DE3410830A1 - Method of producing construction elements in foundation soil, such as piles, anchors, trench walls or the like, and an apparatus for carrying out this method - Google Patents

Abstract

Construction elements in foundation soil, such as piles, anchors, trench walls or the like, are produced by a liquid, hardenable construction material being continuously directed under high pressure via a jet pipe with at least one lateral jet nozzle into the hole, filled with hardenable construction material, in the foundation soil. In the process, the jet pipe is moved upwards and, if need be, rotated. Indentation and thus an increase in the bearing force of the construction element develop in the zone of contact with the foundation soil. <IMAGE>

Description

STUMP BOHR GMBH
Ismaning / Mchn.

Process for the production of building elements in the subsoil,
such as piles, anchors, diaphragm walls or the like,
and an apparatus for carrying out this method

The invention relates to a method for producing building elements in the ground such as piles, anchors, diaphragm walls or the like, in which an opening in the building ground is filled with hardenable building material and before the same liquid building material is introduced, so that building material is driven against the surrounding contact zone, and a device for
Perform this procedure.

Such a method and a device are described in the main application P 33 00 971.6. In this case, the flowable material is moved under high pressure and in a concentrated form against the wall of the soil, the pressure and concentration being such that the material touches the soil wall
is compressed while being pushed back or shot into the ground. The material is fed in in a pulsed manner.

From DE-AS 21 58 764 it is known, underground columns
produce by driving an auger to the bottom of the column. While withdrawing it
a soil consolidating agent is continuously introduced under high pressure via at least one nozzle, which is released into the surrounding soil, destroying the affected soil structure

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door penetrates and mixes with it · An earth auger is used used, which is relatively easy to drill due to its small diameter. By adding earth consolidation agents under high pressure a columnar

Form cross-section, which is considerably larger than the diameter of the auger. The column cross-section consists then essentially a mixture of earth consolidating agents and soil material. The strength and resilience of such columns is not optimal; arranging steel reinforcement can not.

The invention is based on the object of a method and a device for producing reinforced and unreinforced To create construction elements in the subsoil that are free of soil material at least in the core cross-section and their load-bearing capacity and strength is considerably increased.

The invention solves this problem with the features of the method claim 1 and the device claim 6.

The invention achieves that the liquid, hardenable building material introduced continuously under high pressure the contact zone between the building element and the subsoil is interlocked so that there is an increased frictional connection between the subsoil and the building element arises. The core of the component, which is formed from the hardenable building material, remains essentially unmixed.

Further refinements of the invention emerge from the Subclaims.

The invention is illustrated below with reference to in the drawing Embodiments explained in more detail. In the drawing show:

Fig. 1 is a schematic vertical section of an uncased Pile with a high-pressure jet device with jet pipe for carrying out a continuous high-pressure injection;

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FIG. 2 shows a cross section along the line II-II in FIG. 1;

Fig. 3 is a schematic vertical section of a reinforced pile with partially pulled borehole casing with pipe cap and jet pipe;

FIG. 4 shows a cross section along the line IV-IV in FIG. 3; FIG.

5 shows a schematic vertical section of a pile with reinforcement and jet pipe;

Fig. 6 is a plan view of the post according to Fig. 5;

7 shows a schematic vertical section of a barred pile during the filling of the annular space between the soil and the built-in, jet pipe with gravelly aggregate, and

Fig. 8 is a cross section of a pile of another Version with protective tube and separate jet lances.

According to Fig. 1, a pile hole 2 is created in the ground 1 by drilling, dredging or the like.

In the pile hole 2, the jet pipe closed at the bottom is first inserted 3 introduced. High pressure lines 4 are attached to the inner wall of the same. These end in nozzles 5, which are in the Wall of the jet pipe 3 near its lower end, preferably with a large distance, are arranged.

Two nozzles 5 opposite one another are preferably provided. Each nozzle 5 is fed by its own high-pressure line 4. It would also be possible to use the two nozzles 5 only to supply a high pressure line. In this case, such a single high-pressure line 4 would first have to go into an annular chamber end at the lower end of the jet pipe 3, to which the nozzles 5 are then connected.

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By using high-pressure lines 4, a relatively thin-walled, not high-pressure-resistant pipe can be used as a support structure as the jet pipe 3 itself. Several, Opposite nozzles 5 allow self-centering of the jet pipe 3 in the pile hole 2. The jet pipe 3 protects the pile core against contamination by earth material.

