DE102012205484A1 - Embankment structure for use in reinforced soil system, has air-side supporting wall formed from set of gabions, and rear anchorages designed as metal wire lattice, which is connected with gabions by connecting element - Google Patents

Abstract

The structure (1) has an air-side supporting wall (3) connected with rear anchors (13) that are directed in earth material. The supporting wall is formed from a set of gabions (4), and the rear anchorages are designed as a metal wire lattice, which is connected with the gabions by a connecting element (16) i.e. high tensile metal wire. The connecting element is connected with a mesh of edges of the metal wire lattice, where the edges of the metal wire lattice are turned toward earth side of the gabions. The connecting element includes coverable hook-shaped ends. The gabion is selected from a bulk basket, gabion wall, gabion box or gabion with a stone-filled wire basket.

Description

The invention relates to a slope structure according to the preamble of patent claim 1.

Various embankment structures with layers of earth are known in the prior art. Such embankment structures are built according to a system also called reinforced soil, which is understood to mean a composite of soil and a reinforcement. As reinforcement preferably steel or plastic rods, friction bands, mats or grids such as geotextiles are used, which are preferably arranged horizontally.

Furthermore, it is known from the prior art to provide such embankment structures on the air side with a retaining wall. For example, such a retaining wall is formed from a stackable precast concrete or so-called gabions. A gabion, also known as stone basket, sack basket, brick wall, wire ballast box or Schanzkorb, is a wire basket usually filled with stones. Gabions are preferably used in transport, engineering, gardening and landscaping. Gabions are used to build a retaining wall, it is usually sized as a gravity wall, so that depending on the height, a wall thickness of several meters is prescribed. Known gabions are optional portable.

An alternative to forming a retaining wall as a heavyweight wall is the use of so-called back-imposed (anchored) gabions. Here, a floor located behind the gabion for load transfer is pulled up. In the reinforced earth construction, the gabions are usually on-site, i. at the construction site, filled.

The object of the present invention is to provide a gabion which is improved over the prior art.

The object is achieved by a gabion having the features specified in claim 1.

Advantageous embodiments of the invention are the subject of the dependent claims.

An embankment structure with layers of earth comprises a retaining wall arranged on the air side, which is connected to return anchors directed into the earth. According to the invention it is provided that the retaining wall is formed of a plurality of gabions, wherein the rear anchors are each formed as a metal wire mesh, which are connected by means of connecting elements with the gabions. Gabions are usually formed from a grid body which is filled with a filling material, e.g. Natural stones or coarse gravel, is filled. By means of the metal wire mesh back anchoring of the retaining wall is optimized so that the safety level of the embankment structure compared to conventional generic embankment structures is increased and thus slope angle of 90 degrees and corresponding safety level can be realized. Particularly preferred is the construction of a comparatively slender retaining wall is possible, which forms a cost-effective alternative to heavyweight walls.

In a preferred embodiment of the invention, a connecting element is provided for each mesh of one of the earth side of the gabion facing edge of the metal wire grid. Preferably, the connecting elements are connected to a horizontal bar of the gabion. Thus, an optimal load transfer from the gabion to the back anchor is possible in an advantageous manner.

According to the invention, the connecting elements each have two overlapping hook-shaped ends. This ensures a simple and secure connection of the metal wire mesh with the gabions.

For optimum connection of the gabions to the metal wire meshes, the fasteners are made of a tensile metal wire, e.g. Steel wire, formed.

In a particularly preferred embodiment of the invention, the meshes of the metal wire grid are honeycomb-shaped as symmetrical hexagons. Thus, a deformation of the rear anchors under continuous load compared to conventional lattice structures with, for example, square mesh significantly reduced, so that a safety of the embankment structure is further improved. Particularly preferred in the anchoring direction abutting edges of adjacent hexagons, the wires of these hexagons are twisted together.

Furthermore, a linear tension element is provided with an end reinforcement in the form of a thimble which is formed in a preferred embodiment of the invention as a wire rope and is connected in a further preferred embodiment with the twisted edges of the hexagons. Thus, a tensile strength of the metal wire mesh is significantly improved.

