EP0878785A2 - Universal security element and production method thereof - Google Patents

Abstract

The universal security element is in the form of a label (1) attached to the article and has an electromagnetic resonance circuit (2) which unless disabled when passed through a detector field triggers an alarm. An inner electromagnetic resonance circuit (3) has specific coded information that identifies the article. The label may have one or more of these identifying labels.

Description

The invention relates to a universal element for Securing items against theft, at least one has electromagnetic resonant circuit which in Query field of an article monitoring device for Is emitted a characteristic signal, which subsequently triggers an alarm, as well as a Method of manufacturing the universal securing element.

Resonant circuits with resonance frequencies (RF) in the mega hertz range are increasingly becoming electronic Article security used. The main area of application is Retail trade. They are usually in the form of Tags and labels provided and machine or manually connected to the items to be backed up. In However, so-called source integration is becoming increasingly common to use, i.e. the securing element is already during the manufacturing or packaging process in the Article or integrated into its packaging.

An RF security element is already known from EP 0 665 705 A2 known that consists of two conductive, spiral turns (spirals). The two Spirals are separated by a dielectric layer separated and arranged so that they are at least partially overlap.

Such resonance frequency fuse elements are highly flexible. Since they are also very thin and flat, they can be easily printed with the desired imprint in printers. This imprint either serves the customer information or it is machine-readable information, preferably a barcode.
Barcodes are a cost-effective solution when it comes to providing machine-readable information. However, it is disadvantageous that a barcode is always brought in the immediate vicinity of the barcode reader based on optical principles in order to be able to be identified. Furthermore, the barcode reader can only decrypt the information if the barcode is freely accessible, i.e. not covered. The use of a source-integrated security element with a barcode will therefore only make sense - if at all - in exceptional cases.

The invention is based, an inexpensive task universal securing element and a method to propose for its manufacture.

The task is related to the universal securing element solved in that at least one more electromagnetic resonant circuit is provided, the specific, encoded information about the item includes. This encoded information is about a Remote query available and 'readable'. Remote inquiry takes place e.g. by means of a broadband query field that the Resonance frequencies in the universal fuse element contained resonant circuits. It is easy to see that the storage capacity of the universal securing elements on the number of additional resonant circuits is determined.

When using the securing element according to the invention In addition to the backup effect, reading the data in the Resonant resonant circuits stored information about relatively large distances possible. Because the information store designed as flexible resonant circuits are, the universal according to the invention Elements continue to be easily in labels or Integrate goods tags and in the usual way with printed information. Beyond pose the universal elements according to the invention inexpensive solution.

According to an advantageous development of the invention universal securing element is provided that the resonance frequency of the at least one further electromagnetic Resonant circuit outside of Resonance frequency of the resonant circuit for the electronic article surveillance. The resonance frequency of the resonant circuit for the electronic Article surveillance is standardized and lies for one Variety of surveillance systems at 8.2 MHz.

A favorable embodiment of the invention universal securing element is that a Resonant circuit made of two winding conductor tracks composed, at least partially overlapping are arranged on both sides of a dielectric layer.

According to an advantageous development of the invention universal securing element is proposed that the resonant circuit or resonant circuits, which serve to identify the articles in the Interior of the resonant circuit for electronic Article security lie, the interior of the inner track of the resonant circuit for the electronic article surveillance is limited. This Arrangement is very space-saving and makes it possible to do that Previously usual dimensions of the fuse elements for the maintain electronic article surveillance.

In order to increase the storage capacity of the invention universal securing element is proposed that a Element that has essentially the same dimensions as the universal security element, with information-bearing Resonance resonant circuits is equipped. This additional element comes with the universal element connected, e.g. it is glued to the back.

With regard to the method, the task becomes solved that on a carrier at least one more electromagnetic resonant circuit is applied, the specific, encoded information about the item includes.

