Photovoltaic power station
A photovoltaic power station, also known as a solar park, solar farm, or solar power plant is a large-scale photovoltaic system (PV system) designed for the supply of merchant power into the electricity grid. They are differentiated from most building-mounted and other decentralised solar power applications because they supply power at the utility level, rather than to a local user or users. The generic expression utility-scale solar is sometimes used to describe this type of project.
The solar power source is via photovoltaic modules that convert light directly to electricity. However, this differs from, and should not be confused with concentrated solar power, the other large-scale solar generation technology, which uses heat to drive a variety of conventional generator systems. Both approaches have their own advantages and disadvantages, but to date, for a variety of reasons, photovoltaic technology has seen much wider use in the field. As of 2019, concentrator systems represented about 3% of utility-scale solar power capacity.
In some countries, the nameplate capacity of a photovoltaic power stations is rated in megawatt-peak (MWp), which refers to the solar array's theoretical maximum DC power output. In other countries, the manufacturer gives the surface and the efficiency. However, Canada, Japan, Spain and the United States often specify using the converted lower nominal power output in MWAC, a measure directly comparable to other forms of power generation. A third and less common rating is the megavolt-amperes (MVA). Most solar parks are developed at a scale of at least 1 MWp. As of 2018, the world's largest operating photovoltaic power stations surpass 1 gigawatt. As at the end of 2019, about 9,000 plants with a combined capacity of over 220 GWAC were solar farms larger than 4 MWAC (utility scale).
Most of the existing large-scale photovoltaic power stations are owned and operated by independent power producers, but the involvement of community- and utility-owned projects is increasing. To date, almost all have been supported at least in part by regulatory incentives such as feed-in tariffs or tax credits, but as levelized costs have fallen significantly in the last decade and grid parity has been reached in an increasing number of markets, it may not be long before external incentives cease to exist.
The first 1 MWp solar park was built by Arco Solar at Lugo near Hesperia, California at the end of 1982, followed in 1984 by a 5.2 MWp installation in Carrizo Plain. Both have since been decommissioned, though Carrizo Plain is the site for several large plants now being constructed or planned. The next stage followed the 2004 revisions to the feed-in tariffs in Germany when a substantial volume of solar parks were constructed.
Several hundred installations over 1 MWp have been since installed in Germany, of which more than 50 are over 10 MWp. With its introduction of feed-in tariffs in 2008, Spain became briefly the largest market, with some 60 solar parks over 10 MW, but these incentives have since been withdrawn. The USA, China India, France, Canada, Australia, and Italy, among others, have also become major markets as shown on the list of photovoltaic power stations.
Siting and land use
The land area required for a desired power output, varies depending on the location, and on the efficiency of the solar modules, the slope of the site and the type of mounting used. Fixed tilt solar arrays using typical modules of about 15% efficiency on horizontal sites, need about 1 hectare/MW in the tropics and this figure rises to over 2 hectares in northern Europe.
Because of the longer shadow the array casts when tilted at a steeper angle, this area is typically about 10% higher for an adjustable tilt array or a single axis tracker, and 20% higher for a 2-axis tracker, though these figures will vary depending on the latitude and topography.
The best locations for solar parks in terms of land use are held to be brown field sites, or where there is no other valuable land use. Even in cultivated areas, a significant proportion of the site of a solar farm can also be devoted to other productive uses, such as crop growing or biodiversity.
Agrivoltaics is co-developing the same area of land for both solar photovoltaic power as well as for conventional agriculture. A recent study found that the value of solar generated electricity coupled to shade-tolerant crop production created an over 30% increase in economic value from farms deploying agrivoltaic systems instead of conventional agriculture.
In some cases several different solar power stations, with separate owners and contractors, are developed on adjacent sites. This can offer the advantage of the projects sharing the cost and risks of project infrastructure such as grid connections and planning approval. Solar farms can also be co-located with wind farms.
Sometimes the title 'solar park' is used to describe a set of individual solar power stations, which share sites or infrastructure, and 'cluster' is used where several plants are located nearby without any shared resources. Some examples of solar parks are the Charanka Solar Park, where there are 17 different generation projects; Neuhardenberg, with eleven plants, and the Golmud solar park with total reported capacity over 500MW. An extreme example is calling all of the solar farms in the Gujarat state of India a single solar park, the Gujarat Solar Park.
