RU2476656C2 - Engineering and technical structure - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: engineering and technical structure comprises bearing stands and a protective web joined with them. It additionally contains a hardware cabinet arranged inside the territory fenced with the protective web and comprising a system of autonomous reserve supply, and a connected climatic system of control of the system of autonomous reserve supply, joined with a power supply grid, also it contains a linear radiowave annunciator, a receiver and a transmitter of which are arranged on the stands inside the area fenced with the protective web, and are connected with the hardware cabinet and a sensitive cable element with a receiving unit, being a triboelectric sensor connected with the hardware cabinet, and the receiving unit of the triboelectric sensor has controlled sensitivity.

EFFECT: higher reliability and efficiency of protection, provision of uninterrupted operation of electronic recording equipment under any external climatic conditions and in case of unstable operation of grid power supply or temporary absence of such, higher reliability of protection of a hardware cabinet and all electronic equipment and increased universality of a device.

18 cl, 7 dwg

Description

The invention relates to technical means of guarding the perimeters of industrial, military, agricultural facilities and other civilian and special purpose facilities, namely to signaling barriers for detecting and recording direct unauthorized impacts on a barrier, including hidden and disguised attempts to enter a protected area or, on the contrary, from it unauthorized persons, equipment, as well as animals.

Known signaling-blocking devices that use to improve the efficiency of the blocking quality, modify the mechanical properties of the entire barrier or its upper part, for example, mesh signaling barrier (RF patent No. 2266382, ЕНН 17/14, 12/20/2005, Bull. No. 35), containing carriers racks, mesh web and cable sensing element, and the bearing racks are made of three parts having different stiffness due to changes in the cross section of the profile of each part in shape - from box in the bottom to the U-shaped in the middle and upper parts, and in area that decreases with the transition from the middle to the upper, the lower part of the mesh web is buried in the ground, the supporting racks installed along the edges of the linear sections of the signal fence are equipped with braces in the form of cables, which they are adjustable in length with the help of lanyards; at the turning points of the route, two load-bearing racks are installed in one well at a distance from each other so that the angle formed by these racks when tensioning the mesh webs in each of The direction of the track is not obstructed the mesh webs oscillations in the vertical plane at the top of the mesh fabric is cut from the longitudinal and transverse filament yarns of the mesh webs are formed by vertical pins 50 mm in height [1]. Devices of this type can also include an alarm-delaying fence according to USSR patent No. 1840353, F41Н 11/08, 10/10/2006, containing a main fence with a visor based on barbed wire or barbed tape and a cable converter of mechanical vibrations fixed to the visor and connected to device for alarming, and the visor is made in the form of rigid wheelsets with a tubular hub, freely mounted on an elastic long axis, rigidly fixed by means of brackets at the top of the fence, at The rims of each wheel pair are connected by means of barbed wire or barbed tape, and all wheel pairs are connected by a cable converter, which is rigidly fixed to the wheel pairs along their axis with the formation of a free loop between the wheel pairs [2].

Known devices can complicate the overcoming of the obstacle by imparting special mechanical properties to it, for example, in the first device - imparting to the racks of variable stiffness, stepwise decreasing upwards and making it difficult to move through the obstacle using improvised means, for example, a ladder, and also to improve the recording of such events , due to increased vibrations of the upper part of the barrier panels due to their reduced stiffness.

The disadvantages of the known devices are low functionality due to the fact that they allow you to record well enough only a well-defined and definable narrow class of events of unauthorized overcoming of the obstacle, namely, only using attached ladders, or well-defined methods of overcoming barbed wire obstacles, for example, throwing clothes, while there are many other ways to overcome. This is due to the roughened sensitivity of the recording equipment, which is necessary in order to allow fluctuations in the panels of the canvas of significant amplitude or to allow rotation of the wire fence wheels located on top of the canvas with the aim of mechanical difficulty overcoming through the top. In addition, the low functionality is due to the strong dependence of the recording equipment on voltage fluctuations, power outages due to the lack of redundant power supplies and their climate regulation, depending on the integrity of the power supply network that provides power to the equipment for recording impacts on the fence, which significantly increases the vulnerability of the device and reduces its blocking ability and system-element reliability.

