DE4123013A1 - GROUND ANCHOR AND GROUND PILE - Google Patents

Description

The invention relates to a compression anchor and a compression stake.

Compression anchors are known which are the composite anchors Transfer stresses from the tension member directly to the compression body In addition, compression anchors are known, which are used as pressure pipe anchors the composite stresses via a pressure pipe in the compression body initiate.

DE-PS 34 25 941 describes a compression anchor, the Ver federal characteristics of the two previously described anchors added and can absorb about twice the tensile force. However, this known compression anchor requires a special one le clamping press, which is two clamping devices led to the top of the earth links or tendon groups, the unequal tension path ha ben with the same force.

The invention has for its object a compression anchor and to create a grouting pile that is comparatively similar to the Components described in DE-PS 34 25 941 the same can have large or far greater load capacity and moreover are much easier to design.

The invention solves this problem with the features of the patent claims 1, 7 and 8.

Up to now, it was only normal forces that applied to the known compression anchors, the prestressing force in the compression body transferred. The invention makes it possible through asymmetri cal design of the components also a moment on the Transfer compression body, which brings advantages in load capacity.  

The invention has the further advantage that only one instep link or a tendon group is present, so that Clamping is possible with conventional clamping presses.

The arrangement of separate composite links with prestressable Compression anchors make it possible for the composite links to be standard Structural steel to choose. So far, a separate link is only known as a pressure pipe in the pressure pipe anchor. With no grouting Anchor was previously a separate link for the transmission of Tensile stresses known.

Ordinary structural steel is less susceptible to corrosion than instep stole. Composite links made of ordinary structural steel can be used low extra costs oversized who the, so that tensions and thus also strains are reduced what has a favorable influence on the holding force of the compression anchor. According to this principle of the invention, grouting piles can also be used be formed.

Further refinements of the invention result from the Subclaims.

The invention is described below with reference to the drawing illustrated embodiments explained in more detail. In the Show drawing:

Figure 1 is a schematic side view of a compression anchor according to the invention with diagrams for the stress curve.

. Fig. 1a and 1b cross-sections along the line Ia FIG / b-Ia / b in Fig 1 of different embodiments.

Fig. 2 is a modified embodiment of a soil anchor;

Figure 2a shows a cross section along the line IIa-IIa in Fig. 2.

Fig. 3 shows a further embodiment of a soil anchor;

FIGS. 3a and 3b are cross-sections according to lines III-IIIa Fig. Or III / b-III / b in Fig. 3 of different embodiments,

Fig. 4 shows a further modified embodiment of a Ver preßankers with dual cascaded carrier transmission,

Fig. 5 shows another embodiment of a compression anchor with a multi-part tension member and

Fig. 6 shows a cross section along the line VI-VI in Fig. 5.

The Ground anchors of Fig. 1, which is in a hole 2, for example borehole, housed, has a tension member. 3 This is provided with a cladding tube 4 over its entire length. One end of the tension member 3 is firmly connected to an anchor body 5 . The other end of the tension member 3 is connected to an anchor head, not shown. It can be tensioned in the direction of the arrow as usual.

At least one composite member 6 is also firmly connected to the anchor body 5 . The one link member 7 'extends parallel to the tension member 3 in the direction of the earth's top 8th The other composite member part 7 '' extends parallel to the train member 3 in the direction of the hole bottom 10th

There may also be several composite links 6 and 6 '.

As seen from Fig. 1, 1a and 1b, the composite members 6 '6 arranged eccentrically to the tension member 3 are.

As usual, the hole 2 is pressed with hardening building material. It forms over the anchoring length of the compression body 11 . In this, the composite links 6 , 6 'are embedded. Preferably, these composite links 6 , 6 'rods or strands made of steel with a ribbed surface or the like. This creates between the compression body 11 and composite link 6 or 6 ' a directly transmitting composite.

Are the composite links 6 , 6 'firmly connected in the middle of their length with the anchor body 5 , if a tensile force is exerted on the tension member 3 in the direction of the arrow indicated by means of a conventional tensioning press, the composite tension diagram 12 drawn over it in rough approximation in the joint between Grouting body 11 and surrounding building ground 13 .

The part 7 'of the composite glue of 6 directed towards the top of the earth 8 is subject to compressive stress; of the hole bottom 10 directed towards the part 7 '' of the composite member 7 comes under Zugspan voltage.

