DE3309254A1 - PRINTING ELEMENT IN A HEAT-INSULATING COMPONENT FOR PROJECTING BUILDING PARTS - 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

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The invention relates to a pressure element for the transmission of pressure forces in a heat-insulating Component for projecting parts of a building, the component consisting of an elongated insulating body made of thermally insulating material with substantially transverse to the insulating body and laterally protruding reinforcement elements, in which the one or more pressure elements are integrated are made of pressure-resistant material.

In buildings that have protruding wall parts, such as balconies, joggias, outdoor platforms, house input plates or the like. have, in addition to the problem of undesirable heat dissipation as a result of the formation of cold bridges, the further problem that the projecting parts of the building, the are partially stored at their front on supports standing in the open air, and which are directly adjoining wall parts of the building differ in length and expansion movements due to temperature differences carry out. This can be disadvantageous in particular in the case of multi-storey buildings and lead to the formation of cracks and other structural damage.

DE-PS 30 05 571 a component for thermal insulation in buildings has become known that to solve these problems is integrated into 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 a risk that there is a rough surface on the one hand on the concrete on both sides of the wall part lying in the building, for example on the false ceiling, and on the other hand on the Concrete of the projecting part of the building adheres and

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does not allow any relative movement. If the projecting parts of the building are vertical or in . move in the horizontal direction due to thermal elongation relative to the building wall this creates high additional stresses for the connected components that have to last Can cause harm ..

To avoid such additional stresses, a pressure element was proposed in DE patent application P 32 44 472.9, which consists of a rubber-elastic material is formed. Hit one

for each pressure element designed in this way, relative movements of the projecting part of the building with respect to the building and the resulting tensile and compressive stresses in the elastically deforming pressure plate can be absorbed. On the other hand, however, these printing plates have a lower compressive strength. Their service life is therefore also relatively limited under high pressure loads. In addition, the rubber-like bearings yield under load, which means that the cantilever plates bend significantly.
The invention is therefore based on the object of creating a pressure element that, despite a high compressive strength and a long service life, is able to absorb the mechanical stresses when the cantilevered part of the building moves relative to the building without causing stresses that could damage the building or the cantilevered one Building part or on the pressure element can lead.

This object is achieved according to the invention in the initially mentioned pressure element in that the Pressure element consists of at least one rod-shaped element, which due to its slenderness

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is capable of temperature-related longitudinal movements of the projecting part of the building to follow the building g elastically.

This pressure element has the following main advantages:

JQ It has high compressive strength and through its relatively small cross-section has a desired low thermal conductivity. Its relatively high Elasticity makes it possible to follow horizontal displacements of the projecting part of the building, without significant mechanical stresses occurring. This also ensures a long service life the pressure elements guaranteed.

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

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 a

Insulating body with integrated pressure elements according to a fourth embodiment

example,

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 exemplary embodiment,

Fig. 5 shows a cross section through an insulating body with a pressure element according to a ninth embodiment and 20

FIG. B shows a cross section through an insulating body with a pressure element according to FIG 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 these, 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 insulator 3 is not shown extending from Bewehrungsstäben.durchquert obliquely to the horizontal part for receiving tensile and _Z to part for receiving and vertical forces through the insulating body. Usually in the lower part of the insulator there are pressure elements that are used to transmit pressure

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Forces from the protruding part of the building serve on the building. Such a pressure element is c in the arrangement of FIG. 1 by a compression rod

educated. This can be round, rectangular or otherwise shaped Have cross-section. Due to its small cross-section, the pressure rod can displace the balcony slab 2 very easily follow IQ perpendicular to the cutting plane without major mechanical stresses appear.

The pressure element shown in cross section in FIG. 2a consists of several round pressure rods 5 jg of the same cross-section, one of which is a rod in the center and the others surround it. This bundle of rods is surrounded by a sheath 6, which prevents buckling of the bars transmitting the compressive forces.

