CZ1727U1 - Electronic safety device for external surveillance of objects - Google Patents

Description

Technical field.

The technical solution concerns an electronic security device for external guarding of an object, consisting of a sensing oscillator, which includes a capacitive sensor, a detector of frequency deviations of the sensing oscillator and an evaluation and signaling circuit.

BACKGROUND OF THE INVENTION.

In the field of devices for securing objects against intrusion, or for indicating or signaling an attempted intrusion into a guarded object, a number of constructional arrangements are used which utilize sensors and circuits falling within the field of electrical engineering, especially in the field of electronics.

One such group of devices are collectively referred to as capacitive devices that respond to a change in the dielectric constant in the guarded area. It is a change caused by an intruder. Structurally, such devices are designed as wired or cable and have two functional parts - a transmitter and a receiver of a high-frequency signal. The actual sensors of such devices are realized mostly by coaxial, so-called slot cables, which are laid in the ground along the fence of the guarded property. These devices usually operate with frequencies of the order of tens of MHz.

The disadvantage of this group of devices is that the generated electromagnetic field in the area of used frequencies is very sensitive to such changes or interfering frequencies, which are not caused by disturbance of the protected area. These devices are, in addition, sensitive to all conductive objects in the vicinity of the sensor, such as running or standing water, metal structures, especially overhead power lines, and the like. are high frequency devices susceptible to atmospheric influences such as rain, frost, snow and ice.

An undesirable consequence and thus a considerable disadvantage of the mentioned systems is, besides demanding installation and its maintenance, also a high number of false alarms on one side and the possibility of creating so-called deaf, ie unguarded places with the possibility of intrusion without alarm.

The essence of the technical solution.

The above-mentioned disadvantages of the described group of object guarding devices are substantially reduced by the electronic security guard for external guarding of the object, which consists of an oscillator comprising a capacitive sensor, a detector oscillator frequency variation detector and an evaluation and signaling circuit.

The essence of the present invention is that the electronic device comprises a reference oscillator, and that the sensing oscillator frequency variation detector is configured as a phase detector or a frequency detector whose first input is coupled to the output oscillator output and its second input is provided with the reference oscillator output provided and that the electronic device further comprises a frequency controller whose output is coupled to the control input of the reference oscillator.

Part of the subject matter of the present invention is that the capacitive sensor is formed by an open warp conductor, one end of which is free and the other is connected to an output terminal connected to a first input terminal of a sensing oscillator whose second input terminal is grounded. The frequency of the sensing oscillator and the reference oscillator is preferably in the range of 10 to 30 kHz.

Another object of the invention is that it comprises an integrator for monitoring the time variation of the sensing oscillator frequency, comprising at least an input coupled by a phase detector or a frequency detector to the sensing oscillator output, and an output that is coupled to the reference oscillator frequency regulator input.

The warp of the device according to the present invention is further preferably formed by a closed control loop, one end of which is provided with an output terminal and the other with a control terminal. the electrical circuit further comprising a control circuit, the first input of which is coupled to the output terminal and the second input of the control loop of the control loop, and the summation member interposed between the outputs of the control circuit and the phase detector;

In particular, the operational advantage of the present invention is that it can operate at a low operating frequency. This, on the one hand, ensures high operational reliability, on the other hand, considerable independence from the occurrence of random or permanent permanent interfering radio frequency fields in the vicinity of the object to be monitored, thus also independence from electromagnetic atmospheric disturbances.

Another advantage is that the frequency of the embedded reference oscillator used can be varied continuously depending on small and slow changes in the sensing oscillator frequency caused, for example, by a change in the dielectric constant of the guarded space due to a change in weather patterns, atmospheric conditions in acidity and the like.

BRIEF DESCRIPTION OF THE DRAWINGS.

Exemplary embodiments of the electronic device according to the present invention and the associated sensor construction are schematically shown in the accompanying drawings, in which Fig. 1 shows a cross-section of a fence in a guarded area, Fig. 2 shows another modification of the guarded area; Figure 4 shows the basic electrical configuration of the device, Figure 5 shows a portion of the configuration of Figure 3 using the automatic frequency oscillator change, and Figure 6 shows the modification circuits when applying a double sensor control loop.

Examples.

The capacitive sensor is, according to FIGS. 1 and 3, formed by a warp 12 of bare or insulated wire, which is supported by consoles 10 and insulators 11 in several parallel rows in the upper part of the fence 1 of the guarded object. One end of the warp 12 is mounted on one of the insulators 11. the other is then terminated by an output terminal 120 which is insulated from the respective bracket 10 and the fence 1. Due to the low frequency of the sensing oscillator 3 used, as shown below. In terms of frequency, the insulated placement of the warp 12 is not demanding in terms of implementation and long-term operation. The guarded space 13 is then formed in the area of the fence 1 between the warp 12 and the corresponding part of the terrain 100.

