RU2423573C1 - Protective barrier - Google Patents

Abstract

FIELD: construction. ^ SUBSTANCE: barrier net frame is made of separate parallel belts that consist of flexible steel cord sections, and ends of an upper belt cord are pulled into an inner cavity of a fixed support by means of a block and are fixed to a vertical shock absorber, and ends of a lower belt cord are attached to fixed stands by means of traction rods via bushing supports arranged in the inner space of stands and equipped with shock-absorbing elements, and intermediate belts made of flexible steel cord sections are fixed to each other with a shift by a step in the form of inclined crossing linear elements, forming rhombic cells of the net, besides, ends of these cord sections are fixed in nodal elements of the net in a hinged manner. ^ EFFECT: increased specific energy consumption and higher reliability and efficiency of facilities protection due to complex application of shock-absorbing elements that serially reduce intensity of impact action. ^ 2 cl, 6 dwg

Description

The invention relates to devices for protecting objects from the damaging effects of terrorist acts, when a structure perceives rarely occurring, but extremely intense shock loads that threaten the safety of life in crowded places.

It is known "Protective fence from rockfall" (ed. St. USSR No. 949042 from 08/07/82, E01F 7/04), containing fixed racks embedded in the ground and an elastic mesh fence mounted on shock-absorbing elements made of cables whose ends are attached to soil anchors. The disadvantage of this obstacle is the low efficiency of the structure as a whole and its individual elements to dynamic shock loads.

It is known "Elastic fence against rockfalls" (ed. St. USSR No. 1648256 from 07/31/85, E01F 7/04), which is formed by a grid attached to horizontal cables, with one end of each cable connected to the upper part of the rack, and the other with soil using anchors. The disadvantage of the boom is the low efficiency of the design of the device to dynamic shock loads.

Closest to the invention in technical essence and the achieved result is a "Device for protecting objects from dynamic impact" (ed. St. USSR No. 1678951 from 09/23/91, E01F 7/04), which contains supports and trellis fencing between them, made of double horizontally spaced beams fixed on flexible elastic ties. The disadvantage of this barrier is also the lack of effectiveness against the damaging factors of the dynamic impact, low operational reliability, exposure to environmental factors.

The aim of the invention is to increase the specific energy absorption and increase the reliability and efficiency of protection of objects due to the integrated use of shock-absorbing elements, consistently reducing the intensity of the impact.

This goal is achieved in that the frame of the fencing network is made of separate parallel belts, consisting of segments of a flexible steel cable, and the cables of the upper and lower belts are passed through the extreme nodal elements of the frame freely through contact, and the ends of the specified cable of the upper belt are passed into the internal cavity of the fixed supports by means of a block and are attached to a vertical shock absorber, and the ends of the cables of the lower belt are connected to the stationary racks by means of rods through the sleeve supports, located racks in the inner space and equipped with shock absorbing elements, and intermediate belts made of segments of a flexible steel cable are fastened to each other with a step shift in the form of oblique crossing linear elements, forming rhombic network cells, and the ends of these cable segments are fixed in nodal elements the network is articulated, and the extreme nodal elements of the intermediate belts are connected to the stationary racks using rods passed through the sleeve supports located in the inner space of the racks and abge shock absorbers; the specified fence from the elastic network is made with the possibility of folding from the deployed position to the storage position by changing the distance between adjacent belts; the specified fence is equipped with a locking device, with which it is fixed in the storage position, and after unlocking has the ability to move to the deployed position under the action of its own weight.

The essence of the invention is illustrated by drawings, where figure 1 shows the fence in the unfolded position, figure 2 - sleeve support in section; figure 3 - design of the extreme nodal elements of the network; figure 4 - design of internal nodal elements; figure 5 - design of a vertical shock absorber; figure 6 shows the boom in the folded position.

The design of the protective fence includes support racks 1, made, for example, of channels, connected by welding with their own shelves to form a box-shaped profile (section AA, FIG. 1). Each support column 1 on the side of the road passage has a gap for the passage of the cable 2 and rods 3 of the intermediate and lower zones of the network. In the upper part of the rack 1, there is a block 4 of the cable system of the tension of the boom network, passing the cable 2 of the upper belt of the network into the internal cavity of the support rack 1. A shock absorber 5 is vertically attached to the bottom of the support rack, to the rod of which is attached the cable 2 of the upper belt of the cable system of the network tension.