The asymmetrical arrangement of composite member 6 and tension member 3 makes it possible to transmit a moment in the composite members 6 and thus in the compression body, which has an advantageous effect on the load-bearing capacity of the compression anchor. It can be prevented by constructive means that the tension member also suffers 3 bending stresses.

In the embodiment of Fig. 2 is a symmetrical arrangement of the composite is to members 6 '6 is provided to the tension member. 3 This is clearly evident from Fig. 2a.

The embodiment according to FIG. 3 differs from denjeni gene according to FIGS . 1 and 2 in that the tension member 3 attached to the anchor body 5 is aligned in the tensioned composite member part 7 '' continues.

The firmly connected to the armature body 5 , pressurized composite member parts 7 'can also be formed by a tube 14 . This tube 14 concentrically surrounds the tension member 3 and is also firmly connected to the anchor body 5 .

The part 7 '' is, as usual, in direct connection with the compression body, so not provided with a cladding tube. This also applies to the pipe 14 .

The composite member part 7 '' is applied only by half the clamping force of the compression anchor. The other half of the clamping force is derived through the pipe 14 via the compression body 11 in the construction reason 13 . This arrangement brings the further part before that the strains are halved, which has a favorable effect on the load-bearing capacity of the compression anchor 1 . In addition, this form is very space-saving, so that a small hole diameter can be used economically.

In the embodiment according to FIG. 4, two anchor bodies 5 and 5 'spaced one behind the other are fastened to the tension member 3 for carrying force transmission. With the anchor body 5 , in turn, the composite members 6 , 6 'are firmly connected. They are arranged symmetrically around the tension member 3 . The tension member 3 is from the top of the earth 8 to the anchor body 5 'and between the anchor bodies 5 ' and 5 is provided with a cladding tube 4 . The parts 7 ', 7 '', 7 ''' of the composite members 6 , 6 'are directly surrounded by the compression body 11 without such a cladding tube.

The composite link parts 7 'are guided freely by the anchor body by 5 '.

Towards the top of the earth 8 out at a distance to the United composite parts 7 'stop parts 15 are attached, which can also be designed as a drive plate. The space between the stop parts 15 and the anchor body 5 'is kept clear of the hardening building material, for. B. by a compressible material or by an appropriate cover.

The anchor body 5 and 5 'are preferably arranged eccentrically to the Ver press body 11 at equal distances from each other and to the ends of the compression body 11 .

If a tensile force is applied via the tension member 3 in the direction indicated by the arrow, the composite member parts 7 '' are subjected to tension and the composite member parts 7 'are pressed by the anchor body 5 . After appropriate expansion of the tension member 3 interact with the anchor body 5 ', the stop members 15 of the United bundle members 7 '. There are then to the top 8 of the composite link parts 7 '''on pressure and the United composite link parts 7 ' additionally claimed on train.

In an embodiment not shown, the composite member 6 'can be omitted, so that there is an asymmetrical arrangement of composite member 6 and tension member 3 .

In another, not shown, simpler form of implementation, the anchor body 5 , 5 'can be firmly connected both with the train member 3 and with the composite members 6 , 6 '.

During the tensioning of such a soil anchor results in the overall composite to voltage diagram 12, which has in uniform building to Erdoberseite towards the slightly larger amplitudes, so that in the middle of a trapezoidal chart area is formed.

The change in the load capacity compared to the embodiment according to FIG. 4 depends on the soil. For certain floors, the simpler embodiment is sufficient; in the case of alternating soil layers, it can even be cheaper, because the roughly simplified composite voltage diagram 12 results in the form shown only for uniform soil layers.

In the case of known soil parameters of alternating layers, an equally uniform Ver stress diagram 12 can always be achieved by certain choice of the distance between the composite member parts 7 'and the stop parts 15 as with uniform floors.

As usual, the composite parts 6 and 6 'for reasons of corrosion protection with the composite stress-transmitting finned tubes made of plastic, so that such anchoring anchor can also be used as a permanent anchor.

Of course, the tension member 3 can also be formed by several rods or strands. Also any other, not Darge presented arrangements of composite members 6 , 6 'are possible.

