DE19722051A1 - Modular building component system for heat insulation - Google Patents

Abstract

The insulating bodies (1, 5) are fitted between the building and outer parts in the seam area, next to one another and one of them is provided with integrated reinforcement bars (2, 3, 4). These bars run crossways through the insulating body and are effectively connected on both sides with the adjoining building parts. The other insulating body has no reinforcement bars. The connection between adjacent insulating bodies (1, 5) is by means of a separate connecting component (7), which runs from one insulating body at least to the next and in the seam direction extends at least over the major part of the length of the insulating bodies to be joined.

Description

The invention relates to a modular component system for thermal insulation between one preferably to beto part of the building and a cantilevered outer part, consisting of at least two to lay in between the to be arranged side by side in the direction of the joint with interconnectable insulating bodies, of which the one is equipped with integrated reinforcing bars, which run across this insulating body and in active connection on both sides with the adjacent components stand, whereas the other insulating body does not Reinforcement bars must have.

Insulating body with integrated reinforcing bars allowed cantilevered external parts, especially balconies plates, with the corresponding false ceiling of a Ge to connect the building, taking the otherwise usual warmth bridges are largely eliminated. Therefore put such components are becoming increasingly stronger in practice through and are now in numerous execution known shapes. Because of their different dimensions They are practically common to everyone in practice suitable applications. The movement sticks increasingly also as basket or box-shaped Composite structures executed, which is why the term  "Reinforcement bar" here as a naturalized technical term for reinforcement elements in general.

A modular component system described above NEN type is known in the form that that of Beweh insulation bars passed through a box is made of hard plastic. This box has tabs elongated on both sides in the direction of the joint and in the space thus formed becomes one Insulated body made of hard foam inserted, the none Has reinforcing bars. At the latter Iso lier body again closes in the direction of the joint Box with reinforcing bars and side tabs. A The main disadvantage of this system is that the hollow plastic box only a little insulation kung.

The present invention is based on the object to increase the variability of the component system and to adapt it better to practical requirements. The component system according to the invention should through inexpensive construction and easy handling award.

The object is achieved in that the connection of adjacent insulating bodies by at least a separate connecting element is made by an insulating body at least until the next insulating body runs and at least in the direction of the joint over the predominant length of the iso to be connected body extends.  

The modular design with a separate ver binding element has the advantage that any in particular also of the same type, insulated can be ranked because you are no longer on Lich arranged connecting tabs is instructed. Furthermore, extending the separate verb leads element over the predominant length in joints direction of at least two insulating bodies to one off stiffness of the entire component system and thus too an important, especially in the construction site area design resilience.

The connecting element itself is advantageously in shape a bar executed, with bar all profiles continuing in a longitudinal direction means, for example, rods, pipes, beams Etc.

The connecting element expediently runs in one Groove that is arranged on an outside of the insulating body is not. This construction allows one particularly simple and inexpensive construction of the components of the Component system, because the connecting element is single needs to be attached laterally.

Similar advantages arise when connecting element runs in an opening that is inside the Insulating body is arranged.

The connecting element is preferably in cross section U-shaped and at least partially includes the insulating body wise on their top and / or bottom. You get  thereby protecting the sensitive edges of the Insulating body.

A particularly positive and fit together is enabled when the fastener is on Recesses or grooves of the insulating body attack, especially if it jams with the insulator or is locked.

At least two connecting elements run against each other overlying sides of the insulating body and these are Connecting elements can also be connected to one another, see above mutually secure yourself advantageously in their position and lead to another exit of the overall construction. Conveniently done such a connection of the connecting elements facing connectors that at the Run outside of the insulating body. Especially before however, an arrangement in which it from at least one connecting element in the Extend the insulator and connect with the other ver Binding element or connection arranged on it are connectable. In this way you can few, central connecting links that also be protected by the insulating body.

The links are also different Positions can be linked together, so the height or strength of the component system to different Ceiling heights or joint thicknesses can be set. This variable connection is expedient by a Locking mechanism guaranteed.  

Furthermore, it is advantageous if the Verbindungsele ment includes at least some of the reinforcing bars. There through these are increasingly fixed in their position and again the rigidity of the entire construction elevated.

