DE8502754U1 - Steel composite beams - Google Patents

Description

Steel composite beams

The invention relates to a steel composite beam with a steel profile to which a shear reinforcement is assigned, which is anchored in the steel concrete ceiling slab, wherein the steel profile corresponds to a halved double-T beam. whose flange is located below the reinforcement of the reinforced concrete slab and whose web points vertically upwards. The shear reinforcement creates a force-locking connection between the concrete slab and the upper end of the steel web.

Steel beams are used to support large loads. Double-T beams are used as steel profiles, with their upper flanges located within the reinforced concrete ceiling slab or directly under the ceiling slab. It is possible to use rolled double-T profiles instead of welded sheet metal supports. The Top flanges are generally underutilized. With the intention of making steel composite beams available that require a relatively low steel weight and that easily provide a favorable connection between reinforcement and steel beams, steel composite beams have become known whose steel profile corresponds to a halved double-T beam, the flange of which is arranged below the reinforcement of the reinforced concrete slab and the web of which points vertically upwards and forms a force-fit connection between the concrete slab and the upper steel web. It is known that at the upper end of the steel web head

bolts are welded laterally in one or more rows.

It is also known that the upper steel web is provided with holes through which the shear reinforcement runs. In particular, this embodiment of a steel composite beam encounters difficulties during practical assembly. For example, threading reinforcement bars through holes in the steel profile takes a relatively long time, and larger reinforcing bars cannot be handled, for example,

if there are spatial restrictions for other reasons, so that not every type of steel reinforcement can be used.

The invention is therefore based on the object of improving a steel composite beam of the type mentioned at the outset in such a way that the time required for assembly is reduced and other restrictions with regard to the space available and with regard to the type of reinforcement are avoided.

The invention consists in the fact that in a beam of the type mentioned at the beginning the upper end of the steel web has recesses into which reinforcing bars can be inserted.

The recesses consist of slots extending from the upper edge. To ensure a good bond, the contours of the recesses are adapted to the reinforcing bars to be inserted.

According to a further development, the invention proposes that the clear width of the recesses corresponds exactly to the outer circumference of the reinforcing bars to be inserted or is slightly smaller, so that a snug fit is created when the composite reinforcement is hammered in with a hammer.

A further development of the invention is that the steel web is divided into exactly two separate webs that run parallel and at a distance from one another. An advantageous embodiment of the invention is that the reinforcements extend from the recesses at different levels parallel to the ceiling.

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In order to be able to use structural steel mats, it can be provided that the distance between the recesses corresponds to the distance between the reinforcement bars of the structural steel mat to be inserted.

In order to be able to use a halved neck profile on the one hand and still have a large lever arm for jointing on the other, the invention proposes in its further development that the upper end of the steel web ends below the underside of the ceiling and that reinforcement connections lead from the recesses in the upper end of the steel web to the ceiling reinforcement in the form of stirrup reinforcements in the ceiling.

The connecting reinforcements can advantageously consist of loops that lead around the roof reinforcements, or the ceiling reinforcements can lead in the form of loops through the recesses at the upper end of the steel web.

According to an advantageous embodiment, the connecting reinforcement can run continuously from recess to recess along the web. The connecting reinforcement can be provided in the form of a spiral, with the individual turns being pressed into the successive recesses at the top of the steel web and being guided through the plate reinforcement at the top.

According to one embodiment, the distance between the upper end of the steel web and the underside of the ceiling will be at least as large as the length of the steel web.

A practical embodiment consists in an additional reinforcement in the form of a net running from the ceiling, enclosing the connecting reinforcement and the beam, below the flange of the beam back to the ceiling.

Advantageously, the reinforcement to be inserted into the recess in the steel web can be supplemented by additional reinforcement.

The invention also provides a method _for producing the composite beam. The special feature is that the beam is surrounded by a reinforced concrete shell up to the level of the underside of the ceiling slab, with the upper part of the steel web protruding.

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that the beam with reinforced concrete is transported to the construction site as a prefabricated part and assembled and that the ceiling plate with reinforcement is then installed. If the steel web does not reach the underside of the ceiling slab, the prefabricated part is provided with a connecting reinforcement, which is then made of the concrete shell asks her questions.

