DE2716062A1 - Anti-theft detector for stores - has two inductive loops operated in anti-phase to produce dead zone whose position is varied by de-tuning - Google Patents

Abstract

The anti-shoplifting alarm for stores detects magnetic markers and consists of two oscillatory circuits, one either side of a gangway or exit, which comprise open coils (2, 2') and parallel-connected capacitors (4, 4'). The resonant frequency of the circuits is in the region of 10 kH. The circuits are energised via switches (6, 6') operated by means of a control unit (8). The switches are operated at 2, 5 kH. Since the coils are excited in opposing phase, the lines of force produce a pattern with a dead zone in the centre line between the coils. In each circuit are additional determining elements (10) which can be switched in and out of circuit so that the blind spot between the coils is continuously shifted.

Description

Procedure and arrangement for indicating the presence

of objects in a surveillance area, especially for connection of shoplifting The present invention relates to a method and order for displaying the presence of objects in a surveillance area, in particular to prevent shoplifting items in the surveillance area by means of two resonant circuits with open air coils that run through at a distance of several periods given impulses stimulated to vibrations, magnetic alternating fields generated and assess marking elements attached to the objects to be monitored, due to the action of the alternating fields at least one to the frequency of the alternating fields generate and radiate different frequencies.

A procedure and an arrangement of this kind are from DT-OS 21 60 04E known.

This known method and arrangement work with Schwillg circles with open air coils to generate an alternating query field in the monitored area, i.e. the exit of a shop for example. The excitation of the vibrations is done by impulses. The goods to be monitored are marked with a marking element in the form of a soft magnetic, highly periodic @@@ an @@@@ zlich hard magnetic @@ reif @ lying in parallel. With the also not sell @ a @@ @d both parts still unmagnetized, the marking @ @@@@@ d not yet sold Goods therefore generate a distortion in the passage due to its non-linear characteristic the temporal course of the field, which in a special @ e @@ ice coil induction voltages produce. These are fed to an electronic evaluation unit and finally solve an alarm or the like.

Because of the arbitrary position and direction of the marking elements when passing through the passage it can happen that if the position of the Marking element in relation to the field direction of the distortion effect so small lt it doesnt lead to an alert. This is especially to be expected when the two coils are excited in phase, so that a relatively homogeneous A magnetic field is created, the field lines of which are perpendicular to the coil planes. Cheaper are the conditions when the two coils are excited in phase opposition. In this Case there is a strong displacement of the field lines inside the passage, causing them to have different directions at different points in the passage to have. The realization probability is. thereby greatly increased. Still surrendered there are still blind spots where there is no evidence, even with an out-of-phase supply he follows. In order to avoid this too, it is desirable to reduce the field spread of the The query alternation field has to be changed continuously in order to cover all directions.

This is achieved in the known arrangement in that one of the two coil circuits periodically experiences a change in polarity of the excitation pulses.

Because of the high levels flowing in the oscillating circles during the oscillations Str; ine can excitation of one oscillating circuit with compared to the previous one Impulse oppositely polarized impulses only occur when the oscillations are largely subsided are to overload the required switches ve @@ eiden. However, this has the disadvantage that the measuring time during which a marker in the monitoring area can be determined in proportion can only be relatively short to the total time. Dei according to DT-OS 21 60 041 systems, the measurement time is only 25% of the time between polarity reversals of the excitation impulses because of the oscillation behavior of the oscillating circuits and the decay of the vibrations, the minimum amplitude of the field required for measurement is only achieved for this tent space.

Another disadvantage of the known method and arrangement is in that at a natural frequency of the oscillating circuits in the amount of 10 kHz and one maximum feasible alternating frequency with polarity reversal of the excitation pulses of 10 - 20 Hz an inhibition of pacemakers may occur if people who wear pacemakers, step through the surveillance area.

The object of the present invention is to provide a method and a Arrangement of the type mentioned to create which blind spots within the rotation practically completely grazes, without the disadvantages mentioned above the Umpolugsververfahren to have, and it allows a simpler structure to achieve a considerably longer measuring time while avoiding the influence at the same time of pacemakers.

According to the invention, this object is achieved by the characterizing features the claims solved.

