DE102011106648A1 - Portable data carrier with antenna - Google Patents

Abstract

The present invention relates to a portable data carrier (2) consisting of a device (4) for storing and processing data, an antenna (6) for power and data transmission, which is connected to the device (4) and a device (4). 4) and the antenna (6) surrounding body made of plastic, wherein the antenna (6) by connecting longitudinal and transverse threads of an electrically conductive fabric (10) is produced.

Description

The present invention describes a portable data carrier and a method of manufacturing the data carrier suitable for contactless communication.

Portable data carriers for non-contact communication with a terminal are manufactured in various ways. Examples of these production methods include etching or printing of antennas. Another known antenna manufacturing method is the so-called antenna winding technique.

A disadvantage of the previous production method is that antennas are very sensitive to mechanical loads and thus are easily damaged, in particular during manufacture. Furthermore, a change in the antenna geometry is comparatively complicated.

Object of the present invention is to provide an antenna for portable data carriers for contactless communication, which is easy to manufacture and has a high mechanical stability.

The object of the present invention is achieved by the teaching of independent claim 1 and independent claim 14. Advantageous embodiments are described in the subclaims.

The invention discloses a portable data carrier consisting of a device for storing and processing of data, an antenna for power and data transmission, which is connected to the device and a surrounding the device and the antenna body made of plastic, wherein the antenna of a compound of Longitudinal and transverse threads of an electrically conductive fabric.

A great advantage of the invention is that the shape of the antenna or the antenna geometry can be determined individually. For this purpose, in the electrically conductive fabric, the longitudinal and transverse threads at the desired intersection points with each other by a suitable method, for. B. by laser, electrically conductively connected. In general, care must be taken that in the production of an antenna geometry according to the invention, antenna turns are not electrically short-circuited by other threads. To avoid a short circuit such threads, z. B. by laser or punch, which cause a short circuit between turns. The use of a fabric for the antenna has the advantage that both increased mechanical stability and strength of the antenna and the card body is achieved with simultaneous mechanical flexibility of the antenna, since the tissue and thus the antenna in the manufacture, for. As in lamination, an integral part of the card body is. The free spaces between the tissue are penetrated by the films of the card body during lamination. Another advantage to using a tissue for the antenna is that the tissue can be made into rolls in a standardized process. This allows a production of portable data carriers with a tissue as an antenna in the so-called roll-to-roll method. This roll-to-roll process enables the efficient production of a large number of data carriers in a short time.

To improve the properties of the fabric, in particular its processability, this is coated. As coating methods, suitable processes include, for example, an extrusion coating or a coating process. In addition to coating by extrusion, the fabric can also be produced by means of an extrusion process itself.

The fabric itself advantageously consists of electrically conductive and / or electrically non-conductive threads. This has the advantage that electrically non-conductive areas can be integrated in certain areas of the tissue. Furthermore, additional threads, both electrically conductive and electrically non-conductive, in particular for increasing the mechanical strength and / or the electrical conductivity of the tissue, integrated and thus the fabric are at least partially compacted with respect to the arrangement of the threads.

An electrically conductive thread may moreover consist of at least one first electrically conductive partial thread and at least one second electrically insulating partial thread. This has the advantage that especially threads with special mechanical and / or electrical properties can be produced, such. B. special mechanical elastic properties.

As the material for the electrically non-conductive thread and / or the electrically insulating thread part of any suitable plastic can be used, such as. As a polymer consisting of polyethylene terephthalate (PET) or polyamide (PA).

The electrically conductive thread may have an insulating coating consisting, for example, of the aforementioned materials or any other suitable material. This allows isolation between individual threads in the tissue. It is advantageously possible that at least one electrically conductive thread in the manufacture of the fabric receives an electrically insulating coating to reserve at least this one thread for special functions, for. B. as a signal line, which may have no electrically conductive connection with other electrically conductive threads, except at desired contact points. To connect at least one electrically conductive thread with insulation with at least one further electrically conductive thread at a crossing point for producing an antenna geometry, the insulation must first be removed by a suitable method, for. B. by lasers to then make a conductive connection between the threads.

