EP2024580A1

EP2024580A1 - Planar concrete supporting structure and method of producing it

Info

Publication number: EP2024580A1
Application number: EP07718471A
Authority: EP
Inventors: Johann Kollegger; Stefan L. Burtscher; Andreas Kainz
Original assignee: Technische Universitaet Wien
Current assignee: Technische Universitaet Wien
Priority date: 2006-05-30
Filing date: 2007-05-30
Publication date: 2009-02-18
Also published as: WO2007137318A1; RU2008151996A; US20090301011A1

Abstract

A planar concrete supporting structure, in particular a reinforced-concrete supporting structure, such as a reinforced-concrete floor, characterized by the combination of the following features: • a concrete slab (1), the thickness (D) of which is less than the overall thickness of the concrete supporting structure and • intersecting ribs (2) which are each connected with an end region (3) to the concrete slab (1) in a force-transmitting manner and project freely upwards from the concrete slab (1), i.e. without being integrated in a further supporting surface structure, wherein their top end regions (4) are designed to absorb compressive and/or tensile forces and wherein the ribs (2) are each connected to one another in a frictional manner at the intersection points (9) and • their regions lying in each case between the top and bottom end regions (3,4) have at least one aperture (6).

Description

Flat concrete support structure and method for producing the same

The invention relates to a flat concrete support structure, in particular steel concrete support structure, such as a steel-concrete ceiling, and a method for producing the same.

In construction, concrete is indisputably the most suitable material to create flat structures of any shape. Moreover, the construction of reinforced concrete ceilings is extremely simple and economical.

Flat roofs are particularly popular with architects, as they allow easy laying of the lines thanks to the flat ceiling soffit. Only for stiffening massive cores are needed. These flat ceilings can be designed as ceiling with full cross-section (GB 1 284 402 A), hollow ceiling (DE 4 113 028 A1) or ceiling with ■ reinforcements over the supports. The ceiling with full cross-section is made of cast-in-situ concrete or partial precast ceiling (element ceiling). Since the dead weight makes up almost 50% of the ceiling load, it has gone over to producing hollow ceilings. The hollow bodies can be produced in the production process (hollow floorboard) or by displacement bodies during concreting (for example EP 1 350 898 A1). By minimizing weight, the spans can be increased. Assuming a 25 cm thick ceiling, self-weight savings of 35-45% (Cobiax hollow floorboard) can be achieved compared to a ceiling with full cross section.

Ceiling systems require large spans at low height, quick and easy production, very good properties in the area of fire, - moisture and sound insulation, an appealing appearance, low maintenance and repair costs, a high degree of flexibility and much more. However, not only the flexibility during the production is respected, but the ceiling should not lose any of its flexibility during the entire service life. In buildings, new devices are constantly being integrated, which also have to find space in the ceiling systems. Starting with the energy, data and communication lines via heat exchangers and air conditioning systems, whose components and lines must be accommodated in the ceiling construction. In addition, a simple retrofitting should also be possible for future built-in parts. To ensure these possibilities, it is known to install double floor systems or suspended ceilings, as with these elements, a subsequent change of use is easily possible. However, such double floor systems or suspended ceilings require relatively high thicknesses of the ceiling. The aim of the invention is to combine the supporting structure with the advantages of the double floor. A specific object of the invention is to enable a simple placement of supply lines and thereby reduce the total thickness of the ceiling, so that at a given building height, a larger number of bullets is providable. Furthermore, the construction of the invention over known constructions bej same carrying capacity to make a significant weight saving possible. This should result in material savings and also reductions in the work to be done.

This object is achieved according to the invention by the combination of the following features:

• a concrete slab whose thickness is less than the total thickness of the concrete supporting structure, and

• Intersecting ribs, which are connected in a force-transmitting manner with one end region to the concrete slab and free from the concrete slab, i. without being integrated into a further load-bearing surface construction, projecting upwards, wherein their upper end regions are designed to receive compressive and / or tensile forces, and wherein the ribs are positively connected to one another at the points of intersection, at least with their upper end regions, and

Their respective areas lying between the upper and lower end regions have at least one breakthrough.

