Methods for providing a slip-resistant, water-resistant, and antibacterial surface to a piece of sporting equipment include receiving a substrate printed with an image. The image is printed with ultraviolet curable ink and the substrate is non-silicone and includes a top printable layer printed with the image, a middle adhesive layer, and a bottom removable layer. The method includes aligning the substrate to a surface of the piece of sporting equipment, removing the bottom removable layer of the substrate, and contacting the middle adhesive layer that is exposed against the surface of the piece of sporting equipment. The method further includes smoothing the top printable layer printed with the image against the piece of sporting equipment. The substrate and the image printed with ultraviolet curable ink conforms to the shape of the piece of sporting equipment and provides the slip-resistant, water-resistant, and antibacterial surface.

A method for producing a decorated molded part, a decorated molded part, as well as the use of a transfer film for producing a decorated molded part includes: Producing an intermediate product in the form of a composite body by applying a transfer ply of a transfer film to a first surface of a polypropylene film, wherein the transfer ply of the transfer film has at least one decorative layer. Forming the composite body having the polymer film with applied transfer ply of the transfer film. Inserting the formed composite body into an injection mold and back injection molding and/or overmolding and/or insert molding the formed composite body with a plastic material, containing or consisting of polypropylene. Optionally, the back injection-molded and/or overmolded and/or insert-molded formed composite body is coated, in a step, over the whole surface or over part of the surface with one or more primer layers and/or one or more varnish layers.

A conductive transfer for application to a surface of a wearable item comprises a first non-conductive ink layer and a second non-conductive ink layer. An electrically conductive layer is positioned between the first non-conductive ink layer and the second non-conductive ink layer. The conductive transfer also comprises an adhesive layer for adhering the conductive transfer to the surface of the wearable item. The adhesive layer comprises a larger cross-sectional area than the cross-sectional area of each of the first non-conductive ink layer, the second non-conductive ink layer and the electrically conductive layer.

An intermediate transfer medium that allows formation of high-density images on a transfer layer while suppressing printing unevenness and provides good foil cutting properties of the transfer layer, a combination of the intermediate transfer medium and a thermal transfer sheet, and a method for forming a print using the intermediate transfer medium. In an intermediate transfer medium having a transfer layer on a substrate, the transfer layer has a single layer structure including only a receiving layer or a layered structure including the receiving layer. When the transfer layer has the layered structure, the receiving layer is located furthest from the substrate among layers constituting the transfer layer. The receiving layer contains a binder resin having a number average molecular weight of 8000-32000 and a release agent. The content of the release agent based on the total mass of the receiving layer is 6% by mass or more.

Provided is a decorative molded article that uniformizes the brightness of an uneven surface and inhibits whitening. The decorative molded article is provided with a protective layer having an uneven surface on an adherend, and satisfying the following requirement 1-1: <Requirement 1-1> A black plate is stuck to the surface of the article on the adherend side thereof via a transparent pressure-sensitive adhesive layer to prepare a sample A. A visible light inclined by 10 degrees from the normal direction of the sample A is made to run into the uneven surface, and based on the specular direction of the incident light as a reference angle, a luminous reflectance is measured every 0.2 degrees within a range of the reference angle±5.0 degrees.

A method for the refinement of a panel and an apparatus for the refinement of a panel according to a method of this type. The method for the refinement of a panel includes: unpacking of a panel having a core made from wood material from a transport-safe packaging, a grounding in the form of at least one synthetic resin layer pressed together with the core and, if appropriate, a primer being arranged on a top side of the core, and a coating being arranged on a core underside lying opposite the top side of the core, and connection and locking means being attached to at least two mutually opposite side faces; application of a decorative layer having a decoration to the grounding or primer; and application of at least one wear layer to the decorative layer.

An apparatus for texturing a plastic substrate, while forming a dye sublimation image in the plastic substrate, wherein the plastic substrate has a first side and a second side, is provided. A textured cover is on a side of a platen, wherein the platen is on a first, untextured side of the textured cover. A first side of the dye carrier is on a second, textured side of the textured cover, and wherein the plastic substrate is supported on a second side of the dye carrier, wherein a first side of the plastic substrate is supported by the dye carrier, wherein the textured side of the textured cover has a texture to be transferred to the plastic substrate. A membrane is on the second side of the plastic substrate. A vacuum pump provides a vacuum between the membrane and the platen. A heater is positioned to heat the plastic substrate.

The invention relates to a device for carrying a substrate, for example a drinking cup, and clamping against the substrate, for example against an outer wall of the drinking cup, a clamping sheet, wherein the clamping sheet comprises a flexible and bendable material with a width and a length, said length being measured between longitudinal ends of the clamping sheet, wherein coupling members are provided at longitudinal ends of the clamping sheet, said coupling members comprising rods protruding in the width direction of the clamping sheet. The device is characterized in that the device comprises first recesses for receiving rods of a first width side that are positioned at opposite longitudinal ends of the clamping sheet and comprises second recesses for receiving rods of a second width side that are positioned at opposite longitudinal ends of the clamping sheet, and the device comprises a support member for carrying the device and the substrate.

Provided are a decorative film including a reflective layer which consists of a dielectric multi-layer film and develops a color due to an optical interference or a structural color, in which the dielectric multi-layer film has a plurality of regions having different reflection performances in an in-plane direction, at least one of the plurality of regions is a region having a specular reflectivity, and at least another one of the plurality of regions is a region having a diffuse reflectivity; and a molded product and an electronic device using the decorative film.

A design mount includes a design cutout having a design printed or adhered to the design surface and an adhesive tape on the back of the design cutout to mount the design cutout to any design surface. A plurality of design cutouts may be printed on a single sheet of material, and the design cutouts then cut out of the sheet. The design mount may also provide an artwork holder, having a shape that matches the shape of the design cutout. The inner perimeter of the holder may be about 1 mm smaller than the outer perimeter of the design cutout. The artwork holder may be heated, and the design cutout secured within the holder while the holder is heated. The holder then cools, providing a tight fit of the design cutout within the artwork holder.