The enclosing structure is also known (RF patent No. 2151996, F41H 11/08, 06/27/2000, Bull. No. 18), containing spirals of coils connected to each other around the circumference with staples in a checkerboard pattern, the coils being made of barbed tape rolled into it insulated electric cable, which is connected by end connectors at the ends to the electronic control panel [3].

The known device allows to increase the reliability of registration of unauthorized attempts to overcome the obstacle due to an increase in the degree of mechanical contact by the distribution of the connection of the thorny elements of the barrier with the sensitive cable throughout its length, but this increases the likelihood of false positives due to minor interference influences.

In addition, the disadvantages of the known device are low functionality due to the lack of backup power and its climate regulation, which also leads to low reliability of the device and reduces its protective properties.

An electronic barrier is known (KR 200406292, 01.20.2006, ЕНН 17/00) containing load-bearing racks, a protective sheet, a cable element and an apparatus cabinet, the load-bearing posts being connected to a protective sheet to which the cable element is connected. In addition, the device includes a high voltage converter located in the hardware cabinet and connected to the cable element [4].

The known device has low mechanical blocking abilities in connection with the implementation of the barrier functions using high voltage supplied to the barrier web and the absence of signal functions, which reduces the functionality and reliability of the device. In addition, the disadvantages of the known device are low functionality and low efficiency, because the proposed design solutions do not allow the barrier to function normally with large voltage fluctuations in the network, interruptions or temporary interruption of power supply, as well as in various climatic conditions with large ranges of temperature changes air. As a result, the known device has a low degree of reliability in protecting against unauthorized intrusions, as well as attempts to penetrate and break the fence using electrical insulation means. Another disadvantage of the device is the low degree of security of the hardware cabinet, since it is located outside the contour of the fence.

Closest to the proposed device is an engineering obstruction according to patent RU 685651 U1, Е04Н 17/00, 11/27/2007, containing load-bearing racks and a protective sheet connected to it. In addition, the device contains a carrier part, consisting of carrier racks buried in the ground, rectangular frames rigidly mounted on them, and a protective sheet mounted on the frame and contains a flat safety barrier, the carrier part is additionally provided with a carrier wire, stretched over the struts, the fabric is made of two parts flat, made in the form of a flat security barrier "Acacia", and volumetric, made in the form of a security barrier spiral "Fidget", each of the barbed tape reinforced (LCA), both are simply fixed on the bearing part symmetrically to its profile axis [5].

The known device has low functionality due to the low flexibility and functionality of the design, which does not allow any complete variations to work in various conditions, different locations and for various purposes. In addition, the known device uses only the mechanical obstructive properties of a physical obstacle without the use of modern signaling means for detecting unauthorized attempts to penetrate, and therefore have low functional capabilities, since it does not allow the timely prevention of them, as well as intentions and attempts to damage the barrier, or hidden invisible penetration, which greatly limits the scope of the device and reduces the reliability of protection You and efficiency, which in known devices of this type is almost entirely determined by mechanical strength and barrier properties, which are limited.

The aim of the invention is to expand the functionality and increase the reliability and effectiveness of protection against attempts by unauthorized, including inconspicuous masked intrusions with attempts to covertly overcome signaling devices, ensure uninterrupted operation of electronic recording equipment under any external climatic conditions and during unstable operation of network power supply or even temporary lack thereof, as well as by expanding recorded and preventable types of threats and penetration methods, by increasing the operability of the device in a wider range of conditions, using multichannel registration and the possibility of increasing the sensitivity of recording equipment by making the mechanical elements stationary and constant stiffness, as well as increasing the reliability of protection of the hardware cabinet and all electronic equipment and increasing the universality of the device by expanding areas applicability by providing the possibility of delivery in various configurations.

