DE2522807B2 - Clamp anchorage - Google Patents

Description

60

The invention relates to a clamp anchorage for tendons in prestressed concrete, the layers between flat, parallel clamping plates under the Pressure of at least one wedge acting perpendicular to the plane of the plate are held together in a clamping body.

According to DE-PS 10 91 309 it is one of these Anchoring known where the prestressing steel was located

65 wise by wedge pressure between trapezoidal Clamping plates are held that protrude laterally over the clamping channel and with their longer trapezoidal base rest on an anchor plate. As a result, the tension on a layer of prestressing steel is reduced by means of the Transfer adjacent clamping plates to the anchor plate. The clamp body, i.e. the abutment for the clamping force generated by the wedge effect consists of two concrete abutment bodies held together by a tension wire winding. The disadvantage here is that the tension wire winding when Driving in the wedge in the direction of force stretches significantly be embedded before the clamping force is fully effective. Otherwise the concrete would crack get, which is especially true when several clamping bodies in the direction of the clamping forces are concreted next to or on top of each other. Another known design according to DE-PS 10 37 690 avoids this by the fact that the clamping body with the full one already during the manufacture of its sheathing Clamping force is applied and then relaxed again. Such sheathed clamp bodies can be used for the structural concrete without the risk of cracking, but their production is complex and the handling is complicated. In addition, such covered clamp bodies are heavy because they are generally rigidly connected to the required anchor plates.

In another known tension wire bundle anchorage according to DE-PS 12 58 064, the clamping force is increased by tightening high-strength screws A predetermined torque is generated, the screw shafts penetrating the individual clamping plates and act as a clamp body. The screw heads and nuts engage behind pressure plates on both sides of the Clamping packages, which transmit the clamping forces to the clamping plates and are located on an anchor plate prop up. In addition, it is necessary for the operation of these known tension wire bundle anchorages that the means for absorbing the clamping force, such as tension wire winding, screws and the like consist of high-strength material and have a large elastic deformation path under the effect of the full clamping force. This is required to get the To anchor prestressing steels securely until they break. This is because they suffer before their fracture state Changes in shape which lead to a reduction in the clamping package dimensions in the direction of the clamping force to lead. This shrinkage must be absorbed by the elastic reserve of deformation. For very large clamping forces, however, this route is practically no longer feasible, because multi-layer tension wire windings are difficult to implement and because, on the other hand, high-strength screws are not available in any large diameter. An increase in The number of screws beyond four, for example, does not bring any remedy, since then with the planned Tightening the screws will make the mutual interference prevail and the process of the Anchoring confusing, tedious and in any case would be uneconomical.

It is also known from DE-PS 12 58 064 at Use of high-strength screws as clamping bodies, the shrinkage of the clamping package by additional to compensate trapezoidal clamping plates that do not rest on the anchor plate, but only on both sides on the screw shafts. When the

With a prestressing steel train, these trapezoidal plates move in the direction of the train and spread the screw shafts. However, the effectiveness of this training is very much dependent on the accuracy of the installation of the trapezoidal plates depending and on whether the composite steel / clamping plate is on the adjacent, on the anchor plate The immovable clamping plate loosens early enough and sufficiently so that the trapezoidal plate is still can take effect in time for the shaft expansion, before all prestressing steels of the anchorage slip through. It is therefore difficult to apply such a design without risk.

From OE-PS 2 35 535 and BE-PS 5 12 495 wedge anchors are also known in which the Longitudinal tension acting on the tendons indirectly via intermediate pieces or intermediate wedges to the for Generating transverse pressure serving wedges transmits, whereby the wedges are tightened.

The invention is based on the object of providing a clamping anchorage of the type mentioned at the beginning create, through which high clamping forces can be transmitted in a simple manner in a space-saving manner, so that the voile The breaking load of all tendons can be achieved without the anchorage failing prematurely and without the structural concrete surrounding the anchorage is exposed to the risk of impermissible cracks

This object is achieved according to the invention by a clamp anchorage of the type mentioned at the beginning solved in that the clamping plates with decreasing width in the direction of the train of the tendons are formed and rest with their lateral boundary surfaces on the clamping body.

A clamp anchorage according to the invention thus gives the advantage that the clamp package in the area of Working loads is under the effect of a real clamp anchorage and that it is at a Increasing the tendon tension the effect of a real wedge anchorage is superimposed. It surrenders thus a device in which the advantages of both anchoring principles are combined.

