NL2002881C2 - A WATER BARREL, INCLUDING A SANDY BOTTOM WITH A SLOPE, AND A METHOD OF MANUFACTURING IT. - Google Patents

Description

Water barrier, comprising a sandy bottom with a slope, and method for manufacturing it.

The invention relates to a flood defense, comprising a sandy bottom with a slope. The invention also relates to a method for manufacturing such a water barrier.

Such a water barrier is generally known. The flood defense can for example be a dune or a dike. The flood defense may be provided in addition to a water such as, for example, the sea. The water barrier can extend in a longitudinal direction of the water line 10. The flood defense comprises a slope with a height. The height is such that the flood defense protects behind land against high water, for example as a result of a flood or storm.

It is a drawback of the known flood defense that the transverse profile of the flood defense can be changed. In particular, it is a drawback of the known flood defense that the profile 15 is subject to erosion. The profile of, for example, a dune can change due to erosion due to wind and / or water. Dune erosion can occur near a dune. Dune erosion is the phenomenon that a large part of the dunes can turn off after a strong storm and high sea. Dune deposit is a natural process. After the turn, the sand gradually starts to blow up again. This leads to a certain surcharge which, however, is smaller than the deduction. Dune erosion, if the dunes are part of the seawall, poses a major risk of flooding the hinterland. Buildings that are built too close to the edge of the dunes can be undermined by the dune erosion and subsidence. A clear process can also occur with other flood defenses.

It is therefore an object of the invention to provide a water barrier, comprising a sandy bottom with a slope, wherein at least one disadvantage of the known water barriers is reduced or prevented. It is a further object of the invention to provide a water barrier with which the profile of the slope can be maintained and / or formed. It is also an object to provide a method for manufacturing a flood defense, with which at least one disadvantage of the known flood defenses is reduced or prevented.

In order to achieve at least one of the objectives, the invention provides a flood defense, comprising a sandy bottom with a slope, wherein the flood defense 2 comprises a geotextile at least partially placed in the soil for forming and / or maintaining the sandy soil, and at least three anchor elements placed in the bottom and brought into contact with the geotextile to form a geotextile screen, wherein at least two anchor elements are placed at a higher position in the slope relative to at least one anchor element. Due to the placement of the anchor elements, the geotextile screen is provided with a curvature, from a relatively high point on the slope, via a lower point on the slope, to another higher point on the slope. The curvature can be a V shape or a U shape. The geotextile screen can be zigzag in the slope. A bowl is formed in the geotextile screen. The geotextile is permeable to water, but is not permeable to the sandy bottom. The geotextile screen in the slope thus ensures that the sandy bottom is kept in place. The geotextile screen ensures that the slope is relatively well stabilized, preventing erosion and fall-off.

Preferably, the water-retaining structure comprises an additional number of anchor elements placed in the ground and brought into contact with the geotextile, wherein the anchor elements are alternately provided at a high and low position for forming a geotextile screen in a longitudinal direction of the water-retaining structure with a saw-tooth cross section. The size of the cup-shaped parts, such as, for example, the V-shaped parts, can vary. The geotextile screen can be zigzag. This stabilizes the flood defense over a certain length. This prevents the sandy flood defense from sliding. Erosion is also prevented.

On the other hand, it is possible that the water-retaining structure comprises an additional number of anchor elements placed in the ground and brought into contact with the geotextile, wherein two anchor elements, in a longitudinal direction of the water-retaining structure, are alternately placed at a high and low position for forming a geotextile screen with a dovetail-shaped cross section. Here too, the flood defense is stabilized over a certain length. This embodiment also provides a relatively good stabilization, and can for instance be used as an alternative to sheet piles.

To obtain a desired profile of the flood defense, it is possible that a top side of the geotextile screen protrudes a distance above the slope.

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Sand particles from the sandy soil will therefore be able to collect in a point of the V-shape or U-shape. The sandy bottom can hereby be pushed up between an upper part of the slope and the geotextile screen. In this way the profile of the flood defense can be formed into a desired safety profile. For example, it has been found that chipped sand from a dune is largely discharged by the flow. This sand will float on the dune. Because of this there is surcharge on the dune. The protruding geotextile screens hold the drifting sand better, so that the dune can be formed.

It is possible that at least one anchor element is a substantially hollow anchor element. The hollow anchor element is relatively light. However, the anchor element ensures sufficient strength. The anchor element can also be placed relatively easily.

In order to anchor the geotextile screen more thoroughly, it is possible that at least one anchor element is anchored in the ground with a binder. Anchoring 15 additional anchor elements is of course possible.

