KR102009974B1 - Near infrared ray blocking lens - Google Patents

Abstract

The present invention relates to a near infrared ray blocking lens (1) which is able to, when worn as a lens for a pair of glasses, minimize the transmission of near infrared rays to the eyes and the skin around the eyes. According to the present invention, the near infrared ray blocking lens comprises: an anti-reflection coating layer (20) which is made by repeatedly depositing a low-refractive material and a high-refractive material on the surface of a plastic lens (2). The anti-reflection coating layer (20) includes: an ordinary anti-reflection layer (3) which is made by repeatedly laminating and depositing a low-refractive material and a high-refractive material on a surface of the plastic lens (2) to be thin as applied to ordinary anti-reflection coating to prevent light from being reflected; an amplification-type anti-reflection layer (4) which is made by repeatedly laminating and depositing a low-refractive material and a high-refractive material on an external side of the ordinary anti-reflection layer (3) in a thicker shape than the ordinary anti-reflection layer (3) to reflect and block the near infrared rays on an external side of visual rays; a buffer finish layer (6) made of a low-refractive material to be deposited on an external side of the amplification-type anti-reflection layer (4); and a coating protection film (7) made by being deposited on an external surface of the buffer finish layer (6) to protect the surface of the anti-reflection coating deposited on the lens for the pair of glasses and allow water drops to easily fall. Accordingly, the present invention is able to block near infrared rays just by an anti-reflection coating, prevent various diseases in the eyes and skin by the thermal action of near infrared rays, prevent skin around eyes from aging and from having wrinkles, and remarkably reduce the work-hours and costs of manufacture.

Description

Near infrared ray blocking lens

The present invention relates to a near-infrared blocking lens, which will be described in more detail, which relates to a near-infrared blocking lens to prevent aging due to minimizing the transmission of near-infrared rays to the eyes and the edges of eyes when worn with eyeglass lenses, thereby preventing aging. will be.

In general, sunlight is divided into radio waves, microwaves, and other radio waves, infrared rays, visible rays, ultraviolet rays, X-rays, and gamma rays, depending on the length and length of the light. As infrared light of near-infrared light, photo-induced photoelectric action, fluorescence action in addition to thermal action, photo plate, photocell, phototube, thermocouple, etc. are used for detection, and it is widely used for disinfection, sterilization, joint and muscle treatment. The near-infrared rays penetrate into the deeper and deeper muscles of the dermis than the ultraviolet rays that only partially reach the epidermis or upper dermis, causing heat, weakening fibroblasts, destroying collagen, and breaking down elastin. Has been a significant disadvantage to skin aging and wrinkle generation As known and would else was causing the skin disorders and cataracts, keratitis, ocular diseases such as conjunctivitis, such as light sensitive, telangiectasia.

Conventional techniques for absorbing and blocking such near infrared rays include infrared absorbing dyes, resins, and solvents, as disclosed in Republic of Korea No. 80451 (published on July 9, 2015), wherein the solvent contains diacetone alcohol. A near-infrared absorption filter has been developed, which is an essential paint, and is formed by using this paint. The near-infrared absorption filter is applied to lenses of various display panels, cameras, or automobile glass, building materials glass, solar cell module, etc. Although it has been applied to a heat ray cut filter and the like, the near-infrared absorption filter made of the above-described paint had a problem that it is difficult to apply to a spectacle lens made of a thin hard coating and anti-reflective coating on the surface.

In addition, as disclosed in Republic of Korea No. 91996 (published on August 3, 2016), Korea contains a copper complex or a copper complex formed by reacting a compound having two or more coordinating atoms coordinated by a lone pair with respect to a copper component. A technology has been developed that uses a near-infrared cut filter made by curing a near-infrared absorbent composition containing a copper complex containing a compound having two or more coordinating atoms coordinating with a lone pair as a core metal as a camera module. The filter is used in various ways such as a lens for a camera, an optical filter for semiconductor light-receiving elements, protective glasses, sunglasses, heat shielding film, etc., but the near-infrared absorptive composition separately from the manufacture of spectacle lenses when applied to the lens of the glasses containing frequency Or near-infrared cut off using the same After manufacturing the sensor using a separate facility, the near-infrared cutoff filter should be applied when manufacturing the spectacle lens. Therefore, at least two manufacturing facilities and manufacturing processes should be applied, and when the near-infrared cutoff filter is purchased and applied in the manufacturing of the spectacle lens, Since the cost of purchasing the near-infrared cut filter further increases, the manufacturing process of the spectacle lens is complicated, and the manufacturing cost is very high.

