Concentrator photovoltaics

Concentrator photovoltaics (CPV) (also known as concentration photovoltaics) is a photovoltaic technology that generates electricity from sunlight. Unlike conventional photovoltaic systems, it uses lenses or curved mirrors to focus sunlight onto small, highly efficient, multi-junction (MJ) solar cells. In addition, CPV systems often use solar trackers and sometimes a cooling system to further increase their efficiency.[2]:30

This Amonix system in Las Vegas, US, consists of thousands of small Fresnel lenses, each focusing sunlight to ~500X higher intensity onto a tiny, high-efficiency multi-junction solar cell.[1] A Tesla Roadster is parked beneath for scale.
Concentrator photovoltaics (CPV) modules on dual axis solar trackers in Golmud, China

Systems using high-concentration photovoltaics (HCPV) possess the highest efficiency of all existing PV technologies, achieving near 40% for production modules and 30% for systems.[3]:5 They enable a smaller photovoltaic array that has the potential to reduce land use, waste heat and material, and balance of system costs. The rate of annual CPV installations peaked in 2012 and has fallen to near zero since 2018 with the faster price drop in crystalline silicon photovoltaics.[4]:24 In 2016, cumulative CPV installations reached 350 megawatts (MW), less than 0.2% of the global installed capacity of 230,000 MW that year.[2]:10[3]:5[5][6]:21

HCPV directly competes with concentrated solar power (CSP) as both technologies are suited best for areas with high direct normal irradiance, which are also known as the Sun Belt region in the United States and the Golden Banana in Southern Europe.[6]:26 CPV and CSP are often confused with one another, despite being intrinsically different technologies from the start: CPV uses the photovoltaic effect to directly generate electricity from sunlight, while CSP – often called concentrated solar thermal – uses the heat from the sun's radiation in order to make steam to drive a turbine, that then produces electricity using a generator. As of 2012, CSP was more common than CPV.[7]

History

Research into concentrator photovoltaics has taken place since the mid 1970s, initially spurred on by the energy shock from a mideast oil embargo. Sandia National Laboratories in Albuquerque, New Mexico was the site for most of the early work, with the first modern-like photovoltaic concentrating system produced there late in the decade. Their first system was a linear-trough concentrator system that used a point focus acrylic Fresnel lens focusing on water-cooled silicon cells and two axis tracking. Cell cooling with a passive heat sink and use of silicone-on-glass Fresnel lenses was demonstrated in 1979 by the Ramón Areces Project at the Institute of Solar Energy of the Technical University of Madrid. The 350 kW SOLERAS project in Saudi Arabia – the largest until many years later – was constructed by Sandia/Martin Marietta in 1981.[8][9]

Research and development continued through the 1980s and 1990s without significant industry interest. Improvements in cell efficiency were soon recognized as essential to making the technology economical. However the improvements to Si-based cell technologies used by both concentrators and flat PV failed to favor the system-level economics of CPV. The introduction of III-V Multi-junction solar cells starting in the early 2000s has since provided a clear differentiator. MJ cell efficiencies have improved from 34% (3-junctions) to 46% (4-junctions) at research-scale production levels.[3]:14 A substantial number of multi-MW CPV projects have also been commissioned worldwide since 2010.[10]

In 2016, cumulative CPV installations reached 350 megawatts (MW), less than 0.2% of the global installed capacity of 230,000 MW.[2]:10[3]:5[5][6]:21 Commercial HCPV systems reached instantaneous ("spot") efficiencies of up to 42% under standard test conditions (with concentration levels above 400) [6]:26 and the International Energy Agency sees potential to increase the efficiency of this technology to 50% by the mid-2020s.[2]:28 As of December 2014, the best lab cell efficiency for concentrator MJ-cells reached 46% (four or more junctions). Under outdoor, operating conditions, CPV module efficiencies have exceeded 33% ("one third of a sun").[11] System-level AC efficiencies are in the range of 25–28%. CPV installations are located in China, the United States, South Africa, Italy and Spain.[3]:12

Challenges

Modern CPV systems operate most efficiently in highly concentrated sunlight (i.e. concentration levels equivalent to hundreds of suns), as long as the solar cell is kept cool through the use of heat sinks. Diffuse light, which occurs in cloudy and overcast conditions, cannot be highly concentrated using conventional optical components only (i.e. macroscopic lenses and mirrors). Filtered light, which occurs in hazy or polluted conditions, has spectral variations which produce mismatches between the electrical currents generated within the series-connected junctions of spectrally "tuned" multi-junction (MJ) photovoltaic cells.[12] These CPV features lead to rapid decreases in power output when atmospheric conditions are less than ideal.

To produce equal or greater energy per rated watt than conventional PV systems, CPV systems must be located in areas that receive plentiful direct sunlight. This is typically specified as average DNI (Direct Normal Irradiance) greater than 5.5-6m kWh/m2/day or 2000 kWh/m2/yr. Otherwise, evaluations of annualized DNI vs. GNI/GHI (Global Normal Irradiance and Global Horizontal Irradiance) irradiance data have concluded that conventional PV should still perform better over time than presently available CPV technology in most regions of the world (see for example [13]).

CPV StrengthsCPV Weaknesses
High efficiencies under direct normal irradianceHCPV cannot utilize diffuse radiation. LCPV can only utilize a fraction of diffuse radiation.
Low cost per watt of manufacturing capitalPower output of MJ solar cells is more sensitive to shifts in radiation spectra caused by changing atmospheric conditions.
Low temperature coefficientsTracking with sufficient accuracy and reliability is required.
No cooling water required for passively cooled systemsMay require frequent cleaning to mitigate soiling losses, depending on the site
Additional use of waste heat possible for systems with active cooling possible (e.g.large mirror systems)Limited market – can only be used in regions with high DNI, cannot be easily installed on rooftops
Modular – kW to GW scaleStrong cost decrease of competing technologies for electricity production
Increased and stable energy production throughout the day due to (two-axis) trackingBankability and perception issues
Low energy payback timeNew generation technologies, without a history of production (thus increased risk)
Potential double use of land e.g. for agriculture, low environmental impactOptical losses
High potential for cost reductionLack of technology standardization
Opportunities for local manufacturing
Smaller cell sizes could prevent large fluctuations in module price due to variations in semiconductor prices
Greater potential for efficiency increase in the future compared to single-junction flat plate systems could lead to greater improvements in land area use, BOS costs, and BOP costs
Source: Current Status of CPV report, January 2015.[3]:8 Table 2: Analysis of the strengths and weaknesses of CPV.

