AT514300B1 - building - Google Patents

Abstract

A building (1) consists of two or more with semi-finished (4) joined semi-finished components (2, 3), which are formed from wall panels (6, 7), which by means of rod-shaped and / or planar stabilizing elements (8) which are substantially perpendicular to the planes of the wall plates (6, 7), are spaced apart and extend substantially in parallel planes to each other, and each forming a joint (5) at the joint (4). The intermediate spaces (9) between the wall panels (6, 7) can be filled with a hardenable mass, and positionable multi-directional reinforcing elements (10) are provided in the area of the joint (4). The positionable multi-directional reinforcing elements (10) are three-directional baskets and cooperate with stabilizing elements (8). The positionable multi-directional reinforcing elements (10) are slidably and / or tiltably disposed between the stabilizing elements (8) from a position in which they do not span the joint (4) to a second position in which they span the joint (4) and the stabilizing elements (8) are arranged so that free spaces for moving and / or tilting of the reinforcing elements (10) are present.

Description

Description: [0001] The present invention relates to a structure consisting of a plurality of semi-finished components assembled with joints according to the preamble of claim 1.

There are various approaches to make buildings stable even for the case of shock. For example, it is possible to create a building structure that is so stiff that, in the event of vibration, it will in all probability remain in the linear deformation area. But this is accompanied by a significant, economically usually difficult to justify construction costs.

Alternatively, it is possible to install energy dissipation zones in a building. These are intended to absorb the energy applied to the structure during a vibration by intentionally accepting destruction. It is disadvantageous that not infrequently irreparable damage to the structure occur.

In the brochure of the Ministry of Economic Affairs Baden-Württemberg "earthquake safe construction", 6th edition 2008, measures for the design and construction of earthquake-resistant buildings are presented. The simple design and construction principles explained there should have a favorable effect on the structural behavior of buildings. It is expressly pointed out that the hints given there are not to be understood as rigid rules. The aim is rather to improve the basic understanding of earthquake-resistant constructions.

In addition, further publications are known from practice and from the literature. As examples, some patent publications are cited here.

From DE 10 2010 011 430 A1 a proposal has become known, which aims to perform all exterior and interior wall panels as shell wall elements, which are set on a flat smooth foundation surface in frame. To achieve a high level of thermal insulation, the shell wall elements are filled with foam. To achieve a high level of stability and earthquake resistance steel rods are provided in the foundation, which extend through the walls and ceilings and reach into the roof construction.

A completely different proposal is known from DE 10 237 691 A1.

There, an earthquake-resistant structure to be created by standardized components, which is to be avoided by completely dry and loose layering of the standardized components cracking.

Another example of earthquake-resistant construction is shown and described in DE 86 27 730 U1. The structure is constructed in a dry construction from plates, which are spaced apart from each other and form a cavity between them, wherein the plates are connected to each other at at least two opposite side edges by webs. There are provided support pillars, which are included hidden in overlaps of the plates. In the cavities between the plates can be subsequently introduce insulation and Dämmeinsätze. For such a structure, it should be important that a complete drywall wall can be built, i. waiving mortar, concrete or adhesives. The static strength of these structures made of plates should be extremely high. The buildings constructed from this should be largely earthquake-proof and only slightly in danger of collapse. This should also contribute to the low weight.

From FR 2 942 824 A1 a generic structure is known. The multi-directional reinforcing elements are formed by two-directional brackets, which can be moved on baskets between the bars of the baskets, so that they span the shock. The stabilizing elements are formed by three-dimensional lattice girders, which are set back relative to the edges of the plates or baskets.

[0011] In EP 1 146 179 A2 two-directional stirrups are displaceable between the bars of a three-dimensional reinforcement, but the stirrups extend in the longitudinal direction through the entire semi-finished component to the opposite end and can be displaced therefrom.

Semi-finished components for the manufacture of structures are known from EP 2 495 375 A1, in which two-directional bracket are pivotally mounted in the region of the shock, which are pivotally mounted by a position not spanning the shock in a position spanning the shock.