KR 10-2015-0080451 A 2015. 7. 9. KR 10-2016-0091996 A 2016. 8. 3.

The present invention has been made to solve the above problems of the prior art as a new technology, the present invention to improve the anti-reflective coating of the spectacle lens to solve by blocking the near infrared (780 ~ 1,400nm) as much as possible to block The task is to allow total solar infrared transmittance (Tsir) to be 70% or less while blocking more than 40% at 1000nm near infrared.

As described above, by blocking the near infrared rays to the maximum in the spectacle lens to prevent various eye diseases caused by the heat action by the near infrared while preventing the skin aging and wrinkles around the eyes and various skin diseases caused by the near infrared. You can add it to the task you want to solve.

In addition, although not separately described, other objects within the range that can be inferred in consideration of the following detailed description, claims and drawings for describing the near-infrared blocking lens of the present invention in detail, the overall solution of the present invention. It is included in the task.

As a specific means for solving the above problems of the present invention, in the present invention, a near-infrared blocking lens is constructed, but the near-infrared blocking lens of the present invention is formed by repeatedly depositing a low refractive material and a high refractive material on the surface of the plastic lens. On the surface of the lens, a low refractive material and a high refractive material are repeatedly deposited in a thin thickness applied to a conventional antireflective coating to provide a general antireflection layer configured to prevent light reflection, and a low refractive material outside of the general antireflection layer. And the high refractive material is deposited to be repeatedly stacked to a relatively thick thickness than the general anti-reflection layer is provided with an amplification anti-reflection layer configured to block the near infrared rays outside the visible light.
In this case, the general anti-reflection layer is deposited on the surface of the plastic lens with a thickness of 20 ± 10 nm on the outside of the first low refractive index deposition layer of silicon dioxide (SiO 2) and the first low refractive deposition layer deposited on the surface of the plastic lens at a thickness of 30 ± 10 nm. A first high refractive deposition layer of zirconium dioxide (ZrO2), a second low refractive deposition layer of silicon dioxide (SiO2) deposited to a thickness of 40 ± 10 nm on the outside of the first high refractive deposition layer, and a second low refractive index A second high refractive deposition layer of zirconium dioxide (ZrO2) deposited to a thickness of 40 ± 10 nm on the outer side of the deposition layer, and silicon dioxide (SiO2) deposited to a thickness of 15 ± 10 nm on the outside of the second high refractive deposition layer. It consists of a third low refractive layer,
The amplification-type antireflection layer is an amplification inner layer of zirconium dioxide (ZrO2) deposited on the outermost low refractive material on the outermost side of the low reflection material at a thickness of 100 ± 20 nm amplified than the high refractive material of the general anti-reflection layer, and on the outside of the amplification inner layer Amplified intermediate layer made of silicon dioxide (SiO2) deposited at a thickness of 150 ± 20 nm amplified than the low refractive material of the general anti-reflective layer, and 100 ± 20 nm amplified from the high refractive material of the general anti-reflective layer outside the amplified middle layer. It characterized in that the amplified outer layer made of zirconium dioxide (ZrO2).

At this time, the low refractive material is configured to be positioned on the outermost side of the general anti-reflective layer, which is repeatedly laminated with the low refractive material and the high refractive material, and the amplified anti-reflective layer is a high refractive material amplified 2 to 10 times higher than that of the general anti-reflective layer. An amplification inner layer deposited on the outside of the outermost low refractive material of the general anti-reflection layer, and an amplification middle layer deposited on the outer side of the amplification inner layer by a high refractive index of 3 to 10 times the amplification of the low refractive material of the general anti-reflection layer It is made of a high refractive material amplified 2 to 10 times than the material, characterized in that made of an amplified outer layer deposited on the outside of the amplification middle layer.

Conventional near-infrared ray blocking technology is made by reacting a compound having two or more coordinating atoms coordinating with an unshared electron pair to copper or a near-infrared absorbing filter made of a paint containing an infrared absorbing dye, a resin, and a solvent as described above. The near-infrared cut filter formed by curing the near-infrared absorptive composition containing a copper complex is difficult to apply to a spectacle lens or has to go through a complicated manufacturing process.

