DE3130715A1 - Optical glass of high refractive index and low scattering - Google Patents

Abstract

The invention relates to an optical glass of high refractive index and low scattering based on a B2O3/La2O3/Yb2O3/F system which is free from the interfering substances thorium and cadmium and has the following composition, in % by weight: B2O3 20-37 La2O3 34-60 Yb2O3 1-32 F 0.1-7 SiO2 0-3 R2O 0-6 (R2O is one of or a combination of two or more of Li2O, Na2O and K2O) RO 0-18 (RO is one of or a combination of two or more of MgO, CaO, SiO, BaO and ZnO) Y2O3 0-23 ZrO2 0-11 Ta2O5 0-12 Nb2O5 0-5 PbO 0-6 WO3 0-10 Al2O3 0-4 TiO2 0-5 GeO2 0-16 Gd2O3 0-12 (The fluorine content indicates the level of substitution by oxygen if glass is 100%.)

Description

Optical glass with high refractive index and low scattering Description The invention relates to optical glass having a high refractive index and low scattering.

Well-known optical glass with a high refractive index and low scattering contained thorium oxide or cadmium oxide as a component in most cases, which gives the glass a high refractive index and low scattering characteristics borrows. Thorium has radioactive properties and is therefore like cadmium for the Harmful human body For this reason, the use of such substances should be avoided can be avoided in glass production. Instead of thorium and cadmium Ytterbium oxide is known as a component that gives glass a high index of refraction and gives a low scattering characteristic (see Japanese Patent Publication No. 25323/1978). However, this glass does not have sufficient stability for deglassing prevent and is therefore not suitable for production on an industrial scale suitable, the Abbe's number is still sufficiently large.

It is an object of the present invention to provide an optical glass with high refractive index and low scattering, based on a four-component system B203-La203-Yb203-F and which is free of thorium and cadmium and its refractive index (nd) ranges from 1.69 to 1.81 and its Abbe number is 45 to 59. The most important The principles of the invention have been outlined in order that the detailed description can be understood to make and show their worth. Additional features of the invention which follow hereinafter are described form the basis of the claims The basis of the present Revelation can easily be used as a starting point for various possibilities to carry out the individual intentions of the invention. It is therefore on it to point out that the claims also contain such equivalent statements, which do not deviate from the content and scope of the invention.

According to the invention it was found that the four-component system glass from B203-La203-Yb203-F, the composition of which will be explained later, has a high Has a refractive index and a remarkably low liquefaction temperature has compared to the well-known three-component system glasses and therefore amazing is stable against devitrification and is light and stable produced on an industrial scale can be. It has also been found that the four-component system glass is one high Refractive index and, moreover, a low scattering characteristic, namely has a large Abbe's number, which is not the case with glasses of the known composition is achieved and that, moreover, this glass can be produced easily and stably can. E.g.

a known glass has a refractive index of about 1.75 and a maximum Abbe's number of 53.4, while the glass according to the invention with the same Refractive index has an Abbe's number that goes up to 54.9. Furthermore has a well-known Glass has a refractive index of about 1.70 with an Abbe's number of maximum 55.8, while the Abbe's number of a glass according to the invention with the same refractive index up to 58.8.

It has also been found that the desired glass is more stable and lighter can be produced if the four-component system glass made of B2O3-La2O3-Yb2O3-F another component, such as SiO2, R20, (R20 is one or a combination of two or more of Li2O, Na2O, and K20), RO (RO is one or a combination of two or more of MgO, CaO, SrO, BaO and ZnO), Y2O3, ZrO2, Ta205, Nb2O5, PbO, Wo3, Al203, TiO2, GeO and Gd2O3).

The present invention relates to an optical glass having the following Composition: B203 20 - 37% by weight La203 34 - 60 Yb2O3 1 - 32 F 0.1 - 7 SiO2 0 - 3 R20 0- 6 (R20 is one or a combination of two or more of Li2O3, Na20 and K20) RO 0 - 18 (RO is one or a combination of two or more of MgO, CaO, SiO, BaO and ZnO)! 2 ° 3 0 - 23 ZrO2 0 - 11 Ta205 0 - 12 Nb205 0 - 5 PbO 0 - 6 WO3 0 - 10 Al203 0 - 4 TiO2 0 - 5 GeO2 0 ~ 16 Gd203 0 - 12 (The fluorine content indicates the level of substitution with oxygen, if Glass is 100%.) If the content of BS03 is less than 20%, the glass does not own sufficient stability against devitrification and if the content is higher than 37 O / o, then the refractive index is decreased and it cannot do the intended purpose be used. When the content of La 2 O 3 is less than 34%, the refractive index becomes and the glass is not suitable for this use: Exceeds the If the content is 60%, the stability against devitrification is reduced. Is the salary at Yb203 less than 1% or more than 32%, then the devitrification stability becomes decreased.

