A method of stirring and apparatus for stirring are provided. The method includes: a) providing a number of electromagnetic stirrer units, each stirrer unit being moveably mounted on a stirrer support carriage; b) providing a number of locations at which stirring is to be provided by a stirrer unit; c) providing stirring at a first location from amongst the number of locations using a stirrer unit; d) providing stirring at a second location from amongst the number of locations using the same stirrer unit, the second location being different to the first location; and wherein the stirrer unit has a first position relative to the stirrer support carriage during movement between the first location and the second location and the stirrer unit has a second position relative to the stirrer support carriage at the first location and at the second location during stirring. The method allows the stirring unit to be readily conveyed between the locations, whilst also allowing the stirring unit to be optimally positioned for the provision of stirring.

A method of stirring and apparatus for stirring are provided. The method includes: a) providing a number of electromagnetic stirrer units, each stirrer unit being moveably mounted on a stirrer support carriage; b) providing a number of locations at which stirring is to be provided by a stirrer unit; c) providing stirring at a first location from amongst the number of locations using a stirrer unit; d) providing stirring at a second location from amongst the number of locations using the same stirrer unit, the second location being different to the first location; and wherein the stirrer unit has a first position relative to the stirrer support carriage during movement between the first location and the second location and the stirrer unit has a second position relative to the stirrer support carriage at the first location and at the second location during stirring. The method allows the stirring unit to be readily conveyed between the locations, whilst also allowing the stirring unit to be optimally positioned for the provision of stirring.

A method for ironmaking by smelting reduction in a stir-generated vortex includes: (1) placing a pig iron in an induction furnace, and then heating the pig iron to a molten state to form a molten iron, and maintaining the molten iron to be greater than or equal to 1450 C.; (2) stirring a center of the molten iron to form a vortex with a height-to-diameter ratio of 0.5-2.5, and continuously performing stirring; (3) mixing and grinding on an iron-containing mineral, a reducing agent and a slag-forming agent in a mass ratio of 1:(0.1-0.15):(0.25-0.4) to obtain a powder mixture, spraying and blowing the powder mixture to a center of the vortex, performing a reduction reaction, and stopping the stirring after the molten iron and molten slags are obtained, wherein a waste gas is produced; and (4) discharging the molten iron and the molten slags respectively, and exhausting a treated waste gas.

A method for ironmaking by smelting reduction in a stir-generated vortex includes: (1) placing a pig iron in an induction furnace, and then heating the pig iron to a molten state to form a molten iron, and maintaining the molten iron to be greater than or equal to 1450 C.; (2) stirring a center of the molten iron to form a vortex with a height-to-diameter ratio of 0.5-2.5, and continuously performing stirring; (3) mixing and grinding on an iron-containing mineral, a reducing agent and a slag-forming agent in a mass ratio of 1:(0.1-0.15):(0.25-0.4) to obtain a powder mixture, spraying and blowing the powder mixture to a center of the vortex, performing a reduction reaction, and stopping the stirring after the molten iron and molten slags are obtained, wherein a waste gas is produced; and (4) discharging the molten iron and the molten slags respectively, and exhausting a treated waste gas.

An apparatus comprising an induction furnace with a thermally and electrically conductive or non-conductive crucible containing an electrically conductive ferrous or non-ferrous material is provided with at least one bottom induction coil, one side induction coil and one top induction coil disposed exteriorly around the bottom, side and over the top surface of the material in the conductive or non-conductive crucible to provide a non-contact temperature boost or a flow rate boost to the material by selectively energizing a combination of the coils. The induction furnace is particularly useful for electrically conductive materials having a relatively low value of thermal conductivity, such as aluminum or an aluminum alloy.

An apparatus comprising an induction furnace with a thermally and electrically conductive or non-conductive crucible containing an electrically conductive ferrous or non-ferrous material is provided with at least one bottom induction coil, one side induction coil and one top induction coil disposed exteriorly around the bottom, side and over the top surface of the material in the conductive or non-conductive crucible to provide a non-contact temperature boost or a flow rate boost to the material by selectively energizing a combination of the coils. The induction furnace is particularly useful for electrically conductive materials having a relatively low value of thermal conductivity, such as aluminum or an aluminum alloy.

This invention relates to the field of 3D metal printing, and more particularly to a method of rapidly melting metal for 3D metal printers by electromagnetic induction. This is a new cost-effective 3D metal printing method that enables direct heating and rapid melting of metals, higher energy conversion efficiency, higher deposition rates, smaller oxide, higher safety and controllability, faster printing, and larger-size metal components manufacturing.

This invention relates to the field of 3D metal printing, and more particularly to a method of rapidly melting metal for 3D metal printers by electromagnetic induction. This is a new cost-effective 3D metal printing method that enables direct heating and rapid melting of metals, higher energy conversion efficiency, higher deposition rates, smaller oxide, higher safety and controllability, faster printing, and larger-size metal components manufacturing.

A multi-section coil enhanced stirring system wherein only one of the coils is powered from a single-phase AC source to enhance the stirring of the metal.

Methods and apparatus for moving a molten metal are provided in which the electromagnetic inductor includes at least two pairs of electromagnetic pole pairs and in which a first magnetic field component is generated between one pole in a first electromagnetic pole pair and a second pole in a different electromagnetic pole pair, and in which a second magnetic field component is generated between the two poles in one or more electromagnetic pole pairs, the second magnetic field component thereby generating one or more eddy currents in the molten metal. Those eddy currents are generally parallel to the surface of the molten metal and so have greater magnitude and extent that eddy currents perpendicular to the surface. Such eddy currents provide useful additional movement to the molten metal, for instance for stirring purposes, particularly when the depth of molten metal is small.