DE19705722A1 - Resonant circuit for electronic article surveillance - Google Patents

Abstract

This invention concerns a resonant circuit (6) for the electronic element. The task of the invention is to propose a resonant circuit (6) which can be reliably deactivated. This task is achieved by using a resonant circuit (6) consisting of two spiral printed circuits (2, 3) and one dielectric layer (4), wherein both spiral printed circuits (2, 3) are wrapped in opposing directions and arranged on both sides of the dielectric layer (4) so that they at least partly overlap. At least one selected area (8) is provided in which a conductive path arises between the two spiral printed circuits (2, 3) whenever a sufficiently high energy is applied by means of an external alternating field.

Description

The invention relates to a resonant circuit for the electronic article surveillance.

Resonance resonant circuits at a given resonance frequency, which is usually around 8.2 MHz, to resonance Vibrations are excited for the purpose of General anti-theft protection in department stores. They are often an integral part of adhesive labels or Cardboard hang tags attached to the to be secured Articles are attached. Typically the department store with an electronic surveillance system in Output area equipped that the resonant circuits detects and triggers an alarm when a secured Article in an unauthorized manner a secured surveillance zone happens. As soon as a customer has paid for the goods, the resonant circuit is deactivated. By the measure prevents an alarm from being triggered as soon as a Item has been lawfully purchased and subsequently the Surveillance zone happens.

The deactivation systems, often in the checkout area are placed, generate a resonance signal with a greater amplitude than that in the surveillance systems is produced. A resonance label is usually included  a signal whose field strength is between 0.9 A / m and 1.5 A / m is deactivated.

Different deactivation mechanisms for Resonant circuits have become known. Either will the isolation between opposite one another Conductor tracks destroyed, causing a short circuit, or a piece of a conductor track is overloaded and melts, creating an interruption. As a result Deactivating the resonant properties of the Resonant circuit, d. H. the resonance frequency and / or the "Q" factor modified so much that the Resonance label no longer by the surveillance system is detected.

Regarding the deactivation of resonance labels different methods have been described. In the US PS 4,876,555 or in the corresponding EP 0285 559 B1 suggested using a needle to make a hole in the Insulation layer between two opposite To generate capacitor areas. This will be a Deactivation mechanism made that is error free and is permanent.

US Pat. No. 5,187,466 also describes a method for Generation of a deactivatable resonant circuit by means of a short circuit.

Regarding the first-mentioned US Pat. No. 4,876,555 or EP 0 285 559 B1 should be noted that there disclosed resonant circuit capacitor plates has on both sides of the dielectric are arranged. The one between the two capacitor plates lying dielectric layer has a through hole on.

A process is described in the previously mentioned US Pat. No. 5,187,466 described that with a resonant circuit Capacitor plates on both sides of the dielectric  is applied, the capacitor plates first be short-circuited and the short-circuit later Electric power is melted.

EP 0 181 327 B1 describes a deactivable device Resonance label described, which results from a dielectric carrier layer, capacitor plates to both Sides of the dielectric layer and a spiral Turn on either side of the dielectric Layer. To ensure that a the resonance label has been reliably deactivated a selected area prepared for deactivation. In particular, the dielectric layer is thinner than here in the other areas.

The invention has for its object a resonance Propose resonant circuit that reliably deactivates can be.

The object is achieved in that the resonance oscillation circle of two spiral tracks and one dielectric layer, the two Conductor tracks are wound in opposite directions and on both sides of the dielectric layer are arranged so that they overlap at least partially, wherein at least one selected area is provided in which is a conductive path between the two conductor tracks arises as soon as a sufficiently high energy through a external alternating field is supplied. The invention points so no separate capacitor plates; these will rather directly through the two themselves, at least in part overlapping conductor tracks are formed.

According to an advantageous development of the invention According resonant resonant circuit has the dielectric Layer essentially a uniform thickness and none additional manufacturing defects (e.g. air pockets).  

This configuration is particularly advantageous in connection with the training that the selected area to the outer end regions of the conductor tracks, where the Induction voltage of the conductor tracks is maximum. Here is so it’s completely superfluous To prepare the resonant circuit in particular. Under Exploitation of physical laws is the deactivation area automatically in a predeterminable area the outer ends of the spiral traces.

An alternative embodiment of the invention Resonant circuit suggests that the selected one Area at any point of the overlapping Conductors lies and is prepared in such a way that Apply the deactivation signal to the conductive path the prepared site is built up.

