DE4313227A1 - Prestressed reinforcement element - Google Patents

Description

The invention relates to a prestressed reinforcement element according to Preamble of the main claim. This is known from DE-PS 7 49 927.

Similar reinforcement elements are known from DE-PS 11 40 594 and FR-PS 1033005.

The known prestressed reinforcement elements are heavy major defects. It is for economic reasons required the concrete reinforcement elements, e.g. B. rods, not to fit individually for each application, but to manufacture them with standard lengths of z. B. 12 or 20 m in stock and later cut to fit. When cutting the rods on somewhere surprisingly arise in the Introduction area of the tendons high splitting tensile forces, too lead to a zipper-like splitting of the rods. Such Splitting tensile forces also occur at the rod ends of the standard lengths on. These split tensile forces are particularly high when that Reinforcement element is very prestressed. On the other hand a high bias is required to ensure high effectiveness of the To achieve reinforcement with low enforcement. Also has it has been shown in practical application that when the Concrete printing Strength to better absorb the preload length and thus the splitting tensile forces become larger. Except this has been shown in practical tests that the past specified prestressed reinforcement elements at high bending stresses that exceed the preload, a crack subject to education and that there are few major cracks in the blast form element. These cracks settle in the surrounding area concrete continues with the consequence of an impairment of use  ability, e.g. B. by corrosion. This danger is especially then given if for reasons of split tensile forces, the transport stresses or creep losses are insufficient lead can achieve pre-tension. Experiments have also shown that it is easy to handle when handling the reinforcement elements bursting comes up, causing the central arrangement of the steel chips Localization is lost with the result of complete destruction of the reinforcement element.

It is therefore an object of the invention, the prestressed reinforcement to further develop elements in such a way that they can be any length separable standard lengths can be manufactured in stock and even with high preloads not to split the ends tend.

This task is performed by the reinforcement elements according to claim 1 solved.

In the following the invention with reference to drawings and Aus management examples explained in more detail. Show it

Figure 1a shows a bar with a conventional prestressed reinforcement element in longitudinal section.

FIG. 1b shows a bar with the inventive Bewehrungsele elements in longitudinal section;

2a, b show beam cross sections for bridges with an enforcement with the inventive reinforcing elements.

Figure 3 is a longitudinal bridge section of a cycle sliding bridge with the reinforcement elements according to the invention (a) in the Verschubzu and (b) in the end position. and

Fig. 4 is a steel composite bridge in longitudinal section with transverse reinforcement elements according to the invention.

The reinforcement elements according to the invention are against splitting completely stable at the ends. The effectiveness is also increased with the same enforcement and the same preload. This is it is easier possible to avoid gross cracks and the danger reduce destruction during handling. Especially it is possible to use reinforcement bars with a thickness of at most 15 cm in a direction transverse to the clamping direction to manufacture.

Fig. 1a) and b) shows a bar 2 on two bearings 4 with a single load 6 in the middle of the field. The bar is reinforced with prestressed reinforcing bars 8 , 8 'at the bottom. The bar 2 is so heavily loaded that the crack load of the reinforcement bars 8 , 8 'is exceeded.

Concrete reinforcement elements result in small crack widths and uniform crack distribution, as long as the force from the external load in the reinforcement is less than the crack load of the reinforcing bars. Reinforcing bars 8 without fibers ( Fig. 1a) begin when torn with a large first crack 10 at the point of greatest stress. This settles in the same place in the surrounding concrete 20 with a similar crack 12 . The serviceability is no longer given because the prestressing steel 14 can corrode. In the case of rods reinforced by fibers ( FIG. 1b), when the crack load is exceeded, microfine cracks 16 form over a larger area. As a result, the building concrete 20 is not torn open at one point, but there are many fine cracks 18 over a longer distance, which do not influence the usability and which also does not cause corrosion. Since these reinforcing bars 8 'keep their crack-distributing effect even beyond the crack load, the fiber-reinforced bars 8 ' need less concrete compressive stress for the same effectiveness.

A calculation for a highly stressed with concrete bars enforced cross-section has shown that the load-bearing capacity can only be exploited if the remaining compressive stress depends on Concrete quality of the surrounding concrete at least 25 N / mm² and above preferably at least 30 N / mm² and especially at least 40 N / mm² lies.

Highly prestressed concrete bars lose due to the time-dependent plastic deformation of the concrete is part of its compressive stress. For standard bars, however, the chip must have a permanent value guaranteed. By manufacturing in the fitted bed, the Bars loaded early, d. H. at a time when the Strength is not fully developed. Therefore, with Advantage through a bundle of concrete technology measures and who set the concrete creep resistance by post-treatment the. The disadvantages of strong creep can be reduced be avoided. Please note the following:

• (1) For a permanent compressive stress, the compressive strength of the Be high. But this increases the creep.
• (2) The decisive concrete compressive strength is initially short-term much higher than when in use.
• (3) The clamping force and thus also the necessary amount of prestressing steel are larger than it is for because of the briefly high voltage the working load would be necessary.  
• (4) The higher preload force also requires a higher one Split tensile capacity.

