EP0121685A2 - Pressure element in a heat insulating structural member for projecting parts of buildings - Google Patents

Abstract

1. A heat insulating structural member which is positioned between a building part (2) projecting from a building (1), and the building (1), and which comprises an elongated insulation body (3) of thermally insulating material and including reinforcing elements which extend substantially transversely of the insulation body (3) and protrude laterally from the latter, which insulation body has integrated therein one or more pressure or compression elements of a compression-resistant material for transmitting compressive forces, said compression members comprising at least one rod (5 ; 9) having the longitudinal direction thereof positioned transversely of the insulation body, characterized in that the rod, owing to its slender shape, is capable of elastically or resiliently following temperature induced longitudinal movements of the projecting building part (2) relative to the building (1), and that the ends of the rod extend in their longitudinal direction beyond the insulation body (3) into the building (1) and into the projecting building part (2), respectively.

Description

The invention relates to a pressure element for transmitting compressive forces in a heat-insulating component for cantilevered building parts, the component consisting of an elongated insulating body made of thermally insulating material with reinforcing elements extending essentially laterally to the insulating body and in which the one or more pressure elements are integrated made of pressure-resistant material.

In buildings, the cantilevered wall parts, such as balconies, loggias, outdoor platforms, house entrance panels or the like. have, in addition to the problem of undesirable heat dissipation due to the formation of cold bridges, the further problem that the projecting parts of the building, which are partially supported on their front on outdoor supports, and the immediately adjacent wall parts of the building due to temperature differences different length and expansion movements To run. This can have an adverse effect, particularly in the case of multi-storey buildings, and can lead to the formation of cracks and other structural damage.

From DE-PS 30 05 571 a component for thermal insulation in buildings has become known which is integrated to solve these problems in the insulating body as a connecting core element and has dimensions corresponding to the cross section of the insulating body. With this pressure element there is the risk that it adheres on both sides with a rough surface on the one hand to the concrete of the wall part lying in the building, for example on the false ceiling, and on the other hand to the concrete of the projecting part of the building and no relative movement allowed. If the projecting parts of the building move in the vertical or horizontal direction due to thermal expansion in relation to the building wall, this can result in high additional stresses for the connected components, which can lead to permanent damage.

In order to avoid such additional stresses, a pressure element has been proposed in DE patent application P 32 44 472.9, which is formed from a rubber-elastic material. With a pressure element designed in this way, relative movements of the projecting part of the building relative to the building and resulting tensile and compressive stresses can be absorbed in the elastically deforming pressure plate. On the other hand, however, these printing plates have a lower compressive strength. In the case of strong pressure loads, their service life is therefore relatively limited. In addition, the rubber-like bearings give way under load, causing the cantilever plates to bend strongly. The invention is therefore based on the object of providing a pressure element which, despite a high compressive strength and a long service life, is able to absorb the mechanical stresses when the projecting part of the building moves relative to the building, without stresses resulting in damage to the building, on the projecting part Can lead part of the building or on the pressure element.

This object is achieved in the initially mentioned pressure element according to the invention in that the pressure element consists of at least one rod-shaped element which, due to its slenderness is able to elastically follow temperature-related longitudinal movements of the projecting part of the building relative to the building.

• Es besitzt eine hohe Druckfestigkeit und durch seinen relativ geringen Querschnitt eine gewünschte geringe Wärmeleitfähigkeit. Seine relativ hohe Elastizität erlaubt es, horizontalen Verschiebungen des vorkragenden Gebäudeteiles folgen zu können, ohne daß beträchtliche mechanische Beanspruchungen auftreten. Hierdurch ist auch eine lange Lebensdauer der Druckelemente gewährleistet.

This printing element has the following main advantages:

• It has a high compressive strength and, due to its relatively small cross-section, a desired low thermal conductivity. Its relatively high elasticity makes it possible to be able to follow horizontal displacements of the projecting part of the building without considerable mechanical stresses occurring. This also ensures a long service life for the pressure elements.

The invention is explained in more detail below with reference to exemplary embodiments shown in the figures.

• Fig. 1 einen Schnitt durch einen Isolierkörper mit einem integrierten Druckelement gemäß einem ersten Ausführungsbeispiel,
• Fig. 2a einen Querschnitt durch ein Druckelement gemäß einem zweiten Ausführungsbeispiel,
• Fig. 2b einen Querschnitt durch ein Druckelement gemäß einem dritten Ausführungsbeispiel,
• Fig. 2c einen Schnitt durch einen Isolierkörper in Längsrichtung des Druckelementes gemäß dem Ausführungsbeispiel nach Fig. 2b,
• Fig. 3a einen Schnitt in Längsrichtung durch einen Isolierkörper mit integrierten Druckelementen gemäß einem vierten Ausführungsbeispiel,
• Fig. 3b einen Schnitt in Querrichtung durch einen Isolierkörper mit einem Druckelement gemäß einem fünften Ausführungsbeispiel,
• Fig. 4a - 4c Querschnitte durch einen Isolierkörper mit integriertem Druckelement gemäß einem sechsten, siebenten und achten Ausführungsbeispiel,
• Fig. 5 einen Querschnitt durch einen Isolierkörper mit einem Druckelement gemäß einem neunten Ausführungsbeispiel und
• Fig. 6 einen Querschnitt durch einen Isolierkörper mit einem Druckelement gemäß einem zehnten Ausführungsbeispiel.