Due to the periodic detuning of the oscillating circuits according to the invention, which are coupled to one another and thus vibrate and / or at the same frequency the amplitude modulation of the excitation pulses occurs a modulation of the magnetic Field between the two oscillating circles and thus a periodic shift of Magnetic field between the coils in the monitoring area, so that the so-called periodically relocate blind spots in the monitoring area and thus, if this is done with a sufficiently high frequency for one to look through the surveillance area there is no possibility of a non-magnetized marking element, which is characteristic of a non-paid product, undetected by the surveillance area bring through. However, it is not necessary to alternate the oscillating circuits to operate in phase and in phase opposition, so that the commutation switch fiir the impulse excitation of an oscillation circuit can be omitted and it as a result it is not necessary to wait for the oscillation to die out completely the polarity of the excitation pulses can be changed. It is thus special makes possible the modulation of the magnetic field according to the invention with mains frequency, i. 50 Hz so that the field strength is large enough for about 90% of the time is to be used as measuring time. Cardiac pacemakers are also against interference particularly insensitive due to the mains frequency, so that at this excitation frequency also given the greatest possible security against inhibition of a cardiac pacemaker iSt Further details and advantages of the invention emerge from the following list, Description given on the basis of an exemplary embodiment shown in the drawing and they show: FIG. 1 a schematic block diagram of the resonant circuits, FIG. 2 a schematic representation of the field lines with an indication of the displacement of the blind area due to the method according to the invention and the arrangement according to Fig. 1.

As you can see, there is a surveillance area on both sides 1, which can be the exit door of a self-service department store, for example, is an oscillating circuit arranged, consisting of open air-core coils 2, 2 'and capacitors 1, 4'. the Inductance of the air core coils 2, 2 'and the capacitance of the capacitors 4, 4' are chosen so that the oscillating circuits 2, 4 or 2 ', 4' have a natural frequency of approx kHz own.

The oscillating circuits 2, 4 or 2 ', 4' are constructed in such a way that they are as close as possible low losses @ e occur, so that the oscillating circuits 2, 4 or 2 ', 4' after a Excitation of the oscillation by a given impulse natural oscillations for a long time carry out.

The arrangement of the air-core coils 2, 2 'results in a coupling of the two oscillating circuits 2, 4 or 2 ', 4' so that they oscillate at the same frequency, even if between the natural frequency of the two oscillating circuits 2, 4 or 2 ', 4' minor, due to the inevitable differences in the inductance of the air-core coils 2, 2 'and the capacitances of the capacitors 4, 4' are conditional differences.

The excitation of the oscillations in the oscillating circuits 2, 4 or

2 ', 4' takes place by periodic streaking of the switches 6, 6 'whereby a voltage source labeled plus is applied to the oscillating circuits 2, 4 for a short time or 2 ', 4' acts and stimulates them to vibrate in a pulsed manner. The switches 6, 6 ' are periodically at a distance of the several oscillation periods of the oscillating circuit c 2, 4 or 2 ', 4' is actuated by a control device 8. Preferably done the actuation of the switches 6, 6 'with a frequency of cn. 2.5 kIIz. Here must Of course, it must be guaranteed that the excitation pulse is always in the same direction given with an instantaneous oscillation on the oscillating circuits 2, 4 or 2 ', 4' otherwise no new oscillation excitation with the desired amplitude and phase can be reached.

Circuit arrangements that enable the closing of the switches G, 6 ' with the correct phase position, are known per se and are related not described with the present invention.

Since the resonant circuits 2, 4 and 2 ', 4' are excited in phase opposition, results when excited with the same amplitude and with the same natural frequency of the two Oscillating circuits 2, 4; 2 ', 4' a field line image according to the selected lines in Fig. 2. As can be seen, are generated by the air-core coils 2, 2 ' Field lines 20 apart approximately in the middle between the two air coils 2, 2 ' pushed, so that here indicated by the dash-dotted line 18 blind Area arises in which a marking element cannot be detected.

To this disadvantage with periodic, synchronous, impulsive excitation To avoid the two oscillation crises 2, 4 or 2 ', 4' is according to the invention provided the blind steeple 18 by changing the vibration behavior of the Oscillating circuits 2, 4; 2 ', 4' to wiggle back and forth so that the blind can move Point 18 is always at a different point between the air-core coils 2, 2 ' and thus the possibility is excluded that a marking element by a blind area 18 in monitoring area 1 through this monitoring area 1 slips through undetected. In Fig. 2 is a shift of the blind area 18 ', the associated field lines 20' are indicated by dashed lines.