According to Fig. 2, the guarded space 13 is formed at the top of the fence 1 and is delimited on one side by a warp 12 mounted on brackets 10 similar to the example of Fig. 1, on the other side by a grounded barbed wire system 140 , usually on the outside of the fence 1 by means of carriers 14 and forms the usual mechanical protection of the guarded space.

The basic electrical circuit of an exemplary device according to the present invention shown in Fig. 4 is formed by a sensing oscillator 3, for example an oscillator with a serial oscillating LC circuit, whose capacitive member 300, or at least a portion thereof, is formed by warp capacity 12 relative to terrain 100 or in relation to the warp 12 to the nearest grounded neighborhood (not shown in FIG. 1), with a possible link to the mass of the fence 1, as shown in broken lines in FIG. 4. In the construction of Figure 2, a capacitive member 300 is formed between the warp 12 located on the insulators 11 and the grounded barbed wire assembly 140. The sensing oscillator 3 is provided with a pair of input terminals, a first input terminal 30 to which the output terminal 120 of the warp 12 is connected. a second input terminal 31, which is grounded. It further has at least an outlet 33. In FIG. 4, as in the other figures, the power supply and its distribution to the individual circuits are not described. For this purpose it is possible to use common network connection with backup in case of undesirable mains failure, eventually a suitable source of direct current with mains charging etc. can be used.

Another part of the circuit described is a reference oscillator 4 with an output 44 and a control input 41. and a reference frequency controller 5 whose output 55 is connected to a control input 41 of a reference oscillator 4. Finally, the circuit of FIG. one of the known frequency comparator connections. The frequency detector 60 has two inputs, a first input 601 and a second input 602 and an output 606, wherein the first input 601 is connected to output 33 of the sensing oscillator 3 and the second input 602 is connected to output 44 of the reference oscillator

4. Output 606 is then connected to input 71 of signaling circuit 7 with output 77.

In a further preferred embodiment, a substantial part of which is shown in FIG. 5, the frequency detector 60 is replaced by a phase detector 6 with corresponding first input 61, second input 62 and output 66. The circuit described is further completed with integrator 8 with input 81 and output 88. The phase detector 6 is further supplemented by an auxiliary output 63 which is connected to the input 81 of the integrator 8, whose output 88 is then connected to the input 51 of the frequency controller 5.

FIG. 6 shows a wiring which enables simultaneous checking or indication of the mechanical state of the warp 12 of FIG. 1, which in this case is performed as a double control loop 122, at the free ends of which the output terminal 120 is provided The preceding circuits are then supplemented by a control circuit 2 with an output 26. with the first input 20 to which the output terminal 120 of the control loop 122 is connected and with the second input 21 to which the second terminal, i.e. the control terminal 120 of the control loop 122, is connected. the output 22 of the control circuit 2 is connected, with a second input 92 to which the output 66 of the phase detector 6 is connected and finally with the output 99 which is connected to the input 71 of the signaling element 7.

The operation of the electronic device in the examples according to the present invention is as follows.

When the circuit according to FIG. 4 is started, the frequency of the reference oscillator 4 is adjusted by the regulator 5 so that it corresponds to the base frequency of the sensing oscillator 3. Its value

- 7

is dependent on the value of the capacitive member 300 of FIG. 1, unless the particular design of the capacitive sensor constituted by the system of fence 1, brackets 10 and the warp 12 disposed thereon according to FIGS. 2. The balanced state of the frequency detector 6 and the corresponding character of the signal at its output 606 correspond to this condition. The signaling circuit 7 then signals in some of the known ways, i.e. optically or graphically. that the guarded space 13 is not disturbed.

If an unauthorized person enters the guarded area 13, the value of the capacitive member 300 and thus the frequency of the sensing oscillator 3 will change. Since the frequency of the reference oscillator 4 remains unchanged, the state of the frequency detector 60 and thus the signal at its output 606 will change. If said change corresponds to its value or the nature of the signal proportional to the undesirable violation of the guarded space 130, this situation is respected by the signaling member 7 and by its output 77 it emits a corresponding alarm or alarm signal.

