NL8303115A - Undersea pile with air-lifting system - has bottomless conical or pyramidal chamber with fluidisation devices on outsides of walls - Google Patents

Abstract

The pile has an air-lifting system causing its end to penetrate the seabed. This has a bottomless box-shaped chamber into which the system extends from the top, its end being adjustable in the vertical direction. The chamber has conical or pyramidal walls (3), at an angle to the horizontal greater than 30 and pref. greater than 45 deg. Fluidisation devices can be mounted on the outside of the walls, which can have a number of openings near their bottom edges.

Description

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Post with one. air lift system for penetrating the pile end into an underwater surface.

The invention relates to a pile with an air lift system for penetrating the pile end into a bottom underwater, which is provided with a box-shaped chamber without a bottom wall, in which chamber extends from the top thereof at least one air lift-5 system. is provided with means for vertical adjustment of the lower end of the air lift system.

Such a pile used in a drilling platform is described in the article "scintour method uses air lift idea" in Offshore February 1979. This article discusses in detail the problems arising from sanding out and washing away of non-cohesive soil material around the pile ends due to water currents. A solution to these problems was found by having the spawn penetrate into the ground below the flushing and scouring level using air lift systems. With the aid of this system, the soil under the pile end is washed away by means of water jets, which loosened soil whirls into the box-like chamber open at the bottom near the end of the pile and is discharged in an upward direction by supplying air in the discharge pipe. The loosened soil is raised above the level of the soil into which the pile has to penetrate, and settles there, so that the pile can penetrate therein with little disturbance of the soil. The speed with which the pile can sink into the ground is directly dependent on the operation of the air lift system, while for pulling the pile out of the ground a ground plug must be pulled loose and at least lifted over a certain height.

The object of the invention is to improve the penetration system described above, while retaining and if possible improving the advantageous properties, such that both the insertion of the pile end into the bottom and the pulling out of it faster, with a minimum required force and a reduced disturbance and agitation of the soil around the pile can take place.

This is achieved according to the invention in that the chamber is provided with conical or pyramid-shaped walls, enclosing an angle greater than 30 °, preferably greater than 45 °, with the horizontal.These measures exert a horizontally inward directed force when the soil to be removed is pressed into the soil by the inclined walls of the chamber, 5 the comb walls act as a wedge-shaped knife edge, which also means large vertical edge stresses and thus the creation of ground instabilities These effects caused by the chamber walls significantly support and promote the ejection effect of the water jets and thus the power supply of the air lift-10 system, which now leads to an acceleration of the ground discharge and therefore of the penetrate the bottom of the pile end.

The soil removed below the pile end is poured vertically above the chamber again, so that a column of soil is formed above the chamber. This can again be brought under the pile end by the measures taken according to the invention with a minimum of required force and disturbance of the surrounding soil. To this end, the air lift system must first be turned on while the pole is being raised, while the pole is being held in place. In this way, a hollow space is created under the pile end. If the pile, at least the pile end · consists of a rod, tube or beam construction open next to the chamber, as is the case with a half-timbered pile, then by pulling up the pile the ground on the room will be shaped by the wedge shape from that chamber are laterally pushed away and can slide along the bottom edge of the chamber into the cavity formed below. By raising the pile, said hollow space is maintained - if necessary supported by the air lift system - so that the pile can be raised with a smooth movement with minimum force and disturbance from the bottom. It should also be borne in mind here that when the pile is raised in the chamber an underpressure is created, which further increases the influx effect of the soil. When the pile is pressed in, a downward pressure is exerted against this, which creates an overpressure in the chamber, which promotes drainage of the soil. .

Thus, in accordance with the invention, a system has been created which can effect the penetration of the pile end to the desired depth below the sanding depth simply and in a controlled manner, but in a simple, relatively controlled manner. low-force manner allows the pole to be pulled out of the ground again; all this under the least possible disturbance of the soil and the soil profile, that is to say leaving behind the least possible resulting footprint.

When the pile is pulled out of the bottom, the displacement of the soil along the outside of the chamber is advantageously promoted if, according to a further embodiment of the invention, fluidizing means are arranged on the outside of the chamber walls. A further reduction of the disturbance of the soil surrounding the pile end can be effected as. according to a further embodiment of the invention, the chamber walls are provided in their lower edge regions with a number of openings.

At least a large part of the soil to be moved then no longer has to move around the bottom edge of the box-shaped chamber, so that the soil next to the pile is less disturbed. This effect can be further optimized by providing the pile with an outer jacket in accordance with a further embodiment of the invention.

This embodiment has the further advantage that the ground above the chamber no longer has a connection with the ground surrounding the pile, which in turn results in lower lifting forces for the pile.

