DE3005571B1 - Component for heat insulation in buildings - Google Patents

Abstract

1. A contruction element for heat insulation in buildings, especially in protruding cantilever wall portions, comprising an elongate insulation element (10) made of a thermally insulating material, wherein elongate metallic reinforcing elements (20) are provided which extend substantially transversely for the insulation element (10) and which protrude in lateral direction on either side, characterized in that the insulation element (10), together with said reinforcing elements (20), is formed as an integral prefabricated element and provided, or adapted to be provided, with at least one compression element (30) being integrated into the insulation element (10) as an interconnecting (joining) core member and having dimensions corresponding to those of the insulation element (10).

Description

The invention relates to a component for thermal insulation in buildings, in particular in the case of cantilevered ones Wall parts, with an elongated insulating body made of thermally insulating material and with elongated, metal reinforcement elements that extend essentially transversely to the insulating body and laterally protrude.

For buildings that have protruding wall parts, for example balconies, loggias, external landings, house entrance panels Or the like., There arises the problem of undesirable heat dissipation, as such Projecting wall parts are usually connected to a corresponding false ceiling in the building and form their extension to the outside. Thus represent the projecting panels or wall parts Cold bridges to the outside, which on the one hand result in heat losses and on the other hand also structural damage

so can evoke.

In Kragbaikonen, which are stored on their front on supports standing in the open air, namely lead due to temperature fluctuations, these supports move differently than the wall parts in the warm Area of the building. This can have a disadvantageous effect, especially in multi-storey buildings lead to the formation of cracks and structural damage in the wall support.

From the magazine "Bautrichter", October 1958, soaps 253-255 are already components of the above mentioned type known, there to avoid thermal bridges cantilever beams at the two ends of a Balconies are provided, between which the actual balcony slab is suspended or supported.

Thus, these cantilever beams form a real connection between the outside and the inside of Buildings and represent a thermal bridge with a cross-section that is by no means negligible, even if it is

The thermal bridge is smaller than in cases where the entire length of the balcony protrudes outwards. Only in the area between the cantilever is there a thermal insulation layer to interrupt the Thermal bridge provided.

In the known arrangement, continuous reinforcement elements are only available at the two ends of the balcony slab, which are completely embedded in concrete. In the area of the insulating body, however, such reinforcing bars are not installed. \O

The invention is therefore based on the object of providing a component for buildings of the type mentioned at the beginning to create that, when installed, is capable of projecting wall parts, an effective To ensure interruption of the heat dissipation to the outside, without the forces occurring Impair the function of the insulating component and the protruding wall.

The solution according to the invention consists in a component of the type in question as a prefabricated part and to be formed with at least one pressure element which is integrated into the insulating body as a connecting core element and has dimensions corresponding to the cross section of the insulating body.

With such a component, a good thermal insulation on the one hand and a satisfactory load transfer on the other hand is ensured in an advantageous manner, so that a proper holding of the projecting wall parts is given. ^r '.. crimdungsgemäßen component remains namely, the cantilever plate so exist as such, but the one Wärmebrükke forming concrete cross-sections can be kept to an absolute minium, reduce namely the integrated printing elements.

If you use an insulating body made of rigid foam, z. B. polyurethane foam or polystyrene foam, so a material that is as cheap as it is effective can be used in an advantageous manner.

In a further development of the component according to the invention, the insulating body is on its in the longitudinal direction both ends provided with projections or recesses complementary thereto, so that the components can be plugged into one another in the longitudinal direction. So if you set several for a longer, protruding plate Components behind one another, so the projections and recesses act like tongue and groove with one another together and ensure both a seal and an alignment of the components on the Joint.

For assembly purposes of the component, it proves to be advantageous if the insulating body on its Underside has laterally protruding tabs with which a fixation on the outer wall or the masonry at the respective height of the building is possible. Such tabs can either be integrally formed with the insulating body or in the form of cast flat iron to a to enable simple manufacture and fastening of the component.

Finally, in many cases it proves to be so advantageous if the surface of the insulating body is at least partially provided with corrugation, because this enables, for example, a good grip on the external plaster.

