The present disclosure provides a laminating device. The laminating device may include a first conveying device, a second conveying device, and a laminating apparatus. The first conveying device may be configured to convey a film-like structure. The second conveying device may be arranged along a conveying direction of the first conveying device. A conveying speed of the first conveying device may be greater than that of the second conveying device. The second conveying device may receive the film-like structure conveyed by the first conveying device. The film-like structure may form a folded portion on the second conveying device. The laminating apparatus may be configured to convey an object to be laminated and receive the film-like structure conveyed by the second conveying device. The film-like structure with the folded portion may be laminated with the object to be laminated on the laminating apparatus.

There is provided a resin laminate including: at least a first layer; a second layer; and an intermediate layer laminated in contact with the first layer and the second layer, in which a surface of the first layer in contact with the intermediate layer is an oxidized surface, a surface of the intermediate layer in contact with the first layer is an oxidized surface, the first layer is a layer in which a thermoplastic resin is used as a forming material or a layer in which cellophane is used as a forming material, and the intermediate layer is made of polyethylene having a density of 0.915 g/cm3 or less.

Systems and methods for filament fastener that cures with composite part. One embodiment is a method of fabricating a composite part. The method includes placing layers of reinforcement fibers over a tool to form a laminate of composite material to be cured with a first resin, forming a filament fastener comprising bundled fibers with one or more texture elements around the bundled fibers, and coating the filament fastener with a second resin that is chemically compatible with the first resin. The method also includes inserting the filament fastener into the laminate through a plurality of the layers, and curing the filament fastener within the laminate to bind the plurality of the layers of the laminate with the one or more texture elements of the filament fastener via bonding of the first resin and the second resin to form the composite part with delamination resistance.

Embodiments of the invention provide replacements for a continuous layer of feed spacer mesh in spiral-wound reverse osmosis elements and replacing such mesh with discrete regions of feed spacer supporting the inlet and outlet ends of the element and a stiffening bridge feature to bridge between these regions at the tail end of each membrane leaf comprising the element during the element rolling process. The stiffening bridge feature prevents inward deflection of the inner layer of the membrane leaf during rolling, facilitating proper sealing of the adhesive through the permeate carrier to the adjacent membrane film using known membrane rolling techniques.

A system includes a separation tool that separates a carrier wafer to form a plurality of chiplet carriers. The carrier wafer having sheets of thin film material attached. A sensor and processor of the system determine an orientation of the portions of the sheets of thin film material relative to the chiplets to determine a mapping therebetween. A fluid carrier of the system places the chiplet carriers on an assembly surface in a disordered pattern. The system includes a micro assembler that arranges the chiplet carriers from the disordered pattern to a predetermined pattern based on the mapping. A carrier of the system transfers the portions of the thin film material from the chiplet carriers to a target substrate.

A system includes a separation tool that separates a carrier wafer to form a plurality of chiplet carriers. The carrier wafer having sheets of thin film material attached. A sensor and processor of the system determine an orientation of the portions of the sheets of thin film material relative to the chiplets to determine a mapping therebetween. A fluid carrier of the system places the chiplet carriers on an assembly surface in a disordered pattern. The system includes a micro assembler that arranges the chiplet carriers from the disordered pattern to a predetermined pattern based on the mapping. A carrier of the system transfers the portions of the thin film material from the chiplet carriers to a target substrate.

An assembly for forming a gas turbine engine according to an example of the present disclosure includes, among other things, a layup tool including a main body extending along a longitudinal axis and a flange extending radially from the main body, the flange defining an edge face slopes towards the main body to an axial face. At least one compression tool has a tool body having a first tool section and a second tool section extending transversely from the first tool section. The first tool section is translatable along a retention member in a first direction substantially perpendicular to the edge face such that relative movement causes the second tool section to apply a first compressive force on a composite article trapped between the axial face of the flange and the second tool section. A method of forming a gas turbine engine component is also disclosed.

The present invention relates to a functional fabric manufacturing method and a functional fabric thereby, which relates to a method for manufacturing an upcycle functional fabric, comprising steps of: (a) preparing a separator sheet with a microporous structure discarded due to treatment as defective or overproduction in production processes for manufacturing secondary batteries, (b) interposing an adhesive sheet between the separator sheet and a fabric sheet to be added to the separator sheet, thereby supplying each sheet, (c) laminating the separator sheet and the fabric sheet so that they are bonded by melting of the adhesive sheet, wherein in the step (b), each sheet is supplied to maintain a constant tension, but the separator sheet, the adhesive sheet, and the fabric sheet are all supplied at the same speed, and in the step (c), a stacked structure, in which the separator sheet, the adhesive sheet, and the fabric sheet are stacked in this order, is pressurized in a predetermined temperature atmosphere, and laminated.

A cosmetically altered fiberglass piece having an outer layer of curable gel-coat, an intermediate layer of textile fabric having a graphical element depicted thereon, and an inner layer of composite. A resin or epoxy is used to bond the layers to form the cosmetically altered fiberglass piece. Introduction of resin or epoxy is performed through one of a manual application, a vacuum infusion, or light RTM.

A method for obtaining a laminated bent glazing, particularly for a motor vehicle windscreen or roof includes (b) depositing, on a part of the surface of a stack of thin layers deposited on a first glass sheet, in a zone referred to as zone to be demarginated, a washable dissolving layer, a pre-firing at the end of which the stack of thin layers located under the washable dissolving layer is dissolved by the washable dissolving layer, creating a demarginated zone, eliminating (d) the washable dissolving layer by washing, bending (e) the first glass sheet and an additional glass sheet, together or separately, laminating (g) the first glass sheet with an additional glass sheet by a lamination interlayer having an opaque zone arranged facing the demarginated zone.