Fig. 2b shows an embodiment of a pressure element from a bundle of round pressure rods, of which the middle pressure rod 7 is a larger one Has cross section than the pressure rods surrounding it 8. The middle pressure rod 7 is primarily used here serves to prevent buckling of the thinner compression rods θ surrounding it. this happens in cooperation with the casing 6. The middle compression rod 7 is frustoconical at its ends rejuvenates. Such a configuration of this rod is advantageous when it is next to your pressure rods 8 is used for pressure transmission. This makes it easier for this rod to cope with temperature fluctuations caused longitudinal displacements of the balcony plate 2 follow.

Rectangular or other shaped rods can also be used to form a bundle any cross-section can be connected. So can

For example, several rectangular rods are arranged one behind the other in a plane in the longitudinal direction of the insulating body 3.
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The arrangement shown in Fig. 3a shows the insulating body 3 in longitudinal section. As printing elements rectangular bars 9 are provided here, for example can be made of wood or steel. Next-10

Reinforcing bars 10 guided through the insulating body 3 are indicated.

Fig. 3b shows the insulating body 3 according to FIG. 3a in

Cross-section. The rectangular rod 9 extends in Io

its longitudinal direction beyond the insulating body 3 and is in the concrete ceiling 1 and in the balcony slab 2 anchored. The ends of the rectangular rod 9 can extend perpendicular to its longitudinal direction

" _Ft anchor plates 11 or anchor iron 12 be connected. It ZM

V7cire possible, then not only pressure forces, but also Transverse forces are transmitted via the rectangular rod 9 so that the obliquely guided through the insulating body 3 Reinforcing bars could be omitted.

The installation of the pressure rods can, for example, in the arrangements shown in FIGS. 3a and 3b Insertion from below into the corresponding slots in the insulating body 3. According to the arrangements

On Fig. 1 and Fig. 2a to 2c, the pressure elements be inserted, for example, by inserting them from the side into corresponding openings in the Insulating body can be inserted. After the respective pressure element is arranged flush in the insulating body the adjacent concrete layers are made by filling in-situ clay. By the adhesion to the concrete and the pressure forces later acting on the pressure element, this becomes held in place.

4a to 4c show three embodiments of pressure elements which are designed as rectangular bars 9 _ are educated. In FIG. 4 a, the length of the rectangular rod 9 corresponds to the width of the insulating body 3. In the arrangement according to FIG. 4b, the length of the rectangular rod 9 is less than the average Width of the insulator 3. The insulator 3

l _ft must therefore be made correspondingly narrower at the points where it surrounds the rectangular bars 9. In Fig. 4c, the length of the rectangular rod 9 is greater than the average width of the insulating body 3. This case can in particular

ever occur when the longitudinal movements of the projecting building part _t a certain minimum length of the rectangular bars require. 9 The insulating body 3 must then be widened accordingly in the area of the rectangular bars 9.

Fig. 5 shows the ends of a pressure rod 13 opposite pressure plates 14, which in the Concrete ceiling 1 or embedded in the balcony pavement 2 are. Such printing plates can be used anywhere

ο «the pressure rods end on the concrete surfaces, arranged be. This is the case, for example, with the arrangements according to FIGS. 1, 2c and 4a to 4c. the Pressure plates 14 cause a better pressure distribution. In this respect, they have the same effect like the anchor plate 11 anchored in the concrete according to FIG. 3b. The anchor or pressure plates 11 and 14, respectively 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 at its ends tapered towards the pressure plates.

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In this way, on the one hand, a relatively large mobility of the pressure rod is achieved, and on the other hand, it can The compression rod transmits relatively large compressive forces and its thermal conductivity continues through the Tapering of its ends diminished. The pressure plates can be designed so that they means for centering the pressure rod 13 included.

