DE29922297U1 - Steel-concrete ceiling - Google Patents

Description

S teel-concrete ceiling

The invention relates to a steel-concrete ceiling, in particular a steel-concrete ribbed ceiling or a steel-concrete composite ceiling with at least one ceiling support on which transversely running trapezoidal profile sheets are supported, which are filled with concrete on the upper side.

In building construction, various procedures are known for the construction of ceilings. In addition to pure wood or steel ceilings, ceiling structures made of concrete are used in particular. On the one hand, prefabricated, reinforced concrete ceiling elements are used to produce them, which are then poured with in-situ concrete after installation. On the other hand, so-called steel-concrete ribbed ceilings or composite ceilings are also known, in which a steel sheet simultaneously takes on the function of permanent formwork and tensile reinforcement.

A steel-concrete ribbed ceiling or composite ceiling usually has several parallel steel or concrete ceiling beams. Profiled steel sheets, particularly

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in the form of trapezoidal profile sheets that are attached to the top of the ceiling beams. If the ceiling beam is made of steel, several headed bolts are also attached to its top to transfer the shear force. After the trapezoidal profile sheets have been fixed in place and, if necessary, after additional reinforcement has been added, the trapezoidal profile sheets are filled with in-situ concrete to such an extent that the entire sheet is sufficiently covered with concrete, i.e. the wave valleys of the profile are completely filled and the wave crests are also covered with a sufficient layer of concrete. Since the maximum span of the ceiling that can be achieved depends on the profile shape and in particular the profile height of the trapezoidal profile sheets, the profile height to be covered by the concrete is very large for large spans. This makes the ceilings very heavy and has a relatively large construction height. In addition, the effective plane of the ceiling slab has a relatively large upward offset relative to the ceiling beam, which is statically unfavorable.

From DE 42 15 686 Cl it is known to reduce the height of a steel-concrete ribbed ceiling by not placing the trapezoidal profile sheets on the top of the ceiling beams, but suspending them from special cross beams. For this purpose, laterally protruding cross beams are mounted on the top of the ceiling beams, onto which the trapezoidal profile sheets are placed with special bevels in the form of receiving grooves formed in their wave crests. In this way, the construction height 0 of the ceiling can be reduced and the offset between the line of action of the ceiling slab and the ceiling beam is also reduced. The disadvantage here is, however, that such a ceiling construction requires special trapezoidal profile sheets and that the load transfer between the trapezoidal profile sheet and the ceiling beam during construction can only be achieved via the cross beams.

i.e. the trapezoidal profile sheets are subjected to high local tensile stresses.

The invention is based on the object of creating a steel-concrete ribbed ceiling or composite ceiling of the type mentioned, in which a statically favorable load transfer between the trapezoidal profile sheet and the ceiling support can be achieved while maintaining the above-mentioned advantages with a structurally simple design.

This object is achieved according to the invention in a steel-concrete ribbed ceiling or composite ceiling of the type mentioned in that the trapezoidal profile sheets are supported with the end regions of the undersides of their wave valleys on lateral bearing surfaces formed on the ceiling support, which are offset downwards from the top of the ceiling support and protrude laterally from the ceiling support in the manner of a console.

According to the invention, the bearing surfaces between the trapezoidal profile sheets and the ceiling support are not arranged in or near the top of the sheet, but offset downwards from the top. In this way, it is possible to place the trapezoidal sheets in the conventional manner with the underside of their wave troughs on the bearing surfaces, whereby the offset of the bearing surfaces results in a reduction in the construction height of the ceiling and the distance between the effective plane of the ceiling panel and the ceiling support. Since the trapezoidal sheets are not suspended in the ceiling construction according to the invention, but are simply placed on the underside, no special design of bearing elements is necessary on the trapezoidal profile sheets in order to be able to use them in the ceiling according to the invention.

In a preferred embodiment of the invention, several bearing surfaces are arranged one behind the other in the longitudinal direction of the ceiling support at a mutual distance. The distance should correspond to the grid size of the trapezoidal profile sheets used, so that each trough of the trapezoidal profile sheets is placed on a correspondingly assigned bearing surface. Alternatively, the plurality of bearing surfaces arranged in the longitudinal direction of the ceiling support can also be provided on a longitudinal strip, so that no special adjustments have to be made to the size of the trapezoidal profile sheet used for the ceiling.

The ceiling support is preferably a steel support with an I-profile, with the bearing surfaces being formed on bracket parts that are attached to the ceiling support. The bracket parts used are preferably steel profiles that are welded to the ceiling support. It has proven advantageous to attach the bracket parts to the upper chord of the ceiling support, with a preferred embodiment of the invention providing that the bracket parts are welded to the underside of the upper chord of the ceiling support. Alternatively, the bracket parts can also be welded to the top of the upper chord or supported on the top of the lower chord.

