A nonimaging light assembly for flashlights, including a light source and a lens symmetrical about an optical axis for receiving light from the light source and producing therefrom a light beam having concentrated and divergent components resulting in a high intensity core beam surrounded by a smoot
A nonimaging light assembly for flashlights, including a light source and a lens symmetrical about an optical axis for receiving light from the light source and producing therefrom a light beam having concentrated and divergent components resulting in a high intensity core beam surrounded by a smoothly transitioning lower intensity surround beam. In a preferred embodiment utilizing a light emitting diode as the light source, the combined light beam produced by the light assembly has a substantially circular cross section.
대표청구항▼
1. A nonimaging light assembly, comprising: a light source; anda lens symmetrical about an optical axis, including a first rear surface intersecting said optical axis for receiving a first portion of light emanating from said light source positioned along said optical axis,a second rear surface exte
1. A nonimaging light assembly, comprising: a light source; anda lens symmetrical about an optical axis, including a first rear surface intersecting said optical axis for receiving a first portion of light emanating from said light source positioned along said optical axis,a second rear surface extending about said first rear surface for receiving a second portion of light emanating from said light source,a side surface for total-internally reflecting and substantially collimating light received by said second rear surface, anda front surface for exiting light reflected from said side surface and light received by said first rear surface;said lens having an axisymmetric profile substantially described by sample points thereon defined by x,y-coordinate pairs set forth in FIGS. 39a and 39b, incorporated herein by reference, where x represents position along an x-coordinate along said optical axis and y represents position along a y-coordinate radially from said optical axis, the x and y positions of said sample points subject however to reasonable tolerances, for exiting at said front surface a composite light beam comprising a first light component diverging from said optical axis produced from light received by said first rear surface combined with a concentrated substantially collimated second light component resulting in a core beam surrounded by a smoothly transitioning lower intensity surround beam. 2. The light assembly according to claim 1, wherein: the distance between said light source and said first rear surface is selected for allocating to said first rear surface approximately one-third of the light received by said lens from said light source. 3. The light assembly according to claim 1, wherein: said light source comprises a light emitting diode; andsaid composite light beam exiting said front surface has a substantially circular cross-section. 4. The light assembly according to claim 1, wherein: said light source has an approximately square configuration substantially perpendicular to said optical axis; andsaid composite light beam exiting said front surface has a substantially circular cross-section. 5. The light assembly according to claim 1, wherein: said tolerances have negligible effect on performance of said light assembly. 6. The light assembly according to claim 1, wherein: implementation of said tolerances does not noticeably degrade said composite light beam exiting from said front surface. 7. The light assembly according to claim 1, wherein: said x-coordinate and said y-coordinate are dimensioned in millimeters. 8. The light assembly according to claim 7, wherein: said tolerances have negligible effect on performance of said light assembly. 9. The light assembly according to claim 7, wherein: implementation of said tolerances does not noticeably degrade said composite light beam exiting from said front surface. 10. A nonimaging light assembly, comprising: a light source; anda lens symmetrical about an optical axis, including a first rear surface intersecting said optical axis for receiving a first portion of light emanating from said light source positioned along said optical axis,a second rear surface extending about said first rear surface for receiving a second portion of light emanating from said light source,a side surface for total-internally reflecting and substantially collimating light received by said second rear surface, anda substantially flat front surface for exiting light reflected from said side surface and light received by said first rear surface;said first rear surface, said second rear surface and said side surface of said lens having an axisymmetric profile substantially described by sample points thereon defined by x,y-coordinate pairs set forth in FIG. 40, incorporated herein by reference, where x represents position along an x-coordinate along said optical axis and y represents position along a y-coordinate radially from said optical axis, the x and y positions of said sample points subject however to reasonable tolerances, for exiting at said front surface a composite light beam comprising a first light component diverging from said optical axis produced from light received by said first rear surface combined with a concentrated substantially collimated second light component resulting in a core beam surrounded by a smoothly transitioning lower intensity surround beam. 11. The light assembly according to claim 10, wherein: said lens includes a flange section forwardly of said side surface and rearwardly of said front surface. 12. The light assembly according to claim 10, wherein: said tolerances have negligible effect on performance of said light assembly. 13. The light assembly according to claim 10, wherein: implementation of said tolerances does not noticeably degrade said composite light beam exiting from said front surface. 14. The light assembly according to claim 10, wherein: said x-coordinate and said y-coordinate are dimensioned in millimeters. 15. The light assembly according to claim 14, wherein: said lens includes a flange section forwardly of said side surface and rearwardly of said front surface. 16. The light assembly according to claim 14, wherein: said tolerances have negligible effect on performance of said light assembly. 17. The light assembly according to claim 14, wherein: implementation of said tolerances does not noticeable degrade said composite light beam exiting from said front surface. 18. The light assembly according to claim 10, wherein: the distance between said light source and said first rear surface is selected for allocating to said first rear surface approximately one-third of the light received by said lens from said light source. 19. The light assembly according to claim 10, wherein: said light source comprises a light emitting diode; andsaid composite light beam exiting said front surface has a substantially circular cross-section. 20. The light assembly according to claim 10, wherein: said light source has approximately square configuration substantially perpendicular to said optical axis; andsaid composite light beam exiting said front surface has a substantially circular cross-section. 