According to the invention, only a thin concrete slab is provided. On this intersecting ribs are provided, which absorb the pressure forces and optionally tensile forces concentrated. Due to this resolved structure, the dead weight can be greatly minimized (> 55%) and, in addition, a large space in the supporting structure becomes free. The free space can be used for installations of all kinds: from electric cables to supply lines to ventilation and air conditioning lines. Since the ribs have recesses, for example, are formed like a truss, pipes and pipes can pass without problems from one ceiling panel to the next. Instead of placing the installations in the floor area as usual or fixing them to the ceiling with dowels, the cables can be inserted into the supporting structure. If large cross-sections are to be accommodated, the supporting structure becomes higher, as a result of which the span of the construction can also be increased. Instead of creating a separate management level, the height of the supporting structure can be used. This results in a reduction of the total ceiling height. However, apart from the union of the supporting structure level with the installation level, the most important advantage is the flexibility of the system. Because in the first place only the narrow ribs for the carrying capacity be covered, covers can be mounted in between, which are removable at any time, as they are not used for the supporting effect such as a blanket. These covers can be conventional raised floor elements with which one already has long experience. Thus, this system maintains the flexibility of utility throughout its lifetime. If installations are relocated or relocated, the covers are removed by hand and replaced, and after the installation work, no change is visible.

Preferred variants are defined in the subclaims.

The invention also has the task of developing a flat concrete support structure of this type to the effect that it is particularly easy to produce, through the use of semi-finished parts. As a result, complex connection and formwork on the construction site should be eliminated.

This object is achieved in that the concrete slab has at least two immediately adjacent arranged semi-precast slabs, which are covered with a reinforced concrete layer and connected non-positively.

It is known to connect semi-finished panels by welding, screws, rebars in Verguss pockets or biasing. However, these joining techniques are associated with a high outlay on the construction site, with the force transfer from one semi-precast panel to the next also having to be worked with sufficient accuracy.

The special feature of the invention is that a simple connection of the semi-precast panels can be achieved by the reinforced concrete layer, which connection technology is to be regarded as a standard in concrete construction, but this connection method is used only for producing the compound of semi-precast panels, and not, as usual, for the production of the entire concrete slab.

According to a preferred embodiment, the ribs rest on the semi-precast panels with foot portions, the foot portions being circumferentially enclosed by the concrete layer.

The reinforcement of the concrete layer expediently penetrates the openings of the ribs. A further preferred embodiment is characterized in that the foot portions of the ribs are anchored in the concrete layer by means of reinforcement, wherein advantageously the foot portions of the ribs are anchored in the semi-precast panels by means of reinforcement, and further expediently the ribs and the semi-precast panels a common Have reinforcement.

Preferably, the ribs are formed together with a semi-precast slab as HaIb- finished product, whereby the ribs no longer have to be switched on the site.

Depending on the requirements of the breakthroughs, i. the cables to be laid in the ceiling, or depending on the requirement on the carrying capacity, the openings may diverge from top to bottom or converge.

If the concrete support structure is mounted on supports, it is characterized in that advantageously above a support a support member resting on the plate element is provided, are provided by a lying above the support center radially extending radially outwardly extending ribs, the At the edge of the plate element connect to ribs of adjacent elements, wherein expediently the star-shaped ribs are provided with a reinforcement which connects to a reinforcement of adjacent elements or merges into the reinforcement of adjacent elements.

In order to increase the rigidity of the plate element lying on a support, star-shaped ribs are connected to ribs extending in the circumferential direction of the plate element.

An essential aspect of the invention is that the concrete layer is statically cooperative, with their reinforcement extending beyond a semi-precast panel to at least one second adjacent semi-precast panel.

Preferably, the thickness of the semi-finished slab is between 2 and 20 cm, in particular between 4 and 16 cm, and the thickness of the concrete layer between 2 and 20 cm, preferably between 4 and 8 cm. A preferred method for producing a concrete support structure according to the invention is characterized in that formwork elements for forming the ribs are placed on the concrete slab and the concrete support structure by laying reinforcement in the space provided for the rib cavity between the walls of the formwork elements and through Potting this cavity is made with concrete.

