A method for producing separated strip-like laminate components including an electronic component embedded between two laminate layers of a tape-like material. Individual components are placed at defined intervals by a placement device onto a tape-like, lower first laminate layer moved in a conveying direction by a transport device, after which a tape-like, upper second laminate layer moved in the conveying direction is applied to the first laminate layer with embedding of the components to form a laminate tape. The individual strip-like laminate components are cut from the laminate tape by a cutting device having a movable cutting blade, which laminate components are picked up by a gripper device and transported away. The front end of the laminate tape is gripped by the gripper device in the region of a component and moved synchronously with the clocked movement of the transport device by a predetermined distance through the cutting device and positioned relative to the cutting blade. The actual position of the component in the laminate component in relation to the conveying direction is detected by a measuring device connected downstream of the cutting device. When a deviation of the actual position from a defined target position is detected, the synchronous movement of the transport device and the gripper device is controlled in dependence on the detected deviation.

A contactless communication medium according to an embodiment of the present technology includes an IC module, a first member, a second member, and a print layer. The IC module is capable of performing a contactless communication. The first member is made of a first transparent resin material, the first member including a first surface and a second surface, the first surface being a surface in which a concave portion that accommodates therein the IC module is formed, the second surface being situated opposite to the first surface. The second member is made of a second transparent resin material, the second member being connected to the first surface or the second surface. The print layer is arranged between the first member and the second member.

A multifunction electromagnetic induction sealing liner includes, from top to bottom order, a composite function layer, an electromagnetic induction heating layer, and an adhesion layer combined together. The composite function layer includes, from top to bottom order, an information layer and a backing layer combined together. The information layer has therein an information chip and an antenna circuit electrically connected to the information chip. The composite function layer includes a grip portion, a primary cutting line and a secondary cutting line. The primary cutting line runs annularly and divides the composite function layer into an outer ring and an inner ring. The grip portion is disposed inside the inner ring and connected thereto. The secondary cutting line is disposed in the inner ring and connected to a lateral edge of the grip portion. The antenna circuit crosses the primary cutting line and/or the secondary cutting line.

The invention relates to the field of radio-frequency identification, in particular, to materials containing radio-frequency tags in their layers and intended for printing and stamping by commonly available printing methods. The technical result of the invention is to obtain the flexible flat sheet material in which the chips and other electronic components do not affect the level of the sheet material surface flatness. The flat sheet material with radio frequency identification contains the sequentially arranged first layer of flexible material, the first intermediate layer, the substrate layer with an antenna and a chip, the second intermediate layer, the second layer of flexible material, and the first intermediate layer made of the polymer composite.

An antenna includes a self-supporting electrically conductive wire having a width (W) and extending longitudinally along a length and between first and second ends of the conductive wire. The conductive wire forms one or more loops and comprises an electrically conductive layer disposed on and aligned with an adhesive layer. A width and a length of each of the conductive and adhesive layers are substantially co-extensive with the width and the length of the conductive wire.

A multi layered card embodying the invention includes an outer layer of an amorphous laser reactive copolymer material which is embossed with a selected pattern at a selected temperature which is above the glass transition temperature, Tg, of the copolymer and below its melting temperature, Tm. So embossed, the selected pattern is set in the copolymer layer, and its external shape cannot be changed from the embossed form to which it was set at the selected temperature, without destroying the selected pattern. The outer layer may be laminated with the other layers of the card and laser engraved before or after lamination.

A method for manufacturing a printed circuit board (PCB) comprises firstly constructing a first book which includes first and second supported copper foils located at the bottom and top respectively. Each supported copper foil includes a respective poly-based film, a thin copper foil, and an adhesive provided between the film and the thin foil; the adhesive being permanently attached to the film and removably attached to the thin foil. The first book further comprises a first prepreg adjacent the thin foil of the first foil, copper clad laminates adjacent the first prepreg, and a second prepreg on a side of the copper clad laminates that opposes a side adjacent the first prepreg. Next, applying a lamination cycle to the first book using a laminating press to cure the first and second prepregs. Finally, removing the films from the thin foils associated with each of the first and second supported foil.

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.

A laminated transaction card may comprise post-consumer polyethylene with a thickness of at least 30% of a thickness of the laminated transaction card. A first polymer-based layer comprising polyvinyl chloride is coupled to a first surface of the core layer by a first adhesive layer. A second polymer-based layer comprising polyvinyl chloride is coupled to a second surface of the core layer by a second adhesive layer. The first adhesive layer and the second adhesive layer comprise an adhesive formulated to bond the post-consumer polyethylene and the polymer-based layers.

A label containing a base layer (A) and an adhesive layer (C) provided in contact with one surface of the base layer (A), wherein the base layer (A) contains a thermoplastic resin and at least one of inorganic fine powder and an organic filler, and the base layer (A) is stretched in at least one direction, and the film has an internal bond strength measured according to TAPPI T569 of from 0.4 to 0.95 kg.Math.cm on a side of the adhesive layer (C) and from 0.4 to 1.5 kg.Math.cm on a side opposite thereto, is easily recognized by the naked eye for the fact that the film has been peeled from an adherend, and is difficult to be restored by re-adhering after peeling.