EA008357B1 - Device for protecting buildings or installations - Google Patents

Abstract

The invention relates to a device for protecting buildings or installations from external influences by means of wire cables that are stretched around at least part of the building or installation. According to the invention, the wire cables are subjected to a tractive force, and the ends thereof or the extensions thereof are arranged in a clamping body comprising a guide that is embodied in such a way that, when the tractive force increases, the resistance force (reaction) opposed by the clamping body grows in an essentially proportional manner.

Description

The present invention relates to a system for protecting buildings or structures from external influences using wire cables placed under tensile stress at least over a part of a building or structure and / or around it.

Such a system is described in patent ΌΕ 10155174 A1. In order to protect specific buildings (or structures) from external influences, such as protecting chemical plants that contain highly toxic or explosive materials, facilities of nuclear power plants or important public buildings, it is proposed to stretch wire cables around the buildings (or structures) with tensile stress, at least 5 mm. The purpose of this design is to protect buildings (or structures) from intentional collision of aircraft with them.

It is known that when an aircraft collides with an object (intentionally or accidentally), wire cables have a cutting effect on the elements of the aircraft, as a result of which the cables absorb a significant part of the kinetic energy when the aircraft strikes and cause preliminary damage to the aircraft or destroy it. When an aircraft collides with wire ropes, any inevitable explosion occurs at an earlier stage, i.e. before the aircraft reaches the object (much earlier if the wire ropes are located at a sufficiently long distance from the building), as a result of which the effect of a blast wave on the building can be significantly limited. Wire cables installed under tensile stress cannot prevent damage to parts of an aircraft building or structure, but the scale of damage received will be much smaller than in a direct collision, in which the aircraft actually pierces a building or structure, which is accompanied by fuel spills and fires. The specific shape of the cables, in particular, the distance between them, the distance of their placement from the building, their diameter and thickness can be selected appropriately depending on the required protection conditions and on the degree of reconstruction of buildings, which can be carried out at reasonable costs.

A prerequisite to achieve the cutting effect of wire cables, accompanied by a protective effect of the system, is to prevent the cable from breaking. In the above document, it was proposed to appropriately fasten the wire cables to elastic bodies (devices), preferably to coil springs in order to increase the elasticity of the wire cables under tensile stress. However, in practice, an extremely difficult problem is the creation of elastic devices that have directivity constants, which determine the recovery force, and which constants are optimal or remain optimal over time. These problems are characteristic not only of the protective systems offered in the above publication, but they are encountered in any situation where the task is to securely and stably secure and tension the wire cables in the locking mechanism.

The aim of the present invention is to create a system for protecting buildings or structures from external influences using wire cables placed under tensile stress at least over a part of a building or structure and / or around it in such a way that, as the tensile force increases, the cable (acting force), the fixation mechanism created a resistance force (opposing force), while ensuring that the resistance force optimally corresponded to the acting force.

To achieve this goal, a system is proposed that combines the features of claim 1, in which, in accordance with the invention, the wire cables are constantly under tensile stress, and their ends or their extenders are fixed in a clamping device or similar device equipped with a guide given such a form that with an increase in tensile stress, the opposing force created by the clamping device increases mainly in proportion to the tensile stress.

Additional solutions are proposed, each of which will be described separately below. First, it is possible to make a (conical hollow tubular) guide of the conical shape for the end of the wire rope and (or) wire rope extenders in such a way that, in a substantially unstressed or only partially stressed state, the outer surface of the wire rope rests on the inner surface of the guide or is at a distance from her When a tensile force is applied to the cable, it is pulled into a conical shape, additional friction first occurs, and then actual deformation occurs. Such a solution can be provided purely geometrically by the cable and guide design, in some cases the solution can also be provided mechanically, and for this purpose an active mechanism is used, controlled by, for example, a system for measuring movement so that the control is carried out by narrowing and / or reduce the size of the inner surface of the guide. The example is similar to the example with extension cords attached to the ends of the wire rope, the extension cords of which may have various shapes, for example, a plate shape.

