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SOLAR POWER CONCENTRATION
CHAPTER . 1
INTRODUCTIONThe limited supply of fossil hydrocarbon resources and the negative impact of
CO2emissions on the global environment dictate the increasing usage of renewable energy
sources. Concentrated solar power (CSP) is the most likely candidate for providing the
majority of this renewable energy, because it is amongst the most cost-effective renewable
electricity technologies and because its supply is not restricted if the energy generated is
transported from the world's solar belt to the population centres.
Three main technologies have been identified for generating electricity in the 10 kW to
several 1000 MW range:
dish/engine technology, which can directly generate electricity in isolated locations
parabolic and Fresnel trough technology, which produces high pressure superheated
steam
solar tower technology, which produces air above 1000C or synthesis gas for gas
turbine operation. While these technologies have reached a certain maturity, as has been
demonstrated in pilot projects in Israel, Spain and the USA, significant improvements in
the thermo-hydraulic performance are still required if such installations are to achieve the
reliability and effectiveness of conventional power plants. This first article focuses on
present CSP technologies, their history and the state of the art. The second article, in the
next issue ofIngenia, looks at the technical, environmental, social and economic issues
relating to CSP in the future.
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History
Concentrated sunlight has been usedto perform useful tasks from the time ofancient
China. A legend has it thatArchimedesused a "burning glass" to concentrate
sunlight on the invading Roman fleet and repel them fromSyracuse (Sicily). In 1973
a Greek scientist, Dr. Ioannis Sakkas, curious about whether Archimedes could really
have destroyed the Roman fleet in 212 BC, lined up nearly 60 Greek sailors, each
holding an oblong mirror tipped to catch the sun's rays and direct them at a tar-
covered plywood silhouette 160 feet away. The ship caught fire after a few minutes;
however, historians continue to doubt the Archimedes story.[2]
In 1866, Auguste Mouchout used a parabolic trough to produce steam for the first solar
steam engine. The first patent for a solar collector was obtained by the Italian Alessandro
Battaglia in Genoa, Italy, in 1886. Over the following years, inventors such as John
Ericsson and Frank Shuman developed concentrating solar-powered devices for irrigation,
refrigeration, and locomotion. In 1913 Shuman finished a 55 HP parabolic solar thermal
energy station in Meadi, Egypt for irrigation.[3][4][5][6] The first solar-power system using a
mirror dish was built by Dr. R.H. Goddard, who was already well known for his research
on liquid-fueled rockets and wrote an article in 1929 in which he asserted that all the
previous obstacles had been addressed.[7]
Professor Giovanni Francia (19111980) designed and built the first concentrated-solar
plant. which entered into operation in Sant'Ilario, near Genoa, Italy in 1968. This plant had
the architecture of today's concentrated-solar plants with a solar receiver in the center of a
field of solar collectors. The plant was able to produce 1 MW with superheated steam at
100 bar and 500 degrees Celsius.[8] The 10 MW Solar One power tower was developed in
Southern California in 1981, but the parabolic-trough technology of the nearby Solar
Energy Generating Systems (SEGS), begun in 1984, was more workable. The 354 MW
SEGS is still the largest solar power plant in the world.
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CHAPTER . 2
Current technology
CSP is used to produce electricity (sometimes called solar thermoelectricity, usually
generated throughsteam). Concentrated-solar technology systems
use mirrorsorlenseswithtrackingsystems to focus a large area of sunlight onto a
small area. The concentrated light is then used as heat or as a heat source for a
conventional power plant(solar thermoelectricity). The solar concentrators used in
CSP systems can often also be used to provide industrial process heating or cooling,
such as in solar air-conditioning.Concentrating technologies exist in four common
forms, namelyparabolic trough,dish Stirlings, concentrating linear Fresnel
reflector, andsolar power tower.[9]Although simple, these solar concentrators are
quite far from the theoretical maximum concentration.[10][11]For example, the
parabolic-trough concentration gives about 1/3 of the theoretical maximum for the
design acceptance angle, that is, for the same overall tolerances for the system.
