DE29602796U1 - Component for frost apron and for wall crown - Google Patents

Description

Construction element for frost protection and for wall crown

The invention relates to a construction element for frost protection and for wall crowns, which can be used for shallow foundations without significant excavation to prevent frost distortions and as a wall finish to accommodate ceiling elements, for example. For cost reasons, a basement is often not required when building a building. In the current state of the art, a foundation slab is then created at ground level or above ground level to form the foundation of the building. A strip foundation is required as a lateral boundary of the foundation slab until the foundation is frost-free. This strip foundation is referred to as a frost protection apron, whereby this frost protection apron is manually formed on the construction site using different methods and types of formwork, then filled with in-situ concrete and removed from the formwork. Small-format formwork blocks are also used for this purpose.
The disadvantage of this solution is that it requires a great deal of manual effort for formwork installation and demolding.

The object of the invention is to develop a construction element for frost protection aprons and for wall crowns, which is prefabricated as an individual part for the frost protection apron, grid dimension-oriented, standardized and mountable, consists of lightweight concrete, which has thermal insulation in the area of the foundation slab, which has protruding reinforcement as static connection reinforcement to the foundation slab and has built-in sealing systems for drainage and can be used for in-situ concrete casting to the solid ground as a load-bearing frost protection apron. The individual part for wall crowns is prefabricated, grid-sized, standardized and mountable from lightweight concrete, which can be provided with thermal insulation in the area of the ceiling support or not and can be provided with reinforcement as static connection reinforcement from the building element to the wall built on it and is suitable for in-situ casting to the ceiling and the wall arranged below as a load-bearing connection, furthermore these building elements should be adaptable to the geometric assembly conditions on site and consist of lightweight concrete with the addition of recycled material.

According to the invention, the object is achieved by the features specified in claims 1 and 2. Preferred developments of the invention emerge from the subclaims.

The advantages of the invention are that prefabricated, grid-sized, standardized building elements are available for a mountable frost protection apron, which are characterized as load-bearing building elements with integrated thermal insulation in the area of the foundation slab, with protruding reinforcement as static connection reinforcement from the building element to the foundation slab, with built-in sealing systems for drainage and with recesses for concrete intake in the in-situ concrete casting for a firm ground connection and as prefabricated, grid-sized, standardized building elements for a mountable wall crown, which are available with integrated thermal insulation or not with integrated thermal insulation, as required, in the area of the ceiling, which is provided with the reinforcement as static connection reinforcement from the building element to the ceiling and from the building element to the wall arranged on it with reinforcement as static connection reinforcement and is suitable for in-situ casting to the ceiling and to the wall arranged below as a load-bearing connection.
Furthermore, the use of the construction elements according to the invention avoids the high manual effort of forming and removing the formwork from the foundation strips for the production of the frost protection apron. The manual effort of creating the wall crown, which was previously formed and poured or bricked in the area of the ceiling support, is no longer necessary.
The construction elements for frost protection and wall crowns can be manufactured industrially, and they can be adapted to the geometric conditions on site, for example by cutting them using conventional saws.
The industrial production of the building elements is proof of their economical use. At the same time, the use of recycled waste materials, which is used as a lightweight concrete version of the building elements, is environmentally friendly, as the recycled waste materials used are not disposed of in landfills or incineration plants using large amounts of energy, as has previously been the case.

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The invention is explained below using the embodiments

- with Figure 1, as a component for frost protection

- with figure 2, as a building element for wall crowns
explained.

According to Figure 1, a building element 1 consists of a segment 2, which here serves as a frost protection apron segment, to which a support surface 3, a thermal insulation plate 4, which serves as a contact zone between the foundation plate and the frost protection apron as thermal insulation and expansion buffer, and reinforcements 5 as static connection reinforcement to the foundation plate and a support segment 6 for in-situ concrete, to which a recess as a groove 7 and a projection as a spring 8 are assigned vertically on the front sides so that the individual building elements 1 can be aligned in line with the grid dimensions, which in the upper area of . top to bottom conically widening cavities 9 are assigned and in the lower area trapezoidal hollow chambers 10 are connected which widen downwards and merge into the cavities 9, whereby the hollow chambers 10 open into a channel 11 connecting the hollow chambers 10, whereby the cavities 9, the hollow chambers 10 and the channel 11 serve to hold the concrete in the in-situ concrete casting for a firm ground connection as a load-bearing structural element 1 of the frost protection apron, to which a sealing system 12 is assigned for the connection of the drainage and which has transport eyes 13 in the upper area.

