A mixed raw material for a glass of the present invention is a mixed raw material for a silicate glass, including at least a silica sand and a feldspar, in which with respect to the silica glass, a D.sub.50 value is 100 m or more and 300 m or less, the uniformity represented by a value obtained by dividing a D.sub.60 value by a D.sub.10 value is less than 2.0, and with respect to the feldspar, a D.sub.50 value of is 100 m or more and 400 m or less, and the uniformity represented by a value obtained by dividing a D.sub.60 value by a D.sub.10 value is 1.5 or more and less than 4.0. The mixed raw material for a silicate glass is melted and formed into a tube shape.

A mixed raw material for a glass of the present invention is a mixed raw material for a silicate glass, including at least a silica sand and a feldspar, in which with respect to the silica glass, a D.sub.50 value is 100 m or more and 300 m or less, the uniformity represented by a value obtained by dividing a D.sub.60 value by a D.sub.10 value is less than 2.0, and with respect to the feldspar, a D.sub.50 value of is 100 m or more and 400 m or less, and the uniformity represented by a value obtained by dividing a D.sub.60 value by a D.sub.10 value is 1.5 or more and less than 4.0. The mixed raw material for a silicate glass is melted and formed into a tube shape.

To provide high-strength granules having a broad range of applications of the glass composition, and a method for their production. The method for producing glass raw material granules comprises mixing and granulating a glass raw material composition with water, wherein the glass raw material composition contains at least silica and an aluminum source, and the aluminum source contains hydraulic alumina.

Disclosed herein are methods for making glass, comprising forming a slurry comprising at least one fining agent; adjusting the pH of the slurry to a value ranging from about 3 to about 12; combining the slurry with glass batch materials to form a batch composition; and melting the batch composition. Methods for reducing agglomerates in a glass melt are also disclosed herein. Further disclosed herein are systems for making glass, the systems comprising a pre-mixing vessel for preparing a slurry comprising at least one fining agent; an ultrasonic vessel for applying ultrasonic energy to the slurry; a mixing vessel for combining the slurry with glass batch materials to form a batch composition; and a melting vessel for melting the batch composition.

Disclosed herein are methods for making glass, comprising forming a slurry comprising at least one fining agent; adjusting the pH of the slurry to a value ranging from about 3 to about 12; combining the slurry with glass batch materials to form a batch composition; and melting the batch composition. Methods for reducing agglomerates in a glass melt are also disclosed herein. Further disclosed herein are systems for making glass, the systems comprising a pre-mixing vessel for preparing a slurry comprising at least one fining agent; an ultrasonic vessel for applying ultrasonic energy to the slurry; a mixing vessel for combining the slurry with glass batch materials to form a batch composition; and a melting vessel for melting the batch composition.

A pelletized expanded glass material is provided, which is particularly suitable as a growth support for microorganisms, especially for use in a biogas plant or an anaerobic sewage treatment plant. The production process of the invention for the pelletized expanded glass material contains the steps of: mixing a ground glass, an expanding agent and a binder to give a starting mixture. The starting mixture is pelletized to give ground glass pellet green bodies. The ground glass pellet green bodies are foamed to give expanded glass pellet particles at temperatures of 600 to 950 C. Accordingly, especially in the production of the starting mixture, minerals and or trace elements are added, which serve especially for the nutrient supply of microorganisms used in the biogas plant or the anaerobic sewage treatment plant.

A pelletized expanded glass material is provided, which is particularly suitable as a growth support for microorganisms, especially for use in a biogas plant or an anaerobic sewage treatment plant. The production process of the invention for the pelletized expanded glass material contains the steps of: mixing a ground glass, an expanding agent and a binder to give a starting mixture. The starting mixture is pelletized to give ground glass pellet green bodies. The ground glass pellet green bodies are foamed to give expanded glass pellet particles at temperatures of 600 to 950 C. Accordingly, especially in the production of the starting mixture, minerals and or trace elements are added, which serve especially for the nutrient supply of microorganisms used in the biogas plant or the anaerobic sewage treatment plant.

To provide a method for producing granules as glass raw material without using a binder that contains an alkali metal or boron. In the method, granules are produced by mixing a glass raw material composition and water. A method for producing granules to be used for the production of alkali-free glass, which comprises mixing a glass raw material composition and water, wherein the glass raw material composition essentially comprises an aluminum source containing calcium aluminate represented by CaO.2Al.sub.2O.sub.3, a calcium source containing one or both of calcium oxide and calcium hydroxide, and a silicon source.

The invention provides a method for producing composite nanoparticles, the method using a first compound capable of transitioning from a monoclinic to a tetragonal rutile crystal state upon heating, and having the steps of subjecting the first compound to a hydrothermal synthesis to create anisotropic crystals of the compound; encapsulating the first compound with a second compound to create a core-shell construct; and annealing the construct as needed. Also provided is a device for continuously synthesizing composite nanoparticles, the device having a first precursor supply and a second precursor supply; a mixer to homogeneously combine the first precursor and second precursor to create a liquor; a first microreactor to subject the liquor to hydrothermic conditions to create an\isotropic particles in a continuous operation mode; and a second microreactor for coating the particles with a third precursor to create a core-shell construct.

The invention provides a method for producing composite nanoparticles, the method using a first compound capable of transitioning from a monoclinic to a tetragonal rutile crystal state upon heating, and having the steps of subjecting the first compound to a hydrothermal synthesis to create anisotropic crystals of the compound; encapsulating the first compound with a second compound to create a core-shell construct; and annealing the construct as needed. Also provided is a device for continuously synthesizing composite nanoparticles, the device having a first precursor supply and a second precursor supply; a mixer to homogeneously combine the first precursor and second precursor to create a liquor; a first microreactor to subject the liquor to hydrothermic conditions to create an\isotropic particles in a continuous operation mode; and a second microreactor for coating the particles with a third precursor to create a core-shell construct.