A clamp anchorage has the advantage that the prestressing steels are arranged in several layers can, but the clamping force only depends on the number of prestressing steels per layer and not on the number of layers depends and that the tensioning wire pull allocated to each prestressing steel layer directly over the adjacent Clamping plates is removed.

A wedge anchorage for many prestressing steels has the advantage that the clamping body path is not in one Direction takes place, but in all directions in the anchoring plane (and thus the stress of the surrounding building concrete low) and that the wedging force only needs to be measured for the state of use, because the self-tightening of the real wedge anchoring before and in the fracture state done by itself if necessary

The function of the clamp anchorage according to the invention is based on the time sequence of the Processes shown: After tensioning a tension wire bundle by means of a hydraulic tensioning device, the clamping plates with their lateral Boundary surfaces brought into light contact with corresponding recesses in an anchor plate, see above that the clamping plates can still be moved in the direction of the clamping force without significant friction. Then the wedge or wedges are pressed in hydraulically. As a result, the composite prestressing steels / Clamping plates produced, but the tensioning force of the tension wire bundle is still held by the tensioning device and, supported by it, converting this clamping force from the clamping device to the clamping package brings this to the frictional contact with the anchor plate acting as a clamping body. A so-called transfer route occurs on, which results from the clamping plate movement during transfer Clamp anchoring can be much smaller than the slip with a wedge anchoring. In this state, the The clamping force is only calculated for the service load of the prestressing steel bundle plus a safety margin. the Expansion of the clamping body in the direction of the clamping force is correspondingly small.

When converting the clamping force, the lateral boundary surfaces of the clamping plates act because of them decreasing width as a wedge of a real wedge anchorage. This also applies to the entire terminal package, since With more than two-layer anchoring, there is always one supported between the wedge and the clamping package Clamping plate is located The increase in clamping force as a result however, this wedge effect is only in this state comparatively low: the high initial friction (friction of rest) between the wedge-shaped clamping package and the clamping body only causes a certain amount of friction Stress on the clamping body perpendicular to the direction of the clamping force. That has the desired effect a further, albeit slight, reduction in the expansion of the clamping body in the direction of the clamping force. In addition, the repositioning process in the case of anchors arranged next to one another in the clamping force direction, one after the other - and never at the same time - is performed. Thus, the stress on the structural concrete remains low in the usage state due to the expansion of the clamping body.

In the fracture state of the prestressing steel bundle, this structural concrete stress no longer plays a role. the the resulting increase in tension leads to the overcoming of the initial friction in the keiiver anchoring and allows it to become fully effective. The so caused and intentional increase in clamping force be systematically influenced by appropriate shaping of the arcuate bearing surfaces and depends essentially on the type of prestressing steel used and its surface structure.

The lateral boundary surfaces can be flat or run in an arc.

A design of a clamp anchorage according to the invention can be of particular advantage in such a way that that bearing surfaces for the lateral boundary surfaces of the clamping plates on one made of steel Clamping bodies are provided. It is particularly advantageous to make the clamping body as a disk pack To form steel sheets. These can be and are made by stamping or forging advantageously layered one on top of the other that the interruption due to punching is approximately parallel to the Course of the lateral boundary surfaces runs

Embodiments of a clamp anchorage according to the invention are explained below with reference to the drawing. It shows

F i g. 1 a section through the clamp anchorage for four strands in two layers with one? at the same time as Anchor plate formed clamping body and lateral boundary surfaces of the clamping plates in arch form,

F i g. 2 a cut. according to line 2-2 of FIG. 1,

F i g. 3 is a view of the clamp anchorage along line 3-3 of FIG. 1,

4 shows a section analogous to FIG. 1 through the

Clamp anchoring with a different arch shape of the clamp plates,

F i g. 5 shows a section analogous to P i g. 1 with trapezoidally decreasing panel width,

F i g. 0 shows a section along line 6-6 in FIG. 5.

F i g. 7 shows a section through a further embodiment of a clamp anchorage for three prestressing steels each Location with trapezoidal clamping plates and a clamping body that consists of an anchor plate as a partial clamping body and attached lamellar clamping body as an additional partial clamping body.

8 shows a section along line 8-8 in FIG. 7, the shows two laterally arranged flat wedges.

F i g. 9 is a view along line 9-9 of FIG. 7 and

10 shows an enlarged partial section through a stack of lamellae with interruptions in the individual lamellae and envelope surface indicated by dash-dotted lines.