In accordance with another embodiment of the invention, the material of the inner surface of the guide for a wire rope (or cable extension) is chosen so that its hardness is higher than the hardness of the material of the end of the wire rope and (or) the material of the extension cord

- 1 008357 ca; thanks to this, when a tensile force is applied to the end of the cable or the end of the extension, the end is pulled into a guide having a tapered shape and the end is deformed, as a result of which it acquires a smaller outer diameter. It is preferable to adjust the corresponding diameters so that practically the deformation of the wire rope (or extension) occurs at the moment when it makes a relative movement inside the guide in the direction of the tensile force.

In general, it is also possible to divide the ends of the wire cable into several separate cable elements spaced apart from each other in such a way that the ends of the wire cable form a conical end portion of the wire cable.

The guide in the holding device is formed by a conical tube, or a channel having a closed peripheral part, or clamping devices arranged at mutual angles or spring-loaded rollers.

The ends of the wire cables or extension cables of the wire cables can also have configurations that represent several multi-stage diameter increases, due to which stepwise plastic deformation of the wire cable occurs when a tensile force is applied to the wire cable. If the diameter of the end of the wire rope expands gradually (stepless), then in this case, depending on the materials and their degree of deformation, the counteracting force increases mainly in proportion to the increase in diameter. In accordance with a comparable configuration, a stamp is proposed, for example an exhaust stamp, and a material with a larger diameter is pulled through the stamp and its reduction in diameter occurs. Basically, the resistance exerted by the forces creating the deformation should be the same for all cables designed to protect buildings or structures. Nevertheless, in special cases it is possible to create different cables of different opposing forces, and for this purpose you can choose a configuration in which one or several cables will break before other cables, due to the fact that they are under less stress. If there is a regulating device for regulating the indicated differences of the opposing force, under certain circumstances this feature can be used to change the flight path of the aircraft, which has a shock effect.

Within the scope of the present invention, it is also possible to connect several cables to a flat plate fixed in a fixation system (for example, a fastening system) and having such a shape that its width increases with distance from the end with which it is connected to the cables. The plate may be wound, for example, on a roller. When a tensile force is applied to the plate through the cable (s) connected to it, the plate can make a relative movement in the direction of the applied force only due to the deformation.

In order to increase the cutting impact, it was also proposed to apply hot-pressed abrasive cutting material to the surface of wire cables, at least in some areas, or to provide cables with hooks or teeth or similar tearing or cutting devices. In another embodiment of the invention, the wire cables may have an oval or blade shape in cross section, similar to the shape of a knife blade. Similar to the cutting edge of a knife, the cutting edge of a wire rope can be provided with a wavy or sawtooth edge in order to optimize cutting ability. The concept of the invention also includes the possibility of passing through a high-voltage wire cable or setting explosive charges in order to achieve the maximum possible destructive impact on an aircraft colliding with an object. The greater the destruction of the aircraft outside the building, the less likely it is that the aircraft and its dangerous fuel (kerosene) will penetrate inside the building. Fuel is dangerous because it has the ability to ignite and the fire spreads from it throughout the building. For example, in the case of the World Trade Center towers, it was the fire and the high temperature it created that had an impact on their supporting structures that led to the collapse of the towers.

In accordance with another embodiment of the invention, for the purpose of protection, wire cables may be located inside a facade or roof of a building and / or on a facade or roof.

The arrangement of wire cables inside the facade and / or roof of a building that needs protection does not only hide cables from unauthorized persons, but also ensures safe and secure storage of wire cables during periods of time when a building or structure does not need protection from external influences. Thus, it is possible to avoid the circumstances in which intentionally or otherwise damage occurs from external influences of the system as such, in which the wire cables are under constant tensile stress.

Preferably, for the purpose of protection and preservation, wire cables are laid in profiles installed inside the facade and inside the roof, for example, during the reconstruction of an existing building or structure, profiles can be installed outside on the facades and (or) on the roof. These profiles form a recess individually or in combination with the structures of the facade. To ensure the tension of the wire cables they push out of the recesses.

Profiles installed inside the facades and (or) roofs or on them for laying wire in them

- 2 008357 cables, included in the design of facades and (or) roofs or adapted to existing structures so that they were included in the design of facades and (or) roofs and not perceived as elements that spoil the appearance of the building (structure). In particular, the deterioration of the appearance of public buildings or structures that carry a representative function is undesirable.