A particularly simple assembly of the component system tems results when the connecting element to the Insulating bodies can be locked or clamped. It can but instead with at least one insulating body be glued.

For use with a variable number of isolators body, that means for the adaptation to different che joint lengths, the connecting element is advantageous can be cut to length along predefined separation points.

Further features and advantages of the invention result from the following description of Ausfüh Rungsbeispiele based on the drawings; shows

Figure 1 is a view of a modular component system obliquely from above, consisting of two insulating bodies with reinforcing bars and three unreinforced insulating bodies with predetermined separation points.

Figure 2 shows an alternative embodiment of a reinforced insulating body from the side.

FIG. 3 shows a view of the insulating body from FIG. 2 from above;

Fig. 4 shows a further alternative embodiment of an insulating body from the side and

Fig. 5, the connecting elements and connecting members of the embodiment of the construction according to Fig. 4.

The modular component system shown in the first embodiment consists of two prefabricated be reinforced insulating bodies 1 and three unreinforced insulating bodies 5 , 5 a and 5 b, which are arranged between a gebäudeseiti gene concrete slab and a cantilevered outer part, which is usually also made of concrete.

The insulating bodies 1 are traversed in their upper region by tension rods 2 and in their lower region by compression rods 3 , and also by transverse force rods 4 which, coming from the building-side train zone, run obliquely downwards through the insulating bodies and in the region of the pressure zone of the projecting component to step. From the drawn course of the shear bars in Fig. 1 it follows that one has to imagine the building on the right of the building and on the left the projecting outer part. On both sides of the reinforced insulating body 1 there are no reinforcing bars 5 , 5 a and 5 b with the same cross section, through which reinforcing bars are arranged, so that separation points 6 are arranged, so that an insulating body with reinforcing bars follows again on an insulating body without reinforcing bars. The insulating body 5 , 5 a and 5 b are each provided with separation points 6 so that they can easily be brought to the desired length.

It is now essential that a majority, suitably the entire sequence of insulating bodies is connected by a separate connecting element 7 , which runs in the direction of the joints from one insulating body to the next and thereby extends over the predominant length of the insulating body.

The connecting element 7 is designed in the form of a strip which runs in a groove, which in turn is arranged on the top and / or bottom of the insulating body.

The connecting element 7 is locked in its groove ver or jammed. For increased rigidity, it can be glued with at least one insulating body.

The modular component system shown in the second exemplary embodiment in turn consists of an insulating body 1 , tension rods 2 , compression rods 3 and transverse force rods 4 . However, the connecting element 8 has a U-shaped profile. It includes the top and the adjacent areas of the vertical sides of the insulating body running in the direction of the joint. This protects the corner areas in particular against damage. Furthermore, the tension rods 2 are fixed by the Verbindungsele element 8 , ie their position is secured relative to the component and thus the stability of the entire component is increased.

In the example shown, the insulating body has a particularly simple to produce rectangular basic shape. In other alternative embodiments, recesses can be provided in the area of the connecting elements, which allow a flush connection of the connecting element 8 to the contour of the insulating body.

In Fig. 3 it can be seen that the side cheeks of the connecting elements Ver 8 have openings for receiving the tension rods 2 .

Fig. 4 shows the cross section through an insulating body without reinforcing bars. In this embodiment, two connecting elements 8 a and 8 b are used. They face each other on the top and bottom of the insulating body. This is carried out by two sections 5 'and 5 '', which are L-shaped in vertical section.

The two L-shaped sections 5 'and 5 ''are rotated by 180 ° against each other and arranged without offset, so that the overall dimension of the insulating body in the insulation direction corresponds to the dimension of one of the two sections and their mutually protruding projections on each other dense system, while the outer vertical sides of the sections are aligned. The connecting elements 8 a and 8 b are connected to each other via connecting links 9 a and 9 b. The connecting links are designed in the form of tubes and extend from the connec tion elements into the insulating body and engage approximately in the center of each other. At its free ends a locking mechanism 10 is attached, which consists of corresponding depressions and elevations. This locking mechanism allows the distance between the connecting elements 8 a and 8 b to be varied and fixed. This allows you to change the height of the insulating body and the entire modular component system and adapt it to different ceiling heights.

