Abstract: The present invention is a method for manufacturing a titanium ingot (30), the method being characterized by comprising: a step of melting a titanium alloy for a predetermined time by cold crucible induction melting (CCIM); a step of supplying molten titanium (6) to a cold hearth (10), and separating high density inclusions (HDIs) (8) by precipitation in the cold hearth (10) while spraying a plasma jet or an electron beam onto the bath surface of the molten titanium (6); and a step of supplying a molten titanium starting material from which the HDIs (8) are separated by precipitation to a mold (20) to obtain the titanium ingot.

Abstract: The present invention is a method for manufacturing a titanium ingot (30), the method being characterized by comprising: a step of melting a titanium alloy for a predetermined time by cold crucible induction melting (CCIM); a step of supplying molten titanium (6) to a cold hearth (10), and separating high density inclusions (HDIs)(8) by precipitation in the cold hearth (10) while spraying a plasma jet or an electron beam onto the bath surface of the molten titanium (6); and a step of supplying a molten titanium starting material from which the HDIs (8) are separated by precipitation to a mold (20) to obtain the titanium ingot.

Abstract: The present invention provides an electron-beam furnace and a melting method that, in producing an ingot by melting a metal with an electron beam, can suppress the contamination of new impurities in the ingot production, are less likely to again result in inclusion of once evaporated impurities from a molten metal pool within a hearth or a mold, and can be improved in utilization rate. The electron-beam furnace for melting a refractory metal includes a feeder unit for raw materials, a melting unit for raw materials, which is connected to the feeder unit for raw materials and, at the same time, is defined by a furnace wall and a ceiling wall, and includes at least a hearth, a water-cooled mold, and an electron gun, and an evacuation unit for exhaust gas connected to the melting unit for raw materials.

Abstract: A refining apparatus for scrap silicon using an electron beam which is suitable for recycling of scrap silicon which is formed during the manufacture of silicon products such as silicon wafers includes a vacuum chamber, a crucible installed within the vacuum chamber, a hearth which is installed next to the crucible within the vacuum chamber and which receives granular scrap silicon and which melts granular silicon by irradiation with an electron beam and which supplies molten silicon to the crucible, and a raw material supply apparatus which is installed within the vacuum chamber and which stores a prescribed amount of granular scrap silicon and supplies the stored granular scrap silicon via a chute.

Abstract: A method and apparatus for optimizing melting of titanium for processing into ingots or end products. The apparatus provides a main hearth, a plurality of optional refining hearths, and a plurality of casting molds or direct molds whereby direct arc electrodes melt the titanium in the main hearth while plasma torches melt the titanium in the refining chambers and/or adjacent the molds. Each of the direct arc electrodes and plasma torches is extendable and retractable into the melting environment and moveable in a circular pivoting or side to side linear motion.

Abstract: A method for hearthless processing of a solid metallic material consisting essentially of titanium or other metal or alloy thereof which includes providing a solid metal block having a processing surface and a base surface and consisting essentially of titanium or a metal, forming a pool of molten metal on the processing surface of the solid metal block provided in step, adding the metallic material to be processed to the pool of molten metal formed in step, and melting the metallic material to be processed, and removing metallic material melted in step from the pool of molten metal.

Abstract: The invention concerns a method for heating a metal melt, in particular molten steel covered with a casting powder, introduced via a submerged outlet into an ingot mould of a continuous casting plant. In order to ensure uniform heat dissipation over the ingot mould and constant frictional forces between the latter and the casting shell, the heat energy is introduced at given points into the surface of the melt bath and the heat energy point on the surface of the melt bath is brought to a predetermined line.

Abstract: An apparatus and method for forming round wire from non-round wire has: a heat extracting drum having a semi-circular channel formed in and entirely around its outer circumferential surface; a feed device for directing a precursor wire into the channel; and a heater for melting the precursor wire in the channel. The wire is typically flat and is stood up on edge, perpendicular to the surface of the drum, melted with the heater, solidified and removed. The surface tension and wetting characteristics of the liquid metal cause it to "bead up", forming a near round wire when solidified.