The clamp anchorage according to FIGS. 1 to 3 has four prestressing steels 1 designed as strands as tendons on, arranged in two layers of two strands, and three clamping plates 3 with arcuate, namely in substantially convex lateral boundary surfaces 4, which are essentially complementary Support shaped bearing surfaces 9 on a central inner recess 8 of a clamping body 7 made of steel.

As shown in FIG. 3, two outer clamping plates 3a are provided with grooves 5 on one side for receiving the prestressing steels 1, while a central clamping plate 3b has grooves 5 on both sides. The clamping package formed from the clamping plates 3a and 3b and the prestressing steels 1 is subjected to a clamping force by flat wedges 6 driven in on both sides. This clamping force is based on the clamping body 7, which is also designed as an anchor plate Ta. The tensile force prevailing in the prestressing steels 1 is transferred by means of the clamping plates 3a and 3b via their lateral boundary surfaces 4 to the correspondingly shaped bearing surfaces 9 of the clamping body 7 and the anchor plate Ta formed in one piece with this. In this way, the clamping body 7 forms after the Clamping force from a clamping device on the clamping plates 3 with these a supporting arch. This gives the entire clamp anchorage a desirable stiffening so that the clamp plates 3 can be made so thin that they can still be bent sufficiently in the plane of the plate to compensate for tolerances.

The flat wedges 6 are pressed in hydraulically to convert the clamping force and slide on the one hand on the outer sides of the clamping plates 3a, which are plane-parallel in the present case, and on the other hand on inclined surfaces IO of the clamping body 7. After reaching the required wedge pressing force to be determined by tests, the wedges 6 come into contact with their Tips 11 from the part of the clamping body 7 that forms the anchor plate 7a . In this area, only a partial clamping force acts on the clamping plates 3 , since the tips 11 bend easily. The projecting ends 12 (F i g. 1) of the clamping plates 3, therefore, go there with the prestressing steels 1 only a portion of composite one, which the fatigue behavior advantageously, the prestressing steels 1 affected in the portion exceeding the use state of stress acting the Bogenfor men of auflagernden lateral boundary surfaces 4 as sliding a wedge anchor, wherein the clamping package! slides ängs the flat sides 13 of the Kiemmplatten 3a

When using only two flat wedges 6 on opposite sides of the package according to FIG. They can instead of the illustrated rectangular cross-section on their outside approximately hemispherical cross-section to eim in complementary-kon vex shaped recesses of the clamping body 7

To allow rotation about the longitudinal axis of the wedge

thus an absolutely parallel position of the clamping plates:

to reach.

4 shows a clamp anchorage analogous to de

ίο Fig. I to 3, but for a convex arch shape of lateral boundary surfaces IS. the corresponding ™ concave support surfaces 16 of a Klemmkör pers 17 support. This shape enables the pressing down of the clamping plates 15 in front of the

\ s Implementation of the clamping force from the clamping device to the clamping package an exact alignment of the grooves' (Fig. 3) parallel to the axes of the prestressing steels 1. The clamping body 17 thus acts similar to a ball socket support and causes the tendons 1 to nestle precisely in the aligned grooves 5, which should correspond exactly to the outer diameter of the strands or prestressing steels 1. Here, too, clamping plate protrusions ISa can be provided to improve the fatigue behavior.

2ί From Fig. 5 and 6, the configuration is above Clamping plates 18 in trapezoidal shape with a straight limiter, 7ung surfaces 18 'can be seen. This trapezoidal shape can be produced by punching without waste. Such Yrapezoidal clamping plates 18 are used for anchoring

ίο tion of prestressing steels in the form of profiled or Ribbed flat steels 19 used in two layers, in which a Flachkeii 20 is arranged in the middle, and in front the prestressing steels or flat steels 19 is separated by the clamping plates 18. Dit

ti abutment forces for wedge pressing force centric atr Tensioning device on. A lateral migration of the wedge «20 during driving does not therefore occur.

