PHOTOCHROMIC GLASS AND LENS
FIELD OF THE INVENTION
Fixed tint, photochromic glasses, and sunglass lenses produced from such glasses
BACKGROUND OF THE INVENTION
Photochromic glasses characteristically darken under the influence of short wavelength radiation, and fade when the radiation source is removed Such glasses have become well-known since their disclosure in United States Patent No 3,208,860 (Armistead et al )
Initially, the active photochromic ingredient was crystals of a silver halide, other than the fluoride Subsequently, glasses containing copper and cadmium halides were found to be photochromic, but the silver halide glasses have remained the commercial choice
Continuing efforts were made to improve the early glasses with respect to both their photochromic properties and their other properties necessary for ophthalmic use These efforts led to United States Patent No 4,190,451
(Hares et al ) This patent discloses an R2O-AI2O3-B2O3-Sι02 base glass containing, as essential constituents for photochromism, Ag 0 15-0 3%, 0 1 - 0 25% Cl, 0 1-0 2% Br and 0 004-0 02% CuO by weight The patent also discloses the possibility of adding up to one percent transition
metal oxides, such as CoO, NiO and Cr2O3, and up to five percent rare earth metal oxides, such as Er2O3, as glass colorants
A composition for a commercial, photochromic sunglass was developed on the basis of the Hares et al patent teachings This glass has a base glass composition, as calculated in parts by weight from the glass batch, of
SiO2 56 46 Na2O 4 08
AI2O3 6 19 K2O 5 72
B2O3 18 15 ZrO2 4 99
Li2O 1 81 TiO2 2 09
The glass contains photochromic elements as follows
Ag 0 252
Cl 0 195
Br 0 155
CuO 0 006
The glass also has 0 122% NiO and 0 017% Co3O4 added to impart a fixed tint This glass, as melted, has a faded transmittance of 70% When fired in hydrogen, the faded transmittance of the glass is reduced to 45 +/- 2% However a lens having an even lower faded transmittance after hydrogen treatment was found to be desirable
This could be achieved by a more extended hydrogen treatment in terms of time and/or temperature However such extended treatment resulted in a color shift that created a very undesirable cosmetic appearance Also after UV darkening, as by sunlight, a sunglass lens failed to meet the ISO/ANSI sunglass requirements
To achieve the desired transmittance with acceptable color, it became necessary to apply a combination of coatings including a neutral density, durable thin film coating This expedient effectively provided a faded transmittance of about 26% and a UV-darkened transmittance of about 12% at 25° C However, the extra processing added considerable cost to the lens
The present invention is predicated on discovery that the need for a coating can be avoided by modifying and controlling the amounts of the colorant oxide The resulting lens, in a standard 2 0 +/- 0 1 mm thickness satisfies the ISO/ANSI requirements, as well as other ophthalmic requirements These include a refractive index of about 1 53, an ability to be chemically strengthened to meet the FDA ball-drop test and a cosmetically acceptable appearance
It is then a basic purpose of the present invention to produce an improved, darker sunglass lens Another purpose is to provide a fixed tint, photochromic glass from which such lens can be produced
A further purpose is to provide a sunglass lens that possesses the properties of a coated lens while avoiding the costly coating procedure
Another purpose is to provide a fixed tint, photochromic glass lens that has an acceptable color and diminished transmission in the undarkened state, but still satisfies ISO/ANSI sunglass requirements when darkened
A still further purpose is to accomplish the forgoing purposes while modifying only the colorants in a commercial glass
SUMMARY OF THE INVENTION
The invention resides in an R2O-AI2O3-B2O3-SιO2 base glass containing silver chloride and bromide as photochromic constituents and 0 27-0 38% NiO and 0 035-0 060% Co3O4 as glass colorants with the ratio of NiO Co3O4 being at least 6 1 by weight
The invention further resides in an ophthalmic lens composed of such glass and having a refractive index of about 1 523 and a thickness of 1 6-2 0 +/- 0 1 mm
PRIOR ART
Patent literature known to Applicants and deemed of possible relevance is supplied separately
BRIEF DESCRIPTION OF THE DRAWINGS
The single FIGURE in the accompanying drawing is a graphical representation showing transmittance curves for a glass in accordance with the present invention before and after the glass is fired in a reducing atmosphere
DESCRIPTION OF THE INVENTION
The present invention arose from studies designed to obtain a darker, fixed tint, photochromic lens having a low transmittance in the faded state, but still meeting ISO/ANSI sunglass requirements when the lens is exposed to UV radiation As indicated, this could be achieved with a coating, but that involved added processing
We have now discovered that the desired lower transmittance in the hydrogen-fixed lens, can be achieved by modifying the relevant amounts of glass colorants employed to produce the fixed tint Thus, the R2O-AI2O3-B2O3- SιO2 base glass, including the photochromic constituents, remains unchanged from that heretofore commercially available This, of course, is desirable since schedules for glass strengthening can remain unchanged Also, no changes in glass melting procedures are required
The base glass, as calculated from the batch on an oxide basis, consists essentially of
SiO2 20-65% Na2O up to 9%
AI2O3 5-25% K2O up to 17%