Ongoing research and development

International CPV-x Conference - Historical Participation Statistics. Data Source - CPV-x Proceedings

CPV research and development has been pursued in over 20 countries for more than a decade. The annual CPV-x conference series has served as a primary networking and exchange forum between university, government lab, and industry participants. Government agencies have also continued to encourage a number of specific technology thrusts.

ARPA-E announced a first round of R&D funding in late 2015 for the MOSAIC Program (Microscale Optimized Solar-cell Arrays with Integrated Concentration) to further combat the location and expense challenges of existing CPV technology. As stated in the program description: "MOSAIC projects are grouped into three categories: complete systems that cost effectively integrate micro-CPV for regions such as sunny areas of the U.S. southwest that have high Direct Normal Irradiance (DNI) solar radiation; complete systems that apply to regions, such as areas of the U.S. Northeast and Midwest, that have low DNI solar radiation or high diffuse solar radiation; and concepts that seek partial solutions to technology challenges."[14]

In Europe the CPVMATCH Program (Concentrating PhotoVoltaic Modules using Advanced Technologies and Cells for Highest efficiencies) aims "to bring practical performance of HCPV modules closer to theoretical limits". Efficiency goals achievable by 2019 are identified as 48% for cells and 40% for modules at >800x concentration.[15] A 41.4% module efficiency was announced at the end of 2018.[16]

The Australian Renewable Energy Agency (ARENA) extended its support in 2017 for further commercialization of the HCPV technology developed by Raygen.[17] Their 250 kW dense array receivers are the most powerful CPV receivers thus far created, with demonstrated PV efficiency of 40.4% and include usable heat co-generation.[18]

A low concentrating solar device that includes its own internal tracker, is in development by ISP Solar which will enhance the efficiency of solar cell at low cost.[19]

Efficiency

Reported records of solar cell efficiency since 1975. As of December 2014, best lab cell efficiency reached 46% (for multi-junction concentrator, 4+ junctions).

According to theory, semiconductor properties allow solar cells to operate more efficiently in concentrated light than they do under a nominal level of solar irradiance. This is because, along with a proportional increase in the generated current, there also occurs a logarithmic enhancement in operating voltage, in response to the higher illumination.[20]

To be explicit, consider the power (P) generated by a solar cell under "one-sun" illumination at the earth's surface, which corresponds to a peak solar irradiance Q=1000 Watts/m2.[21] The cell power can be expressed as a function of the open-circuit voltage (Voc), the short-circuit current (Isc), and the fill factor (FF) of the cell's characteristic current–voltage (I-V) curve:[22]

Upon increased illumination of the cell at "χ-suns", corresponding to concentration (χ) and irradiance (χQ), there can be similarly expressed:

where, as shown by reference:[20]

and

Note that the unitless fill factor for a "high quality" solar cell typically ranges 0.75–0.9 and can, in practice, depend primarily on the equivalent shunt and series resistances for the particular cell construction.[23] For concentrator applications, FF and FFχ should then have similar values that are both near unity, corresponding to high shunt resistance and very low series resistance (<1 milliohm).[24]

The efficiencies of a cell of area (A) under one-sun and χ-suns are defined as:[25]

and

The efficiency under concentration is then given in terms of χ and the cell characteristics as:[20]

where the term kT/q is the voltage (called the thermal voltage) of a thermalized population of electrons – such as that flowing through a solar cell's p-n junction – and has a value of about 25.85 mV at room temperature (300 K).[26]

The efficiency enhancement of ηχ relative to η is listed in the following table for a set of typical open-circuit voltages that roughly represent different cell technologies. The table shows that the enhancement can be as much as 20-30% at χ = 1000 concentration. The calculation assumes FFχ/FF=1; an assumption which is clarified in the following discussion.

Theoretical Cell Efficiency Increase Due to Sunlight Concentration
Cell
Technology
Multi-crystal
Silicon
Mono-crystal
Silicon
Triple-junction
III-V on GaAs
Approximate
Junction Voc
550 mV700 mV850 mV
χ = 10 10.8%8.5%7.0%
χ = 100 21.6%17.0%14.0%
χ = 1000 32.5%25.5%21.0%

In practice, the higher current densities and temperatures which arise under sunlight concentration may be challenging to prevent from degrading the cell's I-V properties or, worse, causing permanent physical damage. Such effects can reduce the ratio FFχ/FF by an even larger percentage below unity than the tabulated values shown above. To prevent irreversible damage, the rise in cell operating temperature under concentration must be controlled with the use of a suitable heat sink. Additionally, the cell design itself must incorporate features that reduce recombination and the contact, electrode, and busbar resistances to levels that accommodate the target concentration and resulting current density. These features include thin, low-defect semiconductor layers; thick, low-resistivity electrode & busbar materials; and small (typically <1 cm2) cell sizes.[27]

Including such features, the best thin film multi-junction photovoltaic cells developed for terrestrial CPV applications achieve reliable operation at concentrations as high as 500–1000 suns (i.e. irradiances of 50-100 Watts/cm2).[28][29] As of year 2014, their efficiencies are upwards of 44% (three junctions), with the potential to approach 50% (four or more junctions) in the coming years .[30] The theoretical limiting efficiency under concentration approaches 65% for 5 junctions, which is a likely practical maximum.[31]

Optical design

All CPV systems have a solar cell and a concentrating optic. Optical sunlight concentrators for CPV introduce a very specific design problem, with features that make them different from most other optical designs. They have to be efficient, suitable for mass production, capable of high concentration, insensitive to manufacturing and mounting inaccuracies, and capable of providing uniform illumination of the cell. All these reasons make nonimaging optics[32][33] the most suitable for CPV. Non-imaging optics is often used for various lighting applications. In order to achieve high efficiency, glass with high transmission is required and proper manufacturing process needs to be used to ensure shape precision.[34]

For very low concentrations, the wide acceptance angles of nonimaging optics avoid the need for active solar tracking. For medium and high concentrations, a wide acceptance angle can be seen as a measure of how tolerant the optic is to imperfections in the whole system. It is vital to start with a wide acceptance angle since it must be able to accommodate tracking errors, movements of the system due to wind, imperfectly manufactured optics, imperfectly assembled components, finite stiffness of the supporting structure or its deformation due to aging, among other factors. All of these reduce the initial acceptance angle and, after they are all factored in, the system must still be able to capture the finite angular aperture of sunlight.

