DESCRIPTION A SPECTACLE LENS AND A METHOD OF PRODUCING THE SAME
TECHNICAL FIELD
The present invention relates to a spectacle lens and a method of producing the same, in more details, pertains to said lens and method which can prevent eye disorders by especially restraining infrared rays, which are said to be hazardous to our vision, from entering the eyes.
BACKGROUND ART
Conventionally, as a spectacle lens to protect our eyes from hazardous rays, such lens is known as being provided with a light- transmittable layer colored with pigments which absorb ultraviolet rays so as to restrain said rays from penetrating into the eyes. As another example, a light-polarizing lens is also known, which is intended to prevent eyestrains by abating the influence of scattering lights thrown back from water and snow surfaces on the eyes.
However, such prior spectacle lenses as mentioned above can restrain the influence of ultraviolet rays or scattering lights on the eyes, but they are far short of protecting the eyes from infrared rays. A so-called near infrared radiation having the wavelength ranging from 720 to 1000 nm invades into the eyes or far into the eyegrounds of those who routinely watch the screen of a television, factory automation equipment such as a computer and so on or experimental and observational equipment. Our eyes being exposed to such infrared radiation for a long time, we suffer not only from eyestrains, but also from the inflammation of iris, ciliary body and choroid, which are disposed in the middle layer of the eyeball, and of retina, which is disposed in the innermost layer thereof. Such inflammation going worse, it may cause
serious disorders on our eyesight. It is apprehended that such disorders should be caused also by doing outdoor sports such as skiing and yachting or working outdoors. The protection of our eyes from infrared radiation is another issue, which should be resolved in the same stance as the one to protect them from ultraviolet rays.
The present invention is to provide a spectacle lens, which is capable of not only properly restraining the invasion of such hazardous infrared rays into our eyes as mentioned above, but also transmitting sufficient amount of light to make things visible and to provide a method of producing the same lens.
DISCLOSURE OF THE INVENTION
The means adopted in the present invention in order to solve the above issues, is characterized in that semi -reflect ive and semi- trans ittable thin films to absorb infrared rays are dotted on the surface of the ocular side of spectacle lens.
More concretely speaking, it is characterized in that those films are essentially composed of the variety of chromium oxide.
To show another concrete example, it is characterized in that semi-translucent thin films are overlaid on said infrared rays absorbing films.
Far more concretely speaking, it is characterized in that the respective infrared rays absorbing films are hexagonal ly arranged on the ocular side of the lens.
Furthermore concretely speaking, it is characterized in that the respective infrared rays absorbing films are restricted in both length and width within the range of 0.2 to 0.3 mm, and the interval between adjacent films is set within the range of 0.05 to 0.25 mm.
On the other hand, the method adopted in this invention to produce
the above lens is characterized in that a masking sheet with a number of apertures dotted thereon is disposed substantially in parallel to the ocular side of the lens, and through this sheet, vapor deposition of infrared rays absorbing material is performed on the ocular side thereof.
To show another concrete example, it is characterized in that vapor deposition of a semi-translucent material and/or protective coat is performed after that of said absorbing material.
Hereinafter, the best mode for carrying out the invention is described with reference to the accompanying drawings. BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 is a sectional view of a spectacle lens of the first embodiment of the present invention showing its structure and function; Figure 2 is a partly enlarged plan view of infrared rays absorbing films showing their layout on the lens of the first embodiment; Figure 3 is a sectional view taken along the line A-A of Figure 2; Figure 4 is a partly enlarged plan view of infrared rays absorbing films showing their layout on the lens according to the second embodiment; Figure 5 is a sectional view taken along the line B-B of Figure 4; Figure 6 is a sectional view schematically showing the internal structure of a vapor deposition apparatus used in the present invention; Figure 7 is a sectional view of the spectacle lens according to the present invention to explain how to produce the same; Figure 8 is a partly sectional view of the lens according to the present invention to show a modified embodiment; and Figure 9 is a partly sectional view of the lens according to the present invention to show another modified embodiment.