In addition, the system in accordance with the invention can be specifically and intentionally used as a decorative element.

In accordance with a specific embodiment of the protective system, a restraint in which the end of the wire cable or wire cable extension is held is connected to the building or structure with the possibility of translational movement. In addition, T-rails or similar structures can be buried in the ground around a building or structure, while fastening devices and (or) moving carriages for mounting fastening devices in them can move along the rails. Moving a fastener or carriage along rails in a direction away from a building or structure, while the upper ends of the wire cables are attached to the upper portions of the facade, either to the roof or to the central mast installed on the roof, causes the wire cables to move out of its normal installation position and placed under tensile stress. In the event of a wire rope breaking, several other wire cables are located next to each other in the recess, while the cables can be alternately tensioned so that the tensioning process is repeated and the system is brought to the level of functionality. In this regard, the carriage can be equipped with a grip similar to the grip mounted on aircraft carriers (airplanes), so that when the tensioned cable is broken, the carriage can return, grab the next cable, pull out the next cable and place it under tensile stress.

In accordance with a preferred embodiment of the invention, the wire cables are connected to profiles installed in the facade sections and (or) roofs and capable of performing rotational and (or) rotational and (or) translational movement so that, by acceptable movement of the profiles, the wire cables are pulled out storage areas from damage and placing them under tensile stress. In accordance with the indicated embodiment of the invention, the wire cable and / or profile may not be located in close proximity to the ground surface in order to provide access to access roads and road traffic sections around the building. It also helps prevent possible injury to people from wire ropes stretched near the ground.

In accordance with an example embodiment of the invention, a frame structure is proposed that is located outside the main facade of the building and serves as an additional facade. The frame structure can be mounted on the rails to ensure its rotation and (or) translational movement so that the position of the frame structure can be changed in relation to the building or structure, for example, increasing the distance between the frame structure and the building or moving the frame structure around the building . Wire ropes are placed inside the frame structure, and, if necessary, they can be pulled out of the frame structure and stretched in the form of a screen. Wire ropes can be oriented horizontally and (or) vertically and (or) diagonally (for example, at a certain angle), mesh structures can also be created.

The frame structure, located on the outside of the facade, can perform additional functions, for example, it can be located masking elements or shading elements; and / or spotlights to illuminate a building or structure at night. Frame construction can be used as an architectural element, and it must be included in the design of a new building or structure with which it will be used. Architecturally, even existing buildings can be strengthened by installing an appropriate frame construction.

The advantage of the described system is that it is equipped with a central control device connected to the warning system. When a hazard warning is received, the system is switched on manually or automatically, and the wire cables are pulled out of their installation positions and placed under tensile stress. If the wire cables are attached to the profiles, during the subsequent rotational and (or) rotary and (or) translational movement of the profiles, an alarm is triggered so that people in this area, in particular, people who may be on the system’s moving path, are alerted about this and had the opportunity to leave the danger zone in a timely manner.

Examples of the implementation of the system in accordance with the invention is illustrated in the accompanying drawings:

FIG. 1 is a schematic drawing of the end of a wire cable held in a clamping device guide;

FIG. 2 is a schematic drawing of a building with pull-out and deployable profiles on

- 3 008357 plot of the roof;

FIG. 3 is a schematic drawing of buildings with roll-up profiles on the roof section;

FIG. 4 is a schematic drawing of a building with fan-shaped profiles that open outward on the roof section;

FIG. 5 is a schematic drawing of a building with progressively opening outwardly opening profiles in the facade of the building;

FIG. 6 - frame construction installed outside the facade, with the possibility of rotation and (or) translational movement;

FIG. 7 - frame construction, located on the outside of the facade.

