Frasch process
Template:Short description Template:Infobox industrial process
The Frasch process is a method to extract sulfur from underground deposits by taking advantage of the low melting point of sulfur. It is the only industrial method of recovering sulfur from elemental deposits.<ref name = Ullmann/> Most of the world's sulfur was obtained this way until the late 20th century, when sulfur recovered from petroleum and gas sources became more commonplace (see Claus process).
In the Frasch process, superheated water is pumped into the sulfur deposit; the sulfur melts and is extracted. The Frasch process is able to produce high-purity sulfur of about 99.5%. <ref>The Sulphur Institute. "An Introduction to Sulphur." Template:Webarchive, accessed 17 January 2011.</ref>
HistoryEdit
In 1867, miners discovered sulfur in the caprock of a salt dome in Calcasieu Parish, Louisiana, but it was beneath quicksand, which prevented mining. In 1894 the German-born American chemist, Herman Frasch (1852–1914), devised his Frasch method of sulfur removal using pipes to bypass the quicksand.<ref>Template:Cite journal</ref> This replaced the inefficient and polluting Sicilian method. The process proved successful, on December 24, 1894, when the first molten sulfur was brought to the surface. The Union Sulphur Company was incorporated in 1896 to utilize the process. However, the high cost of fuel needed to heat the water made the process uneconomic until the 1901 discovery of the Spindletop oil field in Texas provided cheap fuel oil to the region.<ref>Template:Cite book</ref> The Frasch process began economic production at Sulphur Mines, Louisiana in 1903.<ref name=Ober/>
When Frasch's patent expired, the process was widely applied to similar salt-dome sulfur deposits along the Gulf Coast of the United States. The second Frasch-process mine opened in 1912 in Brazoria County, Texas. The Gulf Coast came to dominate world sulfur production in the early and middle 20th century.<ref>Handbook of Texas Online: Sulfur industry, accessed 20 February 2009.</ref> However, starting in the 1970s, byproduct sulfur recovery from oil and natural gas lowered the price of sulfur and drove many Frasch-process mines out of business. The last United States Frasch sulfur mine closed in 2000.<ref>Joyce A. Ober (2002) Materials Flow of Sulfur, US Geological Survey, Open-File Report 02-298, p.12, PDF file, retrieved 20 February 2009.</ref> A Frasch mine in Iraq closed in 2003 due to the U.S. invasion of Iraq.
The Frasch process is still used to work sulfur deposits in Mexico, Ukraine and Poland.
ProcessEdit
The Frasch sulfur process works best on either salt domes or bedded evaporite deposits, where sulfur is found in permeable rock layers trapped in between impermeable layers. Bacterial alteration of anhydrite or gypsum, in the presence of hydrocarbons, produces limestone and hydrogen sulfide in the sulfur cycle. The hydrogen sulfide then oxidizes into sulfur, from percolating water, or through the action of anaerobic, sulfur-reducing bacteria <ref name=Ober>Template:Cite book</ref><ref name=Haynes>Template:Cite book</ref>
