This article needs to be updated.(April 2017) |
Spain is one of the first countries to deploy large-scale solar photovoltaics, and is the world leader in concentrated solar power (CSP) production.
In 2022, the cumulative total solar power Europe installed was 19.5 GW, of which 17.2 GW were solar PV installations and 2.3 GW were concentrated solar power. [1] [2] In 2016, nearly 8 TWh of electrical power was produced from photovoltaics, and 5 TWh from CSP plants. [3]
In 2022, solar power accounted for 11.5% of total electricity generation in Spain, up from 2.4% in 2010 and less than 0.1% in 2000. [4] [5] Industry organization Solar Power Europe projects Spain will more than double its solar PV capacity between 2022 and 2026. [6] [7]
Spain is one of the European countries with the most hours of sunshine.
The country initially had a leading role in the development of solar power. Generous prices for grid connected solar power were offered to encourage the industry. The boom in solar power installations were faster than anticipated and prices for grid connected solar power were not cut to reflect this, leading to a fast but unsustainable boom in installations. Spain would find itself second only to Germany in the world for solar power installed capacity. In the wake of the 2008 financial crisis, the Spanish government drastically cut its subsidies for solar power and capped future increases in capacity at 500 MW per year, with effects upon the industry worldwide. [8] Between 2012 and 2016, new installations stagnated in Spain while growth accelerated in other leading countries leaving Spain to lose much of its world leading status to countries such as Germany, China and Japan. The controversial "sun tax" and intimidating regulation surrounding solar self consumption introduced in 2015 were only begun to be repealed in late 2018 by the new government.
As a legacy from Spain's earlier development of solar power, the country remains a world leader in concentrated solar power, accounting for almost a third of solar power installed capacity in the country, a much higher ratio than that for other countries as of 2017. Many large concentrated solar power stations remain active in Spain and may have provided some of the impetus for large CSP developments in neighbouring Morocco. In 2017 Spain held large auctions for renewable energy capacity to be constructed by 2020: PV and wind projects each won 4 GW.
The 2020s are seeing a large increase in solar installations in Spain; following three years of strong growth, the country's updated 2023 National Energy and Climate Plan anticipates solar PV capacity reaching 76 GW by 2030. [9] [10]
Installed capacity grew rapidly until 2013. Between 2013 and 2018 growth was negligible in Spain, and the country fell behind many other European countries in the development of capacity, though it retained its leading position in the deployment of solar thermal power. Growth resumed again after 2018.
2006 | 2007 | 2008 | 2009 | 2010 | 2011 | 2012 | 2013 | 2014 | 2015 | 2016 | 2017 | 2018 | 2019 | 2020 | 2021 | 2022 | |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Solar PV* | 125 | 637 | 3,355 | 3,399 | 3,840 | 4,261 | 4,561 | 4,639 | 4,646 | 4,656 | 4,669 | 4,688 | 4,707 | 8,711 | 11,669 | 15,286 | 18,164 |
Solar thermal | 11 | 11 | 61 | 232 | 532 | 999 | 1,950 | 2,304 | 2,304 | 2,304 | 2.304 | 2,304 | 2,304 | 2,304 | |||
Total | 136 | 648 | 3,416 | 3,631 | 4,372 | 5,260 | 6,511 | 6,943 | 6,950 | 6,960 | 6.973 | 6,992 | 7,011 | 11,015 | |||
*Solar PV figures include only grid-connected capacity. |
Through a ministerial ruling in March 2004, the Spanish government removed economic barriers to the connection of renewable energy technologies to the electricity grid. The Royal Decree 436/2004 equalised conditions for large-scale solar thermal and photovoltaic plants and guaranteed feed-in tariffs. [13]
Spain added a record 2.6 GW of solar photovoltaic power in 2008, [14] a figure almost five times that of the next record year, increasing capacity to 3.5 GW. [15] Spain surpassed both Japan and the United States in 2008 as the number two market as measured by cumulative installed PV capacity behind the world leader at the time Germany, accounting for 24% of global PV capacity. [16] PV capacity added during 2008 would still account for more than half of total capacity as of 2016. In 2008 the Spanish government committed to achieving a target of 12% of primary energy from renewable energy by 2010 and by 2020 expected the installed solar generating capacity of 10 GW. [17]
Since 2010, Spain has been the world's leader in concentrated solar power (CSP). Spain is leapfrogged by Italy during 2011 following a later solar boom there to lose its position as the world's second largest installer of solar PV.
