CH675001A5 - - Google Patents

Description

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CH 675 001 A5

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description

The invention relates to a bearing element for absorbing at least vertical forces in buildings, in particular for concrete ceilings, with a cuboid, at least one-sided open body made of elastic, heat and / or sound-absorbing, in particular foamed material, in the bottom of which the vertical forces absorbing a support body less Elasticity is embedded as a load-bearing element.

The invention is therefore based on a support for a reinforced concrete ceiling, in particular an in-situ concrete ceiling as described, for example, in DE-OS 2 552 261. This support consists of an approximately cuboid support body made of deformable material with an open to a longitudinal surface and arranged on both sides of each recess, vertically extending through openings. Apart from these last-mentioned openings, which are intended to be poured with concrete, the known support is in principle a cuboid box made of foamed polystorol which is open on one side to accommodate the concrete cam of the ceiling. This material is intended to avoid cold bridges and to reduce structure-borne noise. A plate made of synthetic plastic, preferably neoprene, is inserted in the lower wall of the box, which is open to the side. This is mainly used to support the ceiling slab, thus forming its load-bearing element.

A support of a comparable type is also described in DE-OS 3 531 441. For the two cases, essentially support elements for absorbing vertical forces should be made available, which should also ensure good sound and heat insulation. Their basic advantage is that the elements can be prefabricated and used immediately at the construction site if necessary, where they are stored in recessed wall niches and the concrete ceiling can be poured into the cavity. However, there are disadvantages in that the relatively small load-bearing elements convert the high weight of the ceiling into large surface pressure, so that the masonry underneath, in particular mortar joints, can be damaged. The known «support boxes» can also be adapted to the respective thickness of the intended ceiling and therefore cannot be used universally. In addition, it is inconceivable how the known bearing elements, in particular taking into account structure-borne sound insulation, should be able to effectively absorb the horizontal forces that occur. Such forces occur to a considerable extent through different movements of the individual components under the influence of shrinkage and creeping of the concrete, temperature changes and the like. In this respect, the known supports in the horizontal direction are characterized only by low resilience.

The invention is based on a bearing element known and outlined in the preamble of claim 1, the task of optimizing such a bearing element while maintaining the possibility of complete prefabrication with regard to the load-bearing capacity and universal usability and thereby all to the sound and heat insulation to meet the demands made.

The bearing element which solves this problem is characterized according to the invention by the following features:

a) the floor and the load-bearing element rest on an inelastic plate,

b) at least the vertical walls of the body and possibly the floor and / or the load-bearing element are firmly connected to the inelastic plate,

c) the body comprises at least three walls perpendicular to the floor and is open both upwards and to the side,

d) the load-bearing element is penetrated by a mandrel that projects freely into the interior of the body,

e) an accommodating sleeve for the lower end of the dome is anchored in the inelastic plate, and f) the lower end of the dome is accommodated in an elastic lining arranged in the sleeve.

A combination of these features is of particular interest with regard to the comprehensive task solution.

Due to the fact that the floor and the load-bearing element rest on an inelastic plate, the bearing forces introduced from the ceiling via the load-bearing element can be transferred to this plate and from it to the rising masonry or the cast wall, while minimizing the surface pressure. The specific wall load is therefore relatively low. The fact that at least the vertical walls of the body and possibly the floor and / or the supporting element are firmly connected to the non-elastic plate, it is possible despite the multi-part construction of the bearing element not only to prefabricate it, but also to transport it as a uniformly manageable object and to be able to use. The element can be used universally because the body has at least three walls that are perpendicular to the floor and is open both upwards and to the side. A bearing element intended for receiving a concrete cam has three walls that are perpendicular to the floor. In the case of a double element, two mutually parallel side walls each adjoin a central transverse wall; the vertical walls are then arranged approximately in a T-shape when viewed from above. Because, in contrast to the prior art, the body is completely open at the top, the height of the entire bearing element can be made so large that it is still suitable for the thickest occurring thickness. If thinner ceilings are to be stored, you only need the protruding ones

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Cut off wall sections. In this respect, the bearing element claimed can be used universally using practically only one standard dimension. The storage and arrangement of the dome, which is supported in an elastically lined sleeve, according to features d) to f) serves to absorb the emerging horizontal forces. However, desired horizontal movements are permitted. The elastic lining of the space between the mandrel and the sleeve, for example by means of elastomers, effectively limits the transmission of structure-borne noise. The concrete cam of the ceiling is supported on the mandrel, which absorbs the horizontal forces and introduces them into the non-elastic plate of the bearing element. Horizontal forces are thus held back by the unsustainable walls of the body.

