Systems and methods are provided for transferring a remote frequency identification (RFID) inlay from a first substrate to a second substrate. An RFID inlay is secured to a first substrate with a first adhesive. The RFID inlay is brought into the vicinity of a second substrate and secured to the second substrate with a second adhesive. The RFID inlay is then dissociated from the first substrate. The RFID inlay may be dissociated from the first substrate by softening the first adhesive, such as by the application of heat or the application of a softening substance. Alternatively, the RFID inlay may be dissociated from the first substrate without softening the first adhesive, but rather by differential release, whereby a release force is applied between the two substrates, with the release force being greater than the release strength of the first adhesive, but less than the release strength of the second adhesive.

A printing device includes a printing mechanism, a first member, a second member and a RFID. The printing mechanism is configured to perform printing. The first member has a portion constituting a receiving portion. The receiving portion configured to receive therein a holder. The holder retains therein a consumable goods and is provided with a RFID. The holder is contactable with the portion of the first member when the holder is attached to the receiving portion. The second member is movable relative to the first member. The RFID reader is provided at the second member and is configured to read data stored in the RFID.

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.

When forming smartcards or pre-forms thereof additional functionality may be implemented by, for instance, incorporating components, such as a display device, and the like, by preparing pre-packages separately from the rest of the pre-forms and subsequently inserting the pre-packages into the pre-forms, thereby achieving superior process robustness and production yield.

A label applicator system includes a first label applicator moveably coupled to a track configured to be moved along the track and fixed at plurality of positions along the track and a second label applicator moveably coupled to the track configured to be moved along the track and fixed at plurality of positions along the track.

A plastic sheet for manufacturing of a plurality of smart cards which respectively include a plurality of electronic units, includes a first sheet formed of a first material having a first hardness or a first Vicat softening temperature, the first sheet including a plurality of apertures and/or cavities. The plastic sheet includes a second material having, when the first material has the first hardness, a second hardness lower than the first hardness, and when the first material has the first Vicat softening temperature, a second Vicat softening temperature lower than the first Vicat softening temperature, the second material being located inside the apertures and/or cavities in the first sheet. The apertures and/or cavities with the second material located inside the apertures and/or cavities are configured to respectively receive said electronic units via an at least partial penetration from the electronic units into the second material.

A label for being applied, by being wrapped around, to an object to be identified, includes a non-adhesive top side including a printing region for receiving a print on the top side and an adhesive bottom side, by which the label is fastened to the object. The label is in the shape of a strip having a length that is greater than a periphery of the object to be labeled. A transparent wrapping tab is arranged adjacently to the printing region in a longitudinal direction of the label. A length of the wrapping tab is at least equal to the periphery of the object to be labeled. The wrapping tab is wrapped on the printing region and covers the printing region when the label has been applied to the object. An RFID transponder is arranged between the top side and the bottom side in the printing region.

Systems, methods, and computer-readable media provide automated identification techniques that associate at least two unique identifiers of one segment of a segmental multimode wireless flexible product to seamlessly and accurately bridge different identification methodologies to enable advanced real-time tracking of shipment location and status, and other such useful and advanced product and service offerings.

An RFID transponder (100), comprising a printable surface (1), an antenna element (2), an IC (3), and a ground plane (4) arranged under the antenna element (2). The ground plane (4) comprises one or more opening(s) (6) through said ground plane (4) for enabling near field communication through the ground plane (4).

A transferring assembly for transferring onto an object a RFID identification device consisting of a microchip connected to an antenna made of electrically conductive material, wherein a film of adhesive material is applied to a supporting element, the microchip is applied on the film of adhesive material in a zone of the supporting element, the antenna is formed by applying the wire made of electrically conductive material to the film of adhesive material and electrically connecting the antenna to the microchip, and the zone is pressed against a surface of the object, with the RFID identification device facing the surface, the adhesive material, and/or the supporting element, being chosen so that the adhesive material has an adhesiveness on the surface of the object that is significantly greater than the adhesiveness of the film on the supporting element.