DE3310846A1 - Barium-free laboratory glass of Type I Class B - Google Patents

Abstract

A barium-free laboratory glass of Type I Class B is disclosed which corresponds to ASTM Standard Specification E 438-80a, has a coefficient of linear thermal expansion (0 to 300 DEG C, cm/cm- DEG C.10<-7>) of about 48-56, a chemical resistance corresponding to a maximum titration equivalent of 0.02 N H2SO4/10 g glass of 1.0 ml, a composition which consists essentially of, in % by weight: SiO2: 70 to 74; B2O3: 9 to 13; Al2O3: 5 to 8; Na2O: 5-8; K2O: 0 to 4; CaO: 0 to 3; and MgO: 0 to 1, an upper cooling temperature of about 550 to 585 DEG C, a liquidus temperature of about 943 to 960 DEG C, and a log n at the liquidus temperature of about 5.0 to 5.5.

Description

Physical requirements Linear expansion coefficient 48 to 56 + 2 O to 3000C cm / cm - ° C x 10-7 0 Upper cooling temperature, ° C 574 - 10 softening point, ° C 783 to 799 t 10 Density, cooled, g / cm³ 2.36 # 0.02 Chemical resistance, Titration equivalent of: 0.02N H2SO4 / 10g of the glass, max., Ml 1.0 It is a laboratory glass for pharmaceutical containers made of a soda-alumina-borosilicate glass desired, that are melted and placed in containers such as ampoules or glass vials with one for economic production can be processed at sufficient speed. According to ASTM E 438-80a, such a glass has a certain composition excellently balanced chemical and physical properties, including high chemical resistance and a relatively low coefficient of thermal expansion ready.

However, it is believed that during storage of the drug container Barium from barium oxide-in the glass dissolves very slowly in very small milks and with very small amount of sulfate or phosphate ions in the drug Formation of precipitates can react, thereby improving the flawlessness of the product gets destroyed.

The invention is therefore based on the object of a barium-free glass composition to create that meets the relatively strict requirements of ASTM regulation E 438 - 80a met and melted in an economical manner and according to the known Tube drawing process, such as the Danner process or the Downdraw process can be.

The object is achieved by the glass of claim 1. Preferred Embodiments are given in the subclaims.

A feature of the invention is the provision of a barium-free one Laboratory glass of type I, class B according to the ASTM regulation E 438 - 80a established standard specification, with a linear coefficient of thermal expansion (0 to 3000C, cm / cm-0c x 10-7) from about 48 to 56 and a chemical resistance a maximum titration equivalent of: 0.02N H2S04 / 10g glass of 1.0 ml; the Glass composition consists essentially of the components listed below in approximately the specified weight percent: constituent weight percent SiO2 70 to 74 B2O3 9 to 13 Al2O3 5 to 8 Na2O 5 to 8 K2O 0 to 4 CaO O to 3 MgO O to 1 the Glass composition has an upper cooling temperature of about 550 to 58500, a Liquidus temperature (equilibrium temperature between molten glass and its primary crystals) of about 942 to 960 ° C and a log n at the liquidus temperature ton about 5.0 to 5.5.

Another feature of the invention is the provision of a barium-free Glass composition that meets the requirements of ASTM E 438 - 80a and is in can be processed economically into pharmaceutical containers. the Composition contains the following ingredients in approximately the specified weight percent: Ingredient% by weight SiO2 71.8 B2O3 11.5 Al2O3 6.8 Na20 6.4 K20 2.7 0a0 0.5 MgO 0.2 The glass composition has the following properties: Property Processing temperature 11350C softening temperature 782 ° C Property Upper cooling temperature 560 C Lower expansion temperature 516 0C Thermal expansion coefficient 54 x density 2.335 g / cm3 Chemical resistance 0.34 ml Logarithm of the viscosity of the glass 5 990 ° C log of the viscosity of the glass 3 1354 ° C liquidus temperature 949 ° C log n at the liquidus temperature 5.4 These will us further characteristics, as in the following Description and the claims specified, achieved.

The glass according to the invention is a barium-free laboratory glass of Type I, Class B, that of the standard specification, specified in ASTM E 438 - 80a, corresponds to a coefficient of linear thermal expansion (0 to 3000C, cm / cm - ° C x 10 7) from about 48 to 56 and a chemical resistance of a maximum Titration equivalents of (a chemical durability, maximum titration equivalent of): 0.02n H2S04 / 10g glass of 1.0 ml and has a composition that is essentially consists of the following components in approximately the specified weight percent: component % By weight SiO2 70 to 74 B2O3 9 to 13 Al 203 5 to 8 Na2O 5 to 8 K20 0 to 4 CaO O to 3 MgO O to 1 an upper cooling temperature of about 550 to 585 0C and one Has a liquidus temperature of about 942 to 9600C.