To achieve this goal in a well-known engineering and obstacle obstacle containing load-bearing racks and a protective sheet connected to them, the hardware cabinet additionally contains an autonomous backup power system and a climate control system of an autonomous backup power system connected to it. In addition, the autonomous backup power system contains a battery power source, a charger and a first switch, the switched inputs of which are inputs of an autonomous backup power system, and the outputs are connected to a charger, the output of which is connected to a battery whose outputs are outputs of an autonomous backup power system, and the control input of the first switch is its control input. In addition, the climate control system of the autonomous power supply system contains at least one air temperature sensor, a microcontroller, one analog information input of which is connected to the output of the temperature sensor, the second information input of the microcontroller is connected to the output of the power supply network, and its third information input is connected to the output of the autonomous system backup power; the first control output of the microcontroller is connected to a heating element thermocontactly connected to the battery of the autonomous backup power system, and also includes a temperature controller connected to the fourth information input of the microcontroller and an indicator element connected to the second output of the microcontroller; contains a second switch, the first switched inputs of which are connected to the power supply network, the second switched inputs - with the battery outputs, the outputs of the switch are connected to the device power circuits, and the control input of the second switch is connected to the third output of the microcontroller, the fourth control output of which is connected to the control input of the autonomous system backup power, the inputs of which are connected to the power circuits of the device. In addition, an air temperature sensor is located inside the hardware cabinet. In addition, the protective sheet forms a closed loop. In addition, it contains at least one gate located in the protective sheet, and the protective sheet with the gate forms a closed loop. In addition, the gates are equipped with magnetocontact sensors connected to a hardware cabinet. In addition, an additional gate was introduced, equipped with magnetocontact sensors connected to a hardware cabinet. In addition, the hardware cabinet contains a door equipped with magnetic sensors connected to the hardware cabinet. In addition, it contains an infrared linear detector, the receiver and transmitter of which are located on racks on either side of the gate above the gate and are connected to the equipment cabinet. In addition, it is made in the form of a kit, providing for a variation of the types of its constituent elements. In addition, the protective fabric is made in the form of a mesh. In addition, it contains a device for tensioning the protective sheet. In addition, the protective fabric is made in the form of panels. In addition, the protective fabric is made in the form of a combination of mesh and panels. In addition, the kit contains a set of tools for mounting the fence. In addition, it further comprises reinforced load-bearing racks located in the places of sharp bends of the protective sheet and connected to it. In addition, the reinforced load-bearing racks contain load-bearing racks and at least one additional support connected at one end to the lower part of the load-bearing rack at a distance from its lower end close to the length of the additional support and directed at the other end downward at an acute angle to the load-bearing rack.

The technical result consists in expanding the functionality in view of increasing the functional flexibility and versatility of the device, as well as increasing adaptability to specific tasks, environmental conditions, terrain, and thereby increasing the efficiency and reliability of protection due to the creation of the possibility of increasing the optimality of the choice of component parts, making up a variable device kit. The functional capabilities are also expanded and the effectiveness and reliability of protection against unauthorized, including hidden, disguised and subtle attempts to penetrate the barrier by increasing the redistribution of protective protective functions from the mechanical part of the structure towards expanding capabilities and improving the quality of electronic detection, is increased. This, in turn, is achieved by increasing the stability of the operation of all systems of the device during voltage fluctuations in the supply network, failures, power outages and temporary blackouts, as well as by expanding the range of changes in climatic conditions while maintaining the ability of the device to operate in normal modes, due to the introduction of at least one backup power source in the form of an autonomous battery (or batteries) and a climate control system tion of autonomous backup power systems. The functionality of the device is also enhanced by making it in the form of a variable set, equipped with all the necessary tools and a device for tensioning the mesh in the case of barrage protective cloths in mesh-wire or combined form. The reliability and effectiveness of the barrier are also enhanced by increasing the reliability and efficiency of detection of penetration attempts by introducing multi-channel registration using qualitatively different detection principles based on various physical effects that are not interconnected. This is also done by increasing the self-protective properties of the device by placing the equipment inside the territory area that is three times protected with the same equipment. By expanding the functionality and reliability of the device, its versatility increases, since the proposed connections of additionally introduced elements allow it to be used in a wide variety of areas where protection of civil, military, industrial, agricultural or special purpose objects is required from bilateral, especially masked and inconspicuous penetration both inside and outside the fence, as well as in wide conditions of various climatic and other changing external influences iah environment. Moreover, the device allows you to easily vary the configuration of the perimeter of the protected area, provides multivariate installation and configuration, which increases its adaptability to specific tasks in each individual application. In addition, the functionality of the device is expanded due to the fact that the device does not require special preparation of the protected area and additional devices, which reduces the cost of installation and increases the speed of deployment. The technical result is also achieved by increased simplicity and reliability of protection, since this does not require additional complications of the structural mechanical part of the fence due to the implementation of the device according to the invention, ensuring maximum use of electronic means by increasing their reliability, expanding the range of regular operation and ensuring multi-channel, as well as providing, in fact, the possibility of their automatic self-protection.

