PASSIVE RADIO TRANSMISSION DEVICE

Abstract

A passive radio transmission device is arranged on a front and a back of an electrically conductive carrier plate, wherein the radio transmission device includes, on the front of the carrier plate, a first film having a first antenna and having a microchip coupled to the first antenna and, on the back, a second film having a second antenna, wherein the first film is coupled to the second film via a flexible web, routed around an end face of the carrier plate, that connects the front to the back, so that the second antenna is connected to the first film via at least one connecting line running along the web in order to transmit information from the microchip using both the first antenna and the second antenna, wherein the first film, the second film and the web are combined as one component.

Claims

1. A passive radio transmission device (FU), which is disposed on a front side (SE) and a rear side (SZ) of an electrically conductive carrier plate, wherein the radio transmission device (FU) comprises, on the front side (SE) of the carrier plate, a first foil (FE) having a first antenna (AE) and a microchip (MC) coupled with the first antenna (AE) and, on the rear side (SZ), a second foil (FZ) having a second antenna (AZ), wherein the first foil (FE) is connected with the second foil (FZ) via a flexible web (ST), which is routed around an end face of the carrier plate connecting the front side (SE) with the rear side (SZ), so that the second antenna (AZ) is connected with the first foil (FE) via at least one connecting line running along the web (ST), in order to transmit information from the microchip (MC) both on the basis of the first antenna (AE) and of the second antenna (AZ), wherein the first foil (FE), the second foil (FZ) and the web (ST) are combined as one component part.

2. A passive radio transmission device (FU), which comprises, on the first foil (FE) or on the second foil (FZ), an energy reservoir (KO), which feeds the microchip (MC) with electrical energy.

3. The passive radio transmission device (FU) according to claim 1, which comprises, on the first foil (FE) or on the second foil (FZ), a data memory (DS), the data of which can be read out by the microchip (MC).

4. The passive radio transmission device (FU) according to claim 1, which is provided on the side turned toward the carrier plate with a layer for conduction of the magnetic flux, which layer is formed in particular as a ferrite foil (FF), which is disposed underneath the first foil or the second foil.

5. The passive radio transmission device (FU) according to claim 1, which is fastened on the carrier plate by means of an adhesive layer (KF), which is designed in particular as an adhesive foil.

6. The passive radio transmission device (FU) according to claim 1, which is provided with a cap (KA) disposed around the carrier plate, wherein the cap (KA) holds the radio transmission device (FU) on the carrier plate.

7. The passive radio transmission device (FU) according to claim 1, in which the first antenna (AE) and the second antenna (AZ) are connected in series, in which the first antenna (AE) and the second antenna (AZ) of the radio transmission device (FU) are respectively connected to the microchip (MC) or the first antenna (AE) and the second antenna (AZ) are connected in parallel.

8. The passive radio transmission device (FU) according to claim 1, in which the flexible web (ST) is selected with a width that is made slightly larger than the conductor-track width of the connecting line.

9. The passive radio transmission device (FU) according to claim 1, in which the carrier plate is a key bow (SR) of a key (SC).

10. The passive radio transmission device (FU) according to claim 1, in which the carrier plate is a key fob.

11. The passive radio transmission device (FU) according to claim 9, in which the first foil (FE) and the second foil (FZ) are chosen in such a way with respect to their dimensions that a ring hole (RL) remains accessible in the key bow (SR) of the key (SC) or of the key fob.

12. The passive radio transmission device (FU) according to claim 1, in which the carrier plate is part of a tool to be identified.

13. A method for retrofitting a mechanical key (SC), comprising the steps: Provision of a mechanical key (SC), which with respect to its function is adapted to a locking system, Provision of a passive radio transmission device (FU), which comprises a first foil (FE) having a first antenna (AE) and a microchip (MC) coupled with the first antenna (AE), and a second foil (FZ) having a second antenna (AZ), wherein the first foil (FE) is connected to the second foil (FZ) via a flexible web (ST), Disposing the first foil (FE) of the radio transmission device (FU) on a front side (SE) of a key bow (SR) of the mechanical key (SC), Disposing the second foil (FZ) of the radio transmission device (FU) on the rear side (SZ) of the key bow (SR) of the mechanical key (SC), wherein the first foil (FE) is connected with the second foil (FZ) via a flexible web (ST), which is routed around an end face of the key (SC) connecting the front side (SE) with the rear side (SZ), so that the second antenna (AZ) is connected with the first foil (FE) via at least one connecting line running along the web (ST), in order to transmit information from the microchip (MC) both on the basis of the first antenna (AE) and of the second antenna (AZ), and Programming the microchip (MC) of the passive radio transmission device (FU) with an access authorization.

