EP0589080A1 - Safety net - Google Patents

Abstract

A safety net, consisting of crossed ropes (2, 3), in particular steel wire ropes, which are interconnected at their respective crossing points (4) by means of connecting elements (5) which, as dynamic force transducers, form energy-absorbing elements at the respective crossing points (4) of the safety net. <IMAGE>

Description

The invention relates to a protective network consisting of crossed ropes, in particular steel wire ropes, which are connected to one another at their respective crossing points by connecting elements.

Protective nets of this type, known for example from EP 0 428 848 A1, are used to secure mountain slopes against exits, such as mudflows, to protect rock walls, in particular brittle rock walls, against stone chips, and also serve as safety nets for avalanche protection structures. Steel wire ropes are used in particular. However, plastic ropes, e.g. Nylon ropes can be used. One rope or several ropes with square or diamond-shaped meshes can be processed to form a network. The connecting elements can be formed as pressed-on metal plates. Two connecting wires, preferably steel wires, are used as further connecting elements at the crossing points, which are wound crosswise around the cable parts adjacent to the crossing point.

The ropes used for such protective nets have a high breaking strength and relatively high elasticity, so that those made from the ropes Networks are able to absorb high energies, such as moving boulders or avalanche snow masses.

The object of the invention is to provide a protective network of the type mentioned, the energy absorption capacity is significantly increased.

This object is achieved in that the connecting elements as dynamic force transducers form energy-absorbing elements at the respective crossing points.

The respective connecting elements can be deformable in the form of brackets encompassing the rope crossing points or in the form of the connecting wires wound at the rope crossing points around the rope parts adjacent to the rope crossing points due to the dynamic force absorption perpendicular to the plane in which the network is spread out.

In such a protective net, the elasticity of the rope forming the protective net or the ropes forming the protective net is advantageously not impaired by the connecting elements at the crossing points of the ropes. Rather, the crossing points are designed so that they also act to destroy kinetic energy of objects caught by the protective net by dynamic force absorption. The connecting elements thus form a multitude of dynamic brakes, which form energy-absorbing elements at the respective rope crossing points. The connecting elements thus have a double function, namely the connecting function at the rope crossing points and the Energy absorbing effect through dynamic force absorption in the destruction of kinetic energy of the objects caught by the network. This kinetic energy can be destroyed by elastic or inelastic deformation of the respective connecting element. The greater the deformation in the direction of the kinetic energy, the lower the maximum force that is exerted on the network. This results in a significant increase in functional reliability and the lifespan of the protective network.

Figur 1:

ein Schutznetz in Draufsicht;

Figur 2:

eine Kreuzungsstelle des Schutznetzes in einer perspektivischen Darstellung von schräg oben;

Figur 3:

die in der Figur 2 dargestellte Kreuzungsstelle von unten; und

Figur 4:

die in den Figuren 2 und 3 dargestellte Kreuzungsstelle nach dynamischer Kraftaufnahme.

Based on the figures, the invention is explained in more detail using an exemplary embodiment. It shows:

Figure 1:

a protective net in top view;

Figure 2:

a crossing point of the protective network in a perspective view obliquely from above;

Figure 3:

the intersection shown in Figure 2 from below; and

Figure 4:

the crossing point shown in Figures 2 and 3 after dynamic force absorption.

A protective net shown in FIG. 1, which is an embodiment of the invention, consists of one or two ropes 2, 3. The ropes 2, 3 are preferably designed as steel wire ropes, in particular triple-stranded ropes. However, single or double-stranded wire ropes can also be used will. The ropes or pieces of rope 2, 3 are laid crosswise to one another at intersection points 4. At the respective crossing points 4 connecting elements 5 in the form of two connecting wires 12, 13 are provided. The connecting wires 12, 13 can be designed as steel wires. These steel wires, as can be seen in particular from FIGS. 2 to 4, have a smaller diameter than the two cables 2, 3 to be connected to one another. Middle regions of the connecting wires 12, 13, namely middle connecting wire pieces 10, 11, are as shown in the figures 2 and 3 can be seen, arranged crosswise at the respective intersection 4. 2 and 3, the middle connecting wire piece 10 (FIG. 3) lies on the back of the crossing point 4 and the middle connecting wire piece 11 (FIG. 2) on the front and top of the crossing point 4. The two connecting wire pieces 10 and 11 have approximately the same crossing angle to each other as the two crossed rope parts 2 and 3.