Types

CPV systems are categorized according to the amount of their solar concentration, measured in "suns" (the square of the magnification).

Low concentration PV (LCPV)

An example of a Low Concentration PV Cell's surface, showing the glass lensing

Low concentration PV are systems with a solar concentration of 2–100 suns.[35] For economic reasons, conventional or modified silicon solar cells are typically used. The heat flux is typically low enough that the cells do not need to be actively cooled. For standard solar modules, there is also modeling and experimental evidence that no tracking or cooling modifications are needed if the concentration level is low [36]

Low-concentration systems often have a simple booster reflector, which can increase solar electric output by over 30% from that of non-concentrator PV systems.[37][36] Experimental results from such LCPV systems in Canada resulted in energy gains over 40% for prismatic glass and 45% for traditional crystalline silicon PV modules.[38]

Medium concentration PV

From concentrations of 100 to 300 suns, the CPV systems require two-axis solar tracking and cooling (whether passive or active), which makes them more complex.

A 10×10 mm HCPV solar cell

High concentration PV (HCPV)

High concentration photovoltaics (HCPV) systems employ concentrating optics consisting of dish reflectors or fresnel lenses that concentrate sunlight to intensities of 1,000 suns or more.[30] The solar cells require high-capacity heat sinks to prevent thermal destruction and to manage temperature related electrical performance and life expectancy losses. To further exacerbate the concentrated cooling design, the heat sink must be passive, otherwise the power required for active cooling will reduce the overall conversion efficiency and economy. Multi-junction solar cells are currently favored over single junction cells, as they are more efficient and have a lower temperature coefficient (less loss in efficiency with an increase in temperature). The efficiency of both cell types rises with increased concentration; multi-junction efficiency rises faster. Multi-junction solar cells, originally designed for non-concentrating PV on space-based satellites, have been re-designed due to the high-current density encountered with CPV (typically 8 A/cm2 at 500 suns). Though the cost of multi-junction solar cells is roughly 100 times that of conventional silicon cells of the same area, the small cell area employed makes the relative costs of cells in each system comparable and the system economics favor the multi-junction cells. Multi-junction cell efficiency has now reached 44% in production cells.

The 44% value given above is for a specific set of conditions known as "standard test conditions". These include a specific spectrum, an incident optical power of 850 W/m2, and a cell temperature of 25 °C. In a concentrating system, the cell will typically operate under conditions of variable spectrum, lower optical power, and higher temperature. The optics needed to concentrate the light have limited efficiency themselves, in the range of 75–90%. Taking these factors into account, a solar module incorporating a 44% multi-junction cell might deliver a DC efficiency around 36%. Under similar conditions, a crystalline silicon module would deliver an efficiency of less than 18%.

When high concentration is needed (500–1000 times), as occurs in the case of high efficiency multi-junction solar cells, it is likely that it will be crucial for commercial success at the system level to achieve such concentration with a sufficient acceptance angle. This allows tolerance in mass production of all components, relaxes the module assembling and system installation, and decreasing the cost of structural elements. Since the main goal of CPV is to make solar energy inexpensive, there are only a few surfaces that can be used. Decreasing the number of elements and achieving high acceptance angle, can be relaxed optical and mechanical requirements, such as accuracy of the optical surfaces profiles, the module assembling, the installation, the supporting structure, etc. To this end, improvements in sun-shape modelling at the system design stage may lead to higher system efficiencies.[39]

Reliability

The higher capital costs, lesser standardization, and added engineering & operational complexities (in comparison to zero and low-concentration PV technologies) make long-life performance a critical demonstration goal for the first generations of CPV technologies. Performance certification standards (UL 3703,UL 8703, IEC 62108, IEC 62670, IEC 62789, and IEC 62817) include stress testing conditions that may be useful to uncover some predominantly infant and early life (<1–2 year) failure modes at the system, tracker, module, receiver, and other sub-component levels.[40] However, such standardized tests – as typically performed on only a small sampling of units – are generally incapable to evaluate comprehensive long-term lifetimes (10 to 25 or more years) for each unique system design and application under its broader range of actual – and occasionally unanticipated – operating conditions. Reliability of these complex systems is therefore assessed in the field, and is improved through aggressive product development cycles which are guided by the results of accelerated component/system aging, performance monitoring diagnostics, and failure analysis.[41] Significant growth in the deployment of CPV can be anticipated once the concerns are better addressed to build confidence in system bankability.[42][43]

Tracker durability and maintenance

The tracker and module support structure for a modern HCPV system must each remain accurate within 0.1°-0.3° in order to keep the solar resource adequately centered within the acceptance angle of the receiver collection optics, and thus concentrated onto the PV cells.[44] This is a challenging requirement for any mechanical system that is subjected to the stresses of varying movements and loads.[45] Economical procedures for periodic realignment and maintenance of the tracker may thus be required to preserve system performance over its expected lifetime.[46]

Receiver temperature control

The maximum multi-junction solar cell operating temperatures (Tmax cell) of HCPV systems are limited to less than about 110 °C on account of their intrinsic reliability limitation.[47][29][28] This contrasts to CSP and other CHP systems which may be designed to function at temperatures in excess of several hundred degrees. More specifically, the cells are fabricated from a layering of thin-film III-V semiconductor materials having intrinsic lifetimes during operation that rapidly decrease with an Arrhenius-type temperature dependence. The system receiver must therefore provide for highly efficient and uniform cell cooling through sufficiently robust active and/or passive methods. In addition to material and design limitations in receiver heat-transfer performance, other extrinsic factors – such as the frequent system thermal cycling – further reduce the practical Tmax receiver compatible with long system life to below about 80 °C.[48][49][50]

