Patent Application
20230004025
The present invention relates to a semi-finished lens that has an object-side surface and an eyeball-side surface and is to be an eyeglass lens completed by processing the eyeball-side surface, and a method for manufacturing an eyeglass lens.
Eyeglass lenses are usually broadly divided into finished lenses and semi-finished lenses. A finished lens refers to a lens whose object-side surface (usually, a convex surface) and eyeball-side surface (usually, a concave surface) are mirror optical surfaces that satisfy a prescription lens power, and whose optical surfaces do not require curving processing. Note that the object-side surface of the lens refers to a surface out of the surfaces that constitute the lens and is to be visible when the lens is worn as an eyeglass. Also, the eyeball-side surface of the lens refers to a surface out of the surfaces that constitute the lens and is located on the eyeball side of the wearer when the lens is worn as the eyeglass.
On the other hand, a semi-finished lens refers to a lens that has an object-side surface (usually, a convex surface) and an eyeball-side surface, and does not have a vision correction function, and only the object-side surface has a mirror-finished optical surface, and the eyeball-side surface is an unprocessed surface. The semi-finished lens is designed to have a lens thickness with a margin to be removed through processing such that the lens manufacturer can produce a lens having a vision correction function by performing surface processing (grinding, cutting, polishing, and the like) on the eyeball-side surface according to a lens prescription power.
Patent Document 1: JP-2012-228806A
Patent Document 2: JP-2014-182278A
Patent Document 3: JP-2019-179219A
In order to reduce the weight of an eyeglass lens so as to not burden the wearer of the eyeglass lens, conventionally, the eyeglass lens is designed in a shape such that the thickness of the frame edge (edge thickness) of the lens is minimized according to a value of the wearer's prescription and frame shape (e.g., see Patent Document 3).
However, because the frame edge thickness of the lens is minimized, a peripheral edge portion of a semi-finished lens may be cut during lens processing. In particular, cuts (also referred to as “knife edges”) are likely to occur in the peripheral edge portion of the semi-finished lens with a positive power or astigmatism prescription while the semi-finished lens is being processed, and the lens may crack during processing.
Also, in a step of polishing the eyeball-side surface of the semi-finished lens, when the entire object-side surface of the lens is fixed through blocking for fixing the semi-finished lens, a blocking material is cut together with the lens while a processing surface is being cut, which causes the problem of having to dispose of waste generated during lens processing. On the other hand, in order to prevent the blocking material from being cut, if the semi-finished lens is fixed at the minimum required blocking diameter, an unfixed area outside the blocking diameter includes a peripheral portion of the frame. Thus, machining accuracy cannot be ensured, resulting in the issue of the resulting surface being optically unstable.
Also, a defective portion being formed due to a cut in the peripheral edge portion of the lens is problematic after the lens is polished. When surface treatment such as antireflection coating or hard coating is to be performed on the convex surface or concave surface of the lens, for example, the outer peripheral shape of the lens may not match the shape of a lens holding tool. Therefore, a problem arises in the surface treatment step, such as surface treatment being performed on a surface that originally does not require surface treatment.
Conventional Patent Document 1 discloses a method for manufacturing a plastic lens for an eyeglass having a structure in which a lens side surface has a groove portion pinched inward and the shape of a cross section in a plan view that intersects the groove portion is non-circular.
Also, conventional Patent Document 2 discloses an eyeglass lens base member (semi-finished lens) constituted by a lens main portion having two lens surfaces formed in a rectangular shape when viewed in the direction of an optical axis and a relatively thin edge portion that protrudes laterally from the lens main portion.
The plastic lens for an eyeglass obtained using the manufacturing method disclosed in Patent Document 1 above has the effect of being able to reduce waste that is generated in the eyeglass manufacturing step. However, it is not possible to avoid the above-described issues, that is, the occurrence of cuts in the peripheral edge portion of the lens in the step of processing the semi-finished lens.
Furthermore, cuts are likely to occur in a thin edge portion of the eyeglass lens base member with the structure disclosed in Patent Document 2 above when the eyeball-side surface is processed, and thus the above-described issues cannot also be resolved.
In view of this, the present invention was made to resolve such conventional issues, and an object thereof is to provide a semi-finished lens with which it is possible to prevent the peripheral edge portion of the lens from being cut during lens processing.