It reduces the stability against devitrification if the content of fluorine is less than 0.1% and more than 7%. SiO2 promotes stability against devitrification and chemical resistance; if the business stop however, is higher than 3%, it will remain unmelted in the melting process and undesirably prolong melting. R20 reduces the viscosity of the glass and thereby facilitates the formation of glass; if the content is more than 6 ° / 0 however, the stability against devitrification is reduced. RO improves stability against Devitrification; however, if the content exceeds 18%, the stability against Reduced deglassing. Y203 increases the Abbe's number of the glass and improves the Chemical resistance; however, if the content exceeds 23%, the stability becomes reduced against deglassing. ZrO2 increases the refractive index of the glass and the Chemical resistance; however, if the content is higher than 11%, the stability will decrease reduced against deglassing. Ta205 increases the refractive index of the glass, the stability against devitrification and chemical resistance; however, the salary is higher than 12%, the Abbe's number is reduced, and the glass becomes more suitable for use unusable.

Nu 203 increases the refractive index of the glass and the chemical resistance; if the content exceeds 5%, it is increasingly colored and thereby not more usable. PbO increases the refractive index of the glass; is the salary however higher than 6%, it will be colored and therefore no longer usable. W03 increases the Refractive index and the stability against devitrification; however, the salary is higher than 10%, it becomes increasingly colored and no longer usable. Al203 increases the chemical Resistance; however, if the content exceeds 4%, the refractive index is reduced, and the glass becomes unsuitable for the desired application. TiO2 increases the refractive index of the glass and chemical resistance; however, if the salary is higher than 5 010, it becomes colored and thus unusable. GeO2 increases the stability against devitrification; however, if the content is higher than 16%, the glass becomes unstable against devitrification.

Gd203 increases the refractive index and chemical resistance; is but if the content is higher than 12%, the glass becomes unstable to devitrification.

Glass with the following compositions outperforms the stability against devitrification the glasses according to the invention with the aforementioned Composition ranges: B203 24 - 37 wt% La2O2 35 - 50 Yb2O3 5 - 15 F 0.1 - 4.1 CaO 0 - 6 SrO 0 - 2 BaO 0 - 8 ZnO 0 - 8 Y203 0 - 11 ZrO2 0 - 7 Ta205 0 - 12 Nb 205 0-5 GeO2 0-16 Gd2O3 0-12 glass of the following composition is still better with regard to the stability against devitrification: B203 26 - 37 wt .-% La2O3 35 - 50 Yb2O3 9 - 15 F 0.1 - 2.5 SrO 0 - 2 BaO 0-3 ZnO 0-6 Y203 0 - 7 ZrO2 0 - 7 The glass according to the invention can be produced using an oxide, carbonate, Nitrate or fluoride can be produced as the raw material of each component.

The desired weight ratio is weighed out and the component is mixed carefully, put the mixture in a platinum crucible and heated in an electric Furnace to 1200 - 14000 C, stir and homogenize it after it has melted and is cleaned and then pour it into an iron mold The composition (in Weight percent), the refractive indices (nd) and Abbe's numbers (<d) of individual Embodiments of the optical glass are summarized in Table 1.

