A self-laminating rotating cable marker label is constructed of a transparent film having a first adhesive area, an adhesive-free smooth area, and a second adhesive area. A print-on area forms one side of the transparent film, the print-on area adapted to receive indicia identifying the cable about which the marker label is applied. A perforation extends across the transparent film providing a line of separation of the transparent film. When wrapped around a cable, the second adhesive area overlies the print-on area such that the cable identifying indicia is visible through the transparent second adhesive area. As the transparent film is wrapped around the cable, the first adhesive area adheres to the cable. The remainder of the transparent film is rotated, breaking the perforation, whereby the smooth area of the film in contact with the cable provides smooth rotation of the label around the cable.

A labeling article and a method of use and assembly of the labeling article, where the labeling article comprises a label, an elastic securing band, and a release liner, and where the elastic securing band is configured to be stretched to define a loop between the elastic securing band and the release liner.

It is intended to provide an electrostatic adsorbable laminated sheet which is less likely to cause paste residues, etc. upon peeling from an adherend, exhibits further enhanced adsorbability to an adherend, additionally exhibits enhanced adhesiveness at an electrostatic adsorbable interface, and thereby has enhanced handleability. Electrostatic adsorbable laminated sheet includes label layer, support layer, and grip layer disposed between the label layer and the support layer, wherein the label layer and the support layer are electrostatically adsorbed to each other via the grip layer.

An article of manufacture (160) in the form of a sign or label comprises a disclosed embodiment, produced in accordance with an example method. A substrate (170) is provided which forms a substantially planar surface area having a desired shape, thickness and size. A design layer (173) is formed through the use of inks (172) applied to the substrate (170) in a pre-determined pattern. When the inks (172) are applied to the substrate (170), no ink (172) is applied on one or more edges formed around the periphery of the sign (160) for an edge bare border (130). Also, a mounting hole (168) is provided, and an opening bare border (132) is formed around the mounting hole (168). An encapsulant (176) is then applied over the inks (172) so as to provide a protective cover. Also, the encapsulant (176) is applied to the edge bare border (130) and the opening bare border (132) so that the encapsulant (176) fully covers not only the inks (172), but also all borders, thereby forming edge encapsulation borders (130) and an opening encapsulation border (132), and the sign (160) is therefore fully encapsulated.

The invention relates to providing a method for obtaining a multilayer film for thermally inducible shrink labels, products thereof and use of such products.

An article of manufacture (160) in the form of a sign or label comprises a disclosed embodiment, produced in accordance with an example method. A substrate (170) is provided which forms a flat planar surface area having a desired shape, thickness and size. A design layer is formed through the use of inks and/or paints (172) applied to the substrate (170) in a predetermined pattern. When the inks and/or paints (172) are applied to the substrate (170), no ink or paint (172) is applied on one or more edges formed around the periphery of the sign (160) for an edge bare border (164). Also, a mounting hole (168) is provided, and an opening bare border (166) is formed around the mounting hole (168). A protective coating (176) is then applied over the inks and/or paints (172) so as to provide a protective cover. Also, the protective coating (176) is applied to the edge bare border (164) and the openings bare border (166) so that the protective coating (176) fully covers not only the inks and/or paints (172), but also all borders, thereby fully encapsulating edge bare borders (164) and an openings bare border (166) between the protective coating and the substrate.

A self-laminating rotating cable marker label is constructed of a transparent film having a first adhesive area, an adhesive-free smooth area, and a second adhesive area. A print-on area forms one side of the transparent film, the print-on area adapted to receive indicia identifying the cable about which the marker label is applied. A perforation extends across the transparent film providing a line of separation of the transparent film. When wrapped around a cable, the second adhesive area overlies the print-on area such that the cable identifying indicia is visible through the transparent second adhesive area. As the transparent film is wrapped around the cable, the first adhesive area adheres to the cable. The remainder of the transparent film is rotated, breaking the perforation, whereby the smooth area of the film in contact with the cable provides smooth rotation of the label around the cable.

The present invention provides a multilayer label having good gas barrier properties and is capable of maintaining the gas barrier properties at a high level even when exposed to physical stresses such as deformation and impart. The present invention relates to a multilayer label for in-mold labeling. This multilayer label includes a base (X), a layer (Z) containing an aluminum atom, and a layer (Y) containing a polymer (A) having a functional group containing a phosphorus atom.

In one aspect, a self-laminating identification band is provided. The band is formed from the face stock of a form sheet, with a laminating flap that folds over a printed surface. Adhesive is provided along the flap and along at least one end of the band, so as to allow the band to positioned and looped around itself.

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.