As a result of intensive studies to resolve the above issues, the inventors of the present invention found that the issues can be resolved by the invention having the following configurations. That is, the present invention has the following configuration in order to resolve the issues.
A semi-finished lens that has an object-side surface and an eyeball-side surface and is to be an eyeglass lens completed by processing the eyeball-side surface,
The semi-finished lens according to Configuration 1,
The semi-finished lens according to Configuration 1 or 2,
The semi-finished lens according to any one of Configurations 1 to 3,
The semi-finished lens according to any one of Configurations 1 to 4,
The semi-finished lens according to any one of Configurations 1 to 5,
The semi-finished lens according to any one of Configurations 1 to 6,
The semi-finished lens according to any one of Configurations 1 to 7,
The semi-finished lens according to any one of Configurations 1 to 8,
The semi-finished lens according to any one of Configurations 1 to 9,
The semi-finished lens according to any one of Configurations 1 to 10,
The semi-finished lens according to any one of Configurations 1 to 11,
A method for manufacturing an eyeglass lens having a lens power that corresponds to a prescription value of a lens, the method including:
According to the semi-finished lens of the present invention, it is possible to prevent a peripheral edge portion of the lens from being cut during lens processing.
Also, according to the semi-finished lens of the present invention, it is possible to prevent the peripheral edge portion of the lens from being cut during lens processing in such a manner, and thus it is possible to solve the above-described problem of having to dispose of waste generated during conventional lens processing and problems in the surface treatment step performed after lens processing is performed.
Hereinafter, embodiments according to the present invention will be described in detail with reference to the drawings.
The semi-finished lens has an object-side surface (usually, a convex surface) and an eyeball-side surface, and only the object-side surface has a mirror-finished optical surface, and the eyeball-side surface is an unprocessed surface. A completed eyeglass lens having a vision correction function can be obtained as a result of the lens manufacturer performing surface processing (grinding, cutting, polishing, and the like) on the eyeball-side surface such that the lens has a desired lens power that corresponds to a lens prescription value. It is possible to obtain an eyeglass lens having only a concave surface on the eyeball side, or an eyeglass lens having a concave surface in which a portion thereof includes a convex surface, for example.
Plastics are mainly used as the material of the eyeglass lens, and plastics are also preferably used as the material of the semi-finished lens according to the present invention. Specifically, it is possible to use various base members that are usually used as plastic lenses, and to manufacture lenses by injecting a lens monomer into a lens forming mold and performing curing treatment thereon.
There is no particular limitation on the lens monomer, and it is possible to use various types of monomers that are usually used to manufacture plastic lenses. It is possible to use a monomer having a benzene ring, a naphthalene ring, an ester bond, a carbonate bond, or a urethane bond, in its molecule, and the like, for example. Also, it is possible to use compounds having a sulfur or halogen element, and in particular, it is also possible to use compounds having a nuclear halogenated aromatic ring. A lens monomer can be manufactured using one, or two or more types of monomers having the above functional groups. Examples thereof include styrene, divinylbenzene, phenyl (meth)acrylate, benzyl (meth)acrylate, naphthyl (meth)acrylate, methyl (meth)acrylate, diethylene glycol bis(allyl carbonate), diallyl (iso)phthalate, dibenzyl itaconate, dibenzyl fumarate, chlorostyrene, nuclear halogenated styrene, nuclear halogenated phenyl (meth)acrylate, nuclear halogenated benzyl (meth)acrylate, tetrabromobisphenol A derivative (di)(meth)acrylate, tetrabromobisphenol A derivative diallyl carbonate, diorthochlorobenzyl itaconate, diorthochlorobenzyl fumarate, diethylene glycol bis(orthochlorobenzyl) fumarate, (di)ethylene glycol di(meth)acrylate, glycidyl methacrylate, products obtained through reactions with polyfunctional isocyanate, such as xylylene diisocyanate and hexamethylene diisocyanate, products obtained through reactions between nuclear halogenated phenol derivative monohydroxy acrylate and polyfunctional isocyanate, products obtained through reactions between nuclear halogenated biphenyl derivative monohydroxy acrylate and polyfunctional isocyanate, products obtained through reactions between xylene diisocyanate and polyfunctional mercaptan, products obtained through reactions between glycidyl methacrylate and polyfunctional methacrylate, and the like, and mixtures thereof. Examples of the material of the lens base member preferably include polyurethane-based materials such as a polythiourethane resin and a polyurethane resin, epithio-based materials such as a polysulfide resin, polycarbonate-based materials, and diethylene glycol bis(allyl carbonate)-based materials.