A carrier device (not shown) holds the jet pipe 3. It is used to lower, raise and cover or pivot the jet pipe 3 back and forth.

Concrete, e.g. flowing concrete, pumped concrete or poured concrete or cement suspension, is then poured through a conventional feed pipe (not shown) starting from the bottom of the pile hole. The annular space 6 between jet pipe 3 and pile hole wall 7 is completely filled with concrete 8.

Liquid building material is then produced by means of two pumps 9 pressed continuously under high pressure into the high-pressure extensions 4 located in the jet pipe 3 and over the lateral Nozzles 5 on the jet pipe 3 introduced through the concrete annulus 6 into the surrounding subsoil 1. The carrier device sets in the jet pipe 3 and thus the nozzles 5 in a rotary motion with simultaneous lifting of the jet pipe 3. The introduction the liquid building material through the nozzles 5 into the subsoil 1 takes place over the length of the intended force introduction area of the stake.

Advantageously, the rotary movement is not constantly rotating, rather, the jet pipe 3 is moved back and forth, that is to say a pivoting movement, so that the high pressure lines 4 do not have to be fed via a special feed head.

The centering of the jet pipe 3 in the pile hole 2 is carried out by the arrangement of at least two opposite nozzles 5, each by an independent pump 9 with the same amount of injection fed at the same pressure. The diameter of the

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Jet pipe 3 is matched to the local soil conditions and pile dimensions so that there is excess grout largely compensated for by the volume released when the jet pipe 3 is pulled up.

From Fig. 2 the treatment of the complete pile circumference is by pulling up and constantly swiveling the jet pipe 3 and the nozzles 5 by a swivel angle of at least + 90 recognizable.

According to the modified version shown in FIG. 3, a pile hole 2 is created in the subsoil -1, which is drilled with a casing became. In this Fig. 3, the piping 10 is shown partially drawn. Before pulling the tubing 10, the Jet pipe 3, the reinforcement 11 and the concrete 8 introduced. The borehole casing 10 has a pipe cap 12 in which the jet pipe 3 is movably and sealingly guided. aside from that this cap 12 also has two valves 13, 14 for letting in and letting out a pressure medium. The printing medium, consisting e.g. made of cement milk, water or air, prevents or at least hinders the breaking out of the through the jet nozzles 5 continuously supplied, liquid building material through the concrete column upwards. This creates the liquid building material increasingly caused to penetrate into the soil of the subsoil 1. The pile concrete is mixed with soil kept free.

From Fig. 4, the treatment of a part of the pile circumference can be seen via mutually opposing circumferential segments. Such pile elements result in overlapping walls lined up next to each other, which, in addition to other functions, e.g. tightness, thanks the reinforced core pile also has a high load-bearing capacity or bending stiffness can own.

According to FIG. 5, there is an uncased pile hole 2 in the subsoil 1 e.g. by bentonite flushing.

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The reinforcement 11 is located within a modified jet pipe 3 ¹ . This is now open at the bottom. It also fulfills a protective function and reliably keeps the reinforced core cross-section of the pile free of soil inclusions.

The high-pressure lines 4 with the nozzles 5 can also be arranged on the outside of the jet pipe 3 ¹ .

The outer ring space 15 between the jet pipe 3 ¹ and the subsoil 1 can be kept narrow. The mouths of the jet nozzles 5 are then located directly in front of the pile hole wall 7. The continuous high pressure jet can accordingly have an optimal effect.

The pile hole 2 is initially uncased, possibly drilled with cement or bentonite flushing. The jet pipe 3 ', including the associated jet compression direction, is installed down to the bottom of the borehole. The reinforcement 11 is then introduced. Inside the jet pipe 3 ¹ , concrete is now introduced from bottom to top by means of a filling pipe until the drilling fluid has been completely displaced and has flowed away at the top.

About the Strahlverpreßexnrichtung the outer ring space filled with pumpable cement or cement-sand mortar at low pressure from bottom to top until the drilling fluid is also here, E.g. the bentonite suspension, completely displaced and flowed away at the top. The continuous high pressure jet feed now takes place with constant turning back and forth and pulling up, so that each associated with a jet nozzle 5 Area exposed to high pressure jets. The pressing process continues until the end of the desired force application path of the stake.

In a modified, not shown embodiment can be used directly with the nozzle 3 with the drill bit attached

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be drilled. For this purpose, the jet pipe 3 can be double-walled so that the high pressure lines 4 can be guided in the protection of this double wall.