Approaching the theoretical maximum may be achieved by using more elaborate
concentrators based onnonimaging optics.Different types of concentrators produce
different peak temperatures and correspondingly varying thermodynamic
efficiencies, due to differences in the way that they track the sun and focus light.
New innovations in CSP technology are leading systems to become more and more
cost-effective.
2.1 Parabolic trough
A parabolic trough consists of a linear parabolic reflector that concentrates light onto a
receiver positioned along the reflector's focal line. The receiver is a tube positioned directly
above the middle of the parabolic mirror and filled with a working fluid. The reflector
follows the sun during the daylight hours by tracking along a single axis. A working fluid
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is heated to 150350 C (423623 K (302662 F)) as it flows through the receiver and is
then used as a heat source for a power generation
system.
[14]
Trough systems are the most developed CSP technology. The Solar EnergyGenerating Systems (SEGS) plants in California, Acciona's Nevada Solar
One nearBoulder City, Nevada, and Plataforma Solar de Almera's SSPS-DCS plant
in Spain are representative of this technology.[15]
2. 2 Fresnel reflectors
Liddell Power Station's Compact Linear Fresnel reflectors are not as efficient as parabolic
mirrors but are much cheaper.Fresnel reflectors are made of many thin, flat mirror strips to concentrate sunlight onto
tubes through which working fluid is pumped. Flat mirrors allow more reflective
surface in the same amount of space as a parabolic reflector, thus capturing more of
the available sunlight, and they are much cheaper than parabolic reflectors. Fresnel
reflectors can be used in various size CSPs
2. 3 Dish Stirling
A dish Stirling or dish engine system consists of a stand-aloneparabolic reflectorthat
concentrates light onto a receiver positioned at the reflector's focal point. The reflector
tracks the Sun along two axes. The working fluid in the receiver is heated to 250700 C
(523973 K (4821292 F)) and then used by a Stirling engine to generate power.
[14] Parabolic-dish systems provide the highest solar-to-electric efficiency among CSP
technologies, and their modular nature provides scalability. The Stirling Energy
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Systems (SES) and Science Applications International Corporation (SAIC) dishes
at UNLV, and Australian National University's Big Dish in Canberra, Australia are
representative of this technology.
2.4 Solar power tower
A solar power tower consists of an array of dual-axis tracking reflectors (heliostats) that
concentrate light on a central receiver atop a tower; the receiver contains a fluid deposit,
which can consist of sea water. The working fluid in the receiver is heated to 5001000 C
(7731273 K (9321832 F)) and then used as a heat source for a power generation or
energy storage system.[14] Power-tower development is less advanced than trough systems,
but they offer higher efficiency and better energy storage capability. The Solar
Two in Daggett, California and the Planta Solar 10 (PS10) in Sanlucar la Mayor, Spain are
representative of this technology. eSolar's 5 MW Sierra SunTower, located in Lancaster,
California, is the only CSP tower facility operating in North America.
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CHAPTER . 3
Technical principles
In general, solar thermal technologies are based on the concept of concentrating solar
radiation to produce steam or hot air, which can then be used for electricity generation
using conventional power cycles. Collecting the solar energy, which has relatively low
density, is one of the main engineering tasks in solar thermal power plant development. For
concentration, most systems use glass mirrors because of their very high reflectivity.
Other materials are under development to meet the needs of solar thermal power systems.
Point focusing and line focusing systems are used, as depicted in Figure 1. These systems
can use only direct radiation, and not the diffuse part of sunlight because this cannot be
concentrated. Line focusing systems are easier to handle, but have a lower concentration
factor and hence achieve lower temperatures than point focusing systems.
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Figure 1 Technologies for concentrating solar radiation: left side parabolic and
linear Fresnel troughs, right side central solar tower receiver and parabolic dish
Table 1 gives an overview of some of the technical parameters of the different
concentrating solar power concepts. Parabolic troughs, linear Fresnel systems and power
towers can be coupled to steam cycles of 10 to 200 MW of electric capacity, with thermal
cycle efficiencies of 3040%. The values for parabolic troughs, by far the most mature
technology, have been demonstrated in the field. Today, these systems achieve annual
solar-toelectricity efficiencies of about 1015%, with the aim that they should reach
about 18% in the medium term. Thenvalues for other systems are, in general,nprojections
based on component and n prototype system test data, and the assumption of mature
development of current technology. Overall solar-electric efficiencies are lower than the
conversion efficiencies of conventional steam or combined cycles, as they include the
conversion of solar radiative energy to heat within the collector and the conversion of the
heat to electricity in the power block. The conversion efficiency of the power block
remains essentially the same as in fuel fired power plants. Because of their thermal nature,
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each of these technologies can be hybridised, or operated with fossil fuel as well as solar
energy.