The circuit of FIG. 5 is preferably filled with a feedback circuit. This is formed by connecting the auxiliary output 63 of the phase detector 6 to the input 81 of the integrator 8, thereby respecting the slow, disruption of the guarded area 13 unrelated to the effects of weather changes and the like. With a small and particularly slow change in the value of the capacitive member 300, for example due to the change in the dielectric constant in the guarded space 13 by the weather change, the frequency of the sensing oscillator 3 changes accordingly and the detector 6 setting is changed. However, this change is transmitted via the auxiliary output 63 of the phase detector 6 and the input 81 to the integrator 8, which via its output 88 affects the regulator 5 so that it automatically adjusts the frequency of the reference oscillator 4 to a new value at which the phase detector 6 is again balanced. The specific struggle of the described circuits is known in the electronic practice and is therefore not described in detail. In practice, however, in an electronic device according to the present invention, a condition arises in which actually the operating frequency values of the sensing oscillator 3 and the bound frequency of the reference oscillator 4 float around the basic value determined by the design of the device. mode.

In the arrangement according to FIG. 6, in addition, the mechanical or electrical integrity of the warp 12 is provided, which in this case is implemented as a double control loop 122. The supplementary control circuit 2 is ineffective in normal operation and its output 22 does not affect the state of the first input 91 This is adapted so that the signal from the output 66 of the phase detector 6 in this case passes unchanged through the second input 92 to its output 99 and hence to the input 71 of the signaling circuit 7. However, if the control loop circuit 122 is interrupted, for example, broken forcibly or for objective reasons, a change occurs at the inputs 20.21 of the control circuit such that at the first input 91 and then at the output 99 of the summation member 9 a signal is generated that changes the state at the input 71 of the signaling member 7 so much be compensated by the integrator 8 and the associated controllers m 5 as described above. In this case, the device signals a violation of the control loop 122 and hence of the oscillation circuit of the sensing oscillator

3. The value of this change is chosen by the design of the control circuit 2 to be substantially different from the change. generated at the output 66 of the phase detector 6 when the guarded area 13 is disrupted, so that the reason for the alarm can also be distinguished.

Obviously, the efficiency of the integrator 8 is set to flow so that it does not respond to such changes in the frequency of the sensing oscillator 3, which by their value or speed correspond to the disruption of the guarded space 13 and are thus substantially greater or faster than small and slow changes. The phase detector 6 can be adjusted in such a way that the device does not react to the disruption of the guarded space 13 by small animals, for example voles.

*

It will be understood that the present invention may differ from the examples without compromising its nature. Thus, for example, the application of the frequency detector 60 in the exemplary wiring of FIG. 4 and the phase detector 6 in the exemplary wiring of FIG. 5 may be interchanged. Also, the circuits of the individual blocks may be formed by any known circuit that performs the desired function.

Industrial applicability.

The electronic security device according to the present invention can be advantageously used for external security of guarded objects, which is also located in high-frequency disturbed and climatically demanding and variable areas.

Claims (5)

Claims O! r- | o 5 »O> _ i M 'ω with c-1 o -f» i o%> | czx o 2 0 o —Ί | x I —K o i> ·> v * - li ** n u - ínS cn tsz r> < 1) An electronic security device for external surveillance of an object, comprising a sensing oscillator comprising a capacitive sensor, a sensing oscillator frequency deviation detector, an evaluation and signaling circuit, characterized by. that the electronic device comprises a reference oscillator (4), and that the frequency deviation detector of the sensing oscillator (3) is configured as a phase detector (6) or a frequency detector (60) whose first input ¢ 61,601) is connected to the output (33) of the sensing oscillator (3) and its second input (62,602) with an output (44) of the reference oscillator (4) having a control input (41) and that the electronic device further comprises a frequency controller (5) whose output (55) is connected to the control input (41) of the reference oscillator (41). 2. The electronic security device according to claim 1, characterized by. The capacitive sensor comprises an open conductor (12) of the conductor, one end of which is free and the other connected to an output terminal (120) connected to a first input terminal (30) of the sensing oscillator (3), the second input terminal (32) of which is grounded. Electronic security device according to claim 1 or 2, characterized in that the frequency of the sensing oscillator (3) and the reference oscillator (4) lies in the range of 10 to 30 kHz. An electronic security device according to any one of claims 1 to 3, characterized in that it comprises an integrator (8) for monitoring the time variation of the frequency of the sensing oscillator (3), comprising at least an input (81) interconnected by means of a phase transistor (6). or km / l of the detector (60) with the output (33) of the sensing oscillator (3) and the output (38) which is connected to the input (51) of the frequency regulator (8) of the reference oscillator (4). Electronic security device according to claim 1 and one of claims 3 or 4, characterized in that the warp (12) is formed by a closed control loop (122), one end of which is provided with an output terminal (120) and the other with a control terminal. (121), and that the electrical device circuit further comprises a control circuit (2), the first input (20) of which is connected to the output terminal (120) and the second input (21) of the control terminal (121) of the control loop (122) , on the one hand, by a summation element (9) which is interposed between the outputs (22,66) of the control circuit (2) and the phase detector (6) and the input (71) of the signaling circuit (7).