Electrolytic reduction of alumina

Abstract

Finely divided particles of alumina are electrolytically reduced to aluminum in an electrolytic reduction vessel having a plurality of vertically disposed, non-consumable anodes and a plurality of vertically disposed, dimensionally stable cathodes in closely spaced, alternating arrangement with the anodes. A horizontally disposed, gas bubble generator is located at the vessel bottom, underlying the cathodes and the spaces between each pair of adjacent electrodes. The vessel contains a molten electrolyte bath composed of (1) NaF+Alf.sub.3 eutectic, (2) KF+AlF.sub.3 eutectic and (3) LiF. The alumina particles are maintained in suspension in the molten electrolyte bath by rising gas bubbles generated at the anodes and at the gas bubble generator during the reduction process.

Description

Claims

1. A method for the electrolytic reduction of alumina to aluminum in a vessel having a bottom and sidewalls, said method comprising the steps of:

containing within said vessel a molten electrolyte bath consisting essentially of (1) NaF+AlF.sub.3 eutectic, (2) KF+AlF.sub.3 eutectic and (3) LiF;

said molten electrolyte bath having a density less than the density of molten alumina and less than the density of alumina;

maintaining said bath at a temperature substantially below 950.degree. C.;

providing within said bath a plurality of vertically disposed, spaced apart, non-consumable anodes and a plurality of vertically disposed, spaced apart, dimensionally stable cathodes in close, alternating relation to said anodes, with a space defined between each pair of adjacent electrodes;

introducing finely divided alumina particles into said bath;

passing an electric current through said bath from said anodes to said cathodes;

forming bubbles of gaseous oxygen at each of said anodes;

allowing said bubbles to pass upwardly from said anodes;

forming a slurry composed of said finely divided alumina particles suspended in said molten electrolyte bath;

forming metallic aluminum at each cathode;

allowing said metallic aluminum to flow downwardly as molten aluminum along each cathode at which aluminum is formed, toward the bottom of said vessel;

and accumulating said molten aluminum at the bottom of said vessel.

2. A method as recited in claim 1 wherein:

said molten electrolyte is capable of dissolving some alumina;

said vessel has an interior lined with alumina;

and said method comprises maintaining the percentage of alumina, introduced into said slurry as alumina particles, high enough to at least contribute to the avoidance of substantial corrosion of said alumina interior lining by said molten electrolyte.

3. A method as recited in claim 2 wherein:

said step of maintaining the alumina percentage provides said slurry with an alumina content, introduced

as alumina, particles, of at least 2 wt. %.

4. A method, as recited in claim 1 and comprising:

maintaining an alumina content in said slurry in the range 2-30 wt. %.

5. A method as recited in claim 4 wherein:

said alumina content in the slurry is maintained in the range 5-10 wt. %.

6. A method as recited in claim 1 wherein:

said bath is maintained at a temperature in the range of about 660.degree. C. to about 800.degree. C.

7. A method as recited in claim 6 wherein:

said bath is maintained at a temperature in the range 730.degree. -760.degree. C.

8. A method as recited in claim 1 wherein:

said alumina particles have a mean size, expressed as equivalent spherical diameter, greater than about 1 micron and less than about 100 microns.

9. A method as recited in claim 8 wherein:

said alumina particles have a mean size in the range of about 2 to about 10 microns.

10. A method as recited in claim 1 wherein:

said anodes are composed of Cu - Ni - Fe cermet.

11. A method as recited in claim 1 wherein:

said molten electrolyte has a composition which provides a relatively low anode resistance, avoids excessive corrosion of the anode and avoids deposition of bath components on said cathodes.

12. A method as recited in claim 1 wherein:

said molten electrolyte contained within said vessel has a composition in the region A on the triangular compositional diagram for NaF+AlF.sub.3 eutectic--KF+AlF.sub.3 eutectic--LiF, depicted in FIG. 3.

13. A method as recited in claim 1 wherein the ingredients in said molten electrolyte contained within said vessel consist essentially of, in wt. % adjusted to exclude impurities:

______________________________________ NaF 6-26 KF 7-33 LiF 1-6 AlF.sub.3 60-65______________________________________

14. A method as recited in claim 1 comprising:

maintaining an alumina content in said slurry in the range 2-30 wt. %;

and substantially continuously measuring the temperature of said bath with a thermocouple contained within an alumina tube, without substantial corrosion of said alumina tube, by immersing said alumina tube in said slurry and maintaining it there throughout the electrolytic reduction process.