The compression anchor 1 according to FIGS . 5 and 6 does not differ in any way, including the anchor plate, up to the end of the stretch of free stretchability of the tension member 3 , where the anchor body 5 is located, from a conventional anchor with a multi-part tension member. In the anchor body 5 , the multi-part tension member 3 is divided into two parts. Part of the tension member 3 formed by strands or wires is anchored in the anchor body 5 ; the other part runs freely through the armature body 5 . When tensioning the compression anchor according to the invention, which differs in nothing from tensioning known anchors with multi-part tension members, act on the in the anchor body 5 , z. B. anchored by means of wedges 15 strands or wires which directed towards the Erdoberseite 8 composite link parts 7 'pressure, and the free passing through the anchor body 5 strands or wires comprising the composite link parts 7' form 'will suffer a tensile stress. This results in the composite voltage diagram 12 (see FIG. 1).

The anchor body 5 can, for. B. for transport reasons as a shock con construction, so that it is possible to couple the endsei term stressed train elements 6 , 7 '' on the construction site in a simple manner.

If the compressive force of an immediate load is applied to the non-buckling member 3 instead of a tensile force via a foundation, not shown, the previously described press anchor can also be used as a pressed pile.

Claims (9)

1. grouting anchor with a hole ( 2 ) in the ground ( 13 ),
with at least one anchor pull member ( 3 ) arranged in the hole ( 2 ) and tensionable from the earth's upper side ( 8 ) against an abutment,
with at least one anchor body ( 5 ) connected to it,
with a sheath ( 4 ) surrounding the anchor tension member ( 3 ) up to the anchor body ( 5 ),
with at least one additional, from the anchor body ( 5 ) to the bottom of the borehole ( 10 ) extending composite member ( 6 , 6 '), which is firmly connected to the anchor body ( 5 ) and embedded in a compression body ( 11 ) formed in the hole ( 2 ) is and
with at least one from the anchor body ( 5 ) in the direction of the top of the earth ( 8 ) extending composite member ( 7 '), which is firmly connected to the anchor body ( 5 ) and embedded in the compression body ( 11 ). 2. compression anchor, characterized in that each composite member ( 6 , 6 ') is formed by a one-piece rod which is firmly connected to the anchor body ( 5 , 5 ') between its ends. 3. grout anchor according to claim 1 or 2, characterized in that the only to the earth top ( 8 ) leading tension member ( 3 ) and the tensile or pressurized composite members ( 6 , 6 ') are arranged eccentrically to each other. 4. compression anchor according to claim 1 or 2, characterized in that the train or. pressurized composite links ( 6 , 6 ') are arranged symmetrically to the only tension member ( 3 ) leading to the top of the earth ( 8 ). 5. grouting anchor according to claim 1 or 4, characterized in that the pressurized composite member part ( 7 ') is a tube ( 14 ) which surrounds the only tension member ( 3 ). 6. grout anchor according to claim 1, characterized in that on the upper side ( 8 ) guided tension member ( 3 ) a further spaced anchor body ( 5 ') is fixed, through which the composite members ( 6 , 6 ') are movably guided and that spaced from this anchor body ( 5 ') to the top of the earth ( 8 ) towards the composite members ( 6 , 6 ') drivers ( 15 ) BEFE Stigt. 7. grout anchor with a hole ( 2 ) in the ground ( 13 ),
with a multi-part anchor link ( 3 ) arranged in the hole ( 2 ) and tensionable from the top of the earth ( 8 ) against an abutment,
with an anchor body ( 5 ), with which at least one partial member of the multi-part anchor tension member ( 3 ) is firmly connected, while at least one other partial member is guided through this anchor body ( 5 ),
with a covering ( 4 ) surrounding each partial link or the entire anchor tension link ( 3 ) up to the anchor body ( 5 ),
with at least one from the anchor body ( 5 ) extending towards the bottom of the borehole composite member ( 6 ), which continues at least one partial member ( 3 ) and is embedded in a compression body ( 11 ) formed in the hole ( 2 ) and
with at least one, from the anchor body ( 5 ) in the direction of the top of the earth ( 8 ) extending composite member ( 7 ') which is firmly connected to the anchor body ( 5 ) and embedded in the compression body ( 11 ). 8. grouting pile with a pressure member supporting the pile load in a hole,
with a pile body attached to it,
with at least one composite member firmly connected to the pile body, which extends with a partial length from the pile body to the hole base and with another partial length to the top of the earth and
with a compression body in the hole in which the composite links are embedded. 9. grouting pile according to claim 8 with one or more of the Features of claims 2 to 6.