A further expedient procedure in the production of a concrete support structure according to the invention is characterized in that thin-walled, plate-shaped elements are placed vertically on a reinforcement applied to a semi-precast panel, a layer covering the semi-precast panel is concreted, and then the space between the thin-walled, plate-shaped elements is filled to form the ribs with concrete.

A particularly efficient method for producing a concrete supporting structure is characterized in that the semi-precast slabs are produced together with rib bodies arranged on them in a precast plant, the rib bodies having channels lying above or being hollow, in that these semi-precast slabs are to the construction site transported there and placed in the correct position according to the building to be erected, then that a reinforcement on the semi-precast panels, which extends over at least two adjacent semi-precast panels, is placed and in the cavities of the rib body reinforcement, resulting in cavities of rib bodies extending adjacent semi-precast slabs, is provided, whereupon the concrete layer applied and the ribbed bodies are cast with concrete.

The invention is explained in more detail below with reference to several exemplary embodiments, wherein FIGS. 1 and 2 schematically depict oblique views of a biaxially stretched floor slab. Fig. 3 is a plan view of such a ceiling. FIGS. 5 and 6 show cross sections of the variants illustrated in FIGS. 1 and 2. Figures 7 to 10 show different configurations of the ribs in section and Figures 11 to 14 illustrate different types of bearings according to the invention steel-concrete structures with associated Schnittgrößenendiagrammen. Figures 15 and 16 show floors for ceilings according to the invention. 17 shows a prefabricated variant of the concrete support structure according to the invention is shown, Fig. 18 illustrates a section along the line XVIII-XVIII of Fig. 17. Fig. 19 shows a plan view of the variant shown in FIG. 17, FIG 20 shows a section according to the line XX - XX of FIG. 19. FIG. 21 shows a detail of FIG. 20 on an enlarged scale again. Figs. 22 to 25 illustrate an embodiment in oblique view, respectively, at various stages of manufacture. Fig. 26 shows a side view in which the layers of the reinforcements are drawn. Fig. 27 shows a plan view of a composite concrete supporting structure composed of a plurality of elements, Figs. 28 and 29 show sections according to the line VII-VII of Fig. 27, again at different stages of manufacture. FIGS. 30 and 31 show further embodiments in an illustration analogous to FIG. 29. Fig. 32 illustrates a section along the line XI-XI of Fig. 27. Figs. 33 to 36 show details of the concrete supporting structure, respectively in plan view.

The flat concrete support structure according to the invention is basically formed by a concrete slab 1, projecting from the ribs 2 upwards. These ribs 2 are each connected in a force-transmitting manner to the concrete slab 1 with one of their end regions 3 - also referred to below as foot parts, and they project freely upwards with their upper end regions 4, ie. they are not in any other supporting surface construction, such as usual for hollow ceilings, integrated. These ribs 2 absorb pressure and / or tensile forces with their upper end regions 4 and, in this regard, can be made reinforced at these upper end regions, for example upper straps 5. Between the upper end portions 4 and the lower end portions 3, which are anchored in a force-transmitting manner in the concrete slab 1, the ribs 2 are provided with apertures 6. This gives rise to the possibility of connecting the fields 7 delimited by the ribs 2 to one another, i. Lay lines from field 7 to field 7.

As an example, FIGS. 1 and 2 show floor slabs supported on vertical supports or columns 8, and the individual panels 7 which are bounded by the ribs 2 can be seen. These are biaxially stretched floors.

The ribs 2 are preferably all of the same height and preferably arranged at right angles to each other in the case of biaxially tensioned concrete support structures. Of course, another arrangement of the ribs 2 according to the plan shape of the concrete support structure to be formed is possible.

At the crossing points 9 of the ribs 2, these are mutually force-transmitting, eg non-positively connected, as well as possibly existing, a floor ceiling limiting support strip 10. Such a support strip can be designed analogous to the ribs 2. Figures 1, 5 and 8 show ribs 2 with a full-surface web 1 1, wherein each rib 2 has at least one opening 6 leaving the upper end portion 4, which preferably extends to the top of the concrete slab 1, so that a laying of lines laying on the concrete slab 1 is easily possible.

