DE1945188A1 - Prefabricated structural parts for the production of prefabricated ceilings - Google Patents

Description

Prefabricated structural parts for the production of prefabricated ceilings The greatest possible rationalization of the building industry is an urgent problem, because as the construction volume increases, so do the costs in the construction industry Show tendency. There is an effort to carry out as much of the work as possible Moving work away from the construction site to factories, where appropriate by using machines manual labor can be saved.

You are also independent of the weather in the factories.

Although one in the course of this development through the production of standardized Wall and ceiling components have made some progress, difficulties arose in the standardization of ceiling load-bearing elements, because there are many factors here, e.g. Span, Payload, floor weight, construction height, play an important role, complications further arise from the fact that z. B. often non-rectangular ceiling fields occur, that shafts, chimneys, stair openings, partitions, etc. are often taken into account must0 This leads to the fact that also for the production and provision of prefabricated parts The most precise static calculations and installation plans are made for each order Need to become. This not only grows in the technical office, but also in the factory significant cost increases, because each order is manufactured, reinforced, relocated separately, must be designated and stacked. So it stays more or less with the customization, without the need for manufacture, only the actual mass production enabled, could be passed over.

First of all, the cross-sections of the girders have to be standardized sought. This is quite possible for components with a span of up to 8 m, because the grouting concrete on the construction site compensates for the different heights of contraction can. The cross-section of the beam depends on the prestressed structures economic utilization of the tensioning tracks. Since girders usually only have one pre-tensioned Tensile zone is established, the cross-section became the norm of the ordinary wall seal, a height of 6.5 cm and a width of 12 cm were chosen.

In most known precast ceilings, the uniform The center distance of the girders represents the Konstraktionsprinzip. Between these girders are then filler -inserted. The reinforcement is made according to the span and load calculated.

Often it is not possible to use a uniform center distance of the beams get along, so that then the Fu'llkörper between the carriers formed differently must be in order to bridge the various distances between the carriers. But it is even with a uniform center distance of the beams mostly unavoidable, different types Use fillers because the construction heights of the ceilings can be different0 It would be advantageous if the construction height is chosen so that the reinforcement is fully utilized, because a break should only occur when the reinforcement is exhausted and not when the forces in the pressure zone or the shear loads can no longer be recorded. Higher constructions reduce the benefits from a static point of view due to increasing dead weight. Economically unfavorable the additional consumption of material and the overall construction increase costs. The optimal ceiling height should essentially not be determined by the height of the packing be determined by statically unnecessary concrete. Material consumption and Otherwise, a higher dead weight would negate the advantages.

The state of the art therefore requires, on the one hand, that the center distances are the same the girder with adapted reinforcement of the same width fillers of different heights, on the other hand, unequal center distances with adapted reinforcement with different packing elements Width and height.

The present invention takes an opposite approach and accomplishes Advantages of using a uniform reinforcement. You need to do this, however - as in the case of the state of the art described - several types of Sull bodies, however these also enable adaptation to the various construction heights. Included the fillers required for the narrower center distance correspond to the larger ones Xonstriction heights and vice versa, within the usual limits for payloads and spans one then comes with a small number of different jar bodies and there are no mix-ups within the body bearing on the construction site, by providing a certain filling body for each center distance.

The invention thus consists in Bertig construction parts for Production of precast ceilings with different spans and payloads, Consists of beams and bodies, in that all beams have the same cross-section and have the same reinforcement, the lengths of the beams depending on the given minimum support length are evenly graduated in such a way that the correspond to the respective gradations of twice the minimum support length or something are larger, and that the width of the packing dependent on the center distance of the beams and their height depending on the construction height the ceiling are also evenly graded. If z. B. for load-bearing walls one Minimum wall thickness of 25 cm and a minimum support length for prefabricated ceilings of 12 cm are provided, provides an expedient embodiment of the invention Graduations of the beam lengths by 25 cm each. in the range of 3 to 8 m beam length this then results in 21 individual lengths of the beams. For each beam length there is a certain area of usability, which is compiled in simple tables can be. These tables tell every foreman which ceilings he is using Can produce carriers. The order can therefore be made according to parts lists and no plans need to be sent in and edited. The delivery is carried out immediately from the stacks, the replenishment of which is done in the factory can be consumed as it is. The production is therefore fluid and there will be really "prefabricated parts" produced that are not made for each individual order Need to become.