Most Solar parks are ground mounted PV systems, also known as free-field solar power plants. They can either be fixed tilt or use a single axis or dual axis solar tracker. While tracking improves the overall performance, it also increases the system's installation and maintenance cost. A solar inverter converts the array's power output from DC to AC, and connection to the utility grid is made through a high voltage, three phase step up transformer of typically 10 kV and above.
Solar array arrangements
The solar arrays are the subsystems which convert incoming light into electrical energy. They comprise a multitude of solar modules, mounted on support structures and interconnected to deliver a power output to electronic power conditioning subsystems.
A minority of utility-scale solar parks are configured on buildings and so use building-mounted solar arrays. The majority are free-field systems using ground-mounted structures, usually of one of the following types:
Many projects use mounting structures where the solar modules are mounted at a fixed inclination calculated to provide the optimum annual output profile. The modules are normally oriented towards the Equator, at a tilt angle slightly less than the latitude of the site. In some cases, depending on local climatic, topographical or electricity pricing regimes, different tilt angles can be used, or the arrays might be offset from the normal east–west axis to favour morning or evening output.
A variant on this design is the use of arrays, whose tilt angle can be adjusted twice or four times annually to optimise seasonal output. They also require more land area to reduce internal shading at the steeper winter tilt angle. Because the increased output is typically only a few percent, it seldom justifies the increased cost and complexity of this design.
Dual axis trackers
To maximise the intensity of incoming direct radiation, solar panels should be orientated normal to the sun's rays. To achieve this, arrays can be designed using two-axis trackers, capable of tracking the sun in its daily orbit across the sky, and as its elevation changes throughout the year.
These arrays need to be spaced out to reduce inter-shading as the sun moves and the array orientations change, so need more land area. They also require more complex mechanisms to maintain the array surface at the required angle. The increased output can be of the order of 30% in locations with high levels of direct radiation, but the increase is lower in temperate climates or those with more significant diffuse radiation, due to overcast conditions. For this reason, dual axis trackers are most commonly used in subtropical regions, and were first deployed at utility scale at the Lugo plant.
Single axis trackers
A third approach achieves some of the output benefits of tracking, with a lesser penalty in terms of land area, capital and operating cost. This involves tracking the sun in one dimension – in its daily journey across the sky – but not adjusting for the seasons. The angle of the axis is normally horizontal, though some, such as the solar park at Nellis Air Force Base, which has a 20° tilt, incline the axis towards the equator in a north–south orientation – effectively a hybrid between tracking and fixed tilt.
Solar panels produce direct current (DC) electricity, so solar parks need conversion equipment to convert this to alternating current (AC), which is the form transmitted by the electricity grid. This conversion is done by inverters. To maximise their efficiency, solar power plants also incorporate maximum power point trackers (MPP tracking), either within the inverters or as separate units. These devices keep each solar array string close to its peak power point.
There are two primary alternatives for configuring this conversion equipment; centralized and string inverters, although in some cases individual, or micro-inverters are used. Single inverters allows optimizing the output of each panel, and multiple inverters increases the reliability by limiting the loss of output when an inverter fails.
These units have relatively high capacity, typically of the order between 1 MW up to 7 MW for newer units (2020), so they condition the output of a substantial block of solar arrays, up to perhaps 2 hectares (4.9 acres) in area. Solar parks using centralized inverters are often configured in discrete rectangular blocks, with the related inverter in one corner, or the centre of the block.
String inverters are substantially lower in capacity than central inverters, of the order of 10 kW up to 250 KW for newer models (2020), and condition the output of a single array string. This is normally a whole, or part of, a row of solar arrays within the overall plant. String inverters can enhance the efficiency of solar parks, where different parts of the array are experiencing different levels of insolation, for example where arranged at different orientations, or closely packed to minimise site area.
The system inverters typically provide power output at voltages of the order of 480 VAC up to 800 VAC. Electricity grids operate at much higher voltages of the order of tens or hundreds of thousands of volts, so transformers are incorporated to deliver the required output to the grid. Due to the long lead time, the Long Island Solar Farm chose to keep a spare transformer onsite, as transformer failure would have kept the solar farm offline for a long period. Transformers typically have a life of 25 to 75 years, and normally do not require replacement during the life of a photovoltaic power station.
The performance of a solar park is a function of the climatic conditions, the equipment used and the system configuration. The primary energy input is the global light irradiance in the plane of the solar arrays, and this in turn is a combination of the direct and the diffuse radiation. In some regions, soiling, i.e. the accumulation of dust or organic material on the solar panels that servers to block incident light, is a significant loss factor.