In particular, it is provided in this connection that the dielectric layer thinner in the selected area is than in the other areas or that it is in the prepared spot around a hole in the dielectric Layer. Another embodiment of the resonant circuit according to the invention provides that the dielectric layer in the selected area other physical or chemical nature having.

An advantageous development of the invention Resonant circuit provides that the dielectric Layer consists of at least two components. Means Such a configuration can be very homogeneous, containing negligible air pockets Manufacture dielectric layers. Here it turned out to be proven favorable when the melting point of one Component above the manufacturing temperature for the Resonant circuits are d. H. this layer will do not melt during the manufacturing process. The Components are also according to a training  of the resonant circuit so that they either can be joined together by coating or lamination.

In the previous place was already on the advantageous Embodiment of the resonance oscillation according to the invention circle, the deactivation area due to physical conditions in the overlapping outer End areas of the spiral conductor tracks occurs. Around intensifying this effect sees an advantageous Development of the resonant circuit according to the invention before that the areas of overlap between the two Traces and thus the capacitance between the spiral shaped conductor tracks at the inner ends of the conductor tracks focus.

Another improvement in terms of a safe Deactivation can also be achieved by that the outer ends of the two conductor tracks in one small area overlap and that adjusts to the outer Ends of the conductor tracks a relatively long overlap-free area.

The invention is illustrated by the following figures explained. It shows:

Fig. 1 is a plan view of an embodiment of the resonant circuit according to the invention,

Fig. 2 shows a cross section according to the marking II-II in Fig. 1,

Fig. 3 is a schematic representation of the voltages at two partially overlapping coiled conductive tracks,

Fig. 4 is a plan view of the outer end portion of the coiled conductive tracks,

Fig. 5 is an enlarged cross section through the upper coil and the upper component of the dielectric layer and

Fig. 6 shows a detailed cross section through the resonant circuit according to the invention.

Fig. 1 shows an embodiment of the resonant circuit 6 according to the invention in plan view. In FIG. 2 the resonant circuit 6 shown in FIG. 1 can be seen in cross section.

The resonant circuit 6 is deactivated by creating a short circuit between the two spiral conductor tracks 2 , 3 , which are preferably made of aluminum, through the dielectric layer 4 . An applied alternating magnetic field, as z. B. is emitted by the monitoring system, induces AC voltages in the two spiral conductor tracks 2 , 3 of the resonant circuit 6 . The two spiral conductor tracks 2 , 3 , which at least partially overlap, are wound in opposite directions. Therefore, the outer end of the lower coil 2 has a positive potential relative to the inner end of the lower coil 2 when the inner end of the upper coil 3 has a positive potential with respect to the outer end of the upper coil 3 . It should therefore be noted that the points / areas in which the induced alternating voltages between the two coils 2 , 3 are maximum are in the end areas of the coils 2 , 3 .

Since the upper coil 3 has fewer turns than the lower coil 2 in the example shown in FIG. 1, the highest voltages are generated between the ends of the upper coil 3 and the locations of the lower coil 2 directly below. Fig. 3 illustrates the Spannungsver ratios in different areas of the two at least partly overlapping coils 2, 3 of a resonant circuit 6, which can be used according to an advantageous further development of the resonant circuit 6 according to the invention.

Fig. 3 shows the different voltages that occur in under different areas of the two overlapping coils 2 , 3 over their length during the electromagnetic induction.

In the resonant circuit 6 described above with a uniform thickness of the dielectric layer 4 between the coils 2 , 3 , the deactivation takes place in the end regions of the upper coil 2 and lower coil 2 , since the induced potential is maximum here. Since the electric field strength occurs concentrated on a surface with a small radius, deactivation occurs precisely at the ends of the conductor tracks 2 , 3 - as shown in FIG. 4.

However, if the dielectric layer 4 is not uniformly thick or contains air bubbles 7 , which is quite possible due to manufacturing errors, deactivation can occur in different areas of the coils 2 , 3 . Such manufacturing defects can cause local weak points and even create holes through air pockets in the dielectric layer 4 . As a result, the dielectric layer 4 breaks down at these local weak points, although the voltage potential here is lower than at the ends of the upper coil 2 and lower coil 3 . Since the voltage potential at the local weak points is lower than at the ends of the conductor tracks 2 , 3 , the electrical energy available to generate the deactivation short circuit is smaller than the electrical energy required to generate a deactivation short circuit at the ends of the upper coil 3 would.

Fig. 5 shows a cross section of an one-layer dielectric 4 with manufacturing errors, here air bubbles 7 and irregularities in the surface.

