Claims
- 1. The process of producing aluminum from a salt containing aluminum and a single other element by steps comprising:
- a. heating said salt to a high temperature of at least 2500.degree.-5500.degree.C to break it into aluminum and said other element in a mixture comprising the two elemental gases;
- b. flash cooling said mixture comprising said two elemental gases from said high temperature, to a lower temperature of not over 1500.degree.C within a time interval of not more than one to five seconds, by contacting said gas mixture directly with a coolant which is liquid at said lower temperature and is chemically nonreactive with said salt and its constituent elements in elemental form at said lower temperature; and
- c. condensing said aluminum in said liquid coolant while allowing said other element to pass on in a gas phase.
- 2. In the process according to claim 1, wherein the boiling point of said liquid coolant is between 136.degree. and 1500.degree.C.
- 3. In the process according to claim 1, wherein said other element is sulfur, and said aluminum salt is aluminum sulfide.
- 4. In the process according to claim 1, wherein said high temperature reaction and said flash cooling both take place under a pressure higher than that of the atmosphere.
- 5. In the process according to claim 1, wherein said liquid coolant comprises said original aluminum salt and sufficient of at least one other salt dissolved therein to form a liquid solution therewith at said lower temperature, said other salt being chemically non-reactive with the constituent elements of said aluminum salt in elemental form at said lower temperature.
- 6. In the process according to claim 5, wherein said liquid coolant comprises another salt containing only the said other element and another metal more chemically reactive than is aluminum at said lower temperature with said other element.
- 7. In the process according to claim 5, wherein heat which is removed in cooling said gas mixture by said liquid coolant is transferred to cooling coils in contact with said liquid coolant.
- 8. In the process according to claim 7, wherein a condensate film on said cooling coils acts as said liquid coolant for said gas mixture.
- 9. In the process according to claim 1, wherein said time interval of said flash cooling is not more than 0.001 to 0.1 seconds.
- 10. In the process according to claim 1, wherein heat removed in flash cooling said gaseous mixture is used to boil said liquid coolant.
- 11. In the process according to claim 10, wherein vapors formed in boiling said liquid coolant are condensed by a reflux condenser which condensate, so formed, is returned to the reservoir of said liquid coolant used in said flash cooling.
- 12. In the process according to claim 1, wherein said condensed aluminum is separated by physical means from said liquid coolant.
- 13. In the process according to claim 1, wherein said other element is one of the three lower halogens, and said aluminum salt is the corresponding tri-halide.
- 14. In the process according to claim 13, wherein said other element is chlorine and said liquid coolant contains aluminum tri-chloride.
- 15. In the process according to claim 13, wherein said liquid coolant comprises said aluminum tri-halide, and a halide of another metal higher than aluminum in the corresponding halogen affinity series.
- 16. In the process according to claim 15, wherein said liquid coolant comprises said aluminum trihalide and said halide of said other metal which are combined as a double salt.
- 17. In the process according to claim 15, wherein said liquid coolant comprises said aluminum trihalide combined as a chemical compound with said halide of said other metal.
- 18. In the process according to claim 17, wherein said chemical compound is cryolite.
- 19. In the process according to claim 1, wherein said high temperature is obtained through the production of a thermal plasma including said salt of aluminum.
- 20. In the process according to claim 1, wherein said aluminum which is condensed in said liquid coolant is in the liquid state.
Parent Case Info
This application is a Continuation in Part of copending Applications: - (a) U.S. Ser. No. 103,765 of January 4th, 1971 now Patent No. 3,793,003, (b) U.S. Ser. No. 308,059 of November 20th, 1972 now Patent No. 3,853,541, and (c) U.S. Ser. No. 370,310 of June 15th, 1973 now Patent No. 3,861,904, all having the same title, Method for Producing Aluminum Metal Directly from Ores, and all referred to hereinafter as the copending applications.
US Referenced Citations (6)
Related Publications (2)
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308059 |
Nov 1972 |
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370310 |
Jun 1973 |
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Continuations (1)
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103765 |
Jan 1971 |
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