According to an advantageous development of the invention The procedure is essentially that identical resonant circuits for the identification of Articles are used, the resonant circuits subsequently encoded with the specific information will.

Possible configurations for the subsequent coding of the Resonant circuits are based on a change in characteristic properties of the resonant circuits. These characteristic properties are: the resonance frequency RF or the capacitance K and the inductance L, which directly determine the resonance frequency Resonance amplitude A (RF) and / or the quality Q of the Resonant circuit. One or more of these sizes Resonant circuits for the identification of articles are determined by physical action in a defined manner and changed way.

One possibility for coding the resonant resonant circuits provides that selected resonant resonant circuits are short-circuited. The short circuit occurs between opposite conductor tracks through the dielectric layer. The methods that can be used to generate the short circuit are identical to the methods that have already become known in connection with the deactivation of resonant circuits for securing articles. A common method is to pierce the resonant circuit at a selected point with a needle-shaped, possibly heated pin. It is also possible to bring opposing conductor tracks into contact with one another by applying pressure and / or heat. A short circuit can also be achieved in that an arc discharge between two opposite conductive areas of the resonant circuit is achieved by applying a correspondingly strong electric field.
The electric field for generating the short circuit is either provided via contact electrodes, or it is generated without contact by applying a sufficiently strong energy pulse in the region of its resonance frequency to the selected resonant circuit. As a result of the bottom discharge, conductive metal of the conductor tracks diffuses into the dielectric layer, so that a permanently conductive connection is created between the coils. Such a deactivation method is also described in EP 0 181 327 A2.

According to an advantageous development of the invention It is proposed that the Resonant circuits to identify the articles be encoded by the length of the traces of the Resonance resonant circuits is reduced or enlarged. A simple method of reducing the length of the Conductor tracks provides that of the one to be encoded Resonant circuit part (open circuit) with a cutting device is separated.

According to an alternative solution, the Conductor of the resonant circuit to be coded one Melt connection introduced. This melts as a result of Temperature increase as soon as the current that flows through it exceeds a predetermined value. Again, the Current in the resonant circuit through electrode contact or contactless in the manner described above respectively.

An alternative method for coding the resonant circuits provides that the resonant circuits to Identification of the items to be encoded by being selective open resonant circuits (at least one turn) to the Resonant circuits are added. This will make the Changed resonant frequency of the resonant circuits. Regarding the connection of the additional turn with the offer selected resonant circuit to be encoded there are several possibilities: the turn can be in series or added in parallel. In addition, it is possible to add the turn in series, with the additional turn however in the opposite direction is wound like the turns of the resonant circuit. By means of these three possible embodiments, at least an additional turn to a resonant circuit add a variety of different Create resonance frequencies.

Another way to change the physical Properties consists in a change in the capacity of the Resonant circuits. This will result in an increase in capacity achieved that the area in which the by the dielectric layer separate conductor tracks of the two Coils overlap, is increased.

According to an advantageous development of the invention The resonance frequency is thereby changed that two separate, at least partially overlapping coils shorted to one will. The point at which the short circuit occurs is determined subsequently the resulting resonance frequency of the coded resonant circuit.

According to an advantageous development of the method according to the invention, the amplitude of the resonant circuit is changed in a defined manner for the purpose of coding. This is advantageously done, for example, by connecting the resonant circuit to be coded to a conductor track of the resonant circuit for article security. The latter then takes on the function of an antenna for the resonant circuit to be coded.
In the event that there are at least two resonant circuits for identifying articles, these can also be connected to one another; one resonant circuit then serves as an antenna for the other.
A third possibility provides that the resonant circuit to be coded is connected to a turn which acts only as an antenna and the length of which can also be selected such that the amplitude of the resonant frequency is changed in the desired manner.