Installations

Concentrator photovoltaics technology established its presence in the solar industry during the period 2006 to 2015. The first HCPV power plant that exceeded 1 MW-level was commissioned in Spain in 2006. By the end of 2015, the number of CPV power plants (including both LCPV and HCPV) around the world accounted for a total installed capacity of 350 MW. Field data collected from a diversity of installations since about 2010 is also benchmarking system reliability over the long term.[51]

Cumulative CPV Installations in MW by country by November 2014[3]:12
Yearly Installed CPV Capacity in MW from 2002 to 2015[3][6]
Yearly Installed PV Capacity in GW from 2002 to 2015[6]

The emerging CPV segment has comprised ~0.1% of the fast-growing utility market for PV installations over the decade up to 2017. Unfortunately, following a rapid drop in traditional flat-panel PV prices, the near term outlook for CPV industry growth has faded as signaled by closure of the largest HCPV manufacturing facilities: including those of Suncore, Soitec, Amonix, and SolFocus.[52][53][54][55][56][57][58][59] The higher cost and complexity of maintaining the precision HCPV dual-axis trackers has also been reported in some instances to be especially challenging.[60][46] Nevertheless, the growth outlook for the PV industry as a whole continues to be strong, thus providing continued optimism that CPV technology will eventually demonstrate its place.[3][6]

List of largest HCPV systems

Field testing a system at a CPV powerplant

Similar to traditional PV, the peak DC rating of a system is specified as MWp (or sometimes MWDC) under concentrator standard test conditions (CSTC) of DNI=1000 W/m2, AM1.5D, & Tcell=25 °C, as per the IEC 62670 standard convention.[61] The AC production capacity is specified as MWAC under IEC 62670 concentrator standard operating conditions (CSOC) of DNI=900 W/m2, AM1.5D, Tambient=20 °C, & Wind speed=2 m/s, and may include adjustments for inverter efficiency, higher/lower solar resource, and other facility-specific factors. The largest CPV power plant currently in operation is of 138 MWp rating located in Golmud, China, hosted by Suncore Photovoltaics.

Power stationRating
(MWp)
Capacity
(MWAC)
Year
Completed
LocationCPV
Vendor
Ref
Golmud (1 and 2)137.81102012–2013in Golmud/Qinghai province/ChinaSuncore[62][63]
Touwsrivier CPV Project44.2362014in Touwsrivier/Western Cape/South AfricaSoitec[64]
Alamosa Solar Project35.3302012in Alamosa, Colorado/San Luis Valley/USAmonix[65]
Hami (1, 2, and 3)10.59.02013–2016in Hami/Xinjiang province/ChinaSoitec-Focusic[66][67][68]
Navarra CPV Plant9.17.82010in Villafranca/Navarra province/SpainAmonix-Guascor Foton[69][70]
Source: The CPV Consortium[10]

List of HCPV systems in United States

Power stationRating
(MWp)
Capacity
(MWAC)
Year
Completed
LocationCPV
Vendor
Owner/OperatorRef
Alamosa Solar Project35.3302012Alamosa, ColoradoAmonixCogentrix[65]
Desert Green Solar Farm7.806.32014Borrego Spgs, CaliforniaSoitecInvenergy[71]
Hatch Solar Energy Center5.885.02011Hatch, New MexicoAmonixNextEra Energy[72]
University of Arizona CPV Array2.382.02011Tucson, ArizonaAmonixArzon Solar[73]
Newberry Springs CPV Power Plant1.681.52013Newberry Spgs, CaliforniaSoitecSTACE[74]
Crafton Hills College Solar Farm1.611.32012Yucaipa, CaliforniaSolFocusCrafton Hills College[75]
Victor Valley College Solar Farm1.261.02010Victorville, CaliforniaSolFocusVictor Valley College[76]
Eubank Landfill Solar Array1.211.02013Albuquerque, New MexicoSuncoreEmcore Solar[77]
Questa Solar Facility1.171.02010Questa, New MexicoSoitecChevron[78]
Fort Irwin CPV Project1.121.02015Fort Irwin, CaliforniaSoitecUS DOD[79][60]
Source: The CPV Consortium[10]

List of LCPV systems in United States

Power stationCapacity
(MWAC)
Year
Completed
LocationCoordinatesCPV
Vendor
Owner/OperatorRef
Fort Churchill Solar Array19.92015Yerington, Nevada39°07′41″N 119°08′24″WSunPowerApple Inc./ NV Energy[80]
Springerville Solar Farm6.02013Springerville, Arizona34°17′40″N 109°16′17″WSunPowerTucson Electric Power[81]
ASU Polytechnic CPV Array1.02012Mesa, Arizona33°17′37″N 111°40′38″WSunPowerSunPower[82]

Concentrated photovoltaics and thermal

Concentrator photovoltaics and thermal (CPVT), also sometimes called combined heat and power solar (CHAPS) or hybrid thermal CPV, is a cogeneration or micro cogeneration technology used in the field of concentrator photovoltaics that produces usable heat and electricity within the same system. CPVT at high concentrations of over 100 suns (HCPVT) utilizes similar components as HCPV, including dual-axis tracking and multi-junction photovoltaic cells. A fluid actively cools the integrated thermal–photovoltaic receiver, and simultaneously transports the collected heat.

Typically, one or more receivers and a heat exchanger operate within a closed thermal loop. To maintain efficient overall operation and avoid damage from thermal runaway, the demand for heat from the secondary side of the exchanger must be consistently high. Collection efficiencies exceeding 70% are anticipated under optimal operating conditions, with up to 35% electric and exceeding 40% thermal for HCPVT.[83] Net operating efficiencies may be substantially lower depending on how well a system is engineered to match the demands of the particular thermal application.

