A method for manufacturing a flat laminate sheet comprises coupling first and second thermoplastic layers to one another without glue by superficially heating coupling surfaces of the two layers and pressing the heated layers onto one another without glue to form a first combined thermoplastic multilayer free from glue, the layers each being a film free of plasticizers and comprising PVC, PET, PETG, PP, and/or PE, and coupling a third thermoplastic layer of a film comprising PVC, PET, PETG, PP, and/or PE to the first combined thermoplastic multilayer by superficially heating coupling surfaces of the third layer and the first combined thermoplastic multilayer and pressing the heated third layer and the first combined thermoplastic multilayer onto one another without glue to form a multilayer laminate sheet free from glue, being planar, flat, and rigid, and having a thickness between approximately 0.75 to 4 mm.

A laminate structure, package, and associated method of manufacturing are described, where the laminate structure includes a first film layer having an uncut laser-distorted region, a second film layer having an inner laser score line laminated to the first film layer, and a third film layer having an outer score line laminated to the second film layer. The inner laser score line is in line with the laser-distorted region, and the outer score line is offset from the inner laser score line and the laser-distorted region. When a consumer peels back the third film layer via the outer score line, the first film layer breaks along the laser-distorted region to form a first film layer cut line continuous with the inner laser score line, allowing the first film layer and the second film layer to be moved together with the third film layer for opening the package.

Embodiments of a system and a method for manufacturing a gypsum board can be used to produce a gypsum board having at least one perforated cover sheet via a cover sheet perforator system. The cover sheet perforator system can include a perforator roller is disposed downstream of a forming station along a machine direction, a roller support frame for rotatably supporting the perforator roller such that its rotational axis extends along the cross-machine direction, and a motor arranged with the perforator roller to rotate the perforator roller about the rotational axis. The drive motor can be adapted to rotate the perforator roller with a tangential speed substantially equal to the line speed to produce a series of perforation holes in an upwardly-facing cover sheet as the gypsum board moves past the perforator roller.

A linerless label including a support, a release layer over one surface of the support, and an adhesive layer over another surface of the support, wherein when the linerless label is cut with an apparatus including a mechanism in which an upper blade of cutter blades is immobilized and a lower blade of the cutter blades is configured to move upward, in a manner that the lower blade is inserted into the linerless label from a side of the linerless label at which the adhesive layer is provided, a cutter load voltage during a cutter operation performed after the linerless label is cut five thousand times repeatedly has a difference of less than or equal to 2.0 V from the cutter load voltage during cutting of a label support, which is the linerless label before treated to have adhesiveness.

A composite ferrite sheet may include a ferrite sheet, and composite sheets attached to both surfaces of the ferrite sheet, respectively, and having insulating properties. The composite sheet may be formed of a resin containing metal powder particles. The composite ferrite sheet may be easily manufactured and have improved shielding performance.

The present disclosure provides an apparatus for pasting a warm edge spacer, comprising: a first and a second conveying mechanism; a rotating mechanism for driving the second conveying mechanism to rotate; a conveying tunnel set in both the first conveying mechanism and the second conveying mechanism; a pressing unit set at the front of the second conveying mechanism; a cutting unit set at the side of the pressing unit; a positioning unit set at the lower side of the pressing unit in correspondence to the exit of the warm edge spacer, and an auxiliary pressing unit set at the upper side of the pressing unit; a pasting unit set at the other side of the warm edge spacer which is opposite to glass. The apparatus for pasting a warm edge spacer can implement automatic pasting operation of warm edge spacer.

Aspects of the present invention relate to methods of making an external nasal dilator amenable to continuous and automated manufacture. For example, in one embodiment of the method, a roll of a three-layered material is used as the starting material, the three layers consisting substantially and respectively of (1) a resilient sheet, (2) an adhesive-protecting sheet, and (3) an adhesive layer between the resilient sheet and the adhesive-protecting sheet. A series of dies are used to cut the three-layered material into the appropriate shape and (when necessary) to impress grooves in the resilient sheet.

A manufacturing method for a liquid crystal display panel includes slitting a first optical film having an elongate shape, to have a width corresponding to a pair of opposing sides of a liquid crystal cell, and by rolling the slit first optical film in its width direction to have a length corresponding to another pair of opposing sides of the liquid crystal cell; slitting a second optical film having an elongate shape, to have a width corresponding to a pair of opposing sides of the liquid crystal cell, and by rolling the slit second optical film in its width direction to have a length corresponding to another pair of opposing sides of the liquid crystal cell; bonding the cut first optical film onto one surface of the liquid crystal cell; and bonding the cut second optical film onto another surface of the liquid crystal cell.

A printed gas sensor is disclosed. The sensor may include a partially porous substrate, an electrode layer, an electrolyte layer, and an encapsulation layer. The electrode layer comprises one or more electrodes that are formed on one side of the porous substrate. The electrolyte layer is in electrolytic contact with the one or more electrodes. The encapsulation layer encapsulates the electrode layer and electrolyte layer thereby forming an integrated structure with the partially porous substrate.

A laminated composite structural panel with fiber reinforcement comprising a skin with a thickness e.sub.1 and a localized reinforcement or patch. The skin is made up of a stack of fibrous plies in a matrix made of a thermoplastic polymer. The localized reinforcement or patch is joined to the surface of the skin and rises to a thickness of e.sub.2 in a direction that is locally normal to the skin, which is made up of a stack of fibrous plies in a matrix made of thermoplastic polymer. The surface of the plies that make up the patch is decreasing from the ply of the patch in contact with the skin so that the edges of the patch have a slope p greater than 0.5. The patch and the skin is joined by a weld.