DE29903589U1 - Component for thermal insulation - Google Patents

Abstract

The element consists of an insulation body (1) located between the two components (A,B). The insulation body has several shear force rods (4), which project through the components in the longitudinal direction of the insulation body. At least some of the shear rods extend in such a way that they are offset from each other in both the horizontal and the vertical plane.

Description

Description

The invention relates to a building element for thermal insulation between two components, in particular between a building (A) and a projecting outer part (B), consisting of an insulating body to be laid between them, which has at least transverse force rods that run through the insulating body transversely to the longitudinal extension of the insulating body and protrude at least on the building side, whereby they pass through the insulating body - starting from the building side - obliquely from top to bottom.

Such construction elements allow projecting external parts, especially balcony panels, to be connected to the corresponding intermediate ceiling of a building, whereby the otherwise usual thermal bridges are largely eliminated by the interposed insulating body. They are therefore becoming increasingly popular in practice and are now known in numerous designs. In addition to the shear force rods mentioned, the insulating bodies are generally also equipped with tension rods and compression rods so that the projecting external part does not require any further support. However, if the external part is supported at its end, the tension rods can be dispensed with. On the other hand, the compression rods are necessary in both cases to prevent the insulating body from being compressed.

The present invention is intended to improve the components mentioned so that they are characterized by a more universal force absorption.

This object is achieved according to the invention in that - with reference to the horizontal installation of the component - at least some of the transverse force rods run out of the vertical plane when they pass through the insulating body, in such a way that the ends of the transverse force rod emerging from the insulating body are not only vertically but also horizontally offset from one another.

The shear bars therefore run slightly inclined in the area of the insulating body compared to the vertical plane and can therefore absorb not only pure vertical forces, but also forces in a horizontal direction, parallel to the insulating body, depending on their angle of inclination compared to the vertical plane. Such forces transverse to the longitudinal direction of the bars can occur when the projecting outer part is subjected to wind or earthquake loads. Furthermore, investigations by the applicant have shown that horizontal stabilization forces occur particularly when steel beams are connected. Finally, horizontal constraint forces can occur due to different thermal expansion of the projecting outer part compared to the building. All of these forces have so far been absorbed by the reinforcement bars via bending stress. Due to this stress, the cross-sectional areas of the reinforcement bars cannot be optimally utilized in an elastic design.

In contrast, the design of the shear force rods according to the invention allows a much more stable fixation of the outer part and the previous bending stress on the reinforcing rods, which often involves a recurring alternating bending load, is eliminated. The reinforcing rods are therefore only subject to a pure normal force stress, so that the cross-sectional area of the rods penetrating the insulating body can be reduced to a minimum.

The inclination of the shear bars in relation to the vertical plane depends, as mentioned, on the expected shear forces. Investigations by the applicant have shown that an inclination of 3° to 35° is sufficient.

is sufficient, with an angle between about 10° and about 25° being preferable.

A particularly useful development of the invention consists in arranging the shear bars that are inclined according to the invention in pairs in a mirror image, i.e. opposite to each other. In this way, the horizontal reaction forces that occur during vertical loading compensate each other, i.e. the connected components do not experience any resulting horizontal stress.

Another advantageous development of the invention consists in choosing the inclination of the transverse force rods so that they approach each other from the building side to the projecting outer part. As a result, the transverse force rods on the outer part side are only a maximum of about 5 cm, in particular about 2 cm to about 4 cm apart, which is particularly advantageous if a wooden or steel construction is to be connected to the building instead of an outer part made of reinforced concrete, because the connection is then only local, quasi point-like, and not over the entire surface as with a balcony slab made of concrete.

For the same purpose, it is also recommended that the ends of at least one pair of crossbars on the outside part as well as the adjacent compression rod ends and, if applicable, adjacent tension rod ends are connected to a common fastening device, in particular a fastening plate. Projecting wooden or steel components can then be mounted on this fastening plate, preferably with the interposition of a connecting plate that fits the fastening plate. In this respect, to avoid repetition, reference is made to the patent application "Component for thermal insulation" filed on the same day by the same applicant, to which reference is made in full.

The connection of the shear force rod ends to the fastening plate is preferably carried out in such a way that the shear force rods are placed at an angle on the fastening

plate, i.e. the shear force rods do not need to be bent back into the horizontal plane at their outer part end. They can either pass through the fastening plate and be screwed or welded to it, or the fastening plate can have formed-on slanted stumps that correspond to the shear force rods arriving at an angle and are butt-welded at the joint.

