A laser cutting machine including an X1 axis provided with clamps which make it possible to firmly grip a material to be cut in sheets or on reels (the blank) enabling the material to be moved from left to right; a Y-axis: perpendicular to the X1 axis, enabling the movement of a laser cutting head; an X2 axis with at least one pair of clamping rollers enabling the material to be moved to the left or to the right; a straightening/de-cambering/levelling system placed beside this X2 axis comprising an optimised number of rollers; a unit incorporating the X2 axis and the straightening system which can be moved upwards or downwards, and a motorized discharge table enabling the cut elements (scrap and good pieces) to be discharged at a precise point, delimiting a picking zone.

The present application relates to an apparatus (52) for supporting sheet material during cutting by laser radiation comprising a support member (42) having a gold facing layer. A method for cutting sheet material using such apparatus is also defined.

A capacitor and methods of processing an anode metal foil are presented. The capacitor includes a housing, one or more anodes disposed within the housing, one or more cathodes disposed within the housing, one or more separators disposed between an adjacent anode and cathode, and an electrolyte disposed around the one or more anodes, one or more cathodes, and one or more separators within the housing. The one or more anodes each include a metal foil that includes a first plurality of tunnels through a thickness of the metal foil in a first ordered arrangement, the first ordered arrangement being a close packed hexagonal array arrangement, and having a first diameter, and a second plurality of tunnels through the thickness of the metal foil having a second ordered arrangement and a second diameter greater than the first diameter.

The invention relates to methods and an apparatus for cutting planar substrates charged with pharmaceutically active agents. In particular, the planar substrates comprise transdermal systems or orally dissolvable films.

An electrode manufacturing device includes a transfer part, a laser irradiation part, and a pattern jig. The transfer part continuously transfers an electrode sheet in order to perform an electrode notching process. The laser irradiation part irradiates the electrode sheet with a laser beam to perform the electrode notching process. The pattern jig is positioned at a portion facing the laser irradiation part with the electrode sheet interposed therebetween to support the electrode sheet. The pattern jig includes a panel having a pattern hole through which the laser beam that has notched the electrode sheet passes, and the pattern hole has a structure which becomes wider from the front toward the rear along a laser beam traveling direction.

The present disclosure relates to a system for manufacturing a hybrid component including a first thermal supplier configured to heat a steel plate, a rolling roll for undercut configured to pressurize the steel plate heated by the first thermal supplier, and to form an undercut on one surface of the steel plate, a first molding roll configured to pressurize the steel plate formed with the undercut to mold the steel plate in a shape of a component to be manufactured, a composite material feeder configured to supply a composite material tape to be seated on one surface of the steel plate formed with the undercut through the first molding roll, and a composite material pressurization roll configured to pressurize the steel plate on which the composite material tape is seated.

Techniques for processing a web with a laser are provided. In an example, an apparatus for processing web material can include multiple processing stages and a laser assembly. Each of the multiple processing stages can be configured to process a moving web of material along a web path. The laser assembly can be configured to process the moving web of material with a laser at a first stage of the multiple stages. The laser assembly can include a laser configured to generate a laser beam, a gimble assembly configured to direct the laser beam along a cut path at a position of a web path of the moving web of material, and a servo driven mirror assembly configured to provide an adjustable field of view for the laser stage at the position of the web path.

A metal strip and a process for manufacturing such a metal strip are disclosed. In order to be able to reproducibly manufacture a durable metal strip, it is proposed for a butt seam to extend essentially between a first cladding layer of a first strip transverse portion and a second strip transverse portion.

A capacitor and methods of processing an anode metal foil are presented. The capacitor includes a housing, one or more anodes disposed within the housing, one or more cathodes disposed within the housing, one or more separators disposed between an adjacent anode and cathode, and an electrolyte disposed around the one or more anodes, one or more cathodes, and one or more separators within the housing. The one or more anodes each include a metal foil that includes a first plurality of tunnels through a thickness of the metal foil in a first ordered arrangement, the first ordered arrangement being a close packed hexagonal array arrangement, and having a first diameter, and a second plurality of tunnels through the thickness of the metal foil having a second ordered arrangement and a second diameter greater than the first diameter.

Provided is a method for refining magnetic domains of grain-oriented electrical steel plates including: a steel plate supporting roll position adjusting step of controlling a vertical direction position of the steel plate while supporting the steel plate; a laser radiating step of melting the steel plate by radiating a laser beam to form grooves on the surface of the steel plate; and a setting and maintaining step of setting and maintaining an internal operation environment of a laser room in which the laser radiation is performed, so as to increase magnetic domain refinement efficiency and improve workability by optimizing equipment and processes, thereby increasing the processing capacity.