EP0505351A1 - Tensioning strand for prestressed concrete structures - Google Patents

Abstract

Tensioning strand consisting of a plurality of tensioning elements 1, such as for example rods, cords or wires, which extend parallel to one another and are covered by at least one common plastics sheath 2 preferably made of polyethylene or the like. In order that the tensioning strand requires only a small space in the support structure, the plastics sheath 2 tightly encloses the tensioning elements 1, which are connected tightly in contact with each other in an ordered configuration, the centre points of adjacent tensioning elements 1 lying at the corners of equilateral triangles or quadrangles. The interstices 4, 5 between the tensioning elements 1 can be filled with respect to one another by a permanently flexible compound, the compound also being able to penetrate between the tensioning elements 1 and the plastics sheath 2, so that the tensioning elements 1 can slide in the plastics sheath 2. In the process for manufacturing the tensioning strand, preferably a vacuum calibrator is used after the tensioning elements 1 have been guided in mutual contact through an extruder, or, if necessary, first through the permanently flexible compound. <IMAGE>

Description

The invention relates to a tension bundle for prestressed structures made of concrete or the like, consisting of a plurality of mutually parallel and mutually touching tensioning elements, such as rods, strands or wires, or the like, of at least one common plastic sheath, preferably made of polyethylene. are encased, and processes for its manufacture and installation.

It is generally known to pull clamping elements into a prefabricated cladding tube in a disordered manner and to press out the remaining free space with a lubricant, for example grease. However, only 50-60% filling of the cross section of the bundle can be achieved with tension bundles produced in this way, so that there is a relatively high space requirement with regard to the load capacity of the tension bundle.

In addition, the center of gravity of the clamping element arrangement does not coincide with the center of gravity of the casing, or its geometric axis. In addition, changes occur at each deflection point, i.e. when the sense of curvature changes, the mutual position of the focal points.

For cables in which the individual tensioning elements are not parallel to one another but twisted in the bundle, it has been proposed ("Structural Engineering International", Volume 1, Number 1, February 1991, pp. 61.62) that the inner spaces between the wires are included a corrosion protection compound. Here the inner sheath is built on the wires. When this cable is tensioned, the outer sheath with the cable expands to the same extent. The problem of reducing the frictional forces between the arrangement of the tensioning elements and the jacket is not addressed.

In the prestressing member according to AT-PS 269 439, essentially linearly arranged and mutually parallel sub-elements are provided, which, however, are connected to one another in a force-locking and shear-resistant manner. This binder, for example a Metal adhesive, fills the spaces between the sub-elements, but there is no plastic sheath that co-surrounds the sub-elements. The problem of choosing the distance between the individual sub-elements is not addressed, and the problem of the frictional forces between the clamping elements and a jacket remains unsolved.

In the tension bundle according to EP-A-0 393 013, a plurality of tendons running parallel to one another are surrounded jointly by a plastic jacket. Due to the provided envelopes of the individual tendons themselves, the cross section of the described and illustrated tension bundles is somewhat coarser than it should actually be. The enveloping plastic sheath is also further away from the individual tendons than would be necessary. The manufacturing method according to EP-A-0 393 913 comprises passing the tendons through an extruder, but no precautions are taken that the plastic jacket in the end product is designed in such a way that it leads to the smallest possible cross-section of the bundle and yet the mobility of the individual tendons in the bundle opposite the jacket.

The mobility of the tendons of the bundle relative to the plastic sheath enveloping them is also not given in the construction according to EP-A-0 160 135. Rather, for this purpose, a sliding layer must be provided outside of the plastic jacket and, radially thereafter, another jacket, the tendons, together with the jacket surrounding them, being able to move within the outer jacket. In addition, the outer tendons of the tension bundle described are arranged twisted around a central tendon, so that when the pretension is changed, there are disadvantageous changes in shape, in particular changes in the cross section of the tension bundle.

A tendon with twisted sub-elements is also described in W0-A-85/05394, which is not a pure tendon bundle, but a Reinforcement element for prestressed concrete structures. This reinforcement element consists of a combination of one or more tendons of conventional reinforcement bars and at least one spiral bar provided between them as a spacer. With this design, the above-mentioned disadvantageous cross-sectional changes of the reinforcement element also occur with changing prestressing, and neither a minimization of the space requirement nor a reduction in the frictional forces between the tensioning elements and a jacket enveloping them is discussed.

