A metal melting apparatus capable of providing a clear melt with little oxides, even when either one or a mixture of scrap material and fresh material is supplied. Solution is provided by a metal melting apparatus including melting chamber to which a melt raw material is supplied, and gas injection system for injecting gas into melt in the melting chamber to generate a vortex of melt in the melting chamber.

A slag discharge door device for an electric furnace is provided. The device prevents slag from flowing out via a slag discharge port by making a discharge control door body move up and down to and from the upper surface of a supporting body where slag is discharged by flowing to the upper surface, and the discharge of slag is controlled, such that during steel-making work in the electric furnace, the outflow of slag is prevented and heat losses are reduced, the efficiency of arc heat due to the formation of foamed slag is increased, and valuable metals are recovered from the molten slag thereby increasing the percentage of molten steel recovered.

A slag discharge door device for an electric furnace is provided. The device prevents slag from flowing out via a slag discharge port by making a discharge control door body move up and down to and from the upper surface of a supporting body where slag is discharged by flowing to the upper surface, and the discharge of slag is controlled, such that during steel-making work in the electric furnace, the outflow of slag is prevented and heat losses are reduced, the efficiency of arc heat due to the formation of foamed slag is increased, and valuable metals are recovered from the molten slag thereby increasing the percentage of molten steel recovered.

A method of tapping a steelmaking furnace comprised of determining a desired level of steel to be attained in a ladle, and calculating the weight of molten steel that will be present when the desired level is attained following a transfer of molten steel from the furnace to the ladle. The furnace is operated such that slag is formed on top of molten steel contained therein. The furnace is moved to a first position to cause transfer of molten steel to the ladle to begin. The transfer of molten steel from the furnace to the ladle is continued, and at the first occurrence of molten steel attaining the desired level in the ladle, molten steel attaining a maximum allowable weight in the ladle, or an excessive amount of slag being present upon the molten steel in the ladle, transfer of molten steel to the ladle is ceased.

A method of tapping a steelmaking furnace comprised of determining a desired level of steel to be attained in a ladle, and calculating the weight of molten steel that will be present when the desired level is attained following a transfer of molten steel from the furnace to the ladle. The furnace is operated such that slag is formed on top of molten steel contained therein. The furnace is moved to a first position to cause transfer of molten steel to the ladle to begin. The transfer of molten steel from the furnace to the ladle is continued, and at the first occurrence of molten steel attaining the desired level in the ladle, molten steel attaining a maximum allowable weight in the ladle, or an excessive amount of slag being present upon the molten steel in the ladle, transfer of molten steel to the ladle is ceased.

A kit enables selective circulation and transfer of molten metal of a furnace. The kit includes a transfer block of refractory material adapted to be disposed downstream of a refractory pump wall of a pump well. The block includes a transfer passageway that extends from alignment with an opening in the pump wall toward an exterior vessel outside the furnace. A support structure can be adapted to be fixed over the furnace. Pulleys can be carried by the support structure. An actuator can be positioned outside of the furnace. A cable can be fastened at one end portion to the transfer block and at another end portion to the actuator and extends around the pulleys. When actuated in one stroke the actuator moves the cable so as to move the block upward out of alignment with the pump wall opening to cause molten metal circulation. When actuated in another stroke the actuator moves the cable to permit the transfer block to move downward into alignment with the pump wall opening to carry out transfer of molten metal to the vessel. Also featured is a furnace including a kit or a selective transfer and circulation device, and a method of installing the kit or device in a furnace.

A kit enables selective circulation and transfer of molten metal of a furnace. The kit includes a transfer block of refractory material adapted to be disposed downstream of a refractory pump wall of a pump well. The block includes a transfer passageway that extends from alignment with an opening in the pump wall toward an exterior vessel outside the furnace. A support structure can be adapted to be fixed over the furnace. Pulleys can be carried by the support structure. An actuator can be positioned outside of the furnace. A cable can be fastened at one end portion to the transfer block and at another end portion to the actuator and extends around the pulleys. When actuated in one stroke the actuator moves the cable so as to move the block upward out of alignment with the pump wall opening to cause molten metal circulation. When actuated in another stroke the actuator moves the cable to permit the transfer block to move downward into alignment with the pump wall opening to carry out transfer of molten metal to the vessel. Also featured is a furnace including a kit or a selective transfer and circulation device, and a method of installing the kit or device in a furnace.

In an electric arc furnace system for making steel, a method and structure (1) for eliminating teeming hang-ups and ensuring temperature homogeneity in a ladle which teems into an ingot mold by gas purging at all possible steps under both atmospheric and vacuum conditions, and (2) for preventing non-metallic inclusions from appearing in the final product by deflecting the granular material in the teeming ladle well block away from the ingot mold by a heat resistant but combustible deflector just prior to entry of the teeming stream into the ingot mold.

In an electric arc furnace system for making steel, a method and structure (1) for eliminating teeming hang-ups and ensuring temperature homogeneity in a ladle which teems into an ingot mold by gas purging at all possible steps under both atmospheric and vacuum conditions, and (2) for preventing non-metallic inclusions from appearing in the final product by deflecting the granular material in the teeming ladle well block away from the ingot mold by a heat resistant but combustible deflector just prior to entry of the teeming stream into the ingot mold.

A casting system, apparatus, and method. The casting system can include an energy source and a hearth, which can have a tapered cavity. The tapered cavity can have a first end portion and a second end portion, and the tapered cavity can narrow between the first and second end portions. Further, the tapered cavity can have an inlet at the first end portion that defines an inlet capacity, and one or more outlets at the second end portion that define an outlet capacity. Where the cavity has a single outlet, the outlet capacity can be less than the inlet capacity. Where the cavity has multiple outlets, the combined outlet capacity can match the inlet capacity. Further, the cross-sectional area of the tapered cavity near the inlet can be similar to the cross-sectional area of the inlet.