Light redirecting films including non-interlockable optical elements
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F21V-005/02
F21V-005/00
출원번호
US-0954551
(2004-09-30)
등록번호
US-7364341
(2008-04-29)
발명자
/ 주소
Parker,Jeffery R.
McCollum,Timothy A.
출원인 / 주소
Solid State Opto Limited
대리인 / 주소
Renner, Otto, Boisselle & Sklar, LLP
인용정보
피인용 횟수 :
28인용 특허 :
87
초록▼
The light redirecting films include a thin optically transparent substrate having a pattern of non-interlocking individual optical elements oriented and placed to produce a desired surface coverage of at least one of the surfaces of the transparent substrate of the transparent substrate occupied by
The light redirecting films include a thin optically transparent substrate having a pattern of non-interlocking individual optical elements oriented and placed to produce a desired surface coverage of at least one of the surfaces of the transparent substrate of the transparent substrate occupied by the optical elements. At least some of the optical elements may have at least one flat surface and at least one curved surface that may intersect each other to a greater extent on the curved surface than on the flat surface to increase the relative percentage of flat surface area to curved surface area of the intersecting optical elements to increase the on axis gain of light passing through the film.
대표청구항▼
What is claimed is: 1. A light redirecting film comprising a thin optically transparent substrate having a light entrance surface for receiving light from a light source and an opposite light exit surface, at least one of the surfaces having a pattern of individual optical elements of well defined
What is claimed is: 1. A light redirecting film comprising a thin optically transparent substrate having a light entrance surface for receiving light from a light source and an opposite light exit surface, at least one of the surfaces having a pattern of individual optical elements of well defined shape having at least two sloping surfaces and being quite small relative to the length and width of the substrate to redistribute light passing through the substrate in a predetermined angular distribution, at least some of the optical elements being non-interlockable optical elements having a geometric shape that prevents the non-interlockable optical elements from interlocking with each other, the non-interlockable optical elements being oriented and placed to produce a desired coverage of the portion of at least one of the surfaces of the substrate within the pattern of non-interlockable optical elements, wherein at least some of the non-interlockable optical elements intersect each other over an intersection area to achieve substantially complete surface coverage of at least one of the surfaces of the substrate within the pattern of non-interlockable optical elements. 2. The film of claim 1 wherein the relative percentage of the remaining flat surface area to the remaining curved surface area of the optical elements that intersect each other is greater than 60%. 3. The film of claim 1 wherein the relative percentage of the remaining flat surface area to the remaining curved surface area of the optical elements that intersect each other is greater than 75%. 4. The film of claim 1 wherein at least some of the optical elements intersect each other only on the curved surface of the optical elements to increase the relative percentage of flat surface area to curved surface area of the optical elements to increase on axis gain of light passing through the substrate. 5. The film of claim 1 wherein the predetermined angular distribution of the light passing through the substrate is in a direction approximately normal to the substrate. 6. The film of claim 1 wherein the predetermined angular distribution of the light passing through the substrate has a peak angular distribution that is normal to the substrate. 7. The film of claim 1 wherein the position or placement of the optical elements on at least one of the surfaces is randomized. 8. The film of claim 1 wherein at least some of the optical elements have at least two curved surfaces, one of the curved surfaces of the optical elements having a smaller radius than the other curved surface, the optical elements being quite small relative to the length and width of the substrate to redistribute light passing through the substrate in a predetermined angular distribution, and wherein at least some of the optical elements intersect each other to a greater extent on the one curved surface of the optical elements than on the other curved surface to decrease the relative percentage of the one curved surface to the other curved surface of the optical elements to increase on axis gain of light passing through the substrate. 9. The film of claim 8 wherein the predetermined angular distribution of the light passing through the substrate is in a direction approximately normal to the substrate. 10. The film of claim 8 wherein the predetermined angular distribution of the light passing through the substrate has a peak angular distribution that is normal to the substrate. 11. The film of claim 1 wherein at least one of the sloping surfaces is flat and at least one other of the sloping surfaces is curved. 12. The film of claim 1 wherein the surface coverage is greater than 90%. 13. The film of claim 1 wherein at least some of the optical elements also interlock each other to achieve substantially complete surface coverage of at least one of the surfaces of the substrate within the pattern of optical elements. 14. The film of claim 1 wherein the predetermined angular distribution of the light passing through the substrate is in a direction approximately normal to the substrate. 