Instead, the shear bars can also be connected to a fastening device in the form of an angle or in another form. For this purpose, reference is made to DE 195 28 130, to which reference is also made in full.

The transition from the inclined course of the shear force rod relative to the vertical plane to the horizontal course, which is to be implemented at least on the building side, but in numerous applications also on the external part side, is conveniently carried out via an arc, in particular a circular arc, whereby it is particularly advantageous to use this arc for the transition from the inclined course of the shear force rod relative to the horizontal plane to the horizontal plane. This means that one and the same arc is sufficient for both inclinations.

For optimal force transmission, it is recommended that the arched transitions are always located outside the insulating body and are thus supported in the concrete.

Finally, a further development of the invention consists in bringing protruding ends of the transverse force rods into operative connection with at least one transverse distribution rod running parallel and at a distance from the insulating body. This can be done in such a way that the transverse force rod ends are welded or tied to the transverse distribution rod or that the transverse distribution rod is laid in the immediate vicinity of the ends of the transverse force rods so that the desired operative connection is created via the concrete composite.

Instead of the aforementioned transverse distribution rod, which is arranged at a certain distance from the insulating body, it is also possible to work with a plate into which the transverse force rods run. This plate can in particular be the fastening device described above.

Further features and advantages of the invention will become apparent from the following description of embodiments based on the drawing, in which

Figure 1 is a front view of the component according to the invention, Figure 2 is a side view of the component according to Figure 1; Figure 3 is a view from above of the component according to Figure 1;

Figure 4 an alternative design of the component in an oblique view and

Figure 5 is an enlarged frontal view of the component according to Figure 4 with the insulating body removed.

The structural element shown in Figures 1 to 3 consists of an elongated, rectangular insulating body 1, which is equipped with a large number of tension rods 2 in its upper area and with the same number of compression rods 3 in its lower area. While the tension rods 2 extend far into the two adjacent concrete components, i.e. into the building indicated by A on the one hand and the cantilevered outer part B indicated by B on the other hand, the compression rods 3 only have relatively short projections compared to the insulating body 1 and are therefore provided with anchor plates 3a at their ends.

In addition, the insulating body 1 is equipped with several shear force rods 4, which enter the insulating body from the building side A approximately at the height of the tension rods, run diagonally downwards inside the insulating body and exit the insulating body approximately at the height of the compression rods 3 and continue into the cantilevered component.

It is now important that these transverse force rods 4 not only have this usual offset from top to bottom, but also an offset with respect to the vertical plane. The inclined course of the transverse force rods 4 with respect to the vertical plane can be seen in Figures 1 and 3. The angle at which the transverse force rods are inclined with respect to the vertical plane is approximately 20° in the exemplary embodiment.

Furthermore, it can be seen in Figures 1 and 3 that the shear bars are not inclined in the same direction, but that one half is inclined in one direction and the other half in the opposite direction.

Instead of the illustrated example, where the shear bars of the same inclination are grouped together, they can also be arranged alternately. The latter design is recommended if the reinforcement elements are to be concentrated as much as possible on the outside part, for example in order to connect them with a common fastening device. Such a design is shown in Figures 4 and 5.

The insulating body 1 is cuboid-shaped and significantly shorter than in the previously described component. For reasons of clarity, it is only indicated by a few dotted lines in Figure 4.

As can be seen in particular in Figure 4, the compression rods and the transverse force rods 4, after passing through the insulating body, open into a common fastening device 5, which is designed in the form of a plate and has a flat vertical contact surface on its outer side 5a facing away from the insulating body 1 for connecting the projecting outer part. From this outer part, a connecting plate 9 can be seen in Figure 4, which can preferably be mounted adjustably on the fastening device 5. For this purpose, the fastening device 5 is supported by adjustable stop nuts 6 on the compression rods 3 assigned to it. By turning the nuts 6 forwards or backwards on the compression rods 3, which in this case

have a thread, the position as well as the angular alignment of the fastening device 5 can be adjusted.

In the same way, the fastening device 5 could also be adjustably connected to the tension rods 2. In the exemplary embodiment, however, the tension rods 2 run through to the connection plate 9, whereby their position in the tension area can also be adjusted by the nuts 6' arranged on the tension rods, which of course must also be located on the rear part of the connection plate 9.

It is usually sufficient if the connection plate 9 can only be adjusted using the nuts 6' arranged on the tension rods 2. Then the nuts 6 arranged on the compression rods no longer need to be accessible from the outside but can be completely enclosed by the insulating body 1. In this case, the compression rods can also be welded directly to the fastening device 5, omitting the nuts 6. In both cases, the insulating body 1 can extend up to the fastening device 5 and extend vertically upwards from there; this automatically creates a gap in the upper area of the fastening device 5 in order to be able to turn the nuts 6'.

