A method of infusing silicon dioxide (SiO.sub.2) in a crystalline state into a structure comprising SiO.sub.2 in a non-crystalline amorphous state is provided. In one embodiment of the present invention, a first material comprising SiO.sub.2 is heated to a melting point, converting the SiO.sub.2 from a crystalline state into a non-crystalline amorphous state. A second material comprising SiO.sub.2 is then applied to the first material while the first material is at a temperature that is hot enough to render the first material pliable, but not so hot as to convert the SiO.sub.2 in the second material from a crystalline state into a non-crystalline state. The first material is then cooled slowly over a period of time to relieve internal stresses introduced during the manufacturing process.

A method of infusing silicon dioxide (SiO.sub.2) in a crystalline state into a structure comprising SiO.sub.2 in a non-crystalline amorphous state is provided. In one embodiment of the present invention, a first material comprising SiO.sub.2 is heated to a melting point, converting the SiO.sub.2 from a crystalline state into a non-crystalline amorphous state. A second material comprising SiO.sub.2 is then applied to the first material while the first material is at a temperature that is hot enough to render the first material pliable, but not so hot as to convert the SiO.sub.2 in the second material from a crystalline state into a non-crystalline state. The first material is then cooled slowly over a period of time to relieve internal stresses introduced during the manufacturing process.

Disclosed are a glass embedded product and a method for fabricating same. The glass embedded product comprises a base, the base having a cavity, several hollowed holes being formed through a side wall of the cavity, and the hollowed holes communicate with the cavity. The glass embedded product further comprises a glass blown decorative structure embedded in the base, the glass blown decorative structure comprising a glass blown lining sheathed in the cavity of the base and glass protruding decorative parts embedded in the hollowed holes of the base. The glass protruding decorative parts and the glass blown lining form an integrated blow-moulded integral structure.

A method of fabricating a glass matrix composite includes providing a fiber preform in a cavity of a die tooling, the fiber preform circumscribing an interior region; providing a parison of glass matrix material in the interior region, the glass matrix material having a first viscosity; introducing pressurized inert gas into the parison to outwardly inflate the parison against the fiber preform; and while under pressure from the pressurized inert gas, decreasing the first viscosity of the glass matrix material to a second viscosity. The pressure and the second viscosity cause the glass matrix material to flow and infiltrate into the fiber preform to thereby form a consolidated workpiece. The consolidated workpiece is then cooled to form a glass matrix composite.

A method of fabricating a glass matrix composite includes providing a fiber preform in a cavity of a die tooling, the fiber preform circumscribing an interior region; providing a parison of glass matrix material in the interior region, the glass matrix material having a first viscosity; introducing pressurized inert gas into the parison to outwardly inflate the parison against the fiber preform; and while under pressure from the pressurized inert gas, decreasing the first viscosity of the glass matrix material to a second viscosity. The pressure and the second viscosity cause the glass matrix material to flow and infiltrate into the fiber preform to thereby form a consolidated workpiece. The consolidated workpiece is then cooled to form a glass matrix composite.

Disclosed are a glass embedded product and a method for fabricating same. The glass embedded product comprises a base, the base having a cavity, several hollowed holes being formed through a side wall of the cavity, and the hollowed holes communicate with the cavity. The glass embedded product further comprises a glass blown decorative structure embedded in the base, the glass blown decorative structure comprising a glass blown lining sheathed in the cavity of the base and glass protruding decorative parts embedded in the hollowed holes of the base. The glass protruding decorative parts and the glass blown lining form an integrated blow-moulded integral structure.

A facility for manufacturing a hollow glass article, including: a finishing mold intended to receive a blank of the hollow glass article and defining a cavity for forming the hollow glass article, at least one gas source, and a blowing head connected to the gas source and adapted for achieving at least one injection of the gas into the inside of the blank contained in the cavity. The facility further includes: at least one reservoir of coloring powder, and a system for injecting the coloring powder into the inside of the blank while the blank is located in the finishing mold and into the inside of the hollow glass article while the hollow glass article is located in the finishing mold, so that the injection of the coloring powder takes place before, during, after, before and during, during and after, or before, during and after the gas injection.

A facility for manufacturing a hollow glass article, including: a finishing mold intended to receive a blank of the hollow glass article and defining a cavity for forming the hollow glass article, at least one gas source, and a blowing head connected to the gas source and adapted for achieving at least one injection of the gas into the inside of the blank contained in the cavity. The facility further includes: at least one reservoir of coloring powder, and a system for injecting the coloring powder into the inside of the blank while the blank is located in the finishing mold and into the inside of the hollow glass article while the hollow glass article is located in the finishing mold, so that the injection of the coloring powder takes place before, during, after, before and during, during and after, or before, during and after the gas injection.

There is provided a method of manufacturing a glass container that can manufacture a glass container, which includes a bubble formed in a bottom portion and independent of the outside, with high yield by accurately controlling the position and size of the bubble. A method of manufacturing a glass container that includes a mouth portion, a body portion, and a bottom portion, includes: a step of molding a glass container, in which a bubble is not yet formed, from molten glass; a step of forming a bubble-forming passage by pulling out a needle-like member after inserting the needle-like member into a bottom portion of the glass container in which a bubble is not yet formed; a step of injecting air from an inlet of the bubble-forming passage to form a reverse teardrop-shaped internal space, which is widened in the bottom portion from the bubble-forming passage as a starting point, in the bottom portion of the glass container in which a bubble is not yet formed, and to obtain a glass container that includes an internal space communicating with the outside; and a step of closing an inlet side of the reverse teardrop-shaped internal space by flow of not yet cured glass, which is caused by the potential heat of the not yet cured glass, to obtain a glass container that includes a bubble formed in the bottom portion and independent of the outside.

There is provided a method of manufacturing a glass container that can manufacture a glass container, which includes a bubble formed in a bottom portion and independent of the outside, with high yield by accurately controlling the position and size of the bubble. A method of manufacturing a glass container that includes a mouth portion, a body portion, and a bottom portion, includes: a step of molding a glass container, in which a bubble is not yet formed, from molten glass; a step of forming a bubble-forming passage by pulling out a needle-like member after inserting the needle-like member into a bottom portion of the glass container in which a bubble is not yet formed; a step of injecting air from an inlet of the bubble-forming passage to form a reverse teardrop-shaped internal space, which is widened in the bottom portion from the bubble-forming passage as a starting point, in the bottom portion of the glass container in which a bubble is not yet formed, and to obtain a glass container that includes an internal space communicating with the outside; and a step of closing an inlet side of the reverse teardrop-shaped internal space by flow of not yet cured glass, which is caused by the potential heat of the not yet cured glass, to obtain a glass container that includes a bubble formed in the bottom portion and independent of the outside.