Photovoltaic Solar EnergyDone by :Reshop Nanda.P
Energy from the Sun
About half the incoming solar energy reaches the Earth's surface.
The Earth receives 174 petawatts (PW) (1015 watts) of incoming solar radiation at the upper atmosphere. Approximately 30% is reflected back to space while the rest is absorbed by clouds, oceans and land masses.
Earth's land surface, oceans and atmosphere absorb solar radiation, and this raises their temperature. Sunlight absorbed by the oceans and land masses keeps the surface at an average temperature of 14 °C.
By photosynthesis green plants convert solar energy into chemical energy, which produces food, wood and the biomass from which fossil fuels are derived.
Breakdown of incoming solar energy
Energy from the Sun The total solar energy absorbed by Earth's atmosphere, oceans
and land masses is approximately 3,850,000 exajoules (EJ) (1018 joules) per year. (70% of incoming sunlight) (1 Joule = energy required to heat one gram of dry, cool air by 1˚ C)
Primary energy use (2005) 487 EJ (0.0126%)
Electricity (2005) 56.7 EJ (0.0015%) Therefore a good target
2002, more energy in one hour than the world used in the year.
Photosynthesis captures approximately 3,000 EJ per year in biomass.
The amount of solar energy reaching the surface of the planet is so vast that in one year it is about twice as much as will ever be obtained from all of the Earth's non-renewable resources of coal, oil, natural gas, and mined uranium combined.
As intermittent resources, solar and wind raise issues.
Solar Cells Background 1839 - French physicist A. E. Becquerel first recognized the
photovoltaic effect.
Photo + voltaic = convert light to electricity
1883 - first solar cell built, by Charles Fritts, coated semiconductor selenium with an extremely thin layer of gold to form the junctions.
1954 - Bell Laboratories, experimenting with semiconductors, accidentally found that silicon doped with certain impurities was very sensitive to light. Daryl Chapin, Calvin Fuller and Gerald Pearson, invented the first practical device for converting sunlight into useful electrical power. Resulted in the production of the first practical solar cells with a sunlight energy conversion efficiency of around 6%.
1958 - First spacecraft to use solar panels was US satellite Vanguard 1
PV Solar for ElectricityPhotovoltaic
For the 2 billion people without access to electricity, it would be cheaper to install solar panels than to extend the electrical grid.
Providing power for villages in developing countries is a fast-growing market for photovoltaic's. The United Nations estimates that more than 2 million villages worldwide are without electric power for water supply, refrigeration, lighting, and other basic needs, and the cost of extending the utility grids is prohibitive, $23,000 to $46,000 per kilometer in 1988.
A one kilowatt PV system* each month: › prevents 150 lbs. of coal from being mined › prevents 300 lbs. of CO2 from entering the atmosphere › keeps 105 gallons of water from being consumed › keeps NO and SO2 from being released into the environment
* in Colorado, or an equivalent system that produces 150 kWh per month
How Solar Cells Work
1. Photons in sunlight hit the solar panel and are absorbed by semiconducting materials, such as silicon.
2. Electrons (negatively charged) are knocked loose from their atoms, allowing them to flow through the material to produce electricity.
3. An array of solar cells converts solar energy into a usable amount of direct current (DC) electricity.
Solar Cells Background
Three generations of solar cells
Solar Cells are classified into three generations which indicates the order of which each became important.
At present there is concurrent research into all three generations while the first generation technologies are most highly represented in commercial production, accounting for 89.6% of 2007 production.
Solar Cells Background
First Generation – Single Junction Silicon Cells
89.6% of 2007 Production
45.2% Single Crystal Si
42.2% Multi-crystal SI
Large-area, high quality and single junction devices.
High energy and labor inputs which limit significant progress in reducing production costs.
Silicon Cell Average Efficiency
Solar Cells Background
Single junction silicon devices are approaching theoretical limit efficiency of 33%.
Achieve cost parity with fossil fuel energy generation after a payback period of 5–7 years. (3.5 yr in Europe)
Single crystal silicon - 16-19% efficiency
Multi-crystal silicon - 14-15% efficiency
Solar Cells Background
Second Generation – Thin Film Cells
CdTe 4.7% & CIGS 0.5% of 2007 Production
New materials and processes to improve efficiency and reduce cost.
As manufacturing techniques evolve, production costs will be dominated by constituent material requirements, whether this be a silicon substrate, or glass cover.
Thin film cells use about 1% of the expensive semiconductors compared to First Generation cells.
The most successful second generation materials have been cadmium telluride (CdTe), copper indium gallium selenide (CIGS), amorphous silicon and micromorphous silicon.
Solar Cells Background
Trend toward second gen., but commercialization has proven difficult.