Fig. 2 illustrates ribs 2 in the manner of a truss structure, wherein from a top flange 5 of the ribs 2, starting diagonals 12 protrude into the concrete slab 1 and are connected to transmit power to the concrete slab 1. Of course, the diagonal 12 could lead from the top flange 5, starting to its own bottom chord and the bottom chord with the concrete slab 1 are connected to transmit power.

FIGS. 7 to 10 illustrate different configurations of the ribs 2. Thus, FIG. 7 shows a rib 2 whose diagonals 12 are formed by steel tubes which are cast in a concrete slab 1 provided with a reinforcement 13. The upper flange 5 of this rib 2 is formed by a Stahlpro fil 14, which is open at the top, wherein in the open cavity of the Stahlpro fils 14, a reinforcement 15 is introduced and this cavity is filled with in-situ concrete 16.

Fig. 8 illustrates a rib 2, which is made entirely of concrete and the upper end portion 4 also with a reinforcement 15 - secured by means of a bracket 15 '- is provided. This rib 2 is poured into a provided with a reinforcement 13 concrete slab 1 and is preferably made simultaneously with the concrete slab 1.

Fig. 9 shows a prefabricated rib 2 made of concrete, which is initially provided with an upwardly open cavity in the upper end portion 4, which is cast after placing the rib 2 on a formwork, not shown, by inserting a reinforcement 15 with concrete 16. This rib 2 is prefabricated as semi-finished part and is by means of in-situ concrete with the concrete slab 1, which also has a reinforcement 13, which passes through a transverse recess 18 of the rib 2, positively connected.

10 shows a similar rib 2 prefabricated as semi-finished part, wherein the concrete slab 1 is formed by prefabricated individual elements 1 ', 1 "which rest on foot flanges 17 of the rib 2. After applying a reinforcement to the individual elements 1', 1 ", the application of cast-in-situ concrete 16 to these individual elements 1 ', 1", whereby the concrete slab 1 is formed in its total thickness and the rib 2 is frictionally connected to the concrete slab 1. To secure the rib 2 with a Transverse recess 18 provided, which is penetrated by the reinforcement 13, which protrudes reinforcement and in the in-situ concrete. In addition, as shown in FIG. 10, the lower end portion 13 of the rib 2 is reinforced with a reinforcement 15.

Figures 1 1 to 13 show different ways of forming a concrete support structure according to the invention, namely according to FIG. 1 1 projecting, according to FIG. 12 mounted on two end supports 8, according to FIG. 13 mounted on three supports, wherein each of the figures a moment diagram is attached, from which the tensile and / or compressive forces occurring at the upper flange 5 and at the upper end region 4 of the ribs 2 are illustrated, in each case for a load of the same load. It can be seen that the construction according to the invention is suitable both for a cantilever plate and for a single-field or double-field plate with a center support.

Fig. 14 shows an example with frame effect in the central region of the construction, in which only small transverse forces are to be transmitted, for a single-field plate, wherein the upper diagram shows the torque curve and the lower diagram shows the transverse force profile for uniform load. This variant offers the advantage of very large breakthroughs 6 in the middle of the field, which allows a particularly easy laying of bulky lines or channels on the concrete slab 1.

Figures 15 and 16 show the construction of floors 19 on concrete support structures according to the invention, wherein Fig. 15 shows a variant in which a bottom 19 is superimposed on the ribs 2 in the manner of a double bottom. Fig. 16 illustrates a variant according to which a floor 19 is also raised in the manner of a double floor on the concrete slab 1.

Essential for the invention is, inter alia, that the concrete slab 1 has a thickness D, which is substantially less than the total thickness of the concrete support structure, preferably the thickness D of the concrete slab is at most about 1/3 of the thickness of the concrete support structure , In a concrete support structure according to the invention are available for installations about 50 to 85% of the ceiling cross-section available; For example, the total thickness of the construction can be 40 cm and the thickness D of the concrete slab 1 about 6 cm.

