WO1980000044A1 - Conduits protected against sabotage,for security installations and installation thereof within a protection network - Google Patents

Abstract

Pneumatic or hydraulic conduits which form a protection against intruders, are connected to a detector which registers a possible variation of the pressure and sets off an alarm. With a view to preventing an interruption, for example, by crashing of the conduits, said conduits comprise a core (2) made of hard and resistant material, for example one or a plurality of steel wires and preferably a steel cable. Upon a crushing attempt inner channels remain (4) due to the limited capacity of extrusion of the core and pressure variations may be sensed by the detector. These conduits are used for making networks which are under pressure and may be used as sensors for the peripheral protection or as a protection for doors or stores. They form an obstacle against the penetration into a space or a local thus protected, which may be entered only after previous destruction. The resulting leak causes a pressure drop and consequently the setting off of the alarm.

Description

Anti-sabotage cables for security systems and their use for a security network

The invention relates to tubular lines for pneumatic or hydraulic security systems secured against sabotage and other malfunctions, which are either themselves used as sensors for the detection of disturbing events, or for the transmission of signals emanating from pressure-sensitive sensors. and the use of these lines for a safety network. Pneumatic or hydraulic security systems in the form of sensor systems are becoming more and more common for monitoring and securing areas of the terrain, doors, windows and interiors against intruders, for preventing escape in prisons, or for protecting against fire, chemical media, flooding, etc. mainly used because of their low susceptibility to false alarms.

For example, For perimeter protection, mats with tubular channels that are under excess pressure or hoses are laid underground, the change in internal pressure of which triggers an alarm in the event of a load caused by an intruder.

^G itter on the windows of prison cells are welded pipes from Stahl¬ which form a coherent Leitungssystan and also under internal pressure, so that triggered when sawing through by the pressure drop a signal You can see that the pneumatic locking principle is very. has a wide range of applications and can play an important role in securing objects in the public, military, industrial and civilian sectors, provided that it is possible to achieve a low susceptibility to malfunction and high security against sabotage.

In all of these security systems, the interior of the sensor which is to trigger the alarm must be connected via a line to a detector which registers any change in pressure. Thus, the connecting line rnύss together with the sensor a communicating, filled with gas or liquid form a closed system, which is in the idle state all under the same pressure and may be interrupted anywhere if it is to be operational. ^" The same applies if, as mentioned above, the line itself functions as a sensor.

This is the possibility of malfunction or tampering with the system. For example, the line to the detector must be interrupted by careful squeezing. Since the detector only responds to pressure changes which must also have a certain minimum value, but does not respond to the pressure as such, this squeezing, if it is carried out carefully and slowly, remains undetected, since the pressure change which occurs nevertheless always occurs below the response value of the detector remains. When the squeezing is complete, pressure changes can no longer reach the detector, and the security system is thus deactivated.

The present invention aims to avoid this disadvantage and has tubular pipes for pneumatic or hydraulic lines which are secured against sabotage and other malfunctions To create security systems that are characterized by the fact that they play inside. contain an insert made of a hard, high-strength and tough material, the play between the insert and the inner tube wall being dimensioned such that a flow conductance value which is still sufficient for the function of the securing system is ensured.

The first aim of the invention is therefore to prevent the line system from being completely interrupted by being squeezed off. The pneumatic or hydraulic pipelines described above, if they are not welded but braided into a latticework, consist either of soft metallic materials of high ductility, e.g. Copper or aluminum, or if they have to be flexible, or are used for fire protection, or are used as signal lines, usually made of plastic hoses reinforced with fabric.

In the case of metallic pipes, it is already with an insert that consists of only one wire, e.g. consists of a piano string wire, extremely difficult to squeeze the tube so that a hermetically sealed separation of the one tube section from the other is achieved. This is different with plastic hoses. Either a profiled wire with a cross-shaped or U-shaped profile or a steel cable made of at least three interwoven or strongly twisted steel cables, or even better a multi-layer steel cable, must be inserted so that enough continuous voids remain free when trying to squeeze, through which alarm-triggering pressure changes can continue to propagate.

In this case it is also advantageous to use the highest possible

OMPI Work inside pressure in order to also reliably exclude the possibility of sealing by softening or liquefying the plastic, with which the cavities could possibly be filled.

The invention further provides for the use of the tubular lines for a safety net. This will make it possible for the first time to develop new types of security systems, as described below.

