DE2727159C3 - Shear reinforcement for flat slabs made of reinforced or prestressed concrete on concrete supports - Google Patents

Description

The invention relates to a shear reinforcement for flat slabs made of steel or steel supported on concrete supports Prestressed concrete, consisting of reinforcement elements arranged radially around the columns with for Reinforcing bars running vertically on the ceiling.

A shear reinforcement of this type is already known (»Schweizerische Bauzeitung«, 78th year, issue 18, May 5, 1960, p. 305). In this known shear reinforcement, they radiate around the respective support around arranged reinforcement elements of U-shaped bent reinforcement meshes provided. The reinforcement elements are, similar to the support cages customary in building construction, after the lower reinforcement has been laid on the formwork and form the support of the upper reinforcement layer. The individual U-shaped beings * The reinforcement bars of these reinforcement elements end butt "on the formwork". Special measures for anchoring in the concrete pressure zone are not provided.

Various types of shear reinforcement have already been tested in which the individual Reinforcing bars were anchored with hooks or loops in the concrete compression and tension zone. These Tests have shown that running at right angles to the plane of the panel ends butt on the formwork Shear reinforcement bars are not very effective because the bar ends are exposed to high bending loads heavily constricted concrete pressure zone are not adequately anchored.

The one connected to the U-shaped rebar by spot welding, above the lower one Ceiling reinforcement running horizontal reinforcing bars of the reinforcement elements of the known Shear reinforcement can no longer be used for anchoring in the bending pressure zone because they are too high for this. As is well known, in the extreme case of bending, the distance between the zero line and the pressed, lower plate edge only the order of magnitude of the concrete covering of the steel inserts.

The transfer of forces through an imaginary, radially symmetrical, truss-like support system is thus impossible due to the early failure of the lower truss nodes, which reduces the shear load with this type of reinforcement not at all or only insignificantly compared to the load-bearing capacity of slabs without shear reinforcement can be increased.

The known shear reinforcement also has other shortcomings. Hook and / or loop anchors are only after a significant deformation, the so-called anchoring slip, effective. This allows for reinforced concrete slabs with shear reinforcement that is not anchored without slip failure due to punching occurs before the shear reinforcement contributes to the load transfer. In the same way it also works with slip-free

3> Anchoring too great a stretch of the perpendicular to the Reinforcing bars running across the ceiling. The shear reinforcement cross-section must therefore be used to limit the expansion be chosen relatively abundantly. The use of thick rebar for

• ίο the known reinforcement elements .. · complicates however their manufacture.

The invention is based on the object of providing a shear reinforcement of the type mentioned at the beginning train that despite a short rod length the

■ Γι vertically extending reinforcing bars a perfect slip ¹ free introduction of force or anchoring in the concrete pressure and tension zone is achieved.

According to the invention, this object is achieved in that the / ur ceiling surface vertical reinforcement

) 0 reinforcement bars 1 of each reinforcement element at their im When installed, ends facing the top of the ceiling each with a conical or truncated pyramidal head 2, and with their lower ends on a flat steel 3

Ί5 are welded on, which in the installed state within the Thickness of the concrete cover of the lower bending reinforcement is arranged and dowel-like in the Stüt / concrete intervenes.

The reinforcement welded onto the flat steel

hi) rods can also be slightly inclined if necessary.

The design according to the invention is a simple installation of the reinforcement elements themselves and the relatively close-meshed, multi-layer bottom * fen and upper bending reinforcement given. The BeWeIv

hi rungs elements encompass the lower and upper Bending reinforcement. By welding these ends perpendicular or slightly inclined to the ceiling surface Reinforcing bars with the in the concrete cover

embedded flat steel is the introduction of force on The lower end of the bar fully guarantees the shear reinforcement can function as a truss post regardless of the constriction of the concrete pressure zone Take over. When concreting and compacting the concrete, the inclined cone or The pyramidal surfaces of the heads of the reinforcing bars do not form any porous areas because of the rising air bubbles or rising water does not settle or accumulate here, but due to the inclination is forwarded to the ceiling surface. This is the full connection of the thickened rod head In the concrete, forces from the reinforcement elements can be guaranteed without slipping on the concrete be delivered.

The cross-section of the reinforcing bars can be as desired, depending on the static or design requirements be adjusted.

It can e.g. B. to reduce the rod elongation and relatively thick rods can be selected without that this affects the introduction of force.

The flat steels are advantageously bundled in flat lengths of several meters for Brought to the construction site and cut to the required length here. Since the flat steel (with a thickness of about 1 to 2 cm) is arranged within the concrete cover of the lower bending reinforcement bars, the Lower and upper bending reinforcement is simply inserted from above or on supports be dropped off; be discontinued; be deducted; be dismissed. Reinforcement meshes can also be used Lay in the support area, as there is practically no obstruction due to the thickened heads is.

The reinforcement elements are arranged around the column head so that in plan seen the flat bars reach a few centimeters into the column area. Put the flat steel ends thus an additional dowelling between the ceiling and the support, the more effective the better the support area on the column concrete is secured by additional brackets on the column.