21. The light assembly according to claim 10, wherein: said light source comprises a hybrid light emitting diode source including a first die and a second die, said lens optimized for use with said first die positioned on said optical axis, said light source adapted for replacing said first die with said second die on said optical axis. 22. The light assembly according to claim 10, wherein: said first die is a white-light die. 23. The light assembly according to claim 22, wherein: said second die is an infrared die. 24. A nonimaging light assembly, comprising: a light source; anda lens symmetrical about an optical axis, including a substantially circular first rear surface intersecting said optical axis for receiving a first portion of light emanating from said light source positioned along said optical axis,a second rear surface extending about said first rear surface for receiving a second portion of light emanating from said light source, said second rear surface having an axisymmetric profile substantially described by sample points thereon defined by x,y-coordinate pairs set forth in FIG. 41, incorporated herein by reference, where x represents position along an x-coordinate along said optical axis and y represents position along a y-coordinate radially from said optical axis, the x and y positions of said sample points subject however to reasonable tolerances,a side surface having an axisymmetric profile for total-internally reflecting and substantially collimating light received by said second rear surface, anda substantially flat front surface for exiting light reflected from said side surface and light received by said first rear surface;the diameter of said first rear surface, said axisymmetric profile of said second rear surface, and said axisymmetric profile of said side surface being related for exiting at said front surface a composite light beam comprising a first light component diverging from said optical axis produced from light received by said first rear surface combined with a concentrated substantially collimated second light component resulting in a core beam surrounded by a smoothly transitioning lower intensity surround beam. 25. The light assembly according to claim 24, wherein: said lens includes a flange section forwardly of said side surface and rearwardly of said front surface. 26. The light assembly according to claim 24, wherein: said tolerances have negligible effect on performance of said light assembly. 27. The light assembly according to claim 24, wherein: implementation of said tolerances does not noticeable degrade said composite light beam exiting from said front surface. 28. The light assembly according to claim 24, wherein: said x-coordinate and said y-coordinate are dimensioned in millimeters. 29. The light assembly according to claim 28, wherein said lens includes a flange section forwardly of said side surface and rearwardly of said front surface. 30. The light assembly according to claim 28, wherein: said tolerances have negligible effect on performance of said light assembly. 31. The light assembly according to claim 28, wherein: implementation of said tolerances does not noticeable degrade said composite light beam exiting from said front surface. 32. The light assembly according to claim 24, wherein: said first rear surface comprises a refractive surface substantially perpendicular to said optical axis;said front surface comprises a refractive surface substantially perpendicular to said optical axis;said second rear surface comprises an aspheric refractive surface; andsaid side surface comprises an aspheric total-internal reflective surface, said axisymmetric profile of said side surface substantially described by sample points thereon defined by x,y-coordinate pairs set forth in FIG. 42, incorporated herein by reference, where x represents position along an x-coordinate along said optical axis and y represents position along a y-coordinate radially from said optical axis, the x and y positions noted in FIG. 42 subject however to reasonable tolerances. 33. The light assembly according to claim 32, wherein: said first rear surface is substantially flat. 34. The light assembly according to claim 32, wherein: said lens includes a flange section forwardly of said side surface and rearwardly of said front surface. 35. The light assembly according to claim 32, wherein: said tolerances have negligible effect on performance of said light assembly. 36. The light assembly according to claim 32, wherein: implementation of said tolerances does not noticeably degrade said composite light beam exiting from said front surface. 37. The light assembly according to claim 32, wherein: said x-coordinate and said y-coordinate are dimensioned in millimeters. 38. The light assembly according to claim 37, wherein: said lens includes a flange section forwardly of said side surface and rearwardly of said front surface. 39. The light assembly according to claim 37, wherein: said tolerances have negligible effect on performance of said light assembly. 40. The light assembly according to claim 37, wherein: implementation of said tolerances does not noticeably degrade said composite light beam exiting from said front surface. 41. A nonimaging light assembly, comprising: a light source; anda lens symmetrical about an optical axis, including a substantially circular first rear surface intersecting said optical axis for receiving a first portion of light emanating from said light source positioned along said optical axis,a second rear surface extending about said first rear surface and having an axisymmetric profile for receiving a second portion of light emanating from said light source,a side surface for total-internally reflecting and substantially collimating light received by said second rear surface, said side surface having an axisymmetric profile substantially described by sample points thereon defined by x,y-coordinate pairs set forth in FIG. 42, incorporated herein by reference, where x represents position along an x-coordinate along said optical axis and y represents position along a y-coordinate radially from said optical axis, the x and y positions of said sample points subject however to reasonable tolerances, anda substantially flat front surface for exiting light reflected from said side surface and light received by said first rear surface;the diameter of said first rear surface, said axisymmetric profile of said second rear surface, and said axisymmetric profile of said side surface being related for exiting at said front surface a composite light beam comprising a first light component diverging from said optical axis produced from light received by said first rear surface combined with a concentrated substantially collimated second light component resulting in a core beam surrounded by a smoothly transitioning lower intensity surround beam. 42. The light assembly according to claim 41, wherein: said lens includes a flange section forwardly of said side surface and rearwardly of said front surface. 43. The light assembly according to claim 41, wherein: said tolerances have negligible effect on performance of said light assembly. 44. The light assembly according to claim 41, wherein: implementation of said tolerances does not noticeably degrade said composite light beam exiting from said front surface. 45. The light assembly according to claim 41, wherein: said x-coordinate and said y-coordinate are dimensioned in millimeters. 46. The light assembly according to claim 45, wherein: said lens includes a flange section forwardly of said side surface and rearwardly of said front surface. 47. The light assembly according to claim 45, wherein: said tolerances have negligible effect on performance of said assembly. 48. The light assembly according to claim 45, wherein: implementation of said tolerances does not noticeably degrade said composite light beam exiting from said front surface.
Taylor, Wilfrid E.; Taylor, Wilfrid L.; Taylor, James R.; Kappel, David W.; Wu, Paul Nam-Kwan, Optical lens system for projecting light in a lambertion pattern from a high power led light source.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.