B2O3 14-23% R2O 8-20%
Li2O up to 2 5% ZrO2 up to 6%
TiO2 up to 3%
In addition, the glass contains, as essential ingredients to impart photochromic properties, in weight %
Ag 0 15-0 3%
Cl 0 1 -0 25%
Br 0 1-0 2%
CuO 0 004-0 02%
The same glass colorants, NiO and Co3O4, are employed to produce the desired fixed tint Surprisingly, markedly changing the amounts of these colorants in the correct proportions is sufficient to achieve the desired color properties and photochromic characteristics in the glass
The amount of each colorant employed depends on the thickness of the glass The standard lens thickness is 2 0 +/- 0 1 mm For this lens, the glass will contain in percent by weight, 0 27-0 32% NiO and 0 035-0 050% Co3O4
Lenses for clip-on glasses are not required to meet the strength requirement of regular lenses Hence, their standard thickness is 1 6 +/- 0 1 mm For this thinner glass, the NiO content must be 0 32-0 38% and the Co3O4 content must be 0 040-0 060% To arrive at the desired color package, a series of color glass melts were made using the commercial photochromic glass composition shown earlier The two composition variables were the NiO and Co3O contents The criticality of the ranges specified can be seen from a comparison of 2 mm thick lenses a lens being pressed from each of the five melts shown in the TABLE below The TABLE reports analyzed contents for NiO and Co3O4 in weight percent, and the luminous transmittance (LT) values as calculated for each glass, the calculations made from measurements on the lenses after hydrogen treatment
TABLE I
NiO Co3O4 LT
1 019 0024 61
2 024 0031 55
3 029 0039 50
4 030 0046 46
5 036 0054 41
Visual testing indicated that lenses formed from glass melts 1 and 2 had initial transmittance values that were too high after hydrogen heat treatment Lenses molded from melts 3 and 4 in 2 mm thickness had a satisfactory transmittance and color after subsequent treatment For a 2 mm thick lens, the optimum colorant contents appear to be about 0 29-0 30% NiO and about
0 046% Co3O4 with the glass having a luminous transmittance value of about 47 +/- 2
The lens of melt 5 had a lower initial luminous transmittance than desired for a 2 mm thick lens, but the melt would be suitable for a 1 6 mm lens
A 1 6 mm lens would require larger contents of both colorants, primarily the Co3O4 constituent Thus, an optimum for this thickness lens was calculated to be about 0 35% NiO and 0 050% Co3O4
It will be appreciated that the final color properties are obtained by heat treating a lens in a reducing atmosphere A virtue of the present invention is that the standard treatment heretofore used is equally effective with the present glass This would be expected, since the photochromic constituents, particularly the silver, remain unchanged Silver is the constituent affected by the reducing treatment The standard treatment is heating in a pure hydrogen atmosphere for about 12-13 minutes at 385° C Any treatment providing an equivalent effect is contemplated Since equipment and other influences will vary, a treatment in the ranges of 350-400° C , and a period of 10-15 minutes should prove satisfactory It may be mecessary, under some circumstances, to use a diluted hydrogen atmosphere This will require a longer heat treatment up to about thirty minutes
Since the base glass composition remains unchanged, the lenses of the invention may be strengthened in known manner to meet FDA requirements Strengthening may be accomplished by chemical tempering in well known manner
Photochromic behavior will also be developed in the usual manner Thus, the glass, after forming, may be heat treated at about 651 ° C for forty minutes to precipitate in the glass the requisite silver halide crystals
A polished sample having a nominal thickness of 2 0 mm was prepared for comparison with a corresponding sample of the commercial glass referred to earlier The latter is the glass that gave rise to the present invention Both samples were fired in a 100% hydrogen atmosphere using the standard commercial cycle of 12-13 minutes at 385° C
TABLE II compares the transmission in percent of the present commercial glass lens M with a 2mm glass N of the present invention under various conditions of treatment The conditions are (1 ) the glass as formed (before H2), (2) after heat treatment in hydrogen (after H2) (3) with the neutral density coating (coated) and (4) after darkening with UV radiation (dark)
TABLE II
M N
Before H2 70 45
After H2 45 30
Coated 26 NA
Darkened 12 16
The single FIGURE in the accompanying drawing shows the spectral transmittance curves for the sample of the present glass The curve based on measurements on the sample before the hydrogen treatment is designated A The curve, as measured on the sample, after firing in hydrogen, is designated
B In the FIGURE, spectral wavelength is plotted on the horizontal axis and transmittance in percent is plotted on the vertical axis
Tπstimulus values X, Y and Z, were computed from the indicated measurements using a weighted ordinate method with the 1931 CIE Standard Observer and Illuminate C Chromaticity coordinates x and y, and luminous transmittance Y values, are given in TABLE III below Columns 1 and 2 show, respectively, the measurements made on an unfired and fired sample of the
standard commercial glass. Columns 3 and 4 show, respectively, the measurements made on an unfired and fired sample of the present new glass.
TABLE III
Parameter 1 2 3 4
X 0.3410 0.3815 0.3601 0.4100 y 0.3455 0.3392 0.3790 0.3625
Y 70.0 48.0 47.7 30.0