For this purpose, according to a further embodiment of the invention, the outer casing should extend at least at the maximum penetration depth, if the casing does not extend over the full pile length, as is customary with a lattice pole.

According to a further embodiment of the invention, in certain application cases, in particular with relatively great adhesion forces exerted by the ground, it is preferable that flux-dispersing means are arranged near the lower end of the pile on the outside thereof.

For piles with a large cross-section, it may be necessary to install several air lift systems within one pole. In accordance with the invention, it is then preferred that a number of lift systems, symmetrically arranged around the pile center line, be present, such as lift systems. such that the partially overlapping working areas of the air lift systems can cover most of the pile cross section without or almost without extending beyond that cross section.

With reference to exemplary embodiments schematically shown in the drawing, the pile with air lift system according to the invention will now be discussed and explained in more detail.

Fig. 1 shows a pole end with an air lift system according to the invention in cross section; Fig. 2 shows a section according to the line II-II in * fig. 1; Fig. 3 shows a cross-section corresponding to Fig. 2. of a modified embodiment; and Fig. 4 shows a correspondingly illustrated further variant.

Figures 1 and 2 show a bottom end of a lattice post 1, 15 of which only vertical uprights 2 are shown. The usual cross connections and / or braces, which are of little or no importance for an explanation of the present invention, have been omitted. The pile can be part of a lifting platform, for instance a drilling platform, as a so-called jack-up pile or as a more permanent construction element, of an anchoring system, etc., ie for all applications, whereby for the ensure and continue to give adequate support, even in cases where there is a risk of washing away from the ground, the pile to one. a certain depth must be introduced into the soil. In the present case, this can be thought of depths of 6-9 m. In addition, the pile should also provide sufficient load-bearing capacity in cohesive soil types without excessive penetration.

In the lower end of the post 1, a pyramid-shaped chamber 4 open at the bottom is formed between the uprights 2 by means of walls 3. In the top of the pyramid there is an opening, to which a guide tube 5 terminating in a flange 6 connects in an upward direction. Slidable and adjustable by means (not shown) a discharge pipe 7, a water supply pipe 8 and an air supply pipe 9 are accommodated in the guide pipe 5. The drain pipe 7 is open at the top and bottom, while the top ends of the pipes 8 and 9 are connected to feed pipes (not shown) and the bottom ends of 6303115 -5- The pipes 8 and 9 terminate in an annular chamber 10, which is arranged such that water is ejected at the bottom and. that air bubbles are introduced into the discharge pipe 7,

Adhesive disruptors 11 are provided near the lower ends of the uprights 2, which can for instance consist of thickenings and can be provided with water-repellent pipes.

For penetrating the pile 1 to the desired depth below the soil level 12 in non-cohesive soil types, the procedure is as follows.

When the pile 1 is lowered, it will sink to a certain depth in the non-cohesive soil due to its own weight. In general, this will not take place below the scrub level. For then further penetration of the pile, use is made of the air lift system 7, 8, 9. For this purpose, water supplied via the pipe 8 is ejected under pressure through the chamber 10.

In this way, soil to be discharged in the room is sprayed out and whirled up. At the same time, air supplied via the conduit 9 is introduced into the discharge pipe 7, in which an upward flow is created, which entrains loosened soil particles from the chamber 4. The soil 20 particles are led upwards via the discharge tube 7 to above the bottom level 12 and will sink downwards when leaving the tube 7 and thus end up on top of the chamber 3. The loosening of the soil to be raised is promoted in a particularly advantageous manner by the pyramid shape of the chamber walls 3, which enclose an angle greater than 30 °, preferably greater than 45 °, for example 60 ° with the horizontal. Due to such an inclined arrangement of the walls 3, which thereby form wedge-shaped knife edges, as it were, the walls exert a horizontal force inwards and cause large vertical edge stresses and thus ground instabilities, which makes the feeding of the air lift system considerably. promoted.

In this way, the pile 1 can be made to penetrate the soil in a relatively quick and simple manner, for instance to a depth of 6-9 m, whereby almost exclusively the soil under the pile is influenced and the soil around the pile is only slightly affected. is disturbed or stirred. The penetration of the pole 1 into the ground can be controlled by adjusting the height of the air lift system, i.e. of the chamber 10.

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Pulling the pile 1 out of the ground, for example for the purpose of moving the working island, starts with the activation of the air lift system, whereby a hollow space is created at the bottom of the pile, which is initially maintained 5. by holding the post 1 in place, that is to say, not lowering it further. If the said hollow space is sufficiently large, the post is pulled upwards. The wedge shape of the chamber walls 3 thereby pushes the soil away, which subsequently enters the hollow space along the bottom edges of the walls 3. Sliding of the soil along the top side of the walls 3 can thereby be promoted by the application of fluidizing agents there.