A key determinant of the output of the system is the conversion efficiency of the solar modules, which will depend in particular on the type of solar cell used.
There will be losses between the DC output of the solar modules and the AC power delivered to the grid, due to a wide range of factors such as light absorption losses, mismatch, cable voltage drop, conversion efficiencies, and other parasitic losses. A parameter called the 'performance ratio' has been developed to evaluate the total value of these losses. The performance ratio gives a measure of the output AC power delivered as a proportion of the total DC power which the solar modules should be able to deliver under the ambient climatic conditions. In modern solar parks the performance ratio should typically be in excess of 80%.
Early photovoltaic systems output decreased as much as 10%/year, but as of 2010 the median degradation rate was 0.5%/year, with modules made after 2000 having a significantly lower degradation rate, so that a system would lose only 12% of its output performance in 25 years. A system using modules which degrade 4%/year will lose 64% of its output during the same period. Many panel makers offer a performance guarantee, typically 90% in ten years and 80% over 25 years. The output of all panels is typically warranted at plus or minus 3% during the first year of operation.
The business of developing solar parks
Some of these power producers develop their own portfolio of power plants, but most solar parks are initially designed and constructed by specialist project developers. Typically the developer will plan the project, obtain planning and connection consents, and arrange financing for the capital required. The actual construction work is normally contracted to one or more EPC (engineering, procurement and construction) contractors.
Major milestones in the development of a new photovoltaic power plant are planning consent, grid connection approval, financial close, construction, connection and commissioning. At each stage in the process, the developer will be able to update estimates of the anticipated performance and costs of the plant and the financial returns it should be able to deliver.
Photovoltaic power stations occupy at least one hectare for each megawatt of rated output, so require a substantial land area; which is subject to planning approval. The chances of obtaining consent, and the related time, cost and conditions, varying from jurisdiction to jurisdiction and location to location. Many planning approvals will also apply conditions on the treatment of the site after the station has been decommissioned in the future. A professional health, safety and environment assessment is usually undertaken during the design of a PV power station in order to ensure the facility is designed and planned in accordance with all HSE regulations.
Most stations are sited within a few kilometres of a suitable grid connection point. This network needs to be capable of absorbing the output of the solar park when operating at its maximum capacity. The project developer will normally have to absorb the cost of providing power lines to this point and making the connection; in addition often to any costs associated with upgrading the grid, so it can accommodate the output from the plant.
Operation and maintenance
Once the solar park has been commissioned, the owner usually enters into a contract with a suitable counterparty to undertake operation and maintenance (O&M). In many cases this may be fulfilled by the original EPC contractor.
Solar plants' reliable solid-state systems require minimal maintenance, compared to rotating machinery for example. A major aspect of the O&M contract will be continuous monitoring of the performance of the plant and all of its primary subsystems, which is normally undertaken remotely. This enables performance to be compared with the anticipated output under the climatic conditions actually experienced. It also provides data to enable the scheduling of both rectification and preventive maintenance. A small number of large solar farms use a separate inverter or maximizer for each solar panel, which provide individual performance data that can be monitored. For other solar farms, thermal imaging is a tool that is used to identify non-performing panels for replacement.
A solar park's income derives from the sales of electricity to the grid, and so its output is metered in real-time with readings of its energy output provided, typically on a half-hourly basis, for balancing and settlement within the electricity market.
Income is affected by the reliability of equipment within the plant and also by the availability of the grid network to which it is exporting. Some connection contracts allow the transmission system operator to constrain the output of a solar park, for example at times of low demand or high availability of other generators. Some countries make statutory provision for priority access to the grid for renewable generators, such as that under the European Renewable Energy Directive.
Economics and finance
In recent years, PV technology has improved its electricity generating efficiency, reduced the installation cost per watt as well as its energy payback time (EPBT). It had reached grid parity in at least 19 different markets by 2014, and in most parts of the world subsequently to become a viable source of mainstream power.
As solar power costs reached grid parity, PV systems were able to offer power competitively in the energy market. The subsidies and incentives, which were needed to stimulate the early market as detailed below, were progressively replaced by auctions and competitive tendering and leading to further price reductions.
Competitive energy costs of utility-scale solar
The improving competitiveness of utility-scale solar became more visible as countries and energy utilities introduced auctions for new generating capacity. Some auctions are reserved for solar projects, while others are open to a wider range of sources.
