CH701464A1 - Cast wall, floor or ceiling element and method for its production. - Google Patents

Abstract

A cast wall, floor or ceiling element (11) is made of a hardenable cement-based casting compound, in particular of lightweight concrete. The element has a first wall (13) with a first thickness and a second wall (15) of a second thickness and between the first wall (13) and the second wall (15) an insulating layer (17) is provided, which over the entire surface in the Casting compound is poured.

Description

The present invention relates to a cast wall, floor or ceiling element according to the preamble of claim 1 and a method for its production according to the preamble 29th

State of the art

For exposed concrete structures (exterior wall and interior wall with exposed concrete) to date, the process is such that you first concreted an inner supporting shell, then allowed to harden the concrete, the formwork then removed, provides an insulating layer, then the formwork for external formwork and again concreted. The whole thing is very time consuming and expensive because of the many operations that are necessary for the creation of the building. A second variant provides that you create a single-shell construction with internal insulation. However, this has the following disadvantages: 1. very many expensive connection details, e.g. In the case of multi-storey buildings, there is a thermal bridge in the area of the ceiling, which can only be laboriously stripped. 2. the lack of storage mass inside the building. This means that you are less protected from the summer heat and that occur during heating larger temperature excursions.

task

The object of the present invention is to provide a cast wall, floor or ceiling element, in particular a fair-faced concrete element, which has the best possible insulating value for a given wall thickness. The aim is in particular to propose a cast and insulated wall and a method for their production, which can be produced quickly and inexpensively. It is also an objective to propose a monolithic wall both on the inside and on the outside in exposed concrete quality.

According to the invention the object is achieved by a cast wall, floor or ceiling element according to the preamble of claim 1, that the element comprises a first wall with a first thickness and a second wall with a second thickness and that between the first wall and the second wall is provided an insulating layer. The inventive element has the advantage that it can be produced quickly and inexpensively, since it can be cast in a single operation. Also, a subsequent insulation is no longer necessary because the insulation is already integrated in the element.

Advantageously, the element of lightweight concrete with a dry density of not more than 2000 Kg / m <3>, preferably <1500 Kg / m <3> and most preferably <1200 Kg / m <3>. is made. The use of lightweight concrete eliminates the risk that the insulating layer will be compressed. Accordingly, inexpensive available insulation materials can be used. Conveniently, the casting material used is essentially made of cements, binders, foam glass or expanded clay as an additive, and mixing water and additives (additives). A lightweight concrete with foam glass as an additive is disclosed, for example, in EP-A-1 183 218, the content of which is hereby incorporated by reference.

According to a preferred embodiment, the first wall is designed as the static support structure and the second wall as a veneer. In this case, a blanket may be supported on the inner tray, and the outer second wall may be relatively thin. For example, the second wall may have a thickness of between 40 and 140 mm, preferably 50 to 120 mm, and most preferably between 60 and 100 mm. Due to the fact that the inner wall or shell is more strongly formed, that is to say the outer shell, a large storage mass is present in the interior of the building. This has the advantage that the temperature fluctuations inside the building are low due to external temperature fluctuations. However, it is conceivable to assign the outer wall a supporting function and the ceiling, for example. partially supported on the outer shell by cam-like ejection. In this case, the outer wall can be carried over the entire surface or supporting only in partial areas. If only one wall has a supporting function, they can have different strengths.

Preferably, the first wall has a reinforcement made of steel, which is preferably arranged centrally in the wall. This has the advantage that shrinkage stresses can not lead to deformation of the wall. Advantageously, the reinforcement has at least two planes, which are firmly connected to each other by means of spacer elements. Conveniently, prefabricated reinforcing steel mesh or metal baskets, which represent a three-dimensional structure used. Of importance is that the metal baskets are inherently stable and can not be compressed.

Advantageously, at least the second wall has a reinforcement with polymer fibers, preferably in the form of short cut fibers. This has the advantage that can be dispensed with a reinforcement made of reinforcing steel in the second wall. This leads to a significant time savings in the production of the insulated wall. In this case, the proportion of polymer fibers in the second wall between 0.4 to 2.0 Kg / m3, preferably between 0.5 to 1.5 Kg / m3, and very particularly preferably between 0.6 and 0.9 Kg / m3.

Polymer fibers are particularly advantageously a highly crystalline polymer, preferably from the group of polyvinyl alcohols used. These fibers have the advantage that they can form chemical bonds with the casting compound. The polymer fibers used are preferably those which have a tensile strength> 1000 N / mm 2, preferably> 1200 and very particularly preferably> 1500 N / mm 2 and an E modulus> 30 000 N / mm 2, preferably> 35 000 N / mm 2, and very particularly preferably> 40 000.- N / mm 2.

