CH670670A5 - - Google Patents

Description

DESCRIPTION The invention relates to a structure of the type specified in the preamble of claim 1 and a method for its production.

In buildings such as buildings, especially in residential buildings, there is generally the problem of noise transmission between different rooms. The transmission of airborne sound and structure-borne sound or impact sound is particularly noticeable when the building has several separate apartments. Structure-borne noise is transmitted, for example, through continuous ceilings from one apartment to another across the partition. The situation is similar between building icons and apartments diagonally underneath, the structure-borne noise also being transmitted through continuous supporting parts, in particular concrete parts. This problem manifests itself particularly in the transmission of sound from stairwells to the adjacent apartments.

In order to avoid the unwanted transmission of structure-borne noise, it has hitherto been known to separate continuous ceilings from one another by means of a joint. In this case, one ceiling part lies fully on a wall, while the adjacent other ceiling part lies on a console with the interposition of an elastic, sound-absorbing underlay, which is molded onto the wall. However, such a construction is very complex. In addition, the consoles required do not usually fit into the design ideas of architects,

The invention has for its object to provide a structure of the type mentioned, which ensures good structure-borne noise reduction and is easy to create.

This task is solved:

a) by the characterizing features of claim 1;

b) by the manufacturing method according to claim 11. Accordingly, the structure according to the invention comprises two

Anchoring sections, which are formed on the parts of the building to be connected, for example concrete slabs, such that they lie one above the other when the two parts of the building are arranged horizontally and overlap one another at a distance. The two parts of the building are connected to each other by means of connecting rods that are anchored in the anchoring sections and at a distance2

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area of the two anchoring sections run vertically.

Due to the exposed support sections of the bars between the parts of the building, only a relatively small proportion of body vibrations is transmitted from one part to the other. This transmitted sound component is additionally dampened by the elastic properties of the connecting rods, which advantageously consist of steel or glass fibers and have a round or rectangular cross section.

According to an advantageous embodiment of the invention, the anchoring sections in the connection area of the building parts are either attached to the building parts in the form of metallic brackets or molded onto them as cantilever brackets. In the latter case, the brackets are made of the same material as the parts of the building, i.e. primarily of concrete.

The connecting rods are expediently curved in an S or Z shape, the curved end sections being anchored in the respective anchoring sections of the building parts, while the straight middle part of these rods forms the exposed, sound-insulating support section. It is advantageous here to produce the connecting rods from different materials, for example the central part serving as the supporting section made of stainless steel and the end sections anchored in the building parts made of corrugated structural steel. The various sections of the connecting rods are expediently welded to one another. The smooth stainless steel of the support sections is not connected to the concrete of the building parts. In this way, the elasticity of the support section is fully effective in the entire area between the welding points. The elastic part can be extended by the fact that the rounded transition part between the vertical support section and the end sections anchored in concrete is made of stainless steel.

A further improvement in structure-borne noise insulation can be achieved in that the smooth stainless steel of the connecting rods is provided with a covering made of elastic material in the curved transition area between the support section and the end sections. For example, a plastic film or rubber can be considered as the elastic material.

The structure according to the invention is manufactured or completed on the spot, with two plate-shaped parts of the building being connected to one another in a way that reduces structure-borne noise. A method of manufacture can be designed, for example, in such a way that the anchoring section of the supporting plate-shaped part of the building comes to lie below that of the supported part of the building. In this case, the connecting rods of the component are subjected to a pressure load, which can be taken into account with special pressure rods.

A particularly advantageous manufacturing method, however, provides a tensile load on the connecting rods, which are to be designed according to this type of load. In this case, the manufacturing process is such that the supporting part of the building is arranged with its anchoring section above the anchoring section of the building part to be supported, the ends of the connecting rods then being anchored in the two anchoring sections.

The two plate-shaped parts of the building can expediently be arranged in vertically offset planes in such a way that their end sections designed as anchoring sections overlap one another at a distance.

As an alternative to this step-like arrangement of the buildings

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These parts can be aligned with one another in one plane, with the exception of an intermediate joint, in which the exposed support sections of the connecting rods extend vertically. The advantage is the step-free, sound-absorbing connection between the two parts of the building.

A particularly advantageous embodiment comprises a separating body made of elastic, sound-absorbing material, in which the connecting rods are inserted, with their straight support sections.

In the case of S-shaped or Z-shaped connecting rods, these are embedded in the separating body with their essentially straight central sections, while the bent end sections protrude from the separating body. This separating body containing the connecting rods is particularly well suited for prefabrication, the free ends of the connecting rods being concreted in place on site in the anchoring sections of the plate-shaped parts of the building to be connected.