The clamping device 10 illustrated in FIG. 1, provided with a guide 11 with an inner conical surface. The wire cable has a small diameter section 12, a middle section 13 with a conical mate and a cylindrical end section 14. When the wire cable moves in the direction indicated by the arrow 15, when a tensile force is applied, the conical outer surface 16 of the middle section 13 is pressed against the inner conical surface 11 of the guide , as a result of this, further movement of the wire rope in the direction indicated by arrow 15 is possible only if plastic deformation of the wire wire takes place wasp and the formation of smaller diameter. The fastening device for wire rope in accordance with the present invention provides a relatively strong, reliable and non-rigid fixation with sufficient flexibility with a significant increase in tensile force, thereby preventing the cable wire from breaking, which could be the case when using a fully rigid clamping device. On the other hand, the clamping device is not so elastic in the case of using spring-loaded fastening devices or fastening devices that show compliance over time during use. In particular, the advantage of the proposed fastening device for wire rope is that the unwanted vibrations and vibrations that may occur when using spring devices are largely eliminated.

In an alternative embodiment of the invention, the mating areas of the outer surface 16 may be made stepped. The clamping system 10 may consist of clamping jaws with a constant or adjustable gap. The end of the wire rope can be connected to the plate-shaped extension, while the extension may have areas that are deformed when moving through the clamping system 10.

Building 21 shown schematically in FIG. 2 is provided with vertically positioned profiles 22, which are a device for protecting the wire cables from damage. The operation of the system in accordance with the invention can be illustrated by the example of this wire cable 23 being under tensile stress. In order to apply a tensile force to the wire cable 23, the profile 24, located on the section of the roof to which the upper end of the wire cable 23 is attached, extends outward in the direction indicated by the arrow and turns upwards in the direction indicated by the arrow “b”. When the profile 24 is moved, the wire rope 23 is pulled out of the receiving device and placed under the tensile stress. The lower end of the wire cable 23 is held in the receiving device with the possibility of translational movement, and it moves in the direction indicated by the arrow "c".

FIG. 3 illustrates a variant of the system shown in FIG. 2. Instead of sliding outward profiles, the swivel profiles 25 rest on the central mast 26 and form a generally conical roof. In general, the conical shape is determined by the basic shape of the building, which does not have to be a circle. In order to accommodate the wire cable 23 under tensile stress, the profile 25 turns outward from the top of the mast in the direction indicated by the arrow "b". A simultaneous movement of the wire cable 23 connected to the free end of the profile 25 occurs. As a result, the lower point of the wire cable 23 is progressively moved in the direction indicated by the arrow “c”, similarly to that described in the embodiment of FIG. 2. The upper end of the wire cable 23 is connected to the top of the mast 26. In order to provide additional length of the wire cable, the upper end of the wire cable 23 can also be placed in the mast, and a wire rope should be extended to create tensile stress.

FIG. 4 illustrates a system in accordance with the invention, consisting of mating profiles 27 located in the plane of the roof, with the profiles having the ability to turn upward in a fan-like direction in the direction indicated by the arrow “e”. With such a rotary movement, the wire cable 23 is simultaneously moved and pulled out of its storage area from damage, flush with the roof surface.

In the configuration of FIG. 5 wire cables placed in the plane of the facade. Profiles 28 are placed on the facade in such a way as to ensure their translational movement in the direction indicated by the arrow "£" while simultaneously turning in the direction indicated by the arrow "d".

- 4 008357

The wire cables 23 are attached to the free ends of the pivot supports of the profile 28, as a result of which they are gripped and placed under the tensile stress. FIG. 6 translational movements of the profiles 28 are illustrated on the left side, while pivoting movements of the profiles 28 are illustrated on the right side.

As variants of the above configurations in FIG. 6 and 7 illustrates the frame structure 29, 29 'located outside the facade, while the position of the frame structure varies with respect to the building.

FIG. 6 illustrates the frame structure 29 located at a distance from the building 21. Wire cables 23 are placed in the side part of the frame structure 29. The ends of the wire cables, in this case the lower and upper ends, are fixed in the frame structure 29 with the possibility of translational movement so as to provide pulling the wire cables from their protective sections in the form of a screen in the direction indicated by the arrow “ί”. The frame structure 29 can move along rails 20 installed in the ground and along a circular path around building 21 (see arrow “11”). Frame construction 29 may be located in the form of a protective screen, for example, to protect a specific area of the building.