By the end of 2012, 4.5 GW of solar photovoltaics had been installed, and in that year 8.2 TWh of electricity was produced. [18] New installations of solar photovoltaics have slowed down significantly to around 300 MW during 2012. By the end of 2012 Spain had also installed over 2,000 MW of CSP.
Almost no new solar capacity is added during this period following the removal of government feed-in tariffs. Having promoted the solar industry with large government subsidies during earlier periods, the system now operates under a 180-degree turn with a punitive 'sun tax' applied to new PV systems which would otherwise flourish. Spain has been cited as a model in how not to develop renewables. [19] The hoped for growth in self consumption solar generation during 2016 fails to materialise due to delays to reforms following the extended time taken to form a government, albeit with just one party opposed to reforms in this area. [4]
In May 2017, Spain held an auction for new renewable capacity to be online by 2020. Solar projects won only 1 MW of the 3000 MW awarded. After complaints by the solar industry which felt the auction terms favoured wind power, another auction occurred in July. In this auction, solar projects received 3,909 MW and wind received 1,128 MW. [20] [21] Financing, land acquisition and solar panel price fluctuations could reduce the actual amount of solar power installed.
A new sector of the market begins to make headway in the Spanish market following the easing of regulations on self consumption generation. 261.7 MW of new solar power was installed, of which just 26 MW were connected to the grid and the remainder, 235.7 MW being self-generating installations. [22] It is expected that this could increase to 300 to 400 MW per year following further easing of regulations in May 2018. [22] Renewable energy auctions held in the previous year have yet to show much impact on grid connected capacity but expected to make a considerable change during 2019. According to industry sources the 3.9 GW tendered through government auctions has been dwarfed by huge merchant and power purchase agreements bringing the combined total under consideration to 29 GW. [23] The re-emerging boom in Spanish solar PV is not being driven by subsidies or government tenders but as a result of solar being a highly cost effective proposition for electricity needs.
Spain is poised to become a major contributor to Europe's renewable energy landscape, supported by its robust solar potential and favorable market conditions. In 2023, Spain is on track to increase its solar capacity by 4 GW. The country also has ambitions to install an additional 19 GW of new capacity between 2022 and 2025, which would make it home to the largest solar pipeline in Europe. However, Spain grapples with lengthy permitting processes, which can take up to five years, posing a significant hurdle to project development. To address this challenge, the government introduced new regulations in March 2023, streamlining permitting for projects below 150 MW capacity and with low or medium environmental impact. These measures aim to reduce permitting times to approximately two years. [24]
Name of Plant | Net Power MW(e) | GW·h /year | Capacity factor | Completed |
---|---|---|---|---|
PS10 | 10 | 23.4 | 0.24 | 2007 |
Andasol 1 | 50 | 165 | 0.41 | 2008 |
PS20 | 20 | 48 | 0.27 | 2009 |
Eureka | 2 | 2009, June [25] | ||
Andasol 2 | 50 | 2009 | ||
Puerto Errado 1 | 1.5 | 2009 | ||
Puertollano | 50 | 2009 | ||
La Risca | 50 | 2009 | ||
Extresol 1 | 50 | 2010 | ||
Extresol 2 | 50 | 2010 | ||
La Florida | 50 | 2010, July | ||
Majadas | 50 | 2010, August | ||
Solnova 1 | 50 | 2010 | ||
Solnova 3 | 50 | 2010 | ||
Alvarado I | 50 | 2010 | ||
Solnova 4 | 50 | 2010 | ||
La Dehesa | 50 | 2010, November | ||
Palma del Rio 2 | 50 | 2011 | ||
Manchasol 1 | 50 | 2011 | ||
Manchasol 2 | 50 | 2011 | ||
Gemasolar | 20 | 2011 | ||
Palma del Rio 1 | 50 | 2011 | ||
Lebrija 1 | 50 | 2011 | ||
Andasol 3 | 50 | 2011 | ||
Helioenergy 1 | 50 | 2011 | ||
