CS274284B2 - Tensioning rope for structures from prestressed concrete - Google Patents

Abstract

A strand for stressed concrete structures, formed as a twist with at least three wires provided with surface profiling. The essential feature of the invention is that the surface profiling of the wires (3) is formed as non-circular cross section profile continuously passing through the wire in longitudinal direction. Furthermore subject of the present invention is a process for the production of this type of strand. Here first the surface profiling of the wires is formed with cold deformation, then at least three wires are simultaneously twisted to a strand. The essential feature of the process is that the surface profiling of the wires is formed by drawing through drawplate of non-circular cross section, preferably of regular hexagon opening cross section with rounded corners.

Description

BACKGROUND OF THE INVENTION The present invention relates to a tension rope for prestressed concrete structures comprising at least three cover wires provided with a surface profile in the form of a helix.

Various tension ropes are used to absorb the tensioning forces acting in prestressed or post-tensioned concrete structures. These cable-shaped tension ropes are manufactured on stranding machines from 3 to 7 steel cold-drawn wires with a diameter of 2 to 5 mm. The tensioning forces of the tensioning ropes are transferred to the concrete structure by a connection between the tensioning ropes and the concrete, possibly by an anchorage. Experts have long sought to find a solution by which the anchoring or suspension between the tensioning ropes and the concrete could be improved so that the tensioning force which is particularly desirable for prestressed concrete structures with a higher load-bearing capacity or larger construction span can be increased.

Tension ropes are known which have a periodically recurring, uniformly distributed, shallow recess on a rolling surface, similar to simple reinforcing bars.

The bonding capacity of tensioning ropes with concrete is improved by such indentation formed by periodic profiling, or the so-called length of adhesive anchorage is shortened, but due to the bending and torsional stresses occurring during tensioning of tensioning ropes, increased cracking or danger break at the angles of indentation into the wires. Moreover, the positions of these tension rope surface profiles are random, which means that the active cross-sectional areas and cuts across the longitudinal axis of the tension rope deviate from each other, with the result that the stresses that occur under load are different.

This implies that the decisive cross-section for dimensioning the tensioning rope must be the smallest cross-section, which, however, is unfavorable in terms of steel consumption.

It is known to manufacture tensioning ropes, according to which the tensioning rope, braided from wires of circular cross-section, is deformed and compacted at the same time by external pressure in the radial direction. In particular, the cover wires are deformed such that an irregular deformed shape results from their circular cross-sections. The aim of this compaction is to achieve the smallest possible cross-section of the tensioning rope, especially in the case of a concrete post-tensioning structure. However, this compaction is associated with a narrowing of the outer surface of the tension rope which comes into contact with the concrete, which is not desirable from the point of view of what has been said.

It is an object of the present invention to overcome these disadvantages and to provide tensioning ropes for prestressed concrete structures which can be used to improve the connection to the concrete, thereby ensuring the same tension in all the tension rope sections.

The object of the invention is based on the aforementioned tensioning rope and a tensioning rope has been provided for prestressed concrete structures, consisting of at least three helix-coated surface wires according to the invention, which consists in that the non-circular continuous cross-section are twisted before alignment. It is preferred that the cross-sectional profile of the wires be a continuous polygon in the longitudinal direction, preferably a hexagon with rounded vertices. Still further, it is preferred that the twist pitch of the tension rope is several times greater, preferably at least ten times, than the twist pitch of each individual covering wire.

The advantage of the tensioning rope according to the invention is that it ensures perfect bonding with the concrete and ensures the same tension in all the tension rope cross sections.

An exemplary embodiment of a tension rope according to the invention is shown in the accompanying drawing which is a cross-section of the tension rope.

The tension rope 1 consists of a central wire 2 forming a support core with a circular cross section and six covering wires 3 surrounding the tangentially central wire 2.

The cover wires 3 which come into contact with the concrete and extend continuously in the longitudinal direction in the transverse profile have a cross section but deviating from the circle, which results in a reinforced connection to the concrete as well as the same tension values in all cross section of the tensioning rope.