The construction of the pipelines according to the invention is explained in more detail, for example, using the accompanying drawings; show it:

1 and 2 cross sections through lines, each with a layer of different cross section, in the initial state,

Fig. 3 shows a cross section through a. Line with an insert consisting of several strands, also in the exit condition,

4 - 6 the corresponding lines according to FIGS. 1-3 in the squeezed state,

Fig. 7 shows a cross section through a line similar to Fig. 3, but with an electrically insulated insert.

8 a conventional securing of a site, including the possibility of overcoming it,

9 the securing of this site by means of the security network according to the invention,

_ 10 is a view of the safety net,

11 details of the safety net,

12 shows a schematic illustration of the monitoring device,

13 shows a section through a frame of the safety net,

14 is a sectional view taken along the line A-A in Fig. 13,

15 the view of a roller shutter with the safety net,

16 shows a section along the line BB in FIG. 15. ^*

Figures 1 to 3 show a circular pipe 1 in the initial state, in which a medium (gas or liquid) is contained in the static pressure state (positive or negative pressure). In this line, an insert 2 with game 3 is shown for the inner wall of the pipeline; For the sake of simplicity, this game is shown as being present on all sides. The insert 2 is U-shaped in Fig. 1 and H-shaped in Fig. 2, while in Fig. 3 it consists of several strands 2 ', for example of individual wires twisted together. If the lines are squeezed, they deform, for example, to the cross sections according to FIGS. 4-6. The inserts are deformed in the process, but at least one free connecting channel 4 always remains. Although this can be narrow.

OMPI WIPO due to its brevity, it causes only a slight pressure drop. If the adjacent pipe section is deformed or even destroyed, the resulting pressure wave (it may also be a pressure drop) can propagate through the pinch point to the detector and trigger the alarm there.

It does not matter how the crimping pliers are attached to the line; their cheeks work e.g. in the figures from above and from below, the insert is deformed differently, but the connecting channel 4 is always retained, albeit in a different form.

It is assumed that the pipes are made of a ductile soft metal, e.g. made of aluminum. This is the more unfavorable case, since plastic tubes become so thin when squeezed because of the greater material displacement at the contact point on the insert that they are very likely to leak.

7 shows a pipeline in which the insert 2 'is electrically insulated from the pipe 1 by an insulation 5. Thus, in addition to its purpose of securing the channel or channels 4, the insert 2 'can also be used as the one conductor of an electrical two-wire monitoring system that is added for hydraulic or pneumatic monitoring. The other conductor is formed either by the pipeline 1 itself or by a second insulated inner conductor, not shown. A current interruption or short circuit caused by an intrusion, or the electrical change in capacitance between the two conductors then triggers the alarm.

Differential pressure converters or other pressure-sensitive means which emit an electrical signal are frequently used as detectors. This can then be routed to the control center via the electrical conductor in the pipeline.

The pneumatic or hydraulic lines according to the invention have an extraordinarily high level of security against sabotage or unintentional interruptions due to mechanical action. In this way, they make the principle of pneumatic securing practically applicable in the first place.

To secure sections of the site and public or private buildings and rooms against intruders, there are already a large number of surveillance systems based on various physical principles. Important criteria for the selection or usability of a surveillance system are the spatial arrangement of the objects to be protected, the possibility of accidental disturbances due to weather influences, animals and plants which could trigger a false alarm, and the possibilities for circumventing or sabotaging the surveillance system.

In addition to a low susceptibility to false alarms and the wish that the system cannot be shut down or bypassed by sabotage, there is also the requirement that, whenever possible, the periphery of the site or space to be protected, i.e. already when trying to overcome the first obstacle, e.g. fencing of a site or the limitation of a house or room by windows, doors, shutters, etc.

OMPI An intruder signals that countermeasures can be taken at an early stage or at least deterring optical or acoustic signals can be triggered.

Monitoring systems for windows and doors with hollow bodies which are under a pressure different from the ambient pressure are known. For example, it has already been proposed in US Pat. No. 1,665,651 to manufacture prison bars from steel pipe which is under excess pressure, so that when an attempt is made to break out during sawing, a pressure drop occurs which triggers an alarm .

Swiss patent 298 712 also proposes a protective grille under pressure, which is welded together from pipes, for the same task. In Swiss Patent No. 510 309, the same system is again proposed as an alarm device for windows and / or doors of prison cells and additionally for vault systems, pipes under pressure which are connected to a supply line which is also a signal line , are built into the safe wall.