The ribs 2 or at least their upper flange 5 can be formed from a high-strength or ultra-high-strength concrete. High-strength concrete is concrete with a compressive strength of 60 to 120 N / mm ² , while in ultra-high-strength concrete it is concrete with a compressive strength between 120 and 250 N / mm ² . It may be advantageous to provide the concrete slab 1 or optionally also the upper chords 5 of the ribs 2 with a steel reinforcement 15, a textile reinforcement or a fiber reinforcement.

As can be seen in particular from FIG. 25, the concrete slab 1 is formed by a semi-precast slab 21 lying underneath and a concrete layer 22 provided thereon and provided with a reinforcement 23. The semi-finished plate 21 is also provided with a reinforcement 24. Preferably, the ribs 2 also have a reinforcement 25 which projects into the semi-finished slab 21 where it is anchored. The reinforcement 25 of the ribs 2 is shown in side view in FIG. 26 and in oblique view, but without ribs, in FIG.

FIG. 22 illustrates the semi-precast slab 21 with hollow ribbed bodies 26 anchored thereto via the reinforcement 25, which are formed by concrete shells and which are already provided with the reinforcements 25. Such a semi-precast slab 21 with the hollow ribbed bodies 26 constitutes a semi-finished product which can be used particularly advantageously for the production of a flat concrete supporting structure according to the invention. This semi-finished product is advantageously produced by the factory, ie away from the construction site where the concrete support structure is to be built.

Fig. 24 shows the arrangement of the reinforcement 23 for the concrete layer and the ribs 2 adjacent half-prefabricated panels 21 connecting reinforcement 27, which is laid in the cavities of the rib body 26. The reinforcement 23, which is applied to the semi-precast panel, also extends over at least two semi-precast panels 21 arranged directly next to each other or over the entire planned concrete supporting structure, as shown for example in FIG. 27.

After arranging the concrete support structure outline-forming HaIb- finished products 21, for example on the supports 8 - as shown in Fig. 27 - and after laying the reinforcement 23 and 27 on the semi-precast slabs 21 to be joined and in the Channel-like cavities of the rib body 26 is poured into the rib body 26 concrete, and there are all semi-precast slabs 21 covered with a concrete layer 22 so that finally a concrete support structure is formed, as shown in Fig. 25 with a single semi-precast slab 21, in Figs. 25 to 31, however, with adjacent semi-precast panels 21, is illustrated. Here are the foot parts 3 of the Concrete layer 22 surrounded, ie enclosed, but can protrude above this height, as shown in Figs. 30 and 31 is shown.

According to the variant illustrated in FIG. 29, the ribs 2 with foot parts 3 protrude directly into the concrete layer 22. According to FIG. 30, however, the foot parts 3 extend to a level 28 above the concrete layer 22, so that the foot parts 3 not only by transverse forces are also claimed on bending. This results in breakthroughs 6, which are larger in cross section.

FIG. 31 shows a variant according to which the openings 6 of the ribs 2 do not expand downwards, ie in the direction of the concrete layer 22, in contrast to the substrates shown in FIGS. 28 to 30, but taper. The foot parts 3 have for the proper application of a reinforcement 23 on the semi-precast slab openings 31, which are then filled after the application of the concrete layer 22 with concrete.

As can be seen from FIG. 27, the concrete supporting structure formed from ten semi-finished products rests on four columns 8 each arranged centrally between intersecting ribs 2. As FIG. 32 shows, this area between the ribs 2 is above the columns 8 poured with concrete. Referring to Figs. 33 to 36, the areas between the ribs 2 and above the columns 8 are provided with star-shaped ribs 29 which are also provided with a reinforcement 27, such as e.g. 33, the reinforcements 27 of the ribs 2 and 29 extend beyond these regions from a semi-precast plate 21 to the next semi-precast plate 21. According to FIG. 34, the reinforcements 27 of the ribs 2 and 29 are connected to one another by means of reinforcing connections 30. The reinforcements arranged in the star-shaped ribs are preferably fastened to a steel element provided centrally above the column 8, such as a steel plate, e.g. welded, wherein the reinforcement 27 may also be included.

The thickness of the semi-precast panels 21 is suitably between 2 and 20 cm, preferably between 4 and 6 cm; the thickness of the concrete layer is between 2 and 20 cm, preferably between 4 and 8 cm. In this way, the connection of the individual semi-precast slabs 21 by the reinforcement 23 laid in the overlay layer 22 can be effected in a simple manner.

