EP1079040B1 - Corrosion protected free tension member, in particular external tendon for prestressed concrete - Google Patents

Description

Technical field

The invention relates to a corrosion-protected free tension member, primarily a external tendon for prestressed concrete, from a bundle from within one Piping arranged tension elements, such as steel rods, wires or strands according to the preamble of claim 1.

State of the art

In the construction of structures made of prestressed concrete, especially in Bridge structures, one knows the prestressing with and without bond. Prestressing with bond is usually considered as prestressing with subsequent Composite, the tendons within the concrete cross-section lie and after tensioning by injecting cement paste in conjunction with brought to the building. With pre-tensioning without bond, they are Tendons outside the concrete cross section, however, are opposite to that Supported structure. These tendons, also called external tendons can be checked, retightened and checked at any time if necessary, also be replaced. External tendons are often used also used for the renovation or subsequent reinforcement of bridges.

It is often necessary, e.g. in the manufacture of bridge superstructures in so-called cycle shifting method, to an already anchored tendon Superstructure section another tendon for a subsequent section to couple and connect both so that they are together by can be stretched towards one end. In this context it is known, at least one of the anchor devices of the tendon as a coupling point train (DE 38 01 451 C2). In this is the usual one against one on the building adjacent abutment body supported armature plate as a coupling plate configured; in addition to holes for anchoring the tension elements of the incoming tension member part also holes for anchoring the tension elements of the outgoing tension member part. In this known tendon are the arriving tension elements in radial distribution in the central area of the Anchor plate anchored and the outgoing tension elements in a circular shape Arrangement outside the same. As a result of this spread, it is necessary to outgoing traction elements with redirection to the normal distance outdoors Area of the tendon.

In this deflection area, the piping of this tendon consists of two Pipe sections that are used to spread the outgoing tension elements The armature disk has different diameters following each. This Pipe sections are at their front ends with radially extending Provide flanges and by means of this both with the anchor device and with each other and with the piping in the normal area of the tendon screwed.

Usually used to achieve corrosion protection and also for fixation the order of the tension elements within the piping into the cavity a hardening material between the tension elements and the piping, e.g. Cement paste, injected.

Normally, the individual sections of such a tendon are each excited from its end anchorage. Due to manufacturing tolerances concerned buildings and changes in shape or movements of the Tendons in relation to the structure when tensioning can be on the Coupling point Angular deviations from the arithmetic axis of the tendon occur. During the individual tension elements such angular deviations Can join without major problems, this is in terms of piping not the case.

Since the individual sections of tendons coupled in this way normally have the same clamping force, axial movements occur when clamping The armature disk is not open in the coupling area. In many cases it is necessary to retension such a tendon to avoid a loss Compensate elasticity due to shrinkage, creep, etc. The possibility of retensioning must be done not only before injecting cement paste, but often even after injecting, especially after it has hardened, be given, albeit often to a lesser extent.

Object of the invention

Against this background, the invention is based on the object Possibility to create one, possibly also in the injected state retensionable, tendon of the type specified in the range Coupling point to be able to record angle deviations without damage to the Piping must fear, especially without the reliability of the Endanger corrosion protection.

Presentation of the invention

According to the invention, this object is achieved by a corrosion-protected free Tension member with the features of claim 1 and claim 7 solved.

Advantageous further developments result from the subclaims.

The basic idea of the invention is in the area of the Anchoring of the incoming tendon, subsequent piping of the outgoing tendon, i.e. where there are changes in angle in the Tendon axis can occur in the piping itself articulated Provide liaison points while maintaining that for a later Inject with hardening material required tightness of the piping in allow changes in angle corresponding to the extent. For this be proposed two solutions according to the invention. For one, at the Junction of two sections of piping with different

Diameter in the context of a frictional connection some play Admission of transverse movements allowed and can be sealing at the same time as well as elastically or plastically deformable components are interposed; on the other hand, a dome-like design of the end of one Piping section within a cylindrical outer support tube joint-like twisting possibility can be created.

Retensionability, even when injected, is low Tensioning paths achieved in a simple manner by the fact that the tensioning path in the area of the anchor device by means of washers or the like is bridged, with larger tensioning paths ensures that the piping inside the outer support pipe is telescopically displaceable.

