NL9201356A - Monolithic sheet-piling stabilizer - Google Patents

Abstract

Method for stabilizing a sheet pile which is composed of pile planks which have been driven into the ground next to one another and forms a revetment for an embankment feature or another sheet pile forming an earth-retaining structure, in which on the land side, parallel to the first sheet pile, a second, temporary sheet pile is arranged, earth is removed between the first and second sheet piles, and a monolithic body is then formed in the trench which has been formed, after which the second sheet pile can be removed. A pipe which is made from a suitably selected material, is watertight and is impermeable to the mixture forming the monolithic body can be arranged in the longitudinal direction of the trench, and the mixture is poured into this pipe and is then able to harden therein. <IMAGE>

Description

Title: Monolith sheet pile stabilization.

The invention relates to a method for stabilizing a sheet pile for a bank supply or other earth-retaining structure consisting of sheet piles driven from next to each other and driven into the ground.

In such revetments for the protection of water edges, such as moorings, embankments and similar bank facilities along waterways or other flood defenses, the strength, as well as the required driving depth, and thus the length of the sheet piles, are determined by the turning height of the sheet pile, that is to say the difference in height between the future water bottom and the ground mass located behind it, as a result of which the upper part of the sheet pile is loaded by the horizontal active soil pressure and often also water overpressure. The sheet pile wall may or may not be anchored in this case.

Sheet piling with a low retaining height, for example up to more than one meter, can consist of light, short and non-anchored sheet piles, which are only clamped in the ground.

At greater retaining heights (e.g. 5-6 m), only sheet piling fixed sheet piles should already be so strong and long that it is often technically and economically more attractive to use less strong and shorter sheet piles and those near the top thereof by means of anchoring anchor purlins and rods to plates, an anchor wall or similar anchoring bodies placed at a great distance (approx. 7 to 10 m) from the sheet piles on the landside. Such anchoring often results in a tighter route line than with anchored sheet piles.

However, there are situations where such sheet pile stabilization with anchor elements buried at a great distance from the sheet pile in the underlying strip of land is not possible and / or not desirable, for example due to property issues, vulnerable planting, planning destinations, buildings, road pavements, flood defenses and of such.

In these cases, anchoring using screw anchors may suffice at relatively low retaining heights, and at relatively large retaining heights with anchoring using grout anchors. However, these two anchoring methods, which do not require digging far into the underlying strip, are often considerably more expensive and moreover less reliable than the aforementioned anchoring methods.

In the case of so-called environmentally friendly banks, where a shallow strip of water is created on the land side of the revetment for the benefit of various types of plants and animals living above and below water, the anchoring methods described above are poorly applicable because they extend directly through and below the shallow land side. anchorage rods that form a water strip form obstacles for the major maintenance of this water strip, which is a commonly used machine.

The object of the invention is to avoid the stated drawbacks of the known stabilization methods for sheet pile sheet piling of the described type and thereby reduce the cost price for sheet pile stabilization.

To this end, according to the invention, a monolith body is formed on the land side of the sheet pile wall from a filler (for example mineral aggregate) and a binder, with cross-sectional dimensions such that the monolith body can absorb the active soil pressure of the underlying soil and any water overpressure. .

Because the monolith body lying on the land side against the sheet pile to be stabilized absorbs the active ground pressure of the ground behind and any water overpressure in the same way as a masonry retaining wall, the sheet pile is relieved with regard to this pressure and no further anchoring is required. The monolith body requires only a narrow ground strip (approx. 3 m) on the land side.

In a preferred embodiment of the invention, on the land side, a second temporary sheet pile wall, which is to be stabilized along the bank, can be arranged substantially parallel thereto, a second temporary sheet pile wall, the ground between the two sheet piles at least to the intended retaining depth is removed from the first sheet pile and the monolith body is formed in the trench thus formed. The second sheet pile can then be removed.

In the stabilization process of the invention, the first sheet pile to be stabilized serves as part of a formwork during the formation of the monolith body. In the completed bank supply, the first sheet pile serves primarily as protection of the cured monolith body against erosion and also as an anti-flooding screen, i.e. as a screen extending to a certain depth in the ground which prevents at least part of the soil underneath the monolith body is flushed from there. This means that the first sheet pile wall can be made relatively light and therefore relatively cheap. In particular, the first sheet pile wall can be light in the case that the sheet pile wall is installed at a bank that is relatively shallow at that time, so that it is possible to absorb a pressure difference (water / soil) over only a small height. After the sheet pile has been stabilized by the monolith body, the waterway along the sheet pile can be deepened.