The prices revealed by these auctions and tenders have led to highly competitive prices in many regions. Amongst the prices quoted are:
Solar generating stations have become progressively cheaper in recent years, and this trend is expected to continue. Meanwhile, traditional electricity generation is becoming progressively more expensive. These trends led to a crossover point when the levelised cost of energy from solar parks, historically more expensive, matched or beat the cost of traditional electricity generation. This point depends on locations and other factors, and is commonly referred to as grid parity.
For merchant solar power stations, where the electricity is being sold into the electricity transmission network, the levelised cost of solar energy will need to match the wholesale electricity price. This point is sometimes called 'wholesale grid parity' or 'busbar parity'.
Some photovoltaic systems, such as rooftop installations, can supply power directly to an electricity user. In these cases, the installation can be competitive when the output cost matches the price at which the user pays for his electricity consumption. This situation is sometimes called 'retail grid parity', 'socket parity' or 'dynamic grid parity'. Research carried out by UN-Energy in 2012 suggests areas of sunny countries with high electricity prices, such as Italy, Spain and Australia, and areas using diesel generators, have reached retail grid parity.
Prices for installed PV systems show regional variations, more than solar cells and panels, which tend to be global commodities. In 2013, utility-scale system prices in highly penetrated markets such as China and Germany were lower ($1.40/W) than in the United States ($3.30/W). The IEA explains these discrepancies due to differences in "soft costs", which include customer acquisition, permitting, inspection and interconnection, installation labor and financing costs. Regional variations reduced or changed as markets grew with the US system price declining to $1.25/W by 2016.
In the years before grid parity had been reached in many parts of the world, solar generating stations needed some form of financial incentive to compete for the supply of electricity. Many legislatures around the world have introduced such incentives to support the deployment of solar power stations.
Feed-in tariffs are designated prices which must be paid by utility companies for each kilowatt hour of renewable electricity produced by qualifying generators and fed into the grid. These tariffs normally represent a premium on wholesale electricity prices and offer a guaranteed revenue stream to help the power producer finance the project.
Renewable portfolio standards and supplier obligations
These standards are obligations on utility companies to source a proportion of their electricity from renewable generators. In most cases, they do not prescribe which technology should be used and the utility is free to select the most appropriate renewable sources.
Loan guarantees and other capital incentives
Some countries and states adopt less targeted financial incentives, available for a wide range of infrastructure investment, such as the US Department of Energy loan guarantee scheme, which stimulated a number of investments in the solar power plant in 2010 and 2011.
Tax credits and other fiscal incentives
Another form of indirect incentive which has been used to stimulate investment in solar power plant was tax credits available to investors. In some cases the credits were linked to the energy produced by the installations, such as the Production Tax Credits. In other cases the credits were related to the capital investment such as the Investment Tax Credits
International, national and regional programmes
In addition to free market commercial incentives, some countries and regions have specific programs to support the deployment of solar energy installations.
The European Union's Renewables Directive sets targets for increasing levels of deployment of renewable energy in all member states. Each has been required to develop a National Renewable Energy Action Plan showing how these targets would be met, and many of these have specific support measures for solar energy deployment. The directive also allows states to develop projects outside their national boundaries, and this may lead to bilateral programs such as the Helios project.
Additionally many other countries have specific solar energy development programmes. Some examples are India's JNNSM, the Flagship Program in Australia, and similar projects in South Africa and Israel.
The electrical output of a solar park will be related to the solar radiation, the capacity of the plant and its performance ratio. The income derived from this electrical output will come primarily from the sale of the electricity, and any incentive payments such as those under Feed-in Tariffs or other support mechanisms.
The dominant costs of solar power plants are the capital cost, and therefore any associated financing and depreciation. Though operating costs are typically relatively low, especially as no fuel is required, most operators will want to ensure that adequate operation and maintenance cover is available to maximise the availability of the plant and thereby optimise the income to cost ratio.
