DE3640985A1 - Semifinished part for concrete floor construction - Google Patents

Abstract

A semifinished part (2) for concrete floor construction comprises essentially a precast concrete slab (4) with installed reinforcement in the form of a bottom reinforcement (6) and latticed iron load-bearing members (8). The precast concrete part is cast, in the manner of a permanent shuttering, with a layer (12) of in-situ concrete, the special shaping of the precast concrete part with supporting protrusions arranged on the underside providing an, according to the invention, lower layer thickness of the in-situ concrete layer for a composite concrete floor, said floor permitting, with the same static loadability, a vastly reduced installation weight and lower overall height than conventional concrete floors. <IMAGE>

Description

The invention relates to a semi-finished part for concrete ceiling construction according to the preamble of claim 1.

It is known that such semi-finished parts both in Use in civil engineering for concrete ceilings, these semi-finished parts as lost formwork be placed and at the same time ent the sub-reinforcement hold. Furthermore, the foot is on the sub-reinforcement necessary iron bars arranged so that this are fixed in the semi-finished part and for connection serve with the in-situ concrete. A disadvantage of such half finished is the fact that complex and order extensive composite iron arrangements and large amounts of concrete have to be processed.

To avoid major concrete work on site therefore prefabricated components used that already  have full ceiling thickness; this has been in practice but only proven with restrictions, since such Components very heavy in relation to the covered area are, so that they with the usually existing Construction cranes cannot be moved. For your assembly are special cranes with a high load-bearing capacity, in particular at wide projections required. The use of narrower and therefore lighter precast components finds its limit insofar as with the continuously large Reducing precisely the advantages of faster laying and inexpensive construction of large Precast components with major disadvantages of elaborate support structures and especially large ones Joint tightness problems are connected. Narrower Precast elements inevitably cause more joints, that have to be reinforced, at least however, need a potting. Such butt joints are constant weaknesses in terms of tightness and Statics.

As a compromise solution to the two presented above competing problems is that arising from DB-GM 81 31 314 resultant state of the art to see a pre manufactured, support-free, thin, formwork set zendes concrete slab element for the production of Stahlbe clay ceilings with one or two reinforced stiffeners ribs affects. With these semi-finished parts, the we considerable part of the area is designed and is thin-walled only reinforced by one or two stiffening ribs. Out composite reinforcements protrude from the thin-walled area. After assembling this semi-finished part, the ver Bund reinforcement and the stiffening ribs in one Ortbe shed clay layer, it being advantageous has an upper one above the stiffening ribs Provide reinforcement layer and over this one as "Überbe ton "designated location of in-situ concrete. The Addi tion of the height of the stiffening ribs with the material  The strength of the over-concrete naturally leads to a strong one Material accumulation with corresponding dead weight problems men who can cause such Semi-finished parts only suitable for limited spans are and the only advantage is the possibility not be supported during in-situ concrete pouring have to. Concrete saving and iron steel saving can however cannot be achieved with it.

From DE-GM 84 06 792 is a prestressed concrete slab as Semi-finished part known for ceilings after their assembly be poured with a layer of in-situ concrete. To this For this purpose, composite reinforcements protrude from the prestressed concrete slabs out. It is in the nature of prestressed concrete that derar not under a minimum of material thickness can be manufactured and very complex and expensive of construction. The one surrounding the prestressed concrete iron Concrete must at least be so strong that it can move through the Take up the tension of the reinforcement occurring can. The reinforcement can also not be arbitrary in their cross-section and their number are reduced because ultimately to the load-bearing capacity of the ceiling in the final state contributes significantly. For this reason, the Spannbe clay plate according to this solution proposal a relatively large Strength on and is also just an unsuitable compro between the prefabricated concrete part to improve the statics and sealing in - situ concrete, which, however, uses a lot of composite iron and Concrete weight required.