The relocation of the blind spots 18, 18 'in the surveillance area l can be achieved in a number of ways. In the example shown, the Vibration amplitudes or

Frequencies of the oscillating circuits 2, 4; 2 ', 4' changing switching elements 10, 10 'provided, which by means of the switches 12, 12' optionally to the oscillating circuit 2, 4 or 2 ', 4' added or

can be switched off. This switching on and off takes place by means of a control device 14 and is preferably synchronized with the impulse application the oscillating circuits 2, 4; 2 ', 4' performed @n in @ @@@ en trap the control units 9, 14 can become a @@ in @@@ n, indicated by dashed lines 16 can be summarized. In the example shown, the switching elements 10, 10 'connected in parallel to the air-core coils 2, 2', even you can also parallel to the capacitors 4, 4 'or in series with the air-core coils 2, 2' resp.

the capacitors 4, 4 'are switched. The switching elements 10, 10 'can be designed as resistors. In this case the amplitudes the oscillations in the oscillating circuits 2, 4 or 2 ', 4' changed. The switching elements 10, 10 'can, however, also consist of capacitors or inductors. In this Case, the natural frequencies of the resonant circuits 2, 4 or 2 ', 4' are accordingly changes.

According to a preferred embodiment, the switching elements bribe 10, 10 'of capacitors, which correspond to the drawing in Fig. 1 are switched into the oscillating circuits 2, 4 or 2 ', 4' and are considerably smaller Have capacitance than the capacitors 4, 4 '. The circuit arrangement shown has the advantage that the switches 12, 12 'only have to switch currents which on the one hand by the ratio of the capacitances of the capacitors 10, 10 'to the capacitors Ii, 4 'and on the other hand to the ratio of the number of turns of the coil 2, 2' nn the Tap are smaller than the currents flowing through the capacitors 4, 4 '. In addition, the capacitances of the capacitors 10, 10 'can be relatively small be chosen because a change in the natural frequency of the coupled Oscillating circuits 2, 4; 2 ', 4' only required in the order of about 30-90 Hz is. If now the switch 12 is closed and the switch 12 'remains open, there is a change in the natural frequency of the resonant circuit 2, 4. Since the Air-core coils 2, 2 'are coupled to one another, this also results in a change of the coil current of the coil 2 compared to the current through the coil 2 '. Through the In other words, detuning of one oscillating circuit 2, 4 or 2 ', 4' results another energy distribution @ @ in the @ @system on the two oscillating circuits 2, 4 or 2 ', 4'. @ af @ r @@ d of this effect there is a change in the course of the field lines @ a, which is shown in phantom in FIG. Wi @ @ now switch 12 is open, this results in the field lines shown with @ u @@ z @ @ ne @ dashes in the Fig. 2, while when the switch 12 'is closed, the blind spot in the vicinity of the Air core coil 2 'wanders. By periodically switching on and off The condensers 10, 10 'can thus cause the bli @ to move back and forth Stei @ en 18, 18 'can be reached in monitoring area 1, so that it is impossible a marking element, without there being a signal a @, through the monitoring area 1 to bring through.

Due to the transient behavior of the oscillating circuits 2, 4; 2 ', 4' takes place the blind spots 18, 18 'do not move abruptly, but continuously, however, this wandering movement can also be made easier and controlled by this the switching elements 10, 10 ', i.e., if they are resistors, inductances or capacitors are formed, are designed to be changeable and migrate the blind spots 18, 18 'by continuously changing the switching elements 10, 10 'is effected Since the actuation of the switches 12, 12' or the continuous Change of the variable switching elements 10, 10 'with a frequency of about 50 Hz is achieved as an additional, very significant advantage that the Switching impulses cannot have any influence on pacemakers and except for them Can bring tact when people who wear pacemakers are in the monitoring area l are located. The usual pacemakers are designed so that they against Interference from the mains frequency, which is 50 Hz, is particularly insensitive are.

It should also be noted that there is a wandering of the blind spots 18, 18 ' also by changing the amplitude of the excitation pulses @@@ icht can be. In this @olle are the switching - @@@@@@ 10, 10 'and the associated Switches 12, 12 'with and control device 14 are not required. Rather, it is sufficient not always to operate the switches 6, 6 'at the same time by means of the control @@@ tes 9, but alternately in each case ei @ switch 6, then both switches 6, 6 'and then to operate a switch 6 '. If both switches 6, 6 'are simultaneously @@@ gt, this results in the solid field line image as shown in FIG. 2. It is only a switch 6 'closed, the loop circuit 2, 4 is indeed due to the coupling at the same time with the Schwing @ eis 2 ', 4' excited to vibrations, but the amplitude is the Oscillations in the oscillating circuit 2, 4 lower than the amplitude of the oscillations in the oscillating circuit 2 ', 4', so that a shift of the field lines and thus the blind Point 18 'occurs according to the manner shown in dashed lines.