The first places to reach grid parity were those with high traditional electricity prices and high levels of solar radiation. Currently, more capacity is being installed in the rooftop than in the utility-scale segment. However, the worldwide distribution of solar parks is expected to change as different regions achieve grid parity. This transition also includes a shift from rooftop towards utility-scale plants, since the focus of new PV deployment has changed from Europe towards the Sunbelt markets where ground-mounted PV systems are favored.:43
Because of the economic background, large-scale systems are presently distributed where the support regimes have been the most consistent, or the most advantageous. Total capacity of worldwide PV plants above 4 MWAC was assessed by Wiki-Solar as c. 220 GW in c. 9,000 installations at the end of 2019 and represents about 35 percent of estimated global PV capacity of 633 GW, up from 25 percent in 2014. The countries which had the most capacity, in descending order, were the China, United States, India, United Kingdom, Germany, Spain, Japan and France. Activities in the key markets are reviewed individually below.
China was reported in early 2013 to have overtaken Germany as the nation with the most utility-scale solar capacity. Much of this has been supported by the Clean Development Mechanism. The distribution of power plants around the country is quite broad, with the highest concentration in the Gobi desert and connected to the Northwest China Power Grid.
The first multi-megawatt plant in Europe was the 4.2 MW community-owned project at Hemau, commissioned in 2003. But it was the revisions to the German feed-in tariffs in 2004, which gave the strongest impetus to the establishment of utility-scale solar power plants. The first to be completed under this programme was the Leipziger Land solar park developed by Geosol. Several dozen plants were built between 2004 and 2011, several of which were at the time the largest in the world. The EEG, the law which establishes Germany's feed-in tariffs, provides the legislative basis not just for the compensation levels, but other regulatory factors, such as priority access to the grid. The law was amended in 2010 to restrict the use of agricultural land, since which time most solar parks have been built on so-called ‘development land’, such as former military sites. Partly for this reason, the geographic distribution of photovoltaic power plants in Germany is biased towards the former Eastern Germany. As of February 2012, Germany had 1.1 million photovoltaic power plants (most are small kW roof mounted).
India has been rising up the leading nations for the installation of utility-scale solar capacity. The Charanka Solar Park in Gujarat was opened officially in April 2012 and was at the time the largest group of solar power plants in the world.
Geographically the states with the largest installed capacity are Telangana, Rajasthan and Andhra Pradesh with over 2 GW of installed solar power capacity each. Rajasthan and Gujarat share the Thar Desert, along with Pakistan. In May 2018, the Pavagada Solar Park became functional and had a production capacity of 2GW. As of February 2020, it is the largest Solar Park in the world. In September 2018 Acme Solar announced that it had commissioned India's cheapest solar power plant, the 200 MW Rajasthan Bhadla solar power park.
By the end of 2017, it was reported that more than 732 MW of solar energy projects had been completed, which contributed to 7% of Jordan's electricity. After having initially set the percentage of renewable energy Jordan aimed to generate by 2020 at 10%, the government announced in 2018 that it sought to beat that figure and aim for 20%.
The majority of the deployment of solar power stations in Spain to date occurred during the boom market of 2007–8. The stations are well distributed around the country, with some concentration in Extremadura, Castile-La Mancha and Murcia.
The introduction of Feed-in tariffs in the United Kingdom in 2010 stimulated the first wave of utility-scale projects, with c. 20 plants being completed before tariffs were reduced on 1 August 2011 following the 'Fast Track Review'. A second wave of installations was undertaken under the UK's Renewables Obligation, with the total number of plants connected by the end of March 2013 reaching 86. This is reported to have made the UK Europe's best market in the first quarter of 2013.
UK projects were originally concentrated in the South West, but have more recently spread across the South of England and into East Anglia and the Midlands. The first solar park in Wales came on stream in 2011 at Rhosygilwen, north Pembrokeshire. As of June 2014 there were 18 schemes generating more than 5 MW and 34 in planning or construction in Wales.
