DE3244472A1 - PRINTING ELEMENT IN A PRE-HEAT INSULATING COMPONENT FOR PROTECTIVE BUILDING PARTS - Google Patents

Description

Ill * "' . ^: .X \ ^: " 32ΛΑ472

Henkel, Pfenning, Feiler, Hänzel a Meinig ^ """" °° Patent attorneys

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Eberhard Schock n.snnr, r.-i.jr: - ^ so

Kastanienhalde 11 Tel C "89-'98 ^{/> n} 8 ^c - ^p 7

7570 Baden-Baden SgI ^ SSo

December 1, 1982

Pressure element in a heat-insulating prefabricated component for projecting parts of the building

The invention relates to a pressure element in a thermally insulating prefabricated component for cantilevered building parts

, the prefabricated part

from an elongated insulating body made of thermally insulating Material with reinforcement elements extending essentially transversely to the insulating body and protruding laterally consists, in which the one or more pressure elements are integrated, which consist of pressure-resistant material.

In buildings , the protruding wall parts, such as balconies, loggias, outer platforms, house entrance panels or the like.

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have, exists in addition to the problem of an undesirable Heat dissipation as a result of the formation of cold bridges the further problem that the cantilevered building parts, the are partially mounted on their front on free standing supports, and the immediately adjoining Wall parts of the building perform different elongation movements due to temperature differences Ren. This "can have a disadvantageous effect, especially in multi-storey buildings, and lead to the formation of cracks and other structural damage.

To solve these problems, a component for thermal insulation in buildings has already been proposed in German Ausle-5 geschrift 30 05 571, 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 this pressure element there is a risk that it adheres on both sides with a rough surface on the one hand to the concrete of the wall part _f 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 does not allow any relative movement. If the protruding parts of the building move vertically or horizontally due to thermal elongation with respect to the building wall, this can result in high additional stresses on the connected components.

The invention is based on the object of designing a pressure element of the type mentioned at the outset in such a way that at no damage occurs to the movement of the cantilevered part of the building in relation to the building,

According to the invention it is provided that each pressure element

with a pressure plate made of a rubber elastic material is formed.

With a pressure element designed in this way, relative movements of the cantilevered building part with respect to one another can be achieved the building and the resulting tensile and compressive stresses in the elastically deforming compressive

2Q plate can be added. As a result, arise in the area the connection of the components to these no extremely large stresses directly, in particular no edge stresses / and due to the existing elasticity of the printing plate, this can cause thermal movements of the two Adjacent components yield elastically in such a way that no damage to the components or points of contact between the components develop. Due to the further envisaged choice of the rubber-elastic material with regard to the expected installation conditions, sufficient deformability is always guaranteed, with certainty Prevents damage from thermally induced relative movement of the components.

The pressure plate is preferably fastened centrally or laterally in the insulating body so that it is more advantageous Way, it is always precisely positioned and in its original form during installation.

If the pressure plate has a steel plate, in particular made of stainless steel, on at least one outside, it can When the concrete is subsequently set in concrete, it will bond with the steel plates. This will make the movement the opposing forces of the pressure plate occurring in the concrete parts are not directly transferred into the concrete with local accumulations, but taken from the steel plate and then

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evenly transferred to the components. Preferably each steel plate has at least the size of the pressure plate, so that the most favorable stress distribution possible is guaranteed. Besides, it is in this context advantageous if the steel plate is at least partially attached to the pressure plate. '■ ■

Instead of the steel plates can also preferably be provided that the pressure plate on at least one Outside has a hard, pressure-distributed material layer, which is advantageously at least the size the pressure plate has, is at least partially attached to the pressure plate and preferably after flared on the outside. By providing hard pressure-distributing material, simple materials such as concrete, ceramic plates, natural stone plates or the like at the point of contact with the elastic Stresses occurring on the printing material are well absorbed and evenly distributed. The materials must be like this be selected so that they can absorb the splitting forces, and the pure pressure loads are also more favorable Way through the increase in area, to which the conical expansion of the material layer to the outside also contributes, reduced. The thickness of the pressure element can correspond to that of the insulating body or, preferably, opposite this may be different, in particular larger.

Further details, features and advantages of the invention are also contained in the following part of the description.

The following are exemplary embodiments of the invention explained in more detail with reference to figures. Show it:

1 shows a section through an insulating body with an integrated pressure element according to the invention a first embodiment;

2 shows a vertical section through another insulating body with a second exemplary embodiment of the pressure element according to the invention; and

3 shows a section through yet another insulating body with a third exemplary embodiment of the printing element according to the invention.

In Fig. 1, only the immediate area around the pressure element 11 of the insulating body 10 is shown. That Pressure element is designed as a pressure plate 11, which consists of a rubber-elastic material that is when Installation of the insulating body 10 is only slightly deformed. The pressure plate 11 is centered in the insulating body 10 attached. The upper edge 14 of the pressure plate 11 is on the web 18, and the lower edge 15 on the web 19 of the Insulating body attached, for example, by gluing.