Although colorless semi-finished lenses are usually used as the above semi-finished lens, depending on the purpose and application, colored semi-finished lenses can be used as long as transparency is not impaired.
The semi-finished lens according to the present invention is a semi-finished lens that is to be an eyeglass lens that has an object-side surface and an eyeball-side surface and is completed by processing the eyeball-side surface as described in the above configuration 1, and the object-side surface includes an optical region and a non-optical region.
As shown in
The non-optical regions 12 and 13 include at least a portion of an outer edge portion of the semi-finished lens 1. The semi-finished lens 1 of this embodiment includes the non-optical region 12 on the upper edge portion side of the optical region 11 having an elliptical shape in a plan view and the non-optical region 13 on the lower edge portion side. Overall, the object-side surface 10 has a circular shape.
As referred to in
The optical region 11 is an optically effective convex surface that has been mirror-processed and optically finished. Also, while the optical region 11 is a region that is always larger than the shape of a frame to which the lens is to be mounted, the non-optical regions 12 and 13 are located outward of the frame shape, and are optically ineffective surfaces. Note that, although the eyeball-side surface 16 of the semi-finished lens 1 is flat in this embodiment (see
In the semi-finished lens 1 according to this embodiment, the optical region 11 has an optical surface having a predetermined design shape (i.e., a shape that is based on the prescription of an eyeglass lens or a shape that is based on a presumed prescription). On the other hand, the non-optical regions 12 and 13 each have a design shape that is different from that of the optical surface (i.e., a shape that is not related to the prescription of the eyeglass lens). A “design shape” refers to a shape determined based on a design. Also, the optical region 11 and the non-optical regions 12 and 13 can be in contact with each other continuously or discontinuously at boundaries 14 and 15.
A “vertical direction” and a “horizontal direction” are defined as follows in the present invention. When the optical region of the semi-finished lens is made conforming to a frame (eyeglass frame), the “horizontal direction” refers to a direction extending along the horizontal width (size A) of the frame, and the “vertical direction” refers to a direction extending along the vertical width (size B) of the frame. Here, the size A and the size B are frame size defined in JIS and ISO standards, and respectively refer to size A and size B in the boxing system.
Therefore, in the plan view in
As shown in
The curvature of the semi-finished lens 1 according to this embodiment changes at the boundary 14 between the optical region 11 and the non-optical region 12 of the object-side surface 10 and the boundary 15 between the optical region 11 and the non-optical region 13. That is, the curvature changes at the boundary 14 from the curvature value of the optical region 11 to the curvature value of the non-optical region 12, and changes at the boundary 15 from the curvature value of the optical region 11 to the curvature value of the non-optical region 13. As referred to in
Incidentally, curvature indicates an amount that usually expresses the degree of bending of a curved line or curved surface, and the value of a base curve can be used as an index with the magnitude of curvature, for example. With an eyeglass lens, an object-side refracting surface of the lens is referred to as a “base curve”. This is because the shape of the object-side refracting surface of the eyeglass lens is determined first, and then the shape and the center thickness of the eyeball-side refracting surface are determined based on the thus determined shape. The value of the base curve is represented by the refractive power of the surface of the lens. Usually, the refractive power of the surface of the lens with a refractive index n can be calculated using the following equation.
Refractive power of surface D [diopters]=(n−1)/R
Therefore, the larger the value of the base curve is, the larger the curvature of a curved surface is, and the smaller the value of the base curve is, the smaller the curvature of a curved surface is. Also, when the value of a base curve is “0 (zero)”, the surface is flat.
In this embodiment, the optical region 11 and the non-optical regions 12 and 13 have different curvatures in at least one of the vertical direction and the horizontal direction.
Also, in this embodiment, the curvature in the vertical direction of the optical region 11 is preferably larger than the curvature in the vertical direction of the non-optical regions 12 and 13. Accordingly, the thickness and the area of the non-optical regions 12 and 13 can be secured with ease, and thus it is possible to more remarkably obtain the effect of preventing the peripheral edge portion of the lens from being cut during lens processing.
