DE102008058398A1 - Data carrier with contactless readable chip and antenna - Google Patents

Abstract

The invention provides a data carrier with a body, as well as with a contactless contactable circuit arrangement and a printed antenna, which are arranged in or on the body. The antenna is at least partially printed from a printing ink comprising at least one kind of electrically conductive fullerenes, e.g. Carbon nanotube, containing as electrically conductive components.

Description

The Invention relates to a data carrier with a body, and with a contactless contactable circuit arrangement and a printed antenna in or on the body are arranged.

One such disk can optionally as a personal document be designed, for example as a passport, identity card, driving license, Employee ID card. The disk has the shape optionally a flat chip card, with a flat chip card body, embedded in the antenna and as a circuit arrangement a chip are. Alternatively, the data carrier is used as a book document designed a plurality of pages, the at least one data sheet has, in which the antenna and a circuit arrangement as a chip are embedded. Alternatively, as a data carrier a Banknote be provided with a body of paper or Plastic, and with an antenna and a circuit arrangement one Chip or an ohmic resistance circuit, which are embedded in the body or on the body are applied.

to Production of an antenna for a data carrier It is known to wind a wire to a flat coil and to be laminated into the data medium. Alternatively, the Antenna made of a silver-containing or copper-containing printing ink on a laminate layer of the future data carrier printed, which subsequently laminated in the disk becomes.

EP-0756244-B1 describes a multilayer printed coil in which conductive flat coil layers and interlayer insulating layers are printed alternately, thereby forming suitable connections between the coil layers, so that the coil is manufactured.

When Material with different and variable conductivity properties have been fullerenes for some time, specially shaped molecules from carbon atoms, known. In particular, the fullerenes count the approximately spherical "football" molecules ("Buckyball"), including the C60 molecule as well-known representative, as well as the tubular ones Carbon nanotubes (CNTs). By suitable choice of process parameters in the production, as well as Optionally by suitable doping, in particular electrically conductive Fullerenes produce excellent electrical conductivity can have. In a sufficiently thin layer can be applied from fullerenes, especially carbon nanotubes, even almost transparent layers or paths with always still good or excellent electrical conductivity getting produced.

The patent application US 2002/0168525 A1 discloses a resonant circuit (RLC) based on carbon nanotubes made by chemical vapor deposition (CVD) of carbon on an inorganic substrate.

DE 600 21 778 T2 describes an electron-emitting element such. Example, a display, which is made by printing and subsequent firing of a carbon nanotube (CNT) -containing ink, wherein the electron-emitting property of the carbon nanotubes is exploited.

The German patent application DE 10 2005 049 600 A1 describes a component with a coil-like winding made of a conductive plastic with carbon nanotubes (carbon nanotubes CNTs) as a conductive filler.

Out DE 10 2004 035 368 B4 are known conductive tracks made of carbon nanotubes (CNTs), which arrange themselves on a suitably prestructured catalyst layer.

DE 10 2008 011 299 describes a security element, eg. B. for a banknote, with at least one thermochromic ink layer having at least one electrical circuit. The electrical circuit has at least one ohmic resistance, which is implemented in the geometric shape of a pattern, an alphanumeric character or an image. The thermochromic ink layer at least partially covers the ohmic resistance. When electrical energy is coupled into the electrical circuit, the ohmic resistance heats up. As a result, only those areas of the thermochromic ink layer undergo a color change, which are arranged above and immediately next to the ohmic resistance, so that at least parts of the pattern, the alphanumeric character or the image of the ohmic resistance can be seen within the thermochromic ink layer. For contactless coupling of the required electrical energy to the circuit an antenna, for. B. a coil and / or a capacitive coupling surface (capacitor), electrically coupled.

DE 10 2006 059 454 A1 The closest prior art to the preamble of claim 1 describes a lamination process for producing a personal document, such as a personal document. As identity card, passport, driver's license or employee card, with a contactless readable chip and a chip connected to the printed antenna. The chip is encapsulated in a polymer, with the exception of contact terminals for electrical contact between the chip and the antenna. and is inseparably bound to adjacent polymer layers by covalent bonding to prevent peeling of the chip within the personal document. The gaps left at the contact terminals are filled with a conductive adhesive containing carbon nanotubes (CNTs).

Of the Invention is based on the object, a cost-effective and powerful disk with a body, and with a contactless contactable circuit arrangement and a printed antenna in or on the body are arranged to create.

The Task is solved by a disk after Claim 1. Advantageous embodiments of the invention are in the specified dependent claims.

Of the Inventive disk according to the independent claim 1 has a body, as well a non-contact contactable circuit arrangement and a with the Schalkreisanordnung coupled printed antenna with which the Circuit arrangement is electrically contacted, in particular to Energy and / or data to couple into the circuit arrangement. The circuit arrangement and the antenna are in or on the body arranged. The disk is characterized by that at least part of the antenna is printed from a printing ink is that at least one sort of electrically conductive Fullerenes contains as electrically conductive component.

silver and copper are expensive raw materials. In contrast, carbon is in large Quantities available. Therefore, with sufficiently large-scale technical Production of fullerenes, a printing ink with fullerenes as electrical conductive component, opposite a printing ink with a precious metal such as silver or copper as electrically conductive Component, a price advantage. In addition, the electrical conductivity of Fullerenes such. B. carbon nanotubes that exceed silver.

