A method of, and apparatus for, handling components for a sheet extrusion system including the steps of: obtaining a carriage configured to support different components each making up a part of a sheet extrusion system; placing a first of the different components in a supported staging position on the carriage; performing an operation on the first of the different components in the supported staging position to at least one of: a) transport the first of the different components; b) perform a maintenance step on the first of the different components; c) repair the first of the different components; or d) set the first of the different components up for installation; separating the first of the different components from the supported staging position on the carriage; and reconfiguring the carriage to maintain a second of the different components, that is different in configuration than the first of the different components, in a supported staging position on the carriage.

A method of, and apparatus for, handling components for a sheet extrusion system including the steps of: obtaining a carriage configured to support different components each making up a part of a sheet extrusion system; placing a first of the different components in a supported staging position on the carriage; performing an operation on the first of the different components in the supported staging position to at least one of: a) transport the first of the different components; b) perform a maintenance step on the first of the different components; c) repair the first of the different components; or d) set the first of the different components up for installation; separating the first of the different components from the supported staging position on the carriage; and reconfiguring the carriage to maintain a second of the different components, that is different in configuration than the first of the different components, in a supported staging position on the carriage.

An aluminum plate manufacturing method capable of achieving an enhancement in productivity through a reduction in the number of processes and a reduction in processing time is disclosed. In the aluminum plate manufacturing method, a plate is rolled after being extruded to a desired thickness. Accordingly, it is possible to reduce the number of processes and a processing time and, as such, achieving an enhancement in productivity, as compared to a conventional manufacturing process using only rolling.

An aluminum plate manufacturing method capable of achieving an enhancement in productivity through a reduction in the number of processes and a reduction in processing time is disclosed. In the aluminum plate manufacturing method, a plate is rolled after being extruded to a desired thickness. Accordingly, it is possible to reduce the number of processes and a processing time and, as such, achieving an enhancement in productivity, as compared to a conventional manufacturing process using only rolling.

A method for producing metal-based thin foils is provided, which includes the steps of extruding a metal through an extruder to form a preliminary foil, cooling the preliminary foil in a coolant bath, and rolling the preliminary foil in a rolling system containing at least two rollers to form a metal-based thin foil.

A method for producing metal-based thin foils is provided, which includes the steps of extruding a metal through an extruder to form a preliminary foil, cooling the preliminary foil in a coolant bath, and rolling the preliminary foil in a rolling system containing at least two rollers to form a metal-based thin foil.

A method for fabricating a non-planar magnet includes extruding a precursor material including neodymium iron boron crystalline grains into an original anisotropic neodymium iron boron permanent magnet having an original shape, wherein the original anisotropic neodymium iron boron permanent magnet has at least about 90 percent neodymium iron boron magnetic material by volume. The original anisotropic neodymium iron boron permanent magnet is heated to a deformation temperature. The original anisotropic neodymium iron boron permanent magnet is deformed into a reshaped anisotropic neodymium iron boron permanent magnet having a second shape substantially different from the original shape using heated tooling to apply a deformation load to the original anisotropic neodymium iron boron permanent magnet. The original anisotropic neodymium iron boron permanent magnet and the reshaped anisotropic neodymium iron boron permanent magnet each have respective magnetic moments substantially aligned with a respective local surface normal corresponding to the respective magnetic moment.

A method for fabricating a non-planar magnet includes extruding a precursor material including neodymium iron boron crystalline grains into an original anisotropic neodymium iron boron permanent magnet having an original shape, wherein the original anisotropic neodymium iron boron permanent magnet has at least about 90 percent neodymium iron boron magnetic material by volume. The original anisotropic neodymium iron boron permanent magnet is heated to a deformation temperature. The original anisotropic neodymium iron boron permanent magnet is deformed into a reshaped anisotropic neodymium iron boron permanent magnet having a second shape substantially different from the original shape using heated tooling to apply a deformation load to the original anisotropic neodymium iron boron permanent magnet. The original anisotropic neodymium iron boron permanent magnet and the reshaped anisotropic neodymium iron boron permanent magnet each have respective magnetic moments substantially aligned with a respective local surface normal corresponding to the respective magnetic moment.

A method and apparatus for progressively forging a mobile device casing is described. The method may include advancing an initial mobile device casing cut from an extruded sheet through a plurality of stations of a transfer die assembly. The method may also include performing a sequence of forgings on the initial mobile device casing to progressively form a mobile device casing having at least one three dimensional feature formed within at least one cavity of the progressively formed mobile device casing.

A method for producing metal-based thin foils is provided, which includes the steps of extruding a metal through an extruder to form a preliminary foil, cooling the preliminary foil in a coolant bath, and rolling the preliminary foil in a rolling system containing at least two rollers to form a metal-based thin foil.