DE2545572A1 - BUILDING ANCHORING - Google Patents

Abstract

Injection rods (1) are driven into the supporting medium (4) in such a way as to be distributed in a grid shape and are grouted with a grouting compound which then hardens. The top ends of the injection rods (1) show above the supporting medium (4). A separate foundation plate (11) is put onto each end. Core areas (5) form around the injection rods (1) due to the grouting by the grouting compound. The core areas (5) can also flow into one another or can interlock. The individual foundation plates (11) enable the load to be passed into the building foundation in a statically favourable manner. <IMAGE>

Description

Building anchoring

The invention relates to a building anchor using a pile-like anchoring element for driving or introducing into the ground.

If the subsoil is earth, the simplest one is Type of building anchorage considered here, an anchoring element in form to drive a concrete, wood or steel pole into the earth. Usually leaves you stick the head of the stake out of the earth and then you can either attach it to the head Attach a rope, hawser or the like or use the post directly as a support post. In the latter case, further support elements can be attached to the pile, for example to build a dam on it.

The manufacture of so-called large bored piles is also known.

It is a pile embedded in the earth by at least 50 cm in diameter, which is used to support a building structure. Such a Large bored pile is thereby made that one in the ground first Hole is drilled, which is then filled with reinforced or unreinforced concrete.

So-called rock nails or rock anchors are known for rocky subsoil, To fix a rock nail, a hole is first drilled in the rock. which is then filled with mortar.

The rock nail is then hammered into the still moist mortar. This has the disadvantage that the mortar in any existing rock crevices can escape where it no longer has any effect and normally provides protection Steel existing rock nail against rust is no longer given.

If the rock is very fissured, it is a complete fill not at all in the vicinity of the borehole due to the usually limited amount of mortar more is possible.

To remedy the disadvantages outlined last, the so-called.

Perfo anchor ". For fastening the perfo anchor, in first drilled a hole in the rock. In this hole two are then against each other set half-shells of a perforated hollow cylinder introduced with mortar are crossed out. Then the anchor is looked up, using it to a limited extent Displaced mortar in the space between the half-shells and the borehole wall. This procedure ensures that the anchor is more likely embedded in mortar and accordingly protected against corrosion. The disadvantage of the perfo anchor opposite the rock nail, however, is that here always the same, The amount of mortar used is not adapted to the local conditions, so that the area around the borehole is not filled with mortar with sufficient certainty will.

The invention is based on the object of a building anchorage The genus considered here should be designed in such a way that it becomes easier and faster can be produced and at the same time ensures improved anchoring.

The object is achieved according to the invention in that the anchoring element is a perforated pipe into which wet mortar is introduced under such high pressure that it exits through the perforation and into the subsoil surrounding the pipe penetrates to harden there. The water content of the mortar introduced into the pipe can be adapted to the special requirements, for example to the subsoil will.

The building anchoring according to the invention ensures an improved Inclusion of the subsoil environment of the anchoring element in the load-bearing or support function of the anchoring element. It is also advantageous that the perforated tube with security embedded in mortar and accordingly protected against corrosion. The invention Building anchoring is also characterized by easy adaptation to the circumstances the local environment. Depending on the subsoil, the steel for the perforated Pipe and the mortar are specifically chosen. For its mortar, for example Cement can be used, which is provided with additives as required. Even can special groundwater conditions and deformation processes of the environment, caused, for example, by slipping or sagging of the subsoil, with master the building anchoring according to the invention without difficulty.

According to an advantageous development of the Invention of slots extending in the longitudinal direction of the pipe or of Holes be formed which are arranged distributed over the circumference of the tube.

If the subsoil is earth, the pipe is expediently with provided with a point. The pipe, referred to in this case as the "lance", then becomes first knocked into the ground and then raised a little so that mortar from the end of the pipe can emerge.

If the building site is rock, a perforated pipe is preferred is used, which is open at its introductory part. First is a hole in the rock drilled into which the pipe is inserted. Then mortar is pressed into the pipe, as much as the area around the borehole with certainty any existing crevices is filled with mortar. Of course a perforated tube with a tip can also be used for rocky ground.

A particularly expedient development of the invention can be therein exist that the mortar has a solidifying liquid in the form of a modified silicate or other additives is added. It is also possible to inject the mentioned liquid into the subsoil before the introduction of mortar. With such a pre-injection, the greatest possible depth effect is achieved, and even if the subsoil is very fine-grained. Fine-grained soil actually sets the injection has a considerably greater resistance than coarse-grained soil or rugged rock. It has been found that the depth of penetration for the Mortar when admixing the liquid is increased by the latter and when making the Pre-injection with the liquid is further improved. The one on a modified one However, silicate-based liquid not only makes it easier for the mortar to penetrate into the subsoil, but it itself contributes to the consolidation of the subsoil.