According to Figure 2, the building element 1 consists of the segment 2, to which the support surface 3 can be assigned to which the thermal insulation panel 4 can be provided, which can be provided as a contact zone between the ceiling and the wall placed on it as thermal insulation and serves as an expansion buffer, and the reinforcement supports 14 for the reinforcements are assigned as static connection reinforcements to the wall placed on top and of the support segment 6 for in-situ concrete, to which a recess as a groove 7 and a projection as a tongue 8 are assigned on the front sides, so that the individual building elements 1 can be aligned in a grid dimension-oriented manner, to which conically widening cavities 9 are assigned from top to bottom, which emerge on the lower surface of the building element 1, whereby the cavities 9 contain the reinforcement 5, which serves as

serve as static connecting reinforcement for the ceiling and serve as a load-bearing structural element 1 of the wall crown for the concrete in cast-in-place concrete for a firm ceiling closure.

The design of the structural element 1 as a lightweight concrete structural element is characterized by the fact that recycled waste material^ is mixed into the concrete, preferably polystyrene, which has a high thermal insulation value with a low weight with a volume percentage of 70 percent to 90 percent and a grain size of 2 mm to 6 mm. This allows geometric adjustment during assembly, for example by conventional sawing, on site, whereby the frost protection apron has a thermal conductivity of Xr = 0.21 W/m · k for a concrete density of e.g. 600 kg/m ³ and a thermal conductivity of Xr = 0.30 W/m · k for a concrete density of e.g. 800 kg/m3. Other concrete densities are possible. (The X _R value provides information about the insulating properties of the polystyrene concrete.)

Furthermore, it is possible to manufacture the building element 1 industrially, in a standardized and grid-sized manner, whereby it is easy to assemble on site and can be endlessly lined up, while at the same time being adapted to the required geometry of the building, whether as a front apron or as a wall crown. This solution is based on the fact that the previously very complex technology for producing a foundation slab for buildings without a basement is rationalized and improved. For example, in order to install the foundation slab, an 80 cm to 90 cm deep trench for strip foundations had to be dug, which had to be manually shuttered, provided with thermal insulation and fitted with at least one sewage sealing sleeve, whereby after the strip foundation had been cast in place and had hardened, the shuttering had to be removed again; only then could the foundation slab be manufactured.

According to the invention, after excavation of the ground (trench), the components 1 are placed in the trench according to the geometric conditions and aligned with one another, whereby the groove 7 and the tongue 8 are in operative connection, then the sealing systems 12 are connected according to the requirements, the free spaces around the adjacent

The lined-up building elements 1 are filled with gravel or soil, in order to then cast these building elements 1 together with the foundation slab 7 using ready-mixed concrete, whereby these cast building elements 1 with the hardened ready-mixed concrete, via the reinforcements 5, with the foundation slab and the cavities 9, hollow chambers 10 and channels 11 filled with ready-mixed concrete, create a firm ground connection, in that the lined-up and firmly connected building elements form the frost protection barrier. It is also conceivable that the building elements 1 can first be cast with in-situ concrete to form a frost protection barrier, in order to then subsequently cast the foundation slab with the frost protection barrier using ready-mixed concrete.

The solution is also based on the fact that the previously complex technology is rationalized and improved when using the building elements to form the wall crown. For example, wall crowns are made using a concrete ring on the masonry or a brick crown, by then positioning or pouring the ceiling, whereby the ceiling rests on part of the lower wall and is limited to the outside by the concrete ring or the brick crown.

