A laminated construct such as a ticket or game piece includes an internal on-demand thermally printable layer hidden between substantially opaque substrates. One of the substrates is a metallized film and the other substrate is a direct thermal print medium. The construct can be arranged in various ways including an arrangement for presenting some thermally printed information for immediate viewing and other thermally printed information that is temporarily hidden from view beneath the metallized film. The arrangements include arranging the metallized film as a plurality of island that are individually peelable apart from the direct thermal print medium for revealing the temporarily hidden information.

A laminated construct such as a ticket or game piece includes an internal on-demand thermally printable layer hidden between substantially opaque substrates. One of the substrates is a metallized film and the other substrate is a direct thermal print medium. The construct can be arranged in various ways including an arrangement for presenting some thermally printed information for immediate viewing and other thermally printed information that is temporarily hidden from view beneath the metallized film. The arrangements include arranging the metallized film as a plurality of island that are individually peelable apart from the direct thermal print medium for revealing the temporarily hidden information.

It is the object of the present invention to provide a new polymer coating for low temperature plastics and plastic foams that allows for the application of disperse dyes in a sublimation process that preserves the original properties of the underlying plastic substrate. The composition includes an optically clear synthetic organic polymer base holding two layers, a first reflective layer supported by the low temperature plastic substrate that includes IR radiation reflecting additives, and a second layer supported by the first layer having light scattering particulate additives. The disperse dyes utilized in the invention may include additives to absorb IR radiation provided by an external IR source positioned above the disperse dyes causing the dyes to sublimate and diffuse quickly into the light scattering layer. The combination of these layers allows for diffusion of the disperse dye ink into the light scattering layer while protecting the low temperature plastic below.

The invention relates to a double-side printable label suitable for machine readable labelling of food containers and a method for manufacturing such label, wherein the label is arranged to comprise a base paper made of chemical pulp that separates the face and reverse sides, the face side comprising a layer of temperature sensitive coating which free of bisphenol A and suitable for direct thermal printing, the reverse side comprising a layer of pressure sensitive adhesive, which is suitable for flexographic printing with ultraviolet curable inks, and wherein the machine readability of the label is improved by means of the pressure sensitive adhesive layer thickness having effect on the static sensitivity of the temperature sensitive coating of the label.

The invention relates to a double-side printable label suitable for machine readable labelling of food containers and a method for manufacturing such label, wherein the label is arranged to comprise a base paper made of chemical pulp that separates the face and reverse sides, the face side comprising a layer of temperature sensitive coating which free of bisphenol A and suitable for direct thermal printing, the reverse side comprising a layer of pressure sensitive adhesive, which is suitable for flexographic printing with ultraviolet curable inks, and wherein the machine readability of the label is improved by means of the pressure sensitive adhesive layer thickness having effect on the static sensitivity of the temperature sensitive coating of the label.

A roll of direct-thermal material may have a length of direct-thermal material including a facestock. An adhesive layer is on a first side of the facestock. A direct thermal coating is on a second side of the facestock, the direct thermal coating configured to selectively darken by heat activation when direct thermal printed. a cured ultraviolet LED coating is on the direct thermal coating, the cured ultraviolet LED coating having photoinitiators with substantial activation at an exposure limited to LED radiation at a 365 nm-450 nm wavelength range, and configured to allow direct thermal printing of the direct thermal coating therethrough, the cured ultraviolet LED coating curable without heat activating the direct thermal coating. The length of direct-thermal material being rolled on itself.

A roll of direct-thermal material may have a length of direct-thermal material including a facestock. An adhesive layer is on a first side of the facestock. A direct thermal coating is on a second side of the facestock, the direct thermal coating configured to selectively darken by heat activation when direct thermal printed. a cured ultraviolet LED coating is on the direct thermal coating, the cured ultraviolet LED coating having photoinitiators with substantial activation at an exposure limited to LED radiation at a 365 nm-450 nm wavelength range, and configured to allow direct thermal printing of the direct thermal coating therethrough, the cured ultraviolet LED coating curable without heat activating the direct thermal coating. The length of direct-thermal material being rolled on itself.

A visual security feature is provided that is disposed on a target. The visual security feature includes two substantially transparent layers. At least one of the two substantially transparent layers is present in an image-wise pattern.

A thermal recording medium includes: a transparent base material and a thermal recording layer on the base material. The thermal recording layer contains a dispersant having a carboxyl group and a crosslinking agent including an epichlorohydrin-modified polyamide polyamine resin or an organic compound containing an oxazoline group.

The thermal transfer image-receiving sheet according to the present disclosure includes a receiving layer, a front substrate, a porous layer, and a rear substrate in this order and further includes a metal-containing layer interposed between the receiving layer and the front substrate or between the front substrate and the porous layer. The thermal conductivity of the thermal transfer image-receiving sheet which is measured on the receiving layer-side is 0.38 W/m.Math.K or less. The Martens hardness of the thermal transfer image-receiving sheet which is measured on the receiving layer-side is 10.0 N/mm.sup.2 or less. The 45-degree specular gloss of the thermal transfer image-receiving sheet which is measured on the receiving layer-side is 800 or more.