It is particularly advantageous that by metering the mentioned Liquid, the setting time of the mortar and the setting time of the subsoil can determine, whereby the structural anchorage according to the invention a further degree of freedom for adaptation to the special conditions of the local environment, and in particular the flow width of the grout can be limited as required.

The invention also relates to a foundation for an example Area to be built with a dam using building anchors from the previous one described type.

This foundation is characterized by the fact that a large number of the Building anchors formed with individual anchoring elements in a grid pattern the area to be built is distributed that the anchoring elements with their ends protrude from the subsoil, and that a foundation plate on each protruding end preferably made of concrete, is placed, wherein the foundation plates do not touch. The earth for a dam, for example, can then be poured onto the foundation slabs will. It is essential that the subsoil through the injections with mortar and the liquid based on a modified silicate completely or almost completely is completely solidified.

The dam load can then be applied to the surrounding subsoil or to lower lying areas more stable soil layers are transferred.

The grid spacing of the anchoring elements and the injection intensity can be chosen so that the anchoring elements develop Consolidation areas of the subsoil flow into one another or interlock.

Another object of the invention is one embedded in the subsoil Large pile using building anchors of the type described above. This Large pile is characterized by the fact that a large number of individual anchoring elements formed building anchors distributed over the planned perimeter of the large pile is that in the middle of the large pile there is also at least one with an anchoring element formed building anchoring is provided that the ends of the anchoring elements protrude from the subsoil and are connected to one another by reinforcement, and that on the ends of the anchoring elements connected by the reinforcement a concrete base approximately corresponding to the cross-section of the large pile is placed.

With the large pile produced in this way as well as with the one previously described The foundation is made from the earth, which in this case normally forms the subsoil, practically earth concrete created.

In doing so, the earth is not just mortar, cement or the modified on a Silicate based and solidifying the soil Liquid supplied, but it is also compacted by driving in the anchoring elements. The reinforcement creates a cohesive structure which is in the Is able to absorb extremely high loads. The concrete base has one hand the purpose of protecting the reinforcement and, on the other hand, a buildable conclusion create the load on all anchoring elements or lances as well as on the interior Distributed embodiments of the invention are described below with reference to the drawings described.

They show: FIG. 1 an anchoring element in the form of a perforated one Pipe; 2 shows a building anchoring in a subsoil made of earth; Fig. 3 a building anchoring in a building ground consisting of rock; Fig. 4 is a view from above onto a foundation using a variety of building anchors of the type shown in Figure 2; Fig. 5 shows a section V-V through the foundation according to Fig. 4, FIG. 6 shows a detail from FIG. 5, which shows the upper end of an anchoring element shows with the foundation plate put on; Fig. 7 using a large pile a plurality of building anchors of the type described in Figure 2 in section; 8 shows a section Vill-Vill through the large pile shown in FIG. 7; Fig. 9 a Top view of the large pile shown in FIG. 7.

An anchoring element is used for building anchoring, which is shown in FIG. This consists of a tube 1 with a perforation 2 is provided. The perforation in the present case consists of slots that Are arranged distributed over the circumference of the tube and extend in the longitudinal direction of the Extend pipe.

When creating a building anchorage in an existing earth 4 The foundation is the perforated pipe with a tip attached 1 first driven into the ground and then pulled out again a little so that the end of the pipe becomes free. The end of the tube 1 protrudes above the surface of the earth Then 7 mortar is pressed into the pipe by means of a compressor 6 via a hose. The mortar then penetrates through the perforation 2 into the vicinity of the pipe 1. When the mortar has set, a solid core 5 is formed from earth concrete. the The structural anchorage formed in this way is denoted by the reference number 3. The mortar can a liquid can be added based on a modified silicate or another Admixtures based.

This liquid has the property that it in turn the building ground solidified. It also enables the mortar to enter the subsoil, if this is very fine-grained. By pre-injecting with the liquid Introduction of the ttörte; ts, a special depth effect can be achieved.

In Fig. 3 is the production of an anchorage in rocky ground 8 shown. In this case, a hole 10 is first drilled in the skins 8. Then the perforated tube 1 is inserted into the hole Io, the hole points in this Does not fall to r but is open at the front. Then again by means of a Compressor 6 and a hose 7 mortar pressed into the pipe 1. The mortar kicks in through the perforation 2 to the outside and also penetrates into crevices 9 in the rock. Also in In this case it is advantageous to use the modified silicate-based mortar Add liquid or other additives, about the setting time control of the mortar.