15. A method as recited in claim 1 wherein:

each of said anodes contains copper;

an oxide of copper forms at each anode during the passage of said electric current, at least during the beginning stages in the performance of said method;

and said method comprises the step of incorporating Li.sup.+ ions into said oxide of copper during said beginning stages, to decrease anode resistance during the performance of said method.

16. A method as recited in claim 15 wherein said incorporating step comprises:

after an initial passage of said electric current, turning the electric current off and then on, a plurality of times during said beginning stages, to allow Li.sup.+ ions to become incorporated into said metallic oxide during the off part of an on-off cycle.

17. A method as recited in claim 15 wherein:

said molten electrolyte bath contains about 1-6 wt. % LiF.

18. A method as recited in claim 1 comprising:

providing horizontally disposed gas bubble generating means at substantially the bottom of said vessel, in contact with said bath at a location underlying at least said cathodes and the spaces between adjacent electrodes;

generating gas bubbles at said gas bubble generating means;

and allowing said bubbles to pass upwardly from said gas bubble generating means.

19. A method as recited in claim 10 comprising:

maintaining the percentage of alumina in said slurry low enough to provide the slurry with a density less than that of molten alumina.

20. A method as recited in claim 19 wherein:

said step of maintaining the alumina percentage provides said slurry with an alumina content less than about 30 wt. %.

21. A method as recited in claim 18 wherein said gas bubble generating means comprises:

a horizontally disposed, non-consumable, auxiliary anode comprising means for forming bubbles of gaseous oxygen when an electric current is passed through said bath from said auxiliary anode to said cathodes.

22. A method as recited in claim 18 wherein said gas bubble generating means comprises:

a pair of laterally disposed anode parts each extending in an opposite direction from the bottom of each of said anodes to form a plurality of inverted T-shaped anodes;

each of said anode bottom parts underlying the space between its anode and a respective adjacent cathode;

adjacent anodes having anode bottom parts which cooperate to substantially underly the cathode between said adjacent anodes;

each anode bottom part comprising means for forming bubbles of gaseous oxygen when an electric current is passed through said bath from the corresponding anode to an adjacent cathode.

23. A method as recited in claim 18 wherein said gas bubble generating means comprises:

an anode part extending laterally from the bottom of each of said anodes to form a plurality of L-shaped anodes;

each anode bottom part underlying the space between its anode and an adjacent cathode and also at least substantially underlying said adjacent cathode;

each anode bottom part comprising means for forming bubbles of gaseous oxygen when an electric current is passed through said bath from the corresponding anode to an adjacent cathode.

24. A method as recited in claim 18 wherein said gas bubble generating means comprises:

25. A method for the electrolytic reduction of alumina to aluminum in a vessel having a bottom and sidewalls, said method comprising the steps of:

containing within said vessel a molten electrolyte bath consisting essentially of (1) NaF+AlF.sub.3 eutectic, (2) KF+AlF.sub.3 eutectic and (3) LiF;

maintaining said bath at a temperature substantially below 950.degree. C.;

providing within said bath a plurality of vertically disposed, spaced apart, non-consumable, copper-containing anodes and a plurality of vertically disposed, spaced apart, dimensionally stable cathodes in close, alternating relation with said anodes;

introducing finely divided alumina particles into said bath;

passing an electric current through said bath from said anodes to said cathodes;

forming metallic aluminum at each cathode;

forming an oxide of copper at each anode during the passage of said electric current, at least during the beginning stages in the performance of said method;

and incorporating Li.sup.+ ions into said oxide of copper during said beginning stages, to decrease anode resistance during the performance of said method.

26. A method as recited in claim 25 wherein said incorporating step comprises:

after an initial passage of said electric current, turning the electric current off and then on, a plurality of times during said beginning stages, to allow Li.sup.+ ions to become incorporated into said metallic oxide-during the off part of an on-off cycle.

27. A method as recited in claim 26 wherein:

said alumina particles are maintained in suspension in said slurry substantially uniformly throughout said slurry;

and said bubbles of gas rising from said gas bubble generating means at the vessel bottom at least contribute substantially to the maintenance of said suspension.

28. A method as recited in claim 25 wherein:

said molten electrolyte bath contains about 1-6 wt. % LiF.