The binder may comprise a hardening grout. The mortar can be applied relatively easily, after which the mortar will harden. The anchor element will hereby be firmly anchored in the bottom.

In one embodiment, the anchor element comprises a bamboo pole. Bamboo is a relatively inexpensive and environmentally friendly material. Bamboo is also a relatively light and sturdy material. Bamboo is also relatively resilient.

The diameter of the anchor element can be approximately 20 cm. The anchor element can have a length that is between 3 and 6 m. This diameter and / or length of the anchor element ensures that the anchor element can be handled relatively well. The anchor element is also relatively easy to install in the ground.

The anchor element can, if necessary, be arranged such that it can be extended. For example, it is possible to use attachments, inserts and / or cleats to achieve dimensions greater than 3 to 6 meters.

In one embodiment, the water barrier comprises at least a second geotextile screen that is placed lower or higher on the slope than the first geotextile screen. The use of more geotextile screens at different heights will contribute to the stability of the flood defense.

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The second geotextile screen preferably extends substantially parallel to the first geotextile screen. The at least two geotextile screens may, for example, be cascaded in the flood defense. In this way the profile of the flood defense can be maintained over a width thereof.

It is possible that tops of the at least two geotextile screens coincide with a desired level of the slope. In this way it is possible to form the profile of the flood defense into a desired profile. The desired profile can be a safety profile. The safety profile can for example be based on a calculation level.

Preferably, at least one geotextile screen is placed in a foreshore of a coastline, and at least one geotextile screen is placed in a dune foot of a dune profile. The flood defense is in this case a dune. The geotextile screens can be placed in places where there is a relatively large change in the steepness of the profile of the dune. These places are usually the foreshore and the 15 dune foot. The geotextile screen in the foreshore can be partially or completely submerged in water. This geotextile screen is designed to protect the profile of the foreshore. Continuous erosion takes place in the foreshore due to the cyclical movement of the sea. Sea currents also ensure a continuous supply of sandy soil. This sandy soil can be collected in the foreshore with the aid of a geotextile screen. This allows the profile of the foreland in particular to be protected. The profile of the flood defense, at the location of the foreshore, can be maintained and / or formed. This increases the stability of the base of the flood defense. In combination with a geotextile screen in the dune foot of the dune, the entire flood defense is stabilized.

In order to increase the stability of the complete flood barrier, at least two geotextile screens are preferably placed in the foreshore, and at least two geotextile screens are placed in the dune foot.

According to an aspect of the invention, a method is provided for reinforcing a flood defense structure comprising a sandy bottom with a slope. The method comprises the steps of: applying a geotextile to the bottom; placing at least three anchor elements in the bottom, wherein at least two anchor elements are placed at a higher position of the slope relative to at least one anchor element; and bringing the geotextile into contact with the at least three anchor elements, and thus forming a geotextile screen. In this way it is relatively simple to provide a geotextile screen in a sandy bottom, and thus to reinforce the water barrier, such as for example a dune.

It is possible that the method comprises the steps of placing at least one additional anchor element in the bottom, and bringing the geotextile into contact with the at least one additional anchor element. In this way it is possible to place a relatively long geotextile screen in the bottom. The geotextile screen can, for example, extend in a longitudinal direction of the flood defense, and thus reinforce a large length of the flood defense.

The geotextile can be brought into contact with the anchor elements alternately.

The geotextile can be tensioned in such a relatively simple manner.

It is possible that the method according to the invention is repeated at least once. It is thereby possible to obtain an elongated geotextile screen, or to place an additional geotextile screen.

Repeating the method may include providing an additional geotextile screen at a lower or higher position of the ramp. In this way a system of geotextile screens is obtained with which it can be maintained and / or formed over a width of the slope.

The method may comprise the additional step of providing a groove in the bottom, and then placing the geotextile therein. In this way the geotextile can be placed relatively easily and quickly.

The groove is preferably provided in the ground with a groove cutter. In this way it is relatively simple, safe and quick to make a groove in a sandy bottom.

Preferably, arranging the anchor elements in the ground comprises screwing in the anchor elements. The anchor elements can thus be firmly anchored in the bottom. The screwing in of the anchor element also makes it possible to tighten the geotextile. Fitting the anchor elements by means of screwing in is relatively easy. The screwing in may be done manually, or with the aid of a machine designed for this purpose. The anchor elements can also be provided with a pointed head, such that screwing into the ground can easily take place. Applying a serrated edge can also facilitate screwing in.