The object of the present invention is to provide a building, which has a higher strength with economically justifiable effort, as with the known measures of the prior art.

This object is achieved by a building with the features of claim 1. Advantageous embodiments of the invention are the subject of the dependent claims.

The positionable multi-directional reinforcing elements are formed by baskets. Whereby it is particularly favorable if the positionable multi-directional reinforcement elements are arranged to be displaceable and / or tiltable.

The particular advantages of the structure according to the invention lie in its ease of manufacture, which do not require excessive new investments on the part of the manufacturing company. The demands on the specialist personnel remain in the known framework, the energy required to produce the building is not increased and may possibly even decrease. Last but not least, the stability of the structure is significantly increased.

Furthermore, in a further development of the invention, a structure is advantageous if it consists of several assembled with joint semi-finished components, which are formed from wall panels, which are spaced by means of connecting or stabilizing elements and extend substantially in parallel planes to each other whose resulting intermediate spaces can be filled with a curable casting compound, and which each form a joint at the joint, and in which the connecting or stabilizing elements are formed by rod-shaped and / or planar spacers which extend essentially at right angles to the planes of the wall panels, and wherein at least the stabilizing elements in the region of the joint interact with positionable, multi-directional reinforcing elements, the multi-directional reinforcing elements extending in planes substantially perpendicular to the planes of the wall plates.

Further, a structure is advantageous in which the stabilizing elements are realized by rod-shaped and / or planar composite components, which cooperate with the positionable multi-directional reinforcing elements.

A building can be designed particularly advantageous if the positionable multi-directional reinforcing elements cooperate with other reinforcing elements, wherein the other reinforcing elements connected to stabilizing elements and / or are firmly anchored in the wall panels.

A building according to the invention is extremely stable when a statically required overlap length is created by the interaction of the stabilizing elements and / or the other reinforcing elements with the positionable multi-directional reinforcing elements over the impact.

Further features and advantages of the invention will become apparent from the following preferred embodiments, which are explained in more detail with reference to the drawings.

1 shows two semi-finished components joined together with butt in a schematic illustration, FIG. 2 shows a variant of the semi-finished components according to FIG. 1, [0025] FIG Connection with the embodiment of Fig. 1 or 2 among the

4 variant of FIG. 3 in another assembly phase, FIG. 5 a in connection with the embodiment of FIG. 1 or 2 under the

Additional variant of two butt-joined semi-finished components, Fig. 6 shows a connection with the embodiment of Fig. 1 or 2 under the

Protective area falling detail of two joined with joint at a corner semi-finished components in a schematic representation, Fig. 7 shows the variant of FIG. 6 in a different assembly phase, Fig. 8 shows a further embodiment of the invention prior to moving FIG. 9 shows the embodiment of FIG. 8 after the reinforcement element has been displaced. FIG.

In Fig. 1 is a highly schematic part of a structure 1 is shown, which consists in the illustrated embodiment of two semi-finished components 2 and 3, which are joined together with a shock 4. However, a building according to the invention may also consist of more than two semi-finished components and in addition to the semi-finished components also have differently shaped components that may be finished parts, semi-finished parts or locally manufactured components. At the joint 4 creates a joint 5, which can remain unprocessed in the ideal case 1 in the ideal case. The two semi-finished components 2 and 3 are each formed of wall plates 6 and 7, which are spaced apart by means of stabilizing elements 8. The wall panels 6 and 7 extend in two mutually parallel planes and thus form a gap 9, which can be filled with hardenable casting compound, for example concrete. The stabilizing elements 8 are e.g. formed as a flat structure with meandering or wavy cross-section. As will be shown and described in the following embodiments, other stabilizing elements, such as rod-shaped stabilizing elements are advantageously used, but they must fulfill the purpose to fix the wall plates 6 and 7 stable in their parallel distance and spatially positioning of mehrdirektionalen reinforcement elements enable.