15. The film of claim 1 wherein the predetermined angular distribution of the light passing through the substrate has a peak angular distribution that is normal to the substrate. 16. The film of claim 1 wherein at least some of said optical elements have at least two sides or surfaces that come together to form a ridge, said ridge having at least one section that is non-distinct or misshaped, wherein: where: Ai=The surface area of the ith side and Bj=The surface area of the jth non-distinct ridge section n=The number of sides m=The number of non-distinct ridge sections. 17. The film of claim 16 wherein the predetermined angular distribution of the light passing through the substrate is in a direction more normal to the substrate. 18. The film of claim 1 wherein at least some of said optical elements have at least two sides or surfaces that come together to form a ridge, said ridge having at least one section that is non-distinct or misshaped, wherein: where: αi=The surface area of the ith side if the ridge was fully formed or replicated, and βj=The side surface area that is missing because of the jth non-distinct ridge section, n=The number of sides if the ridge was fully formed or replicated, m=The number of non-distinct ridge sections. 19. The film of claim 18 wherein the predetermined angular distribution of the light passing through the substrate is in a direction approximately normal to the substrate. 20. The film of claim 1 wherein said optical elements have only two sides or surfaces, one of the sides being flat and the other side being curved, the two sides coming together to form a ridge, said ridge having a flattened, rounded, curved or otherwise misshaped peak, wherein: where: R=Radius of curvature of the curved side, D=Peak depth or height of the optical element, θ=Interior angle of the flat side to the surface of the substrate, and γ=Width of the flattened, rounded, curved or otherwise misshaped ridge peak when viewed from above and normal to the substrate. 21. The film of claim 20 wherein the predetermined angular distribution of the light passing through the substrate is in a direction approximately normal to the substrate. 22. A light redirecting film comprising a thin optically transparent substrate having a light entrance surface for receiving light from a light source and an opposite light exit surface, at least one of the surfaces having a pattern of individual optical elements of well defined shape having at least two sloping surfaces and being quite small relative to the length and width of the substrate to redistribute light passing through the substrate in a predetermined angular distribution, at least some of the optical elements being non-interlockable optical elements having a geometric shape that prevents the non-interlockable optical elements from interlocking with each other, the non-interlockable optical elements being oriented and placed to produce a desired coverage of the portion of at least one of the surfaces of the substrate within the pattern of non-interlockable optical elements, wherein some portion of the area of the one surface of the substrate, within the pattern of non-interlockable optical elements, has an area that is not completely covered by the non-interlockable optical elements, and another portion or portions of the area of the one surface of the substrate, within the pattern of non-interlockable optical elements, has an area where the non-interlockable optical elements intersect each other over an intersection area which alters a perimeter shape of the intersecting non-interlockable optical elements and increases the amount of coverage of the surface of the substrate within the pattern of non-interlockable optical elements. 23. The film of claim 22 wherein the percentage of unpatterned area is chosen to fit a particular application. 24. The film of claim 22 wherein the entire area within the pattern of non-interlockable optical elements that is not completely covered by the non-interlockable optical elements has one or more of an optically smooth finish, a surface treatment, a texture, or a coating. 25. The film of claim 22 wherein the predetermined angular distribution of the light passing through the substrate is in a direction approximately normal to the substrate. 26. The film of claim 22 wherein the predetermined angular distribution of the light passing through the substrate has a peak angular distribution that is normal to the substrate. 27. A light redirecting film comprising a thin optically transparent substrate having a light entrance surface for receiving light from a light source and an opposite light exit surface, at least one of the surfaces having a pattern of individual optical elements of well defined shape that are quite small relative to the length and width of the substrate to redistribute light passing through the substrate in a predetermined angular distribution, at least some of the optical elements being non-interlockable optical elements having a geometric shape that prevents the non-interlockable optical elements from interlocking with each other, the non-interlockable optical elements being oriented and placed to produce a desired coverage of the portion of at least one of the surfaces of the substrate within the pattern of non-interlockable optical elements, wherein the non-interlockable optical elements have at least one curved surface and at least one flat surface, and at least some of the non-interlockable optical elements are positioned to intersect each other over an intersection area in order to increase the amount of coverage of the surface of the substrate within the pattern of non-interlockable optical elements. 