According to the near-infrared blocking lens of the present invention, which is a specific means for solving the problems of the present invention, the order and angle of the low refractive material and the high refractive material deposited during the anti-reflective coating after hard coating the plastic lens in the manufacture of the spectacle lens By reflecting and blocking near-infrared rays with only the anti-reflective coating by changing the thickness of the deposited material, the manufacturing process and manufacturing cost are significantly reduced since a separate manufacturing process or manufacturing method or a separately manufactured composition or component is not added when manufacturing the spectacle lens. To have.

In this way, the anti-reflective coating of the spectacle lens is improved to block and reflect the near infrared rays of 780 ~ 1,400nm as much as possible, and the infrared ray transmittance (Tsir) of the total sun is 70% or less and 40% or more blocked in the near infrared 1000nm. By making this possible, it is possible to block the near infrared rays to the maximum by the spectacle lens to prevent various eye diseases caused by the heat action of the near infrared rays, as well as to prevent skin aging and wrinkles around the eyes, and to prevent various skin diseases. It is a great invention.

1 is a cross-sectional view showing the configuration of a spectacle lens showing a preferred example of the present invention
FIG. 2 is a graph and a contrast table showing the transmittance of each wavelength band between the near-infrared blocking lens and the general spectacle lens of the present invention
3 is a composition table showing the configuration of FIG.
4A to 4M are composition tables showing various examples of the near-infrared blocking lens of the present invention.

The present invention is to provide a near-infrared blocking lens that can prevent the aging by preventing the near infrared rays transmitted through the eye and the eye area when wearing as a spectacle lens, to prevent aging, more specifically with the drawings in the following The accompanying drawings will be described as being illustrative only and not limited to the description of the technical spirit and scope of the present invention, and the terms used herein are not limited thereto. It should not be construed as limited.

The near-infrared blocking lens 1 of the present invention is an anti-reflective coating so as to repeatedly laminate the low refractive material and the high refractive material on both surfaces by etching and hard coating the plastic lens 2 as shown in FIG. In shaping a conventional spectacle lens (= AR coating), the antireflection coating layer 20 is composed of a general antireflection layer 3 to the inside and an amplification antireflection layer 4 to the outside, respectively, and amplification of the outside is performed. The buffer antireflection layer 6 and the coating protective film 7 are formed on the outside of the anti-reflective layer 4.

At this time, between the amplification type antireflection layer 4 and the buffer closing layer 6, a conductive film 5 made of a conductive material has a voltage of 50 to 150V, a current of 10 to 30 A, and an oxygen amount of 5 Vacuum deposition may be performed by ion assisted deposition under a condition of ˜50 sccm (Standard Cubic Centimeter per Minute: cm 3 / min), wherein the buffer finish layer 6 is vacuum deposited to the outside of the conductive film 5 to be interposed. Unlike the illustrated example, the conductive film 5 is not interposed between the amplifying antireflection layer 4 and the buffer closing layer 6 and the amplification antireflection layer 4 and the buffer closing layer 6 are directly vacuum deposited. It may be done.

The general anti-reflective layer 3 of the present invention is configured to prevent the reflection of light by repeatedly depositing a low refractive material and a high refractive material on a surface of the plastic lens 2 in a thin thickness applied to a conventional antireflective coating. On the outer surface of the general anti-reflective layer 3 on which the low refractive material and the high refractive material are repeatedly laminated and deposited, regardless of whether the low refractive material is deposited on the surface of the plastic lens 2 or the high refractive material is deposited. Configure the refractive material to be located.

The amplification-type antireflection layer 4 of the present invention is deposited on the outside of the general anti-reflection layer 3 in a relatively thick thickness with respect to the general anti-reflection layer 3 to be repeatedly laminated with a low refractive material and a high refractive material. It is configured to reflect near infrared rays to block.

