CH716174A2 - Insulated wall element. - Google Patents

Abstract

The invention relates to a wall element with a concrete inner shell (1), an insulating layer (2) spaced from the concrete inner shell (1) and an outer shell (3) resting against the insulating layer (2). According to the invention, the outer shell (3) as a facing shell is connected to the insulating layer (2) via pieces of tissue partially embedded in the outer shell (3). In particular, the outer shell (3) is attached to the insulating layer (2) via pieces of tissue protruding from the outer shell (3) into a slot (11) in the insulating layer (2) on the insulating layer (2).

Description

Insulated wall element

The invention relates to a wall element, with a concrete inner shell, an insulating layer arranged at a distance from and parallel to the inner shell and an outer shell resting against the insulating layer.

Insulated wall elements of this type are known through use. The connection of the inner and outer shell of these known wall construction elements is used to connect lattice girders or bolts, in particular bolts made of glass fiber reinforced plastic, which are partially embedded in the shells and penetrate the insulating layer.

By the present invention, a new wall element of the type mentioned is created, which is characterized in that the outer shell is connected as a facing with pieces of tissue partially embedded in the facing with the insulation layer.

According to the invention, the insulating layer has a supporting function in this wall element. In contrast to the prior art, the outer shell, which is designed as a facing and is connected to the insulating layer via flexible pieces of material, itself does not take on any or only low load-bearing loads.

[0005] A fabric layer, in particular a textile fabric layer, parallel to the wall plane is preferably embedded in the facing shell as reinforcement. In addition to concrete, the material used for the facing shell e.g. plaster or mineral foam can also be considered. At least two pieces of fabric are preferably provided at least in an upper region of the facing shell.

[0006] The pieces of fabric preferably protrude into slots in the insulation layer at an incline to the wall plane. The inclination generates both vertical and horizontal holding forces, which press the facing layer against the insulation layer.

[0007] Preferably, the pieces of fabric in the insulating layer can each be clamped by a wedge-shaped insert that forms a component of the insulating layer.

[0008] Furthermore, projections protruding from the insulating layer preferably engage in the facing shell, with which the facing shell can also be connected.

These projections can be formed by the concrete inner shell with the insulating layer connecting elements, in particular extensions of connecting bolts.

In a further embodiment of the invention, the connecting elements have a widening that engages behind the insulation layer for removing the pressure from in-situ concrete that can be filled between the inner shell and the insulation layer. The widenings of these connecting elements, preferably connecting bolts, preferably made of fiberglass-reinforced plastic, are expediently designed in the form of plates. After the in-situ concrete has softened, the insulation layer is pretensioned against the in-situ concrete by the connecting elements, since the tensile stress of the connecting elements is partially retained after the in-situ concrete has hardened. This increases the static friction of the insulation layer on the in-situ concrete and increases the load-bearing capacity of the insulation layer for the facing layer accordingly.

The invention is explained in more detail below with reference to an embodiment and the accompanying drawings relating to this embodiment. Show it: <tb> Fig. 1 <SEP> shows a part of a wall component according to the invention in a vertical section, and <tb> Fig. 2 <SEP> part of the wall component from FIG. 1 in a side view.

A prefabricated, preferably story-high wall element 15 with a horizontal length of e.g. 4 m has a concrete inner shell 1, an insulating layer 2 arranged at a distance from the plate-shaped concrete inner shell, and an outer shell 3 as a facing layer resting against the insulating layer. In the example shown, the thickness of the inner shell 1 is 4.5 cm, the insulation layer 2 is 10 cm and the thickness of the outer shell 3 is 2 cm. The distance between the concrete inner shell 1 and the insulation layer 2 is 7 cm. Core concrete can be poured into the space 4 formed on site.

The connection between the plate parts 1 to 3 of the component are used in a grid arranged bolts, of which in the partial representation of Fig. 1, a bolt 5 is visible. In the example shown, the bolts 5 consist of a glass fiber reinforced plastic, in particular glass fiber reinforced polyamide. As FIG. 1 also shows, the bolts 5 are embedded with one end at 6 in the concrete of the inner shell 1 and engage behind the insulation layer 2 with a plate-shaped widening 7. An end section 8 of the bolts 5 protruding beyond the plate-shaped widening 7 protrudes into the outer shell 3. In the example 4 to 6 such bolts 5 are provided per square meter.

In the concrete or plaster of the outer shell or facing shell 3, a layer of fabric 9 parallel to the plate plane is embedded as reinforcement, which is formed in the example shown by textile fabric. The fabric layer 9 could e.g. also a plaster base or screed mat made of stainless steel.

According to FIG. 2, pieces of tissue 10 with an end section are also embedded in the outer shell 3, the pieces of tissue forming a connecting tab for connecting the outer shell 3 to the insulation 2.