A deliberate change in the physical quality Q of the resonant circuit can, for example, by means of following method can be achieved: short circuits generated between two opposite conductor tracks. There these shorts typically have a higher resistance than the conductive traces have, the goodness of the resonant circuit to be encoded is reduced. So the decisive factor for the change in quality is Change in the resistance of the resonant circuit. This Change can also be achieved as follows: Since the Resistance is inversely proportional to the width of the trace it is sufficient to take appropriate measures to reduce the width to change.

Fig. 1: eine Draufsicht auf eine Ausführungsform des erfindungsgemäßen Sicherungselements,

Fig. 2: eine Draufsicht auf eine Anordnung von Resonanzschwingkreisen zur Identifizierung von Artikeln,

Fig. 3: das Frequenzspektrum eines Resonanzschwingkreises,

Fig. 4a: eine schematische Darstellung einer ersten Alternative zum Kurzschließen eines Resonanzschwingkreises,

Fig. 4b: eine schematische Darstellung einer zweiten Alternative zum Kurzschließen eines Resonanzschwingkreises,

Fig. 4c: eine schematische Darstellung einer dritten Alternative zum Kurzschließen eines Resonanzschwingkreises,

Fig. 4d: eine schematische Darstellung einer ersten Alternative zum Verändern der Resonanzfrequenz eines Resonanzschwingkreises,

Fig. 4e: eine schematische Darstellung einer zweiten Alternative zum Verändern der Resonanzfrequenz eines Resonanzschwingkreises,

Fig. 5a: eine schematische Darstellung einer speziellen Ausgestaltung des erfindungsgemäßen universellen Sicherungselements, bei dem eine Leiterbahn seriell angefügt ist,

Fig. 5b: eine schematische Darstellung einer speziellen Ausgestaltung des erfindungsgemäßen universellen Sicherungselements, bei dem eine Leiterbahn parallel angefügt ist,

Fig. 5c: eine schematische Darstellung einer speziellen Ausgestaltung des erfindungsgemäßen universellen Sicherungselements, bei dem eine in entgegengesetzte Richtung gewickelte Windung an den Resonanzschwingkreis angefügt ist,

Fig. 6: eine schematische Darstellung einer speziellen Ausgestaltung des erfindungsgemäßen universellen Sicherungselements mit modifizierter Kapazität,

Fig. 7: eine schematische Darstellung einer zweiten speziellen Ausgestaltung des erfindungsgemäßen universellen Sicherungselements mit modifizierter Amplitude und

Fig. 8: eine schematische Darstellung einer speziellen Ausgestaltung des erfindungsgemäßen universellen Sicherungselements mit modifizierter Güte Q.

The invention is explained in more detail with reference to the following figures. It shows:

1: a plan view of an embodiment of the securing element according to the invention,

2 shows a plan view of an arrangement of resonant resonant circuits for identifying articles,

3: the frequency spectrum of a resonant circuit,

4a: a schematic representation of a first alternative for short-circuiting a resonant circuit,

4b: a schematic representation of a second alternative for short-circuiting a resonant circuit,

4c: a schematic representation of a third alternative for short-circuiting a resonant circuit,

4d: a schematic representation of a first alternative for changing the resonance frequency of a resonant circuit,

4e: a schematic representation of a second alternative for changing the resonance frequency of a resonant circuit,

5a: a schematic representation of a special embodiment of the universal securing element according to the invention, in which a conductor track is serially attached,

5b: a schematic representation of a special embodiment of the universal securing element according to the invention, in which a conductor track is attached in parallel,

5c: a schematic representation of a special embodiment of the universal securing element according to the invention, in which a turn wound in the opposite direction is attached to the resonant circuit,

6: a schematic representation of a special embodiment of the universal securing element according to the invention with modified capacity,

7: a schematic representation of a second special embodiment of the universal securing element according to the invention with modified amplitude and

8: a schematic representation of a special embodiment of the universal securing element according to the invention with modified quality Q.

