DE4220746A1 - Protection of banks and underwater embankments to a depth of approximately 100 m - involves laying of several wire netting strips of customary width to form netting mat. - Google Patents

Abstract

The netting structure (1) comprises several net mats overlapping at their edges laid on a steep bank beneath the water surface and flattened out in the uppermost area at the water surface level. The original run (3) of the embankment is removed in order to obtain a locating surface with only slight inclination for the network. The upper ends of the netting mats are fixed to floor anchors, and the thus constituted mat field is secured with laterally arranged retaining pegs. The mats are also laid and secured on both sides by load bearers with extending arms. They are also coated with sealing material. USE/ADVANTAGE - To protect banks and underwater embankments against erosion.

Description

The invention relates to a method for producing a Schut zes for banks and steep slopes below the Was surface to depths of around 100 m, especially for protection of banks and underwater embankments of artificial ge water.

The artificial design of banks and underwater embankments is often determined by previous use. The inclinations angles and possible berms within the embankment are common the result of the technical device that this embankment left behind. The embankments can be used as examples artificially created driving water (canal, technically regulated Riverside), exploited gravel lakes or open-pit holes become. Open pit remnants usually occur in one mining for the extraction of mineral rocks or of brown coal. These technically designed embankments were omitted do not meet the requirements of the later episode from the outset use because the remaining holes are filled with groundwater the effects of natural forces from wind and water with waves and above and below water currents be viewed.

Since the effects of natural forces are not predictable, esp especially not with large open-cast mining holes with water surface  areas of several square kilometers often result in major consequential damage to the direct bank. It should be borne in mind that in the immediate Close to a residual hole an urbanized region with all Possibilities of use located. Please note here a residential area, the settlement of trade and industry, Roads, supply and disposal lines as well as leisure facilities in of any shape. If the natural forces mentioned occur now, so be there is a high risk potential due to bank demolition and gusts relocation to the hinterland. Depending on the para meters of starting rock, bedding density, grit lines, shear forces etc., slope slope and length, sea depth, water total area and embankment depth, wind frequency, wind directions, Wind force distribution, permanent water level depending on na natural fluctuations or depending on the use of the Third party water, such as industry and water supply population, and the resultant, sometimes very much Large differences in water levels can cause demolition and relocation for extremely different changes up to 10 m per year to lead.

The previous possibility of averting danger and / or danger Renal limitation consists in following with great technical effort of exploitation flatten the banks and embankments and on a hoping for a self-balancing profile that will have stabilized after years or decades. A Flattening of banks and embankments could have a volume of several Record millions of cubic meters.

Recent experiences on the northeast shore of Lake Senftenberg (Lau seat) and in other open-cast mine regions, however, show that a permanent stability is not guaranteed and reflected put this accept. Thus, subsequent uses, e.g. B. Bath beach uses, associated with a high risk potential. It should be noted that bathing beach uses without Ge set authorizations and cannot be prevented. Also Total closures are not feasible.  

It has been known for many years, embankments with stone fill secure and possibly the stone fillings as in dike construction to be provided with an asphalt coating. There is also the possibility ability to secure embankments with wire ballast boxes. This The variant is technically and economically only to a shallow depth or for relatively short embankment lengths, about 10 to 20 m feasible.

With a slope length of 60 or 100 m, for example a controlled entry of gravel or stones can not be guaranteed because the amount to be determined can far exceed an economically acceptable level. Ver drive on an industrial scale for laying prefabricated, connected wire ballast boxes are because of the ver bound mass of many tons per single compound not possible Lich. For example, if you wanted an area of 30 · 12 m Producing wire ballast boxes would be per pontoon and additional equipment Armor for pontoon anchoring and when filling the Boxes up to approx. 0.25 m with a specific weight of the wire matt plus stone gravel of approx. 0.5 t / sqm for one installation process about 180 t. Technical facilities for Mastering these tasks is not known. The currently Known technical performance is many times over wrestler.

The object of the invention is a method for producing a Protection for banks and steep slopes below the Water surface as well as a facility for carrying out the To create a process with which to ensure sustainable security Changes due to erosion, irrigation and the like. Independent gig of the slope length and slope as well as larger slope depths is possible, and without it being necessary, in the istzu was to intervene in the region to be secured in such a way that Gö inclinations in the underwater area have to be changed, and without the need to lower the water level. The Equipment manufactured in accordance with the process must be able to eliminate the natural dangers over decades. Which he  Solution according to the invention is characterized in that several Wire mesh tracks of commercial width to form a mesh mat placed side by side and joined together at the edges be that several net mats overlap each other on the endangered bank and embankment areas and with their top Ren ends are attached to ground anchors, the side rims that of the resulting mat field with laterally arranged Pegs are secured. One according to the invention This is what distinguishes the process of mesh cladding that they consist of several arranged side by side, to the Edges firmly interconnected network tracks, which consists of two superimposed layers are formed, and that a layer of geo-textiles arranged between the layers and with the network layers is connected.

In a further embodiment of the invention it is proposed that ready-to-install mesh mats with a sealing material layers. The geo-textiles used are advantageous mechanically consolidated, in particular needled, spunbonded nonwoven fabrics.

