A method of cutting a web structure that is utilized in the manufacture of an absorbent article. The method of cutting the web structure can employ a laser having a pulse mode of operation. In various embodiments, the frequency of the beam of radiation pulsed from the laser can be patterned to correspond to the material of the web structure. In various embodiments, the frequency of the beam of radiation pulsed from the laser can be patterned to correspond to the speed at which the web structure is moving and can change with any change in speed of the web structure movement.

A galvanometric laser for cutting and/or etching textile embellishments such as transfers or applique's and a method of operation thereof that is capable of visually capturing an incoming graphic image and referencing a cut pattern to the captured image and dynamically adjusting the cut pattern during cutting, etching and/or application of energy from the laser to thereby compensate for distortions in the fabric. The device includes a conveyor with an imaging station at which the graphic product is indexed under a high-resolution static camera with color recognition capability for the purposes of image capture. A high intensity bottoms-up light source resident at the imaging station provides ample illumination regardless of whether the design elements are face up toward the camera or face down toward the light source, or a combination of both. The system includes a computer at which the captured product image is analyzed, and the analytics are used to adjust the input cut file specifying the location and power settings for laser application. The product is then advanced in a controlled manner by means of the conveyor into a galvanometric cutting station where laser energy is applied. After completion the product is advanced out of the galvanometric cutting station for packaging.

In a laser cutting machine for cutting a sheet of material, a laser scanner (12) is traversable in a lateral direction across a cutting surface (14). The laser scanner is controllable to direct a laser beam onto the cutting surface within a cutting area (A) of the cutting surface. A material-advancing mechanism is provided that is controllable to incrementally advance the sheet of material in a longitudinal direction over the cutting surface. In use, the material-advancing mechanism is controllable to position and hold stationary successive laterally- extending portions of the material in the cutting area. The laser scanner is controllable to cut each successive laterally-extending portion of the material held stationary in the cutting area before the material is advanced.

A method and device for producing a tear line on a planar workpiece by material removal by means of a pulsed laser, wherein machining cycles are preceded by a method step for generating and storing a reference signal curve which is formed by reference signals, causing the pulse amplitude of the laser pulses, via removal locations along the contour of the tear line. The achievement of a respective predetermined percentage of the reference signal or of an absolute distance from the reference signal by a measurement signal is used as the space-resolved deactivation criterion for each removal location, which measurement signal is obtained from a transmitted part of the pulse amplitude at the respective removal location.

The invention relates to a planar decorative material (11) comprising perforations (12), for interior fittings, in particular for the automobile industry, which decorative material serves to be illuminated on the rearward face (13) thereof, by an illumination means (18), and allows a portion of the light from the illumination means (18) to pass from the rear face (13) of the decorative material (11), through the perforations (12), to the visible side (14) of the decorative material (11), wherein a film (20) is adhesively bonded to the rear face (13) of the decorative material (11) and the perforations (12) extend from the rear face (13) of the decorative material (11) as far as the visible side (14) thereof, but not through the film (20). The present invention also relates to a production method.

A tool allows a user to create new designs for apparel and preview these designs in three dimensions before manufacture. Software and lasers are used in finishing apparel to produce a desired wear pattern or other design. Based on a laser input file with a pattern, a laser will burn the pattern onto apparel. With the tool, the user will be able to create, make changes, and view images of a design, in real time, before burning by a laser. The tool can be accessed or executes via a Web browser.

A tool allows a user to create new designs for apparel and preview these designs in three dimensions before manufacture. Software and lasers are used in finishing apparel to produce a desired wear pattern or other design. Based on a laser input file with a pattern, a laser will burn the pattern onto apparel. With the tool, the user will be able to create, make changes, and view images of a design, in real time, before burning by a laser. The tool can be accessed or executes via a Web browser.

A method of scribing abrasion aesthetics, patterns, images, serial numbers, ply markings and/or other information, such as sizing or care information, on fabric such as denim, before or during the fabric cutting process is provided. The method comprises loading the panel abrasion software, pattern marker software, and fabric scribing software; placing the fabric on a flat surface under at least one laser; laser scribing ply numbers, serial labels, fabric markers, and panel abrasions on the fabric; cutting the fabric into fabric lengths; spreading the pre-abraded and pre-marked fabric lengths on top of each other to create multiple plies in precise alignment; cutting shaped panels along the lines of the pattern marker with a conventional knife, laser, or other appropriate cutting tool; and stacking the abraded, labeled and shaped panels robotically or manually for sewing.

The present application relates to silk fibroin-based hydrogels, methods for making and using the same.

A GDL cutting system of a fuel cell includes: a laser-cutting device that forms a gas diffusion layer by radiating a laser on the surface of a GDL fabric panel moving on a conveyer; an adsorbing-conveying device that adsorbs and conveys at least two gas diffusion layers cut by the laser-cutting device; a first vision sensor that senses an upper side of the gas diffusion layers cut by the laser-cutting device; and a second vision sensor that senses a lower side of the gas diffusion layers adsorbed and conveyed by the adsorbing-conveying device.