OPHTHALMIC LENS COMPRISING A BASE OF POLYMERIC MATERIAL WITH A COATING HAVING AN INTERFERENTIAL, ANTI-REFLECTIVE, ANTI-IRIDESCENT AND IR FILTER MULTIPLE LAYER STRUCTURE

Abstract

Ophthalmic lens including a base of polymeric material with a coating having an interferential, anti-reflective, anti-iridescent and infrared filter multiple layer structure. An interphase, a first layer (of 91-169 nm) with a refraction index higher than 1.8, a second layer (of 128-248 nm) with a refraction index lower than 1.65, a third layer (of 73-159 nm) with a refraction index higher than 1.8 and a fourth layer (of 40-138 nm) with a refraction index lower than 1.8. A total thickness of the multiple layer structure is less than 600 nm. The structure can have intermediate layers with intermediate refraction indices, in which case a doublet of two adjacent layers that fulfil the thicknesses above is replaced by a triplet so that the thickness and an optical thickness of the triplet differ from those of the doublet by less than 5%, respectively.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the foreign priority benefit of Spanish Patent Application No. P201331729 filed Nov. 27, 2013, the contents of which are incorporated herein by reference.

FIELD OF THE INVENTION

The invention relates to an ophthalmic lens comprising a base of polymeric material with a coating having an interferential multiple layer structure.

BACKGROUND

The technology of multiple layer structures is known for creating interferential effects on optical surfaces.

In the field of ophthalmic lenses, it is usual to use interferential multiple layer structures to create anti-reflective or reflective surfaces of different intensities and residual colours, usually anti-reflective of green colour with visible light reflection percentages lower than 2.5%, or even lower than 1.5% for each surface including a multiple layer structure.

Also known is the use of treatments for filtering a percentage of the IRA (infra-red A) or blue radiation selectively. However, the IR light filtering requires complex solutions that are not easily applicable to transparent lenses without colouring. In particular, layers of metals can be applied that absorb or help to reflect part of the IRA radiation but these materials absorb at the same time visible light, and so they do not enable obtaining high visible transmittance lenses with these features.

Interferential filters exist (for example the ones of the heat mirror type) that are used in applications for precision optics on a mineral lens, and they enable reducing the IRA radiation transmittance while maintaining a high visible transmittance: these filters have a multiple layer structure with between 40 and 100 layers and they have a total thickness over 1000 nm (nanometres), These filters are designed specifically for a certain angle of incidence of the incident radiation, and therefore if the angle varies, they display the typical effects of iridescence. Also, these treatments usually have a slight residual colouring which, in comparison with the anti-reflective lenses, makes them rather unattractive in aesthetic terms.

SUMMARY OF THE INVENTION

An object of the invention is to overcome these drawbacks. This purpose is achieved by means of an ophthalmic lens of the type indicated at the beginning characterised in that the multiple layer structure comprises:

• • an interphase, orientated towards the base, of a material from the group made up of SiO_x, SiO₂, Cr, Ni/Cr, SnO₂, Al₂O₃, AlN, ZnO, SiO/Cr, SiO_x/Al₂O₃, ITO, MoO₃, with a thickness between 0 and 150 nm, preferably between 5 and 25 nm
  • a first high refraction index layer, of a material from the group made up of oxides, nitrides or oxynitrides of Zr, Ti, Sb, In, Sn, Ta, Nb, Hf and mixtures thereof, with a refraction index n_D higher than 1.8,
  • a second low refraction index layer, of a material from the group made up of SiO₂, MgF₂, Al₂O₃, LaF₃ and mixtures thereof, with a refraction index n_D lower than 1.65,
  • a third high refraction index layer made of a material from the group made up of oxides, nitrides or oxynitrides Zr, Ti, Sb, In, Sn, Ta, Nb, Hf and mixtures thereof, with a refraction index n_D higher than 1.8,
  • a fourth layer, made of a material from the group made up of SiO₂, MgF₂, Al₂O₃, LaF₃ and mixtures thereof, with a refraction index n_D lower than 1.8,

where between the interphase and the first high refraction index layer there is a first intermediate layer with a refraction index n_D lower than 1.8 and with a thickness of between 0 and 160 nm,

where between the first high refraction index layer and the second low refraction index layer there is a second intermediate layer with a refraction index n_D between 1.65 and 1.8 and with a thickness of between 0 and 100 nm,

where between the second low refraction index layer and the third high refraction index layer there is a third intermediate layer with a refraction index n_D between 1.65 and 1.8 and with a thickness between 0 and 110 nm,

where the total thickness of the multiple layer structure is at the most 600 nm, measured from the start of the interphase to the end of the fourth layer, and where, if there is none of said intermediate layers, the thickness of said first high refraction index layer is between 91 and 169 nm, preferably between 101 and 159 nm, the thickness of said second low refraction index layer is between 128 and 248 nm, preferably between 138 and 240 nm, the thickness of said third high refraction index layer is between 73 and 159 nm, preferably between 83 and 147 nm, and the thickness of said fourth layer is between 40 and 138 nm,

and, if there is one of said intermediate layers, it holds that:

• • the doublet made up of the first high refraction index layer and the second low refraction index layer that fulfil said thicknesses is replaced by a triplet made up of a first intermediate layer, a first high refraction index layer and a second low refraction index layer such that the thickness of said triplet differs from the thickness of said doublet by less than 5%, and such that the optical thickness of said triplet differs from the optical thickness of said doublet by less than 5%,

and/or

• • the doublet made up of the first high refraction index layer and the second low refraction index layer which fulfil said thicknesses is replaced by a triplet made up of a first high refraction index layer, a second intermediate layer and a second low refraction index layer such that the thickness of said triplet differs from the thickness of said doublet by less than 5%, and such that the optical thickness of said triplet differs from the optical thickness of said doublet by less than 5%,

and/or

• • the doublet made up of the second low refraction index layer and the third high refraction index layer which fulfil said thicknesses is replaced by a triplet made up of a second low refraction index layer, a third intermediate layer and a third high refraction index layer such that the thickness of said triplet differs from the thickness of said doublet by less than 5%, and such that the optical thickness of said triplet differs from the optical thickness of said doublet by less than 5%.

In fact, this way a multiple layer structure is obtained that reflects a significant percentage of infra-red radiation while it maintains the anti-reflective properties in the visible, with a limited angular dispersion in the residual reflection, by adapting standard anti-reflective filter technology.

Multiple layers exist in the market for ophthalmic products, which are anti-reflective, with an infra-red filter or which limit the angular dispersion in the residual reflection, but there is no solution that groups together these four characteristics in one and the same treatment with a total thickness of less than 600 nm. This is due to the fact that each of the desired effects is achieved by including a group of layers specifically designed to fulfil the specific function in question (anti-reflective, IR filter or angular dispersion limiter in the residual reflection). This way, the total of the multiple layer structure has a plurality of layers and a high thickness. This high thickness produces secondary mechanical effects (residual stress, cracking, delamination) which, although they are maintained within acceptable values in the case of mineral precision optics lenses, they are not acceptable in the case of ophthalmic organic based lenses. Even if the amount of filtered IRA light is reduced, you still need a high overall thickness to maintain some standard anti-reflective characteristics in the visible spectrum of the ophthalmic sector.

However, it has been discovered that there is a very specific subset of thicknesses of interferential multiple layers, with an overall thickness less than 600 nm, which allows obtaining at the same time an anti-reflective treatment in the visible with low angular dispersion in the residual reflection (a visible reflection less than 5% for an incident angle of 60°, preferably less than 4%), and partially reflecting the IR-A light (an average transmission of between 780 and 1400 nm less than 76%, preferably less than 70%). The singularity of this subset of treatment layer thicknesses is revealed because when varying the thickness of each layer within a relatively small range, and without exceeding 600 nm total, some of the three desired requirements are not fulfilled.

The ranges of thicknesses that include the value “0” (for example, “from 0 to 150 nm” mean that the layer in question is optional (the value “0” is equivalent to saying that said layer is not present).

Preferably, in the event that there is none of the intermediate layers, the thickness x of the first high refraction index layer, the thickness y of the second low refraction index layer, the thickness z of the third high refraction index layer and the thickness t of the fourth layer fulfil the following relation:

$\left(\mathrm{xyzt}\right)-\left(\begin{array}{cccc}129.5& 188.3& 116.0& 89.0\end{array}\right)·A·\left(\begin{array}{c}x-129.5\\ y-188.3\\ z-166.0\\ t-89.0\end{array}\right)\le 1$ $\mathrm{where}$ $A=\left(\begin{array}{cccc}8.29·{10}^4& -1.76·{10}^{-4}& -1.18·{10}^{-4}& 1.50·{10}^{-4}\\ -1.76·{10}^{-4}& 3.34·{10}^{-4}& -1.80·{10}^{-5}& -3.50·{10}^{-5}\\ -1.18·{10}^{-4}& -1.80·{10}^{-5}& 7.16·{10}^{-4}& -2.60·{10}^{-4}\\ 1.50·{10}^{-4}& -3.50·{10}^{-5}& -2.60·{10}^{-4}& 5.34·{10}^{-4}\end{array}\right)$

and, if there is one of the intermediate layers, it holds that:

• • the doublet made up of the first high refraction index layer and the second low refraction index layer that that fulfil the relation above is replaced by a triplet made up of a first intermediate layer, a first high refraction index layer and a second low refraction index layer such that the thickness of said triplet differs from the thickness of said doublet by less than 5%, and such that the optical thickness of said triplet differs from the optical thickness of said doublet by less than 5%,

and/or

• • the doublet made up of the first high refraction index layer and the second low refraction index layer which fulfil the relation above is replaced by a triplet made up of a first high refraction index layer, a second intermediate layer and a second low refraction index layer such that the thickness of said triplet differs from the thickness of said doublet by less than 5%, and such that the optical thickness of said triplet differs from the optical thickness of said doublet by less than 5%,

and/or

the doublet made up of the second low refraction index layer and the third high refraction index layer which fulfil the relation above is replaced by a triplet made up of a second low refraction index layer, a third intermediate layer and a third high refraction index layer such that the thickness of said triplet differs from the thickness of said doublet by less than 5%, and such that the optical thickness of said triplet differs from the optical thickness of said doublet by less than 5%.