Fig. 1 shows a plan view of an embodiment of the universal securing element according to the invention 1. It consists of a resonant circuit 2, which in Query field of an electronic article surveillance for Emission of a characteristic signal is excited and subsequently triggers an alarm. The resonant circuit 2 is arranged in the outer region of the carrier 14 and encloses two further resonant circuits 3, the identification of appropriately secured articles to serve.

2 is a top view of an arrangement of Resonant circuits 3 for the identification of articles to see. This arrangement is an addition to one universal element 1 according to the invention is intended and used to increase the storage capacity many times over.

Fig. 3 shows the typical frequency spectrum of a resonant circuit 2; 3. It is characterized in that the Amplitude A (F) and thus the intensity of the signal pronounced maximum (peak) in the area around the resonance frequency (RF) owns. The quality of a resonant circuit 2; 3 is defined as the quotient of the resonance frequency RF and 3 dB bandwidth.

As already explained above, the physical properties of the resonant resonant circuits are changed in a defined manner for the purpose of coding the resonant resonant circuits to identify goods. The following figures schematically show various options for changing the individual parameters of resonant circuits. 4a to 4e show various possibilities of how a resonant circuit 3 is permanently short-circuited (FIG. 4a to 4c) and how the circuit can be interrupted.
The short circuit - shown in FIGS. 4a to 4c - takes place through the dielectric layer 13. As can be seen in FIG. 4 a, the resonant circuit 3 is pierced in at least one area of opposite conductor tracks 4, 5 by means of a needle-shaped pin 6. An alternative provides (Fig. 4b) that the upper conductor track 4 is pressed against the lower conductor track 5 by means of a specially shaped pressing tool 7. In order to achieve complete removal of the dielectric layer 13, the pressing tool 7 is additionally heated.

Apart from these mechanical methods, a short circuit can occur also - as indicated in Fig. 4c - by means of a electrical arc discharge through the dielectric layer 13 done through. A is required for this correspondingly strong energy impulse in the area of Resonance frequency of the resonant circuit. This Energy pulse can either be by means of contact electrodes be provided, or it is provided by a transmitter in the form of electromagnetic radiation emitted. Diffuse as a result of the arc discharge Particle of the conductive material - usually will aluminum is used in the dielectric layer and carbonate them.

Another possibility for deactivating and thus changing the information content of a resonant circuit is to interrupt the conductor tracks 4, 5. According to one embodiment, this is done mechanically - see FIG. 4d - by means of a cutting device 10. According to an alternative solution, a fusible link (fuse) is built into the conductor track 4, 5, which melts and evaporates when the current flow is sufficiently high due to the heating.
5a shows a schematic illustration of a special embodiment of the element according to the invention, in which a conductor track is attached in series. In FIG. 5b, the conductor track is added in parallel, while FIG. 5c describes the case in which a conductor track which is in the opposite direction to the conductor track 4; 5 is wound, is added serially. With these configurations, the resonance frequency of the resonance resonant circuits 3 can be changed in a defined manner.

A change in the resonant frequency of a resonant circuit 3 can also be achieved in that the Capacity K of the resonant circuit is increased or decreased. In Fig. 6 the case is shown that the capacitance K increased by adding a conductor track section 16 is, the conductor track section 16 is placed so that he an area of the lower conductor track 4 or the upper Conductor 5 of the resonant circuit 3 is opposite. Trace section 16 and trace 4; 5 are about one Junction 12 connected to each other.

Fig. 7 shows a schematic representation of a Resonant circuit 3, in which the resonance frequency is changed in that two overlapping coils 4; 5 by short circuit at one of the connection points 12 in a Coil are transformed. The resulting resonance frequency depends on the location of the connection point 12.

In Fig. 8, a solution is shown schematically, via the specifically influences the amplitude A (RF) of the resonance frequency can be. In addition to the coil 4; 5 of Resonant circuit 3 is an additional turn 17th provided that once they are at the junction 12 with the coil 4; 5 is connected as an antenna for this coil 4; 5 acts. Depending on the design of the additional turn 17 the amplitude signal S changed in a defined manner.

