A method of forming a rope material from a loose feed scrap includes a number of operations to mechanically bind the loose feed scrap. The feed scrap is collected. The feed scrap is twisted and compressed, operations that may be performed simultaneously. This twisted and compressed feed scrap, now in the form of a rope material, is then fed into a melter system.

A method of and an arrangement for recycling mineral wool waste to mineral wool production includes at least one melting furnace for melting virgin mineral wool raw material, the melting furnace including an inlet for virgin mineral wool raw material and an outlet for molten mineral wool material, a production line connected to the outlet for molten mineral wool material for producing a mineral wool product from the molten mineral wool material. The production line includes a curing oven, a fluidized bed reactor including an exhaust gas duct, an inlet for predetermined primary fuel, an inlet for predetermined bed material, and an outlet for an ash material, the ash material including bottom ash discharged via a bottom outlet from the fluidized bed reactor or fly ash separated by a particle separator from exhaust gas in the exhaust gas duct or a mixture of the bottom ash and the fly ash.

A process for cullet beneficiation by precipitation. A mass of cullet is melted to form a body of molten glass having a heavy metal con ration of greater than 100 ppm. A precipitate agent is introduced into the body of molten glass to form a heavy metal-containing precipitate phase and a liquid beneficiated glass phase within the body of molten glass. The precipitate phase may have a density greater than that of the liquid beneficiated glass phase. Thereafter, the liquid beneficiated glass phase is physically separated from the precipitate phase. The separated liquid beneficiated glass phase has a reduced concentration of heavy metals, as compared to the concentration of heavy metals in the body of molten glass.

Provided are a vitrification equipment starting method and starting unit. The vitrification equipment starting method includes: preparing an ignition module; putting the ignition module into a chamber of a low-temperature melting furnace; and performing an ignition operation inside the chamber of the low-temperature melting furnace using the ignition module connected to a high-frequency heating unit outside the low-temperature melting furnace, wherein the ignition module is put into the chamber of the low-temperature melting furnace in an initial state before a form thereof is changed and, when put into the chamber of the low-temperature melting furnace, becomes a variable state in which the form thereof is changed from the initial state and performs the ignition operation.

Methods and systems include melting or augmenting a melt rate of material in a melter using electromagnetic radiation with a frequency between 0.9 GHz and 10 GHz. In some examples, a power and/or frequency of radiation used may be selected so as to control a temperature of a cold cap in the melter while maintaining emissions from the melter below a threshold level. In this manner, examples described herein may provide for efficient and safe melting and vitrification of radioactive wastes.

A method of and an arrangement for recycling mineral wool waste to mineral wool production includes at least one melting furnace for melting virgin mineral wool raw material, the melting furnace including an inlet for virgin mineral wool raw material and an outlet for molten mineral wool material, a production line connected to the outlet for molten mineral wool material for producing a mineral wool product from the molten mineral wool material. The production line includes a curing oven, a fluidized bed reactor including an exhaust gas duct, an inlet for predetermined primary fuel, an inlet for predetermined bed material, and an outlet for an ash material, the ash material including bottom ash discharged via a bottom outlet from the fluidized bed reactor or fly ash separated by a particle separator from exhaust gas in the exhaust gas duct or a mixture of the bottom ash and the fly ash.

A fabrication method of a mass-produced glass containers with visible light shielding using recovered post-consumer glass, the method comprising obtaining successive batches of raw material for glass manufacture, each batch including between 80% and 100% by weight of a mixture of pieces of soda-lime-silica recovered post-consumer glass with a heterogeneous chromatic composition predominantly transparent; mixing to the successive batches of raw material visible light shielding additives including at least cobalt oxide, nickel oxide, manganese oxide, chromium oxide and iron oxide; melting the successive batches of raw material and automatically manufacturing therewith the mass-produced glass containers with a glass thickness of at least 2 mm through an automatic blow molding process; automatically detecting and rejecting manufactured containers with permeability against visible light between 450 nm and 680 nm wavelength above 3% or above 1%.

A method for melting vitrifiable materials to produce flat glass, including: providing a furnace including: a melting tank, a fining tank, a neck, at least one inlet means located at the melting tank, an outlet means located downstream of the fining tank, and at least one extraction means of a flue gas located at the at least one upstream zone; charging the vitrifiable materials including raw materials and cullet in the melting tank with the at least one inlet means; cullet pre-heating; melting the vitrifiable materials in the melting tank; fining the melt in the fining tank; flowing the melt from the fining tank to a working zone through the outlet means; and capturing CO.sub.2 from the flue gas.

Described herein is a method for combining waste-loaded zeolites and geopolymers with glass-forming components to produce materials with improved chemical durability and stability.

An apparatus for charging a heating element for heating a glass melt, to restart a vitrified melting furnace, during emergency stop of the vitrified melting furnace for vitrifying radioactive waste is disclosed. The apparatus for charging a heating element into a vitrified melting furnace according to the present invention comprises a main frame, a universal joint positioned at one end of the main frame, at least one heating element binding portion rotating by being connected to the universal joint, and a gripper positioned at an end of the heating element binding portion, gripping the heating element.