A method for waste-free production of mineral wool insulation material products, in which insulation material product is produced in a first production area in a plurality of processing steps and granular and fibrous production waste, produced during the storage and transportation of the mineral input materials and after the melt emerges from a cupola, electric arc, or gas-fired melting furnace, are accumulated, shredded and fed to an inductively heated melting furnace in a second production area. The extracted melt is processed with known processing steps to form an insulation material product. The granular and fibrous shredded production waste formed in the second production area is fed to the inductively heated melting furnace as a component of the feed material. Mineral input materials, such as basalt, dolomite and mineral wool waste, which do not originate in either production area, can also be fed to the inductively heated melting furnace.

A method for waste-free production of mineral wool insulation material products, in which insulation material product is produced in a first production area in a plurality of processing steps and granular and fibrous production waste, produced during the storage and transportation of the mineral input materials and after the melt emerges from a cupola, electric arc, or gas-fired melting furnace, are accumulated, shredded and fed to an inductively heated melting furnace in a second production area. The extracted melt is processed with known processing steps to form an insulation material product. The granular and fibrous shredded production waste formed in the second production area is fed to the inductively heated melting furnace as a component of the feed material. Mineral input materials, such as basalt, dolomite and mineral wool waste, which do not originate in either production area, can also be fed to the inductively heated melting furnace.

A melting furnace feedstock charger includes a charger conduit including an inlet to receive feedstock and an outlet at an outlet portion of the charger conduit to transmit feedstock, and an auger or other feedstock mover coupled to the charger conduit to convey feedstock in a direction from the inlet toward the outlet. A gate may be detachably coupled to the outlet portion of the charger conduit and configured to be coupled directly to a wall of a melting vessel. The auger may have a helical flight with an outer diameter of varying size. A stripper may be movably carried by the charger conduit and may include a stripping tool moved by an actuator with respect to the charger conduit to facilitate transmission of feedstock and/or to strip away clogged feedstock and/or molten material.

Apparatus, system, and method for blending batch and cullet at a predetermined cullet ratio for feeding to a furnace. It includes a first hopper for holding cullet; a second hopper for holding batch; feeder associated with the second hopper; a chamber positioned to receive cullet from the first hopper, an inlet spout configured to receive cullet from the first hopper so that cullet flood feeds into the chamber to keep it constantly filled with cullet up to its angle of repose, and an outlet spout; a chute positioned to receive batch from the feeder and extending into the chamber and having a chute outlet having a diameter equal to or larger than the outlet spout; a charger for receiving mixed batch and cullet from the chamber; and a controller operatively connected to the feeder and to the charger.

A melting furnace feedstock charger includes a charger conduit including an inlet to receive feedstock and an outlet at an outlet portion of the charger conduit to transmit feedstock, and an auger or other feedstock mover coupled to the charger conduit to convey feedstock in a direction from the inlet toward the outlet. A gate may be detachably coupled to the outlet portion of the charger conduit and configured to be coupled directly to a wall of a melting vessel. The auger may have a helical flight with an outer diameter of varying size. A stripper may be movably carried by the charger conduit and may include a stripping tool moved by an actuator with respect to the charger conduit to facilitate transmission of feedstock and/or to strip away clogged feedstock and/or molten material.

The melting method, wherein the unmelted charges form a pile 30 having a free surface 40 that is inclined relative to the vertical in the furnace 10; the unmelted charges are heated by means of flames 51, 52, 53 at a regulated power and momentum and are directed towards the free surface 40 in at least two directions 1, 2, 3 forming various acute angles 1, 2, 3 with the horizontal plane so that the flames 51, 52, 53 define impact zones 41, 42, 43 on the free surface 40 that are located over at least two different vertical levels h1, h2, h3.

The melting method, wherein the unmelted charges form a pile 30 having a free surface 40 that is inclined relative to the vertical in the furnace 10; the unmelted charges are heated by means of flames 51, 52, 53 at a regulated power and momentum and are directed towards the free surface 40 in at least two directions 1, 2, 3 forming various acute angles 1, 2, 3 with the horizontal plane so that the flames 51, 52, 53 define impact zones 41, 42, 43 on the free surface 40 that are located over at least two different vertical levels h1, h2, h3.

The melting method, wherein the unmelted charges form a pile 30 having a free surface 40 that is inclined relative to the vertical in the furnace 10; the unmelted charges are heated by means of flames 51, 52, 53 at a regulated power and momentum and are directed towards the free surface 40 in at least two directions 1, 2, 3 forming various acute angles 1, 2, 3 with the horizontal plane so that the flames 51, 52, 53 define impact zones 41, 42, 43 on the free surface 40 that are located over at least two different vertical levels h1, h2, h3.

The melting method, wherein the unmelted charges form a pile 30 having a free surface 40 that is inclined relative to the vertical in the furnace 10; the unmelted charges are heated by means of flames 51, 52, 53 at a regulated power and momentum and are directed towards the free surface 40 in at least two directions 1, 2, 3 forming various acute angles 1, 2, 3 with the horizontal plane so that the flames 51, 52, 53 define impact zones 41, 42, 43 on the free surface 40 that are located over at least two different vertical levels h1, h2, h3.

A mixture of biomass and vitrifiable raw material for introducing into a fuel combustion furnace for the melting of a vitrifiable inorganic material, such as glass or rock or a silicate, includes an oleaginous biomass, the use of which reduces the damage to the equipment for metering and transporting the vitrifiable raw material.