Embodiments of the invention are explained in more detail below with reference to drawings.

Showing:

1 schematically a sectional view of a slope work according to the invention,

2 schematically a top view of a back anchoring a gabion,

3 1 is a schematic perspective view of a non-filled gabion with a back anchor;

4A schematically a front view of a connecting element,

4B schematically a side view of the connecting element according to 4A , and

4C schematically a perspective view of the connecting element according to 4A ,

Corresponding parts are provided in all figures with the same reference numerals.

1 shows an embankment structure according to the invention 1 in section. In a known manner, an embankment is built according to the system of reinforced earth, wherein well compactable earth in several layers 2 piled up on top of each other and compacted in layers. The slope has an angle of 90 degrees in the present embodiment.

The embankment structure 1 has a retaining wall on the air side 3 on, which preferably from laterally juxtaposed and in rows stacked gabions 4 is formed, with the return anchors directed into the earth 13 by means of connecting elements 16 are connected. In the present sectional view of 1 are three stacked gabions 4 shown. There is a gabion 4 a return 13 assigned.

A gabion 4 is made of a nearly rectangular grid body 5 composed of which with filler material 6 is filled. The filling of the gabions 4 is particularly preferably factory. The use of factory-filled gabions 4 offers the advantage of a compression of the filling material 6 can be monitored well, causing a bulge of the grid body 5 can be counteracted. This is an even and appealing appearance of the gabion 4 and with it the retaining wall 3 possible.

As filler 6 Different natural stones with edge lengths of, for example, 100 to 300 mm or alternatively coarse gravel can be used. Conveniently, the mesh sizes of the grid body 5 the gabion 4 smaller than the diameter of individual elements of the filler 6 ,

The grid body 5 is made of spot welded, rectangular grid parts 7 . 8th . 9 . 10 formed, in particular from an air-side front grille part 7 , a ground-side front grille part 8th , two side rail parts 9 and a bottom gate part 10 , Alternative to the bottom gate part 10 have the side rail parts 9 lower end portions. In addition, the grid body 5 a lid grid part (not shown).

The lattice parts 7 . 8th . 9 . 10 each consist of horizontal bars 11 and vertical bars 12 that cross at right angles. The horizontal bars 11 the front grill parts 7 . 8th thereby run in a direction which is parallel to an axis z. The axis z defines a transverse orientation of the embankment structure 1 , The vertical bars 12 the front grill parts 7 . 8th accordingly run in a direction which is parallel to an axis x. The axis x is extending from a slope foot to a slope crown.

The horizontal and vertical bars 11 . 12 are preferably made of a tensile material, such as steel. For example, the tensile strength of the material is 450 N / mm ² , a diameter of the rods 11 . 12 for example, 5.0 mm to 6.0 mm and a distance of two adjacent horizontal bars 11 for example, 100 mm, wherein the distance between two adjacent vertical bars 12 for example 50mm. The front grill parts 7 . 8th can have a length between 50cm and 200cm and a height between 50cm and 100cm.

Particularly preferred are the horizontal and vertical rods 11 . 12 provided with a Galfanbeschichtung with a layer thickness of eg 350g / m ² , so that the gabion 4 permanently corrosion resistant.

For the reintroduction of the gabions 4 are the already mentioned anchorages 13 provided, which serve in particular the large-scale distribution of static loads on the soil and thus a slope structure 1 according to 1 can be realized with an angle of 90 degrees.

One of these anchorages 13 is exemplary in 2 shown in more detail. The anchoring 13 is as a metal wire grid 14 , preferably made of a high tensile steel wire, formed.

For an optimal return of the gabions 4 are the metal wire mesh 14 respectively in the direction of an axis y stretched accordingly. For example, on a the ground-side front grille part 8th opposite edge of the metal wire grid 14 Positioned steel rods which extend longitudinally in the direction of the axis x. These can be removed after dumping the soil.

In the present embodiment, the meshes 15 of the metal wire grid 14 formed like a knob. In a preferred embodiment, not shown, the stitches are 15 of the metal wire grid 14 honeycomb shaped as symmetrical hexagons. Particularly preferably, in the direction of the axis y adjoining edges of adjacent hexagons, the wires of these hexagons are twisted together.

