With a method for detecting variables in an outlet of a metallurgical vessel, different variables in the outlet are detected or measured by at least one coil surrounding the outlet channel and/or an induction coil of an induction heater as a monitoring system, wherein the variables relate to the slag portion when pouring out the metal melt, wear condition of refractory parts in the outlet channel, the solidified metal melt, flow rate and/or plugging mass in the outlet channel. After evaluation, a closure element for the outlet is actuated, heating of the metal in the outlet channel is activated and/or renewal of the outlet channel is triggered. In this way, optimum operation in the pouring of metal melt out of a vessel is simply achieved, wherein occurrence of irregularities are detected during the entire pouring, and pouring out of slag can be successfully prevented at the end of the pouring.

Additive manufacturing apparatus for fabricating a three-dimensional object, the apparatus comprising: means for directing energy onto a growth surface of a workpiece to form thereon a liquid melt-pool; means for feeding additional material into the melt-pool so as to cause the additional material to become incorporated into the liquid of the melt-pool; and means for cryogenically cooling the liquid melt-pool, thereby to achieve a cooling rate of the liquid melt pool of at least 100 C. per second and to cause the liquid melt-pool to solidify.

Apparatus and methods for injecting molten filler material into a hole. The method in accordance with one embodiment comprises: drilling a hole in a composite layer; heating filler material comprising an electrically conductive low-melting alloy to a molten state; inserting a nozzle having an internal channel system into the hole with a gap separating the nozzle and the hole; forcing molten filler material into, through and out of the internal channel system of the nozzle and into the gap; and retracting the nozzle from the hole. The nozzle may be rotary or not rotary.

Slide closure unit on the spout of a metallurgical vessel, preferably a copper-anode furnace, includes a housing in which refractory closure plates, as well as at least one connecting refractory inner casing, are arranged. A removable induction heater is provided, having at least one induction coil surrounding the refractory inner casing outside of the housing. In this way, it is possible to constantly keep the melt located in the outlet channel of the spout sufficiently warm so that it does not freeze before and/or during the pouring of the melt, or that any frozen metal and/or slag can be melted in the spout.

Slide closure unit on the spout of a metallurgical vessel, preferably a copper-anode furnace, includes a housing in which refractory closure plates, as well as at least one connecting refractory inner casing, are arranged. A removable induction heater is provided, having at least one induction coil surrounding the refractory inner casing outside of the housing. In this way, it is possible to constantly keep the melt located in the outlet channel of the spout sufficiently warm so that it does not freeze before and/or during the pouring of the melt, or that any frozen metal and/or slag can be melted in the spout.

A system, method, and apparatus are provided for electrically shielding heated components, and more particularly, to electrically shielding electrically heated components in such a way as to be compatible with GFCI (ground fault circuit interrupter) protected circuits. Examples include an electrically shielded heated component including: a conductor, where the conductor is a heating element connected between a power line and a neutral line of a circuit from a GFCI; and a shield proximate the conductor and connected to the GFCI, where the shield receives a portion of current from the conductor and returns the portion of the current received to the GFCI.

A system, method, and apparatus are provided for electrically shielding heated components, and more particularly, to electrically shielding electrically heated components in such a way as to be compatible with GFCI (ground fault circuit interrupter) protected circuits. Examples include an electrically shielded heated component including: a conductor, where the conductor is a heating element connected between a power line and a neutral line of a circuit from a GFCI; and a shield proximate the conductor and connected to the GFCI, where the shield receives a portion of current from the conductor and returns the portion of the current received to the GFCI.

A cold crucible may include a plurality of fingers extending in an axial direction and arranged in a circumferential direction, and a slit between each pair of adjacent fingers. The cold crucible may also include at least one insert in each of the slits. The at least one insert may include a first component made of a soft magnetic composite material, and a second component made of a soft magnetic component.

A cold crucible may include a plurality of fingers extending in an axial direction and arranged in a circumferential direction, and a slit between each pair of adjacent fingers. The cold crucible may also include at least one insert in each of the slits. The at least one insert may include a first component made of a soft magnetic composite material, and a second component made of a soft magnetic component.

Provided herein is a system, apparatus, and method for producing refractory products, and more particularly, to producing heated refractories, passive refractories, transition plates, moldable refractories, and accessories such as heated spouts, heated pins, thimbles, and dams. A heated refractory channel as disclosed herein may include a working surface to contain molten metal within the channel; a core adjacent to the working surface; one or more heating elements disposed within the core; and insulation, where the core is disposed between the working surface and the insulation. The one or more heating elements may be molded into the core. The heating elements may be electrical resistance heating elements.