Method and apparatus for ophthalmic devices including gradient-indexed liquid crystal layers and shaped dielectric layers
First Claim
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1. An ophthalmic lens device with a sealed variable optic insert positioned within at least a portion of an optical zone of the ophthalmic lens device, wherein the variable optic insert comprises:
- a curved front surface and a curved back surface, wherein the front surface and the back surface are configured to bound at least a portion of one chamber;
a dielectric layer proximate to at least one of the curved front surface and the curved back surface, wherein a thickness of the dielectric layer varies at least within the portion within the optical zone;
an energy source embedded in the variable optic insert in at least a region comprising a non-optical zone;
a layer containing liquid crystal material positioned within the at least one chamber, wherein the layer includes regions of liquid crystal material aligned in a pattern by a non-rubbed alignment layer which orients molecules in the liquid crystal material thereby varying the index of refraction across at least a first portion of the variable optic insert with a radial dependence in the absence of an electric field;
wherein the index of refraction of the layer containing liquid crystal material across at least the first portion of the optic insert has a parabolic dependence on a radial dimension in the absence of an electric field; and
wherein an optical effect of the layer containing liquid crystal material is supplemented by an effect of different radii of the curved front surface and the curved back surface.
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Abstract
This invention discloses methods and apparatus for providing a variable optic insert into an ophthalmic lens. A liquid crystal layer may be used to provide a variable optic function and in some embodiments, an alignment layer for the liquid crystal layer may be patterned in a radially dependent manner. The patterning may allow for the index of refraction of the optic device to vary in a gradient indexed or GRIN manner. At least a first layer of dielectric material that may vary in thickness at least across the optic zone of the device may aid in defining an electric field across the liquid crystal layer. An energy source is capable of powering the variable optic insert included within the ophthalmic lens. In some embodiments, an ophthalmic lens is cast-molded from a silicone hydrogel. The various ophthalmic lens entities may include electroactive liquid crystal layers to electrically control optical characteristics.
70 Citations
35 Claims
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1. An ophthalmic lens device with a sealed variable optic insert positioned within at least a portion of an optical zone of the ophthalmic lens device, wherein the variable optic insert comprises:
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a curved front surface and a curved back surface, wherein the front surface and the back surface are configured to bound at least a portion of one chamber; a dielectric layer proximate to at least one of the curved front surface and the curved back surface, wherein a thickness of the dielectric layer varies at least within the portion within the optical zone; an energy source embedded in the variable optic insert in at least a region comprising a non-optical zone; a layer containing liquid crystal material positioned within the at least one chamber, wherein the layer includes regions of liquid crystal material aligned in a pattern by a non-rubbed alignment layer which orients molecules in the liquid crystal material thereby varying the index of refraction across at least a first portion of the variable optic insert with a radial dependence in the absence of an electric field; wherein the index of refraction of the layer containing liquid crystal material across at least the first portion of the optic insert has a parabolic dependence on a radial dimension in the absence of an electric field; and wherein an optical effect of the layer containing liquid crystal material is supplemented by an effect of different radii of the curved front surface and the curved back surface. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
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9. An ophthalmic lens device with a variable optic insert positioned within at least a portion of an optical zone of the ophthalmic lens device, wherein the variable optic insert comprises:
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a curved first front surface and a curved first back surface wherein the first front surface and the first back surface are configured to bound at least a portion of a first chamber; a curved second front surface and a curved second back surface wherein the second front surface and the second back surface are configured to bound at least a portion of a second chamber; a dielectric layer proximate to at least one of the curved first front surface and the curved first back surface, wherein a thickness of the dielectric layer varies at least within the portion within the optical zone; at least one layer containing liquid crystal material positioned within the at least one chamber, wherein the at least one layer includes regions of liquid crystal material aligned in a pattern by a non-rubbed alignment layer which orients molecules in the liquid crystal material thereby varying the index of refraction across at least a first portion of the variable optic insert with a radial dependence in the absence of an electric field; wherein an optical effect of the layer containing liquid crystal material is supplemented by an effect of different radii of the curved first front surface and the curved first back surface; wherein an optical effect of the layer containing liquid crystal material is supplemented by an effect of different radii of the curved second front surface and the curved second back surface and an energy source embedded in the insert in at least a region comprising a non-optical zone. - View Dependent Claims (10, 11, 12, 13, 14, 15, 16, 17)
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18. A contact lens device with a variable optic insert positioned within at least a portion of an optical zone of the contact lens device, wherein the variable optic insert comprises:
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a curved first front surface and a curved first back surface wherein the first front surface and the first back surface are configured to form at least a first chamber; a first layer of electrode material proximate to the curved first front surface; a second layer of electrode material proximate to the curved first back surface; a dielectric layer proximate to at least one of the curved first front surface and the curved first back surface, wherein the dielectric layer varies in thickness at least within the portion within the optical zone; a first layer containing liquid crystal material positioned within the first chamber, wherein the first layer includes regions of liquid crystal material aligned in a first pattern by a non-rubbed alignment layer which orients molecules in the liquid crystal material thereby varying the first index of refraction across at least a first portion of the variable optic insert with a first radial dependence in the absence of an electric field, wherein an optical effect of the layer containing liquid crystal material is supplemented by an effect of different radii of the curved first front surface and the curved first back surface; wherein the first layer containing liquid crystal material varies its first index of refraction affecting a first ray of light traversing the first layer containing liquid crystal material when a first electric potential is applied across the first layer of electrode material and the second layer of electrode material; a curved second front surface and a curved second back surface wherein the second front surface and the second back surface are configured to form at least a second chamber; a third layer of electrode material proximate to the curved second front surface; a fourth layer of electrode material proximate to the curved second back surface; a second layer containing liquid crystal material positioned within the second chamber, wherein the second layer includes regions of liquid crystal material aligned by a second non-rubbed alignment layer which orients molecules in the liquid crystal material thereby varying the second index of refraction across at least a second portion of the variable optic insert varies with a second radial dependence in the absence of an electric field, wherein an optical effect of the layer containing liquid crystal material is supplemented by an effect of different radii of the curved second front surface and the curved second back surface; wherein the second layer containing liquid crystal material varies its second index of refraction affecting a second ray of light traversing the second layer containing liquid crystal material when a second electric potential is applied across the third layer of electrode material and the fourth layer of electrode material; an energy source embedded in the insert in at least a region comprising a non-optical zone; an electrical circuit comprising a processor, wherein the electrical circuit controls a flow of electrical energy from the energy source to one or more of the first, second, third or fourth electrode layers; and wherein the variable optic insert alters a focal characteristic of the contact lens device.