The monolith body is preferably formed by depositing a mixture of a filler and a binder in the trowel state and allowing it to harden therein. This mixture may for example consist of a mixture of cement as a binder and soil removed from the trench, sludge removed from the waterway or externally supplied material, or a combination thereof, as a filler. Optionally, an additive can be added to the mixture, thereby immobilizing any impurities, i.e., bringing them into a chemically bonded state, so that these impurities no longer easily penetrate into the surrounding soil.

The dug trench will generally fill with water. When the mixture is poured into water for the formation of the monolith body, separation will occur, which must be prevented.

For this purpose, in further elaboration of the invention, a tube can be arranged in the longitudinal direction of the slot, made of a suitably chosen, waterproof and impermeable foil material for the mixture forming the monolith body, the tube of which dimensions are chosen such that the monolith body in the final form can be form-fitting. This tube is filled with the mixture, after which it can harden in the trench.

An additional advantage of the use of such a tube is that if contaminated soil or sludge, whether or not immobilized, is used for the formation of the monolith body, this soil is efficiently isolated from the environment. This prevents contamination of the environment by mixing or leaching the mixture or the finished monolith body.

The sheet pile stabilization according to the invention can be carried out as a continuous process, whereby the bank length of the second temporary sheet pile to be used need only be small relative to the length of the first sheet pile. When the part of the monolith body that extends along a certain length of the second sheet pile has hardened to such an extent that it is at least substantially dimensionally stable, the relevant length part of the second sheet pile can be removed and reused in a subsequent work compartment. As a result, only a small number of sheet piles for the second sheet pile are required.

To clarify the invention, some embodiments of the stabilized sheet pile wall will be described with reference to the drawing, in which the figures always show a cross-section of a waterway and an adjacent waterfront.

Figures 1-6 show successive stages of the method of stabilizing a sheet pile wall with a monolith body encased in a tube; and FIG. 7 shows a stabilized sheet pile at a waterway with an environmentally friendly bank, the monolith body being lower than the retaining height of the first sheet pile.

According to the drawing, the water 3 in a waterway 1 is bounded by a bottom 4 and a waterfront 2. For the protection of the base body 5 that forms the waterfront 2, and provisions arranged along it, such as moorings, loose walls, vegetation and the like, are used made from a first sheet pile wall 6 which is built up of sheet piles vertically driven into the ground. As can be seen from Fig. 1, a first sheet pile 6 is placed in the ground, the length of the sheet piles being greater than the intended retaining height of the first sheet pile 6, in the situation after the waterway 1 has been brought to the desired depth 7. It is then particularly favorable if, at the moment of driving the first sheet pile 6, the existing bottom 4 of the waterway 1 is higher than the ultimately desired bottom 7. As a result, relatively short and light sheet piles can be used for the first sheet pile 6.

At a distance from the first sheet pile wall 6, as shown in Fig. 2, a second sheet pile wall 8 is arranged on its bank side, at least substantially parallel to the first sheet pile wall 6, which second sheet pile wall 8 extends through the base body 5 from ground level 9 to a depth at least corresponding to the intended retaining height of the first sheet pile 6, the strength and driving depth of the planks of the second sheet pile 8 being chosen such that the active ground pressure of the adjoining ground body 5 during perform the process.

After the second sheet pile 8 has been placed in the ground, the ground mass 10 located between the first and second sheet pile 6, 8 is removed, at least to a depth corresponding to the intended retaining height of the first sheet pile 6, as appears from Fig. 3. In the slot 11 obtained in this way (Fig. 4), a hardening mixture 12 is applied, which mixture cures in the slot 11, thereby forming a monolith body 13 (Fig. 5).

By arranging a hose-like body or tube 14 in the slot 11, which is watertight and impermeable to the mixture 12 forming the monolith body, pouring the mixture 12 therein and allowing it to harden in the tube 14 in the slot 11 especially when the slot 11 is full of water, separation of the mixture 12 is prevented. This tube is indicated in Fig. 5-7 by a dashed-dotted line. An additional advantage of forming the monolith body 13 in the tube 14 is that any contamination contained in the mixture 12 cannot leak out into the environment.