Astexol 3 | 50 | 2011 | ||
Arcosol 50 | 50 | 2011 | ||
Termosol 50 | 50 | 2011 | ||
Helioenergy 2 | 50 | 2012 | ||
Valle 1 | 50 | 170 | 2012 | |
Valle 2 | 50 | 170 | 2012 | |
Puerto Errado 2 | 30 | 2012 | ||
Aste 1A | 50 | 2012 | ||
Aste 1B | 50 | 2012 | ||
Moron | 50 | 2012 | ||
Helios 1 | 50 | 2012, May | ||
Solaben 3 | 50 | 2012, June | ||
Guzman | 50 | 2012, July | ||
La Africana | 50 | 2012, July | ||
Olivenza 1 | 50 | 2012, July | ||
Helios 2 | 50 | 2012, August | ||
Extresol 3 | 50 | 2012, August | ||
Orellana | 50 | 2012, August | ||
Solaben 2 | 50 | 2012, October | ||
Solarcor 1 | 50 | 2012 | ||
Solarcor 2 | 50 | 2012 | ||
Termosolar Borges | 25 | 2012, December |
In March 2007, Europe's first commercial concentrating solar power tower plant was opened near the sunny Andalusian city of Seville. The 11 MW plant, known as the PS10 solar power tower, produces electricity with 624 large heliostats. Each of these mirrors has a surface measuring 120 square meters (1,290 square feet) that concentrates the Sun's rays to the top of a 115-meter (377 feet) high tower where a solar receiver and a steam turbine are located. The turbine drives a generator, producing electricity. [26]
The Andasol 1 solar power station is Europe's first parabolic trough commercial power plant (50 MWe), located near Guadix in the province of Granada, also in Andalusia (the plant is named after the region). The Andasol 1 power plant went online in November 2008, and has a thermal storage system which absorbs part of the heat produced in the solar field during the day. This heat is then stored in a molten salt mixture and used to generate electricity during the night, or when the sky is overcast. [27]
A 15 MWe solar-only power tower plant, the Solar Tres project, is in the hands of the Spanish company SENER, employing molten salt technologies for receiving and energy storage. Its 16-hour molten salt storage system will be able to deliver power around the clock. The Solar Tres project has received a €5 million grant from the EC's Fifth Framework Programme. [13]
Solar thermal power plants designed for solar-only generation are well matched to summer noon peak loads in prosperous areas with significant cooling demands, such as Spain. Using thermal energy storage systems, solar thermal operating periods can even be extended to meet base-load needs. [13]
Abengoa Solar began commercial operation of a 20-megawatt solar power tower plant near Seville in late April 2009. Called the PS20, the plant uses a field of 1,255 flat mirrors, or heliostats, to concentrate sunlight on a receiver mounted on a central tower. Water pumped up the tower and through the receiver boils into steam, which is then directed through a turbine to produce electricity. The new facility is located adjacent to one with half its capacity, called PS10, which was the world's first commercial solar power tower plant. According to Abengoa Solar, the new facility is exceeding its predicted power output. [28]
Installed PV capacity in Spain by class size in 2017 [29] | |
---|---|
<10 kW | 2% |
10-100 kW | 27% |
100-500 kW | 43% |
>500 kW | 28% |
Utility scale solar PV dominated the cumulative installed capacity in 2018 accounting for over 75% of the total in Spain although some sources would not define smaller sized installations as utility scale. Only 2% of Spain's installations in 2017 were in the size typical for residential rooftop solar. This is typically the situation in European countries which had a short-term generous feed in their tariff system with little attention to policy consistency and scale of installations. As of 2018, 19% of Europe's cumulative PV capacity was installed on residential rooftops, and about 30% on commercial roofs, while the industrial segment accounted for 17%, and the utility market for 34%. [30]
The government projects an increase in solar PV capacity by approximately 30 GW, rising from 9 GW in 2020 to 21.7 GW by 2025, and reaching 39.2 GW by 2030. [31]
