RU2617666C2 - Method for detecting intruder overcoming mesh fence facilities - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention can be used to detect an intruder invading the territory of the protected object by overcoming barriers made of steel mesh, by destructing it with various methods: snacking, sawing and cutting off.

EFFECT: increasing the detection reliability.

2 cl, 4 dwg

Description

The invention relates to the field of burglar alarms and can be used to detect an intruder intruding into the territory of a guarded object by overcoming a fence made of steel mesh by destroying it by various methods: by snacking, sawing and chopping.

It is a well-known method for detecting an intruder that overcomes the mesh enclosure of an object, which consists in applying an extended segment of a vibration-sensitive cable fixed to the obstacle, in converting the mechanical vibrations of the obstacle into an electrical signal, in extracting the useful signal in the spectrum of the characteristic mechanical frequencies of the intruder's impact on the obstacle, in comparison with the amplitude components of the extracted useful signal with a predetermined threshold level and in the formation of an alarm for exceeding a threshold level of the amplitude of the useful signal.

Most often, vibration-sensitive cables based on the triboelectric effect are used to convert the mechanical vibrations of the barrier into an electrical signal because of the simplicity and low cost of the cable.

A common significant drawback of well-known methods is the impossibility of localizing the place of violation within the area equipped with one sensitive element. Another disadvantage of well-known methods, as a consequence of the previous one, is low noise immunity to external interference factors, such as wind and acoustic noise, since it is obvious that the intruder’s influence is strictly localized, and this kind of interference is distributed throughout the guard area and the actual signal value interference is determined by the total exposure along the entire length of the cable.

A known method for detecting an intruder, implemented in the device according to US patent No. 5446446, IPC G08B 13/16, 1995, eliminating the disadvantage of the previous method, which uses a vibration-sensitive cable of a special design, rigidly fixed to the fence. The cable comprises an inner conductor, an outer conductor, and a dielectric between the inner conductor and the outer conductor. Sensitive wires "float" in the "keyways" made in the core of polyethylene during the manufacture of the cable. Mechanical vibrations of the enclosure, and therefore of the sensitive cable when exposed to the intruder, cause movements of the sensitive conductors of the cable, these movements are recorded and localized using radio frequency pulse reflectometry methods.

A significant disadvantage of the known method, limiting its use, is the high cost of a special sensitive cable, due to the complexity of its design.

Closest to the claimed method according to the technical nature and the technical result achieved is a method for detecting an intruder described in patent RU No. 2473970, IPC G08B, 2012. A method of protecting the perimeter of an object. The described method is adopted as a prototype of the invention. This method consists in the fact that it is proposed to use point sensitive elements to detect the intruder, in the particular case, strain gages installed on each section of the fence. The electrical signal generated by the sensitive elements is monitored and processed according to a specific algorithm by the signal processing controller. The controller is targetedly connected to the central unit, which makes it possible to determine the location of the intruder's impact on the fence with accuracy up to the length of one section.

Technical implementation of the described detection method is not possible when using existing (previously installed) fences, since it requires the use of supports and canvases of a special design, which limits its use and, in addition, has the following disadvantages:

1. The method does not allow to increase the length of the sensitivity zones, which is due to the need to install sensitive elements and controllers in each section, therefore, the implementation of the method involves high equipment costs even if there is no need to localize the impact on the fence to the length of one section.

2. The proposed method does not contain significant features that can reliably localize the impact site, taking into account the transmission of vibration of the canvases from one section through the support mounting device to the adjacent one.

3. The proposed method does not contain significant features that can reliably identify the effects of interference of anthropogenic and natural nature (thunder, salutes, explosive works, movement or the work of heavy mechanisms, etc.), distributed over several sensitivity zones, and exclude the formation of a signal anxiety.

An object of the present invention is to remedy these disadvantages.

The problem is solved as follows.

The point detector vibration detector is installed on the fence section, which determines the sensitivity zone and consists of one or more sections - mesh panels. The signal generated by the vibration sensor is recorded when the intruder overcomes the fence by the method of destruction of the web or climb. Using the processor of the vibration sensor, signals intrinsic to the intruder are extracted, their current values are determined and transmitted in a discrete form to the central unit. The processor of the central unit compares the obtained values with a predetermined value, in case of exceeding the obtained value of a predetermined threshold value, the exposure time is measured. The measured value is compared with the initially set threshold time value and, if the measured value is greater than or equal to the set value, an alarm is issued. If the measured value does not exceed a predetermined threshold value, determine the nature of the signal change and compare the nature of the signal change with the typical function of the signal change at a single exposure. A single impact in this case is the result of a single blow, snacking, chopping the wire rod. In accordance with the nature of the change in the signal of a typical function, the number of unit actions is counted over a given time interval. If the number of single actions is equal to the threshold value of the number of actions, an alarm is issued.

An increase in the sensitivity zone is achieved by connecting adjacent mesh panels within the sensitivity zone outside the racks using vibration-conducting jumpers.

Localization of the impact site is achieved by dividing adjacent mesh panels at the border of the sensitivity zone using vibration-isolating elements.

To identify the impact of man-made and natural disturbances, distributed over several sensitivity zones, and exclude the formation of an alarm signal, determine the time interval of actions and the order of signal changes, compare the obtained intervals and the order of signal changes for all sensitivity zones and, if they coincide, block the alarm .

The invention is illustrated figures 1-3.