The invention is therefore based on the object, a half to create a prefabricated part for the ceiling construction, despite one the lowest possible material thickness and therefore considerable Concrete and composite iron savings in connection with a Layer of in-situ concrete, a high load-bearing ceiling possible.

This object is achieved according to the invention in a semi-finished  part for ceiling construction according to the feature of the generic term of Claim 1 together with the features of the characterizing Part of claim 1 solved.

Advantageous further developments of the invention result from the subclaims.

A particular advantage of the solution according to the invention is to be seen in the fact that through the support projections the concrete thickness of the semi-finished part can be greatly reduced, because the semi-finished part according to the invention management of forces according to the statics or can be used. The bond with the after assembly In-situ concrete to be applied is carried out by conventional grating girders that protrude from the semi-finished part. Im with The lattice iron girders provide cast-in-place concrete also the longitudinal reinforcement in the pressure zone of the slab and direct the load and dead weight forces over them Reinforcement from the middle area to the side Support tabs.

The semi-finished parts according to the invention, for example, come from a span of about 6.5 m and a steel reinforcement of 30 kg per m ² with a concrete thickness of 6 cm. With an in-situ concrete layer of 16 cm, an underground garage ceiling with 60 cm of earth can be built, which would otherwise have to have a thickness of 35 to 40 cm in conventional construction. Of course, these values have to be adjusted with the corresponding static values depending on the intended load. This means 40 to 50% concrete savings and approx. 40 to 50% steel savings compared to the prior art with the same statics. This reduced concrete thickness also leads to a gain in height in the aisle area of the ceiling, which is particularly noticeable in the case of ceilings for underground garages, because it can reduce the overall height by up to 25 cm.

These semi-finished parts are so light that they can be easily transported and assembled in their usual sizes by the cranes on site. A semi-finished part according to the invention with a dimension of 17 m ² weighs, for example, two to three tons. In contrast, a comparable prefabricated part made of solid concrete with steel reinforcement weighs eight to nine tons. The known semi-finished parts with in-situ concrete even come to about 15 tons for the same area.

It is obvious that these weight savings too used for easier bridging of larger spans can be d. H. that the construction according to the inven with the same ceiling thickness as conventional ceilings allows a substantial increase in the span.

For the optimization of the semi-finished parts according to the invention it is necessary to strengthen the support area so that a better flow of force is achieved on the support. The gain is advantageously by a Support projection in the form of a rib. The rib preferably has a hammer-head-shaped cross cut, with the inclined surface towards the center the surface of the precast slab runs. It However, it is obvious that other forms of Rib can be used. For example, at a cross-section like a hammer head, the slope surface be concave and / or convex; is also a pure rectangular cross section of the rib-shaped support jumps possible, but not such a good distribution of strength relationship.

Advantageously, the ribs can be shortened by short loading reinforcement bars are reinforced. This short reinforcement bars can either be from an excess length of reinforcement the precast concrete slab can be bent or from short Pieces of rebar are made. Here  it is advantageous if the short reinforcement bar with the continuous reinforcement of the precast concrete slab that will.

The connection of two semi-finished parts according to the invention as well as the connection to the surrounding parts of the building follows through the reinforcement bars in the joint area between the Lattice girders are used. However, it is also possible Lich, the impact zones of the semi-finished parts according to the invention to train in a toothing which for more precise Mon days and serve to improve power transmission. Leakage problems occur due to the compared to that Semi-finished part strong layer of the place according to the invention concrete, especially if it is water dense barrier concrete is executed, which z. B. at Tiefga cantilever ceilings is particularly important.

When pouring the in-situ concrete, the inventive works Semi-finished part like a lost formwork. As a result of his thin material thickness it has to absorb the load (Dead weight, weight of the concrete for the composite pitch, including any provided for this as well as traffic loads when applying the Ver concrete layer) by an appropriate number of ceilings support to be undertaken. After the in-situ concrete has hardened the ceiling supports can be removed again. The Un Tersicht of the semi-finished part according to the invention is before preferably flat and has exposed concrete quality, so that the Postprocessing effort is greatly reduced and in essentially limited to grouting the butt joints.

