Claims
- 1. An arc utilizing device, comprising:a first electrode; a second electrode electrically insulated and disposed radially outward from said first electrode; said electrodes forming a gap region across which an arc is established, and a structure for modification of said arc, said modification including rotation of said arc.
- 2. A spark plug device, comprising:a substantially electrically insulating shell; a first electrode situated substantially within said shell, said first electrode having a length protruding from said shell defining an axis for rotation; a second electrode disposed radially outward from said first electrode; said electrodes forming a gap region across which an arc is established, and a structure for modification of said arc, said modification including rotation of said arc.
- 3. The spark plug device of claim 2, wherein said structure for modification is adapted for oscillating or causing fluctuations of said arc.
- 4. The spark plug device of claim 2, wherein said structure for modification includes at least one magnet.
- 5. The spark plug device of claim 4, wherein said at least one magnet is a permanent magnet.
- 6. The spark plug device of claim 2, wherein said first electrode includes a broadened tip for at least a portion of said first electrode length within said gap region, said broadened length having larger cross sectional areas relative to cross sectional areas adjacent to said gap region.
- 7. The spark plug device of claim 2, wherein said arc rotates in a path substantially around said axis for rotation.
- 8. The spark plug device of claim 7, wherein said structure for modification provides a magnetic field oriented substantially parallel to said axis for rotation, whereby an electric field in said gap region generated from an electrical potential applied between said electrodes is oriented substantially perpendicular to said magnetic field.
- 9. The spark plug device of claim 8, wherein said structure for modification provides a magnetic field in said gap region of from approximately 0.05 to 1 Tesla.
- 10. The spark plug device of claim 8, wherein said gap region is substantially annular.
- 11. The spark plug device of claim 10, wherein said electrode spacing is approximately 0.5 mm to 4 mm in said gap region.
- 12. The spark plug device of claim 10, wherein said applied electrical potential is from approximately 5 kV to 80 kV.
- 13. The spark plug device of claim 4, wherein said magnet is at least one electromagnet.
- 14. The spark plug device of claim 12, wherein said electromagnet is also used to provide a pulsed electrical field between said electrodes.
- 15. A method for operating a spark plug device, comprising the steps of:providing a spark plug device having a substantially electrically insulating shell, a first electrode situated substantially within said shell, said first electrode having a length protruding from said shell defining an axis for rotation, a second electrode disposed radially outward from said first electrode, said electrodes forming a gap region across which an arc is established, and modifying said arc, said modifying including rotating said arc.
- 16. The method for operating a spark plug device of claim 15, further comprising the step of oscillating or causing fluctuations of said arc.
- 17. The method for operating a spark plug device of claim 15, wherein said spark plug includes at least one magnet for modifying said arc.
- 18. The method for operating a spark plug device of claim 17, wherein said at least one magnet is a permanent magnet.
- 19. The method for operating a spark plug device of claim 17, wherein said rotation is at least in part around said axis for rotation, said at least one magnet generates a magnetic field oriented substantially parallel to said axis for rotation, whereby an electric field in said gap region generated from an electrical potential applied between said electrodes is oriented substantially perpendicular to said magnetic field.
- 20. The method for operating a spark plug device of claim 17, wherein said at least one magnet generates a magnetic field strength in said gap region of approximately 0.05 to 1 Tesla.
- 21. The method for operating a spark plug device of claim 19, wherein said gap region is substantially annular.
- 22. The method for operating a spark plug device of claim 21, wherein said electrode spacing is approximately 0.5 mm to 4 mm in said gap region and said applied electrical potential is from approximately 5 kV to 80 kV.
- 23. A method for operating a combustion engine, comprising the steps of:providing a spark plug device having a substantially electrically insulating shell, a first electrode situated substantially within said shell, said first electrode having a length protruding from said shell defining an axis for rotation, a second electrode disposed radially outward from said first electrode, said electrodes forming a gap region across which an arc is established; modifying said arc, wherein said arc modifying includes rotating said arc, and operating said combustion engine to produce combustion.