In the Frasch process, three concentric tubes are introduced into the sulfur deposit. Superheated water (165 °C, 2.5-3 MPa) is injected into the deposit via the outermost tube. Sulfur (m.p. 115 °C) melts and flows into the middle tube. Water pressure alone is unable to force the sulfur into the surface due to the molten sulfur's greater density, so hot air is introduced via the innermost tube to froth the sulfur, making it less dense, and pushing it to the surface.<ref name = Ullmann/>
The sulfur obtained can be very pure (99.7 - 99.8%). In this form, it is light yellow in color. If contaminated by organic compounds, it can be dark-colored; further purification is not economic, and usually unnecessary. Using this method, the United States produced 3.89 million tons of sulfur in 1989, and Mexico produced 1.02 million tons of sulfur in 1991. <ref name =Ullmann>Template:Ullmann</ref>
The Frasch process can be used for deposits 50–800 meters deep. 3-38 cubic meters of superheated water are required to produce every tonne of sulfur, and the associated energy cost is significant.<ref name = Ullmann/> A working demonstration model of the Frasch process suitable for the classroom has been described.<ref>Template:Cite journal</ref>
Economic ImpactEdit
| Year | United States | Italy | Japan | Chile | Spain | TotalTemplate:Efn |
|---|---|---|---|---|---|---|
| 1900 | 3,147 | 535,525 | 14,211 | 1,661 | 738 | 555,282 |
| 1901 | 6,867 | 554,203 | 16,287 | 2,037 | 600 | 597,994 |
| 1902 | 7,446 | 530,913 | 17,996 | 2,594 | 443 | 559,394 |
| 1903 | 35,097 | 545,005 | 22,513 | 3,504 | 1,653 | 607,772 |
| 1904 | 85,000 | 519,231 | 25,165 | 3,538 | 595 | 633,529 |
| 1905 | 220,000 | 559,942 | 24,264 | 3,417 | 600 | 808,223 |
| 1906 | 295,123 | 491,920 | 27,885 | 4,525 | 689 | 820,142 |
| 1907 | 188,878 | 420,229 | 32,803 | 2,859 | 3,555 | 648,324 |
| 1908 | 364,444 | 438,279 | 32,891 | 2,662 | 2,941 | 841,217 |
| 1909 | 273,983 | 428,189 | 36,317 | 4,437 | 3,375 | 746,301 |
| 1910 | 247,060 | 423,563 | 43,154 | 3,762 | 3,773 | 721,312 |
| 1911 | 205,066 | 407,620 | 49,481 | 4,380 | 6,476 | 673,023 |
| 1912 | 787,735 | 383,300 | 53,692 | 4,361 | 4,519 | 1,233,607 |
| 1913 | 491,080 | 380,209 | 58,509 | 6,542 | 7,381 | 943,721 |
| 1914 | 417,690 | 371,875 | 72,944 | 9,850 | 7,933 | 880,292 |
| 1915 | 520,582 | 352,451 | 71,066 | 9,615 | 9,517 | 963,231 |
| 1916 | 649,683 | 265,120 | 104,707 | 14,644 | 10,461 | 1,044,515 |
| 1917 | 1,134,412 | 208,501 | 116,224 | 17,787 | 12,681 | 1,489,605 |
| 1918 | 1,353,525 | 230,596 | 63,748 | 19,248 | 12,537 | 1,679,654 |
| 1919 | 1,190,575 | 222,555 | 49,831 | 18,611 | 11,263 | 1,492,835 |
| 1920 | 1,255,249 | 259,440 | 38,975 | 13,129 | 12,200 | 1,578,993 |
| 1921 | 1,879,150 | 269,547 | 36,013 | 9,517 | 5,170 | 2,199,397 |
| 1922 | 1,830,942 | 154,696 | 34,095 | 12,057 | 13,028 | 2,054,818 |
| 1923 | 2,036,097 | 252,293 | 36,825 | 11,200 | 8,382 | 2,344,797 |
| 1924 | 1,220,561 | 290,241 | 46,133 | 9,611 | 9,388 | 1,575,934 |
| 1925 | 1,409,262 | 259,428 | 46,962 | 8,929 | 7,859 | 1,732,440 |
| 1926 | 1,890,027 | 267,107 | 47,020 | 8,787 | 9,351 | 2,222,292 |
| 1927 | 2,111,618 | 300,888 | 60,371 | 12,303 | 10,065 | 2,495,245 |
| 1928 | 1,981,873 | 291,430 | 68,956 | 15,423 | 10,199 | 2,367,881 |
| 1929 | 2,362,389 | 323,000Template:Efn | 58,718 | 16,000Template:Efn | 10,000Template:Efn | 2,770,107 |
List of MinesEdit
| CitationClass=web
}}</ref> |