› 2007 - First Solar produced 200 MW of CdTe solar cells, 5th largest producer in 2007 and the first to reach top 10 from of second generation technologies alone.
› 2007 - Wurth Solar commercialized its CIGS technology producing 15 MW.
› 2007 - Nanosolar commercialized its CIGS technology in 2007 with a production . capacity of 430 MW for 2008 in the USA and Germany.
› 2008 - Honda began to commercialize their CIGS base solar panel.
CdTe – 8 – 11% efficiency (18% demonstrated)
CIGS – 7-11% efficiency (20% demonstrated)
Payback time < 1 year in Europe
Solar Cells Background
Third Generation – Multi-junction Cells Third generation technologies aim to enhance poor electrical
performance of second generation (thin-film technologies) while maintaining very low production costs.
Current research is targeting conversion efficiencies of 30-60% while retaining low cost materials and manufacturing techniques.
They can exceed the theoretical solar conversion efficiency limit for a single energy threshold material, 31% under 1 sun illumination and 40.8% under the maximal artificial concentration of sunlight (46,200 suns).
Solar Cells Background
Approaches to achieving these high efficiencies including the use of multijunction photovoltaic cells, concentration of the incident spectrum, the use of thermal generation by UV light to enhance voltage or carrier collection, or the use of the infrared spectrum for night-time operation.
Typically use fresnel lens (3M) or other concentrators, but cannot use diffuse sunlight and require sun tracking hardware
Multi-junction cells – 30% efficiency (40-43% demonstrated
Global Cumulative PV Power
Global Annual PV Market
Solar Cells 2010 Market Share Estimate
0%
10%
20%
30%
40%
50%
Type
Mark
et
Sh
are
Solar Cell Market Estimate
-- First Generation -- -- Second Generation -- - Third Gen -
Global Annual PV Market Outlook
Solar PV Market Outlook
Annual PV Market Outlook
$-
$100
$200
$300
$400
$500
$600
$700
2007 2010 2015 2020 2025 2030
Sal
es i
n B
illi
on
s
Rest of World
South Asia
China
Central + SouthAmericaNorth America
Europe
by 2030 8.9% of Global Energy, 1,864 GW Production Capacity, 2,646 TWh Electricity
Cost Projections
$1.35
$1.07
$0.81
$0.54
$0.27
$0.13 ---
$/kWh“Grid parity’ where PV cost are equal to residential electricity costs is expected to be achieved first in southern European countries and then to move north
World's largest photovoltaic (PV) power plants (12 MW or larger)
Name of PV power plant Country
DCPeak
Power(MW)
GW·h/
year
Notes
Olmedilla Photovoltaic Park Spain 60 85 Completed September 2008
Puertollano Photovoltaic Park Spain 50 2008
Moura photovoltaic power station
Portugal 46 93 Completed December 2008
Waldpolenz Solar Park Germany 40 40 550,000 First Solar thin-film CdTe modules. Completed Dec 2008
Arnedo Solar Plant Spain 34 Completed October 2008
Merida/Don Alvaro Solar Park Spain 30 Completed September 2008
Koethen Germany 14.75 13 200,000 First Solar thin-film CdTe modules. Completed Dec 2008
Nellis Solar Power Plant USA 14.02 30 70,000 solar panels
Planta Solar de Salamanca6 more Spain, 1 US, 1 Germany
Spain 13.8Avg 12
n.a. 70,000 Kyocera panels
Large systems in planning or under construction
Name of Plant Country DCPeak
Power(MW)
GW·h/
year
Notes
Rancho Cielo Solar Farm USA 600 Thin film silicon from Signet Solar**
Topaz Solar Farm USA 550 1,100
Thin film silicon from OptiSolar **
High Plains Ranch USA 250 550 Monocrystaline silicon from SunPower with tracking **
Mildura Solar concentrator power station
Australia 154 270 Heliostat concentrator using GaAs cells from Spectrolab**
KCRD Solar Farm USA 80 Scheduled to be completed in 2012 **
DeSoto County, Florida USA 25 To be constructed by SunPower for FPL Energy, completion date 2009.*
Davidson County solar farm USA 21.5 36 individual structures**
Cádiz solar power plant Spain 20.1 36 *
Kennedy Space Center, Florida
USA 10 To be constructed by SunPower for FPL Energy, completion date 2010.**
* Under construction; ** Proposed
Spain
Blessed with almost year-round sunshine, Spain's socialist government is trying to capitalize on this natural resource.
In an effort to encourage private individuals and companies to install solar power, Spain introduced subsidies of €0.42 per kilowatt per hour ($0.57/KWhr) (‘feed-in’ tariff and off-grid subsidies)
But the Spanish government is considering reducing this subsidy in September, a move which is likely to face opposition from within the solar energy industry.
