WO2007066228A2

WO2007066228A2 - Composite pillar for junction connections on constructions and building frames

Info

Publication number: WO2007066228A2
Application number: PCT/IB2006/003923
Authority: WO
Inventors: Bernard Douet
Original assignee: Bernard Douet
Priority date: 2005-09-29
Filing date: 2006-09-28
Publication date: 2007-06-14
Also published as: AT502604A2; AT502604A3; WO2007066228A3; EA200800968A1; US20090038263A1; EP1931832A2; AT502604B1; CN101313113A

Abstract

According to the invention, a arrangement for connection of a composite pillar (1) to a beam (9, 10) of a building frame, wherein the composite pillar (1) comprises at least one vertical steel support (2) and an envelope (3) made from steel arranged all around the steel support (2) at least in the region of the connection and wherein the cavity (4) between the steel support (2) and envelope (3) is filled with a filling material such as concrete and building frame with such an arrangement with economical static load transmission (9, 10) from the beam to the composite pillar may be achieved by fixing at least one connector element (6) to the steel support (2), running between the steel support and the envelope (3) with an opening (11) in the envelope in the region of the connector element (6) through which the beam (9, 10) can be connected to the steel support.

Description

Composite column for node connections of buildings and building skeleton

The invention relates to an arrangement for connecting a composite support to a beam of a building skeleton, the composite support having at least one vertical steel girder and a steel sheathing arranged at least in the connection area on all sides at a distance from the steel girder, and wherein the space between the steel girder and the sheathing is filled with a filling compound such as Concrete is filled, as well as a building skeleton with connection nodes with such an arrangement.

When constructing building skeletons from reinforced concrete, composite supports are known, which usually consist of three components, namely a beam in the form of a steel profile and concrete and, if appropriate, additional reinforcement. There are various cross-sectional options for composite columns, whereby a basic distinction can be made between concrete-filled round tubes or hollow profiles, steel profiles with chamber concrete and fully embedded steel profiles. In the case of steel profiles with chamber concrete, the outer surface of the composite column is partly formed by the steel profile and partly by the concrete. With steel profiles concreted in, the steel profile is enclosed on all sides by concrete.

In contrast, the invention is concerned with concrete-filled round tubes or hollow profiles in which the outer surface of the

Composite column is formed by the round tube or hollow profile, which thus forms the formwork for the composite column. Furthermore, in the arrangement according to the invention, the inside of the casing is in

Provided the form of the round pipe or hollow section, one or more steel beam, or which the cover is spaced from ^'from the steel. ^■

In order to produce connecting knots, it has previously been customary with such composite supports to fasten the beams to the outer casing made of steel, ie to screw or weld them on. The force is transmitted from the beam into the composite column via the sheathing in the reinforced concrete and from there into the steel girder, whereby the critical areas of the load transfer represent the separating surfaces between steel and concrete, so that additional measures must be taken to ensure sufficient load transfer. ensure support at the parting surfaces. From AT 405 067 B it is known to formwork the beams and uprights and their connections in such a way that the formwork is spaced on all sides from the beams and uprights and their connections, so that the beams and uprights and their connections are completely surrounded by concrete.

The invention is based on the object, a generic

Arrangement and a building skeleton with such an arrangement for

To make available in which the force transmission from the beam into the

Composite column can be carried out both statically and economically advantageous.

This object is achieved with an arrangement with the features of claim -1 and with a building skeleton with the features of claim 9.

In the invention, connecting elements are provided which are fastened to the steel beam and only extend within the casing. This makes it possible either to deliver steel girders to the construction site where the connecting elements are already fastened, or these can be fastened to the steel girders on site before the covering is attached to the steel girder. The connecting elements can also be used as spacers for precisely positioning the casing around the steel girder. In principle, however, it is of course also possible to attach some or all of the connecting elements only after the casing has been positioned, provided that there is sufficient access. In this case, the connecting elements could also protrude through the opening to the outer circumference of the casing.

Since there is an opening in the envelope in the area of each connecting element, the beam can be attached directly to the connecting element, i.e. screwed or welded on so that the force is transmitted from the beam into the composite support directly into the steel beam. Since the connecting element is enclosed by concrete after the cavity between the steel girder and the casing has been filled, the force is also introduced directly into the concrete or reinforced concrete.

This construction can be used with a particularly static and economic advantage in a structure with penetrating frame elements, as is known from AT 405 661 B, since several connections to a connection point of a node are required there, which are to be covered with concrete. ό

len.

If required, the connecting element and / or the beam can also be connected directly to the covering, so that forces can also be introduced directly into the covering.

The connecting element advantageously extends directly to an inner surface of the casing and closes the opening, so that no additional measures have to be taken to prevent concrete from escaping in the region of the opening.