Therefore is a cost according to claim 1 and more powerful disk with a contactless contactable circuit arrangement and a printed antenna created.

When Fullerenes are optionally provided with carbon nanotubes, alternatively football molecules (buckyball molecules), such as The C60 molecule.

Optional the antenna has a coil. Optionally, the coil is the antenna printed from the ink, the electrically conductive Fullerene contains as electrically conductive component. In this case, the antenna is, for example, as an RFID antenna or NFC antenna set up. Such an antenna can in particular in a contactless smart card, z. B. a suitably equipped Payment card or employee ID card, or contactless contactable personal document such. Passport or identity card be provided.

Optional the antenna has at least one capacitive coupling surface on, optionally one, two or more capacitive coupling surfaces. Optionally, the capacitive coupling surface of the antenna is off the printed ink, the electrically conductive fullerenes contains as electrically conductive component. Capacitive coupling surfaces can z. B. in particular at Banknotes should be provided with a chip that is in the stack, that is without previous Singling, to be read out.

Optional The antenna has both at least one coil and at least a capacitive coupling surface coupled together are. In particular, a capacitive coupling surface for tuning the resonance frequency of a coil provided with only a few turns be, wherein for coupling energy and / or data in the circuit arrangement the coil is used. Optionally, both the coil and the capacitive coupling surface of the fullerene having printing ink printed. Optionally, only the area capacitive Coupling surface of the fullerene having printing ink printed. The area of the printed capacitive coupling surface is usually larger than the area a printed coil. Therefore, the cost savings through use a cost-effective ink for a capacitive Coupling surface particularly large.

Optional The ink is printed in a layer thickness that the antenna at least partially or completely, especially at least in the part printed with the fullerene-containing ink, transparent or translucent, d. H. at least translucent.

Optional the body of the volume is at least partially transparent or translucent. In this case, one is transparent or translucent appearing antenna particularly advantageous since they less the optical appearance of the disk impaired as an opaque (opaque) antenna.

One advantageous application of transparent or translucent appearing Antennas made of fullerene-containing printing ink are large-area capacitive coupling surfaces, as in particular banknotes with chip for batch reading, d. H. Reading out the chips of banknotes can be provided without prior separation of banknotes.

One Another advantageous application of transparent or translucent Appearing antennas are antennas that are both a coil and have a capacitive coupling surface, and in which at least the capacitive coupling surface transparent or translucent is printed from fullerene-containing ink.

at a conventional, in particular transparent or translucent, Disk with a conventional antenna with a coil and a capacitive coupling surface z. B. off Silberleitfarbe it is known the opaque capacitive coupling surface under an opaque patch, e.g. As a metallic hologram, too hide. This hiding the capacitive coupling surface can in a data carrier according to the invention, in which the capacitive coupling surface is transparent or translucent is printed from fullerene-containing ink, if necessary omitted.

Of the Disk is optionally designed as a contactless chip card. Optionally, the data carrier is designed as a personal document. Optionally, the data carrier is a payment transaction card designed.

Of the Body of the disk is optional means Laminating made. Optionally, when laminating two or more laminating layers laminated together, wherein the antenna is printed on one of the lamination layers prior to lamination has been.

Optionally, the disk is designed as a banknote. The banknote has a body, the z. B. made of paper, a polymer film or a paper-polymer film composite. Optionally, the bill has a chip as a circuit arrangement. Optionally, the banknote has as a circuit arrangement a resistive circuit such as in DE 10 2008 011 299 described, in which the ohmic resistance is performed in the geometric shape of a pattern, an alphanumeric character or an image and is at least partially covered by a thermochromic ink layer. Optionally, the banknote further than the circuit coupled to the circuit, so in particular with the ohmic resistance, antenna, a coil or alternatively a coil and a coupled with the coil capacitive coupling surface. Optionally, the coil and / or the capacitive coupling surface is printed from the fullerene-containing printing ink, and optionally made transparent or translucent. Optionally, only the capacitive coupling surface is printed from the fullerene-containing printing ink, and optionally made transparent or translucent.

at a method for producing a data carrier with a Body, as well as with a contactless contactable circuit arrangement and a printed circuit electrically coupled to the circuit arrangement Antenna, which are arranged in or on the body the following steps are performed. At least two laminating layers will be provided. At least one of the laminating layers is provided with a an ink containing an electrically conductive component printed to form at least a portion of an antenna. The least two laminating layers are joined together by lamination, so that a data carrier with an antenna is generated. According to the invention, at least a part of the antenna printed from a printing ink containing at least one sort of electric conductive fullerenes as electrically conductive Component contains.

