DE1132701B - Welded steel girder of? -Shaped cross-section with hollow flanges - Google Patents

Description

I-shaped cross-section welded steel beam with hollow flanges Rolled profiles with I-cross section are because of their relative to the bending stiffness low torsional and warping stiffness often endangered by lateral torsional buckling and tilting. It is known that for I-beams those specified in the official regulations permissible tensions can often not be exploited if the tilting length is the same as the system length because the stability specified in the stability regulation then is not achieved. Often a must because of compliance with the tilt security A significantly stronger 1-profile can be selected than the dimensioning according to the permissible one Would allow tension (see "Stahl im Hochbau", 12th edition, p. 491).

It is well known that the security against tipping can be increased significantly when used of closed box girders, which are bent because of their double-walled construction Construction can usually not be used so cheaply. That's why you have I-shaped ones Beams with hollow flanges constructed in such a way that an isosceles angle profile welded with the angle tip on a web plate and the two free edges of the Angle legs were connected with a lamella. This creates a flange the I-shaped beam is a triangular box girder. It has been found to be disadvantageous in this regard found that the weld joint between the web plate and the angle tip on a particularly at risk of segregation, which can lead to brittle fractures. An improvement was achieved by using two inclined angles instead of the angle Has used flat steels, with the web plate carried through to the upper cover lamella became.

The invention consists in the fact that for reasons of increased torsional rigidity hollow flanges of the I-shaped beam do not consist of two or three Divide, but each from a single, multiple angled, work-hardened Strip steel exist and an almost equal increase in the yield strength at every point in their cross-section have (Fig. 1).

If so far the flanges of solid wall girders have been used to increase economic efficiency be made of high-strength material compared to the less stressed web should, this was only remunerated in a metallurgical sense, i.e. H. alloyed Structural steel achieved. In contrast, the carrier according to the invention consists chemically from one and the same material. One and the same enamel analysis can therefore be used for Web plate and flanges can be used. Of the three hot strips for production of the hollow flange beam, two become hollow boxes in this way during cold profiling solidified that the yield strength increase for the entire flange is almost the same is effectively achieved. With cold profiling, there is not necessarily also one for the design usable reinforcement must be connected. There are numerous cases known, in which steel sheets or steel strips were cold-formed into profiles, without any significant or any increase in the yield strength being determined could become. Or the yield strength increases were on the narrowest range of the Deformation point of a profile localized, so that it is in the sense of a solidification of the overall profile could not be used. In many cases it has even been the case with one Cold deformation occurred and hardening associated with embrittlement as viewed as disadvantageous and undesirable. Prerequisite for an economic and Work hardening that takes safety requirements into account is therefore the choice a metallurgically suitable melt analysis (e.g. for the production of tough steel with significantly lower admixtures of the undesirable iron companions of steel), the rolling of the steel strip on a suitable, known strip rolling train, which Manufacture tapes with high elongation at break allows, and the Restriction to thin sheet metal.

Not necessarily given in cold profiling, but but achievable, almost uniform increase in the yield strength can be achieved for the flanges of the I-shaped hollow flange girder increased service stresses, as otherwise only apply to alloyed material. The economic height and The thickness of the web plate results from the buckling resistance and that for the unconsolidated Structural steel of the non-profiled web plate prescribed permissible stress at the transition from the web to the hollow flange.

In the case of high-web hollow flange girders, the ratio of web plate height to total profile height can be greater than the ratio of normal permissible service stress to permissible service stress that is increased due to strain hardening, e.g. B. In these cases, the increased permissible stress of the work-hardened hollow flanges can still be used if the open ends of the hollow flanges are angled obliquely or at right angles to the carrier zero line so that they still form part of the web (Fig. 2, 3). In the latter case, too, the connection can be solved very well in terms of welding technology and construction, because the economic thickness of the web plate is roughly twice the thickness of the flange profile.

With only two or three different work-hardened hollow flange dimensions and corresponding web plate heights and thicknesses, a series can be made economically set up of I-hollow flange girders, which the normal profile series by the essential lower weight and increased stability due to greater torsional and Warping stiffness is superior with the same flexural strength.

In cases where an even greater torsional and warping stiffness is required as they already have a hollow flange I-profile according to the invention has, it does not present any difficulties in terms of production and technical rolling Extra costs to modify the work-hardened hollow profile in such a way that the web is also hollow, d. H. is double-walled, so that the work-hardened hollow profile row is still can be used more universally (Fig. 4).

The hollow flanges or those with hollow web and hollow flanges trained, work-hardened double I-profiles can be used in addition to their static Also use the function for conveying gases or liquids. So you can z. B. with hollow beams according to the invention, which are used as purlins in halls, direct the warm air of the heater through the hollow profiles, whereby the less stressed Outlet openings for the warm air are to be provided at certain intervals.

An even further increase in load-bearing capacity with increased profitability can be achieved by filling one or both of the hollow flanges with load-bearing concrete reach. Especially through the combination and composite effect of work-hardened As tests have shown, hollow cross-sections with concrete can improve the load-bearing capacity increase quite considerably. If the permissible values are different for tensile and compressive loads Voltages are prescribed (this is intended for the new version of DIN 1050), can make this particularly easy by varying the thickness of the hollow flanges taken into account in tension and compression (Fig. 5). In contrast, the I-normal profile series the more favorable higher permissible tensile stress due to the symmetry of the profile are not used.

Embodiments of the invention show the drawings, namely Fig. 1 shows a welded steel beam with multiple angled, work-hardened hollow flanges 1, 2, the open ends of which are welded to a web plate 3 at 4, 5 are, Fig. 2 the same with oblique and for. 3 with at right angles to the carrier zero line angled and part of the web forming ends of the hollow flanges.

In Fig. 2 the upper hollow flange is filled with concrete 6.

Fig. 4 shows a support profile with a double-walled web 3 a, 3 b, Fig. 5 a profile with hollow flanges of different thicknesses in the tension and compression area to have; Fig. 6 shows a profile with one up to the outer flanges of the hollow flanges guided web plate 3 c; Fig. 7 to 9 show series of hollow profile beams according to Invention with three different hollow flanges, each of which with z. B. four different Web sizes can be composed.

Claims (7)

PATENT CLAIMS: 1. Welded steel beam of I-shaped cross-section with hollow flanges, characterized in that the hollow flanges (1, 2) consist of Multiple angled work-hardened strip steel of small thickness exist, whose Steel grade is chosen so that the flanges after the rolling and profiling of the Ribbon at every point of its cross-section an almost identical significant increase in the yield strength exhibit. 2. Welded steel girder according to claim 1, characterized in that that the sheet metal band edges of the flanges are connected to a single-walled web plate (3) which is not work-hardened. 3. Welded steel beam according to claim 1 or 2, characterized in that the sheet metal strip edges of the flanges are inclined (Fig. 2) or angled in the web (Fig. 3) are brought up to the web plate. 4. Welded steel beam according to claim 1, characterized in that the sheet metal edges of the flanges angled approximately in the third points of the flange width and with two Web plates are connected to form a closed box (Fig. 4). 5. Welded Steel beam according to one of Claims 1 to 4, characterized in that the flanges have different sheet thicknesses (Fig. 5). 6. Welded steel beam according to claim 1, 2, 3 or 5, characterized in that the Web plate for stiffening is passed through the cavity of the flanges (Fig. 6). 7. Welded steel beam -according to claim 1, 2, 3 or 5, characterized in that at least one of the Flanges is filled with concrete. Publications considered: German patent specification No. 449 633; German patent application P 2054 V / 37 b (published on March 3, 1956).