The present invention provides a coating material that can improve gravure printing characteristics of the printing surface of a printing substrate to favorably transfer an ink fed in the cell of a gravure printing roll to the printing surface of the printing substrate, thereby achieving the beautiful gravure printing. The coating material of the present invention is a coating material for forming a surface layer, serving as a printing surface, on a printing substrate on which gravure printing is to be performed, and the coating material is characterized by including a vinyl chloride-vinyl acetate-unsaturated fatty acid copolymer that includes 80 to 90% by mass of a component of vinyl chloride, 9.2 to 19.5% by mass of a component of vinyl acetate, and 0.1 to 0.8% by mass of a component of an unsaturated fatty acid.

An inkjet printed flexible film for decor applications is provided. In particular the present invention relates to an inkjet printed flexible film comprising a polymer film and an ink-receptive layer comprising polymerizable and/or crosslinkable compounds or a polymer crosslinked via (meth)acrylate moieties. Ink pigments can be applied to the ink-receptive layer in a print pattern by ink jet printing. The ink-receptive layer can be printed by means of industrial digital inkjet printing. The decor applications include any decorated surfaces for flooring, wall covering, furniture, ceilings and the like.

[Problem] To provide a thermal transfer image-receiving sheet that enables a high-density image to be formed on the receiving layer, has high easiness of cutting, and in addition, has high concave curl generation preventiveness.

[Solution] A thermal transfer image-receiving sheet according to the present invention is characterized by including a first extrusion resin layer, a substrate, a second extrusion resin layer, a porous layer, and a receiving layer, wherein the ratio of the total of the thickness of the second extrusion resin layer and the thickness of the porous layer to the thickness of the first extrusion resin layer (the total of the thickness of the second extrusion resin layer and the thickness of the porous layer/the thick of the first extrusion resin layer) is 1.05 or more and 1.40 or less, and the substrate has a bending resistance of 1600 mg or more and 2500 mg or less.

An inkjet printable flexible film for packaging applications is provided which includes (a) a biaxially oriented polymer film having a thickness in the range of from 8 to 70 μm; and (b) at least one ink-receiving layer including boehmite particles and poly(vinyl alcohol) having a degree of hydrolysis of from 78 to 96 mol % in a weight ratio ranging from 6.5:1 to 20:1 coated over one surface of the biaxially oriented polymer film at a dry coating weight being in the range of from 5 to less than 25 g/m.sup.2, wherein the ink-receiving layer (b) is formed by (i) applying an aqueous coating composition including boehmite particles, an acidic dispersing agent, poly(vinyl alcohol), and boric acid and/or a borate, or (ii) applying boric acid and/or a borate in a first step and then an aqueous coating composition including boehmite particles, an acidic dispersing agent, poly(vinyl alcohol), and optionally further boric acid and/or borate. The packaging applications include the packaging of food, pet food, beverages, pharmaceuticals and/or personal care products.

The present disclosure is drawn to printable media. A printable medium includes a substrate having a first side and a second side. An ink-receiving layer is positioned on the first side of the substrate. The ink-receiving layer includes a colloidal sol. An ink-penetrable layer is positioned on the ink-receiving layer. The ink-penetrable layer includes a binder and polymer particles having a glass transition temperature from 80° C. to 150° C. A repositionable adhesive layer is positioned on the second side of the substrate. A release liner is removably positioned on the repositionable adhesive layer. A friction control layer is positioned on the release liner, where the friction control layer includes a slip aid.

An inkjet recording medium includes a substrate having a resin layer, a bonding layer disposed on the resin layer, and an ink-receiving layer disposed on the bonding layer. The surface of the inkjet recording medium on the ink-receiving layer side of the inkjet recording medium has a 20° glossiness of 13.0 or more. The bonding layer contains an ultraviolet inhibitor at a content of 5.0% by mass or more and 35.0% by mass or less based on the total mass of the bonding layer.

Dispersible record materials or media include a water-soluble or water-dispersible paper substrate, a printable layer carried by the substrate, and a base coat between the substrate and the printable layer. The printable layer may be a thermally responsive layer, e.g. containing a leuco dye and an acidic color developer, or an inkjet receptive layer. The binder material used in the base coat, and the base coat itself, are non-water-soluble, but nevertheless tailored in such a way that the record material as a whole is water-dispersible, i.e., it breaks apart under the influence of water with minimal agitation. The binder material of the base coat is preferably a non-resinous binder, a particulate binder, and/or a binder derived from a dispersion, such as latex. Use of such a binder material in a carefully selected concentration, with other elements, provides a base coat that allows for high quality images to be thermally printed at high print speeds on the thermally responsive layer.

The present invention relates to: an ink-receiving layer composition for a decorative member, the composition comprising an acrylic emulsion, a metal salt, and organic particles or inorganic particles; a decorative member comprising a base layer, a printing layer formed on the base layer, and an ink-receiving layer disposed between the base layer and the printing layer and formed of a composition comprising an acrylic emulsion, a metal salt, and inorganic particles; and a method for manufacturing a decorative member, the method comprising a step for preparing a base layer in a flat state, a step for coating a composition comprising an acrylic emulsion, a metal salt, and organic particles or inorganic particles on the base layer, a step for drying or UV curing the coated composition to form an ink-receiving layer, and a step for forming a printing layer on the ink-receiving layer.

A printable sheet assembly and method provide for feeding cardstock sheets through a printer. The printable sheet assembly may include a first fold region. The first fold region comprises a robust perforated line disposed horizontally across the sheet assembly. The printable sheet assembly may include a second fold region. The second fold region may comprise a second robust perforated line disposed horizontally across the sheet assembly. The sheet assembly may include a product such as a name tag, business card, label, or card formed into the sheet assembly and configured to be processed through a printer device to receive indicia thereon.

A fabric printable medium includes a fabric base substrate including yarn strands and voids among the yarn strands; a finishing coating attached to the yarn strands of the fabric base substrate to form coated yarn strands; and pore spaces among the coated yarn strands and coinciding with at least some of the voids of the fabric base substrate. The finishing coating includes a crosslinked polymeric network. The fabric printable medium further includes a fire retardant coating applied to aback-side of the coated yarn strands.