These features of the invention, thus, due to the proposed additionally introduced elements and the relationships between them together to ensure the achievement of a technical result, since the effect of introducing the whole set of additional elements connected in the proposed way and in interaction with restrictive features significantly exceeds the simple sum of the effectiveness of additional elements , in connection with which, the distinguishing features of the proposed invention can be considered as satisfying the criterion of su publicity differences.

Figure 1-2 shows a diagram of device options of various configurations.

Figure 3 shows a functional diagram of an autonomous backup power system with a climate system for its regulation.

Figure 4-6 shows a diagram of a single-tier and two-tier embodiments of the canvas 3 from a wire mesh 5 with the same and different tier widths, respectively, and a tensioner 6.

Figure 7 shows a diagram of embodiments of reinforced racks 2.

Engineering fence (Fig.1-2) contains a protected area 1, a set of vertical posts 2 and reinforced vertical posts 4 located along the perimeter of the protected area 1, a protective sheet 3, which can be used manufactured flat security barriers (PBB) "Acacia", or spiral "Fidget" (figure 2), or a standard wire mesh 5 (figure 1, 4-7), for example, a welded galvanized wire mesh type SSCP or OTs, stretched by a plane on racks using a special tensioner 6 included in the kit for razhdeniya (4); panel panels 3 can be located in any combination of types between each other and with a wire mesh 5 in one or more tiers (Fig.1-2, 5-6); the web 3 is fixed to the posts 2 and 4, for example, using the strips 7 of the holes 8 made on them (Fig. 7); reinforced racks 4 can be made of larger cross-section, or each with one or two additional racks 9 (Figs. 1, 7), the device can also contain at least one gate 10, built into the perimeter of the protective sheet 3 and suspended from reinforced racks 4 the doorway with hinges 11 may also contain at least one wicket 12, built into the perimeter of the protective sheet 3 and suspended with the help of hinges 11, in combination with the gates, or instead of them in the form of different configuration options; throughout the protective sheet 3, a sensitive triboelectric cable 13 is fixed and possibly masked (Fig. 1-2) connected to the input of the receiving unit connected to the equipment cabinet 14, located inside the protected area 1 or outside, if the protected area is outside the fenced by a barrier, respectively, the sensitive cable 13 in this case is also fixed on the inside of the web 3 or on the outside; the device also contains magnetocontact sensors 15, racks 16, a transmitter 17 and a receiver 18 of a linear radio wave detector, the information and supply outputs of which are connected to a hardware cabinet 14; racks 19, the transmitter 20 and the receiver 21 of the infrared linear detector, the information and supply outputs of which are connected to the hardware cabinet 14; magnetocontact sensors 15 are located on the interlocking parts of the gate leaves 10 and / or gates 12, and the transmitter 17 and the receiver 18 of the linear radio wave detector are located on both sides of the gate on the uprights 16 along the edges of the doorway opposite each other; also on both sides of the gate 10 on the gate racks there are racks 19 on top of them, on which the transmitter 20 and the receiver 21 of the linear infrared detector are fixed opposite each other; the hardware cabinet contains a door 22 provided with magnetocontact sensors 15. The climate control system of the autonomous power system (Fig. 3) contains an indicator element 23 located on the hardware cabinet 14, an autonomous backup power supply system 24, the inputs of which are connected to the power supply circuits (buses) 25 of the device 25 comprising at least one battery 26, a charger 29, and a first switch 31; the climate control system of the autonomous power system also contains a second 27 switch, a microcontroller 28, a power supply network 30 (outputs of the power supply unit), an air temperature sensor 32, a temperature setpoint 33, a heating element 34, the power supply network 30 being connected to the first switched inputs of the second switch 27, the outputs the backup battery 26 is connected to the second switched inputs of the switch 27 and the third information input of the microcontroller 28, the first input of which is connected to the output of the temperature sensor 32 air, the second information input of the microcontroller 28 is connected to the power supply 30, the fourth information input of the microcontroller 28 is connected to the output of the temperature setter 33, the first output of the microcontroller 28 is connected to the input of the heating element 34, thermally contacted with the backup battery 26, the second output of the microcontroller 28 is connected to the indicator element 23, and the fourth output with the control input of the system 24, that is, with the control input of the first switch 31; the inputs of the switch 31 are connected to the power circuits 25 of the device.

