A label web and method utilize a substrate, first and second longitudinally spaced label arrays each including two or more double-sided adhesive labels removably attached to the substrate, and a peelable protective covering web extending generally coextensive with the substrate. The label arrays and the peelable protective web are configured such that the peelable protective web is selectively removable to expose the first label array while remaining removably attached to the second label array, with both the first and second label arrays remaining removably attached to the substrate, to thereby facilitate removal of all labels in the first label array as a group while the peelable protective covering web remains in place over the second label array.

An adhesive sign suited to use in retail applications includes a substrate layer. An adhesive layer is disposed on the substrate layer. The adhesive layer defines an exposed region for attachment to an associated structure. The adhesive layer is derived from a photo-curable inkjet composition. An ink layer is disposed on the substrate layer. The ink layer includes an image. The ink layer is derived from a photo-curable inkjet composition. The adhesive layer and ink layer can be formed in the same inkjet printing process and cured in a common photo-curing station. A stack of the adhesive signs can be assembled without interleaving a release liner between each pair of signs.

An RFID tag manufacturing system is provided that includes a conveyance device that conveys a base sheet provided with a plurality of antenna patterns to each of which an RFIC module is fixed. The system includes a laminating device that attaches a cover seal on the base sheet to cover the antenna patterns and a punching device that produces RFID tags by punching the cover seal and the base sheet with a punching blade that includes a frame-shaped cutting edge surrounding the antenna patterns to form a frame-shaped cut. The base sheet includes alignment mark in a non-attachment part of the cover seal. The punching device specifies the position of each of the antenna patterns covered with the cover seal based on the alignment mark, and punches the cover seal and the base sheet based on the specified position of the antenna pattern.

A liner in a label-liner combination is provided with a die cut portion made in the liner. The die cut portion is aligned with at least one edge in a label and a front side of the liner is attached to a backside of the label. The die cut portion of the liner is adapted to be removed from the liner when the label is removed from the label-liner combination. Dimensions, and orientation, and a location of the die cut portion in the liner are adapted to allow the label to be removed from the label-liner combination and applied to a surface by digits of a hand without touching an adhesive coating on the backside of the label and adapted to maintain proper printer waste liner spool operations when the liner is wound after application of the label.

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 first side (111) and a second side (112), the face comprising a direct thermal printable coating, wherein the method comprises supplying the face (110), and applying modified adhesive coating (121) on to a substrate (110, 611). The modified adhesive coating comprises water-based acrylic adhesive, and emulsified silicone additive. The method further comprises thermally drying the modified adhesive coating (121) on the substrate (110, 611) into a pressure sensitive adhesive coating (120). The substrate is the face (110) or a carrier material (611, 611a, 611b). 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 die cutting method that cuts patterns in a label is provided. According an embodiment, a method adjusts temperature of a label sheet comprising a laminated layer and a liner layer. The method further separates the laminated layer from the liner layer prior to making the cuts on the laminated layer. The method further cuts one or more patterns on the laminated layer. The method further re-attaches, the laminated layer to the liner layer.

A method of reducing label waste that employs a stand-alone or printer attached apparatus for cleanly and efficiently cutting a web of media or tag stock into individual units. The apparatus used by the method may cut vinyl, plastic, or RFID stock material in both back and forth directions without sacrificing cut quality, and preferably comprises a housing, a carriage assembly and a movable cutter assembly. The cutter assembly comprises a cutting element such as a wheel blade, and a pressure adjusting element for adjusting the amount of pressure applied by the cutting element to the stock material. Alternatively, the cutter assembly may be manufactured with a predetermined pressure load, but still permit an operator to adjust the depth of cut. The method involves using the cutting apparatus to make a series of cuts as the label material is incrementally advanced through the cutting apparatus.

A method of making a pad of labels comprises: printing display information on a top surface of a substrate; affixing a first layer of lamination material to a bottom surface of the substrate; affixing a second layer of lamination material to the top surface of the substrate, the second layer of lamination material having a release coating applied to a top surface thereof; applying an adhesive strip to a bottom surface of the first layer of lamination material, the adhesive strip being covered by a liner material; cutting the substrate having first and second layers of lamination material affixed into at least one label; removing the liner material to expose the adhesive strip after cutting the substrate into at least one label; and arranging the labels into a pad of labels.

A stand-alone apparatus for cutting a web of media or tag stock into individual units for use downstream of a printer. The apparatus may cut vinyl, plastic, or RFID stock material in both back and forth directions. The apparatus comprises a housing, a carriage assembly and a movable cutter assembly. The cutter assembly is easily interchangeable and comprises a cutting element such as a wheel blade, and a pressure adjusting element for adjusting the amount of pressure applied by the cutting element to the stock material. Alternatively, the cutter assembly may be manufactured with a predetermined pressure load, but still permit an operator to adjust the depth of cut. The apparatus may be powered by and or in hardline or wireless communication with a printer, or may further comprise a computer microprocessor, memory and user interface to function wholly independent from a printer.

A label manufacturing method includes: a cladding material manufacturing step, including: manufacturing adhesive, a release film including a base material and a surface material, and a transparent film into a cladding material, wherein a first side of the cladding material includes the base material of the release film, the transparent film, and the surface material of the release film, and a second side of the cladding material includes the adhesive and the surface material of the release film, and the first side and the second side are two sides of the cladding material which are side by side; and, a label die cutting step, including die cutting the transparent film and the base material of the release film at the first side of the cladding material into a first label unit, and die cutting the adhesive at the second side of the cladding material into a second label unit.