For the production of a concrete support structure according to the invention, various variants are available, for example the concrete slab 1 can be made of in-situ concrete and can the diagonal 12 and upper chords 5 of the ribs 2 may be formed as prefabricated elements with or without Vergussbeton in the diagonal 12 and upper straps 5. Here, the diagonal 12 and upper straps 5 can serve as formwork forms are inserted into the reinforcements 15, whereupon the casting of the diagonal 12 and upper straps 5 takes place with concrete. If the diagonals 12 are made of reinforced concrete or steel, only the upper belts 5 can serve as formwork forms, in which a reinforcement 15 is inserted and cast. If the diagonals 12 are made of reinforced concrete or steel and the upper belts 5 are formed only of steel, the connecting of the upper belts 5 with the diagonal 12 with connection methods of the steel structure takes place.

Furthermore, it is possible to form the concrete support structure according to the invention entirely from prefabricated elements, which are connected to each other with in-situ concrete, optionally with prior provision of a reinforcement, so that a frictional connection between the individual parts is given. As already described above, the concrete slab 1 can also be designed as a half-finished element 1 ', 1 "on which a reinforcement 13 is placed, followed by casting with in-situ concrete 16 with simultaneous incorporation of the lower end regions 3 of the ribs 2 In this case, therefore, the completion of the concrete slab 1 takes place by means of the in-situ concrete 16 applied to the semifinished elements 1 ', 1 "(cf., Fig. 10), whereby the upper belts 5 are also to be connected non-positively.

The known methods of prestressing concrete support structures can be advantageously used in the concrete support structure according to the invention (pre-stress with subsequent bond, bias without bond, Spannbettvorspannung the finished parts, external Vorspannng next to the ribs).

17-21 illustrates a concrete support structure formed of prefabricated parts F ', F "juxtaposed to each other Each of the finished parts F', F" has a concrete slab 1 and ribs 2, which in the illustrated embodiment - since it is a biaxially tensioned construction - are arranged crossing each other.

The concrete slabs 1 are each made in one piece with the ribs 2, to a maximum extent such that transport of the finished parts F ', F "by truck is possible F ', F "are arranged side by side and connected to one another, wherein the connection of the finished parts F', F" on the one hand by a Vergussfuge 20 and on the other hand by tensioned reinforcements 15, hereinafter referred to as tendons 15. The tendons 15 are after the Arrangement of the finished parts F ', F "threaded through provided in these precast parts for the tendons in the production channels, and preferably as illustrated in Figures 21 and 22, according to which variant, the tendons 15 come to lie in the tension zones of the concrete support structure.

The advantages of the concrete support structure according to the invention are as follows:

supporting structure

• Reduction of the dead weight by more than 55% (compared to a full cross-section),

• Almost the entire height of the construction can be used for installations.

manufacturing

• The individual elements can be manufactured as finished parts. As connecting means pressure surges and grouting concrete and tendons or a Aufbetonschicht be used.

• Therefore, only a little bit of concrete has to be concreted on the construction sites.

• No or only minimal formwork is required.

• Saves working time and built-in material, and less tools are needed to make it.

installations

• Easy installation installation, no fixing required.

• Access to the installations is always possible from the floor.

• Laying the cables is possible without technical aids. After completion, covers are placed.

covers

• Proven covers of raised floor systems usable,

• From a static point of view, no strong concrete slabs are required, as the spans are small.

Building physics

• improvement of sound insulation by elastomeric bearings,

Mass-spring-mass-spring-mass system,

Increasing the sound insulation through the cavity,

• The fire protection is secured by the thin concrete plate on the underside. Subsequent reinforcement with changed use

• The compression and tension zones as well as the thrust connections can be reinforced separately according to a changed usage.

• Gain covers only a selected area.

• No impairment of the aesthetics

• The neighbors are hardly affected.

economics

• is given by the lower dead weight, the reduction in construction time and the quality assurance,

• Conversion work is possible at any time with little effort.

flexibility

• Detachable covers make the installations accessible at all times.