The two end pieces of each connecting wire 12 and 13 are wound in windings 6, 7 and 8, 9 around the rope pieces of the ropes 2 and 3 adjacent to the crossing points 4. The illustrated embodiment is three turns in each winding 6, 7, 8 and 9. This number of turns is a minimum number of turns for each winding in the illustrated embodiment. In this way, a connecting element is created at the respective intersection 4, but it still functions as an energy-absorbing element due to the possibility of dynamic force absorption Has. The respective two windings 6, 7 and 8, 9 of each connecting wire 12 and 13 are wound in opposite directions around the respective rope. The intersecting pieces of rope are crossed once at the bottom and once at the top to form the network.

FIG. 4 shows the state of the connecting element 5, which consists of the two connecting wires 12 and 13, after loading the crossing point. It can be seen from FIG. 4 that the distance between the two connecting wire pieces 10 and 11 arranged crosswise has increased in relation to the unloaded state shown in FIGS. 2 and 3 perpendicular to the plane in which the network 1 is stretched out. That is, the connecting element consisting of the two connecting wires 12 and 13 at the crossing point has increased in the direction perpendicular to the plane of propagation of the protective network 1. This deformation of the connecting element in the illustrated embodiment can be attributed to three effects, firstly to the elongation of the wire caused by the tensile stress in the respective connecting wire 12 or 13, a slippage of the windings 6 to 9 relative to the two cables 2 and 3 and a constriction of the Rope by reducing the respective winding radius of the windings 6 to 9 under the tensile stress. The tensile stress applied has a direction perpendicular to the plane of propagation of the opened protective net or perpendicular to the crossing point of the two ropes shown in FIGS. 2 and 3, which have a diameter of 8 mm. The connecting wires 12, 13 made of steel have a diameter of about 3 mm.

In the exemplary embodiment of the invention, when the tensile stress acting in the direction perpendicular to the crossing point results in the following deformations in the direction of the tensile force on the connecting element 5 consisting of the two connecting wires 12 and 13, the deformation as a change in distance between the two on the top and the bottom of the respective Crossing point 4 cross-lying wire connectors 10 and 11 in millimeters depending on the tensile stress (kN) applied are given in the following table: Tensile stress (kN) Distance change (mm) 0.5 0.18 1.0 0.22 1.5 0.36 2.0 0.49 3.0 0.78 3.5 1.12 4.0 1.44 4.5 1.66 5.0 1.98 5.5 2.27 6.0 2.49 6.5 2.94 7.0 3.02 7.5 3.41 8.0 3.66 8.5 4.01

From this it can be seen that the connecting element 5, which in the illustrated embodiment the two connecting wires 12 and 13, there is an energy absorber acting as a dynamic force transducer at each crossing point 4 of the protective network 1. The total effect of the energy absorber elements present at the several intersections, which are distributed over the entire protective network, results in a considerable improvement in the energy absorber effect of the overall network.

The square or diamond-shaped mesh mesh of the protective net generally has a side length of 200 to 300 mm. The ropes, especially the steel wire side to form the net, have a diameter between 5 and 10 mm. With tensile stresses in the order of 8.0 to 9.0 kN acting in a vertical direction on the intersection, length changes in this direction result in the order of magnitude of 3.5 to 4.2 mm for a connecting element which is subjected to this load with dynamic force absorption.

Claims (3)

Protective net, consisting of crossed ropes (2, 3), in particular steel wire ropes, which are connected to one another at their respective crossing points (4) by connecting elements (5),
characterized by
that the connecting elements (5) as dynamic force transducers form energy-absorbing elements at the respective crossing points (4). Protective net according to claim 1, characterized in that the respective connecting element (5) can be deformed by the dynamic force absorption perpendicular to the plane in which the net is spread. Protective net according to claim 1 or 2, in which the connecting element (5) at the crossing point (4) consists of four windings (6, 7, 8, 9) of two connecting wires (12, 13) with a smaller diameter than the cables (2, 3) is formed, the two windings (6, 7) of the one connecting wire (12) around the two pieces of rope adjacent to the crossing point (4) of one rope and the two windings (8, 9) of the other connecting wire (13) around the two of the Crossing point (4) adjacent rope pieces of the other Rope (3) are wound, the two windings (6, 7) of one connecting wire (12) via a connecting wire piece (10) lying on one network side and the two windings (8, 9) of the other connecting wire (13) via one connecting wire piece (11) lying on the other side of the network and the two cables (2, 3) lie at the respective crossing point (4) between the two crossed connecting wire pieces (10, 11), characterized in that the distance between the two crossed connecting wire pieces (10 , 11) can be enlarged from one another by the dynamic force absorption.

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