According to a report on behalf of the European Commission Spain had just 49 MW of residential solar PV capacity with just 12,000 residential solar PV prosumers in the country representing only 0.1% of households as of 2015. [32] The average size of residential solar PV installations in Spain moving forwards to 2030 is 3.94 kW. [32] The technical potential for residential solar PV in Spain is estimated at 13,620 MW. [32] The United Kingdom, a relative latecomer to Solar PV development, had 2,499 MW of residential solar PV installed as of 2015. [32]
Location | Organisation (linked) | Online | Capacity (MW) |
---|---|---|---|
Figueruelas | GM facility | 2008 | 11.8 |
Martorell | Seat al Sol, SEAT facility | 2010–2013 | 11.0 |
Castala | Actiu Technology Park | 2008 | 5.2 |
At the time of opening, the General Motors facility at Figueruelas was the world's largest photovoltaic (PV) roof, consisting of 85,000 lightweight panels, thereby reducing annual carbon dioxide emissions by 6,700 tonnes per year. [34] GM planned to install solar panels at eleven other plants across Europe.
Photovoltaics (PV) convert sunlight into electricity and many solar photovoltaic power stations have been built in Spain. [35] As of November 2010, the largest PV power plants in Spain include the Olmedilla Photovoltaic Park (60 MW), Puertollano Photovoltaic Park (47.6 MW), Planta Solar La Magascona & La Magasquila (34.5 MW), Arnedo Solar Plant (34 MW), and Planta Solar Dulcinea (31.8 MW). [35]
BP Solar begun constructing a new solar photovoltaic cell manufacturing plant at its European headquarters in Tres Cantos, Madrid. [38] For phase one of the Madrid expansion, BP Solar aimed to expand its annual cell capacity from 55 MW to around 300 MW. Construction of this facility was underway, with the first manufacturing line expected to be fully operational in 2009. [38] The new cell lines would use innovative screen-printing technology. By fully automating wafer handling, the manufacturing lines would be able to handle the very thinnest of wafers available and ensure the highest quality. [38] Thin wafers are of particular importance since there has been a silicon shortage in recent years. However, after the new national law limiting installed power by year, in April 2009 BP Solar closed its factories. [39]
Since the beginning of 2007, Aleo Solar AG has also been manufacturing high-quality solar modules for the Spanish market at its own factory in Santa Maria de Palautordera near Barcelona. In 2014 SITECNO S.A. took over this facility [38]
<1 watt 1—10 watts 10—50 watts 50—100 watts 100—200 watts | 200—350 watts 350—500 watts 500—750 watts >750 watts |
Autonomous Communities | 2010 | 2011 | 2022 | Watts per capita (2022) |
---|---|---|---|---|
Andalusia | 765 | 822 | 4,163 | 488 |
Aragon | 142 | 146 | 1,851 | 1,408 |
Asturias | 1 | 1 | 1 | |
Balearic Islands | 60 | 66 | 225 | 183 |
Basque Country | 20 | 23 | 51 | 23 |
Canary Islands | 133 | 138 | 212 | 94 |
Cantabria | 2 | 2 | 4 | 6 |
Castile-La Mancha | 897 | 923 | 4,048 | 1,974 |
Castile and León | 410 | 467 | 1,438 | 605 |
Catalonia | 202 | 234 | 295 | 38 |
Ceuta and Melilla | 0.1 | 0.1 | ||
Community of Madrid | 38 | 48 | 63 | 9 |
Extremadura | 492 | 558 | 5,347 | 5,076 |
Galicia | 10 | 12 | 18 | 6 |
La Rioja | 83 | 89 | 99 | 313 |
Navarre | 142 | 155 | 166 | 251 |
Region of Murcia | 357 | 404 | 1,384 | 908 |
Valencian Community | 277 | 313 | 419 | 82 |
Source: [41] [42] [43] |
In 2006, Spain implemented a regulatory instrument of national jurisdiction promulgated by the Royal Decree 314/2006 referred to as the technical building code (TBC or CTE in Spanish) to regulate the basic quality requirements of buildings and their respective installations concerning thermal and photovoltaic solar energy. It applies to new constructions as well as any modifications made on any existing building with the final goal to guarantee and promote the use of renewable sources of energy. [44]