28. The film of claim 27 wherein the coverage of the portion of at least one of the surfaces within the pattern of non-interlockable optical elements is substantially complete. 29. The film of claim 27 wherein the pattern of non-interlockable optical elements is comprised of at least two different shaped optical elements. 30. The film of claim 27 wherein the pattern of optical elements is on the light exit surface of the substrate. 31. The film of claim 27 wherein the pattern of optical elements is on the light entrance surface of the substrate. 32. The film of claim 27 wherein the predetermined angular distribution of the light passing through the substrate is in a direction approximately normal to the substrate. 33. The film of claim 27 wherein the light passing through the substrate has a peak angular distribution that is normal to the substrate. 34. The film of claim 27 wherein the percentage of uncovered area of the surface within the pattern of non-interlockable optical elements is chosen to fit a particular application. 35. The film of claim 27 wherein the uncovered area of the surface within the pattern of non-interlockable optical elements has one or more of an optically smooth finish, a surface treatment, a texture, or a coating. 36. A light redirecting film comprising a thin optically transparent substrate having a light entrance surface for receiving light from a light source and an opposite light exit surface, at least one of the surfaces having a pattern of individual optical elements of well defined shape having at least two sloping surfaces and being quite small relative to the length and width of the substrate to redistribute light passing through the substrate in a predetermined angular distribution, wherein at least some portion of the area of the one surface of the substrate, within the pattern of optical elements, has an area that is not completely covered by the optical elements leaving said area unpatterned, and wherein the position or placement of the optical elements on at least one of the surfaces is randomized. 37. A light redirecting film comprising a thin optically transparent substrate having a light entrance surface for receiving light from a light source and an opposite light exit surface, at least one of the surfaces having a pattern of individual optical elements of well defined shape that are quite small relative to the length and width of the substrate to redistribute light passing through the substrate in a predetermined angular distribution, at least some of the optical elements being non-interlockable optical elements having a geometric shape that prevents the non-interlockable optical elements from interlocking with each other, the non-interlockable optical elements being oriented and placed to produce a desired coverage of the portion of at least one of the surfaces of the substrate within the pattern of non-interlockable optical elements, and wherein the position or placement of the non-interlockable optical elements on at least one of the surfaces is randomized. 38. A light redirecting film comprising a thin optically transparent substrate having a light entrance surface for receiving light from a light source and an opposite light exit surface, at least one of the surfaces having a pattern of individual optical elements of well defined shape having at least two sloping surfaces and being quite small relative to the length and width of the substrate to redistribute light passing through the substrate in a predetermined angular distribution, wherein at least some of the optical elements intersect each other to achieve substantially complete surface coverage of at least one of the surfaces of the substrate within the pattern of optical elements, and wherein the position or placement of the optical elements on at least one of the surfaces is randomized. 39. A light redirecting film comprising a thin optically transparent substrate having a light entrance surface for receiving light from a light source and an opposite light exit surface, at least one of the surfaces having a pattern of individual optical elements of well defined shape that are quite small relative to the length and width of the substrate to redistribute light passing through the substrate in a predetermined angular distribution, at least some of the optical elements being non-interlockable optical elements having a geometric shape that prevents the non-interlockable optical elements from interlocking with each other, the non-interlockable optical elements being oriented and placed to produce a desired coverage of the portion of at least one of the surfaces of the substrate within the pattern of non-interlockable optical elements, wherein the non-interlockable optical elements have at least one curved surface and at least one flat surface, and at least some of the non-interlockable optical elements are positioned to intersect each other in order to increase the amount of coverage of the surface of the substrate within the pattern of non-interlockable optical elements, and wherein at least some of the non-interlockable optical elements are positioned to intersect each other to a greater extent on the curved surface than on the flat surface to increase the relative percentage of flat surface area to curved surface area of the non-interlockable optical elements to increase on axis gain of light passing through the substrate. 40. The film of claim 39 wherein the surface coverage is greater than 90%.
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