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19. A contact lens device with a variable optic insert positioned within at least a portion of an optical zone of the contact lens device, wherein the variable optic insert comprises:
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a layer containing liquid crystal material positioned within the variable optic insert, wherein the layer includes regions of liquid crystal material aligned by a non-rubbed alignment layer which orients molecules in the liquid crystal material thereby varying the index of refraction across at least a first portion of the variable optic insert with a radial dependence in the absence of an electric field; and a dielectric layer proximate to the layer containing liquid crystal material, wherein the dielectric layer varies in thickness at least within the portion within the optical zone wherein at least a first surface of the layer containing liquid crystal material is curved with a first radius and a second surface of the layer containing liquid crystal material is curved with a second radius.
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20. An ophthalmic lens device with a variable optic insert positioned within at least a portion of an optical zone of the ophthalmic lens device, wherein the variable optic insert comprises:
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an insert front curve piece and an insert back curve piece, wherein a back surface of the front curve piece has a first radius of curvature and a front surface of the back curve piece has a second radius of curvature wherein the different radii of curvature cause an optical effect; a dielectric layer proximate to at least one of the front curve piece and the back curve piece, wherein a thickness of the dielectric layer varies at least within the portion within the optical zone; an energy source embedded in the insert in at least a region comprising a non-optical zone; and a layer containing liquid crystal material, wherein the layer includes regions of liquid crystal material aligned by a non-rubbed alignment layer which orients molecules in the liquid crystal material thereby varying the index of refraction across at least a first portion of the variable optic insert with a parabolic dependence on a radial dimension in the absence of an electric field. - View Dependent Claims (21, 22, 23, 24, 25, 26, 27)
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28. An ophthalmic lens device with a variable optic insert positioned within at least a portion of an optical zone of the ophthalmic lens device, wherein the variable optic insert comprises:
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an insert front curve piece, at least a first intermediate curve piece and an insert back curve piece, wherein a back surface of the front curve piece has a first radius of curvature and a front surface of the first intermediate curve piece has a second radius of curvature, wherein the different radii of curvature cause an optical effect; a dielectric layer proximate to at least one of the front curve piece and the intermediate curve piece, wherein the dielectric layer varies in thickness at least within the portion within the optical zone; an energy source embedded in the insert in at least a region comprising a non-optical zone; and the variable optic insert comprising a layer containing liquid crystal material, wherein the layer includes regions of liquid crystal material aligned in a pattern by a non-rubbed alignment layer which orients molecules in the liquid crystal material thereby varying the index of refraction across at least a first portion of the variable optic insert with a parabolic dependence on a radial dimension in the absence of an electric field. - View Dependent Claims (29, 30, 31, 32, 33, 34, 35)
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Specification
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Current AssigneeJohnson & Johnson Vision Care Incorporated (Johnson & Johnson)
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Original AssigneeJohnson & Johnson Vision Care Incorporated (Johnson & Johnson)
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InventorsDe Sio, Luciano, Flitsch, Frederick A., Pandojirao-S, Praveen, Pugh, Randall Braxton, Riall, James Daniel, Serak, Svetlana, Tabirian, Nelson V., Toner, Adam, Uskova, Olena
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Primary Examiner(s)Mack, Ricky
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Assistant Examiner(s)Tallman, Robert E
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Application NumberUS14/487,798Publication NumberTime in Patent Office1,218 DaysField of Search35115901, 35115902, 35115903, 35115905, 35115939, 3511594, 35115941US Class CurrentCPC Class CodesB29D 11/00038 Production of contact lensesB29D 11/00817 Producing electro-active le...G02C 7/04 Contact lenses for the eyes...G02C 7/083 Electrooptic lensesG02F 1/13775 Polymer-stabilized liquid c...G02F 1/139 based on orientation effect...G02F 1/294 Variable focal length devices
