DE4110614A1 - Rugged lens e.g. for spectacles - has main body with diffractive focussing features on side covered with protective e.g. polysiloxane coating of lower refractive index - Google Patents

Abstract

A lens for the complete spectrum of visible light, and partic. one for use in spectacles, consists of a basic member of transparent material with diffractive features on at least one face to produce a focal length. This surface concerned has a smooth transparent protective coating on its outside, the refractive index of which is less than that of the main body of the lens. The coating is pref. based on polysiloxane or heateropolysiloxane; the prod. can have a glass or transparent plastic disc. The diffractive body (1) is in the shape of a flat disc of glass. On its inner and focussing side (2) it has the diffractive features in the form of recesses (4) to produce a phase grating. The width of these recesses decreases further from the optical axis (5) which passes through the focal point (3). Parallel rays of light (7) incident on the outer side (6) of the lens are bent inwards towards the focal pt. (3) on the edges (8) of the recesses. The figure portrays the effect with monochromatic light. ADVANTAGE - Suitable for rough usage.

Description

The invention relates to a lens according to the Oberbe handle of claim 1.

Diffractive optics, ie lenses whose optical Effect not about refraction, so refractive, but About diffraction, that is diffractive, are be already from Appl. Phys. Lett. 52 (21), 23 May 1988, Sci th 1771 to 1773 known. There is the mission such as a micro-optics trained optics for Laser light, ie for monochromatic light, be wrote.

From the German magazine "Der Augenoptiker 9/90", Sei 16 to 18 is the use of diffractive Lin sen known as contact lenses. These must be in Unlike the application for laser light the image non-color properties throughout the range be of visible light. An application suchi ger diffractive optics, as with a through  diameter of about 5 mm used as contact lenses be attached to the eye of the wearer protected be, for normal glasses or other lin sen in diameters ranging from 30 to 80 or be preferably 60 to 80 mm is not readily possible Lich.

The invention is based on the object lenses of generic type and in particular eyeglass lenses with at least one surface with a diffrak create a structure that is robust Operation are suitable.

This object is achieved by the Merk Male solved in the characterizing part of claim 1. Through the protective layer are the most sensitive diffractive structures, namely in the corre sponding etched surface or by means of a laser covered phase lattice covered and thus against mechanical wear, contamination and the like protected. The smooth outward protection Layer can be easily cleaned.

Diffraction phenomena are usually very wel lenlängenabhängig; this fact plays with users applications in the laser sector are irrelevant, as mo is worked on a supromatic light. For lenses for the entire spectral region and in particular at Spectacle lenses are used to generate a diffraction grids with variable lattice structures Distance on the corresponding surface of the ground body applied. These grids will be redone  refined with substructures through which both unwanted stray light should be avoided as also the necessary especially for eyeglass lenses Achromasie, ie color neutrality, is achieved. The The size and shape of these structures then cause the desired optical imaging properties, so so that a lens with any focal length, but the thickness and weight of a plan or Null glass arises.

To achieve a high diffractive effect is the development according to claim 2 of large ago part. Claims 3 and 4 each give glass or plastic as material of the body before applied refractive index ranges to those in practice correspond to available materials.

It is particularly advantageous according to claim 5 a Cover disc to use as a protective layer whose preferred, the lowest possible refractive index ranges in Claim 6 are given. Kitte according to claim 7 are available in practice.

Alternatively to a cover plate as a protective layer May use a plastic paint according to claim 8 be, d. H. the protective layer is by Lackauf on the provided with diffractive structures Surface generated. Paints available in practice with advantageous properties arise from An award 9. If it is a spectacle lens, then the development according to claim 10 of be special advantage.  

As the number of necessary diffractive struk with increasing diameter and with increasing the dioptric effect, d. H. with decreasing Focal length, and thus increases the size of the Structures decreases, resulting in increased Fertigungsauf wall, it may be useful, as per claim 11 a part of the dioptric effect or To produce focal length via refraction. In a sol In this case, a hybrid system will be created; H. the Base body has a conventional lens shape with conventional breaking properties. Especially at In such a hybrid system, the influence of the Dispersion are largely neutralized and thus the Achromasie be achieved. Under dispersion one understands the material property of all transpa pensions materials, different focal lengths for To have light of different wavelengths. This Dispersion effect is in the refraction and in the Diffraction in each case reversed, so that the overlay these effects to an approximate mutual Suspension can result.