US Pat. No. 3,961,328 also describes a pressure line made of rubber hose which is connected to the goods to be transported or a trailer when the goods are being transported from the driver's seat, so that a pressure drop occurs when the trailer or the goods are lost as a result of the line being interrupted and a signal is triggered.

A similar problem also exists with regard to preventing breakouts from prisons. An attempt to break out should also be signaled here. The surveillance systems for prisons are massive, heavy lattice structures made of welded steel pipes. Such grids can be considered for a limited area such as ^" windows of prison cells or vaults, but not for securing private buildings or public buildings, if only for aesthetic reasons, and even less for extensive protective fences for securing nuclear power ¬ works, military facilities or airfields.

Protective grids of this type would be very expensive and, because of their great mechanical stability, would also be easy to climb over. Above all, they are completely unsuitable where, e.g. A high degree of flexibility is required in the case of roller shutter security or * in the event of temporary securing of goods and objects, as will be shown later.

The break protection described in US Pat. No. 3,961,328 also does not teach how a pneumatic protection against intruders, saboteurs and breakouts must be designed. that it can reliably perform its task. It is only suitable for solving the problem described in the patent.

Although the invention uses the same principle of pneumatic security, it has a new way of practically realizing a surveillance system that does not have the restrictions mentioned and therefore can be used very universally and is also inexpensive.

According to the invention, this route consists in the use of the pipelines mentioned for a safety net, which is characterized in that the safety net consists of Mesh network exists, which is braided from these pipelines and that the pipelines are under a pressure which deviates from the ambient pressure, the change of which serves for signaling in the event of destruction or interruption of the pipeline system.

If no one had previously thought of using a braid of thin tubes of a few millimeters in diameter as a pneumatic security network according to the invention, this was probably due to the fact that mechanically stable systems were considered necessary for securing against breakouts and intruders , to overcome which a longer time is required than in a system made of mechanically weaker material, even though mechanically stable systems can be overcome quickly with today's tools and means. Furthermore, they were not aware that set especially with a braided from a pipeline in Gegen¬ the interwoven wires can be a welded grid no longer be resolved from each other ^■ while welds by sawed,. can, unless the welded pipes communicate via holes in the weld, which in turn requires a dense and therefore more difficult weld.

After all, if this thought was considered at all, the possibility was probably feared sabotage by pinching off or squeezing the thin cables. This problem is of particular importance and only if it can be solved satisfactorily can a pneumatic safety net fulfill its protective function in full.

To create a safety net or grid, thin pipes made of a ductile metal such as aluminum or copper, e.g. with an inner diameter of approx. 3 mm and a wall thickness of approx. 1 mm, or plastic hoses of similar dimensions, which can be reinforced with fabric. The mesh size is dimensioned so that a human body can no longer get through. It can therefore be 20 to 25 cm, i.e. relatively large, which makes braiding the net easier.

Without the additional loose insert according to the invention made of a hard, high-strength material, it would be easy for an intruder to cut out a passage in the network without the alarm system responding by squeezing all the tubes tightly around this zone. However, the insert according to the invention prevents such a procedure as described at the beginning.

You also have to take into account that when using metal pipes, the internal pressure is of the order of magnitude from 10 to 100 bar and when using plastic hoses in the order of 1 to 10 bar. Under these circumstances, the conductance, which leads to a sufficiently rapid pressure drop in the system if destroyed, is by far sufficient. The only requirement is that the insert lies loosely, ie with play in the pipe, so that the flow conductance is sufficient for the system to function. This insert also prevents the line from kinking during transport or during the manufacture of the nets and thus possible overloading of the pipes, which could lead to a weakening of the material.

The possibility of bypassing the alarm system by squeezing could also be prevented by connecting all the lines in series and by making a leak at the end of the line, through which air is constantly drawn in with a vacuum system and gas is blown out with a pressure system. An interruption in the line system would then be noticeable by the change in pressure immediately before this artificial leak. The disadvantages of this solution are, on the one hand, that vacuum or pressure is then constantly being generated, that is to say energy would be consumed, and, on the other hand, that it would have to accept a significant restriction in the free design and arrangement of the security network. It is important that a parallel connection of pipelines is permitted, especially because with very long pipe lengths with the pipe cross-sections suitable for processing, the flow resistances could reach such high values that the signal only

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O would get from the defective spot to the detector with great delay.