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It is possible that the anchor element is hollow, and comprises at least one casing opening that runs from the outer casing to the inner casing, and which is in open communication with a filling opening at the top of the anchor element. The method may comprise the additional step of anchoring the anchor elements. The anchoring can be effected by injecting a binder under pressure through the filling opening and connecting the binder to the ground via the casing opening. The filling opening and the casing opening of the anchor element ensures that the anchor element can be more firmly anchored with a binder in a relatively simple manner. The binder may, for example, comprise a hardening mortar.

According to a further aspect of the invention, a geotextile screen is provided for use in a water barrier according to the invention, wherein the geotextile screen comprises a geotextile and at least three anchor elements.

The invention will be further described on the basis of a description of a number of exemplary embodiments shown in the figures. However, the invention is not limited to these embodiments. Although the invention is described on the basis of a number of explicitly stated advantages, the described embodiments also comprise a number of non-explicitly stated advantages. It is possible to submit a spin-off focused on one of these explicit or implicit benefits.

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In the figures show:

FIG. 1: a side sectional view of a dune profile provided with a system of a number of geotextile screens for maintaining and / or forming the dune profile; FIG. 2a and 2b: a top view and a perspective view of an embodiment of a geotextile screen;

FIG. 3a and 3b: top views of embodiments of the geotextile screen;

FIG. 4: a side view of an embodiment of the geotextile screen.

FIG. 1 shows a sectional view of a sandy coast 1 with a dune 2 and sea 3. The dune comprises a foreshore 11, a beach 12, a dune foot 13 and a dune top 15. The dune forms a sandy bottom with a slope. The sea 3 has a level or level that corresponds to the current level (for example NAP - Normal Amsterdam Level), and that is indicated by the line I. The calculation level, that is, the 7 expected storm surge level in the near future, taking into account with the rise in sea level, is indicated by line II. The anticipated level over a number of centuries, for example the calculation level over 200 years, is also indicated by the line III. The levels 11, Til in the near and distant future are higher than the current level 1. The current profile of the dune top is indicated by the solid line A. The current dune profile has a dune top 15. The height of the existing dune profile, which that is, the height of the top 15 may in some cases be insufficient for adequate protection against rising water. In particular, it may be that the height of the top 15 is insufficient for sufficient protection, starting from the calculation level II, and certainly the future calculation level III, if no measures are taken in the foreland of the flood defense. It may therefore be desirable to raise the dune profile to a desired profile. The desired or required profile of the dune 2 is indicated by the dotted line B. In the desired profile, the dune has a dune top 14 which is higher than the dune top 15 of the current profile A.

A number of geotextile screens 21-25 are provided in the dune 2, for forming and / or maintaining the dune thereby. The geotextile screen can comprise a number of anchor elements, as well as a geotextile brought into contact with the anchor elements. In the embodiment shown, the anchor elements and the geotextile are arranged substantially vertically in the bottom. Another placement, such as, for example, a somewhat sloping placement, is of course possible. Each geotextile screen 21-25 preferably extends substantially in a longitudinal direction of the border between land 2 and sea 3 (also referred to as the water line). The geotextile screens 21-25 can run substantially parallel to each other. However, it may be advantageous to locally place two geotextile screens at an angle with respect to each other.

As described below with reference to FIG. 2 and 3, the anchor elements of one geotextile screen are placed at different heights in the slope. All-round V-shaped or U-shaped parts are provided in the geotextile screen. The V-shaped or U-shaped parts can be formed in the geotextile such that the geotextile screen is zigzag in the slope. The V-shaped, 30 or U-shaped parts form receiving parts. The open sides of those receiving parts face the top 15 of the ramp. The open side forms, as it were, a collection tray for sandy soil, to prevent the sand from moving from the dune to the sea.

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The geotextile screen 21, 22 can be largely underground. In this way it is ensured that the sandy bottom 2 is kept in place. The sand is stopped so that it cannot move towards the sea (in the direction of lower potential). This increases the stability of the slope.

In addition, it is possible that part of the geotextile screen 23-25 is above the ground. This makes it possible to form the profile of the flood defense. For example, due to influences of the wind, the sand will be led in the direction of the top 15 of the slope. Gravity will then cause the sand to move toward the foot of the slope. The sand will then be collected by the geotextile screen. Sand is deposited in the geotextile screen, which increases the profile of the flood defense.

It is possible to provide a system 5,6 with a number of geotextile screens 21-22,23-25 in the bottom. The geotextile screens are spaced apart from each other and are placed at a higher or lower position in the slope relative to each other. The geotextile screens can extend substantially parallel to each other. The tops 28 of the geotextile screens can protrude above the ground 2. The tops 28 can be positioned such that they coincide with a desired dune profile B.