4-6 shows the construction of a foundation for a dam using a variety of building anchors of the type shown in Fig. 2 shown. In this case, the perforated tubes 1 are grid-like over the The area to be built on with the dam was driven into the ground.

Then, as described, mortar, if necessary with the one on the modified one Silicate-based liquid or other additives are pressed into the pipes. In this way, solidified core areas are formed around the tubes 1, which also flow into one another or are mutually interlocked. At those looking out of the ground Concrete slabs 11 are placed on the ends of the pipes 1. These are at the bottom provided with a recess 13 which is used to accommodate the protruding from the ground Ends of the tubes are used. You let the pipes look so far out of the ground that the concrete slabs 11 just touch the ground surface. The dimensions of the plates 11 or the grid size for driving the perforated tubes 1 into the floor are chosen so that the concrete slabs 11 do not touch. On the Concrete slabs 11 then the earth 12 for the dam is poured in which then the Settlements can be reduced, prevented or largely compensated for.

FIGS. 7-9 show the manufacture of a large pile. For this purpose, perforated pipes 1 are first of all approximately over the circumference of the pipe to be produced Large pile driven into the ground 4 distributed. Also in the middle is a perforated one Tube driven. Thereafter, in the perforated tubes 1 in the above-described Way mortar pressed, which may contain the liquid based on the modified silicate or other additives are added. Here, too, is a pre-injection with the mentioned liquid if necessary appropriate. The spacing of the perforated tubes as well the injection intensity are chosen so that the solidification areas 5 interlock or merge. This way it becomes practically the whole from the / perforated pipes 1 bordered area of the earth as well as extending around the pipes outer ring formed into earth concrete.

Reinforcement is then applied to the protruding ends of the pipes 1 14 put on. Then on de with the reinforcement 14 connected ends of the pipes 1, a base 15 is concreted on, around which the load can then be applied.

Expectations:

Claims (9)

Claims Building anchoring using a pile-like anchoring element for driving or introducing into the subsoil, characterized in that the Anchoring element (1) is a perforated tube into which moist mortar is underneath so high pressure is introduced that it exits through the perforation (2) and into which the pipe (1> surrounding subsoil (4,8) penetrates in order to harden there. 2 building anchoring according to claim 1, characterized in that the Perforation (2) of slots extending in the longitudinal direction of the tube or Holes is formed which are arranged distributed over the circumference of the tube. 3. Building anchoring according to claim 1 or 2, characterized in that that the tube is provided with a point. 4. Building anchoring according to claim 1 or 2, characterized in that that the tube is open at its inlet end. 5. Building anchoring according to one of the preceding claims, characterized characterized in that the mortar is a liquid that solidifies the subsoil in the form a modified silicate or another additional agent is added. 6. Building anchoring according to one of claims 1-4, characterized in that that in the perforated pipe in front of the mortar a liquid that solidifies the subsoil introduced in the form of a modified silicate or another additive under pressure will, 7. Foundation for an area under, for example, to be built with a Dan Use of building anchors according to one of the preceding claims, characterized in that a plurality of the individual anchoring elements (1> building anchors formed (3> grid-like over the area to be built on is distributed that the anchoring elements Ci> with their ends from the subsoil (4) protrude and that on each protruding end a foundation plate (11>, is preferably made of concrete, the foundation plates (11) not touch. 8. Foundation according to claim 7, characterized in that the foundation plates (11) on its underside with a recess (13) for receiving the relevant Anchoring element ends are provided, and that the ends are so far out of the subsoil (4) protrude so that the foundation plates (11> sit straight on the subsoil (4)) 9. B's building ground embedded large pile using building anchors claims 1 - 6, characterized in that a plurality of the individual Anchoring elements (1) formed building anchors (3) about the planned Perimeter of the large pile is arranged distributed that in the middle of the large pile likewise at least one structural anchorage formed with an anchoring element (1) it is provided that the ends of the anchoring elements (1> from the subsoil protrude and are connected to one another by a reinforcement (14), and that on the ends of the anchoring elements (1) connected by the reinforcement (14) Concrete base roughly corresponding to the cross-section of the large pile (15> placed on top is. lo. Method for producing a large bored pile according to claim 9, characterized in that first the building anchors at the Circumference of the large bored pile and then subsequently the one in the middle Building anchors arranged in the pile area are filled with grout under high pressure will.