It is also important that nets can be braided from a relatively inexpensive raw material, which are light in weight, easily transported in rolls and fastened in place on the supporting frame or transported as finished lattice units and can be joined together at the installation site and then can be connected to one or more pressure lines coming from the control center via a few connection points.

The mechanical reinforcement by the insert gives the nets sufficient strength and elasticity against undesired mechanical influences even when using plastic hoses. On the other hand, when you attempt to climb over the grating, its flexibility transmits the forces to the suspension, so that, as will be shown later with examples, a target leak point is opened there and also in such a case when a limit value of the Load a signal is triggered. If this interruption is reversible, the safety network immediately fulfills its protective function again after the alarm is triggered.

From the large number of possible uses of the safety net, some important ones will be selected below:

The first example concerns the securing of the site of a large industrial object, for example a nuclear power plant, on its periphery. Fig. 8 shows common backup methods today and also the possible to overcome them. The terrain here is initially secured by the wire fence 6 at the outer border. 7 and 3 are microwave transmitters, of which a larger number must be installed on the perimeter of the site due to their limited range. The delimitation of the areas 9 and 10 _/ within which an alarm may be triggered when an object passes through the change in intensity of the microwave radiation at the receiver is indicated by dashed lines.

As a further safeguard, pressure-sensitive mats n and 12 are located in the floor which also trigger an alarm when an intruder enters, and finally an internal barrier is formed by a further chain link fence 13.

8 shows how these fuses could be overcome by means of a conductor 14. The intruder 15 could be the border area abseilen with the cable 16 'in the inner ^overall'.

9 and 10 show a solution with the security network according to the invention. In Fig. 9, which corresponds to the section AA 'in Fig. 0, there is again a normal chain link fence 17 at the outermost boundary. The previous inner fence 13 in Fig. 8 is, however, replaced by individual safety nets 18, 19, 20, 21, 22, 23, which are attached to frames made of hollow beams. The fence has a large projection upwards and is supported there with double T-beams 24. It also continues down into the earth at 23 to make it difficult to dig.

10 shows on the left how the network is connected to the hollow frames mentioned. The network is only hinted at in the middle and right row of frames. - 15 -

11 shows further details. The network is, as described above, braided from ductile metal tubes and has two ends 25 and 26 which are connected to the steel or aluminum frame 27, which is welded from tubes, and are sealed are screwed. The network is fastened with a second pipeline 28, the ends of which are also connected to the hollow frame at 29 and 30 and are screwed tightly together. In principle, the net could also be braided directly onto the frame. The attachment of a prefabricated network with a second pipe 28 is simpler in terms of production.

The construction of a fence with a large extension can now be carried out in such a way that prefabricated frame units are delivered with a network that has already been fastened and checked for leaks, and are assembled on site using seals at 31, 32, 33, 34. The frame system then forms a coherent, uninterrupted pressure system with a high flow conductance, in which the safety nets with a lower flow conductance lie in the bypass. One can therefore expect that the signal size in the event of damage to any network is practically independent of the location at which the compressed air is fed in. However, if you want to locate the location where the damage occurred, the security fence must be divided into separate sections, which are fed separately, each of which has its own control device.

12 shows how the monitoring device can be designed. 35 is a pressure bottle with a reducing valve

36. From there, the pressure line branches to the individual sectors that are to be monitored. In each branch line 38 39 leads to a respective differential detector ^"37, which is formed as a membrane switch

OMPI can be. The membrane switch 17 limits the membrane

40, the two spaces 41 and 42 which are connected to a Druck¬ lead 43 and a pressure discharge line 44 connected ^•. The latter leads to the safety net in the field. The two spaces 41 and 42 are connected via a throttle point 45, which compensates for slow pressure fluctuations, so that the membrane always remains in the neutral, sensitive position in the normal state.

Instead, a check valve "can also be installed, which closes in the event of an alarm and as the first irreversible element even when, as when climbing over the fence using the device shown in FIGS. 13 and 14, only over ¬ a leak occurs, maintains the alarm state and also avoids gas losses, however, in order to reactivate this branch of the safety system, the check valve must then be reset to the initial position.

If the safety net leaks, there is a permanent pressure drop at the throttle point. The membrane is deflected and actuates an organ for triggering an alarm, e.g. a capacitive or inductive proximity switch or a reed relay.

