The invention relates to a method of automatic mass production of glass containers with texture which comprises producing a mold including a texture of non-parametric three-dimensional motifs (5) by means of protuberances, with said motifs being irregular, non-geometric, and non-figurative and being irregularly distributed; manufacturing glass containers with non-parametric texture bas-relief motifs covering and concealing potential aesthetic manufacturing defects by means of an automatic process of molten glass compression and/or blow molding; automatically detecting and rejecting the containers having manufacturing dimensional and/or safety defects.

Disclosed herein are methods and components for manufacturing substantially square glass containers and components and a method for forming parisons are disclosed. A plunger is extended into a mold which presses molten glass against the walls of the mold and against the extended plunger. Compressed air is applied through the neck of the parison to expand the parison outwardly against another mold and an end surface defined by a baffle. The neck ring provides retention features on the neck of the glass container and can include child-resistance features. Each of the molds, neck ring, and plunger produce substantially square glass containers having a substantially square neck.

Disclosed herein are methods and components for manufacturing substantially square glass containers and components and a method for forming parisons are disclosed. A plunger is extended into a mold which presses molten glass against the walls of the mold and against the extended plunger. Compressed air is applied through the neck of the parison to expand the parison outwardly against another mold and an end surface defined by a baffle. The neck ring provides retention features on the neck of the glass container and can include child-resistance features. Each of the molds, neck ring, and plunger produce substantially square glass containers having a substantially square neck.

Provided is a method for manufacturing a glass container with which a glass container having a distinctively shaped inner space and excellent aesthetic appearance can be manufactured in good yield. The method for manufacturing a glass container includes steps (A) to (E). (A) A step of introducing a gob into a mold through a funnel. (B) A step of blowing air into the mold through the funnel, bringing a plunger disposed on a side opposite the side to which the funnel is fitted in contact with the gob, separating the plunger from the gob, and forming a recess on the surface of the gob. (C) A step of removing the funnel from the mold and fitting a baffle to the mold. (D) A step of blowing air from the plunger, and forming an inner space inside the gob with the recess as a starting point while simultaneously forming an outer shape by pressing the outer side of the gob to a molding surface of the mold to obtain a glass container of the final shape. (E) A step of transferring the glass container of the final shape to a cooling mold and cooling the same.

Provided is a method for manufacturing a glass container with which a glass container having a distinctively shaped inner space and excellent aesthetic appearance can be manufactured in good yield. The method for manufacturing a glass container includes steps (A) to (E). (A) A step of introducing a gob into a mold through a funnel. (B) A step of blowing air into the mold through the funnel, bringing a plunger disposed on a side opposite the side to which the funnel is fitted in contact with the gob, separating the plunger from the gob, and forming a recess on the surface of the gob. (C) A step of removing the funnel from the mold and fitting a baffle to the mold. (D) A step of blowing air from the plunger, and forming an inner space inside the gob with the recess as a starting point while simultaneously forming an outer shape by pressing the outer side of the gob to a molding surface of the mold to obtain a glass container of the final shape. (E) A step of transferring the glass container of the final shape to a cooling mold and cooling the same.

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 glass container includes legible indicia having an indicia outer surface coextensive with an outer surface of an adjacent portion of the container and with no V-shaped depressions, and having an indicia inner surface that protrudes radially inwardly with respect to an inner surface of the container adjacent to the indicia inner surface.

A glass container includes legible indicia having an indicia outer surface coextensive with an outer surface of an adjacent portion of the container and with no V-shaped depressions, and having an indicia inner surface that protrudes radially inwardly with respect to an inner surface of the container adjacent to the indicia inner surface.

An additive manufacturing device is provided and includes a housing, a printing bed, a printing head and a controller. The printing bed is rotatably disposed in the housing and includes a surface and a body. The body defines an air conduit terminating at an open end at the surface and is fluidly communicative with an exterior of the housing. The printing head is movably disposed in the housing and configured to print molten glass material onto the printing bed at a location corresponding to the open end of the air conduit. The controller is configured to control movements and printing operations of the printing head, rotations of the printing bed and airflow to the molten glass material through the air conduit.

An additive manufacturing device is provided and includes a housing, a printing bed, a printing head and a controller. The printing bed is rotatably disposed in the housing and includes a surface and a body. The body defines an air conduit terminating at an open end at the surface and is fluidly communicative with an exterior of the housing. The printing head is movably disposed in the housing and configured to print molten glass material onto the printing bed at a location corresponding to the open end of the air conduit. The controller is configured to control movements and printing operations of the printing head, rotations of the printing bed and airflow to the molten glass material through the air conduit.