Odeillo solar furnace

The Odeillo solar furnace is the world's largest solar furnace. It is situated in Font-Romeu-Odeillo-Via, in the department of Pyrénées-Orientales, in south of France. It is 54 metres (177 ft) high and 48 metres (157 ft) wide, and includes 63 heliostats. It was built between 1962 and 1968, and started operating in 1969[1][2], and has a power of one megawatt.

Odeillo solar furnace
Four solaire d'Odeillo
The solar furnace at Odeillo in the Pyrénées-Orientales in France can reach temperatures up to 3,500 °C (6,330 °F)
Coordinates42.4939°N 2.0292°E / 42.4939; 2.0292
LocationFont-Romeu-Odeillo-Via
Width48 metres (157 ft)
Height54 metres (177 ft)
Beginning date1962
Completion date1968
Opening date1969

It serves as a science research site studying materials at very high temperatures.

Geography

It is situated in Font-Romeu-Odeillo-Via, in the department of Pyrénées-Orientales, region of Languedoc-Roussillon, in south of France. The site was chosen because:

  • the length and the quality of sunshine with direct light (more than 2,500 h/year);[3]
  • the purity of its atmosphere (high altitude and low average humidity).

The solar power plant of Themis and the Mont-Louis Solar Furnace are situated nearby.

Working principle

Working principle
View to the East from the parabola center
One of the 63 heliostats

The principle used is the concentration of rays by reflecting mirrors (9,600 of them). The solar rays are picked up by a first set of steerable mirrors located on the slope, and then sent to a second series of mirrors (the concentrators), placed in a parabola and eventually converging on a circular target, 40 cm in diameter, on top of the central tower.

Equivalent to concentrating the energy of "10,000 suns", the solar furnace produces a peak power of 3200 Kw.

Advantages

  • Temperatures above 3,500 °C (6,330 °F) can be obtained in a few seconds.
  • The energy is "free", and non-polluting.
  • This furnace provides rapid temperature changes and therefore allow studying the effect of thermal shocks;
  • There are no contaminating elements (combustion gas, pollution, waste, etc.), since only the object to be examined is heated only by radiation;
  • This heating can be done in a controlled atmosphere (the vacuum of space, the upper atmosphere of Mars, etc.)

Uses

The research areas are also extended to the aviation and aerospace industries. Experiments can be conducted there in conditions of high chemical purity. The high temperature materials division use the furnace to evaluate radome survival during MIRV warhead earth re-entry along with investigating other material properties under the "high energy thermal radiation environment" frequently produced by "nuclear devices".[4]

History

In 1946 French chemist Felix Trombe and his team achieved in Meudon their first experience of using a DCA (French: Défense Contre Avions = anti-aircraft) mirror. They demonstrated the ability to reach high temperatures very quickly, and in a very pure environment, using highly concentrated sunlight. Their aim was to melt ore and extract highly pure materials for making new and improved refractories.

To achieve this objective and test the various possibilities, a first solar furnace was built at Mont-Louis in 1949. Some years later, on the model of the Mont-Louis furnace and using the results obtained there, a solar furnace of almost industrial size was built at Odeillo. Work on the construction of the Great Solar Oven of Odeillo lasted from 1962 to 1968, and it was commissioned in 1969.

Being strong supporters of solar power, following the first oil shock of 1973, researchers at the Odeillo solar furnace made further progress in the conversion of solar energy into electricity.

Public information center Héliodyssée

Since 1990, there has been an information center on the site which is open to the public, and is independent of the CNRS laboratory.

Designed for young and old, Héliodyssée allows them to learn about solar energy and its derivatives (other forms of renewable energy, and its uses in the home) and the work of researchers from CNRS on energy, environmental, materials for space, and materials of the future.

Annexes

Bibliography

  • (in French) G. Olalde et J.L. Peube, « Étude expérimentale d'un récepteur solaire en nid d'abeilles pour le chauffage solaire des gaz à haute température », Revue de Physique Appliquée, no 17, 1982, p. 563-568
  • (in French) Bernard Spinner, « La construction d’un pôle de recherche et d’expérimentation solaire », La revue pour l’histoire du CNRS, no 5, 2001
  • (in French) Merimée database, French Ministry of Culture

References

  1. "II.C Alternative Energy". Final Volume I Environmental Impact Statement: OCS Sale No. 73. United States Department of the Interior - Minerals Management Service. p. II-66. Retrieved 2020-01-11.
  2. Joffre, André; Busquet, Jean-Louis (2019-07-10). "Le jubilé du grand four solaire d'Odeillo dans les Pyrénées-Orientales" [The jubilee of the great solar oven of Odeillo in the Pyrénées-Orientales] (in French). Retrieved 2020-01-11.
  3. http://www.actualitix.com/nombre-d-heures-d-ensoleillement-par-depa.html
  4. High Energy Solar Energy
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