A label sticker is provided and includes: a base layer; a release layer coated on an upper surface of the base layer; a first surface material layer having a lower surface coated with a first glue layer and coated on or adhered to the release layer through the first glue layer; and a second surface material layer having a lower surface coated with a second glue layer and adhered to an upper surface of the first surface material layer through the second glue layer. The area of the second surface material layer is greater than the area of the first surface material layer. The label sticker. Therefore, glue residues left behind by a process of making the label sticker do not interfere with use thereof.

A decrease in the adhesiveness of an in-mold label can be suppressed even when a silicone transferred from the protective layer side to the heat-sealable resin layer side. An in-mold label includes a substrate layer, a printed layer provided on one surface of the substrate layer, and a heat-sealable resin layer provided on the other surface of the substrate layer, a protective layer containing a silicone is provided on an outermost surface on one surface side of the substrate layer on which the printed layer is provided, and an adhesive strength decrease-inhibiting layer containing a (meth)acrylic acid based copolymer having a polar group is provided on an outermost surface on the other surface side of the substrate layer on which the heat-sealable resin layer is provided.

The present invention relates to the particularly innovative field of electronics applied to textiles. In particular, the present invention provides a method and a multilayer device which allows the use of known and present electronic passive electronic devices on the market or other electronic devices, making them one-piece with textiles or polymers through the use of heat-sealing materials and creating a stable innovative device.

An electronic heat transfer label includes a substrate. A pattern layer is printed on the substrate, and an adhesive is printed on the pattern layer to form a first adhesive layer. A chip is attached onto the first adhesive layer, and an adhesive is printed on the chip to form a second adhesive layer. The second adhesive layer covers the chip, and a hot-melt layer is arranged on the second adhesive layer. A method for preparing the electronic heat transfer label includes: S1: printing an ink on a substrate and drying the ink to form a pattern layer; S2: printing an adhesive on the pattern layer and drying to form a first adhesive layer; S3: attaching a chip onto the first adhesive layer; S4: printing an adhesive onto the first adhesive layer and the chip, and drying to form a second adhesive layer.

A label sheet assembly and method is disclosed for improving the process of feeding label sheets through a printer. The label sheet assembly may include a facestock layer and a liner sheet. The facestock layer may include an adhesive layer along at least a portion of a first side and include a label surface along at least a portion of the second side opposite the adhesive layer. The facestock layer may include at least one cut line that defines at least one label within the facestock layer while the remaining portions of the facestock layer may be a matrix portion. The matrix portion may include at least one discontinuous cut line spaced from the cut line that defines at least one label wherein the discontinuous cut line may create a zone of decreased bending stiffness along the label sheet assembly.

The present invention relates to a mono or multi-layer polyester film, a process for producing the mono or multi-layer polyester film, an article comprising the mono or multi-layer polyester film as well as the use of the mono or multi-layer polyester film packaging products, insulating materials, solar, marine or aviation applications, science, electronic or acoustic applications, wires, cables, radio frequency identifications, flexible circuits, graphic arts, stone paper, holograms, filter products, cosmetic products, household products imaging, recording media, or industrial products.

In an example embodiment, there is disclosed herein a sleeve that has a peel-off appliqué or label that includes desired graphics that can be combined with a drink cup or container. The label or appliqué or “collectable” acts as a “mini-poster” that is removable and repositionable. The label may have graphics of sports starts or other things such as musical performers, super heroes, etc. Particular embodiments include interior die cut images within the main graphic as “collectibles within a collectible.” In another example embodiment, a container appliqué is applied to the container

A sheet processing system including: a sheet feeding station, configured to feed and place single and separate printed sheets, one at a time, on at least one continuous sheet, one printed sheet adjacent to the other with a front edge of one printed sheet of the separate printed sheets overlapping on top of or below a rear edge of its previously fed printed sheet; and a pressing roller configured to move the at least one continuous sheet, and to adhere the at least one continuous sheet on the printed sheets, thereby turning each one of the fed single and separate printed sheets into a continuous printed sheet (roll), thereby allowing utilizing a separated sheet printer for producing the printed roll.

A polymer composition for use in a hot melt adhesive comprises at least one semierystalline, low molecular weight (LMW) propylene-based polymer; at least one essentially amorphous, high molecular weight (HMW) propylene-based polymer; and at least one essentially amorphous, LMW propylene-based polymer. A hot melt adhesive composition further contains a tackifier, a plasticizer, an antioxidant, and optionally a wax, a filler, a colorant, a UV absorber, another polymer, or combinations thereof. The hot melt adhesive is useful for a variety of industrial applications where bonding of low surface energy substrates is encountered, including disposable nonwoven hygienic articles, labeling and other assembly applications. Particularly preferred applications include nonwoven disposable diaper and feminine sanitary napkin construction, diaper and adult incontinent brief elastic attachment, diaper and napkin core stabilization, diaper backsheet lamination, industrial filter material conversion, and surgical gown and surgical drape assemblies. The composition demonstrates improved peel strength while maintaining very good creep resistance.

Disclosed are hot-melt, curl-free methods, structures, and compositions, which in flexible packaging applications, reduce mineral-oil, hydrocarbon migration into packaged food. One embodiment provides an optionally oriented base film having a first side and a second side that is a transparent or opaque film. Further, the composition comprises, consists essentially of, or consists of a water-based primer applied to the first side. Further still, the composition includes a barrier layer to mineral-oil migration, wherein the barrier layer is located between the adhesive-receptive layer and the polymeric substrate, and wherein the barrier layer consists essentially of: (i) polymers of polyvinyl alcohol, ethylene vinyl alcohol, polyester, polyamide, or combinations thereof; and (ii) optionally additives. The barrier layer provides a barrier to mineral-oil migration of 0.1 μg/day*dm.sup.2 or less at 40° C. for 40 days, and the curl-resistant composition does not curl when heated for at least one hour at 60° C.