FIG. 7 illustrates a generally rectangular building. However, in principle, the building can have any shape. The frame structure 29 'is able to move outward from the building 21 in the direction indicated by the arrow << p> along the rails 20 installed in the ground. Due to this movement, the distance between the frame structure 29' and the building 21 is increased. Similarly to the configuration of FIG. 6, the wire cables 23 are arranged in the side part of the frame structure 29 ', and if necessary they can be pulled out.

The use of the system in accordance with the present invention is not limited to either the specific basic form of the building or structure, or the specific structure of the facade or roof. Thus, the system can be adapted for use on existing buildings or structures. In addition, a combination of the described configurations or embodiments of the invention may be used, for example, the use of a combination of configurations of FIG. 4 and 5 for high-rise buildings. The roof and the upper part of the facade are protected by the system of FIG. 4, while the downstream areas are protected by the system of FIG. five.

Claims (19)

CLAIM 1. A system for protecting buildings or structures from external influences using wire cables placed under a tensile stress at least over a part of the building or structure and / or around it, characterized in that the wire cables are constantly under tensile stress, and the ends or their extenders are fixed in a clamping device or similar device (10) provided with a guide (11), which is shaped such that, as the tensile force increases, the opposing force created by the clamping means (10) increases substantially in proportion to a tensile force. 2. The system according to claim 1, characterized in that the guide (11) for the end of the wire cable (13) and / or the extension of the end of the cable is provided with a peripheral surface gradually tapering in the direction of the tensile force and preferably having a conical shape. 3. The system according to claim 1 or 2, characterized in that the material of the inner surface of the guide (11) of the clamping device (10) has a higher hardness than the material of the end of the wire rope (13) or the material of the extension of the end. 4. The system according to claim 3, characterized in that the wire cable or its extension is plastically deformed with relative movement inside the guide (11) in the direction of the tensile force (15). 5. System according to one of claims 1 to 4, characterized in that the end of the wire cable or its extension is divided into several separate cable elements located at an acute angle relative to each other. 6. System according to one of claims 1 to 5, characterized in that the guide (11) for a wire rope or for its guide consists of several clamping devices or spring-loaded rollers mounted at separate mutual angles. 7. The system according to one of claims 1 to 6, characterized in that the extension cable wire consists of a plate body, preferably wound on a roller. 8. The system according to one of claims 1 to 7, characterized in that the wire cable or its extension is provided with several stepped widening or continuous broadening. 9. The system according to one of claims 1 to 8, characterized in that different cables have different opposing force or different tensile strength. 10. System according to one of the claims 1 to 9, characterized in that the wire cables (23) can be placed inside the facade or roof or on the facade or roof of a building or structure in order to protect it from damage. - 5 008357 11. The system according to one of claims 1 to 10, characterized in that the frame structure (29, 29 ') is located in front of the building or structure, due to which an additional front surface is formed, in which wire cables can be placed to prevent damage. 12. System according to one of claims 1 to 10, characterized in that the profiles (22) installed on the facade or the roof, or inside the facade or the roof, form indentations in which wire cables are laid to prevent damage. 13. System according to one of claims 1 to 12, characterized in that the clamping device (10), in which the end of the wire cable (23) or its extension is held, is connected to the building or structure with the possibility of performing translational movement. 14. The system according to one of claims 1 to 13, characterized in that the wire cables (23) are connected to profiles (24, 25, 27, 28) installed on the facade or roof, or inside the facade or roof, and can be rotated, unfold or make translational movement. 15. The system according to one of claims 1 to 14, characterized in that the profiles (24, 25, 27, 28) carry out the extension of the wire cables (23) from the sections of the storage of the wire cables and their placement under the tensile stress due to the rotation, unfolding or progressive movement of profiles. 16. The system according to one of claims 1 to 15, characterized in that the profiles (22, 24, 25, 27, 28) and / or frame structures (29, 29 ') mainly consist of metal. 17. The system according to one of claims 1 to 16, characterized in that the wire cables placed under the tensile stress, form a mesh structure. 18. The system according to one of claims 1 to 18, characterized in that the central control device is installed to ensure the rotary, unfolding and translational movement of the profiles (24, 25, 27, 28) and (or) frame structures (29, 29 ' ). 19. System p. 18, characterized in that the control device is connected to the warning system (alarm system).