The present invention relates to a peel detection label that is a laminate having a backing, a pattern layer formed on a part of a surface of the backing, and a pressure sensitive adhesive laminate in this order, the pressure sensitive adhesive laminate having at least an intermediate layer and a pressure sensitive adhesive layer, wherein a tensile modulus Et at 23° C. of the backing is 50 MPa or greater and 1000 MPa or less.

A peel off assembly for exposing a safety feature comprising an aversive agent for a battery includes a first adhesive layer adhered to a base layer. Optionally, a layer comprising a colorant is disposed over and coupled to the first adhesive layer. A layer comprising a water-soluble material and an aversive agent is disposed over and coupled to the first adhesive layer. A second adhesive layer is disposed over and coupled to the layer comprising a water-soluble material. A kill strip layer is disposed between the second adhesive layer and the base layer. Optionally, a label is disposed over and coupled to the second adhesive layer. The second adhesive layer is adapted and arranged to release from the layer comprising the water-soluble material, when a peel force is applied such that the second adhesive layer and the kill strip layer are removable from the layer comprising a water-soluble material when the peel force is applied to the second adhesive layer.

Disclosed pressure sensitive adhesive compositions, having enhanced heat resistance, obtained by the emulsion polymerization of (a) one or more acrylic acid ester or (meth)acrylate acid ester(s), (b) one or more hydroxyl functional (meth)acrylic monomer and (c) one or more ureido substituted (meth)acrylate monomers(s).

A plant label has a substrate and a permanent adhesive layer on a release liner. An identifier portion of the substrate and a tag portion of the substrate are defined by a detach line that enables the tag portion to be detached from the identifier portion. The tag portion has an adhesive deadener on the permanent adhesive layer, a strip of the permanent adhesive layer of the detachable portion free of adhesive deadener, and a tab having only adhesive deadener on the permanent adhesive layer that enables the tag portion to be detached from the identifier portion and from a container to which the label is affixed.

An adhesive label is provided. The adhesive label includes an adhesive patch that covers at least 50% but less than 85% of a backside surface of the adhesive label and that is at least partially horizontally and vertically centered on the backside surface.

The development of the Dissolvable Labels for Medvantage® Machine fulfills this need. The Dissolvable Labels for Medvantage® Machine, as its name implies, is a line of dissolvable labels for use on a specific brand of printer. The labels would be used in a wide variety of applications including healthcare, foodservice, sterile processing, and other similar applications. They would be made available in a wide variety of sizes including but not limited to 2½″ square, ⅞″ by 1⅝″, ⅞″ by 2¼″, and similar sizes. Also, in addition to various colors, the invention would be made in various finishes such as synthetic and matte. The invention is specifically designed for use in printers manufactured by MedVantage®, although they could be adapted for use with different manufacturers as well. The use of the Dissolvable Labels for Medvantage® Machine allows for the production of labels that can be removed at a later time in a manner which is not only quick, easy, and effective, but ecologically and economically friendly as well.

Disclosed are pre-cure RFID-enabled bead labels based on an RFID inlay construction consisting of an aluminum antenna etched on to a high temperature resistant polyimide film that is connected to an integrated memory circuit positioned on the surface of the polyimide film. This RFID inlay being further inserted into an overall label construction having a plurality of layers that include, for example, a plurality of polyester layers and a plurality of high temperature resistant adhesive layers that bond/adhere layers together, the plurality of layers further protecting and insulating the RFID inlay while the label is bonded to the external bead (or sidewall) of a tire. The compositions/devices disclosed herein can be used for electronic identification when applied on rubber-based articles (e.g., tires) prior to being subjected to stress related to the vulcanization process and normal use of this article during the manufacturing process.

According to an embodiment of the present disclosure, a method of labeling a plurality of products includes coating a pressure sensitive adhesive to a roll of face stock, the roll of face stock configured to be converted to a plurality of individual labels aligned in a single lane; singulating an individual label from the roll of face stock; and applying the individual label to a product of the plurality of products, wherein the coating, singulating and applying are conducted sequentially in a single continuous operation with a single continuous web of material.

A method for ablating a label having a topcoat layer and a sacrificial layer includes irradiating at least one target region on the topcoat layer with a laser beam and further includes removing the topcoat layer and at least a portion of the sacrificial layer in the at least one target region.

Provided herein is a pressure sensitive adhesive (PSA) that has balanced high shear and high peel strength. The PSA comprises a combination of epoxy and isocyanate crosslinkers and a polyacrylate tackifier.