In the figures and the associated description of the figures is always referred to resonant circuits 3 with two coils 4, 5 on either side of a dielectric Layer - at least partially overlapping - are arranged. Of course, the invention is not based on this Design limited, but it is also without further applicable to resonant circuits which are based on a Side of the dielectric layer 13, a coil and a Capacitor plate and on the other side e.g. just one Have capacitor plate.

Reference list

1

Securing element

2nd

Resonant circuit (EAS)

3rd

Resonant circuit (ID)

4th

lower coil

5

upper coil

6

needle-shaped pen

7

Press tool

8th

electrically conductive connection

9

Conductor track

10th

Cutting tool

11

Fuse link

12th

Liaison

13

dielectric layer

14

carrier

15

Resonant circuit

16

Conductor section

17th

additional winding or additional coil

RF

Resonance frequency

Q

quality

A (RF)

Signal amplitude of the resonance frequency

C.

capacity

L

Inductance

Claims (14)

Universal element for securing articles against theft, which has at least one electromagnetic resonant circuit which is excited in the interrogation field of an article monitoring device to emit a characteristic signal which subsequently triggers an alarm,
characterized,
that at least one further electromagnetic resonant circuit (3) is provided, which contains specific, coded information about the article. Universal securing element according to claim 1,
characterized,
that the resonance frequency (RF) of the at least one further electromagnetic resonance circuit (3) lies outside the resonance frequency (RF) of the resonance circuit (2) for electronic article surveillance. Universal securing element according to claim 1 or 2,
characterized,
that a resonant circuit (2; 3) is composed of two winding conductor tracks (9) which are at least partially overlapping on both sides of a dielectric layer (13). Universal securing element according to claim 1, 2 or 3,
characterized,
that the resonant circuit (3) or the resonant circuits (3), which serve to identify the article, are in the interior of the resonant circuit (2) for electronic article surveillance, the inner region through the inner conductor tracks (9) of the resonant circuit (2) for electronic Article security is limited. Method for producing a universal security element for securing articles against theft, which has at least one electromagnetic resonant circuit which is arranged on a carrier and is excited in the query field of an article monitoring device to emit a characteristic signal which subsequently triggers an alarm,
characterized,
that at least one further electromagnetic resonant circuit (3) is applied to the carrier (14) and contains specific, coded information about the article. Method according to claim 5,
characterized,
that essentially identical resonant circuits (3) are used to identify articles, the resonant circuits (3) being subsequently encoded with the specific information. Method according to claim 6 or 7,
characterized by
that the characteristic properties (resonance frequency RF or capacitance K and inductance L; resonance amplitude A (RF); quality Q) of the resonant oscillating circuits (3) for identifying articles are changed in a defined manner by physical action on the resonant oscillating circuits (3). Method according to claim 7,
characterized,
that the resonant circuits (3) are coded to identify the article, in the selected resonant circuits (3) are short-circuited. Method according to claim 7,
characterized,
that the resonant circuits (3) are coded to identify the articles by interrupting the current flow through the conductor tracks (9). Method according to claim 7,
characterized,
that the resonant circuits (3) are coded to identify the articles by increasing or reducing the length of the conductor tracks (9) of the resonant circuits (3). Method according to claim 7,
characterized,
that the resonant circuits (3) are coded to identify the articles by selectively adding open resonant circuits (15) to the resonant circuits (3). Method according to claim 7,
characterized,
that the resonant circuits (3) are coded to identify the articles by connecting an additional conductor track section (16) to a coil (4; 5) which is placed so that it is opposite the other coil (5; 4). Method according to claim 7,
characterized,
that two at least partially overlapping coils (4, 5) are short-circuited so that they subsequently form a coil with a changed resonance frequency. Method according to claim 7,
characterized,
that a resonant circuit (3) is connected to a coil (2; 3; 17), the coil (2; 3; 17) serving as an antenna for the resonant circuit (3).

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