DE29505968U1 - Steel composite beams - Google Patents

Description

- 2 Description:

Steel composite beams of the usual design consist of a double-T-shaped steel profile and a reinforced concrete slab, with the upper flange of the steel profile either inside or directly under the underside of the slab. Newer steel composite beams (82 03 302.1) have a T-shaped steel profile, with the web being arranged above the flange and protruding into the reinforced concrete slab. In this composite beam variant, the reinforced concrete slab completely takes over the function of the steel upper flange, so that this is no longer necessary. Since special measures are required for these beams to ensure stability during transport and installation, this composite beam variant has not yet become generally accepted.

Steel composite beams of the usual design have headed bolts or block dowels as connecting elements that serve to transfer the shear forces from the reinforced concrete slab to the steel beam. Both types of dowel are welded onto the upper flange of the double-T-shaped steel beam and onto both sides of the upper web edge of the T-shaped steel beam. Block dowels are hardly used anymore because of the complex welding work involved. Welding the headed bolts requires expensive electrical equipment.

In order to introduce more economical bonding agents, reinforced concrete dowels have been developed and tested. These dowels form as concrete cores within the reinforced concrete slab in the area of recesses in the steel beam, whereby shear reinforcement (5, 10, 16) is first inserted into the recesses (3, 8, 14), and then the space between the recess wall and the reinforcement is filled with concrete. The clear width between the recess wall and the reinforcement must be larger than the largest grain of concrete. This creates two-section, dowel-like connections made of reinforced concrete in the recess area, which create the bond between the reinforced concrete slab and the steel beam.

The recesses are designed either as circular openings (Perfobond strip) or as pear-shaped cuts (3, 8, 14) open to the web edge. Threading the reinforcement into the openings is time-consuming; in the case of cuts, however, the shear reinforcement (5, 10, 16) can be inserted quickly and easily. This type of doweling using recesses in the steel beam is particularly suitable for steel composite beams with T-shaped steel profiles.

The load-bearing capacity of reinforced concrete dowels depends on the quality of the concrete and the reinforcement, as well as on the size of the recess. Larger reinforced concrete dowels are able to transfer correspondingly larger shear forces. The forces are initially absorbed by the smallest steel cross-section in the area between the recesses on the way into the steel web. Larger shear forces require larger distances between the recesses or thicker web plates. This means that there are limits to the cost-effectiveness of reinforced concrete dowels, particularly with T-shaped steel profiles.

The invention mentioned in claim 1 aims to double the load-bearing capacity of the known reinforced concrete dowels, based on the length of the beam, by aiming for a two-row arrangement. For this purpose, recourse is made to the double-T-shaped steel profile (1). According to claim 1, the recesses (3) required for the reinforced concrete dowels are arranged in the upper flange (2) on both sides of the beam web, whereby the number of reinforced concrete dowels is doubled compared to the possible arrangement with the T-shaped steel profile with the same distance between the recesses. The objection that a T-shaped steel beam is superior to the double-T beam in terms of material requirements is countered by pointing out the significantly increased overall load-bearing capacity of the connecting elements, based on the length of the beam with the double-T profile. The increased shear load-bearing capacity means that the object of the invention penetrates into load areas that are not accessible to the T-shaped steel beam with its recesses for reinforced concrete dowels.

An advantageous embodiment of the invention is specified in claim 2 .

In this variant, the upper flange is bent lengthwise, whereby the legs (7), which have recesses (8) as in claim 1, run diagonally upwards within the reinforced concrete slab (9). Since bending the upper flange with a rolled double-T profile is technically problematic, it is recommended to use a sheet steel support in which the upper flange sheet is bent after the recesses have been fired and, if necessary, subjected to a heat treatment. It is also possible to use a rolled angle bar (7) as the upper flange.

The inclined guidance of the two legs (7) of the upper flange ensures that the reinforcement (10) to be inserted into the recesses (8) can be laid horizontally. It is also advantageous that one reinforcement bar (10) penetrates two opposite recesses (8) at the same time. As a rule, the lower reinforcement layer of the reinforced concrete ceiling slab can also be used as shear reinforcement for the reinforced concrete dowels, which allows additional material savings in the reinforcement of the steel composite beams according to the invention.

A further variant of the invention is expressed in claim 3.

In this case, a horizontal U-profile (12) is used as the upper flange of a steel sheet girder, the flanges (13) of which have recesses (14) as in claim 1 and are directed upwards within the reinforced concrete slab (15). Both a double-edged steel sheet and a rolled U-profile can be used as the U-profile. The profile is welded to the upper web edge of a T-shaped steel girder (11) in the middle of the web. The steel girder combined in this way can be used in conjunction with the reinforced concrete slab (15) in such a way that the lower edge of the U-profile (12) is flush with the lower edge of the reinforced concrete slab (15). The arrangement of the shear reinforcement corresponds to the reinforcement layout according to claim 2. The technically more favorable weldability of the U-shaped upper flange to the web of the T-shaped steel girder (11) proves to be an advantage over the variant according to claim 2.

The invention is explained in more detail using embodiments with reference to the accompanying drawings.
The drawings show:

Figure la is an isometric view of a double-T-shaped steel beam (l) with a flat upper flange (2) running at right angles to the beam and provided with pear-shaped recesses (3) arranged on both sides of the web.

Figure Ib shows the cross-section of the double-T-shaped steel beam (1) showing the reinforced concrete slab (4) enclosing the upper flange and the shear reinforcement (5) inserted in the recesses (3),

Figure 2a is an isometric view of a T-shaped steel sheet beam (6) with an angle bar welded along the upper edge of the beam web, the upwardly directed legs (7) of which are provided with pear-shaped recesses,

Figure 2b shows the cross-section of the T-shaped steel beam (6) combined with an angle profile (7) showing the reinforced concrete slab (9) enclosing the angle profile (7) and the shear reinforcement (10) inserted into the recesses (8),

Figure 3a is an isometric view of a T-shaped steel beam (11) with a horizontal U-profile (12) welded along the upper edge of the beam web, the upwardly directed flanges (13) of which are provided with pear-shaped recesses (14),

Figure 3b shows the cross-section of the T-shaped steel beam (11) combined with a horizontal U-profile (12) showing the reinforced concrete slab covering and filling the U-profile (15) and the shear reinforcement (16) inserted into the recesses (14).

Claims (3)

protection claims; 1. Steel composite beam with a steel profile (1) in the shape of a double T-beam, the upper flange (2) being arranged in the area of the reinforced concrete slab, characterized, that the upper flange is flat and at right angles to the support web , and that recesses (3) are provided in the upper flange on both sides of the web to accommodate the shear reinforcement (5), whereby the clear width between the recess wall and the inserted reinforcement is larger than the diameter of the largest grain of the concrete and thus in the recess area two-cut, dowel-like connections made of reinforced concrete bring about the bond between the reinforced concrete slab (4) and the steel profile (1), 2. Steel composite beam according to claim 1, characterized in that that the upper flange is bent lengthwise at the web attachment and the legs (7), which have recesses (8) as in claim 1, point obliquely upwards within the reinforced concrete slab (9). 3. Steel composite beam according to claim 1, characterized in that that the upper flange (12) is a horizontal U-profile, the flanges (13) of which, which have recesses (14) as in claim 1, are directed upwards within the reinforced concrete slab (15).