Hybridisation has the potential to improve dramatically the value of CSP technology by
increasing its power availability and dispatchability, decreasing its cost (by making more
effective use of the power block equipment), and reducing the technological risk by
allowing conventional fuel use if, for example, the collector has to be repaired. Solar heat
collected during the daytime can be stored in concrete, molten salt, ceramics or phase-
change media. At night, it can be extracted from storage to run the power block. Fossil and
renewable fuels such as oil, gas, coal and biomass can be used for co-firing the plant, thus
providing power capacity whenever required.
Moreover, solar energy can be used for co-generation of electricity and heat.
In this case, the high value solar energy input is used with the best possible efficiencies of
up to 85%. Possible applications include the combined production of electricity, industrial
process heat, district cooling and sea water desalination. It is generally assumed that solar
concentrating systems are economic only for locations with direct incidence radiation
above 1800 kWh m2 year1. Typical examples are Barstow, USA, with 25002700 kWh
m2 year1 and Almeria, Spain, with 18502000 kWh m2 year1. Today, all installations
would have capacity factors of 25%, equivalent to about 2000 full load operating hours peryear, with the aim of using solar operation for base load with thermal
energy storage and larger collector fields. To generate 1 MWh of solar electricity per year
with CSP, a land area of only 412 m2 is required. This means, that 1 km2 of arid land can
continuously and indefinitely generate as much electricity as any conventional 50 MW
coal- or gas-fired power station.
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CHAPTER . 4
Line focusing systems
As schematically shown in Figure 1, line focusing systems use a trough-like mirror and a
specially coated steel absorber tube to convert sunlight into useful heat. The troughs are
usually designed to track the Sun along one axis, predominantly northsouth. The
first parabolic trough systems were installed in 1912 near Cairo (Egypt), to generate steam
for a 73 kW pump that delivered 2000 m3/h of water for irrigation (see Figure 3). At the
time, this plant was competitive with coal-fired installations in regions, where the cost of
coal exceeded 10 German Marks per tonne (Stinnesbeck, 191411). To generate electricity,
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the fluid flowing through the absorber tube usually synthetic oil or water/steam
transfers the heat to a conventional
Figure 2 Schematic diagram of a steam cycle power plant with a parabolic trough
collector and a thermal energy storage
steam turbine power cycle (Figure 2). With the sunlight concentrated by about 70100
times, the operating temperatures achieved are in the range of 350 to 550C.
With 354 MW of parabolic trough power plants (about 2 million m2 of mirror area)
connected to the grid in southern California, parabolic troughs represent the most mature
CSP technology. In the solar electricity generating systems (SEGS) plants developed since
the 1980s in California, a synthetic thermal oil is used for\ operating temperatures up to
400C. In a steam generator, this heat-transfer oil is used to produce slightly superheated
steam at 510 MPa pressure, which then feeds a steam turbine connected to
a generator to produce electricity. No new plants have been built since 1991, because
declining fossil-fuel prices in the United States resulted in unattractive
economic predictions for future plants. However, the performance of these power plants
has been continuously improved. For example, the Kramer Junction site (see Figure 4) has
achieved
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Figure 3 First parabolic trough plant in Egypt
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Figure 4 Parabolic trough concentrating solar collector field of the 150 MW (5
30 MW) steam cycle solar electricity generating systems at Kramer
Junction, California
a 30% reduction in operation and maintenance costs during the last five years. In addition,
trough component manufacturing companies have made significant advances in improving
absorber tubes, process know-how and system integration. It is estimated that
new plants, using current technology with these proven enhancements, will produce
electrical power today for about 10 to 12 US cents/kWh in solar only operation mode.