The latter also applies to EP-A-0 105 839, in which it is only described that it is known to provide clamping elements with a two-layer plastic covering. This document then goes into more detail on the choice of material for the plastic sheathing, but does not deal with minimizing the space required to reduce the friction between the tensioning elements and the jacket, or maintaining the shape and geometry of the tensioning bundle.

EP-A-0 095 413 only addresses the partial problem of the sliding properties of the tendons with respect to a cladding tube, which can also be made of plastic. However, the latter document gives no indication of how the problem of reducing the friction can be solved at the same time as minimizing the space requirement and maintaining the shape and geometry of a tendon bundle composed of several individual tendons.

The object of the present invention is to provide a tensioning bundle which avoids the above-mentioned disadvantages while minimizing the space requirement as much as possible, at the same time reducing the friction and maintaining the shape and geometry of the bundle in any position, and in the case of tensioning elements can also be tensioned individually or in groups.

To achieve this object it is provided according to the invention that the clamping elements are touchingly close in an orderly configuration are closely connected to one another by the plastic jacket, the centers of adjacent clamping elements being at the corners of isosceles triangles or squares or rectangles or on a straight line. Hiebei the term is to be understood narrowly so that the tensioning elements can be tensioned individually or together essentially smoothly and without entrainment of the jacket at most under the influence of a permanently plastic mass surrounding them in the plastic jacket. Due to the mutually touching clamping elements, the clamping bundle takes up only a relatively small amount of space in the structure or at the respective place of use.

According to a further feature of the invention, spaces between the tensioning elements can be filled with one another by a permanently plastic mass, so that the mass has also penetrated between the tensioning elements and the plastic jacket, so that the tensioning elements can slide in the plastic jacket.

Due to the permanently plastic mass between the tensioning elements themselves and in particular between the tensioning elements and the plastic jacket, the friction is largely reduced, and tensioning, also individual and especially the outermost tensioning elements, is facilitated. All the advantages of the compact parallel bundle are retained. The permanently plastic mass can also serve to protect the clamping elements against corrosion. A thickness of one or a few µm at the points of contact between the clamping elements or these and the plastic jacket is sufficient for the desired smooth clamping of the elements. Sliding masses, e.g. B. environmentally, in particular water-compatible fats, preferably based on silicone or mineral oil, or natural products, eg. B. rapeseed used.

According to a further feature of the invention, the tensioning elements are advantageously held together by at least one enveloping element, for example a film or a net made of plastic or steel, as a result of which the geometric configuration of the bundle is even more stable preserved. This also prevents the tensioning elements from striking against one another or against the inner wall of the plastic jacket, so that the risk of damage is further reduced.

In an advantageous variant for the embodiment of the tensioning bundle according to the invention, it is provided that the plastic sheath at least partially fills out at least some of the mostly gusset-shaped gaps, which are delimited by the outermost tensioning elements, by projections.

In order to ensure that the tensioning elements in the casing can move as freely as possible, it is provided according to an additional feature that materials with the lowest possible coefficient of friction or adhesion to the material of the tensioning elements are selected for the plastic casing. This additional feature, on the one hand, achieves better and more precise guidance of the outermost clamping elements, even between possibly provided enveloping elements, and a reduction in the necessary amount of permanently plastic mass.

Of course, the clamping elements can be protected against corrosion individually or in groups, for example by a plastic covering or a galvanic coating.

Advantageously, the clamping bundle described is produced in a process which is characterized in that the clamping elements are passed through an extruder, in which the plastic jacket is applied, in contact with one another, the clamping bundle is then guided in a vacuum calibrator with the still heated plastic jacket, whereby the jacket is sucked onto the wall of the calibrator by creating a vacuum, so that during the subsequent cooling and shrinking of the plastic jacket it leaves the clamping elements sufficient space so that the elements can slide in the jacket.

