A recyclable, laminated polyolefin-based film structure comprises two or more film plies laminated to each other. Each of the laminated film plies comprises one or more polyolefin-based films. The film structure has an energy cured coating layer or a two-part coating layer disposed on the outermost outward facing surface of the film structure and a printed ink layer on an interior surface of one of the polyolefin-based polyolefin layers. In certain embodiments, the outermost surface of the laminated polyolefin-based film structure has a melting temperature which is at least 100 degrees Celsius, and more preferably 150 or 180 degrees Celsius, higher than a melting temperature of the innermost surface of the laminated polyolefin-based film structure.

The present application is drawn to infrared reflective ink formulations, infrared reflective dried coatings prepared from such inks, and IR-reflective substrates and adhesive tapes prepared from such inks and coatings. The inks are suitable for printing by gravure or flexo methods onto polymeric substrates such as PET, paper, or other substrate materials. The coatings are reflective in the near-infrared range. The coatings and tapes are well suited for use in manufacturing methods. The coatings and/or the tapes are ultrathin, on the order of a few micrometers, making them attractive for use in different industrial applications.

A fabric formed by an interweaving of monofilaments (2) of synthetic material and which has two opposite metalized faces, in which at least one of said faces has at least one color (5) which determines the level of transparency.

Compared to the known fabrics for making transparent panels for the building sector, the fabric according to the invention offers the advantage of allowing control of the level of transparency to light, depending on the color applied to the metalized surface of the fabric.

The present application relates to a method for manufacturing an indicator for food that can visually check the quality change in food in a package state, an indicator for food manufactured therefrom, and a method for checking the storage status of food using the same. The manufacturing method of an indicator for food of the present application includes bonding a first film, on which an indicator layer including a pH-sensitive indicator is formed on one surface thereof, and a second film, on which an adhesive layer is formed on one surface thereof, so that the indicator layer of the first film and the adhesive layer of the second film can face each other.

A floor element includes a substrate made of polymer, a top layer on one of the two sides of the substrate and a polymeric foamed layer on the other of the two sides of the substrate. The density of the polymeric foamed layer is less than 120 kg/m.sup.3.

A seamless three-dimensional cover (1) for an electronic device (2), the seamless three-dimensional cover (1) comprising of at least one glass base layer (3) and at least one glass rim layer (4). At least one layer of color inducing film (5) is arranged between at least one of the base layer (3) and the rim layer (4), or between two adjacent rim layers (4). The base layer (3), the rim layer(s) (4), and the layer of color inducing film (5) are fused together to form the seamless three-dimensional cover (1). This facilitates a strong and durable three-dimensional cover, which cover is translucent as well as at least partially colored. Furthermore, the cover does not affect the function of components such as millimeter-wave antennas.

Floor element comprising a top layer (102) attached to a substrate layer (104), in which the top layer (102) is itself layered, the top layer (102) comprising: —an optional backing layer (122) made of flexible polymer, —a flexible or semi-rigid polymer layer (124), onto or into which optionally at least one reinforcing layer (126) is attached or embedded, and —a finishing layer comprising a decorative layer (132), a wearing layer (134) thereon and optionally a coating (136) thereon; the substrate layer (104) being a rigid substrate layer.

Described herein is a process for preparing a flexible packaging material. The process may comprise: providing a printed first flexible substrate comprising an ink composition on a surface of a first flexible substrate, the ink composition comprising a first thermoplastic resin; depositing a further composition comprising a cross-linker, a white pigment and a second thermoplastic resin onto the printed ink composition such that the thermoplastic resin of the ink composition is cross-linked; and laminating the first flexible substrate with a second flexible substrate such that the ink composition, the further composition and the cross-linker are disposed between the first and second flexible substrates.

The present disclosure relates to a decoration member comprising a color developing layer comprising a light reflective layer and a light absorbing layer provided on the light reflective layer; and a substrate provided on one surface of the color developing layer, wherein the light absorbing layer comprises a molybdenum-titanium oxide (Mo.sub.aTi.sub.bO.sub.x).

The present invention relates to method for producing a printed decorative paper comprising the steps of: i) providing a substrate paper; ii) applying to said substrate paper a decorative layer; iii) applying to said decorative layer a liquid coating consisting essentially of a polymerizable mixture; iv) applying polymerization conditions to form a polymerized layer on said decorative layer. An object of the present invention is to provide a method for manufacturing a printed decorative paper, which decorative paper is processed to form a decorative panel, which decorative panel thus obtained will exhibit a good resistance against weather influences.