Description of the drawing

Fig. 1

einen Längsschnitt durch den Kopplungsbereich eines gespannten, noch nicht injizierten Spanngliedteils, der an einen gespannten und injizierten Spanngliedteil angeschlossen ist,

Fig. 1a

ein Detail aus Fig. 1 in größerem Maßstab,

Fig. 2

einen der Fig. 1 entsprechenden Längsschnitt vor und nach dem Nachspannen bei einem kurzen Nachspannweg,

Fig. 3

einen Längsschnitt durch den Kopplungsbereich eines gespannten und injizierten Spannglieds für einen längeren Nachspannweg,

Fig. 4

einen der Fig. 3 entsprechenden Längsschnitt vor und nach dem Nachspannen,

Fig. 5

einen Längsschnitt durch eine andere Ausführungsform der Erfindung und

Fig. 6

einen entsprechenden Längsschnitt vor und nach dem Nachspannen.

Further features and advantageous properties of the invention result from the following description of the drawings. It shows

Fig. 1

2 shows a longitudinal section through the coupling area of a tensioned, not yet injected tendon part which is connected to a tensioned and injected tendon part,

Fig. 1a

2 shows a detail from FIG. 1 on a larger scale,

Fig. 2

1 shows a longitudinal section corresponding to FIG. 1 before and after re-tensioning with a short re-tensioning path,

Fig. 3

2 shows a longitudinal section through the coupling area of a tensioned and injected tendon for a longer tensioning path,

Fig. 4

3 shows a longitudinal section corresponding to FIG. 3 before and after retensioning,

Fig. 5

a longitudinal section through another embodiment of the invention and

Fig. 6

a corresponding longitudinal section before and after retensioning.

In Fig. 1, the anchoring area designed as a coupling point is one Tendon 1 shown for prestressed concrete without bond in longitudinal section. The Tendon 1 consists of a bundle of tension elements, e.g. Strands 2, off Steel wires, which are arranged together in a piping 3.

The tendon 1 is supported by an anchor device 4 as Intermediate anchoring compared to a building part 5, the one Construction phase, e.g. a bridge cross member, a pilaster strip or the like can limit; it continues beyond the anchor device 4 to one next, in an analogous manner designed anchor device or one End anchorage. The one on the right in front of the anchor device 4 lying part of the entire tendon is called "incoming" part 1a, the one in which Representation on the left, part lying behind the anchor device 4 as a "leaving" part 1b designated.

The piping 3 of the tendon 1 extends in the area of the incoming part 1a into an anchor body 6 made of cast iron, to which an abutment body is flange-like 7 connects. Compared to this abutment body 7 is supported Coupling disc 8, in the central region of which there are bores in which the Strand 2a in a manner known per se, e.g. are anchored by ring wedges.

In the coupling plate 8 are outside the anchorage of the incoming strands 2a in a circular manner in a corresponding manner outgoing strands anchored 2b. These are the actual ones Coupling point adjacent area by redirecting back to the distance returned, in which they also in the area of the outgoing tendon part 1b lie.

On the coupling plate 8 is on the side of the outgoing part 1b Tension member on a spacer 9, for example made of plastic; he has the Task, in this sensitive area of the exit of the strands 2b from the Coupling disc 8 Avoid discontinuities in the course. The spacer 9 is for this purpose firmly connected to the coupling plate 8.

Due to manufacturing tolerances of the structure, also due to Changes in shape or movements of the tendons in relation to the structure when clamping, can in the area of such a coupling point Angular deviations from the arithmetic axis of the tendon occur. Such a deviation by the angle α between the axis of the incoming tendon 2a and the axis of the outgoing tendon 2b is indicated in Fig. 1. To record such an angular deviation additional measures are required in the piping area; a The solution for this is shown in FIGS. 1 to 4, another solution in FIGS. 5 and 6.

In the coupling point shown in Fig. 1, the piping is in the area of Coupling point from a cylindrical deflection tube 10, which at its the Anchor device 4 facing end by means of a flange 11 and Screw connection 12 on the anchor device 4, in the example shown one of the abutment body 7 surrounding ring plate 13 is attached, which in the Building part 5 is concreted. The connection between the so rigid the anchor device 4 connected deflection pipe 10 and the piping 3 of the Outgoing tendon part 1b subjected to angle changes is shown in FIG shown on a larger scale.

As shown in FIG. 1 a, the deflection tube 10 has the anchor device 4 on it facing away from the outer end an inwardly facing flange 14. Die Piping 3, which in the normal range usually consists of a plastic pipe, e.g. one PE pipe, is over a design-related transition area 15, the also comprises a plastic tube, connected to a tube section 16 which, enclosing the bundle of strands extends into the deflection tube 10. This Pipe section 16, which is also made of plastic, has an outside facing flange 17, which advantageously has the same thickness as the Flange 14 of the deflecting tube 10 and lies in the same radial plane as this. These two flanges 14 and 17 lie between an outer flange ring 18th and an inner flange ring 19 which is interposed by an annular Element 20 made of elastic material such as rubber, plastic or the like clamped by screws 21 and thus frictionally connected are.