According to this manufacturing process, the tension bundle is produced in the configuration which has the smallest possible space requirement and by sucking the plastic jacket onto the inner wall of the calibrator it is achieved that the jacket is expanded to such an extent that it only cools in one in the subsequent cooling and associated shrinkage Dimensions become narrower that the internal clamping elements still have enough freedom to slide against the plastic jacket. The jacket must therefore be widened to such an extent that its inner wall does not lie so tightly in the finished clamping bundle in order to prevent the clamping elements from sliding. The exact extent of the expansion required depends on the material of the plastic jacket used, since different plastics can have different shrinkage coefficients. The coefficient of friction or adhesion of the plastic material compared to the material of the tensioning elements also influences the necessary expansion of the plastic jacket. Materials with a very low coefficient of friction or adhesion can be pressed more firmly against the clamping elements than those with a high coefficient. While smaller widenings are possible in the former case, in the second case the plastic sheath has to be sucked out so far that the tensioning elements are relatively loosely enclosed after the subsequent shrinking on of the sheath.

Depending on the area of application for the finished clamping bundle or the desired procedure with regard to a subsequent squeezing of the space between the clamping elements with different substances, it can be provided that the clamping elements are passed through the extruder dry or with a thin layer of a permanently plastic mass .

If the tensioning bundle according to the invention is to be designed such that the spaces between the tensioning elements are to be filled with a permanently plastic mass and this mass is also intended to surround the tensioning elements, according to a further feature the Invention the manufacturing process be characterized in that the clamping elements are guided mutually touching the permanently plastic mass, the mass penetrating into the inner and outer spaces of the clamping elements and surrounding the clamping elements, whereupon the clamping elements together and together with the mass thereon by a Extruder are performed in which the plastic jacket is applied.

In order to ensure that the tensioning elements can slide freely in the plastic jacket, even in the last-described manufacturing process, it can also be provided here that the tensioning bundle with the still heated plastic jacket is guided in a vacuum calibrator, the jacket being produced against the wall in this way by creating a vacuum of the calibrator is sucked, so that during the subsequent cooling and shrinking of the plastic jacket this leaves the clamping elements sufficient space so that the elements can slide in the jacket.

In order to facilitate the guiding of the tensioning elements and to be able to maintain the configuration with the smallest space requirement even when the tensioning bundle is finished, it can be provided according to a further feature of the method that the tensioning elements before, during or after the passage through the extruder or the permanently plastic mass with at least be surrounded by an enveloping element.

The tensioning bundle according to the invention is preferably installed in such a way that the complete tensioning bundle is drawn into or applied to the supporting structure and the tensioning elements are tensioned together, if necessary in groups or individually. The clamping elements can then preferably be anchored individually in anchor bodies, preferably using wedges.

As one of the last process steps when installing the tensioning bundle according to the invention, provision can be made for the tensioning bundle to be coated with a permanently plastic mass, preferably grease, before or after tensioning, or with a hardening mass after tensioning. preferably cement. When using a permanently plastic mass, it is possible, as stated, to compress the tension bundle both before and after tensioning, which is why this option is mainly used where the tensioning elements must be re-tensioned after the first installation, or their pretensioning is reduced if necessary should. The second specified option of pressing with a hardening compound will be used in those cases in which the tension bundle is not subjected to any change in the prestressing forces over the entire service life.

The tension bundle according to the invention is advantageously used for internal or external prestressing arrangements in a concrete structure using a plurality of tension bundles, between which intermediate layers of hard metal are preferably inserted at any deflection points, the ends of the tension bundles being in a common anchor body or in separate ones Anchor bodies are anchored. Between the deflection points, a plurality of clamping bundles are preferably combined to form a group of bundles touching one another.

• Fig.1 das erfindungsgemäße Spannbündel mit im wesentlichen kreisförmigem innerem Querschnitt des Kunststoffmantels,
• Fig.2 das gleiche Spannbündel der Fig.1, jedoch mit einem umhüllenden Element,
• Fig.3 eine Variante, bei welcher der Kunststoffmantel in die äußeren Zwischenräume der Spannelemente eindringt,
• Fig.4 ein Spannbündel mit einem umhüllenden Element der Spannelemente in einer Ausführung entsprechend der Fig.3,
• Fig. 5 bis 15 verschiedene Varianten des erfindungsgemäßen Spannbündels mit unterschiedlichen Anzahlen und Anordnungen der einzelnen Spannelemente,
• Fig. 16 ein erfindungsgemäßes Spannbündel, bei welchem zwei Arten von Spannelementen Verwendung finden,
• Fig. 17 eine Umlenkstelle im Tragwerk mit drei Spannbündeln,
• Fig. 18 einen Schnitt nach der Linie XVIII-XVIII der Fig. 17 und
• Fig. 19 bis 21 drei Variationen der Anordnung von Spannbündeln, z. B. nach den Fig. 9, 12 und 16.

