Solar furnace

A solar furnace is a structure that uses concentrated solar power to produce high temperatures, usually for industry. Parabolic mirrors or heliostats concentrate light (Insolation) onto a focal point. The temperature at the focal point may reach 3,500 °C (6,330 °F), and this heat can be used to generate electricity, melt steel, make hydrogen fuel or nanomaterials.

The largest solar furnace is at Odeillo in the Pyrénées-Orientales in France, opened in 1970. It employs an array of plane mirrors to gather sunlight, reflecting it onto a larger curved mirror.

History

The ancient Greek / Latin term heliocaminus means "solar furnace" and refers to a glass-enclosed sunroom intentionally designed to become hotter than the outside air temperature.^[1]

Legendary accounts of the Siege of Syracuse (213–212 BC) tell of Archimedes' heat ray, a set of burnished brass mirrors or burning glasses supposedly used to ignite attacking ships, though modern historians doubt its veracity.

On 24 September 1901, Knut C. Wideen was granted a patent for a "System for collecting and utilizing solar heat", which included a solar furnace^[2].

The first modern solar furnace is believed to have been built in France in 1949 by Professor Félix Trombe. The device, the Mont-Louis Solar Furnace is still in place at Mont-Louis. The Pyrenees were chosen as the site because the area experiences clear skies up to 300 days a year.^[3]

The Odeillo Solar Furnace is a larger and more powerful solar furnace. It was built between 1962 and 1968, and started operating in 1969. It's currently the most powerful, based on an achievable temperature of 3500 °C.

The Solar Furnace of Uzbekistan was built in Uzbekistan and opened in 1981 as a part of a Soviet Union "Sun" Complex Research Facility, being the world largest concentrator.^[4]

Uses

The rays are focused onto an area the size of a cooking pot and can reach 4,000 °C (7,230 °F), depending on the process installed; for example:

about 1,000 °C (1,830 °F) for metallic receivers producing hot air for the next-generation solar towers as it will be tested at the Themis plant with the Pegase project^[5]
about 1,400 °C (2,550 °F) to produce hydrogen by cracking methane molecules^[6]
up to 2,500 °C (4,530 °F) to test materials for extreme environment such as nuclear reactors or space vehicle atmospheric reentry
up to 3,500 °C (6,330 °F) to produce nanomaterials by solar induced sublimation and controlled cooling, such as carbon nanotubes^[7] or zinc nanoparticles^[8]

It has been suggested that solar furnaces could be used in space to provide energy for manufacturing purposes.

Their reliance on sunny weather is a limiting factor as a source of renewable energy on Earth but could be tied to thermal energy storage systems for energy production through these periods and into the night.

Smaller-scale devices

The solar furnace principle is being used to make inexpensive solar cookers and solar-powered barbecues, and for solar water pasteurization.^[9]^[10] A prototype Scheffler reflector is being constructed in India for use in a solar crematorium. This 50 m² reflector will generate temperatures of 700 °C (1,292 °F) and save 200–300 kg of firewood used per cremation.^[11]

References

^ "MEEF Roman Architectural Glossary". Archived from the original on 2017-06-12. Retrieved 2009-12-05.
^ U.S. Patent 683,088
^ Odeillo Solar Furnace official website, retrieved 12 July 2007
^ English Russia's post about the Uzbekistan Soviet Solar Furnace
^ "PEGASE project home page". Archived from the original on 2017-12-01. Retrieved 2010-01-24.
^ SOLHYCARB, EU funded project, ETHZ official page Archived 2009-03-13 at the Wayback Machine
^ Flamant G., Luxembourg D., Robert J.F., Laplaze D., Optimizing fullerene synthesis in a 50 kW solar reactor, (2004) Solar Energy, 77 (1), pp. 73-80.
^ T. Ait Ahcene, C. Monty, J. Kouam, A. Thorel, G. Petot-Ervas, A. Djemel, Preparation by solar physical vapor deposition (SPVD) and nanostructural study of pure and Bi doped ZnO nanopowders, Journal of the European Ceramic Society, Volume 27, Issue 12, 2007, Pages 3413-342
^ "SOLAR COOKERS How to make, use, and enjoy" (PDF). Solar Cookers International. 2004.
^ US patent for solar barbecue granted in 1992 Archived 2017-12-01 at the Wayback Machine.
^ "Development Of A Solar Crematorium" (PDF). Solare Brüecke. Retrieved 2008-05-20.

External links

[1] "MEEF Roman Architectural Glossary". Archived from the original on 2017-06-12. Retrieved 2009-12-05.

[2] U.S. Patent 683,088

[3] Odeillo Solar Furnace official website, retrieved 12 July 2007

[4] English Russia's post about the Uzbekistan Soviet Solar Furnace

[5] "PEGASE project home page". Archived from the original on 2017-12-01. Retrieved 2010-01-24.

[6] SOLHYCARB, EU funded project, ETHZ official page Archived 2009-03-13 at the Wayback Machine

[7] Flamant G., Luxembourg D., Robert J.F., Laplaze D., Optimizing fullerene synthesis in a 50 kW solar reactor, (2004) Solar Energy, 77 (1), pp. 73-80.

[8] T. Ait Ahcene, C. Monty, J. Kouam, A. Thorel, G. Petot-Ervas, A. Djemel, Preparation by solar physical vapor deposition (SPVD) and nanostructural study of pure and Bi doped ZnO nanopowders, Journal of the European Ceramic Society, Volume 27, Issue 12, 2007, Pages 3413-342

[9] "SOLAR COOKERS How to make, use, and enjoy" (PDF). Solar Cookers International. 2004.

[10] US patent for solar barbecue granted in 1992 Archived 2017-12-01 at the Wayback Machine.

[11] "Development Of A Solar Crematorium" (PDF). Solare Brüecke. Retrieved 2008-05-20.

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History

Uses

Smaller-scale devices

See also

References

External links