Performance data for the nine SEGS plants are given . Despite the promising technology,
the initiator of these plants, LUZ International Ltd, did not succeed. There were several
reasons for LUZs failure:
Energy prices did not increase as projected in the mid 1980s.
The value of the environmental benefits was not recompensed.
A changing undefined tax status did not allow for the necessary profit to be realised.
However, three operating companies took over the plants and are delivering 800900
million kWh of electricity to the Californian grid every year, reaching today a total
accumulated solar electricity production of almost 9 billion kWh (12 billion kWh including
natural gas operation), which is roughly half of the solar electricity generated
world wide to date. The plants had a total turnover of over US$1.5 billion. While the plants
in California use a synthetic oil as a heat transfer fluid within the collectors, and a separate
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heat exchanger for steam generation, efforts to achieve direct steam generation within the
absorber tubes are underway in the DISS and INDITEP projects sponsored
by the European Commission, with the aim of reducing costs and enhancing
efficiency by 1520% each. Direct solar steam generation has recently been demonstrated
by CIEMAT and DLR on the Plataforma Solar in Almeria, Spain, in a 500 m long test loop
with an aperture of 5.78 m (Figure 5, top), providing superheated steam at 400C and 10
MPa. Two-phase, steam-water flow
Direct steam generating parabolic trough of the DISS project at Plataforma Solarde Almeria, Spain
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Enhanced parabolic trough structure of the EUROTOUGH project facility at Plataforma
Solar de Almeria, Spain
Linear Fresnel collector at the Solarmundo test facility in Liege, Belgium
Figure 5 Highlights of line concentrating systems development in Europe
(Source: DLR, Flagsol, Solarmundo)
in a large number of long, parallel and horizontal absorber tubes is a major technical
challenge. Constant turbine inlet conditions must be maintained and flow instabilities must
be avoided, even in times of spatially and temporally changing insolation. Control
strategies have been developed based on extensive experimentation and modelling
of two-phase flow phenomena (Eck, 20014; Steinmann, 200210) A European industrial
consortium has developed the EURO-TROUGH collector, which aims to achieve better
performance and cost by enhancing the mechanical structure, and the optical and thermalproperties of the parabolic troughs (Figure 5, middle). A prototype was successfully tested
in summer 2003 under real operating conditions at the Californian solar thermal power
plants within the PARASOL project funded by the German Federal Ministry for the
Environment. Another European consortium has developed a collector with segmented flat
mirrors following the principle of Fresnel (Figure 5). The linear Fresnel
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system also shows a good potential for low cost steam generation, and provides a semi-
shaded space below, which may be particularly useful in desert climates. Acting like a
large, segmented blind, it could shade crops, pasture and water sheds to protect them from
excessive evaporation and provide shelter from the cold desert sky at night. However, the
performance of the linear Fresnel system has so far only been tested in a 50 m installation
in Belgium; further modeling and experimental work will be required to determine under
what conditions it may be more cost-effective than the parabolic trough system with direct
steam generation.
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energy is absorbed by a working fluid and then used to generate steam to power a
conventional turbine. In over 15 years of experiments worldwide, power tower plants have
proven to be technically feasible in projects using different heat transfer media (steam, air
and molten salts) in the thermal cycle and with different heliostat designs. At Barstow,
California (see Figure 7), a 10 MW pilot plant operating with steam from 1982 to 1988,
and subsequently with molten salt as the heat transfer and energy storage medium, has now
several thousand hours of operating experience delivering power to the
electricity grid on a regular basis. Early approaches with central receivers used bundles of
steel tubes on top of the tower to absorb the concentrated solar heat coming from the
heliostat field. The Californian 10 MW test plant Solar II used molten salt as heat transfer
fluid and as the thermal storage medium for night time operation. In Europe, air was
preferred as the heat transfer medium, but the 20 MW air cooled central receiver project
GAST in the early 1980s showed that tube receivers where not appropriate for that
purpose, because of an inadequate heat transfer and local overheating of the tubes.