29. A combination for use in the electrolytic reduction of alumina to aluminum, said combination comprising:

a vessel having a bottom and sidewalls;

a molten electrolyte bath contained within said vessel and consisting essentially of (1) NaF+AlF.sub.3 eutectic, (2) KF+AlF.sub.3 eutectic and (3) LiF;

said molten electrolyte bath having a density less than that of molten aluminum and less than that of alumina;

means for maintaining said bath at a temperature substantially below 950.degree. C.;

a plurality of electrodes within said bath, said electrodes including a plurality of vertically disposed, spaced apart, non-consumable anodes and a plurality of vertically disposed, spaced apart dimensionally stable cathodes in close, alternating relation to said primary anodes, with a space defined between each pair of adjacent electrodes;

means for introducing finely divided alumina particles into said bath;

means for passing an electric current through said bath from said anodes to said cathodes;

each of said anodes comprising means for forming, from said alumina, during passage of said electric current, bubbles of gaseous oxygen at said anode;

said combination comprising means for allowing said bubbles to pass upwardly from said anodes;

each of said cathodes comprising means for forming metallic aluminum at said cathode, during passage of said electric current;

said combination comprising means for allowing said metallic aluminum, formed at said cathodes, to flow downwardly as molten aluminum along each cathode at which aluminum is formed, toward the bottom of said vessel;

and means at the bottom of said vessel for accumulating and draining molten aluminum.

30. A combination as recited in claim 28 comprising:

a slurry contained within said vessel;

said slurry comprising finely divided alumina particles suspended in said molten electrolyte bath.

31. A combination as recited in claim 29 wherein:

said slurry has an alumina content in the range 30 wt. %.

32. A combination as recited in claim 30 wherein:

said vessel has an interior lined with alumina.

33. A combination as recited in claim 30 and comprising:

an alumina thermocouple tube immersed in said slurry.

34. A combination as recited in claim 29 wherein:

said alumina particles in the slurry have a mean size, expressed as equivalent spherical diameter, greater than about 1 micron and less than about 100 microns.

35. A combination as recited in claim 33 wherein:

said alumina particles have a mean size in the range of about 2 to about 10 microns.

36. A combination as recited in claim 29 wherein:

said slurry has an alumina content in the range 10 wt. %.

37. A combination as recited in claim 28 wherein:

said anodes are composed of Cu - Ni - Fe cermet.

38. A combination as recited in claim 28 wherein:

said molten electrolyte has a composition in the region A on the triangular compositional diagram for NaF+AlF.sub.3 eutectic--KF+AlF.sub.3 eutectic--LiF, depicted in FIG. 3.

39. A combination as recited in claim 28 wherein the ingredients in said molten electrolyte consist essentially of, in wt. % adjusted to exclude impurities:

40. A combination as recited in claim 28 comprising:

providing horizontally disposed gas bubble generating means at substantially the bottom of said vessel, in contact with said bath at a location underlying at least said cathodes and the spaces between adjacent electrodes;

generating gas bubbles at said gas bubble generating means;

and allowing said bubbles to pass upwardly from said gas bubble generating means.

______________________________________ NaF 6-26 KF 7-33 LiF 1-6 AlF.sub.3 60-65______________________________________

41. A combination as recited in claim 18 wherein said gas bubble generating means comprises:

a horizontally disposed, non-consumable, auxiliary anode comprising means for forming bubbles of gaseous oxygen when an electric current is passed through said bath from said auxiliary anode to said cathodes.

42. A combination as recited in claim 40 wherein said gas bubble generating means comprises:

a pair of laterally disposed anode parts each extending in an opposite direction from the bottom of each of said anodes to form a plurality of inverted T-shaped anodes;

each of said anode bottom parts underlying the space between its anode and a respective adjacent cathode;

adjacent anodes having anode bottom parts which cooperate to substantially underly the cathode between said adjacent anodes;

each anode bottom part comprising means for forming bubbles of gaseous oxygen when an electric current is passed through said bath from the corresponding anode to an adjacent cathode.

43. A combination as recited in claim 40 wherein said gas bubble generating means comprises:

an anode part extending laterally from the bottom of each of said anodes to form a plurality of L-shaped anodes;

each anode bottom part underlying the space between its anode and an adjacent cathode and also at least substantially underlying said adjacent cathode;

each anode bottom part comprising means for forming bubbles of gaseous oxygen when an electric current is passed through said bath from the corresponding anode to an adjacent cathode.

44. A combination as recited in claim 40 wherein said gas bubble generating means comprises gas sparger means.

45. A combination as recited in claim 40 comprising:

a slurry contained within said vessel;

said slurry comprising finely divided alumina particles suspended in said molten electrolyte bath;

said slurry having a density less than that of molten alumina.

46. A combination as recited in claim 45 wherein:

said slurry has an alumina content in the range 2-30 wt. %.

47. A slurry formed during a process for the electrolytic reduction of alumina to aluminum, said slurry consisting essentially of:

finely divided alumina particles suspended in a molten electrolyte;

said molten electrolyte consisting essentially of (1) NaF+AlF.sub.3 eutectic, (2) KF+AlF.sub.3 eutectic and (3) LiF.