Insulating layer materials are advantageously used, which have a thermal conductivity (lambda D value = λD) ≤ 0.04 W / mK, preferably ≤ 0.035 W / mK and most preferably ≤ 0.03 W / mK. Ideally, insulation boards with a thermal conductivity ≤ 0.029 W / mK are used. As materials in particular plastics come with the exception of polyurethane in question. It has been shown that even mineral fibers (rockwool or glass fiber) are unsuitable because they have too high water absorption capacity. In a preferred embodiment, the insulating layer consists essentially of polystyrene, preferably an expanded or extruded polystyrene rigid foam. Polystyrene insulation boards are available at low cost and generally have sufficient compressive strength.

According to a preferred embodiment insulation boards are used as an insulating layer, which are preferably equipped with a groove and comb. This has the advantage that the insulation can not be moved against each other. It is also conceivable to use the largest possible possible insulation boards. In order to prevent the insulation boards from being compressed during filling with the concrete, the compressive stress at 10% compression is σ10 ≥ 50 kPa, preferably σ10> 150 kPa, and very particularly preferably σ10 ≥ 300 kPa. It can be used depending on floor height plates with different compressive strengths. Plates with a σ10 between about 100 kPa and 250 kPa are ideal since they are relatively inexpensive. It is also advantageous if the insulation boards used as insulating layer have a water vapor diffusion number ≤ ∞, preferably ≤ 250 μ, and most preferably ≤ 50 μ.

In order not to impair the drying of the cast element, the water absorption capacity of the insulating layer should be <4 vol .-%, preferably <1.0 vol .-% and very particularly preferably <0.2 vol .-%. Ideally, the water absorption capacity is 0 V% measured according to the test standard EN 12087. It is important that in case of any water absorption, the insulation board is dimensionally stable. Otherwise, it can lead to tensions and deformations of the cast wall. To avoid shrinkage stresses, the casting compound is preferably admixed with shrinkage reducing agents.

Advantageously, the first wall and the second wall are interconnected by means of coupling bracket. This can prevent the walls from coming off each other. The coupling straps may have a U, Z shape, for example. Conveniently, 0.1 to 0.6 coupling bracket, preferably 0.2 to 0.4 coupling bracket are provided per square meter.

Advantageously, that the cured element has a thermal conductivity <0.16 W / mK.

The present invention is also a method according to the preamble of claim 29, which is characterized in that at a distance from the first reinforcement and the second shuttering wall an insulating layer is arranged, which extends substantially over the entire surface of the shuttering walls, so a first formwork space with reinforcement and a second formwork space without reinforcement is formed, and that the formwork spaces are filled at substantially the same time or with a slight flow for the second formwork space with the curable casting material, so that a first wall and a second wall are formed. The inventive method has the advantage that a wall with a core insulation can be poured in one operation.

The cast wall, floor or ceiling element of the present invention can be used as a vertical component (wall) or lying component (plate). Accordingly, in the context of the present invention, the term "wall" in each case also "plates" are understood. In the latter case, the element is cast horizontally by first casting a disc, then applying the insulating layer and then casting the second disc.

The invention will be explained by way of example with reference to the figures. It shows: <Tb> FIG. 1 <sep> in plan view an embodiment of a novel wall element with a first wall, which usually represents the inner wall, a second wall, which usually represents the outer wall, and a cast between the first and second walls insulating layer; <Tb> FIG. 2 <sep> is a section through the wall element of Fig. 1 along the line A - A; <Tb> FIG. 3 <sep> is a section through the wall element of Fig. 1 along the line B - B; <Tb> FIG. Fig. 4 is an enlarged vertical section through the wall of Fig. 1; and <Tb> FIG. 5 <sep> is an enlarged horizontal section through the wall of FIG. 1.

The wall element 11 shown in Figs. 1 to 3 has a first wall 13, which is usually the inner wall of a multi-walled wall, and a second wall 15, which is usually the outer wall of a multi-walled wall. Between the first and the second wall 13, 15 an insulating layer 17 is arranged, which is in conjunction with the first and second walls 13,15. The first wall 13 is provided with a reinforcement 19 made of reinforcing steel. The reinforcement 19 preferably consists of a three-dimensional, inherently stable structure, e.g. a steel wire basket. The reinforcement 19 has two in each case arranged wire or reinforcing steel networks, which are spaced apart by means of spacers 21. At the lateral ends of the two levels of wire or iron nets are connected by means of U-shaped bracket 23 with each other, so that a per se stable wire or reinforcing steel basket is formed. Preferably, the reinforcement consists of overlapping reinforcing steel nets 24 (Figure 2).

