The disclosed transponder arrangement includes adhesive transfer tape and an RF transponder. The adhesive transfer tape includes an adhesive layer disposed directly on a release liner, and the release liner is separable from the adhesive layer. An antenna is adhered directly to the adhesive layer, and an RF transponder is disposed on the adhesive layer and coupled to the antenna. A layer of ink is disposed directly on one of the first adhesive surface or the second adhesive surface.

An RFID tag manufacturing system is provided that includes a conveyance device that conveys a base sheet provided with a plurality of antenna patterns to each of which an RFIC module is fixed. The system includes a laminating device that attaches a cover seal on the base sheet to cover the antenna patterns and a punching device that produces RFID tags by punching the cover seal and the base sheet with a punching blade that includes a frame-shaped cutting edge surrounding the antenna patterns to form a frame-shaped cut. The base sheet includes alignment mark in a non-attachment part of the cover seal. The punching device specifies the position of each of the antenna patterns covered with the cover seal based on the alignment mark, and punches the cover seal and the base sheet based on the specified position of the antenna pattern.

Label apparatus having identification tags and tamper evident pattern release layers and methods of producing such labels are disclosed. An example apparatus includes a first substrate, a first pattern of adhesive, a tamper-evident release layer, a second pattern of adhesive, a tag, a third pattern of adhesive, and a second substrate. The first pattern of adhesive includes a first adhesive. The first pattern of adhesive and the tamper-evident release layer are disposed on the first substrate. The second and third patterns of adhesive include a second adhesive. The second pattern of adhesive is disposed on the first substrate and surrounded by the first pattern of adhesive. The tag includes a remaining portion coupled to the first pattern of adhesive and a removable portion coupled to the second pattern of adhesive. The third pattern of adhesive is coupled to the tag, the first pattern of adhesive, and the second substrate.

A method for providing a packaging material is provided. The method comprises feeding a web of packaging material through a packaging material processing unit; determining a target position of the packaging material; and controlling a printing unit to print an RFID antenna at the target position, wherein the material used for printing the RFID antenna is conductive substance. A packaging material is also provided.

The present invention provides a process for incorporating a wireless device into a plastic container as part of the steps of manufacturing the container. The plastic container can be a flexible plastic bag and are formed of one or more sheets, generally two or more sheets of plastic film or a rigid plastic container such as a tub or tote. The bags are formed by sealing together adjacent edge portions of each film layer. One embodiment of the present invention is to incorporate a wireless device between the edge portions of the film(s) before or during sealing so that the wireless device becomes permanently sealed into the film material but is isolated from both the bag interior and the outside environment. Another embodiment is to incorporate the wireless device onto or into a plastic component that is sealed to the container, such as a nipple or port, so that the wireless device becomes permanently sealed to the container but is isolated from both the container interior and the outside environment.

A device configured to receive a first carrier with a first receptacle; to guide a second carrier in a conveying direction with a second receptacle; to receive the first carrier with the first receptacle so that the components carried by it are oriented towards the second receptacle; to separate the components in response to information from a control unit; and convey the second carrier in its position relative to a placement position so that an electronic subassembly on the second carrier reaches the placement position. The second receptacle has a contact surface for the second carrier which is curved in the conveying direction of the second carrier and the second receptacle at least partially includes a second conveying device which occupies only part of the second receptacle transversely to the conveying direction of the second carrier.

The invention relates to a transfer stack (TS) for transferring a portion of a foil within a perimeter (P) that includes a transducer (T) to an article (A) such as a medical device or a medical needle. The transfer stack includes a carrier substrate (CS), a foil (F) having a transducer (T) incorporated therein, and the transducer is laterally surrounded by a perimeter (P). The foil (F) is separable from the carrier substrate (CS) by overcoming a first peel retaining force (PRF1). An adhesive layer (AL) is also attached to the foil. The adhesive layer (AL) is configured to provide adhesion between the foil (F) and an article (A) such that when the article (A) is attached to the foil via the adhesive layer (AL) the foil (F) is separable from the surface of the article (A) by overcoming a second peel retaining force (PRF2). The second peel retaining force (PRF2) is greater than the first peel retaining force (PRF1).

The present invention provides a process for incorporating a wireless device into a plastic container as part of the steps of manufacturing the container. The plastic container can be a flexible plastic bag and are formed of one or more sheets, generally two or more sheets of plastic film or a rigid plastic container such as a tub or tote. The bags are formed by sealing together adjacent edge portions of each film layer. One embodiment of the present invention is to incorporate a wireless device between the edge portions of the film(s) before or during sealing so that the wireless device becomes permanently sealed into the film material but is isolated from both the bag interior and the outside environment. Another embodiment is to incorporate the wireless device onto or into a plastic component that is sealed to the container, such as a nipple or port, so that the wireless device becomes permanently sealed to the container but is isolated from both the container interior and the outside environment.

Systems and methods for processing RFID element or chip components allow for the use of relatively common and inexpensive vibratory feeder handling equipment that require a much lower capital cost than systems incorporating technology such as flip chipping or direct punching down approaches. Instead, vibratory feeders provide feed handling equipment for the RFID element or chip components, which are subsequently fed and combined with RFID antennas in forming RFID devices such as RFID tags. The RFID chips are formed on or of non-silicon substrates such as printed parts. These substrates are relatively flexible, of materials such as polymeric sheets or other plastics. A stream of the RFID components is presented at a transfer station to an ordered series of RFID antennas, with the RFID components and antennas being combined in forming RFID devices.

Represented and described is an RFID conversion system for producing RFID products on one and/or more tracks, with a plurality of inlay dispensing modules and with a control device for controlling the inlay dispensing modules. According to the invention, it is provided that each inlay dispensing module is meant and configured for directly loading inlays onto a carrier material, in particular a web shaped or sheet shaped carrier material, or for indirectly loading inlays onto a transport means, such as a vacuum conveyor belt, wherein the inlay dispensing modules can be controlled independently of each other.