In the following description, two exemplary embodiments of the tension bundle according to the invention will be described in more detail with reference to the accompanying drawings.
Show

• 1 the tension bundle according to the invention with a substantially circular inner cross section of the plastic jacket,
• 2 shows the same tension bundle of FIG. 1, but with an enveloping element,
• 3 shows a variant in which the plastic jacket penetrates into the outer spaces between the clamping elements,
• 4 shows a tensioning bundle with an enveloping element of the tensioning elements in an embodiment corresponding to FIG. 3,
• 5 to 15 different variants of the clamping bundle according to the invention with different numbers and arrangements of the individual clamping elements,
• 16 an inventive tensioning bundle, in which two types of tensioning elements are used,
• 17 a deflection point in the structure with three tension bundles,
• Fig. 18 is a section along the line XVIII-XVIII of Fig. 17 and
• 19 to 21 three variations of the arrangement of clamping bundles, for. 9, 12 and 16.

In the drawings, 1 denotes the individual tensioning elements of the tensioning bundle. This can be, for example, rods, strands or wires. At most, the clamping elements shown can themselves consist of individual sub-elements, which can also be surrounded by a common jacket. The cross-sectional shape of the individual tensioning elements 1 can optionally also differ from the circular shape and can be hexagonal or oval, for example. In addition, the individual tensioning elements 1 can again be constructed from several thinner elements, for example rods, strands or wires. Envelopes of the tensioning elements 1 or groups thereof are also possible, in particular made of plastic or by means of galvanic coating, in order to ensure corrosion protection for each individual element or group of elements.

All clamping elements 1 are surrounded by a common plastic jacket 2. This is preferably made of polyethylene or a similar material. In the illustrated exemplary embodiments, the configuration of the tensioning elements 1 is selected such that a ring of six outer tensioning elements is arranged around a central tensioning element. In this case, the centers of three adjacent clamping elements 1 form an isosceles triangle.

For certain areas of application, however, it may also be necessary to provide configurations deviating from this arrangement, in which the centers of all the clamping elements 1 lie on a straight line or four clamping elements in each case in the corners of a square or a rectangle. For example, only three adjacent tensioning elements 1 could be arranged in such a way that their centers form, for example, an isosceles triangle (FIG. 5). The simplest arrangement results from two clamping elements lying side by side. In this case, the tension bundle forms a flat band (FIG. 6). However, three (FIG. 7), four (FIG. 8) or a plurality of clamping elements can also be arranged in a row lying side by side. Furthermore, two or more rows of clamping elements lying one above the other are also conceivable. For example, a clamping bundle is shown in FIG. 9, in which four clamping elements form a square.

In a corresponding manner, however, two rows of three (FIG. 10), two rows of four (FIG. 11) or two rows of any number of adjacent clamping elements can also be arranged one above the other. Of course, arrangements of three (FIG. 12, FIG. 13) or a plurality of rows of clamping elements lying one above the other are also possible. In principle, there is no upper limit for the number of possible clamping elements 1, so that essentially any number of clamping elements in all possible geometric configurations can be combined to form a clamping bundle according to the invention. For example, several concentric rings of clamping elements are also possible. For example, two wreaths as shown in Fig. 14. However, a triangular arrangement, as in FIG. 5, can also be supplemented by a further outer ring of tensioning elements, so that, for example, the arrangement shown in FIG. 15 results (in FIGS. 5 to 15 only the schematic arrangement of the tensioning elements 1 in FIG Tension bundles are shown without going into the structure according to the invention, of course, the features according to the invention of the sliding mass penetrating between the casing 2 and the tensioning elements 1 or the additional features provided All these versions are available.) A further variant, which is shown in FIG. 16 in the two embodiments according to the invention, would be a mixture of the tensioning elements 1 from one-piece elements such as rods or wires or multi-piece elements, which in turn consist of several individual elements are composed. In any case, the geometry of the tensioning bundle, ie the relative position of the centers of gravity of the tensioning element arrangement and the sheathing remains, even in the case of deflections or the like. receive.