Noteworthy solar parks
The following solar parks were, at the time they became operational, the largest in the world or their continent, or are notable for the reasons given:
|Lugo, San Bernardino County, California||USA||1 MW||Dec 1982||First MW plant|
|Carrisa Plain||USA||5.6 MW||Dec 1985||World's largest at the time|
|Hemau||Germany||4.0 MW||Apr 2003||Europe's largest community-owned facility at the time|
|Leipziger Land||Germany||4.2 MW||Aug 2004||Europe's largest at the time; first under FITs|
|Pocking||Germany||10 MW||Apr 2006||Briefly the world's largest|
|Nellis Air Force Base, Nevada||USA||14 MW||Dec 2007||America's largest at the time|
|Olmedilla||Spain||60 MW||Jul 2008||World's and Europe's largest at the time|
|Sinan||Korea||24 MW||Aug 2008||Asia's largest at the time|
|Waldpolenz, Saxony||Germany||40 MW||Dec 2008||World's largest thin film plant. Extended to 52 MW in 2011|
|DeSoto, Florida||USA||25 MW||Oct 2009||America's largest at the time|
|La Roseraye||Reunion||11 MW||Apr 2010||Africa's first 10 MW+ plant|
|Sarnia, Ontario||Canada||97 MWP||Sep 2010||World's largest at the time. Corresponds to 80 MWAC.|
|Golmud, Qinghai,||China||200 MW||Oct 2011||World's largest at the time|
|Finow Tower||Germany||85 MW||Dec 2011||Extension takes it to Europe's largest|
|Lopburi||Thailand||73 MW||Dec 2011||Asia's largest (outside China) at the time|
|Perovo, Crimea||Ukraine||100 MW||Dec 2011||Becomes Europe's largest|
|Charanka, Gujarat||India||221 MW||Apr 2012||Asia's largest solar park|
|Agua Caliente, Arizona||USA||290 MWAC||Jul 2012||World's largest solar plant at the time|
|Neuhardenberg, Brandenburg||Germany||145 MW||Sep 2012||Becomes Europe's largest solar cluster|
|Greenhough River, Western Australia,||Australia||10 MW||Oct 2012||Australasia's first 10 MW+ plant|
|Majes and Repartición||Peru||22 MW||Oct 2012||First utility-scale plants in South America|
|Westmill Solar Park, Oxfordshire||United Kingdom||5 MW||Oct 2012||Acquired by Westmill Solar Co-operative to become world's largest community-owned solar power station|
|San Miguel Power, Colorado||USA||1.1 MW||Dec 2012||Biggest community-owned plant in USA|
|Sheikh Zayed, Nouakchott||Mauritania||15 MW||Apr 2013||Largest solar power plant in Africa|
|Topaz, Riverside County, California||USA||550 MWAC||Nov 2013||World's largest solar park at the time|
|Amanacer, Copiapó, Atacama||Chile||93.7 MW||Jan 2014||Largest in South America at the time|
|Jasper, Postmasburg, Northern Cape||South Africa||88 MW||Nov 2014||Largest plant in Africa|
|Longyangxia PV/Hydro power project, Gonghe, Qinghai||China||850 MWP||Dec 2014||Phase II of 530 MW added to 320 MW Phase I (2013) makes this the world's largest solar power station|
|Nyngan, New South Wales||Australia||102 MW||Jun 2015||Becomes largest plant in Australasia and Oceania|
|Solar Star, Los Angeles County, California||USA||579 MWAC||Jun 2015||Becomes the world's largest solar farm installation project (Longyanxia having been constructed in two phases)|
|Cestas, Aquitaine||France||300 MW||Dec 2015||Largest PV plant in Europe|
|Finis Terrae, María Elena, Tocopilla||Chile||138 MWAC||May 2016||Becomes largest plant in South America|
|Monte Plata Solar, Monte Plata||Dominican Republic||30 MW||March 2016||Largest PV plant in The Caribbean.|
|Ituverava, Ituverava, São Paulo||Brazil||210 MW||Sep 2017||Largest PV plant in South America|
|Bungala, Port Augusta, SA||Australia||220 MWAC||Nov 2018||Becomes Australasia's largest solar power plant|
|Noor Abu Dhabi, Sweihan, Abu Dhabi||United Arab Emirates||1,177 MWP||Jun 2019||The largest single solar power plant (as opposed to co-located group of projects) in Asia and the world.|
|Cauchari Solar Plant, Cauchari||Argentina||300 MW||Oct 2019||Becomes South America's largest solar power plant|
|Benban Solar Park, Benban, Aswan||Egypt||1,500 MW||Oct 2019||Group of 32 co-located projects becomes the largest in Africa.|
|Bhadla Solar Park, Bhadlachuhron Ki, Rajasthan||India||2,245 MW||Mar 2020||Group of 31 co-located solar plants reported to be the largest solar park in the world.|
|Núñez de Balboa solar plant, Usagre, Badajoz||Spain||500 MWAC||Mar 2020||Overtakes Mula Photovoltaic Power Plant (450 MWAC installed three months earlier) to become Europe's largest solar power plant.|
Solar power plants under development are not included here, but may be on this list.
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The locations of these and other plants over 10MW are illustrated in
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