As can be seen from FIG. 1, the first and second walls 13, 15 are connected to one another by means of a plurality of wind anchors 25. The wind anchors 25 may have a U, Z, or any other shape that ensures that the ends of the wind anchors 25 can not be pulled out of the walls under tensile load.

A wall or panel element according to the invention is produced as follows: On a formwork wall (not visible in the figures), first distance-retaining means 27, e.g. in the form of rails, arranged and fixed to the armor 19 (FIGS. 4 and 5). At the distance holding means 27 opposite side of the reinforcement 19 second distance holding means 29, also preferably in the form of rails, attached. Then, the insulating layer 19 is disposed on the second distance-retaining means 29 and fixed by means of plastic dowels 31 to the reinforcement 19 or the rails. As plastic dowel 31 can be used as they are used for the attachment of insulation boards to facades for use. These dowels have a head 33 with a large contact surface. The attachment of the dowel shaft can be done for example by a wire 35. Between individual insulation elements wind anchor 25 can be inserted, which protrude with their ends on opposite sides of the insulation layer. Subsequently, a second shuttering wall is then arranged at a distance from the first shuttering wall and the insulating layer (not shown in the figures). The formwork walls are, depending on the formwork system, e.g. by means of binding points and connecting pipes (spacers) 37 and then the formwork cavities between the shuttering walls and the insulating layer 19 filled with a lightweight concrete mixture.

Wall example (mass in cm): <Tb> total wall thickness: <sep> 44 <tb> Inner Disc: <sep> 16 <tb> Rebar mesh 4-ply with spacer: <sep> <tb> Outer pane without reinforcement mesh: <sep> 12 <tb> Core insulation (EPS plastic): <sep> 16 <tb> Stainless steel coupling bracket <sep> 0.2 / m2 <tb> Lightweight concrete with foam glass chunks and fly ash <sep> <tb> as aggregates, shrinkage reducing agents and <sep> <Tb> synthetic fibers <sep> <tb> Thermal conductivity of total wall (calculated) <sep>

Concrete according to the European standard (SN) EN 206-1 is generally used with the following properties: <tb> Compressive strength class: <sep> LC12 / 13 or better LC8 / 9 <tb> Exposure classes: <sep> XC4 XF1 <Tb> Grösstkornklasse; (all classes): <sep> e.g. Dmax = 8 or Dmax 016, or <tb> <sep> Dmax = 32 <tb> chloride content class: <sep> C1 0.10 <Tb> Consistency class: <sep> <tb> Compaction mass after rolling: <sep> at least C2, better C3, or <tb> Slump: <sep> F3, better range F4 to F6, or <b> Setzmass: <sep> S3 better S4 or S5 <tb> Crude density class: <sep> D1.4 or D1.2 better D 1.0

Legend:

[0023] <Tb> 11 <sep> wall element <tb> 13 <sep> first wall <tb> 15 <sep> second wall <Tb> 17 <sep> insulation <Tb> 19 <sep> reinforcement <Tb> 21 <sep> Spacers <tb> 23 <sep> U-shaped stirrups <Tb> 25 <sep> Wind anchor <tb> 27 <sep> Distance holding means on outer formwork wall <tb> 29 <sep> second spacer between reinforcement and insulation layer <Tb> 31 <sep> plastic anchors <tb> 33 <sep> Head of the dowel <Tb> 35 <sep> Wire <Tb> 37 <sep> connecting pipe

Claims (31)