Other features, details and benefits of He The following will be made with reference to some Zeichnun described. It shows

Fig. 1 is a schematic diagram of a diffractive Abbil dung,

Fig. 2 shows a partial section of a phase grating for non-monochromatic light,

Fig. 3 shows the focal point changes in a hybrid lens, which is provided with a protective layer of synthetic material paint and

Fig. 4 is a hybrid lens with a cover plate as a protective layer.

Fig. 1 shows a base body 1 in the form of a ebe nen disc, a so-called face plate, made of glass and indeed of high refractive index glass. On the inner side 2 , that is, the focal point 3 facing side of the base body 1 , diffractive structures 4 are formed in the form of recesses. It is a phase grating. As is apparent from FIG. 1, the width of the diffractive structures, ie, the width of the individual recesses, decreases with increasing distance from the optical axis 5 passing through the focal point 3 to the outside.

On the outside 6 of the base body 1 is incident on parallel light beams 7 existing light, which is bent at the edges 8 of the diffractive structures 4 such that it is focused to the focal point 3 out. The illustration in FIG. 1 applies to monochromatic light.

In the illustration in Fig. 2 are made of the Grundkör per 1 diffractive structures 4 enlarged herausge records, each single diffractive structure 4 has a number of diffractive fine structure 9, which, for a corresponding flexion of the non-single chromatic light, thus for example by visual Barem light necessary.

For clarity, in Figs. 1 and 2 no protective layer is shown in the drawing.

Fig. 3 shows a so-called hybrid lens, ie a lens with a base 1 ', which is ausgebil det in the form of a classic lens with refractive effect. There are on its outer side 6 'incident light beams 7 shown in their course exclusively on the basis of the refractive action of the body 1 . Here, therefore, the light would be focused on a focal point 10 . Due to the additional diffractive effect due to diffractive Struktu ren 4 on the inside 2 'of the base body 1 ', a focal point 11 , whose focal length is significantly lower than that of the fictitious focal point 10th The not visible in Fig. 3 dif diffractive structures 4 and diffractive fine structures 9 supporting inner side 2 'of the base body 1 ' is coated with a protective layer 12 of plastic paint to protect the diffractive structures. It is a plastic paint preferably based on polysiloxane or heteropolysiloxane.

In Fig. 4, in turn, a hybrid lens is shown as shown in Fig. 3, in which on the inside 2 'of the base body 1 ' in this case, a protective layer of a curved cover plate 13 is attached, which is itself optically neutral, ie constant thickness even though it is curved. In particular, the cover plate 13 is also a same curve design as the associated Oberflä surface, so the inside 2 'of the body 1 ' have on. The cover plate 13 is glued with a putty 14 on the inside 2 'of the base body 1 ', wherein the not visible in Fig. 4 diffraction structures 4 and 9 are completely filled by the putty 14 . The putty 14 and the cover plate 13 have identical refractive indices. Between the Mate rial of the base body 1 'on the one hand and the mate rials of the protective layer 12 and the cover layer 13 with putty 14 is the largest possible refractive index jump, ie the largest possible Brechzahldiffe, exist. The outer side 15 of the protective layer 12 and the outer side 15 'of the cover plate 13 are completely smooth.

