DE29623502U1 - Buoyancy-proof sole, especially for an excavation pit in groundwater, which uses the sealing properties of natural soil layers - Google Patents

Description

DESCRIPTION

For the construction of excavations, especially in areas with high groundwater levels (e.g. Berlin) or changing groundwater levels (e.g. Rhine plain), the state of the art essentially provides two designs of a base by means of which the ingress of groundwater from below into the excavation pit is prevented:
Firstly, artificial sealing layers are present, e.g. a) a high sealing base (jet grouting, underwater concrete) which is anchored downwards via tension members (e.g. described in DE-OS 20 22 787, DE-PS 22 40 935 and DE 35 34 655 A1), or

b.) a deep sealing base (soft gel, jet grouting, fine cement) with sufficient overlay and deeper excavation pit walls.

At other times, natural, deep-lying, cohesive and therefore sealing layers, above which there is so much soil material that no uplift movement occurs, act as a sealing layer.
Devices of this type are described, for example, by U. Smoltczyk (Gundbau-Taschenbuch; Ernst und Sohn, Publisher for Architecture and Technical Sciences, Berlin).

The disadvantage of a first type of construction, as is specified in a similar form in DE 22 40 935, for example, is the high cost of producing a layer that reliably seals at low cost. Any leaks are difficult to subsequently close and even more difficult to reliably detect. The disadvantage of the second type of construction is that only very deep layers, over which there is enough material to prevent buoyancy, can be used, which requires very deep lateral sealing walls.

There is therefore still a need for a device that reliably prevents groundwater from penetrating through the bottom of the excavation pit.

The problem is solved by the means specified in the characterising part of the claims.

The invention provides for the use of naturally occurring sealing layers, even at higher levels, as sealing layers and for protecting these against the inevitable buoyancy by anchoring the material above them.

The material above the sealing layer itself does not have to have sealing properties. Either the material naturally present above the sealing layer itself can be used as a covering layer, whereby the pressure exerted by the sealing layer on the material above it is transferred to anchoring elements (eg piles, anchors, nails, dowels) which are anchored downwards through the sealing layer into the subsoil.
Or an artificial solid covering layer is created above the sealing layer, e.g. by means of jet grouting (Soil-Jet, HDI, Soilcre-

te ), which is fixed to the subsoil by means of anchoring elements.

In one variant, a possibility can also be realized that lies between the options given and in which individual, but larger bodies/seals/head elements take up the load, which can reach from the sealing layer to the bottom of the excavation pit or only extend over an area of it. The individual load-bearing parts of the anchoring element preferably have a diameter of the order of 1.5 meters and can partially be linked together to form larger conglomerates. The artificial continuous cover layer is to be seen as a particularly ordered special case of completely conglomerated elements of a certain shape.

The penetration of the anchoring elements through the sealing layer does not require an additional sealing compound if the element penetrating the sealing layer consists of a subsequently hardening compound, e.g. concrete suspension, which automatically adapts to the opening of the penetration through the sealing layer.

The artificial covering layer does not have to lie directly on the sealing layer, but there can be other soil material between the sealing layer and the covering layer, which acts as a force-transmitting medium. A layer thickness of this soil material that is no thicker than 1 meter is preferred, because then, despite the anchor elements not being prestressed during manufacture, after the load is removed when the building base is excavated, only a slight lifting of the sealing layer can take place when the buoyancy forces are applied when the substructure is tensioned.

Considering the general operating principle, the invention transforms water pressure into soil tensions with the help of a naturally existing impermeable layer. While water pressure is used to

If the generation of counterpressure requires a sealing layer, a permeable layer is also possible as a means of counteracting the soil tensions. The material between the sealing layer and the covering layer, possibly also the material of the sealing layer itself, acts as a force-transmitting medium on the covering layer, or the material in which the load is introduced into the anchoring elements.

An artificial covering layer can be made, for example, from overlapping columns produced using the jet grouting method (see Fig. 1 and 2). The resulting support grid can be suspended back into deeper soil layers using tension members. The columns do not necessarily have to be in contact everywhere and form a regular support grid: Free-standing columns or those that are only partially connected to one another can also be used.
The combination of an anchored pressure-absorbing layer with an underlying natural sealing layer has the following decisive advantages:

• The natural, very high-quality sealing layer is preserved and can be used. The anchoring elements (e.g. buoyancy piles) installed below the sealing layer do not impair its tightness due to the deformability of this layer.