Also, in this embodiment, the curvature in the vertical direction of the non-optical regions 12 and 13 is preferably different from the curvature in the horizontal direction thereof. A configuration can be adopted in which the curvature in the horizontal direction of the non-optical regions 12 and 13 is larger than the curvature in the vertical direction thereof, for example. The curvature in the vertical direction of the non-optical regions 12 and 13 may be zero. By making the eyeball-side surface 16 a concave surface, the lens thickness at any position in the non-optical regions 12 and 13 can be larger than the smallest thickness at the boundaries 14 and 15 between the optical region 11 and the non-optical regions 12 and 13, for example.
With the semi-finished lens 1 according to this embodiment, the curvature in the vertical direction of the optical region 11 is base curve 5, and the curvature in the horizontal direction is also base curve 5, for example. Note that “base curve” is abbreviated as “BC” hereinafter.
Also, the curvature in the vertical direction of the non-optical regions 12 is BC0 (zero), and the curvature in the horizontal direction is BC4. Also, the curvature in the vertical direction of the non-optical regions 13 is BC0 (zero), and the curvature in the horizontal direction is BC4.
The above curvature values are merely examples, and the curvature values are not limited to these values, and may be optimized according to a frame shape, lens prescription values, and the like.
As described above, the semi-finished lens 1 according to this embodiment includes the optically ineffective non-optical regions 12 and 13 that are located on the upper and lower sides of and adjacent to the optical region 11. The optical region 11 is larger than the shape of the frame to which an eyeglass lens is to be ultimately mounted, and the non-optical regions 12 and 13 are outside the frame when the lens is mounted to the frame. Also, preferably, for the optical region 11 and the non-optical regions 12 and 13, the values of curvature in the vertical direction and the horizontal direction are adjusted as described above.
The shape of the optical region 11 is basically set according to the shape of the frame. The shape of a frame here includes not only the shape of a frame when a specific frame to which a lens is to be mounted is determined but also multiple types of frames whose various shapes are roughly determined in advance based on their characteristics. Also, how to set the curvature (base curve) of the optical region 11, that is, how a semi-finished lens is to be selected according to base curve, is usually determined by the prescription value, frame shape, lens layout, wearing parameters, and the like.
Note that the optical region 11 may be a bifocal lens having a small round lens at its lower portion or a progressive addition lens, for example. In the case of a bifocal lens, a portion of a small round lens that is to be outside the frame may be lost due to the non-optical region 13. Also, with regard to a progressive addition lens, usually, a lower region includes a near-portion region (near portion) and a progressive-portion region (intermediate region), and an upper region includes a distance-portion region (distance portion). However, a portion of the distance portion or the near portion that is to be outside the frame may be lost due to the non-optical regions 12 and 13.
According to the semi-finished lens 1 of this embodiment, a cutting allowance can be provided by providing the optically ineffective non-optical regions 12 and 13 that are located on the upper and lower sides of and adjacent to the optical region 11, and thus, even when the thickness of a lens edge is optimized for the frame shape, it is possible to prevent the peripheral edge portion of the lens from being cut during lens processing, regardless of the prescription power and frame shape of the eyeglass wearer, and the like.
Also, it is possible to prevent the peripheral edge portion of the lens from being cut during such lens processing, and the outer diameter of the lens is maintained because no defective portion results from the peripheral edge portion of the lens being cut. Thus, when surface treatment such as antireflection coating or hard coating is performed on a convex surface or a concave surface of the polished lens, the outer peripheral shape of the lens matches the shape of the lens holding tool, and thus it is possible to resolve the above-described conventional issues arising in a surface treatment step performed after lens processing is performed. Also, even if blocking is performed at a blocking diameter with which the entire frame is covered during lens processing, there is no need to cut a blocking material at an outer peripheral portion of the lens, which is to be a portion outside the frame, and waste disposal is facilitated during the above-described conventional lens processing. Furthermore, blocking can be performed according to the outer diameter of a semi-finished lens, and the types of block rings used in blocking can be reduced, regardless of the size of the frame.