In the illustrated embodiment, the inner flange ring 19 is at the same time connected to a tubular deflection fitting 22 on which the strands 2b with the interposition of the pipe section 16 and the radial Absorbs expansion forces when tensioning the strands. The pipe section 16 is used for Tensioning the strands 2b as an intermediate layer to make a metal contact between the Avoid strands and the deflection fitting 22. In an analogous way it can Deflection fitting 22 also outside the deflection pipe in the area of outgoing tendon part 1b. In any case, the flange ring remains 19 in the position shown.

As can also be seen in FIG. 1 a, the clear diameter of the end face Flange 14 of the deflection tube 10 and the diameter of the flange rings 18th and 19 and the radial distance between the screws 21 are chosen so that in this Area transverse displacements can be recorded. Through this Training has the deflection fitting 22 abutting the strands 2b Possibility of automatically stretching the strands 2b into the corresponding one Position, possibly at a deflection angle α (Fig. 1) to the incoming Set up part 1a of the tendon before tightening the screw 21 becomes. The interposed elastic intermediate layer 20 also does not provide parallel position of the flange rings 18 and 19 a perfect seal this Junction safe.

The same effect can also be achieved if the flange 14 and the Flange ring 19 overlap and the screw 21 is larger Bores in the flange 14 would extend, which are covered by disks become.

If such a tension member results in the need for retensioning, then the screw connection 12 of the deflection tube 10 on the ring plate 13 concreted in can be loosened. The required tensioning path in the size Δl ₁ can be bridged after the re-tensioning by divided washers 23 which are penetrated by the screw 12 with correspondingly longer screws. Fig. 2 shows the state after tensioning the tendon in the upper representation, the state after tensioning over a short tensioning path in the lower representation, in each case not yet injected state of the outgoing tendon part 1b and without taking into account a deflection angle α.

The embodiment of the invention shown in FIGS. 3 and 4 corresponds with regard to the connection between the fixed part of the piping and any changes in shape subject part, but allows a longer tension path. To this The piping in the deflection area consists of two telescopic ends tubes that can be moved and sealed against each other, namely an - inner - deflection tube 10a and an - outer - support tube 24, which in turn has a flange 25 and a screw connection 26 with the Concreted ring plate 13 is screwed.

The tendon 1 is shown in Figures 3 and 4 in the injected state, i.e. both the cavity between the incoming strands 2a and the piping, as well as the cavities within the deflection tube 10a and within the Piping 3 of the outgoing tendon part 1b is with cement mortar 27 filled.

The telescopic guidance of the deflection tube 10 within the support tube 24 enables the tensioning element to be re-tensioned even with longer tensioning paths. This is shown in Fig. 4; the upper region of the illustration shows the tensioned and injected state of the tendon as in FIG. 3, the lower half the state after the tensioning of the tendon 1 in its outgoing part 1 b by the tensioning path ΔI ₂ . In this state, the cavity 28 created by re-tensioning between the anchoring area 4 and the coupling disk 8 is again pressed out with cement mortar.

To prevent when tensioning or re-tensioning the tendon 1 Deflection tube 10a are pulled out of the support tube 24 approximately prematurely could, this can be done at its inner end by bolts 29 or the like be fixed relative to the coupling plate 8.

Another option for taking a deflection angle α under Maintaining the retensionability of a tendon is shown in FIGS. 5 and 6 shown. 5 corresponds with regard to the State of construction of that of Fig. 3, i.e. both the cavity between the incoming strands 2a and the piping, as well as the cavities within the piping of the outgoing tendon part 1b are with cement paste filled.

While in this embodiment the cylindrical support tube 24 is approximately in the same way via a flange 25 and screws 26 on the anchor device, is attached to the concreted ring plate 13, the deflection pipe 30 follows is designed as a casting, geometrically in its outer contour the course of the outgoing strands 2b in the deflection area between the coupling plate 8 and normal range of the tendon. The deflection tube 30, which is in its outer Area via a flange 31 and a screw connection 32 with the piping 3 is connected, is in its inner region within the support tube 24 its outer circumference is approximately dome-shaped (33). This ensures that the inner end of the deflecting tube 30 should be when tightening Squeezes occur, can rotate in an articulated manner within the support tube 24. Around to facilitate this rotary movement, a corresponding dome-like Training also provided on the inside of the deflection tube 33 and can Coupling plate 8 be spherical on its outer circumference 34.