The clamping elements 1 touch each other as shown in Fig.1, i.e. the tensioning elements 1 are arranged as close as possible to one another in the tension bundle. The gaps between the clamping elements are filled by the permanently plastic mass mentioned at the beginning.

The inner wall 3 of the plastic jacket 2 is essentially circular in cross-section. It lies tightly against the outer clamping elements 1. However, this tight contact of the jacket 2 with the tensioning elements 1 takes place only to such an extent that the relative mobility of the tensioning elements 1 relative to the plastic jacket 2, for example in the case of tensioning the tensioning elements, is maintained. The force with which the inner wall 3 of the jacket 2 is pressed against the tensioning elements 1 must not exceed the value at which the coefficient of friction or adhesion between the two components 1, 2 becomes so great that no more displacement is possible. To reduce the said coefficient, a permanently plastic mass can of course also be provided, this mass forming at least one film that has penetrated between the outermost elements 1 and the jacket 2 and has a thickness of at least one or less μm. Between every two of the outermost clamping elements 1 there is an intermediate space 5 which, in the case of an essentially circular outer cross section of the clamping elements, has a gusset outline. These gusset-shaped spaces 5 and the inner spaces 4 between the individual tensioning elements 1 can be filled with the previously mentioned permanently plastic mass.

In the case of differently designed tensioning bundles with respect to the outer contour of the individual tensioning elements 1 or their configuration in the tensioning bundle, it can be provided that the plastic jacket 2 only fits tightly on some of the outermost tensioning elements 1. As an example, only one arrangement of tensioning elements is mentioned here, in which a plurality of concentric rings are arranged around a central element, and in which an essentially hexagonal arrangement finally results. If the inner wall 3 of the plastic jacket 2 is in the shape of an ice sheet, it will only fit snugly against the six clamping elements 1 which are at the greatest distance from the central element. Even with triangular configurations of the clamping elements 1, this applies analogously to the three outermost clamping elements 1, which form the corners of the triangle.

2 shows a variant of the clamping bundle according to the invention described above, the clamping elements 1 now being held in the densest possible arrangement by an enveloping element 7 in which they touch one another. This variant also offers advantages in the manufacture of the tensioning bundle, since the individual tensioning elements 1 already during the passage through the extruder for applying the plastic jacket 2 to the tensioning elements 1 or through the anti-corrosion compound, in order to fill the spaces 4 and 5 with said mass , are kept in the desired configuration. The tensioning elements 1 therefore do not have to be subsequently compressed by additional devices in order to obtain the desired tight arrangement or to press excess lubricant out of the tensioning bundle, but rather the tensioning elements 1 with the mass located thereon can be introduced directly into the extruder.

Another variant is shown in FIG. 3. Here, the inner wall 3 of the plastic jacket 2 also adjoins the outermost clamping elements 1 at any point along the circumference. However, the plastic jacket 2 fills at least part of the mostly gusset-shaped gaps that are delimited on the outside by the outermost clamping elements by projections 6 at least partially. However, since the tensioning elements 1 lie close together, the material of the plastic jacket 2 cannot penetrate between the outermost tensioning elements 1, so that all the interstices 4 within the outermost ring of tensioning elements 1 continue to be filled only by the sliding compound. Of course, an enveloping element 7 can also be provided in this variant, as shown in FIG. 4.

To produce the above-described tension bundle or the above-described embodiments, the procedure can advantageously be such that the tensioning elements 1 are guided through an extruder in which the plastic jacket 2 is applied so as to touch one another. The use of extruders to apply jackets is a common technique. However, in order to achieve or achieve a sufficient degree of freedom for the tensioning elements 1 with respect to the inner wall 3 of the plastic jacket, that the plastic jacket 2 with its inner wall 3 does not lie so tightly against the tensioning elements 1 in order to prevent the relative displacement of these components against one another , the next step in the process is to guide the tension bundle with the still heated plastic jacket into a vacuum calibrator. In this device, the jacket 2 is sucked onto the wall of the calibrator by creating a vacuum, so that during the subsequent cooling and shrinking of the plastic jacket, the clamping elements leave enough space for the elements 1 to slide in the jacket 2.