The amplification type antireflection layer 4 is made of a high refractive material amplified by 2-10 times more than the high refractive material of the general antireflection layer 3 on the outer side of the low refractive material located on the outermost side of the general antireflection layer 3 An amplification intermediate layer 42 and an amplification intermediate layer 42 formed of an inner layer 41 and a low refractive material amplified 3 to 10 times higher than the low refractive material of the general anti-reflective layer 3 on the outer side of the amplifying inner layer 41. The amplified outer layer 43 is made of a high refractive material amplified 2 to 10 times higher than the high refractive material on the outside of the.

The buffer closing layer 6 of the present invention is made of a thicker than the low refractive material of the general anti-reflection layer (3), made of a low refractive material made thinner than the amplification side of the low refractive material of the amplification-type prevention layer, the buffer The finishing layer 6 is configured to absorb and block ultraviolet rays and total light, such as visible light and infrared rays, which are absorbed from the outside or reflected from the lens to mitigate glare or lens gloss.

In the general antireflection layer 3, the amplification antireflection layer 4, and the buffer closing layer 6, silicon dioxide (SiO ₂ ) called silica is mainly used as a low refractive material. SiO ₂ ) is a transparent low-refractive index material having a relatively low refractive index that transmits in a wide wavelength range (200-4500 nm) .It is widely used for an anemic coating and a protective layer of a metal thin film because it is durable and resistant to external environmental changes. In addition, the silicon dioxide (SiO ₂ ) thin film has a characteristic that physical properties such as density, water absorption, refractive index, etc. change according to vacuum deposition conditions such as vacuum degree, deposition temperature, deposition method, substrate temperature, oxygen pressure, deposition rate, and the like. .

In the general antireflection layer 3 and the amplification antireflection layer 4, zirconium dioxide (ZrO ₂ ) is used as a high refractive material, and such zirconium dioxide (ZrO ₂ ) shows transmission in a wide wavelength region (340 to 1200 nm). Transparent high refractive index material with high refractive index, it is widely used for the deposition of multilayer thin film because of its durability, and zirconium dioxide (ZrO ₂ ) thin film has a large variation in refractive index according to vacuum deposition conditions, and a heterogeneous film is formed. To compensate for this, a method of forming a homogeneous film can be applied by increasing the oxygen injection amount and lowering the refractive index. In addition to the zirconium dioxide (ZrO ₂ ) as the high refractive material, titanium dioxide (TiO ₂ ) and titanium oxide (Ti ₃ O ₅ ), Tantalum oxide (Ta ₂ O ₅ ), niobium oxide (Nb ₂ O ₅ ) may be applied, the titanium dioxide (TiO ₂ ), titanium oxide (Ti ₃ O ₅ ), carbon oxide Thallium (Ta ₂ O ₅ ) and niobium oxide (Nb ₂ O ₅ ) are all transparent and have a relatively high refractive index.

In the present invention, an indium tin oxide (ITO) is used as the conductive film 5 interposed between the amplification type anti-reflection layer 4 and the buffer closing layer 6, such an indium tin oxide (ITO) Silver is a mixture of indium oxide (In ₂ O ₃ ) and tin oxide (SnO ₂ ), also known as transparent electrode or ITO. Its features are high electrical conductivity and optical transparency at the same time. Indium tin oxide (ITO) thin film The change in physical properties such as absorbency and conductivity is large depending on the vacuum deposition conditions, and has a transparent property when present in the form of a thin film, and when thickened, the electrical conductivity increases but the transparency decreases.

The coating protective film 7 of the present invention is composed of a coating by vacuum deposition on the outer surface of the buffer closing layer 6, ethyl nonafluorobutyl coated through the deposition and drying process during vacuum deposition in a sol (sol) state The cemented carbide film (SH-HT) made of ether (Ethyl Nonafluorobutyl Ether) is applied. The cemented carbide film (SH-HT) is a hydrophobic material and has a contact angle with water of about 120 °. It is about 5 times better than HT-100, which is used as a protective agent, and has excellent oil repellency, so it is very easy to remove external contamination such as fingerprints and oils on the hand, and the surface is very smooth, so it is easy to remove foreign substances and does not scratch well. It improves transmittance by reducing diffuse reflection caused by scratches and has almost no color change after deposition.

