A solar power tower, also known as 'central tower' power plant or 'heliostat' power plant, is a type of solar furnace using a tower to receive focused sunlight. It uses an array of flat, movable mirrors (called heliostats) to focus the sun's rays upon a collector tower (the target). Concentrating Solar Power (CSP) systems are seen as one viable solution for renewable, pollution-free energy.[1]
Early designs used these focused rays to heat water and used the resulting steam to power a turbine. Newer designs using liquid sodium have been demonstrated, and systems using molten salts (40% potassium nitrate, 60% sodium nitrate) as the working fluids are now in operation. These working fluids have high heat capacity, which can be used to store the energy before using it to boil water to drive turbines. Storing the heat energy for later recovery allows power to be generated continuously, while the sun is shining, and for several hours after the sun has set (or been clouded over).
Cost
This section needs to be updated.(December 2020) |
In 2021, the US National Renewable Energy Laboratory (NREL) estimated the cost of electricity from concentrated solar with 10 hours of storage at $0.076 per kWh in 2021, $0.056 per kWh in 2030, and $0.052 per kWh in 2050.[2] In 2007, companies such as ESolar (then backed by Google.org) were developing cheap, low maintenance, mass producible heliostat components that were to reduce costs in the near future.[3] ESolar's design used large numbers of small mirrors (1.14 m2), to reduce costs for installing mounting systems such as concrete, steel, drilling, and cranes. In October 2017, an article in GreenTech Media suggested that eSolar ceased business in late 2016.[4]
Improvements in working fluid systems, such as moving from current two tank (hot/cold) designs to single tank thermocline systems with quartzite thermal fillers and oxygen blankets will improve material efficiency and reduce costs further.
Design
- Some concentrating solar power (CSP) towers are air-cooled instead of water-cooled, to avoid using limited desert water[5]
- Flat glass is used instead of the more expensive curved glass[5]
- Thermal storage to store the heat in molten salt containers to continue producing electricity while the sun is not shining
- Steam is heated to 500 °C to drive turbines that are coupled to generators which produce electricity
- Control systems to supervise and control all the plant activity including the heliostat array positions, alarms, other data acquisition and communication.
Generally, installations use from 150 hectares (1,500,000 m2) to 320 hectares (3,200,000 m2).
In 2023, Australia’s national science agency CSIRO tested a CSP arrangement in which tiny ceramic particles fall through the beam of concentrated solar energy, the ceramic particles capable of storing a greater amount of heat than molten salt, while not requiring a container that would diminish heat transfer.[6]
Environmental concerns
There is evidence that such large area solar concentrating installations can burn birds that fly over them. Near the center of the array, temperatures can reach 550 °C which, with the solar flux itself, is enough to incinerate birds. More distant birds’ feathers can be scorched, leading to the eventual death of the bird. Ivanpah reported one bird scorching in every two minutes. Workers at the Ivanpah solar power plant call these birds "streamers," as they ignite in midair and plummet to the ground trailing smoke. During testing of the initial standby position for the heliostats, 115 birds were killed as they entered the concentrated solar flux. During the first 6 months of operations, a total of 321 birds were killed. After altering the standby procedure to focus no more than four heliostats on any one point, there have been no further bird fatalities.[7]
The Ivanpah Solar Power Facility is classified as a greenhouse gas emitter by the State of California because it has to burn fossil fuel for several hours each morning so that it can quickly reach its operating temperature.[8]
Commercial applications
Several companies have been involved in planning, designing, and building utility size power plants. There are numerous examples of case studies of applying innovative solutions to solar power. Beam-down (a variation of central receiver plants with Cassegrainian optics[9])[clarification needed] tower application is also feasible with heliostats to heat the working fluid.[10]
Novel applications
The Pit Power Tower[11][12] combines a solar power tower and an aero-electric power tower[13] in a decommissioned open pit mine. Traditional solar power towers are constrained in size by the height of the tower and closer heliostats blocking the line of sight of outer heliostats to the receiver. The use of the pit mine's "stadium seating" helps overcome the blocking constraint.
As solar power towers commonly use steam to drive the turbines, and water tends to be scarce in regions with high solar energy, another advantage of open pits is that they tend to collect water, having been dug below the water table. The Pit Power Tower uses low heat steam to drive the pneumatic tubes in a co-generation system. A third benefit of re-purposing a pit mine for this kind of project is the possibility of reusing mine infrastructure such as roads, buildings, and electricity.
