DE3516568A1 - Process for colouring spectacle glasses made from plastic by means of organic dyes - Google Patents

Abstract

Published without abstract.

Description

description

The invention relates to a method for coloring spectacle lenses Made of plastic with organic and, in particular, photochromic dyes.

A wide variety of methods have already been proposed with which organic and especially photochromic dyes in eyeglass lenses Plastic material can be introduced.

For example, it is known from US Pat. No. 4,342,668, the photochromic Substance, such as spirooxazine, in the material that makes up the lens is prepared to mix before its polymerization.

This incorporation of the dye and especially the photochromic Material in the "matrix" of the spectacle lens has a number of disadvantages: When it is introduced a photochromic substance in the matrix, the color of the lens depends on the thickness. In addition, sensitive dyes are used in the polymerization of the base material the lens damaged; this is done, for example, by the peroxides used or UV-initiated radical formers, etc. and impaired, for example, in the case of spirooxazines the photochromic effect considerably.

In order to avoid the thickness-dependent coloring, is therefore already in US Pat. No. 4,342,668, from the material from which the The lens consists of applying a thin film to the lens. This method eliminated Although the thickness-dependent coloring, the disadvantages that continue due to the necessary polymerisation of the film, but persist.

In addition, this process can be used for spectacle lenses made of diethylene glycol bis-allyl carbonate, a material often used for spectacle lenses at the moment, not in practice use.

Another known method of coloring eyeglass lenses Dip dyeing is made of plastic with organic dyes. For this purpose, the Dye suspended or partially dissolved in a carrier liquid and the spectacle lens immersed in the carrier liquid. This procedure is used by default for coloring used in eyeglass lenses with non-photochromic organic dyes. For This process is photochromic dyes, for example in US Pat. No. 4,043,637 suggested. According to this document, the bath in which the to be colored Eyeglass lenses are immersed to temperatures between about 25 "C and 150 0c heated so that the photochromic dye dissolved in the bath liquid is immersed in the Lens diffused.

This method has the advantage that - regardless of the Thickness of the lens - a uniform coloring results, as the dye only approx. 1 to 10 µm diffused into the plastic material of the spectacle lens.

In particular for the introduction of photochromic dyes this has known dip dyeing process, however, the disadvantage that the use of material expensive photochromic dyes is comparatively high, so that sufficient Diffusion can be achieved: Typical figures for the coloring of spectacle lenses with photochromic dyes are for example: In a bath with a volume of 2 liters, in the 5 % By weight dye is dissolved, 5-6 batches can be used of 10 glasses can be colored. In addition, the lens is in the immersion bath colored on both sides, unless one is a laborious process Side is covered. This has the disadvantage of coloring so-called blanks, that the side that will be processed later in the recipe grinding shop is also colored is lost, and the dye introduced into this side of the lens is lost goes. Above all, however, blanks and finished glasses need to be in different bathrooms be colored so that a matching color impression is achieved. When coloring In different bathrooms, however, it is very time-consuming to find a completely matching one To achieve color impression or the same coloring (kinetics). The reason for this is that the coloring in the immersion bath because of loss of dye, aging of the dye or short service life of the baths is difficult to reproduce.

Further methods of coloring plastic ophthalmic lenses with photochromic dyes are known from US Pat. No. 4,286,957 and EU Pat. No. 3,191. In one of the processes described in these documents, the photochromic Substance taken up by an intermediate carrier made of filter or kraft paper. The paper is placed on the surface to be colored and, using a heating tool, whose shape is adapted to the shape of the surface to be colored, to such a high Temperatures heated so that the photochromic substance sublimates.

The sublimated photochromic substance is then absorbed by the lens, This known method also has a number of disadvantages: In order to sublimate to achieve the photochromic substance, this must be very high Temperatures, i.e. to 200 "C or more. This allows photochromic Dyes and especially spirooxazines can be damaged considerably. Furthermore a separate heating tool is required for each special surface, its The shape of the lens surface to be colored is adapted. This means that under Many different heating tools may have to be provided.

Above all, however, this process very often leads to an uneven process Coloring, because even with a precisely adapted heating tool there is a more uneven surface over the surface Contact or effectively effective pressure can hardly be avoided.

The other one proposed in US Pat. No. 4,286,957 and EU Pat. No. 3,191 In the process, the photochromic substance is dissolved in a solvent and then dissolved in Condition applied to the surface to be colored. After the solvent has evaporated the pure photochromic substance remains on the surface. Then will the photochromic substance adjacent heating tool is heated to such an extent that the photochromic Substance is partially converted into the gas phase, so that the organic material the lens can absorb the photochromic substance.

This known method also has the disadvantage that the coloring can be uneven. The reason for this is that the photochromic substance after does not remain as a thin film on the surface after the solvent has evaporated, but that a multitude of small crystals forms, more or less are regularly distributed over the area to be colored.