48. A slurry as recited in claim 41 wherein:

said slurry has an alumina content in the range 2-30 wt. %.

49. A slurry as recited in claim 44 wherein:

said alumina particles in the slurry have a mean size, expressed as equivalent spherical diameter, greater than about 1 micron and less than about 100 microns.

50. A slurry as recited in claim 43 wherein:

said slurry has an alumina content in the range 5-10 wt. %.

51. A slurry as recited in claim 43 wherein:

said alumina particles in the slurry have a mean size, expressed as equivalent spherical diameter, greater than about 1 micron and less than about 100 microns.

52. A slurry as recited in claim 47 wherein:

said alumina particles have a mean size in the range of about 2 to about 10 microns.

53. A slurry as recited in claim 43 wherein:

said molten electrolyte has a composition in the region A on the triangular compositional diagram for NaF+AlF.sub.3 eutectic--KF+AlF.sub.3 eutectic--LiF, depicted in FIG. 3.

54. A slurry as recited in claim 43 wherein the ingredients in said molten electrolyte consist essentially of, in wt. % adjusted to exclude impurities:

______________________________________ NaF 6-26 KF 7-33 LiF 1-6 AlF.sub.3 60-65______________________________________

55. A molten electrolyte for use in the electrolytic reduction of alumina to aluminum, said molten electrolyte consisting essentially of:

(1) NaF+AlF.sub.3 eutectic, (2) KF+AlF.sub.3 eutectic and (3) LiF.

56. A molten electrolyte as recited in claim 51 wherein:

said molten electrolyte has a composition in region A on the triangular compositional diagram for NaF+AlF.sub.3 eutectic--KF+AlF.sub.3 eutectic--LiF, depicted in FIG. 3.

57. A molten electrolyte as recited in claim 51 wherein the ingredients in said molten electrolyte consist essentially of, in wt. % adjusted to exclude impurities:

______________________________________ NaF 6-26 KF 7-33 LiF 1-6 AlF.sub.3 60-65______________________________________

58. A composition for use as an electrolyte in the electrolytic reduction of alumina to aluminum, the ingredients in said composition consisting essentially of, in wt. % adjusted to exclude impurities:

______________________________________ NaF 6-26 KF 7-33 LiF 1-6 AlF.sub.3 60-65______________________________________

59. An apparatus for use in the electrolytic reduction of alumina to aluminum, said apparatus comprising:

a vessel having a bottom and sidewalls;

a plurality of electrodes extending into said vessel, said electrodes including a plurality of vertically disposed, spaced apart, non-consumable primary anodes and a plurality of vertically disposed, spaced apart dimensionally stable cathodes in close, alternating relation to said primary anodes, with a space defined between each pair of adjacent electrodes;

said space being defined unfilled by solid material;

and horizontally disposed gas bubble generating means at substantially the bottom of said vessel, at a location underlying at least said cathodes and the spaces between adjacent electrodes.

60. An apparatus as recited in claim 55 wherein:

said vessel has an interior lined with alumina.

61. An apparatus as recited in claim 55 comprising:

an alumina thermocouple tube extending into the interior of said vessel.

62. An apparatus as recited in claim 55 wherein said gas bubble generating means comprising:

a horizontally disposed, non-consumable, auxiliary anode comprising means for forming bubbles of gaseous oxygen, when an electric current is passed through said bath from said auxiliary anode to said cathodes.

63. An apparatus as recited in claim 55 wherein said gas bubble generating means comprises:

a pair of laterally disposed anode parts each extending in an opposite direction from the bottom of each of said anodes to form a plurality of inverted T-shaped anodes;

each of said anode bottom parts underlying the space between its anode and a respective adjacent cathode;

adjacent anodes having anode bottom parts which cooperate to substantially underly the cathode between said adjacent anodes;

each anode bottom part comprising means for forming bubbles of gaseous oxygen when an electric current is passed through said bath from the corresponding anode to an adjacent cathode.

64. An apparatus as recited in claim 55 wherein said gas bubble generating means comprises:

an anode part extending laterally from the bottom of each of said anodes to form a plurality of L-shaped anodes;

each anode bottom part underlying the space between its anode and an adjacent cathode and also at least substantially underlying said adjacent cathode;

each anode bottom part comprising means for forming bubbles of gaseous oxygen when an electric current is passed through said bath from the corresponding anode to an adjacent cathode.

65. An apparatus as recited in claim 55 wherein said gas bubble generating means comprises:

gas sparger means.