SK135494A3 - Method of creating of thin walls in ground - Google Patents

Abstract

The invention relates to a method for making leaktight walls in the ground, of the type in which a pile is driven vertically into the ground along the path of the wall to be produced, by vibration, and raised back up, injecting, at low pressure, at the base of the pile, a conventional slurry and a jet of very high pressure liquid substantially in the plane of the wall and in the direction of the part of the wall to be produced. As the pile (1) is raised back up, a jet of very high pressure liquid directed towards that part (2) of the wall which has already been produced is sent to the bottom part of this pile, the very high pressure liquid which is sent to the lower part of the pile as it is lowered and as it is raised back up consists of a fluid slurry based on water, bentonite, additives, and cement, while a thick conventional slurry based on water, bentonite, cement, additives and an aggregate which gives it its consistency is injected at the base (6) of the pile as it is lowered and raised back up. <IMAGE>

Description

Technical field

The invention relates to a new improved method for forming thin sealing walls in the ground.

BACKGROUND OF THE INVENTION

It is known that thin-walled walls are used in the ground from a liquid composition capable of solidifying to form particularly continuous waterproof barriers. Such walls may, for example, have a thickness of several tens of centimeters and a height of twenty meters.

The Applicant has already proposed in European Patent Application 91402175.3 a method of forming such walls in which vibrations are grounded by beams provided at the bottom with a low-pressure injection device into the ground of a liquid composition which, when solidified, forms a thin wall, discharging horizontally in the lower at least one very high pressure liquid stream oriented substantially in the plane of the wall to be formed.

By the liquid discharged under very high pressure is meant according to this specification a liquid discharged at pressures of, for example, 200 to 600 kg per square centimeter.

The present invention is directed to an improvement of the method described above, which would make it possible to significantly improve the quality of the obtained thin wall and to increase its rate of formation.

SUMMARY OF THE INVENTION

The present invention provides a method of forming thin walls in the ground, in which it is punched vertically by vibrations and subsequently lifted the beams in the ground along the path of the wall to be formed, injecting under low pressure at the bottom of the beam a conventional liquid composition and very high liquid flow. a pressure substantially in the plane of the wall and towards the part of the wall to be formed, which consists in releasing, at the lower part of the beam, a stream of liquid of very high pressure towards the part of the wall already formed, and wherein the very high pressure liquid which is discharged at the lower part of the beam during its lowering and during lifting is formed by a thin liquid composition based on water, bentonite, additives and cement, while discharged at the lower part of the beam during lowering and lifting a conventional dense liquid composition based on water, bentonite, cement, additives and filler that confers her consistency.

As used herein, the term &quot; beam &quot; means a rigid metal profile, in particular of steel, which strikes the ground gradually along the path of the wall to be formed.

By the term additive is meant within the meaning of this description liquid or powdered products, the incorporation of which in a small dose causes changes in certain properties of the liquid composition in a fresh or cured state. The main ingredients are:

- solidification retardants, such as those based on sodium or ammonium lignosulfonate,

- liquids, such as those based on sodium lignosulfonate, sodium polyacrylate, naphthalene sulfonate and melanin,

- mineral activating agents such as sodium bicarbonate,

filtrate reducers such as organic polymers based on carbomethylcellulose.

The additives may also be formed by any product intended to modify the rheology of the liquid compositions under conditions occurring on site (e.g. anti-gel products).

Contrary to what might be feared, injecting a thin liquid composition at high pressure while lifting the beam towards a portion of a wall already formed of a dense liquid composition does not disturb the structure of the so formed wall, but on the contrary allows perfect, if necessary, the continuity of the wall to exclude parts of the soil that could reach its thickness when driving the beam.

The invention thus makes it possible to give the wall a perfect connection and to improve its quality. In addition, it has been shown that injecting a high pressure liquid when lowering a beam, which is a thin liquid composition, facilitates a thin wall of good quality.

It should be pointed out that according to the invention, the liquid composition injected under low pressure in the lower part of the beam during punching and lifting it has a relatively high consistency such that the strength, flexibility and impermeability of the wall and its resistance to erosion can be achieved.

Conversely, a liquid composition that is injected under very high pressure into an already formed wall when lifting a beam is a liquid composition that is very thin and fluid, based solely on water, cement, bentonite and additives, so there is a legitimate concern whether injection of such a liquid composition under very high pressure would not lead to the loss of essential properties of the already formed part of the wall, such as its strength, flexibility, impermeability, and erosion resistance.

Despite these concerns, it has been shown in practice that such a liquid composition discharged under very high pressure into an already formed wall when the beam is lifted again blends perfectly with the dense liquid composition that served to form the wall, improving the homogeneity and other properties of the wall.

According to the invention, it is preferable that the axis of the nozzles mounted on the lower part of the beam from which the thin liquid composition is discharged under very high pressure is easily inclined downwards, for example by 8 to 20% relative to the horizontal direction.

According to the invention, it is preferred that the nozzles which do not discharge the liquid composition under very high pressure at different stages of the process, nevertheless allow a low flow out of the liquid composition under low pressure to prevent them from clogging.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be explained in more detail in the following description by way of example with reference to the accompanying drawings, in which:

Fig. 1 shows an overall diagram of an embodiment of the method according to the invention, FIG. 2 shows a detail of the lower part of the beam used in the method according to the invention, FIG. 3 is a section along line III - III in FIG. 2, FIG. 4 shows a diagram of injection molding carried out in the lower part of a beam when it is driven in, and FIG. 5 shows an injection scheme corresponding to FIG. 4, but carried out when lifting the beam again.

