The composite structure includes a fiber-containing layer, such as a fiberboard layer or other layer having fibers from natural and/or synthetic sources, and a mineral-containing layer covering the fiber-containing layer. The fiber-containing layer and mineral-containing layer can be shaped, sized and manufactured such that the composite structure formed therefrom is capable of being machined to form a storage article. The composite structure has advantages in that it can improve whiteness, opacity, ink adhesion, materials reduction, barrier properties, recyclability, and printability. The composite can reduce polymer mass requirements for heat seal, barrier, and fiber adhesion. Further improvements include economics, pliability, and flexibility that is increased over the pliability of the fiber-containing layer alone.

Paper is disclosed for use in making repositionable or removable adhesive labels. The adhesive can be applied in patches or discrete areas to the paper or to a layer of material that cleans rollers in the manufacturing line and/or in printers. The adhesive can be applied in single or multiple layers. The paper is light weight paper and preferably thermal paper for use in POS printers.

Paper is disclosed for use in making repositionable or removable adhesive labels. The adhesive can be applied in patches or discrete areas to the paper or to a layer of material that cleans rollers in the manufacturing line and/or in printers. The adhesive can be applied in single or multiple layers. The paper is light weight paper and preferably thermal paper for use in POS printers.

A device, system and method for making custom printed products. In one embodiment of the method, an image is received from a user device along with a size of for the printed product. Pixel edge detection is performed on the image to generate a plurality of polygons corresponding to all shapes in the image. Polygons below a size threshold are removed. An offset is applied to each polygon. The polygons are combined. A smoothing algorithm is applied to the combined polygon. A set of curves that define the smoothed polygon is determined. A cut path is dynamically generating for the printed product in real-time in dependence on the set of curves and the received size so that the cut path has a shape dependent on the set of curves and a size dependent on the received size. The image is printed on a substrate material for the image product in dependence on the received size and the offset so that the printed image has a printed size equal to the received size less the offset. The substrate is cut in dependence on the cut path.

Disclosed is a method of cutting off self-adhesive linerless endless tape labels, using a cutter of a label printer, wherein the cutter comprises a transport roller, which is rotatable about an axis of rotation, and a blade unit that is linearly travelable in parallel with the axis of rotation of the transport roller and that has a cutting blade directed in the direction toward the transport roller, where tape labels pass between the transport roller and the blade unit, and are transported further step-wise in a motorized manner, by one label, and, between two consecutive further transport steps, the blade unit is linearly traveled in a motorized manner between a start position and a target position in order to cut off a label, such that the label is completely cut off and is held at the transport roller by the blade unit in the target position of the blade unit.

A label is to be wrapped around an adherend after being printed. The adherend has a diameter equal to or smaller than a prescribed diameter. In the label, a base material has a printing surface. An adhesive layer is provided on an opposite side surface of the base material from the printing surface. A release material is bonded to the adhesive layer with a portion of the adhesive layer exposed. The release material has a higher stiffness than the base material. A mark for alignment is to be used when bonding together exposed sections of the adhesive layer or an exposed section of the adhesive layer with the release material in order to form the label into a loop shape. The mark is provided at a position for forming the label in the loop shape having an inner diameter greater than the prescribed diameter.

The composite structure includes a fiber-containing layer, such as a fiberboard layer or other layer having fibers from natural and/or synthetic sources, and a mineral-containing layer covering the fiber-containing layer. The fiber-containing layer and mineral-containing layer can be shaped, sized and manufactured such that the composite structure formed therefrom is capable of being machined to form a storage article. The composite structure has advantages in that it can improve whiteness, opacity, ink adhesion, materials reduction, barrier properties, recyclability, and printability. The composite can reduce polymer mass requirements for heat seal, barrier, and fiber adhesion. Further improvements include economics, pliability, and flexibility that is increased over the pliability of the fiber-containing layer alone.

This invention relates to a method for manufacturing a direct thermal linerless label web (100), the direct thermal linerless label web (100) comprising a face (110) having a multilayer structure comprising at least three layers, the face comprising a base layer (113), a direct thermal printable coating (115), and an intermediate layer (114) disposed between the base layer and the direct thermal printable coating, wherein the intermediate layer has a grammage in a range between 0.9 g/m2 and 7 g/m2, total amount of mineral pigments in the intermediate layer is equal to or less than 4 g/m2, and a mineral pigment content of the intermediate layer is less than 85 wt. %, preferably equal to or less than 75 wt. %, calculated from total dry weight of the intermediate layer, wherein the method comprises: supplying the face (110), applying a water-based acrylic adhesive coating (121), and the thermally drying the adhesive coating (121) into a pressure sensitive adhesive coating (120), wherein the water-based acrylic adhesive coating (121) is applied onto the face, or the water-based acrylic adhesive coating (121) is applied on to a carrier material, and the method further comprises: transferring the pressure sensitive adhesive coating from the carrier material on to the face. This invention further relates to a direct thermal linerless label web (100), and a use of a direct thermal linerless label (100) in on-demand printing.

A process for automatically correcting defects and non-compliances in self-adhesive labels or the like on a continuous band, comprising the steps of: advancing the continuous band (10) so as to expose the self-adhesive labels to inspection means (12); if these inspection means (12) detect a non-compliance in at least one self-adhesive label, imparting a bend to the continuous band (10) as to cause detachment of the defective label from said main continuous band (10); replacing this defective label with a replacement label (11); and rewinding the continuous band (10) in a direction opposite to the direction of travel until the replacement label (11) is upstream of the inspection means (12).

The composite structure includes a fiber-containing layer, such as a fiberboard layer or other layer having fibers from natural and/or synthetic sources, and a mineral-containing layer covering the fiber-containing layer. The fiber-containing layer and mineral-containing layer can be shaped, sized and manufactured such that the composite structure formed therefrom is capable of being machined to form a storage article. The composite structure has advantages in that it can improve whiteness, opacity, ink adhesion, materials reduction, barrier properties, recyclability, and printability. The composite can reduce polymer mass requirements for heat seal, barrier, and fiber adhesion. Further improvements include economics, pliability, and flexibility that is increased over the pliability of the fiber-containing layer alone.