FR2583454A1 - Method and device making it possible to detect the opening and breaking of safes and armoured enclosures - Google Patents

Abstract

In order to make it possible to detect the opening of safes or strongboxes (or strongrooms), the volume of the safe (strongbox or strongroom) is made similar to atuned resonant cavity 19. Atuned resonant cavity is made similar to an antenna. By exerting (physical, electrical, magnetic or mechanical) stresses on a safe or by opening a safe, the resonant volume of the latter is changed, thus resulting in electromagnetic detection. Detection can be carried out by means of a wired connection 20 or by radio.

Description

The present invention relates to a method and to a device for detecting the opening of safes. Currently, detecting the opening of a safe requires the installation or provision of special sensors. Ex: vibration detector, infrared detector (heat), magnetic detection, shock detector and all other stress detectors (mechanical, electrical, magnetic, etc.). All these modes of detection of opening or breaking of safes offer possibilities of countermeasure or neutralization of the system. The present invention therefore aims to detect the opening of a chest or a set of safes without resorting to the installation of one or more stress sensors. The principle is as follows: it is considered that a chest (which whatever its shape) is a resonant metallic cavity. A safe is therefore assimilated to an antenna having its own resonance and its own impedance.

This resonant cavity, represented by the safe is also assimilated to an antenna sensitive to different parameters.

These parameters are as follows: a) if we heat part of the safe, using a blowtorch in order to fracture it, we will modify the resonance frequency of the safe as well as its impedance. b) if we try to open the safe with metallic objects, we will also modify the resonance frequency of it. c) if we open the door of a safe after breaking in, we also change the resonance frequency of the resonant cavity formed by the safe.

We note that, in the present invention, the safe reacts well like an antenna or a tuned resonant cavity.

We can therefore electromagnetically detune a safe (resonant cavity) by subjecting it to different constraints (physical, electrical, magnetic or chemical).

The safe (resonant cavity) can be connected to its electronic system like a transmit / receive antenna.

The safe (resonant cavity) can be monitored remotely (or through walls and walls) over the air.

Example of calculation to determine the resonance frequency of a cubic resonant cavity (or useful volume of a safe) of
I, 4I m side.

We have the following calculation method

Determination of the de-resonance frequency of this cubic safe, 1.4 m side

The resonant frequency of a cubic safe of 1.4 M side will be 300 Mhz. This is of course, a non-limiting example with regard to the various dimensions of the safes.

The invention will be better understood with the aid of the various plates appended to this patent.

FIG. I of plate I represents a conventional oscillating circuit constituted by a coil I and a capacitor 2, the output can be taken at 3.

Figure 2 of Plate I represents the physical evolution of a choke (or coil) and a capacitor in order to obtain a resonant cavity (or tuned oscillator). A choke is represented in 4, a capacitor is represented in 5. If we associate the choke 4 and the capacitor 5, we obtain an oscillator represented in 6. I1 now suffices to add a certain number of chokes 4 in order to obtain the assembly represented in 7. If we complete assembly 7 with an inductive extrapolation, we obtain a cube 8 (or resonant cavity).

FIG. 3 of plate I therefore represents a cubic resonant cavity 9.

FIG. 4 of plate I schematically represents a resonant cavity 10 (safe) in its armored structure.

Figure I of plate II represents a resonant cavity I3 connected like an antenna by a coaxial cable I4. The shielded structure is represented at 12. This constitutes a resonant cavity (antenna) connected by means of a cable.

Figure 2 of Plate II represents the second version possible by radio (propagation through the walls and the walls). The resonant cavity is shown in I5. (safe)
A transmitter 16 excites the antenna I7. The I7 antenna can also power the I8 receiver.

