DE19652165A1 - Insulating support body for overhanging balcony - Google Patents

Abstract

The insulating and support body (1) is for an overhanging balcony on a building. It is of rectangular cross-section and is made of material which is a good thermal insulator. There are slots on its top surface which accommodate reinforcing rods (2) under tension to support the balcony. The rectangular-section insulating body is made in two pieces with upper and lower portions divided by a diagonal joint. This joint may accommodate cranked reinforcing rods (3) which are used for diagonal bracing.

Description

The invention relates to a prefabricated component according to the Preamble of the main claim.

Prefabricated components for the formation of balcony slabs have the task not only the required load-bearing capacity for the balcony slab create, but must also be attached to the main structure be concluded that on the one hand a power transmission in the Main structure when the balcony slab is loaded, others because heat transfer is prevented as far as possible, so that in winter such balcony slabs no cold bridges for that Represent main structure.

The invention is based, based on the task well-known precast panels to create an arrangement with which it is possible, together with that for the balcony certain precast plate a connection arrangement to the To deliver the construction site, on the one hand the required strength, on the other hand, the required low heat transfer coefficient has, but also by using concrete billi ger is formed than if the connection exclusively via Steel components are made.

This object of the invention is achieved by Teaching of the main claim solved.  

Advantageous embodiments are in the subclaims purifies.

In other words, an insulating body will beat, which is equipped with connecting means that connect on the one hand to the reinforcement of the main structure, on the other hand allow connection to the reinforcement of the prefabricated part of the balcony slab, but with concrete thrust bearings in the lower area , ie connected to the main structure at the height of the precast slabs. The use of such, made of concrete thrust bearing is wesent Lich cheaper than a connection via metal components, especially stainless steel, which has a high thermal conductivity. It was surprisingly found that if, for example, every 17 cm continuous openings of a size 5 × 5 cm, ie width × height, are seen in the insulating body, these openings are then filled with normal elements having a concrete strength of B25, these elements have a concrete strength of B45 due to their geometry. The recesses are filled with a concrete mixture that has a low thermal conductivity, but at the same time a high strength is achieved by the geometry for these teeth or thrust bearings.

In addition, it is now possible to manufacture the Precast plate at the same time the insulating body in the concrete plant to deliver, so that in the manufacture of balconies the arrangement reinforcement in the insulation body easier to the respective Construction can be adjusted, which in the manufacture in the prefabricated concrete component plant a more flexible and cost-effective  production is achievable, on the other hand on the construction site can be worked faster than before.

The tension rods installed in the insulation body are available preferably made of V4A steel, because it has a favorable heat has transition value, the transverse bars also a corresponding stainless steel can be manufactured. It However, other types of stainless steel can also be used or surface-treated steels, for example galvanized Steels, or surface-coated, e.g. B. plastic coating steels.

Is the unit consisting of the prefabricated panel and the insulating body connected to the structure and the tension rods with the construction factory, the free space above the precast slab, which is equipped with the lattice girders, cast with in-situ concrete sen.

In a modified embodiment of the invention, so be proceeded that the shear bar partially through there is a recess that is provided in the insulating body, then when casting the attached to the building Finished component now filled this opening with in-situ concrete becomes. This in-situ concrete filling is immediately above the concrete thrust bearing.

In a further embodiment of the invention, the above gone that on the shear bars made of metal is dispensed with and the transverse force is absorbed in that in the insulating body preferably - seen from above -  dovetail-shaped recesses are provided, which run diagonally from the top outside to the bottom inside and which are filled with concrete. These shear supports then put the shear bars made of metal.

Exemplary embodiments of the invention are described below hand of the drawings explained. The drawings show in

Fig. 1 shows a view of an insulating body with inserted tension rods and shear bars, in

Fig. 2 is a prefabricated component consisting of a prefabricated plate, cast-on insulating body and inserted lattice girder and tension and shear bars, in

Fig. 3 is a sectional view through part of a wall body to illustrate the invention, in

Fig. 4 is an illustration of FIG. 3 in a modified embodiment and in

Fig. 5 shows a modified embodiment of the invention.

In Fig. 1, an insulating body 1 is shown, which consists of an insulating material that is poorly heat-conducting. Are in the insulating body 1 incorporated in the upper portion tension members 2 and in the central region transverse force rods 3, wherein the transverse force rods 3, so as to show clearly Figs. 2 and 3, pass through the insulating body obliquely. Both the tension rods 2 and the transverse force rods 3 are made of stainless steel, which is less thermally conductive than normal steel, preferably so-called V4A steel.

In the lower region of the insulating body 1 , recesses 4 can be seen , which are used to form thrust bearings 5 , the recesses having a size of 10-70 cm ² , for example 5 × 5 cm, having a distance of 17 cm, while the whole Insulation body has a length of 1.05 m. In contrast to the illustrated embodiment, it can be provided to close the recesses 4 of the insulating body 1 th. The underside of the insulating body 1 can be covered in example by a continuous adhesive strip. This holds the underside of the insulating body 1 together over its length and prevents the insulating body 1 from moving apart and curving like a fan at the bottom. Furthermore, damage to the webs between the cutouts 4 is avoided. The adhesive strip can later be removed to enable a visual inspection of the thrust bearing 5 . Instead of an adhesive strip, other covering materials can also be provided, possibly even non-removable covering materials: the recesses 4 do not necessarily have to open on the lower edge of the insulating body.