The design of the lens and in particular of the spectacle lens with diffractive structures leads to a significant reduction in thickness and thus a significant weight reduction of the base body 1 , 1 ', which is particularly important for spectacle lenses. Table 1 below shows the weight savings and Table 2 shows the corresponding thickness reduction using the example of spectacle lenses. Similar weight and thickness savings can be achieved for any other lens shape who the. For the glasses compared, the following applies:

Glass 1 Conventional, exclusively refractive spectacle lens made of spectacle grain with a refractive index n _e = 1.523 Glass 2 Spectacle lens of high refractive index material with a refractive index n _e = 1.706 exclusively diffractive with a cover plate of spectacle crown with a refractive index n _e = 1.523 Glass 3 Hybrid lens, consisting of a refractive base of high refractive index material with a refractive index n _e = 1.706 and an optical power of 3.00 diopters, residual effect via diffractive optics, cover plate of spectacle crown with a refractive index n _e = 1.523 saving Percent difference between glass 3 and glass 1.

In a comparison of glass 2 with glass 1 result even higher weight and thickness reductions.  

Table 1

weight savings

Table 2

Thickness reduction (center thickness)

For spherical lenses, the diffractive struk in the form of concentric with the optical axis formed running rings. At Toric Lin The diffractive structures are in shape of ellipses. Toric lenses are also eliminated the different when refractive lenses Edge thickness.

The diffractive structures shown in FIGS . 1 and 2 for a plane-parallel base body 1 can also be applied to conventional bent-through lenses in spectacle optics which have no refractory effect.

Serve for producing the diffractive structures the usual etching methods using a mask. the same However, the diffractive structures can also be measured by means of a laser, in particular an excimer sers, written in the appropriate surface become. An excimer laser is a UV laser operating at low wavelength tet, so can write very fine structures.

Claims (13)

1. Lens for the entire spectral range of visible light Baren, in particular spectacle lens, consisting of a base body ( 1 , 1 ') of translucent material having a refractive index (n _e ) on at least one surface ( 2 , 2 ') with diffractive structures ( 4 , 9 ) is provided for generating a focal length, characterized in that the diffractive structures ( 4 , 9 ) provided with surface ( 2 , 2 ') with a on its outside ( 15 , 15 ') smooth protective layer ( 12 , 13 ) is made of translucent material whose refractive index (n _e ) is smaller than the refractive power (n _e ) of the material of the base body ( 1 , 1 '). 2. Lens according to claim 1, characterized in that the base body ( 1 , 1 ') consists of high-refracting Ma material. 3. Lens according to claim 1 or 2, characterized in that the base body ( 1 , 1 ') made of glass having a refractive index in the range of n _e = 1.44 to 1.9, preferably n _e = 1.6 to 1 , 8 and in particular n _e = 1.7. 4. Lens according to claim 1 or 2, characterized in that the base body ( 1 , 1 ') made of plastic having a refractive index in the range of n _e = 1.498 to 1.7, preferably _e = 1.55 to 1.65 , 5. Lens according to one of claims 1 to 4, characterized in that a cover disc ( 13 ) is provided as a protective layer, which is connected to the base body ( 1 ') by means of a putty ( 14 ). 6. Lens according to claim 5, characterized in that the cover plate ( 13 ) has a refractive index in the range of n _e = 1.44 to 1.7, preferably n _e = 1.5 to 1.6 and in particular n _e = 1.523 , 7. Lens according to claim 5 or 6, characterized in that the putty ( 14 ) has the same refractive index (n _e ) as the cover plate ( 13 ). 8. Lens according to one of claims 1 to 4, characterized in that the protective layer ( 12 ) consists of a plastic paint. 9. Lens according to claim 8, characterized in that the protective layer ( 12 ) is formed of a plastic paint based on polysiloxane or heteropolysiloxane. 10. Lens according to one of claims 1 to 9, characterized in that the diffractive structures ( 4 , 9 ) and the protective layer ( 12 , 13 ) on the focal point ( 3 , 11 ) facing the inside ( 2 , 2 ') is are orders. 11. Lens according to one of claims 1 to 10, characterized in that the base body ( 1 ') formed refractive effect and on at least one upper surface ( 2 ') with a diffractive structure ( 4 , 9 ) is provided. 12. Lens according to one of claims 1 to 7 and 10, 11, characterized in that the cover plate ( 13 ) consists of glass. 13. Lens according to one of claims 1 to 7 and 10, 11, characterized in that the cover plate ( 13 ) consists of transparent plastic.