The term "multi-directional " By definition, reinforcing elements are used in the present subject matter of the invention to make it clear that the reinforcing elements expand in a plurality of (at least two) directions. This term is intended to describe the articles described in this way in relation to the common term "multidimensional". because every object used in construction practice, physically considered, is "multi-dimensional". is. A simple staff is necessarily "multi-dimensional" because, as a physical body, it is "multi-dimensional". is, but it extends in one direction only, so by definition it is "unidirectional". The "multidirectional" used in accordance with the invention Reinforcement elements thus expand according to definition into several directions (directions).

In the space 9 are multi-directional reinforcing elements in the form of baskets 10 which are arranged as prefabricated assemblies in the space 9 longitudinally displaceable. They slide on the flat, wave-shaped stabilizing elements 8, by which they are largely fixed in their position within the interstices 9 to their horizontal displaceability. After setting up the semi-finished components 2 and 3 on the site, the baskets 10 are shifted in the longitudinal direction so far that they span the joint 5 in the area of the joint 4 and create a sufficient Übergreifungslänge Ü required for the stability of the structure 1. When the baskets 10 are in their intended position or position, the gap 9 can be poured with in-situ concrete. It is understood that in place of cast-in-place also every other hardening

Mass in the spaces 9 can be filled.

2, an embodiment of the invention is shown, which represents a variant of the embodiment of FIG. When assembled at the site semi-finished components 2 and 3 4 three-directional baskets 10 are slid obliquely into the interstices 9 of the wall panels 6 and 7 in the area of the impact. In the interstices 9 of the wall panels 6 and 7, the stabilizing elements 8 are arranged so that open spaces for insertion of the three-directional baskets 10 result. The oblique insertion of the baskets 10 can be done manually or mechanically - ie actively - but it can also be used gravity, with the help of the baskets 10 slide into their final position. The end position of a basket 10 is reached when it can not be pushed further into the gap 9 between the wall plates 6 and 7 or slide into it. In Fig. 2, the lower basket 10 assumes such an end position. In this position, the required overlap length is achieved over the shock 4 and the curable casting material can be filled. The arranged above basket 10 has not yet reached its final position.

In Fig. 3, another variant of the invention is shown. The assembled semi-finished components 2 and 3 essentially correspond to those already described with reference to FIGS. 1 and 2. In one of the semi-finished components 2, the stabilizing elements 8 are assigned permanently to multi-directional reinforcing elements in the form of bidirectional brackets 11, the brackets 11 spanning in two directions a plane perpendicular to the planes in which the wall panels 6 and 7 extend. For this reason, the brackets 11 and 12 are referred to as two-directional reinforcing elements, whereas the baskets 10 described above extend in a further direction and are therefore referred to as three-directional reinforcing elements. The two-directional stirrups 11 cooperate with the stabilizing elements 8 and are preferably fastened to them. More bidirectional reinforcing elements in the form of positionable brackets 12 are introduced into the space 9 of the other semi-finished component 3 and there shifted in the direction of the first semi-finished component 2 and optionally tilted until the positionable bracket 12 with the rigid brackets 11 in the other half finished Component 2 interact and produce in this way the required overlap length Ü.

In Fig. 4, the end position of the positioned in the manner described above bracket 12 is illustrated within the gap 9. The positionable bracket 12 and connected to the stabilizing elements 8 bracket 11 are with a predetermined overlap each other. In this position to each other they are fixed with pins 13, which are arranged in the region of the joint 4 within the gap 9 and for reinforcement with the brackets 11 and 12 cooperate.

In Fig. 5, a further variant of the article according to the invention is shown. By analogy with, for example, FIG. 4, rigidly mounted stirrups 11 and positionable stirrups 12 are shown. The peculiarity of the current embodiment lies in the fact that the rigidly mounted stirrups 11 were already cast into the wall panels 6 and 7 together with the stabilizing elements 8 during the production of the semi-finished component 2. They are therefore "invisible" which should be illustrated by the dashed representation in the left half of the figure. In the case of broken wall plate 7 shown, the bracket 11 are schematically visible. The positionable bracket 12 are introduced in the same manner in the gap 9 as to the embodiments of FIGS. 3 and 4 has already been explained. Cotter pins 13 also provide in this variant of the invention the reinforcement connection of both types of brackets, so that a sufficient reinforcement and overlapping length Ü is ensured in the region of the joint 4.