• All load-bearing parts can be reinforced independently and independently of each other.

• Increase of the double floor by conventional spacers for additional installations, which find no more space, is possible at any time.

Claims

claims:

1. A flat concrete support structure, in particular steel-concrete support structure, such as a steel-concrete ceiling, characterized by the combination of the following features: β a concrete slab (1) whose thickness (D) exceeds the total thickness of the concrete support structure , and

• intersecting ribs (2) which are connected to one end region (3) in a force-transmitting manner with the concrete slab (1) and are free from the concrete slab (1), i. without being integrated into a further load-bearing surface construction, projecting upwards, wherein their upper end regions (4) are designed to receive compressive and / or tensile forces and wherein the ribs (2) are positively connected to one another at the points of intersection (9) at least with their upper end regions (4), and

• Their each lying between the upper and lower end portions (3,4) lying areas at least one opening (6).

2. Concrete support structure according to claim 1, characterized in that ribs (2) are designed in the manner of a truss structure, with an upper flange (5) and with the upper flange (5) outgoing diagonals (12), directly or indirectly are connected in a force-transmitting manner via a lower flange to the concrete slab (1).

3. Concrete support structure according to claim 1 or 2, characterized in that the upper end region (4) with the lower end region (3) of the ribs (2) connecting full-surface web (11) is provided with at least one opening (6).

4. Concrete support structure according to one of claims 1 to 3, characterized in that at least the upper end region (4) of the ribs (2), optionally also the lower end region (3) of the ribs (2), with a reinforcement, in particular from Steel, (13) is provided.

5. Concrete support structure according to one of claims 1 to 4, characterized in that ribs (2) with diagonals (12), preferably formed by steel tubes, are provided.

6. Concrete support structure according to one of claims 1 to 5, characterized in that ribs (2) at least with an upper Endberich (4) made of high-strength or ultra-high strength concrete, preferably made of concrete with a compressive strength of 60 to 250 N / mm ² , are provided.

7. Concrete support structure according to one of claims 1 to 6, characterized in that ribs (2) are non-positively connected to the concrete slab (1) by means of in-situ concrete.

8. concrete support structure according to one of claims 1 to 7, characterized in that a web of the ribs (2) and optionally an upper flange (5) and a lower flange is made of steel.

9. Concrete support structure according to one of claims 1 to 8, characterized in that an upper flange (5) of the ribs (2) is formed by a filled with concrete steel profile (14).

10. concrete support structure according to one of claims 1 to 9, characterized in that the concrete slab (1) has at least one layer of high-strength, preferably ultra-high-strength concrete.

1 1. Concrete support structure according to claim 10, characterized in that the concrete slab (1) has a steel reinforcement, a textile reinforcement or a fiber reinforcement.

12. concrete support structure according to one of claims 1 to 1 1, characterized in that the concrete slab (1) is formed of a thin semi-finished slab (1 \ 1 ") made of reinforced concrete, to which a surface reinforcement (13) is placed on and cast with in-situ concrete (16) with the semi-finished plate (V, 1 "), while simultaneously incorporating the lower end portions (3) of the ribs (2).

13. Concrete support structure according to one of claims 1 to 12, characterized in that the entire height of the concrete support structure between 12 and 120 cm, preferably between 20 cm and 50 cm.

14 concrete support structure according to one of claims 1 to 13, characterized thereby that the thickness (D) of the concrete slab (1) is between 4 cm and 40 cm, preferably between 8 cm and 20 cm.

15. Concrete support structure according to one of claims 1 to 14, characterized in that the concrete slab (1) with the or the rib (s) (2) is integrally connected as a finished part.

16 concrete support structure according to claim 15, characterized thereby that several prefabricated concrete slabs (1) are connected with their ribs to a concrete support structure, wherein for connection Vergussfugen and tendons (15) are provided.

17. Concrete support structure according to claim 16, characterized in that the tendons (15) in the ribs (2) and the concrete slabs (1) are respectively provided in the tension zones.

