WO1995025859A1

WO1995025859A1 - Ferroconcrete support

Info

Publication number: WO1995025859A1
Application number: PCT/EP1995/000863
Authority: WO
Inventors: Hans-Peter ANDRÄ; Karl H. Jung; Peter Ernst
Original assignee: Zellner, Wilhelm; GÖHLER, Bernhard; Saul, Reiner; Seifried, Gerhard; Svensson, Holger; Detec Fertigung Gmbh
Priority date: 1994-03-22
Filing date: 1995-03-09
Publication date: 1995-09-28
Also published as: DE4409707A1

Abstract

A ferroconcrete support (1) has a reinforcing layer (2) consisting of longitudinal reinforcing rods (5) and reinforcing brackets (6) surrounding them. The reinforcing layer (2) is anchored in a shell region (7) of the support (1) on at least two opposite side surfaces (3) by means of bolt-head plugs arranged perpendicularly to the side surface (3). This prevents the longitudinal reinforcing rods (5) from bending outwards when the supports are subjected to pressure. A central region remains free between the shell regions (7) for pouring the concrete.

Description

Reinforced concrete column

The invention relates to a column made of reinforced concrete with a reinforcement, which has at least one outer reinforcement layer arranged near the side surfaces, which consists of longitudinal reinforcement bars and reinforcement brackets enclosing them.

In this context, a "support" is to be understood as any pressure element made of reinforced concrete in the building industry which is essentially subjected to pressure. In most applications, these supports or walls are arranged vertically and carry loads such as ceilings or other parts of the building.

The reinforcement of such supports usually consists of a reinforcement cage which consists of longitudinal reinforcement bars and reinforcement stirrups which enclose these longitudinal reinforcement bars. The longitudinal reinforcement bars are arranged along the side surfaces of the column at a distance predetermined by the necessary concrete cover.

The limit state of the load-bearing capacity is achieved in columns either by reaching the compressive strength of the concrete and the longitudinal reinforcement, by bending the column sideways or by bending the longitudinal reinforcement to the side. When considering the limit state it can be assumed that the concrete covering of the longitudinal reinforcement has come off, so that the longitudinal reinforcement is exposed and is no longer secured against buckling. The necessary resistance to buckling of the longitudinal reinforcement and an improvement in the ductility of the otherwise brittle concrete can be achieved by strapping in the form of stirrup reinforcement. However, this effect is only slight in areas which are further away from the longitudinal edges of the supports, in particular in a central area of a wider side surface. There, the lateral buckling of the longitudinal reinforcement under pressure can be prevented or at least delayed by additional bars of the reinforcement, such as S-hooks. These additional bars, which extend across the entire column to connect opposite longitudinal reinforcement bars, interfere with the placing of the concrete. Such supports are usually concreted upright, with the hose of the concrete pump being lowered from above into the central area of the support. This area must therefore be free of reinforcement parts. This would interfere with additional bars that connect the opposite reinforcement layers.

In order to keep an internal cross-sectional area free of reinforcement parts for the introduction of the concrete, but at the same time to counteract the buckling of longitudinal reinforcement bars, it is known to use reinforcement brackets which run diagonally at the corners of the column. The attachment of these reinforcement brackets is relatively expensive; moreover, the desired reinforcement effect is only achieved in the areas close to the corners of the column.

The object of the invention is to provide a support of the type mentioned at the outset such that an effective anchoring of the longitudinal reinforcement bars against buckling to the outside is achieved while maintaining a free core area for filling the concrete.

This object is achieved in that the outer reinforcement layer at least two to each other opposite side surfaces of the support cross section is anchored by means of head bolt anchors arranged perpendicular to the respective side surface in a shell region of the support extending along the respective side surface and that the head bolt anchors each have a widened dowel head at least at their end facing the interior of the support.

By means of the headed pin anchors, a shell area of the concrete determined by the length of these headed pin anchors and lying along the respective side surface is used for anchoring the outer reinforcement layer. This anchoring is sufficient to counteract a lateral buckling of the longitudinal reinforcement bars to a large extent, so that the load-bearing capacity of the support is increased significantly. However, the core of the column remains free of reinforcement elements, so that this core is available for pouring the concrete.