Thus, the concept of the volumetric receiver was developed in the 1990s within the
PHOEBUS project, using a wire mesh directly exposed to the incident
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Figure 8 Volumetric receiver (Source: DLR)
radiation and cooled by air flowing through that mesh (Figure 8). This receiver easily
achieved 800C and was used to operate a 1 MW steam cycle. A ceramic thermal heat
storage was used for night time operation. This concept has been validated at 2.5 MW
(thermal) level in tests conducted at the Plataforma Solar in Almera. In this installation,
the solar energy is harvested by 350 heliostats of 40 m2 area each. For even higher
temperatures, the wire mesh screens are replaced by porous SiC or Al2O3 structures.
The high temperatures available in solar towers can be used not only to drive steam cycles,
but also for gas turbines and combined cycle systems. Since such systems promise up to
35% peak and 25% annual solar-electric efficiency when coupled with a combined cyclepower plant, a solar receiver was developed within the
Figure 9 REFOS pressurized receiver concept (Source: DLR)
European SOLGATE project for heating pressurised air by placing the volumetric absorber
into a pressure vessel with a parabolic quartz window for solar radiation incidence. This
design is shown in Figure 9.
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Figure 10 Schematic of a combined cycle system powered by a volumetric
central receiver using pressurised air as heat transfer fluid (Source: DLR)
Since December 2002, this absorber has been successfully used to operate a 250 kW gas
turbine at over 800C. Combined cycle power plants using this method will requirem 30%
less collector area than plants using equivalent steam cycles (Figure 10). Ceramic
volumetric absorbers with an operating temperature of over 1200C are under development
for this purpose.
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CHAPTER . 6
FUTURE OF CSP
A study done by Greenpeace International, the European Solar Thermal Electricity
Association, and the International Energy Agency's SolarPACES group investigated the
potential and future of concentrated solar power. The study found that concentrated solar
power could account for up to 25% of the world's energy needs by 2050. The increase in
investment would be from 2 billion euros worldwide to 92.5 billion euros in that time
period.Spain is the leader in concentrated solar power technology, with more than 50government-approved projects in the works. Also, it exports its technology, further
increasing the technology's stake in energy worldwide. Because the technology works best
with areas of high insolation (solar radiation), experts predict the biggest growth in places
like Africa, Mexico, and the southwest United States. The study examined three different
outcomes for this technology: no increases in CSP technology, investment continuing as it
has been in Spain and the US, and finally the true potential of CSP without any barriers on
its growth. The findings of the third part are shown in the table below:
TimeAnnual
Investment
Cumulative
Capacity
2015 21 billion euros a year 420 megawatts
2050 174 billion euros a year 1500 gigawatts
Finally, the study acknowledged how technology for CSP was improving and how this
would result in a drastic price decrease by 2050. It predicted a drop from the current range
of 0.230.15/kwh to 0.140.10/kwh. Recently the EU has begun to look into developing
a 400 billion ($774 billion) network of solar power plants based in the Sahara region
using CSP technology known as Desertec, to create "a new carbon-free network linking
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Europe, the Middle East and North Africa". The plan is backed mainly by German
industrialists and predicts production of 15% of Europe's power by 2050. Morocco is a
major partner in Desertec and as it has barely 1% of the electricity consumption of the EU,
it will produce more than enough energy for the entire country with a large energy surplus
to deliver to Europe.
Algeria has the biggest area of desert, and private Algerian firm Cevital has signed up
forDesertec.[24] With its wide desert (the highest CSP potential in the Mediterranean and
Middle East regions ~ about 170 TWh/year) and its strategic geographical location near
Europe Algeria is one of the key countries to ensure the success of Desertec project.
Moreover, with the abundant natural-gas reserve in the Algerian desert, this will strengthen
the technical potential of Algeria in acquiring Solar-Gas Hybrid Power Plants for 24-hour
electricity generation.
Other organizations expect CSP to cost $0.06(US)/kWh by 2015 due to efficiency
improvements and mass production of equipment.That would make CSP as cheap as
conventional power. Investors such as venture capitalistVinod Khosla expect CSP to
continuously reduce costs and actually be cheaper than coal power after 2015.
On September 9, 2009; 2 years ago, Bill Weihl, Google.org's green-energy spokesperson
said that the firm was conducting research on the heliostat mirrors and gas turbine
technology, which he expects will drop the cost of solar thermal electric power to less than
$0.05/kWh in 2 or 3 years.