With regard to the reinforcement elements, it proves to be useful if they are made of rustproof or <" consist of galvanized steel and run obliquely to the horizontal in their central area, while their laterally protruding areas up on one side and down on the other side are arranged offset from the horizontal. In this way, the component is easily in the Able to absorb not only tensile forces and shear forces in the horizontal, but also vertical forces. In addition or as an alternative, the reinforcement elements in the component according to the invention also have obliquely to the longitudinal direction of the insulator areas so that these in the Are able to absorb forces occurring in the longitudinal direction of the cantilevered plates, about then occur when wind forces act on the side of the balcony.

In one embodiment, the reinforcing elements can consist of individual, possibly elongated reinforcing bars, which then pass through the insulating body can be pushed through, while in another embodiment the reinforcement elements within the The insulating body can be formed in one piece and extend in a zigzag shape through the insulating body. In both cases, simple manufacture of the component is possible.

During the manufacture of the components, the reinforcement elements can be cast into the insulating body or be plugged in. In the first case, the material of the insulating body adheres directly to the reinforcing bars, in the second case, one can think of the insulating body itself in two parts with appropriate, to form transverse recesses into which the reinforcement elements are then inserted or are inserted, after which the two parts are then attached to each other.

If, in a further development of the component according to the invention, the pressure elements in the longitudinal direction of the Insulating body are arranged distributed at intervals, so that a good power transmission from across the Building alignment protruding panels on the ceiling o. The like. Reached.

From a structural point of view, the pressure elements can be made of metal pipe sections or angle profiles, optionally with head and foot plates on the end faces, with the most varied of profile cross-sections can be used.

In a further embodiment of the component according to the invention, the pressure elements can be used as I-profile parts be formed, which run in the longitudinal direction of the insulating body and optionally with transverse projections arranged for this purpose are provided. On the one hand, this creates an intimate connection between the insulating body and pressure element reached, on the other hand, these two parts cannot move against each other, which makes assembly easier.

In a further embodiment, cavities or the pressure elements are provided in the insulating body Can be filled with concrete when installing the component, so that the pressure elements may not be placed until pouring form and the material is used, which is already used when casting the cantilevered plates is used.

The pressure elements can, however, also consist of concrete plugs which are inserted into the insulating body or cast so that prefabricated parts can be integrated into the component.

The pressure elements expediently only take up a small part of the cross-sectional area of the insulating body a and are arranged in its lower area to facilitate the transmission of forces between protruding

to improve the slab and building. Of course can also be used in those cases where concrete cores are used as pressure elements Compression steel bars are made use of.

The invention is explained below with reference to the description of exemplary embodiments and below Explained in more detail with reference to the accompanying drawing. The drawing shows in

F i g. 1 shows a schematic representation in cross section to explain the arrangement of the invention Component,

F i g. 2 shows a schematic cross section through a component according to the invention,

F i g. 3 the top view of the component,

Fig. 4a-4d and Fig. 5a-5d are cross-sections or Longitudinal sections to explain different embodiments of the reinforcement elements,

6 and 7 show a cross section and a longitudinal section, respectively to explain the arrangement of the pressure elements,

8 shows a cross section to explain the Assembly of the component,

Figures 9 and 10 are a cross-section and a plan view, respectively to explain further embodiments of the component and in

Fig. 11a-1c cross-sections of various embodiments of the component.

In the illustration according to FIG. 1 one recognizes an outer wall 43 which carries an intermediate ceiling 47 and On its outside, a heat-insulating component 1 in a parting line 45 and an insulating plaster 44 having. On the outside is also a cantilever balcony with a floor plate 40, a front wall or Parapet 42 and a support 41 are shown. The heat insulating component 1 is expedient Arranged in the same plane as the insulating external plaster so that there is no contact between the protruding plate 40 on the one hand and the outer wall 43 on the other hand takes place in order to achieve optimal thermal insulation to enable.

The structural element 1 is equipped with the various reinforcement elements 20 to both vertical forces, essentially horizontal tensile forces and shear forces as well as longitudinal forces To be able to absorb wind forces. In Fig. 2 and 3, the component 1 is therefore with its insulating body 10 and the various reinforcement elements 20 shown, the latter, as in F i g. 2 recognizable, one Central region 21 running obliquely to the horizontal as well as laterally protruding regions 22 which offset upwards on one side and downwards on the other side relative to the horizontal are arranged. At the ends of the laterally protruding areas 22 hooks 25 are also provided, which serve for anchoring. If there are no vertical forces to be absorbed, this is of course sufficient Use of stretched tensile reinforcement 27, as shown in FIG. 2 are shown above.