Advantageously the thickness x of the first high refraction index layer, the thickness y of the second low refraction index layer, the thickness z of the third high refraction index layer and the thickness t of the fourth layer fulfil the following relation:

$\left(\mathrm{xyzt}\right)-\left(\begin{array}{cccc}129.7& 189.7& 114.2& 87.2\end{array}\right)·A·\left(\begin{array}{c}x-129.7\\ y-189.7\\ z-114.2\\ t-87.2\end{array}\right)\le 1$ $\mathrm{where}$ $A=\left(\begin{array}{cccc}1.53·{10}^{-3}& -3.41·{10}^{-4}& -1.35·{10}^{-4}& 8.99·{10}^{-5}\\ -3.41·{10}^{-4}& {4.82}^{-4}& -1.86·{10}^{-5}& -9.77·{10}^{-6}\\ -1.35·{10}^{-4}& -1.86·{10}^{-5}& 1.12·{10}^{-3}& -2.53·{10}^{-4}\\ 8.99·{10}^{-5}& 9.77·{10}^{-6}& -2.53·{10}^{-4}& 8.44·{10}^{-4}\end{array}\right)$

and, if there are some of the intermediate layers, preferably they fulfil the same is relations above.

Preferably a simulation of the reflection and transmission curves of the multiple layer structure has the following characteristics:

• • a visible reflection R_vis by a light incidence angle of 15° lower than 2.5%, preferably lower than 1.5%; calculated as an average of the reflection value in the range 380-780 nm, weighted by the spectral light efficiency spectrum for day light and by the spectral distribution of the lighting D65, according to Spanish standard UNI-EN ISO 13666:1998,
  • a visible reflection R_vis by a light incidence angle of 60° lower than 5.0%, preferably lower than 4.5%; calculated as in the case above, and
  • a transmission value in infra-red A T_IR-A lower than 76%, preferably lower than 70%; calculated as an average transmission value in the range 780-1400 nm according to the following formula:

$T_{\mathrm{IR}-A}=\sum _{\lambda \in A}\frac{T\left(\lambda \right)}{14}$ $\mathrm{where}A=\left\{780,800,850,900,950,1000,1050,1100,1150,1200,1250,1300,1350,1400\right\}$

In fact, the combination of these three properties within the ranges indicted makes it possible to obtain lenses with optimum results. The parameters indicated are usual in the state of the art, are clearly determined and they can be obtained in a reliable manner by following the specified standards, that include some procedures for determining the values of the parameters in question in an objective manner and common to the state of the art.

Advantageously a simulation of the reflection and transmission curves of the multiple layer structure has a blue light transmittance value T_azul lower than 95%, preferably lower than 92%; calculated as the average transmission value in the range 410-460 nm according to the following formula:

$T_{\mathrm{azul}}=\sum _{\lambda \in B}\frac{T\left(\lambda \right)}{6}$ $\mathrm{where}B=\left\{410,420,430,440,450,460\right\}$

In fact, an additional advantage is that a suitable definition of each of the layers in the multiple layer structures also allows fulfilling an additional result, which is that the (little) visible light reflected is concentrated in the blue-violet spectrum. This way the lens offers additional protection to the user, reducing the amount of blue light that reaches the user's eye.

Preferably the coating comprises a layer of anti-scratching lacquer between the multiple layer structure and the base.

Advantageously the lens has a multiple layer structure both on the inner surface and on the outer surface of the lens. In fact, this way it is possible to noticeably increase the effect of the IRA radiation filtered, with an improvement also in the transmittance in visible light.

Preferably the first high refraction index layer and/or the third high refraction index layer have a refraction index n_D higher than 1.95.

Preferably the second low refraction index layer has a refraction index n_D lower than 1.5.

Advantageously the fourth layer has a refraction index n_D lower than 1.65.

Preferably the fourth layer has a refraction index n_D between 1.4 and 1.6 and a thickness between 50 and 124 nm.

Advantageously the first intermediate layer has a thickness between 0 and 25 nm.

Advantageously the first high refraction index layer and/or the third high refraction index layer is made up of two high refraction index sub-layers, preferably by a first sub-layer of TiO₂ and a second sub-layer of ZrO₂ or vice versa. In fact, the ZrO₂ has a high evaporation temperature and, as a layer of considerable thickness should be applied this can cause cracking problems due to residual stress. An alternative would be to completely replace this layer of ZrO₂ with a layer of TiO₂, which has a lower evaporation temperature. However, this layer of TiO₂ is less hard, therefore is scratches more easily. The solution proposed allows combining the advantages in both cases. Generally, in this specification and claims it must be understood that, when a layer is defined by indicating that the materials can be “a mixture of the above”, this includes not only the case where a layer comprises a more or less homogenous mixture of said materials, but also the case where the layer is divided into sub-layers, each one of them made of one of said materials. The specific case of the two sub-layers of TiO₂ and ZrO₂ is an example of this. So, another advantageous solution example is when the second low refraction index layer and/or the fourth layer are made up of two low refraction index sub-layers, preferably by a first sub-layer of SiO₂ and a second sub-layer of Al₂O₃ or vice versa.

Advantageously on the fourth layer there is a hydrophobic outer layer.

The lenses can be both sun lenses (absorbent in the visible spectrum) and substantially transparent lenses in the visible spectrum (indoor lenses).

The application of these layers is usually done using PVD (Physical Vapor Deposition) techniques through evaporation with electron guns or thermal evaporation, although other techniques exist like Plasma enhanced Chemical Vapor Deposition (PeCVD) or the reactive Sputtering with which it is also possible to obtain this type of interferential layers.

