DE10311597A1 - Method for constructing an earth embankment involves introduction of at least a few layers of load distributing elements during or after construction of a consolidated central region - Google Patents

Abstract

The method for constructing an earth embankment involves introduction of at least a few layers of bar-shaped load distributing elements during or after construction of a consolidated central region. Hooks are used to join the load distributing elements to the distance maintenance members. An independent claim is also included for a resultant earth embankment.

Description

The invention relates to a Method of making an earth embankment, in which layers a load-bearing and solidified core area is built up composed of several layers of filling soil, one of each layer essentially horizontal section, one from the bottom up extending portion and a folded-back portion of one flexible geogrid track is enclosed and compressed, and at at a distance from the compacted core area using steel wire existing spacers attached a stiff, large-area grid mat will, so that between the rigid mesh mat and the core area from bottom to top continuous free space is created, preferably with a vegetation floor filled becomes.

From the EP-1 054 110 Such a method for producing an earth embankment is known.

So with the compaction of the filling layers the front extending essentially from the bottom up the geogrid track does not migrate to the front, before compacting detachable formwork attached to each layer. In the supporting and solidified core area are about the projecting rod-shaped spacers projecting vertical sections of the geogrid track arranged. After creating the load-bearing and compacted core area at a distance from the front of the core area a stiff, large grid mat attached to the 20 cm or 40 cm protruding rod-shaped spacers, so that between the rigid mesh mat and the core area from bottom to top continuous free space is created, preferably with a vegetation floor, but also with gravel, crushed stone or concrete.

If the lattice mat has relatively large lattice openings has, then on the inside of this mesh mat is a rooted thin Mesh or a thin one Fleece attached so that between the solidified area and the rigid mesh mat to be filled Vegetation soil not through the openings in the mesh mat fall through.

This known method can be used also soundproof walls erect that can be planted on both sides and are constructed according to the described method are. The filling layers are thereby narrowing upwards so that the side walls of the Walls an inclination of about 60 ° to Get 70 °.

The individual filler layers are by means of Jogger or vibratory rollers compacted before the next higher filler layer is applied. To ensure good interlocking of the filler layers the flexible reinforcement meshes can be reached as geogrids designed with a mesh size of 20 mm × 20 mm to 50 mm × 50 mm. The thread strands of the geogrid are equipped with a polymer protective layer.

Instead of the woven geogrid with several threads existing warp strands and Weft strands can geogrids made differently can also be used.

In the known method the rod-shaped and over the solidified core area by 20, 30 or 40 cm protruding spacers during the Structure of the core area between the filling layers. It it is difficult to arrange the spacers so that they also compressing the higher layers of fill soil maintain their position. The protruding rod-shaped spacers also cause for the Construction workers at risk of injury.

However, it is also possible to post Production of the solidified core area provided with barbs rod-shaped Drive spacers into the compacted filler floor layers. this leads to however, to difficulties if the filling layers with larger stones are enforced.

Based on the procedure mentioned at the beginning the object of the invention is to develop the method in such a way that this precise mounting the spacer is relieved.

This object is achieved according to the invention solved, that the Spacers for attaching the rigid mesh mat an angled have load-distributing part or to a load-distributing base part connectable which is behind the bottom-up section of the filler floor layers at least partially enclosing geogrid leaning against it is attachable, and after production of the solidified core area and after setting up the stiff mesh mat at a distance from the compacted Core area the mesh mat is attached to the spacers.

Anchoring the spacers on the geogrid tracks, especially on the vertical ones in the front area trending strands, has the advantage that the Spacers reliable being held. Furthermore, for the manufacture of the spacers requires less material. Farther can the spacers and the load-distributing components are designed in this way be them only after the compacted core area has been produced.

In a preferred embodiment the invention will be during or after manufacturing the solidified core area in the area the sections of the geogrid tracks that run from bottom to top behind the geogrid tracks crossing several vertical strands of thread load-distributing bars attached, and after making the solidified core area the rigid grid mat is set up at a distance from this core area and is made using spacers that have U-shaped hooks at both ends are provided, connected to the load-distributing bars by each a hook of the spacer engages behind a load-distributing rod and the other hook grips a rod of the rigid mesh mat.

The load-distributing bars can be used for Structure of the filling floor layers behind the bottom-up portion of the Geogrid track can be attached. These load-distributing bars can, however even after the compacted core area has been created behind the geogrid track of the individual layers of filling floor inserted or driven in. The bars distribute those from the spacer practiced Load on the thread strands of the Geogrid. These are preferably warp thread strands.

In another embodiment The spacer with the invention are essentially one right angled part in the area from bottom to top running sections behind several thread strands of the geogrid tracks brought behind the front of the geogrid tracks and after installation the stiff grid mat at a distance from the core area with an am other end of the spacer located U-shaped hooks around or over a Bar of the mesh mat hooked.

With this procedure, the Spacer during the construction or after production of the solidified core area with its angled part behind those that run from bottom to top Section of the geogrid track.