A conventional semi-finished lens does not have a cutting allowance so as to provide versatility such that the semi-finished lens can take various frame shapes. In contrast, in the present invention, frame shapes are narrowed in advance, and a cutting allowance (non-optical region) for when an eyeglass lens is processed is provided. Accordingly, it is possible to prevent the peripheral edge portion of the lens from being cut during lens processing. That is, in the present invention, at the cost of versatility, it is possible to prevent the edge portion from being cut when processing is performed, compared to conventional semi-finished lenses. When eyeglass lenses whose frame shapes are narrowed down to some extent are to be manufactured, the semi-finished lens according to the present invention can be suitably used.
As shown in
The non-optical regions 22 and 23 each includes at least a portion of the outer edge portion of the semi-finished lens 2. The semi-finished lens 2 of this embodiment includes the non-optical region 22 on the upper edge portion side of the optical region 21 having a barrel shape in a plan view, and the non-optical region 23 on the lower edge portion side thereof, and overall, the object-side surface 20 has a circular shape.
As referred to in
In this embodiment, the optical region 21 is also an optically effective convex surface that has been mirror-processed and optically finished. Also, while the optical region 21 is a region that is always larger than the shape of a frame to which the lens is to be mounted, the non-optical regions 22 and 23 are located outward of the frame shape, and are optically ineffective surfaces. Note that, although the eyeball-side surface 26 of the semi-finished lens 2 is flat in this embodiment (see
In the semi-finished lens 2 according to this embodiment, the optical region 21 has an optical surface having a predetermined design shape (i.e., a shape that is based on the prescription of an eyeglass lens or a shape that is based on a presumed prescription). On the other hand, the non-optical regions 22 and 23 each have a design shape that is different from that of the optical surface (i.e., a shape that is not related to the prescription of the eyeglass lens). A “design shape” refers to a shape determined based on a design. Also, the optical region 21 and the non-optical regions 22 and 23 can be in contact with each other continuously or discontinuously at boundaries 24 and 25.
Although not shown, in this embodiment as well, the amount of sag in the vertical direction of the optical region 21 increases from the center to the peripheral edge of the semi-finished lens 2. On the other hand, it is preferable that the amounts of sag in the vertical direction of the non-optical regions 22 and 23 are constant, or increase from the center to the peripheral edge of the semi-finished lens 2 at a smaller ratio than in the optical region 21. Accordingly, the thickness and the area of the non-optical regions 22 and 23 can be secured with ease, and thus it is possible to more remarkably obtain the effect of preventing the peripheral edge portion of the lens from being cut during lens processing.
With the semi-finished lens 2 according to this embodiment, curvature changes at a boundary 24 between the optical region 21 and the non-optical region 22 of the object-side surface 20 and a boundary 25 between the optical region 21 and the non-optical region 23. That is, the curvature changes at the boundary 24 from the curvature value of the optical region 21 to the curvature value of the non-optical region 22, and changes at the boundary 25 from the curvature value of the optical region 21 to the curvature value of the non-optical region 23. As referred to in
In this embodiment, the optical region 21 and the non-optical regions 22 and 23 also have different curvatures in at least one of the vertical direction and the horizontal direction.
Also, in this embodiment, the curvature in the vertical direction of the optical region 21 is preferably larger than the curvature in the vertical direction of the non-optical regions 22 and 23. Accordingly, the thickness and the area of the non-optical regions 22 and 23 can be secured with ease, and thus it is possible to more remarkably obtain the effect of preventing the peripheral edge portion of the lens from being cut during lens processing.
Also, in this embodiment, the curvature in the vertical direction of the non-optical regions 22 and 23 is also preferably different from the curvature in the horizontal direction thereof. A configuration can be adopted in which the curvature in the horizontal direction of the non-optical regions 22 and 23 is larger than the curvature in the vertical direction thereof, for example. The curvature in the vertical direction of the non-optical regions 22 and 23 may be zero. The lens thickness at any position in the non-optical regions 22 and 23 can be larger than the smallest thickness at the boundaries 24 and 25 between the optical region 21 and the non-optical regions 22 and 23.
With the semi-finished lens 2 according to this embodiment, the curvature in the vertical direction of the optical region 21 is BCS, and the curvature in the horizontal direction is also BCS, for example.