Signal engineering fence is mounted as follows.

Along the perimeter of the territory 1 to be protected, vertical posts 2 are installed in the usual known way, for example, driving into the ground with control using a level or plumb line, followed by ramming or concreting the posts. Next, the protective sheet 3 is hung in each gap between the uprights 2, followed by its fastening on each uprift 3 (Figs. 1-2, 7). In places of sharp bends of the protective web, reinforced racks of a larger cross-section can be installed 4. If the web 3 is made in the form of a wire mesh 5 (Figs. 4-6), the web 3 is pre-fixed on the racks 2, followed by the tension of the net 5 using the tensioner 6 and final fixation. If necessary, depending on the required total height of the fence, the protective sheet 3 can be made in two or more tiers (Figs. 4-6), both if it is made in the form of a wire mesh 4 and other types of panels in any combination thereof (Fig. .1-2). In this case, the width of the tier can vary and be unequal for different tiers, which is determined by the required height of the fence (figure 5). The fastening of the protective web 3 to the uprights can be carried out using the strips 7, with their fastening by known methods, for example, bolts in the holes 8 made in the uprights 3 (Fig. 7). If necessary, depending on the terrain and the required concrete configuration of the fence, reinforced racks 4 are installed, each of which contains one or two additional supports 9. If a specific implementation of the device requires the installation of a gate 10. They are hung on the hinges 11 for hanging the gate 10 (Fig. 1-2), on racks 2 in contact with the gate 10 in the same way as in the case of the gate 12. After this, the sensitive triboelectric cable 13 is hung on the panel of the protective canvas 3 around the entire perimeter of the fence Except for the gate 10 and the gate 12, so that the cable 13 is in contact throughout the panels of the protective sheet 3 and connect its receiving unit with a hardware cabinet 14 located anywhere inside the protected area 1. After attaching the gate 10, they are installed on their wings magnetocontact sensors 15, and on both sides of the gate 10 from the inside inside the protected area 1, the transmitter 17 and the receiver 18 of the linear radio wave detector are mounted on the racks 16, connected by power cables and an information cable with a hardware cabinet 14. If the fence additionally contains one or more small single-leaf gates 12, they can be equipped with magnetocontact sensors 15 connected to the hardware cabinet 14. They are also installed on racks 19 located on top of the canvas 3 on both sides above gates 10 of the transmitter 20 and receiver 21 of the infrared linear detector and connect them with information and power cables to the hardware cabinet 14. All sensors are connected to the hardware cabinet 14 information and power to belyami, laid along the protected area 1, for example, inside the area bounded by the protective sheet 3, and a hardware cabinet 14 is connected to the mains. Magneto-contact sensors 15 are installed on the door 22 of the hardware cabinet 14, the outputs of which are connected by cables laid inside the hardware cabinet 14. This provides an additional level of self-protection of the device, in particular, its hardware cabinet 14. Turning on the device puts the triboelectric sensor 13 into standby mode, sets up a continuous radio wave the beam in accordance with the radiation pattern between the transmitter 17 and the receiver 18 of the radio wave detector and sets the continuous narrow-focused infrared e rays between the transmitter 20 and the receiver 21 of the infrared detector. The signal-supply circuits of the magnetic contact sensors 15 of the gate 10, the wickets 12 and the door 22 of the cabinet 14 itself are also closed. The inclusion and operation of all electrical systems of the device is indicated by the indicator 23. Thus, the deployment of the device is a minimal set of simple operations that are carried out in a minimum time and do not require any special equipment other than the supplied tool kit with the device.