2007: 26,800 employees in Spanish solar companies
Olmedilla Solar Park
60 MWp photovoltaic park installed by Nobesol with modules from Silikin
Germany 10,000 companies, including installers work in solar PV
80 companies are cell and module makers
42,000 employees
Sales were $5.7 B including $2.5 B in exports
The ‘feed-in’ tariff 2008 German utilities pay $0.47 to $0.68/kWh depending
on type and size of system for new solar systems
Utilities pass cost to consumers – Germany average is $1.65/month
Waldpolenz Solar Park The Waldpolenz Solar Park is built on a surface area equivalent
to 200 soccer fields, the solar park will be capable of feeding 40 megawatts into the power grid when fully operational in 2009.
In the start-up phase, the 130-million-euro ($201 million) plant it will have a capacity of 24 megawatts, according to the Juwi group, which operates the installation.
The facility, located east of Leipzig, uses state-of-the-art, thin-film technology. Some 550,000 thin-film modules will be used, of which 350,000 have already been installed.
The direct current produced in the PV solar modules will be converted into alternating current and fed completely into the power grid.
After just a year the solar power station will have produced the energy needed to build it, according to the Juwi group.
Waldpolenz Solar Park
Waldpolenz Solar Park
United States of America (USA) 2007 - PV production grew in all areas of US market
US leads development of thin-film technology accounting for nearly half the global production
2007 – about 50,000 employees
CA dominates with 60% of installed capacity
Various state Renewable Portfolio Standards (RPS) and Federal Investment Tax Credits (ITC) are incentives.
Solar America Initiative making progress on goal to bring PV costs to grid parity by 2015
Renewable Energy Consumption in the US Energy Supply, 2007
Chart DataThe Role of Renewable Energy Consumption in the Nation's
Energy Supply, 2007 (Quadrillion Btu)
Consumption Share
Total US 101.545
Coal 22.776 22%
Natural Gas 23.637 23%
Petroleum 39.773 39%
Nuclear Electric Power 8.415 8%
Renewable Energy: 6.813 7%
Of which:
Hydroelectric 2.446 36%
Geothermal Energy 0.349 5%
Biomass 3.596 53%
Solar Energy 0.081 1%
Wind Energy 0.341 5%
US Solar Industry Data
Size of U.S. Market2008 - U.S. had about 8,800 megawatts (MW) of installed solar capacity. 1,100 MW of photovoltaics (PV),
418 MW of utility-scale concentrating solar power, 485 MWTh (megawatts thermal equivalent) of solar water heating systems
7,000 MWTh of solar pool heating systems.
Ranking of U.S. Market: Cumulative installed solar electric power by 2007. 1st Germany 3.8 GW, 2nd Japan 1.9 GW, 3rd US 814 MW, 4th Spain 632 MW
Growth of U.S. Market 2008 - more than 18,000 individual PV systems were installed. Totaled 342 MW: 292 MW was grid-connected.
Growth of U.S. Manufacturing 2008 domestic PV cell manufacturing capacity grew 65 percent to 685 MW and production grew 53 percent to 414 MW. (Results preliminary) (Source: Greentech Media Research and the Prometheus Institute)
Nellis AFB Solar panels
GM installs world's biggest rooftop solar panels
The largest rooftop solar power station in the world is being built in Spain. With a capacity of 12 MW of power, the station is made up of 85,000 lightweight panels covering an area of two million SqFt.
Manufactured in rolls, rather like carpet, the photovoltaic panels are to be installed on the roof of a General Motors car factory in Zaragoza, Spain.
General Motors, which plans to install solar panels at another 11 plants across Europe, unveiled the €50M ($68M) project yesterday. The power station should be producing energy by September.
The panels will produce an expected annual output of 15.1 million kilowatt hours (kWh) - enough to meet the needs of 4,600 households with an average consumption of 3,300kWh, or power a third of the GM factory. The solar energy produced should cut CO2 emissions by 6,700 tons a year.
Energy Conversion Devices who makes the panels, said it would be the largest rooftop solar array in the world.
GM installs world's biggest rooftop solar panels
Japan
2002 - Basic Act on Energy Policy to secure stable energy supply, environmental suitability and use of market mechanisms
By 2006, installed 1.2 GW for 350,000 homes
2008 – New research initiative to improve yields from 10-15% to 40% and reduce cost from $0.48/kWh to $0.073/kWh
China 2007
National Renewable Energy targets › 10% by 2010 (300 MW)› 15% by 2020 (1.8 GW)
Supplies 1,130 tons of polysilicon from 6 companies
Supplies 21,400 tons of silicon ingot from 70 companies
Number 1 PV panel producer – 1.1 GW
50 PV panel companies including Suntech, Yingli, Hebei Jingao, Jiansu Linyang, and Nangjing CEEG
82,800 employees (6 times that of 2005)
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