At the same time, the flat steels with their relatively large cross-section contribute significantly Relief of the bending pressure zone of the concrete in the immediate column area. Thus, with the Shear reinforcement according to the invention, the failure of the bending pressure zone as a reason for punching through (Shear pressure break) can be better prevented. There are therefore similar load-bearing struts as with mushroom ceilings Mushroom reinforcement available.

Advantageous configurations of the shear reinforcement according to the invention are the subject matter of claims 2 until 6.

Embodiments of the invention are shown in the drawing. It shows

Fig. La and Ib part of a reinforcement element in longitudinal view and cross-section,

F i g. 2 a longitudinal view of a shear reinforcement,

3 shows a cross section through a reinforcement element with a special embodiment for thermal protection.,.

F1 g. 4 the connection of the reinforcement elements to the Support and

F i g. S a top view of the shear reinforcement.

According to Fig. La and Ib there is a Bewehliingselemenl from the vertical reinforcing bars 1

with the truncated cone or truncated pyramidal heads 2 and the flat steel 3.

The reinforcing bars 1 are connected to the flat steel S by welding 2a. The length of the reinforcement element or the distance between the reinforcing bars 1 depends on the thickness of the flat slab. The flat steel 3 is protected on its underside against corrosion and / or the effects of heat by a protective layer 4. Normally, an appropriate coat of paint or the concrete cover is sufficient.

The flat steel 3 is fastened to the formwork 6 with a few nails 5 or stainless pins, whereby the reinforcement elements are secured against falling over. The flat steel 3 including the Protective layer 4 lies within the concrete cover of the lower slab reinforcement. The surface of the heads 2 In the embodiment shown here, the reinforcing bars have the same concrete cover as the upper bending reinforcement. The concrete cover of the heads 2 can, however, also be selected to be less or completely can be omitted, as in Fig. 4 '.' . is the Surface of the heads 2 can in this case a corresponding paint 4a are protected.

In Fig. 2 is the position of zv / egg reinforcement elements on both sides of the support 9 in a longitudinal view! The three vertical reinforcing bars 1 pierce the outer surface of the punching cone 8. The end 3a of the flat steel 3 on the support side engages, as in FIG. 4 and 5 shown in the Support area. F i g. 4 also shows the support area of the additionally secured by bracket 15 Flat steel 3. The protective layer 4 on the underside can be omitted here depending on the type of design. The upper and lower bending reinforcement 12 and 13 of the flat slab each lie above the flat bar 3 or under the heads 2 with the required concrete cover 10 or 11. The width of the flat bars 3 is in this embodiment chosen so that they still have a few centimeters between the vertical reinforcement rods 14 of the support 9 can be pushed through.

Ir FIG. 3 is used as a protective layer 4 for the flat bar 3 a U-shaped asbestos profile is provided, so that the flat bar is particularly good at protecting against the effects of heat is protected. The asbestos profile is here by a corresponding interlocking with the surrounding Concrete connected.

The truncated cone or truncated pyramidal heads 2 can be machined in a known manner be upset. The base area of the heads 2 is expediently 5-10 times the rod cross-section. The inclination of the conical or truncated pyramidal heads 2 can vary depending on the manufacturing process and dimensional ratios between about 10 ° -40 ° can be selected.

The reinforcement bars 1 are expediently also machine welded onto the flat bars 3, for. B. in a similar way to the so-called head bolt dowels in Stahlverb'ind Konstruktionseii. If necessary, the reinforcement rods 1 can also be welded to the flat steel 3 at an angle other than 90 °, or only later bent to the desired angle at the construction site. This enables extensive adaptation to structural inaccuracies.

For this purpose 2 sheets of drawings

Claims (6)

Patent claims: 1. Shear reinforcement for flat slabs made of reinforced or prestressed concrete supported on concrete columns, consisting of reinforcement elements arranged radially around the columns with the ceiling surface vertically extending reinforcing bars, characterized in that the reinforcing bars (1) perpendicular to the ceiling surface each reinforcement element at its ends directed towards the top of the ceiling in the installed state each with an upwardly thickening, conical or truncated pyramid-shaped head (2) are provided, and are welded with their lower ends on a flat steel (3), which in the installed state is arranged within the thickness of the concrete cover of the lower bending reinforcement and dowel-like engages in the supporting concrete. Z shear reinforcement according to claim 1, characterized in that the vertical reinforcing bars (1) atb head bolt dowels are formed and shot onto the flat steel (3). 3. shear reinforcement according to claim 1 or 2, characterized in that the flat steel (3) with Holes for attachment to the formwork is provided 4. shear reinforcement according to eirem of claims 1 to 3, characterized in that the flat steel (3) has corrosion protection and / or heat protection on its underside 5. shear reinforcement according to claim 4, characterized in that the thermal protection of the flat steel (3) consists of a U-shaped asbestos profile, which when installed in the concrete is anchored. 6. shear reinforcement according to one of claims 1 to 5, characterized in that the conical or truncated pyramidal heads (2) wholly or partially within the upper concrete cover are arranged and their surfaces, which may not be covered with concrete, have corrosion protection.