In a preferred embodiment of the invention, provision can be made for a flange to be attached to the end of the connecting element facing the casing.

This flange, which preferably bears against the inner surface of the casing, taking into account manufacturing inaccuracies, makes it possible to compensate for positioning errors in the casing or manufacturing inaccuracies when the opening is made, if the area of the flange is larger than the area of the opening, since the opening then does not have to be positioned exactly with respect to the connecting element. In addition, the flange can facilitate the connection of the connecting element to the casing, which may be desired.

With regard to the opening that is provided for each connecting element in the casing, there is either the possibility of providing a single opening which is so large that the beam with its entire connection area can be arranged within the opening and connected to the connecting element. Alternatively, it is also possible to provide several openings per connecting element through which connecting bolts, connecting screws or the like. protrude, with the help of which the beam is connected to the connecting element. This embodiment would have the advantage that the covering between the connecting element and the connection area of the beam would also be received and fixed at the same time. In principle, the latter advantage can also be achieved with only a single opening if the connecting element or its flange and the connection area of the beam are larger than the opening.

In the production of building skeletons in the area of the connection nodes it is usually the case that not just one but several beams in the area of a connection node have to be connected to a composite support. For this case, in the area of the connection node there are a number of connection elements corresponding to the number of bars and openings associated therewith the envelope to which the beams can be connected.

Within the scope of the invention, however, it is also possible, for example in the area of connection nodes, for example to provide four connecting elements which, as mentioned, also serve as spacers for the sheathing, if necessary only in the area of those

Connecting elements to which beams should be connected,

Openings are cut out in the covering, whereas in the area of connecting elements to which no beams have to be connected, the covering remains closed or, if it is prefabricated, is closed.

Further features and advantages of the invention result from the following description of a preferred embodiment of the invention with reference to the drawings.

1 shows a view of a connecting node with an arrangement according to the invention on a composite support 1, FIG. 2 shows a top view of the arrangement from FIG. 1 and FIG. 3 shows a section along the line III-III FIG. 2.

1 to 3 show an embodiment of a connection node on a connection support 1 with an arrangement according to the present invention. In the exemplary embodiment shown, the composite support is a so-called double-tube support consisting of a central tubular steel support 2 and an equally tubular casing 3, which is also arranged concentrically with the support 2 and also consists of steel. The casing can consist of a continuous, closed tube or of a tube composed of several parts. E.g. the casing 3 can consist of two half-shells which are connected to one another at two longitudinal connection points. A space 4 is created between the carrier 2 and the casing 3, which is filled with a filling compound, usually concrete, when the composite support has been completed. The cavity 5 within the carrier 2 can also be filled with concrete. Instead of a tubular support 2, any other steel support, for example extruded profiles, special rolled profiles, crossed rolled profiles of any shape or polygonal profiles, can also be used. Instead of hollow profiles or rolled profiles, solid profiles can also be used as carrier 2. Common to all embodiments of such profiles or carriers, however, is that they are spaced apart from the casing 3.

In the illustrated embodiment, four are on the carrier 2 Connection elements 6 welded in form I profiles. At the end facing the casing 3, flanges 7, end plates or the like are welded to a connecting element 6, which abut the inner surface 8 of the casing 3. The connecting elements 6 with the flanges 7 thus form spacers within the space 4, which ensure an exact spacing of the casing 3 with respect to the carrier 2 on all sides.

In the area of the node of the composite support 1 shown in FIGS. 1 to 3, two beams 9 and 10 are connected to the composite support 1. For this purpose, there are two rectangular openings 11 in the casing 3 on the two connecting elements 6 assigned to the beams 9 and 10, the outer dimensions of which are somewhat smaller than the flanges 7. This will completely seal the

Opening 11 is also ensured if the opening 11 is not quite exactly in the area of the associated connecting element or its

Flange 7 is arranged.

However, it is also possible not to close the opening 11, so that concrete can pass through the opening 11, so that the connecting element 6 and, if present, a flange 7 or the like and the connected beams 9, 10 are completely surrounded by concrete, such as this is known per se from AT 405 067 B. Likewise, it is also possible to make further openings in the casing 3 around the connection area or the opening 11, through which concrete can pass in order to establish a connection with a concrete casing of the beam 9, 10.

. A further opening 11 is shown on the lower side of the casing 3 in FIG. 2, since a bar still has to be connected to this connecting element 6. No opening 11 is provided on the upper side of the casing 3 in FIG. 2, since no beam is to be connected to the connecting element 6 there.