The maximum temperature of CPVT systems is too low, typically below 80–90 °C, to alone power a boiler for additional steam-based cogeneration of electricity. These very low temperatures compared to CSP systems also make CPVT less compatible with efficient and economic thermal energy storage (TES).[84] The captured thermal energy may nevertheless be directly employed in district heating, water heating and air conditioning, desalination or process heat. For thermal applications having lower or intermittent demand, a system may be augmented with a switchable heat dump to the external environment in order to safeguard cell life and maintain reliable photovoltaic output, despite the resulting reduction in net operating efficiency.

HCPVT active cooling enables the use of much higher power thermal–photovoltaic receiver units, generating typically 1–100 kilowatts (kW) electric, as compared to HCPV systems that mostly rely upon passive cooling of single ~20 W cells. Such high-power receivers utilize dense arrays of cells mounted on a high-efficiency heat sink.[85] Minimizing the number of individual receiver units is a simplification that may ultimately yield improvement in the overall balance of system costs, manufacturability, maintainability/upgradeability, and reliability.[86] A system combining receivers sized up to 1 MWelectric/2 MWthermal with TES using an accompanying organic Rankine cycle generator to provide electricity on demand[87][88] operated in 2023 in Australia, at a combined 4 MW power and 51 MWh storage.[89]

This 240 x 80 mm 1,000 suns CPV heat sink design thermal animation, was created using high resolution CFD analysis, and shows temperature contoured heat sink surface and flow trajectories as predicted.

Demonstration projects

The economics of a mature CPVT industry is anticipated to be competitive, despite the large recent cost reductions and gradual efficiency improvements for conventional silicon PV (which can be installed alongside conventional CSP to provide for similar electrical+thermal generation capabilities).[3] CPVT may currently be economical for niche markets having all of the following application characteristics:

  • high solar direct normal irradiance (DNI)
  • tight space constraints for placement of a solar collector array
  • high and constant demand for low-temperature (<80 °C) heat
  • high cost of grid electricity
  • access to backup sources of power or cost-efficient storage (electrical and thermal)

Utilization of a power purchase agreement (PPA), government assistance programs, and innovative financing schemes are also helping potential manufacturers and users to mitigate the risks of early CPVT technology adoption.

CPVT equipment offerings ranging from low (LCPVT) to high (HCPVT) concentration are now being deployed by several startup ventures. As such, longer-term viability of the technical and/or business approach being pursued by any individual system provider is typically speculative. Notably, the minimum viable products of startups can vary widely in their attention to reliability engineering. Nevertheless, the following incomplete compilation is offered to assist with the identification of some early industry trends.

LCPVT systems at ~14x concentration using reflective trough concentrators, and receiver pipes clad with silicon cells having dense interconnects, have been assembled by Cogenra with a claimed 75% efficiency (~15-20% electric, 60% thermal).[90] Several such systems are in operation for more than five years as of 2015, and similar systems are being produced by Absolicon[91] and Idhelio[92] at 10x and 50x concentration, respectively.

HCPVT offerings at over 700x concentration have more recently emerged, and may be classified into three power tiers. Third tier systems are distributed generators consisting of large arrays of ~20W single-cell receiver/collector units, similar to those previously pioneered by Amonix and SolFocus for HCPV. Second tier systems utilize localized dense-arrays of cells that produce 1–100 kW of electrical power output per receiver/generator unit. First tier systems exceed 100 kW of electrical output and are most aggressive in targeting the utility market.

Several HCPVT system providers are listed in the following table. Nearly all are early demonstration systems which have been in service for under five years as of 2015. Collected thermal power is typically 1.5x-2x the rated electrical power.

Provider Country Concentrator Type Unit Size in  kWe Ref
Generator Receiver
- Tier 1 -
RaygenAustraliaLarge Heliostat Array250250[18]
- Tier 2 -
Airlight Energy/dsolarSwitzerlandLarge Dish1212[93][94][95]
RehnuUnited StatesLarge Dish6.40.8[96]
SolartronCanadaLarge Dish2020[97]
Southwest SolarUnited StatesLarge Dish2020[98]
Sun OysterGermanyLarge Trough + Lens4.72.35[99]
Zenith Solar/SuncoreIsrael/China/USLarge Dish4.52.25[100][101]
- Tier 3 -
BSQ SolarSpainSmall Lens Array13.440.02[102]
Silex PowerMaltaSmall Dish Array160.04[103]
SolergyItaly/USSmall Lens Array200.02[104]

