Systems and associated methods are provided for controlling the shape of an ingot head during formation. At the end of a cast, prior to forming the ingot head, chill bars or other cooling structure may be lowered into an ingot mold and define a reduced casting footprint for forming the ingot head. Supplemental molten metal may be fed into the reduced casting footprint, and the chill bars may be moved laterally towards the center of the ingot, further reducing the casting footprint. As additional molten metal fills the reduced mold footprint, the ingot may be lowered relative to the chill bars to further increase the height of the ingot head. Additional molten metal may be added until the desired shape of the ingot head is formed.

A method for obtaining a product made of titanium alloy or a titanium-aluminum intermetallic compound by plasma torch melting, the alloy having an oriented structure, the method including heating the molten alloy surface in a casting ring with a plasma torch; cooling a cold zone of the casting ring over a length L1, the cooling forming a semi-solid crown of alloy; heating a hot zone of the casting ring over a length L2, thereby forming a solidification front, the flatness of which relative to a plane perpendicular to a drawing direction is less than 10?; and drawing the solidified alloy at a speed of more than 10.sup.?4 m/s in the drawing direction. The present disclosure also relates to a plant having one or more devices for implementing the method.

A method for obtaining a product made of titanium alloy or a titanium-aluminum intermetallic compound by plasma torch melting, the alloy having an oriented structure, the method including heating the molten alloy surface in a casting ring with a plasma torch; cooling a cold zone of the casting ring over a length L1, the cooling forming a semi-solid crown of alloy; heating a hot zone of the casting ring over a length L2, thereby forming a solidification front, the flatness of which relative to a plane perpendicular to a drawing direction is less than 10?; and drawing the solidified alloy at a speed of more than 10.sup.?4 m/s in the drawing direction. The present disclosure also relates to a plant having one or more devices for implementing the method.

A device for the production of a metallic strip using a rapid solidification technology is provided. The device includes a movable heat sink with an external surface onto which a melt is poured and on which the melt solidifies to produce the strip, and which device includes a rolling device which can be pressed against the external surface of the movable heat sink while the heat sink is in motion.

A device for the production of a metallic strip using a rapid solidification technology is provided. The device includes a movable heat sink with an external surface onto which a melt is poured and on which the melt solidifies to produce the strip, and which device includes a rolling device which can be pressed against the external surface of the movable heat sink while the heat sink is in motion.

A device for the production of a metallic strip using a rapid solidification technology is specified, which device includes a movable heat sink with an external surface onto which a melt is poured and on which the melt solidifies to produce the strip, and which device includes a rolling device which can be pressed against the external surface of the movable heat sink while the heat sink is in motion.

A device for the production of a metallic strip using a rapid solidification technology is specified, which device includes a movable heat sink with an external surface onto which a melt is poured and on which the melt solidifies to produce the strip, and which device includes a rolling device which can be pressed against the external surface of the movable heat sink while the heat sink is in motion.

A device for the production of a metallic strip using a rapid solidification technology is specified, which device includes a movable heat sink with an external surface onto which a melt is poured and on which the melt solidifies to produce the strip, and which device includes a rolling device which can be pressed against the external surface of the movable heat sink while the heat sink is in motion.

An R, R, C method and equipment for continuously casting amorphous, ultra-microcrystalline, microcrystalline and the like, metal profiles is provided. A working chamber of an exhaust hood with a powerful exhaust hood, and a working cold source of liquid nitrogen at a temperature of t=190 C. and a pressure of p=1.877 bar are used. The working chamber of exhaust hood is located at the outlet of hot mold, and only air is contained therein in addition to slabs or profiles that are pulled out, without any device or equipment. A traction mechanism pulls metal slabs or profiles out from the outlet of cross section of hot mold. A liquid nitrogen ejector ejects liquid nitrogen to the metal slabs or profiles of different brands and specifications at a liquid nitrogen ejection volume of liquid nitrogen V, an ejection speed of liquid nitrogen K and a thickness of liquid nitrogen ejection layer h.

An R, R, C method and equipment for continuously casting amorphous, ultra-microcrystalline, microcrystalline and the like, metal profiles is provided. A working chamber of an exhaust hood with a powerful exhaust hood, and a working cold source of liquid nitrogen at a temperature of t=190 C. and a pressure of p=1.877 bar are used. The working chamber of exhaust hood is located at the outlet of hot mold, and only air is contained therein in addition to slabs or profiles that are pulled out, without any device or equipment. A traction mechanism pulls metal slabs or profiles out from the outlet of cross section of hot mold. A liquid nitrogen ejector ejects liquid nitrogen to the metal slabs or profiles of different brands and specifications at a liquid nitrogen ejection volume of liquid nitrogen V, an ejection speed of liquid nitrogen K and a thickness of liquid nitrogen ejection layer h.