Abstract: In the representative embodiment described in the specification, an electron beam furnace has an evacuation system which maintains the interior of the furnace at a pressure in the range from about 50 microns Hg to 300 microns Hg. The relatively high pressure reduces degassing time from a cold start, suppresses volatilization of constituents of metal being refined, and causes volatilized metal to condense in powder form on a condensing screen. A vibrator assists in removing the powder from the condensing screen. The electron beam gun has a series of compartments which are individually evacuated to maintain the pressure in the compartment containing the cathode at a level less than about 1 micron Hg.

Abstract: In the embodiments described in the specification, continuous casting of ingots is carried out by transferring molten metal from a hearth to a mold through one or more flow channels which provide flow paths having a shallow angle to the horizontal and which terminates adjacent to the surface of the molten metal in the mold so that the vertical velocity component of the stream of molten metal flowing into the mold is minimal and the horizontal velocity component is low. In one form, the hearth surrounds the mold, providing four shallow-angle flow channels uniformly spaced around the periphery of the mold to avoid unilateral introduction of the molten material into the mold.

Abstract: In the particular embodiment of an electron beam furnace arrangement described in the specification, an electron beam gun unit is supported on rails for motion between two hearth and casting units, each having a lid to seal the unit when the electron beam gun unit is not in place. Sealing covers are also provided for the molds associated with the casting units. A common pump, preheating and hearth cooling unit communicates with each of the hearth and casting units so that, when one of the hearth and casting units is in use, the other unit can be cleaned and maintained and then outgassed and preheated in preparation for transfer of the electron beam gun unit from the other hearth and casting unit.

Abstract: Melting furnace (1) for the production of strand-cast ingots (17, 18) in a protective gas atmosphere, has a charging apparatus (8) for feeding starting material (11) into a melting area (14). Within a melting chamber provided with a chamber floor (2d) and at least one energy source (4,5) there is situated a strand-casting mold (15) for the transformation of the melt to an ingot (17, 18) and underneath the strand-casting mold is disposed an offbearing apparatus (25) for offbearing the ingot, and an offbearing chamber enveloping the ingot and the offbearing apparatus. To solve the problem of operating such a melting furnace virtually continuously, the strand-casting mold (15) together with at least one additional strand-casting mold (16) is disposed in the chamber flow (2d) in such a manner that each of the strand-casting molds (15, 16) can be brought into the drop path of the melt by a preferably horizontal relative movement.

Abstract: In the particular embodiment of an electron beam cold hearth refining arrangement described in the specification, two separate hearth segments are disposed at right angles to each other and raw material is supplied to a melt area at the end of the first hearth segment remote from the second hearth segment. Molten material is poured from the opposite end of the first hearth segment into the adjacent end of the second hearth segment and refined molten material is poured into a mold from the opposite end of the second hearth segment. To prevent spattering of unrefined material into the mold or the adjacent refining area of the second hearth segment a baffle is positioned in the angle between the two mold segments.

Abstract: Metal particles are remelted in a fusion zone by electron beam bombardment and formed in a continuous casting mould. Furthermore,(a) the metal particles are evenly distributed over the horizontally positioned floor of a fusion ladle,(b) the metal particles are joined together into a plate-shaped structure by means of the electron beam, whereafter(c) the floor of the fusion ladle is moved into a position inclined in relation to the horizontal,(d) the electron beam is guided upwards over the sloping, plate-shaped particle structure so that this is firstly preheated and fused directly thereafter, while(e) the molten metal running over the lower part of the floor is simultaneously kept liquid by electron beam bombardment, whereafter(f) the electron beam is guided back downwards over the sloping floor of the fusion ladle, and(g) the floor of the fusion ladle is returned to the horizontal starting position and is once again charged with metal particles according to feature (a).

Abstract: In the particular embodiment of an electron beam cold hearth refining arrangement described in the specification, two separate hearth segments are disposed at right angles to each other and raw material is supplied to a melt area at the end of the first hearth segment remote from the second hearth segment. Molten material is poured from the opposite end of the first hearth segment into the adjacent end of the second hearth segment and refined molten material is poured into a mold from the opposite end of the second hearth segment. To prevent spattering of unrefined material into the mold or the adjacent refining area of the second hearth segment a baffle is positioned in the angle between the two mold segments.