In Fig. 3 can also be seen at the two ends of the insulating body 10, a projection 11 or a Recess 12, which are expediently designed to be complementary to one another, to facilitate the assembly of to facilitate several components 1 one behind the other in the longitudinal direction. These projections 11 and Recesses 12 cooperate with one another like tongue and groove, with a mutual displacement the components can be prevented in a simple manner that the projections 11 about

cross-shaped. In Fig. 3 also shows those reinforcement elements that are inclined to the longitudinal direction of the insulating body 10 have extending regions 24 in order to reduce forces in the longitudinal direction of the component 1 to be able to record. These inclined areas 24 can, if necessary, also be inclined to the horizontal at the same time run, such as the lower reinforcement element 20 in FIG. 2. You can also see a pressure element 30, which is built into the insulating body 10.

In the representations of FIG. 4 and 5 you can see different reinforcement elements to the respective Needs to be taken into account. 4a and 5a are individual reinforcing bars 23, which are shown in the insulating body 10 can be cast or inserted. In the latter case, you can also use two-part Insulating body 10, consisting of upper half and lower half with corresponding recesses for the Use reinforcement elements 20, whereby the attachment of the upper part and lower part to each other The most varied of ways is possible, for example by gluing, complementary projections and recesses as well as by clamping bands that are placed around the insulating body 10 and tightened.

FIGS. 4b to 4d and 5b to 5d show connected reinforcement elements 20 in different ways Configurations that meander or zigzag through the insulating body 10 extend. If necessary, straight parts can be placed between the respective inclined regions 24 26 may be provided.

When installed, the forces transmitted by the steel reinforcement are transferred between Ceiling and projecting plate by means customary in construction, with the sloping areas can be arranged inclined both to the longitudinal direction and to the horizontal to simultaneously to absorb vertical forces in the longitudinal direction, for example due to the influence of wind.

The material used for the reinforcement elements is appropriately stainless or galvanized steel used to prevent corrosion, while the insulating body 10 made of hard foam, for example made of polystyrene or polyurethane. Are the reinforcement elements 20 in such a Insulating body 10 is cast in, so particularly good adhesion to one another is achieved, and the reinforcement elements are fixed in such a way that they cannot be displaced.

In Fig. 6 and 7 is indicated schematically in cross section and in longitudinal section, as the pressure elements 30 in FIG the insulating body 10 are installed. The spaced apart in the longitudinal direction pressure elements 30 can from metallic pipe pieces 31 or angle profile parts 32, as it is in cross section or in the Side view in FIG. 6 is indicated. If necessary, head and foot plates can be attached to the front sides of the Pressure elements 30 may be provided. A wide variety of profiles are possible for the printing elements, the cross-section z. B. square, circular, I-shaped, cross-shaped or U-shaped.

The pressure elements 30 are either hollow, for example sleeve-shaped, and are through during construction filled the concrete used to pour the cantilever slab. Used in other embodiments one prefabricated concrete cores that are inserted into the insulating body 10 or poured into it, or leaves openings or cavities in the insulating body 10, which become pressure elements 30 as a result of the concrete casting.

In order to achieve a particularly close connection between insulating bodies

to reach by 10 and pressure elements 30, the latter can be designed as an I-profile part and transversely Have extending projections that a mutual displacement of the insulating body 10 and pressure element 30 prevent.

In all cases, it is advisable to design the pressure elements so that they are only a small part of the Occupy the cross-sectional area of the insulating body 10 in order to allow the formation of as few cold bridges as possible. the Pressure elements 30 are expediently arranged in the lower area of the insulating body 10, such as it in Fig. 11 is indicated in order to ensure a good transmission of the forces from the projecting plate to the Enable building.

In the arrangement according to FIG. 11 a one leaves something like that lower third of the component free so that the in-situ concrete takes over the pressure. Additionally you can be inserted pressure steel rods. Also b'i Arrangement according to FIG. 1 Ib contains the component a concrete core 30 in the lower area, while in the Arrangement according to Fig. Lic a profile bar as a pressure element 30 is provided.