Are the pressure rods combined into a bundle is guided beyond the width of the insulating body into the adjacent concrete slabs, so is it is advantageous to let the ends of the bars diverge in the concrete in order to achieve better anchoring to achieve the pressure rods. Such an arrangement is for example for the in Fig. 2a Pressure element shown in cross section in Fig. 6 dargeste11t.

The pressure elements are preferably arranged in the insulating body in such a way that they can be exchanged later if necessary can be. For this it may be necessary to lift the Baltan plate 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. solid and aging-resistant plastics, glass, ceramics, plastic-concrete, synthetic resins and the like .. The Rods can consist of solid material, but they can also be hollow. When using hollow rods these preferably contain stiffeners on the inside through bars or partitions.

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Claims (1)

Claims Pressure element for the transmission of pressure forces in a heat insulating component for projecting parts of the building, the component consisting of a elongated insulating body made of thermally insulating material with essentially transverse to the insulating jQ body-extending and laterally protruding reinforcement elements, in which the one or more pressure elements are integrated, which consist of pressure-resistant material, characterized in that the pressure element consists of .at least one rod-shaped element C4j 5 _} 7, Bi 9; 13), which due to its slimness is able to elastically follow temperature-related longitudinal movements of the projecting building part (2) relative to the building (1). 2. Printing element according to claim 1, characterized in that that the rod-shaped elements (5j 7, Bj 13) are round are. 3. Printing element according to claim 1, characterized in that that the rod-shaped elements (9) are rectangular. 4. Printing element according to one of claims 1 to 3, characterized in that it is formed by a bundle a plurality of rod-shaped elements (5j 7, B) running parallel next to one another is formed. 5. Printing element according to claim 4, characterized in that that the bundle of rod-shaped elements C5j 7, B) is surrounded by a common envelope (6). ε. Printing element according to claim 4 or 5, characterized in that that the bundle of round rod-shaped Elements (7, 8) consists in such a way that one element (7) of larger diameter is surrounded by several elements (ß) of smaller diameter. 7. Printing element according to claim 6, characterized in that the middle element (7) of larger diameter tapers at both ends. ß. Printing element according to Claim 4, characterized in that the bundle consists of in a longitudinal direction Insulating body (3) one behind the other rectangular bars. 9. Printing 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) runs. 10. Printing element according to claim 9, characterized in that the ends of the rod-shaped elements C9) in the cantilevered building part C2) and in building C1) are anchored and with transverse to their longitudinal direction extending plate or rod-shaped anchor iron (11, 12) are connected. on 11 printing element according to one of claims 1 to 10, characterized in that the rod-shaped elements into corresponding openings in the insulator C3) can be inserted or pushed in from the side or from below. 12. Pressure element according to one of claims 1 to 11, characterized in that the insulating body (3) in the area of the rod-shaped elements (9) a ~ 3 1 has a different thickness than in the other areas. _e 13. Printing element according to one of claims 4 to 7, dao characterized in that the ends of the rod-shaped elements (5) arranged in the bundle in the cantilevered Part of the building (2) and / or in the building (1] are anchored and arranged diverging. 10 14. Printing element according to one of claims 1 to 9, 11 or 12, characterized in that it is arranged to be exchangeable. 15. Printing element according to one of claims 1 to 9, 11 each or 12-, characterized in that the ends of the Bar-shaped elements (13) opposite one another in the projecting part of the building (2) and / or in the building (1) pressure plates (14) are arranged. 20th 16. Printing element according to one of claims 1 to 3, characterized in that the rod-shaped elements (13) is tapered at its ends and these are arranged ^{in the} building (1) pressure plates (14) opposite the projecting building part (2) and / or (25th 17. Printing element according to one of claims 1 to 16, characterized in that the rod-shaped elements consist of solid material. 30th 18. Printing element according to one of claims 1 to 16, characterized in that the rod-shaped elements are hollow. 35. 19. Printing element according to claim 18, characterized in that the rod-shaped elements with internal stiffeners are provided.