Sicilian method

The Sicilian method was one of the first ways to extract sulfur from underground deposits. It was the only industrial method of recovering sulfur from elemental deposits until replaced by the Frasch process.[1] Most of the world's sulfur was obtained this way until the late 19th century.[2]

Sicilian method of sulfur extraction
Process typeExtraction
Industrial sector(s)Mining
Main technologies or sub-processesMelting
Product(s)Sulfur
Year of inventionAncient

In its most basic form the ores were piled in a mound and ignited. The semi-pure sulfur flowed down and the solidified mass was collected at a lower level. It gets its name from the center of sulfur production until the 19th century when it was replaced by the Frasch process. [3][4]

History

Sulfur, also known as brimstone (the stone that burns), has a variety of purposes such as bleaching agent, incense for religious rights, insecticides, and glue. The Romans used it to make fireworks and weapons. Sicilian industrial sulfur comes from the sedimentary Miocene rocks found about 200 meters underground. [5][6]

By the middle of the 19th century, Sicily produced 3/4 of the world's production. The excavation in Sicily was very easy and close to the surface. Local wages were low and underpaid children were also used. Sicily also had easy transport by sea. The economy in Sicily was mostly agricultural and the presence of sulfur mines helped support it. Nevertheless, the method of extracting the sulfur created serious ecological hardship on the country. [7]

By 1912 the United States overtook Sicily for the worldwide production of sulfur. Large consistent bases of sulfur in Texas and Louisiana, as well as low-cost fuel and large quantities of water, made the newly invented Frasch process economical.[5]

After the Second World War most of the mines in Sicily closed down.[8]

Process

Sulfur ore was carried up manually from shallow mines and placed in fire pits. The stones are heated to separate the sulfur from its other elements. The method is relatively inefficient as a large part is burned instead of melting. There is also a large amount of pollution coming from sulfuric anhydride.[9]

Sulfur, with a melting point of 115 °C (239 °F), is heated until it melts and flows downward with gravity. As it moves away from the source of the heat it resolidifies and is collected. The sulfur obtained is not very pure.[8]

The Sicilian method went through four different phases of improvement. The first two were the main methods used in Sicily.

Calcarelle

Calcarelle was the most basic approach. A stack of ore was made of about 10 square feet (0.93 m2) in a ditch and the floors were beaten hard and sloped downward allowing the molten sulfur to flow to the bottom. The largest pieces were stacked at the bottom with smaller pieces on top as the stack grew higher. This stack was then set on fire and by the third-day molten ore started to flow from an opening called a Morto (Death). Ore in the center melted more than the outside which oxidized.[8] The yield could be as low as 6%.[10]

It was a very polluting approach and is not very efficient. Much of the product was destroyed and probably only yielded 1/3 of the total sulfur entered into the furnace. The process could take days depending on the weather. The side facing the wind tended to burn rather than melt and efficiencies in the winter were lower. [10][11]

This archaic technology had the disadvantage of producing large quantities of sulfur dioxide and other compounds highly polluting and harmful for the health of workers, for agriculture, and for all the surrounding environment. It was required to install these rudimentary facilities at a distance of at least 3 kilometres (1.9 mi) from inhabited areas.[12] In 1870 there were about 4,367 Calcarelle in Sicily. [10]

Calcaroni

Calcaroni was a more successful and efficient method and started to replace the Calcarelle method after around 1850.