Show it:

• 1 shows a section through an insulating body with an integrated pressure element according to a first embodiment,
• 2a shows a cross section through a pressure element according to a second exemplary embodiment,
• 2b shows a cross section through a pressure element according to a third embodiment,
• 2c shows a section through an insulating body in the longitudinal direction of the pressure element according to the embodiment of FIG. 2b,
• 3a shows a section in the longitudinal direction through an insulating body with integrated pressure elements according to a fourth exemplary embodiment,
• 3b shows a section in the transverse direction through an insulating body with a pressure element according to a fifth embodiment,
• 4a - 4c cross sections through an insulating body with an integrated pressure element according to a sixth, seventh and eighth embodiment,
• Fig. 5 shows a cross section through an insulating body with a pressure element according to a ninth embodiment and
• Fig. 6 shows a cross section through an insulating body with a pressure element according to a tenth embodiment.

1 shows a part of the building, for example a concrete ceiling 1, and a concrete part of the projecting part of the building, for example a balcony slab 2. Between them, a heat-insulating prefabricated component with an insulating body 3 is arranged in a known manner. The longitudinal direction of this insulating body 3 extends perpendicular to the cutting plane. The insulating body 3 is crossed by reinforcing bars, not shown, which run partly horizontally to absorb tensile stress and partly obliquely to absorb vertical forces through the insulating body. Usually in the lower part of the insulator there are pressure elements that are used to transmit pressure serve forces from the projecting part of the building onto the building. Such a pressure element is formed in the arrangement according to FIG. 1 by a pressure rod 4. This can have a round, rectangular or other cross-section. Due to its small cross-section, the pressure rod can very easily follow displacements of the balcony slab 2 perpendicular to the cutting plane, without major mechanical stresses occurring.

The pressure element shown in cross section in FIG. 2 a consists of several round pressure rods 5 of the same cross section, of which one rod is in the middle and the other surround it. This bundle of rods is surrounded by a sheathing 6, which prevents the rods transmitting the compressive forces from buckling.

2b shows an embodiment of a pressure element from a bundle of round pressure rods, of which the middle pressure rod 7 has a larger cross-section than the pressure rods 8 surrounding it. The middle pressure rod 7 serves primarily to buckle the thinner pressure rods 8 surrounding it prevent. This takes place in cooperation with the covering 6. The middle pressure rod 7 is tapered in the shape of a truncated cone at its ends. Such a design of this rod is advantageous if it is used in addition to the pressure rods 8 for pressure transmission. As a result, this rod can more easily follow the longitudinal displacements of the balcony plate 2 caused by temperature fluctuations.

Rectangular or other shaped rods can also be connected to form a bundle of any cross-section. So can For example, several rectangular bars can be arranged one behind the other in one plane in the longitudinal direction of the insulating body 3.

The arrangement shown in Fig. 3a shows the insulating body 3 in longitudinal section. Rectangular bars 9 are provided here as pressure elements, which may consist of wood or steel, for example. Reinforcement bars 10 guided through the insulating body 3 are also indicated.

3b shows the insulating body 3 according to FIG. 3a in cross section. The rectangular rod 9 extending in its longitudinal direction via the insulating member 3 addition, and is anchored in the concrete slab 1 as well as in the balcony ^p latte. 2 The ends of the rectangular bar 9 can be connected to anchor plates 11 or anchor bars 12 running perpendicular to its longitudinal direction. It would then be possible to transmit not only compressive forces, but also transverse forces via the rectangular bar 9, so that the reinforcing bars guided obliquely through the insulating body 3 could be omitted.

In the arrangements shown in FIGS. 3a and 3b, the pressure rods can be installed, for example, by inserting them from below into corresponding slots in the insulating body 3. In the arrangements according to FIGS. 1 and 2a to 2c, the pressure elements can be inserted, for example, by inserting them into corresponding openings in the insulating body from the side. After the respective pressure element is arranged flush in the insulating body, the adjacent concrete layers are made by filling in-situ concrete. Adhesion to the concrete and the compressive forces later acting on the pressure element keep it in position.

4a to 4c show three embodiments of pressure elements which are designed as rectangular bars 9. In Fig. 4a, the length of the rectangular bar 9 corresponds to the width of the insulating body 3. In the arrangement according to Fig. 4b, the length of the rectangular bar 9 is less than the average width of the insulating body 3. The insulating body 3 must therefore at the points where it the rectangular bars 9 surrounds, be made correspondingly narrower. In Fig. 4c, the length of the rectangular bar 9 is greater than the average width of the insulating body 3. This case can occur in particular when the longitudinal displacements of the projecting part of the building require a certain minimum length of the rectangular bars 9. The insulating body 3 must then be widened accordingly in the area of the rectangular bars 9.

