Provided is a method of welding laminated metal foils that can prevent blowholes and spatter from being formed. It is a method of welding laminated metal foils sandwiched between a pair of metal plates to the pair of metal plates. The method of welding laminated metal foils sandwiched between a pair of metal plates to the pair of metal plates includes locally pressing and crimping the laminated metal foils sandwiched between the pair of metal plates at a welding point in a laminating direction, and welding the crimped pair of metal plates and laminated metal foils at the welding point.

A system includes a laser welder and a filler wire feed. The laser welder is configured to weld a workpiece to at least one additional workpiece to form a welded assembly. Each of the workpieces is formed from a steel material and comprises an aluminum based coating thereon. The filler wire feed is configured to feed a filler wire to an interface between the workpieces when the workpieces are being welded to each other to form the welded assembly. The filler wire comprises a composition that includes nickel and chromium. The filler wire is configured to bind with aluminum in the aluminum based coating so as to minimize formation of brittle intermetallics due to mixing of the aluminum in the aluminum based coating with the iron/steel material in the weld joint.

A method for creating modifications in a solid-state material is described, wherein a crack guidance region for guiding a crack for separating a solid-state layer from the solid-state material is predetermined by the modifications. The method includes: moving the solid-state material relative to a laser processing system; successively emitting a plurality of laser beams from the laser processing system to the solid-state material to create at least one modification within the solid-state material; and continuously adjusting the laser processing system for defined focusing of the plurality of laser beams and/or for adjustment of energy of the plurality of laser beams as a function of at least one parameter.

An assembly to connect together first and second sheet members. The assembly includes a pressure device that applies pressure to the sheet members while the sheet members are in an overlapping arrangement and positioned on a support platform. A sensing system that includes one or more thin film pressure sensors detects the positions of the leading and trailing edges. A connection device connects the members together in an overlapping arrangement.

A laser processing method includes a step of irradiating a workpiece, in which a metal layer made of a heat-resistant alloy and a protective layer made of a thermal barrier coating are laminated, with a first laser beam that is a short-pulse laser beam, and forming a through-hole penetrating the metal layer, and a step of irradiating the workpiece with a laser beam to expand the through-hole.

A method for applying an abrasive comprises: applying, to a substrate, the integral combination of: a self-braze material; and an abrasive embedded in the self-braze material; and securing the combination to the substrate.

A method of weeding a design in a substrate have a first layer and a second layer is disclosed. The method determines an outline of the design and an inlet portion of the outline. The inlet portion is defined on at least a first and second side by the outline of the design and is open on at least a third side. The method cuts through the first layer but not the second layer along at least a portion of the outline that is not included in the inlet portion. The method also cuts through both the first and second layers along the inlet portion of the outline. The method also cuts through both the first and second layers along a path that closes the third side of the inlet portion.

A method for the remote laser welding of at least two metal sheets, where at least one metal sheet has a coating with a low boiling point, in particular for welding galvanized steel sheets, includes moving a laser beam at a welding velocity along a welding contour in order to produce a weld seam. The laser beam executes an oscillating movement which is superposed on the welding velocity, where the energy input into the joint is controlled by a power modulation, dependent on the oscillating movement, such that the energy input increases in at least one lateral oscillation periphery or a preceding oscillation periphery of the melt bath volume, but the size of the melt bath surface in the root area remains unaffected.

A method for joining a first part formed of an aluminum material to a second part formed of a steel material by metal inert gas welding and cold metal transfer is provided. An aluminum filler material forms a fillet joint between the parts and provides a structure for automotive body applications, such an aluminum bumper extrusion joined to a steel crush box connection. The first part includes a notch for hiding the start and end of the joint. A transition plate formed of a mixture of aluminum material and steel material can be disposed between the first part and the second part to provide the notch. The second part can include a mechanical fastener further joining the parts together. In another embodiment, the second part includes a plurality of dimples and is welded to the first part along the dimples.

A method for manufacturing a porous layer of an acoustic attenuation structure, porous layer of an acoustic attenuation structure thus obtained and acoustic attenuation structure comprising the porous layer. A method for manufacturing a porous layer of an acoustic attenuation structure includes a first step of production of a solid layer including at least one structural frame embedded in a resin matrix and having first and second reinforcing strips arranged so as to delimit zones without reinforcing strips and a second step of production of through-holes in the zones without reinforcing strips of the solid layer using a laser beam.