The geotextile screens can be provided in various places in the dune 2. In the embodiment shown, in the front bank 11, two geotextile screens 21, 22 are placed at a mutual distance from each other. The geotextile screens in the foreshore 11 form a system 5. The system 5 is located below the water level. The system 5 prevents erosion of the foreshore 11 and, as it were, protects the foundation of the dune. By protecting the foreshore 11, and keeping the water depth on site relatively shallow, the energy of the waves can be dissipated locally. The force of the waves reaching the beach 12 and the dune base 13 will therefore be relatively small. In fact, this also protects the dune profile at the location of the top 15. To form the dune profile at the location of the foreshore 11, it is also possible that the geotextile screens 21, 22 partially protrude from the ground. The geotextile is water permeable, so that the water can move freely through the screen. However, the geotextile is not permeable to sand, so that the sand carried by the flow is kept in place. The geotextiles are relatively strong, so that they act as a reinforcement layer for keeping part 9 of the dune in place. This will make local sand deposits possible, and the foreshore will become less deep.

In order to break the wave attack during high tide and storm, the system at the foreshore can be provided with geotextiles that are lowered seaward and are provided with self-inflatable compartments at the top that rise at a certain water level and / or storm and thus the wave attack will break.

In the dune foot 13 there are three geotextile screens 23-25 at a mutual distance from each other. These geotextile screens 23-25 also form a system 6. This system is positioned such that sand deposits will lead to the formation of a dune with a desired dune profile B. The tops 28 can, for example, coincide with the desired profile, but can also be placed above it . It is also possible to place additional geotextile screens, for example by placing a geotextile screen near or on top. It is also possible to place these additional geotextile screens over time, such that the dune profile is already slightly raised.

FIG. 2a and FIG. 2b show a top view and a perspective view, respectively, of (a part of) a geotextile screen 31. The geotextile screen comprises a geotextile 35, which is brought into contact with at least three anchor elements 32-34. The anchor elements 32-34 ensure that the geotextile 35 is tensioned. The geotextile can be arranged alternately around the anchor elements, such that the geotextile can easily be tensioned. The anchor elements 32-24 are zigzag relative to each other. The anchor elements 32-34 form a triangle. A base is formed by an imaginary line between anchor 34 and anchor element 32. The geotextile runs between anchor element 34 and anchor element 33 with an angle α with respect to the base. Anchor element 33 has a distance δ perpendicular to the base. The geotextile screen thus forms a V-shaped cross section. It is possible that two anchor elements 32,34 are placed at a higher position in the slope relative to each other than one anchor element 33.

In FIG. 3a and 3b, embodiments of geotextile screens are shown. FIG. 3a 30 shows a geotextile screen 41 with a number of anchor elements 42,43,46 which have been brought into contact with a geotextile 45. The geotextile can be connected to the anchor elements by means of suitable means such as, for example, Velcro. The anchor elements are positioned such that a dovetail-shaped geotextile screen 41 is formed. In the geotextile screen, receiving parts 47, 48 are thus created. Fig. 3b shows a geotextile screen 51 with a saw-tooth shaped cross-section, as a result of a suitable placement of anchor elements 52, 56 and the geotextile 55. Here, too, receiving parts 57,58 have been created.

FIG. 4 shows a side view of a part of a geotextile screen 60 according to an embodiment. The geotextile screen 60 is placed in a sandy bottom 61. The geotextile screen 60 projects a part above the bottom surface N. The geotextile screen comprises a geotextile 65 with height h, which has been brought into contact with the anchor element 62 with height H. The anchor element is placed deeper in the bottom 61 than the geotextile 65. The anchor element can be a hollow anchor element. A filling opening 67 is provided on an upper side of the anchor element. Casing openings 64 are provided on a bottom side of the anchor element. The casing openings 64 can be provided around the casing. The casing openings 64 are adapted to be able to anchor the anchor element 62 in a simple manner by introducing a suitable binding agent under pressure from the filling opening. This binder will then flow out through the casing openings 66 and come into contact with the sandy bottom 61.

It is possible to use different geotextiles. The geotextiles can, for example, be subdivided into woven, non-woven and knitted textile according to the manufacturing method. The materials most commonly used to make geotextiles are polypropylene and polyester, but other plastics such as polyethylene, nylon and fiberglass can also be used. Sometimes jute, hemp or coconut is also used. These materials are particularly suitable for use in situations where the geotextile must be biodegradable. In combination with an anchor element made of bamboo, a fully biodegradable geotextile screen is obtained. The water resistance of the different geotextiles can be different. A suitable water resistance of the geotextile can be selected as desired.

