DE3442355C1 - Sheet-metal profile for false-ceiling load-bearing members, upright supports and the like - Google Patents

Abstract

A sheet-metal profile having a U-shaped truss-section for false-ceiling load-bearing members, upright supports for a load-bearing skeleton for partition walls of the prefabricated type and the like, exhibits a web wall (1) and flange surfaces (2) which are angled off therefrom. Transverse beads (4) are arranged at a distance from one another and run, transversely to the longitudinal direction of the profile, from the web wall (1) into the flange surfaces (2). By means of the transverse beads (4), the thin-walled sheet-metal profile is reinforced against a lateral deformation of the flange surfaces (2). <IMAGE>

Description

Further refinements of the invention are the subject of further subclaims. The invention is explained in more detail below using exemplary embodiments that are shown in FIG are shown in the drawing. It shows in spatial representation: F i g. 1 a sheet metal profile with longitudinal beads in the web wall and with transverse beads, F i G. 2 shows a modified embodiment of a sheet metal profile with transverse beads, FIG. 3 a further modified embodiment of a sheet metal profile with longitudinal beads and Transverse beads, F i g. 4 a sheet metal profile with inclined transverse beads and F i g. 5 a sheet metal profile with transverse beads that have a closed figure or a Form recessed area.

The in Fig. 1 shown sheet metal profile is U-shaped in cross section and can be used, for example, as a stand for the supporting framework of partition walls in prefabricated construction be used. It has a web wall 1 from which two flange surfaces extend 2 extend vertically upwards.

In the web wall 1 there are longitudinal beads that run at a distance from one another 3 provided, which increases the rigidity of the thin-walled sheet metal profile serve in the longitudinal direction.

Transverse beads 4, which extend transversely to the longitudinal direction of the profile, run from the web wall 1 into the flange surfaces 2 and over their entire height.

In the area of the web wall 1, they are arranged at a distance from one another Cross beads 4 are made at the same height as the longitudinal beads 3, so that the cross beads 4 and the longitudinal beads 3 merge into one another.

Both the longitudinal beads 3 and the transverse beads 4 are preferred Arched towards the inside of the profile so that no parts of the bead protrude from the outside of the profile. This design is useful when the sheet metal profile with a second sheet metal profile or with other structural elements such as wall shells. Could the other way round the beads 3, 4 protrude outwards, if in special cases the protrusion the beading inwards is undesirable.

Those extending from the web wall 1 into the paddling surfaces 2 Transverse beads 4 increase the rigidity of the thin-walled sheet metal profile against a lateral one Expanding or compressing the flange surfaces 2.

In the case of the FIG. 2 are at the edges of the flange surfaces 2, edge strips 5 projecting inwardly towards one another are angled, so that a C-shaped profile cross-section is created. The transverse beads 4 run here not completely over the height of the flange surfaces 2, but each end before the upper edge of the flange surface 2 provided with the edge strips 5. In the exemplary embodiment according to FIG. 2 no longitudinal beads are provided in the web wall 1.

A modified embodiment of a C-shaped cross-section The sheet metal profile is shown in FIG. 3. Here are from the edges of the flange 2 after internally projecting profile strips 6 with a semicircular cross section are provided. In addition to the longitudinal beads 3 running longitudinally in the web wall 1, there are also in the flange surfaces 2 longitudinal beads 7 arranged at a distance from one another are provided. All longitudinal beads 3, 7, like the profile strips 6, serve for longitudinal reinforcement of the sheet metal profile.

The transverse beads arranged at a distance from one another in the longitudinal direction of the profile run here from the web wall 1 into the flange surfaces 2 up to the topmost Longitudinal bead 7. All beads are made at the same height and therefore go to the Crossing points into each other. Both in the web wall 1 and in the flange surfaces 2 creates a grid of beads crossing each other at right angles, which are proportionate to the thin-walled sheet metal profile in the longitudinal direction and in the transverse direction a substantial increase Give dimensional stability.

Using the example according to FIG. 4 it is shown that the transverse sinks 4 also run obliquely to a plane lying at right angles to the profiling direction can they for example through the cutting plane in FIG. 4 is represented. The transverse beads 4 can have this inclined course either only in the web wall 1 or only in the flange surfaces 2 or - as in FIG. 4 shown - both in the web wall 1 as well as in the adjoining flange surfaces 2.

With dash-dotted lines in FIG. 4 indicated that the Transverse beads 4 in the flange surfaces 2, for example, also in the opposite direction can run obliquely to the course in the web wall 1, it also being possible is to make the transverse beads 4 forked, d. H. in the web wall 2 extend V-shaped transverse beads, as shown in FIG. 4 with solid lines and are shown with dash-dotted lines.

Further in FIG. 4 shown that the transverse beads 4 either before the upper edge of the flange 2 can end or extend into the edge strips 5 can extend into it. It goes without saying that there is also an intermediate solution is possible in which the transverse beads 4 run out at the upper edge of the web surfaces 2, without extending into the edge strips 5.

An oblique course of the transverse beads 4, as shown in FIG. 4 at different Embodiments is shown, is particularly advantageous if the sheet metal profile in a continuous workflow, for example in a rolling process, with the transverse beads 4 is provided because this results in a rolling embossing process for the transverse beads 4 results.

F i g. 5 generally shows a curved profile of the transverse beads. 4 in a sheet metal profile. In particular, in FIG. 5 shown that the transverse beads 4 and 4 'form a closed figure that extends from the web wall 1 to the two flange surfaces 2 extends into it. An elliptical course is shown the transverse beads 4 or 4 '.