Furthermore, an unillustrated linear tension element is provided with an end reinforcement in the form of a thimble, which is formed as a wire rope and connected to the twisted edges of the hexagons. The linear tension element extends in the direction of the axis y. For example, one per stitch 15 of the metal wire grid 14 provided in the direction of the axis z a linear tension element. Alternatively, a linear tension member is for every second or every third stitch 15 of the metal wire grid 14 provided in the direction of the axis z.

Optionally, the individual stitches 15 of the metal wire grid 14 square or hexagonal formed.

The metal wire grid 14 is how in 3 shown with a horizontal bar 11 of the earth-side front lattice part 8th the gabion 4 connected. For optimal load transfer is for each stitch 15 one of the earth-side front grille part 8th facing edge of the metal wire grid 14 a connecting element 16 provided, which in 4 is shown in more detail.

The connecting element 16 is made of a metal rod, preferably made of steel, which leads to an openable eyelet 17 with two overlapping hook-shaped ends 18 is shaped. The material of the connecting element 16 preferably has a minimum tensile strength of 1770 N / mm ² . For example, a diameter of the metal rod of the connecting element 16 four millimeters, with a width of the connecting element 16 21 millimeters and a length of the connecting element 16 60mm. The width of the connecting element 16 is the sum of the diameter of the eyelet 17 and diameter of the metal rod from which the connecting element 16 is shaped.

In a profitable manner, a load capacity of the connecting element 16 larger than one from the metal wire grid 14 absorbable tensile strength, allowing optimal load transfer of the connecting element 16 is ensured.

The fact that the set as before the embankment retaining wall 3 with rear anchorages 13 Made of metal, the retaining wall can 3 be made very slim. This is the embankment structure according to the invention 1 comparatively inexpensive executable.

LIST OF REFERENCE NUMBERS

1

inclined structure

2

location

3

retaining wall

4

gabion

5

grid body

6

filling material

7

air-side front grille part

8th

earth-side front grille part

9

Side rail part

10

Floor grating part

11

Horizontal bar

12

vertical bar

13

back anchoring

14

Metal wire mesh

15

mesh

16

connecting element

17

eyelet

18

hook-shaped ends

x, y, z

axis

Claims (10)

Embankment structure ( 1 ) with layers ( 2 ) of earth, comprising a retaining wall arranged on the air side ( 3 ), which are connected to earth-anchoring ( 13 ), characterized in that the retaining wall ( 3 ) of a plurality of gabions ( 4 ), the rear anchors ( 13 ) each as a metal wire grid ( 14 ) are formed, which by means of connecting elements ( 16 ) with the gabions ( 4 ) are connected. Embankment structure ( 1 ) according to claim 1, characterized in that for each mesh ( 15 ) one of the earth side of the gabions ( 4 ) facing edge of the metal wire grid ( 14 ) a connecting element ( 16 ) is provided. Embankment structure ( 1 ) according to claim 1 or 2, characterized in that the connecting elements ( 16 ) with a horizontal rod ( 11 ) of the gabion ( 4 ) are connected. Embankment structure ( 1 ) according to one of the preceding claims, characterized in that the connecting elements ( 16 ) each two overlapping hook-shaped ends ( 18 ) exhibit. Embankment structure ( 1 ) according to one of the preceding claims, characterized in that the connecting elements ( 16 ) are formed of a tensile metal wire. Embankment structure ( 1 ) according to one of the preceding claims, characterized in that the stitches ( 15 ) of the metal wire grid ( 14 ) are shaped honeycomb-shaped as symmetrical hexagons. Embankment structure ( 1 ) according to claim 6, characterized in that adjoining edges of adjacent hexagons in the anchoring direction, the wires of these hexagons are twisted together. Embankment structure ( 1 ) according to claim 6 or 7, characterized in that at least one linear tension element is provided with an end reinforcement in the form of a thimble. Embankment structure ( 1 ) according to claim 8, characterized in that the tension element is designed as a wire rope. Embankment structure ( 1 ) according to 8 or 9, characterized in that the tension element is connected to the twisted edges.

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