Compression molding methods for improving the durability and weatherability of a composite material are provided. The methods include disposing a protective surface film on a composite material; adhering the protective surface film to the composite material; and compression molding the protective surface film. The composite material comprises a thermoplastic polymer and a reinforcement material. The protective surface film comprises at least one stabilizer that minimizes or prevents degradation of the underlying composite material when exposed to ultraviolet radiation and/or heat. The composite material may be heated in an oven having an environment comprising oxygen. The protective surface film may be disposed on the composite material prior to the composite material entering the oven; while the composite material is in the oven; or after the composite material exits the oven.

One embodiment provides a multilayer hard coating film which sequentially includes, from the superficial layer side, a first hard coating and a resin film, and wherein: the first hard coating is formed from a coating material that contains a specific amount of (A) a polyfunctional (meth)acrylate and a specific amount of (B) a water repellent agent, while containing no inorganic particles; and the resin film includes at least one layer of () an acrylic resin that contains 50-95% by mole of a structural unit derived from methyl methacrylate and 50-5% by mole of a structural unit derived from vinyl cyclohexane when the total of the structural units derived from polymerizable monomers is taken as 100% by mole. Another embodiment provides a multilayer hard coating film which includes a second hard coating in addition to a first hard coating, and wherein: the first hard coating contains (C) a silane coupling agent in addition to the above-described components (A) and (B); and the second hard coating is formed from a coating material that contains a specific amount of (A) a polyfunctional (meth)acrylate and a specific amount of (D) inorganic fine particles having an average particle diameter of 1-300 nm.

Disclosed are a retro-reflective sheet and a method for manufacturing the same. The retro-reflective sheet includes a heat-resistant film, a first thermoplastic bonding layer, a first heat-resistant layer, a colored layer, a light transmitting layer, a colored part allowing a portion of scattered light to be emitted to the outside through a first light condensing layer, a second thermoplastic bonding layer, a second heat-resistant layer, a reflective layer, and a reflective part reflecting light input to a reflective area through a second light condensing layer.

The disclosure provides an attaching device for conductive adhesive tape and a manufacturing method of display panel. The attaching device disclosed herein comprises an adhesive tape attaching unit and a frame. An upper portion of the frame is provided with a first guide rail and a pair of second guide rails in parallel. The first guide rail is arranged to be perpendicular to the pair of second guide rails and movably connected between the pair of second guide rails. The adhesive tape attaching unit is movably mounted on the first guide rail. The attaching device for conductive adhesive tape and the manufacturing method of display panel according to the disclosure can attach the adhesive tape to a motherboard. The motherboard with the adhesive tape attached to can be cut to form a plurality of display panels. Therefore, it is possible to improve attaching efficiency and reduce cost of manufacturing.

An embodiment provides an adhesive film having, in order from the surface layer side, a first hard coat, a second hard coat, a transparent resin film layer, and an adhesive layer. The first hard coat is formed from a coating that does not include inorganic particles. The second hard coat is formed from a coating that includes inorganic particles. The adhesive film satisfies the following conditions: (i) the total light transmittance is at least 85%; and (vii) the pencil hardness of the first hard coat surface is at least 5H. Another embodiment provides an adhesive film having, in order from the surface layer side, a first hard coat, a second hard coat, a transparent resin film layer, and an adhesive layer. The first hard coat is formed from a coating that does not include inorganic particles. The second hard coat is formed from a coating that includes inorganic particles. The adhesive film satisfies the following conditions: (i) the total light transmittance is at least 85%; (iv) the water contact angle at the first hard coat surface is at least 100 degrees; and (v) the water contact angle at the first hard coat surface after 20,000 reciprocal cotton rubs is at least 100 degrees.

A printable blank sheet includes a sheet with a top substrate and a bottom layer, a dry lift adhesive connecting the top substrate to the bottom layer, cut lines in the sheet that extend through the top substrate and the dry lift adhesive but not through the bottom layer, and a folder pocket cut into the top substrate with a periphery of the folder pocket defined by the cut lines. The folder pocket can be removed from the sheet by separating the folder pocket and the bottom layer along the dry lift adhesive.

A light emitting device can further improve light extraction efficiency. A method of manufacturing such a light emitting device can also prove advantageous. The light emitting device includes a light emitting element, a light-transmissive member which is disposed on a light extracting surface side of the light emitting element, and a reflecting layer disposed on an element bonding surface of the light transmissive member where the light emitting element is disposed and adjacent to the light emitting element. The light-transmissive member, in a plan view, has a planar dimension greater than the light extracting surface of the light emitting element.

A system for laminating an optical film according to an exemplary embodiment of the present disclosure includes a panel transfer unit to transfer a panel, a first laminating unit to laminate an optical film full-cut into a predetermined length on a first surface of the panel along a first direction parallel to a transfer direction of the panel, and a second laminating unit to laminate an optical film full-cut into a predetermined length on a second surface of the panel along a second direction equal or opposite to the first direction, the second laminating unit rotating the optical film supplied in a full-cut state along the second direction in a horizontal direction and laminating the optical film.

Provided are an electroacoustic conversion film web, an electroacoustic conversion film, and manufacturing methods thereof in which costs can be reduced by reducing the number of operations without damage to thin film electrodes, the points of electrode lead-out portions can be freely determined, and thus high productivity can be achieved. A preparation step of preparing an electrode laminated body in which a single thin film electrode and a single protective layer are laminated and a lamination step of laminating the electrode laminated body and an piezoelectric layer are included. A non-adhered portion that is not adhered to the piezoelectric layer is provided in at least one end portion of the thin film electrode in a case where the electrode laminated body and the piezoelectric layer are laminated in the lamination step.

The present invention relates to an apparatus and a method for manufacturing a vehicle dash isolation pad. The method includes bonding a microfiber sound absorbing material to an adherend by using latent heat of a preheated adherend. As such, the vehicle dash isolation pad with improved weight reduction, sound absorption, and sound insulation effects can be obtained.