The webs 18 and 19 widen from the pressure plate. 11 facing away from the direction of the profile parts 20 and 21 of the insulating body 10. The recess formed in the insulating body 10 for receiving the pressure plate 11 is widened conically from both sides 12 and 13 of the pressure plate 11 to the outside.

Fig. 2 shows part of another insulating body 10 ', which only with the upper profile part 20' and the web 18 ' is formed, which is attached to the edge 14 'of the pressure plate 11' ^. The pressure plate 11 'has in this embodiment

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management example about the same size as in Fig. 1, however, it can also be made thicker or thinner. On the outer sides 12 'and 13 "of the pressure plate 11' are Steel plates 25 and 26 are arranged, which protrude above and below the pressure plate 11 'and its surface cover completely. The steel plates 25 and 26 are attached to the pressure plate made of rubber-like material ^ q 11 'vulcanized, glued or loosely inserted, whereby they remain in this position due to friction during installation. The steel plates 25 and 26 are made in terms of the loads to be absorbed preferably made of stainless steel.

In the further embodiment shown in FIG is a pressure plate 11 ″ that is approximately the same size and material as the pressure plates 11 and 11 "in the above embodiments, attached to a part of the insulating body 10", which is made of Insulating material is formed and has approximately the same shape as the insulating body 10 *. Different from that The embodiment according to FIG. 2 is here the outsides 12 "and 13" of the pressure plate 11 "provided with a hard pressure-distributing material layer 30 and 31 which the outer sides 12 'and 13' of the elastic pressure plate 11 "completely covered and here over the upper edge 14"

- and the lower edge protrudes 15 ". The layers of material 30 and 31 can be glued to the pressure plate 11 ″.

Your cut surface in Fig. 3 has the shape of an elongated Trapezoid, because the material layers 30 expand conically when viewed from the pressure plate 11 ″ outwards. The pressure distributing hard material is attached in such a way that that of the pressure plate 11 ″ and the material layers 30 and 31 existing printing element thinly

Diger than the insulating body 10 is. However, the thickness of the pressure element can also be the same as that of the insulating body.
§ 'speak or be larger than this.

The pressure elements shown in the individual exemplary embodiments are in a heat-insulating prefabricated component integrated for projecting parts of the building, whereby the pressure

I Q element in the embodiment according to FIG. 1 is used between the components before the in-situ concrete is introduced to produce the components. The pressure elements according to FIGS. 2 and 3 are used at the same stage, but are at the lower end of the insulating body 10 '

or 10 ". Since the rubber-elastic printing material provided has better thermal insulation properties than ceramic, concrete and the like, the
pressure element according to the invention not only in a simple and effective manner in the occurrence of damage

Movement of the cantilevered part of the building opposite the building, but also good thermal insulation
achieved.

Claims (13)

Pressure element in a heat-insulating Prefabricated component for projecting parts of the building P AT CLAIMS: Pressure element in a heat-insulating prefabricated component for projecting parts of the building , the prefabricated part from a elongated insulating body made of thermally insulating material with itself-essentially transversely to the insulating body extending and laterally protruding reinforcement elements in which one or more Integrated pressure elements made of pressure-resistant material characterized in that each pressure element (11, 11 ', 11 ") consists of a rubber elastip. see material is formed. 2. Printing element according to claim 1, characterized in that the elasticity of the material is such that J _0, the pressure plate (11, 11 ', 11 ") only slightly deformed during installation · 3. Printing element according to claim 1 or 2, characterized in that the 5 pressure plate (11, 11 ', 11 ") in the insulating body (10, 10V, 10 ") is attached in the middle or on the side. 4. Printing element according to claim 1, 2 or 3, characterized in that the pressure plate (11, 1-1 ' _f 11 ") has a steel plate (25; 26) at least on one outer side (12 ·; 13'). 5. Printing element according to claim 4, characterized in that the steel plate (25; 26) is at least the size of the pressure plate (11 ') owns. 6. Printing element according to claim 4 or 5, characterized in that the steel plate (25; 26) on the pressure plate (11 ') at least is partially attached. 7. Printing element according to claim 1, 2 or 3, characterized in that the I- "\. 32ΑΑ472 Pressure plate (11 ") has a hard, pressure-distributing material layer on at least one outer side (12"; 13 ") (30; 31). 8. Printing element according to claim 7, characterized in that the material layer (30; 31) is at least the size of the Has pressure plate (11 "). 9. Printing element according to claim 7 or 8, characterized in that the material layer (30; 31) at least partially on the Pressure plate (11 ") is attached. 10. Printing element according to one of claims 7 to 9, characterized in that the material layer (30; 31) widens conically outwards. 11. Printing element according to one of the preceding claims, characterized in that the thickness of the pressure element (11, 11 ', 11 ") is equal to the thickness of the insulating body (10, 10 ', 10 "). 12. Printing element according to one of claims 1 to 10, characterized in that the thickness of the pressure element (11, 11 ", 11") versus the thickness of the insulating body (10, 10 ', 10 ") is different. 13. Printing element according to claim 1, characterized in that the rubber-elastic Material is reinforced with at least one internal steel plate.