A molten material furnace system having a liquid cooled flow control mechanism and method are disclosed. In particular, the flow control mechanism can include a needle including: a longitudinal axis; an outer conduit including an outer base end, an outer body, and an outer free end; an inner conduit including an inner base end, an inner body radially spaced from the outer body, an inner free end, and a central inlet passage extending between the inlet and the inner free end. Also disclosed is a needle control assembly to position the flow control needle relative to a stilling tank outlet orifice to control flow of molten material through the outlet orifice.

A column of molten glass is cut transversely to make a plurality of glass gobs by means of a cutting device having an elongated piece orthogonal to a conveying direction of the column and carried by a moveable frame operated by a motor controlled by a unit to rotate the piece at either constant or variable speed in one or both directions of rotation about a fixed hinged axis orthogonal to the conveying direction of the glass column.

A column of molten glass is cut transversely to make a plurality of glass gobs by means of a cutting device having an elongated piece orthogonal to a conveying direction of the column and carried by a moveable frame operated by a motor controlled by a unit to rotate the piece at either constant or variable speed in one or both directions of rotation about a fixed hinged axis orthogonal to the conveying direction of the glass column.

In illustrative implementations of this invention, a crucible kiln heats glass such that the glass becomes or remains molten. A nozzle extrudes the molten glass while one or more actuators actuate movements of the nozzle, a build platform or both. A computer controls these movements such that the extruded molten glass is selectively deposited to form a 3D glass object. The selective deposition of molten glass occurs inside an annealing kiln. The annealing kiln anneals the glass after it is extruded. In some cases, the actuators actuate the crucible kiln and nozzle to move in horizontal x, y directions and actuate the build platform to move in a z-direction. In some cases, fluid flows through a cavity or tubes adjacent to the nozzle tip, in order to cool the nozzle tip and thereby reduce the amount of glass that sticks to the nozzle tip.

In illustrative implementations of this invention, a crucible kiln heats glass such that the glass becomes or remains molten. A nozzle extrudes the molten glass while one or more actuators actuate movements of the nozzle, a build platform or both. A computer controls these movements such that the extruded molten glass is selectively deposited to form a 3D glass object. The selective deposition of molten glass occurs inside an annealing kiln. The annealing kiln anneals the glass after it is extruded. In some cases, the actuators actuate the crucible kiln and nozzle to move in horizontal x, y directions and actuate the build platform to move in a z-direction. In some cases, fluid flows through a cavity or tubes adjacent to the nozzle tip, in order to cool the nozzle tip and thereby reduce the amount of glass that sticks to the nozzle tip.

A glass manufacturing apparatus includes an exit conduit positioned to deliver molten glass from a delivery vessel to an inlet conduit of a forming apparatus. The apparatus also includes a leak blocking component that circumferentially surrounds a portion of the exit conduit and is configured to inhibit flow of molten glass towards an outer surface of the glass manufacturing apparatus.

A glass manufacturing apparatus includes an exit conduit positioned to deliver molten glass from a delivery vessel to an inlet conduit of a forming apparatus. The apparatus also includes a leak blocking component that circumferentially surrounds a portion of the exit conduit and is configured to inhibit flow of molten glass towards an outer surface of the glass manufacturing apparatus.

A molten material furnace system having a liquid cooled flow control mechanism and method are disclosed. In particular, the flow control mechanism can include a needle including: a longitudinal axis; an outer conduit including an outer base end, an outer body, and an outer free end; an inner conduit including an inner base end, an inner body radially spaced from the outer body, an inner free end, and a central inlet passage extending between the inlet and the inner free end. Also disclosed is a needle control assembly to position the flow control needle relative to a stilling tank outlet orifice to control flow of molten material through the outlet orifice.

In illustrative implementations of this invention, a crucible kiln heats glass such that the glass becomes or remains molten. A nozzle extrudes the molten glass while one or more actuators actuate movements of the nozzle, a build platform or both. A computer controls these movements such that the extruded molten glass is selectively deposited to form a 3D glass object. The selective deposition of molten glass occurs inside an annealing kiln. The annealing kiln anneals the glass after it is extruded. In some cases, the actuators actuate the crucible kiln and nozzle to move in horizontal x, y directions and actuate the build platform to move in a z-direction. In some cases, fluid flows through a cavity or tubes adjacent to the nozzle tip, in order to cool the nozzle tip and thereby reduce the amount of glass that sticks to the nozzle tip.

In illustrative implementations of this invention, a crucible kiln heats glass such that the glass becomes or remains molten. A nozzle extrudes the molten glass while one or more actuators actuate movements of the nozzle, a build platform or both. A computer controls these movements such that the extruded molten glass is selectively deposited to form a 3D glass object. The selective deposition of molten glass occurs inside an annealing kiln. The annealing kiln anneals the glass after it is extruded. In some cases, the actuators actuate the crucible kiln and nozzle to move in horizontal x, y directions and actuate the build platform to move in a z-direction. In some cases, fluid flows through a cavity or tubes adjacent to the nozzle tip, in order to cool the nozzle tip and thereby reduce the amount of glass that sticks to the nozzle tip.