In contrast to the known inner reinforcement layers or reinforcement stirrups with diagonally extending stirrup legs, the headed dowels for anchoring the outer reinforcement layer are easy to install and require little work.

The headed dowels are expediently arranged in the shell regions facing all side surfaces of the support. This prevents the longitudinal reinforcement bars from buckling on all side surfaces of the column. This arrangement is particularly useful for supports that have a square or almost square cross section.

Compared to the known stirrups, the shell edging reinforced with headed dowels also has a considerably greater bending stiffness and is also suitable for ductility when the core is enclosed in a frame to improve the concrete significantly. The headed dowels also take on the function of shear reinforcement for the shell and can be dimensioned accordingly in terms of number and arrangement. By changing the length of engagement of the headed dowels in the support, a corresponding change in the shell thickness can be brought about. If the middle surface of the shell is curved or kinked, deflecting forces of the normal shell forces are generated which, according to the invention, can be oriented toward the column core in order to prevent the shell as a whole from buckling outwards.

In the case of supports with a rectangular cross-sectional area, it is provided in an embodiment of the inventive concept that the headed dowels are only arranged in the shell areas assigned to the two broader side surfaces of the support. In these wider side areas, the tying through the reinforcement bar has less effect, so that there is an increased risk of lateral buckling there. In contrast, in many cases there is no need for separate anchoring using the headed dowels on the narrower side surfaces because there is still sufficient anchoring effect through the reinforcement stirrups.

The widened dowel head on the end of each head bolt dowel facing the inside of the column results in a particularly effective anchoring, regardless of whether an inner reinforcement layer is provided in the area of the inner ends of the head bolt dowels.

At their outer ends, the headed dowels can also each have a widened dowel head, which effects anchoring in the area of the outer reinforcement layer. Instead, however, it is also possible to bend the end of the headed bolt facing the side surface to form a hook encompassing a longitudinal reinforcement bar.

Another possibility is to connect two headed dowels to each other at their ends facing the side surface by a bracket section to form a U-shaped bracket. This simplifies the fixing of the headed dowels on the reinforcement.

According to a particularly preferred embodiment of the invention, it is provided that a plurality of adjacent headed dowels are connected at their ends facing the side face to a common connecting rod which extends parallel to the side face and which can extend in the longitudinal direction of the beam or transversely thereto. The connecting rod can consist of round material or can preferably be designed as a strip made of flat material.

In this way, several adjacent headed dowels form a unit that is particularly easy to handle when producing the reinforcement. In addition, the head is held in their predetermined position by the common connecting rod, so that they do not change this position even when the concrete is poured.

A further modification of the inventive concept is that the headed dowels are welded onto the longitudinal reinforcement bars by default.

Further advantageous embodiments of the inventive concept are the subject of further subclaims.

Exemplary embodiments of the invention are illustrated below, which are shown in the drawing. It shows: 1 shows a cross section through a support made of reinforced concrete with anchoring of the longitudinal reinforcement bars by means of headed pin anchors in two opposite side surfaces,

2 shows a cross section through another support made of reinforced concrete, which has a second, inner reinforcement layer on its two broader side surfaces, with different embodiments of headed bolt anchors,

3 shows a cross section through a support made of reinforced concrete according to a further embodiment, wherein different exemplary embodiments of headed bolt plugs are also used,

4 to 10 enlarged partial longitudinal sections in different embodiments of the headed studs,

11 shows a simplified longitudinal section through a support made of reinforced concrete,

Fig. 12 shows a simplified longitudinal section through another embodiment of a support made of reinforced concrete and

Fig. 13 is a schematic longitudinal section through a support made of reinforced concrete to illustrate the shells resulting from the anchoring.

The support 1 shown in cross section in FIG. 1 with a rectangular cross-sectional area made of reinforced concrete has a reinforcement layer 2 which runs along the two wider side surfaces 3 and the two narrower side surfaces 4 of the support 1 with the necessary concrete cover. The reinforcement layer 2 forms one - 1 -

closed cage and consists of longitudinal reinforcing bars 5 and reinforcing stirrups 6 surrounding them.