Another proposal according to the invention is that the cross-section of the mandrel and / or sleeve can deviate from that of a circle, such that the wall thickness of the lining arranged between the mandrel and sleeve is substantially greater in at least one direction within the ceiling plane than in all other directions of that plane. This allows the blanket to be given preferred movement behavior. For example, if you imagine that the mandrel was, as usual, of circular cross-section, while the lined sleeve, on the other hand, had an elongated rectangular cross-section, the mandrel could mainly move in the direction of the longitudinal extension of the sleeve, but not or hardly across it.

Overall, the bearing element according to the invention is therefore advantageous in many respects.

The side walls and the rear walls of the body are preferably made of hard foam, while the bottom is made of soft foam. The inelastic slab is expediently formed by a concrete slab, the lower surface of which can be profiled for the non-positive connection with the mortar joint underneath.

The invention is best understood from the following explanation of two exemplary embodiments shown in the drawings. The drawings show:

1 shows a bearing element intended for receiving a concrete cam of a ceiling in a diagrammatic representation;

FIG. 2 shows a central cross section through the bearing element according to FIG. 1 corresponding to the section line II-II there;

3 shows the arrangement of a bearing element according to FIGS. 1 and 2 within a masonry in the ceiling-mounted installation state, the ceiling being poured during the bricking;

FIG. 4 shows a representation corresponding to FIG. 3, the ceiling being subsequently introduced here;

5 shows a “double” bearing element for receiving two opposing concrete cams;

6 shows a cross-sectional view of the bearing element according to FIG. 5 along section line VI-VI, and

Fig. 7 shows a bearing element according to FIGS. 5 and 6 in the installed state.

The one-sided bearing element 10 according to FIG. 1 is based on an inelastic, in particular concrete plate 11. A space 12 which is open at the top and towards the ceiling to be supported is delimited by a body 13 which comprises three vertical walls 14, 15 and 16. This essentially U-shaped body thus formed can e.g. by gluing together three plates corresponding to the heatings 14 to 16. The body 13 with its side walls 14 and 16 and its rear wall 15 is made of rigid foam, e.g. made of a polystyrene-like material. The walls 14, 15 and 16 are preferably at least partially cast with the end sections facing the concrete slab 11 with the concrete slab 11, so that these walls form a solid unit with the concrete slab. It is also possible to connect or stabilize the body 13 to the base plate 11 via support and connection angles, brackets or the like.

A plate 17 made of soft foam is arranged in the interior 12 of the body 13 and lying on the base plate 11 and is preferably glued to the surface of the plate 11. A supporting element 19 is embedded in an approximately central cutout 18 of this soft foam plate 17 and is intended to absorb the vertical forces. This is, for example, a plate that is preferably thick in accordance with the thickness of the plate 17 and made of a polymer that is less elastic than this, for example neoprene.

Furthermore, the load-bearing element 19 is penetrated by a vertically arranged steel mandrel 20 which, as shown in FIG. 1, projects into the interior 12 of the body 13. Since the interior 12 is cast with the concrete cam of the ceiling, the end of the dome 20 protruding into the interior 12 is cast in the ceiling cam. So while the elastic element 19 absorbs the vertical forces, the ceiling cam is supported horizontally on the mandrel 20.

As shown in FIG. 2, the mandrel 20 also extends through the elastic, load-bearing element 19 and, with a lower end 20a, dips into the interior of a steel sleeve 21 cast with the concrete of the inelastic plate 11, the inside diameter of which is larger than the outside diameter of the dome 20 and the space thus created is lined with an elastomeric material 22. The mandrel 20 can therefore perform transverse movements as well as pivoting movements about its longitudinal axis against the force of the elastic — or also plastic — material, which is desired to a certain extent. The adjustment of the elasticity modules of the elastic materials used, mainly the adjustment of the load-bearing element 19 and the sleeve lining 22 depend on the force relationships to be expected in each case.

As can also be seen from FIGS. 1 and 2, the bottom of the bearing element 10 formed by the plate 17 made of soft foam is on the side facing the ceiling to be supported

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opposite the end faces of the side walls 14 and 16 and the flush side wall of the inelastic plate 11 with a projection 23. This protrusion forms a plaster connection and consequently prevents structure-borne noise transmission through the plaster. Any parts of the projection 23 that still protrude over the plaster can be easily cut off.

3 and 4, which illustrate the installation position of a bearing element according to FIGS. 1 and 2, 24 denotes the rising masonry; 25 and 26 are layers of plaster. The ceiling cast into a bearing element with its concrete cam bears the reference number 27. In both cases -Fig. 3 shows the installation of a ceiling drawn in during bricking up, FIG. 4 shows a ceiling cast in subsequently - the entire bearing element 10 has double the stone height.

In the event that the ceiling 27 is introduced in the course of the bricking (FIG. 3), the ceiling cam is covered on the top side of the bearing element 10 with an elastomer plate 28. For this purpose, the three vertical wall sections 14, 15 and 16, that is to say the rigid foam bulkhead, are cut off, if necessary, up to level 29 of the associated brick 30.