Also, the curvature in the vertical direction of the non-optical region 22 is larger than BC0 (zero) and less than BCS, and the curvature in the horizontal direction is BCS. Also, the curvature in the vertical direction of the non-optical region 23 is larger than BC0 (zero) and less than BCS, and the curvature in the horizontal direction is BCS.
The above curvature values are merely examples, and the curvature values are not limited to these values, and may be optimized according to a frame shape, lens prescription values, and the like.
As described above, the semi-finished lens 2 according to this embodiment includes the optically ineffective non-optical regions 22 and 23 that are located on the upper and lower sides of and adjacent to the optical region 21 that is larger than a frame shape. Also, preferably, for the optical region 21 and the non-optical regions 22 and 23, the values of curvature in the vertical direction and the horizontal direction are adjusted as described above.
The semi-finished lens 2 of this embodiment also has the same effects as the semi-finished lens 1 of the above-described first embodiment. That is, according to the semi-finished lens 2 of this embodiment, a cutting allowance can be provided by providing the optically ineffective non-optical regions 22 and 23 that are located on the upper and lower sides of and adjacent to the optical region 21, and thus, even when the thickness of a lens edge is optimized for the frame shape, it is possible to prevent the peripheral edge portion of the lens from being cut during lens processing, regardless of the prescription power and frame shape of the eyeglass wearer, and the like. Also, it is possible to prevent the peripheral edge portion of the lens from being cut during such lens processing, and the outer diameter of the lens is maintained. Thus, no problem arises in the surface treatment step performed after conventional lens processing described above is performed. It is also possible to solve the above-described problem of having to dispose of waste generated during the conventional lens processing.
As shown in
The semi-finished lens 3 of this embodiment includes the non-optical region 32 in a peripheral edge portion of the optical region 31 having an elliptical shape in a plan view, and overall, the object-side surface 30 has a circular shape. In this embodiment, the optical region 31 is also an optically effective convex surface that has been mirror-processed and optically finished. Also, while the optical region 31 is a region that is always larger than the shape of a frame, the non-optical region 32 is an optically ineffective surface outward of the frame shape.
Note that, although the eyeball-side surface of the semi-finished lens 3 is not shown, the eyeball-side surface may be a flat surface, concave surface, or a convex surface, for example.
In the semi-finished lens 3 according to this embodiment, the optical region 31 has an optical surface having a predetermined design shape (i.e., a shape that is based on the prescription of an eyeglass lens or a shape that is based on a presumed prescription). The non-optical region 32 has a design shape that is different from that of the optical surface (i.e., a shape that is not related to the prescription of the eyeglass lens). A “design shape” refers to a shape determined based on a design. Also, the optical region 31 and the non-optical region 32 can be in contact with each other continuously or discontinuously at a boundary 33.
In the semi-finished lens 3 of this embodiment, the non-optical region 32 is located so as to surround the optical region 31. That is, unlike the first and second embodiments, the non-optical region 32 is also arranged in the left-right direction of the optical region 31. Accordingly, it is possible to prevent the peripheral edge portion of the lens from being cut in multiple directions.
Although not shown, in this embodiment as well, the amount of sag in the vertical direction of the optical region 31 increases from the center to the peripheral edge of the semi-finished lens 3. On the other hand, it is preferable that the amount of sag in the vertical direction of the non-optical region 32 is constant, or increases from the center to the peripheral edge of the semi-finished lens 3 at a smaller ratio than in the optical region 31. Accordingly, the thickness and the area of the non-optical region 32 can be secured with ease, and thus it is possible to more remarkably obtain the effect of preventing the peripheral edge portion of the lens from being cut during lens processing.
With the semi-finished lens 3 according to this embodiment, curvature changes at the boundary 33 between the optical region 31 and the non-optical region 32 of the object-side surface 30. That is, the curvature changes at the boundary 33 from the curvature value of the optical region 31 to the curvature value of the non-optical region 32. The curvature value may change discontinuously or continuously.
In this embodiment as well, the optical region 31 and the non-optical region 32 also have different curvatures in at least one of the vertical direction and the horizontal direction.
Also, in this embodiment as well, the curvature in the vertical direction of the optical region 31 is preferably larger than the curvature in the vertical direction of the non-optical region 32. Accordingly, the thickness and the area of the non-optical region 32 can be secured with ease, and thus it is possible to more remarkably obtain the effect of preventing the peripheral edge portion of the lens from being cut during lens processing.