When carried out by the extruder, the clamping elements can, if desired, be surrounded dry or by means of any application method with a thin layer of a permanently plastic mass. For example, such a mass could be provided by spraying on each individual clamping element or the final configuration of the clamping elements. According to a modification of the manufacturing method according to the invention, however, it is also possible to proceed in a manner in which the clamping elements are guided through the permanently plastic mass in contact with one another, the mass penetrating into the inner and outer spaces between the clamping elements 1. Then the clamping elements 1 are passed together with the mass located thereon through an extruder in which the plastic jacket is applied. The gusset-shaped interstices are first filled with the permanently plastic mass, and in the extruder the extrusion of the plastic casing 2 can then optionally be controlled in such a way that either the outer interstices only remain filled with the sliding compound, or that the material of the plastic casing 2 also has at least partial projections 6 forms, which at least partially fills the outer spaces. Of course, this possibility also exists for the method described first.

In the second case, the mass penetrates between the outermost clamping elements 1 and the inner wall 3 of the casing 2, so that the clamping elements 1 lie slidably in the casing 2 and are covered on the outside by at least one film of the sliding compound.

In order to keep the tensioning elements 1 in a configuration, especially during the manufacture of the tensioning bundle according to the invention, in which the individual elements 1 touch each other, it can advantageously be provided that the tensioning elements 1 already during the passage through the extruder in the first manufacturing process or in second case are held together by the permanently plastic mass by at least one enveloping element 7. For this purpose, for example, a film or a mesh made of plastic or steel mesh can be used, which, however, is also attached during the passage of the mass or the extruder or after the tensioning bundle has passed through the mass.

The given as an example of such an element 7 network has the advantage that it prevents the penetration of the sliding mass in the Gaps between the clamping elements are not hindered, and even have a certain restraining effect for that portion of the mass which fills the outer gaps 5. As can be seen from Figure 4, the enveloping element 7 in its design as a net-like structure allows the projections 6 of the plastic jacket 2 to penetrate through the element 7 and thereby establish a firm connection between the enveloping element 7 and the jacket 2, while the tensioning elements 1 remain slidable. In this embodiment, the element 7 also takes on the function of a stabilizing “reinforcement” of the plastic jacket 2.

When installing the clamping bundle, the complete and factory-made, possibly already cut to length bundle can be pulled in, whereupon the clamping elements are clamped together to the desired value using a clamping press. The parallel bundle has the additional advantage that the tensioning elements can also be tensioned in groups or individually, since due to the construction according to the invention the tensioning elements 1 are easily movable relative to one another and relative to the plastic jacket 2. The anchoring in anchor bodies is preferably carried out separately using wedges for each clamping element. It is possible to anchor several tension bundles in a common anchor body or in individual anchor bodies.

The tension bundles can also be summarized in various configurations, such as. B. FIGS. 19 to 21 show in which square tension bundles, such as those shown in FIGS. 9, 12 and 16, are selected, the individual bundle being designated by 10.

At the deflection points in the structure, 10 hard intermediate layers, e.g. B. made of sheet metal or the like. In the deflection point shown in FIGS. 17 and 18, 11 denotes a deflection saddle on which three band-shaped tension bundles 10, each consisting of four tensioning elements, lie, between which one hard intermediate layer 12 is arranged. Between the possible deflection points, the tension bundles are preferably combined into a group of bundles touching one another.

Of course, various design changes can be made within the scope of the invention. So there is the possibility to use the clamping elements dry or to only cover them with a hint of permanently plastic mass, so that the sliding ability of the clamping elements within the plastic jacket is guaranteed. In the usual way, the space between the tensioning elements or between the tensioning elements and the inner wall of the plastic jacket can be pressed with a hardening mass, preferably cement, after the tensioning elements have been tensioned. In this case, a further change in the pretension is prevented by the hardening of the mass and the firm embedding of the tensioning elements in it. If, on the other hand, it is provided or desired that the pretensioning of the tensioning bundle should also be changed after the first installation and the first clamping, it can be provided as an alternative to the first-mentioned possibility that the tensioning bundle before or after tensioning with a permanently plastic mass, preferably grease, to squeeze.