A particularly advantageous embodiment of the invention is obtained when the multiple layer structure comprises:

• • an interphase with a thickness between 15 and 45 nm, preferably of SiO₂,
  • a first high refraction index layer with a thickness between 123 and 145 nm, preferably of TiO₂,
  • a second low refraction index layer with a thickness between 170 and 217 nm, preferably of SiO₂,
  • a third high refraction index layer, divided into a first sub-layer with a thickness between 59 and 67 nm, preferably of TiO₂, and a second sub-layer with a thickness between 50 and 74 nm, preferably of ZrO₂,
  • a fourth layer with a thickness between 44 and 68 nm, preferably of SiO₂.

BRIEF DESCRIPTION OF THE DRAWINGS

Other advantages and characteristics of the invention are appreciated from the following description, where, in a non-limiting manner, some preferable embodiments of the invention are explained, with reference to the accompanying drawings. The figures show:

FIG. 1, a diagrammatic view of a cross section of an embodiment of a lens with a coating according to the invention.

FIG. 2, a diagrammatic view of a cross section of a multiple layer structure according to the invention.

FIGS. 3 to 15, graph showing the reflection (in %) according to the wave length (λ, in nm) of the incident radiation for the lenses in the respective examples.

DETAILED DESCRIPTION

FIG. 1 shows a general structure example of a lens according to the invention. The lens comprises a base P of polymeric material on which there is a primer layer IM, which is optional and which usually has a thickness between 0.3 and 1.5 microns. Next there is a hardening layer E (usually with a thickness between 1 and 4 microns) on which the multiple layer structure M according to the invention is arranged. This multiple layer structure M is made up of a plurality of layers, which will be detailed later. The last layer of the structure is a hydrophobic layer H, with a thickness between 3 and 25 nm. Generally this structure can exist on the two lens surfaces or only on one of them. If present on one of them, any other conventional coating can be applied to the opposite surface.

FIG. 2 shows diagrammatically a multiple layer structure M according to the invention in greater detail.

It comprises an interphase IN (which is optional) of metallic material or metallic oxide, with scarce repercussion in the optical properties but critical for the mechanical properties, particularly those regarding adherence and wear, and a barrier against oxidation and diffusion. Preferably the material is one of the group made up of SiO_x, SiO₂, Cr, Ni/Cr, SnO₂, Al₂O₃, AlN, ZnO, SiO/Cr, SiO_x/Al₂O₃, ITO and MoO₃.

Next there is a layer of metallic oxide, metallic nitride or metallic oxynitride with a refraction index n_D>1.8 (preferably >1.95) necessary for adjusting the optical properties and essential for obtaining mechanical properties resistant to scratching. It is the first high refraction index layer 1A. Preferably it is made of a material from the group made up of oxides, nitrides or oxynitrides of Zr, Ti, Sb, In, Sn, Ta, Nb, Hf and mixtures thereof.

The following layer is made of a metallic oxide or fluoride with a refraction index n_D<1.65 (preferably <1.5) necessary for adjusting the optical properties and essential for obtaining the mechanical properties resistant to scratching. It forms the second low refraction index layer 2B. Preferably it is made of a material from the group made up of SiO₂, MgF₂, Al₂O₃, LaF₃ and mixtures thereof.

On the second low refraction index layer 2B there is a third high refraction index layer 3A, made of metallic oxide, metallic nitride or metallic oxynitride with a refraction index n_D>1.8 (preferably >1.95). Preferably it is made of a material from the group made up of oxides, nitrides or oxynitrides of Zr, Ti, Sb, In, Sn, Ta, Nb, Hf and mixtures thereof.

On the third high refraction layer 3A there is a layer of metallic oxide or fluoride with a refraction index n_D<1.8 (preferably <1.65). It is the fourth layer 4. Preferably it is made of a material from the group made up of SiO₂, MgF₂, Al₂O₃, LaF₃ and mixtures thereof.

The total thickness of the multiple layer structure is less than 600 nm, measured from the start of the interphase to the end of the fourth layer, and preferably it is less than 500 nm.

The simulation of the reflection and transmission curves of the multiple layers is achieved using the transfer matrix method, introduced by F. Abelés (F. Abelés, J. Phys. Radium 11, 307 (1950)) and described in the state of the art (for example in H. A. Macleod, Thin-Film Optical Filters, 4^th Edition, CRC Press (2010)). It is the method applied by most of the commercial programs (see, for example, FilmStar™ (www.ftqsoftware.com) or Essential Macleod (www.thinfilmcenter.com)) on the simulation of the reflection of multiple layers, and it is used knowing the dispersion of the complex refraction indices of the materials in each layer and the substrate, in the range of 380-1400 nm, the thicknesses of each layer and the incidence angle of the light radiation.

Methods of Analysing a Lens with a Coating According to the Invention

The analyses required to analyse a lens according to the invention can be, for example:

• • Optical properties: optical transmittance and reflection spectra from 200 to 3000 nm. The reference standard will be EN1836
  • Layer thickness and composition: ESCA (Electron Spectroscopy for Chemical Analysis), XPS (X-ray Photoelectron Spectroscopy), Electron Microscopy, SIMS (Secondary Ion Mass Spectroscopy).