The figure 1 shows an example of the formed sensitivity zone, consisting of three sections of the fence and six cloths of the SSSC network with a vibration sensor, conductive and vibration isolating jumpers.

Figure 2 shows a possible embodiment of a vibration-conducting jumper.

Figure 3 shows a possible embodiment of a vibration isolating damping element.

The figure 4 shows a method of mounting a vibration sensor on a vibration-conducting jumper to form a sensitivity zone from two adjacent sections of the fence.

The method is as follows.

As the material of the paintings of the sections, a welded mesh with a zinc coating (SSCP) is used, the fence supports are metal pipes of any section. The appearance of the fence section is shown in Figure 1. To combine the paintings into a single sensitivity zone, any fasteners that are standard for this type of fence are used, while the paintings are additionally connected to each other outside the racks using jumpers that conduct vibration. In the simplest case, as such a jumper, a U-shaped bracket made of metal wire can be used, fastened to two adjacent canvases at some distance from the line of the fixing fastening (support).

To combine the paintings of the two sections, a jumper is used, which is mounted on the fence as shown in figure 2. To separate the paintings of the two sensitivity zones on the fence support, a massive damping element is additionally installed at the border of the sensitivity zone. An example of such an element, which is a metal channel (in a particular case - 24U GOST 8240-97), is shown in figure 3. A vibration sensor is installed in the middle of the central canvas of the sensitivity zone as shown in figure 1. If an even number of sections of the fence are combined into one sensitivity zone , for example two, the vibration sensor can be installed directly on the vibration-conducting jumper, as shown in figure 4. The vibration sensors of all sensitivity zones are connected to the main via a wire line Nome unit. The vibration sensor, when the intruder overcomes the fence by the method of destruction of the web or climb, registers a signal corresponding to the specified range in frequency characteristics.

It was experimentally established that the frequency range, essential for determining the nature of the impact on the fence from the SSSC, is 10 ... 1000 Hz. The current signal values are transmitted in a discrete form to the central unit. The processor of the central unit compares the obtained values with a predetermined value, in case of exceeding the obtained value of a predetermined threshold value, the exposure time is measured. When destroying the fence by sawing or in any other way, providing for continuous exposure lasting more than a predetermined threshold value. The measured value is compared with the initially set threshold time value and, if the measured value is greater than or equal to the set value, an alarm is issued. If the measured value does not exceed a predetermined threshold value, determine the nature of the signal change and compare the nature of the signal change with the typical function of the signal change at a single exposure. A single impact in this case is the result of a single blow, snacking, chopping the wire rod. In accordance with the nature of the change in the signal of a typical function, the number of unit actions is counted over a given time interval. If the number of single actions is equal to the threshold value of the number of actions, an alarm is issued.

An increase in the sensitivity zone is achieved by connecting adjacent mesh panels within the sensitivity zone outside the racks using vibration-conducting jumpers.

Thus, the method consists in the fact that the point sensors of vibration of the detector are installed in the area of the fence, consisting of mesh panels and determining the sensitivity zone, register the signal that occurs when the intruder overcomes the fence by the method of destruction of the canvas or climb, select the signals characteristic of the intruder, determine their values and in the form of a digital code is transmitted to the processing unit; comparing the obtained values with a predetermined value, in case of exceeding the obtained value of the predetermined value with continuous long-term exposure, determining the exposure time, comparing the obtained interval with the initially set first time interval and, if they correspond, give an alarm; with a single short-term exposure, the nature of the signal change is determined, the nature of the signal change is compared with the typical function of the signal change, and when they are consistent, the number of unit actions during the second predetermined interval is calculated; if the number of unit actions is equal to the threshold value, an alarm signal is generated, characterized in that the sensitivity zones an arbitrary size is formed by connecting within the sensitivity zone of adjacent mesh panels to each other outside the racks when using vibration-conducting jumpers and by dividing adjacent mesh panels at the boundary of the sensitivity zone using vibration-damping elements.

In this case, in the case of interference distributed over several independent sensitivity zones (fencing sections), the time interval of the effects and the order of signal changes are determined, the obtained intervals and the order of signal changes are compared, and if they coincide, they block the alarm signal.

Claims (2)

1. The method of protecting the perimeter is that the point vibration sensors of the detector are installed on the fencing section, consisting of mesh panels and determining the sensitivity zone, the signal that occurs when the intruder overcomes the fence by the method of destroying the canvas or climb, the signals characteristic of the intruder are isolated, they are determined values and in the form of a digital code are transmitted to the processing unit; comparing the obtained values with a predetermined value, in case of exceeding the obtained value of the predetermined value with continuous long-term exposure, determining the exposure time, comparing the obtained interval with the initially set first time interval and, if they correspond, give an alarm; with a single short-term exposure, the nature of the signal change is determined, the nature of the signal change is compared with the typical function of the signal change, and when they are consistent, the number of unit actions during the second predetermined interval is calculated; if the number of unit actions is equal to the threshold value, an alarm signal is generated, characterized in that the sensitivity zones an arbitrary size is formed by connecting within the sensitivity zone of adjacent mesh panels to each other outside the racks when using vibration-conducting jumpers and by dividing adjacent mesh panels at the boundary of the sensitivity zone using vibration-damping elements. 2. The method according to p. 1, characterized in that when exposed to interference distributed over several independent sensitivity zones (sections of the fence), determine the time interval of actions and the order of change of signals, compare the obtained intervals and the order of change of signals, and if they coincide, block the signal anxiety.

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