DE3302719C1 - Component for heat insulation in buildings - Google Patents

Abstract

1. A building (construction) element for thermal insulation of buildings, especially in cantilevered projecting exterior portions, comprising an elongated insulating body (1, 2) of a thermally insulating material ; elongated metallic reinforcing elements (6, 7) which extend substantially transversely with respect to the insulating body (1, 2) and which protrude laterally ; and compression elements (12) for force transmission between the cantilevered projecting portion and the remainder of the building portions ; with the insulating body (1, 2) comprising an upper part (2) and a lower part (1) provided with recesses (5, 8) for the reinforcing elements (6, 7), and said upper part (2) and said lower part (1) being adapted to be secured to each other through complementary projections (4, 10) and notches (3, 11), characterized in that the upper part (2) includes grooves (5), extending horizontally in the installed state, for receiving reinforcing elements (6) which pass horizontally through the insulating body (1, 2), as well as pins (4) for the fixing of reinforcing elements (7) passing through the insulating body (1, 2) with an inclination to the horizontal ; that the compression elements (12) are adapted to be installed in the lower part (1) ; and that the reinforcing elements (6, 7) are adapted to be fixed by fitting together the upper part (2) and the lower part (1).

Description

The invention relates to a component for thermal insulation in buildings, in particular in cantilevered outer parts, with an elongated insulating body made of thermally insulating material, with elongated, metal reinforcement elements that extend essentially transversely to the insulating body and protrude laterally, and with pressure elements for transmitting force between the protruding Part and the remaining parts of the building.
In buildings that have protruding wall parts, for example balconies, loggias, outside landings, house entrance panels or the like, the problem of undesirable heat dissipation occurs, since such protruding wall parts are usually connected to a corresponding false ceiling in the building and form their extension to the outside . Thus, the protruding panels or wall parts represent cold bridges to the outside, which on the one hand result in heat losses and on the other hand can also cause structural damage.

There are therefore components between the protruding parts and the building provided that a Ensure thermal insulation on the one hand and satisfactory load transfer on the other. Through the DE-AS 30 05 571 such a component is known, which is designed as a prefabricated part and at least one Has pressure element which is integrated into the insulating body as a connecting core element and the cross section of the insulating body has appropriate dimensions. Here, the insulating body is in the reinforcement elements are inserted or cast in one piece. Pouring the reinforcing bars has the disadvantage that the insulating element including the reinforcement elements as a unitary whole from Production site must be transported to the respective construction site. In addition, each element must be used for can be specially made for the respective requirement. When inserting the reinforcing bars into the insulating body it is difficult to always get the desired alignment of the reinforcing bars. That Insertion is particularly problematic when the rods are bent over like a hook at their ends, as well as when they run obliquely through the insulating body, but are otherwise arranged horizontally, so that they have at least two break points.

The invention is therefore based on the object of providing a component for thermal insulation between protruding To create external parts and the building itself, in which the reinforcement elements - whichever

3 4

Shape - given in a simple manner with the insulating body.

be bound, this connection directly on site. The insulating body consists of a lower part 1 as well the use of the component or in the manufacturer's an upper part 2. The lower part 1 is in the longitudinal direction can be done. It should be as precise a device as possible one behind the other recesses 3 verse alignment the reinforcement elements with reference to the 5 hen. The upper part 2 has the recesses 3 of the insulating body occur. part 1 opposite pin 4 on. When meeting

This object is achieved in the case of the above-mentioned assembly of the upper part and the lower part, the structural element according to the invention being achieved in that the recesses 3 completely accommodate the pegs 4.
Insulating body consisting of an upper part and a lower part Between the pins 4 are located on the lower part, the reinforcement elements io te of the upper part 2 grooves 5 in the upper part, in which the horizontally extending and pressure elements are arranged in the lower part reinforcing bars 6 are inserted. This reinforcement rods and rods 6 that plug together the upper part and the lower part serve to accommodate horizontal pullable rods. Tensions. The lower edge of the pin 4 runs

The horizontal and the oblique through the insulating body obliquely to the horizontal. Reinforcing rods 7 guided through insulating bodies are attached to the upper part 15 at an angle through the extending reinforcing rods and form a reinforcing cage. You are solidified. These are also preferably located in such a way that they are unmeasurably oriented towards the upper edge of the insulating body. The lower side of the pin 4 runs parallel to the lower edge. In particular, the horizontal rebar grooves 8, in which the rebar 7 are inserted, have to be fixed at a fixed distance from and then on top. The reinforcing bars 7 die-surface of the balcony or the ceiling. Therefore, 20 can also be used to absorb vertical forces. The fastening of the insulating body is well aligned at the top and attached to the area around the reinforcing bars 6 or 7 in the grooves 5 or reinforcement of the ceiling or balcony. 8 can be done with the help of an adhesive or through brackets attached to the grooves because the pressure elements are arranged in the lower part,
and thus lie in the area of the pressure zone, the assembly of the in FIG. 1 the optimal transmission of forces between the previous 25 follows in such a way that first the reinforcing bars 6 cantilevered outer part and the building ensured. and 7 inserted or on in the corresponding grooves

