WO1999037867A1 - Shuttering grid for supporting slopes - Google Patents

Abstract

A shuttering grid (1) for supporting slopes has a bottom part (2) and a slope part (3) which projects from the bottom part at an angle of maximum 90°. These two parts (2, 3) consist of a wire net made in a single piece with wires which extend perpendicular to one another and are welded together at their crossing points. The slope part (3) is held by bracing anchors (6) to the bottom part (2). Some of the wires (5) in the bottom part (2) and slope part (3) are thicker than the remaining shuttering wires (7) and act as anchoring wires for the bracing anchor (6). The two connecting wires adjacent to the fastening plane are more closely spaced than the remaining connecting wires (7) in the slope part (3) and in the bottom part (2). All points where the bracing anchors (6) are hooked into the wire nets are thus reinforced and buckling is no longer possible because not only one bracing anchor (6) is provided for each anchoring point, but two or more bracing anchors can be provided depending on the solidity to be achieved.

Description

 SHUTTER GRID FOR SUPPORTING SLOPES

The present invention relates to a formwork grid for supporting embankments, comprising a floor section and an embankment section projecting at an angle of at most 90 ° with respect to the floor section, each of which is produced by bending from one-piece nets with mostly perpendicular to one another and welded wires at the crossing points are and are also provided with anchoring anchors to support the slope area relative to the ground area with the slope angle provided for the respective slope.

In slope and / or embankment fastenings, it has been known for a long time to use the known reinforcement nets for concrete work to hold the embankment front in order to produce it as evenly as possible and running straight. So that these nets can withstand the pressure of the soil behind them, it has been shown that these nets are to be bent in such a way that a bottom part and a slope part are created, the angle enclosed by these two parts mostly being between 45 ° and almost 90 ° . However, the larger this angle, the greater the pressure of the soil on the slope area than at smaller angles. In order to withstand this, the embankment area was supported by anchor rods between it and the floor area on the one hand during installation and pulled back after it was filled in, so as to form the embankment wall as a plane. However, it has been shown that this is not always possible with the conventional type of network.

The anchor rods were also arranged according to discretion and not according to the areas of the highest bending stress on the network. However, this only fulfills part of the task of these anchor rods, namely the support of the slope area during the division of the formwork grids and not the correct improvement in the strength of the structure.

Accordingly, it is an object of the invention to improve the formwork grids so that on the one hand the overall height of the slope part can be increased and on the other hand the stiffening by the anchors can be optimally provided.

According to the invention this is achieved by the features in claim 1 by replacing individual wires in the bottom part and also in the embankment part with anchor rods with a larger diameter than that of the wires, that an anchor rod is at least approximately in the edge region in the edge region and in the Embankment part an anchor rod is also arranged at the edge area and at least one further in the region of greatest bending stress of the embankment part, that furthermore at least two tie anchors lying at least approximately one above the other in the same vertical fastening plane on two anchor rods of the embankment ngpartie and are attached to an anchor rod in the ground part, and that the two wires adjacent to the fastening plane are arranged closer to each other both in the embankment part and in the ground part than the other wires of the embankment and ground part.

The invention is explained in more detail below on the basis of exemplary embodiments. The attached drawing shows:

Fig.l is a perspective view of a formwork grid according to the invention together with other elements for the construction of a

Embankment,.

2 shows a side view of a formwork grid with anchoring anchor,

3 shows a sectional view of a completed embankment,

4 shows a sectional view, like that according to FIG. 3, but with a different structure of the greening area,

5 shows a sectional view like that according to FIG. 3, but without greening on the bank side and only covered with a filter fabric, 6 shows a sectional view, like that according to FIG. 3, with a stone layer on the slope side, similar to a cabione.

1 and 2 consists of a wire mesh 1, as they are known in the construction industry for the insert in the concrete. Some of these exist. from different thickness wires and with different distances from each other. These wires are arranged crosswise and welded together at the crossing points, so that a stable wire mesh network is formed. Such a basic network has been modified for the intended purpose so that it meets the requirements for rigidity and dimensional stability that are required when building embankments. The network consists of longitudinal formwork wires 4 and connecting wires 7 arranged perpendicular to it.

For the special application in the construction of embankments, the grid 1 is bent, so that a bottom part 2 and an embankment part 3 are formed. The angle between the two parts gives the angle of attack of the embankment, which can be of the order of magnitude between 45 ° and at least approximately 90 °. The distances between formwork wires 4 in the embankment section 3 have a smaller distance from one another than those in the floor section, as is clearly shown in Fig.l. This then also results in a different holding strength, which is known to be great where the strongest pressure is to be expected, namely in the embankment section 3. The guy wires 5 on which the guy anchor 6 is to be hung are thicker than the other formwork wires 4 and are therefore more resilient.