Reinforcement bars that creep when installed shorten, partially transfer their compressive stress to the building factory concrete. This effect is used according to the invention to Reinforcement bars with a particularly creepable set Generate concrete matrix prestress in structures.

When loosening the tendon sections in the built-in Condition may be in a pressure zone, e.g. B. by electrical Heating the tension wires, will pull on the construction factory concrete applied. This makes sense for pressure zones or Pressure members, because this results in relief.

Strands or rods made of high quality are used as tendons Prestressing steel used. For these strands are common Tensioning devices and wedge anchors available. Have strands a good bond with the surrounding concrete. For creep-resistant reinforcement elements, it makes sense, if possible high quality prestressing steel with high tensile strength. When the pressure stresses are transferred to the reverse Practice concrete by creep is a prestressing steel with a larger area, d. H. cheaper with less strength. With several Tendons in the rod are arranged so that they enforce the cross section evenly and if possible in The focus of their proportional area is.

The concrete of the reinforcing bars is because of the high required Compressive stress is a high-strength concrete. It becomes from the Manufacturing process made the requirement that if possible high strength can be achieved quickly, so that the fitted bed  can be used again. The concrete has a particularly good off Coordinated grain size ratio for round grain shapes. Either Strength as well as creep resistance have with tight grain equip more favorable values. Especially filling the fine pores by replacing part of the cement with fine sili Katstaub, which with a grain size of 0.1 µm is much finer than Cement is a high pressure and creep resistance is achieved. At the same time, the concrete is poured with little water, i.e. H. preferably with a water-cement weight ratio below 0.3 provides, the processability caused by a superplasticizer to be led.

Concreting is easy for the simple rod cross-sections. The concrete is placed in molds and by shaking or Walking compacted. The concrete can be used for faster hardening saturated steam to be heated, so that after one or two Days can be stressed by relaxing the tendons become. After that, the rods are preferably in a damp condition stood hermetically sealed with foils in transport units reduce creep by drying out.

The fibers are preferably added to the fresh concrete. The The type of fiber depends on the desired degree of strength increase. There are fibers made of glass, plastic, Carbon or steel in question. The fibers in the Be reinforcing bars according to the present invention have several functions: On the one hand, the fiber content and the type of fiber are chosen so that when cutting the rods at the free end of the cut resulting split train can be absorbed. So it will possible to fit the rods at any point during installation to cut. Another function of the fiber component is the Er increasing the ductility of the bars. Especially the pressure zone of the  Rods caused by bending during transport are brittle against fibers Chipped secured. Such flaking leads to the high Compressive stresses to destroy the rod. The fibers protect the rods even during impact loads during transport and Installation. The effective length of the fibers depends on the component thickness dependent. A length in the range of 5 to 30 mm and preferably 6 to 25 mm is advantageous.

When glass and plastic fibers are added, the concrete must be in its Alkalinity can be changed by additives so that the fibers do not become brittle. The fiber content will vary depending on the requirement between 0.5 and 5.0% by volume, preferably 1 to 3% by volume. The best reinforcements are made with special metal parts instead of fibers that have a shape that changes particularly suitable for good adhesion in concrete, e.g. B. the shape of wire or sheet metal sections with extended ends or kinked ends.

In the following there are application examples for the concrete rod reinforcement tion described according to the present invention.

In Fig. 2a, b cross sections of a conventional Plat tenbalkenbrücke are shown schematically. The tensile zones in the field ( Fig. 2a) are interspersed with reinforcing bars at the bottom, while the column cross sections ( Fig. 2b) are interspersed at the top. The bars are staggered in the longitudinal direction of the bridge according to the usual torque coverage line. The shocks are offset evenly.

In Fig. 3a, b the longitudinal section of a cycle sliding bridge is shown when pushing and in the end position. When pushing both an upper 30 and a lower reinforcement 32 is required at all points. This is shown endlessly, but in practice it consists of overlapping reinforcing bars. In the end position, the reinforcement elements in the pressure zones, ie in the field above and in the column areas below, are no longer required. The subsequent loosening of the tendons at this point, for. B. by heating, indicated by a dashed line 34 , results in a cheaper, steel-saving stress on the bridge.

