A method and apparatus for resistive heating usable in composite-based additive manufacturing is disclosed. The method includes providing a prepared stack of substrate sheets, placing the stack between electrode assemblies of a compression device, applying a current to thereby heat the stack to a final temperature to liquefy applied powder, compressing the stack to a final height, cooling the stack, and removing the cooled, compressed stack from the compression device. The apparatus comprises at least two plates, a power supply for providing current, a first electrode assembly and a second electrode assembly.

A method and apparatus for resistive heating usable in composite-based additive manufacturing is disclosed. The method includes providing a prepared stack of substrate sheets, placing the stack between electrode assemblies of a compression device, applying a current to thereby heat the stack to a final temperature to liquefy applied powder, compressing the stack to a final height, cooling the stack, and removing the cooled, compressed stack from the compression device. The apparatus comprises at least two plates, a power supply for providing current, a first electrode assembly and a second electrode assembly.

A metal-carbon particle composite material (30) is provided with one or more flake-like graphite particle dispersion layers (1) in which flake-like graphite particles (1a) as carbon particles are dispersed in a metal matrix (9), one or more carbon fiber dispersion layers (2) in which carbon fibers (2a) as carbon particles are dispersed in a metal matrix (9), and one or more metal layers (3) formed by the metal matrix (9) in a laminated manner. One or more flake-like graphite particle dispersion layers (1), one or more carbon fiber dispersion layers (2), and one or more metal layers (3) are integrally bonded. One of the flake-like graphite particle dispersion layer (1) and the carbon fiber dispersion layer (2) and the metal layer (3) are alternately laminated substantially entirely in the thickness direction of the composite material (30).

A method for manufacturing a metal assembly including an aluminum sheet and at least one metal sheet. An aluminum sheet is treated by heating to a temperature of between 80% and 100% of the melting temperature of the material of which it is comprised for a sufficiently long duration to create and stabilize an alpha alumina layer at the surface of the aluminum sheet. The sheet is then cooled. A metal sheet having a ductility less than or equal to the ductility of the aluminum sheet after cooling is provided, which has surface irregularities having a depth greater than or equal to the thickness of the alpha alumina layer. The aluminum sheet and the metal sheet are roll bonded in a rolling mill to produce the metal assembly, wherein the rolling mill includes at least one cylinder, the outer rolling surface of which is provided with raised portions.

A method, product, apparatus, and article of manufacture for the application of the Composite Based Additive Manufacturing (CBAM) method to produce objects in metal, and in metal fiber hybrids or composites. The approach has many advantages, including the ability to produce more complex geometries than conventional methods such as milling and casting, improved material properties, higher production rates and the elimination of complex fixturing, complex tool paths and tool changes and, for casting, the need for patterns and tools. The approach works by slicing a 3D model, selectively printing a fluid onto a sheet of substrate material for each layer based on the model, flooding onto the substrate a powdered metal to which the fluid adheres in printed areas, clamping and aligning a stack of coated sheets, heating the stacked sheets to melt the powdered metal and fuse the layers of substrate, and removing excess powder and unfused substrate.

A method, product, apparatus, and article of manufacture for the application of the Composite Based Additive Manufacturing (CBAM) method to produce objects in metal, and in metal fiber hybrids or composites. The approach has many advantages, including the ability to produce more complex geometries than conventional methods such as milling and casting, improved material properties, higher production rates and the elimination of complex fixturing, complex tool paths and tool changes and, for casting, the need for patterns and tools. The approach works by slicing a 3D model, selectively printing a fluid onto a sheet of substrate material for each layer based on the model, flooding onto the substrate a powdered metal to which the fluid adheres in printed areas, clamping and aligning a stack of coated sheets, heating the stacked sheets to melt the powdered metal and fuse the layers of substrate, and removing excess powder and unfused substrate.

A method, product, apparatus, and article of manufacture for the application of the Composite Based Additive Manufacturing (CBAM) method to produce objects in metal, and in metal fiber hybrids or composites. The approach has many advantages, including the ability to produce more complex geometries than conventional methods such as milling and casting, improved material properties, higher production rates and the elimination of complex fixturing, complex tool paths and tool changes and, for casting, the need for patterns and tools. The approach works by slicing a 3D model, selectively printing a fluid onto a sheet of substrate material for each layer based on the model, flooding onto the substrate a powdered metal to which the fluid adheres in printed areas, clamping and aligning a stack of coated sheets, heating the stacked sheets to melt the powdered metal and fuse the layers of substrate, and removing excess powder and unfused substrate.

A method for making alloy matrix composite, comprising: providing a metal matrix composite, the metal matrix composite includes a metal body and a reinforcement body; placing an alloying element layer on a surface of the metal matrix composite to obtain a first composite structure; rolling the first composite structure to obtain a middle composite structure; repeatedly folding and rolling the middle composite structure to obtain a second composite structure; annealing the second composite structure to obtain the alloy matrix composite.

A method for making alloy matrix composite, comprising: providing a metal matrix composite, the metal matrix composite includes a metal body and a reinforcement body; placing an alloying element layer on a surface of the metal matrix composite to obtain a first composite structure; rolling the first composite structure to obtain a middle composite structure; repeatedly folding and rolling the middle composite structure to obtain a second composite structure; annealing the second composite structure to obtain the alloy matrix composite.

A method for producing a metal-carbon fiber composite material includes the steps of: obtaining a coated foil (12) in which a carbon fiber layer (11) is formed on a surface (10a) of a metal foil (10) by applying a coating liquid (5) containing carbon fibers (1), etc., on the surface (10a) of the metal foil (10) with a gravure coating device (20); forming a laminate in which a plurality of coated foils (12) is laminated; and integrally joining the coated foils (12) by heating while pressurizing the laminate in a lamination direction of the coated foils (12). The shape of a cell (22) of a circumferential surface (21a) of a gravure roll (21) of the gravure coating device (20) is a cup shape and a diameter of a circle inscribed in a mouth shape of the cell (22) is set to 1.2 times or more the average fiber length.