In a possible embodiment of the invention, it is provided that the console parts are formed from a Z-profile known per se. The upper leg of the Z-profile is welded to the upper part of the ceiling beam, so that the web of the Z-profile extends downwards essentially vertically and parallel to the web of the ceiling beam and the second leg of the Z-profile arranged at the lower end of the web projects outwards at the side and the bearing surface

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on which the trapezoidal profile sheet is placed. Alternatively, the console parts can also be formed from a steel molded part, for example a pressed part.

Further details and features of the invention will become apparent from the following description of an embodiment with reference to the drawing, wherein the single figure shows a perspective view of a steel-concrete ribbed ceiling according to the invention in the assembled state.

A steel-concrete ribbed ceiling 10 has several ceiling beams 11 arranged parallel and spaced apart from one another, of which only one is shown in the figure. The ceiling beam 11 is a steel beam with an I-profile and has an upper flange 11a, a vertical web lic and a lower flange 11b. A large number of headed bolts 14 are welded onto the upper side of the upper flange 11a of the ceiling beam 11 in the longitudinal direction and at a mutual distance from one another.

On both sides of the web lic of the ceiling support 11, console parts 12 are arranged, which are formed by a Z-profile, which is welded with its upper leg to the underside of the upper flange 11a and with its lower leg protrudes laterally from the ceiling support 11. The lower, laterally protruding leg of the console part 12 forms a bearing surface 13. As the figure shows, several console parts 12 are arranged one behind the other at a mutual distance in the longitudinal direction of the ceiling support 11.

Trapezoidal profile sheets 15 are supported on the bearing surfaces 13 of the console parts 12 on both sides of the ceiling support 11, which extend perpendicular to the longitudinal direction of the ceiling support 11 and have a cross-sectional shape with wave crests and wave troughs in a known manner. The trapezoidal profile sheets 15 lie with the end areas of the undersides

their wave troughs 15a on the bearing surfaces 13, which are offset downwards by the height of the web of the console parts 12 relative to the upper flange 11a of the ceiling support 11. The offset is selected so that it is equal to or slightly less than the height of the trapezoidal profile sheets 15. In the embodiment shown, the upper side of the trapezoidal profile sheets 15 is arranged slightly above the upper side of the upper flange 11a of the ceiling support 11, with the resulting slots being closed by covers 18. At the same time, in the area of the wave troughs, the ends of the trapezoidal profile sheets 15 on the side facing the ceiling support 11 are closed with filler bodies 19.

An additional reinforcement 16 extends in each of the wave valleys, which is guided around the upper side of the ceiling support 11 or can be inserted only in the deep bead area of the trapezoidal profile sheet 15.

After the trapezoidal profile sheets 15 have been laid down and secured on the bearing surfaces 13 of the console parts 12, the trapezoidal profile sheets 15 are filled on the top with concrete 17 to such an extent that the headed bolt dowels 14 and the top of the wave crests of the trapezoidal profile sheets 15 are covered with a concrete layer of sufficient thickness. The trapezoidal profile sheets 15 form a permanent formwork on the one hand and, if appropriate profile undercuts are designed, the tensile reinforcement of a steel-concrete composite ceiling on the other. During the pouring process of the still liquid concrete, the covers 18 and the filler bodies 19 prevent the concrete from leaking out.

Claims (7)

1. Steel-concrete ceiling with at least one ceiling support ( 11 ) on which transversely running trapezoidal profile sheets ( 15 ) are supported, the upper side of which is filled with concrete ( 17 ), characterized in that the trapezoidal profile sheets ( 15 ) are supported with the end regions of the undersides of their wave troughs ( 15a ) on lateral bearing surfaces ( 13 ) formed on the ceiling support ( 11 ), which are offset downwards from the upper side of the ceiling support ( 11 ) and protrude laterally from the ceiling support ( 11 ) in the manner of a console. 2. Steel-concrete ceiling according to claim 1, characterized in that several bearing surfaces ( 13 ) are arranged one behind the other in the longitudinal direction of the ceiling support at a mutual distance. 3. Steel-concrete ceiling according to claim 1 or 2, characterized in that the ceiling support ( 11 ) has an I-profile and the bearing surfaces ( 13 ) are formed on console parts ( 12 ) which are attached to the ceiling support ( 11 ). 4. Steel-concrete ceiling according to claim 3, characterized in that the console parts ( 12 ) are attached to the upper chord ( 11a ) of the ceiling support ( 11 ). 5. Steel-concrete ceiling according to claim 4, characterized in that the bracket parts ( 12 ) are welded to the underside of the upper chord ( 11a ) of the ceiling support ( 11 ). 6. Steel-concrete ceiling according to one of claims 3 to 5, characterized in that the console parts ( 12 ) have a Z-profile. 7. Steel-concrete ribbed ceiling or composite ceiling according to one of claims 3 to 5, characterized in that the console parts are formed from a steel molded part, in particular a pressed part.