DE19539748A1 - Stressed concrete structural part - Google Patents

Abstract

The ready-made concrete structural part (1) has a circular arc-shaped cross-section and can be used for production of a circular container or the cladding of a tunnel. On its face sides (2) for abutting connection with correspondingly formed parts, channels (3) formed as hollow tubes are provided for insertion of stress components (4). The channels run in the area of the face sides in the longitudinal central plane of the structural part, where a niche (5) can be provided for insertion of an anchor component (6) and the fitment of a tension press (7) with a curved tubular extension (8), in permanent curvature out of the longitudinal central axis to the inside of the structural part.

Description

The invention relates to a prestressed concrete component, in particular a component with a curved wall, e.g. B. concrete container, Concrete pipe, tunnel or tunnel lining or the like, with at least one tendon, according to the preamble of Claim 1.

In some structures made of prestressed concrete, the tendons are relatively close under an outer surface of the concerned building parallel to this and in Anchored niches, mostly after tensioning the Tendons are concreted. To such structures include in particular containers with a circular cross-section, Concrete pipes or tunnel and gallery linings, in the wall of which tendons arranged in a ring are provided are at one or more points on the circumference be anchored. These anchorages can either be fixed or be "flying". I.e. it is one at a time with appropriately trained, directed against each other Holes provided anchor element in which the Individual elements of one end of the tendon and the other ends are anchored in tension.

Especially for structures with a circular cross-section, especially with containers, leads the relatively large Length of the niches that guide the tendons the size of the niche and the position of the anchor element subordinate. The tendons over the length of the Niches must be exposed, i.e. straight, must therefore start the ends of the niche into the curvature of the building wall can be traced back only by using curvatures Minimum radii can be reached, which in turn too Loss of friction when clamping.

To the length of the niches in the respective outer surface of the  Structure that corresponds to the length of the prestressing press plus the length of the expansion path of the tendons must be kept as short as possible, it is known between the anchor body and the press Arrange so-called deflection chair (DE 23 58 256 C3). This Deflecting chair has a number of curved guides for the individual elements of the tendon, along which these be led out of the niche so that the clamping press outside the niche and at an angle to the tendon axis can be applied. In this reversing chair they have to Individual elements of the tendon are guided individually because otherwise they would wedge against each other when tensioning. This reversing chair is therefore very complicated and expensive built up; it must consist of several parts on the Place of use assembled and again after use be removed.

To avoid the disadvantages of this chair, it is already known, for clamping the individual elements a single jack with a curved, tubular Front part to use (DE 82 27 569 U1). Because here every Single element is recorded separately, the fixed Anchors between the tensionable anchors be arranged, resulting in a space-saving arrangement and thus leads to smaller anchor elements. To one to achieve uniform force distribution in the anchor element, are therefore in the known anchor element for the Anchoring the ends of the lead through this Individual elements of a bundle tendon the holes for the Implementation of the firmly anchored and the exciting anchored ends mixed.

Around the ends of two single tendons or one Tension and anchor the ring tendon against each other can, an anchor element is also known in which the ends of the individual elements along curved surfaces through this  are passed through (US-A 4 212 558). If those curved surfaces in the anchor element so to each other are arranged that the axes of the ends of the single element at their opposite entry points align, arises when a clamping force is applied the single element the anchor element itself in one Inclined position representing the state of equilibrium.

Against this background, the object of the invention based on finding a way to size, especially the length of the for tensioning and anchoring Tendons, especially ring tendons in one circular wall, required niches as little as possible hold.

According to the invention, this object is achieved by the Features specified claim 1 solved.

Advantageous further developments result from the Subclaims.

The basic idea of the invention is the design the clamping niches to be provided in the relevant component to divide into a niche according to their function only the placement of the anchor element with the Anchoring the ring tendon is used, and at least one elongated recess for inserting the tendons or for tensioning by attaching the front part of the Clamping press is used. The possible minimization of the Size of the actual niche in which the tendons lying freely, up to a complete waiver of one Niche when concreting the anchor element from the start, leads to a more harmonious guidance of the tendons. There in this way the minimum radii of curvature for the geometry of the building are available, can also be used smaller radii than previously biased. Doing there  there are two basic, depending on the design of the anchor element Possibilities.