The upper part preferably has to be attached to the corresponding surfaces in the upper region. then horizontal grooves for receiving the horizontal are the upper part 2 and the lower part 1 of the insulating body reinforcing elements crossing the body. The pins 4 and pins for defining obliquely to the horizontal 30 hinden completely into the corresponding recesses 3 Reinforcing elements traversing the insulating body, pressed in. The inclined reinforcing bars th and if the lower part is to be torn with recesses, the walls of the recesses 3 break provided with an engaging recording of the pin. Then down to a depth that corresponds to their penetration depth, at the lower part is in the area of the recesses. The reinforcing bars 7 are placed so that they partly so thin-walled that it hit the recesses when inserting 35 where their walls stick the cone is thinnest due to the manure held by it. They therefore only leave behind vertically inclined reinforcing elements up to their running, slot-like incisions. The F i g. 2a and Penetration depth is breakable. 2b show the cross-sections of two different

The invention is based on the savings in the following. At the hexagonal recess after Exemplary embodiments shown in the drawing in more detail 40 F i g. 2a is obtained without the additional measure that is explained. It shows the points at which the wall of the lower part is at

F i g. 1 is a section through the insulating body is thinnest. Between these two points will be

right to its longitudinal direction with inserted reinforcement- the reinforcement bars 7 through the lower part 1-

bracing elements; guided. F i g. 2b shows a rectangular recess

F i g. 2a the top view of a recess in the bottom 45 3. Around here two defined points with the thinnest

part of the insulator; Wall thicknesses are to be created on opposite

F i g. 2b shows the plan view of a further, differently designed sides of the recess 3 in the lower part 1, two imagined Recess in the lower part of the insulating body; Sections 9 provided, whereby it is determined at which

F i g. 3 the view of the long side of a second area of the corresponding reinforcing bar 7

Embodiment of the upper part and the top view of 50 is passed through the insulating body,

the corresponding section of the base; The pins 4 fit frictionally into the recess

F i g. 4 shows a section through a further embodiment 3, so that after the lower mold has been joined together the insulating body perpendicular to its longitudinal direction part 1 and the upper part 2 this frictionally averaging; are connected to each other and only with the use of force

F i g. 5 a section through a further embodiment 55 can be separated again. To the strength dieform of the insulating body perpendicular to its longitudinal connection can be increased in the upper part 2 tung; additional pin 10 and in the lower part 1 corresponding

Fig.fe a device for fastening the lower additional recesses 11 may be provided, which are not

part. for traversing reinforcing bars through the

The in Fi g. The insulating body shown is & o insulating bodies are used, but only serve the task of, for example, between the floor slab of a balcony, the frictional force between the upper and lower part and an intermediate ceiling of a building. He is pre-raise. Furthermore, the connection can be improved in the plane of the insulating plaster that an adhesive is arranged between the contacting building wall. It should be brought into contact with the upper and lower part,
tion between the bottom plate of the balcony on the one hand 65 In the lower area of the lower part are in and the outer wall of the building as well as the intermediate longitudinal direction of the insulating body one behind the other, on the other hand, largely prevent and thus arranged pressure elements. These consist, for example, of optimal thermal insulation between them made possible by a pressure plate 12 made of a rubber-elastic one

Material and pressure-distributing layers 13 and 14 made of a hard material on both sides of the pressure plate 12, the outside of which are preferably in one plane with the outside wall of the lower part 1. The printing plate 12 and the layers 13 and 14 are preferably glued into the lower part 1. The arrangement of the Pressure elements in the lower area of the lower part 1 is a good transmission of the forces from the cantilevered Allow plate on the building.

In Fig. 1 the pressure element is only for convenience Representation arranged directly under the recess 3. As a rule, however, there are recesses 3 and pressure elements offset from one another in the longitudinal direction of the insulating body to the strength of the lower part, which is preferably made of a foam such as polystyrene.

In Fig. 4 shows an upper part 2 which is wider than the lower part 1 and which is in the assembled state these two parts engages around the upper outer edge of the lower part. This gives you a still fixed j20 re connection of the two parts. In addition, the guidance of the reinforcing bars 6 through the insulating material and thereby the distance between the points where these rebars on one side in the Balcony slab and on the other side in the false ceiling are clamped, extended. This results in The following advantage: The insulating body creates a separation between the balcony (Component with changing temperature) and the building (component with usually constant temperature). This creates temperature-related movements between the balcony and the building, which cause the horizontal reinforcing bars stress on bending. The greater the distance between the balcony slab and the false ceiling is, the lower the bending stress.