EXAMPLES

Below are shown a series of examples wherein, in each case, the composition and thickness of the layer is indicated and the optical properties obtained.

Example 1: Minimising the Reflection of Visible Radiation

Layer 4         SiO2-81.2 nm
Layer 3A        TiO2-101.8 nm
Layer 2B        SiO2-169.9 nm
Layer 1A        TiO2-120.8 nm
Base            Polymer nD = 1.6
RV 15°          0.5%
RV 60°          5.0%
T IR-A          71.8%
Total thickness 437.7 nm

FIG. 3 shows a graph showing the reflection (in %) according to the wave length (λ, in nm) of the incident radiation.

Example 2: Minimising the Transmission of IR-A Radiation

Layer 4         SiO2-61.4 nm
Layer 3A        TiO2-107.6 nm
Layer 2B        SiO2-169.0 nm
Layer 1A        TiO2-126.0 nm
Base            Polymer nD = 1.6
RV 15°          1.5%
RV 60°          5.0%
T IR-A          69.7%
Total thickness 463.9 nm

FIG. 4 shows a graph showing the reflection (in %) according to the wave length (λ, in nm) of the incident radiation.

Example 3: Minimising the Reflection of Radiation at 60°

Layer 4         SiO2-98.0 nm
Layer 3A        TiO2-117.7 nm
Layer 2B        SiO2-202.3 nm
Layer 1A        TiO2-129.9 nm
Base            Polymer nD = 1.6
RV 15°          1.5%
RV 600          3.0%
T IR-A          75.3%
Total thickness 547.8 nm

FIG. 5 shows a graph showing the reflection (in %) according to the wave length (λ, in nm) of the incident radiation.

Example 4: Minimising the Transmission of Blue Light

Layer 4         SiO2-70.6 nm
Layer 3A        TiO2-121.7 nm
Layer 2B        SiO2-226.0 nm
Layer 1A        TiO2-140.1 nm
Base            Polymer nD = 1.6
RV 15°          1.5%
RV 60°          4.4%
T IR-A          74.3%
Total thickness 558.2 nm

FIG. 6 shows a graph showing the reflection (in %) according to the wave length (λ, in nm) of the incident radiation.

A 70.6% transmission of blue light is obtained.

Example 5: Minimising the Reflection of Visible Radiation

In this Example other materials have been used to produce the layers in the multiple layer structure.

Layer 4         MgF2-77.1 nm
Layer 3A        ZrO2-115.8 nm
Layer 2B        MgF2-189.7 nm
Layer 1A        ZrO2-141.0 nm
Base            Polymer nD = 1.6
RV 15°          0.4%
RV 60°          5.0%
T IR-A          76.0%
Total thickness 523.7 nm

FIG. 7 shows a graph showing the reflection (in %) according to the wave length (λ, in nm) of the incident radiation.

Example 6: Residual Reflection Concentrated in Green

Layer 4         SiO2-100.9 nm
Layer 3A        TiO2-118.5 nm
Layer 2B        SiO2-188.3 nm
Layer 1A        TiO2-116.9 nm
Base            Polymer nD = 1.6
RV 15°          1.5%
RV 60°          3.8%
T IR-A          75.0%
Total thickness 524.6 nm

FIG. 8 shows a graph showing the reflection (in %) according to the wave length (λ, in nm) of the incident radiation.

Example 7: Solution According to the State of the Art

In this Example the solution that would have been obtained from the knowledge of the state of the art has been reproduced.

Layer 6         SiO2-73.0 nm
Layer 5         TiO2-103.3 nm
Layer 4         SiO2-158.6 nm
Layer 3         TiO2-100.1 nm
Layer 2         SiO2-169.2 nm
Layer 1         TiO2-113.2 nm
Base            Polymer nD = 1.6
RV 15°          1.2%
RV 60°          6.2%
T IR-A          67.1%
Total thickness 717.4 nm

As you can see, more layers are used and the thickness is greater than 600 nm.

FIG. 9 shows a graph showing the reflection (in %) according to the wave length (λ, in nm) of the incident radiation.

Example 8

This Example shows how, starting with a first multiple layer structure (#8a), it is possible to improve the optical properties by including a third intermediate layer between the second low refraction index layer and the third high refraction index layer (#8b). It also shows another multiple layer structure (#8c) which, without the presence of the third intermediate layer, has practically the same optical properties. The structure #8c fulfils an equivalence relation between the physical thicknesses and the optical thicknesses of the central triplet in the structure #8b (intermediate layer of Al₂O₃ and its two adjacent layers) and the doublet in the structure #8c (the second low refraction index layer (SiO₂) and the third high refraction index layer (TiO₂)).

	#8a	#8b	#8c
SiO2	84.4 nm	84.4 nm	84.4 nm
TiO2	90.0 nm	90.0 nm	98.4 nm
Al2O3	0.0 nm	34.8 nm	0.0 nm
SiO2	142.6 nm	142.6 nm	174.2 nm
TiO2	122.5 nm	122.5 nm	122.5 nm
Base	Polymer nD = 1.6	Polymer nD = 1.6	Polymer nD = 1.6
RV 15°	1.8%	0.4%	0.5%
RV 60°	11.0%	4.8%	5.0%
T IR-A	747%	72.9%	72.1%
Total thickness	439.6 nm	474.4 nm	479.5 nm
Thickness of the central triplet	232.6 nm	267.5 nm	272.6 nm
Optical thickness of the central triplet	388.4 nm	445.4 nm	450.6 nm

FIG. 10 shows a graph showing the reflection (in %) according to the wave length (λ, in nm) of the incident radiation for each of the three cases.