The at least 20 mm × 20 mm huge Meshes of the geogrid webs and a local extensibility of the geogrid thread strands allow it that the load-distributing bars or the right-angled parts of the spacers as well after creating the solidified core area behind the front the geogrid tracks can be brought.

The following description will be inventive method as well as the earth embankments made with these methods with reference to the drawings using exemplary embodiments explained in more detail. The Drawings show in:

1 a cross section through an embankment produced according to the invention,

2 3 shows an enlarged illustration of a spacer which connects the load-distributing rod to a rod of the rigid grid mat,

3 a perspective view of a spacer that reaches behind the geogrid track,

4 a perspective view of a spacer with opposite 3 modified hook,

5 an enlarged view of a spacer 1 ,

The 1 shows a cross section of an earth embankment, which is composed of a natural, existing earth embankment 3 , in front of the layered geotextile reinforced core area 1 was built and in front of which there is an outer skin area 2 located.

The solidified core area 1 in this example is made up of five layers 21 - 25 fill soil 4 , each layer on three sides by a flexible geogrid 5 is enclosed. The flexible geogrid track 5 every filling layer 21 - 25 has a substantially horizontal lower section, a front vertical section 6 and a folded-back top section. Every filling layer 21 - 25 is compacted by means of vibratory rollers or the like before the next higher layer is built up. To achieve the most vertical section possible 6 the geogrid track 5 will before filling the soil 4 A detachable vertical formwork is attached to each layer. Has the floor to be filled 4 reaches its layer thickness, the upper section of the geogrid track is folded back and the filled soil is compacted. The flexible geogrid track and the formwork of the next layer are installed in such a way that the slope receives the desired inclination. This creates steps that are greater the smaller the angle of repose relative to the horizontal. At a distance from the solidified core area 1 is a stiff, over several layers of filling floor 21 - 25 extending mesh mat 7 attached by spacers 8th is held. The spacers 8th are made of galvanized or non-galvanized steel wire and have an approximately 20 to 70 cm long straight section and according to the embodiment 1 . 2 and 5 U-shaped hooks at both ends 12 or 12 ' , The spacer 8th according to the 1 . 2 and 5 serves to carry out the method according to claim 2, while the spacers 8th' are intended to carry out the method according to claim 3.

In the 1 and 5 shown spacers 8th have U-shaped hooks at both ends 12 , which are formed by bending an initially straight rod by 180 °. A catch 12 encompasses the load-distributing rod 15 while the other hook 12 a horizontal bar 16 the stiff mesh mat 7 embraces.

The stiff mesh mat 7 can be a steel mesh mat or can also be made of plastic. If the mesh is made of steel wire, it is made corrosion-resistant by galvanizing or by a plastic coating.

The one out 2 visible spacers 8th also has U-shaped hooks at both ends 12 ' , These are open at the bottom, so that they are above the load-distributing rod 15 and a horizontal bar 16 of the lattice mat 7 be put over and the grid mat 7 tensile and pressure resistant with the geogrid sheets 5 of the solidified core area 1 connect.

If behind the stiff mesh mat 7 a thin fleece layer 9 is arranged, then this can be from the spacers 8th . 8th' be easily pierced. Is on the stiff mesh mat 7 a rootable tissue attached, then can be used to attach the spacers 8th . 8th' to the required holes are cut.

The attachment of the stiff mesh mat 7 on the spacers 8th can be done in a known manner. A quick and easy connection can be achieved in that the spacers are provided with U-shaped hooks, which are above rods 16 the stiff mesh mat 7 to grab.

1

solidified core area

2

Skin area

3

natural embankment

4

fill soil (Compressed)

5

Geogitterbahn

6

front the filler floor layers

7

stiffness grid mat

8th

spacer

8th'

spacer

9

rooting thin fleece mat or mesh fabric

10

vegetation soil

11

angled part of the spacer 8th'

12

vertical open hook

12 '

horizontal open hook

13

thread strand horizontal

14

thread strand vertical

15

load spreading Rod

16

horizontal bar of rigid mesh mat 7

21

lowest Füllbodenlage

22

second Füllbodenlage

23

third Füllbodenlage

24

fourth Füllbodenlage

25

fifth filling layer

Claims (9)