In the case of one consisting of at least two individual elements Tendons, especially a bundle tendon, are Individual elements in the area of the anchor element parallel and so led that on this the tensionable anchorages in the central and fixed anchorages in the outer area lie. This creates the prerequisite for one to Accommodation of the anchor element suitable, for. B. square Niche only on one side in the middle in a slim Recess needs to be continued gradually can become flatter, since only the tubular curved one is in it Press approach needs to be accommodated. Of course, it is also possible the other way round, the fixed ones Anchoring in the central and the tensionable anchoring to be arranged in the marginal areas, but then two requires elongated recesses.

In the case of a single element Ring tendon, the ends of which are anchored in an anchor element that balances itself is sufficient either one the niche to accommodate the anchor element Recess obliquely to the tendon axis or can also be two opposite one another Recesses are provided when the ring tendon on both ends should be tensioned.

Advantageous further developments result from the Description below in the drawings illustrated embodiments. It shows

Fig. 1 shows a first embodiment of the invention in a cross section through a circular tank wall,

Fig. 2 is an interior view of the illustration of FIG. 1,

Fig. 3 shows a second embodiment in cross-section,

Fig. 4 is an interior view of the representation according to Fig. 3,

Fig. 5 shows a third embodiment in cross-section,

Fig. 6 is an interior view of the illustration of FIG. 5, the

FIGS. 7 and 8 inside views of two other embodiments of the invention,

Fig. 9 shows a further embodiment, again in cross-section by a circular-shaped component,

Fig. 10 is an interior view of the representation of FIG. 9 and

Fig. 11 in different views and on an enlarged scale an anchor element for use according to the invention.

In Figs. 1 and 2, a first embodiment is shown of a device according to the invention schematically. Fig. 1 shows in cross section an arcuate concrete prefabricated component 1 , which in this form can be used, for example, for the production of a circular container or can also be used as tubbing for a tunnel lining. The prefabricated component 1 is designed on its end faces 2 in a manner known per se for butt connection with appropriately trained prefabricated components and z. B. in the form of concreted-in cladding tubes with tensioning channels 3 for inserting tendons 4 . The clamping channels 3 run in the normal area, as can be seen in FIG. 1 in the area of the end faces 2 , in the longitudinal center plane of the prefabricated component 1 ; they are in the central region of the prefabricated component 1 , where a niche 5 is provided for accommodating an anchor element 6 and for attaching a tensioning press 7 with a curved tubular extension 8 , in a constant curvature out of the longitudinal central axis to the inside of the component 1 and only run in the area of niche 5 straight.

As can be seen above all in Fig. 2, which represents an interior view of the component 1 , each ring tendon 4 consists of two individual elements 4 a, 4 b, which are guided in separate tensioning channels 3 a, 3 b and whose ends in the recess 5 in the Anchor element 6 are anchored across one another. Ring tendons of this type and design are provided in different levels of the container according to the respective load.

For this purpose, the anchor element 6 is provided with transverse bores through which the ends of the individual elements 4 a and 4 b can be inserted. The holes are flared in opposite directions to accommodate the usual ring wedges for anchoring the individual elements, usually steel wire strands. The arrangement is such that the ends of the tendons 4 a, 4 b, which are firmly anchored in the anchor element 6 , are on the outside, while the ends at which the tendon is tensioned by applying the tensioning press 7 are concentrated in the inner region .

In order to be able to apply the tensioning press 7 to the anchor element 6 for tensioning the ends of the tendons 4 a, 4 b, the niche 5 , which, as can be seen in FIG. 2, corresponds in size and outline to the anchor element 6 in the central region on one side into a recess 9 which extends between the approximately parallel, firmly anchored ends of the individual elements 4 a and 4 b with parallel side edges in this area and which runs out towards the end 10 of the press attachment part 8 in accordance with the curved shape. In this way, for the size of the niche 5 and for the anchoring parts to be accommodated there, a size oriented to the dimensions of the anchor element 6 and possibly an expected expansion path is sufficient, while the space required for attaching the press 7 , which of course also for inserting the tendons 4 can be used, is separated from it. As a result, the area in which the individual elements 4 a, 4 b have to be guided is reduced to a very short length, which, as the cross-section according to FIG. 1 clearly shows, can be converted into the curvature of the container wall itself in a constant curvature .