Further advantages, features and possible applications of the Semi-finished parts according to the invention result from the Description of an embodiment in connection with the Drawing.

It shows:  

Figure 1 is a schematically simplified perspective view of a known semi-finished part.

FIG. 2 shows an end cross section through the semi-finished part according to FIG. 1;

Fig. 3 is a simplified perspective view of an embodiment of a half-finished part according to the invention;

Fig. 4 an end cross section through the semi-finished part according to FIG. 3 in the area of Stützvor jump.

Referring to FIGS. 1 and 2 is a known semi-finished part 2 essentially consists of a prefabricated concrete slab 4, comprising a viewing surface 3 and a composite surface 5, and two end faces 7. In the precast concrete slab 4 there is a sub-reinforcement 6 , which can consist of individual braided iron bars or a structural steel mat. Grid iron girders 8 stand on the sub-reinforcement 6 , wherein, as can be seen in particular from FIG. 2, the largest part of the grating iron girders 8 protrudes from the composite surface 5 of the precast concrete slab 4 . The lattice girder 8 , which carry an upper chord 10 , serve as composite reinforcement for an in-situ concrete layer 12 to be poured onto the precast concrete slab 4 . Two abutting precast concrete slabs 4 and 4 'are preferably connected to each other by a butt joint reinforcement 14 in the layer of in-situ concrete.

The lattice girder 8 have the known triangular cross-section, wherein between the upper chord 10 and the lower reinforcement 6 , which forms the lower chord, meandering or individual girder spacer 11 are BEFE Stigt. The length of a precast concrete slab 4 can range from 1 to 10 and more meters, while the width should generally not exceed 3 m because of the road transportability.

In Fig. 3 and 4, the inventive design of the semi-finished part is shown, the ent speaking components in FIGS . 3 and 4 are provided with the same reference numerals for better comparison with the prior art according to FIGS. 1 and 2.

Referring to FIGS. 3 and 4, the precast concrete plate 4 in the region of the later Auflagers, that is, in the illustrated embodiment at the two end faces 7 each have a supporting protrusion 17 consisting of a rectangular part 16 and a triangular member 18 on. This support projection 17 serves to improve the flow of force introduction into the support. For this purpose, short auxiliary reinforcement bars 20 are arranged in the rectangular part 16 or the triangular part 18 . The short auxiliary reinforcement bars 20 are preferably adapted to the shape of the support part 17 . In the case of support projections 17 with an approximately hammer-shaped cross-section, as shown in FIG. 3, the short auxiliary reinforcement bars 20 run parallel to the inclination, ie along a hypotenuse surface 23 , in order to then run parallel to a support surface 22 after a kink. In support projections 17 with only a rectangular cross-section 16 , the auxiliary reinforcement rods 20 can also have a bow-shaped or rectangular shape.

At butt joints of a precast concrete slab 4 to a neighboring concrete precast slab 4 'butt joint reinforcements 14 are introduced over the butt joint in the area of the lattice girder 8 before the precast concrete slab 4 is poured with in-situ concrete. The butt joints provided with a phase 25 are leveled out later on the lower surface of view. 3 The precast concrete slab 4 has connection reinforcements in the edge area.

If a lattice girder 8 has to be cut because of the selected length of the concrete slab, this should happen so that care is taken at one end of cut that the welded to the lower longitudinal girder bars 9 Trä gerabstandsseisen 11 , thereby forming the lower chord point 13 , not in the area of Support tab. This means that, if possible, all the lattice girders lie at least on one side directly with their lower chord points over the rectangular part 16 of the support projections 17 . When designing, make sure that at least every second lattice girder comes to rest with its end-side lower chord points over the support projection. For this need for statics, beams made of corrugated iron or light solid iron structures are also possible. Fortunately, it has been found in the present invention that the construction, which is not considered possible by experts, is not only fully subject to the laws of statics, but also does not occur during the manufacture and transportation of the feared breakage problems caused by the two lateral, heavy support projections .