Signal engineering fence works as follows.

The implementation of the device in the form of a variable set allows you to select the most appropriate configuration of combinations of panels of various types, flat lattice or solid, three-dimensional, mesh 5 of the protective fabric 3 in various combinations, together or separately (figure 1, 2), with alternating height and / or width, which allows you to optimally flexibly modify the device for various specific goals and objectives. The proposed device allows you to use it with a gate 10, at least one, and without them, or equipped with one or more gates 12 (figure 1), including in combination with a gate 10 as necessary. The variable completeness of the device also allows the use of various racks for cross-section and configuration, also in various qualitative and quantitative combinations. This makes it possible to form a kit for a specific task and significantly increases the adaptability of the device to the necessary requirements in each individual case, which increases the reliability and efficiency of protection and extends the functionality.

When unauthorized attempts to overcome the engineering and technical barriers with the aim of penetrating into the protected area 1 or, conversely, from it by unauthorized persons, equipment and animals, or when bringing them into contact with the protective sheet 3 or with the stands 2, 4, the protective sheet 3 fluctuates (5), recorded by a sensitive triboelectric cable 13 and its receiving unit, the signal of which enters the equipment cabinet 14 and is an alarm signal. Since the web 3 is rigidly fixed on the racks 2 and 4 and together with them has a constantly distributed stiffness, its fluctuations are much weaker associated with the structural features of the mechanical part of the fence, in contrast to the known devices using additional mechanical elements to increase the barrage properties, due to with which the vibrations of the web 3 contain a large fraction of the useful signal and this allows to increase the sensitivity of the recording equipment, thus redistributing Part signaling-barrier properties of the electronic part of the device. In the case of attempts to open the gate 10, the magnetocontact sensors 15 are opened with the corresponding alarm signal issued to the equipment cabinet 14 and the radio beam crosses from the transmitter 17 mounted on the racks 16 to the receiver 18 of the linear radio wave detector with the corresponding alarm signal supplied to the equipment cabinet. The gates are also protected from climbing through them by an infrared linear detector that gives an alarm signal when one of the infrared rays crosses from the transmitter 20 to the receiver 21, which, in addition to duplicating the gate protection, provides protection from a qualitatively different type of overcoming, which makes it possible in combination with other distinctive signs to make the fence almost insurmountable unauthorized. Thus, there is a quantitative and qualitative duplication of the useful signal through various physically unconnected information channels, which increases the reliability of the protective functions of the signal barrage. In case of unstable operation of the mains power supply or in case of a power outage through the network or in the absence of such, the autonomous backup power supply system 24 (Fig. 3) is turned on by automatically connecting to the power circuits 25 of the battery device 26 by switching the second switch 27 with a signal from its third input microcontroller output 28; recharging the battery 26 is a charger 29 from the mains 30 (output of the mains power supply) during its stable operation, which increases the reliability and efficiency of protection using the proposed device. When charging the battery to the maximum value, the microcontroller 28, based on the analysis of the signal values from the output of the battery 26 and the network 29, generates a control signal from the fourth output of the microcontroller 28, which is fed to the control input of the first switch 31, disconnecting the charger 29 from the power supply 25. In case of decrease air temperature, especially to subzero temperatures, the battery 26 is quickly discharged, which could significantly reduce the functionality of the use of roystva and reduce the advantages of the introduction of reserve power in the operation of autonomous devices in a wide range of climatic conditions. To prevent this, an automatic climate control system is additionally introduced into the device, at least one air temperature sensor 32 of which is installed inside the hardware cabinet 14 and generates a signal proportional to the air temperature inside the cabinet 14 in the immediate vicinity of the battery 26, which is supplied to the first information input of the microcontroller 28, the second input of which receives a signal from the output of the power supply 29, and the third - the signal from the output of the backup battery 26. To the fourth information The control input of the microcontroller 28 receives a reference signal from the output of the temperature setter 33, from which the threshold temperature for switching on the autonomous power supply system 24 is input. The microcontroller 28 compares this signal with the signal from the output of the temperature sensor 32 and, when the last value drops below the set value, switches on according to the first the output of the heating element 34, thermally contacted with a backup battery 26, and produces its heating until the external temperature remains is lower than the threshold, which prevents the discharge of the battery 26. Thus, this ensures constant availability of the backup power source 24 for operation regardless of climatic conditions, which significantly increases the reliability, protective properties of the entire device and extends the functionality of its application. If the voltage of the network 30 is temporarily or permanently lower than the maximum permissible, the microcontroller 28 generates a control signal at the third output, which switches the switch 27, which switches the power buses 25 of all systems of the device to power from the backup source 24. When the voltage in the network 30 is normalized, switch 27 returns to its original state at the command of the microcontroller 28 and reconnects the power bus 25 of the device to the network 30.

