Abstract: At least one closed container includes a glass container having a total height, being characterized by a center axis and including a shoulder region; and a press-fit cap closing the glass container and including a cylindrical body having an upper end and a lower end. P is any given point at the lower end of the press-fit cap that is located above the shoulder region and that lies on a straight line running parallel to the center axis and hitting an outer surface of the shoulder region at a point Q. Among these points P at the lower end of the press-fit cap point P? is the one that has a smallest distance to its corresponding point Q? and a distance between points P? and Q? on the straight line is in a range from 0.17 to 8.4 mm.

Abstract: A supporting structure for concurrently supporting a plurality of containers having a predetermined length for medical, pharmaceutical or cosmetic applications comprises a carrier having a plurality of supporting means for supporting the containers on the carrier, optionally, at least in a first orientation (e.g. upright) or in a second orientation (upside-down or also upright). According to the invention the carrier is matched to the lengths of the containers such that the upper ends of the containers are arranged in the first position at the same distance to the carrier as the lower ends of the containers in the second position and that the upper ends and/or lower ends of the containers are accessible for a further processing of the containers while they are supported on the carrier.

Abstract: A method for sterile packaging of a plurality of containers is provided that includes: providing a carrier in which a plurality of receptacles are formed, the receptacles being formed by a closed bottom and a circumferential side wall, the upper ends of the receptacles, which are opposite to the respective bottom, are open and circumferential connecting webs are provided at the upper ends; placing the containers in the receptacles; providing a gas-impermeable protective foil; bonding the protective foil along the connecting webs with the upper surface of the carrier to package all the receptacles with the containers accommodated individually therein; and sterilizing the receptacles with the containers accommodated therein and/or the inner volumes of the containers by a gas flowing into the receptacles and/or into the inner volumes of the containers through at least one gas-permeable portion.

Abstract: A method for sterile packaging of a plurality of containers is provided that includes: providing a carrier in which a plurality of receptacles are formed, the receptacles being formed by a closed bottom and a circumferential side wall, the upper ends of the receptacles, which are opposite to the respective bottom, are open and circumferential connecting webs are provided at the upper ends; placing the containers in the receptacles; providing a gas-impermeable protective foil; bonding the protective foil along the connecting webs with the upper surface of the carrier to package all the receptacles with the containers accommodated individually therein; and sterilizing the receptacles with the containers accommodated therein and/or the inner volumes of the containers by a gas flowing into the receptacles and/or into the inner volumes of the containers through at least one gas-permeable portion.

Abstract: A supporting structure for concurrently supporting a plurality of containers having a predetermined length for medical, pharmaceutical or cosmetic applications is provided. The support structure includes a carrier having a plurality of supports for the containers on the carrier, optionally, at least in a first orientation (e.g. upright) or in a second orientation (upside-down or also upright). The carrier is matched to the lengths of the containers such that the upper ends of the containers are arranged in a first position at the same distance to the carrier as the lower ends of the containers in the second position and that the upper ends and/or lower ends of the containers are accessible for a further processing of the containers while they are supported on the carrier.

Abstract: The PbO-free UV-absorbing glass is made under oxidative conditions and has a composition, in % by weight, of: SiO2, 55-79; B2O3, 3-25; Al2O3, 0-10; Li2O, 0-10; Na2O, 0-10; K2O, 0-10; MgO, 0-2; CaO, 0-3; SrO, 0-3; BaO, 0-3; ZnO, 0-3; ZrO2, 0-3; CeO2, 0-1; Fe2O3, 0-1; WO3, 0-3; Bi2O3, 0-3; MoO3, 0-3; ?Li2O+Na2O+K2O=0.5 to 16 and ?MgO+CaO+SrO+BaO+ZnO=0-10. It also contains from 0.1 to 10% TiO2 with at least 95% of the titanium as Ti+4 so that it has a high visible transmission, reduced color centers, and a sharp UV absorption edge.

Abstract: The PbO-free UV-absorbing glass is made under oxidative conditions and has a composition, in % by weight, of: SiO2, 55-79; B2O3, 3-25; Al2O3, 0-10; Li2O, 0-10; Na2O, 0-10; K2O, 0-10; MgO, 0-2; CaO, 0-3; SrO, 0-3; BaO, 0-3; ZnO, 0-3; ZrO2, 0-3; CeO2, 0-1; Fe2O3, 0-1; WO3, 0-3; Bi2O3, 0-3; MoO3, 0-3; ?LiO+Na2O+K2O=0.5 to 16 and ?MgO+CaO+SrO+BaO+ZnO=0-10. It also contains from 0.1 to 10% TiO2 with at least 95% of the titanium as Ti+4 so that it has a high visible transmission, reduced color centers, and a sharp UV absorption edge. It is especially useful in lamps display devices and glass-to-metal seals.

Abstract: The method for making UV-absorbing glass, which transmits in a visible range, includes melting raw materials to form a melt and producing the melt under oxidative conditions. The UV-absorbing glass is free of PbO and has the following composition (in % by weight): SiO2, 55-79; B2O3, 3-25; Al2O3, 0-10; Li2O, 0-10; Na2O, 0-10; K2O, 0-10; MgO, 0-2; CaO, 0-3; SrO, 0-3; BaO, 0-3; ZnO, 0-3; ZrO2, 0-3; CeO2, 0-1; Fe2O3, 0-1; WO3, 0-3; Bi2O3, 0-3; MoO3, 0-3; with ? Li2O+Na2O+K2O=0.5 to 16 and ? MgO+CaO+SrO+BaO+ZnO=0-10. The melt composition is characterized by including 0.1 to 10 % TiO2 and from 0.01-10 % As2O3. The glass made by the method and its properties are also disclosed. The glass is useful in lamps, LCD displays, monitors and glass-to-metal seals with molybdenum, tungsten and Fe—Co—Ni alloys.

Abstract: The method for making UV-absorbing glass, which transmits in a visible range, includes melting raw materials to form a melt and producing the melt under oxidative conditions. The melt has the following composition (in % by weight): SiO2, 55-79; B2O3, 3-25; Al2O3, 0-10; Li2O, 0-10; Na2O, 0-10; K20, 0-10; MgO, 0-2; CaO, 0-3; SrO, 0-3; BaO, 0-3; ZnO, 0-3; ZrO2, 0-3; CeO2, 0-1; Fe2O3, 0-1; WO3, 0-3; Bi2O3, 0-3; MoO3, 0-3; with ?Li2O+Na2O+K2O=0.5 to 16 and ?MgO+CaO+SrO+BaO+ZnO=0-10. The melt composition is characterized by including 0.1 to 10% TiO2 and from 0.01-10% As2O3. The glass made by the method and its properties are also disclosed. The glass is useful in lamps, LCD displays, monitors and glass-to-metal seals with molybdenum, tungsten and Fe—Co—Ni (KOVAR) alloys.