The structure of a marking element and the circuit arrangement for receiving the marking element located in the monitoring area 1 emitted signals are not in connection with the present invention described individually, as they are known from DT-OS 21 60 041.

Claims (14)

P a t e n t a n s p r ü c h e 1. Procedure @@@@ sige of being in front of @ @ from against @@@ who in a Ü @@@ ch @@@@@ choose themselves, in @ special to connect @ aden @@ chs @, in the overnight area by means of two oscillating @@ eise m. @ open air coils, the given impulses at intervals of @ @reren periods to oscillations ange @@ gt magnetic alternating fields are generated and on the objects to be monitored Marking elements are attached as a result of the action of the alternating fields generate at least one frequency that is different from the frequencies of the alternating fields and emit that the oscillating circuits do not appear are coupled with each other and are always excited in phase opposition and that in at least one of the resonant circuits, the natural frequency and / or the amplitude changing and switching elements causing detuning of the oscillating circuit periodically and switched off. 2. The method according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that in each of the resonant circuits the natural frequency and / or the amplitude changing switching elements alternately periodically and with temporal spacing added and be switched off. 3. The method according to claim 1 or 2, d a d u r c h g e k e n n z e i c h n e t that the switching on and off of the switching elements synchronously with the impulses the oscillating circuits takes place. 4. The method according to the preamble of claim 1, d a d u r c h g e k e n n n n n e i c h n e t that the resonant circuits are coupled to each other and are always excited in phase opposition and that the amplitudes of the excitation pulses for at least a resonant circuit can be changed periodically. 5. The method according to claim 4, d a d u r c h g e k e n n -z e 1 c h n e t that the amplitudes of the excitation pulses alternate for each resonant circuit can be changed periodically and with a time interval. 6. Circuit arrangement for performing the method according to a or more of claims 1 to g e k e n n -z e i c h n e t d u r c h at least an oscillating circuit (2, 4 or 2 ', 4') associated with its natural frequency and / or Vibration amplitude changing switching elements (10, 10 ') and one periodically Operable switch (12, 12 ') for switching the switching element (s) on and off (10 or 10 ') in / into the oscillating circuit (s) (2, 4 or 2', 4 '). 7. Circuit arrangement according to claim 6, g e k e n n -z e i c h n e Switching elements (10, 10 ') designed as capacitors are used. 8. Circuit arrangement according to claim 6, g o k e n n -z e i c h n e Switching elements (10, 10 ') designed as inductors are d u r c h. 9. Circuit arrangement according to claim 6, g e k e n n -z e i c h n e t d u r c h switching element @ (10, 10 ') designed as resistors. 10. Circuit arrangement according to claim 7, 8 or 9, d a d u r c g e It is not possible to indicate that the switching elements (10, 10 ') have an effect are designed to be variable and the switch (10, 12 ') the change of the switching elements (10, 10 ') causes. 11. Circuit arrangement according to claim 10, d a d u r c h g e k e n n z e i c h n e t that for each resonant circuit (2, 4 or 2 ', 4') variable switching elements (10, 10 ') are provided and that their action quantities counteract by the switch (12, 12 ') are changeable. 12. Circuit arrangement according to one or more of claims 6 bir; i1, d a d u r c h g e k e n n -z c i c h n c t that the switching elements (10, 10 ') connected in series with the elements (2, 4; 2', 4 ') of the resonant circuit (s) are. 13. Circuit arrangement according to one or more of claims 6 to 11, that the switching elements (10, 10 ') connected in parallel to the elements (2, 4; 2 ', 4') of the resonant circuit (s) are. 14. Circuit arrangement according to one or more of claims G to 13, d a d u r c h g e k c n n -z e i c h n c t that the switch (s) (12, 12 ') for the switching on and off of the switching elements (10, 10 ') and the switches (6, 6') for adding and disconnecting the impulses to the oscillating circuits (2, 4; 2 ', 4') can be switched by a common control device (16).