5 shows the ends of a pressure rod 13 opposite pressure plates 14 which are embedded in the concrete ceiling 1 or in the balcony plate 2. Such pressure plates can be arranged wherever the pressure rods end on the concrete surfaces. This is the case, for example, in the arrangements according to FIGS. 1, 2c and 4a to 4c. The pressure plates 14 bring about a better pressure distribution. In this respect they have the same effect as the anchor plate 11 anchored in the concrete according to FIG. 3b. The anchor or pressure plates 11 or 14 can also be profiled, e.g. have a U-shaped design.

The pressure rod 13 in Fig. 5 has a relatively large cross section. It is therefore tapered at its ends towards the pressure plates.

In this way, on the one hand, a relatively large mobility of the pressure rod is achieved, on the other hand, this pressure rod can transmit relatively large pressure forces, and furthermore its thermal conductivity is reduced by the tapering of its ends. The pressure plates can be designed so that they contain means for centering the pressure rod 13.

If the pressure bars combined into a bundle are guided beyond the width of the insulating body into the adjacent concrete slabs, it is advantageous to let the ends of the bars diverge in the concrete in order to achieve better anchoring of the pressure bars. Such an arrangement is shown for example for the pressure element shown in cross section in FIG. 2a in FIG. 6.

The pressure elements are preferably arranged in the insulating body in such a way that they can be replaced later if necessary. For this it may be necessary to raise the balcony slab 2 a little to remove the pressure element and insert a new one.

All pressure-resistant materials are suitable for the rod-shaped pressure elements, e.g. Steel, wood, pressure-resistant and age-resistant plastics, glass, ceramics, plastic-concrete, synthetic resins and the like. The rods can consist of solid material, but they can also be hollow. If hollow rods are used, they preferably contain stiffeners by means of webs or partition walls.

Claims (19)

1. Pressure element for the transmission of compressive forces in a heat-insulating component for cantilevered building parts, the component consisting of an elongated insulating body made of thermally insulating material with reinforcement elements that extend essentially transversely to the insulating body and laterally projecting reinforcing elements, in which the one or more pressure elements are integrated consist of pressure-resistant material, characterized in that the pressure element consists of at least one rod-shaped element (4; 5; 7, 8; 9; 13) which, due to its slenderness, is capable of temperature-related longitudinal movements of the projecting part of the building (2) relative to the Building (1) to follow elastically. 2. Pressure element according to claim 1, characterized in that the rod-shaped elements (5; 7, 8; 13) are round. 3. Pressure element according to claim 1, characterized in that the rod-shaped elements (9) are rectangular. 4. Pressure element according to one of claims 1 to 3, characterized in that it is formed by a bundle of a plurality of parallel rod-shaped elements (5; 7, 8). 5. Pressure element according to claim 4, characterized in that the bundle of rod-shaped elements (5; 7, 8) is surrounded by a common envelope (6). 6. Pressure element according to claim 4 or 5, characterized in that the bundle of round rod-shaped Elements (7, 8) are such that one element (7) of larger diameter is surrounded by several elements (8) of smaller diameter. 7. Pressure element according to claim 6, characterized in that the central element (7) of larger diameter tapers at its two ends. 8. Pressure element according to claim 4, characterized in that the bundle consists of in a longitudinal direction of the insulating body (3) one behind the other rectangular bars. 9. Pressure element according to claim 3, characterized in that the longer edge of the rectangular rod-shaped elements (9) perpendicular to the temperature-related longitudinal movements of the projecting part of the building (2). 10. Pressure element according to claim 9, characterized in that the ends of the rod-shaped elements (9) in the projecting part of the building (2) and in the building (1) are anchored and with transverse to their longitudinal direction plate or rod-shaped anchor bars (11, 12) are connected. 11. Pressure element according to one of claims 1 to 10, characterized in that the rod-shaped elements can be inserted or inserted laterally or from below into corresponding openings in the insulating body (3). 12. Pressure element according to one of claims 1 to 11, characterized in that the insulating body (3) in the region of the rod-shaped elements (9) has a different thickness than in the other areas. 13. Pressure element according to one of claims 4 to 7, characterized in that the ends of the rod-shaped elements (5) arranged in the bundle are anchored in the projecting part of the building (2) and / or in the building (1) and arranged to diverge. 14. Printing element according to one of claims 1 to 9, 11 or 12, characterized in that it is arranged interchangeably. 15. Pressure element according to one of claims 1 to 9, 11 or 12, characterized in that the ends of the rod-shaped elements (13) are arranged opposite in the projecting part of the building (2) and / or in the building (1) pressure plates (14). 16. Pressure element according to one of claims 1 to 3, characterized in that the rod-shaped elements (13) tapers at their ends and these are arranged opposite in the projecting part of the building (2) and / or in the building (1) pressure plates (14). 17. Pressure element according to one of claims 1 to 16, characterized in that the rod-shaped elements consist of solid material. 18. Pressure element according to one of claims 1 to 16, characterized in that the rod-shaped elements are hollow. 19. Pressure element according to claim 18, characterized in that the rod-shaped elements are provided with internal stiffeners.

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