent light
bulb. CFL lamps require electronic ballasts to be operated with a DC system.
The quality of such ballasts varies considerably and sometimes proves
to be very poor. Low-quality ballasts will result in high costs for continuous
replacement of worn-out tubes. It is important for ballasts to have a good
efficiency, a high number starting cycles, reliable ignition at low temperatures
and low voltages (10.5 V), and protection against short-circuit, open circuit,
reverse polarity and radio interference. Despite the fact that most CFL
lamps on the market are working only with AC current there are few companies
offering also DC powered lamps.
LIFETIME AND PRICING OF COMPONENTS
A very important consideration in the economic analysis is the lifetime
of a PV system. Lifetimes of the various components of a PV power supply
have been estimated, based on experiences gained over the past few years.
The lifetime of PV panels
is estimated at 20 years. Proper encapsulation and the use of low-iron
tempered glass ensure a lifetime which may go well beyond.
Galvanized iron frames and
anchors are part of most PV systems. Properly galvanized material should
last as long as the panels although some
maintenance may be required.
Batteries. Depending on
the character of the charge/discharge cycles, the average lifetime of the
so-called “Solar Batteries”, has been 4 years.
Battery chargers are assumed
to last at least 10 years.
Inverters are assumed to
last for 10 years.
Rough guidelines for pricing of the several components:
Inverters - USD 0.50/W
Frames (galvanized) - USD
0.30/Wp
Control Devices - USD 0.50/Wp
Cables - USD 0.70/m
Local stationary batteries
- USD 100/kWh capacity
PV modules - USD 5 /Wp.
PV WITH GENERATORS
Working together, PV and other electric generators can meet more
varied demands for electricity, conveniently and for a lower cost than
either can meet alone. When power must always be available or when larger
amounts of electricity than a PV system alone can supply are occasionally
needed, an electric generator can work effectively with a PV system to
supply the load. During the daytime, the PV modules quietly supply daytime
energy needs and charge batteries. If the batteries run low, the engine-generator
runs at full power its most constant fuel-efficient mode of operation until
they are charged. And in some systems the generator makes up the difference
when electrical demand exceeds the combined output of the PV modules and
the batteries. Systems using several types of electrical generation combine
the advantages of each. Engine-generators can produce electricity any time.
Thus, they provide an excellent backup for the PV modules (which produce
power only during daylight hours) when power is needed at night or on cloudy
days. On the other hand, PV operates quietly and inexpensively, and does
not pollute. Using PV and generators together can also reduce the initial
cost of the system. If no other form of generation is available, the PV
array and the battery storage must be large enough to supply night time
electrical needs.
However, having an engine-generator as backup means fewer PV modules
and batteries are necessary to supply power whenever it is needed. Including
generators makes designing PV systems more complex, but they are still
easy to operate. In fact, modern electronic controllers allow such systems
to operate automatically. Controllers can be set to automatically switch
generators or to supply AC or DC loads or some of each. In addition to
engine generators, electricity from wind generators, small hydro plants,
and any other source of electrical energy can be added to make a larger
hybrid power system.
GRID-CONNECTED PV
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Where utility power is available, a grid-connected home PV system can supply some of the energy needed and use the utility in place of batteries. Several thousands of homeowners around the world are using PV systems connected to the utility grid. They are doing so because they like that the system reduces the amount of electricity they purchase from the utility each month. They also like the fact that PV consumes no fuel and generates no pollution. The owner of a grid-connected PV system buys and sells electricity each month. Electricity generated by the PV system is either used on site or fed through a meter into the utility grid. When a home or business requires more electricity than the PV array is generating, for example, in the evening, the need is automatically met by power from the utility grid. When the home or business requires less electricity than the PV array is generating, the excess is fed (or sold ) back to the utility. Used this way, the utility backs up the PV like batteries do in stand-alone systems. At the end of the month a credit for electricity sold gets deducted from charges for electricity purchased. In some countries utilities are required to buy power from owners of PV systems (and other independent producers of electricity). |
UTILITY-SCALE PV
Electric,
gas, and water utilities have been using small PV systems economically
for several years. Most of these systems are less than 1 kW and use batteries
for energy storage. These systems are performing many jobs for utilities,
from powering aircraft warning beacons on transmission towers to monitoring
air quality of fluid flows. They have demonstrated the reliability and
durability of PV for utility applications and are paving the way for larger
systems to be added in the future.
Utilities are exploring PV to expand generation capacity and meet
increasing environmental and safety concerns. Large-scale photovoltaic
power plants, consisting of many PV arrays installed together, can prove
useful to utilities. Utilities can build PV plants much more quickly than
they can build conventional power plants because the arrays themselves
are easy to install and connect together electrically. Utilities can locate
PV plants where they are most needed in the grid because siting PV arrays
is much easier than siting a conventional power plant. And unlike conventional
power plants, PV plants can be expanded incrementally as demand increases.
Finally, PV power plants consume no fuel and produce no air or water pollution
while they silently generate electricity. Unfortunately, PV generation
plants have several characteristics that have slowed their use by utilities.