Process for the production of an earth embankment, in which a load-bearing and solidified core area ( 1 ) that is composed of several layers ( 21 - 25 ) Filling floor ( 4 ) which, depending on the position, of an essentially horizontal section, a section extending from the bottom upwards ( 6 ) and a folded-back section of a flexible geogrid track ( 5 ) is enclosed and compacted, and at a distance from the compacted core area ( 1 ) using spacers made of steel wire ( 8th ) a rigid, large-area mesh mat is attached so that between the rigid mesh mat ( 7 ) and the core area ( 1 ) there is a free space running from bottom to top, which is preferably filled with a vegetation floor, characterized in that the spacers ( 8th . 8th' ) for fastening the rigid grid mat ( 7 ) an angled load-distributing part ( 11 ) or to a load-distributing base part ( 15 ) can be connected, which is behind the section from bottom to top ( 6 ) of the filling floor layers ( 21 - 25 ) at least partially enclosing geogrid sheet can be attached to it for support, and after the solidified core area has been produced ( 1 ) and after setting up the stiff mesh mat ( 7 ) at a distance from the compressed core area ( 1 ) the grid mat ( 7 ) on the spacers ( 8th . 8th' ) is attached. A method according to claim 1, characterized in that during or after production of the solidified core area ( 1 ) in the area of the sections running from bottom to top ( 6 ) of the geogrid tracks ( 5 ) several vertical strands of thread behind the geogrid tracks ( 14 ) crossing load-distributing bars ( 15 ) are attached and after production of the solidified core area ( 1 ) at a distance from this core area ( 1 ) the stiff mesh mat ( 7 ) is set up and using spacers ( 8th ) with U-shaped hooks at both ends ( 12 . 12 ' ) are provided with the load-distributing bars ( 15 ) is connected by a hook ( 12 . 12 ' ) the spacer ( 8th ) a load-distributing rod ( 15 ) reaches behind and the other hook ( 12 . 12 ' ) a stick ( 16 ) the stiff mesh mat ( 7 ) embraces. Method according to claim 2, characterized in that the spacers ( 8th' ) with an essentially angled part ( 11 ) in the area of the sections running from bottom to top ( 6 ) several strands of thread ( 14 ) of the geogrid tracks ( 5 ) can be pushed behind and after setting up the stiff mesh mat ( 7 ) at a distance from the core area ( 1 ) with one at the other end of the spacers ( 8th' ) U-shaped hook ( 12 . 12 ' ) around or over a rod ( 16 ) the grid mat ( 7 ) be hooked. Earth embankment with a layered, solidified core area ( 1 ), which is composed of several layers ( 21 - 25 ) Filling floor ( 4 ), which at least on the front side of a geogrid track ( 5 ) is enclosed and compressed on three sides, at a distance from this core area ( 1 ) using spacers ( 8th ) a stiff, large mesh mat ( 7 ) is fixed and the space between the stiff mesh mat ( 7 ) and the core area ( 1 ) preferably with a vegetation soil ( 10 ) is produced by the method according to claim 2, characterized in that in the region of the sections running from bottom to top ( 6 ) of the geogrid tracks ( 5 ) at least some layers of filling soil ( 21 - 25 ) behind the geogrid track ( 5 ) several vertical strands of thread ( 14 ) crossing load-distributing bars are arranged and at a distance from the core area ( 1 ) the stiff mesh mat ( 7 ) of spacers ( 8th' ) is made of steel wire, the U-shaped hooks at both ends ( 12 . 12 ' ), of which the one over the load-distributing rods ( 15 ) grab and the other hooks ( 12 . 12 ' ) Rods ( 16 ) of the rigid grid ( 7 ) reach around. Earth slope according to claim 4, characterized ge indicates that the spacers ( 8th ) are bent at both ends of their 20 to 70 cm long straight course by approx. 180 ° and U-shaped hooks ( 12 ) which, when the spacers are arranged horizontally ( 8th ) are open in the vertical plane. Earth slope according to claim 4, characterized in that the spacers ( 8th ) are at right angles at both ends of their 20 to 70 cm long straight course and then bent by approx. 180 ° and U-shaped hooks ( 12 ' ) which, when the spacers are arranged horizontally ( 8th ) are open in the horizontal plane. Earth embankment with a layered, solidified core area ( 1 ), which consists of several layers ( 21 - 25 ) Filling floor ( 4 ), which at least on the front side of a geogrid track ( 5 ) is enclosed and compressed in three places, and at a distance from this core area ( 1 ) using spacers ( 8th ) a stiff, large mesh mat ( 7 ) is fixed and the space between the stiff mesh mat ( 7 ) and the core area ( 1 ) preferably with a vegetation soil ( 10 ) is produced by the method according to claim 3, characterized in that the spacers ( 8th' ) made of steel wire are 20 to 70 cm long and angled at one end by approx. 90 ° and with this angled part ( 11 ) several strands of thread ( 14 ) the geogrid track ( 5 ) at least some filling layers ( 21 - 25 ) reach behind and at the other end a U-shaped hook ( 12 . 12 ' ) which rods ( 16 ) the stiff mesh mat ( 7 ) reach around and keep them at a distance. Earth slope according to claim 7, characterized in that the U-shaped rod ( 16 ) the stiff mesh mat ( 7 ) encompassing hooks ( 12 ) is formed by bending through 180 ° and when the spacer is arranged horizontally ( 8th ) to the core area ( 1 ) is open. Earth slope according to claim 7, characterized in that the U-shaped rod ( 16 ) the stiff mesh mat ( 7 ) encompassing hooks ( 12 ) is formed by turning through 90 ° and then by bending through 180 ° and is open when arranged horizontally in the horizontal plane.