DE1068878B - - Google Patents

Description

Floor ceiling erected according to the lifting plate method In the case of the known Lifting plate processes are based on the ceiling plates intended for a storey ceiling a low level, e.g. B. the ground, made, then raised and anchored to supports. This anchoring the flat ceiling panels to the supports poses a particular problem. For reasons of strength, the panels must be on the anchoring points a certain amount in consideration of the unfavorable stresses Have thickness, so that it is necessary to make the ceiling panels considerably thicker as a whole than is actually necessary according to the assumed ceiling load were. This is due to the fact that the lifting plate method so far only in has been applied to a limited extent.

According to the invention, the building of a floor in the lifting plate method certain ceiling panels in the area of the columns arranged for the passage of the columns Recesses drawn in funnel-shaped downwards, so that the anchored on supports Ceiling tiles form a cove ceiling. This shape of the ceiling panels can the thickness can be significantly reduced compared to the usual flat plates, so that there is a substantial saving in material.

Those formed by the funnel-shaped indentation on the plates Haunches can run straight or curved on their lower surface. These Haunches can be made so much thinner that the ceiling panels in the middle Part and in the haunches - measured in the vertical direction - have the same thickness.

The funnels formed by the coves are after attachment the ceiling panels on the supports filled with in-situ concrete. This is using usual reinforcement a good and safe anchoring of the ceiling panels to the supports achieved.

Up until now, cove ceilings could only be produced as a whole by casting will. Compared to this type of construction, the invention enables the erection of cove ceilings using the lifting plate method in a simple and cost-saving manner.

The invention is illustrated in the drawing. It shows Fig. 1 the known lifting plate method, FIG. 2 a vertical section through a Lifting plate according to Fig. 1, Fig. 3 is a vertical partial section through several ceiling panels according to the invention, Fig. 4 is a vertical partial section through one on a support anchored ceiling plate according to the invention, Fig. 5 is a vertical partial section through several ceiling panels in a modified design during manufacture, 6 shows a vertical partial section through a known mushroom cover.

In Fig. 1, any pad 1, e.g. B. the ground, indicated, the surface of which forms the floor formwork 2 for producing the ceiling panels 3. The completed ceiling panels are lifted against the supports 4, which by Go through the recesses 5 of the ceiling panels. The lifting is done by means of spindle screws 6 and tie rods 7. All ceiling tiles are at the appropriate height attached to the supports.

In this known lifting plate method, the ceiling panels 3 have recesses 8 on their underside to save weight, so that the full upper plate part 9 is stiffened by intersecting ribs 10.

In the embodiment of the invention according to FIGS. 3 and 4, this known lifting plate method is used. In FIG. 3, the central axis of a support 4 for the ceiling panels is designated by 11. The floor formwork 2 is drawn in like a funnel down around the support 4. On this floor formwork 2, a number of ceiling panels have been produced according to FIG. The flat ceiling part 12 has the thickness t1, which corresponds to the thickness t2 of the funnel-shaped part, measured in the vertical direction. When concreting the ceiling panels, insert forms are used in which the reinforcement extending from the ceiling parts 12 and coves 13 is located, which is later embedded in the in-situ concrete in the bent state after the ceiling panel has been raised to its height. This state is illustrated in FIG. 4, from which the reinforcement 15 of the flat ceiling part 12, reinforcement stirrups 16, which are bent out of the coves 13, and the reinforcement 17 of the in-situ concrete 18 can be seen. When the in-situ concrete 18 is introduced, the coves act as a partial shape, which is supplemented by an additional shape 19 directly on the support 4. The supports 4 have a taper 20 at the level of the ceiling panels, so that bearing surfaces 21 are obtained. The in-situ concrete 18 also has reinforcement in the upper part, which is not shown, and which is connected to the reinforcement 15 of the flat ceiling part 12 is prestressed before placing the concrete or after it has hardened. This is shown in dashed lines in FIG. The in-situ concrete 18 is filled up to the level 22 , and prestressed reinforcing wires 23 are wrapped around.

The embodiment described according to FIGS. 3 and 4 has the advantage that each ceiling tile has an increased load capacity compared to its own weight Has. The ceiling panels can be raised using simple holding devices, for example in the form of angle steels 24, are made, optionally in the finished Ceiling remain.

Fig.5 shows an embodiment in which the floor formwork 2 in addition to the supports is curved, with the angle of inclination always downwards becomes steeper. Here, too, the ceiling panels 3 are measured in the vertical direction with constant thickness t1 or t2. For the production of these ceiling tiles 3 additional formwork is required, namely rings 25 and an upper mold 26 for the top ceiling tile. The rings 25 sit on an anchored in a base 27 Stand 28 on which a sleeve 29 with a tiller 30 can be rotated, which has a handle 31 carries. By rotating the mold board 30 about the stand 28, the part of the Shaped ceiling plate, which is not detected by the upper mold 26.

The significance of this embodiment according to FIG. 5 is best shown from a comparison with the geometric shape (see Fig. 6) in which, so far so-called Mushroom blankets usually have been made. The support 4 has a conical shape enlarged part 32, on which a thickened, to the same thick, flat ceiling plate 12 belonging part 33 is at rest. It is clear that the discontinuities that occur in the transitions occur between the support 4 and said parts 32, 33 and 12, with regard to cause extremely unfavorable stress concentrations of strength, namely both when absorbing bending moments between ceiling slabs and columns as well as taking up occurring section forces. The shape of a column capital 6 is therefore a technically incomplete solution. That this kind of Mushroom blankets are common, can be traced back to the fact that with traditional Means the shaping of the curved surfaces of Fig. 5 due to the high cost comes into consideration.

The columns can also be designed as wall parts.

Claims (7)

PATENT APPEAL: 1. Floor ceiling built according to the lifting plate method, their ceiling panels on a low level, e.g. B. the ground, produced, then lifted and anchored to supports, characterized in that that the ceiling panels (3) are arranged in the area for the supports (4) to pass through Recesses (5) are drawn down like a funnel, so that the supports (4) anchored ceiling panels (3) form a V outendecke. 2nd floor ceiling after Claim 1, characterized in that the coves of the ceiling panels (3) on their The lower surface is straight or curved, for example in the shape of a circular arc. 3. Storey ceiling according to claim 1 or 2, characterized in that the ceiling panels (3) in the middle part (12) and at the haunches (13) - measured in the vertical direction - have a constant thickness (t1, t2). 4. Floor ceiling according to one of the claims 1 to 3, characterized in that the on the supports (4) by the arrangement the cones (13) resulting funnel are filled with in-situ concrete (18). 5th floor ceiling according to one of claims 1 to 4, characterized in that on the top of the haunch (13) recesses (14) are arranged in which the free ends of Reinforcement brackets (16) are located, which are bent up before the in-situ concrete (18) is introduced will. 6. Storey ceiling according to one of claims 1 to 5, characterized in that that the edges of the ceiling panels (3) by remaining in the ceiling construction or recyclable angle steels (24) are reinforced. References considered: U.S. Patent No. 2,686,420; Journal »Der Bauingenieur«, year 1955, issue 7. pp. 253,254.