Under current utility accounting, PV-generated electricity still costs
considerably more than electricity generated by conventional plants. Furthermore,
photovoltaic systems produce power only during daylight hours and their
output varies with the weather.
Utility planners must therefore treat a PV power plant differently
than a conventional plant in order to integrate PV generation into the
rest of their power generation, transmission, and distribution systems.
On the other hand, utilities are becoming more involved with PV. For example
in USA utilities are exploring connecting PV systems to the utility grid
in locations where they have a higher value. For example, adding PV generation
near where the electricity is used avoids the energy losses resulting from
sending current long distances through the power lines. Thus, the PV system
is worth more to the utility when it is located near the customer. PV systems
could also be installed at locations in the utility distribution system
that are servicing areas whose populations are growing rapidly. Placed
in these locations, the PV systems could eliminate the need for the utility
to increase the size of the power lines and servicing area. Installing
PV systems near other utility distribution equipment such as substations
can also relieve overloading of the equipment in the substation.
Photovoltaics are unlike any other energy source that has ever been
available to utilities. PV generation requires a large initial expense,
but the fuel costs are zero. Coal- or gas- fired plants cost less to build
initially (relative to their output) but require continued fuel expense.
Fuel expenses fluctuate and are difficult to predict due to the uncertainty
of future environmental regulations. Fossil fuel prices will rise over
time, while the overall cost of PVs (and all renewable energy resources)
is expected to continue to drop, especially as their environmental advantages
are valued.
Guideline for Estimation of Solar Potentials, Barriers and Effects
Energy Content
The yearly incoming solar energy varies from 900-1000 kWh/m2 North
of the Baltic Sea to e.g. 1077 kWh/m2 in Central Europe (Hradec Kralove
in Bohemia) and up to 1600 kWh/m2 in Mediterranean and Black Sea areas
on a horizontal surface. On a south sloping surface, the incoming solar
energy is about 20% higher.
Resource Estimation
The incoming solar energy on most buildings exceed the energy consumption
of the building, e.g. a 5 storey apartment house in Hradec Kralove receives
1077 kWh/m2, while each storey consumes about 150 kWh/m2 for heating and
25-50 kWh/m2 for light and cooking, adding up to 875 - 1000 kWh/m2 for
the 5 storeys together (all measured per. m2 horizontal surface).
While the incoming solar energy is sufficient over the year, the
practical usable resource is limited by the fluctuations of the solar energy
and the storage capacity. Reasonable good estimates of usable solar heat
can be made as a fraction of the different heat demands.
For house-integrated systems, the limitations are normally that solar heating can only cover 60-80% of the hot water demand and 25 - 50% of space heating. The variations are depending on location and systems used. In Northern Europe the limitations are respectively 70% and 30% for hot water and space heating coverage.
For central solar heating systems for district heating, analyses and experience show that these systems can cover 5% of consumption without storage, 10% with 12 hour storage and about 80% with seasonal storage. These figures are based on district heating systems which have 20% average energy losses and mainly deliver to dwellings. The energy delivered from solar heating systems without storage is by far the cheapest solution.
For industries that uses heat below 100oC, solar heating can cover
about 30% if they have a steady consumption of heat. For drying processes
solar energy can cover up to 100% depending on season, temperature, and
limitations to drying period.
Solar heating to swimming pools can cover most of the heat demand
for indoor pools and up to 100% for outdoor pools used during summer.
To evaluate the potential for solar heating is, thus, most a question of assessing the demand for low-temperature heat.
Barriers
Most applications for solar heating are well developed, and the
technical barrier is more lack of local availability of a certain technology
than lack of the technology as such. Thus the main barriers, beside economy,
are:
lack of information of
available technologies and their optimal design and integration in heating
systems.
lack of local skills for
production and installation.
In some occasions lack of access to solar energy can be a barrier.
For active solar heating it is almost always possible to find a place for
the solar collectors with enough sunshine. For passive solar energy, where
the solar energy is typically coming through normal windows, neighbouring
buildings or high trees can give a severe reduction of the solar energy
gain.
Effect on economy, environment
and employment
Economy
The economy of using solar energy ranges from almost no costs, when
simple passive solar energy designs are integrated into building design
and land-use planning to very high costs for solar heating systems with
seasonal storage. For solar heating systems, some typical prices are for
installed systems:
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Environment
The heat produced in a solar heater replaces energy produced in
more polluting ways, which is the main environmental effect. The energy
produced to produce a solar heater is equivalent to 1-4 years of production
of the solar heater.
Usually the solar collectors are mounted on top of a roof, in which
case there is no local impact of the environment.
Effects of employment
The majority of the employment is in the production and installation
of solar heaters. Based on Danish experience, the employment is estimated
to 17 man-years to produce and install 1,000 m2 of solar heaters for families.
These 1,000 m2 replaces 800 MWh of primary energy (net energy production
400 MWh). With 30 years lifetime of the solar heaters, the constant employment
of producing solar heaters to replace 1 TWh will be 700 persons.