Further features which advantageously design the invention are in specified in the subclaims.

The devices designed according to the invention have a high Sealing ability against the effects of water without the water exchange that occur naturally must, to hinder, and without it being rinsed out when Groundwater exchange from the land comes into the water. Advantageous is further that on all upper and lower water parameters can be reacted flexibly. It should be noted that i. d. R. at least 30 m embankment depth can be sealed, but a further 60 m can be secured in sections. Rest holes often have depths between 60 and 100 m. The main senior and underwater currents with the greatest risk potential len are in depths of 15 to 20 m and in weakened form up to approx. 30 m. Among them are only groundwater exchange currents, source currents or low underwater currents bar.  

In the drawing, the invention is purely schematic based on a Embodiment shown and explained below.

Show it:

Figure 1 is a vertical section through a steep slope of a Ta building residual hole with a net cladding.

Fig. 2 shows the chain link Deten USAGE for the production of a power panel;

Figure 3 shows the cross section through the mesh panel.

Fig. 4 shows the edge area of a mesh panel with rod-shaped, vertical catch iron;

Figure 5 shows the cross section through a mesh panel using geo-textiles.

Fig. 6 is a plan view of a net cladding on a sub-water slope;

Fig. 7 is a diagrammatic representation of a net cladding, which is composed of two net mats that overlap with their neighboring areas, each net mat being composed of several net tracks and

Fig. 8 is a schematic representation of a laying process.

For proper storage and attachment of a network 1 , which consists of a plurality of net mats 29 overlapping at the edges, on a steep bank 2 below a water surface, the uppermost region can be flattened at water level. The original course 3 of the bank embankment, indicated in broken lines, was removed in order to create a support surface with only a slight inclination for the network. In this area, anchors 4 are driven into the ground and ensure that the network is adequately secured against slipping. In this area, the network can additionally be completely covered with a sufficient layer of gravel 5 , a layer thickness of approximately 30 cm being sufficient. In the network area marked 6 , the strongest attacks by natural forces, such as wind and the resulting waves and strong underwater currents, the network is additionally coated with sealing material. Below this, in area 7 , a network of mesh mats without registered sealing material is sufficient. In this area, the mesh mats are provided with rods 8 extending perpendicularly to the plane of the mat as catching iron.

Fig. 1 is only to give an overview of the course of a steeply sloping bank of a hole created by day mining.

To form the network are advantageously provided with six angular mesh metal networks with double torsion ver, as can be seen in FIG. 2. These nets 4 are usually wide and are delivered in rolls. In order to ensure a secure coverage of net mats, which are formed from individual net tracks, in the underwater area, an overlap between two net mats of at least 1.5 m is provided. In order not to make the ratio of usable area to overlap area uneconomical, a minimum width of a net mat of 12 m is provided. For the production, 4 m wide rolls are laid out next to each other and then connected to each other in the side area, for example with binding wire or clips. Advantageously, the use of a strongly galvanized wire and additionally coated with plastic is provided.

After the wire rolls have been rolled out and linked at the edges, a layer of geo-textiles 10 ( FIG. 5) is spread out flat on the net mats. Mechanically reinforced, needled spunbond nonwovens based on polyester with high tear, puncture and stretch resistance are advantageous. After being rolled out, they are also overlapped and then sewn or otherwise connected. After the geo-textiles have been laid and connected to one another, they are in turn connected to the mesh mat underneath at least at certain points in order to prevent mutual displacement. In addition, this increases the overall strength of a mat produced in this way. Finally, another mesh mat is placed on the top and connected with geo-textiles on the one hand and the mesh mat underneath. The two mesh mats are designated 1 a and 1 b in FIG. 5.

The total mat to be laid must be sufficient Have flexibility to adapt to the different sub to be able to adapt basic formations of a steep bank. In addition However, must be in areas of a bank or embankment that be are particularly exposed to attacks by natural forces Sealing material used in a mesh mat is brought. The mobility of the mesh mat is preserved, if the sealing material becomes permanently elastic. In spite of The use of a sealing material requires a certain amount of water exchange are made possible. Mixtures can be used as materials of bitumen, sand and gravel with the addition of pore formers to serve. The sealing material is of a thickness of little at least 2 cm on the prefabricated mat either hot or cold applied and then smoothed. It can after cooling time to be processed further.

Before entering the sealant, the second, upper Wire mesh mat with spacers at the desired distance brought so that a gap between the wire nets of about 2 to 3 cm.

So that the tension and the distance between the mesh mats is reached, wire pegs 15 are placed on both sides of a mesh mat in the bank to be protected, as can be seen in FIG. 6. The wire tension between the pegs 15 and the edges of a mesh mat is designated 16 . The entire mat, about 15 m wide and 60 m long, is aligned on the wire pegs.

The anchors arranged in the bank area 4 sufficient diam sers and corresponding length may be placed in concrete and other sealants. Bored piles, steel beams and the like can be used for this. The anchors must absorb all the tensile forces of the installed mesh mats.