According to FIG. 7 to 9, the prestressing steels, namely dre flat steel 19 each layer, arranged according to Figure 8 in five bearing between trapezoidal clamping plates 22 are the Klemmplattten 22 superimposed on to a clamping body which is formed of an anchor plate 23, and a multi-plate stack 24th The latter consists of steel plates 24a. b to χ and is used by the trapezoidal shape of the clamping plates 22 to distribute the tension force on the anchor plate 23. The individual lamellas can be connected to one another, for example by grooved pins, screws, rivets, external clamps, heHschweiUufig, gluing

so or the like. With a reliable connection of the individual lamellae to one another, it is also possible to dispense with a separate anchor plate and instead to build up the entire clamping body, including a part acting as an anchor plate, from steel lamellae

ss to use a partial body made of steel lamellas and a further partial body in the form of the anchor plate 23 Flat wedges 25 dismantled into partial wedges, which rest on the outside of the outer clamping plate 22a, generate the clamping force when pressed in and can be temporarily connected to a wedge / clamping plate piece during assembly . Each part wedge can have a driver cam 26 protruding on both sides, which is used for larger bundles of prestressing steel. If, for example, the stroke of a tensioning device is sufficient to achieve the full tensioning path , the initially achieved partial tensioning force is temporarily anchored by pressing in the flat wedges 25. The tensioning device is then re-anchored on the anchored clamping package

applied, and when the partial clamping force achieved is exceeded, the clamping package moves out of the clamping body, sliding along the inner wedge surfaces. The outer clamping plates 22a run against the driver cams 26 and thereby release the intermediate anchoring. It is now possible to continue tensioning or to lower it again. In the case of the latter, however, there is a risk that the flat parts 25 will pull themselves in and thereby cause premature anchoring. This can be countered by blocking the wedges with intermediate layers under the driver cams 26 until the desired tensioning state of the prestressing steel is achieved.
Finally, Cig. 10 building a

Clamping body or partial clamping body according to P ig, 7 to S. The individual steel lamellae 24a to e are shown here. The interruptions 27 that arise during the punching of the trapezoidal plates are placed approximately in the direction of the ultimately desired, enveloping surface 28. When the interruptions 27 are acted upon either by flat wedges or lateral bearing surfaces of arcuate or trapezoidal clamping plates, slight local cold deformations take place, so that practically exactly the desired surface 28 is produced. A prerequisite for this is that a material is used for the stack of lamellae 24 that, with sufficient strength to absorb the clamping forces, still has sufficient plastic deformation capacity. to avoid cracks. A suitable material is, for example, steel grade St 60.2 in thicknesses of 5 to 15 mm.

For this purpose 3 sheets of drawings

Claims (9)

Patent claims: 1. Clamp anchorage for tendons in prestressed concrete construction, which are placed in layers between flat, parallel clamping plates under the pressure at least a wedge acting perpendicular to the plane of the plate in a clamping body are held together, el a -characterized in that the clamping plates (3; 15; 18) with in the direction of the train Tendons of decreasing width are formed and with their lateral boundary surfaces (4; H4; 18 ') on the clamping body (7; 17; 30). 2. Clamp anchorage according to claim 1, characterized in that the lateral boundary surfaces (4; 14) are arcuate. 3. Clamp anchorage according to claim 1, characterized in that the lateral boundary surfaces (18 ') are flat. 4. clamp anchorage according to one of the speeches 1 to 3, characterized in that support surfaces (9; te; 30 ') for the lateral boundary surfaces (4; 14; 18') of the clamping plates on one off Existing steel clamping body (7; 17; 3K)) are provided and at least over a partial area complementary to these boundary surfaces get lost. 5. clamp anchorage according to claim 4, characterized in that the lateral boundary surfaces (14) of the clamping plates (15) are convex Have arch shape and concave shaped: o The bearing surfaces (16) of the clamping body (17) rest. 6. Klemmverankerucg according to any one of claims 1 to 5, wherein the clamping body a from Clamping plates, wedges and spans are structurally formed » Has the inner recess receiving the clamping package, characterized in that the inner recess (8) in the direction of the by the wedge effect generated clamping force has the shape of the compressed clamping package *> 7. Clamping anchorage according to one of the claims 1 to 6, characterized in that the clamping body forming the bearing surfaces for the lateral boundary surfaces of the clamping plates (22) is formed as a lamellar pack of steel sheets (24a to 2 '\ x) ·· 8. Clamp anchorage according to claim 7, characterized in that the steel lamellas (24a to 2 <\ x) are produced by punching or forging and are layered so that the interruption (27) is approximately parallel to the course of the lateral boundary surfaces of the clamping plates (22) runs 9. clamp anchorage according to claim 7 or B, characterized in that the steel plates (24a up to 24; rJ are connected to one another by holding means, tack welding or gluing.