WO1985002212A1

WO1985002212A1 - Process for building by sectors a slit trench foundation wall

Info

Publication number: WO1985002212A1
Application number: PCT/DE1984/000237
Authority: WO
Inventors: Winfried Rosenstock
Original assignee: Winfried Rosenstock
Priority date: 1983-11-10
Filing date: 1984-11-07
Publication date: 1985-05-23
Also published as: PT79484B; ZA848699B; EP0161311B1; DE3340725A1; AU3672684A; EP0161311A1; PT79484A; DE3470899D1

Abstract

Two holes (9, 10) are dug into the ground, at a certain interval from each other, and are as wide as the future slit trench foundation wall and have the definitive depth of said wall and are filled during their formation with a thixotropic liquid, so that the final interval separating the holes is suppressed and is also filled with the thixotropic liquid, and so that the whole segment is then filled with concrete from the bottom to the top while the thixotropic liquid is discharged. The invention provides during the construction of the slit trench foundation wall into a rocky underground, to dig into the ground between the two holes (9, 10) a drilling hole (16) provided on its length with an explosive charge (17); at the lower end of the two holes a pressure effect is produced during a short time lapse, which pressure effect enables to take out temporarily the thixotropic liquid from the holes and to discharge it upwardly, as well as to fire the first explosive charge (17) during the discharge of the thixotropic liquid. The discharge may be carried out by means of a second explosive charge (18) placed at the bottom of each of the two holes, the second explosive charges (18) being fired a little before the first explosive charge (17) is fired. It would also be possible to cause a pressure air thrust at the bottom of both holes (9, 10) a little before the firing of the first explosive charge (17).

Description

Method for producing a diaphragm wall in sections

In recent years, diaphragm walls have become increasingly important for the manufacture of vertical walls, whether as load-bearing walls made of reinforced concrete or as sealing walls to prevent the flow of groundwater.

Compared to sheet piling, diaphragm walls have considerable advantages because they can be carried out without noise and vibration and then do not meet the requirements of numerous cities in residential areas, in the vicinity of hospitals and rest homes, as well as near vibration-sensitive buildings. In many cases, their use makes it possible to dispense with groundwater lowering or to restrict it and thus build it more economically, because lowering groundwater often creates the risk of subsidence with damage to neighboring buildings, and finally, diaphragm walls enable the construction of deep streets , Underground railways, etc. directly next to existing buildings to largely avoid the damage to neighboring buildings caused by underpinning.

The diaphragm walls are produced in sections, with z. B. a section of a certain length is excavated and concreted, whereupon the next section is excavated and concreted in the same way, so that subsequently

O

Λ WI The section remaining between the two sections produced can be excavated and concreted.

Special grapples are used for excavating the soil, depending on the weight of the soil, a section can be excavated over its entire length or two holes can be made in the subsoil, which are as wide as the later diaphragm wall and extend to their final depth. whereupon the subsoil remaining between the holes is then removed by a gripper.

In any case, it is customary in diaphragm wall production to fill the excavated soil with a thixotropic liquid which is able to exert a strongly supporting effect on the walls. Such walls filled with thixotropic liquid remain vertically without any stiffening even with completely non-cohesive floors.

Diaphragm walls are generally created in thicknesses of about 40 to 60 cm. Their depth can be between about 10 to 50 m. So far, however, there has been no possibility of erecting diaphragm walls if the subsoil contains layers of rock, because grabs are then no longer usable, and drilling tools that are able to produce holes with a diameter of ^ Drilling from 0 to 60 cm to the required depths is not yet available.

On the other hand, there is often the need to provide a diaphragm wall even on a rock underground, z. B. to seal the valley below the dam base when building a dam.

The invention is based on a method for producing a diaphragm wall section by section, in which a section is formed by making two holes in the subsurface at a distance from one another which are as wide as the subsequent one.

OMPI

^ ^WI∑, ° There are diaphragm walls and extend to their final depth, which are filled with a thixotropic liquid during their manufacture, that the substrate remaining between the holes is subsequently removed and likewise filled with the thixotropic liquid, and that finally the whole Section is filled from bottom to top with concrete, displacing the thixotropic liquid.