Any gaps remaining between the sections 5 'and 5 ''of the insulating body are filled by insulating spacers 11 . The height of these spacers preferably corresponds to the grid dimension of the locking mechanism of the connecting links 9 a and 9 b.

For a particularly good insulation effect, it is advantageous if both the insulating bodies 1 , 5 , 5 a, 5 b, 5 'and 5 ''of the modular component system and the spacers 11 are constructed from the same insulating material (preferably hard foam), whereas the connecting elements 7 , 8 and the connecting members 9 a, 9 b consist of a plastic of higher strength, in particular of impact-resistant material.

Fig. 5 shows the connecting elements and connecting members from Fig. 4. It can be seen that the interlocking tubes 9 a and 9 b extend from top to bottom or from bottom to top and that several such corresponding pairs of tubes are arranged next to each other in the direction of the joint .

Claims (19)

1.Modular component system for thermal insulation between a part of the building which is preferably to be concreted and a cantilevered outer part, consisting of at least two insulating bodies ( 1 , 5 ) to be laid between them, to be arranged next to each other in the direction of the joint, one of which with integrated reinforcing bars ( 2 , 3 , 4 ) is provided, which run across this insulating body and are in active connection on both sides with the adjacent components, the other insulating body not having to have reinforcing bars, characterized in that the connection of adjacent insulating bodies ( 1 , 5 ) by at least a separate connecting element ( 7 , 8 ) is made, which extends from one insulating body at least to the next insulating body and extends in the direction of the joint at least over the predominant length of the insulating body to be connected. 2. Modular component system according to claim 1, characterized in that the connecting element ( 7 , 8 ) is designed in the form of a bar. 3. Modular component system according to claim 1, characterized in that the connecting element ( 7 ) extends in a groove or in recesses which are arranged on an outside of the insulating body. 4. Modular component system according to claim 1, characterized, that the connecting element in at least one opening runs, which are arranged inside the insulating body is. 5. Modular component system according to claim 1, characterized in that the connecting element ( 8 ) is U-shaped in cross section. 6. Modular component system according to claim 1, characterized in that the connecting element ( 8 ) extends at least partially on the top and / or bottom of the insulating body ( 1 , 5 ) and comprises them. 7. Modular component system according to claim 1, characterized in that at least two connecting elements ( 8 a, 8 b) extend on opposite sides of the insulating body and at least two of these connecting elements can also be connected to one another. 8. Modular component system according to claim 7, characterized in that the connection of the connecting elements ( 8 a, 8 b) by mutually directed connecting members ( 9 a, 9 b). 9. Modular component system according to claim 8, characterized in that the connecting members ( 9 a, 9 b) from at least one connecting element ( 8 a, 8 b) extend into the insulating body and with the other connecting element ( 8 b, 8 a) or arranged on it connecting elements are connectable. 10. Modular component system according to claim 7, characterized in that the connectivity of the connecting elements ( 8 a, 8 b) is ensured by a locking mechanism ( 10 ). 11. Modular component according to claim 1, characterized in that the connecting element ( 7 , 8 ) is made of impact-resistant material. 12. Modular component system according to claim 1, characterized in that the connecting element ( 7 , 8 ) is made of heat-insulating material. 13. Modular component system according to claim 1, characterized in that the insulating body ( 1 , 5 ) are made of rigid foam. 14. Modular component system according to claim 1, characterized in that the connecting element ( 8 ) also leads some of the reinforcement bars ( 2 ). 15. Modular component system according to claim 1, characterized in that the connecting element ( 8 ) on at least one insulating body ( 1 , 5 ) can be latched or clamped. 16. Modular component system according to claim 1, characterized in that the connecting element ( 8 ) with at least one insulating body ( 1 , 5 ) is glued. 17. Modular component system according to claim 1, characterized in that breaking points ( 6 ) are arranged for cutting to length on the connecting element ( 5 ). 18. Modular component system according to claim 1, characterized, that the component system is adjustable in height and can be fixed at the desired height. 19. Modular component system according to claim 1, characterized in that at least one insulating body ( 1 , 5 ) is divided into at least two sections ( 5 ', 5 ''), which in turn are vertically adjustable to each other.