Example 9

In this Example, as in Example 8, it shows how, starting with a first multiple layer structure (#9a), it is possible to improve the optical properties by including an intermediate layer. In this case it is a second intermediate layer between the first high refraction index layer and the second low refraction index layer (#9b). It also shows another multiple layer structure (#9c) which, without the presence of the second intermediate layer, has virtually the same optical properties. Also in this case the structure #9c fulfils an equivalence relation between the physical thicknesses and the optical thicknesses of the central triplet in the structure #9b (intermediate layer of Al₂O₃ and its two adjacent layers) and the doublet in the structure #9c (the first high refraction index layer (TiO₂) and the second low refraction index layer (SiO₂)).

	#9a	#9b	#9c
SiO2	87.7 nm	87.7 nm	87.7 nm
TiO2	110.8 nm	110.8 nm	110.8 nm
SiO2	148.3 nm	148.3 nm	175.9 nm
Al2O3	0.0 nm	33.9 nm	0.0 nm
TiO2	104.0 nm	104.0 nm	109.7 nm
Base	Polymer nD = 1.6	Polymer nD = 1.6	Polymer nD = 1.6
RV 15°	2.9%	1.0%	1.1%
RV 600	9.7%	4.5%	5.0%
T IR-A	74.5%	73.5%	73.0%
Total thickness	450.9 nm	484.8 nm	484.1 nm
Thickness of the triplet in	252.3 nm	286.3 nm	285.6 nm
contact with the base
Optical thickness of the triplet	424.9 nm	480.4 nm	476.2 nm
in contact with the base

FIG. 11 shows a graph showing the reflection (in %) according to the wave length (λ, in nm) of the incident radiation for each of the three cases.

Example 10

In this Example, the multiple layer structure has an interphase (of SiO₂ and 15 nm thick), and the third high refraction index layer is sub-divided into two sub-layers (one of TiO₂ and one of ZrO₂).

Layer 4         SiO2-62.4 nm
Layer 3A-2      ZrO2-50.0 nm
Layer 3A-1      TiO2-59.3 nm
Layer 28        SiO2-175.7 nm
Layer 1A        TiO2-126.5 nm
Interphase      SiO2-15 nm
Base            Polymer nD = 1.6
RV 15°          0.9%
RV 60°          4.7%
T IR-A          72.0%
Total thickness 488.9 nm

This solution is a preferable embodiment of the invention.

FIG. 12 shows a graph showing the reflection (in %) according to the wave length (λ, in nm) of the incident radiation.

Examples 11 and 12

In these Examples, as in Examples 8 and 9, it shows how, starting with a first multiple layer structure (#11a, #12a), it is possible to improve the optical properties by including an intermediate layer (a third intermediate layer in Example 11 and a second intermediate layer in Example 12). They are the structures #11 b and #12b, respectively. They also show other multiple layer structures (#11c, #12c) which, without the presence of the second intermediate layer, has virtually the same optical properties. Also in these cases the structures #11c and #12c fulfil an equivalence relation between the physical thicknesses and the optical thicknesses of the triplet in the structures #11b and #12b and the corresponding doublets in structures #11c and #12c.

	#11a	#11b	#11c
SiO2	85.0 nm	85.0 nm	85.0 nm
TiO2	95.9 nm	95.9 nm	102.0 nm
Al2O3	0.0 nm	40.7 nm	0.0 nm
SiO2	127.0 nm	127.0 nm	170.7 nm
TiO2	124.3 nm	124.3 nm	124.3 nm
Base	Polymer nD = 1.6	Polymer nD = 1.6	Polymer nD = 1.6
RV 15°	3.0%	0.7%	0.6%
RV 60°	11.3%	4.5%	4.8%
T IR-A	76.0%	73.6%	72.2%
Total thickness	432.2 nm	472.9 nm	481.9 nm
Thickness of the	222.9 nm	263.6 nm	272.6 nm
central triplet
Optical thickness	377.7 nm	444.3 nm	452.9 nm
of the central triplet

FIG. 13 shows a graph showing the reflection (in %) according to the wave length (λ, in nm) of the incident radiation for each one of the three cases in Example 11.

	#12a	#12b	#12c
SiO2	78.5 nm	78.5 nm	78.5 nm
TiO2	112.1 nm	112.1 nm	112.1 nm
SiO2	127.0 nm	127.0 nm	160.4 nm
Al2O3	0.0 nm	41.2 nm	0.0 nm
TiO2	111.3 nm	111.3 nm	122.1 nm
Base	Polymer nD = 1.6	Polymer nD = 1.6	Polymer nD = 1.6
RV 15°	3.7%	1.0%	1.1%
RV 60°	10.0%	4.5%	4.7%
T IR-A	75.1%	72.9%	71.8%
Total thickness	428.9 nm	470.1 nm	473.1 nm
Thickness of the triplet in	238.3 nm	279.4 nm	282.4 nm
contact with the base
Optical thickness of the triplet	409.0 nm	476.5 nm	478.9 nm
in contact with the base

FIG. 14 shows a graph showing the reflection (in %) according to the wave length (λ, in nm) of the incident radiation for each one of the three cases in Example 12.

