DE19503992A1 - Security label for theft prevention - Google Patents

Abstract

The security label, for safeguarding an article against theft, comprises at least one carrier layer and an electronically detectable security element, which comprises a quartz oscillator (1), which specifically has a given resonance frequency (fres). The specified resonance frequency (fres) is designed to lie in the MHz-range of frequencies. At least one additional carrier layer is provided, with the quartz oscillator (1) arranged between the two carrier layers.

Description

The invention relates to a label for securing a Anti-theft article, with the label at least a support layer and one in a surveillance zone electronically detectable security element.

Labels with securing elements are becoming increasingly popular used for article security in department stores. Both Fuse elements are mostly soft magnetic materials of high permeability and low Coercive force caused by an external alternating magnetic field stimulated to emit a characteristic signal or resonance tags that make up a resonant circuit have a capacitive and an inductive element and through a correspondingly coordinated query field within in a surveillance zone. While in first case the receipt of the remitted characteristic Signals is a clear sign that an article in transported through the surveillance zone without permission in the second case, the strong energy absorption is over the query field in the area of the resonance frequency as an indication of the presence of one provided with a securing element Article in the surveillance zone. As soon as one Detector device in the surveillance zone makes up a characteristic signal of a fuse element, it causes an optical and / or an acoustic Alarm.  

US 3,967,161 is already electronic detectable security tag with resonant circuit known. The resonant circuit consists of at least one inductive and one capacitive element in Parallel connection. Starting material for what has become known Security label is a dielectric carrier material. On at least one side of the dielectric material is one winding conductor track applied that the function of the inductive element takes over. The capacitive element is formed by conductive coatings that are on both Opposite sides of the dielectric layer. The manufacture of these well-known resonance labels is pretty complex: the inductive and capacitive elements must be in separate process steps mechanically cut out or are manufactured by means of a chemical process and then applied to the dielectric carrier layer will. To ensure a high quality of the resonant circuits achieve, are also the highest demands on the Manufacturing process and the materials used put.

The invention is based on the object Propose security label that in a simple way can be produced.

The problem is solved in that the electronically detectable security element by one Quartz crystal acts.

Quartz crystals are piezoelectric crystals with two Electrodes. Their effect is based on the inverse piezoelectric effect: is on opposite surfaces certain crystals (preferably quartz SiO₂ or tourmaline) an AC voltage is applied, this solves mechanical Vibrations out of their maximum at the natural frequency of the Quartz crystal or reached at its resonance frequency.  

The resonance frequency or the natural frequency of quartz crystals is relatively high; it can be determined by the geometrical Specify dimensions of the crystal and lies in an area from a few kHz up to approx. 200 MHz. A precise comparison of the Resonance frequency is through in the manufacturing process Fine grinding and with a finished quartz crystal by one capacitor connected in series possible.

Quartz crystals have - as already mentioned - the advantage that the resonance signal is limited to a small band range or, in other words, quartz crystals behave electrical like high quality resonant circuits. In addition point Quartz crystals have a very high frequency constancy, for example, they are highly sensitive to temperature changes independent in their environment. This high quality of Resonance properties of the quartz crystals can be achieved with the usual security elements only with considerable additional effort to reach. Due to the usual manufacturing tolerances or by z. B. temperature fluctuations in the environment must here the frequency band range of the query field is selected broadly will.

An increased bandwidth of the query field has an effect disadvantageous to the functional reliability of the Detector devices for the electronic Fuse elements out because energy absorption from the Interrogation field in the monitored frequency also banded by others Objects as caused only by the resonance labels can be. The wider the frequency band has to be selected, the higher the risk that a Alarm (a false alarm) also by objects other than the actual fuse elements is triggered. At Quartz crystals that are almost independent of the Environmental conditions a sharp, pronounced peak at the show respective resonance frequency is the danger of a False alarms, however, are significantly reduced.

The quartz crystal is preferably dimensioned such that it has a resonance frequency which is in the MHz range.  

This advantageous embodiment is the inventive one Securing element as well as that from the prior art known resonance frequency (RF) labels from the commercially available detector devices are detectable.

According to an advantageous development of the invention It is provided that at least one additional label Carrier layer is provided and that the quartz crystal between the two carrier layers is arranged. Through this Training is the quartz crystal against external mechanical Impacts additionally protected.

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

Fig. 1 is an equivalent circuit diagram of a quartz crystal, which is used according to the invention as an electronically detectable fuse element, and

Fig. 2 is a circuit diagram which illustrates the adjustment of the resonance frequency of a quartz crystal by means of a capacitor.

Fig. 1 shows a quartz oscillator 1 and an equivalent circuit diagram of the quartz oscillator 1, which is according to the invention used as a security element for securing articles in department stores. The equivalent circuit diagram approximately shows the quartz crystal 1 with the connections A, B, the individual electrical elements embodying the following functions:
L: the dynamic inductance that models the oscillating mass of the quartz,
C _r : the dynamic capacity that models the elasticity of the vibrating body,
R _r : the dynamic loss resistance as a result of various friction losses,
C _p : the static parallel capacitance (between the two metal electrodes with quartz material as dielectric, carrier system).

FIG. 2 shows an adjustment of the resonance frequency of a quartz crystal 1 by means of an additional adjustable capacitor C _s . The capacitance of the capacitor C _s is much larger than the dynamic capacitance C _r , which models the elasticity of the vibrating body. The capacitor C _s is connected in series with the quartz crystal 1 and allows a so-called "pulling" of the frequency, the frequency change Δf / f _{res being} approximately 0.5 _* (C _r / C _s ).

Claims (3)

1. Label for securing an article against theft, consisting of at least one carrier layer and an electronically detectable security element, characterized in that the electronically detectable security element is a quartz crystal ( 1 ). 2. Label according to claim 1, characterized in that the quartz crystal ( 1 ) has a resonance frequency (f _res ) which is in the MHz range. 3. Label according to claim 1, characterized in that at least one further carrier layer is provided and that the quartz crystal ( 1 ) is arranged between the two carrier layers.