BEST MODE FOR CARRYING OUT THE INVENTION (FIRST EMBODIMENT)
With a spectacle lens (1) according to this embodiment, a number of thin films (3) to absorb infrared rays are dotted by vapor deposition on the ocular side (the side that faces the eyeballs when worn) surface of the lens proper (2) which is made of glass or plastics. Said films (3) are made of chromium dioxide (Cr02 )• Those films are, as shown in Figure 2, each hexagonal ly arranged on the surface and adjacent films are equi -distantly disposed. Concretely speaking, as shown in Figure 2, they are arranged so that the length (L) and the width (W) of each film is 0.2~0.3 mm and 0.14 ~0.18 mm respectively, while the lengthwise pitch (pi) is 0.13 ~0.33 mm and the widthwise pitch (p2) is 0.15—0.38 mm.
Due to such layout and sizes as mentioned above, when light rays have penetrated into the lens (1) from the side thereof facing outwards when worn, an infrared rays abated field, in which shadowy spaces (4) as shown in Figure 1 to filter out infrared rays are formed, is generated in the proximity of the ocular side of said lens in accordance with the arrangement of those films thereon, while the light rays that get through the gaps between adjacent films (3) are diffracted at those gaps so as to turn to said shadowy spaces (4). The gone-through infrared rays interfere with those remained after passed through said films at said spaces (4) so as to set off the wavelength of the former against that of the latter, so that infrared rays abate, which the present inventor specifically calls "set-off effect".
That is to say, with the spectacle lens ( 1 ) of this embodiment, as the synergistic effect between infrared rays filtering operation and a so-called "set-off effect" greatly reduces the radiation of same onto the ocular side of the lens or into the eyeballs, the affect on iris, ciliary body, choroid and retina thereof as mentioned above is much lightened, so that it can securely prevent the eyes from being damaged.
Further explaining such optical function of the lens as mentioned above on the basis of Figure 1, when sunbeam (Sb) has penetrated into the lens (1), infrared rays are filtered out by said films (3) so that the light beam of less infrared rays pass through. At this time, a certain amount of light which is to penetrate into the lens is thrown back to outer space according to the reflectivity of said film (3).
Likewise, as the infrared rays of the sunbeam (Sb ' ) which has penetrated into the respective gaps between adjacent films (3) diffract there, they interfere with those remained after passed through said films (3) at said shadowy spaces (4) so as to abate. In this way, the infrared rays which pass through the lens (1), which is taken as a whole, extremely decreases. According to the lens of this embodiment, it can greatly abate the infrared rays which are contained in the sunlight, while it can secure sufficient visible light to make us see things. With the spectacle lens of this embodiment, said shadowy spaces
(4) are properly generated, not only because said thin films (3) are each hexagonal ly arranged, but also because the length (L) and the width
(W) of each film (3) in such arrangement range from 0.2 to 0.3 mm and from 0.14 to 0.18 mm respectively, while the lengthwise pitch (pi) and the widthwise pitch (p2) range from 0.13 to 0.33 mm and from 0.15 to
0.38 mm respectively. Moreover, as said films (3) are hexagonally disposed like a honeycomb, any adjacent films are uniformly spaced apart from one another.
(SECOND EMBODIMENT)
With the spectacle lens (1) of this embodiment, infrared absorbing thin films (3) are each formed in circular shape as shown in Figure 4, and adjacent files of those films are staggered by a half pitch from one another. Therefor, those films are uniformly disposed on the lens. The diameter ( k ) of each film ranges from 0.2 to 0.3 mm, while the
lengthwise pitch (pi) and the widthwise pitch (p2) both range from 0.15 to 0.4 mm. Due to such arrangement and sizes as mentioned above, said shadowy spaces (4) are effectively generated. As the function of the spectacle lens of this embodiment is the same as that of the above first embodiment, it is omitted to describe it in order to avoid the redundancy of the explanation.
Following the description of the above embodiments, a method for producing the above lens is described below.
Figure 6 is a sectional view of a vapor deposition apparatus, which is used for producing said spectacle lens, schematically showing its structure.