Example 13: Triplet and Doublet High Index Refraction Layers, without Interphase and with Residual Reflex Concentrated in the Green Colour

• • The interphase between the base and the first high refraction index layer has a thickness of 0 nm, i.e., there is not an interphase layer
  • The first high refraction index layer is a triplet formed by 41.8 nm ZrO₂+92.7 nm TiO₂+28.8 nm ZrO₂ (total 162.9 nm), in this order, starting from the base
  • The second low refraction index layer is formed by 153.4 nm of SiO₂
  • The third high refraction index layer is a doublet formed by 15.0 nm ZrO₂+105.1 nm TiO₂
  • The fourth layer is formed by 78.8 nm of SiO₂.

The base has a refraction index of 1.6

Capa 4       SiO2-78.8 nm
Capa 3A-2    TiO2-105.1 nm
Capa 3A-1    ZrO2-15.0 nm
Capa 2B      SiO2-153.4 nm
Capa 1A-3    ZrO2-28.4 nm
Capa 1A-2    TiO2-92.7 nm
Capa 1A-1    ZrO2-41.8 nm
Base         Polimero nD = 1.6
RV 15°       0.8%
RV 60°       4.6%
T IR-A       63.6%
Grosor total 515.1 nm

FIG. 15 shows a graph showing the reflection (in %) according to the wave length (λ, in nm) of the incident radiation.

Claims

1- Ophthalmic lens having a base of polymeric material with a coating having an interferential multiple layer structure, comprising: where between the interphase and the first high refraction index layer there is a first intermediate layer with a refraction index nD lower than 1.8 and with a thickness between 0 and 160 nm, where between the first high refraction index layer and the second low refraction index layer there is a second intermediate layer with a refraction index nD between 1.65 and 1.8 and with a thickness between 0 and 100 nm, where between the second low refraction index layer and the third high refraction index layer there is a third intermediate layer with a refraction index nD between 1.65 and 1.8 and with a thickness between 0 and 110 nm, where a total thickness of said multiple layer structure is at the most 600 nm, measured from a start of the interphase to an end of the fourth layer, and where, if there is none of said intermediate layers, the thickness of said first high refraction index layer is between 91 and 169 nm, preferably between 101 and 159 nm, the thickness of said second low refraction index layer is between 128 and 248 nm, preferably entre 138 and 240 nm, the thickness of said third high refraction index layer is between 73 and 159 nm, preferably between 83 and 147 nm, and the thickness of said fourth layer is between 40 and 138 nm, and, if there is one of said intermediate layers, it holds that: and/or and/or

an interphase, orientated towards the base, of a material from the group made up of SiOx, SiO2, Cr, Ni/Cr, SnO2, Al2O3, AlN, ZnO, SiO/Cr, SiOx/Al2O3, ITO, MoO3, with a thickness between 0 and 150 nm,

a first high refraction index layer, of a material from the group made up of oxides, nitrides or oxynitrides of Zr, Ti, Sb, In, Sn, Ta, Nb, Hf and mixtures thereof, with a refraction index nD higher than 1.8,

a second low refraction index layer, of a material from the group made up of SiO2, MgF2, Al2O3, LaF3 and mixtures thereof, with a refraction index nD lower than 1.65,

a third high refraction index layer of a material from the group made up of oxides, nitrides or oxynitrides of Zr, Ti, Sb, In, Sn, Ta, Nb, Hf and mixtures thereof, with a refraction index nD higher than 1.8,

a fourth layer, of a material from the group made up of SiO2, MgF2, Al2O3, LaF3 and mixtures thereof, with a refraction index nD lower than 1.8,

the doublet made up of the first high refraction index layer and the second low refraction index layer that fulfil said thicknesses is replaced by a triplet made up of a first intermediate layer, a first high refraction index layer and a second low refraction index layer such that the thickness of said triplet differs from the thickness of said doublet by less than 5%, and such that the optical thickness of said triplet differs from the optical thickness of said doublet by less than 5%,

the doublet made up of the first high refraction index layer and the second low refraction index layer which fulfil said thicknesses is replaced by a triplet made up of a first high refraction index layer, a second intermediate layer and a second low refraction index layer such that the thickness of said triplet differs from the thickness of said doublet by less than 5%, and such that the optical thickness of said triplet differs from the optical thickness of said doublet by less than 5%,

the doublet made up of the second low refraction index layer and the third high refraction index layer which fulfil said thicknesses is replaced by a triplet made up of a second low refraction index layer, a third intermediate layer and a third high refraction index layer such that the thickness of said triplet differs from the thickness of said doublet by less than 5%, and such that the optical thickness of said triplet differs from the optical thickness of said doublet by less than 5%.

