A label containing a base layer (A) and an adhesive layer (C) provided in contact with one surface of the base layer (A), wherein the base layer (A) contains a thermoplastic resin and at least one of inorganic fine powder and an organic filler, and the base layer (A) is stretched in at least one direction, and the film has an internal bond strength measured according to TAPPI T569 of from 0.4 to 0.95 kg.Math.cm on a side of the adhesive layer (C) and from 0.4 to 1.5 kg.Math.cm on a side opposite thereto, is easily recognized by the naked eye for the fact that the film has been peeled from an adherend, and is difficult to be restored by re-adhering after peeling.

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.

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.

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 method for producing labels of different label variants includes: performing first and second printing operations to form on a source material web using a digital printing device first and second digital prints associated with first and second label variants, respectively, the two digital prints differing at least with respect to a respective print image; forming on the source material web a machine-readable indicating element detectably different from the first and second label variants and arranged to indicate a change of label variant type; and die cutting to form a material web and processing the web, including controlling and making up the first label variant, detecting the indicating element using a controller, cutting the web in the transition between the label variants and controlling and making up the second label variant so that separate first and second label webs are formed with the first and second label variants, respectively.

The invention concerns a linerless self-adhesive material obtained starting from a self-adhesive material with a liner, by means of a process that comprises the delamination of the liner from a self-adhesive layer, activation of the liner or self- adhesive layer, transferral of the liner over the self-adhesive layer and re-lamination of the two components so as to produce the linerless self-adhesive material. The liner or the self-adhesive layer is coated with a thermo-adhesive that allows for permanent lamination of the liner located on the self-adhesive layer.

In accordance some aspects of the present application, there is provided a label assembly, a release liner and methods of preparing label assemblies and release liners. In one aspect, a label assembly includes a top layer having a front side and a back side and an adhesive applied at the back side of the top layer. The label assembly also includes a silicone-treated liner contacting the adhesive to sandwich the adhesive between the top layer and the liner. The silicone-treated liner comprises paper that does not have a machine finish or gloss finish on a side of the paper that contacts the adhesive to allow at least a portion of the silicone in the silicone treatment to penetrate the paper.

A label web including a substrate is provided. The label web includes a first label removably affixed to a first side of the substrate. The first label is fabricated from a first material. A second label is removably affixed to the first side of the substrate adjacent to the first label in a side-by-side relationship. The second label is fabricated from a second material which differs from the first material. The first labels may be utilized to print desired information thereon and the second labels may fabricated from a transparent, protective material coating which may positioned on the first labels to discourage damage to the first labels from exposure to water or handling when the first labels are affixed to corresponding products.

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.

The invention relates to methods and an apparatus for cutting planar substrates charged with pharmaceutically active agents. In particular, the planar substrates comprise transdermal systems or orally dissolvable films.