A metal transfer film of thermoplastic polymer includes a polymeric carrier film, a layer of metal to be transferred onto an article, and a layer of retention adhesive suitable for bonding the transferred metal layer to a surface of the article. The transferable metal layer is adjacent between the carrier film and the retention adhesive layer. Optionally, the carrier film has a releasably adhesive layer on the side in contact with the metal. The retention adhesive is a polyvinyl amine crosslinked with citric acid. The retention adhesive is deposited on the metal layer from a liquid solution and dried to a non-tacky, solid coating enabling handling of the metal transfer film in conventional film processing unit operations. The dry retention adhesive can be activated by the metal transfer operator remotely from the adhesive application process and provides significant oxygen, moisture and aroma barrier properties to the metal covered article.

A transfer apparatus includes: a body portion; and an adhesive portion connected to the body portion, with which a point light source of a display apparatus is attachable to and detachable from the transfer apparatus by contact therewith. The adhesive portion is defined by a plurality of surfaces in different planes from each other.

A method conceals optical defects in surfaces. The method includes: obtaining a digital image by a digital optical recording the optical defect and a surrounding surface; obtaining an imitation of the surface in a region of the at least one optical defect by image processing of the digital image; printing a mirror-inverted, true-to-scale representation of the surface imitation onto a transfer film; soaking the transfer film; applying an activator onto a the transfer film or onto the surface; aligning the transfer film onto the surface so that the surface imitation on the transfer film coincides with the optical defect on the surface; pressing the transfer film onto the surface; peeling the transfer film from the surface; pressing on the ink remaining on the surface; and after complete drying of the activator and of the ink: applying a protective layer onto the surface imitation.

A decorative article includes a base and a decorative portion. The base includes a grained surface formed in a grained manner. The decorative portion includes at least a protective layer, a metal layer, and an adhesive layer. The decorative portion is bonded to at least a part of the grained surface of the base by the adhesive layer.

A device for translaminating tension-sensitive films from a first liner to a second liner, wherein the device has a first transport device, a second transport device, and a laminating device. The first transport device is configured to transport a first laminated strip to a film delaminating station. The second transport device is configured to transport a second strip-shaped liner to the laminating device, which is designed to laminate the tension-sensitive film onto the second liner in order to form a second laminated strip. The first transport device and the laminating device are arranged relative to each other such that the tension-sensitive film is pulled off at the film delaminating station in the direction opposite the running direction of the first laminated strip at said station.

Transfer films, articles made therewith, and methods of making and using transfer films that include antireflective structures are disclosed.

The transfer film includes a temporary support, a resin layer, and a cover film in this order, in which when the cover film is peeled from the resin layer, a surface of the cover film that contacted the resin layer has surface roughnesses SRz and SRa of equal to or less than 130 nm and equal to or less than 8 nm respectively that are measured based on JIS-B0601-2001.

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 %.

In one aspect the invention provides a method of fabricating a laminate of flexible and compliant layers of material, such as used to provide a dielectric elastomer sensor. According to the method a flexible and compliant layer of material which is affixed to a substrate to avoid strain during processing is bonded to another layer of flexible and compliant material and released from the substrate to form a laminate. The layer of flexible and compliant material affixed to the substrate may be inspected prior to bonding.