By standardizing the fillers to be inserted between the carriers in terms of their evenly graduated widths and heights, so too will the number the bull body is reduced to just a few types, which are common to all constructions in question of different span and different payload can be used. The width of the packing is depending on the center distance of the carrier, and the The height of the fillers is graded depending on the construction height of the ceiling, wherein the width gradations z. B. expediently 12.5 cm (approximately in the area from 25 to 75 cm), and the height increments of the filler bodies are 3 cm (approx Range from 14 to 32 cm).

The invention is explained in more detail with reference to the accompanying drawings 1 shows a stepped set of ceiling supports; 2 and 3 two longitudinal sections through finished ceilings; Figures 4 to 7 illustrate cross sections through ceilings with different center distance of the beams and corresponding variation of the packing, which are therefore suitable for different spans and payloads 0 As shown in Fig. 1 can be seen, according to the invention, a prefabricated set of z. Be 21 pieces, Depending on the dimension d, ceiling beams T1 - 21 of different lengths are provided, all of them have the same cross-section; the dimension d, i.e. the same length gradation in each case, is in the range from 3.00 to 8.00 m z. Bo 25 cmO The carrier prefabricated in this way are sufficient to create all ceiling spans in this area The following table shows how clear spans (wall clearances) from 3 to 3.25 m the length 1 of the ceiling beam is to be selected so that on the one hand the Support length a does not fall below the prescribed minimum dimension and on the other hand the full length of the girder can be placed on the two load-bearing walls.

1 type of length of the beam a in m beam in m in cm 3.00 20 3.25 12.5 3s ° 5 m 3.50 22.5 3.10 T19 3.50 20.0 3.15 219 3.50 17.5 3.20 T19 3.50 15.0 3.25 T18 3.75 25.0 The task is set to several neighboring rooms to be provided with a prefabricated ceiling according to the invention, with a central wall is present, the strength of which is insufficient to accommodate excess lengths of the carrier i.e.

The girders can be staggered in lengths of more than half the wall thickness be arranged to each other.

In Fig. 2, W denotes load-bearing walls, the distance between which l1 from each other is, for example, 3 m.

The thickness of the wall (minimum thickness) is 25 cm. Become a 2z-ager those of the type T2O? So used with a length of 3, -25 m, both sides 12.5 cm rest. The support here extends exactly to the middle of the walls With B, the fillers are indicated, which are placed between the carriers T20. The top concrete that connects the girders and the pull bodies is denoted by A.

In Fig. 3 a similar representation is given, the distance 12 of the walls @, which are again 25 cm thick, is 3.05 m. To manufacture the Ceiling beams of type 219 are used here, which have a length of 3.50 m and 22; 5 cm on both sides. With F the packing is again and with A the Aufbeton denoted 0 In the cross-sections of FIGS. 4 to 7, 2 are the cross-sections the bearer designates which, as can be seen, are all equal. Your center distance, according to the different payloads to be taken up, varies and is marked with x1, x2, The packing elements F, marked x3 and X4, have stepped widths b1, b2, b3 and b4 and graduated heights h1, h2, h3 and h4, the smallest distance between the beams and the smallest width of the packing corresponds to the greatest height. The concrete topping A connects the prefabricated elements to form the finished ceiling structure.

Claims (1)

Patent claims: Prefabricated structural parts for the production of prefabricated ceilings with different spans and payloads, consisting of beams and fillers, characterized in that all carriers have the same cross-section and the same reinforcement the lengths of the beams depending on the given minimum support length are evenly graded in such a way that the respective gradations are double The minimum support length or slightly larger, and that the width of the Bull body depending on the center distance of the girders and their height depending on the construction height of the ceiling are also evenly graded. L e r s e i t e