According to the invention, the wall crown is formed by the building elements 1 in that the building elements 1 are placed together and on the lower wall using a groove 7 and tongue 8, adapted to the geometric conditions. Then the building elements 1 placed together are cast using in-situ concrete to form a wall crown, whereby the in-situ concrete hardened in the cavities 9 forms a firm connection between the building element and the lower wall. The ceiling is then installed, whereby the reinforcements 5 of the building elements 1 are firmly connected to the ceiling after the ready-mixed concrete has hardened. It is also conceivable that the building elements 1 can be cast with ready-mixed concrete at the same time as the ceiling, whereby after the ready-mixed concrete has hardened, the ceiling and the building elements 1 form a wall crown a unit.

The subsequent wall can then be built onto the top of the wall by creating the static connecting reinforcement using the reinforcement supports 14 of the structural elements 1.

Reference symbols used

1 Component 2 segment 3 Recording area 4 Thermal insulation board 5 Reinforcement 6 Recording segment 7 Groove 8th Feather 9 cavity 10 Hollow chamber 11 channel 12 Sealing system 13 Transport eyes 14 B ewing recording

Claims (6)

9I I·· II*· · · ···< &bull; · &bull; · Protection claims 1. Component for frost protection, characterized in that
a building element 1 consisting of a segment 2, which here serves as a frost protection segment, to which a receiving surface 3, a thermal insulation plate 4, which serves as a contact zone between the foundation plate and the frost protection as thermal insulation and expansion buffer, and reinforcements 5 as static connection reinforcement to the foundation plate and a receiving segment 6 for in-situ concrete, to which a recess as a groove 7 and a projection as a spring 8 are assigned on the front sides, so that the individual building elements 1 can be aligned in a grid dimension-oriented manner, to which cavities 9 which widen conically from top to bottom are assigned in the upper area and trapezoidal hollow chambers 10 which widen downwards are connected in the lower area, which merge into the cavities 9 by the hollow chambers 10 opening into a channel 11 connecting the hollow chambers 10, whereby the cavities 9, the hollow chambers 10 and the channel 11 for receiving the concrete in the cast-in-situ concrete for solid ground contact serve as a load-bearing structural element 1 of the frost protection apron, to which a sealing system 12 is assigned for the connection of the drainage and which has transport eyes 13 in the upper area. 2. Construction element for wall crowns, characterized in that the building element 1 consists of the segment 2, to which the support surface 3 can be assigned to the thermal insulation panel 4, which can be provided as a contact zone between the ceiling and the wall placed on it as thermal insulation and serves as an expansion buffer, and the reinforcement supports 14 for the reinforcements as static connecting reinforcements to the wall placed on top and of the support segment 6 for in-situ concrete, to which a recess as a groove 7 and a projection as a tongue 8 are assigned on the front sides, so that the individual building elements 1 can be aligned in line with the grid dimensions, to which conically widening cavities 9 are assigned from top to bottom which emerge on the lower surface of the structural element 1, whereby the cavities 9 accommodate the reinforcement 5, which serve as static connecting reinforcement for the ceiling, and serve to accommodate the concrete in cast-in-place concrete for a firm ceiling closure as a load-bearing structural element 1 of the wall crown.
3. Component for frost protection according to claim 1, characterized in that that the frost protection layer has a thermal conductivity of Xr = 0.21 W/m.k for a concrete density of e.g. 600 kg/m ³ and a thermal conductivity of Xr = 0.30 W/m.k for a concrete density of e.g. 800 kg/m ³ .
4. Construction element for frost protection aprons and wall crowns, according to claim 1 and claim 2, characterized in that that the construction element (1) is made of lightweight concrete by mixing in recycled waste materials, preferably polystyrene, which has a high thermal insulation value with low weight, with 70 volume percent to 90 volume percent and a grain size of 2 mm to 6 mm. 5. Construction element for frost protection aprons and wall crowns, according to claim 1 and claim 2, characterized in that the geometric adjustment of the component (1) is carried out during assembly by machining.
6. Construction element for frost protection aprons and wall crowns, according to claim 1 and claim 2, characterized in that that the component (1) can be manufactured industrially, in a standardized and grid-sized manner and can be assembled on site to form a frost protection apron or a wall crown. HERE ARE TWO PAGES OF DRAWINGS!