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.

A device and a method for producing a continuous strip-shaped composite material. For this purpose, a base material, which is produced using at least one casting machine as a continuous strand, in particular made of steel, and providing at least one cladding material, which is unwound in the form of at least one metal strip by a coil unwinding unit are provided. Subsequently, a slab which has formed by solidification from the strand produced by the casting machine and the metal strip unwound by the coil unwinding unit, in the hot state are brought together, wherein the materials, which are moved in the direction toward one another, formed from the slab and the unwound metal strip are hot rolled, so that a single continuous strip-shaped composite material is thus produced by roll cladding. The base material is continuously cast in the vertical direction in the casting direction.

The present disclosure relates to an electrode plate processing device. The electrode plate processing device includes: an electrode plate cutting mechanism having a cutting position; and an electrode plate rolling mechanism, through which an electrode plate passes. The electrode plate rolling mechanism includes a first roller and a second roller. The first roller has a vacuum adsorption zone for adsorbing a waste edge of the electrode plate. The cutting position is provided in upstream of the vacuum adsorption zone along a conveying direction of the electrode plate processing device.

A machine for cutting sheets by fluid projection is provided. The machine has a head displaceable in three dimensions, arranged on a support table for supporting sheets to be cut, in which there is a hole for the passage of the cutting fluid, the support table being formed by a set of rollers distributed in two groups of rollers and which determine therebetween the hole, being arranged at the entrance to the support table feed rollers provided with rotary drive action, between which a step for introducing the sheets is determined, in movement on the support table, while a synchronization belt is arranged in relation to one end of the rollers and has displacement drive action combined with the rotary drive action of the feed rollers.

A laser cutting method for a steel strip, includes cutting a vicinity of a joint obtained by joining a rear end of a preceding steel strip and a front end of a following steel strip by using a pulse-type laser beam, wherein output of the pulse-type laser beam is set to 0.5 kw or more per 1 ms, a processing point diameter of the pulse-type laser beam is set to 0.1 mm or more and less than 0.6 mm, and a ratio between a pulse period time and a down-time is set to 0.3 or more and less than 0.8.

The invention relates to a device (10) and to a method for producing a continuous strip-shaped composite material (11). A base material of metal, which is unwound in the form of a metal strip (13) by a first coil-unwinding apparatus (12), and at least one cladding material of metal, which is unwound in the form of a metal strip (15) by a second coil-unwinding apparatus (14), are provided. Then, the metal strips (13, 15) unwound by said coil-unwinding apparatuses (12, 14) are brought together in the hot state, wherein then the unwound metal strips (13, 15) brought toward each other are hot-rolled such that a single continuous strip-shaped composite material (11) is thus formed by roll cladding, said composite material consisting of the base material and the cladding material. Both the base material and the cladding material and the metal strips (13, 15) thereby unwound each consist of steel.

A method and associated system are provided for producing a perforation line between adjacent lottery tickets in an automated production line wherein a substrate having lottery tickets printed thereon is conveyed through a perforation station in the production line. A perforation machine in the line is controlled to define a perforation line between the adjacent lottery tickets. The controlling process includes inputting control variables into a controller associated with the perforation machine, the control variables relating to conditions that determine a desired perforation profile of the perforation line. The controller programs the perforation machine with a specific perforation profile for the perforation line that is generated based on the entered control variables, and changes the perforation profile upon inputting of different values for the control variables. The perforation profile is specifically tailored to the control variables between different ticket production runs, or between tickets in the same ticket production run.

A method for producing a composite material by plating a band arrangement with a top side (O) and a bottom side (U), wherein the band arrangement comprises at least a first strip and a second strip, which form between them a filling channel, wherein the band arrangement comprises at least one filler strip, wherein the abovementioned band arrangement is plated, wherein a part of the filler strip, during the plating, is extruded into the filling channel; and a composite material, characterized in that it has been produced according to the method as disclosed.

Described is a weakening device for weakening packaging materials having at least one laser unit comprising a laser having a laser beam and at least one transport device for transport of the packaging material relative to the laser unit. The laser unit has at least one focusing optics for focusing the laser beam on the packaging material transported relative to the laser. In order to be able to inscribe both straight lines of weakness and shapes included from lines, it is provided that the laser unit has at least one scanner for adjusting the laser beam at least in one direction transversely to the transport direction for inscribing predetermined shapes into the packaging material transported past the laser, and that a beam switch is provided in the path of the laser beam for transmitting the beam to the focusing optics in a liner position or to the scanner.

A conversion station (300) comprising a mechanism (240) operable to support at least some portion of a web (250), a conversion device located above the mechanism (240), the conversion device operable to traverse a conversion zone (244) located below the conversion device to bring a cutting member into contact with the web (250) to convert the web (250) into one or more individual products (201A, 202A; 201B, 202B; 201C, 202C), an image capturing device (260) located above the mechanism (240) and adjacent to the conversion device but outside the conversion zone (244), the image capturing device (260) positioned at a non-perpendicular imaging angle (271) relative to a surface plane (270) of the web (250), the image capturing device (260) operable to capture image information (261, 263) by imaging the one or more features located on the web (250) while the features are positioned within the conversion zone (244), and a control system operable to align the web (250) within the conversion zone (244) based on the image information (261, 263).