In order to use the fabric as a security feature, it is possible that at least one electrically conductive and / or electrically non-conductive thread and / or partial thread has a security feature. This is advantageously to install on the surface. As a security feature, any suitable security feature can be used, such. As a fluorescent element that can be perceived from the outside through an at least partially transparent or translucent area of the card surface. In addition to the security features on the surface of a thread there is also the possibility that threads are used as a security feature, which are light-conducting threads.

The fabric itself may consist of at least one layer of electrically conductive and / or electrically non-conductive threads. This has the advantage that each layer has certain mechanical and / or electrical properties, such. B. electrically conductive or electrically non-conductive, can be assigned. Furthermore, different antenna geometries are possible in this way within a tissue, but in different layers. For this, the individual layers with the respective antenna geometries must be produced individually and then joined together to form a tissue.

Each layer consists of at least two planes, each plane having at least one thread and the threads of at least one upper plane being disposed above the threads of at least one lower plane such that the threads of the upper plane with the threads of the lower plane are at an angle between 0 and Include 180 degrees. Within a plane, the threads may be arranged parallel to each other or in any other suitable position. With this arrangement thus special mechanical and / or electrical properties can be achieved, such. B. special elasticity in a bending direction and special rigidity in another direction.

To achieve certain mechanical and / or electrical properties, it is possible that the threads of the upper level are interwoven with the threads of the lower level. Thus, the properties of different antenna geometries can be combined or the mechanical properties of the different layers can be changed, eg. B. to increase the resistance to external shear forces.

For special cases, it is even possible that the threads of the upper level are arranged parallel to the threads of the lower level.

In the manufacture of the fabric, it is possible for at least one upper-level thread in a layer to contact at least one lower-level thread at at least one point of intersection so that there is an electrically conductive connection between the upper-level thread and the lower-level thread , Alternatively, it is possible that there is no electrically conductive connection between at least one thread of the upper level and at least one thread of the lower level at at least one intersection point, e.g. B. by means of distance between the threads or by an insulating layer on the threads. Thus, an electrically conductive connection or no electrically conductive connection can be selectively achieved at certain crossing points already in the production of the tissue.

In the case of a fabric having a plurality of layers, it is also possible for at least one thread of one layer to be interwoven with at least one thread of the other layer between at least one layer and at least one other layer. In this case, a mechanically particularly strong connection between the layers can be produced.

Furthermore, it is possible for at least one thread of one layer with at least one thread of the other layer to have an electrically conductive connection between at least one layer and at least one other layer. This allows, for example, the electrical connection between antennas of different layers.

In the following, advantageous embodiments of the invention will be described. However, the invention is not limited by the described embodiments. The description is only for the better understanding of how the invention can be put into practice.

1 shows a portable data carrier with an electrically conductive tissue from which the antenna is formed.

2 shows a portable data carrier with an electrically conductive fabric, which is reinforced by additional threads in selected areas.

3 and 4 show possible structures of portable data carriers with an electrically conductive fabric.

1 shows a portable data carrier according to the invention 2 for contactless communication with a terminal. The disk 2 has an electrically conductive fabric 10 in the form of a grid with longitudinal and transverse threads on. In addition to the lattice shape, the tissue may have any other suitable shape. To form an antenna 6 were longitudinal and transverse threads of the fabric 10 at points 8th electrically connected. The longitudinal and transverse threads can be electrically connected to one another by means of a soldering point or by means of any other suitable method. The points 8th are crossing points of longitudinal and transverse threads of the fabric 10 , For reasons of clarity, only one intersection point with the reference numeral 8th Mistake. For all other crossing points that are used to shape the antenna 6 serve and are marked with a black dot, the reference numeral applies accordingly. The longitudinal and transverse threads were connected here so that three turns have emerged. Nevertheless, any other suitable antenna geometry is possible. If a fabric with electrically non-insulated longitudinal and transverse threads, it is necessary to avoid electrical short circuits between the turns, that all longitudinal and transverse threads are interrupted, which connect at least two turns electrically conductive. The longitudinal and transverse threads can be interrupted for example by means of a laser, a punch or any other suitable method or tool. For clarity, the interruptions in 1 not shown. The two endpoints of the antenna 6 are by means of contacts 12 on a chip 4 connected to the processing and storage of data electrically conductive. For connecting the antenna 6 to the chip 4 by means of the contacts 12 usually a solder joint is used. However, all other suitable methods of making the contacts may be used 12 be used.

