NL1010332C2 - Method for remediating dikes. - Google Patents

Description

Method for remediating dikes.

The present invention relates to a method for remediation of dikes by compaction.

Compaction of an old dike is primarily preferable to new construction or demolition and reconstruction for psychological and planning reasons.

It has proved suitable to use deep vibrators for recompressing an existing dike, which vibrate the bottom in such a way that the grains shift relative to each other by decreasing their mutual friction and rearrange to a geometrically densest stack, which leads to settling of the bottom but also to the appearance of cracks.

Years of experience have also been gained with dynamic intensive compactions, in which weights with a certain energy are beaten on the dike body.

Furthermore, reconsolidation of an existing mineral seal is generally used in combination with the remediation of dikes. Although such a reconstruction and amplification is inexpensive, it does have the following drawbacks.

20 - Optimal compaction is difficult on steep slopes, ie the possible sealing action is not fully obtained.

Cavities left behind can cause suffusion damage. This danger exists in particular in combination with seepage flows along the drought cracks.

The sealing action is reduced by root action as well as frost and animal influence.

Movements in the substrate or due to water pressure lead to cracks. If the dike crown 3 0 is raised at the same time as the remediation, the additional load on the subsurface triggers an additional settlement, which subsequently leads to cracks.

The thickness of the reinforcement, in particular in combination with an elevation of the dyke, is detrimental to the discharge cross-section.

The provision of sealing material presents a logistical problem.

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The installation of a mineral seal is weather dependent.

The installation of a mineral seal is mainly carried out by large contracting companies.

Dam, trench and narrow walls require dewatering of the dike core after compaction after a high water level or a long rainfall for backfilling and large equipment, for the use of which a dike must have a sufficient load-bearing capacity. In addition, as with presses by injection lances or spray jet reinforcement, such sealing walls require additional measures to avoid movements in the dike, otherwise damage to the soil reinforcement, due to movements of the dike, in the form of irreparable cracks, which can only occur in the most serious cases, ie for instance at the next high tide, can be determined when they lead to major damage.

Concrete slabs are often used as covering for dikes.

Protective layers for plastic sealing strips made of concrete-filled fabric formwork have been used in the construction of reservoirs for more than ten 20 years.

Due to the sensitivity to frost and drying, reinforcement by so-called concrete mats is not recommended. In addition, concrete mats require high over-casting, and the loss of their sealing function due to ion displacement has not yet been investigated.

The installation of an asphalt seal requires the production of a load-bearing flat substrate in order to obtain the retaining layer necessary for compacting the asphalt layers, whereby a special, device-intensive technique is required. In addition, the installation of asphalt seals is weather dependent.

Seals with plastic sealing strips are known from the construction of landfills and tunnels. Against the application in dike remediation, there are prejudices regarding the tolerance of larger stretches in several directions.

From DE-U-2 951 737 6.9 a drainage element is known for consolidating the drainage of the substrate at construction sites on a soft substrate, which consists of a stocking-like filter-stable fabric covering, which has a water-permeable filling, such as gravel or pebbles. , is filled.

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In addition, DE-C-44 07 747 discloses the use of deep foundation elements as well as a grain mixture applied thereon between two reinforcement layers for reinforcing railway tracks. An object of the present invention is to provide a method for remediation of dikes by compaction. which can also be carried out by small firms, and which can be easily adapted to any location for different circumstances and at the same time provide a safe dike 10.

The object is achieved according to the invention in that the key figures of a dike are first determined, after which the corresponding dike body is excavated up to the dike core, then the dike core is reconsolidated with the aid of 15 vibration compactions, dynamic intensive compaction and / or rolling, depending on the key figures, followed by a plastic sealing strip for sealing on the water-side embankment slope.

After the compaction, the bottom can first be replenished, in particular to compensate for the cracks that arise during movement of the subsoil and of the dike body, optionally applying a thin layer of silt or clay, and subsequently rolling and / or leveling . Another embodiment of the invention is characterized in that before applying the plastic sealing strip, an anchor trench is first arranged in the dike head and a sealing gap in the water side of the dike foot, after which the plastic sealing strip, preferably at least locally with an upper and / or the protective layer is spread and placed in the anchor trench as well as in the sealing gap, and then the anchor trench is filled with, in particular, bulk material, as well as the sealing gap, in particular clay concrete or clay sand concrete.

According to the invention, as a protective layer, a mechanically reinforced fleece of polypropylene fibers, preferably with a surface weight of about 400 to 600 g / m, can be laid.

According to the invention, it is preferred that as a plastic sealing strip a flexible, multi-way stretchable polyolefin strip, preferably co-extruded, is laid with a glass fiber reinforcement in the middle of the 1010332 4.

