Solar furnace explained

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 3500C, 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 literally 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.

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.^[2]

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.^[3]

Uses

The rays are focused onto an area the size of a cooking pot and can reach 4000C, depending on the process installed; for example:

• about 1000C 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^[4]
• about 1400C to produce hydrogen by cracking methane molecules^[5]
• up to 2500C to test materials for extreme environment such as nuclear reactors or space vehicle atmospheric reentry
• up to 3500C to produce nanomaterials by solar induced sublimation and controlled cooling, such as carbon nanotubes^[6] or zinc nanoparticles^[7]

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.^{[8] [9]} A prototype Scheffler reflector is being constructed in India for use in a solar crematorium. This 50 m² reflector will generate temperatures of 700C and save 200–300 kg of firewood used per cremation.^[10]

See also

• Solar power tower
• Solar thermal energy
• Solar thermal collector
• Solar furnace of Uzbekistan

External links

• Article about the Odeillo and Mont Louis solar furnaces
• Hochflussdichte Sonnenofen des DLR, Köln
• Page including an animation of a solar furnace
• BBC News article about the solar power station serving Seville, Spain
• Build a solar furnace

Notes and References

1. Web site: MEEF Roman Architectural Glossary . 2009-12-05 . 2017-06-12 . https://web.archive.org/web/20170612121650/http://www.eng-forum.com/articles/Glossaries/Architecture_Roman.htm . dead .
2. http://www.promes.cnrs.fr/ Odeillo Solar Furnace official website
3. http://englishrussia.com/2012/01/25/the-solar-furnace-of-uzbekistan/#more-88701 English Russia's post about the Uzbekistan Soviet Solar Furnace
4. Web site: PEGASE project home page . 2010-01-24 . 2017-12-01 . https://web.archive.org/web/20171201081635/https://www.promes.cnrs.fr/pegase/index.php . dead .
5. http://www.pre.ethz.ch/research/projects/?id=solhycarb SOLHYCARB, EU funded project, ETHZ official page
6. 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.
7. 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
8. Web site: SOLAR COOKERS How to make, use, and enjoy . Solar Cookers International . 2004.
9. http://patft.uspto.gov/netacgi/nph-Parser?Sect1=PTO1&Sect2=HITOFF&d=PALL&p=1&u=%2Fnetahtml%2FPTO%2Fsrchnum.htm&r=1&f=G&l=50&s1=5090399.PN.&OS=PN/5090399&RS=PN/5090399 US patent for solar barbecue granted in 1992
10. Web site: Development Of A Solar Crematorium. Solare Brüecke. 2008-05-20.