See also

References

  1. 500x concentration ratio is claimed at Amonix website Archived 2018-12-29 at the Wayback Machine.
  2. "Technology Roadmap: Solar Photovoltaic Energy" (PDF). IEA. 2014. Archived from the original (PDF) on 1 October 2014. Retrieved 7 October 2014.
  3. Fraunhofer ISE and NREL (January 2015). "Current Status of Concentrator Photovoltaic (CPV) Technology" (PDF). Archived from the original (PDF) on 11 February 2017. Retrieved 25 April 2015.
  4. "Photovoltaics Report" (PDF). Fraunhofer ISE. 16 September 2020. Archived (PDF) from the original on 9 August 2014. Retrieved 5 January 2021.
  5. "Snapshot of Global PV 1992-2013" (PDF). www.iea-pvps.org/. International Energy Agency - Photovoltaic Power Systems Programme. 2014. Archived from the original (PDF) on 30 November 2014. Retrieved 4 February 2015.
  6. "Photovoltaics Report" (PDF). Fraunhofer ISE. 28 July 2014. Archived from the original (PDF) on 9 August 2014. Retrieved 31 August 2014.
  7. PV-insider.com How CPV trumps CSP in high DNI locations Archived 2014-11-22 at the Wayback Machine, 14 February 2012
  8. López, Antonio Luque; Andreev, Viacheslav M. (2007). Past Experiences and New Challenges of PV Concentrators, G Sala and A Luque, Springer Series in Optical Sciences 130, 1, (2007). Vol. 130. doi:10.1007/978-3-540-68798-6. ISBN 978-3-540-68796-2. Archived from the original on 2021-10-24. Retrieved 2018-12-21.
  9. "The Promise of Concentrators, R M Swanson, Prog. Photovolt. Res. Appl. 8, 93-111 (2000)" (PDF). Archived from the original (PDF) on 2017-08-08. Retrieved 2017-03-03.
  10. "The CPV Consortium - Projects". Archived from the original on 2016-03-10. Retrieved 2015-03-24.
  11. Kinsey, G. S.; Bagienski, W.; Nayak, A.; Liu, M.; Gordon, R.; Garboushian, V. (2013-04-01). "Advancing Efficiency and Scale in CPV Arrays". IEEE Journal of Photovoltaics. 3 (2): 873–878. doi:10.1109/JPHOTOV.2012.2227992. ISSN 2156-3381. S2CID 21815258.
  12. Fernández, Eduardo F.; Almonacid, F.; Ruiz-Arias, J.A.; Soria-Moya, A. (August 2014). "Analysis of the spectral variations on the performance of high concentrator photovoltaic modules operating under different real climate conditions". Solar Energy Materials & Solar Cells. 127: 179–187. doi:10.1016/j.solmat.2014.04.026.
  13. Jo, Jin Ho; Waszak, Ryan; Shawgo, Michael (2014). "Feasibility of Concentrated Photovoltaic Systems (CPV) in Various United States Geographic Locations". Energy Technology & Policy. 1 (1): 84–90. doi:10.1080/23317000.2014.971982. S2CID 108844215.
  14. "MOSAIC Project Descriptions" (PDF). Archived (PDF) from the original on 2017-01-23. Retrieved 2017-01-20.
  15. "CPVMatch". Archived from the original on 2019-07-13. Retrieved 2019-07-31.
  16. "Fraunhofer ISE Led Consortium Achieves 41.4% Module Efficiency For Concentrator Photovoltaics Using Multi-Junction Solar Cells In European Union Funded Project". 23 November 2018. Archived from the original on 7 February 2019. Retrieved 4 February 2019.
  17. "ARENA Raygen". Archived from the original on 2018-08-13. Retrieved 2018-08-13.
  18. "RayGen". Archived from the original on 2015-05-20. Retrieved 2015-05-18.
  19. "The next big solar technology". 6 February 2020. Archived from the original on 11 March 2020. Retrieved 9 February 2020.
  20. Gray, Jeffery (2003), "The Physics of the Solar Cell", in Luque, Antonio; Hegedus, Steven (eds.), Handbook of Photovoltaic Science and Engineering, London: John Wiley & Sons, pp. 61–112
  21. "PV Education - Average Solar Radiation". Archived from the original on May 8, 2019. Retrieved March 3, 2019.
  22. "PV Education - Solar Cell Efficiency". Archived from the original on May 8, 2019. Retrieved February 22, 2019.
  23. "PV Education - Fill Factor". Archived from the original on May 8, 2019. Retrieved March 3, 2019.
  24. D. L. Pulfrey (1978). "On the fill factor of solar cells". Solid State Electronics. 21 (3): 519–520. Bibcode:1978SSEle..21..519P. doi:10.1016/0038-1101(78)90021-7. ISSN 0038-1101.
  25. Keith Emery and Carl Osterwald (1987). "Measurement of photovoltaic device current as a function of voltage, temperature, intensity and spectrum". Solar Cells. 21 (1–4): 313–327. Bibcode:1987SoCe...21..313E. doi:10.1016/0379-6787(87)90130-X. ISSN 0927-0248.
  26. Rashid, Muhammad H. (2016). Microelectronic circuits : analysis and design (Third ed.). Cengage Learning. pp. 183–184. ISBN 9781305635166.
  27. Yupeng Xing; et al. (2015). "A review of concentrator silicon solar cells". Renewable and Sustainable Energy Reviews. 51: 1697–1708. doi:10.1016/j.rser.2015.07.035. ISSN 1364-0321.
  28. "Data Sheet-Spectrolab C3P5 39.5% Solar Cell" (PDF). Archived (PDF) from the original on 20 January 2019. Retrieved 19 January 2019.
  29. "Data Sheet-Spectrolab C4MJ 40% Solar Cell" (PDF). Archived (PDF) from the original on 19 January 2019. Retrieved 19 January 2019.
  30. S. Kurtz. "Opportunities and Challenges for Development of a Mature Concentrating Photovoltaic Power Industry" (PDF). www.nrel.gov. p. 5 (PDF: p. 8). Archived (PDF) from the original on 2021-10-24. Retrieved 2019-01-13.
  31. N.V.Yastrebova (2007). High-efficiency multi-junction solar cells: current status and future potential (PDF). Archived (PDF) from the original on 2017-08-08. Retrieved 2017-03-13.
  32. Chaves, Julio (2015). Introduction to Nonimaging Optics, Second Edition. CRC Press. ISBN 978-1482206739. Archived from the original on 2016-02-18. Retrieved 2016-02-12.