Concerning thermosolar energy, Spain was the first country in Europe to enforce the integration of solar thermal systems in new constructed or refurnished buildings to cover from 30 to 70% of the Domestic Hot Water (DHW) demand. Article 15.4 of the TBC states that "buildings with foreseen demand for hot water or the conditioning of a covered swimming pool, part of the thermal energy needs shall be covered by incorporating systems for the collection, storage and use of low temperature solar energy [...]". [45]
In relation to Photovoltaic power, Article 15.5 requires the incorporation of "systems for the collection and transformation of solar energy into electric power by photovoltaic processes for proprietary use or supply to the network". [46] This policy triggered the production of this type of renewable energy positioning Spain on top of the largest producers of photovoltaic electricity in the world by 2009. [47]
In the wake of the 2008 financial crisis, the Spanish government drastically cut its subsidies for solar power and capped future increases in capacity at 500 MW per year, with effects upon the industry worldwide. "The solar industry in 2009 has been undermined by [a] collapse in demand due to the decision by Spain", according to Henning Wicht, a solar-power analyst. [8] In 2010, the Spanish government went further, retroactively cutting subsidies for existing solar projects, aiming to save several billion euro it owed. [14] [48] According to the Photovoltaic Industry Association, several hundred photovoltaic plant operators may face bankruptcy. [49] Phil Dominy of Ernst & Young, comparing the feed-in tariff reductions in Germany and Italy, said; "Spain stands out as an example of how not to do it". [50] As a result, a Spanish association of solar power producers has announced its intention to go to court over the government's plans to cap solar subsidies. In 2014 alternative energy group NextEra filed a complaint against Spain at the International Centre for Settlement of Investment Disputes. [51]
The Plataforma Solar de Almería (PSA), part of the Center for Energy, Environment and Technological Research (CIEMAT), is a center for research, development, and testing of concentrating solar power technologies. [52] ISFOC [53] in Puertollano is a development institute for concentrator photovoltaics (CPV) which evaluates CPV technologies at the pilot production scale to optimise operation and determine cost. Technical University of Madrid has a photovoltaic research group. [54]
Solar Concentra is the Spanish technology platform for concentrated solar power (CSP). [55] It was created in 2010, and it combines the efforts of the different agents of the CSP sector in Spain.
Many countries and territories have installed significant solar power capacity into their electrical grids to supplement or provide an alternative to conventional energy sources. Solar power plants use one of two technologies:
India's solar power installed capacity was 73.32 GWAC as of 31 December 2023.
Solar power accounted for an estimated 10.7% electricity in Germany in 2022, up from 1.9% in 2010 and less than 0.1% in 2000.
Solar power has a small role in electricity production in the United Kingdom.
Renewable energy in Spain, comprising bioenergy, wind, solar, and hydro sources, accounted for 15.0% of the Total Energy Supply (TES) in 2019. Oil was the largest contributor at 42.4% of the TES, followed by gas, which made up 25.4%.
Solar power consists of photovoltaics (PV) and solar thermal energy in the European Union (EU).
China is the largest market in the world for both photovoltaics and solar thermal energy. China's photovoltaic industry began by making panels for satellites, and transitioned to the manufacture of domestic panels in the late 1990s. After substantial government incentives were introduced in 2011, China's solar power market grew dramatically: the country became the world's leading installer of photovoltaics in 2013. China surpassed Germany as the world's largest producer of photovoltaic energy in 2015, and became the first country to have over 100 GW of total installed photovoltaic capacity in 2017.