Since, as mentioned at the beginning, currents often do not occur over the entire depth of the lake and therefore the depth of the embankment, but predominantly only to depths of approx. 30 m, sealing is only necessary to this depth. However, to secure deeper areas, only double, possibly triple, interconnected wire networks are used for this purpose, which are connected to one another by wire rings 17 or similar fastening means. The nets provided with vertically standing rods, in particular in the lower area at the edges, are bound at a distance of about 1 m and with a margin of about 20 to 15 cm and a height of 50 cm. Their job is to catch neighboring nets when laying them underground and also to ensure an overlap in the area that is not provided with sealing material.

Conventional mobile cranes with a suitable reach and lifting capacity can be used for laying. The cranes as load carriers are positioned at precisely defined, precisely measured locations. The anchors 4 as main anchor elements are also precisely measured so that they can be found again at any time by technical means. The load carriers pick up the ready-made net mats in order to lay them in the precisely defined positions. For this purpose, the nets can be weighted beforehand with weights at defined points in order to lower them securely against the water buoyancy and to anchor them to the wire pegs attached at the side. In this way it is possible to lay prefabricated net mats flush. The load carriers in the form of mobile cranes are designated by 20 according to FIG . A number of suspension ropes 21 are used for carrying and attach to several points of attack 22 , 23 and 24 distributed over the length of a mat. By means of tensioning cables 25 running in the diagonal direction, a connection is made with the anchors 4 arranged in the upper region. In the mat longitudinal direction duri fende and incorporated pulling, holding and tensioning ropes are designated by 26 .

For clarity, the abutting edges are shown in Figs. 6 and 7, 27 individual network paths 28, from which a mesh mat is composed illustrated. Fig. 6 shows a single, composed of several wire mesh tracks 28 mesh mat. Two such net mats 29 are shown overlapping one another in FIG. 7 in the installed state. The overlap area of approximately 1.5 m is indicated by 30 .

With the manufacturing and laying method according to the invention and the facilities created by it are not dangers for use by water sports enthusiasts or swimmers bound. There are no wires or stones exposed. Are against Dangers when using wire ballast boxes themselves appropriate bitumen not to be prevented. An association from Wire ballast boxes does not have the high flexibility of one Mat on, so that with a deformation always with breaks and Cracks in the wires can be expected. To also have a residual risk of Turn off sealing mats, they will arre under water animals, provided bathing use of the bank areas is planned. The finished mat can be held and held over the entire length Directional ropes are added. Because a mat is precisely measured , it can be found even years later and with Hal ropes can be retensioned if necessary. Directional ropes can be incorporated to help immediately a diagonal bracing and thus additional To achieve backup.

The manufacturing process ensures using the ge named materials a secure seal that protects the Banks and steep slopes before the effects of natural forces is sufficient. The weight differences between a siche tion of steep banks through the network according to the invention in the Ver equal to usual and known wire ballast boxes is considerable Lich, namely 1: 6 in favor of the network, so that this for the first time a rehabilitation of underwater embankments is made possible.

Claims (12)

1. A method for producing protection for bank and steeply falling embankments below the water surface to depths of about 100 m, in particular for the protection of bank and underwater embankments of artificial waters, characterized in that several wire mesh tracks of commercial width to form a mesh mat placed side by side and connected to each other at the edges so that several net mats overlap one another on the endangered bank and embankment surfaces and are attached with their upper ends to ground anchors, the side edges of the mat field thus created being secured with holding posts arranged laterally. 2. The method according to claim 1, characterized in that the Net mats with the help of two net mats on both sides erected load carrier with cantilever arms detected and relocated become. 3. Net cladding, manufactured and installed according to the procedure according to claim 1 or 2, characterized in that they from meh reren arranged side by side, with each other at the edges firmly connected network tracks, which consist of two of the arranged layers are formed, and that between the layers a layer of geo-textiles arranged and ver with the net layers is bound.   4. Net covering according to claim 3, characterized in that the ready-to-install mesh mats with sealing material are stratified. 5. mesh panel according to claim 3 or 4, characterized net that as geo-textiles mechanically consolidated (needled) Spunbond nonwovens are used. 6. mesh panel according to one of claims 3 to 5, characterized ge indicates that they are made of plastic-coated, galvanized Me tall wire is made. 7. mesh panel according to claim 6, characterized in that the wire mesh used hexagonal mesh with double Have torsion. 8. mesh panel according to claim 6 or 7, characterized net that the mesh panels with vertical and diagonal steel ropes are reinforced. 9. mesh panel according to one of claims 3 to 8, characterized ge indicates that as the sealing material with which the mesh mats are coated, a mixture of bitumen, sand, gravel and Pore formers is used. 10. Net covering according to claim 9, characterized in that the sealing material in a thickness of at least 2 cm is wearing. 11. Net covering according to one of claims 3 to 10, characterized characterized in that spacers between the two network layers are ordered with which the distance between the network layers is adhered to at least 2 cm. 12. Net covering according to one of claims 3 to 11, characterized characterized that the composed of individual network tracks net mesh in the edge areas with vertical, to the mats plane aligned steel bars are provided with which hooking in adjacent mesh mats and thus a safe one Overlap is allowed.