Dome | State | Company | From | Until | Total long tons | Template:Font color Template:Font color Template:Font color |
|---|---|---|---|---|---|---|---|
| Sulphur Mine | La | Union | Dec 27, 1894 | Dec 23, 1924 | 9,412,165 | ||
| Bryan Mound | Tx | Freeport | Nov 12, 1912 | Sep 30, 1935 | 5,001,068 | Template:Coord | |
| Big Hill | Tx | Texas Gulf | Mar 19, 1919 | Aug 10, 1936 | 12,349,597 | ||
| Hoskins Mound | Tx | Freeport | Mar 31, 1923 | May 26, 1955 | 10,895,090 | Template:Coord | |
| Big Creek | Tx | Union | Mar 6, 1925 | Feb 24, 1926 | 1,450 | ||
| Palangana | Tx | Duval | Oct 27, 1928 | Mar 10, 1935 | 236,662 | ||
| Boling | Tx | Union | Nov 14, 1928 | Aug 30, 1929 | 9,164 | ||
| Boling | Tx | Texas Gulf | Mar 19, 1929 | >61,118,065 | |||
| Long Point | Tx | Texas Gulf | Mar 19, 1930 | Oct 19, 1938 | 402,105 | ||
| Lake Peigneur | La | Jefferson Lake | Oct 20, 1932 | Jun 7, 1936 | 430,811 | Template:Coord | |
| Grand Ecaille | La | Freeport | Dec 8, 1933 | >30,885,243 | Template:Coord | ||
| Boling | Tx | Duval | Mar 23, 1935 | Apr 25, 1940 | 571,123 | ||
| Boling | Tx | Baker-Williams | Jun 2, 1935 | Dec 18, 1935 | 1,435 | ||
| Clemens | Tx | Jefferson Lake | May 3, 1937 | Dec 14, 1960 | 2,975,828 | ||
| Orchard<ref>Template:Cite news</ref> | Tx | Duval | 1938 | ||||
| Orchard | Tx | Jefferson Lake | Jun 7, 1946 | >4,551,472 | |||
| Moss Bluff | Tx | Texas Gulf | Jun 24, 1948 | >5,081,343 | |||
| Starks Dome | La | Jefferson Lake | Jun 15, 1951 | Dec 13, 1960 | 840,249 | ||
| Spindletop Mine | Tx | Texas Lake | May 12, 1952 | >6,310,721 | |||
| Bay Ste. Elaine | La | Freeport | Nov 19, 1952 | Dec 29, 1959 | 1,131,204 | Template:Coord | |
| Damon | Tx | Standard Sulphur | Nov 11, 1953 | Apr 20, 1957 | 139,618 | ||
| Garden Island Bay | La | Freeport | Nov 19, 1953 | 1991<ref name="myb_1991_v1"/> | >7,006,991 | Template:Coord<ref>{{#invoke:citation/CS1|citation | CitationClass=web
}}</ref> |
| Nash | Tx | Freeport | Feb 3, 1954 | Nov 23, 1956 | 153,115 | Template:Coord<ref>{{#invoke:citation/CS1|citation | CitationClass=web
}}</ref> |
| Chacahoula | La | Freeport | Feb 25, 1955 | Sep 28, 1962 | 1,199,015 | Template:Coord | |
| Fannett | Tx | Texas Gulf | May 6, 1958 | >1,773,737 | |||
| High Island | Tx | United States | Mar 25, 1960 | Feb 8, 1962 | 36,708 | ||
| Grand Isle | La | Freeport | Apr 17, 1960 | 1991<ref name="myb_1991_v1">Template:Cite book</ref> | >4,466,021 | Template:Coord<ref>{{#invoke:citation/CS1|citation | CitationClass=web
}}</ref> |
| Lake Pelto | La | Freeport | Nov 26, 1960 | >2,474,693 | Template:Coord | ||
| Big Hill | Tx | Texas Gulf | Oct 8, 1965 | >107,830 | |||
| Sulphur Mine | La | Allied Chemical | Sep 18, 1966 | >1,447 | |||
| Nash | Tx | Phelan Sulphur | Nov 7, 1966 | >622 |
MexicoEdit
In 1955 Mexico became the world's second largest producer of sulfur behind the United States.
| 1948-1952 (avg) | 1953 | 1954 | 1955 | 1956 | 1957 | |
|---|---|---|---|---|---|---|
| Total | 8,452 | 5,900 | 52,407 | 475,487 | 758,415 | 1,007,915 |
| Frasch | 990,122 | |||||
ReferencesEdit
<references/> Template:Notelist
Further readingEdit
- Template:Cite journal
- Template:Cite journal
- History of Sulphur (Sulphur, Louisiana)
- Template:Cite journal
- Template:Cite journal
External linksEdit
- {{#invoke:citation/CS1|citation
|CitationClass=web }} (Description of Frasch process)