As can also be seen in FIG. 2, it may be useful to arrange the recesses 9 on successive tendons 4 on the opposite side of the niche 5 .

Following the basic representations of the invention in FIGS. 1 and 2, FIGS. 3 to 8 each show alternative embodiments on a larger scale, which can be chosen according to the special requirements. Here, FIGS. 3 and 4 and 5 and 6 respectively show in section and plan view of the anchoring and clamping possibilities for a clamping member 14, consisting of a bundle of individual elements, here steel wire strands.

The illustrations of FIGS. 5 and 6 correspond in principle to those of Figs. 1 and 2, that the recess 15 in the concrete component 11, which is shown with a flat surface 12 for simplicity, is made on one side on the right in the drawing page in a recess 19 continues. In this embodiment, the individual elements of the tensioning member 14 in the direction of arrow 20 are so inserted from right to left in the clamping channel 13; the recess 19 with the depth reducing from the recess 15 to the surface 12 serves to guide the individual elements.

If, as is assumed here, the tendon 14 is a ring tendon, the front end of the tendon in the insertion direction after passing through the tensioning channel 13 appears again in the area on the right in the illustration, in order to be divided into two groups 14 a, 14 b to be spread out by individual elements. In order to enable this spreading, a further niche 21 must be arranged in its area, in which the incoming individual elements are each assigned to the individual groups 14 a, 14 b. While the groups 14 a, 14 b are firmly anchored in the outer regions of the anchor element 16 , the individual elements are anchored at the other end of the tendon 14 in the central region of the anchor element 16 . The individual elements protrude here as a whole bundle 14 c beyond the anchor element 16 in order to be gripped and tensioned by the tensioning press 17 in the area of the press attachment part 18 after deflection. Just like the niche 15 , the niche 21 is of course subsequently filled with hardening material, in particular concrete.

If the niche 21 for spreading the individual elements of the bundle tendon in two groups is to be avoided, it is also possible, as shown in FIGS. 3 and 4, in addition to the recess 19 on the right side in the illustration and also in the illustration To provide two recesses 22 on the left side in order to be able to push the individual elements of the bundle in the direction of arrows 23 from left to right. Here, too, the groups 14 a and 14 b are firmly anchored in the outer regions of the anchor element 16 and the group 14 c in the central region.

FIG. 7 shows how, analogously to the illustration according to FIG. 4, it is of course also possible to widen the left recesses 24 instead of the right recess 19 such that not only the individual elements can be inserted from here (Arrows 23 ), but that the clamping press 17 can also be used for clamping there with the press attachment 18 . In relation to the anchor element 16 , the ends 14 c are firmly anchored in the central area and the groups 14 a and 14 b can be anchored in the edge areas.

While each of the niches 15 has to be concreted in the above-described exemplary embodiments, it is also possible according to the invention to concretize the anchor element 16 from the outset and have recesses 20 and 24 on both the right and left sides of the anchor element 16 allow; this embodiment is shown in FIG. 8. In this case, it is possible to insert the tendon 14 either from the right side through the recess 20 , which of course then requires a niche according to FIG. 6 as a "switch" for spreading the individual elements into two groups, as well as from the left side forth through the recesses 24 . Depending on the, the tendon can also be tensioned out of both recesses.

Another embodiment of the invention is indicated schematically in FIGS. 9 and 10. Here, similar to FIG. 1, a tensioning channel 3 is formed in a concrete component 1 by embedding cladding tubes, into which a tensioning member 4 is inserted, which is anchored in an anchor element 6 in a recess accessible from the inside. The anchor element 6 is an anchor body known per se, in which the ends of the tendon 4 are passed through it along curved surfaces. If these curved surfaces are arranged with respect to one another in the anchor element such that the axes of the ends of the tendon are aligned with one another at their opposite entry points, the anchor element, when a tensile force is applied to the tendon, sets itself into one that can be seen from the inside in FIG. 10 Inclined position representing the state of equilibrium. In this case, it is necessary to provide recesses 27 and 28 on both sides of the recess 5 , which, depending on the inclined position of the anchor element 26 , each extend at an angle alpha to the longitudinal axis 29 of the tendon 4 .