The advantages of the proposed engineering and technical barriers in comparison with known devices, including the prototype, are:

- wide functionality by providing the ability to flexibly modify the device for various specific goals and objectives by performing the device in the form of a quick-assembled variable kit that allows you to create different delivery kits for specific goals, which significantly increases the adaptability of the device to individual conditions and operation goals, and therefore reliability and effectiveness of protection;

- wide functionality due to the introduction of additional elements connected in the proposed manner, allowing to ensure the regular functioning of all systems of the device in wider ranges of changes in climatic conditions of the external environment, which allows equally efficient operation of the device at any time of the year in any territories, as well as during voltage fluctuations in the power supply network, interruptions, interruptions in the supply of electricity, temporary blackouts and in conditions of complete temporary non-availability loss from her;

- wide functionality and high versatility due to the use of standard materials and assembly technologies, due to the introduction of additional elements to simplify the mechanical part of the device;

- the possibility of further expanding the functionality by expanding the scope of applications, which is provided by expanding the types of recorded possible threats, increasing universality and simplifying installation and dismantling of the device;

- high reliability and efficiency of use of the device due to the redistribution by means of the invention of protective and protective functions from the mechanical part to the electronic part by increasing the functionality of the latter, as well as providing the possibility of self-protection of the electronic part and the introduction of multi-channel information collection and recording;

- the ability to increase the sensitivity of the device due to the use of the simplest physical physical barrier part of constant stiffness and thus eliminating some of the sources of interfering signals, which makes it possible to increase the functionality of the electronic part of the device provided by additionally introduced elements connected in the proposed manner and interacting with the elements of the prototype according to the proposed the invention;

- high structural strength of the device with the possibility of using low alloy structural steels of ordinary strength, which is ensured by the simplicity of the mechanical part of the device due to the improvement of the electronic part, which also allows to increase the period of its use;

- low cost of the device due to the simplicity, the scope of the assembly, high efficiency of the device, the possibility of using low alloy structural steels, the optimal distribution of protective and signaling properties and a high degree of automation due to the proposed introduction of additional elements made and connected in the proposed manner.