Alternatively, a connection of the fastening device 5 with the pressure rods 3 can be dispensed with, for example by supporting the outer part, in the exemplary embodiment its connection plate 9, directly on the pressure rods 3.

On its upper side, the fastening device 5 is provided with a horizontal support surface 5c, onto which a projection 9a mounted on the connecting plate 9 can be placed. This results in a positive transfer of the vertical transverse forces. In addition, this arrangement allows the connecting plate 9 to be leveled in height by placing spacer plates 23 between the support surface 5c and the projection 9a. Depending on the desired extent of height leveling, it is recommended to use the through holes in the connecting plate 9 for

to form the reinforcement bars as elongated holes. This provides optimal adjustability of the cantilevered outer part, not only horizontally and vertically, but also in terms of inclination.

The transverse force rods 4 are, as is particularly clear from Figure 5, arranged in such a way that they approach each other from the building side to the projecting outer part. However, they are no longer bent back to the horizontal at their lower ends, but run directly at an angle towards the fastening device 5. In order to nevertheless produce a welded connection that is optimal in terms of production technology and statics, the fastening device 5 has two stumps 5b that run diagonally upwards and are shaped and positioned in such a way that they correspond to the ends of the transverse force rods 4 that run diagonally downwards, so that the abutting surfaces on both sides run flush together and can be welded there, in particular by flash butt welding. These stumps can be produced by the fastening device 5 being a drop-forged part or by locally compressing it on the opposite side of the stumps, with the compression tools acting at an angle.

Claims (14)

_ Pal nsnriir.hi 1. Construction element for thermal insulation between two components, in particular between a building (A) and a projecting outer part (B), consisting of one of the insulating bodies (1) to be laid between them, which has at least transverse force rods (4) which run through the insulating body transversely to the longitudinal extension of the insulating body and protrude at least on the building side, whereby they pass through the insulating body - starting from the building side - diagonally from top to bottom, characterized, that - with respect to the horizontal installation of the component - at least some of the transverse force rods (4) extend out of the vertical plane as they pass through the insulating body (1), such that the ends of the transverse force rod (4) emerging from the insulating body (1) are offset from one another not only vertically but also horizontally. 2. Component according to claim 1, characterized in that the transverse force rods (4) in the insulating body 1 are inclined at an angle of 3 degrees to 35 degrees, in particular 10 degrees to 25 degrees, relative to the vertical plane. 3. Component according to claim 1, characterized in that the transverse force rods (4) are inclined in pairs in a mirror image to each other. 4. Construction element according to claim 1, characterized in that the inclination of the transverse force rods (4) with respect to the vertical plane is selected so that they approach each other from the building side (A) to the projecting outer part (B). 5. Construction element according to claim 1,1, characterized in that the distance between mutually associated transverse force rods (4) on the outer part side is a maximum of about 5 cm, in particular 2 cm to 4 cm. 6. Component according to claim 1, characterized in that the outer part-side ends of at least one pair of transverse force rods (4) and optionally adjacent ends of compression rods (3) as well as optionally adjacent ends of tension rods (2) carry a common fastening device (5). 7. Component according to claim 6, characterized in that the fastening device (5) is designed as a plate with a vertical outer side (5a). 8. Construction element according to claim 6, characterized in that the fastening device (5) has molded stumps (5b) which correspond to the transverse force rods (4) striking from above. 9. Component according to claim 6, characterized in that projections (9a) and/or recesses are arranged on the fastening device (5) and/or a connecting element (9) of the projecting component, via which the connecting element (9) is supported in the vertical direction on the fastening device (5). IC *·«· »it t« ·» «· 10. Component according to claim 6, characterized in that the fastening device (5) is adjustably mounted on its pressure rods (3). 11. Structural element according to claim 1, characterized in that the transition from the course of the transverse force rods (4) inclined relative to the vertical plane to the horizontal course takes place via an arc, in particular a circular arc. 12. Construction element according to claim 11, characterized in that the transition from the course of the transverse force rod (4) inclined relative to the horizontal plane into the horizontal plane follows the same arc. 13. Component according to claim 11 or 12, characterized in that the arcuate transitions are each located outside the insulating body (1). 14. Component according to claim 1, characterized in that the projecting ends of the transverse force rods (4) are in operative connection with at least one transverse distribution rod (10) running parallel and at a distance from the insulating body (1).