Through the openings 11 in the casing 3, the beams 9, 10 can be connected directly to the respective connecting element 6 with its flange 7. In order to connect the beams 9, 10 to the flanges 7, they can be welded or screwed onto the flanges 7. Since the opening 11 is somewhat larger than the cross section of the beams 9 and 10, any inaccuracies in the manufacture or positioning of the beams 9, 10 or the composite support 1 can also be compensated for here.

The openings 11 in the casing 3 can be prefabricated via the steel carrier 2 before they are positioned. The off Solutions 11 can also be cut out only when the casing 2 has already been arranged around the steel beam 2, since it is possible in this way to make the openings 11 exactly at the points at which bars 9, 10 are later to be connected.

It goes without saying that the flanges 7 do not necessarily have to be provided on the connecting elements 6, so that the beams 9, 10 are attached directly to the connecting elements 6. In this case, the openings 11 would either have to be made so precisely that when the space 4 is filled with concrete there is no appreciable leakage of concrete, or measures can be taken in a simple manner to seal the spaces of the opening 11 that remain free.

The connecting elements 6 and, if present, their flanges 7 or the like can also be covered with the casing 3 e.g. be connected by welding or screwing. This can take place either from the outside through the opening 11 or from the inside, in which case sufficient access or size of the space 4 between the casing 3 and the carrier 2 must be ensured.

If required, a reinforcement can also be provided in space 4, the connecting elements 6 being able to be used in a practical way for positioning and fastening the reinforcement.

After the beams 9, 10 have been fastened to the composite support 1, they can be switched on and completely or only partially concreted in, depending on what the beams 9, 10 are subsequently used for. The beams 9, 10 can also not only be beams in the actual sense, which lead to other supports or composite supports, but also as shear force connections for flat ceilings or the like. be used.

It can be seen that the beam forces are not only introduced directly into the beam 2 by connecting the beams 9, 10 to the connecting elements 6, but also directly into the concrete or reinforced concrete surrounding the beam 2, in which the connecting elements 6 are embedded. If necessary, a connection of the beams 9, 10 and / or of the flanges 7 or of the connecting elements -6 to the sheath 2 can also be introduced directly into these forces. The disadvantages known in comparable composite supports of the prior art that the beam forces are applied to the concrete 3 and beyond in the casing 3 are thus avoided Only then be derived on the steel beam 2.

Finally, according to an embodiment not shown in the drawings, it is also possible to establish a connection between the beams 9, 10 and the connecting element 6 or flange 7 by, for example, producing bores or openings in the casing 3 through which connecting screws or bolts protrude with the help of the connecting elements 6 or their flanges 7 can be connected directly to the beams 9, 10, provided on the beams 9, 10 appropriately designed connection areas are provided.

Claims

Expectations :

1. Arrangement for connecting a composite support (1) to a beam (9, 10) of a building skeleton, the composite support (1) having at least one vertical steel girder (2) and a sheathing (at least in the connection area) spaced apart from the steel girder (2) 3) made of steel and wherein the space (4) between the steel beam (2) and the casing (3) is filled with a filling compound such as concrete, characterized in that at least one connecting element (6) is fastened to the steel beam (2) extends between the steel girder and the sheathing (3) and that there is an opening (11) in the sheathing in the region of the connecting element (6) through which the beam (9, 10) can be connected to the steel girder.

2. Arrangement according to claim 1, characterized in that two or more connecting elements (6) are attached to the steel support (2), which extend between the steel support (2) and the casing (3) and that in the casing (3) in the area of the connecting elements (6) are openings (11) through which beams (9, 10) can be connected to the connecting elements (6).

3. Arrangement according to claim 1 or 2, characterized in that the connecting element (6) extends to an inner surface (8) of the casing (3).

4. Arrangement according to one of claims 1 to 3, characterized in that the connecting element (6) is connected to the casing (3).

5. Arrangement according to one of claims 1 to 4, characterized in that a flange (7) is attached to the end of the connecting element (6) facing the sheath (3).

6. Arrangement according to claim 4 and 5, characterized in that the flange (7) is connected to the sheath (3).

7. Arrangement according to one of claims 3 to 6, characterized in that at least one connecting bolt, a connecting screw or the like extends through the opening (11), by means of which the bar (9, 10) can be connected to the connecting element (6) .

8. Arrangement according to claim 7, characterized in that a plurality of openings (11) and a corresponding number of connecting bolts, connecting screws or the like are provided for each connecting element (6).

9. Building skeleton with connecting nodes, on which supports are connected with beams (9, 10), at least one support being a composite support (1) with at least one vertical steel support (2) and a casing (3) arranged on all sides at a distance from the steel support (2) ) is made of steel and the space (4) between the steel girder (2) and the casing (3) is filled with a filling compound such as concrete, characterized in that at least one connecting node has an arrangement according to one of Claims 1 to 8.