  33. Roland Winston et al., Nonimaging Optics, Academic Press, 2004 ISBN 978-0127597515
  34. "Solar power plants | EcoGlass". Archived from the original on 2021-10-06. Retrieved 2021-10-06.
  35. A Strategic Research Agenda for Photovoltaic Solar Energy Technology Archived 2010-07-05 at the Wayback Machine Photovoltaic technology platform
  36. Andrews, Rob W.; Pollard, Andrew; Pearce, Joshua M. (2013). "Photovoltaic system performance enhancement with non-tracking planar concentrators: Experimental results and BDRF based modelling" (PDF). 2013 IEEE 39th Photovoltaic Specialists Conference (PVSC). pp. 0229–0234. doi:10.1109/PVSC.2013.6744136. ISBN 978-1-4799-3299-3. S2CID 32127698. Archived (PDF) from the original on 2020-03-10. Retrieved 2019-12-03.
  37. Rob Andrews, Nabeil Alazzam, and Joshua M. Pearce, "Model of Loss Mechanisms for Low Optical Concentration on Solar Photovoltaic Arrays with Planar Reflectors Archived 2021-10-24 at the Wayback Machine", 40th American Solar Energy Society National Solar Conference Proceedings, pp. 446-453 (2011).free and open access ,
  38. Andrews, R.W.; Pollard, A.; Pearce, J.M., "Photovoltaic System Performance Enhancement With Nontracking Planar Concentrators: Experimental Results and Bidirectional Reflectance Function (BDRF)-Based Modeling," IEEE Journal of Photovoltaics 5(6), pp.1626-1635 (2015). DOI: 10.1109/JPHOTOV.2015.2478064 Archived 2021-10-24 at the Wayback Machine open access Archived 2017-11-22 at the Wayback Machine
  39. Cole, IR; Betts, TR; Gottschalg, R (2012), "Solar profiles and spectral modeling for CPV simulations", IEEE Journal of Photovoltaics, 2 (1): 62–67, doi:10.1109/JPHOTOV.2011.2177445, ISSN 2156-3381, S2CID 42900625
  40. "IEC 61215: What it is and isn't" (PDF). Archived (PDF) from the original on 2017-02-15. Retrieved 2019-01-13.
  41. Spencer, M; Kearney, A; Bowman, J (2012), "Compact CPV-hydrogen system to convert sunlight to hydrogen", AIP Conference Proceedings, 1477: 272–275, doi:10.1063/1.4753884, ISSN 1551-7616
  42. Concentrated Photovoltaics Update 2014 Archived 2015-01-15 at the Wayback Machine, GlobalData Market Research Report
  43. Gupta, R (2013), "CPV: Expansion and Bankability Required", Renewable Energy Focus, 14 (4): 12–13, doi:10.1016/s1755-0084(13)70064-4, ISSN 1755-0084
  44. Burhan, M; Shahzad, MW; Choon, NK (2018), "Compact CPV-hydrogen system to convert sunlight to hydrogen", Applied Thermal Engineering, 132: 154–164, doi:10.1016/j.applthermaleng.2017.12.094, hdl:10754/626742, ISSN 1359-4311, S2CID 116055639
  45. Ignacio Luque-Heredia, Pedro Magalhães, and Matthew Muller, Chapter 6: CPV Tracking and Trackers. In: Handbook of Concentrator Photovoltaic Technology, C. Algora and I. Rey-Stolle editors, 2016, Pages 293-333, doi:10.1002/9781118755655.ch06, ISBN 978-1118472965
  46. "CPV Trackers: A Crucial Aspect of Project Success?". 3 September 2012. Archived from the original on 13 January 2019. Retrieved 5 February 2019.
  47. Ermer, JH; Jones, RK; Hebert, P; Pien, P; King, RR; Bhusari, D; Brandt, R; Al-Taher, O; Fetzer, C; Kinsey, GS; Karam, N (2012), "Status of C3MJ+ and C4MJ Production Concentrator Solar Cells at Spectrolab", IEEE Journal of Photovoltaics, 2 (2): 209–213, doi:10.1109/JPHOTOV.2011.2180893, ISSN 2156-3381, S2CID 22904649
  48. Espinet-Gonzalez, P; Algora, C; Nunez, N; Orlando, V; Vazquez, M; Bautista, J; Araki, K (2013), "Evaluation of the reliability of commercial concentrator triple-junction solar cells by means of accelerated life tests", AIP Conference Proceedings, 1556: 222–225, doi:10.1063/1.4822236, ISSN 1551-7616
  49. C, Nunez; N, Gonzalez; JR, Vazquez; P, Algora; C, Espinet, P (2013), "Evaluation of the reliability of high concentrator GaAs solar cells by means of temperature accelerated aging tests", Progress in Photovoltaics, 21 (5): 1104–1113, doi:10.1002/pip.2212, ISSN 1099-159X, S2CID 97772907, archived from the original on 2019-11-25, retrieved 2019-12-03{{citation}}: CS1 maint: multiple names: authors list (link)
  50. N. Bosco, C. Sweet, and S. Kurtz. "Reliability Testing the Die-Attach of CPV Cell Assemblies" (PDF). www.nrel.gov. Archived (PDF) from the original on 2016-12-29. Retrieved 2019-01-13.{{cite web}}: CS1 maint: multiple names: authors list (link)
  51. Gerstmaier, T; Zech, T; Rottger, M; Braun, C; Gombert, A (2015). "Large-scale and long-term CPV power plant field results". AIP Conference Proceedings. 1679 (1): 030002. Bibcode:2015AIPC.1679c0002G. doi:10.1063/1.4931506.
  52. Eric Wesoff, "Amonix Plant Closure: Death Rattle for CPV Solar Industry? Archived 2019-01-14 at the Wayback Machine, 20 July 2012
  53. Eric Wesoff, "CPV: Amonix Founder Speaks, Blames VCs, Laments Lack of Supply Chain Archived 2019-01-14 at the Wayback Machine, 27 June 2013
  54. Eric Wesoff, "CPV Startup SolFocus Joins List of Deceased Solar Companies Archived 2019-01-15 at the Wayback Machine, 05 September 2013
  55. Eric Wesoff, "Rest in Peace: The List of Deceased Solar Companies, 2009 to 2013 Archived 2019-01-19 at the Wayback Machine, 01 December 2013
  56. Eric Wesoff, "Soitec, SunPower and Suncore: The Last CPV Vendors Standing Archived 2015-03-12 at the Wayback Machine, 29 October 2014
  57. Eric Wesoff, "CPV Hopeful Soitec Latest Victim of the Economics of Silicon Photovoltaics Archived 2019-03-06 at the Wayback Machine, 22 December 2014
  58. Eric Wesoff, "CPV Hopeful Soitec Exits the Solar Business Archived 2019-01-19 at the Wayback Machine, 25 January 2015