A circular stone wall was built on an inclined slope. In front was the Morto (Death) or outlet, having a height of four to six feet, and a width of two feet; over it is erected a wooden shelter for the workman in charge. Calcaroni may contain about 6 long tons (6.1 t). These could last ten years. The largest pieces of ore were selected for the first layer, leaving spaces between them and the size of the lumps gradually diminished as the height increased. Narrow channels, about 2 feet (0.61 m) apart, are left for air to carry the heat down. The whole is covered with a layer of the refuse from previous operations.[10] The internal floor had an inclination of about ten degrees ending at the bottom.[8] The sulfur melts slowly downwards and, collected from the inclined floor, runs towards the exit. When the Morto was opened the sulfur cooled into ingots called balate.[8] The process treated about 2000 cubic meters of ore at a time and the process lasts for about 20-30 days. [8]

Although the number of pollutants and losses was considerably lower, Calcaroni produced a considerable waste of mineral and its yield was only around 50% due to the burning of the sulfur necessary for the heating process, which also caused environmental pollution. [8]

Calcarone method of sulfur extraction

Doppioni

Doppioni (or Doppione) means double in Italian. There were two terracotta vessels connected with a pipe and one of the vessels was heated and sulfur stones were put inside. The sulfur evaporated and passed through the pipe to cool down and poured it into molds. This was more a process of distillation than melting. This process was used in other areas of Italy, such as Romagna, because of the need for fuels to heat the process other than sulfur, which Sicily lacked.[10]

Distillation process of sulfur
Doppione method for sulfur extraction by distillation

Gill kiln

The Gill kiln was a continuous furnace developed in 1880 and named after its inventor, the engineer Roberto Gill. It employed a series of chambers that would preheat and set fire to the next chamber. Each chamber had a floor with several openings for moving the molten sulfur. Each of the openings would move a shot of sulfur at different times and would allow small amounts of sulfur to be processed. It was a very expensive system to put in place but it also reduced a large amount of gas and pollution that entered into the air. It had yields over 60%.[8]

Replacement

The Sicilian method was replaced slowly after 1894 by the Frasch process, or American approach, where the sulfur was processed in the ground by superheating steam through a pipe to melt the sulfur in the ground and extracting as it came up. This led to a much purer form of sulfur, using fewer workers and less waste. A lot of freshwater and fuel was needed, so it was never employed in water-poor Italy. [13][10]

References

  1. Alden P. Armagnac (December 1942). "Strange mines tap sulphur". Popular Science. Popular Science Publishing Co. Archived from the original on 2016-04-17. Retrieved 2019-02-04.
  2. Stuart Bruchey (1960). "Brimstone, The Stone That Burns: The Story of the Frasch Sulphur Industry by Williams Haynes". Journal of Economic History. 20 (2): 326–327. JSTOR 2114864. It was a simple but not environmentally sound process.Walter Botsch (2001). "Chemiker, Techniker, Unternehmer: Zum 150. Geburtstag von Hermann Frasch". Chemie in Unserer Zeit. 35 (5): 324–331. doi:10.1002/1521-3781(200110)35:5<324::AID-CIUZ324>3.0.CO;2-9.
  3. "Learn More About Sulphur - Introduction". The Sulphur Institute. Archived from the original on 2019-02-07. Retrieved 2019-02-05.
  4. Gray, C.W. (1920). Fundamentals of Chemistry. p. 76.
  5. Ingraham, John L. (2012-05-07). March of the Microbes. ISBN 9780674054035.
  6. Hunt, Walter Frederick (1915). "The origin of the sulphur deposits of Sicily" (PDF). Economic Geology. 10 (6): 543–579. doi:10.2113/gsecongeo.10.6.543.
  7. Mormino, Vincenzo. "Sulfur in Sicily". Archived from the original on 2018-06-09. Retrieved 2019-02-04.
  8. Kutney, Gerald. Sulfur. History, Technology, Applications & Industry (2nd ed.). ISBN 978-1-895198-67-6.
  9. Notizie sullo zolfo di Sicilia e i suoi trattamenti Archived 2015-09-24 at the Wayback Machine.
  10. Meyer, Beat (2013-09-11). Sulfur, Energy, and Environment. pp. 173–175. ISBN 9781483163468.
  11. La calcarella Archived 2018-05-21 at the Wayback Machine.
  12. "Sulfur, Production History". Archived from the original on 2019-02-07. Retrieved 2019-02-04.
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