In the first place, as shown in Figure 6, a lens proper (2) to be processed in accordance with the present invention is fixed on a supporting table (S) provided in a vacuum deposition apparatus (D), and a masking sheet (5) with a number of apertures (5A) provided thereon such that they conform with a layout of infrared rays absorbing thin films (3) to be formed on the lens surface is mounted on said lens proper. Instead of this arrangement, as shown in Figure 7, said masking sheet may be disposed against said lens with a certain interval therebetween. Then, a vapor deposition is performed on the lens surface through said sheet (5) by heating and evaporating chromium dioxide (CrO 2 ) mounted on a dish (V). In this operation, it enables a thin film (3) , which well conforms with the shape of said aperture (5), to be effectively formed on the lens surface by performing vapor deposition while cooling said surface to a temprature which varies with a material of the lens to be used. In this way, by means of vacuum deposition method, productivity improves even on such thin films (3) as finely dotted on the lens surface. The shape of an aperture (5A) of said masking sheet (5) is not limited to hexagon or circle as disclosed in
the above embodiments, but it may be modified in such other forms as rectangle or triangle.
It should be understood that the present invention is not limited to the above embodiments, but it can be modified in various manners. For example, in the respective embodiments as mentioned above, only said infrared rays absorbing films (3) are formed on the lens surface, but as shown in Figure 8, sem i -trans lucent thin films (6) capable of polarizing light such as mica are overlaid on said films (3) and transparent protective coats (7) are further overlaid on said films (6). Also, as shown in Figure 9, after said films (6) are overlaid on said films (3), which are formed on the lens surface, the whole surface may be covered with a resin coat (8). In addition to said infrared rays absorbing films (3), a number of ultraviolet rays absorbing thin films each having 20 μ. to 600 μ in thickness and made of such compounds as Z r O2 , T i O, T i 2 03 , Ta2 05 , C e 03 , which are not shown in the drawings, may be formed on the lens surface. In the above embodiments, it is exemplified that only chromium dioxide is used as a material for the film (3), but other compounds such as tungsten hexachlor ide, molybdeum pentachlor ide or ferric oxide are also available. Also, in the above embodiments, the infrared rays absorbing thin films are uniformly disposed on the lens surface, but it is not necessary to persist in this disposition. As far as the shadowy spaces (4) are generated in the vicinity of the lens surface, they do not have to be uniformly disposed. INDSUTRIAL APPLICABILITY
As having been described up to here, according to the present invention, the generation of infrared rays absorbing thin films each having semi-transmittancy on the lens surface effectively restrains the penetration of infrared rays into the eyes without hampering us from
seeing things. The use of a pair of spectacles on which the lenses as disclosed in this invention are mounted, in such occasions as watching the screen of factory automation equipment for a long time, doing outdoor sports or working outside, prevents the eyes from being damaged by the hazardous infrared rays.
Also, in this invention, inexpensive chromium oxide is adopted as a material for an infrared rays absorbing thin film, so that the lens as disclosed in this invention can be suppplied on the market at a reasonable price.
Semi-translucent films are overlaid on infrared rays absorbing films, so that the applicability of the lens as disclosed in this invention expands to various fields of activity.
The infrared rays absorbing thin films are hexagonal ly disposed on the lens surface like a honeycomb, so that said rays can be uniformly blocked throughout the whole surface of the lens.
Where further appropriate, the length and width of an infrared rays absorbing film are specified at such ranges as described in the above embodiments so that the abatement of hazardous infrared rays, resulting from the interference of lights, is maximized.
On the other hand, with the adoption of a method of producing the above spectacle lens wherein a masking sheet with a number of apertures arranged thereon is disposed substantially in parallel to the ocular side of the lens proper, and vapor deposition of infrared rays absorbing material is performed on said lens surface through said masking sheet, it enables the same layout of infrared rays absorbing films that consists of finely dotted pattern to be easily reproduced on the lens surface, which leads to efficient mass-production of such lens as well as the reduction of its production cost.
Furthermore, vapor deposition of a semi -translucent material
and/or protective coat is further performed on infrared rays absorbing material dotted on the lens surface by said deposition method, so that a spectacle lens provided with both infrared rays absorptive and semi- translucent characteristics is realized, which leads to a spectacle lens product of multi-purpose use.
In view of the foregoing, practically speaking, the present invention is of high applicability.