The cationically photopolymerizable composition according to the present disclosure includes: (A) a polyfunctional epoxy compound having two or more epoxy groups per molecule; (B) a monofunctional epoxy compound having one epoxy group per molecule; (C) a photocation generator; and (D) an oxetane compound. At least one of the component (A) and the component (B) contains an epoxy compound ((A1) or (B1)) having a polyether backbone per molecule. A mass ratio of the component (A) to the component (B) falls within a range of 90:10 to 30:70.

A transparent protective layer and an electronic device including a transparent protective layer are provided. The transparent protective layer includes a first transparent plate having a first surface facing in a first direction and a second surface facing in a second direction opposite to the first direction; and an adhesive layer disposed on the second surface of the first transparent plate. The adhesive layer includes a first adhesive layer having a first adhesive force, and a second adhesive layer having a second adhesive force, which is less than the first adhesive force.

A window glass is disclosed. The window glass is divided into a transparent area and an opaque area formed to surround at least part of the transparent area. The window glass includes a transparent layer and an opaque layer that forms the opaque area by being stacked on a partial area of the transparent layer to correspond to the opaque area. The transparent layer includes a protective glass that forms a first surface of the window glass, a first transparent layer formed of a material that is hardened by irradiation of UV light, the first transparent layer including a pattern portion having a pattern formed on an area corresponding to the opaque area, and a second transparent layer formed of an optically isotropic material and formed between the protective glass and the first transparent layer. The opaque layer is formed on the pattern portion of the window glass.

The present invention provides a laminated film comprising a polyester film having a resin layer on at least one side thereof, wherein said resin layer contains at least metal oxide particles (A) having a number average particle diameter of 3 nm or more and 50 nm or less, and an acrylic resin (B), and a component (C.sub.1) derived from an oxazoline-based compound and/or a component (C.sub.2) derived from a melamine-based compound, and wherein said acrylic resin (B) contains a monomer unit (b.sub.1), a monomer unit (b.sub.2) and a monomer unit (b.sub.3). The present invention provides a laminated film which is excellent in transparency, suppression of interference pattern upon lamination of a high refractive index hard coat layer, adhesive property to a high refractive index hard coat layer, and adhesion under high temperature and high humidity conditions (adhesion under high temperature and high humidity conditions), at a low cost.

The yield of a peeling process is improved. A peeling apparatus includes a structure body with a convex surface and a stage with a supporting surface which faces the convex surface. The structure body can hold a first member of a process member between the convex surface and the supporting surface. The stage can hold a second member of the process member. The radius of curvature of the convex surface is less than the radius of curvature of the supporting surface. The linear velocity of the convex surface is greater than or equal to the speed of a rotation center of the structure body passing the stage. The first member is wound along the convex surface to be separated from the second member.

The present invention aims to provide a conductive layered body having excellent solvent resistance and scratch resistance as well as a low haze value and a significantly high light transmittance. The present invention relates to a conductive layered body including, as an outermost layer thereof, a conductive layer containing a conductive fibrous filler, wherein the conductive layered body has a Martens hardness of 150 to 3,000 N/mm.sup.2 as measured at an indentation depth of 100 nm from a surface, and a ratio, in atomic percentage, of a conductive material element constituting the conductive fibrous filler on an outermost surface-side surface of the conductive layer is 0.15 to 5.00 at %.

The present disclosure relates to a touch screen, a manufacturing method thereof and a display device. The touch screen comprises: a glass substrate, a touch functional layer on the glass substrate, a white ink frame on the touch functional layer, and a black ink layer partially covering the white ink frame. The black ink layer has an extension portion extending away from the white ink frame along the touch functional layer. The extension portion has a via hole for electrically connecting to the touch functional layer. In this case, by adding a black ink layer on the white ink frame and fabricating a via hole structure in the extension portion of the black ink layer, an electrical connection with the touch functional layer is achieved.

A plastic laminate structure including a plurality of, or a plurality of kinds of, plastic layers and an adhesive layer. The plastic layers are laminated together in a first direction. All the plastic layers are comprised exclusively of extruded plastic layers. The adhesive layer affixes together two of the plastic layers that are adjacent to each other in the first direction.

A protective shield includes a rigid base layer, and an outer cushioning layer from a flexible film material laminated to an outer surface of the base layer. The outer cushioning layer includes two or more layers of flexible film laminated together via an intermediary adhesive. The protective shield also has a mounting adhesive layer applied on the lower surface of the shield. The mounting adhesive allows the shield to be removably mounted to a display surface, such as a touch screen surface for an electronic device. When the shield is properly mounted to the display surface, the outer layer formed from flexible film material faces away from the display surface. The flexible cushioning layer on the outer surface of the shield allows the shield to protect the display surface such that the display surface can withstand higher levels of impacts without breaking or shattering.

A bonding operation to increase the bond between a coating layer and substrate is described. The coating layer may be designed to resist residue on a substrate that covers a display of an electronic device. An adhesion layer including silica (SiO.sub.2) and a catalyst or dopant, such as zirconium, may be used to bond the coating layer with the substrate. The dopant can alter the chemical nature of the adhesion layer and increase the number of chemical bonding sites at a bonding surface of the adhesion layer, thereby creating an activated bonding surface. One activated surface of the adhesion layer can be bonded with the substrate, while another activated surface of the adhesion layer can be bonded with the coating layer.