Claims (15)

1. Semi-finished part for concrete slab construction, consisting of a concrete precast slab made of reinforced concrete with a visible surface and a composite surface, in which a sub-reinforcement is embedded, and a composite reinforcement that protrudes from the composite surface and is intended to support an upper reinforcement, which can be cast into a composite concrete slab made of in-situ concrete , characterized in that the precast concrete slab ( 4 ) has at least one support projection ( 16 , 18 ) on its underside forming the visible surface ( 3 ). 2. Semi-finished part according to claim 1, characterized in that the supporting projection is arranged in the region of at least one of the two end faces ( 7 ) of the precast concrete slab ( 4 ). 3. Semi-finished part according to claim 1 or 2, characterized in that in each support projection ( 16 , 18 ) at least one auxiliary reinforcing bar ( 20 ) is provided. 4. Semi-finished part according to claim 3, characterized in that each auxiliary reinforcing bar ( 20 ) is adapted to the shape of the support projection ( 16 , 18 ). 5. Semi-finished part according to claim 3 or 4, characterized in that at least part of the auxiliary reinforcement bars ( 20 ) consists of a curved extension of the lower reinforcement ( 6 ) and / or the composite reinforcement ( 8 ). 6. Semi-finished part according to one of claims 1 to 5, characterized in that the supporting projection ( 16 , 18 ) has a rectangular cross section ( 16 ). 7. Semi-finished part according to one of claims 1 to 5, characterized in that the supporting projection ( 16 , 18 ) has a substantially triangular cross-section ( 18 ), the hypotenuse surface with the viewing surface ( 3 ) having an angle of more than 90 °, preferably from 120 ° to 170 °. 8. Semi-finished part according to one of claims 5 to 7, characterized in that the supporting projection ( 16 , 18 ) with a cross-sectionally rectangular part ( 16 ) and an adjoining triangular part ( 18 ) is designed so that the as a visible surface trained hypotenuse surface ( 23 ) of the cross-sectionally triangular part ( 18 ) connects the view surface with a parallel to this support surface ( 22 ), which is formed as a lower side surface of the cross-sectionally rectangular part ( 16 ) of the support projection. 9. Semi-finished part according to claim 8, characterized in that the hypotenuse surface ( 23 ) is concave and / or convex continuous or alternating. 10. Semi-finished part according to one of claims 1 to 9, there characterized in that connecting reinforcements are featured are seen, which are preferably hook-shaped or arch-shaped are trained. 11. Semi-finished part according to one of claims 1 to 10, characterized in that the composite reinforcement is in the form of lattice girders ( 8 ), which preferably consist of triangularly connected longitudinal girder bars ( 9 , 10 ), two of which ( 9 ) in the area of the sub-reinforcement ( 6 ) are arranged. 12. Semi-finished part according to claim 11, characterized in that at least every second lattice girder ( 8 ) is arranged such that lower chord points ( 7 ) are arranged over the part ( 16 ) of cross-section of the support projection ( 17 ), the lower chord points of the in the area of the lower reinforcement ( 6 ) arranged side member ( 9 ) and the free upper side member upper belt iron ( 10 ) connected spacer ( 11 ) are formed. 13. Semi-finished part according to one of claims 1 to 12, characterized in that the thickness of the finished clay plate ( 4 ) in its central region is approximately 4 to 10 cm. 14. Semi-finished part according to one of claims 1 to 13, characterized in that the support projection a greatest thickness of about 5 to 25 cm, so that the total thickness of the semi-finished part in the area of Support projection is about 7 to 55 cm.   15. Semi-finished part according to claim 14, characterized in that the length of the spacer bars ( 11 ) and the thickness of the longitudinal girder bars ( 9 ) has one of the statics for an in-situ concrete layer of 5 to 50 cm thickness accordingly dimensioning.