2- Lens according to claim 1, wherein, if there is none of said intermediate layers, a thickness x of said first high refraction index layer, a thickness y of said second low refraction index layer, a thickness z of said third high refraction index layer and a thickness t of said fourth layer fulfil the following relation: ( xyzt ) - ( 129.5 188.3 116.0 89.0 ) · A · ( x - 129.5 y - 188.3 z - 166.0 t - 89.0 ) ≤ 1 where A = ( 8.29 · 10 4 - 1.76 · 10 - 4 - 1.18 · 10 - 4 1.50 · 10 - 4 - 1.76 · 10 - 4 3.34 · 10 - 4 - 1.80 · 10 - 5 - 3.50 · 10 - 5 - 1.18 · 10 - 4 - 1.80 · 10 - 5 7.16 · 10 - 4 - 2.60 · 10 - 4 1.50 · 10 - 4 - 3.50 · 10 - 5 - 2.60 · 10 - 4 5.34 · 10 - 4 )

and, if there is one of said intermediate layers, it holds that: the doublet made up of the first high refraction index layer and the second low refraction index layer that that fulfil said relation is replaced by a triplet made up of a first intermediate layer, a first high refraction index layer and a second low refraction index layer such that the thickness of said triplet differs from the thickness of said doublet by less than 5%, and such that the optical thickness of said triplet differs from the optical thickness of said doublet by less than 5%,

and/or the doublet made up of the first high refraction index layer and the second low refraction index layer which fulfil said relation is replaced by a triplet made up of a first high refraction index layer, a second intermediate layer and a second low refraction index layer such that the thickness of said triplet differs from the thickness of said doublet by less than 5%, and such that the optical thickness of said triplet differs from the optical thickness of said doublet by less than 5%,

and/or the doublet made up of the second low refraction index layer and the third high refraction index layer which fulfil said relation is replaced by a triplet made up of a second low refraction index layer, a third intermediate layer and a third high refraction index layer such that the thickness of said triplet differs from the thickness of said doublet by less than 5%, and such that the optical thickness of said triplet differs from the optical thickness of said doublet by less than 5%.

3- Lens according to claim 1, wherein a thickness x of said first high refraction index layer, a thickness y of said second low refraction layer, a thickness z of said third high refraction index layer and a thickness t of said fourth layer fulfil the following relation: ( xyzt ) - ( 129.7 189.7 114.2 87.2 ) · A · ( x - 129.7 y - 189.7 z - 114.2 t - 87.2 ) ≤ 1 where A = ( 1.53 · 10 - 3 - 3.41 · 10 - 4 - 1.35 · 10 - 4 8.99 · 10 - 5 - 3.41 · 10 - 4 4.82 - 4 - 1.86 · 10 - 5 9.77 · 10 - 6 - 1.35 · 10 - 4 - 1.86 · 10 - 5 1.12 · 10 - 3 - 2.53 · 10 - 4 8.99 · 10 - 5 9.77 · 10 - 5 - 2.53 · 10 - 4 8.44 · 10 - 4 )

4- Lens according to claim 1, wherein a simulation of the reflection and transmission curves of said multiple layer structure has the following characteristics: T IR - A = ∑ λ ∈ A   T  ( λ ) 14 where   A = { 780, 800, 850, 900, 950, 1000, 1050, 1100, 1150, 1200, 1250, 1300, 1350, 1400 }

a visible reflection Rvis by a light incidence angle of 15° lower than 2.5%; calculated as an average of the reflection value in the range 380-780 nm, weighted by the efficiency spectrum of spectral light for day light and by the spectral distribution of the illuminant D65, according to Spanish standard UNI-EN ISO 13666:1998,

a visible reflection Rvis by a light incidence angle of 60° lower than 5.0% calculated as in the case above, and

a transmission value in the infra-red A TIR-A lower than 76%; calculated as an average transmission value in the range 780-1400 nm according to the following formula:

5- Lens according to claim 1, wherein a simulation of reflection and transmission curves of said multiple layer structure has a blue light transmittance value Tazul lower than 95%; calculated as an average transmission value in the range 410-460 nm according to the following formula: T azul = ∑ λ ∈ B   T  ( λ ) 6 where   B = { 410, 420, 430, 440, 450, 460 }

6- Lens according to claim 1, wherein between said multiple layer structure and said base there is an anti-scratching lacquer layer.

7- Lens according to claim 1, wherein the multiple layer structure is both on an inner surface and on an outer surface of the lens.

8- Lens according to claim 1, wherein at least one of said first high refraction index layer or said third high refraction index layer have a refraction index nD higher than 1.95.

9- Lens according to claim 1, wherein said second low refraction index layer has a refraction index nD lower than 1.5.

10- Lens according to claim 1, wherein said fourth layer has a refraction index nD lower than 1.65.

11- Lens according to claim 10, wherein said fourth layer has a refraction index nD between 1.4 and 1.6 and a thickness between 50 and 124 nm.

12- Lens according to claim 1, wherein said first intermediate layer has a thickness between 0 and 25 nm.

13- Lens according to claim 1, wherein at least one of said first high refraction index layer or said third high refraction index layer is made up of two high refraction index sub-layers.

14- Lens according to claim 1, wherein at least one of said second low refraction index layer or said fourth layer is made up of two low refraction index sub-layers.

15- Lens according to claim 1, wherein on said fourth layer there is a hydrophobic outer layer.

16- Lens according to claim 1, wherein:

the interphase has a thickness between 15 and 45 nm,

the first high refraction index layer has a thickness between 123 and 145 nm,

the second low refraction index layer has a thickness between 170 and 217 nm, preferably of SiO2,

the third high refraction index layer, divided into a first sub-layer with a thickness between 59 and 67 nm, and a second sub-layer with a thickness between 50 and 74 nm, and

the fourth layer with a thickness between 44 and 68 nm.