The invention has for its object to provide a method of the aforementioned type which can also be used on a rock base.

The object is achieved according to the invention in that when the diaphragm wall is produced in a rock sub-base provided with a layer, if necessary, a borehole is made in the sub-base between the two holes, which bore a first explosive charge over its length is that a pressure effect is briefly generated at the lower end of the two holes, through which the thixotropic liquid is temporarily displaced upward from the holes, and that the first explosive charge is ignited during the displacement of the thixotropic liquid.

It is achieved by the invention that the rock base between the two holes is removed in layers and can then be removed with a gripper. The explosive charge is only weak and dimensioned in such a way that a dislocating effect does not occur beyond the width of the later diaphragm wall, but the dislocation in the plane of the diaphragm wall to be created is made possible by the fact that the holes with of the thixotropic liquid are filled, temporarily allow the rock between them to expand. Without this measure, ^'the explosion would not be able to influence in the desired direction, as di thixotropic fluid is incompressible and would the Explosionsdruc oppose an infinite resistance.

_Λ> IF - H -

The pressure effect in the holes is preferably generated by attaching a second explosive charge to the bottom of the holes and by igniting the second explosive charges shortly before the first explosive charge.

Instead, a blast of compressed air can also be generated at the bottom of the two holes before the first explosive charge is ignited.

However, in order to be able to produce the two holes in the rock underground at all, in a further embodiment of the method according to the invention it is provided that first two small holes are drilled in the center line of the route of the diaphragm wall in comparison to the slot wall, that in each Hole one or more containers each containing an explosive charge are used, the volume fraction of the explosive charges being small compared to the volume of the containers, so that the strength of the explosive charges is selected such that the rock underground is only approximately in the region of the thickness of the later diaphragm wall shattered in its structure, but remains approximately unchanged in its outer shape, and that the holes with their final large diameter are then drilled into the shattered structure.

This method, which is known in connection with the manufacture of sheet piling, in order to prepare a rock sub-base for ramming the sheet piles, enables drilling to be carried out in the first place without the otherwise unacceptable wear of drilling tools.

The invention is explained below with reference to the drawing. In the drawing:

Fig. 1 is a plan view of a trench wall section and

O PI FIG. 2 shows a cross section corresponding to the illustration in FIG. 1

In FIG. 1, lines 1 and 2 are the lateral boundaries of a diaphragm wall, and circles 3 and 4 are the contours of large boreholes that speak the width of the diaphragm wall and delimit a diaphragm wall section 5.

From Fig. 2 it can be seen that the diaphragm wall is to be installed in a terrain that has a rock surface 8 under its surface 6 and an overlay 7.

The diaphragm wall has a width of 600 mm, for example, and the center distance of the circles 3 and 4 is approximately 1.4 m, for example. As has already been mentioned above, the large boreholes 9 and 10 given by circles 3 and 4 around a rock underground cannot be produced by a drilling process.

For this purpose, boreholes 11 and 12, which are relatively small in comparison to the large boreholes 9 and 10, are first made in the center of the circles, and one or more containers 14 each containing an explosive charge 13 are inserted into the two boreholes 10 and 11 , the volume fraction of the explosive charges being small compared to the volume of the container, and then the explosive charges 13 are ignited, but the thickness of the explosive charges is dimensioned such that the rock underground is only destroyed in its structure approximately in the region of the thickness of the later diaphragm wall , however, remains almost unchanged in its outer shape, so that in this way the rock underground is prepared for the drilling of the large drill holes 9 and 10, without any major tool wear subsequently occurring during drilling. This means that only a comparatively small explosive charge is used, which does have its full shock effect in the lateral direction during the explosion.

JTTR

OM V / I tion can exert on the rock, but the gases expanding through the combustion find a sufficiently large volume in the container to be able to expand therein initially without acting on the rock adjacent to the borehole in such a way that it is displaced. The explosion gases, which cannot act downwards due to the massive rock underground, therefore escape from the container upwards into the borehole, without however creating the usual funnel. It is thus achieved that the rock adjacent to the borehole is not shot away, but is only broken up into the smallest grain fractions with a size of less than 0.5 cm. The large borehole can then be made in a rock surface prepared in this way without difficulty. The thixotropic liquid, which has the function here of preventing the overlay 7 from collapsing into the large boreholes 9, 10, is introduced into the large boreholes directly in connection with their production.