In 2009, scientists at theNational Renewable Energy Laboratory (NREL)
and SkyFuel teamed to develop large curved sheets of metal that have the potential to be
30% less expensive than today's best collectors of concentrated solar power by replacing
glass-based models with a silverpolymer sheet that has the same performance as the heavy
glass mirrors, but at much lower cost and weight. It also is much easier to deploy and
install. The glossy film uses several layers of polymers, with an inner layer of pure silver.
Telescope designer Roger Angel (Univ. of Arizona) has turned his attention to CPV, and is
a partner in a company called Rehnu. Angel utilizes a spherical concentrating lens with
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http://en.wikipedia.org/wiki/Moroccohttp://en.wikipedia.org/wiki/Algeriahttp://en.wikipedia.org/wiki/Cevitalhttp://en.wikipedia.org/wiki/Desertechttp://en.wikipedia.org/wiki/Concentrated_solar_power#cite_note-reuters.com-23http://en.wikipedia.org/wiki/Algeriahttp://en.wikipedia.org/wiki/Hassi_R'Mel_integrated_solar_combined_cycle_power_stationhttp://en.wikipedia.org/wiki/Venture_capitalisthttp://en.wikipedia.org/wiki/Vinod_Khoslahttp://en.wikipedia.org/wiki/Google.orghttp://en.wikipedia.org/wiki/National_Renewable_Energy_Laboratoryhttp://en.wikipedia.org/wiki/SkyFuelhttp://en.wikipedia.org/wiki/Silverhttp://en.wikipedia.org/wiki/Concentrated_photovoltaicshttp://en.wikipedia.org/wiki/Moroccohttp://en.wikipedia.org/wiki/Algeriahttp://en.wikipedia.org/wiki/Cevitalhttp://en.wikipedia.org/wiki/Desertechttp://en.wikipedia.org/wiki/Concentrated_solar_power#cite_note-reuters.com-23http://en.wikipedia.org/wiki/Algeriahttp://en.wikipedia.org/wiki/Hassi_R'Mel_integrated_solar_combined_cycle_power_stationhttp://en.wikipedia.org/wiki/Venture_capitalisthttp://en.wikipedia.org/wiki/Vinod_Khoslahttp://en.wikipedia.org/wiki/Google.orghttp://en.wikipedia.org/wiki/National_Renewable_Energy_Laboratoryhttp://en.wikipedia.org/wiki/SkyFuelhttp://en.wikipedia.org/wiki/Silverhttp://en.wikipedia.org/wiki/Concentrated_photovoltaics -
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large-telescope technologies, but much cheaper materials and mechanisms, to create
efficient systems.
CHAPTER . 7
CONCLUSION
Concentrating solar power technology for electricity generation is ready for the market.
Various types of single- and dual-purpose plants have been analysed and tested in the field.
In addition, experience has been gained from the first commercial installations in
use worldwide since the beginning of the 1980s. Solar thermal power plants will, within the
next decade, provide a significant contribution to an efficient, economical andenvironmentally benign energy supply both in large-scale gridconnected dispatchable
markets and remote or modular distributed markets. Parabolic and Fresnel troughs, central
receivers and parabolic dishes will be installed for solar/fossil hybrid and
solar-only power plant operation. In parallel, decentralised process heat for industrial
applications will be provided by low-cost concentrated collectors. Following a subsidised
introduction phase in green markets, electricity costs will decrease from 14 to 18 Euro
cents per kilowatt hour presently in Southern Europe towards 5 to 6 Euro cents per kilowatt
hour in the near future at good sites in the countries of the Earths sunbelt. After that, there
will be no further additional cost in the emission reduction by CSP. This, and
the vast potential for bulk electricity generation, moves the goal of longterm stabilisation of
the global climate into a realistic range. Moreover, the problem of sustainable water
resources and development in arid regions is addressed in an excellent way, making use of
highly efficient, solar powered co-generation systems. However, during the introduction
phase, strong political and financial support from the responsible authorities is still
required, and many barriers must be overcome. These topics will be addressed in the
second article.
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