The present invention relates to a method for joining a first blank and a second blank, wherein at least one of the first and second blanks comprises at least a layer of aluminum or an aluminum alloy. In particular, the method comprises placing the first and second blanks for welding; laser welding the first and second blanks following a welding path thus forming a tailor welded blank, wherein the welding path combines a linear movement along a welding direction and oscillating movements substantially transverse to the welding direction and then hot deforming and quenching the tailor welded blank to form a component, wherein the welding is done without using a filler.

A method for producing a shaped sheet of wrapping, including a hollow portion and a perimetral edge that extends along a pre-set profile, is provided. The method includes laying a sheet of wrapping on a treatment surface having a forming cavity. The method includes forming the sheet of wrapping within the forming cavity so as to reproduce the shape of the hollow portion thereon, without subjecting the sheet of wrapping to deformation by stretching. The method includes cutting the formed sheet of wrapping along the pre-set profile for producing the perimetral edge and obtaining the shaped sheet of wrapping. In the method, the cutting step envisages the use of a laser beam according to a particular cutting mode.

A laser processing device includes a conveyance device, a laser irradiating unit, a controller, and a guide. The conveyance device conveys a strip electrode in a conveyance direction. The laser irradiating unit irradiates the strip electrode with a laser beam. The laser irradiating unit is configured to change the irradiating direction of the laser beam. The controller controls the laser irradiating unit so as to cut the strip electrode into a tab shape by causing the laser beam to move along a predetermined path on the strip electrode. The guide holds the strip electrode. The guide includes a notch. The notch has a shape that follows at least a portion of the predetermined path.

A welding wire for obtaining a giga-grade weld, a welded structure manufactured using same, and a welding method thereof are provided. The welding wire of the present invention comprises: by mass % of the whole wire, 0.08 to 0.15% of C; 0.001% to 0.1% of Si; 1.6 to 1.9% of Mn; 0.015% or less of P; 0.015% or less of S; 4.0 to 5.2% of Cr; 0.4 to 0.65% of Mo, and the remainder being Fe and unavoidable impurities, wherein value X defined by the following relation 1 satisfies the range of 0.7 to 1.1%. [Relational Expression 1] X (%)=[Cr]/10+[Mo]−4x[Si]/[Mn]

Systems and methods are provided for braiding Metal Matrix composite (MMC) tape. One method includes drawing multiple lanes of MMC tape, comprising a matrix of metal reinforced by fibers, from bobbins arranged around a mandrel. The method also includes braiding the multiple lanes to form a preform at the mandrel for an MMC part and consolidating the preform via application of heat and pressure.

Disclosed is a welded member for plated steel plate having excellent weld zone porosity resistance and fatigue properties and a method of manufacturing the same. The welded member for plated steel plate having excellent weld zone porosity resistance and fatigue properties according to an embodiment of the present invention comprises a weld metal portion formed by arc welding and overlapping a first member and a laminated second member so as to partially overlap the first member, wherein the toe angle (θ) of the weld metal portion is 45° or less, and the first member and the second member are plated steel plates.

Provided is a surface treatment method of a metallic material having a protective layer formed thereon. A surface of the protective layer is scanned while irradiating the surface and the surface is scanned while moving an irradiation spot along the surface, in a state in which a side layer of the protective layer along the metallic material remains covering the metallic material, and a side layer of the protective layer opposite to the metallic material side is removed by irradiation with the laser beam.

A method for the preparation of steel sheets for fabricating a welded steel blank is provided. The method includes a step of removing at least part of the first and second metal alloy layers in first and second peripheral zones of pre-coated steel first and second sheets, respectively, by simultaneously ablating the first and second precoatings in the first and second peripheral zones of the pre-coated steel first and second sheets to define first and second ablation zones, the first and second peripheral zones being zones of the first and second principal faces closest to the median plane and located on either side of the median plane.

A carbon steel main body defines a flow passage. The carbon steel main body includes an end. The carbon steel main body includes a beveled edge at the end. A corrosion resistant cladding is deposited along an inner surface of the carbon steel main body. The corrosion resistant cladding extends from the end to a distance into the carbon steel main body.

A vehicle wheel and method of manufacturing the vehicle wheel is disclosed. A first polymeric coating is applied to a surface of an alloy substrate that defines the vehicle wheel. The first polymeric coating defines a first coloration. An intermediate clear polymeric coating is applied over the first polymeric coating. A second polymeric coating is applied over the first polymeric coating with the second polymeric coating defining a second coloration that is distinguishable from the first coloration. A laser scans a pattern over the second polymeric coating resulting in ablation of the second polymeric coating rendering the first polymeric coating visible through the intermediate clear polymeric coating defining a pattern of exposed first polymeric coating. Thus, a two-tone appears is present between the first coloration and the second coloration in the shape of the pattern scanned by the laser.