The mixture 12 used to form the monolith body 13 may consist of a combination of a binder, such as, for example, cement, water and one or more of the following three fillers: at least part of the soil of the soil mass 10 ; at least a portion of the sludge 16 removed from the waterway; and externally supplied filler, such as sand.

In addition, an additive may be added to the mixture 12, which can immobilize any impurities present in the fillers, i.e. bind in such a way that these substances can no longer simply be leached out by the groundwater or otherwise get into the surrounding soil.

When the monolith body 13 has cured to the extent that it is at least substantially dimensionally stable, the second sheet pile 8 can be removed. This final phase is shown in fig. 6.

The possibility of being able to remove the second sheet pile 8 is particularly advantageous. After all, the second sheet pile wall is temporarily self-supporting in the phase after the excavation of the soil between the sheet pile walls and before the monolith body has hardened, so that for this second wall relatively long and strong and therefore relatively expensive sheet piles have to be used. The sheet piles removed from the second sheet pile 8 can be reused in a subsequent work compartment. This makes it possible with the method according to the invention to realize such a sheet pile stabilization with a second sheet pile 8 of short length relative to the length of the first sheet pile 6, over a large length, while moreover the sheet piles of the second sheet pile 8 remains.

When an environmentally friendly bank 20 is to be constructed along a waterway 1, whereby a shallow strip of water 17 is created on the land side of the sheeting formed by the first sheet pile 6 for the benefit of various types of plants and animals living above and below water, such as shown in Fig. 7, the tube 14 and hence the monolith body 15 should be sized such that the monolith body 15 from the bottom of the trench 11 has a height less than the retaining height of the first sheet pile 6, so that on top of the monolith body 15 a layer of soil 18, for instance half a meter thick, can be applied, above which a layer of water 17 can be situated.

Claims (8)

A method for stabilizing a sheet pile composed of side-by-side driven sheet piles, a sheet piling for the purpose of a bank supply or other earth-retaining wall, characterized in that on the land side of the sheet pile wall (6) a filler and a binder a monolith body (13, 15) is formed with cross-sectional dimensions such that the monolith body (13, 15) can absorb the active ground pressure of the back ground (5). A method according to claim 1, characterized in that a second, temporary sheet pile wall (8) is arranged on the land side at some distance from the first sheet pile wall (6) to be stabilized along the bank, substantially parallel thereto, wherein the soil (10) between the two sheet piles (6, 8) is removed at least to a depth corresponding to the intended retaining height of the first sheet pile (6) and in the trench (11) thus formed the monolith body (13, 15) is formed. Method according to claim 1 or 2, characterized in that the monolith body (13, 15) is formed by placing in the slot (11) a mixture (12) of at least one filler and a binder in the pourable state and the mixture (12) in the slot (11) is allowed to cure. Method according to claim 1 or 2, characterized in that at least a part of the soil mass (10) removed from the slot (11) is used for the filler in the mixture (12). Method according to claim 2 or 3, characterized in that soil or sludge (16) supplied from the waterway (1) is used for the filler in the mixture (12). A method according to any one of claims 3-5, characterized in that reagents are added to the mixture (12) to immobilize substances whose penetration into the surrounding soil is considered undesirable. Method according to any one of claims 2 to 6, characterized in that a watertight tube, made of foil material and impermeable to the monolith body (13, 15), which is impermeable to the monolith body (13, 15) in the longitudinal direction of the slot (11) (14) is applied, the dimensions of which are selected to include the monolith body (13, 15) in the final shape in a tight-fitting manner, the tube (14) being poured into the tube in one or the step in one step . Method according to any one of claims 2 to 7, characterized in that the length of the second sheet pile (8) is clearly less than the length of the first sheet pile (6), which becomes at least a part of the second sheet pile (8) removed when the mixture (12) extending along said portion of the second sheet pile (8) has cured to such an extent that the monolith body (13, 15) is at least largely dimensionally stable, and that said portion of the second sheet pile (8) becomes reused, such that the formation of the monolith body (13, 15), and thus the sheet pile stabilization, is carried out at least largely over time.