The connecting wires 7 arranged perpendicularly to these formwork wires 4 have, as FIG. 1 also clearly shows, different distances. So each have two such connecting wires 7, between which it is provided to hang in anchor anchors 6 a smaller distance apart than the other connecting wires. This fulfills two tasks. On the one hand, the strength of the wire mesh 1 at the hanging points is greater than next to it and, secondly, the construction workers then also know where to place the guy anchors.

In addition, it is also intended to hang more than just one anchor point 6 anchor anchor 6, as shown for example in Figures 1 and 2, two anchor anchors 6 are attached to the embankment section 3, namely one at the upper end of the wire mesh and one at least approximately in the middle the slope part 3. The anchoring in the bottom part 2 is provided at a single point, namely on the edge wire 5. Of course, however, more than two guy anchors 6 could also be provided and these could also be fastened to the floor part 2 at different points.

However, if there are only two guy anchors 6, they could also be made in one piece so that fewer individual parts are transported to the construction site. But also in order to advance the construction more quickly than if the construction workers had to look for two different guy anchors 6.

As usual, an earth reinforcement 13 is to be installed on the mountain side of the formwork grid 1. In a known version, this consists, for example, of a uniaxial geogrid which may already contain seeds for subsequent greening, or seeds may be sprinkled upon installation. In order to simplify the laying of such a geogrid, an installation aid 8 is provided, by which the exposed tips of the connecting wires 7 are covered. so that the geogrid cannot be attached. This installation aid 8 is a U-shaped angled sheet, of which the one leg provided for the inside is shorter than that for the outside. With such a design, this installation aid can be placed over the tips of the connecting wires 7 by rotation and removed again.

Figure 2 shows in particular a section through an embankment where the backfill and the anchorages can be seen. In this case, the backfilling is a horizontally layered material layer with a Hunus part 10 located at the front of the formwork grid and a filling material part 9 located at the rear. This filling material can be excavated material from the construction site currently being worked on or from a remote construction site. As can be seen, the geogrid 13 forms a lower anchoring 14 and an upper anchoring 11. The lower anchoring 14 is held on the ground by means of two cramps and therefore cannot move during the backfilling.

3 to 6 show different types of backfilling with or without geogrid. For example, FIG. 3 essentially shows a similar structure to that described above with reference to FIG. 2. Only the greening 20 and an overgrowth with bushes 21 are shown.

FIG. 4, on the other hand, shows macro-humusification with small plants, as in a natural meadow, and FIG. 5 has a filter fabric 50 behind the formwork grid. In a further embodiment, FIG. 6 shows a backfill with coarse rock 60, so that a view arises from the outside of the slope, as in a cabione in which a basket of wire nets is filled with stones and fixes the slope by the weight of the stones . As is well known, bushes and grasses grow in such a variety after a while in such fortifications.

Claims

P A T E N T A N S P R U C H E

Formwork grid for supporting embankments, comprising a floor section (2) and an embankment section (3) rising up at an angle of no more than 90 ° with respect to the floor section (2), each of which is made of one-piece nets, usually arranged at right angles to one another and welded together at the crossing points - 5 first wires (4, 5, 7) are produced by bending and furthermore are provided with anchoring anchors (6) for supporting the slope part (3) with respect to the ground part (2) with the slope angle provided for the respective slope, characterized in that in the bottom part (2) and also in the embankment part (3) individual 10 wires (4) are replaced by anchor rods (5) with a larger diameter than that of the wires (4), so that an anchor rod (5) is in the bottom part (2 ) is at least approximately in the edge area and in the slope (3) an anchor rod (5) also in the edge area and at least one other in the area I 15 largest bending stress of the embankment section (3) is arranged that further at least two tie anchors (6) at least approximately one above the other in the same vertical fastening plane on two anchor rods (5) of the embankment section (2) and on an anchor rod (5) in the bottom section ( 2) are fastened, and that the two 20 connecting wires (7) adjacent to the fastening level are arranged closer to each other both in the slope part (3) and in the bottom part (2) than the other wires (4) of the slope and ground part .

25th Formwork grid according to claim 1, characterized in that two

Anchor rods (6) are made from a wire by bending as an integral anchor.

Formwork grid according to claim 1 or 2, characterized in that at least two anchor points are provided per grid width, in which the two connecting wires adjacent to the fastening plane are arranged closer to one another than the other connecting wires.

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