A method for folding a fastener during a high speed manufacturing process and maintaining the fastener in a folded configuration throughout the high speed manufacturing process. The method includes obtaining an article that has a foldable fastener and moving the article in the machine direction during the high speed manufacturing process. The foldable fastener has first and second opposing surfaces, a web and at least one engaging member joined to the web. The method includes applying a frangible bonding agent to a first portion of the first surface of the fastening system; folding the fastening system such that the frangible bonding agent contacts a second portion of the first surface of the fastening system; and allowing the frangible bonding agent to cool at a temperature of less than 60° C.

A method of manufacturing a display apparatus includes: providing a substrate having a first surface and a second surface and arranging the substrate on a carrier such that the second surface of the substrate contacts the carrier; forming a display device on the first surface of the substrate; arranging a first protective film on the display device; cutting a substrate by irradiating a first short pulse laser beam onto the second surface of the substrate through the carrier; and cutting the first protective film by irradiating a laser beam of an infrared wavelength range onto an area of the first protective film that overlaps a cut area of the substrate.

A line of prints has passed through a laminating machine so that a laminating film has been applied to both surfaces of the line. To enable individual prints to be torn off the laminating film is indented or perforated near to an edge of the line of prints. Tearing is then effected from the perforated edge to the other edge. The indentation or perforation of both films occurs downstream of their respective supply rolls.

A film for conveying in an industrial process, industrial fabrics made from the film, and methods of manufacture. The film has a plurality of protrusions separated by land areas. Each protrusion comprises a top member having opposing lateral edges and is supported by opposed compression resistant first and second end walls, which with at least one of the lateral edges define an aperture extending through the film to provide a flow path. The base edge of each end wall has a configuration selected from at least one of the base edge being convexly curved away from the protrusion body; and each end wall extending below at least a part of each of the first and second lateral edges and being connected to each of the first and second lateral edges. The film structure provides physical properties equivalent to a woven fabric, with improved strength, stability and compression resistance.

A laminate substrate for receiving a semiconductor chip. Included are laminate layers stacked to form the laminate substrate, each laminate layer includes a core that includes particle-filled epoxy and a metallic layer on the core. At least one laminate layer has a radial cut through the metallic layer, the radial cut extending from a periphery of the at least one laminate layer towards a center of the at least one laminate layer. The radial cut cuts only through the metallic layer and does not cut through the core.

A method of producing a sandwich panel core of mineral wool fibres from a cured mineral fibre product includes the steps of providing a cured mineral fibre product with a dual density having a top layer with mineral fibres with a first density and a base layer having mineral fibres with a second density, the second density is at least two times lower than said first density. The top layer and the base layer have different fibre orientations. Further steps including cutting the mineral fibre product into a plurality of lamellae, rotating the lamellae 90 degrees, and re-joining the lamellae so that the top layers with the first density are vertically oriented.

In-line systems and in-line methods of producing lightweight reinforcing thermoplastic composite panels are described. The in-line systems and in-line method can be used to produce composite panels with smoother surfaces and enhanced properties in an automated manner. The produced composite panels can include a decorative layer that can provide an overall smoother panel surface compared to a composite panel lacking a decorative layer.

A prop wrap in the current invention can quickly and easily change the appearance of irregularly shaped rigid props used in pageantry art shows and enable the prop to graphically integrate with the show's concept, design, and theme. The prop wrap provides a flexible film on which an infinite number of designs can be applied. These designs include but are not limited to customized patterns that integrate tightly with the shows, school mascots, or group logos. By using the prop wrap a user is not limited to solid colors or simple patterns made available by conventional methods of painting or taping props. Each piece of the prop wrap incorporates a unique cutting pattern that matches a designated surface of a specific prop, such as a particular model and size of mock rifles, shakos, or shoes. This allows the prop wrap to align perfectly to the shape and size of the prop when it is affixed to the prop. The prop wrap also serves to protect the prop itself.

A composite wood panel is manufactured from thin wood laminae cut from wood unsuitable for peeler logs or dimensional lumber. A cold set adhesive is applied to the wood laminae and they are formed into a randomly oriented mat that is cold rolled into a thin, pliable cold rolled stock that can be corrugated. A hot set adhesive may also be applied to the laminae to improve strength of the composite wood panel. The hot set adhesive is set in a hot press after the cold rolled stock is produced.

A method for producing a fuel cell membrane electrode assembly includes: a step of bonding a polymer electrolyte membrane and a first catalyst layer-including substrate; a step of making a cut by way of a laser beam so that the first catalyst layer-including substrate bonded with the polymer electrolyte membrane becomes a predetermined shape; a step of peeling an unwanted portion of the first catalyst layer-including substrate from the polymer electrolyte membrane; and a step of forming a second catalyst layer on the other face of the polymer electrolyte membrane, and punching out the polymer electrolyte membrane and second catalyst layer so that the first catalyst layer-including substrate of the predetermined shape bonded on one face is surrounded, in which the laser beam has a wavelength that penetrates the polymer electrolyte membrane without penetrating the first catalyst layer-including substrate.