The central wire 2 has a circular cross-section with a diameter D 4. The cover wires 3 have a regular hexagon, the circle inscribed in the hexagon has a diameter and the circle circumscribed about the hexagon having rounded peaks has a diameter D. The tension rope, measured at opposite rounded apexes of the cover wires 3, has a diameter. and measured at the locations of opposite faces of the cover wires 3, diameter Lg.

It has been found by experience that it is advantageous to dimension the diameter D ~ of the central wire 2 by 3 to 4% larger than the diameter of the cover wires 3, since this results in a better fit of the cover wires 3 on the central wire 2. , the diameter Dg of the middle wire 2 was 4.26 mm and the diameter D 5 of the top wire 3 was 4.11 mm.

The twist pitch of the tension rope 1 is selected several times greater, preferably at least ten times greater than the twist pitch of each individual covering wire 3.

It should be noted that the cover wires 3 are shown in an idealized state in the drawing since the edges of the hexagon of adjacent cover wires 3 abut one another. In fact, this illustrated state is rarely achieved.

The production of the tension rope 2 in the illustrated embodiment can be carried out, for example, as follows:

The production technologies of the intermediate wires 2 and the cover wires 3 essentially coincide with the traditional production technology. In the production of the cover wires 3, only the last working step of cold forming is different, in which a special hexagonal drawing tool is used to produce the desired longitudinally extending wire with a cross-section different from the circular shape.

The cover wire 3 additionally shortens around the longitudinal axis as it passes through the pulling tool. Depending on the circumstances, this twisting may be omitted. The pitch of the twist when twisting the wire is determined by the pitch of the thread in the drawing tool. The pulling tool was positioned so that it could rotate about the forwardly advanced wire during the tests.

After the production of the cover wires 3, the tensioning rope 1 is assembled from the middle wire 2 and the six cover wires 3 on a known stranding machine (not shown). In the tests, the twisting direction of the covering wires 3 and the twisting direction of the tensioning rope 1 were the same and the twisting pitch of the tensioning rope was about ten times greater than the twisting pitch of the covering wire 3.

As a result of the selected ratio, a favorable contact between the center wire 2 and the cover wires 3 occurred after the torsion. After the installation of the tension rope 2 in the concrete, an improved anchorage was achieved.

The strength of the tension ropes can be increased by known and commonly used heat treatment methods such as tempering, stabilization, which are conventional.

It has been found by the experience of the tests that the illustrated embodiment of the tensioning rope 1 can be produced simply and productively on the existing devices, apart from the relatively low cost.

In the direction of the longitudinal axis of the cover wires 3, the cross-sectional hexagonal cross-sections of the tensioning ropes 2 are the same at all points and, therefore, in the stopped state, the stresses therein are the same. In contrast to the periodic profiling, the tensioning rope 2 has an enlarged outer surface, thereby acquiring a more anchoring ability. As a result, the carrying capacity of the tensioning rope 1 is increased or the safety factor of the tensioning rope 1 is increased. If the same carrying capacity of the tensioning rope 2 is chosen, the steel consumption is reduced, thereby reducing the cost of raw material needed for production of tension ropes 2 ·

It is also possible for the central wire 2 forming the core of the tensioning rope 2 to be omitted and the tensioning rope 2 to consist only of covering wires 3. In tensioning ropes 2 ^with several wires, the middle wire 2 can be the same as the covering wires 3. instead of the described hexagonal profiles other profiles deviating from the circle, for example a pentagon, an octagon and the like, can be used with the same result. It is furthermore possible to use circular or polygonal profiles in the cover wires 3, which are provided with groove depressions (not shown) running in the longitudinal direction and / or in the longitudinal direction of the rib-like or ridged ridges. For creating these last

As is evident from what has been mentioned above, any known method, such as rollers, can be used for these cold tension ropes.

Claims (3)

Tensioning rope for prestressed concrete structures, comprising at least three surface wires provided with a surface profile formed as helix, characterized in that the cover wires (3) of the non-circular continuous cross-sectional profile are twisted before alignment. Tensioning rope according to claim 1, characterized in that the cross-sectional profile of the covering wires (3) is a continuous polygon in the longitudinal direction, preferably a hexagon with rounded peaks. Tension cable according to claim 1, characterized in that the torsion pitch of the tension rope (i) is at least ten times greater than the torsion pitch of each individual covering wire (3).