EP1112421A1

EP1112421A1 - Device for connecting a girder of a composite floor to a beam

Info

Publication number: EP1112421A1
Application number: EP99944147A
Authority: EP
Inventors: Ferdinand Tschemmernegg
Original assignee: A-MBT Anwendungszentrum Mischbautechnologie GmbH
Current assignee: A-MBT Anwendungszentrum Mischbautechnologie GmbH
Priority date: 1998-09-10
Filing date: 1999-09-07
Publication date: 2001-07-04
Also published as: BR9913570A; TW461931B; WO2000015920A1; DE19841442A1; AU5719499A

Abstract

The invention relates to a device for connecting a girder of a composite floor to a beam, wherein the girder (2) is pivotally mounted on the beam (1) in such a way that the girder can pivot around an axis located in a normal plane in relation to the beam (1).

Description

Device for connecting a beam of a composite ceiling to a support

The present invention relates to a device for connecting a beam of a composite ceiling to a support, a component and a method for erecting a building with at least one composite ceiling.

Composite ceilings represent a further development of reinforced concrete ceilings, which are carried out today on a large scale in building construction. In the case of reinforced concrete ceilings, which are made of concrete with inserted reinforcing bars or mats, there are serious restrictions with regard to the reduction in the ceiling thickness that is sought for economic reasons. On the one hand, the so-called punching problem arises with reinforced concrete ceilings: the transverse forces occurring in the connection area of the reinforced concrete ceiling to the column, which result from constant loads and payloads, can only be absorbed if the shear stress cone that forms is sufficient. This results in a minimum thickness of the reinforced concrete ceiling. Another limitation arises from the limited pressure and deformation capacity of the concrete, which is easily destroyed by the moments occurring in the connection area on the lower edge of the reinforced concrete ceiling.

In the case of composite ceilings, attempts are now being made to overcome these restrictions by using additional steel components. The steel components designed as supports have so far always been delivered to construction sites as individual parts and connected to the supports on site by welding or by mounting bolts. The connection of the girders to the supports was thus associated with a great deal of work on the construction site.

The object of the invention is to reduce this workload in order to be able to erect structures having composite ceilings more quickly.

According to the invention it is provided that the carrier is pivotally connected to the support about an axis lying in a normal plane to the support. Furthermore, the invention provides a component which consists of a support with supports pivotably connected thereto, the pivot axes lying in one or more spaced normal planes to the support.

Finally, the method according to the invention for the erection of a building with at least one composite ceiling provides that supports with supports connected to them about a pivot axis lying in a normal plane to the support are set up, the supports being folded approximately parallel to the support during installation, and that then the beams are folded out into a position approximately at right angles to the column and, after the formwork has been attached, are concreted in for the composite floor.

The component according to the invention can be delivered prefabricated to the construction site, with supports for several floors, i.e. for several composite ceilings to which the support can be pivotally connected. Due to the pivotable connection of the beams to the column, it is possible to transport the column in a space-saving manner with beams aligned approximately parallel and folded onto the column and to position them at the appropriate place in the building. Only then are the beams folded out into a position approximately at right angles to the support and concreted in together with the reinforcements after the formwork has been attached to the composite floor.

In this context, it is desirable if the girder is designed in such a way that in the unfolded position in which the girder is concreted in, a moment-transmitting connection of the composite ceiling to the support is created. For this purpose, it can be provided that the carrier has a T-shape, the central web protruding upward from the cross flange and the cross flange resting directly or indirectly on the support, at least under load. Through the cross flange of the beam, a force transmission from the beam into the column, which is independent of the pressure and deformation capacity of the concrete, is now achieved, so that the forces resulting from the occurring moments can be easily derived.

A preferred embodiment variant provides for a structurally simple connection of the carrier to the support that a connecting strap with a through fixed bore, preferably welded, and that the central web of the

Carrier in the connection area has a corresponding through hole, the carrier being pivotally connected to the support by a pivot bolt passing through both through holes.

In order to be able to align the carrier precisely, it can be provided in this connection that the relative position of the carrier to the support in the extended position can be adjusted by means of fitting plates inserted between the transverse flange and the support. The adapter plates also ensure that the cross flange lies firmly against the support, so that occurring loads are passed on directly and without play from the cross flange to the support.

In order to improve the transmission of the forces from the composite ceiling into the girder, it can also be provided that the transverse flange is provided with a large number of pin-shaped elements, in particular protruding nails or bolts.

In order to increase the capacity of the structure with respect to transverse forces resulting from constant loads and payloads, it can additionally be provided that a peg is attached to the support for introducing transverse forces, preferably welded on, the carrier in the unfolded position on the peg lies on. In the final state it is preferably provided that the carrier, which is shorter than the distance between adjacent supports, is only connected on one side to a support. This is achieved through the torque-transmitting connection.

Further features and details of the present invention result from the subsequent description of the figures. It shows:

1 shows a device according to the invention in side view, FIG. 2 shows a device according to the invention in the associated view from above, FIG. 3 shows a section through a carrier,

Fig. 4 shows a component according to the invention with the supports folded and

Fig. 5 shows a component according to the invention with differently opened

Carriers. The device according to the invention relates to modern buildings in which a plurality of supports supports the composite ceilings which divide the building into storeys downwards on the foundation. One of these supports 1 is shown in FIGS. 1 and 2.

The support 1 is designed as a hollow profile support made of steel, a steel core 7 being additionally provided in the interior of the support 1. In particular in the connection area of the support 2 to the support 1, the support 1 is provided with dowels or nails 8, which form a reinforcement of the cavity that can be filled with concrete around the steel core 7 and transmit the forces introduced from the outer hollow profile of the support 1 into the interior.