• The requirements for the support grid described in the example are significantly lower than for an artificial base using a conventional method, since no watertightness is required.

· Since the deviations from the vertical increase with increasing depth of the retaining wall due to manufacturing, the positional accuracy at the foot of the wall is greater with the device according to the invention, which requires the use of shorter retaining walls compared to the deep sealing base.

• The reduction of the flow pressure gradient takes place almost completely in the sealing layer (e.g. till). If there are any weak points, the densely gridded support grid described as an example has an additional erosion-stabilizing effect and thus supports the reduction of the gradient.

• The support grid described in the example has a dual function, as it also represents a very rigid, horizontal base support for the retaining walls. The expected translational displacements of the retaining system from the excavation relief and the compression of the soil under the base of the excavation pit are thus reduced.

• Due to the high-quality sealing of the excavation pit, only a small amount of residual water retention is required.

• With a deep sealing base according to conventional constructions, relaxation must be ensured below the natural sealing layer (e.g. marl). This technically complex and sometimes risky relaxation is no longer necessary with the new solution.

• The water retention can be switched off at an earlier time.

In principle, there are inherent residual risks in the execution of any artificial sealing base in the process used (e.g. jet grouting). These also represent a risk to the construction company's schedule, as any additional sealing measures required and unforeseeable situations in the event of a leaky base can lead to disruptions in the usually tight construction schedule.

A risk assessment for the natural sealing base secured by a support grid against this background also results in the construction operational advantage of increasing schedule reliability.

The same argument applies when constructing very deep retaining walls. Deviations from the vertical that are within the tolerance have only a minor impact on the wall base position in the case of short walls.

When producing the described alternative buoyancy protection, no additional costs are incurred compared to the deep-lying artificial sealing base.

The production of an embodiment of the device according to the invention, as it is now to be carried out on one of the large construction pits in Berlin, is listed below as one of the possible variants without restriction of generality:

1. Exploration drilling to check whether there is a sufficiently dense marl layer.

2. Construction of a reinforced concrete diaphragm wall and the sealing wall with sheet pile wall installed up to 1 m below the lower edge of the marl or a maximum of 3 m below the upper edge of the marl. The marl layer is at a depth of 18 to 20 meters, the groundwater level is approximately 3 meters below the surface of the ground. The remaining soil material is sand, on top of which lies a layer of rubble from the Second World War.

3. Pumping test to verify the existing dense marl layer and parallel pre-excavation of the rubble.

4. Production of the medium-deep base using the jet grouting method (Soil-Jet, HDI) as a rigid support grid and installation of the anchoring elements. The anchoring elements are

They are not prestressed. They only come under tension when the load on the sealing layer is reduced when the excavation pit is dug.

5. Lowering the groundwater in the excavation pit and implementing the residual water retention system with two wells and drainage ditches, through which a constant lowering target is to be achieved. If required, vacuum lances can be used for locally deeper excavation areas.

6. Excavation of the excavation pit with anchoring and bracing of the excavation pit walls.

7. Floor slab and shell of basement.

8. Adjust the residual water level and close the well pots.

Fig. 1 shows a cross-section of an excavation pit according to the invention using the example of a construction project in Berlin. Not all anchoring elements are explicitly shown.

For the same example, Fig. 2 shows a section of the floor plan of a support grid with passages produced using the jet grouting method

Fig. 3 shows an example of how the buoyancy of the sole is prevented in a device according to the invention without a solid covering layer. Again, not all anchoring elements are implemented.

Combinations of Fig. 1 and Fig. 3 are also possible, in which the anchoring element continues above the covering layer, possibly into the base plate of the later building. In this case, the anchoring elements can also be used for the classic buoyancy protection of the later building.

The artificial covering layer, or in the non-closed version the support grid or the individual load-bearing elements, do not of course have to be horizontal, but can also be inclined or adapted to an existing irregular ground formation.