To fix the upper part mechanically, which is particularly important for transport, is recommended it is appropriate to provide a reinforcing bar 15 extending in the longitudinal direction in this. This can be made of wood, Steel, plastic or the like exist and is inserted into the upper part 2 or already during its manufacture foamed.

In order to ensure a firm connection between upper part 2 and lower part 1, especially during transport, one can run through in the pin 4 of the upper part in the longitudinal direction of the insulating body Openings 16 as well as in the lower part 1 also running in the longitudinal direction between the recesses 3 Provide openings 17 through which a rod is inserted after the upper and lower parts have been joined who holds these parts together. Several openings arranged one above the other can be arranged in the lower part 17 may be provided so that the insertion depth of the pin 4 can be varied.

F i g. 6 shows the fastening of the lower part before the balcony slab and the false ceiling are attached. The lower end of the lower part 1 is enclosed by a U-shaped holder 18 which is attached to the balcony protruding side has a protrusion. This projection is on the formwork 19 for the balcony slab attached to. Fastening to the top of the building wall 20 is also possible in a corresponding manner.

To the claimed component for ceilings of different thicknesses, for example for the range of 14 cm to 25 cm, can be used, if necessary, a piece of the lower part 1 in the upper area be cut off accordingly. The pins 4 must therefore not extend over the full length of the recesses 3 extend. Even when the peg is fully inserted, there is usually a cavity in the lower part Area of the recesses 3. In this cavity, however, when the balcony slab is subsequently poured or the functional ceiling, no concrete runs in, as the recesses are covered from above by the pegs are, and, as far as the walls of the lower part 1 have been torn open by the reinforcing bars 7, the corresponding Downward cuts through the rebar 7 itself can be closed. The good thermal insulation of the insulating body is thus retained.

1 sheet of drawings

Claims (12)

Patent claims: 1.Component for thermal insulation in buildings, especially in the case of protruding exterior parts, with an elongated insulating body made of thermally insulating material, with elongated, metal ones Reinforcement elements that extend essentially transversely to the insulating body and protrude laterally, and with pressure elements for power transmission between the protruding part and the rest Building parts, characterized that the insulating body consists of an upper part (2) and a lower part (1), wherein in the upper part (2) the reinforcement elements (6, 7) and in the lower part (1) the pressure elements (12) are arranged and that the upper part (2) and the lower part (t) are designed to be plugged together. 2. Component according to claim 1, characterized in that the upper part (2) in the upper region horizontal grooves for receiving reinforcement elements horizontally traversing the insulating body (6) and pin (4) for the definition of reinforcement elements crossing the insulating body obliquely to the horizontal (7) and that the lower part) with recesses (3) for frictional engagement Receiving the pin (4) is provided. 3. Component according to claim 2, characterized in that the lower part (1) in the region of the recesses (3) is so thin-walled that when you insert the pin (4) through the of these held, inclined reinforcing elements (7) can be broken up to their penetration depth is. 4. The component according to claim 2 or 3, characterized in that the pin (4) at its lower Provide the end with grooves (8) to guide the inserted, sloping reinforcement elements (7) are. 5. Component according to one of claims 2 to 4, characterized in that additional, only for strengthening the connection between the upper and lower part (2 and 1), arranged on the upper part (2) and in additional recesses (11) of the lower part (1) frictionally engaging pins (10) are provided. 6. Component according to one of claims 2 to 5, characterized in that the upper part (2) in the upper area is wider than the lower part (1). 7. The component according to claim 6, characterized in that the upper part (2) in the assembled State encompasses the upper area of the lower part (1). 8. Component according to one of claims 2 to 7, characterized in that for strengthening the connection between the upper part (2) and the lower part (1) by means of an insertable rod or the like, the pins (4) at least one continuous opening (16) running in the longitudinal direction of the insulating body and the lower part (1) has a plurality of longitudinally arranged one behind the other in the longitudinal direction of the pin through openings running through the insulating body (17). 9. Component according to one of claims 2 to 7, characterized in that to stabilize the Upper part (2) in its upper area in the longitudinal direction of the insulating body is a continuous rod (15) is arranged. 10. Component according to one of claims 1 to 9, characterized in that the Bcwchrungselemente (6,7) can be attached to the upper part (2) by means of clamps or adhesive. 11. Component according to one of claims 1 to 10, characterized in that the lower part (1) with the help of one of its lower end encompassing U-shaped holding element (18) can be fastened to the casing (19). 12. Component according to one of claims 1 to 11, characterized in that the lower part (1) to adapt to the respective thickness of the to be isolated Building parts can be changed in height by cutting off its upper area.