To connect the support 1 to the support 2, a connecting bracket 6 is welded to the support 1 and is provided with a through hole. Beneath the connecting bracket 6, a collar 9 made of steel is additionally welded to the support 1. Both the connecting strap 6 and the collar 9 serve to introduce the forces absorbed by the carrier 2 into the support 1.

The carrier 2 is provided with a multiplicity of pin-shaped elements 5 to absorb the forces from the composite ceiling formed within the dashed lines of reinforced concrete 4. The pin-shaped elements 5, for example nails, screws or bolts, are - as can be seen from FIG. 2 - arranged on the horizontal transverse flange 2b of the carrier 2. Depending on the design, the pin-shaped elements are either welded to the cross flange or, if they pass through the cross flange 2b, fixed by means of a screw connection.

The carrier 2 has on its central web 2a in the connection area a through hole corresponding to the through hole of the connecting plate 6, so that the carrier 2 can be pivotably connected to the support 1 by means of a pivot bolt 3 passing through the two through holes.

The pivotable connection enables the economical production of the component shown in FIGS. 4 and 5, which consists of a support 1 with a plurality of supports 2 connected to it. The support 1 can be up to 20 m long and have 2 beams for several storeys that can be folded out at spaced levels. The component can be easily transported in the form shown in FIG. 4 with the supports 2 folded down. The carrier 2 are only at the construction site after positioning the

Support 1 folded out into a moment-transmitting position approximately at right angles to support 1 and concreted in after the installation of formwork for the composite floor.

The cross-sectional shape of the carrier 2, which can be seen in FIG. 3, is essential for the torque transmission. The transverse flange 2b of the carrier 2 enables the pressure forces resulting from the moment M to be introduced into the column 1. The introduction takes place indirectly via the adapter plates 10 and the collar 9, it being essential that all components involved (support, carrier, collar, adapter plates) ) are made of steel. The

Dowel plates 10 ensure the play-free concern of the

Cross flange 2b on the peg 9, so that even small loads are transferred directly to the support 1 without play. In addition, the relative location of the

Carrier 2 to support 1 can be set exactly.

Apart from the transmission of the compressive forces from the transverse flange 2b to the support 1, the main function of the peg 9 is to absorb the transverse forces Q which result from constant loads and payloads. For this purpose, the carrier 2 rests with its central web 2a on top of the peg 9.

In addition to the pressure absorption via the transverse flange 2b, a classic tensile reinforcement arranged in the upper area of the concrete 4 ensures the torque-transmitting connection of the composite slab to the column 1. This tensile reinforcement interacts with the introduction of pressure via the transverse flange 2b in the lower area of the composite slab.

Depending on the position of the support 1 in the building, either several beams distributed over the circumference are connected to the support, as shown in FIGS. 4 and 5, or only one, as in FIGS. 1 and 2. A lost formwork can be on the supports 2 be fixed for the reinforced concrete 4, whereby a classic formwork, which is associated with high labor costs, can be dispensed with.

Claims

Patent claims

1. Device for connecting a carrier of a composite ceiling to a support, characterized in that the carrier (2) to one in a normal plane

Support (1) lying axis is pivotally connected to the support (1).

2. Device according to claim 1, characterized in that the carrier (2) from an approximately parallel to the support (1) position in an unfolded position approximately at right angles to the support (1) is pivotable.

3. Apparatus according to claim 1 or 2, characterized in that the carrier (2) has a T-shape, the central web (2a) protruding from the cross flange (2b) and the cross flange (2b) at least under load on the support (1) directly or indirectly.

4. Device according to one of claims 1 to 3, characterized in that on the support (1) a connecting bracket (6) with a through hole is preferably welded, and that the central web (2a) of the carrier in the connection area has a corresponding through hole The carrier (2) is pivotally connected to the support (1) by a pivot pin (3) passing through both through bores.

5. Device according to one of claims 1 to 4, characterized in that the relative position of the carrier (2) to the support (1) in the extended position by means of between the transverse flange (2b) and support (1) inserted shims (10) is adjustable .

6. Device according to one of claims 1 to 5, characterized in that on the support (1) for introducing transverse forces a peg (9) attached, preferably welded, the carrier (2) in the unfolded position on the peg ( 9) rests.

7. Device according to one of claims 1 to 6, characterized in that the transverse flange (2b) is provided with a plurality of pin-shaped elements (5), in particular projecting nails or bolts.

8. Device according to one of claims 1 to 7, characterized in that the support (1) is designed as a hollow profile support made of steel.

9. The device according to claim 8, characterized in that the support (1) is provided at least in the connection region of the carrier (2) with dowels or nails (8) which project as reinforcement into the interior of the support (1).

10. Device according to one of claims 1 to 9, characterized in that the carrier (2) is connected on one side.

11. The device according to one of claims 1 to 10, characterized in that the carrier (2) is shorter than the distance between adjacent supports (1).

12. Device according to one of claims 1 to 11, characterized in that a plurality of carriers (2) distributed over the circumference are connected to the support (1).

13. Component, characterized in that it consists of a support (1) with pivotally connected supports (2), the pivot axes lying in one or more spaced normal planes to the support (1).

14. A method for erecting a structure with at least one composite ceiling, characterized in that supports (1) with attached to it in a normal plane to the support (1) pivot axis connected supports (2) are set up, the supports (2) during the installation on the support (1) are folded almost parallel, and that then

The girder (2) is folded out into a position approximately at right angles to the support (1) and concreted in after the formwork has been installed for the composite floor.