The single figure in Plate III represents a system for detecting the opening of a safe using a wired system. The safe (or resonant cavity) is shown in I9. This trunk is connected by means of a coaxial cable 20 to the transmitter 21. Part of the coaxial cable 20 is converted into a "Strip-line" track 22 on a printed circuit. A second printed and parallel track 23 acts as an inductive collector. The frequency of the transmitter is tuned to the resonance frequency of the safe (resonant cavity). If we impose constraints on the safe, or, if we open the safe door, we will modify the resonance frequency of the safe (as well as its impedance). Hence a return of standing waves detected by the diode of rectification 24 and amplified by circuit 25. The level of amplified standing waves is collected at 26.

The single figure in Plate IV represents a safe 27 (or resonant cavity) connected by means of a coaxial cable 28 to the transmitter 29, the latter being modulated / coded by the circuit 30.

(this in order to avoid nuisance alarms) The printed strip (line) 31 is connected to the standing wave detection circuit 32. The output of this T.O.S.

is connected to the input of a calibration circuit 33. The calibration level 33 is detected by the circuit 34. The detected level 34 'is connected to a modulation filter 35 (emission identification). A threshold control circuit 36 (comparator) armet for alarming, circuit 37.

The single figure in Plate V represents a derivative system for detecting the opening of a safe by radio. The advantage of this method makes it possible to detect the opening of a safe (resonant cavity) through the walls or the walls. This method does not require the installation of a connection cable with the safe. The safe (or resonant cavity) is represented oi 38. We place a transmitting / receiving antenna 39 beyond a wall (wall or partition) 40. It is therefore a detector of the opening of a safe 38 through a wall 40 without cable connection.

In coded modulator 41 connected to a low power transmitter 42 transmits the resonance frequency of the boot to the antenna 39.

The antenna 39 plays the dual role of transmission and reception, hence
The utility 'a circuit zancle 43 and a line to ret; r I feed the reception circuit 45. The output of the receiver 45 - t connected to the filter / decoder 46 (coded identification of the emission). The filtered level 46 is then detected by a circuit 47.

Circuits 48, 49, 50, 51 constitute the final electronic chain for alarming.

 The alarm threshold can be adjusted according to the number and the amount of objects deposited in the safe. It is obvious that a certain number of objects deposited in the safe (or resonant cavity) causes a selfic and capacitive effect and thus m easifies the resonant value of the safe.

sut all electronic systems will of course be linked to
the special mains / battery power supply in order to compensate for power cuts in the EDF network and eliminate breaks (or voluntary sections) in the power cables.

The single figure in Plate VI represents a set of safes to watch. This set of safes constitutes a set of resonant cavities (or a network of primary antennas)
The wired detection mode remains the same as for the wireless remote detection mode.

The detection of a multitude of safes will find its application in the banking field.

Claims (9)

 R ICATIONS  I. Method and device according to which a safe, a strong cabinet, a strong room constitute resonant electromagnetic volumes.  2. Method and device according to which one can give any dimensional shape to the resonant volume constituting the safe.  3. Method and device according to which a safe (or resonant cavity) is assimilated to a tuned antenna.  4. Method by which the safe is connected to the emission am olifier with a coaxial cable.  5. Method according to which the safe is connected to the receiver with a coaxial cable.  6. Method according to which the frequency of resonance of a safe is controlled over the air. (Transmission / reception)  7. Method according to which the carrier frequency of interrogation is modulated or coded in order to identify the resonant volume of the safe.  8. Process by which the resonant volume of a safe can be controlled over the air through walls, walls, buildings.  9. Method and device according to which, the resonant frequency of a safe (or resonant cavity) is modified by imposing physical constraints on it (mechanical, electrical, calorific, megnetic).  IO. Method and device according to which, the resonant frequency of a safe (or resonant cavity) is modified by forcing or opening its door (or its opening system).  II. Method according to which a large number of safes (banking systems) constitutes a network of primary antennas (or network of primary resonant cavities).  I2. Method and device according to which, the resonant frequency and the impedance of a safe (resonant volume) are modified by causing it to open.  I3. Process according to which a resonant cavity (safe) can be resonated on a frequency different from the incident frequency.