From Fig. 6 it can be seen that four high-pressure lines 4 with nozzles 5 are fed by four high-pressure pumps 9. With a swivel angle of the jet pipe 3 ¹ - of 90 °, a total circumference of 360 ° is then covered.

According to FIG. 7, a borehole with casing 10 has been made in the subsoil 1. The reinforcement 11 is located inside the jet pipe 3 ', which is open at the bottom and which also has a protective function. The annular space 15 between the subsoil 1 and the jet pipe 3 ¹ is filled up to the top with gravelly concrete aggregates (FIG. 7 shows the operation during the backfilling).

The gravelly concrete aggregate is penetrated by the liquid building material ejected through the jet nozzle 5 and is thereby part of the pile concrete.

On the one hand, the gravelly concrete aggregate is ideally suited to to prevent or hinder the breaking out of the building material ejected through the jet nozzle 5 upwards and fulfills this on the other hand, a protective filter function to keep the pile core cross-section clean .

In this embodiment, the hole drilling takes place first with piping. The jet pipe 3 'including the associated The jet grouting device is installed so that it protrudes to the bottom of the borehole. The reinforcement 11 is then used. Concrete is then broken into within the jet pipe 3 '. The well casing 10 is pulled and thereby in the outer Annular space aggregate filled. The high-pressure jet is now fed in continuously while turning and pulling up of the jet pipe 3 'and the piping 10. The jet pipe 3' is moved back and forth through a pivoting angle of 90 °.

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The pressing process continues until the end, the desired force input distance of the stake.

As can be seen from FIG. 8, separate, lance-shaped jet pipes 3 ″ can also be used.
a separate protective tube 16 can be used.

Patent attorney
~ "" - ■ 80.0 coin "hent

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Claims (11)

PatenteiW / äfta.; .. · .. Munich 4O1 u.::--.--.r· <> ■ STUMP BOHR GMBH 8045 Ismaning / Mchn. Method for the production of building elements in the ground, such as piles, anchors, diaphragm walls or the like, as well as a device for carrying out this method 1. Process for the production of building elements in the subsoil, such as piles, anchors, diaphragm walls or the like, in which a hole in the subsoil is filled with hardenable building material and before it solidifies, it becomes more liquid Building material is introduced so that building material is driven against the surrounding contact zone, according to the patent (Patent application P 33 00 971.6), characterized in that the introduction of the liquid, hardenable building material takes place in the form of a continuous high pressure jet. 2. The method according to claim 1, characterized in that the hole (2) in the subsoil (1) with concrete, such as flowing concrete, Pum.p- or poured concrete. 3. The method according to claim 1, characterized in that, the hole (2) in the subsoil (1) is filled with cement suspension will. 4. The method according to claim 1, characterized in that the high pressure jet is fed over a peripheral segment will. EPO - COPY 5. The method according to claims 1 to 3, characterized in that that the high pressure jet is fed through several opposed nozzles (5). 6. Device for performing the method according to claims 1 to 5, characterized in that at least one continuously operating high pressure pump (9) for supplying a hardenable, liquid building material with at least one outlet nozzle (5) having a jet pipe (3, 3 ¹ , 3 ") is connected, which is rotatably and vertically movable or additionally longitudinally displaceable in a hole (2) or slot in the subsoil (1). 7. Apparatus according to claim 6, characterized in that the jet pipe (3, 3 ¹ ) inside or outside at least one pressure-resistant high-pressure line (4). which ends in a side nozzle (5). 8. Device according to claims 6 and 7, characterized in that that the jet pipe (3) is closed at the bottom. 9. Device according to claims 6 and 7, characterized in that the jet pipe (3 ¹ ) is open at the bottom. 10. The device according to claim 6, characterized in that a reinforcement "(Π) is arranged inside or outside a jet pipe (3, 3 ¹ ) in the hole (2) in the subsoil (1). 11. The device according to claim 6, characterized in that the jet pipe (3) passes through an outer pipe (10) longitudinally, which can be locked at the top by a cover (12 = 0, which seals against the jet pipe and has valves (12, 13), Via which a pressure medium can be fed into the interior of the outer tube. Pstentanwä.'ia Dip! .-! Ng. E, Eder Dipl.-ίπα. K. 1, 'ünci-cn ψ / ^ &ψ'ά;. ^, 34 EPO - COPY ä \