Additional protective devices can be provided so that exceeding the safety net leads to the alarm being triggered. FIG. 13 shows the upper left corner of a frame, such as is installed at 18 in the protective fence shown in FIG. Fig. 14 shows a section along AA in Fig. 13. The upper crossbar 46 of the frame, on which the safety net is suspended, is interrupted at both ends - the upper right corner of the frame being symmetrical to the left - and via an elastic link 47 - 17 -

with the rest of the frame _. 48 connected. In this rule elasti¬ member 4 are desired leakage points 49, 50, 51, 52, which communicate with the cavity of the cross piece 6 in connection, which in turn communicates with ^'53 with the rest of the frame ^* 48th

These leaks are normally sealed by means of a cylindrical rubber ring 54, which in turn is held in an elastic, thin-walled spring tube body 55. 4 support elements 56, 57, 58, 59, which are fastened to the part 60, engage in the annular sealing sleeve and carry the tube 46. If the pipe is additionally loaded in any direction transversely to its axis, the sealing collar yields and one or two of the target leak points open and trigger an alarm due to the pressure drop which arises in the process. If the additional weight load disappears, the tube 46 returns to the starting position and the leakages close.

The tube 46 should be as light as possible. own and is therefore conveniently made of light metal. The spring 55 is dimensioned such that additional loads caused by snow or ice cannot yet trigger the alarm. Only loads of the order of 10-20 kp, as are caused by an intruder, cause the target leak points to open.

This fuse normally only needs to be attached to the top crossbar of a fence, i.e.. only there, where the danger of exceeding becomes acute. If a ladder were placed on the fence, an alarm would also be triggered. - 18 -

It is important that the fence constructions described above cannot be influenced in their protective function by weather, birds, projectiles or other vibrations. At a lower height, they are also suitable for securing private property. Since the fence is mechanically very stable, it can also be used as an external property boundary.

Another example of the use of the security network is the protection of shutters on doors and windows against intruders. The high flexibility of * safety nets made of plastic pipes enables the installation of such nets on the back of roller shutters and the rolling up and down together with the roller shutters. 15 and 16 show an example. Fig. 16 corresponds to section B-B in Fig. 15. In the view (FIG. 15), the closure cover 80 shown in FIG. 16 has been removed and in FIG. 16 the lower part of the safety net .61 '(FIG. 15) is again not shown.

The figures show how the net% 61 is wound onto the cylinder 62 ' _/ via which the roller shutter 63, which consists, for example, of light metal tubular profiles

64, 65, 66 • is suspended. At the lower end of the roller shutter is a metal tube 67 .. which, when the roller shutter is closed, is connected at 68 and 69 via seals 70- and 71 via check valves with the pressure supply line 72 and the return line 73 to the monitoring central is connected. The ends of the mesh are tightly connected to the pipe at 74th and 75th and the whole forms a coherent pipe system. With brackets 76 and 77, which grip over the connecting pieces 68 and 69 ^' , and by means of the eccentric levers 78 and 79

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the seals 70 and 71 can be clamped when the roller shutters are closed. In order for the net to remain taut, a pawl 82 engages in a slot 81 in the tube 62 in the end position of the roller shutter and is biased by springs 83, 83 '.

If the line is pressurized, it can be checked by opening the return line at its end in the monitoring center whether the security system is functional, i.e. is really closed and has not been made ineffective by clogging the connections at 70 • and 71.

If an attempt to circumvent the safety net side, this can not happen 78 and ^'79 without solution of the closures, in which case a leak immediately arise as any other damage and would cause alarm.

When the roller shutter is open, the safety net is no longer visible. The external and internal image of the rooms secured in this way is therefore not impaired by the security system. It is therefore also suitable for private rooms, shops and showrooms. If protection is required "^'only in the times when the shutter is let down, then there is no need monitoring devices in the windows and doors installed itself.

This securing device is particularly important and valuable if there is no possibility of installing the protective fence according to the invention or if an additional second securing device, which is based on the pneumatic principle, is desired. You can then do the same pressure generating and monitoring system for both protection ar ^'th use. Another application example is the securing of valuable goods against theft, for example in a warehouse or outdoors, and the protection of valuable operating equipment against sabotage. This can be done in such a way that a safety net made of plastic tubes covers the goods or operating equipment and the frame between which the net is stretched, which also consists of plastic tubes with an insert, is above the target in several points - Leak points attached and, like the ends of the network, connected to a pressure line which is installed underground. The plastic line forming the frame must be stretched tight between the fastenings so that it cannot be raised without opening the line system.