The near-infrared blocking lens 1 (= 1.60 PUV NIR) of the present invention configured as described above has a general spectacle lens (= 1.60 PUV) in the wavelength range of near-infrared ray of 780-1400 nm as shown in FIG. It can be seen that the transmittance is significantly reduced, and according to this, the near-infrared blocking lens (1) of the present invention has a near-infrared blocking rate of 780 to 1400nm of 30% or more, compared to a general spectacle lens, and at 1000nm, the blocking rate is 40%. In the graph and diagram of FIG. 2, the total infrared infrared transmittance (= Tsir) of 780 to 2000 nm is 70% or less, and the total infrared transmittance is also lowered.

As a preferable example of the near-infrared blocking lens 1 of the present invention, a total of 11 layers of deposition materials are vacuum deposited as shown in the composition table shown in FIG. 3, and the thickness of the plastic lens 2 is 30 ± 10 nm. A first low refractive deposition layer 31 of silicon dioxide (SiO ₂ ) to be deposited, and a zirconium dioxide (ZrO ₂ ) deposited to a thickness of 20 ± 10 nm on the outside of the first low refractive deposition layer 31. A second low refractive deposition layer 33 made of silicon dioxide (SiO ₂ ) deposited at a thickness of 40 ± 10 nm on the outer side of the first high refractive deposition layer 32, the first high refractive deposition layer 32, and a second low refractive deposition layer 32; The second high refractive index deposition layer 34 of zirconium dioxide (ZrO ₂ ) deposited on the outer side of the refractive deposition layer 33 to a thickness of 40 ± 10 nm, and 15 ± 10 nm outside of the second high refractive deposition layer 34. A general anti-reflection layer 3 composed of a third low refractive deposition layer 35 made of silicon dioxide (SiO ₂ ) deposited to a thickness is first implemented.

Then, the amplification inner layer 41 made of zirconium dioxide (ZrO ₂ ) deposited to a thickness of 100 ± 20 nm amplified than the high refractive material of the general anti-reflection layer (3) outside the low-reflection material on the outermost general antireflection layer (3), The amplification intermediate layer 42 of silicon dioxide (SiO ₂ ) deposited on the outer side of the amplification inner layer 41 to a thickness of 150 ± 20 nm amplified from the low refractive material of the general anti-reflective layer 3 and the amplification intermediate layer 42 An amplification reflection prevention layer consisting of an amplification outer layer 43 made of zirconium dioxide (ZrO ₂ ), which is deposited to a thickness of 100 ± 20 nm, amplified from the high refractive material of the general anti-reflection layer on the outside.

As described above, the general anti-reflective layer 3 and the amplified anti-reflective layer 4 are deposited on the surface of the plastic lens 2, and then the outer side of the amplified outer layer 43 deposited on the outermost side of the amplified anti-reflective layer 4. A conductive film 5 made of indium tin oxide (ITO) was deposited to a thickness of 10 ± 7 nm, and a buffered finish layer 6 made of silicon dioxide (SiO ₂ ) was formed on the outside of the conductive film 5 to 70 ± 20 nm. The coating protective film 7 of ethyl nonnafluorobutyl ether (Ethyl Nonafluorobutyl Ether) is deposited to a thickness of 15 ± 10 nm on the outer side of the buffer closing layer 6 so as to deposit the near-infrared blocking lens of the present invention ( 1) will be composed.

At this time, the first low refractive index deposition layer 31, the first high refractive index deposition layer 32, the second low refractive index deposition layer 33, the second high refractive index deposition layer 34 and the third bottom of the general anti-reflection layer (3) When the amplification inner layer 41, the amplification middle layer 42, the amplification outer layer 43, and the buffer closing layer 6 of the refractive deposition layer 35, the amplification type antireflection layer 4 are deposited, respectively, a voltage of 50 to 150 V and a current The ion assisted deposition can be performed under conditions of 10 ~ 30A and 5 ~ 50sccm (Standard Cubic Centimeter per Minute: cm3 / min).

The general antireflection layer 3 made relatively thin on the surface of the plastic lens 2 of the present invention and the amplification antireflection layer 4 made of a relatively thick layer, and the buffer closing layer 6 and the coating protective film 7 based on the surface of the plastic lens 2 of the present invention. The conductive film 5 may be selectively formed by vapor deposition and variously implemented as follows.

