An object of the present invention is to provide a process for laminating works together that are capable of giving laminates a high bonding strength ensured therein. The process for laminating works together laminates a work composed of a resin to a work composed of a resin or glass, the process including a surface activation step of treating a laminating surface of at least the work composed of a resin with vacuum ultraviolet ray or with atmospheric pressure plasma, and a bonding step of bonding together the two works stacked on each other such that a laminating surface of one of the works abuts a laminating surface of the other work, wherein in the surface activation step, the treatment of the laminating surfaces with vacuum ultraviolet ray or with atmospheric pressure plasma is terminated when an accumulated treatment quantity of the vacuum ultraviolet ray or the atmospheric pressure plasma applied to the laminating surfaces is within an initial drop range shown in a variation curve of a water contact angle on the laminating surfaces with respect to the accumulated treatment quantity.

A bond ply, comprising a first outer layer comprising a thermosetting composition and a filler composition; a second outer layer comprising a thermosetting composition and a filler composition that is of the same type as that of the first outer layer; and an intermediate layer disposed between the first and the second outer layers, and comprising a thermosetting composition and a filler composition that is of the same type as the first and second outer layers, wherein the thermosetting composition of the intermediate layer has a degree of cure that is greater than a degree of cure for each of the thermosetting compositions of the first and the second outer layers.

ABSTRACT OF THE DISCLOSURE A method of manufacturing a composite panel comprises the steps of: a) Providing a first textile layer (10); b) Applying a first adhesive to at least a portion of the first textile layer (10); c) Placing a plurality of first profiles (11) adjacent to each other onto at least a portion of the first textile layer which has been contacted with the first adhesive, wherein each of the first profiles (11) comprises a foam core (12) and a reinforcement fabric (13) located on the foam core (12) and wherein each of the first profiles (11) is obtained by bonding a respective foam core (12) to a respective pre-formed reinforcement fabric (13); d) Applying a second adhesive to at least a portion of the reinforcement fabrics (13) of the first profiles (11); e) Placing, at least once, at least one second profile (14) between two first profiles (11); and f) Providing a second textile layer (15) onto the at least one second profile (14). The invention also relates to a composite panel obtainable by such a method and to the use of a such a composite panel for the manufacture of rotor blades for wind energy systems, of panels for reefer containers or of panels for trailers.

A method of producing floor panels is disclosed. The method includes the steps of separating a sheet formed surface material into surface strips and gluing said surface strips to a core with a space between the surface strips. A method of producing floor panels, wherein the method includes the steps of: separating a sheet formed surface layer material into surface strips; and gluing the surface strips to a sheet of core material to be cut into a plurality of floor panels, and providing a space between the surface strips, and cutting the sheet of core material, at the space, into at least two individual floor panels, forming a mechanical locking system in the sheet of core material at the space.

A method for producing a composite multi-layered absorbent article. At least two of the layers include a colored region.

An isolation layer is arranged between two adjacent upright portions of a T-section stiffener, which is arranged on and bonded to a surface.

A roofing product can include a ceramic base material and a recycled roofing material. In a particular embodiment, an open structure of the ceramic base material is filled with a bituminous material that has no greater than approximately 5 weight % of abrasive particles or 0.1 weight % metal content. The recycled roofing material can be disposed along one or both sides of the ceramic base material. The bituminous material may have a characteristic particle size that is smaller than a characteristic particle size of the recycled roofing material. In another embodiment, the roofing product having the recycled roofing material can have tear strength characteristics as compared to a different roofing product having a substantially the same construction but having abrasive particles embedded within the ceramic base material.

The present invention is directed to a method of making a door having first and second door facings and an internal doorframe. An interior side of a first facing is coated with quick acting adhesive. A frame is placed on the coated interior side about the periphery of the first facing. The frame is then coated with quick acting adhesive. An interior side of a second facing is placed on the coated frame. The facings and frame assembly are then compressed to form a door. The present invention also provides for an automated system of making the door.

Laminated rolls of sealed graphite pouches and methods for making the same are provided. The laminated roll can include a first substrate having a length and a plurality of sealed pouches disposed on the substrate at predetermined intervals along its length. Each sealed pouch can include a graphite sheet having first and second sides, the first side affixed to the substrate, and a second substrate affixed to at least the second side of the graphite sheet and to a portion of the substrate to fully seal the graphite sheet within an enclosed space. In one embodiment, the roll of sealed graphite sheet pouches can be fixed to a roll of another substrate in a roll-to-roll fashion and the combined rolls can be cut into discrete portions for use in a particular application. For example, the roll of the other substrate can be a roll of enhanced spectral reflector (ESR).

A lens array fabrication method for fabricating a lens array includes: receiving pins (16) of a film attaching instrument (jig) in second guide holes (10) of a film-containing base plate; bonding a placement area and an adhesion layer (F); removing the pins (16); causing a detachment between a first detachment film (C) and a pressure-sensitive adhesive optical film (D); separating three layers (D) to (F) from two layers (B) and (C); receiving the pins (16) in first guide holes (7) of a lens array main unit; fitting a film holding protrusion (15) in a depression part (6); bonding the film (D) to a bonding region (i); removing the pins (16); and causing a detachment between the film (D) and a second detachment film (E).