A special embodiment of the anchor element, as shown in FIGS. 3 to 8, is shown on a larger scale in the representations of FIGS. 11a to d. Show here

11A, the anchor element in a plan view, Fig. 11b bb. An end view along the line, Fig. 11c cc is an end view taken along the line and Fig. 11d dd is a side view along the line.

The anchor element 26 here consists of an upper cover plate 30 and a lower cover plate 31 , which are trapezoidal and have a longer trapezoidal side 32 and a shorter trapezoidal side 33 . On the end faces, the two cover plates 30 and 31 are connected to one another by end plates 34 , 35 , on the longer trapezoidal side 32 by two end plates 34 and on the shorter trapezoidal side by an end plate 35 . The end plates 34 and 35 have in their central area circular openings 36 and 37 , which are adapted in shape and outline to the shape of commercially available anchor plates, which are supported against these end plates. Accordingly, the number of each to be anchored individual elements, these are on the side of the longer side of the trapezium armature discs 38 and on the side of shorter side of the trapezoid 31, an armature plate. 39 The armature disks 38 and 39 have, in a manner known per se, bores 40 which expand conically towards the outside and are thus suitable for receiving ring wedges known per se for anchoring individual elements designed as strands.

The anchor element 26 consists of a welded construction, ie the individual parts are connected to one another by welding.

Claims (13)

1. prestressed concrete component, in particular component with a curved wall, such as. B. container, tube, tunnel or tunnel liner or the like, with at least one tendon which is guided within the component in a clamping channel and the ends of which are anchored in an anchoring element, which is arranged in a niche in the component, which is subsequently filled with hardening material, characterized in that the dimensions of the niche are adapted in shape and size to those of the anchor element and that the niche is on one and / or both sides in at least one elongated recess following the tendon axis with the surface of the component decreasing depth continues to lead out the ends of the tendon. 2. Prestressed concrete component, in particular component with a circular wall, such as B. container, pipe, tunnel or Cleat lining or the like, with at least one Tendon that is inside the component in a tendon is guided and the ends overlapping in one Anchoring element are anchored in a tensionable manner characterized in that the anchor element in the component is concreted and that one and / or both sides of the Anchor element then at least one of each Tendon axis following elongated recess with itself Surface of the component of decreasing depth for leading out the tendon ends is provided. 3. prestressed concrete component according to claim 1 or 2, with one at least two individual tendons, at one end of the tendon on the anchor element is firmly anchored and the other end is tensioned characterized that the fixed and the tensionable Anchoring of the individual elements of the tendon each  Groups summarized symmetrically to the tendon axis the anchor element are arranged. 4. prestressed concrete component according to claim 3, characterized characterized in that the tensionable anchorages in the central area of the anchor element and the fixed Anchors are located in the edge areas. 5. prestressed concrete component according to claim 3, characterized characterized in that the fixed anchorages in the central area of the anchor element and the tensionable Anchors are located in the edge areas. 6. prestressed concrete component according to one of claims 3 to 5, characterized in that the individual elements of the Tendon outside the tendons and anchor points are brought together in a single bundle tendon. 7. prestressed concrete component according to claim 6, characterized characterized in that in the course of the tendon at the point the merging of the individual elements into a niche is provided after the insertion and tensioning of the Tendon is filled with hardening material. 8. prestressed concrete component according to claim 1 with only one consisting of a single element and a tendon self-balancing anchor element in which the ends of the single element along curved surfaces are performed, characterized in that the recesses starting from the niche at an acute angle alpha run inclined to the axis of the tendon. 9. Anchor element for use in a prestressed concrete component according to claims 1 to 7, wherein the anchors of Individual elements each grouped symmetrically are arranged to the tendon axis, characterized by  an anchor body with two opposite one another, mutually parallel end faces, on one of which The anchoring of the front in the central area Individual elements of one tendon end and at the other Front in the edge areas each in groups summarized anchorages of the individual elements of the other tendons are arranged. 10. Anchor element according to claim 9, characterized in that the anchor body is approximately trapezoidal. 11. Anchor element according to claim 9 or 10, characterized characterized in that the anchor body from an upper and there is a lower cover plate, the front of which Anchoring of the individual elements are arranged. 12. Anchor element according to one of claims 9 to 11, characterized in that the cover plates on the End faces through end plates running at right angles to it are connected. 13. Anchor element according to claim 12, characterized in that bore holes against the end plates Support anchor plates for anchoring the individual elements.