The Circuit arrangement, eg. As a chip, can optionally before or during of lamination, optionally also laminated, optionally be introduced only after lamination. In the second case will For example, a recess in the body of the disk leave or subsequently produced (eg milled) and the chip subsequently introduced into the recess.

in the The invention is based on exemplary embodiments and explained in more detail with reference to the drawing, in the shows:

1 a data carrier with a chip and an antenna, according to an embodiment of the invention;

2 a data carrier with a chip and an antenna, according to another embodiment of the invention;

3 a data carrier with a circuit arrangement and an antenna, according to another embodiment of the invention.

1 shows a schematic representation of a disk 10 with a body, a chip 11 and an antenna 12 for contactless contacting of the chip 11 , according to an embodiment of the invention. The disk 10 still has a contact field 13 for contact-contacting of the chip 11 , The chip 11 is with both the antenna 12 as well as with the contact field 13 electrically coupled. The antenna 12 is as a coil 12-1 designed and is printed from a printing ink having carbon nanotubes as an electrically conductive component.

2 shows a schematic representation of a disk 10 with a body, a chip 11 and an antenna 12 for contactless contacting of the chip 11 , According to another embodiment of the invention. The body of the data carrier 10 is partially transparent. The antenna 12 has both a coil 12-1 as well as one with the coil 12-1 electrically (galvanic) coupled capacitive coupling surface 12-2 on. The sink 12-1 is in an opaque area of the disk 10 arranged. The capacitive coupling surface 12-2 is in a transparent area of the volume 10 is arranged, is printed from a printing ink having carbon nanotubes as an electrically conductive component and printed in a layer thickness that the capacitive coupling surface 12-2 appears transparent.

3 shows a volume 10 with a circuit arrangement 11 and an antenna 12 , According to another embodiment of the invention. The disk 10 is designed as a banknote with a denomination of 50 currency units. The circuit arrangement 11 is designed as an ohmic resistance in the form of a number "50", according to the denomination of the banknote. The circuit arrangement 11 in the form of the "50" and a surrounding rectangle are of a black at room temperature (for example) opaque thermochromic paint layer 14 covered. The "50" electrically coupled antenna 12 has a coil 12-1 and a capacitive coupling surface 12-2 , The sink 12-1 and the capacitive coupling surface 12-2 are printed from a carbon nanotube (CNTs) as a conductive component having printing ink, in a sufficiently thin layer thickness that the coil 12-1 and the capacitive coupling surface 12-2 appear transparent. On the occasion of a coupling of energy into the circuit arrangement 11 over the antenna 12 or coil 12-1 , whose resonant frequency with the capacitive coupling surface 12-2 is tuned, the circuit assembly heats up 11 , Consequently, the color of the thermochromic ink layer changes in the region of "50" 14 from black to green or red, for example, so that a green or red "50" appears on a black background.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• EP 0756244 B1 [0004]
• US 2002/0168525 A1 [0006]
• - DE 60021778 T2 [0007]
• - DE 102005049600 A1 [0008]
• - DE 102004035368 B4 [0009]
• - DE 102008011299 [0010, 0028]
• - DE 102006059454 A1 [0011]

Claims (13)

Disk ( 10 ) with a body, as well as with a contactless contactable electrical circuit arrangement ( 11 ) and a printed antenna ( 12 ) arranged in or on the body, characterized in that at least a part of the antenna ( 12 ) is printed from a printing ink containing at least one kind of electrically conductive fullerenes as an electrically conductive component. Disk ( 10 ) according to claim 1, wherein carbon nanotubes (CNTs) are provided as fullerenes. Disk ( 10 ) according to claim 1 or 2, wherein the antenna ( 12 ) a coil ( 12-1 ) having. Disk ( 10 ) according to one of claims 1 to 3, wherein the antenna ( 12 ) at least one capacitive coupling surface ( 12-2 ) having. Disk ( 10 ) according to one of claims 1 to 4, wherein the printing ink is printed in a layer thickness such that the antenna ( 12 ) appears at least partially transparent or translucent. Disk ( 10 ) according to any one of claims 1 to 5, wherein the body is at least partially transparent or translucent. Disk ( 10 ) according to one of claims 1 to 6, which is designed as a contactless chip card. Disk ( 10 ) according to one of claims 1 to 7, which is designed as a personal document. Disk ( 10 ) according to one of claims 1 to 7, which is designed as a payment transaction card. Disk ( 10 ) according to one of claims 1 to 6, which is designed as a banknote. Disk ( 10 ) according to one of claims 1 to 10, used as a circuit arrangement ( 11 ) has a chip. Disk ( 10 ) according to one of claims 1 to 11, used as a circuit arrangement ( 11 ) has an ohmic resistance circuit. Method for producing a data carrier ( 10 ) with a body, as well as with a contactless contactable electrical circuit arrangement ( 11 ) and a printed antenna ( 12 ), which are arranged in or on the body, wherein - at least two lamination layers are provided, - at least one of the lamination layers is printed with an ink containing an electrically conductive component to at least a part of an antenna ( 12 ), and - the at least two laminating layers are laminated together so that a data carrier ( 10 ) with an antenna ( 12 ) is generated, characterized in that at least a part of the antenna ( 12 ) is printed from a printing ink containing at least one kind of electrically conductive fullerenes as an electrically conductive component.