In this way the pile 1 can be smoothly pulled out of the ground without the need to lift large soil masses in the form of relatively high columns of ground or plugs over a considerable height. This method of pulling out of the ground also has the advantage that the ground around the pile is only slightly disturbed and that only a small footprint results.

In the flg. 3 and 4, variants of the exemplary embodiment discussed above are shown. Fig. 3 is a plan view of a chamber 4 of the same basic shape as that of FIG. 2. However, openings 13 are arranged near the lower edges of the walls 3, while the uprights 14 have a square cross-section and post-enclosing plates 15 are arranged between these uprights 14, which extend over at least the maximum penetration height. Adhesive disruptors can also be arranged at the lower ends of the uprights in this embodiment. The embodiment according to Fig. 3 has the advantage that the soil surrounding the pile is disturbed even less than in the exemplary embodiment according to Fig. 2, since when the pile is pulled out of the bottom, the soil via the openings 13 in the formed hollow space. This pile can also be pulled out of the soil with less force, because the soil within the plates 15 cannot adhere to that outside the plates, so that it can be considered that there is less soil to be lifted above the chamber 4 and the soil above the chamber 4 more loosely packed can flow away.

Fig. 4 shows a cross-sectional triangular lattice post 16, which is provided with three uprights 17. The chamber 4 is serving 8 5 C i 1 1 3 -7-.

* * Correspondingly but again pyramid-shaped, that is to say now with three walls 18 instead of four walls. The inclination of the walls is chosen equal to that according to Fig. 1. This construction, too, can be provided in accordance with what is shown in Fig. 3 with 5 cm sheathing plates and openings near the bottom edges of the walls 18.

It goes without saying that many modifications and variants are possible within the scope of the invention. For example, if the cross-section of a pile is so large that it cannot be adequately covered by an air lift system, several of these systems can also be arranged in one pile 10, each in a separate pyramid-shaped chamber or all in one such a room.

When using several air lift systems, it is preferred, because of the least possible disturbance of the soil surrounding the pile, that the circular working areas of the air lift systems 15 can cover at least partly overlapping the major part of the pile cross-section without or almost without reaching beyond that cross-section. In addition, it is of course also possible, when using a pile enclosure, to adapt at least its lower end to the selected air lift work pattern. Although there has always been talk of a pyramid shape for the agitation or swirl chamber, it will be clear that in the case of a circular cross section of the pile, a conical chamber is preferred. Depending on the cross-section of the pile, combinations of pyramid and conical chamber are of course also possible. It is important in this respect that the wedge shape 25 is retained, which presses inward when the soil penetrates into the soil and, when it is pulled out of the soil, guides the soil located above the chamber and presses it in the direction of the cavity formed.

The pile can also be used as a device for removing a column of soil from the ground. To this end, the pile is introduced into the soil to a certain depth in the manner described above, and then pulled out of the soil with the column of soil present above the chamber. In this way, minerals can be extracted, for example an amount of gold whose location has been previously determined, or a stirred soil sample can be taken.

A further application possibility of the pile according to the invention is the burial of material. For this purpose, before the pile is penetrated into the soil, the material to be buried is placed in chamber 4 in such a way that it is not moved by the air lift system, for example by placing it in a holder. After the pile has been sunk into the soil to the desired depth, the material can be unloaded and the pile raised. It is also possible to leave the pole in the ground.

In that case, the material to be buried can also be placed on top of the chamber 4. It is also relatively easy to excavate the buried material later and retrieve it above water.

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Claims (7)

1. Post with an air lift system for one in one. penetrate the bottom of the pile end, which is provided with a box-shaped chamber without bottom wall / in which chamber extends from the top thereof at least one air lift system, which is provided with means for being able to adjust the vertical position lower end of the air lift system, characterized in that the chamber is provided with conical or pyramid-shaped walls, enclosing an angle greater than 30®, preferably greater than 45 ° with the horizontal. Post according to claim 1, characterized in that fluidizing means are arranged on the outside of the chamber walls. Post according to claim 1 or 2, characterized in that the chamber walls are provided with a number of openings in their lower edge regions. Post according to claim 3, characterized in that it is provided with an outer jacket. Pile according to claim 4, characterized in that the outer casing extends over at least the maximum penetration depth. Pile according to any one of the preceding claims, characterized in that fluidization means are arranged near the lower end of the pile on the outside thereof. Pile according to any one of the preceding claims, characterized in that a number of air lift systems arranged symmetrically around the pile center line are present, such that the partly overlapping working areas of the air lift systems can cover most of the pile cross section cover without or almost without reaching beyond that cross-section. 8t λ a λ q 0 y 0 i i ö