Provided is a glass product manufacturing apparatus. The glass product manufacturing apparatus includes a furnace including a gas heating zone and an electric heating zone, a first heat exchange module configured to recover heat from the furnace, and a pump configured to drive flow of a heat transfer medium fluid passing through the first heat exchange module, wherein at least a part of the first heat exchange module is thermally coupled with at least a part of an external surface of the electric heating zone. The glass product manufacturing apparatus may reduce defect rate while exhibiting high energy efficiency.

Provided is a glass manufacturing method in which temperature can be easily increased and decreased at a high speed and in which the productivity can be improved. A glass manufacturing method according to an embodiment of the present invention includes the steps of: making a melt 11 by melting a raw material disposed in a container 1; obtaining a glass by cooling the melt 11, in which the raw material contains a metal, and in the step of making the melt 11 from the raw material, the raw material is induction-heated.

A glass fining system, glass fining device, and method are disclosed. The glass fining device in accordance with one aspect of the disclosure includes at least one heated orifice through which molten glass flows from a glass melter to produce at least one superheated glass stream; and a low-pressure chamber disposed downstream from the heated orifice, where the at least one superheated glass stream flows from the at least one heated orifice and into the low-pressure chamber, and where the low-pressure chamber surrounds the at least one superheated glass stream. In some embodiments, the low-pressure chamber may include at least one surface extender.

A glass fining system, glass fining device, and method are disclosed. The glass fining device in accordance with one aspect of the disclosure includes at least one heated orifice through which molten glass flows from a glass melter to produce at least one superheated glass stream; and a low-pressure chamber disposed downstream from the heated orifice, where the at least one superheated glass stream flows from the at least one heated orifice and into the low-pressure chamber, and where the low-pressure chamber surrounds the at least one superheated glass stream. In some embodiments, the low-pressure chamber may include at least one surface extender.

A glass article manufacturing system (10) includes a crucible (38) that defines a barrel (46) and a nozzle (54). The barrel (46) accepts a glass feedstock (62). A heater 66 is in thermal communication with the nozzle (54). The heater 66 heats the feedstock (62) within the nozzle (54). An actuator (22) is positioned proximate the barrel (46) and extrudes the feedstock (62) through the nozzle (54) as extruded feedstock.

The invention is a microwave gun and arc plasma torch furnace used to refine titanium, Ti, from titanium dioxide, TiO.sub.2, powder. The furnace includes high frequency microwave emitters that create a high temperature zone strongly vibrating the titanium dioxide powder, TiO.sub.2, and lengthening and weakening the valence bonds in the titanium dioxide powder, TiO.sub.2, titanium, Ti, and oxygen, O, atoms. The furnace also uses nitrogen arc plasma torch generators to generate a N.sup.+ plasma to completely disassociate the titanium, Ti, and oxygen, O, atoms into titanium ions, Ti.sup.+ and oxygen ions, O.sup., and permitting the formation of nitrogen dioxide, NO.sub.2, and melted titanium, Ti.

An optimized gasification/vitrification processing system having a gasification unit which converts organic materials to a hydrogen rich gas and ash in communication with a joule heated vitrification unit which converts the ash formed in the gasification unit into glass, and a plasma which converts elemental carbon and products of incomplete combustion formed in the gasification unit into a hydrogen rich gas.

Methods and apparatus for producing fibers from igneous rock, including basalt include heating igneous rock by electrical conductive coils to achieve an homogenous melt and forming homogenous fibers from the melt.

This disclosure relates to fabrication of quartz hollow cylinder with reduced bubbles using atmospheric control. An example horizontal rotating arc furnace includes a housing, supports, and a rotary union. The housing defines an interior configured to receive silica particles and electrodes that generate a plasma arc and includes a plurality of first ports on an exterior of the housing fluidly connected to the interior and supply pipes fluidly coupled to the first ports. The supports mechanically couple the housing to a drive system to provide rotational motion to the housing. The rotary union is coupled to the housing includes second ports to fluidly connect to a vacuum supply. The second ports are fluidly connected to the first ports via the supply pipes. The horizontal rotating arc furnace is configured to apply a vacuum to the interior of the housing via the first ports when the housing is spinning.

A glass ceramic containing lithium-ions and having a garnet-like main crystal phase having an amorphous proportion of at least 5% is disclosed. The garnet-like main crystal phase preferably has the chemical formula Li.sub.7+xyM.sub.x.sup.IIM.sub.3x.sup.IIIM.sub.2y.sup.IVM.sub.y.sup.VO.sub.12, wherein M.sup.II is a bivalent cation, M.sup.III is a trivalent cation, M.sup.IV is a tetravalent cation, M.sup.V is a pentavalent cation. The glass ceramic is prepared by a melting technology preferably within a Skull crucible and has an ion conductivity of at least 5.Math.10.sup.5 S/cm, preferably of at least 1.Math.10.sup.4 S/cm.