Methods of making printed flexible packaging material for retort applications include steps of digital printing on a flexible substrate material using polymeric ink and curing the printed ink. The printed ink on the material and packaging made therefrom exhibits resistance to blurring and discoloration under retort conditions.

In an aspect, there is provided a method of foil printing that may comprise providing a substrate having a surface comprising a first area and a second area, wherein the first area has printed thereon a first electrostatic ink composition comprising a first thermoplastic resin and substantially lacking a pigment and the second area has printed thereon a second electrostatic ink composition comprising a second thermoplastic resin and a pigment; applying a liquid solvent composition to the first electrostatic ink composition on the first area and the second electrostatic ink composition on the second area, to swell the first and second thermoplastic resins; and contacting a foiling material with the first electrostatic ink composition on the first area, such that the foiling material selectively adheres to the first area on the surface of the substrate. In another aspect, an electrostatic and foil printing system for performing the method is provided.

Provided is laminated glass and a preparation method thereof, an electronic device housing, and an electronic device. The laminated glass comprises at least two glass members and at least one adhesive film disposed in a stacked manner, where the glass members and the adhesive film are alternately disposed, wherein decorative layers are provided on surfaces of at least two of the glass members facing toward the adhesive film, and at least two of the decorative layers independently comprise at least one of an etched texture, an optical coating layer, and a pattern layer.

An electronic heat transfer label includes a substrate. A pattern layer is printed on the substrate, and an adhesive is printed on the pattern layer to form a first adhesive layer. A chip is attached onto the first adhesive layer, and an adhesive is printed on the chip to form a second adhesive layer. The second adhesive layer covers the chip, and a hot-melt layer is arranged on the second adhesive layer. A method for preparing the electronic heat transfer label includes: S1: printing an ink on a substrate and drying the ink to form a pattern layer; S2: printing an adhesive on the pattern layer and drying to form a first adhesive layer; S3: attaching a chip onto the first adhesive layer; S4: printing an adhesive onto the first adhesive layer and the chip, and drying to form a second adhesive layer.

A floor may include a substrate having a top side and a bottom side. A top layer may be provided on the substrate. The top layer may consist of a printed thermoplastic film and a thermoplastic transparent or translucent layer provided on the printed thermoplastic film. The top layer may be directly adhered to the substrate by heat welding the printed thermoplastic film and the top side of the substrate, in the absence of a glue layer. The substrate may be a synthetic material board including a filler. The substrate at least at two opposite edges may include coupling means provided in the synthetic material board. The thermoplastic transparent or translucent layer may be provided with a structure.

Described is a method of making a densified fiber batt that includes the steps of: a) providing a fiber batt with a first plurality of fibers having a first melting point and a second plurality of fibers having a second melting point different from the first melting point; and b) subjecting the fiber batt to heat and pressure in a static press, thereby forming a densified fiber batt having a first surface and an opposed second surface.

The invention relates to a method for the production of a laminated core comprising a stack of metallic plates, in which: —a metallic sheet (2, 3) is chosen, having a first main face (4, 8) and a second main face (6, 9) which are coated with a sub-layer comprising at least one material selected from epoxides and polyepoxides, —a layer (12, 20) with a thickness of less than 500 μm of a precursor composition selected from partly epoxides and at least partly cross-linked polyepoxides is placed in contact with said sub-layer, —a layer (16, 22) with a thickness of less than 500 μm of a curing composition comprising at least one crosslinking agent is placed in contact with said sub-layer, —said metallic sheet is punched, —the metallic plates are then superposed to each other.

A decorative asphaltic membrane that comprises a lower non-stick layer; an intermediate layer composed of a support between two layers of plastic and oxidized modified bitumen wherein the support is a polyethilene; an upper layer composed of three sheets: a lower metallic sheet, preferably aluminium, an intermediate polyester sheet and an upper polyethilene sheet wherein the polyester sheet provides a superficial printing with different chromatic patterns on its lower face. The printing imitates, not exclusively, bricks, tiles, lawn, wood, stone, texts, sports logotypes or those belonging to institutions and/or enterprises. The manufacturing process of the asphaltic membrane comprises the steps of: a. printing the lower face of the polyester sheet with a flexographic process or a hollow engraving process; b. drying the printing; c. laminating said printed polyester sheet between a polyethilene sheet and a support sheet forming the upper layer; and d. laminating said upper layer with an intermediate layer and a lower non-stick layer, wherein the intermediate layer is, in turn, a lamination of a polyethilene sheet between two layers of plastic or oxidized modified bitumen.

A medium includes a heat-sensitive medium and an adhesive medium. The heat-sensitive medium includes a first base material and a first color-developing layer. The first base material has a transparency. The first color-developing layer has a transparency. The first color-developing layer is provided on a first surface of the first base material. The first color-developing layer is configured to become less transparent to develop a first color when heated to a first temperature or higher. The adhesive medium is to be superimposed on and bonded to the heat-sensitive medium in their thickness direction. The adhesive medium includes a second base material and an adhesive layer provided on the second base material. The adhesive medium is to be bonded to the heat-sensitive medium on an opposite side of the first color-developing layer from the first base material. The first base material has one or more images pre-printed thereon.

A floor panel has a rectangular and oblong shape, and includes a substrate and a top layer provided on the substrate and forming a decorative side of the floor panel. The top layer is composed of a print provided on a carrier sheet and a transparent thermoplastic layer situated above the print. The substrate has a thickness from 2 to 10 millimeter and forms at least half of the thickness of the floor panel. The substrate is a polyurethane-based substrate and the transparent thermoplastic layer is polyurethane-based. The floor panel has a length of more than 1.1 meters and has a plurality of reinforcing layers situated outside the center line of the substrate. A reinforcing layer may be provided in combination with the substrate and the top layer.