The frame of the elastic network 6 includes a cable tension system consisting of upper 7 and lower 8 network belts made of a flexible steel cable, the cable of the tension system attached to the stationary racks with the possibility of horizontal movement, and the ends of the cable of the upper belt are passed into the internal cavity of the stationary supports 1 by means of block 4 and are attached to a vertical shock absorber 5. The ends of the cable 8 of the lower belt are connected to the fixed posts 1 by means of rods 3 through sleeve supports 9 located in the inner m space uprights 1 and provided with damping elements.

The intermediate belts are made of segments of a flexible steel cable, fastened to each other with a step shift, forming oblique crossed linear elements 10 of a rhombic cell, the vertices of which are nodal elements 11, 12 - the points of fastening of the ends of the cable segments, the ends of these cable segments being pinched into the internal nodal elements of the network 11 are pivotally, and the extreme nodal elements 12 are connected to the stationary racks 1 using rods 3, passed through the sleeve supports 9 located in the inner space of the racks 1 and equipped with shock absorbing elements.

The sleeve support 9 (Fig. 2) structurally consists of a thin-walled body 13 of cylindrical shape mounted on a cylindrical section of the rod 3. Two disk springs 14 are placed inside the body, facing each other with large bases, an elastic-hysteresis element 15 made of non-woven is placed between them MP-type wire material (metal analogue of rubber), which has a high ability to absorb energy [1]. An energy-absorbing device is installed in the annular space formed by the inner surface of the housing 13 and rod 3 — a plastic shock absorber 16, which is made in the form of a cylindrical shell with support flanges, the outer surface of the shell of the shock absorber 16 has attenuating grooves 17, 18 of a given depth [2].

Nodal elements of the frame 11 and 12 are structurally different. The extreme nodal elements 12 (figure 3) are evenly distributed along the borders of the fence 6, they serve to connect with linear elements 10 of the frame and pass the cables 2, 8 of the fence network. The design of the assembly 12 consists of a welded housing 19, an eye 20 and a finger 21. The ends of the cables of the linear elements 10 are rigidly fixed with the thimble and the finger 21 in the eye 20. The internal node elements 11 (Fig. 4) serve to pass the cable lengths of the linear elements of the network 10 . The design of the node 11 consists of four cup-shaped washers 22 with transverse drilling for the passage of cables. Washers 22 are mounted on a centering rod 23 ending in thread. After the assembly of the assembly 11 and the passage of the cables 10, each pair of cups 22 is fixed by an intermittent weld, so that an articulation of adjacent linear elements is formed. After that, the site is scalded from the threaded part of the centering rod 23.

The vertical shock absorber 5 (Fig. 5) plays the role of a soil anchor, is placed in the inner space of the support posts 1 and is fixed to the base of the supports using foundation bolts. Structurally, it represents a shock absorber, the absorption of the impact energy in which occurs when the mandrel is pulled through a mutually contacting hole. The base of the shock absorber 5 is a mandrel 24, containing successively located deforming and smoothing elements 25. The annular space formed by the inner surface of the shock absorber body and the mandrel 24 is filled with metal washers 26 of different thicknesses. The rod 27 of the mandrel 24 is connected to the upper cable 2 of the network by means of an eye and a finger.

The design of the protective fence is deployed during the threatened period, and at normal times is minimized in the storage position. To do this, using an electromechanical winch (not shown in the drawings) attached to the rod 3 of the cable 8 of the lower belt of the boom, it rises to the upper position (Fig.6) and is fixed in this position using the locking device 28 [3]. The structure of the skeleton of the network 6, which forms rhombic cells, transforms more efficiently when compared with rectangular cells when folding the network into a storage position. In this case, the linear elements of the network 10 and the nodal elements 11, 12 located at the vertices of the rhombic cells form a hinged parallelogram kinematic mechanism.

The device operates as follows. At the required time, the locking device 28 manually or remotely activates and unlocks the fence, after which the fence unfolds under the action of its own weight, taking the form in figure 1, closing the protected passage or object.