Another embodiment of the invention is characterized in that a two-layer textile formwork, preferably of a polyamide fabric, is spread on the plastic sealing strip to prevent slipping of a ground cover, after which concrete is pressed between the fabric layers to form a lattice structure, after which the gaps between the formed lattice lines are cut open and the resulting hollow spaces, in particular with a sandy soil, are filled, after which the soil which has been dug up initially, including the top layer, is preferably applied and rolled.

The invention furthermore proposes that concrete stone mats, in particular at the outer bend of bends in a river, be laid as outer protection, after which the joints between the individual concrete blocks are preferably filled with humus for sealing.

To increase the dike, deposits can be made on the landside embankment slope.

It is also proposed according to the invention that, between the densification of the dike core and the pouring, a drainage layer is built in, in order to gradually eliminate a water build-up as a result of an seepage or rainfall, without damage.

Sand and / or gravel, which is packed in the filter fabric on the land side to prevent erosion, can be used as a bulk material.

! An embodiment of the invention can further be characterized in that at least one gravel mattress, preferably made of a water-permeable gravel beaten in geotextile fabric, is built in between the drainage layer and the paving.

In addition, according to the invention, for the distribution of possible sliding joints, for the rapid introduction of a load into the deeper subsoil, and for the relaxation and removal of seepage water layers, gravel columns can be pressed into the land side of the dike core, on which the gravel mattress is preferably applied.

Geotextile-armed slopes can be applied to the dike surfaces.

Finally, the invention also proposes that an anchor is placed in 1010332 5 the dike body, to which coiled hoses can be attached, which, if necessary for a rapid dike elevation, can be unrolled and filled with water.

The invention is therefore based on the surprising insight into the use of a plastic sealing strip known from the construction of landfill sites and tunnel construction, in order to seal the water-side embankment bank, in particular the cracks resulting from the recompression, with a reconsolidated dike core. In contrast to all the seals used hitherto in dike remediation 10, the sealing action provided by a plastic sealing strip can be tested on site, so that this does not lead to unpleasant surprises, for example during high water.

The plastic sealing strip can be placed in a sealing gap for attachment, which moreover prevents an underflow at the water-side dike foot along the length of the sealing gap.

Furthermore, according to the invention, the plastic sealing strip can be placed between non-woven layers, which has the advantage that possible shrinkage cracks in the mineral seal cannot be transferred to the plastic sealing strip. The moisture present in the fleece also reduces the occurrence of shrinkage cracks. Finally, the nonwoven layers also equalize movements by settling between the bottom and the plastic sealing strip.

Further features and advantages of the invention will become apparent from the following description, in which an exemplary embodiment of the invention is explained in detail with reference to a schematic drawing. The drawing 30 consisting of one figure shows a cross-section of a remediated dyke according to the invention.

According to the figure, a remediated dike 1 according to the invention comprises a dike crown 3, a dike head 4, a water-side dike foot 5 as well as a landside dike foot 6, a densified dike core 2, the reconsolidation being illustrated by axes 7 in the figure. A deposit for the dike crown 3 is shown on the dike head 4. Furthermore, an anchor trench 10 in the area of the dike head 4 as well as a sealing gap 11 in the area of the water-side dike foot 5 for a plastic strip 1010332 6 embedded at least locally between two protective layers 12 and 14 can be seen on the water-side embankment slope. the anchor trench 10 being filled with sheet pile material and the sealing gap with clay-sand concrete. In addition, a formwork mat 20 with concrete filling, a bottom covering 30 and an upper layer 40 are provided on the water-side embankment embankment. The landside dike foot 6 comprises a drainage mat 50, with a displaced inner trench 60 next to it, gravel columns 70 with a gravel mattress 80 applied thereon, and on top of that filter fabric 90 with sheet pile material and a crushed stone grass road 100. an anchor 120 for raising the dike in the form of a hose 122 wound in a wire braided casing 121 is provided.

The above-described dike construction is obtained as follows: Pre-processing 15 - Probing of the dike body 1 to determine the layer density.

Drilling and probing of the landside dike foot 6. i - Determination of the area of the gravel pillars 70 and the | gravel mattresses 80.

20 - Determining the normal foundation or the lapse of the landside crash.

Possible construction of supply roads.

Seal on the water side

Excavating approximately 1 m of the dike crown 3 and laying 25 of these in the dike hinterland.

Excavation of approx. 50 cm from the top layer 40 as well as the bottom cover 30 and pouring of the water-side clay seal.

Reconsolidation of the existing dike core 2 by deep vibration. 30 - Recompression of the clay seal with sheep leg rollers.

Applying the bulkhead to the dike head 4 and compacting it with rolling mills.