As described above, the present invention provides a first low refractive index made of silicon dioxide (SiO ₂ ), which is a low refractive material when the general anti-reflection layer 3 is deposited on the surface of the plastic lens 2 as shown in FIGS. 4A to 4D. Instead of the deposition layer 31, a high refractive index deposition layer 32 made of zirconium dioxide (ZrO ₂ ), which is a high refractive material, may be deposited, and as shown in FIGS. 4A and 4B, the amplification type anti-reflection layer 4 and a buffered finish The conductive layer 5 may be formed between the layers 6 without interposing the conductive layer 5, and the conductive layer 5 may be interposed between the amplification antireflection layer and the buffer closing layer 6 as shown in FIGS. 4C and 4D. 4A and 4B, the thickness of the amplification inner layer 41 of the amplification-type antireflection layer 4 may be varied, and each low refractive material layer or the high refractive index of the general type anti-reflection layer 3 may be performed as shown in FIGS. 4C and 4D. It can also be carried out by varying the thickness of the material layer, the buffer closing layer (6) Again, the thickness can be varied.

In the composition table of FIG. 3, which is a preferred example of the present invention, the conductive film 5 may be deposited as shown in FIG. 4E, and as shown in FIG. 4F, the general antireflection layer 3 may be formed of the first high refractive index deposition layer 32, respectively. Only the first low refractive index layer 31 may be laminated thinly to realize the whole without repetition.

4G shows that the amplification inner layer 41 of the amplification-type antireflection layer 4 may be implemented to be thinner than the thickest high refractive material layer of the general anti-reflection layer 3, and FIG. 4G. 4H to 4J show that the general anti-reflection layer 3 can be configured to be thin so that the entire thickness can be made thinner.

4J and 4K, as described above, instead of zirconium dioxide (ZrO ₂ ) as a high refractive material, titanium dioxide (TiO ₂ ), titanium oxide (Ti ₃ O ₅ ), tantalum oxide (Ta ₂ O ₅ ), and niobium oxide ( Nb ₂ O ₅ ) can be selected and deposited, and in FIG. 4J, the first high refractive deposition layer 32, the second high refractive deposition layer 34, and the amplification type antireflection layer of the general antireflection layer 3 are illustrated. The amplification inner layer 41 and the amplification outer layer 43 of (4) are respectively replaced by tantalum oxide (Ta ₂ O ₅ ), and in FIG. 4K, the first high refractive index deposition layer 32 and the second antireflection layer 3 of FIG. It was shown that the amplification inner layer 41 and the amplification outer layer 43 of the high refractive index deposition layer 34 and the amplification reflection preventing layer 4 were replaced with titanium dioxide (TiO ₂ ) or titanium oxide (Ti ₃ O ₅ ), respectively. It can be seen that the refractive indices are slightly different.

4L and 4M, the general antireflection layer 3 is composed of three layers of the first low refractive index deposition layer 31, the first high refractive index deposition layer 32, and the second low refractive index deposition layer 33. The three layers of the amplification inner layer 41, the amplification middle layer 42, and the amplification outer layer 43 of the antireflection layer 4 are the same, but the thickness of the three layers of the general anti-reflection layer 3 is the same in FIG. 4L. And, in Figure 4m it is shown that the thickness of the three layers of the general anti-reflection layer (3) can be configured differently.

The near-infrared blocking lens 1 of the present invention having various configurations as described above blocks the near-infrared rays by the amplification-type anti-reflection layer 4 and the buffer closing layer 6 to prevent various eye diseases caused by heat action by the near-infrared rays. It prevents skin aging and wrinkles around the eyes, and prevents various skin diseases caused by near infrared rays. It also has a very high effect of UV blocking rate along with near infrared rays, and reflects and blocks near infrared rays with only anti-reflective coating, When the lens is manufactured, a separate manufacturing process, a manufacturing method, or a separately manufactured composition or component is not added, thereby providing a significant reduction in manufacturing labor and manufacturing cost.

As described above in the detailed description of the present invention has been described with respect to the most preferred embodiment of the present invention, various modifications may be made within the scope not departing from the technical scope of the present invention, the protection scope of the present invention is therefore Not limited to the examples, the scope of protection from the description of the claims and the equivalent technical means to those described below will be recognized.