DETAILED DESCRIPTION OF THE INVENTION

In FIG. 1 is a schematic representation of the means used to practice the invention. The device comprises a beam 1 intended to be driven into the ground to form a thin wall 2. For this purpose, the beam at its upper part is provided with a vibratory stopper 3, operated, for example, by a powerful hydraulic motor that vibrates the beam to be driven into the ground.

The vibratory stopper 3 is supported by a mast of a schematically shown lifting machine 5, shown schematically. The beam 1 is guided as it descends through a device connected to a lifting machine 5, which is not shown for the sake of simplicity of the drawing. The diagram of FIG. 1 shows the hammering of the beam 1, indicated by the arrow F.

According to the invention, under the beam, a conventional thin wall-forming dense liquid composition is ejected under low to very high pressure, discharged through the nozzle 6, while being blown backward under high pressure, i.e., at a high pressure. transporting in the drawing, towards the soil in which the thin wall is to be formed, a thin liquid composition.

In FIG. 2 shows a special embodiment of a beam 1 having a central web 8 and two flanges 9. The central web 8 has a reinforcing thickness reinforcement 8a in its lower part. Likewise, the flanges 9 are provided with reinforcing thicknesses 9a.

As shown in FIG. 2, the left flange 9 and its reinforcing thickness reinforcement 9a are extended downward beyond the range of the central web 53. On the outside of the left flange of the beam 1 is located a wing 10 extending in the extension of the central web 8 so as to move a wall that has already been formed and stabilizes the beam's path as it descends.

Below the central part of the beam is shown a double nozzle 6, fed by a duct 11 with a dense liquid composition under low pressure, while the left flange has two nozzles 12 and 13 in the reverse directions at each bottom, each fed with a thin liquid composition under very high pressure. separate pipes 14 and 15.

In FIG. 3 shows the central web 8 and the beam flanges 9, as well as the reinforcing thickness reinforcements 8a and 9a and the vane 10. There are also obvious nozzles 6, 12 and 13 and their supply lines 11, 14 and 15.

In FIG. 4 is a schematic representation of the lower part of a beam as it sinks into the ground during its driving. In this movement, the beam 1 is guided so that it preferably lies at the interface between the part of the wall 2 which has already been formed and the part of the soil to be sealed lying to the right in the drawing.

As the beam descends, a dense liquid composition of the type typically used to form sealing walls, based on water, bentonite, cement and filler, is discharged by a double nozzle 6 under a pressure of several tens of kilograms per square centimeter. This discharge of the dense liquid composition is essentially intended to facilitate the penetration of the beam into the ground by the vibration that is imparted to it.

At the same time, a thin liquid composition based on cement, bentonite, additives and water is injected under very high pressure, for example 600 kg per square centimeter, through a nozzle 12 to the right towards the soil in which the wall is to be formed. According to a particular embodiment of the invention, the axis is inclined approximately 15% downwards with respect to the horizontal.

As the beam descends, the thin liquid composition is also fed into the nozzle 13, which is oriented towards the already formed wall 2, but only under a pressure of a few kilograms per square centimeter and only to block line 15 and nozzle 13.

Thus, in this first phase of the method of the invention, the thin liquid composition, which is discharged under very high pressure by the nozzle 12, causes the soil to be disrupted and impregnated under the beam, which greatly facilitates and accelerates the descent of the beam to create space in which the wall will be formed.

In FIG. 5 shows the lower part of the beam and the injection molding carried out according to the invention during the beam stroke. During this second phase, the dense liquid composition continues to be discharged under the beam by a double nozzle 6 at a pressure of several tens of kilograms per square centimeter, so that the cavity left in the soil by the beam retreats and the adjacent soil that was loosened during the beam descent. At the same time it is discharged according to the invention through a nozzle. 13 shows a flow of a thin liquid composition under very high pressure to the left towards a thin wall 2 that has already been formed.

It is noteworthy that the liquid composition thus discharged is intimately mixed with the dense liquid composition which has been applied by the nozzle 6 during the previous descent and the lifting of the beam, thus improving substantially the quality of the wall thus obtained.

During the lifting of the beam, the thin liquid composition also continues to be discharged at a pressure of a few kilograms per square centimeter through the nozzle 12 to prevent the nozzle and its feed line 14 from clogging.

The process according to the invention described above makes it possible to form in the ground at a high speed a wall of excellent quality, which has good continuity and tightness.

It is to be understood that the described embodiment is not limiting in nature and that it can be subjected to any desired variation without departing from the scope of the invention.

Claims (4)

PATENT CLAIMS A method of forming thin walls in the ground, in which the vibration is stopped vertically and subsequently rebounds the beams in the ground along the path of the wall to be formed, injecting under low pressure at the bottom of the beam a conventional liquid composition and a very high liquid flow a pressure substantially in the plane of the wall and towards the part of the wall to be formed, characterized in that, when the beam (1) is being lifted again, a very high pressure liquid flow towards the part already formed is discharged in the lower part; a very high pressure liquid, which is discharged at the lower part of the beam during its lowering and during lifting, is formed by a thin liquid composition based on water, bentonite, additives and cement, while at the lower part (6) of the beam is discharged and lifting a conventional liquid composition based on water, bentonite, cement, additives and filler component, which confers its consistency TenCate. (13) beam (2) walls, Method according to claim 1, characterized in that the stream of the thin liquid composition which is injected under very high pressure to the already formed wall when lifting the beam is substantially horizontal. Method according to claim 1, characterized in that the stream of the thin liquid composition which is injected under very high pressure when the beam is lowered is easily inclined downwards. The method of claim 1, wherein the stream of thin liquid composition is inclined downward by 8 to 20%.