F i g. 8 shows one of the FIGS. 1 similar representation of how the component 1 is used on the construction site. At least part of the surface of the insulating body 10 is provided with a corrugation 14 to to enable a good attachment of the external plaster 44. In many cases, however, that is enough anyway existing surface roughness of the insulating body 10 in order to ensure good adhesion of plaster or concrete to enable this insulating body.

Finally, FIGS. 9 and 10 show additional ones Ways to fix the component 1 during assembly. For this purpose, the insulating body 10 is with laterally protruding tabs 13 provided on its underside, which serve to hold the insulating body on To fix the masonry or the outer wall 43. This can either be done with nails through pre-made holes happen or by appropriate gluing. The tabs 13 can either be integral with the insulating body 10 itself or be present in the form of flat iron, which in turn in the insulating body 10 is cast in or attached to it with adhesives.

These tabs 13 can thus be used as additional fastening means when the Assembly of the component 1, the reinforcement elements 20 using tie wire to the corresponding reinforcements of the ceiling and the cantilevered plate are attached. If necessary, can the reinforcement elements 20 can also be equipped with spacers in order to achieve the desired arrangement of the Ensure components during assembly.

For this purpose 3 sheets of drawings 130123/322

Claims (18)

Patent claims: 1. Component for thermal insulation in buildings, especially in the case of protruding wall parts an elongated insulating body made of thermally insulating material and with elongated, metallic Reinforcement elements that extend essentially transversely to the insulating body and laterally protrude, characterized in that the component (1) is designed as a prefabricated part and has at least one pressure element (30) which is inserted into the insulating body (10) as a connecting core element is integrated and the cross-section of the insulating body (10) corresponding dimensions owns. 2. Component according to claim 1, characterized in that the insulating body (10) made of hard foam, such as B. polyurethane foam or polystyrene foam. 3. Component according to claim 1 or 2, characterized in that the insulating body (10) in Longitudinal direction at both ends of the projections (11) or recesses (12) complementary thereto having. 4. Component according to one of claims 1 to 3, characterized in that the insulating body (10) has laterally protruding tabs (13) on its underside. 5. The component according to claim 4, characterized in that the tabs (13) are integral with the Insulating body (10) or in the form of cast flat iron. 6. Component according to one of claims 1 to 5, characterized in that the surface of the The insulating body (10) is at least partially provided with a corrugation (14). 7. Component according to one of claims 1 to 6, characterized in that the reinforcement elements (20) made of stainless or galvanized steel and inclined in its central area (21) run to the horizontal, while their laterally protruding areas (22) on one side are arranged above and on the other side offset downwards relative to the horizontal. 8. Component according to one of claims 1 to 7, characterized in that the reinforcement elements (20) have areas (24) running obliquely to the longitudinal direction of the insulating body (10). 9. Component according to one of claims 1 to 8, characterized in that the reinforcement elements (20) consist of individual, possibly stretched reinforcing bars (23, 27). 10. Component according to one of claims 1 to 8, characterized in that the reinforcement elements (20) within the insulating body (10) are integrally formed and extend in a zigzag shape through the insulating body (10). 11. Component according to one of claims 1 to 10, characterized in that the reinforcement elements (20) are cast or inserted into the insulating body (10). 12. Component according to one of claims 1 to 11, characterized in that the pressure elements (30) in the longitudinal direction of the insulating body (10) in Are arranged spaced apart. 13. Component according to one of claims 1 to 12, characterized in that the pressure elements (30) made of metal pipe pieces (31) or angle profile parts (32), optionally with head and Base plate on the front sides exist. 14. The component according to claim 13, characterized in that the pressure elements (30) as I-profile parts are formed which run in the longitudinal direction of the insulating body (10) and optionally are provided with transversely arranged projections. 15. Component according to one of claims 1 to 14, characterized in that in the insulating body provided cavities or the pressure elements (30) when installing the component (1) with concrete are fillable. 16. Component according to one of claims 1 to 13, characterized in that the pressure elements (30) consist of concrete plugs which are inserted or cast into the insulating body (10). 17. Component according to one of claims 1 to 16, characterized in that the pressure elements (30) occupy only a small part of the cross-sectional area of the insulating body (10) and in his are arranged in the lower area. 18. Component according to one of claims 1 to 17, characterized in that the insulating body (10) consists of at least one prefabricated component with prepared recesses for receiving the reinforcement element or elements (20).