- 24. The method for operating a combustion engine of claim 23, further comprising the step of causing oscillations or fluctuations in output of said arc.
- 25. The method for operating a combustion engine of claim 23, further comprising the step of providing said spark plug with at least one magnet for modifying said arc.
- 26. The method for operating a combustion engine of claim 25, wherein said at least one magnet is a permanent magnet.
- 27. The method for operating a combustion engine of claim 25, wherein said rotation is at least in part around said axis for rotation, said at least one magnet generates a magnetic field oriented substantially parallel to said axis for rotation, whereby an electric field in said gap region generated from an electrical potential applied between said electrodes is oriented substantially perpendicular to said magnetic field.
- 28. The method for operating a combustion engine of claim 25, wherein said at least one magnet generates a magnetic field strength in said gap region of from approximately 0.05 to 1 Tesla.
- 29. The method for operating a combustion engine of claim 27, wherein said gap region is substantially annular having a nearly constant electrode spacing throughout.
- 30. The method for operating a combustion engine of claim 29, wherein said electrode spacing is approximately 0.5 mm to 4 mm in said gap region and said applied electrical potential is from approximately 5 kV to 80 kV.
- 31. The method of operating a combustion engine of claim 23, wherein said operating said combustion engine to produce combustion produces levels of NOx which are reduced compared to NOx levels generated by combustion engines using conventional spark plugs.
- 32. The method of operating a combustion engine of claim 23, wherein said operating said combustion engine produces levels of NOx which are reduced compared to NOx levels generated by combustion engines using conventional spark plugs and fuel efficiency of said combustion engine is enhanced compared to combustion engines which use conventional spark plugs.
- 33. The method of operating a combustion engine of claim 23, further comprising the step of supplying a lean-burn fuel mixture to said combustion engine.
- 34. The method of operating a combustion engine of claim 33, wherein the air to fuel ratio used by said combustion engine is from approximately 20:1 to approximately 100:1.
- 35. A combustion engine comprising:at least one cylinder, said at least one cylinder for receiving a combustible fuel mixture therein, and a spark plug to combust said combustible fuel mixture, said spark plug including a first electrode situated substantially within a shell, said first electrode having a length protruding from said shell defining an axis for rotation; a second electrode disposed radially outward from said first electrode, said electrodes forming a gap region across which an arc is established, and a structure for modification of said arc, said modification including rotation.
- 36. The combustion engine of claim 35, wherein an output of said arc oscillates.
- 37. The combustion engine of claim 35, wherein said structure for modification includes at least one magnet.
- 38. The combustion engine of claim 37, wherein said at least one magnet is a permanent magnet.
- 39. The combustion engine of claim 37, wherein said rotation is at least in part around said axis for rotation, said at least one magnet generates a magnetic field oriented substantially parallel to said axis for rotation, whereby an electric field in said gap region generated from an electrical potential applied between said electrodes is oriented substantially perpendicular to said magnetic field.
- 40. The combustion engine of claim 37, wherein said at least one magnet provides a magnetic field strength in said gap region of from approximately 0.05 to 1 Tesla.
- 41. The combustion engine of claim 39, wherein said gap region is substantially annular.
- 42. The combustion engine of claim 41, wherein said electrode spacing is approximately 0.5 mm to 4 mm in said gap region and said applied electrical potential is from approximately 5 kV to 80 kV.
- 43. The combustion engine of claim 35, wherein said combustible fuel mixture is a lean-burn mixture.
- 44. The combustion engine of claim 43, wherein said combustible fuel mixture comprises an air to fuel ratio of from approximately 20:1 to approximately 100:1.
STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT
The United States Government has rights in this invention pursuant to Contract No. DE-AC05-00OR22725 between the United States Department of Energy and UT-Battelle, LLC.
US Referenced Citations (5)