If the concrete ceiling 27 is retracted (Fig. 4), i.e. if the wall is bricked up in one work step, the forces on the masonry above it are absorbed by lintels 31 to be used on site. Here, an upper elastomer cover can be omitted if there is a corresponding air gap 32 between the top and bottom lintel.

In the case of concrete walls, the niche required for the installation of the bearing element 10 is created by inserting a hard foam block of the required thickness before concreting and then scraping the hard foam block out.

The double bearing element shown in FIG. 5 differs only insignificantly from the simple element of the type previously described. The soft foam plate 17, the elastomer bearing as the load-bearing element 19 and the mandrel 20 with a lined sleeve 21 are provided twice. The vertical walls do not form an "U" here, but an "H", the two interior spaces 12, 12 'now being open both to the side and to the top. The inelastic, in particular concrete slab 11 is approximately twice as large as that of the simple bearing element 10.

. 5 to 7 the same or equivalent parts are provided with the same reference numerals with the embodiment of FIGS. 1 to 4. In this respect, FIGS. 6 and 7 are self-explanatory without a further description.

The desired and achieved effect of the single or double bearing element 10 is summarized as follows:

The inelastic plate 11, made in particular of concrete, of a statically sufficient size and thickness, serves to receive the concrete cam of the ceiling 27 and ensures a favorable force distribution from the bearing derivation of the concrete ceiling via the load-bearing (elastomer) bearing 19

Concrete slab 11 for absorbing the transverse tensile forces of the elastomer bearing 19, which has a predictable and planned deflection. Damage in the underlying mortar joint, for the non-positive connection of which the concrete slab 11 is preferably profiled on its underside, cannot occur. The hard foam covering formed by the vertical walls 14, 15 and 16 serves to separate the concrete cam of the ceiling vertically from the rest of the building and is dimensioned so that the thickest ceiling can be accommodated as standard, whereas in the case of smaller ceiling thicknesses, excess hard foam sections are cut off flush with the top edge of the ceiling will. The actual bearing of the concrete cam consists of the load-bearing element 19, the elastomer bearing, which initiates the load in a defined manner and the non-load-bearing soft foam of the plate 17, which acts as a filler and at the same time takes over the horizontal, acoustic separation from the bearing. On the side open to the ceiling, the soft foam 17 protrudes approximately by the thickness of the plaster in order to prevent unwanted sound bridges even after the plaster has been applied.

The steel mandrel 20 is used in conjunction with the steel sleeve 21 to absorb the horizontal forces, but due to the larger diameter of the sleeve allows a desired horizontal movement, the space between the sleeve and the mandrel being lined with sound-absorbing structure-borne sound insulation by elastomers.

Claims (8)

Claims 1. Bearing element for absorbing at least vertical forces in buildings, in particular for concrete ceilings, with a cuboid, at least one-sided open body made of elastic, heat and / or sound-absorbing, in particular foamed material, in the bottom of which the vertical forces absorbing a support body of lower elasticity as a supporting element is embedded, characterized by the following features: a) the bottom (17) and the supporting element (19) rest on an inelastic plate (11), b) at least the vertical walls (14, 15, 16) of the body (13) are firmly connected to the inelastic plate (11), c) the body (13) comprises at least three walls (14, 15, 16) running perpendicular to the floor and is open both upwards and to the side, d) the supporting element (19) is penetrated by a mandrel (20) which projects freely into the interior (12, 12 ') of the body (13), e) an accommodating sleeve (21) for the lower end (20a) of the dome (20) is anchored in the inelastic plate (11), and f) the lower end (20a) of the mandrel (20) is in an in the sleeve ( 21) arranged elastic lining (22) added. 2. Bearing element according to claim 1, characterized in that the bottom (17) and / or the supporting element (19) with the inelastic plate (11) are firmly connected. 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 4th 7 CH 675 001 A5 3. Bearing element according to claim 1, characterized in that the side walls (14, 16) and the rear wall (15) of the body (13) consist of rigid foam and the bottom (17) consist of flexible foam. 4. Bearing element according to claim 1 or claim 2, characterized in that the bottom (17) on the open-facing side of the body (13) overhangs the side walls and the inelastic plate to form a plaster connection (23) 5. Bearing element according to claim 1, characterized in that the inelastic plate (11) is formed by a concrete plate. 6. Bearing element according to claim 4, characterized in that the lower surface of the inelastic plate (11) is profiled. 7. Bearing element according to claim 4, characterized in that the height of the body (13) formed by the vertical walls (14, 15, 16) of the body (13) and the inelastic plate (11) is at least as large as the standard thickest ceiling is measured. 8. Bearing element according to claim 1, characterized in that the cross section of the mandrel (20) and / or sleeve (21) deviates from that of a circle, such that the wall thickness of the lining (20) and sleeve (21) arranged between the liner ( 22) is greater in at least one direction within the ceiling level than in all other directions of this level. 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 5