Analogously to FIGS. 1 and 2, which show the tension member in the injected state, FIG. 6 also shows the retensioning process for this embodiment, the tension member in the upper part of the illustration in the tensioned and injected state, in the lower part in one around the tensioning path Δl ₃ post-tensioned state is shown. It can be seen how the deflection tube 30 can also be displaced within the support tube 24 in this embodiment. In order to ensure the tightness of the coupling point for the injection of cement mortar, it is arranged between the outer circumference of the deflection pipe, in particular in its area adjacent to the inner wall of the support pipe 24, and the latter sealing material. The cavity created by the tensioning by the tensioning path Δl ₃ within the support tube 24 following the anchoring is again grouted with cement mortar 28 here.

To properly loosen the grouting material from the anchor device to achieve this can be provided with a release agent before pressing his.

Claims (10)

1. A corrosion-protected free tension member, especially an external tendon for prestressed concrete, comprising a bundle of tension elements, such as steel rods, wires or strands, disposed inside a casing, having anchoring devices provided at least its ends, wherein the tension member comprises at least two parts in each case butt-jointed at an anchoring device in the form of a coupling point, in which a preferably circular anchoring disc bearing against an abutment member has, in addition to bores for anchoring the tension elements of the incoming tension member part, also bores for anchoring the tension elements of the outgoing tension member part, and in which the casing of the outgoing tension member part in the zone adjoining the anchoring device comprises at least two portions which are releasably joined together and which are each of different diameter conforming to the spreading of the tension elements of the outgoing tension member part, characterised in that to accommodate angular rotations and/or transverse displacements between the axes of the incoming tension member part (1a) and of the outgoing tension member part (1b) the portions (10 and 3,15,16) of the casing of the outgoing tension member part are joined together by frictional resistance generated as a result of clamping between opposing flanges (14,17) protruding radially from the portions and flange rings (18,19) enclosing the latter between them, with the interposition of a sealing elastically and/or plastically deformable component, wherein to generate the frictional resistance a bolted connection (21) with bolts passing through the flange rings (18,19) is provided, the bolts of which have sufficient clearance between the flanges (14,17) to ensure displacements transversely to the longitudinal axis of the tension member (1) .
2. A tension member according to Claim 1, characterised in that an annular elastic intermediate layer (20) consisting of rubber, plastics or the like is disposed between the flange rings (18,19), especially on the inside.
3. A tension member according to Claim 1 or 2, characterised in that the portion of the casing nearest the anchoring device (4) is in the form of a deflecting tube (10) and is connected rigidly but releasably to the structural member (5).
4. A tension member according to Claim 1 or 2, characterised in that the portion of the casing nearest the anchoring device (4) is in the form of a deflecting tube (10a) and can slide telescopically in a supporting tube (24) which, in turn, is connected rigidly to the structural member (5).
5. A tension member according to Claim 4, characterised in that the space between the outer surface of the deflecting tube (10a) and the inner wall of the supporting tube (24) is sealed.
6. A tension member according to any one of Claims 1 to 5, in which the cavity between the individual elements and the casing is filled with a material (27,28) which sets, for example cement mortar, characterised in that the surface of the anchoring device (4) is coated with a release agent.
7. A corrosion-protected free tension member, especially an external tendon for prestressed concrete, comprising a bundle of tension elements, such as steel rods, wires or strands, disposed inside a casing, having anchoring devices provided at least its ends, wherein the tension member comprises at least two parts in each case butt-jointed at an anchoring device in the form of a coupling point, in which a preferably circular anchoring disc bearing against an abutment member has, in addition to bores for anchoring the tension elements of the incoming tension member part, also bores for anchoring the tension elements of the outgoing tension member part, and in which the casing of the outgoing tension member part in the zone adjoining the anchoring device comprises at least two portions which are releasably joined together and which are each of different diameter conforming to the spreading of the tension elements of the outgoing tension member part, characterised in that to accommodate angular rotations and/or transverse displacements between the axes of the incoming tension member part (1a) and of the outgoing tension member part (1b) the portion of the casing nearest the anchoring device (4) is in the form of a deflecting tube (30) and is displaceable in a supporting tube (24) connected rigidly to the structural member (5), and in that the end of the portion (30) facing the anchoring device (4) has a spherical-type bulge (33) which is adjacent the cylindrical inner wall of the supporting tube (24).
8. A tension member according to Claim 7, characterised in that the coupling disc (8) is circular and for co-operation with the spherical-type bulge (33) of the deflecting tube (30) is convexly shaped on its outer periphery.
9. A tension member according to Claim 7 or 8, characterised in that the space between the outer surface of the deflecting tube (30) and the inner wall of the supporting tube (24) is filled in a sealed manner with a corrosion-protecting material.
10. A tension member according to any one of Claims 7 to 9, characterised in that the deflecting tube (30) consists of a one-piece component, for example of cast iron.

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