14. The method according to claim 13, in which the passive radio transmission device (FU) is provided with a cap (KA).

15. The method according to claim 13, in which the key bow (SR), after removal of a key bit, forms a key fob.

Description

[0068] The invention will be explained in more detail in the following with reference to the drawing, wherein:

[0069] FIG. 1 shows a first embodiment of a radio transmission device,

[0070] FIG. 2 shows a further embodiment of the radio transmission device,

[0071] FIG. 3 shows a further embodiment of a radio transmission device, disposed on a key,

[0072] FIG. 4 shows the radio transmission device and the key from FIG. 3 in a sectional diagram,

[0073] FIG. 5 shows a further embodiment of a radio transmission device, disposed on a key,

[0074] FIG. 6 shows the radio transmission device and the key from FIG. 5 in a sectional diagram, together with a cap, and

[0075] FIG. 7 shows the radio transmission device on a carrier plate, which is part of a workpiece, within a receiver device.

[0076] FIG. 1 shows a passive radio transmission device FU having a first foil FE, on which a first antenna AE is disposed, and a second foil FZ, on which a second antenna AZ is disposed. The first foil FE and the second foil FZ are connected to one another via a web ST. Across the web ST, the first antenna AE and the second antenna AZ are connected by means of a connecting line. At the center of the first antenna AE, a microchip MC, the information of which can be transmitted by radio from the first antenna AE and the second antenna AZ, is disposed on the first foil FE. The first antenna AE and the second antenna AZ are respectively constructed in the form of spirals, wherein the spiral begins in the middle of the two foils.

[0077] The passive radio transmission device FU shown in FIG. 1 may be disposed together with its two foils on two sides of an electrically conductive carrier plate. For this purpose, the web ST is designed to be flexible, so that it can be bent around the carrier plate. However, the outer shape of the first foil and of the second foil are not limited to the rectangular shape as shown in FIG. 1.

[0078] FIG. 2 shows an embodiment of the passive radio transmission device FU in which a first antenna AE and a microchip MC are disposed on the first foil FE and a second antenna AZ, a capacitor KO and a data memory DS are disposed on the second foil FZ. The first antenna AE and the second antenna AZ are respectively formed as spirals, which are connected in series across the web ST. The microchip MC is disposed at the center of the first antenna AE. The capacitor KO and the data memory DS are disposed at the center of the second antenna AZ. The data memory DS and the capacitor KO are likewise disposed in the series circuit of the first antenna AE, of the second antenna AZ.

[0079] In FIG. 3, a passive radio transmission device FU is shown that is disposed on a key bow SR or a key SC. The key SC comprises a key blade FS, a profile PR, key cuts ES, a key shoulder SA and a key bow SR. The key blade FS, the profile PR, the key cuts ES and the key shoulder SA form the part of the key referred to as the bit. The radio transmission device FU was disposed with the first foil FE on a first side of the key bow SR, then folded over the web ST, so that the second foil FZ is made to lie on the rear side SZ of the key bow SR, whereupon the second foil FZ has been fastened on the rear side SZ of the key bow. The web ST then forms a connection of the foils disposed on the two opposite sides of the key. Connecting lines that connect the two antennas with one another or connect the two antennas with the microchip run through the flexible web.

[0080] In FIG. 4, the key together with radio transmission device FU from FIG. 3 is shown in a sectional diagram. On the front side SE of the key SC, the first foil FE was fixed by means of an adhesive layer KF. Then the second foil FZ was folded across the web ST onto the rear side SZ of the key SC and finally the second foil FZ was joined to the rear side SZ of the key SC via an adhesive layer KF. The web ST projects beyond the key bow SR. The adhesive layers KF end in the region of the web ST, so that this projects beyond the end face of the key bow SR only by the material thickness of the web ST. The key blade SS is not contacted by the radio transmission device FU, so that the key SC may also continue to be used without restriction as a mechanical key. In particular, it was not necessary to mechanically remachine the key SC from FIG. 3 and FIG. 4. Due to the arrangement of the radio transmission device FU on both sides of the key, as shown in FIG. 4, the first antenna AE and the second antenna AZ are able to reach an almost spherical space around the key SC with radio waves. Thus the orientation of the key SC relative to a receiver device (not illustrated) is almost without significance for the function of the radio transmission device FU.