Table 1 1 2 3 4 5 6 7 8 9 10 11 Example no. B2O3 34.23 30.51 29.74 25.64 35.69 30.02 31.56 34.23 33.93 28.06 20.05 La2O3 41.32 49.15 55.79 43.58 56.00 54.97 58.88 39.52 37.03 37.81 47.60 Yb2O3 24.45 20.34 4.47 30.78 8.31 15.01 9.56 12.00 12.40 9.35 4.81 F 0.64 1.46 1.91 2.18 1.78 4.16 6.44 0.64 0.66 0.88 4.70 SiO2 1.23 Li2O Na2O 4.68 K2O 3.51 MgO CaO 2.81 SrO 0.90 BaO 1.37 1.87 ZnO 4.16 4.30 12.15 PbO 4.81 Y2O3 4.69 6.60 9.61 ZrO2 4.50 3.14 Ta2O5 Nb2O5 WO3 Al2O3 TiO2 3.27 GeO2 9.61 Gd2O3 nd 1.7371 1.7570 1.7291 1.7588 1.7392 1.7484 1.7391 1.7459 1.7356 1.7233 1.7702 vd 54.4 53.6 53.7 53.6 55.1 54.9 55.5 52.3 53.2 53.9 51.2 Table I (continued) Example No. 12 13 14 15 16 17 18 19 20 21 22 B2O3 24.50 29.35 35.93 26.42 27.00 32.01 28.67 26.89 24.04 34.21 24.88 La2O3 42.82 39.09 35.72 47.17 39.70 37.00 47.91 42.38 37.42 39.55 37.50 Yb2O3 20.42 9.54 6.61 7.29 13.50 1.41 12.52 14.56 11.99 14.90 F 5.04 4.07 3.31 4.64 4.35 0.55 2.14 0.69 0.75 0.64 0.63 SiO2 1.88 2.14 Li2O 1.63 Na2O K2O MgO 2.45 CaO 4.73 1.82 4.80 SrO 6.37 BaO 6.61 2.01 1.03 0.90 0.97 ZnO 7.34 6.03 4.11 5.54 4.16 5.20 PbO Y2O3 9.54 21.66 4.78 4.69 ZrO2 9.00 5.94 4.50 5.57 Ta2O5 4.09 10.93 9.33 10.98 Nb2O5 3.67 WO3 4.09 8.10 Al2O3 1.47 2.70 TiO2 GeO2 14.41 Gd2O3 10.40 nd 1.7523 1.6998 1.7233 1.7145 1.7595 1.7369 1.7387 1.7674 1.7969 1.7481 1.80614 vd. 51.8 58.8 56.8 55.8 50.2 53.0 53.8 52.2 46.7 52.3 45.9 Table 1 (continued) 23 24 25 Example no. B2O3 28.28 23.94 30.82 La2O3 42.34 42.75 39.09 Yb2O3 13.37 11.53 9.54 F 3.45 3.54 4.07 SiO2 0.41 Li2O 0.54 0.54 Na2O 1.56 K2O 1.44 MgO 0.82 0.82 CaO 0.61 0.94 SrO 2.12 BaO 0.46 0.62 ZnO 1.43 4.05 7.34 PbO 1.60 Y2O3 2.20 3.20 9.54 ZrO2 1.05 Ta2O5 5.01 1.36 Nb2O5 3.67 WO3 1.36 1.36 Al2O3 nd 1.7341 1.7486 1.7001 vd 53.6 52.3 58.9 According to the present invention, optical glass having a high refractive index and low scattering, particularly optical glass having a refractive index (nd) of 1.69 to 1.81 and an Abbe's number (vd) of 45 to 59 can be stably manufactured on an industrial scale will.

Claims (4)

Optical glass with high refractive index and low scattering P a t e n t a n t a n t p r ü c h e 1. Optical glass with a high refractive index and a lower one Scatter, free of thorium and cadmium, which has the following composition in% by weight: B203 20 - 37 La203 34 - 60 Yb2O3 1 - 32 F 0.1 - 7 SiO2 0 - 3 R20 0 - 6 (R20 is one or a combination of two or more of Li20, Na2O and K20) RO 0 - 18 (RO is one or a combination of two or more of MgO, CaO, SiO, BaO and ZnO) Y203 o - 23 ZrO2 0 - 11 Ta203 0 - 12 Nb2O5 0 - 5 PbO O - 6 WO3 0 - 10 Al2O3 0 - 4 TiO2 0 - 5 GeO2 0 - 16 Gd2O3 0 - 12 (The fluorine content shows the Amount of substitution with oxygen if glass is 100%) 2. Optical glass according to Claim 1, wherein the content of F is 0.5-7% by weight. 3. Optical glass according to claim 1 with the following composition: B203 24 - 37% by weight La203 35 - 50 t Yb203 5 - 15 F 0.1 - 4.1 CaO 0 - 6 SrO 0 - 2 BaO 0 - 8 ZnO 0 - 8 Y2O3 0 - 11 ZrO2 0 - 7 Ta2O5 0 - 12 Nb205 0 - 5 GeO2 0 - 16 Gd2O3 0 - 12 4. Optical glass according to claim 1 with the following composition: B203 26 - 37% by weight La2O3 35 - 50 Yb2O3 9 - 15 F 0.1 - 2.5 SrO 0 - 2 BaO 0 - 3 ZnO 0 - 6 Y2O3 0 - 7 ZrO2 0 - 7