The invention is based on the object of a method for coloring of plastic eyeglass lenses with an organic dye and in particular to indicate with a photochromic dye that uses little dye and even coloring of an or without the use of special heating tools results in both surfaces of the spectacle lens.

This object is achieved according to the invention by the in the characterizing part of claim 1 specified process steps solved. Further training of the Invention are specified in the subclaims.

According to the invention, the dyes to be introduced into the spectacle lens, for example organic photochromic substances, or a mixture of photochromic substances Dyes with non-photochromic dyes mixed in a varnish that has the property has that it practically does not get into the plastic even at the maximum process temperature diffused, from which the spectacle lens consists. This varnish with the mixed in Dye is applied to one or both sides of the lens and for example according to claim 2 air-dried. Of course, the drying can also be at a higher Temperature which, however, is below the temperature of the subsequent heat treatment, take place.

After the lacquer has dried, the lens with the one on it is removed Lacquer layer in which the dyes are homogeneously distributed, a heat treatment subjected.

This heat treatment causes the dyes to diffuse out of the lacquer layer into the plastic glass.

The thermodynamic properties of the solid solution lacquer / photochromer This is because the thermodynamic properties essentially do not make dyes of the dye, but rather by that of the lacquer, since it contains the dye in Concentrations of approx. 10 - 20% based on the paint after the solvent has evaporated is resolved. Since the lacquer neither melts nor sublimates under the process conditions, such processes do not occur in the overall system either. Since no Phase transitions, such as those that occur in sublimation processes, but rather only solid-state diffusion processes from the close to the organic material the lacquer layer adjacent to the lens take place in the lens, i.e. from one solid solution into another solid solution, the homogeneous distribution, des The dye in the lacquer layer is retained even after the diffusion process.

After the end of the heat treatment, the one on the lens Paint layer removed, for example washed off with a solvent according to claim 7. Of course, the lacquer layer can also be removed in other ways.

The method according to the invention has a number of advantages: Process is not only suitable for introducing a dye into a plastic glass, but also to introduce a mixture of different dyes.

In this way, for example, a plastic glass can be produced in one work step colored photochromically and non-photochromically.

The method according to the invention can not only be used with everyone today materials used for plastic glasses, such as diethylene glycol bis allyl carbonate, Use polycarbonate or polymethacrylate, but also with organic materials with a high refractive index, as they are currently available on the market.

The material use of dye is comparatively low, since only a lacquer layer that is a few to a few µm thick with the dye mixed in, must be applied to the lens. The lacquer layer with what is still contained in it Furthermore, the dye can be reused after it has been removed from the spectacle lens; for this purpose, the lacquer layer only has to be dissolved in a solvent and, if necessary, the Dye concentration can be readjusted.

If the heat treatment is carried out at an increased pressure, the The duration of the heat treatment is essential, for example from 5 hours to 1 hour be shortened.

This dependence on the duration of the heat treatment, which for a certain coloring effect is required also shows that the dye is in the organic Material of the spectacle lens by means of a diffusion process and not for example is introduced by means of a sublimation process.

The heat treatment at an increased pressure also has the further advantage that this enables intensive coloring to be achieved, which are often unreachable otherwise.

The heat treatment according to claim 4 in an inert gas atmosphere running, can also use sensitive dyes, which at elevated temperature easily are oxidatively damaged, can be used for coloring.

The inventive method comes with comparatively low Temperatures between 100 "C and 1500C, because the dye not only does not sublime should be, but a sublimation of the dye even avoided in any case shall be. Therefore, sensitive dyes are also used when they are introduced into the Glass not damaged, like that that the photochromic effect also after has a long service life after being introduced into the spectacle lens.

To carry out the process according to the invention, the paint must be different have special properties: It must adhere well to the plastic material and have a similar thermal expansion as the plastic material, so that he himself even at elevated temperatures at which the heat treatment is carried out, does not partially peel off.

In addition, it must have very little or no tendency to diffuse into the plastic itself.

Furthermore, it must be easily removable after the heat treatment.

Suitable paints are, for example, cellulose propionate dissolved in methylene chloride, Cellulose acetate and / or cellulose butyrate.

The lacquer can be applied to the plastic spectacle lens in the usual way can be applied, for example, the spectacle lens in a filled with the lacquer Bath to be immersed.

However, it is particularly advantageous with regard to the use of material to spray the lacquer onto the lens. With the spraying process using masks Partial application of the lacquer to the spectacle lens is also possible, so that the glass can be colored in patterns etc. This enables fashionable effects, which cannot be produced in any other way without additional effort.