Country Estimates
In principle all heat demand can be covered by solar energy with
seasonal storage. There is therefore no absolute limit to this resource,
only economical limitations. In Denmark it is estimated that without seasonal
storage, solar energy can cover 13% of the heat demand, including commercial
and industrial use. In more sunny places, this fraction is naturally larger.
Photovoltaics Electricity
Photovoltaic (PV) cells produce direct current electricity with
output varying directly with the level of solar radiation. PV cells are
integrated in modules which are the basic elements of PV systems. PV modules
can be designed to operate at almost any voltage, up to several hundred
Volt, by connecting cells and modules in series. For applications requiring
alternating current, inverters must be used.
PV cell efficiency is calculated as the percentage difference between
the irradiated power (Watt) per area unit (m2), and the power supplied
as electric energy from the photovoltaic cell. There is a distinction between
theoretical efficiency, laboratory efficiency, and practical efficiency.
It is important to know the difference between these terms, and it is of
course only the practical efficiency which is of interest to users of photovoltaics.
Practical efficiency of mass produced PV cells:
single crystalline silicon : 16 - 17%
polycrystalline silicon : 14 - 15%
amorphous silicon : 8 - 9%
PV systems are usually divided in:
1. Stand-alone systems that rely on PV power
only. Beside the PV modules they include charge controllers and batteries.
2. Hybrid systems that consists of a combination
of PV cells and a complementary means of electricity generation such as
wind, diesel or gas. Often smaller batteries and chargers/controllers are
also used in these systems.
3. Grid connected systems, which work as small
power stations feeding power into the grid.
Tips and Applications
When designing a photovoltaic installation a number of things must
be taken into consideration, if an optimum solution is wanted. At first
it must be clarified, how much energy is demanded from the photovoltaic
installation. After that the total daily consumption in Ampere hours (Ah)
must be estimated. From the total daily and weekly consumption the total
energy storage capacity can be calculated. It must be considered how many
days without sun, the installation shall be capable of functioning. At
the end it can be calculated, how many photovoltaic modules are required
to produce sufficient energy. The photovoltaic application can also be
combined with other energy sources. A combination of small wind generators
and photovoltaics is an obvious possibility. The energy can be stored in
good lead batteries (solar batteries, traction-batteries) or in nickel/cadmium
batteries.
Resource estimation
The solar energy which is available during the day varies because
of the relative motion of the sun, and depends strongly on the local sky
conditions. At noon in clear sky conditions, the solar irradiation can
reach 1000 W/m2 while, in very cloudy weather, it may fall to less than
100 W/m2 even at midday. The availability of solar energy varies both with
tilt angle and the orientation of surface, decreasing as the surface is
moved away from South.
Commercial cells are sold with rated output power (Watt peak power, Wp). This corresponds to their maximum output in standard test conditions, when the solar irradiation is near to its maximum at 1000 W/m2, and the cell temperature is 25oC. In practice, PV modules seldom work at these conditions. Rough estimate of the output (P) from PV systems can be made according to the equation:
Daily mean solar irradiation (I) in Europe in kWh/m2 per day (sloping south, tilt angle from horizon 30 deg.):
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Typical System Performance
Stand alone systems have low yields because they operate with an
almost constant load throughout the year and their PV modules must be sized
to provide enough energy in winter even though they will be oversized during
summer.
Typical professional systems in Europe have annual average yields
of 200 - 550 kWp.
Hybrid systems have higher performance ratio, because they can be
sized to meet the required load in the summer and can be backed up by other
systems like wind or diesel in the winter and in bad weather.
Typical annual average yield is 500 - 1250 kWh/kWp depending on
the losses caused by the charge controller and the battery.
Grid connected systems have the highest Performance Ratio because
all of the energy which they produce can either be used locally or exported
to the grid.
Typical annual yield is 800 - 1400 kWh/kWp.
Barriers
Despite a sharp decline in costs, PV cells currently cost 5 US$/Wp
(4 ECU/Wp). Electricity generation costs is currently 0.5 - 1 ECU/kWh,
which is higher than from other renewable energy sources. In the future,
the costs of PV are expected to fall with increasing utilization. Despite
its high costs, PV electricity can be cheaper than other sources in remote
areas without electric grid and where production of electricity by other
means like diesel is difficult or environmentally unacceptable (mountain
areas).
Effects on economy, environment
and employment
When the only cost-effective applications of PV systems in Europe
are remote areas without electric grid, it will have a positive economical
effect only for those areas.
There are no environmental effects of using PV systems. Environmental problems can occur in the production of the cells, and in the production and (improper) disposal of the batteries.
The use of PV is not expected to have any measurable employment effect
in Europe for the time being.
Hand Rule
In a typical photovoltaic system based on crystalline Silicon
with 12% efficiency each kWp of installed power capacity can produce 1150
kWh of electricity per year for grid connected systems and 300 kWh/year
for stand alone systems in Central Europe.
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