To clarify the proportions, it is pointed out that the insulating body 1 can have a width of 8 cm and a height of 20 cm.

The insulating body 1 is constructed in two parts: the oblique dividing line between the upper part and the lower part of the insulating body 1 runs in the inclined plane, along which the transverse force rods 3 run with their obliquely running middle section. In this way, the transverse force wires 3 can be placed in a simple manner on the lower part of the insulating body 1 , so that a quick assembly is supported with little expenditure of time. Arranged in the upper part of the tension rods 2 can Dämmkör pers 1 by slots which are provided in the upper part of the insulating body 1 can be inserted into this shell, so that here also a very rapid mounting is supported. As an alternative to such slots, provision can be made only to provide through holes in the upper part of the insulating body 1 .

In Fig. 2 and 3, a pre-assembled plate 6 is seen from the girder 11 and the connecting them tension rod 9 are visible. When casting the precast plate 6 , the procedure is such that a concrete mixture is used to form the thrust bearing 5 in the area of the recesses 4 , which has high compressive strength, but has a low thermal conductivity, these properties being achieved by appropriate impacts. To achieve the low thermal conductivity, z. B. basalt and / or lime mixtures added as additives.

The finished cast prefabricated plate 6 thus engages with thrust bearing 5 in the recesses 4 , so that the finished part shown in Fig. 2 is created, which can now be attached in place on the building, as shown in Fig. 3, where in Fig. 3, the wall body 7 and 8 are shown and the building-side tie rod 10 can be seen. The tension rod 2 located in the insulating body 1 is made of stainless steel and is extended for cost reasons by welded extensions made of special steel, since outside the insulating body 1 in the concrete itself the corrosion-resistant properties of the stainless steel are not required. The visible in Fig. 3 free space is the area, then in-situ concrete is in the cast, and the wall bodies 7 and 8 covers, on both sides of the heat insulation 12, the side with the outside and are embedded in the then the transverse force rods 3.

In the embodiment according to FIG. 4, the prefabricated part plate 6 a is again recognizable, further the thrust bearing 5 a which fills the concrete and fills the next existing recess 4 a and the transverse force rod 3 a, which in the embodiment shown in FIG. 4 is flatter than at the embodiment shown in Figs. 1 to 3.

In addition, a recess 14 is provided above the thrust bearing 5 for the in-situ concrete to be poured in later, whereby a connection is created between the building-side in-situ concrete and the in-situ concrete of the balcony slab and whereby the transverse force wire 3 a is surrounded on all sides by concrete. It is therefore protected against corrosion so that it does not have to be made of stainless steel.

In the embodiment according to FIG. 5, the transverse force rods made of stainless steel are avoided and the transverse force is absorbed by transverse force supports 15 . This shear force supports 15 are achieved in that in the insulating body 1 b are seen in the plan view dovetail-shaped recesses into which a concrete 16 applied in the prefabricated structure can flow. For this reason, the last lattice bar is equipped with an expanded metal 17 , which shields the outflow of concrete 16 to the free end of the balcony element 6 b.

In Fig. 5, the thrust bearing 5 is b recognizable again, which is obtained from a poorly heat conductive but highly pressure-resistant concrete.

The insulation body 1 can be viewed and used as lost formwork. Both when pouring the in-situ concrete and when the balcony slab is not manufactured as a thin slab 6 in the precast concrete sub-plant, but as a complete concrete slab with its final layer thickness, which can be between 12 and 30 cm.

Claims (8)

1. Prefabricated component for a cantilevered balcony slab, characterized by

• a) store an insulating body ( 1 ) as a prefabricated component with tension rods ( 2 ) distributed over the length, incorporated transverse force rods ( 3 ) and recesses ( 4 ) provided in the lower area to form pressure ( 5 ),
• b) a prefabricated panel ( 6 ) corresponding to the balcony size, which engages in the recess ( 4 ) with tooth-like thrust bearings ( 5 ),
• c) thrust bearing ( 5 ), which are formed from a concrete mixture with low thermal conductivity and a compressive strength.

2. Prefabricated component according to claim 1, characterized in that the recess ( 4 ) have a geometry of 5 × 5 cm (width × height) size. 3. Prefabricated component according to claim 1 or 2, characterized in that the prefabricated panel ( 6 ) with the integrally formed insulating body ( 1 ) is made in one piece. 4. Prefabricated component according to one of the preceding claims, characterized in that the tension rods ( 2 ) of the insulating body ( 1 ) are formed from V4A steels. 5. Prefabricated component according to one of the preceding claims, characterized in that the transverse force bars ( 3 ) are made of V4A steels. 6. Prefabricated component according to one of the preceding claims, characterized in that the prefabricated panel ( 6 ) and its lattice girder ( 11 ) with the tie rod ( 9 ) can be filled with in-situ concrete. 7. prefabricated component according to claim 1, characterized in that the transverse force rod ( 3 a) partially through the recess ( 4 a) and in the insulating body ( 1 a) a further recess ( 14 ) is seen before, which above the recess ( 4th a) is provided for the thrust bearing ( 5 a) and can be filled with in-situ concrete ( Fig. 4). 8. Prefabricated component according to one of the preceding claims, characterized by in the insulating body (1 b) above the recess for the thrust bearing ( 5 b) provided, in plan view dovetail-shaped recesses which fill out with concrete serve as shear force supports ( 15 ).