However, in order to be able to remove the rock subsoil 15 which has remained between the large boreholes 9 and 10, a borehole 16 is made approximately in the middle between the large boreholes 9 and 10, into which an explosive charge distributed over its length or a plurality of explosive charges 17 staggered one above the other are introduced become. These explosive charges are necessary in order to be able to remove the underground 15 economically. They must, of course, be dimensioned so weakly that there is no dislocation of the rock base adjacent to the diaphragm wall section, i. H. the effect of the explosion should be limited to the diaphragm wall width.

Ignition of the explosive charges 17 measured in this sense would, in the conventional method in which the large boreholes 9 and 10 are filled with the thixotropic liquid, lead to the explosive forces acting on an infinite resistance because the ^" Thixotropic liquid is incompressible, so that it does not have the desired effect is achievable.

According to the invention, it is now provided that a pressure effect is briefly generated at the bottom of the two large boreholes through which the thixotropic liquid is temporarily pushed upwards, and after this displacement, the explosive charges 17 are ignited, so that the rock masses are thereby removed from the area of the subsoil 15 can move in the direction of the large boreholes and thus obtain a structure which then allows removal by a gripper without difficulty.

The pressure effect at the lower end of the large boreholes can be created in different ways. A preferred possibility is that a small second explosive charge 18 is deposited on the bottom of each of the two large boreholes 9 and 10, which is ignited shortly before the ignition of the first explosive charges 20, so that the explosive charges 17 have their effect can unfold as long as the thixotropic liquid in the large boreholes 9 and 10 has been displaced by the action of the explosive charges 18.

Instead, however, the pressure effect can also be built up at the bottom of the large boreholes 9 and 10 by a compressed air source, which generates a burst of compressed air at the required point in time.

Since the effect of both explosive charges 17 and 18 is locally limited, the advantages of the diaphragm wall mentioned at the outset remain fully intact.

Claims

Patent claims

1. A method for section-wise production of a diaphragm wall, in which a section is formed by making two holes in the underground at a distance from one another, which are as wide as the subsequent diaphragm wall and extend to their final depth, and which are used in their production be filled with a thixotropic liquid, that the subsoil remaining between the holes is then removed and also filled with the thixotropic liquid, and that the entire section is then finally filled with concrete from below, displacing the thixotropic liquid, characterized in that that when the diaphragm wall is produced in a rock sub-surface (8), optionally provided with an overlay ^" (7), a borehole (16) is produced in the sub-surface (15) between the 'two holes (9, 10), which over its length has a first explosive charge (17) is provided that at the lower end de For both holes (9, 10) a pressure effect is briefly generated, by means of which the thixotropic liquid is temporarily displaced upwards from the holes (9, 10) and that the first explosive charge (17) is ignited during the displacement of the thixotropic liquid becomes.

2. The method according to claim 1, characterized in that at the bottom of the two holes (9, 10) a second explosive charge (18) is attached, and that the second explosive charges (18) are ignited shortly before the first explosive charge (17).

3- The method according to claim 1, characterized in that before the ignition of the first explosive charge (17) at the bottom of the two holes (9, 10) a blast of compressed air is generated.

OMPI 4. The method according to any one of the preceding claims, characterized in that the two holes (9, 10) are made in the rock underground by means that first in the center line of the route of the diaphragm wall, two small holes (11, 12) compared to the diaphragm wall thickness ) are drilled so that one or more containers (14) containing an explosive charge (13) are inserted into each hole, the volume fraction of the explosive charges (13) being small compared to the volume of the containers (14), so that the strength of the explosive charges ( 13) is chosen so that the stone base is only smashed in its structure, approximately in the area of the thickness of the later diaphragm wall, but remains almost unchanged in its outer shape, and that the holes (9, 10) with their final large size are then in the smashed structure Diameter are drilled.