It will be clear to a person skilled in the art that the geotextile screen according to the invention can be used for maintaining and / or forming a water barrier. The application is not limited to an application in a dune with a sea. The geotextile screen can, for example, also be used for reinforcing other basic bodies. Application in a (sandy) dike is possible. Application 11 of the geotextile screen at construction sites is also possible. The geotextile screen can be used particularly advantageously at construction sites to prevent subsidence of the soil on or near the construction sites.

Apart from that, the geotextile screen according to the invention can help prevent various instabilities of flood defenses. These instabilities can be, for example, macro-instabilities (inward and / or outward), instabilities due to infiltration and erosion in transshipment, piping, and / or heaving. Those skilled in the art will be familiar with these instabilities, and will be able to position the geotextile screens such that these instabilities are prevented.

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Claims (24)

1. Water barrier, comprising a sandy bottom with a slope, wherein the water barrier comprises a geotextile at least partially placed in the bottom for forming and / or maintaining the sandy bottom, as well as at least three anchor elements placed in the bottom brought into contact be with the geotextile for forming a geotextile screen thereby, wherein at least two anchor elements are placed at a higher position of the slope relative to at least one anchor element. 10 A water barrier as claimed in claim 1, comprising an additional number of anchor elements placed in the ground and brought into contact with the geotextile, wherein the anchor elements are alternately provided at a high and low position in a longitudinal direction of the water barrier for forming a geotextile screen with a saw-tooth shaped cross section. 3. Water barrier as claimed in claim 1, comprising an additional number of anchor elements placed in the ground and brought into contact with the geotextile, wherein in each case two anchor elements, in a longitudinal direction of the water barrier, are alternately placed at a high and low position for forming a geotextile screen with a saw-tooth cross-section. Water barrier as claimed in any of the foregoing claims, wherein a top side of the geotextile screen protrudes a distance above the bottom. 25 A water barrier according to any one of the preceding claims, wherein at least one anchor element is a substantially hollow anchor element. 6. Water barrier as claimed in any of the foregoing claims, wherein at least one anchor element is anchored in the bottom with a binder. Water barrier according to claim 6, wherein the binder comprises a hardening mortar. A water barrier as claimed in any one of the preceding claims, wherein the anchor element comprises a bamboo pole. 9. Water barrier as claimed in any of the foregoing claims, wherein the anchor element 5 has a diameter of approximately 20 cm. Water barrier according to one of the preceding claims, wherein the anchor element has a length that is between 3 and 6 m. A water barrier according to any one of the preceding claims, comprising at least a second geotextile screen that is placed lower or higher on the slope than the first geotextile screen. 12. Water barrier as claimed in claim 11, wherein the second geotextile screen extends substantially parallel to the first geotextile screen. A water barrier as claimed in claim 11 or 12, wherein tops of the at least two geotextile screens coincide with a desired level of the slope. A water barrier according to any one of claims 11-13, wherein at least one geotextile screen is placed in a foreshore of a coastline, and wherein at least one geotextile screen is placed in a dune foot of a dune profile. 15. Water barrier as claimed in claim 14, wherein the water barrier comprises at least two geotextile screens placed in the foreshore, and wherein the water barrier comprises at least two geotextile screens placed in the dune foot. A method for reinforcing a flood defense structure comprising a sandy bottom with a slope, the method comprising the steps of: 30. Applying a geotextile to the soil; Placing at least three anchor elements in the bottom, wherein at least two anchor elements are placed at a higher position of the slope relative to at least one anchor element. Bringing the geotextile into contact with the at least three anchor elements, and thus forming a geotextile screen. 17. Method as claimed in claim 16, wherein the method comprises the steps of placing at least one additional anchor element in the bottom, and bringing the geotextile into contact with the at least one additional anchor element. The method of claim 16 or 17, wherein the method is repeated at least once. 10 The method of claim 18, wherein repeating the method comprises providing an additional geotextile screen at a lower or higher position of the ramp. A method according to any one of claims 16-19, wherein the method comprises the additional step of providing a groove in the bottom, and then placing the geotextile therein. 21. Method as claimed in claim 20, wherein the groove is arranged in the ground with a groove cutter. A method according to any of claims 16-21, wherein mounting the anchor elements in the ground comprises screwing in the anchor elements. A method according to any one of claims 16-22, wherein the anchor element is hollow, and comprises at least one casing opening that runs from the outer casing to the inner casing, and which is in open connection with a filling opening on the upper side of the anchor element, wherein dc method comprising an additional step of anchoring the anchor elements, comprising injecting a binder under pressure through the filling opening, and connecting the binder to the ground via the casing opening. A geotextile screen for apparent use in a water-retaining structure as claimed in any of the claims 1-15, comprising a geotextile and at least three anchor elements.