DE20220509U1 - Building panel comprises two reinforced concrete plates held apart by grids embedded in concrete, the space between plates being filled with insulation and upper plate containing pipes for underfloor heating system - Google Patents

Abstract

Building panel comprises two reinforced concrete plates (12, 14). These are held apart by support grids (16) which are embedded in the concrete. The space between the plates is filled with thermal insulation (24) and the upper plate contains embedded pipes (22) for an underfloor heating system.

Description

Prefabricated component with insulation material and heating pipes embedded in concrete and associated manufacturing process

The invention relates to a prefabricated component for construction engineering in the form of a plate in which two reinforced concrete panes are held at a distance from one another by several lattice girders. The respective lattice girder is concreted into the upper and lower panes. The space between the panes is filled with insulating material. The invention also relates to a method for producing such a prefabricated component.

A prefabricated component according to the preamble of claim 1 is known from EP-A-1 106 745 by the same applicant. The space between the two reinforced concrete slabs is filled with foamed polyurethane. Such a prefabricated component can be used as a ceiling element in prefabricated house construction. These ceiling elements can be manufactured as large-format prefabricated components and can be assembled relatively easily and quickly on a construction site. This avoids complex concreting work. On the construction site, screed is applied to the upper concrete slab in the form of a layer of mortar or mastic asphalt a few centimeters thick. This screed serves as a floor construction and can be covered with a floor covering. The screed is laid by hand.

It is an object of the invention to provide a prefabricated component for construction engineering and a manufacturing method therefor, which, with simple production, provides improved technical applications and increases economic efficiency.

This task is solved for a prefabricated component of the type mentioned above in that the upper disc made of reinforced concrete contains heating pipes of an underfloor heating system embedded in concrete.

In the invention, underfloor heating is incorporated as an integral unit into the panel, which can be used as a ceiling element, floor panel or basement ceiling. In this way, the manual application of screed, which is still required with a conventional panel, and the possible need to embed the heating pipes in this screed can be omitted. The panel manufactured in this way as a prefabricated component is highly economical. The total number of work steps required is reduced because the application of screed is not required during assembly on site. In addition, such a panel offers a high level of comfort for the user of a prefabricated house.

By integrating the heating into the upper concrete slab, a double technical effect is achieved. On the one hand, it serves to improve people's comfort by warming the floor. On the other hand, the heat generated by heating the upper concrete slab ensures that the insulation material in the gap remains dry and that any moisture that penetrates is not a problem.

Furthermore, according to the invention, a method for producing a prefabricated structural component for construction engineering in the form of a plate is specified. In this manufacturing method, an edge formwork is erected on the smooth surface of a steel plate. A lattice girder layer and the necessary longitudinal and transverse reinforcement are arranged within this edge formwork. A lower disc made of reinforced concrete is produced by pouring concrete into the edge formwork and allowing the concrete to harden. Heating pipes for underfloor heating are then attached to the pre-strengthened longitudinal and transverse reinforcement above the lattice girders. An edge formwork for the upper concrete disc is then arranged on the smooth surface of the same steel plate or another steel plate. Concrete is poured inside the edge formwork. The previously manufactured lower concrete disc is rotated by 180° and immersed in the liquid concrete, which is allowed to harden. The two concrete discs are spaced apart from one another with a gap only between them by the lattice girders.

Additional spacers to absorb static forces to maintain the distance between the two concrete slabs are not required.

Embodiments of the invention are explained below with reference to the drawing.

Fig. 1 a cross-section through a perspective view of the structure

a base plate, and

Fig. 2 shows the process sequence in the form of a flow chart during production

of the prefabricated component.

Fig. 1 shows a schematic, perspective view of a cross section through a prefabricated component that can be used as a floor slab, floor slab or basement slab. The prefabricated component 10 has a lower concrete slab 12 and an upper concrete slab 14, which is generally thicker than the lower concrete slab 12. The end sections of lattice girders 16 are concreted into the lower concrete slab 12 together with reinforcement indicated by a cross bar 18. Additional reinforcement bars are not shown for reasons of clarity.

End sections of the same lattice girders 16 are also concreted into the upper concrete slab 14 together with reinforcement, indicated by a cross bar 20. Above the lattice girders 16, heating pipes 22 of an underfloor heating system rest on the reinforcement 20. They are also concreted into the upper concrete slab 14. The lattice girders 16 keep the two concrete slabs 12, 14 at a distance from each other. Additional spacers are not required.

Insulating material 24 is filled into the space between the concrete discs 12, 14. Polyurethane foam, for example, is filled in and cured during production as insulating material. The cured PU foam can support the stability of the entire prefabricated component 10 to a certain extent. Alternatively, polystyrene beads can also be used as insulating material.

Cellulose flakes and/or mineral wool flakes can be used. The loose insulation material can be poured, blown in or vacuumed in.