1: NIR blocking lens
2: plastic lens 20: anti-reflective coating layer
3: general antireflection layer 31: first low refractive deposition layer 32: first high refractive deposition layer 33: second low refractive deposition layer 34: second high refractive deposition layer 35: third low refractive deposition layer
4: amplification reflection prevention layer 41: amplification inner layer 42: amplification intermediate layer 43: amplification outer layer
5: conductive film
6: buffered finishing layer
7: Coating protective film

Claims (6)

An anti-reflective coating layer 20 repeatedly depositing a low refractive material and a high refractive material on the surface of the plastic lens 2;
The anti-reflective coating layer 20 is formed on the surface of the plastic lens 2 by repeatedly depositing a low refractive material and a high refractive material in a thin thickness applied to a conventional anti-reflective coating to prevent reflection of light. );
The amplification type antireflection layer 4 configured to block the near-infrared ray outside the visible light is deposited by repeatedly stacking the low refractive material and the high refractive material to a thickness relatively thicker than the general anti-reflection layer 3 outside the general anti-reflection layer 3. Included;
The general anti-reflection layer 3 includes a first low refractive index deposition layer 31 of silicon dioxide (SiO2) deposited on the surface of the plastic lens 2 and a thickness of 30 ± 10 nm, and a first low refractive deposition layer 31. The first high refractive deposition layer 32 of zirconium dioxide (ZrO2) deposited on the outside of the 20 ± 10 nm thickness, and the silicon dioxide deposited to a thickness of 40 ± 10 nm on the outside of the first high refractive deposition layer 32 ( Second high refractive deposition layer (34) made of zirconium dioxide (ZrO2) deposited to a thickness of 40 ± 10 nm on the outside of the second low refractive deposition layer (33) of SiO2) and the second low refractive deposition layer (33). And a third low refractive deposition layer 35 made of silicon dioxide (SiO 2) deposited to a thickness of 15 ± 10 nm on the outside of the second high refractive deposition layer 34;
The amplification-type antireflection layer 4 is amplified by zirconium dioxide (ZrO2) deposited to a thickness of 100 ± 20 nm, which is amplified than the high refractive material of the general anti-reflection layer 3 on the outermost low-reflection material of the general anti-reflection layer 3 An amplification intermediate layer 42 made of silicon dioxide (SiO 2) deposited to an inner layer 41, a thickness of 150 ± 20 nm amplified from the low refractive material of the general anti-reflective layer 3 outside the amplification inner layer 41, and amplification Near-infrared blocking lens, characterized in that the amplification outer layer (43) made of zirconium dioxide (ZrO2) is deposited on the outer side of the middle layer 42 to a thickness of 100 ± 20nm amplified than the high refractive material of the anti-reflective layer.
The method according to claim 1;
A buffer closing layer 6 of low refractive index material configured to be deposited outside of the amplification type antireflection layer 4;
A coating protective film 7 deposited on the outer surface of the buffer closing layer 6 so that water droplets easily fall off while protecting the surface of the antireflective coating deposited on the spectacle lens;
A conductive film 5 made of a conductive material vacuum deposited by ion assisted deposition so as to be interposed between the amplification type antireflection layer 4 and the buffer closing layer 6;
Near-infrared cut off lens characterized in that it further comprises.
The method according to claim 2;
The conductive film 5 is made of indium tin oxide (ITO) deposited on the outer side of the amplifying outer layer 43 to a thickness of 10 ± 7 nm;
The buffer closing layer 6 is made of silicon dioxide (SiO 2) deposited on the outer side of the conductive film 5 to a thickness of 70 ± 20 nm;
The coating protective film (7) is a near-infrared blocking lens, characterized in that the ethyl nonafluorobutyl ether (Ethyl Nonafluorobutyl Ether) is deposited on the outside of the buffer closing layer (6) to a thickness of 15 ± 10nm.
The method according to claim 2;
The first low refractive index deposition layer 31, the first high refractive index deposition layer 32, the second low refractive index deposition layer 33, the second high refractive index deposition layer 34, and the third low refractive index deposition layer of the general anti-reflection layer 3. When the layer 35, the amplification inner layer 41 of the amplification type antireflection layer 4, the amplification middle layer 42, the amplification outer layer 43, and the buffer closing layer 6 are respectively deposited, the voltage is 50 to 150 V and the current is 10 to Near-infrared blocking lens, characterized in that the ion assisted deposition is carried out under the conditions of 30A and oxygen amount of 5 ~ 50sccm.
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