1478 results about "Glass container" patented technology

The glass containers described herein are resistant to delamination, have improved strength, and increased damage resistance. In one embodiment, a glass container may include a body having an inner surface, an outer surface and a wall thickness extending between the outer surface and the inner surface. At least the inner surface of the body may have a delamination factor less than or equal to 10. The body may also have a compressively stressed layer extending from the outer surface of the body into the wall thickness. The compressively stressed layer may have a surface compressive stress greater than or equal to 150 MPa. A lubricous coating may be positioned around at least a portion of the outer surface of the body, such that the outer surface of the body with the lubricous coating has a coefficient of friction less than or equal to 0.7.

The container is a glass bottle (10) encased with a plastic coating (4) from its base section (3) to a sealing rim (2) around its mouth (M) in order to protect against shattering or explosive failure. The glass bottle, preferably a glass inlet, is fillable under pressure with a sprayable medically active substance and a propellant and provided with a delivery element attached to the sealing rim. To facilitate lower injection molding temperatures and pressures and to permit autoclaving at high temperatures the glass bottle with the plastic coating (4) is made by a method which includes injecting at least one reactively cross-linkable plastic capable of being heat-softened into a mold surrounding the glass bottle and forming the plastic coating (4) by a reaction injection molding (RIM) method.

The invention provides a mold for processing a glass container and belongs to the technical field of mold. The mold includes a pair of half molds that are opposite to each other and have the same shape, and a mold cavity is formed in each half mold. The mold is characterized in that vertical through ventilation holes which are communicated with each other are alternatively distributed around the mold cavity at the height direction of the half molds. The invention has the advantages that the bottle temperature can be cooled effectively due to the through ventilation holes around the mold cavity at the height direction, thus preventing the bottle from being deformed by high temperature and guaranteeing the strength of the half molds.

A narrow neck glass container includes a container body and a container neck finish. The container neck finish has an external closure attachment diameter of not more than 36 mm, and the container body has at least one internal embossment of predetermined geometry. The at least one internal embossment preferably comprises a plurality of internal embossments in a geometric pattern.

An electronic cigarette, including a cigarette holder assembly, an atomization assembly, a glass container for accommodating smoke oil, and a gas flow regulator. The cigarette holder assembly includes a mouthpiece, a first sealing ring, a seat for supporting the mouthpiece, a fixed screw, and a pole. The atomization assembly includes a pair of heating wires, a glass casing, a second sealing ring, a third sealing ring, oil-guiding cotton, a limit cover, an insulating ring, and a fixed ring. The glass container includes a first sealing gasket and a second sealing gasket which are respectively disposed at both ends of the glass container. The gas flow regulator includes a control ring, a steel ball, a spring, and a rotary button. The first sealing ring of the cigarette holder assembly is sleeved on the mouthpiece, and the mouthpiece is fixed on the seat via the fixed screw.

The invention provides a mold for producing a glass container and belongs to the technical field of mold. The mold includes a pair of half bottle molds that are opposite to each other, and a bottle die cavity is formed in the inner wall of each half bottle mold and is composed of a bottle body cavity and a bottleneck cavity. The mold is characterized in that a first heat-insulating hole and a second heat-insulating hole are alternatively distributed around the bottleneck cavity at the upper part of the half bottle mold, wherein, the depth of the two heat-insulating holes is different. The mold has the advantages that the temperature around the bottleneck cavity can be improved as the first heat-insulating hole and the second heat-insulating hole are arranged at the upper part of the half bottle mold and are corresponding to the surrounding of the bottleneck cavity, which is helpful to lead the materials to distribute evenly during the two blowing process and can guarantee that the wall thickness of the bottleneck is uniform.

A system and method is provided for tempering a glass container. The method includes the steps of pre-heating the glass container to a first predetermined temperature. The method also includes the steps of applying radio-frequency energy to the pre-heated glass container to heat the glass container to a second predetermined temperature and, after a predetermined amount of time, simultaneously cooling at least one surface of the heated glass container to a third predetermined temperature to treat the glass container. The method further includes the steps of, after a predetermined amount of time, quenching the treated glass container to a fourth predetermined temperature to produce a tempered glass container.

The invention provides a mold for processing a glass container and belongs to the technical field of mold. The mold includes a pair of half molds that are opposite to each other and a pair of bottom molds at the bottom of the half molds, a mold cavity is respectively opened along the height direction at the middle of each side of the opposing sides of the two half molds. The mold is characterized in that a vacuum groove is respectively opened at each side along the height direction of the mold cavity, and ventholes which are equal in number with the vacuum grooves and are communicated with the vacuum grooves are opened at the side edge of the bottom mold core, also a central hole for connecting with the vacuum pipeline is opened at the center of the bottom mold core and the central hole is communicated with the venthole. The mold has the advantages that the pair of half molds can have ideal closing effect due to the vacuum grooves at each side of the mold cavity, which restricts the deformation of the half molds, and guarantees that the glass container is smooth and has good quality.

Pharmaceutical compositions in the form of ready-to-use preparations of gemcitabine in aqueous solutions in a glass containers having specified dimensional relationships demonstrate long shelf life over a wide range of solution pH values. The ratio of the surface area of the container wetted by the solution to the volume of the solution, expressed in cm² to cm³, is less than 3.4.