When trying to unauthorized access to the protected object, the fence operates as follows. The efforts arising at the time of collision with the fence are redistributed between all elements of the fence. The dynamic effect is transmitted to the nodal 11, 12 and linear elements of the network 10, to the cables 7, 8 of the tension system, rods 3 and shock absorbing elements 5, 9. Since the cables 7, 8 of the tension system of the network 6 are mounted with the possibility of horizontal movement and are connected with shock absorbers 5, then at first the barrier network, elastically deformed, forms a receiving circuit in which the object of influence is localized. Then, elastic deformation of the linear sections 10 of the network frame — the cable segments attached to the hinge elements 11 and 12 — occurs, moreover, since they have different lengths, they are deformed differently - the cable segment is deformed more from the side facing the object of influence. These forces are transmitted from the upper cable 7 of the tension system through the blocks 4 to the shock absorbers 5, and from the intermediate belts and the lower cable 8 through the rods 3 and the sleeve supports 9 - to the shock-absorbing elements 14, 15, 16. Then, sequentially, as the intermediate guard belts turn on , the plastic shock absorbers 16 of the sleeve supports are deformed 9, as their bearing capacity is exhausted, the dynamic load is transmitted through the linear elements of the network 10 (cable segments) to the nodal elements 11, 12 of the network. In this case, the cables 10, stretching with friction through the holes in the cup-shaped washers 22 of the hinges 11, absorb a certain part of the dynamic load. At the last stage of protection, the dynamic load is transferred from the lower belts of the boom to the upper belts, including the upper cable 7 of the tension system, while through block 4 the load is transmitted to the vertical shock absorber 5. The mandrel 24 moves through a package of metal washers 26, accompanied by plastic deformation and cutting and smoothing the washers 26. The process of deformation of the barrier continues either until the collision energy is completely absorbed, or until the cushioning properties are completely exhausted, thereby ensuring um, the object of damaging factors of terrorism.

Thus, the process of damping the dynamic load when trying to unauthorized access to the protected object is ensured by controlled controlled elastic deformation of the network frame, in general, and plastic deformation of the cushioning elements of the fence: plastic shock absorbers of the sleeve supports of the fence belts, plastic deformation of the nodal elements of the network and plastic deformation of the vertical shock absorbers of the upper cable system tension.

The proposed device has several advantages that provide a positive effect, namely:

- with minimum initial dimensions, the fence has a higher energy intensity due to the use of shock absorbing elements using plastic deformation;

- the ability to set the required characteristic of the protective properties of the fence, changing the characteristics of plastic shock absorbers;

- the speed of deployment of the fence and the possibility of camouflage when folded.

Thus, in increasing the specific energy absorption and increasing the reliability and efficiency of protecting objects due to the integrated use of shock-absorbing elements, which consistently reduce the intensity of the impact, the positive effect of the proposed barrier design is specifically expressed.

Literature

1. A method of manufacturing a cone-shaped elastic hysteresis elements from wire materials. Auto St USSR No. 766714 B21F 21/00 dated 05/07/78.

2. Plastic shock absorber. Auto St USSR No. 846886, F16F 7/12, 1981.

3. High-speed latch lock. Utility model No. 88418 of November 10, 2009, by application No. 2009128646 F16L 59/22 of July 24, 2009.

Claims (3)

1. A security fence comprising fixed racks, a fence made of elastic network mounted on shock absorbing elements made of cables, the ends of which are attached to soil anchors, characterized in that the frame of the fence made of elastic network is made of separate parallel belts consisting of pieces of flexible steel cable, moreover, the cables of the upper and lower zones are passed through the extreme nodal elements of the frame freely through contact, and the ends of the specified cable of the upper belt are passed into the inner cavity motionless th support by means of a block and are attached to a vertical shock absorber, and the ends of the lower belt cables are connected to the fixed racks by means of rods through sleeve supports located in the internal space of the racks and equipped with shock absorbing elements, and intermediate belts made of pieces of flexible steel cable are fastened to each other with a shift by a step in the form of oblique crossing linear elements, forming rhombic cells of the network, and the ends of these cable segments are fixed in the internal nodal elements eti pivotally and nodal marginal zone intermediate elements are connected to the fixed uprights through rods, passed through the sleeve bearing disposed in the inner space of racks and provided with shock absorbers. 2. The security fence according to claim 1, characterized in that, the fence of the elastic network is made with the possibility of folding from the deployed position to the storage position by changing the distance between adjacent belts. 3. The security fence according to claim 1, 2, characterized in that the fence is equipped with a locking device, with which it is fixed in the storage position, and after unlocking it can move to the deployed position under the action of its own weight.

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