In steel composite bridges over several fields ( Fig. 4), the tensile force from the column moments in the carriageway slab is often covered with reinforcing steel because this eliminates the problems of introducing the prestressing. The cross-section of composite bridges usually has cantilevers that are so large that a transverse pretension is necessary. This gives rise to the problem that cross-members in the supporting area with corrosion-promoting transverse cracks 36 occur parallel to the tendons. For a transverse reinforcement with concrete reinforcement bars 8 'such cracks are harmless Lich and when covering the supporting moments with concrete reinforcement bars 8 ' in the longitudinal direction, the cracks become harmlessly small. In addition, there is no problem for the transverse direction that part of the prestress migrates from the concrete slab into the steel construction.

In tower-like structures, there is often strong wind concentration with recesses near the foundation. But the compressive stress reserves of the concrete are used cross-section additionally, which one for the bend under wind needed. In the case of reinforcement with concrete bars, the high ones can be used Utilize steel grades without closing the pressure zone of the cross section  strain. The stiffness is when reinforcing with concrete reinforcing bars larger; that leads to a reduction in Load eccentricities from the deflection.

When underpinning it is often necessary to add supports later insert and give them a defined force. That will be with Preliminary deformation via hydraulic presses on the side of the supports realized. Are supports installed with concrete reinforcement tion bars with subsequently releasable tendons are armed, a defined can be achieved by loosening the links Force or deformation are initiated, which is the sum of the of the entire length of the column in the tension strands speaks.

It is known that slabs without shear reinforcement have higher cross can absorb forces if the tension belts are stiff. In the You can reinforce slabs with concrete bar elements achieve larger spans without the complex shear reinforcement.

Another application arises with cylindrical containers. The reinforcement elements can be adapted to the curvature, and they are formed with offset joints. The use of according to schedule creepable elements results from the ver shortening the elements a ring preload in the container wall.

In all applications, the concrete reinforcement elements can cross contain sheets with holes for the tendons that turn out to be Connection plates for various attachments to the outside extend.

Claims (19)

1. Prestressed reinforcement element with at least one direction, centrally arranged tendons made of steel, glass or aramid or carbon in a concrete or mortar matrix and with for the connection with the surrounding concrete from the outer surfaces, characterized in that the concrete or mortar matrix contains flexible plastic, glass, carbon or metal fibers or rigid reinforcing wires or strips of metal in an amount effective to even out the crack distribution. 2. Reinforcing element according to claim 1, characterized in that the concrete or mortar matrix has a creep resistant finish. 3. Reinforcing element according to claim 1, characterized in that the concrete or mortar matrix is chosen so that the front tensioned reinforcement element in the tensioning direction a permanent Compressive stress of at least 25 N / mm². 4. Reinforcing element according to claim 1 to 3, characterized in that the reinforcing element has transverse plates with passages for the tendons 14 . 5. Reinforcement element according to claim 4, characterized in that the cross plates on the reinforcement element laterally protruding Have anchoring and connection plates. 6. Reinforcing element according to claim 1, characterized in that the concrete or mortar matrix one for a partial transfer the creep capacity measured on the surrounding concrete ability.   7. Reinforcing element according to claim 6, characterized in that the reinforcement element is protected against drying out. 8. Reinforcing element according to claim 1 to 7, characterized records that the centrally prestressed reinforcement elements have a curved or kinked clamping direction. 9. Reinforcing element according to one of claims 1 to 8, characterized characterized in that the concrete or mortar matrix for the contract is inert with the fibers. 10. Reinforcing element according to one of claims 1 to 5 or 8, 9, characterized in that the tendons 4 in the concreted state of the reinforcing element 8 'can be relaxed by heating, so that their tension is converted into a tension of the surrounding concrete. 11. Use of the reinforcement elements according to one of claims 1 to 9 for the reinforcement of structural areas that are subject to tension. 12. Use of the reinforcement elements according to one of claims 1 to 9 for the reinforcement of bridge structures in places with parallel to the longitudinal direction of the reinforcement elements 8 'develop the cracks. 13. Use of the reinforcement elements according to claim 10 for Erection of bridges in the cycle shift process under relaxation NEN the only necessary for the displacement state elements. 14. Use of the reinforcement elements according to one of claims 1 to 9 for vertical reinforcement of tower structures.   15. Use of the reinforcement elements according to claim 9 in through the relaxation stretchable supports for underpinning measures. 16. Use of the reinforcement elements according to one of claims 7 or 8 and claim 10 for generating an annular pressure tension in containers or tubes. 17. Use of the reinforcement elements according to one of claims 1 to 9 for the reinforcement of structural areas that are subject to tension. 18. Use of the reinforcement elements according to one of claims 1 to 9 to prevent the supports from punching through on flat cover. 19. Buildings obtained according to one of claims 11 to 18.