18. Concrete support structure according to one of claims 1 to 17, characterized in that the concrete slab (1) has at least two semi-precast slabs (21) arranged directly next to each other, which are covered with a reinforced concrete layer (22) and connected non-positively ,

19. Concrete support structure according to claim 18, characterized in that the ribs (2) rest on the semi-precast slabs (21) with foot parts (3), wherein the foot parts (3) of the Aufbetonschicht (22) are circumferentially enclosed.

20. Concrete support structure according to claim 18 or 19, characterized in that the reinforcement (23) of the concrete layer (22) passes through the openings (6) of the ribs (2).

21. Concrete support structure according to one of claims 18 to 20, characterized in that the foot parts (3) of the ribs (2) in the concrete layer (22) by means of reinforcement (25) are anchored.

22. Concrete support structure according to one of claims 18 to 21, characterized in that the foot parts (3) of the ribs (2) in the semi-precast slabs (21) by means of reinforcement (25) are anchored.

23. Concrete support structure according to claim 22, characterized in that the ribs (2) and the semi-precast slabs (21) have a common reinforcement (25).

24. Concrete support structure according to claim 23, characterized in that the ribs (2) are formed together with a semi-finished part plate (21) as a semi-finished product.

25. Concrete support structure according to one of claims 18 to 24, characterized in that the openings (6) of the ribs (2) diverge from top to bottom.

26. Concrete support structure according to one of claims 18 to 24, characterized in that the openings (6) of the ribs (2) converge from top to bottom.

27. Concrete support structure according to one of claims 18 to 26, characterized in that above a support (8) a resting on the support plate member is provided, wherein from a above the support (8) to lie next center is radially star-shaped outward extending ribs (29) are provided, which connect at the edge of the plate element to ribs (2) of adjacent elements.

28. Concrete support structure according to claim 27, characterized in that the star-shaped extending ribs (29) are provided with a reinforcement which connects to a reinforcement (27) of adjacent elements or merges into the reinforcement of adjacent elements.

29. concrete support structure according to claim 27 or 28, characterized in that radially extending ribs (29) are connected with extending in the circumferential direction of the plate member ribs.

30. Concrete support structure according to one of claims 18 to 29, characterized in that the concrete layer (22) is statically cooperative, wherein the reinforcement (23) over a semi-precast panel (21) addition to at least one second adjacent semi-precast panel (21) extends.

31. Concrete support structure according to one of claims 18 to 30, characterized in that the thickness of the semi-finished part plate (21) between 2 and 20 cm, preferably between 4 and 16 cm, and the thickness of the Aufbetonschicht (22) between 2 and 20 cm, preferably between 4 and 8 cm.

32. A method for producing a concrete support structure according to one of claims 1 to 31, characterized in that on the concrete slab (1) formwork elements for forming the ribs (2) are placed and the concrete support structure by laying reinforcement (13 ) is made in the space provided for the ribs (2) between the walls of the formwork elements and by casting this cavity with concrete (16).

33. A method for producing a concrete support structure according to one of claims 1 to 31, characterized in that on a semi-finished part plate (V, 1 ") applied reinforcement (13) thin-walled, plate-shaped elements are placed vertically, one half Concrete is then poured into the concrete covering layer (V, 1 ") and then the space between the thin-walled plate-shaped elements is filled with concrete to form the ribs.

34. A method for producing a concrete support structure according to claim 15 or 16, characterized in that concrete slabs (1) integral with ribs (2) as finished parts (F ', F ") are produced, which after transport to the construction site with each other are connected, preferably by Vergussfugen (20) and tendons (15).

35. A method for producing a concrete support structure according to any one of claims 18 to 31, characterized in that the semi-precast slabs (21) are produced together with rib bodies (26) provided on them in a precast plant, wherein the rib bodies (26) above Have lying channels or hollow, that these semi-precast panels (21) are transported to the site and placed there in the correct position according to the structure to be erected, then that a reinforcement (23) on the semi-precast panels (21) extending over at least two adjacent half-finished panels (21) extends, is placed and in the cavities of the rib body (26) a reinforcement (27) extending into cavities of rib bodies (26) adjacent semi-precast slabs (21) is provided, after which Applied to concrete layer (22) and the rib body (26) are cast with concrete.