Manufacture of the sealing gap 11 in the dike foot 5. Manufacture of a flat surface on the post-compacted clay seal.

Manufacture of an anchor trench 10 in the dike head 4. Placing the protective fleece 12 and the plastic sealing strip 13 on the clay seal with accommodation in the sealing gap 11 and the anchor trench 10.

4 0 - Filling the anchor trench 10 and rebuilding the 1010332 7 dike crown 3.

Filling the sealing gap 11 with clay-sand concrete 15. Applying a protective fleece 14 on the plastic sealing strip 13 and a geotextile form mat 20 for a concrete filling on the slope.

Re-application of the excavated soil 30 and the top layer 40 with protection by degradable landscaping mats. Manufacture of the 101 crown road with an asphalt-bearing top layer.

10 - Removing the supply route.

Placing stone mats (not shown) as additional protection.

Confirmation of the landzindice checker base

Thickness widening by impacted filling wall with flushing surface 15 in the form of the drainage mat 50 as well as of the filter fabric 90 including the pouring.

Remediation of the dike foot 6 with the gravel columns 70 and the gravel mattress 80.

Construction of the slope.

20 Additional security

Striking the anchor 120, so that during a catastrophe the hose 122 is hung in, unrolled and then pumped up with water.

The features of the invention disclosed in the above description, in the drawing, as well as in the claims, may be important individually or in any combination for the practice of the invention in their various embodiments.

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Claims (14)

Method for remediating dykes by compaction, characterized in that the characteristic numbers of a dyke are first determined, after which the corresponding dyke body is excavated to a dyke core, then the dyke core is recompressed, as with the aid of vibration compactions, dynamically intensive compaction and / or rollers, depending on the key figures, and subsequently a plastic sealing strip is applied for sealing on the water-side embankment slope. Method according to claim 1, characterized in that after the reconsolidation the soil is first replenished, in particular to compensate for the cracks that arise during movement of the substrate and the dike body, whereby a thin silt or 1 layer of clay is optionally inserted and then rolled and / or leveled. Method according to claim 1 or 2, characterized in that before applying the plastic sealing strip, an anchor trench is first arranged in the dike head and a sealing gap in the water-side dike foot, after which the plastic sealing strip, preferably, at least locally, is spread with an upper and / or lower protective layer and is placed in the anchor trench and in the sealing gap, and subsequently the anchor trench is filled with, in particular, bulk material, as well as the sealing gap, in particular clay concrete or clay-sand concrete. 4. Method according to claim 3, characterized in that a mechanically reinforced polypropylene fleece, preferably with a surface weight of about 400 to 600 g / m, is laid as the protective layer. Method according to one or more of the preceding claims, characterized in that a flexible, multidirectional stretch polyolefin strip, preferably co-extruded with a glass fiber reinforcement inlay, is laid as the plastic sealing strip 35. Method according to one or more of the preceding claims, characterized in that a 1010332 two-layer textile formwork, preferably of a polyamide fabric, is subsequently pressed onto the plastic sealing strip 40 to prevent slipping of a bottom cover, after which concrete is pressed to form a lattice structure, after which the interstices between the formed lattice lines 5 are cut open and the resulting cavities, in particular with a sandy soil, are filled, preferably the soil excavated initially, including the top layer, is applied and rolled. Method according to one or more of the preceding claims, characterized in that concrete stone mats, in particular at the outer bend side of bends in a river, are placed as outer protection, after which preferably sealing between the individual concrete blocks with humus to be filled. Method according to one or more of the preceding claims, characterized in that, in order to increase the dike in the landward side of the dike slope, pourings are applied. 9. Method according to claim 8, characterized in that a drainage layer is built in between the after-densified dike core and the collapse, in order to gradually eliminate a water build-up as a result of an seepage or rainfall, without damage. 10. A method according to claim 9, characterized in that sand and / or gravel, which is packed on the land side, in order to prevent erosion, from being used in the filter fabric, is used as a bulk material. 11. Method according to one or more of claims 8-10, characterized in that at least one gravel mattress, preferably of a water-permeable gravel encased in geotextile fabric, is built in between the drainage layer and the paving. Method according to one or more of the preceding claims, characterized in that sliders may be used for dispersion, for the rapid introduction of a load into the deeper subsoil, and for the relaxation and removal of 35 seepage water layers, gravel columns in the land side of the dike core, on which the gravel mattress is preferably applied. Method according to one or more of the preceding claims, characterized in that embankments are provided with 40 geotextile-reinforced embankments. 1010332 Method according to one or more of the preceding claims, characterized in that an anchor is placed in the dike body, to which coiled hoses can be fitted, which, if necessary, can be rolled off and filled with water for a rapid dike increase. i 101033?