Solar power towers
List of solar power towers
Name | Developer/Owner | Completed | Country | Town | Height m | Height ft | Collectors | Installed maximum capacity *(MW) |
Yearly total energy production (GWh) |
---|---|---|---|---|---|---|---|---|---|
Noor Energy 1 | ACWA Power | 2022 | United Arab Emirates | Saih Al-Dahal, Dubai | 262.44 m | 861 ft | |||
Ashalim Power Station | Megalim Solar Power | 2019 | Israel | Negev Desert | 260 m | 853 ft | 50,600 | 121 MW | 320 |
Ouarzazate Solar Power Station | Moroccan Agency for Sustainable Energy | 2019 | Morocco | Ouarzazate | 250 m | 820 ft | 7,400 | 150 MW | 500 |
Cerro Dominador Solar Thermal Plant[14] | Acciona (51%) and Abengoa (49%) | 2021 | Chile | Calama | 250 m | 820 ft | 10,600 | 110 MW | |
Redstone Solar Thermal Power | ACWA Power | 2023 | South Africa | Postmasburg, Northern Cape Province | 100 MW[15] | ||||
Shouhang Dunhuang 100 MW Phase II[16] | Beijing Shouhang IHW | 2018 | China | Dunhuang | 220 m | 722 ft | 12,000 | 100 MW | 390[17] |
Qinghai Gonghe CSP[18] | 2019 | China | Gonghe | 210 m | 689 ft | 50 MW | 156.9 | ||
Khi Solar One | Abengoa | 2016 | South Africa | Upington | 205 m | 673 ft | 4,120 | 50 MW | 180 |
Crescent Dunes Solar Energy Project | SolarReserve | 2016 | United States | Tonopah | 200 m | 656 ft | 10,347 | 110 MW | 500 |
Supcon Solar Delingha[19] | Supcon Solar | 2016 | China | Delingha | 200 m | 656 ft | 50 MW | 146 | |
Haixi 50 MW CSP Project[20] | Luneng Qinghai Guangheng New Energy | 2019 | China | Haixi Zhou | 188 m | 617 ft | 4,400 | 50 MW | |
Hami 50 MW CSP Project[21][22] | Supcon Solar | 2019 | China | Hami | 180 m | 590 ft | 50 MW | ||
PS20 solar power plant | Abengoa Solar | 2009 | Spain | Sanlúcar la Mayor | 165 m | 541 ft | 1,255 | 20 MW | 48 |
Gemasolar Thermosolar Plant | Torresol Energy | 2011 | Spain | Sevilla | 140 m | 460 ft | 2,650 | 19.9 MW | 80 |
Ivanpah Solar Power Facility (3 towers) | BrightSource Energy | 2014 | United States | Mojave Desert | 139.9 m | 459 ft | 173,500 | 392 MW | 650 |
Shouhang Dunhuang 10 MW Phase I[23] | 2018 | China | Dunhuang | 138 m | 453 ft | 1,525[24] | 10 MW | ||
Sundrop Farms | Aalborg CSP | 2016 | Australia | Port Augusta | 127 m | 417 ft | 23,712[25] | 1.5 MW | |
Dahan Power Plant[26] | Institute of Electrical Engineering of Chinese Academy of Sciences | 2012 | China | Dahan | 118 m | 387 ft | 100 | 1 MW | |
PS10 solar power plant | Abengoa Solar | 2007 | Spain | Sanlúcar la Mayor | 115 m | 377 ft | 624 | 11 MW | 23.4 |
The Solar Project | U.S. Department of Energy | 1981 | United States | Mojave Desert | 100 m | 328 ft | 1,818 later 1,926 | 7 MW, later 10 MW | na, demolished |
Supcon Solar Delingha 10MW[27] (2 towers) | Supcon Solar | 2013 | China | Delingha | 100 m | 328 ft | 10 MW | ||
National Solar Thermal Test Facility | U.S. Department of Energy | 1978 | United States | Mojave Desert | 60 m | 200 ft | 1 MW (5-6 MWt) | na, demonstrator | |
Jülich Solar Tower | German Aerospace Center | 2008 | Germany | Jülich | 60 m | 200 ft | 2000 | 1.5 MW | na, demonstrator |
Greenway CSP Mersin Solar Tower | Greenway CSP | 2013 | Turkey | Mersin | 60 m | 200 ft | 510 | 1 MW (5 MWt) | |
ACME Solar Tower[28] | ACME Group | 2011 | India | Bikaner | 46 m | 150 ft | 14,280 | 2.5 MW | |
Sierra SunTower (2 towers) | eSolar | 2010 | United States | Mojave Desert | 46 m | 150 ft[29] | 24,000 | 5 MW | na, demolished |
Jemalong CSP Pilot Plant[30] | 2017 | Australia | Jemalong | 5x 27 m | 5x 89 ft | 3,500 | 1.1 MW (6 MWt) |
See also
References
- ^ "The cost of Concentrated Solar Power fell by 47% between 2010 and 2019 | REVE News of the wind sector in Spain and in the world". 29 July 2020. Retrieved 2022-04-16.