Also, in this embodiment, the curvature in the vertical direction of the non-optical region 32 located in the peripheral edge portion of the optical region 31 is also preferably different from the curvature in the horizontal direction thereof. A configuration can be adopted in which the curvature in the horizontal direction of the non-optical region 32 is larger than the curvature in the vertical direction thereof, for example. The curvature in the vertical direction of the non-optical region 32 may be zero. The lens thickness at any position in the non-optical region 32 can be larger than the smallest thickness at the boundary 33 between the optical region 31 and the non-optical region 32.
With the semi-finished lens 3 according to this embodiment, the curvature in the vertical direction of the optical region 31 is BC5,and the curvature in the horizontal direction is also BC5, for example.
Also, the curvature in the vertical direction of the non-optical region 32 located in a peripheral edge portion of the optical region 31 is BC0 (zero), and the curvature in the horizontal direction is BC3.
The above curvature values are merely examples, and the curvature values are not limited to these values, and may be optimized according to a frame shape, lens prescription values, and the like.
As described above, in the semi-finished lens 3 of this embodiment, the optically ineffective non-optical region 32 is provided outside the optical region 31 that is larger than the frame shape, along the outer edge portion of the semi-finished lens 3. Also, preferably, for the optical region 31 and the non-optical region 32, the values of curvature in the vertical direction and the horizontal direction are adjusted as described above.
The semi-finished lens 3 of this embodiment also has the same effects as the semi-finished lens 1 of the above-described first embodiment. That is, according to the semi-finished lens 3 of this embodiment, a cutting allowance can be provided by providing the optically ineffective non-optical region 32 at the peripheral edge portion of the optical region 31, and thus, even when the thickness of a lens edge is optimized for the frame shape, it is possible to prevent the peripheral edge portion of the lens from being cut during lens processing, regardless of the prescription power and frame shape of the eyeglass wearer, and the like. Also, it is possible to prevent the peripheral edge portion of the lens from being cut during lens processing in this manner, and thus, the outer diameter of the lens is maintained. Thus, no problem arises in the surface treatment step performed after conventional lens processing described above is performed. Furthermore, it is also possible to solve the above-described conventional problem of having to dispose of waste generated during lens processing.
Although the semi-finished lens according to the present invention was described above in detail using the first to third embodiments, the present invention is not limited to these embodiments.
A non-optical region may have a spherical or an aspherical surface, and may have a round columnar surface or an astigmatic surface (toric surface), for example. Furthermore, the non-optical region may be a region that includes a combination of these surfaces. Also, the non-optical region may include a flat surface.
Furthermore, although the non-optical regions 12 and 13 of the semi-finished lens 1 are formed as two regions that are located at opposing positions with the optical region 11 interposed therebetween in the first embodiment, the number of non-optical regions need not be two, and may be one, for example. The same applies to the second embodiment.
Furthermore, the invention of this application includes a method for manufacturing an eyeglass lens.
That is, a method for manufacturing an eyeglass lens having a lens power that corresponds to a prescription value of the lens includes a step of preparing a semi-finished lens having an object-side surface and an eyeball-side surface and a step of processing the eyeball-side surface of the semi-finished lens according to the prescription value of the lens. The object-side surface of the semi-finished lens includes an optical region and a non-optical region that have different design shapes. The semi-finished lens prepared using this manufacturing method can have favorable characteristics of the semi-finished lenses according to the above embodiments.
1 Semi-finished lens
10 Object-side surface
11 Optical region
12, 13 Non-optical region
14, 15 Boundary (between optical region and non-optical region)
16 Eyeball-side surface
2 Semi-finished lens
20 Object-side surface
21 Optical region
22, 23 Non-optical region
24, 25 Boundary (between optical region and non-optical region)
26 Eyeball-side surface
3 Semi-finished lens
30 Object-side surface
31 Optical region
32 Non-optical region
33 Boundary (between optical region and non-optical region)
L Vertical direction
H Horizontal direction
| Number | Date | Country | Kind |
|---|---|---|---|
| 2019-232743 | Dec 2019 | JP | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/JP2020/044737 | 12/1/2020 | WO |