The invention will be explained in more detail using the exemplary embodiments with reference to the attached drawings. The drawings show:

Fig. 1 shows the side view of a beam with recesses at the upper end of the steel web; Fig. 2 shows a cross-section of a beam according to Fig. 1; Fig. 3 shows a cross-section corresponding to Fig. 1, 1§ but with the web divided into two laterally parallel

divided into separate partial webs;

Pig. 4 a beam according to Pig.1, in which a steel mesh is inserted; Pig. S a steel composite beam with reinforcement bars

at different levels;

Fig. 6 a steel composite beam with additional reinforcing bars;

Fig. 7 the top view of a beam according to Pig.1 with a loop-shaped reinforcement insert j

Fig. 8 shows an embodiment with a support in which the upper end of the steel web ends below the underside of the ceiling;

Fig. 9 shows an embodiment according to Fig. 8 with additional reinforcement;

Fig. 10 a beam with a spiral connecting reinforcement; and
Fig. 11 a view of the carrier from the direction

"A" in Fig. 10.

_Fig . 1 shows a halved double-T-beam 1, which has recesses 2 at the upper end of a steel web 3. The recesses 2 are designed according to the required reinforcement bars for the steel composite beam

arranged.

In this way, as can be seen in particular in Fig. 2, reinforcing bars 5 can be inserted into the recesses 2 at the upper end of the steel web 3 without difficulty; even longer lengths of reinforcing bars do not cause any difficulties. This enables rapid assembly .

In the case of a very high shear force load having to be met with a low construction height, the invention proposes that the web ₃ is divided into two webs 3a and 3b which extend upwards from the flange 4 at a parallel distance from one another and have recesses 2 at their upper end in which the common reinforcing bar S is placed.

i& An advantageous embodiment of the invention is shown in Fig. 4. The distance between the recesses 2 at the upper end of the web 3 is selected so that it corresponds to the distance between the bars 5 of a structural steel mat 8, so that this can be inserted into the support 1 without difficulty.

Fig. 5 shows a composite beam with a factory-made reinforced concrete shell in conjunction with large-area slabs 9 as lost ceiling formwork, in the recess 2 at the upper end 26 of the steel web 23 runs a connecting reinforcement 28 to the slab reinforcements 25 present in the ceiling 20.

The connecting reinforcement 28 consists, as shown in Fig. 8, of a loop which leads around additional reinforcements 29. However, it is also possible for the plate reinforcement loops 25 ³ ^ to lead directly in a loop-like manner through the recesses 22 at the upper end 26 of the steel web 23.

As shown in particular in Fig. 9, the distance between the upper end 26 of the steel web 23 and the underside 27 of the cover 20 is approximately equal to the length of the ³ ^ steel web 23, but can also be even greater. In this way, the material savings of a halved roller profile can be achieved, and nevertheless a

large lever arm of the length of the distance between flange 24 and ceiling 20 made available.

As can be seen from Fig. 9, an additional reinforcement 30 can be provided which encloses the connecting reinforcement 28 and the beam 23, 24. The additional reinforcement 30 runs from the ceiling 20 along the outside of the additional reinforcement 28 and below the beam flange 24 and back to the ceiling 20. In Fig. 10, a beam 24 is shown which has a connecting reinforcement 32 which extends continuously from one recess 22 to the adjacent recess 22 in the web 23 of the beam 24. As can be seen from Fig. 11 , the reinforcement 32 has the shape of a spiral, with the turns of the connecting reinforcement 32 at the bottom in

IB the successive recesses 22 are pressed into the upper end 26 of the steel web 23 and are guided at the top by the plate reinforcements 25 (not shown).

When producing the composite beam described, the beam 4 is provided with a reinforced concrete casing 33, as shown for example in Fig. 5, up to the height of the ceiling slab 20 or 34, as shown in Fig. 8 or 5. The web 3 with its recesses 2 protrudes from the concrete casing 34 at the top. The part prefabricated in this way is transported to the construction site,

^2ö is mounted, ie brought into position, and the ceiling plate 20 or 34 with the plate reinforcements 25, 27 or 5a, 5b is then applied.

In the case that the carrier 21 has a shortened steel web 23 of halved roller profile, as

^O As Figs. 8 and 9 show, the beam 21 with its flange 24 and web 23 is also provided with a reinforced concrete casing up to the level of the underside of the ceiling slab 20, with the upper part of the additional connecting reinforcement 28 protruding from the concrete casing. The assembly is then carried out as described above.

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It is clear that the measures according to the invention make it much easier to attach reinforcements, whereby different types of reinforcement can be used without difficulty and a halved roller profile can be used to save material by making a large lever arm available. By producing the beam with reinforced concrete casing as a prefabricated part, the manufacture of the steel composite beam is made much easier.