Claims (20)

Tensioning bundles for prestressed structures made of concrete or the like, consisting of a plurality of tensioning elements (1) running parallel to one another and touching one another, such as rods, strands or wires, which are made of at least one common plastic sheath (2), preferably made of polyethylene or the like. are encased, characterized in that the clamping elements (1) are touchingly connected to one another in an ordered configuration and are closely enclosed by the plastic jacket (2), the centers of adjacent clamping elements (1) at the corners of isosceles triangles or squares or rectangles or lie on a straight line. Tensioning bundle according to claim 1, characterized in that the spaces (4, 5) between the tensioning elements (1) are filled with one another by a permanently plastic mass and that the mass has also penetrated between the tensioning elements (1) and the plastic jacket (2), so that the tensioning elements (1) can slide in the plastic jacket (2). Clamping bundle according to claim 2, characterized in that sliding masses are used as the permanently plastic mass, e.g. B. environmentally, in particular water-compatible fats, preferably based on silicone or mineral oil. Tensioning bundle according to claim 3, characterized in that natural products, e.g. B. rapeseed can be used. Clamping bundle according to claim 2, characterized in that the permanently plastic mass also serves as an anti-corrosion compound. Tensioning bundle according to claim 1, characterized in that the tensioning elements (1) are held together by at least one enveloping element (7), for example a film or a net made of plastic or steel. Tensioning bundle according to claim 1, characterized in that the tensioning elements (1), individually or in groups, are protected against corrosion by a surface coating, for example by a plastic covering or a galvanic coating. Tensioning bundle according to claim 1, characterized in that the plastic jacket (2) at least partially fills at least some of the mostly gusset-shaped spaces (5) delimited on the outside by the outermost tensioning elements (1) by means of projections (6). Tension bundle according to claim 1, characterized in that for the plastic jacket (2) materials with the lowest possible friction or. Adhesion coefficients compared to the material of the clamping elements (1) are selected. A method for producing a tensioning bundle according to claim 1, characterized in that the tensioning elements (1) are guided in contact with one another through an extruder in which the plastic jacket (2) is applied, the tensioning bundle with the still heated plastic jacket in a vacuum calibrator is performed, whereby the jacket (2) is sucked onto the wall of the calibrator by generating a vacuum, so that during the subsequent cooling and shrinking of the plastic jacket (2) it leaves the clamping elements (1) sufficient space so that the elements (1) in Can slide (2). A method according to claim 10, characterized in that the clamping elements (1) are passed through the extruder dry or surrounded by a thin layer of a permanently plastic mass. A process for producing a tensioning bundle according to claim 2, characterized in that the tensioning elements (1) are guided in contact with one another through the permanently plastic mass, the mass penetrating into the spaces (4, 5) and surrounding the tensioning elements (1), whereupon the Clamping elements (1), together with the mass located thereon, are passed through an extruder in which the plastic jacket (2) is applied. A method according to claim 12, characterized in that the tension bundle is then guided with the still heated plastic jacket into a vacuum calibrator, the jacket (2) being sucked onto the wall of the calibrator by generating a vacuum, so that during the subsequent cooling and shrinking of the plastic jacket (2) this leaves the clamping elements (1) enough space so that the elements (1) can slide in the jacket (2). Method according to claim 10 or 12, characterized in that the tensioning elements (1) are surrounded by at least one enveloping element (7) before, during or after the passage through the extruder or the permanently plastic mass. A method for installing a tensioning bundle according to claim 1, characterized in that the complete tensioning bundle is drawn into or applied to the supporting structure and the tensioning elements (1) are tensioned together, if necessary in groups or individually. A method according to claim 15, characterized in that the clamping elements (1) are anchored individually, preferably using wedges, in anchor bodies. A method according to claim 15, characterized in that several tension bundles are anchored in a common anchor body. A method according to claim 15, characterized in that the tensioning bundle is pressed with a permanently plastic mass, preferably fat, or after tensioning with a hardening mass, preferably cement. Use of the tension bundle according to at least one of claims 1 to 9 for inner or outer prestressing arrangements in a concrete structure using a plurality of tension bundles, between which intermediate layers of hard material are preferably inserted at any deflection points, the ends of the tension bundles in a common anchor body or are anchored in separate anchor bodies. Use of tensioning bundles according to claim 19, characterized in that several tensioning bundles are combined into a group of bundles touching one another between the deflection points.

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