The present invention is based, at least in part, on the identification of a pharmaceutical container formed, at least in part, of a glass composition which exhibits a reduced propensity to delaminate, i.e., a reduced propensity to shed glass particulates. As a result, the presently claimed containers are particularly suited for storage of pharmaceutical compositions and, specifically, a pharmaceutical solution comprising a pharmaceutically active ingredient, for example, NEUPOGEN (filgrastim), NEULASTA (pegfilgrastim), EPOGEN (epoetin alfa) or ENBREL (etanercept).

A strengthened glass container or vessel such as, but not limited to, vials for holding pharmaceutical products or vaccines in a hermetic and/or sterile state. The strengthened glass container undergoes a strengthening process that produces compression at the surface and tension within the container wall. The strengthening process is designed such that the tension within the wall is great enough to ensure catastrophic failure of the container, thus rendering the product unusable, should sterility be compromised by a through-wall crack. The tension is greater than a threshold central tension, above which catastrophic failure of the container is guaranteed, thus eliminating any potential for violation of pharmaceutical integrity.

A method is disclosed herein for uniformly coating the exterior surface of a glass bottle and the label affixed thereon to enhance the aesthetic appeal of the bottle and the label affixed thereon, to waterproof the label, and to allow the reuse of the label when the bottle is recycled without the need to remove or peel the label and reapply a new label. The method comprises preparing the clear coating to be applied on the surface of the bottle, rotating the bottle in a horizontal position about its center-line, applying the clear coating on the surface of the rotating bottle, adjusting the rotational speed of the bottle to allow the clear coating to spread uniformly over the surface of the bottle and the label affixed thereon, and allowing the applied coating to cure with or without the application of heat.

The invention provides a mold for processing a glass container and belongs to the technical field of mold. The mold includes a pair of half molds that are opposite to each other and have the same shape and a bottle mold cavity, a first heat-radiating groove and a second heat-radiating groove are alternatively opened on the outer wall of the two half molds. The mold has the advantages that the first and the second heat-radiating grooves on the outer wall of the two half molds are helpful for heat radiation of the half molds, which leads the temperature of the mold cavity to drop under the softening point rapidly and is favorable for improving the formation speed of the bottle in the mold cavity and the production speed of the bottle; the opening of the first heat-radiating groove and the second heat-radiating groove does not affect the strength of the half molds, thus being capable of ensuring the service life of the mold.

The invention belongs to the field of edible fungus culture and discloses a method for culturing cordyceps militaris by living silkworm chrysalises. The method comprises the following steps of: the preparation of stains, the selection of the silkworm chrysalises and disinfection treatment. The method is characterized by specifically comprising the following steps of: inoculating cordyceps militaris stains into silkworm chrysalis bodies through an injection method, wherein the stain dosage of each silkworm chrysalis body is 0.1-0.5ml; putting the inoculated silkworm chrysalises in sterile glass containers to culture the silkworm chrysalises in a culture room for 10-15 days at 18-25 DEG C, wherein 10-20 silkworm chrysalises are put in each container generally; increasing illumination from the twelfth day to promote sprouts to form; when little grass grows to 1cm, puncturing holes on sealing films so as to increase oxygen supply; meanwhile, watering the ground of the culture room to supplement the humidity; and after 20-30 days, when the height of stromata is 5-8 cm and the tops grow into wooden club shapes, collecting and drying. The method directly adopts the live silkworm chrysalises as culture carriers, can harvest the cordyceps militaris with the silkworm chrysalis bodies and changes the current situation that the cordyceps militaris cultured by rice culture media has no silkworm chrysalises.

In order to avoid deposition of evaporating alkali compounds on an inner surface of a hollow glass body during thermal processing to form a glass container from the hollow glass body, an overpressure is provided in the hollow glass body during the thermal processing. Either rinsing the hollow glass body with a gas, such as air, or at least partially closing the glass body at one end so that sufficiently rapid pressure equilibration is avoided, can provide this overpressure. The glass containers made by these methods are especially suited for food or pharmaceuticals because they have a reduced alkali release from their inner surfaces, for example at most about 2.0 mg/l sodium oxide.

The invention discloses a corrosive capable of displaying an ultra low carbon solidification arborescent structure and a preparation method thereof. The corrosive is prepared from the following components: picric acid, stannous chloride, copper chloride, hydrochloric acid, surfactant, absolute ethyl alcohol and distilled water. The preparation method is as follows: taking a specified amount of the distilled water, and equally dividing the distilled water into two parts; mixing and putting solid medicament into a glass container according to fixed quantity, and adding one part of the distilledwater into the solid mixed medicament to dissolve the medicament; adding a specified amount of the absolute ethyl alcohol into another part of spare distilled water; adding a hydrochloric acid solution into the absolute ethyl alcohol solution; mixing the ethyl alcohol and the hydrochloric acid solution which are poured into an aqueous solution containing the solid medicament; fully stirring; and finally adding the surfactant to finish preparing. By utilizing the reagent provided by the invention, the solidified arborescent structure forms of ultra low C, S, P continuous casting steel billets can be displayed clearly, a finish requirement on sample surface is lowered, the sample preparation working procedure is simplified and the larbour intensity of operators is lowered.

Delamination resistant glass containers with heat-tolerant coatings are disclosed. In one embodiment, a glass container may include a glass body having an interior surface, an exterior surface and a wall thickness extending from the exterior surface to the interior surface. At least the interior surface of the glass body is delamination resistant. The glass container may further include a heat-tolerant coating positioned on at least a portion of the exterior surface of the glass body. The heat-tolerant coating may be thermally stable at temperatures greater than or equal to 260° C. for 30 minutes.