The last example is the possibility of securing a vault. In principle, it is done in the same way as the securing of goods just described, in that all walls, the ceiling and the floor are covered with safety nets, whereby the ring lines to which the individual nets are attached or suspended each cover one wall, best along the corners, where the walls meet, installed and again provided with the necessary number of target leak points, at which the attachment takes place at regular intervals. Wiede is on one. Place each ring line and the associated network connected to a pressure line. The networks can e.g. be covered with plastic plates so that they are invisible.

This makes it impossible to enter a vault in any direction. You get a much cheaper and more reliable security system than e can be created by concrete reinforcement or infrared, ultrasonic or microwave barriers. It can also remain in operation permanently and not be disturbed by working in the safe.

The doors to the vault or doors to apartments and business premises can also be protected in the same way as the roller shutter security by a safety net that is built into the door panel. The same security principle can also be used for walls and doors in prison cells.

These examples show that the security network according to the invention has numerous advantages over known security methods, in addition to its versatility for protection against intruders: possibilities of sabotage are practically excluded. Accidental false alarm is not possible. The protective effect begins at the outermost periphery of the space to be protected. It is easy to install; no trained specialists are required for this and for the operation. It cannot be influenced by weather or mechanical influences that are not aimed at destroying it. Rain, wind, snow, ice and fog and moving animals or plants or vibrations have no influence on the system. It has no electricity and energy consumption. Large areas over long distances as well as individual rooms can be secured. The. System can be set up completely pneumatically without power supply if pneumatic alarm devices, such as sirens _, are used. Because no electrical or ^'magnetic fields are present, the system can be disturbed neither tracked nor. - 22 -

The simple mechanical structure makes the system very reliable. There are clear and unambiguous signals that do not require amplification. If it is not used as a protective fence, it can be installed invisibly. Several types of protection based on this principle can be operated in parallel with the same supply system.

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Claims

Patent claims

1. Tubular lines for pneumatic or hydraulic security systems secured against sabotage and other malfunctions, characterized in that they contain an insert made of a hard, high-strength and tough material with play inside, the play between the insert and the inner pipe wall is dimensioned such that a flow conductance value that is still sufficient for the function of the safety system is ensured.

2. Pipes according to claim 1, characterized in that they are made of soft metallic materials of high ductility such as Copper or aluminum exist.

3. Pipes according to claim 1, characterized in that they consist of plastic.

4. Pipes according to claim 1, characterized 'in that they contain a profiled wire with a cross or U-shaped profile as an insert.

5. Pipes according to claim 1, characterized in that the insert consists of several twisted or braided wires.

6. Pipes according to claim 5, characterized in that the insert is a steel cable.

7. Pipes according to claim 2, characterized in that the insert is electrically insulated from the jacket and is used as an electrical signal line for a sensor.

8. Pipes according to claims 2 and 7, characterized in that the insert is the one conductor of an electrical two-wire monitoring system with an alarm device reacting to power interruptions or changes in capacity, the pipeline or a second insulated inner conductor forming the other conductor.

9. Use of the pipelines according to claim 1 in a pneumatic security network for securing rooms, areas and objects against intruders and saboteurs and / or for escape protection from prisons, characterized in that the security network consists of a mesh network consisting of these pipelines ¬ is braided and that the pipelines are under a pressure which deviates from the ambient pressure, the change of which serves for signaling when the pipeline system is destroyed or interrupted.

10. Use according to claim 9 in the form of a fence, characterized in that when the mesh is loaded by the weight of an intruder, a target leak in the fastening frame of the network is opened by the crossbar of the hollow fastening frame loaded by the intruder with the spring the rest of the hollow frame is connected in such a way that displacement is possible when the network or the crossbar is loaded.

S which leads to the opening of one or more target leak points.

11. Use according to claim 9, characterized in that the safety net is used as a roller shutter security for windows, doors, shop windows and the like by being made of flexible plastic tube attached to the back of the roller shutter so that it is wound up and unwound with it and that it is connected to a pressure line coming from the monitoring center at at least one point at the lower end of the roller shutter when the roller shutter is closed.

12. Use according to claim 9, characterized in that the safety net is stretched over the walls, ceilings and floors of the rooms to be secured as a barrier against intruders and breakouts.

13. Use according to claim 9, characterized in that the safety net made of flexible plastic tube to protect goods. Goods and other valuable objects against theft. Damage and Sabo¬ day on the protected object ^• is unclamped.