A preferred barium-free glass, Type I, Class B (ASTM E 438 - 80a) according to the invention consists essentially of the following components the specified weight percent: constituent weight% SiO2 71 to 73 B2O3 10 to 12 Al2O3 6 to 7 Na2 0 6 to 7 K2O 1 to 3 CaO 0.2 to 2 MgO 0.1 to 0.3 A particularly Preferred baritune-free glass, type I, class B (ASTM E 438 - 80a) according to the invention with excellent properties, a glass is one Composition containing the ingredients listed below approximately those specified Percentage by weight contains: Component% by weight SiO2 71.8 B2O3 11.5 Al2O3 6.8 Na2O 6.4 K20 2.7 CaO 0.5 MgO 0.2 This glass composition has the following properties: Property Processing temperature 1135 ° C Softening temperature 782 ° C Upper cooling temperature 560 ° C Lower relaxation temperature 516 ° C Thermal expansion coefficient 54 x 10 density 2.335 g / cm3 Chemical resistance 0.34 ml Log of viscosity 5 99000 Log of viscosity 3 1354 ° C liquidus temperature 9490t Log n at the liquidus temperature the The invention also provides another very preferred glass composition, the but for some purposes in terms of chemical resistance and high performance production does not have the excellent properties as the above-mentioned glass composition having. This barium-free glass composition contains the following ingredients approximately the specified weight percent: constituent weight% SiO2 70.6 3203 11.7 Al2O3 6.6 Na2O 6.1 K20 2.5 Ca0 2.2 MgO 0.2 The glass composition has the following Properties listed: Property processing temperature 1118 0C softening temperature 7790 Upper cooling temperature 574 ° C Lower expansion temperature 5320C Coefficient of thermal expansion 55 x 10-7 Property Density 2.348 g / cm3 Chemical resistance 0.49 ml log of viscosity 5 980 ° C log of viscosity 3 133500 liquidus temperature 96000 Log n at the liquidus temperature 5.2 The following example is intended to illustrate the invention illustrate in more detail, but does not represent a limitation of the invention.

Example Two barium-free soda-alumina-borosilicate glass compositions (ASTM E 438-80a) were fired from two sets of glass, the sand, borax, boric acid Contained dolomite, lime, feldspar, potassium nitrate and sodium chloride, according to the known Methods made. The crude gas sets were melted in a known manner and fired to obtain glasses A and B that are those given in Table -I Composition in the approximate weight percent and that too indicated chemical and physical properties.

TABLE I Chemical and Physical Properties A B ASTM E 438 - 80a Chemical composition (%) determined calculated determined calculated standard Glass silicon oxide (SiO2) 71.93 71.80 70.35 70.60 70.6 boron oxide (B2O3) 11.62 11.55 12.00 11.70 11.2 aluminum oxide (Al2O3) 6.69 6.75 6.40 6.60 6.6 barium oxide (BaO) - - - - 2.2 Calcium oxide (CaO) 0.43 0.50 2.30 2.20 0.5 Magnesium oxide (MgO) 0.21 0.20 0.01 0.20 0.2 Sodium Oxide (Na2O) 6.61 6.40 6.35 6.10 6.1 Potassium Oxide (K2O) 2.49 2.70 2.29 2.50 2.5 Chloride (Cl-) 0.17 0.10 0.22 0.10 0.1 O # Cl 0.04 0.05 Total 100.11 99.87 TABLE I (continued) A B ASTM E 438-80a Physical Properties determined calculated determined calculated Standard glass Processing temperature (° C) 1135 1135 1118 1124 1130 Softening temperature (° C) 782 788 779 788 785 Upper cooling temperature (° C) 560 574 575 Lower expansion temperature (° C) 516 532 530 Coefficient of thermal expansion 0 to 300 ° C (x 10-7) 54.3 54.7 55.2 55.5 55 Contraction coefficient A.P. - 25 ° C (x 10-7) 68.1 71.2 73 Density (g / cm³) 2.3335 2.3476 2.374 Refractive index (nD) 1.4904 1.4948 1.495 Chemical resistance USP XX (ml 0.2N acid) 0.34 0.49 0.36 Cooling time (Seconds) 79 79 78 77 79 TABLE I (continued) A B ASTM E 438 - 80a Physical properties determined calculated determined calculated Standard Glass viscosity (° C): Log n = 7.6 782 780 785 7.0 818 818 813 816 816 6.0 890 893 885 890 890 5.0 990 995 979 988 990 4.0 1135 1135 1119 1123 1132 3.0 1354 1354 1335 1332 1349 2.5 1518 1496 1504 2.0 1740 1730 1713 1696 1715 Liquidus temperature (° C) 949 958 957 Log n at liquidus temperature 5.41 5.22 5.35 Primary phase tridymite tridymite Tridymite The barium-free compositions A and B according to the invention are made with an ASTM E 438-80a standard glass (manufactured according to the standard specification with BaO). The compositions A and B can be determined with the standard Composition with regard to the physical properties, such as liquidus temperature, chemical resistance, upper cooling temperature, gloss, processability and tendency almost equal to splintering. The consistency of the properties of the composition A and standard glass in important properties such as viscosity, coefficient of expansion and chemical resistance is particularly close.