By an increased addition of customary plasticizers according to claim 9 it can be achieved that the lacquer layer also on protruding edges of the spectacle lens etc., as they can occur with bifocal glasses, fits tightly, so that also with difficult surface designs in any case even Coloring is achieved.

The inventive method also allows, in contrast to the known process also includes the production of gradually tinted spectacle lenses made of plastic: For the production of a gradually tinted spectacle lens, i. a spectacle lens with the photochromic or non-photochromic in the upper part Coloring is stronger than in the lower part, for example, first in the upper part Part of a layer of varnish with dye contained in it can be applied. To this A second layer of varnish is applied, which does not contain any dye. A third layer of varnish is then applied to this dye-free layer, which in turn Contains dye, for example applied in such a way that they are essentially located above the lower part of the lens and the first layer of lacquer only in overlaps a certain area.

In a certain period of time diffuses out of the third dye layer less dye into the lens than from the one directly on the lens Dye layer, so that a gradual flow can be achieved with this method leaves.

Another possibility to achieve a gradual progression is the dye after it has been introduced into the spectacle lens with a solvent, for example Partly "washed out" again with methylene chloride. The colored spectacle lens is used for this purpose at least partially immersed in a solvent bath according to a special time program and removed from this bath again.

Of course, it is also possible to create a gradual progression through variation the thickness of the lacquer layer on the lens to achieve: Off thinner parts of the lacquer layer allow fewer dye molecules to enter the lens diffuse, since the "dye reservoir" is "exhausted" during the heat treatment.

The invention is explained below using an exemplary embodiment without Restriction of the generality described in more detail: First, a suitable paint mixture for example made by using cellulose propionate, e.g., "Bayer Cellidor Type 3406/11 "is dissolved in methylene chloride. The solution becomes a suitable plasticizer added in a comparatively high concentration.

This solution contains phototropic and / or non-phototropic dye Stirred in at a concentration of about 2% by weight.

The plastic glasses to be colored are made with this lacquer mixture by means of a spray gun painted in such a way that the film layer after drying in room air (about 1 minute) has a thickness of 3 to 50 µm. The concentration of the dye based on the paint after evaporation of the solvent is typically between 10 and 20% by weight.

The glasses are placed in an autoclave, which is evacuated several times and filled with nitrogen. During the last filling there is an overpressure of 5 bar nitrogen adjusted. The autoclave is running at a heating rate heated from 3 "C / min to 135" C and held this temperature for about 90 minutes. then the heating is switched off so that the glasses can cool down.

After removing the glasses from the autoclave, the adherent Washed off paint residue with methylene chloride.

The glasses can be phototropic and non-phototropic in one operation, i.e. are permanently colored and are for example without further pretreatment for tempering treatments with anti-reflective, anti-fog and / or anti-scratch coatings usable.

Claims (11)

Process for coloring plastic eyeglass lenses with Organic dyes Patent claims 1. A method for coloring plastic ophthalmic lenses with organic dyes, characterized by the combination of the following features: - the dye is mixed into a varnish that practically does not diffuse into the plastic even at the maximum process temperature, - the varnish is applied to one or both sides of the spectacle lens, - the spectacle lens with the dried lacquer is subjected to a heat treatment in which the dye diffuses from the lacquer layer into the plastic, and - after the end of the heat treatment, the lacquer layer is removed. 2. The method according to claim 1, characterized in that the paint is air dried after application. 3. The method according to claim 1 or 2, characterized in that the Heat treatment is carried out at an elevated pressure. 4. The method according to any one of claims 1 to 3, characterized in that that the heat treatment is carried out in an inert gas atmosphere. 5. The method according to any one of claims 1 to 4, characterized in, that the heat treatment takes place at temperatures between 100 ° C and 150 ° C. 6. The method according to claim 5, characterized in that the Heat treatment extends over a period of between 1 and 5 hours. 7. The method according to any one of claims 1 to 6, characterized in, that the paint is washed off with a solvent after the heat treatment. 8. The method according to any one of claims 1 to 7, characterized in that that the paint consists of cellulose propionate, cellulose acetate, dissolved in methylene chloride and / or cellulose butyrate. 9. The method according to any one of claims 1 to 8, characterized in that that the paint conventional plasticizers are added in increased concentration. 10. The method according to any one of claims 1 to 9, characterized in that that for the production of a gradually tinted lens on part of the Spectacle lenses have a layer of lacquer with dye, and a second layer on top of this layer of lacquer Lacquer layer without dye, and on this lacquer layer at least partially a third Lacquer layer with dye is applied. 11. The method according to any one of claims 1 to 9, characterized in, that for the production of a gradually tinted spectacle lens the dye after Removal of the lacquer layer, at least partially washed out with a solvent will. 1 2. The method according to claim 11, characterized in that the washing out takes place in an ultrasonic bath.