A race bib and a method of assembling the same. The bib includes a first and second layers with a programmable tag embedded between them. Indicia are provided on a first surface or a second surface of the first layer. A backer is positionable between the tag and the first or second layers. During assembly, a competitor number is printed on the first layer with an ink printer, a tag number correlating to or corresponding to the competitor number is encoded into the tag with a RFID tag printer. The printing and encoding can be accomplished by a combined printer. Alternatively, an optical scanner reads the printed competitor number and transmits the same to the tag printer. The second layer overlays the first layer and is thermally welded or adhesively secured to the first layer.

Package laminate comprising a multilayer laminate with an outer layer having at least one carrier layer, an electrically conductive barrier layer and a top layer, characterized in that a functional element is arranged on a first side of the barrier layer and in that an electrical element is arranged on the second side of the barrier layer remote from the functional element, the functional element being connected to the electrical element via at least two mutually insulated electrical conductors.

The mechanically stable value or security document 2000 according to the invention comprising an electric circuit 1270 is characterised by the following features: the document is formed of at least three document layers which are arranged in a stack 1700 and which are connected together face-to-face by a joining method, wherein a first document layer is formed by a circuit carrier layer 1200 which supports the electric circuit 1270, at least one second document layer is formed in each case by a compensation layer 1100 which has at least one opening 1120 and/or recess, and at least one third document layer is formed in each case by an outer cover layer 1300. The first 1200, the at least one second 1100, and the at least one third document layer 1300 are formed from a fibre composite material.

A multilayer magnetic sheet is described which comprises a plurality of stacked magnetic component layers separated by first electrically insulating layers. Each of the plurality of magnetic component layers comprises a plurality of isolated magnetic sublayers having a magnetic layer thickness of less than one micron. The multilayer magnetic sheet has a magnetic fraction between about 5% and about 80%; a total magnetic thickness of greater than or equal to 5 microns; and a relative composite permeability of greater than about 20.

Label constructions comprise a first section and a second section that are laminate constructions of a card stock top surface that may include printed indicia, an adhesive layer disposed underneath the card stock, and a removable liner adhered to the adhesive layer and common to the first and second sections. The first section includes an RFID device. The first section may be configured once removed from the liner to fold on itself to form an RFID tag, or to form an RFID adhesive label. The second section once separately removed from the liner forms an adhesive label. The construction first and second sections are positioned adjacent one another and are formed during the same manufacturing process for purposes of manufacturing efficiency. The first and second sections may be treated to facilitate separate removal from the liner to provide labeling flexibility.

Disclosed embodiments generally relate to a transaction card with a fabric inlay. The transaction card may include a housing component having a first housing surface opposite a second housing surface and an inlay component having a first inlay surface opposite a second inlay surface. The inlay and housing may be joined along the second inlay surface and the first housing surface. In addition, the first inlay surface may include a fabric material and a backer layer configured to support the fabric material of the first inlay surface.

A method for labeling fabrics, such as fabric garments, and a heat-transfer label well-suited for use in the method. In one embodiment, the heat-transfer label includes (a) a support portion; and (b) a transfer portion, the transfer portion being positioned over the support portion for transfer of the transfer portion from the support portion to an article of fabric under conditions of heat and pressure, the transfer portion including (i) an ink design layer; (ii) a heat-activatable adhesive layer; and (iii) an RFID device.

Methods and a device are provided for conditioning, in particular smoothing, a data carrier constructed as a card-like and multi-layer laminate, in particular an RFID or NFC ticket, for a subsequent application of data, in particular by printing thereon. A simultaneous heating of the data carrier and application of pressure to a first main surface of the card-like data carrier takes place while the second main surface opposite the first main surface is in contact with an at least substantially flat support surface, to cause a reduction or elimination of a curvature of the data carrier which may have existed previously.

The invention relates to the field of radio frequency identification, in particular, to the one containing a radio frequency tag in printing paper for typographical printing. The technical result is the creation of the technical solution as an alternative to the known one. The sheet material with the radio frequency identification is characterized in by the fact that it is made in the form of a rectangular sheet with a layer for printing, a length of 480 mm and a width of 325 mm, and it contains an antenna and a chip placed inside the sheet, what's more one of the sheet angles is made with a 45 bevel and a length of 10 mm.

Smartcards with metal layers manufactured according to various techniques disclosed herein. One or more metal layers of a smartcard stackup may be provided with slits overlapping at least a portion of a module antenna in an associated transponder chip module disposed in the smartcard so that the metal layer functions as a coupling frame. One or more metal layers may be pre-laminated with plastic layers to form a metal core or clad subassembly for a smartcard, and outer printed and/or overlay plastic layers may be laminated to the front and/or back of the metal core. Front and back overlays may be provided. Various constructions of and manufacturing techniques (including temperature, time, and pressure regimes for laminating) for smartcards are disclosed herein.