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Steel composite beams

In a steel composite beam with a steel profile to which shear reinforcement is assigned, where the steel profile corresponds to a halved double-T beam, the flange of which is arranged below the reinforcement of the reinforced concrete slab and the web of which is vertically v-? and a force-fit connection is provided between the concrete slab and the upper end of the steel web, the upper end of the steel web has recesses into which reinforcing bars are inserted. If the upper end of the steel web ends below the underside of the ceiling, connecting reinforcements lead from the recesses at the upper end of the steel web to the ceiling reinforcements. The beam, with connecting reinforcements if necessary, is manufactured with a concrete shell as a prefabricated part.

Claims (15)

it* \ BLUMBAQH · WgBlR · BiRSgN*'KRAMER " / ZWIRNER. HOFFMANN EUROPEAN PATENT ATTORNEYS IN WIESBADEN IN MDNCHEN P. G. BLUMBACH DIPMNG. PATENT ATTORNEY R. KRAMER DIPL-ING. PATENT ATTORNEY P. BERGEN PROFESSOR DR. IUR. DIPL-ING. W. WESER DIPL-PHYS. DR. RER. NAT. PATENT ATTORNEY G. ZWIRNER DIPL-ING. DIPl.-W.-ING. PATENT ATTORNEY E. HOFFMANN DIPL-ING. PATENT ATTORNEY Dipl.-Ing. Irmfried Brendel Obermattweg 18, 7847 Badenweiler Protection claims 1. Steel composite beam with a steel profile, to which a shear reinforcement is assigned, whereby the steel profile corresponds to a halved double-T beam, the flange of which is below the reinforcement of the reinforced concrete slab is arranged and the web points vertically upwards and a force-locking connection is provided between the concrete slab and the upper end of the steel web ^is ' (26) characterized in that the upper end of the steel web (3) has recesses (2) which are inserted into the reinforcement irons (5). 2. Steel composite beam according to claim 1, characterized in that the recesses (2) consist of slots extending from the upper edge of the steel web (3). 3. Steel composite beam according to claim 1 or 2, characterized in that the contour of the recesses (2) is adapted to that of the reinforcing iron (5) to be inserted. 4. Steel composite beam according to claim 3, characterized in that the clear width of the recesses (2) corresponds exactly to the outer circumference of the reinforcing iron (5) to be inserted or is slightly smaller, so that a snug fit is created. 5. Steel composite beam according to one of claims 1 to 4, characterized in that the steel web (3) is divided into two separate, spaced-apart, parallel web sections (3a, 3b). 6. Steel composite beam according to one of claims 1 to 5, characterized in that the reinforcements (5a, 5b) extend from the recesses (2) of the steel webs (3) in different planes parallel to the ceiling profile. 7. Steel composite beam according to one of claims 1 to 5, characterized in that a reinforcing steel (11) is inserted in the recesses (2) in a loop-like manner. 8. Steel composite beam according to one of claims 1 to 5, characterized in that the spacing of the recesses (2) corresponds to the spacing of the reinforcing bars (5) of a structural steel mat (8) to be inserted. 9. Steel composite beam according to one of claims 1 to 7, characterized in that the upper end (26) of the steel web (23) ends below the underside (24) of the ceiling (20) and that connecting reinforcements (28) lead from the recesses (22) in the upper end (26) of the steel web (23) to the plate reinforcements (25). 10. Steel composite beam according to claim 9, characterized in that <the connecting reinforcements (28) consist of loops which lead through the recess (132) in the steel web (23) and through the plate reinforcements (25). 11. Steel composite beam according to claim 9 or 10, characterized in that the connecting structure (32) runs continuously from recess (22) to recess (22) along the web (23). &bull;&bgr; «V 12. Steel composite beam according to claim 11, characterized in that the connecting reinforcement (32) has the shape of a spiral, the individual turns being inserted into the successive recesses (22) at the upper end (26) the steel webs (23) are pressed in and are guided at the top through the plate reinforcement (2S). 13. Steel composite beams «see them*! 4«? Claims 9 to 12, characterized in that the distance between the upper end (26) of the steel web (23) and the underside (27) on the ceiling (20) is at least as large as the length of the steel web (23). 14. Steel composite beam according to one of claims 1 to 13, ^ _61n characterized in that the reinforcement (5, 28) to be inserted into the recesses (2, 22) is supplemented by an additional reinforcement (10, 30). 15. steel composite beam according to one of claims 11 to 14, characterized in that the additional reinforcement (30) extends from the ceiling (20), enclosing the connecting reinforcement (28) and the beam (23, 24), below the flange (24) back to the ceiling (20).