Fig. 6 illustrates a detail of a building 1, in which a corner of the building 1 is shown. Two semi-finished components 2 and 3 have been assembled on the construction site to form a corner joint. The semi-finished components 2 and 3 are formed in a known manner by two wall plates 6 and 7 respectively. The mutually parallel wall plates 6 and 7 are connected to each other by stabilizing elements 8. Here, too, the flat, wave-shaped stabilizing elements 8 can be formed by rod-shaped stabilizing elements 14. In the corner shown here, the overlapping length required for stability is generated by means of positionable brackets 12 in the space 9 of the semi-finished components 2 and 3. In each of the semi-finished components 2 and 3, the positionable stirrups 12 are overlapped by being inserted and tilted in the area of impact 4 of the corner and can be fixed by means of splints 13, as shown in FIG. 7 showing an advanced assembly phase, is shown.

8 and 9, another embodiment of the invention is shown, in which a three-directional basket is used as the reinforcing element, which is made of horizontal brackets 16 and vertical bars 17. After the basket 15 has been inserted as shown in Fig. 8 in the semi-finished component 3, a sword 18 is pushed with its tip in front between the stabilizing elements 8 and the horizontal bracket 16 from above in the direction of arrow 19, whereby the basket 15 in Direction of the arrow 20 is moved to the left until the bracket 16 of the basket 15, the bracket 11 of the other semi-finished component 2 overlap by the desired overlap length Ü.

In the embodiments described, plate-like or wave-shaped shapes have always been represented and described as stabilizing elements. The stabilizing elements may also be other forms, e.g. a bar shape, or may be used mixed or arranged in groups arranged different types of stabilizing elements.

REFERENCE LIST 1 Structure 2 Semi-finished component 3 Semi-finished component 4 Bumper 5 Fugue 6 Wall panel 7 Wall panel 8 Stabilizing elements 9 Intermediate space 10 Baskets 11 Brackets 12 Positionable brackets 13 Split pins 14 Stabilizing elements 15 Basket 16 Horizontal brackets 17 Vertical brackets 18 Sword 19 Arrow 20 Arrow

Claims (4)

1. building (1), consisting of two or more with joint (4) joined together Halbfer-tig components (2, 3), which are formed from wall plates (6, 7) by means of rod-shaped and / or planar stabilizing elements (8) which are substantially perpendicular to the planes of the wall plates (6, 7) are spaced and substantially in parallel planes to each other, and each at the joint (4) form a joint (5), wherein the Interspaces (9) between the wall plates (6, 7) are filled with a curable composition, and wherein in the region of the joint (4) positionable mehrdirektiona-le reinforcing elements (10) are provided, characterized in that the positionable multi-directional reinforcing elements (10) three - directional baskets and with stabilizing elements (8) cooperate in that the positionable multi - directional reinforcing elements (10) between the stabilizing elements (8) from a position in de they do not span the joint (4) into a second position in which they span the joint (4), are displaceable and / or tiltable, and that the stabilizing elements (8) are arranged so that free spaces for moving and / or Tilting of the reinforcing elements (10) are present. 2. Structure according to claim 1, characterized in that the stabilizing elements (8) are realized by rod-shaped and / or planar composite components, which cooperate with the positionable, multi-directional reinforcing elements (10). 3. Building according to claim 1 or 2, characterized in that the positionable multi-directional reinforcing elements (10) with further reinforcing elements (11) co-operate, and that the further reinforcing element (11) with stabilizing elements (8) connected and / or fixed in the wall panels ( 6, 7) are anchored. 4. Structure according to one of claims 1 to 3, characterized in that the stabilizing elements (8) and / or the further reinforcing elements (11) with the positionable multi-directional reinforcing elements (10) over the joint (4) away a statically required overlap length (Ü ) form. For this 8 sheets of drawings