A molded wall, floor or ceiling element made of a hardenable cement-based casting compound, in particular of lightweight concrete, characterized in that the element comprises a first wall with a first thickness and a second wall with a second thickness and that between the first wall and the second wall is provided an insulating layer. 2. Element according to claim 1, characterized in that the element of lightweight concrete with a dry density of at most 1500 kg / m3. preferably <1200 Kg / m3 and very particularly preferably <1000 Kg / m3 is produced. 3. Element according to spoke 1 or 2, characterized in that the casting material used is essentially made of cements, binders, foam glass or expanded clay as an additive, additives (additives), and mixing water. 4. Element according to any one of claims 1 to 3, characterized in that the first wall is designed as the static support structure and the second wall as a veneer. 5. Element according to any one of claims 1 to 4, characterized in that the thickness of the first wall is greater than the thickness of the second wall. 6. Element according to any one of claims 1 to 5, characterized in that the second wall has a thickness between 40 and 140 mm, preferably 50 to 120 and most preferably between 60 and 100 mm. 7. Element according to any one of claims 1 to 6, characterized in that the first wall has a reinforcement made of steel, which is preferably arranged centrally in the wall. 8. Element according to one of claims 1 to 7, characterized in that the reinforcement has at least two levels, which are interconnected by means of spacer elements. An element according to any one of claims 1 to 8, characterized in that the reinforcement consists of a three-dimensional structure, e.g. Reinforcing steel basket, is formed. 10. Element according to any one of claims 1 to 9, characterized in that at least the second wall has a reinforcement with polymer fibers, preferably in the form of short cut fibers possesses. 11. Element according to spoke 10, characterized in that the proportion of polymer fibers in the second wall between 0.4 to 2.0 Kg / m3, preferably between 0.5 to 1.5 Kg / m3, and most preferably between 0..6 and 1.2 Kg / m3 is. 12. Element according to claim 10 or 11, characterized in that a highly crystalline polymer, preferably from the group of polyvinyl alcohols, are used as polymer fibers. 13. Element according to any one of claims 10 to 12, characterized in that the polymer fibers have a tensile strength> 1000 N / mm2, preferably> T200 and very particularly preferably> 1500 N / mm2 and an E modulus> 30 000N / mm2, preferably> 35,000 N / mm2, and most preferably> 40,000 .-- N / mm2. 14. Element according to any one of claims 1 to 13, characterized in that spacers are provided between the reinforcement and the insulating layer. 15. Element according to any one of claims 1 to 14, characterized in that the insulating layer has a thermal conductivity <0.04 W / mK, preferably <0.035 W / mK and most preferably <0.03 W / mK. 16. Element according to any one of claims 1 to 15, characterized in that the insulating layer is made of a plastic with the exception of polyurethane. 17. Element according to any one of claims 1 to 16, characterized in that insulation boards are used as an insulating layer, which are preferably equipped with a groove and comb. 18. Element according to any one of claims 1 to 17, characterized in that as insulation layer insulation boards with a compression stress at 10% compression Σ10 ≥ 60 kPa, preferably Σ10≥ 150 kPa, and most preferably Σ10-300 kPa are used. 19. Element according to any one of claims 1 to 18, characterized in that insulation boards are used as an insulating layer with a water vapor diffusion number ≤ ∞, preferably ≤ 250 μ, and most preferably ≤ 50 μ, 20. Element according to any one of claims 1 to 19, characterized in that the insulating layer used has a thermal conductivity (lambda d value) less than 0.04 W / mK, preferably <0.036 W / mK, and particularly preferably <0.03 W / Km. 21. Element according to any one of claims 1 to 20, characterized in that the insulating layer consists essentially of polystyrene, preferably an expanded or extruded polystyrene rigid foam. 22. Element according to any one of claims 1 to 21, characterized in that the water absorption capacity of the insulating layer is <4 vol .-%, preferably <1 vol .-% and very particularly preferably <0.2 vol .-%. 23. Element according to any one of claims 1 to 22, characterized in that the insulating layer is substantially dimensionally stable even when water is absorbed. 24. Element according to any one of claims 1 to 23, characterized in that the cast mass Schwindreduktionsmittel are added. 25. Element according to any one of claims 1 to 24, characterized in that the first wall and the second wall are connected to each other by means of coupling bracket. 26. Element according to claim 25, characterized in that the coupling straps have a U, Z shape or spiral anchor. 27. Element according to claim 25 or 26, characterized in that 0.2 to 0.4 coupling straps are provided per square meter. 28. Element according to any one of claims 1 to 27, characterized in that the cured and dried element has a thermal conductivity <0.16 W / mK. 29. Method for producing a concrete wall with the following process carriages: - creating a first formwork wall, Attaching a first reinforcement at a distance from the first formwork, - Optional installation of the reinforcing steel spacer baskets - Optional insertion of the second reinforcement - Optional introduction of the insulating layer - creating a second formwork wall, - Casting the shuttering space between the first shuttering wall and the second shuttering wall with a hardenable casting material, and Curing the casting compound, characterized in that at a distance from the second reinforcement and the second shuttering wall an insulating layer is arranged, which extends substantially over the entire surface of the shuttering walls, so that a first shuttering space with reinforcement and a second shuttering space is formed without reinforcement, and that the shuttering spaces in Are filled substantially simultaneously or with a slight lead for the second formwork space with the curable casting material, so that a first wall and a second wall are formed. 30. The method according to claim 29, characterized in that the casting material for the second formwork space Schwindreduktionsmittel and plastic fibers are added. 31. The method according to claim 29 or 30, characterized in that the cast mass is a lightweight concrete with a dry bulk density of a maximum of 1500 kg / m3. preferably <1200 Kg / m3 and most preferably <1000 Kg / m3 is used.