To the left of the in FIG. 5 center line is shown, that narrow transverse beads 4 follow the course of an ellipse that emerges from the web wall 1 extends at an angle of 90 "into the flange surface 2.

To the right of the one shown in FIG. 5 indicated center line is a deeper one Area 8 shown, which is also in the web wall 1 and into the neighboring Flange surfaces 2 extends. In the illustrated embodiment, this is also Area 8 bounded by an ellipse if you look at the web wall 1 and the Flange surfaces 2 handled in one plane thinks.

It goes without saying that other bead shapes also form the edges of deeper lying Can form surface areas.

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Claims (11)

Claims: 1. Sheet metal profile with a U-shaped cross-section for lower ceiling beams, Stand for supporting frame of partition walls in prefabricated construction u dgL, with a web wall, of the two longitudinal edges of the flange surfaces are angled, with in the web wall transverse beads arranged at a distance from one another run transversely to the longitudinal direction of the profile, d a d u r c h g e - indicates that the transverse beads (4) each come from the web wall (1) Extend over at least most of the height of the flange surfaces. 2. Sheet metal profile according to claim 1, characterized in that the transverse beads (4) run out into the free edge of the flange surface (2). 3. Sheet metal profile according to claim 1, characterized in that the transverse beads (4) run out in front of the edge of the flange surface (2). 4. Sheet metal profile according to claim 1, characterized in that the transverse beads (4) are designed at the same height as in the web wall (1) and / or in the flange surfaces (2) longitudinal beads (3 or 7) and that the transverse beads (4) and the longitudinal beads (3,7) merge into one another 5. Sheet metal profile according to claim 1, characterized in that that the transverse beads (4) in the web wall (1) and / or in the flange surfaces (2) inclined run to a plane lying at right angles to the longitudinal direction of the profile. 6. Sheet metal profile according to claim 1, characterized in that the transverse beads (4) run out in edge strips (5) or bow-shaped profile strips (6), which are attached to the protrude inward from the free edges of the flange surfaces (2). 7. Sheet metal profile according to claim 1, characterized in that the transverse beads (4) are curved. 8. Sheet metal profile according to claim 1, characterized in that the transverse beads (4) form a closed figure. 9. Sheet metal profile according to claim 1, characterized in that the transverse beads (4) one extending from the web wall (1) into both flange surfaces (2) Form a closed figure. 10. Sheet metal profile according to claim 8 or 9, characterized in that the inner surface of the closed figure one opposite to the rest of the sheet metal profile Form deeper surface area. 11. Sheet metal profile according to claim 8 or 9, characterized in that the closed figure is an ellipse. The invention relates to a sheet metal profile with a U-shaped cross section for sub-ceiling beams, stands for supporting frameworks of partition walls in prefabricated construction and the like, with a web wall, angled flange surfaces from the two longitudinal edges are, with transverse beads arranged at a distance from one another in the web wall transversely to Run in the longitudinal direction of the profile. Since such sheet metal profiles have load-bearing functions in most applications have to meet, the rigidity of the profile should be as high as possible. on the other hand the sheet thickness should be chosen as small as possible in order to simplify the production, to keep the weight low and to keep the material requirements as low as possible. These two requirements can only be met by the profile stiffness Achieve increasing structural design of the sheet metal profiles. So it is known (DE-OS 30 31 381), transversely to the longitudinal direction of the profile to provide running beads in the web wall, because it was recognized that the border the resilience of the partition wall to pressure and thrust in many applications the represents the decisive limit for the load-bearing capacity of the entire sheet metal profile. Due to the known transverse beads, it is possible to use a relatively small sheet metal thickness a substantial stiffening of the web wall against pressure and shear loads reach. However, it has been shown that in many applications the limit the permissible load is determined by a change in shape of the profile cross-section is, namely by a lateral spreading or pressing together of the two im Initial state parallel flange surfaces. This can be the case with sheet metal profiles, for example occur in which the free edges of the flange surfaces with inwardly angled Edge strips are provided so that a C-shaped profile cross-section is created. These Edge strips are used in many cases to transfer load-bearing forces, for example if the sheet metal profile is used as a sub-ceiling beam, a slight amount of springing back is required the flange surfaces would jeopardize the secure suspension of the suspended ceiling beam. The object of the invention is therefore to provide a sheet metal profile of the initially to train named genus so that with relatively small sheet thicknesses a high dimensional rigidity of the sheet metal profile, also against lateral deformation of the flange surfaces given is. This object is achieved according to the invention in that the transverse beads in each case from the web wall up to at least the greater part of the height of the flange surfaces extend. This reduces the flexural rigidity of the flange surfaces against a lateral one Deformation significantly increased, and not only in the area of the flange surfaces themselves, but in particular also at the transition edge between the web wall and the flange surface. The transverse beads can be in the free edge of the flange surfaces run out or run out in front of the edge of the flange surface, regardless of whether whether an angled or bow-shaped curved one at the edge of the fan surface Edge strip is provided. If in the web wall and / or in the flange surfaces If longitudinal beads are provided, it is advisable to make the transverse beads at the same height how these longitudinal beads and the transverse beads and the longitudinal beads merge into one another allow. This creates a network of oneself in the area of the web wall on the right Corrugations crossing angles, which is essential even with very thin sheet metal Leads to an increase in stiffness.