- ^ CSP, 10hrs TES - Class 3 - Moderate (2021). "NREL Electricity Annual Technology Baseline (ATB)". National Renewable Energy Laboratory.
{{cite web}}
: CS1 maint: numeric names: authors list (link) - ^ Google's Goal: Renewable Energy Cheaper than Coal November 27, 2007
- ^ Deign, Jason (12 October 2017). "Concentrated Solar Power Contender ESolar Goes AWOL". GreenTech Media. Retrieved 13 June 2019.
- ^ a b "FAQs". Brightsourceenergy.com. Retrieved 2019-09-28.
- ^ Houser, Kristin (12 November 2023). "Aussie scientists hit milestone in concentrated solar power They heated ceramic particles to a blistering 1450 F by dropping them through a beam of concentrated sunlight". Freethink. Archived from the original on 15 November 2023.
- ^ Kraemer, Susan (16 April 2015). "One Weird Trick Prevents Bird Deaths At Solar Towers". Clean Technica. Retrieved 20 February 2017.
- ^ Danelski, David (21 October 2015). "It's not easy being green: Ivanpah solar plant near Nevada burns much natural gas, making it a greenhouse gas emitter under state law". Orange County Register. Santa Ana, California. Retrieved 14 September 2016.
- ^ Mokhtar, Marwan Basem (2011). "The Beam-Down Solar Thermal Concentrator: Experimental Characterization and Modeling" (PDF). Masdar Institute of Science and Technology: i – via Massachusetts Institute of Technology.
- ^ "Three solar modules of world's first commercial beam-down tower Concentrated Solar Power project to be connected to grid". Retrieved 18 August 2019.
- ^ Pit Power Tower - Alternative Energy News Feb 2009
- ^ Pit Power Tower US Patent
- ^ Energy tower
- ^ "Atacama-1 | Concentrating Solar Power Projects". solarpaces.nrel.gov. Archived from the original on 2020-01-31.
- ^ "ACWA Power's Redstone CSP Draws Down Debt in 9th Month of Construction". 22 February 2022.
- ^ https://www.sh-ihw.es/dunhuang100 [dead link ]
- ^ "Shouhang Dunhuang 100 MW Phase II | Concentrating Solar Power Projects". solarpaces.nrel.gov. Archived from the original on 2019-06-16.
- ^ "Cosin Solar Technology Co., Ltd".
- ^ "Cosin Solar Technology Co., Ltd".
- ^ "Luneng Haixi 50MW Molten Salt Tower | Concentrating Solar Power Projects". solarpaces.nrel.gov. Archived from the original on 2019-06-16.
- ^ "CPECC Hami Tower Concentrated Solar Power Project to be completed in Mid 2019".
- ^ "Hami 50 MW CSP Project | Concentrating Solar Power Projects". solarpaces.nrel.gov. Archived from the original on 2019-06-16.
- ^ "Shouhang Dunhuang 10 MW Phase I | Concentrating Solar Power Projects". solarpaces.nrel.gov. Archived from the original on 2019-06-16.
- ^ "Shouhang and EDF to Test s-CO2 Cycle in Concentrated Solar Power". 29 March 2019.
- ^ "Sundrop CSP Project | Concentrating Solar Power Projects | NREL".
- ^ "Dahan Power Plant | Concentrating Solar Power Projects". solarpaces.nrel.gov. Archived from the original on 2019-06-16.
- ^ "Cosin Solar Technology Co., Ltd".
- ^ "ACME Solar Tower | Concentrating Solar Power Projects | NREL".
- ^ "ESolar Sierra SunTower Project offline - Clarified". 16 June 2010.
- ^ "Jemalong CSP Pilot Plant – 1.1MWe". Vast Solar. Retrieved 24 April 2021.