An advantageous method for producing the building structure using the separating body containing connecting rods in the case of plate-shaped building parts aligned in one plane provides for the separating body to be arranged in the shape of the joint between the two building parts and to be embedded therein together with the production of the building parts. In the case of concrete slabs or false ceilings, the separating body containing the connecting rods is therefore concreted into them when the concrete slabs are poured.

The invention is explained in more detail below using exemplary embodiments with reference to the drawing. It shows:

1 shows a sound-absorbing connection between two partially superimposed concrete slabs,

2 shows a sound-absorbing connection between two concrete slabs lying in one plane with embedded metal brackets,

3 shows a sound-absorbing connection between two concrete slabs lying in one plane via molded consoles, FIG. 4 shows a similar arrangement to FIG. 3, connecting rods inserted between the concrete slabs consisting of different materials,

5 shows a detail of the connecting rod from FIG. 4, FIG. 6 shows a further embodiment of the rod section shown in FIG. 5 and

7 and 8 a prefabricated as a separate component separating body with embedded connecting rods in a perspective view and in section.

Fig. 1 shows the simplest way to absorb the vertical forces between two concrete slabs while insulating the structure-borne noise. The two concrete slabs 1 and 2 are arranged in vertically staggered planes so that their end sections la and 2a overlap one another while maintaining a distance. The supporting forces between the supporting concrete slab 1 and the supported concrete slab 2 are absorbed via a connecting rod 3 which, with a vertical supporting section 3a, lies in the overlap area between the end sections la and 2a and with its curved end sections 3b and 3c in the respective concrete slab 1 and 2 is anchored. In special circumstances, a single connecting rod may be sufficient, but usually several connecting rods will always be required. The connecting rod 3 is made of steel, glass fibers or the like. The carrying section 3a must in any case run vertically in order to be able to absorb the carrying forces. Otherwise, the end sections anchored in the concrete slabs can be shaped as desired.

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670670

Fig. 2 shows another embodiment in which the two concrete slabs 11 and 12 to be connected to one another are arranged in alignment with one another in one plane. In this case, the supporting forces are absorbed by connecting rods 13, which are arranged vertically in a joint 14 between the two concrete slabs and engage with their ends on two brackets 15 and 16. The brackets 15 and 16 are made of steel in this case and are embedded in the respective concrete slab 11 and 12, respectively. Of course, they could also be shaped differently and attached in a different manner, for example by screwing. The connecting rods 14 are attached to the brackets in the usual way, for example screwed.

3 shows a further embodiment with two concrete slabs 21 and 22 lying in one plane. In this case, a connecting rod 23 is approximately S-shaped, and in this case too, the central section as support section 23a runs vertically in the region of a parting line 24. In this area of the parting line, the two concrete slabs 21 and 22 each carry oppositely formed concrete brackets 21a and 22a, which in turn form an overlap area for the vertical guidance of the support section 23a.

Fig. 4 shows a similar arrangement of two concrete slabs 31 and 32 with molded concrete brackets 31a and 32a. The Z-shaped bent connecting rod 33 consists in this case of different materials, namely in the area of the support section 33a, which runs vertically in the joint 34, of stainless steel and in its end sections 33b and 33c of corrugated structural steel, which is easy to anchor in concrete . The smooth stainless steel in the middle section does not bond with the concrete. Since the curved transition areas 33d and 33e are also made of stainless steel, the elastic part of the rod is considerably extended in this way, namely to the two welding points 35 and 36. The vibrations transmitted by the rod are in the curves 33d and 33e drained into the concrete over a relatively long distance.

5 shows, in an enlarged detail representation of the curve 33d, the section 37 of the concrete slab 31 which absorbs the transmitted vibrations over a relatively large distance. The larger the radius of the rounding, the lower the load on the transmission surface 37 between stainless steel and concrete, and therefore the less the transmission of the vibration of steel into the concrete of the adjacent slab.

A further embodiment is shown in FIG. 6. The rounded stainless steel area 33d is provided with an elastic covering 38, which, for example, in the form of a plastic film, a rubber covering or the like. can be trained. This envelope further reduces the transmission of vibrations.

The intermediate joint 24 or 34 shown in FIGS. 3 and 4 can also be filled by a separating body which is manufactured as a separate component before the production of the concrete slabs 21 and 22 or 31 and 32 and which accommodates the connecting rods. Such a prefabricated component is shown in FIGS. 7 and 8. The separating body 41 is made of elastic and heat-insulating material and has essentially the shape of the desired joints between the plate-shaped components to be connected, that is to say the cross-sectional shape of the joints 24 or 34 in FIGS. 3 and 4. In this separating body 41 are Z- or S-shaped connecting rods 42 are embedded, their essentially straight central sections 42a, which are perpendicular in the later installation position, are anchored in the central region 41a of the separating body 41 and are encased by the elastic material, while the end sections 42b and 42c, as well as that curved transition sections 42d and 42e initially remain free and are only embedded in the concrete slabs during the manufacture thereof. In this case too, as in FIG. 4, the central sections 42a and the adjoining curved sections 42b and 42e are made of stainless steel, while the end sections 42b and 42c are made of normal, if necessary, corrugated structural steel.

