Apparatus and methods for transferring a pigment-based decorative design onto a surface without using a plastic film or adhesive.

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 thermal transfer and process for producing it that provides a fully-digital printed heat transfer capable of little to no process changeover between different graphics. Specifically, the method comprises printing a digital image onto a treated adhesive substrate, applying the image side to a carrier substrate, then digitally cutting and removing substrate not containing graphic elements through a combination of kiss-and-through cutting to produce a high stretch, multi-color photographic quality print transfers for the apparel and soft goods industry.

A thermal transfer and process for producing it that provides a fully-digital printed heat transfer capable of little to no process changeover between different graphics. Specifically, the method comprises printing a digital image onto a treated adhesive substrate, applying the image side to a carrier substrate, then digitally cutting and removing substrate not containing graphic elements photographic quality, durable print transfers for the apparel and soft goods industry.

Provided are a decorative molded article that prevents sparkle and has a high contrast, a method for producing the decorative molded article, and a transfer sheet for use for the decorative molded article. The decorative molded article 10 is provided with a protective layer 2 having unevenness on a resin molded article 1, wherein in the surface of the protective layer 2, the arithmetic average roughness (Ra.sub.x1) according to JIS B0601:1994 at a cutoff value of 0.8 mm, the arithmetic average roughness (Ra.sub.y1) according to JIS B0601:1994 at a cutoff value of 0.08 mm, and the ten-point average roughness (Rz.sub.x1) according to JIS B0601:1994 at a cutoff value of 0.8 mm satisfy the following requirements (1) to (3): 0.30≤(Ra.sub.x1−Ra.sub.y1)/Ra.sub.y1≤0.85 (1), Rz.sub.x1/Ra.sub.x1≤15.0 (2), Ra.sub.x1≥0.14 μm (3).

The problem of this invention is to provide a transfer paper with good close contact to fiber materials and good color density of patterns formed on the fiber materials, good peeling, and no significant difference in texture between patterned and non-patterned areas of the fiber materials.

The present invention provides a transfer paper having a base material with one or more non-aqueous resin laminate layer(s) on one side of a base paper, and one or more coating layer(s) on the laminate layer(s) of the base material, wherein an outermost coating layer, which is positioned outermost in the coating layer(s) with respect to the base material, contains a white pigment and a binder, the white pigment contains at least an amorphous silica, and the binder contains at least five types consisting of a water-soluble polyester resin, a carboxylic acid-modified polyvinyl alcohol resin, an acrylic resin, a hydroxypropyl starch and an alginate.

There is provided an article comprising at least a first surface having: (a) a first binder layer; (b) a plurality of transparent microspheres partially embedded in the first binder layer wherein the transparent microspheres have refractive indices that are less than a refractive index of the first binder layer and wherein the plurality of transparent microspheres consist of microspheres having a refractive index of no more than 1.490. There is also provided a transfer article comprising: (a) a transfer carrier, the transfer carrier comprising: (i) a support layer; and (ii) a thermoplastic release layer bonded to the support layer; (b) a layer of a plurality of transparent microspheres, formed on a side of the thermoplastic transparent microsphere release layer opposite the support layer, wherein the plurality of transparent microspheres consist of microspheres having a refractive index of no more than 1.490.

In a foil transfer device for transferring a transfer layer from a foil film onto a sheet laid on the foil film, the foil film is wound on a supply reel, and taken up on a take-up reel. A heating member heats the foil film, and a pressure member is provided to press the foil film and the sheet between the pressure member and the heating member. A separator changes a traveling direction of the foil film having passed through between the heating member and the pressure member into a direction different from a direction of conveyance of the sheet, to thereby separate the foil film from the sheet. A first fan blows air toward the foil film positioned between the heating member and the separator.

An artificial textured stone slab and methods for manufacturing thereof, the method comprising the following steps: Step S01: using a printer to print an image in accordance with the size of an artificial stone slab to arrive at a print of the image; Step S02: placing the front face of the print onto a side of the artificial stone slab and smoothing out the print on the artificial stone slab; Step S03: feeding the artificial stone attached to the print into a heat and ink transferring machine and using the upper and lower clamp plates of the heat and ink transferring machine to tightly clamp the print to the artificial stone slab; Step S04: heating the artificial stone slab to 120° C. to 185° C. and maintaining for the temperature constant for 5-15 minutes, wherein the ink on the print is transferred onto the surface of the artificial stone slab; and Step S05: feeding the artificial stone slab, heated in accordance with the above step, out of the heat and ink transferring machine, removing the print, and cooling the artificial stone slab to room temperature.

Described herein a heat transfer label comprising a support portion comprising a release layer having a first side and a second side and a first carrier at least partially disposed on the first side of the release layer; and a transfer portion comprising a engravable first ink layer having a first side and a second side; and an adhesive layer having a first side and a second side, wherein a graphic design is engraved on the first ink layer using the laser light after the heat transfer label is at least partially bonded onto a substrate. Also described herein are methods of laser engraving a heat transfer label comprising at least partially bonding the heat transfer label described herein onto a substrate; and at least partially laser engraving the ink layer.