Information sources

1. RF patent No. 2266382, Е04Н 17/14, 12/20/2005, Bull. Number 35.

2. USSR patent No. 1840353, F41H 11/08, 10/10/2006.

3. RF patent No. 2151996, F41H 11/08, 06/27/2000, bull. Number 18.

4. KR patent No. 200406292, 01.20.2006, ЕНН 17/00, 02.20.2006.

5. Patent for a utility model of the Russian Federation No. RU 685651 U1, E04H 17/00, 11.27.2007.

Claims (18)

1. An engineering and technical barrier containing load-bearing racks and a protective sheet connected to them, characterized in that it further includes a hardware cabinet located inside a territory enclosed by a protective sheet and containing an autonomous backup power supply system and a climate control system of an autonomous system connected to it a backup power supply connected to the power supply network also introduced a linear radio wave detector, the receiver and transmitter of which are located on racks inside the territory and, enclosed by a protective sheet, and a sensitive cable element with a receiving unit, which is a triboelectric sensor, connected to the hardware cabinet, and the receiving unit of the triboelectric sensor has an adjustable sensitivity connected to the hardware cabinet. 2. The engineering barrier according to claim 1, characterized in that the autonomous backup power system contains a battery source of electricity, a charger and a first switch, the switched inputs of which are inputs of the autonomous backup power system, and the outputs are connected to a charger, the output of which is connected with a battery, the outputs of which are the outputs of the autonomous backup power system, and the control input of the first switch is its control input. 3. The engineering fence according to claim 1, characterized in that the climate control system of the autonomous power system contains at least one air temperature sensor, a microcontroller, one analog information input of which is connected to the output of the temperature sensor, the second information input of the microcontroller is connected with the output of the power supply network, its third information input is connected to the output of the autonomous backup power system, the first control output of the microcontroller is connected to the heating electric with a component thermocontactly connected to the battery of the autonomous backup power supply system, and also contains a temperature controller connected to the fourth information input of the microcontroller, and an indicator element connected to the second output of the microcontroller contains a second switch, the first switched inputs of which are connected to the power supply network, the second switched inputs with battery outputs, the outputs of the switch are connected to the power circuits of the device, and the control input of the second switch is connected to the third the course of the microcontroller, the fourth control output of which is connected to the control input of the autonomous backup power system, the inputs of which are connected to the device power circuits. 4. The engineering barrier according to claim 1, characterized in that the air temperature sensor is located inside the hardware cabinet. 5. The engineering fence according to claim 1, characterized in that the protective sheet forms a closed loop. 6. The engineering barrier according to claim 1, characterized in that it contains at least one gate located in the protective sheet, and the protective sheet with the gate forms a closed loop. 7. The engineering barrier according to claim 1, characterized in that the gate is equipped with magnetocontact sensors connected to a hardware cabinet. 8. The engineering barrier according to claim 1, characterized in that an additional gate is introduced, equipped with magnetocontact sensors connected to a hardware cabinet. 9. The engineering barrier according to claim 1, characterized in that the hardware cabinet comprises a door equipped with magnetic contact sensors connected to the hardware cabinet. 10. The engineering fence according to claim 1, characterized in that it comprises an infrared linear detector, the receiver and transmitter of which are located on racks on either side of the gate above the gate and are connected to the equipment cabinet. 11. The engineering fence according to claim 1, characterized in that it is made in the form of a kit, providing for a variation of the types of its constituent elements. 12. Engineering fence according to claim 1, characterized in that the protective fabric is made in the form of a grid. 13. Engineering fence according to item 12, characterized in that the kit contains a device for tensioning the protective sheet. 14. Engineering fence according to claim 1, characterized in that the protective canvas is made in the form of panels. 15. Engineering fence according to claim 1, characterized in that the protective canvas is made in the form of a combination of mesh and panels. 16. Engineering fence according to claim 11, characterized in that the kit contains a set of tools for mounting the fence. 17. The engineering fence according to claim 1, characterized in that it further comprises reinforced load-bearing racks located in the places of sharp bends of the protective sheet and connected to it. 18. Engineering fence according to claim 17, characterized in that the reinforced load-bearing racks contain load-bearing racks and at least one additional support connected at one end to the lower part of the load-bearing rack at a distance from its lower end close to the length of the additional support, and directed the other end down at an acute angle to the support column.

Images