The reinforcement layer 2 is anchored to the two opposite, broader side surfaces 3 by means of head bolt plugs 6a arranged perpendicular to the respective side surface 3 in a shell region 7, which is indicated in FIG. 1 by dash-dotted lines. The two shell regions 7 extend along the two side surfaces 3. The width (depth) of the two shell regions is essentially determined by the length of the headed stud dowels 6a. It can be seen that between the two shell regions 7 of the mutually opposite side surfaces 3 there remains a central region 8 which forms the core of the support and which is free of reinforcement elements. This middle area 8 is available for filling the concrete. For example, a hose of a concrete pump can be lowered into this central area 8 in order to concrete the support 1 standing.

As shown in Fig. 1, the head bolt dowels 6a arranged at regular intervals, namely for example in each case between adjacent longitudinal reinforcement bars 5, are connected at their ends facing the side face 3 to a common connecting bar 9 which extends parallel to the side face 3 and in which in Fig 1 shown embodiment is designed as a strip made of flat material, which extends transversely to the longitudinal direction of the column. The common connecting rod 9 serves, on the one hand, to establish a load-bearing connection of the headed bolt dowels 6a with the longitudinal reinforcement rods 5 of the reinforcement layer 2; on the other hand, the common connecting rod 9 represents a stable holder for all the head bolt dowels 6a connected to it.

In Fig. 6 is a headed pin 6a of the type used in Fig. 1 in a partial longitudinal section along the line VI-VI shown. Each headed pin dowel 6a has at its end facing the inside of the support a widened dowel head 10, which is preferably of plate-like design and merges into the dowel shaft 11 in a flat truncated cone. This flat cone-shaped design results in a particularly favorable introduction of force into the surrounding concrete. In all of the modified embodiments of the headed studs described below, the same head shape is preferably used.

The support 1 shown in cross section in FIG. 2 also has a rectangular cross-sectional area. The same parts are designated with the same reference numerals as in Fig. 1.

In addition to the previously described outer reinforcement layer 2, an inner reinforcement layer 12 is provided on the two side surfaces 3, each consisting of longitudinal reinforcement bars 5 and bracket sections 6 ′ of the reinforcement bracket 6.

The outer reinforcement layer 2 is also anchored in the shell region 7, which is delimited on the inside by the inner reinforcement layer 12, by means of stud bolts, of which different embodiments are shown in FIG. 2 for explanation. The head bolt dowels 6b have a widened dowel head 10 at both ends. Such an embodiment is also shown in FIG. 4, for example.

In each case two headed dowels 6c are connected to one another at their ends facing the side surface 3 by a bracket section 13 to form a U-shaped bracket which is shown in detail in FIG. 8. The bracket section 13 encompasses two reinforcement brackets 6. Using the example of a support 1 with a square cross-section, it is shown in FIG. 3 that the headed studs are arranged in the shell regions 7 assigned to all side surfaces 14.

Also in Fig. 3 different embodiments of the headed studs are shown for explanation. In addition to the previously described dowel plugs 6b with dowel heads 10 at both ends and the dowel dowels 6c connected to one another by a bracket section 13, dowel dowels 6a are shown which are connected to a common connecting rod 9 in the form of a strip. 1, the connecting rods 9, however, extend in the longitudinal direction of the support, as can be seen in detail in FIG. 9 in a section along the line IX-IX in FIG. 3.

Head bolt dowels 6d in another embodiment are bent at their end facing the side surface 14 to form a hook 15 encompassing a longitudinal reinforcement bar 5. A similar embodiment is shown in FIG. 7, but the hook 15 here encompasses a section of the reinforcement bracket 6.

Head bolt dowels 6e are directly welded to longitudinal reinforcement bars 5 at their ends facing the side surface 14, which thus form the common connecting rods for a plurality of head bolt dowels 6e (FIG. 10).

Fig. 5 shows an embodiment of stud bolts 6f, which are welded to a common rod 16 made of round material as a connecting rod.

