Submerged combustion burners having improved fuel and oxidant mixing characteristics. Submerged combustion melters including the burners. Methods of using submerged combustion melters to melt glass-forming materials and produce molten glass.

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 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 glass manufacturing apparatus comprises at least one nozzle facing a conduit and extending transverse to a travel path defined by the conduit. The at least one nozzle is configured to cool molten material within the interior of the conduit with a stream of cooling fluid forced against an exterior of the conduit along a cooling axis extending transverse to the travel path defined by the conduit. In further examples, methods of processing molten material includes cooling the molten material within an interior of a conduit by forcing a stream of cooling fluid against an exterior of the conduit along a cooling axis extending transverse to a travel path defined by the conduit.

A glass manufacturing apparatus comprises at least one nozzle facing a conduit and extending transverse to a travel path defined by the conduit. The at least one nozzle is configured to cool molten material within the interior of the conduit with a stream of cooling fluid forced against an exterior of the conduit along a cooling axis extending transverse to the travel path defined by the conduit. In further examples, methods of processing molten material includes cooling the molten material within an interior of a conduit by forcing a stream of cooling fluid against an exterior of the conduit along a cooling axis extending transverse to a travel path defined by the conduit.

Methods, systems and apparatus for producing continuous basalt fibers, microfibers, and microspheres from high temperature melts are disclosed. A cold crucible induction furnace is used to super heat crushed basalt rock to form a melt. The melt is cooled prior to forming a fiber. The fiber produced from the superheated melt possesses superior properties not found with conventional basalt fibers produced in gas furnaces. In some implementations, the superheated melt is spun into continuous basalt fibers. In some implementations, the superheated melt is blown into microfibers and microspheres.

Provided is a molten glass transfer device (3), including: a transfer pipe (P) through which molten glass (Gm) flows; a retaining brick (14), which is arranged on an outer peripheral side of the transfer pipe (P), and retains the transfer pipe (P); and a casing (16), which accommodates the transfer pipe (P) and the retaining brick (14), and includes a space (15) defined by the retaining brick (14). A cooling device (18) configured to cool the casing (16) is provided.

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 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.

The present invention relates to a method for producing phase-separated glass, sequentially including a melting step of melting a glass, a phase separation step of separating phases in the glass, and a shaping step of shaping the glass, and to the phase-separated glass obtained by the production method.