Solar power includes solar farms as well as local distributed generation, mostly on rooftops and increasingly from community solar arrays. In 2023, utility-scale solar power generated 164.5 terawatt-hours (TWh), or 3.9% of electricity in the United States. Total solar generation that year, including estimated small-scale photovoltaic generation, was 238 TWh.
Concentrated solar power systems generate solar power by using mirrors or lenses to concentrate a large area of sunlight into a receiver. Electricity is generated when the concentrated light is converted to heat, which drives a heat engine connected to an electrical power generator or powers a thermochemical reaction.
Turkey’s sunny climate possesses a high solar energy potential, specifically in the South Eastern Anatolia and Mediterranean regions. Solar power is a growing part of renewable energy in the country, with 12 gigawatts (GW) of solar panels generating 6% of the country's electricity. Solar thermal is also important.
Development of solar power in Greece started in 2006 and installations of photovoltaic systems skyrocketed from 2009 because of the appealing feed-in tariffs introduced and the corresponding regulations for domestic applications of rooftop solar PV. In 2019, 90% of the around 2.5 GWp capacity was installed in 2011, 2012 and 2013. However, funding the FITs created an unacceptable deficit of more than €500 million in the Greek "Operator of Electricity Market" RES fund. To reduce that deficit, new regulations were introduced in August 2012 including retrospective feed-in tariffs reduction, with further reductions over time. These measures enabled the deficit to be erased by 2017.
Solar power is an important contributor to electricity generation in Italy, accounting for 8% of the total in 2017. As of 2022, the country has a total installed capacity of 22.56 GW. In 2019, Italy set a national goal of reaching 50 GW by 2030.
Solar power in France including overseas territories reached an installed capacity figure of 11.2 GW in 2020, and rose further to 17.1 GW at the end of 2022. Government plans announced in 2022 foresee solar PV capacity in France rising to 100 GW by 2050.
Solar power in Mexico has the potential to produce vast amounts of energy. 70% of the country has an insolation of greater than 4.5 kWh/m2/day. Using 15% efficient photovoltaics, a square 25 km (16 mi) on each side in the state of Chihuahua or the Sonoran Desert could supply all of Mexico's electricity.
Solar power in Florida has been increasing, as the cost of solar power systems using photovoltaics (PV) has decreased in recent years. Florida has low electricity costs compared with other states, which makes individual solar investment less attractive. Florida ranks ninth nationally in solar resource strength according to the National Renewable Energy Laboratory and tenth in solar generation by the Solar Energy Industries Association.
Solar power in South Africa includes photovoltaics (PV) as well as concentrated solar power (CSP). As of 2023, South Africa had over 2700 MW of installed PV solar power capacity in its grid, in addition to 500 MW of CSP. Installed capacity is expected to reach 8,400 MW by 2030.
Solar power in Belgium reached an installed capacity of 9.9 GW at the end of 2023, an increase of 1.8 GW from 2022.
Solar power in Denmark amounts to 3,529 MW of grid-connected PV capacity at the end of December 2023, and contributes to a goal to use 100% renewable electricity by 2030 and 100% renewable energy by 2050. Solar power met 6.1% of Danish electricity demand in 2022, the highest share in the Nordic countries.
Under its commitment to the EU renewable energy directive of 2009, France has a target of producing 23% of its total energy needs from renewable energy by 2020. This figure breaks down to renewable energy providing 33% of energy used in the heating and cooling sector, 27% of the electricity sector and 10.5% in the transport sector. By the end of 2014, 14.3% of France's total energy requirements came from renewable energy, a rise from 9.6% in 2005.
In 2022 Chile produced about 18% of its electricity from solar power, up from 7% in 2018. As of 2022, Chile produces the highest percentage of its electricity from solar in the world. At the end of 2021 Chile was ranked 22nd in the world in terms of installed solar energy.
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