Therefore, it is another object of the present invention to form a dielectric layer that is substantially uniform in thickness and largely free of localized weaknesses that result from manufacturing. Such a uniform dielectric layer 4 ensures deactivation at the points at which a maximum voltage and energy can be found, ie, at the ends of the upper conductor track 2 , based on the example shown. Short circuits that result from such a deactivation are very robust and less susceptible to inadvertent reactivation.

According to an advantageous development of the resonant circuit 6 according to the invention, the dielectric layer 4 consists of at least two components 4 a, 4 b, an upper component 4 a and a lower component 4 b. The lower component 4 b is applied to the lower coil 3 before punching and hot stamping. The upper component 4 a is applied to the upper coil 2 . The upper component 4 a has a relatively low melting point, which enables it to serve as a hot melt adhesive and to glue the two coils 2 , 3 to the lower coil 3 during hot stamping of the upper coil 2 . The upper component 4 a of the dielectric layer 4 melts during the hot stamping of the upper coil 2 . The lower component 4 b of the dielectric layer 4 has a higher melting point and does not melt onto the upper coil 2 during hot stamping. The uniformity of the lower component 4 b of the dielectric layer 4 , which does not melt, improves the uniformity in the thickness of the dielectric layer 4 as a whole.

Fig. 6 shows a cross section of a resonant circuit 6 with a dielectric layer 4 of two components 4 a, 4 b. The lower component 4 b can be produced either by coating the lower coil 3 or by laminating the lower component 4 b of the dielectric layer 4 onto the coil 3 . The coil material (A1) is usually in the form of a wide roll material, so that the uniformity of the surface of the dielectric layer 4 can be maintained and other defects, which are caused, for example, by air pockets 7 , are minimized.

Reference list

1 carrier material
2 upper coil
3 lower coil
4 dielectric layer
4 a top component
4 b lower component
5 adhesive layer
6 resonant circuit
7 trapped air
8 groomed area
9 area without overlap

Claims (11)

1. resonant circuit ( 6 ) for the electronic article fuse, consisting of two spiral conductor tracks (coils 2, 3 ) and a dielectric layer ( 4 ), the two spiral conductor tracks ( 2 , 3 ) being wound in opposite directions and on both sides of the dielectric layer ( 4 ) are arranged such that they overlap at least partially, at least one selected area ( 8 ) being provided in which a conductive path between the two spiral conductor tracks ( 2 , 3 ) is created as soon as a sufficiently high energy is generated by an external alternating field is supplied. 2. resonant circuit according to claim 1, wherein the dielectric layer ( 4 ) has a substantially uniform thickness and no additional manufacturing defects (z. B. air pockets ( 7 )). 3. resonant circuit according to claim 1 and 2, wherein the selected region ( 8 ) is at the outer end regions of the coils ( 2 , 3 ), at which the induction voltage of the coils ( 2 , 3 ) conductor tracks is maximum. 4. resonant circuit according to claim 1, wherein the selected area ( 8 ) at any location of the overlapping coils ( 2 , 3 ) and is prepared such that the conductive path is established in the selected area ( 9 ) when the deactivation signal is applied. 5. resonant circuit according to claim 4, wherein the dielectric layer ( 4 ) at the selected point ( 9 ) is thinner than in the other areas or that the selected area ( 8 ) is a hole in the dielectric layer ( 4 ) . 6. resonant circuit according to claim 4, wherein the dielectric layer ( 4 ) in the selected region ( 8 ) has a different physical or chemical nature. 7. resonant circuit according to claim 1 or 2, wherein the dielectric layer ( 4 ) consists of at least two components ( 4 a, 4 b). 8. resonant circuit according to claim 1 or 7, wherein the melting point of one component ( 4 a; 4 b) is above the manufacturing temperature for the resonant resonant circuits ( 6 ). 9. resonant circuit according to claim 7 or 8, wherein the components ( 4 a, 4 b) are such that they can be joined together either by coating or lamination. 10. Fuse element according to claim 2, wherein the overlap regions between the two spiral conductor tracks ( 2 , 3 ) and thus the capacitance between the spiral conductor tracks ( 2 , 3 ) at the inner ends of the spiral conductor tracks ( 2 , 3 ) concentrate. (2, 3) overlap 11. The resonant circuit as claimed in claim 10, wherein the outer ends of the two coiled conductive tracks in a small area, and wherein at the outer ends of the conductor tracks (2, 3), a relatively long non-overlapping region (9) is connected.