The outward-facing surface 26 is smooth so that a floor covering can be applied directly to this surface 26. Tiles, parquet flooring or plastic flooring can be used as floor coverings, for example.

Typical dimensions for the prefabricated component are, for example, for the length I approximately 5 m to 13 m and for the width b 2.5 m to 3.5 m. The lower concrete slab 12 can have a typical thickness d3 of 40 mm to 60 mm, preferably of approximately 50 mm; the distance d2 between the two concrete slabs 12, 14 and thus the thickness of the space for the insulation material is in the range of 130 mm to 170 mm, preferably approximately 150 mm; the thickness d1 of the upper concrete slab 14 is in the range of 80 mm to 100 mm, preferably approximately 90 mm.

Further details on the structure of the plate 10 can be found in EP-A-1 106 745 of the same applicant, for example information on the reinforcement and other fastening elements. The content of this patent application is hereby incorporated by reference into the disclosure content of the present application.

Fig. 2 shows the process sequence for producing a prefabricated component according to Fig. 1 in the form of a flow chart. In step S1, a steel pallet is provided to a pallet circulation system. In the following step S2, an edge formwork is erected on the smooth surface of the steel pallet.

In step S3, lattice girders and, if applicable, the lower reinforcement are arranged within the edge formwork and connected to each other.

In step S4, concrete is poured into the edge formwork so that the lower end sections of the lattice girders and the lower reinforcement are embedded in concrete.

·

In the next step S5, the pallet is transported to a drying oven and the concrete hardens. This completes the lower reinforced concrete pane.

In the next step S6, the upper reinforcement and the heating pipes for underfloor heating are attached to the lattice girders. This reinforcement layer serves as a support level for fixing the heating pipes.

In a further step S7, an edge formwork for the upper concrete slab is arranged on the smooth surface of the steel plate of another pallet.

In the next step S8, concrete is poured inside this edge formwork.

The previously manufactured concrete disc is rotated by 180° so that the cast-in lattice girders with their outward-facing end sections can be immersed in the liquid concrete (step S9).

Then, in step S10, the pallet is conveyed into the drying oven and the concrete is cured. This creates a slab in which the two concrete slabs are held at a distance from each other with a gap between them by the lattice girders.

Loose insulation material such as polystyrene beads, cellulose flakes or mineral wool flakes can now be filled into the gap by filling, blowing or sucking it in. Alternatively, PU foam can be filled in and cured. It is also possible to fill in PU foam after the lower concrete slab has been made and allow it to cure. Only then do the work steps mentioned above in step S6 take place.

Claims (13)

1. Prefabricated structural component in the form of a panel,
in which two discs ( 12 , 14 ) made of reinforced concrete are held at a distance (d2) from each other by several lattice girders ( 16 ),
the respective lattice girder ( 16 ) is concreted into the upper and lower panes ( 12 , 14 ),
and in which the space between the panes ( 12 , 14 ) is filled with insulating material ( 24 ),
characterized in that the upper disc ( 14 ) contains heating pipes ( 22 ) of an underfloor heating system embedded in concrete. 2. Prefabricated component according to claim 1, characterized in that at least one of the panes, preferably both panes ( 12 , 14 ), contains a reinforcement made of steel ( 18 , 20 ). 3. Prefabricated component according to claim 1 or 2, characterized in that PU foam is used as the insulating material. 4. Prefabricated component according to claim 1 or 2, characterized in that polystyrene beads, cellulose flakes and/or mineral wool flakes are provided as insulating material. 5. Prefabricated component according to one of the preceding claims, characterized in that the surface ( 26 ) of the upper concrete slab ( 14 ) is designed such that a floor covering can be applied directly to it. 6. Prefabricated component according to claim 5, characterized in that tiles, carpet, parquet flooring or plastic flooring is used as the floor covering. 7. Prefabricated component according to one of the preceding claims, characterized in that it has a width of 2.5 m to 3.5 m. 8. Prefabricated component according to one of the preceding claims, characterized in that it has a length of 5 m to 13 m. 9. Prefabricated component according to one of the preceding claims, in which the upper pane ( 14 ) with the heating lines ( 22 ) is thicker than the lower pane ( 12 ). 10. Prefabricated component according to one of the preceding claims, characterized in that the lower pane ( 12 ) has a thickness of 40 mm to 60 mm, preferably about 50 mm. 11. Prefabricated component according to one of the preceding claims, characterized in that the upper pane ( 14 ) has a thickness of 80 mm to 100 mm, preferably about 90 mm. 12. Prefabricated component according to one of the preceding claims, characterized in that the distance (d2) between the two panes is in the range of 130 mm to 170 mm, preferably about 150 mm. 13. Prefabricated component according to one of the preceding claims, characterized in that the heating lines ( 22 ) rest on the upper reinforcement ( 20 ) for the upper pane ( 14 ).