A structure for secure containment of information (SSCI) that is in the form of a laminate which includes at least two layers. The laminate is constructed to contain information such as a code, serial number, informational feature, encryption key or personal identification number (PIN). The information is located between the layer of the laminate such that the code, serial number, informational feature, encryption key, or PIN is not detectable from outside the laminate. The SSCI is configured to provide access and expose the code, serial number, informational feature, encryption key, or PIN by delaminating at least one layer, thereby indicating that tampering has occurred to the laminate. The SSCI can also function as a public key or private key for a blockchain, to provide access to a physical lock or to provide account access to claim financial value.

A system and method for manufacturing a strip or label used to place a substantially invisible identifying mark is disclosed. A strip is treated by removing at least one area of a liner element, a film layer and an adhesive layer. Each one of the removed areas is substantially congruent with the other removed areas. A laser or other ablating device is used to remove the areas through vaporization. The strip element is peeled away from the liner element, exposing the adhesive layer. The adhesive layer is thereafter pressed against a substantially flat metal surface. The laminate top coat and the film layer are removed from the object, leaving the adhesive layer in place. The adhesive material is impregnated with a UV sensitive material, but is otherwise invisible.

An RFID tag is disclosed that is formed as part of a printed fabric label (PFL). Generally, foil is adhered to a fabric material with a releasable adhesive, the foil is then cut, such as by a laser to define the antenna pattern and a removable portion. The removable portion is then manually stripped away, and a strap is then attached with adhesive to the antenna. A small square of hot melt over-laminate may be placed over the strap and bonded, and then a top layer of fabric is added and secured with an adhesive from a transfer tape.

Compositions which are well suited for forming into machine direction orientation (MDO) films are described. Multilayer films containing one or more layers of the compositions and/or films are also described. Additionally, label assemblies utilizing the multilayer films, labeled substrates, and related methods are described. Various versions of the multilayer films are described including films having at least two skin layers and an interior core layer. Particular multilayer films are described having polyethylene rich cores.

A multi-layer shrink film comprising, consisting of, or consisting essentially of at least two layers, Layer A and Layer B, wherein Layer A is at least one skin layer comprising an amorphous glassy polymer material and Layer B is at least one core layer comprising i) 15-100 weight percent of a maleic anhydride-modified plastomer having a density in the range of 0.86-0.925 g/cm.sup.3; and ii) optionally a polyolefm which does not contain maleic anhydride having a density in the range of 0.86-0.925 g/cm.sup.3 and wherein the multi-level shrink film has an overall density of less than 1.0 g/cm.sup.3, is disclosed.

A label for a tube having a diameter D may have a transparent facestock. A printing area is defined on a first surface of the transparent facestock, the printing area configured to receive data thereon, the printing area covering only a portion of the transparent facestock, whereby a shielding portion of the length of the label is transparent. An adhesive layer is on a second surface of the facestock. A wireless communication inlay is adhered to the adhesive layer in a portion of the label corresponding to the printing area. The printing area and the facestock are sized for the shielding portion to overlap at least partially the printing area when the label is wrapped on a tube.

Methods of making recyclable heavy-gauge films are provided. The methods of the present disclosure involve bonding the inner layers of a coextruded blown film together such that the film is sufficiently thick enough for it to be oriented in the MDO section using the typical 5:1 orientation ratio and result in a film with twice the gauge typically made by the MDO process (while maintaining acceptable stiffness and dimensional rigidity). Recyclable heavy-gauge films formed by the methods are also provided.

Multi-layer films and labels are disclosed herein. In an embodiment, a multi-layer film comprises a first skin layer, a first intermediate layer, a core layer, a second intermediate layer, and a second skin layer arranged sequentially, wherein the core layer has a thickness that is greater than thickness of the first or the second intermediate layers or the skin layer, wherein the core layer includes polybutylene terephthalate (PBT) particles disposed therein, wherein the amount of PBT particles ranges from about 5 to about 10 percent by weight (wt %), based on the total weight of the core layer, wherein the multi-layer film has a thickness ranging from about 25 microns to about 45 microns, wherein the core layer has a thickness ranging from about 20 microns to about 40 microns.

An identification tag is described that includes a tab portion having a unique identifier, an anchor portion, and a tether portion connecting the tab portion to the anchor portion. The anchor portion has a permanent pressure sensitive adhesive to secure the tag to one of a patch cable or a port disposed in a patch panel. In an exemplary aspect, the tag portion, anchor portion and the tether portion of the tag are formed as an integral structure. The unique identifier is a two-dimensional code, that is printed as an inversed image to provide improved network security and prevent reading of the unique identifiers by unapproved reading devices.

The invention relates to an applicator for die-cut parts (2), having a die-cut part strip (1) with a longitudinal direction (L) having a carrier layer (3) and an adhesive layer (4), where an outer contour of the die-cut parts (2) is punched through the carrier layer and adhesive layer (3, 4) down to predetertnined breaking points (18) and a die-cut part complement (19) protrudes beyond the die-cut parts (2) continuously laterally to a longitudinal direction (L), and a punch head (8) over which the die-cut part strip (1) runs, where the die-cut parts (2) running over the punch head (8) face away from the punch head (8) by their adhesive layer (4), and the die-cut parts (2) can be pressed by means of the punch head (8) onto a surface (11).