In the simplified representation of a support 1 in longitudinal section in FIG. 11, the longitudinal reinforcement bars and the reinforcement stirrups are omitted from the illustration; only the headed dowels inserted in each case 6a indicated. It can be seen that the headed pin dowels 6a are each arranged in an area 17 at the two ends of the support 1 at an angle to the longitudinal direction of the support such that the inner ends of the headed pin dowels 6a are inclined towards the central area 18 of the support 1. In the central area 18, which is shown shortened in FIG. 11, the headed stud dowels 6a are directed perpendicular to the respective side surface 3.

In a correspondingly simplified illustration of a longitudinal section of a support 1 in FIG. 12, it is indicated in a simplified manner that the headed pin dowels 6a are provided in the middle region 18 of the support 1 in a uniform length, while the length of the headed pin dowels 6a in the one end region 17 of the support 1 steadily reduced towards the end of the column. Deviating from this, it is shown at the upper end of the support 1 according to FIG. 12 that only uniformly shorter headed studs 6a are used in this area 17 '.

With both measures described alternatively it results, as shown schematically in FIG. 13, that the shell region 7, which is determined by the length of the headed bolt dowels 6a and serves to anchor, becomes narrower towards the two ends of the support 1. The resulting increase in the shell thickness in the central region 18 of the support 1 generates deflecting forces acting towards the support core when subjected to pressure. The support shell lying in the shell region 7 of the support 1 can therefore not buckle outwards away from the support when subjected to pressure, but is supported in the transverse direction on the support core.

The headed pin dowels 6e can be welded onto the longitudinal reinforcement bars 5 already in the delivery state.

Claims

Reinforced concrete column

1. Support (1) made of reinforced concrete with a reinforcement which has at least one outer reinforcement layer (2) arranged near the side surfaces, which consists of longitudinal reinforcement bars (5) and reinforcement brackets (6) surrounding them, characterized in that the outer reinforcement layer ( 2) at least on two mutually opposite side surfaces (3; 14) of the column cross section by means of head bolt dowels (6a-f) arranged perpendicular to the respective side surface (3; 14) in a shell region (7) of the extending along the respective side surface (3; 14) Support is anchored and that the headed dowels (6a-f) each have a widened dowel head (10) at least at their end facing the inside of the support.

2. Support according to claim 1, characterized in that the headed dowels (6a-f) are arranged in the shell areas (7) facing all the side surfaces (14) of the support.

3. Support according to claim 1 with a rectangular cross-sectional area, characterized in that the headed studs (6a-f) are arranged only in the shell areas (7) assigned to the two broader side faces (3) of the support.

4. Support according to claim l, characterized in that the head bolt dowels (6b) have a widened dowel head (10) at both ends.

5. Support according to claim 1, characterized in that the side surface (14) facing the end of

Kopfbolzendübelε (6d) is bent to a hook (15) encompassing a longitudinal reinforcement bar (5).

6. Support according to claim 1, characterized in that in each case two headed studs (6c) are connected to one another at their ends of the side face (3; 14) by a bracket section (13) to form a U-shaped bracket.

7. Support according to claim 1, characterized in that a plurality of adjacent stud bolts (6a, 6f) are connected at their end facing the side surface (3; 14) to a common connecting rod (9) extending parallel to the side surface (3; 14) .

8. Support according to claim 7, characterized in that the connecting rod (9) extends in the longitudinal direction of the support.

9. Support according to claim 7, characterized in that the connecting rod extends transversely to the longitudinal direction of the support.

10. Support according to claim 7, characterized in that the connecting rod (9) is a rod (16) made of round material.

11. Support according to claim 7, characterized in that the connecting rod (9) is a strip made of flat material.

12. Support according to claim 7, characterized in that the connecting rod is formed by one of the longitudinal reinforcing rods (5).

13. A support according to claim 1, characterized in that the head bolt dowels (6a-f) are each arranged in an area (17) at the end of the support at an angle to the longitudinal direction of the support that the respective inner ends of the head bolt dowels (6a-f) middle area (18) of the support are inclined.

14. Support according to claim 1, characterized in that the shell region (7) determined by the length of the headed pin dowels (6a) and serving for anchoring becomes narrower towards the two ends of the support.

15. Support according to claim 1, characterized in that the headed studs (6e) are welded onto the longitudinal reinforcing bars (5) in the delivery state.