  59. Eric Wesoff, "Is Time Running Out for CPV Startup Semprius? Archived 2019-01-14 at the Wayback Machine, 03 January 2017
  60. "ESTCP Cost and Performance Report" (PDF). March 2018. Archived (PDF) from the original on 24 October 2021. Retrieved 5 February 2012.
  61. "Photovoltaic concentrators (CPV) - Performance testing - Part 1: Standard conditions". www.iec.ch. Archived from the original on 2019-01-24. Retrieved 2019-01-20.
  62. "Golmud 1". Archived from the original on 2016-12-10. Retrieved 2015-04-25.
  63. "Golmud 2". Archived from the original on 2016-11-09. Retrieved 2015-04-25.
  64. "Touwsrivier". Archived from the original on 2017-01-01. Retrieved 2016-12-31.
  65. "Alamosa". Archived from the original on 2015-02-15. Retrieved 2015-04-25.
  66. "Hami Phase 1". Archived from the original on 2019-01-14. Retrieved 2019-01-18.
  67. "Hami Phase 2". Archived from the original on 2019-01-20. Retrieved 2019-01-19.
  68. "Hami Phase 3". Archived from the original on 2019-01-20. Retrieved 2019-01-19.
  69. "Parques Solares Navarra". Archived from the original on 20 January 2019. Retrieved 25 January 2019.
  70. "Guascor Foton's Navarra and Murcia CPV Power Plants". Archived from the original on 30 June 2018. Retrieved 25 January 2019.
  71. "Invenergy Announces Start of Operation Of Desert Green Solar Farm in California". Solar Power World. 8 December 2014. Archived from the original on 6 March 2019. Retrieved 4 March 2019.
  72. "Hatch" (PDF). Archived (PDF) from the original on 2019-01-07. Retrieved 2019-01-08.
  73. "Tucson". Archived from the original on 2019-01-14. Retrieved 2019-01-13.
  74. "Newberry". Archived from the original on 2016-07-15. Retrieved 2015-04-25.
  75. "Crafton Hills". Archived from the original on 2019-01-08. Retrieved 2019-01-08.
  76. "Victor Valley". Archived from the original on 2019-01-13. Retrieved 2019-01-13.
  77. "Eubank Landfill". Archived from the original on 2019-01-08. Retrieved 2019-01-08.
  78. "Questa" (PDF). Archived from the original (PDF) on 2016-08-15. Retrieved 2019-01-18.
  79. "Fort Irwin". 22 September 2013. Archived from the original on 2019-01-19. Retrieved 2019-01-18.
  80. "Fort Churchill Solar Project - Fact Sheet" (PDF). greentechmedia.com. Archived from the original (PDF) on July 14, 2015. Retrieved March 15, 2019.
  81. Eric Wesoff (September 14, 2012). "SunPower's C7 Tracker System in 6 MW Solar Farm at Tucson Electric Power". greentechmedia.com. Archived from the original on August 17, 2018. Retrieved March 15, 2019.
  82. "SRP and SunPower Dedicate Completed C7 Tracker Solar Power System at ASU Polytechnic Campus". SunPower. April 5, 2013. Archived from the original on October 24, 2021. Retrieved March 15, 2019.
  83. Helmers, H.; Bett, A.W.; Parisi, J.; Agert, C. (2014). "Modeling of concentrating photovoltaic and thermal systems". Progress in Photovoltaics: Research and Applications. 22 (4): 427–439. doi:10.1002/pip.2287. S2CID 94094698.
  84. Santos, Jose J.C.S.; Palacio, Jose C.E.; Reyes, Arnaldo M.M.; Carvalho, Monica; Friere, Alberto J.R.; Barone, Marcelo A. (February 16, 2018). "Chapter 12: Concentrating Solar Power". In Yahyaoui, Imene (ed.). Advances in Renewable Energies and Power Technologies. Elsevier. pp. 373–402. doi:10.1016/C2016-0-04518-7. ISBN 978-0-12-812959-3. Archived from the original on September 7, 2021. Retrieved September 7, 2021.
  85. "ADAM (Advanced Dense Array Module)". Archived from the original on 2015-02-22. Retrieved 2015-06-07.
  86. Igor Bazovsky, Chapter 18: Reliability Design Considerations. In: Reliability Theory and Practice, 1963 (reprinted 2004), Pages 176-185, ISBN 978-0486438672
  87. "RayGen focuses its energies on vast storage potential". www.ecogeneration.com.au. 2020-04-23. Archived from the original on 2021-01-23. Retrieved 2021-01-28.
  88. Blake Matich (2020-03-20). "ARENA boosts funding for RayGen's "solar hydro" power plant". PV Magazine. Archived from the original on 2021-02-03. Retrieved 2021-01-28.
  89. Parkinson, Giles (8 September 2023). "The Australian solar tech that may have found a low cost solution to deep storage". RenewEconomy.
  90. "Cogenra, acquired by Sunpower 2016". Archived from the original on 2013-12-27. Retrieved 2014-01-17.
  91. "Absolicon Solar". Archived from the original on 2016-03-15. Retrieved 2016-03-15.
  92. "Idhelio". Archived from the original on 2014-06-30. Retrieved 2016-03-15.
  93. "Airlight Energy". Archived from the original on 2015-04-18. Retrieved 2015-04-18.
  94. "dsolar". Archived from the original on 2015-04-18. Retrieved 2015-04-18.
  95. "Gianluca Ambrosetti 2014 TED Talk". Archived from the original on 2015-05-19. Retrieved 2015-05-06.
  96. "Rehnu". Archived from the original on 2019-04-15. Retrieved 2019-07-31.
  97. "Solartron". Archived from the original on 2017-12-27. Retrieved 2017-12-27.
  98. "Southwest Solar". Archived from the original on 2015-11-19. Retrieved 2015-12-13.
  99. "Sun Oyster". Archived from the original on 2019-07-02. Retrieved 2019-07-31.
  100. "Zenith Solar Projects - Yavne". zenithsolar.com. 2011. Archived from the original on April 15, 2011. Retrieved May 14, 2011.
  101. "Suncore". Archived from the original on 2015-04-18. Retrieved 2015-04-18.
  102. "BSQ Solar". Archived from the original on 2018-03-17. Retrieved 2018-10-21.
  103. "Silex Power". Archived from the original on 2016-03-14. Retrieved 2016-03-14.
  104. "Solergy Cogen CPV". Archived from the original on 2016-02-22. Retrieved 2016-02-13.
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