[0081] An alternative configuration of the passive radio transmission device FU on a key was illustrated in FIG. 5. The radio transmission device FU in this case is selected such that a ring hole RL of the key SC is not covered. Nevertheless, it was possible to dispose the radio transmission device FU on both sides of the key bow SR, wherein only the front side SE of the key SC is illustrated in FIG. 5, on which side the first foil FE is disposed together with the first antenna AE. The web ST connects the first foil FE with the second foil FZ disposed on the rear side (not visible) of the key bow SR. A connecting line runs through the web.

[0082] In FIG. 6, the passive radio transmission device for arrangement on a key SC from FIG. 5 is illustrated in a sectional view. A layer in the form of a ferrite foil FF for conduction of the magnetic flux was applied between the radio transmission device FU and the key SC, which layer is fastened on the key by means of an adhesive layer KF. The ferrite foil FF functions for reflection and amplification of radio signals as well as for suppression of eddy currents in the electrically conductive key, wherein the first foil FE and the second foil FZ, in which the first antenna AE and the second antenna AZ as well as further electronic component parts are disposed, was constructed as a polymer foil.

[0083] A cap KA, which holds the passive radio transmission device FU on the key and protects if from mechanical damage, was disposed around the radio transmission device FU in FIG. 6. This cap KA is made from a soft elastic material, so that the cap KA can be pulled easily over the key bow SR, as in the view illustrated in FIG. 6, the interior of the cap KA may have a hollowed-out space, which accommodates the radio transmission device FU. However, since the radio transmission device FU usually has an overall structure in the millimeter range, this hollow in the interior of the cap KA is not absolutely necessary. Instead of a soft elastic cap KA, it had also been possible to use a hard cap KA of plastic formed from two half shells. The ring hole RL of the key SC is also cut out through the cap KA, so that the ring hole may continue to be used for passage of a key ring, for example on a bunch of keys.

[0084] By separation of the bit of the key, the key from FIGS. 3 to 6 may be converted to a key fob having passive transponder function.

[0085] The description for FIGS. 3 to 6 can be expanded without restrictions to key fobs as carrier plates of the radio transmission device, wherein key fobs, in contrast to mechanical keys, have no bits from the very beginning or these have been removed.

[0086] In FIG. 7, a passive radio transmission device having a first foil FE, a second foil FZ and a web ST is shown, which was disposed on a workpiece WS. A detail view of the passive radio transmission device is shown by way of example in FIG. 2. The workpiece is disposed on a conveyor belt within a production line and is to be identified by a receiver EM. The receiver is disposed on one side of the conveyor belt FB, so that a radio shadow FS is formed on the side of the workpiece situated opposite the receiver EM.

[0087] The second foil FZ of the radio transmission device FU is situated within this radio shadow and thus is unable to receive any electromagnetic waves of the receiver EM. However, the first foil FE of the radio transmission device FU was disposed on another side face of the workpiece WS, which is oriented such that the electromagnetic waves of the receiver EM can be received by the first antenna AE disposed in the first foil FE. Thus the radio transmission device is able to communicate with the receiver and to transmit the information relevant for identification to the receiver. The first antenna AE converts the necessary energy for transmission to the form of an induction current from the electromagnetic waves of the receiver EM, which current is temporarily stored for transmission of the information by a capacitor KO (not illustrated) and is delivered to the microchip. On the basis of the arrangement of the two foils on two sides, which are differently oriented in space, the function of the transponder is almost independent of the location of the workpiece WS in space and the workpiece WS can be identified despite radio shadows.

[0088] The features indicated in the forgoing and those indicated in the claims as well as those that can be inferred from the figures can be advantageously implemented both individually and in various combinations. The invention is not restricted to the described exemplary embodiments but instead may be modified in quite a few ways within the scope of the abilities of persons skilled in the art.