For better handling and to avoid bending of the connecting rods 42 during transport and storage, they are each connected to a free cross rod 43 at their free ends. This cross bar 43 also ensures a uniform alignment when the connecting bars 42 are inserted into the concrete formwork.

The separating body 41 is therefore attached at the location of the desired separation joint during the manufacture of the building, so that the concrete slabs or false ceilings can be cast directly onto it. The function of the power transmission and the structure-borne sound insulation is then the same as that which has already been explained with reference to the other figures.

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1 sheet of drawings

Claims (14)

670670 PATENT CLAIMS 1. Building structure with structure-borne sound insulation between a load-bearing and a supported plate-shaped part of the building, characterized by two anchoring sections (1 a, 2a; 15, 16; 21 a, 22a; 31 a, 32a) which are attached to the two parts of the building (1,2; 11, 12; 21, 22; 31, 32) are designed such that when the parts of the building are arranged horizontally, they lie one above the other and overlap one another at a distance, and by connecting rods (3; 13; 23; 33), by means of which the two parts of the building are fastened to one another , and of which exposed support sections (3a; 13; 23a; 33a) run vertically in the distance between the two anchoring sections when the building parts are arranged horizontally. 2. Building structure according to claim 1, characterized in that the anchoring sections (15, 16) are attached as metal brackets to the building parts (11, 12) or are anchored to them. 3. Building structure according to claim 1, characterized in that the anchoring sections are formed as projecting brackets (21a, 22a; 31a, 32a) on the building parts (21; 22; 31,32) and made of the same material as this, in particular of concrete , consist. 4. Building structure according to claim 3, characterized in that the connecting rods (3; 23; 33) are S-shaped or Z-shaped and each have a straight central section as a support section (3a; 23a; 33a) and curved, anchored in the respective parts of the building Have end sections (3b, 3c; 23b, 23c; 33b, 33c). 5. Building structure according to one of claims 1 to 4, characterized by a separating body (41) made of elastic, sound-absorbing material, in which a plurality of S- or Z-shaped connecting rods (42) are embedded essentially parallel to one another such that their essentially straight middle sections (42a) are enveloped by the material of the separating body (41), while their respective end sections (42b, 42c) on both sides run essentially horizontally when the middle sections (42a) are arranged vertically and lie outside the separating body (41). 6. Structure according to claim 5, characterized in that the curved transition regions (42d) between the embedded central sections (42a) of the connecting rods and their end sections (42b, 42c) are also outside the separating body (41). 7. Building structure according to one of claims 4 to 6, characterized in that the central sections (33a, 42a) of the connecting rods (33; 42) made of stainless steel and the end sections (33b, 33c, 42b, 42c) consist of corrugated structural steel. 8. Structure according to claim 7, characterized in that the curved transition regions (33d, 33e; 42d, 42e) between the central portion (33a) and the end portions (33b, 33c; 42b, 42c) of the connecting rods (33; 42) each also consist of smooth stainless steel. 9. Structure according to one of claims 4 to 8, characterized in that the curved transition regions (33d, 33e; 42d, 42c) between the central section (33a; 42a) and the end sections (33b, 33c; 42b, 42c) of the connecting rods ( 33; 42) each have an elastic covering (38). 10. Building structure according to one of claims 1 to 6, characterized in that the connecting rods (3; 13; 23; 33; 42) consist of glass fibers. 11. A method for producing the building structure according to one of claims 1 to 10, characterized in that the supporting part of the building (1; 11; 21; 31) is arranged in relation to the supported part of the building (2; 12; 22; 32) in such a way that that its anchoring section (la; 15; 21a; 3 la) comes to lie over its anchoring section (2a; 16; 22a; 32a), and that the connecting rods (3; 13; 23; 33) then have their ends in the two anchoring sections be anchored. 12. The method according to claim 11, characterized in that the two plate-shaped building parts (1, 2) are arranged in vertically offset planes such that their end sections (la, 2a) serving as anchoring sections overlap one another at a distance. 13. The method according to claim 11, characterized in that the two plate-shaped parts of the building (11, 12; 21,22; 31,32) are aligned with each other in a plane with the exception of an intermediate joint (14; 24; 34), in which the exposed support sections (13; 23a; 33a) of the connecting rods (13; 23; 33) extend vertically. 14. The method according to claim 13, characterized in that the separating body (41) receiving the central sections (42a) of the connecting rods (42) is designed in the form of the intermediate joint (14; 24; 34) and with the manufacture of the two plate-shaped building parts (1st , 2) is embedded in this.