The pieces of tissue 10 each protrude as shown in FIG. 1 in a slot 11 traversing the insulation layer 2 and preferably with an end portion 12 beyond the slot 11 into the gap 4 that can be filled with core concrete. In the example shown, the slot 11 is limited wedge-shaped insert 13, which forms part of the insulating layer 2 and can be pushed into the insulating layer 2 in the direction of an arrow 14 while the piece of fabric 10 is jammed with the insulating layer 2. It goes without saying that the compressive strength of the insert 13 can differ from the compressive strength of the rest of the insulation layer 2.

The insulation layer 2 is a load-bearing insulation layer that gives the component at least one sufficient strength for transport to the construction site and is also able to hold the facing shell 3 together with the bolts 5. In the vertical alignment of the component according to the installation position, the facing shell 3 is connected on the one hand to the end sections 8 of the bolts 5 embedded therein, while on the other hand both a vertical load is absorbed via the fabric pieces 10 and a compressive force that pulls the facing layer 3 onto the insulation layer 2 is generated perpendicular to the plane of the panel becomes.

The end section 8 can advantageously absorb wind suction forces and prevent the cladding from being broken up in the event of greater temperature gradients. It expediently has a profile. Furthermore, the end section 8 can absorb adhesive forces that occur when the hardened facing concrete is lifted from a form of form.

In the installed state of the wall component 15, the clamped pieces of tissue 10 are also fixed by the embedded end portion 12 in the solidified core concrete. The plate-shaped widenings 7 engaging behind the insulation layer 2 advantageously counteract the concrete pressure of the core concrete.

To produce the wall element 15 described above, the insulation layer 2 is first prefabricated with the bolts 5 inserted in the passages in the insulation layer and placed in a next production step on the still liquid concrete of the poured facing shell 3 after the fabric layer 9 and partially the tissue pieces 10 have been embedded in the concrete of the facing shell 3. In a further step, the fabric pieces 10 are then clamped in the insulating layer 2 by insert pieces 13.

After the facing shell 3 has cured, the insulating layer and facing shell are introduced into the still liquid concrete of the poured inner shell 1 with the ends of the bolts 5 first.

It goes without saying that the facing shell 3 can be profiled for better adhesion to the insulating layer 2. If the adhesion is good, end sections 8 of the bolts 5 protruding into the facing shell 3 can then be dispensed with.

Notwithstanding the embodiment described above, the insert pieces 13 could be omitted and only the pieces of tissue 10 receiving slots 11 be formed in the insulating layer 2. The fabric pieces 10 can consist of the same material as the fabric layer 9 forming a reinforcement or can be made of a material different therefrom. It goes without saying that pieces of tissue are only meant to be flexible pieces of material that are extended over a large area in the manner of tissue.

In one embodiment, the piece of tissue 10 could extend into the inner shell 1, the insert piece 13 then also reaching up to the inner shell 1. During transport and assembly, the wall element could be hung over such a piece of fabric, e.g. on a crane hook.

Claims (11)

1. Wall construction element, with a concrete inner shell (1), an insulating layer (2) arranged at a distance from the concrete inner shell (1) and an outer shell (3) resting against the insulating layer (2), characterized, that the outer shell (3) as a facing shell is connected to the insulating layer (2) via pieces of fabric (10) partially embedded in the outer shell (3). 2. Wall element according to claim 1, characterized, that in the concrete outer shell (3) a fabric layer (9) parallel to the wall plane, in particular a fabric layer, plaster mat or screed mat, is embedded as reinforcement. 3. Wall element according to claim 1 or 2, characterized, that at least two pieces of fabric (13) are provided in at least one upper region of the wall component (15). 4. Wall element according to one of claims 1 to 3, characterized, that the pieces of fabric (10) protrude into a slot (11) in the insulation layer (2) at an incline to the wall plane. 5. Wall element according to one of claims 1 to 4, characterized, that the pieces of fabric (10) are clamped in the insulating layer (2) by a wedge-shaped insert (13) forming a component of the insulating layer (2) and possibly having properties that differ from the rest of the insulating layer (2) in terms of compressive strength. 6. Wall element according to one of claims 1 to 5, characterized, that the piece of fabric (10) protrudes beyond the insulation layer (2) into an intermediate space (4) of the wall construction element (15) to be filled with core concrete, possibly with partial embedding in the concrete of the concrete inner shell (1) up to the concrete inner shell (1) inside. 7. Wall element according to one of claims 1 to 6, characterized, that projections (8) protruding from the insulating layer (2) are also cast into the outer shell (3). 8. wall element according to claim 7, characterized, that the projections (8) are formed by elements connecting the concrete inner shell (1) to the insulating layer (2), in particular by extensions of connecting bolts (5). 9. Wall element according to one of claims 1 to 8, characterized, that the connecting elements (5) have a, in particular plate-like, widening (7) engaging behind the insulating layer (2) for transferring core concrete pressure. 10. Wall element according to one of claims 1 to 9, characterized, that the connecting elements (5) are made of glass fiber reinforced plastic. 11. Wall element according to one of claims 1 to 10, characterized, that the projections (8) are embedded in a projection of the outer shell (3) protruding from the outer shell (3) into the insulating layer (2).