2 shows the disk 2 according to 1 , In 2 is the disk 2 but supplemented by additional threads 14 , The additional threads 14 may be both electrically conductive and / or electrically non-conductive. The additional threads 14 serve for this purpose the mechanical and / or electrical properties of the data carrier 2 at least in subregions of the data carrier 2 to reinforce or improve, for. B. improved mechanical strength and / or increased electrical conductivity.

3 and 4 show possible constructions of the portable data carrier 2 ,

3 shows the structure of a data carrier 2 , which in the middle a tissue 10 has, for example, electrically conductive threads. On both sides of the fabric 10 are opaque films 16 applied. On the tissue 10 opposite sides of the films 16 For example, there are transparent foils 18 ,

4 shows the corresponding structure of 3 , In 4 is however the tissue 10 both sides with foils 20 laminated. Instead of the slides 20 can be on both sides of the slide 10 also an extrusion coating or a coating coating or other suitable coating.

Claims (15)

Portable data carrier ( 2 ) consisting of - a device ( 4 ) for storing and processing data - an antenna ( 6 ) for power and data transmission associated with the device ( 4 ), - the device ( 4 ) and the antenna ( 6 ) surrounding plastic body characterized in that the antenna ( 6 ) of a compound of longitudinal and transverse threads of an electrically conductive fabric ( 10 ) consists. Disk ( 2 ) according to claim 1, characterized in that the tissue ( 10 ) consists of electrically conductive and / or electrically non-conductive threads. Disk ( 2 ) according to claim 2, characterized in that the electrically conductive thread consists of at least one first electrically conductive partial thread and at least one second electrically non-conductive partial thread. Disk ( 2 ) according to claim 2 or 3, characterized in that the electrically non-conductive thread and / or the electrically insulating part thread consists of a polymer. Disk ( 2 ) according to claim 2 or 3, characterized in that the electrically conductive thread has an insulating coating. Disk ( 2 ) according to the preceding claims, characterized in that the electrically conductive and / or electrically non-conductive threads and / or partial threads have at least one security feature. Disk ( 2 ) according to claim 6, characterized in that the security feature is a fluorescent element. Disk ( 2 ) according to claims 1 to 8, characterized in that the tissue ( 10 ) consists of at least one layer. Disk ( 2 ) according to claim 8, characterized in that the layer consists of at least two planes, each plane having at least one thread and the threads of at least one upper plane are arranged over the threads of at least one lower plane, so that the threads of the upper plane with the Lower level threads include an angle between 0 and 180 degrees. Disk ( 2 ) according to claim 9, characterized in that the threads of the upper level are interwoven with the threads of the lower level. Disk ( 2 ) according to claim 9, characterized in that the threads of the upper plane are arranged parallel to the threads of the lower plane. Disk ( 2 ) according to claims 10 or 11, characterized in that at least one thread of the upper level comprises at least one thread of the lower level at at least one point of intersection ( 8th ) so that there is an electrically conductive connection between the upper level thread and the lower level thread. Disk ( 2 ) according to claims 10 or 11, characterized in that between at least one thread of the upper level and at least one thread of the lower level at at least one crossing point ( 8th ) no electrically conductive connection exists. Method of manufacturing a portable data carrier ( 2 ) according to claims 1 to 13 consisting of - a device ( 4 ) for storing and processing data - an antenna ( 6 ) for power and data transmission, which is connected to the device, - a device ( 4 ) and the antenna ( 6 ) surrounding plastic body characterized in that for the formation of the antenna ( 6 ) Longitudinal and transverse threads of an electrically conductive fabric ( 10 ) are electrically connected. Method according to claim 14, characterized in that the tissue ( 10 ) is coated.

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