The glasses were made into medicine containers The molding properties, the surface durability, the lack of inclination to splinter and bloom, and the ampoule power properties were satisfactory. In addition, compositions A and B do not contain any BaO. Surprisingly the demands for economical processability into glass containers and Meets strict ASTM regulations.

In US Pat. No. 3,054,686, modified borosilicate glasses are used for manufacture small container for the packaging of medicines and foodstuffs is disclosed. In this PS, the following theoretical glass composition, in percent by weight, is disclosed: Ingredient wt% Sio2 67 to 71 Al203 2.5 to 6.0 B203 2.0 to 5.0 CaO + MgO 6.0 to 10.0 BaO O to 2.0 Na20 10.5 to 14.5 K20 0.1 to 2.0 Li2O 0 to 1.0 Cl 0 to 0.2 SO3 0 to 0.2 are in this composition the amounts of CaO + MgO / g and the amount of Na2 0 too high to achieve the excellent To provide glass compositions according to the invention. The excellent combination of properties, that by the glass composition according to the invention (which meets the ASTM specification fulfilled) is obtained by the US-PS or the glasses described therein not disclosed. As stated earlier, is the coefficient of thermal expansion an important property. It is critical in meeting the ASTM specification. The glasses of US Pat. No. 3,054,686 have a much higher coefficient of thermal expansion than that of the present invention and range from 74 to 85.

Another important property, chemical resistance, is in the range of glasses known from US Pat from 1.7 up to 5.0 ml, is therefore not as good as that of the glasses according to the invention and fulfills does not meet the requirements of ASTM E 438 -80a.

Claims (4)

Barium-free laboratory glass of type I class B A n s p r ü c h e: 1. Barium-free laboratory glass of type I, class B, characterized that it is the standard specification laid down in ASTM regulation E 438. - 80a corresponds to a linear thermal expansion coefficient, (0 to 3000C, cm / cm - oC x 10-7) of about 48 to 56 and a chemical resistance of a maximum titration equivalent of 0.02n H2S04 / iOg glass of 1.0 ml, has a composition that is im essentially from the following ingredients in approximately the specified weight percent consists: Ingredient% by weight SiO2 70 to 74 B2O3 9 to 13 Al2O3 5 up to 8 Na2 0 5 to 8 K20 0 to 4 CaO O to 3 MgO O to 1 an upper cooling temperature from about 5500C to 585 ° C, a liquidus temperature of about 9430c to 960 ° C and one Log n at the liquidus temperature is from about 5.0 to 5.5. 2. Glass composition according to claim 1, characterized by the following Components in approximately the specified weight percent: Component% by weight SiO2 71 to 73 B2O3 10 to 12 Al2O3 6 to 7 Na2 0 6 to 7 K20 1 to 3 CaO 0.2 to 2 MgO 0.1 to 0.3 3. Glass composition according to claim 1, characterized by the following components in approximately the specified weight percent: component Wt .-% SiO2 71.8 B203 11.5 Al2O3 6.8 Na2O 6.4 K20 2.7 CaO 0.5 MgO 0.2 and through the properties listed below: property processing temperature 113500 softening temperature 78200 upper cooling temperature 560 ° C lower relaxation temperature 516 ° C coefficient of thermal expansion 54 x 10 density 2.335 g / cm3 chemical resistance 0.34 ml logarithm of the viscosity 990 ° C of the glass 5 log of the viscosity 3 1354 ° C Liquidus temperature 949 ° C Log n at the liquidus temperature 5.4 4th Glass composition according to Claim 1, characterized by the following components in approximately the specified weight percent: component SiO2 70.6 3203 11.2 Al203 6.6 Na2O 6.1 K20 2.5 Ca0 2.7 MgO 0.2 and through the following properties: Property Processing temperature 1118 ° C Softening temperature 779 ° C upper cool temperature 57400 lower relaxation temperature 53200 coefficient of thermal expansion 55 x 10-7 density 2.348 g / cm3 chemical resistance 0.49 ml logarithm of viscosity of the glass 5 980 ° C Log of the viscosity of the glass 3 13350C Liquidus temperature 960 ° C Log n at the liquidus temperature 5.2 The invention relates to on laboratory glassware of Type I, Class B, as in the standard specification ASTM E 438 - 80a specified, in particular on barium-free soda-alumina-borosilicate laboratory glasses, specially designed as glass containers for pharmaceuticals, including ampoules, glass vials and syringes are suitable. As in the .ASTM E 438 - 80a (standard specification for glasses in Laboratory equipment), Type I, Class B prescribed, have aluminum oxide-borosilicate laboratory glasses to meet the following chemical and physical requirements: Chemical requirement Hauot constituents wt. about SiO2 73 B2O3 10 Al2O3 7 BaO 2 Ca0 1 Na2 0 6 K2O 1 Snure components As202 plus Sb203 0.1 PbO 0.1 MgO 0.3 ZnO 0.1 all other components ~ parts, max. 1.0