Legend

· 4

1 retaining wall (e.g. diaphragm wall, sheet pile wall, secant pile wall)

2 Excavation floor

3 Top layer

4a columnar part of the support grid (produced by jet grouting) with

Anchoring elements

4b. Column-shaped part of the support grid (produced using the jet grouting method) without anchoring elements)

5 Passage in the surface layer

6 naturally occurring sealing layer (e.g. glacial till)

7 Anchoring element (e.g. GEWI® piles, tension piles, anchors)

8 Terrain surface

9 Groundwater level

10a Introduction area of the main part of the buoyancy load into the anchoring element

(e.g. a post)

10b Load introduction area of the anchoring element (e.g. jet grouting pile)
11 Load transfer area of the anchoring element (e.g. GEWI® pile)

Claims (16)

Ed. Züblin AG P1272 Albstadtweg 3 DW/Brosig 70567 Stuttgart 08.06.98 CLAIMS 5 1. Buoyancy-proof sole, characterized in that it consists of the following components: - a sealing layer, - an overlying layer which absorbs the buoyancy force exerted by the sealing layer due to the water pressure, and - anchoring elements that prevent the buoyancy of the two layers. 2. Device according to claim 1, characterized in that the material located above the sealing layer, in which the anchoring elements are at least partially seated, is a solid covering layer which lies directly or at a distance from the sealing layer and on which the forces from below act either directly via the sealing layer or indirectly via material located between the sealing layer and the covering layer. 3. Device according to claim 1, characterized in that anchoring elements, e.g. piles, anchors, nails, dowels in the naturally existing material above the sealing layer absorb the buoyancy forces via skin friction or other suitable Load introduction structures, such as wide head elements, absorb and the anchoring elements are anchored in the subsoil below the sealing layer, i.e. the buoyancy forces absorbed by the load introduction structures are transferred there. 5 4. Device according to at least one of claims 1 to 3, characterized in that the layer thickness of the soil material which lies above the sealing layer and below that part of the anchoring elements which absorbs the majority of the buoyancy forces is on the order of maximum one meter. 5. Device according to at least one of claims 1 to 4, characterized in that the layer lying above the sealing layer, which absorbs the buoyancy forces, is itself not sealing or is only sealing to a lesser extent. 6. Device according to at least one of claims 1 to 5, characterized in that the sealing layer used consists of a naturally occurring water barrier which can be described as impermeable (e.g. boulder clay). 7. Device according to at least one of claims 1, 2, 4 to 6, characterized in that the layer absorbing the buoyancy forces is a solid cover layer which has the form of a support grid with openings. 8. Device according to at least one of claims 1, 2, 4 to 7, characterized in that it contains a covering layer which was produced by a jet-jet process. 9. Device according to at least one of claims 1, 2, 4 to 8,
characterized in that the covering layer which absorbs the buoyancy forces consists of only partially or not at all connected individual elements. 10. Device according to at least one of claims 1, 2 and 4 to 9,
characterized in that the covering layer is inclined relative to the horizontal or is adapted to the surface shape of the sealing layer. fits or takes on another useful, essentially horizontally selling shape that is modified from the basic horizontal planar shape. 11. Device according to at least one of claims 1, 2 and 4 to 10, characterized in that the covering layer represents the subsequent foundation of the structure to be constructed. 12. Method for producing a device according to at least one of the
Claims 1 to 11, characterized in that unplanned openings in the natural sealing layer are filled by an artificial sealing layer or
The openings can be filled using injection methods. 13. Cover layer according to at least one of claims 1 to 11, characterized in that the part of the anchoring elements which absorbs the largest part of the buoyancy force, which in the case of unconnected anchoring elements are the head elements thereof or in the case of the support grid
whose elementary cells have a horizontal diameter of 1.5 meters and that the buoyancy forces the part of the anchoring elements that is eroding in the subsoil beneath the sealing layer has a horizontal diameter of the order of 0.25 metres. 14. Anchoring element according to at least one of claims 1 to 13, characterized in that it has, in its lower part, which transfers the buoyancy force to the subsoil, at least one thickening which does not exceed a horizontal diameter of the order of 1.5 meters.
10 15. Anchoring elements according to claim 14, characterized in that the thickenings of several anchoring elements are connected to one another. 16. Anchoring elements according to at least one of claims 14 and 15, characterized in that the anchoring elements are not vertical, but inclined at an angle so that they activate a larger earth body.